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Leukemia, Acute Myeloid OMIM

Fong et al. (2015) used primary mouse hematopoietic stem and progenitor cells immortalized with the fusion protein MLL-AF9 (see 159555) to generate several single-cell clones that demonstrated resistance, in vitro and in vivo, to the prototypical bromodomain and extra terminal protein (BET) inhibitor I-BET. Resistance to I-BET conferred cross-resistance to chemically distinct BET inhibitors such as JQ1, as well as resistance to genetic knockdown of BET proteins. ... Fong et al. (2015) demonstrated that resistance to BET inhibitors, in human and mouse leukemia cells, is in part a consequence of increased Wnt/beta-catenin (see 116806) signaling, and negative regulation of this pathway results in restoration of sensitivity to I-BET in vitro and in vivo. ... Rathert et al. (2015) performed a chromatin-focused RNAi screen in a sensitive MLL-AF9;Nras(G12D)-driven AML mouse model to identify factors involved in primary and acquired BET resistance in leukemia. The screen showed that suppression of the Polycomb repressive complex-2 (PRC2; see 606245), contrary to effects in other contexts, promotes BET inhibitor resistance in AML. ... This process involved the activation and recruitment of WNT (see 606359) signaling components, which compensated for the loss of BRD4 and drove resistance in various cancer models. Additional studies revealed that BET-resistant states are characterized by remodeled regulatory landscapes, involving the activation of a focal MYC enhancer that recruits WNT machinery in response to BET inhibition. Rathert et al. (2015) concluded that their results identified and validated WNT signaling as a driver and candidate biomarker of primary and acquired BET resistance in leukemia, and implicated the rewiring of transcriptional programs as an important mechanism promoting resistance to BET inhibitors and, potentially, other chromatin-targeted therapies.

RUNX1, CEBPA, MECOM, FLT3, GATA2

Nut Midline Carcinoma Wikipedia

One of the most helpful and characteristic findings is the focal abrupt squamous differentiation, where stratification and gradual differentiation are absent, resembling a Hassall corpuscle of the thymus. [6] The defining feature of NMCs is rearrangement of the NUT gene. [4] Most common is a translocation involving the BRD4 gene and NUT gene (t(15;19)(q13;p13.1)). [5] [7] Treatment [ edit ] BET inhibitors are used for treatment [ citation needed ] Prognosis [ edit ] NUT midline carcinoma is very resistant to standard chemotherapy treatments. ... Specific molecular targeted therapies ( BET inhibitors and histone deacetylase inhibitors (HDACi)) may help to yield growth arrest of the neoplastic cells. [6] Overall, there is a mean survival of 6–9 months. [8] [9] See also [ edit ] BET inhibitor Mediastinum References [ edit ] ^ RESERVED, INSERM US14-- ALL RIGHTS.

BRD4, NUTM1, MYC, AFP, CDK9, SMARCA4, DNER, NSD3, HDAC9, CIC, SF3B1, ZNF532, CD274, SYP, MIR145, MIR99A, MIR3140, TP63, SMARCB1, SOX2, CCNT1, ROS1, BRD2, PIK3CG, PIK3CD, PIK3CB, PIK3CA, EZH2, EP300, EGFR, CDKN2A, CDK4, H3P10

Chemical Eye Injury Wikipedia

"Towards evidence based emergency medicine: best BETs from the Manchester Royal Infirmary. BET 4: use of litmus paper in chemical eye injury".

Cerebral Amyloid Angiopathy, App-Related OMIM

A number sign (#) is used with this entry because cerebral amyloid angiopathy (CAA) can be caused by mutation in the gene encoding the amyloid precursor protein (APP; 104760). Mutations in the APP gene can also cause autosomal dominant Alzheimer disease-1 (AD1; 104300), which shows overlapping clinical and neuropathologic features. ... Revesz et al. (2003) reviewed the pathology and genetics of APP-related CAA and discussed the different neuropathologic consequences of different APP mutations. ... In 4 affected members of an Italian family with cerebral amyloid angiopathy, Obici et al. (2005) identified a mutation in the APP gene (104760.0019). In 2 brothers from an extensive Iowa kindred with progressive dementia and cerebroarterial amyloidosis, Grabowski et al. (2001) identified a heterozygous mutation in the APP gene (N694D; 104760.0016). ... Human APP mRNA was detected in neurons and neuronal processes, but not in vessel walls. ... Herzig et al. (2006) extended their earlier studies by developing several murine models of APP-related CAA and APP-related parenchymal amyloid deposition.

APP, APOE, PAOX, SMOX, DELEC1, TSHZ1, SCRN1, BHLHE40, TGFBR2, TGFB1, PSEN1, SERPINF2, SERPINF1, NOTCH3, SMAD2, LAMC2, CST3, CSF2, CRP, LINC01672

Abeta Amyloidosis, Iowa Type Orphanet

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.
Abeta Amyloidosis, Dutch Type Orphanet

Etiology HCHWA-D is due to a mutation in the APP gene on chromosome 21q21.2, encoding the beta-amyloid precursor protein. ... Genetic testing reveals a mutation in the APP gene. Differential diagnosis Differential diagnoses include other conditions that could cause intracerebral hemorrhage such as coagulopathies, vasculitis (see these terms), CNS neoplasms, cerebral vascular malformations, ischemic stroke and antecedent trauma.
Hereditary Cerebral Amyloid Angiopathy MedlinePlus

The Dutch type is the most common, with over 200 affected individuals reported in the scientific literature. Causes Mutations in the APP gene are the most common cause of hereditary cerebral amyloid angiopathy. APP gene mutations cause the Dutch, Italian, Arctic, Iowa, Flemish, and Piedmont types of this condition. ... Familial British and Danish dementia are caused by mutations in the ITM2B gene. The APP gene provides instructions for making a protein called amyloid precursor protein. ... Additionally, the ITM2B protein may be involved in processing the amyloid precursor protein. Mutations in the APP , CST3 , or ITM2B gene lead to the production of proteins that are less stable than normal and that tend to cluster together (aggregate). ... Learn more about the genes associated with Hereditary cerebral amyloid angiopathy APP CST3 ITM2B Inheritance Pattern Hereditary cerebral amyloid angiopathy caused by mutations in the APP , CST3 , or ITM2B gene is inherited in an autosomal dominant pattern , which means one copy of the altered gene in each cell is sufficient to cause the disorder.
Abetal34v Amyloidosis Orphanet

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.
Abetaa21g Amyloidosis Orphanet

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.
Abeta Amyloidosis, Arctic Type Orphanet

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.
Abeta Amyloidosis, Italian Type Orphanet

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.

Inclusion Body Myositis OMIM

The authors discussed the abnormalities of APP processing, the role of abnormal intracellular protein folding, oxidative stress, and the potential role of cholesterol in the pathogenic cascade of IBM. ... Accumulation of the amyloid-beta peptide, which is derived from proteolysis of the larger beta-APP, seems to be an early pathologic event in both Alzheimer disease and IBM; in the latter, it occurs predominantly intracellularly within affected myofibers. To elucidate the possible role of beta-APP mismetabolism in the pathogenesis of IBM, Sugarman et al. (2002) selectively targeted beta-APP overexpression to skeletal muscle in transgenic mice, using the muscle creatine kinase promoter. They reported that older (more than 10 months) transgenic mice exhibited intracellular immunoreactivity to beta-APP and its proteolytic derivatives in skeletal muscle. In this transgenic model, selective overexpression of beta-APP led to the development of a subset of other histopathologic and clinical features characteristic of IBM, including centric nuclei, inflammation, and deficiencies in motor performance.

GNE, NT5C1A, APP, TARDBP, HLA-DRB1, SQSTM1, APOE, KHDRBS1, NUP62, DCTN4, GTF2H1, SDC1, CDR3, GSN, MAPT, TRBV20OR9-2, HLA-C, PLAAT4, FYCO1, MSTN, TNFRSF12A, NFAT5, CCR2, UBB, MALAT1, VCP, RBM45, AOC3, DCD, UCN2, DNAJB6, OPTN, KLRG1, MAP1LC3A, LILRB1, KDELR1, ICOSLG, SYNM, ROBO3, DDX58, CHMP1B, PABPC1, TIMP1, RRM2B, TWNK, FOXP3, KRT20, TTR, ACTB, THBS1, CST3, HLA-DQA1, HK1, H1-0, NR3C1, EPHB2, EMD, DES, CD47, TGFB1, CD38, CD36, CD34, MS4A1, CAPN3, BCL2, AOC2, HLA-DRB3, HMGB1, IFN1@, IFNG, TRIM21, AGER, MOK, PTPRC, PSME1, PSMB10, MAPK1, POLG, PMP22, MMP9, MMP1, MLF1, LMNA, IL6, IL1B, LOC102723996

Inclusion Body Myositis Orphanet

Inclusion body myositis (IBM) is a slowly progressive degenerative inflammatory disorder of skeletal muscles characterized by late onset weakness of specific muscles and distinctive histopathological features. Epidemiology IBM has a highly variable prevalence according to geographic, ethnic and age criteria. Prevalence in the general population ranges from 1:1,000,000 to 1:14,000 but a three-fold increase is observed when considering only a population over 50 years. Underdiagnosis may be an explanation for the high ethno-geographic variation. Male-to-female ratio is 2:1 on average (0.5 to 6.5:1). Clinical description IBM onset is over 50 years but may also occur earlier, in the 5th decade.
Inclusion Body Myositis Wikipedia

Inflammatory muscle disease in older adults This article needs additional citations for verification . Please help improve this article by adding citations to reliable sources . Unsourced material may be challenged and removed. Find sources: "Inclusion body myositis" – news · newspapers · books · scholar · JSTOR ( September 2009 ) ( Learn how and when to remove this template message ) Inclusion body myositis Other names sIBM Specialty Rheumatology Inclusion body myositis ( IBM ) ( / m aɪ oʊ ˈ s aɪ t ɪ s / ) (sometimes called sporadic inclusion body myositis , sIBM ) is the most common inflammatory muscle disease in older adults. [1] The disease is characterized by slowly progressive weakness and wasting of both proximal muscles (closest to the body's midline) and distal muscles (the limbs), most apparent in the finger flexors and knee extensors . [2] IBM is often confused with an entirely different class of diseases, called hereditary inclusion body myopathies (hIBM). [3] [4] The "M" in hIBM is an abbreviation for "myopathy" while the "M" in IBM is an abbreviation for "myositis". These diseases should not be confused with each other. In IBM, two processes appear to occur in the muscles in parallel, one autoimmune and the other degenerative. Inflammation is evident from the invasion of muscle fibers by immune cells .
Idiopathic Inflammatory Myopathy MedlinePlus

Idiopathic inflammatory myopathy is a group of disorders characterized by inflammation of the muscles used for movement (skeletal muscles). Idiopathic inflammatory myopathy usually appears in adults between ages 40 and 60 or in children between ages 5 and 15, though it can occur at any age. The primary symptom of idiopathic inflammatory myopathy is muscle weakness, which develops gradually over a period of weeks to months or even years. Other symptoms include joint pain and general tiredness (fatigue). There are several forms of idiopathic inflammatory myopathy, including polymyositis, dermatomyositis, and sporadic inclusion body myositis. Polymyositis and dermatomyositis involve weakness of the muscles closest to the center of the body (proximal muscles), such as the muscles of the hips and thighs, upper arms, and neck.
Inclusion Body Myositis GARD

Inclusion body myositis (IBM) is a progressive muscle disorder characterized by muscle inflammation, weakness, and atrophy (wasting). It is a type of inflammatory myopathy . IBM develops in adulthood, usually after age 50. The symptoms and rate of progression vary from person to person. The most common symptoms include progressive weakness of the legs, arms, fingers, and wrists. Some people also have weakness of the facial muscles (especially muscles controlling eye closure), or difficulty swallowing (dysphagia). Muscle cramping and pain are uncommon, but have been reported in some people.

Angioedema Induced By Ace Inhibitors, Susceptibility To OMIM

Clinical Features Blais et al. (1999) and Adam et al. (2002) reported significantly lower plasma aminopeptidase P (APP) activities in patients with a history of AEACEI. ... Measured genotype analysis strongly suggested that the linkage signal for APP activity at this locus was accounted for predominantly by the SNP association. ... There was a significant association between the -2399A allele and decreased serum APP activity in both men and women, but the APP activity was lower in men regardless of genotype. ... This haplotype was associated with decreased plasma APP activity and decreased luciferase gene expression compared to other haplotypes of these SNPs. Cilia La Corte et al. (2011) concluded that the ATG haplotype of XPNPEP2 is functional and contributes to the development of ACEi-angioedema through a reduction in APP activity.

SERPING1, KNG1, ACE, AGT

Acquired Angioedema GARD

Acquired angioedema (AAE) is a rare disorder that causes recurrent episodes of swelling (edema) of the face or body, lasting several days. People with AAE may have swelling of the face, lips, tongue, limbs, or genitals. People with AAE can have edema of the lining of the digestive tract, which can cause abdominal pain and nausea, as well as edema of the upper airway, which can be life-threatening. Swelling episodes may have various triggers, such as mild trauma (such as dental work), viral illness, cold exposure, pregnancy, certain foods, or emotional stress. The frequency of episodes is unpredictable and can vary widely. There are two forms of AAE.
Acquired Angioedema Orphanet

A rare disease characterized by the occurrence of transitory and recurrent subcutaneous and/or submucosal edemas resulting in swelling and/or abdominal pain due to an acquired C1 inhibitor (C1-INH) deficiency. Epidemiology Prevalence is unknown. Clinical description Onset most commonly occurs after 50 years of age. Patients present with white, circumscribed nonpruritic edemas that remain for a period of 48 to 72 hours and recur with variable frequency. The edemas may involve the digestive tract resulting in a clinical picture similar to that seen in intestinal occlusion syndrome, sometimes associated with ascites and hypovolemic shock. Laryngeal edema can be life-threatening with a risk of death of 25% in the absence of appropriate treatment.
Acquired C1 Esterase Inhibitor Deficiency Wikipedia

Acquired C1 esterase inhibitor deficiency Other names Acquired angioedema Specialty Hematology Acquired C1 esterase inhibitor deficiency presents with symptoms indistinguishable from hereditary angioedema , but generally with onset after the fourth decade of life. [1] : 153 C4 levels are low and C3 levels are normal. [2] See also [ edit ] Hereditary Angioedema Wheal response Urticaria Skin lesion List of cutaneous conditions References [ edit ] ^ James, William; Berger, Timothy; Elston, Dirk (2005). Andrews' Diseases of the Skin: Clinical Dermatology . (10th ed.). Saunders. ISBN 0-7216-2921-0 . ^ Markovic SN, Inwards DJ, Frigas EA, Phyliky RP (January 2000). "Acquired C1 esterase inhibitor deficiency". Ann. Intern. Med . 132 (2): 144–50. doi : 10.7326/0003-4819-132-2-200001180-00009 . PMID 10644276 . External links [ edit ] Classification D ICD - 10 : D84.1 ( ILDS D84.112) MeSH : C538173 External resources eMedicine : article/104888 v t e Lymphoid and complement disorders causing immunodeficiency Primary Antibody / humoral ( B ) Hypogammaglobulinemia X-linked agammaglobulinemia Transient hypogammaglobulinemia of infancy Dysgammaglobulinemia IgA deficiency IgG deficiency IgM deficiency Hyper IgM syndrome ( 1 2 3 4 5 ) Wiskott–Aldrich syndrome Hyper-IgE syndrome Other Common variable immunodeficiency ICF syndrome T cell deficiency ( T ) thymic hypoplasia : hypoparathyroid ( Di George's syndrome ) euparathyroid ( Nezelof syndrome Ataxia–telangiectasia ) peripheral: Purine nucleoside phosphorylase deficiency Hyper IgM syndrome ( 1 ) Severe combined (B+T) x-linked: X-SCID autosomal: Adenosine deaminase deficiency Omenn syndrome ZAP70 deficiency Bare lymphocyte syndrome Acquired HIV/AIDS Leukopenia : Lymphocytopenia Idiopathic CD4+ lymphocytopenia Complement deficiency C1-inhibitor ( Angioedema / Hereditary angioedema ) Complement 2 deficiency / Complement 4 deficiency MBL deficiency Properdin deficiency Complement 3 deficiency Terminal complement pathway deficiency Paroxysmal nocturnal hemoglobinuria Complement receptor deficiency This cutaneous condition article is a stub .

Alzheimer Disease 18 OMIM

Q170H and R181G mutant mice showed significant attenuation of APP processing compared to wildtype, with a decrease in APP-CTF-alpha levels and an increase in sAPP-beta levels, indicating that the mutations attenuated Adam10 alpha-secretase activity on APP. Crossing these Adam10 mutant mice with the Tg2576 AD mouse model showed that the Adam10 mutations increased amyloidogenic APP processing, as manifest by a shift from the alpha-secretase to the amyloidogenic beta-secretase pathway. ... Collectively, these findings suggested that diminished alpha-secretase activity of ADAM10 on APP resulting from mutations in the ADAM10 prodomain can cause AD-related pathology.

ADAM10, PSEN2

Early-Onset Alzheimer's Disease Wikipedia

This loss of brain volume affects ones ability to live and function properly, ultimately being fatal. [5] Beta-amyloid is a small piece of a larger protein called the amyloid precursor protein (APP). Once APP is activated, it is cut into smaller sections of other proteins. ... Alpha-secretase cleavage of APP, which precludes the production of Aβ, is the most common processing event for APP. 21 allelic mutations have been discovered in the APP gene. These guarantee onset of early-onset familial Alzheimer disease and all occur in the region of the APP gene that encodes the Aβ domain. ... "A pathogenic mutation for probable Alzheimer's disease in the APP gene at the N-terminus of beta-amyloid". ... PMID 16817891 . ^ Chow VW, Mattson MP, Wong PC, Gleichmann M (March 2010). "An overview of APP processing enzymes and products" .

Alzheimer Disease OMIM

See also APP-related cerebral amyloid angiopathy (CAA; 605714), which shows overlapping clinical and neuropathologic features. ... Genetic analysis identified a mutation in the APP gene (V717I; 104760.0002). Farlow et al. (1994) reviewed the clinical characteristics of the disorder in the AD family reported by Murrell et al. (1991) in which affected members had a mutation in the APP gene (V717F; 104760.0003). ... Rovelet-Lecrux et al. (2006) estimated that in their whole cohort of 65 ADEOAD families, the frequency of the APP locus duplication was roughly 8% (5 of 65), which corresponds to half of the contribution of APP missense mutations to ADEOAD. ... Revesz et al. (2003) reviewed the pathology and genetics of APP-related CAA and discussed the different neuropathologic consequences of different APP mutations. ... Further studies indicated that suppression of PPARGC1A in hyperglycemia resulted in activation of the FOXO3A (602681) transcription factor, which inhibits nonamyloidogenic secretase processing of APP and promotes amyloidogenic processing of APP.

TOMM40, TREM2, ABCA7, APP, APOE, PSEN2, PSEN1, MAPT, SORL1, PRNP, CASP3, BACE1, GSK3B, NCSTN, IDE, IL1B, HFE, A2M, ACE, DHCR24, BIN1, ESR1, ADAM10, ADAMTS1, PGRMC1, VEGFA, ARC, CYP46A1, SLC30A4, VSNL1, PICALM, HMOX1, HLA-DRB5, IGF1R, IGF1, INPP5D, IGF2, MPO, NPY, NOS3, PLAU, PLCG2, PPARG, RELN, MTHFR, PYY, NECTIN2, SLC2A4, IGF2R, SOD2, MAOB, TF, LEP, TFAM, INSR, INS, TNF, TPI1, EPHA1, F2, ENO1, CR1, CASS4, ATP5F1A, CLU, CHRNB2, CHRNA7, MIR766, CD33, IQCK, EIF2S1, MIR505, APOC1, CALM1, MIR100, MIR146A, BDNF, BCL2, MIR375, MIR296, BCHE, MIR708, TPP1, SLC30A6, SNAR-I, DPYSL2, ACHE, CD2AP, GAPDHS, PCDH11X, CYP2D6, MIR4467, CRH, MIR3622B, BAX, AMFR, ABI3, CST3, MS4A4A, WWOX, BRCA2, FANCD2, TFF1, TAS2R64P, CTNNB1, SUCLA2, SNCA, CTSD, RNR2, NEFL, TAS2R62P, SOD1, ITPR3, ITPR2, ITPR1, FLAD1, PSENEN, TP53, CDK5R1, EIF2AK3, UBQLN1, ALG3, PIK3CG, PIK3CA, PIK3CD, SERPINA3, PIK3CB, DOCK3, APLP1, OGDH, CREB1, NOTCH1, CASP6, NGF, CCND1, FOS, DLX4, DLG4, DDIT3, RABGEF1, PEBP1, PYCARD, DAPK2, KCNIP3, CTSB, CSF2, CRMP1, CTSG, EHMT2, ENO2, ERBB4, TMED10, TERF2IP, PTK2B, FCN2, PTGES3, FGF2, ACKR1, DNM1L, SDC3, G6PD, GCHFR, ITM2B, CREBBP, MAP3K8, TRPM7, ADI1, MTCO2P12, UPK3B, ACTB, AKT1, AKT2, ANXA1, APBB1, DNLZ, STS, MIR34A, BRCA1, MIR137, C5AR1, DDR1, CAMK4, TMED10P1, MPEG1, C9orf72, ESCO1, CDCA5, PRRT2, MAP1LC3B, CAT, EHMT1, CNR2, SPPL2B, RAB9A, NRXN3, GFAP, SYNJ1, SERPINB5, CD99, MME, MNAT1, CCL2, RRAS, RPS27, RPS21, RAP1A, PYCR1, COX2, PTS, PTGS2, MTHFD1, MMUT, NCAM1, NFIA, NFIB, MAPK8, MAPK3, PRKCB, PRKCA, PPBP, MED1, NFIC, PPARA, NFIX, PKD1, NOTCH3, NRGN, MEOX2, MEF2A, SPRR2A, TTC3, GRIN2A, DENR, GRIN2B, RAB7A, LRP8, HPRT1, HSP90AA1, VIM, IDUA, UTRN, SUMO1, UBE2I, TTK, TPT1, SULT1E1, IL1A, IL6, IL12A, TSPAN6, TIE1, TGFB1, TG, KNG1, LAMC2, LGALS3, TERT, TERC, STIM1, H3P17

Alzheimer Disease 13 OMIM

For a general phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease, see 104300. Mapping Liu et al. (2007) conducted a genome screen of 103 patients with late-onset AD who were ascertained as part of the Genetic Research in Isolated Populations (GRIP) program that was conducted in an isolated population from the southwestern area of the Netherlands. Genealogic information resulted in an extremely large and complex pedigree of 4,645 members. The pedigree was split into 35 subpedigrees to reduce the computational burden of linkage analysis. The strongest evidence for linkage, hlod = 5.20 at marker D1S498, was obtained at chromosome 1q21 (AD13).
Early-Onset Autosomal Dominant Alzheimer Disease GARD

There are three subtypes of early-onset familial AD which are each associated with changes (mutations) in unique genes: (1) Alzheimer disease, type 1 is caused by mutations in the APP gene (2) Alzheimer disease, type 3 is caused by mutations in the PSEN1 gene (3) Alzheimer disease, type 4 is caused by mutations in the PSEN2 gene.
Alzheimer Disease 11 OMIM

For a general phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping By genomewide linkage analysis of 466 families with late-onset AD, including 730 affected sib pairs, Pericak-Vance et al. (2000) identified a candidate disease locus on chromosome 9p22.1 (nonparametric maximum lod score of 2.97 at marker D9S741). Analysis of a subset of 199 families in which there was at least 1 autopsy-confirmed AD case yielded a higher lod score of 4.31 at the same marker. Scott et al. (2003) reexamined 437 white AD families included in the original report by Pericak-Vance et al. (2000) by considering age of onset as a covariate. Ordered-subsets analysis included continuous covariates in linkage analysis by rank ordering families by a covariate and summing lod scores.
Alzheimer Disease 6 OMIM

In HEK293 cells with an AD-associated APP mutation (104760.0008), overexpression of SORCS1 resulted in a significant decrease in amyloid-beta-40 and -beta-42 secretion, whereas suppression of SORCS1 in HEK293 cells increased beta-amyloid-40 levels. The findings indicated that SORCS1 can influence APP processing, and Reitz et al. (2011) suggested that variation in the SORCS1 gene may be associated with risk of LOAD. ... The findings indicated a role for calcium signaling in APP (104760) processing and suggested that variations in the CALHM1 gene may influence susceptibility to late-onset AD.
Alzheimer Disease 5 OMIM

For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping In a late-onset form of familial Alzheimer disease (AD), Pericak-Vance et al. (1997) identified linkage to a locus on chromosome 12. From a series of multiplex families affected with late-onset AD (at least 60 years) ascertained during the previous 14 years and for which DNA had been obtained, Pericak-Vance et al. (1997) selected a subset of 16 families (with 52 AD patients) to use for a genomewide screen. A second subset of 38 families (with 89 AD patients) was used for a follow-up analysis. Linkage analysis was performed using both genetic model-dependent (lod score) and model-independent methods.
Alzheimer Disease, Familial Early-Onset, With Coexisting Amyloid And Prion Pathology OMIM

Clinical Features Leuba et al. (2000) described a Swiss family whose members presented with standard clinical and neuropathologic features of Alzheimer disease (104300) and, in particular, severe neurofibrillary tangle degeneration present in the hippocampus and in several cortical areas, together with a large number of beta-amyloid deposits and senile plaques. The brain pathology of 5 deceased members of this family, from 2 generations, represented a coexisting beta-amyloid and prion protein (PrP; 176640) pathology. Frequent beta-amyloid-positive senile plaques were observed, together with senile plaques stained by the monoclonal antibody against PrP(106-126). In all 5 cases, the cerebral cortex showed spongiform changes, mainly in the superficial layers, with some degree of gliosis. Successive sections showed that both beta-amyloid- and PrP-positive senile plaques were deposited in all layers of the frontal and temporal cortex.
Alzheimer Disease 8 OMIM

Within this candidate region, 1 gene of particular interest was that encoding cystatin-3 (CST3; 604312), because it is known to be an amyloidogenic protein and is codeposited with the amyloid-beta precursor protein (APP; 104760) in amyloid plaques in the brain of AD patients. Using a covariate-based linkage method, Olson et al. (2001) showed that the APP region on chromosome 21q21 is strongly linked to AD-affected sib pairs of the oldest current age (i.e., age either at last exam or at death) who lacked E4 alleles at the apolipoprotein E (APOE; 107741) locus. ... Two-locus analysis provided evidence of strong epistasis between 20p and the APP region, limited to the oldest age group and to those lacking E4 alleles at the APOE locus.
Alzheimer Disease 2 OMIM

Onset was early in 4 other families tested; 2 had chromosome 21 APP (104760) mutations and 2 showed linkage to chromosome 14, thus representing AD1 (104300) and AD3 (607822), respectively.
Early-Onset Autosomal Dominant Alzheimer Disease Orphanet

Etiology EOAD is the consequence of either PSEN1 mutations (69%), APP mutations (13%), or APP duplication (7,5%), and exceptionally of PSEN2 mutations (2%).
Alzheimer Disease 4 OMIM

A number sign (#) is used with this entry because Alzheimer disease-4 (AD4) is caused by heterozygous mutation in the presenilin-2 gene (PSEN2; 600759) on chromosome 1q42. For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease, see 104300. Clinical Features Bird et al. (1988) described 5 German kindreds with an autosomal dominant early-onset form of Alzheimer disease. All families were descendants of a group of immigrants, known as the Volga Germans, who came to the United States between 1870 and 1920. Their ancestors had moved from Germany to the southern Volga region of Russia in the 1760s.
Familial Alzheimer Disease GARD

There are three subtypes of early-onset familial AD which are each associated with changes (mutations) in unique genes: (1) Alzheimer disease, type 1 is caused by mutations in the APP gene (2) Alzheimer disease, type 3 is caused by mutations in the PSEN1 gene (3) Alzheimer disease, type 4 is caused by mutations in the PSEN2 gene.
Alzheimer Disease 15 OMIM

For a general phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease, see 104300. Mapping Liu et al. (2007) conducted a genome screen of 103 patients with late-onset AD who were ascertained as part of the Genetic Research in Isolated Populations (GRIP) program that was conducted in an isolated population from the southwestern area of the Netherlands. Genealogic information resulted in an extremely large and complex pedigree of 4,645 members. The pedigree was split into 35 subpedigrees to reduce the computational burden of linkage analysis. They found significant evidence of linkage of AD to 3q22-q24 (AD15), in a region of 18 cM from D3S3514 to D3S3626 that reached a maximum hlod of 4.44 at marker D3S1579.
Alzheimer Disease 14 OMIM

For a general phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease, see 104300. Mapping In a genome screen of individuals from an isolated population from the southwestern area of the Netherlands, ascertained as part of the Genetic Research in Isolated Populations (GRIP) program, Liu et al. (2007) found the strongest evidence of linkage for chromosome 1q21 (AD13; 611152). Approximately 30 cM upstream of this locus, at 1q25, another peak (AD14) was found (hlod = 4.0 at marker D1S218). Liu et al. (2007) noted that these 2 loci were in a linkage region spanning 1q21-q31 identified by Zubenko et al. (1998), Hiltunen et al. (2001), Myers et al. (2002), and Blacker et al. (2003). Haplotype analysis showed that the 2 linkage peaks on chromosome 1q21 and 1q25 are explained by different haplotypes, of 15 cM and 21 cM, respectively, segregating in different families.
Alzheimer Disease 12 OMIM

For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping Giedraitis et al. (2006) conducted a genome scan with 369 microsatellite markers in 12 extended families collected in Sweden. Age at disease onset ranged from 53 to 78 years, but in 10 of the families there was at least 1 member with age at onset of less than 65 years. Mutations in known early-onset Alzheimer disease susceptibility genes were excluded. All persons were genotyped for APOE (107741), but no clear linkage with the E4 allele was observed.
Alzheimer Disease 3 OMIM

In 2 Belgian families with early-onset autosomal dominant AD, Van Broeckhoven et al. (1987) excluded linkage to the APP locus on chromosome 21q. One pedigree contained 36 patients in 6 generations, and the second had 22 patients spanning 5 generations.
Alzheimer Disease 10 OMIM

For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping In an extended multiplex family, ascertained in a population-based study of early-onset AD in the northern Netherlands, Rademakers et al. (2005) obtained conclusive evidence of linkage of AD with a candidate region of 19.7 cM at 7q36. They identified a shared haplotype at 7q36 between the index family and 3 of 6 multiplex AD-affected families from the same geographic region, which was indicative of a founder effect and defined a priority region of 9.3 cM. Mutation analysis of coding exons of 29 candidate genes identified only an exonic silent mutation in the PAXIP1 gene (608254), 38030G-C in the exon 10 genomic sequence, which affected codon 626. It remained to be determined whether PAXIP1 has a functional role in the expression of AD in the index family or whether another mutation at this locus explained the observed linkage and sharing.
Alzheimer Disease 7 OMIM

For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping In a systematic survey of the human genome in patients with AD, Zubenko et al. (1998) identified D10S1423, located at 10p13, as a candidate susceptibility locus. The allelic associations in this survey were observed in independent samples of autopsied AD cases and controls from geographically disparate sites (Boston and Pittsburgh). Majores et al. (2000) replicated these findings by identifying an association of the D10S1423 234-bp allele with AD in an ethnically homogeneous group of 397 German AD cases and controls. Zubenko et al. (2001) described a prospective, longitudinal, double-blind assessment of the age-specific risk of AD encountered by 325 asymptomatic first-degree relatives of AD probands who carried the D10S1423 234-bp allele, the APOE E4 allele (107741), or both, after 11.5 years of systematic follow-up.

Compulsive Gambling Mayo Clinic

If you have a problem with compulsive gambling, you may continually chase bets that lead to losses, use up savings and create debt. ... Tell yourself it's too risky to gamble at all. One bet typically leads to another and another. ... Recognize and then avoid situations that trigger your urge to bet. Family members of people with a compulsive gambling problem may benefit from counseling, even if the gambler is unwilling to participate in therapy.

DRD3, PLTP, DRD2, DRD4, SCLY, KRT7, TAL1, SLC6A3, BDNF, CHPT1, FZD10, CIT, TRIM31, BAG3, VLDLR, MAOB, OPRM1, COMT, MAOA, LEP, HTR2A, HTR1B, DRD1, DBH, CREB1, DHDDS

Gambling, Pathologic OMIM

Inheritance Eisen et al. (1997, 1998) studied 3,359 mono- and dizygotic U.S. male twin pairs who had served in the military and found that inherited factors explained between 37 and 55% of the prevalence of 5 individual symptoms of pathologic gambling (attempts to wind back losses at same place, gambling larger amounts than intended, repeated efforts to reduce or stop gambling, frequent preoccupation with gambling, and increase betting to maintain interest) from DSM-III-R for which data was informative.
Problem Gambling Wikipedia

urge to continuously gamble despite harmful negative consequences or a desire to stop Problem gambling Other names Ludomania, degenerate gambling, gambling addiction, compulsive gambling, gambling disorder Specialty Psychiatry , clinical psychology Symptoms Spending a lot of money and time in casino/sports betting, Video game addiction [1] Addiction and dependence glossary [2] [3] [4] [5] addiction – a biopsychosocial disorder characterized by persistent use of drugs (including alcohol) despite substantial harm and adverse consequences addictive behavior – a behavior that is both rewarding and reinforcing addictive drug – a drug that is both rewarding and reinforcing dependence – an adaptive state associated with a withdrawal syndrome upon cessation of repeated exposure to a stimulus (e.g., drug intake) drug sensitization or reverse tolerance – the escalating effect of a drug resulting from repeated administration at a given dose drug withdrawal – symptoms that occur upon cessation of repeated drug use physical dependence – dependence that involves persistent physical– somatic withdrawal symptoms (e.g., fatigue and delirium tremens ) psychological dependence – dependence that involves emotional–motivational withdrawal symptoms (e.g., dysphoria and anhedonia ) reinforcing stimuli – stimuli that increase the probability of repeating behaviors paired with them rewarding stimuli – stimuli that the brain interprets as intrinsically positive and desirable or as something to approach sensitization – an amplified response to a stimulus resulting from repeated exposure to it substance use disorder – a condition in which the use of substances leads to clinically and functionally significant impairment or distress tolerance – the diminishing effect of a drug resulting from repeated administration at a given dose v t e Problem gambling is an urge to gamble continuously despite negative consequences or a desire to stop. ... These authors point out that social factors may be a far more important determinant of gambling behaviour than brain chemicals and they suggest that a social model may be more useful in understanding the issue. [29] For example, an apparent increase in problem gambling in the UK may be better understood as a consequence of changes in legislation which came into force in 2007 and enabled casinos, bookmakers, and online betting sites to advertise on TV and radio for the first time and which eased restrictions on the opening of betting shops and online gambling sites. [30] Pathological gambling is similar to many other impulse control disorders such as kleptomania . [31] According to evidence from both community- and clinic-based studies, individuals who are pathological gamblers are highly likely to exhibit other psychiatric problems concurrently, including substance use disorders , mood and anxiety disorders , or personality disorders . [32] Pathological gambling shows several similarities with substance abuse. ... Jackson and Shane A.Thomas a survey done from 1994–2008 in Tasmania gave results that gambling participation rates have risen rather than fallen over this period. [53] Prevalence [ edit ] Europe [ edit ] In Europe, the rate of problem gambling is typically 0.5 to 3 percent. [54] The "British Gambling Prevalence Survey 2007", conducted by the United Kingdom Gambling Commission, found approximately 0.6 percent of the adult population had problem gambling issues—the same percentage as in 1999. [55] The highest prevalence of problem gambling was found among those who participated in spread betting (14.7%), fixed odds betting terminals (11.2%), and betting exchanges (9.8%). [55] In Norway, a December 2007 study showed the amount of present problem gamblers was 0.7 percent. [56] With gambling addiction on the rise and across Europe in particular, the voices calling gambling a disease has been gaining grounds. ... PMID 25167843 . ^ "Problem Gaming" (PDF) . European Gaming and Betting Association . Retrieved April 4, 2012 . ^ a b Wardle, Heather; Sproston, Kerry; Orford, Jim; Erens, Bob; Griffiths, Mark; Constantine, Rebecca; Pigott, Sarah (September 2007).

Alzheimer's Disease Wikipedia

The hypothesis holds that an amyloid-related mechanism that prunes neuronal connections in the brain in the fast-growth phase of early life may be triggered by ageing-related processes in later life to cause the neuronal withering of Alzheimer's disease. [64] N-APP, a fragment of APP from the peptide's N-terminus , is adjacent to beta-amyloid and is cleaved from APP by one of the same enzymes. N-APP triggers the self-destruct pathway by binding to a neuronal receptor called death receptor 6 (DR6, also known as TNFRSF21 ). [64] DR6 is highly expressed in the human brain regions most affected by Alzheimer's, so it is possible that the N-APP/DR6 pathway might be hijacked in the ageing brain to cause damage. ... Osaka mutation A Japanese pedigree of familial Alzheimer's disease was found to be associated with a deletion mutation of codon 693 of APP. [65] This mutation and its association with Alzheimer's disease was first reported in 2008. [66] This mutation is known as the Osaka mutation. ... A β is a fragment from the larger amyloid precursor protein (APP). APP is a transmembrane protein that penetrates through the neuron's membrane. APP is critical to neuron growth, survival, and post-injury repair. [103] [104] In Alzheimer's disease, gamma secretase and beta secretase act together in a proteolytic process which causes APP to be divided into smaller fragments. [105] One of these fragments gives rise to fibrils of amyloid beta, which then form clumps that deposit outside neurons in dense formations known as senile plaques . [98] [106] AD is also considered a tauopathy due to abnormal aggregation of the tau protein .

APP, ACE, TREM2, ADAM10, APOE, PSEN1, GSK3B, HFE, MAPT, PLAU, NPY, BCL2, CASP3, BDNF, IDE, INSR, IL1B, LEP, BACE1, IGF2, IGF1R, ATP5F1A, INS, BAX, CR1, A2M, ABCA7, TOMM40, CD2AP, BIN1, EPHA1, CLU, PICALM, NOS3, PSEN2, APOC1, MPO, SORL1, VSNL1, INPP5D, NECTIN2, MS4A4A, PCDH11X, CASS4, BCHE, MIR146A, CYP46A1, DHCR24, CHRNA7, NCSTN, VEGFA, DPYSL2, PRNP, ESR1, PPARG, RELN, HMOX1, ACHE, CST3, MAOB, TNF, MTHFR, IGF1, CD33, TFAM, IL6, CYP2D6, CRH, SOD2, UNC5C, PLCG2, TF, ABI3, WWOX, SLC30A6, CHRNB2, ARC, PGRMC1, F2, CALM1, EIF2S1, HLA-DRB5, ENO1, TPI1, IGF2R, SLC30A4, MIR296, SLC2A4, MIR100, IQCK, MIR375, AMFR, SNAR-I, ADAMTS1, MAPK14, PIN1, PYY, PTGS2, S100B, PPARGC1A, NOS2, NGFR, NGF, NFE2L2, SOD1, SYP, CDK5, NGB, MIR505, GAPDHS, MME, MAP2, CTNNB1, TPP1, LRP1, IRS1, CHAT, GAPDH, MIR4467, MIR3622B, AGER, MIR766, MIR708, CAV1, NTRK2, PTGS1, APLP2, ADAM17, MFN2, DNM1, HSF1, GSR, IL33, CCR5, HSPD1, HSPB1, CIB1, CASP8, IKBKB, SERPINF1, ATP7A, MT2A, ADAM9, INS-IGF2, BCL2L2, CASP9, GAB2, PTK2B, PLCB1, ABCA1, GRN, CASP12, SQSTM1, FERMT2, HLA-DRB1, NFIC, CSF1R, APOB, MARK4, HSPG2, MS4A6A, CELF1, VCP, SYNJ1, ZCWPW1, MS4A4E, APH1B, APOC2, F13A1, EXOC3L2, PLXNA4, ADAMTS4, AKAP9, MADD, DST, PILRA, FRMD4A, LAMP1, SLC24A4, GLIS3, SPON1, CADPS2, IL34, COL18A1, TRIP4, SPI1, TGFB2, BCL3, MTHFD1L, AICDA, IL6R, DCHS2, MEGF10, SLC16A7, EPHX2, NDUFAF6, DSG2, OSBPL6, CELF2, UBE2L3, SPPL2A, MAPK7, CDH13, LAMA1, SGK1, SUCLG2, LUZP2, PTPRG, ST6GAL1, AP2A2, RBFOX1, SORCS3, TSPOAP1-AS1, TLN2, ZAP70, ALDH1A2, TCF7L2, FMN2, OTOF, EXOC4, HSD17B10, DNM1L, ALOX5, GULOP, HTR2A, AHCYL1, SDR42E2, HTR6, GTF2H1, GRM5, IAPP, AHSA1, STAG3, ALB, FARP1, TSHZ1, HRES1, AGFG2, DCAF7, SIGMAR1, BCKDK, RTN3, TPPP, HSPA4, HCLS1, HSP90AA1, G3BP1, PGAM5P1, BACE1-AS, KHDRBS1, ALDH2, CFH, HCRT, GPC6, ABCA8, GLP1R, NR3C1, TNRC6A, IL19, PARVB, DDX25, BZW2, FCN2, FGF10, GOLIM4, LINC00476, HPGDS, FANCD2, PDE7B, SIGLEC7, TSPAN16, TRPC4AP, POLDIP2, CNTNAP2, RNF19A, BACE2, UBQLN1, ITSN2, GRIN2B, ZGLP1, BCAS3, EPDR1, TMED9, ENO2, CYCS, ANXA1, EPHB2, EPO, RAPGEF6, APH1A, LARS1, EYA4, SNX9, ESR2, WAC, SLC8A1-AS1, DCTN4, RMDN1, QPCT, MTOR, SGK3, FBXL7, SZT2, GIP, ACSL6, WWC1, CLEC16A, KAZN, LINC01672, PRRC2C, COLGALT2, PLD3, HECW1, ZNF292, MYO16, DKK1, SIRT2, ACOT7, PSIP1, CLASRP, LINC00271, SIRT3, SIRT1, GFAP, NUP62, FYN, CBLC, INHCAP, TRIM51CP, GABPA, GABRA2, GABRG3, DAPK2, SMUG1, GAP43, GATA1, GCG, GCHFR, TARDBP, NCS1, GDNF, HDAC6, RAB3D, MVP, OGG1, LINC02268, LINC02325, SOAT1, ACTG2, ACTG1, SNCG, SNCA, SNCB, SNAP25, NOS1, ACTB, MEF2C-AS1, SLC6A4, NPC1, SLC6A3, GEMIN7-AS1, SLC1A2, LINC01508, LINC01725, NEFL, COX2, TNFRSF1B, STAG3L5P, TLR4, TLR2, MSH2, THY1, MT3, TH, SST, STAG3L5P-PVRIG2P-PILRB, TGFB1, TFF1, RNR2, LINC02653, LINC01712, TCF3, NRGN, CX3CL1, ELMO1, CCL2, PIK3CG, ABCA2, PLA2G1B, EIF2AK2, SERPINA3, PLG, MAPK8, MAPK1, PRKCB, PRKCA, PRKAB1, PRKAA2, PRKAA1, PMS2P1, POLD1, PTPA, PON1, PIK3CD, PIK3CB, PIK3CA, MOK, UPK3B, SORT1, ROS1, SERPINE1, REST, REN, RELB, RAC1, LINC01965, PVR, PVALB, PTPRA, LINC00972, ABCB1, LINC02008, MTCO2P12, TP53, OVCH1-AS1, MOBP, MNAT1, SLC4A8, AGT, INSIG1, AZIN1-AS1, EIF3E, FHL5, IRF2, GSTO1, ITM2B, GRAP2, LIPG, ADIPOQ, KL, MSC, LRAT, AP4M1, CCRL2, IL18, IL17A, IL12A, ST18, IFNG, ARL17B, AKT1, AIF1, KRBOX1, IGFALS, HDAC9, PHF14, IL10, IL1A, ALOX12-AS1, MICAL2, IL2RB, IL4, CLOCK, CXCL8, KCNN2, MPZL1, HERC2, VDR, TFEB, MAOA, COX10-AS1, ZNF232, YWHAZ, VLDLR, PARP1, UTRN, BCAM, UCHL1, UBB, TYROBP, AFF1, TTR, TRPM1, MMP9, AIMP2, LTBP2, KNG1, CRADD, CACNA1G, LAMC2, RPSA, CDK5R1, SUCLA2, LCN2, LDLR, BECN1, LPL, PDE5A, ABCB11, APOC4-APOC2, KHSRP, DENR, AGPS, LPA, CDKAL1, PPARA, MEIKIN, COL4A4, CRK, CEACAM22P, SCIMP, CREB1, CR1L, ZNF862, SH2D4B, CP, PNPLA7, SIMC1, GGACT, COMT, COL12A1, FAM181A, BRCA2, PPP1R37, GPR141, TENM3-AS1, CNR2, L3MBTL4, UBXN11, ACKR2, TMEM132C, CASTOR3, CLPTM1, STRADA, FNIP1, CDCA5, NLRP3, APOA1, CRMP1, KAT8, CSMD1, CLMN, PINK1, CYP8B1, AHNAK, MIR132, MIR107, CUX1, POTEM, PPP1R3B, FAS, SAP30L, ANKRD55, CTSD, CTSB, GEMIN7, EHMT1, LINC01184, CTNNA2, LINC01185, TMC5, THSD4, CCDC134, SP6, LINC01567, PDCD1LG2, SETD7, APOD, BHMG1, CSF2, HYI, BLOC1S3, TSPO, CHRNA4, CHRNA2, TAS2R62P, C3orf67, C9orf72, CCDC83, CCDC89, KDM1B, CD14, TGM6, ATXN7L1, RSPO4, ADGRF2, STH, TAS2R64P, CALHM1, RUNX1T1, PPP1R42, ALPK2, PCSK9, CAT, ANKRD31, CASP6, NKAIN3, TRIQK, CALB1, STEAP1B, CASP1, EPHA1-AS1, CAPN1, APOC4, FAM181A-AS1, NKPD1, SPRED2, CD36, SCARB1, PLPP4, MED12L, ARAP2, CHN2, CHI3L1, ACTBL2, C10orf71, MCIDAS, LRRK2, AKR1C4, ANO4, AGBL1, CEACAM20, ZNF813, RMDN3, CETP, CDR1, LINC00343, TCAM1P, APOC1P1, IGSF23, RMDN2, CDK1, SLC25A48, NKAIN2, FSIP1, CD68, BMPER, C3, CD40, CYP19A1, CRP, NIT2, ANO3, DLG4, ARHGAP20, RCAN1, WDR41, NDUFA12, STK32B, EDEM2, DSCAML1, RNF165, SH3RF1, DYRK1A, MIR29A, SYBU, AQP4, APBB1, DLX5, DBN1, PALM2AKAP2, CEACAM19, DPP4, IL6-AS1, ARVCF, CDC42SE2, DMXL1, TULP4, DAPK1, PMS2CL, POTEKP, MIR34A, VAT1L, OLR1, HDAC2, LRP8, GSN, CCL11, S100A9, COL25A1, POTEF, KLK6, BLMH, HSD17B7, P2RX7, COX8A, ABCB6, PRRT2, IL2, SORCS1, NR1I2, MAPK3, ITGAM, CASR, ATP7B, VDAC1, EGR1, PDE4A, RAB5A, SUMO1, NRG1, OXER1, NTRK1, TFCP2, ANK1, CSNK1D, DLST, APLP1, BLVRA, NFIB, IL1RN, HTT, ACAT1, PLA2G4A, NFIX, NLRP1, GPRC6A, HMGCR, PPID, LPAR3, FZD4, REG1A, MRGPRX1, LRP2, DBH, PSENEN, VPS35, ESCO1, HSD11B1, VN1R17P, SOX2, AGTR1, XBP1, MIR155, MRGPRX4, MRGPRX3, GAL, GPR151, IL13, PAEP, OGDH, GPR166P, STAT3, SET, NFIA, PLB1, AR, LGR6, DHRS11, ABCG2, C4A, KCNIP3, HSD17B13, ABCG1, TTBK1, NOTCH1, EIF2AK3, SLCO6A1, CHMP2B, RBM45, CD44, RIPK1, APBA1, GSTK1, ADNP, ICAM1, BRCA1, APCS, TNFRSF1A, NFKB1, CNTF, MMP3, KLC1, LBP, CTNNA3, SGSM3, FGF2, C4B, HIF1A, CREBBP, SERPINA1, TMEM106B, GRIA1, GRIA2, ECE1, C4B_2, GSAP, OGA, TFRC, PLA2G6, ST3GAL4, PAWR, MFAP1, KAT5, GSTM1, APRT, COX1, HP, NTF3, MIR206, FPR2, CDC42, FUS, MARK1, FGF1, PREP, C5AR1, PON2, MIR29C, CALB2, PDIK1L, SYK, S100A1, CH25H, SREBF2, COX5A, GRIN2A, VCAM1, TMED10, GSTP1, KLK8, PHF1, CXCL10, MEFV, SP1, GJA1, IGFBP3, SLC17A7, CYP3A4, FOXO3, HMGA1, SLC11A2, XPR1, MARK2, PPIF, CRHR1, SHANK3, MYC, CD40LG, CPOX, FKBP5, ANPEP, CAST, C1D, FKBP4, HSPA1A, FLT1, MIF, PLA2G2A, CX3CR1, CSF3, IFNB1, KALRN, PLTP, STXBP3, DDR1, PWAR1, PRDX2, TP63, VIM, IL23A, F2RL3, MMP14, MEF2C, TREM1, TMED10P1, NAT2, MIR342, SAMD9, RAB7A, PGR-AS1, TRPM2, EGFR, ADRB2, CLDN5, ETS2, SYT1, TIMP1, NME8, ELANE, F2R, CD59, EPHA4, CBS, MSMB, APLN, MMP2, MYCL, CALML5, SYN1, XRCC1, TGM2, EEF2, PLA2G7, ELAVL2, EDN1, TMEM97, HMGB1, MIR455, HTRA1, BPIFA2, SLC52A2, NQO1, TUBA1B, FOS, CRYAB, SLC2A1, GPR3, LGMN, SLC2A3, RIDA, FN1, ABCA4, HSPA1B, PECAM1, PTEN, HSPA8, HLA-A, PTPN1, HAMP, TXNIP, GRM2, P4HB, LIN28A, PSPH, GSTT1, CCN2, DECR1, CPLX1, BCYRN1, NES, POU5F1P4, MIR21, GRK5, POU5F1, NTSR1, MIR212, PRKN, LINC02210-CRHR1, HSPA5, DLD, DAB1, HTRA2, POU5F1P3, MIR137, DNAH8, MAPK10, GH1, SERPING1, ADAMTS2, EEF2K, GSTO2, ROCK2, NEDD9, SPTBN1, NTN1, CEBPD, GDF2, CEBPB, PWAR4, SYNM, IGFBP2, GLUL, ABCC9, ATM, PSPN, PTPRC, MIR29B1, RANBP9, NDRG2, CNR1, RTN4R, PTBP1, AQP1, PDK1, MIR106B, PDE4D, ARNTL, PRDX1, ADM, RENBP, POMC, PTPN4, MS, PDGFRB, P2RY2, MIR142, PDE9A, SSTR4, KLK3, BCL2A1, C2, SRPK2, NFATC2, ADCYAP1, LRRTM3, PLD1, NUBP1, MIR424, ATF4, BSG, MIR29B2, PPY, BMP4, TBP, SLC18A3, POLB, NOTCH3, SLC18A2, NPTX2, MTR, SI, MIR222, SH3GL2, ND2, NR4A2, SELENOP, CXCL12, CCL5, ATXN1, CALM3, ITGAX, IFNA13, DISC1, OPTN, HTR1F, HTR4, WNT3A, COL11A2, C20orf181, IFNA1, KEAP1, HDAC4, KLK4, SEMA6A, LRRC4, CRTC1, IL9, DAO, ALOX15, AGTR2, IDO1, SLC25A27, ABCG4, CD55, APOA4, MCOLN1, REM1, ATCAY, EBPL, HSPB2, HSPA9, PLK2, GAD1, NANOG, DCX, COASY, UBE2K, DDIT3, TREML2, APBB2, MAP1LC3B, SRRM2, GZMB, FXN, HNRNPA1, HPSE, RAB10, CIP2A, FOLH1, STIM2, DIO2, MMP24, CEBPZ, GBA, CDR2, ITPR3, CDKN2A, MELTF, SLC30A3, ADRA2B, FTO, FNDC5, GGA3, XPNPEP1, VGF, NR1H2, UGCG, MFGE8, MGAT3, CXCR4, TLR9, APOC3, GPT, ELK3, NEAT1, ADORA2A, MMEL1, TRPC6, EIF4E, CAMK2A, MS4A6E, SRR, HSPA14, IRS2, MGAM, C1orf52, HDAC3, PABPC4, ACKR3, LGALS3, FAM20C, WNK1, DRD4, CYP2C9, MBTPS1, DRD1, LRP6, GRK2, CYP2B6, OGT, LIPA, AD11, GORASP1, PTGDS, SPEN, MIR200B, NPTXR, DNMBP, MIR200A, NCOA6, MIR181C, RBP4, RELA, OPN1LW, EFHD2, MIR188, TPH1, HNRNPA1P10, CTNNBL1, SLC40A1, PNO1, CHCHD2, SDF4, RETN, GOLM1, PPP3R1, PYCARD, PAG1, CCR2, DDIT4, RCBTB1, SBNO1, PPARD, CD274, PCBP4, ACE2, PROS1, PRND, PPP1R15A, CIZ1, MIR26B, TPSG1, GGA1, CFAP97, MAP2K1, AATF, SHANK2, PRL, RBMS3, LOC107987479, MAP2K2, PAXIP1, CHCHD10, SBNO2, PTGES, SPHK1, LPAR2, PPIG, NRXN3, MED23, SPP1, MAPK8IP1, BAG3, APBA3, TAP2, PRDX6, CARTPT, SNAP91, SV2A, MALAT1, MAK16, SYVN1, GDF11, TAC1, TAT, SLC6A2, TRPV1, CISD3, TPT1, TSC2, TM7SF2, TXN, UBE2I, TLE1, TIMP2, XK, CNTN2, TGFBR2, YY1, GOLGA6A, ANP32A, TAM, TERT, DCP1B, TNFSF10, PPP1R1B, GPHN, RGS2, ADAM30, SAA1, METAP2, IMMT, SDS, ADAP1, RYR3, ECHDC3, RYR2, RXRA, SCD, RPS6KB1, CIT, RPS6, CTXN3, LMTK2, NLGN1, ROCK1, RGS4, ATXN2, SRL, STUB1, SHBG, LILRB2, AKR1A1, OLFM1, SKIL, SLC9A6, CREB3, PITRM1, SCGN, CXCR6, OCM, RIN3, SGCA, SFPQ, NCKAP1, CPLX2, TP73, EDAR, CCL3, NPS, BEST1, HPS1, CXCL1, GLO1, LIF, CDH1, LHCGR, CDK4, PCNA, PCK1, L1CAM, GPR42, GPX1, GRB2, ANGPT1, ANGPT2, CETN1, MYD88, GLB1, AKT2, LMNA, DNMT3B, TSC22D3, CD38, PER1, CD69, DRD3, LOX, CD74, LMNB1, DNM2, GAS6, AVP, GC, DMRT1, SARDH, GRIN1, ANXA5, BACH1, P2RY1, INPPL1, CSF1, CS, NEFM, NTS, APEX1, STS, HTC2, NEUROD1, NPTX1, NPPA, ATF2, HTR2C, ARRB2, IGFBP7, HMGCS2, CLK1, CKB, APBA2, CYP17A1, GSTM3, CHGA, CYBB, JUN, CTSS, ORM1, ITPR1, CHRM1, CHRM2, OPRK1, OPRD1, CTRL, HK1, ADRB1, LAMP2, CASP2, EDNRA, PLD2, CAPN2, F2RL1, ACO1, ERBB4, FAT1, FGFR3, CALM2, BRS3, CALCA, CAD, EGF, CASP4, FCGR3B, FDPS, LYZ, FCGR3A, FLNA, MECP2, FABP3, ADRA1A, PLXNA2, MBP, FAAH, ENPEP, F12, BAG1, MEOX2, HOMER1, ITGB2, DBA2, ITGAL, ITGB1, AIM2, AZIN2, CD80, ITIH4, CD46, VIP, CHRNA3, ATG5, TREML1, MCL1, GPRASP2, VWF, APOA5, TMEM119, KLF4, SOCS6, WNT1, XBP1P1, FOXQ1, C3AR1, OPN4, USF1, C1QA, CXCR2, VPS26A, MOGAT3, CCR3, IL6ST, IL5, IL1RAP, LMF2, IL1R1, CREB3L1, UNG, MCU, CLSTN3, SNPH, IL9R, NPEPPS, NAPSA, USF2, MEF2A, ING1, CGB8, FTMT, CHM, VAV1, IMPA1, C1R, ILK, ADAMTS3, IL16, MAP3K5, IL15, GDF15, CGB5, CA2, KCNB1, TSPOAP1, SMAD2, DPPA2, SGO1, LIG3, IFNL3, TNK1, CP20, APCDD1, HSD17B6, CDKN1A, TTBK2, CDKN1B, SLC2A14, CFLAR, STMN1, LIPC, TAB3, CHIT1, BRAP, SPARCL1, MLKL, PTCRA, CD47, LGR5, CD8A, CCT, NR4A3, USP9X, MSRB3, CDR3, CCK, LNPEP, CASP7, CHRFAM7A, CAMP, PER3, YES1, CGA, MARK3, CGB3, SYNGR1, CALCR, IL1RL1, ARHGEF2, PER2, SLC33A1, TPH2, CHEK1, RAB7B, NOG, MBL2, CFL2, HSPB6, AHSA2P, SLC30A1, CD200R1, SOCS3, KDR, KIF5A, HAP1, CALR, CES1, TRPA1, HSPB3, WASF1, SLC32A1, ARHGEF7, CAMK4, COL3A1, H3P40, SCRN1, PTCD1, SPHK2, ATN1, PPIL2, POU2F1, FOSB, GCA, FLT4, SH2B1, APPL1, DNMT1, FLG, FOXO1, DUSP1, DUSP6, HHAT, HSPB8, E2F1, PLXNA3, DOCK2, PNPLA2, ADI1, GMFB, GPI, GPC1, KIF21B, NMNAT2, TRIB3, ALS2, DLG2, DLG3, GLS, PDSS2, ASTN2, MCF2L, GLI2, KIDINS220, CBLIF, SYNE1, DMD, GGT1, FKBP1A, SIT1, SV2C, GDE1, FOXP3, ASCC1, TMED7, FIS1, PRLH, CRYL1, ADIPOR1, LSR, F11, MBL3P, SIRT6, TRMO, NRN1, LCMT1, PRRX2, ERN1, BIN2, UBR5, HEBP1, GEMIN4, PDCD4, TBK1, SLC25A38, FGF14, PCSK1N, TRPM7, DLL1, FLVCR1, AHI1, SETD2, ELK1, IL22, NCAPH2, ELN, PADI1, BPTF, NRBF2, FABP5, EP300, PLA2G3, GRHL3, CXCR3, NAV3, SIRPB1, FLOT1, MET, KCNMB2, CRISPLD2, ARHGAP24, HNMT, SNX27, NPL, BHLHB9, TRIM13, HMOX2, KLF2, CSNK1E, LPAL2, CPQ, PPP1R2C, RAPGEF3, TET1, CRYZ, SORBS3, CTBP1, BCL2L11, COL17A1, NCAPD2, COX10, UBASH3B, NR1I3, ACOT8, PTPN5, PPP1R9B, TOM1, MINDY4, CPE, HTR7, NR1H3, HTR1B, HTR1A, LRPPRC, PDIA6, RHBDD1, NAA25, HLA-C, TPX2, BCAN, ADAMTS13, MOAP1, TNMD, GRIA3, NEUROD6, CHEK2, PADI2, HRH3, PHB2, SIL1, MGLL, FFAR1, GADD45A, MMRN1, DEFA1, IL21, NLRC4, GPR17, AZI2, HHIP, CTF1, HCRTR2, HLA-B, CTNND2, HHEX, HGF, CTSG, HDAC1, CTCF, DHX40, PTGES3, STIP1, CTSZ, CXADR, CARD14, CYP1A2, PDE10A, LILRB1, EHMT2, PDIA2, UMOD, ANGPT4, MIR339, SYN2, MSD, ACP3, APEH, ST8SIA1, AZU1, PI4KA, NCAM1, MIR144, SMIM10L2B, MSI1, NAP1L1, PRSS3, PEBP1, MASP1, SIM2, TIA1, MIR15B, ATD, RPL29, ABCC1, NCAM2, MIR125A, TLR5, SERPINF2, TNFAIP1, CXADRP1, MAPK9, ZFHX3, GGTLC4P, AD10, SGCG, MIR451A, CDR1-AS, TPTEP2-CSNK1E, MIR384, ITSN1, CBSL, MPZ, NFATC4, PKM, NCL, NTF4, LOC643387, SLC1A3, APOA2, THAS, PSMB6, SERPINB6, PSMB9, RHOA, ARMCX5-GPRASP2, SMPD1, REG3A, ATP4A, MIR193B, RFC1, NOTCH4, SLPI, PGF, AEBP1, MIR214, MIR219A1, SLC19A1, MIR22, PCSK1, ALPP, AMD1, MTNR1A, TGFBR1, COX3, ATP12A, NM, ADD3, PSD, TGM1, ARR3, NPM1, PAK1, TMED7-TICAM2, PNP, MIR195, MTHFD1, ADH1B, AMPH, ND4, AMD1P2, ARG1, SULT2A1, RRAS, PDE7A, TTPA, TYK2, TXNRD1, PPP1R1A, PPP1R10, SPG7, SPAST, RAB4A, PPP2CA, OTC, PPP2R2B, MMP1, ARMS2, RAB3A, GGTLC3, RTL1, P2RX4, ST13, SPARC, ALAS1, PPP3CA, NEFH, SEL1L, TYR, RAB6A, MICB, PPIA, CCL4, BST1, TICAM2, BNIP3, MIR326, OPRL1, PON3, BMP6, OPRM1, AHSG, H3P17, SDC2, AGRN, TYRP1, PPP1CA, BMI1, TYRO3, PNMT, DEFA1B, GGT2, ORI6, SMIM10L2A, CISD2, ARSA, EIF2AK4, PRKAR1A, LRP1-AS, SRSF2, MIR98, MIRLET7B, CD200, PDCD1, RAP1A, GGTLC5P, CCND1, ANXA6, FXYD1, S100A6, NFATC3, PLK1, ABO, PTGER3, APC, S100A12, ASL, HSP90B2P, SETMAR, PRRX1, PZP, STAT1, ODC1, CFB, CDNF, ZBTB4, PARK16, SUGP1, DIO1, SORCS2, MAGEE1, ALDH1A1, MIR1306, DES, DIAPH1, LSM2, MIR1229, XPO5, HCN3, CFD, MIR664A, KIF17, WDR48, MTRNR2L12, PRX, DHFR, EPG5, SEPTIN1, FAS-AS1, RNF213, MIR320E, MIR1908, HECW2, LINC00672, NUFIP2, ABCD1, DLG1, QRFP, ZNF410, AOC2, NBEAL1, CYP11A1, OPN1MW2, AD6, P2RY12, NMNAT1, DEPTOR, TNS3, CYP2D7, FAM72A, NUCKS1, CLEC7A, CYP26A1, ARAP3, GREM2, CDKN2B-AS1, CYP2J2, UBE2Z, MIR1246, TSPY3, MIR632, CTSK, GTDC1, CTSL, MIR650, MIR660, SNORD118, TNFAIP8L2, LYNX1, MUL1, PAGR1, CYLD, MAPKAP1, APOF, PDCL3, CYP2C19, NOC3L, CYP27A1, DPEP2, MFT2, PROK2, HPSE2, AD14, AKR1C2, ALPI, TRPV4, NTN4, PRM3, PDF, JAM2, ALOX5AP, TSPY10, DEFB4A, DEFB4B, ALOX12, PTBP2, DCN, NECAB3, FKBPL, NEUROG2, DGKQ, SLC25A4, MIR873, MIR301B, CENPK, DAXX, GFRA4, GOLPH3, ERVK-6, MTUS1, DBI, MIR937, ANG, ACE3P, SOD2-OT1, ANK3, DRD2, ZNF608, NAT10, DYM, LOC102724334, TRIT1, EIF4G2, TET2, EIF5, SERPINB1, ELAVL4, PDP1, ACO2, THRA1/BTR, UGT1A1, CCHCR1, CPVL, SMOX, TOLLIP, TERF2IP, SNTG1, EMP1, LOC102723407, EIF4EBP1, MIR6845, EIF2S3, ADCY2, NUDT11, EGR2, MSTO1, ADARB1, SLC6A15, ADA, TAPBPL, TESC, MIR6840, ACVRL1, FOCAD, EIF4A1, CASZ1, QRICH1, PGPEP1, EIF4A2, NDE1, ASIC2, CTTN, ACADVL, GSKIP, LNCRNA-ATB, ATP6V1H, H3P7, TDP2, ERBB2, CINP, ZCCHC17, H3P13, DTL, GPRC5B, ERCC1, DCDC2, NAT8B, GULP1, H3P23, ERG, H3P28, H3P11, PPIL1, STIN2-VNTR, NANS, EPHA8, H2BS1, POLE3, ACACA, SLC29A1, FXYD6, LRP1B, CST12P, SIRT1-AS, INPP5K, MSRB1, ARID4B, EPOR, ABL1, AAVS1, NR2F6, ERVK-32, LOC110366354, MNS16A, EFNA5, SLC47A1, ALAD, EEF1A1, SNHG19, MICA, DNTT, SOX21-AS1, DOCK3, DPYSL3, MIR626, XAB2, MFF, DUSP22, ARNTL2, SPPL2B, MCCC1, TMX2-CTNND1, ANKS1B, DPYSL5, FXYD6-FXYD2, BARHL1, DSC1, TWSG1, TLE5, DNASE1, DNA2, OCLN, NLN, AMIGO1, AHR, PLEKHG5, SLC24A3, SPC25, TTC7A, PELI1, JAG1, TMEM159, RTN4, APMAP, CD177, CAMK1D, PLAAT1, NR0B1, TIGAR, P2RX5-TAX1BP3, PARD3, GKN1, ADH6, INAVA, CDK5RAP2, OGDHL, LINC01080, ATF7IP, IPO9, VAC14, DVL1, PPP4R3A, OPN1MW3, EBM, OTUB1, SOX6, SLC30A10, SMPD3, MEG3, PLIN2, FBXW7, TDP1, ADORA1, DSC3, ACSS2, BTNL2, KIAA1217, ZNF253, CFC1, MIR4668, DSG1, APOM, MYO5C, MIR4487, NOTCH2NLC, USE1, SELENOS, GDNF-AS1, DSPP, ADCY10, ADRA2A, ZNF415, LINC-ROR, NARS2, CSF2RB, MIR616, MIR20A, CDC25C, PROM2, ATP6V1E1, IL23R, GLIS1, PM20D1, PHF13, CDH2, ZNF569, MIR191, CDK9, MIR192, PRIMA1, CDKN2D, MIR196A1, OR2AG1, LAYN, PIWIL4, MIR19B1, GPBAR1, CDC25B, GDF7, ZDHHC15, MIR139, CD63, SGMS2, MIR140, TMPRSS6, RHBDL3, AVPR2, MIR15A, CBLL2, MIR186, PRUNE2, AMOTL1, CD81, MIR18A, SLC2A12, CDA, MIR181A2, ATP5PO, SESN3, ATP6V1B2, UBR1, ATP5PF, PPME1, MIR224, LYZL4, KCNH8, MTERF4, MIR23A, CPO, ACMSD, MIR23B, BHLHE23, MIR25, CFL1, OSCAR, SPNS2, SEZ6, SLC38A10, MSI2, CFTR, MIR27A, MIR223, ALDH7A1, MIR221, SELENOM, ATP5MC2, CACUL1, HECTD2, SREK1, CTCFL, CBLN4, CDSN, ATP5MC1, DEFB104A, OCIAD2, MAGEC3, MIR210, CEACAM5, CECR, PPARGC1B, ATP5F1B, IL31RA, GNPDA2, SCARB2, NSMCE1, SOCS4, UBE2L1, BNC1, CACNA1C, SLC25A20, SERPINA13P, BLM, SREK1IP1, MIF-AS1, C20orf203, SYPL2, ZNF763, CCL4L1, BID, BGN, ZSCAN1, ZADH2, SMIM20, MILR1, PGP, GOLGA6L2, TMEM189-UBE2V1, TMEM189, IL31, C4BPA, BTK, AMIGO2, HCN1, NHLRC2, ATP9B, SBSN, BMP1, OSTN, C5, CFAP410, BARHL2, NANOS3, C9, STING1, GADL1, ARMH1, VPS51, HCAR2, CAPG, LINC00639, TMEM201, LIN28B, CD5L, MIR127, CD19, KIF6, MS4A1, MS4A3, HYLS1, STOX1, FOLH1B, OR8J1, TRIML2, CD28, KHDRBS2, GAPT, CENPV, KLHDC8B, MIR134, CD86, PIKFYVE, SLC29A4, CCNC, KRIT1, PTF1A, DAOA-AS1, BDKRB2, HCA1, BRD3OS, ASPM, BCS1L, SGMS1, BCR, MIRLET7D, MIR122, RUNX1, ANKK1, BCL6, PHYHD1, BAK1, MIR10A, EBF3, CCKAR, MIR28, FRMD6, MIR613, ADAMTS10, TMEM175, XIAP, MAF1, BIRC3, SLA2, ANTXR1, ASCC2, CRHBP, EVA1A, QRFPR, MAGT1, NCALD, LOC646506, ROPN1L, L3MBTL2, GMNC, SCFV, CSE1L, RNF146, PHF6, HOOK3, BRSK1, MBOAT4, COX15, MIR497, MFSD2A, MIR501, ACCS, ARG2, FAM126A, CPB1, CPN1, ECSCR, MAP1LC3A, MIR484, AQP9, CPS1, SNORD35B, CPT1A, ABLIM2, FASLG, NETO1, DOCK8, RNFT2, C1QBP, TM2D3, ASRGL1, PTGES2, PANK2, MIR590, SCD5, CSNK2A1, VCAN, ZC3H14, CSPG4, CTBS, MIR592, MIR598, CAMKMT, CTNS, SLTM, PTCD2, CTNND1, MIR603, NUBPL, WDR26, SPHKAP, GSTT2B, TMEM163, NCF1, LBH, SPAG11A, SFTPA1, CSF3R, ZNF436, CSN2, NDFIP1, MIR545, SLC44A4, SLC19A3, FAM72B, AIRE, IQCJ, CSNK1G2, DNAJC5, CSNK1G3, LINGO1, ATG4C, ATP2B4, MIR346, SERPINC1, CISH, ASPA, CLC, UCN3, TMEM54, ASS1P1, CLCN3, NACC1, ASIP, STX1B, IFT43, MIR133B, MIR151A, CLK2, TP53INP1, MIR330, MIR335, MIR338, MIR93, SLC26A7, OMA1, CHGB, PLD4, TDRD9, CHD1, MIR299, ATIC, ATHS, H4-16, LRIG3, EXOSC6, CHRM3, MIR30B, MIR30E, AGAP2, MIR31, MIR34C, MIR9-1, GRIN3B, GRIN3A, ASAH1, MIR369, H2BC12, KPRP, LRSAM1, MIR429, H4C15, SHF, GADD45GIP1, COL11A1, ZNF628, MIR431, HNP1, NAV2, MIR409, SLC31A1, RPPH1, SNORD14E, SNORD14D, SNORD14C, SNORD14B, COX6B1, MIR485, CNTN1, DNM1P33, CNTFR, CHRDL1, CLN3, MIR361, MYOCD, PRDM6, DNER, SPECC1, MIR377, CLN5, EXOC3L4, CNP, MIR425, ARRB1, ZNF804A, BDNF-AS, NLRP12, CCR6, ABCC2, DEFB104B, LRRC15, POU3F4, HOOK1, TERC, NAT1, MCM2, EZR, MDH1, VEGFC, MDH2, MDM4, MEF2D, UVRAG, UROD, UQCRC1, UGT1A, SLC35A2, UCP2, UBTF, UBP1, MID1, UBE3A, UBE2V1, CXCL9, ATXN3, UBE2D2, UBE2A, UBC, MAP3K10, MC1R, WARS1, WAS, ZMYM2, MANF, SCG2, FZD5, SMAD7, MAG, MAP3K12, MAP1A, MAP1B, ZNF236, ZNF224, ZNF217, RNF112, WEE1, MZF1, ZIC1, MARS1, MAS1, MAT1A, MAT2A, MAZ, XIST, WT1, WNT2B, WNT5A, UBA52, KMT2A, MLLT3, THBS1, TLR3, TLE3, MSH3, TKT, TIMP4, TIMP3, MSR1, MSRA, THRA, THOP1, THBS4, CYTB, MRE11, NUDT1, TGFBI, TGFB3, ND1, TFF3, TFDP1, MTNR1B, MTRR, TRNL1, MUC1, TERF2, TSPAN7, MRC1, TWIST1, TRAF2, TUBA4A, NR3C2, TTN, TSPY1, TSHR, TSG101, TSC1, MMP7, MMP8, TRPC1, TRH, NR2C2, TNFAIP6, MMP13, TPM1, MOG, MOV10, TP53BP2, TP53BP1, MPG, TNR, TNNI3, MPI, MPST, SLBP, REEP5, DEK, SNX3, TNFRSF6B, RAB11A, LDHA, LEPR, LGALS4, LGALS9, GPAA1, RNMT, GBF1, ADAM19, URI1, TRADD, LCK, B3GALT4, LIFR, LIG1, SOCS1, NUMB, LIMS1, AOC3, PDE8B, USO1, TNFSF11, STK16, LCT, CES2, KMO, KLRC1, BRSK2, KCNQ1, KIR2DL2, NOL3, ATP6V0E1, SELENBP1, USP13, KLKB1, CDK5R2, RAB29, MBD2, KIF11, TMEM11, ENDOU, EIF2S2, TAX1BP1, NAE1, KRT14, KRT18, LAMC1, LBR, PROM1, LCAT, SOCS2, PRKRA, DEGS1, DDX39B, PABPN1, EOMES, BAP1, LTF, H4C9, COLQ, DYSF, CHAF1B, LYN, NRIP1, COIL, SLC7A5, AD5, H4C1, FGF23, ADAM12, BRD3, PSCA, ARHGEF5, TFPI2, FZD3, GHS, M6PR, MARCKS, SMAD1, LTC4S, H4C4, BHLHE40, IRS4, MAPKAPK5, LMO4, LOXL1, CST7, DDO, DGKZ, GAS7, PIK3R3, PKP4, PPFIA1, LRPAP1, SORBS2, H4C6, CUL4A, GNPAT, LTB, H4C14, H4C13, H4C5, H4C2, H4C8, H4C3, H4C11, H4C12, TERF1, MUC4, KCNMA1, TDO2, PCP4, CDK18, RBM3, RBL2, RBBP6, RB1, RASGRF1, RASA1, RARRES2, RAN, RAF1, RAD52, PCYT1A, RAD23B, RAC2, PDB1, RAB27B, RAB27A, PDC, PDE2A, PURA, PDGFB, ENPP2, PDYN, PTPN13, PC, PAX6, PARN, RPL15, P2RX1, S100A8, P2RX3, P2RX5, P2RY4, RREB1, RPS23, RPS21, RPS6KB2, P2RY6, RPS3A, RPL13, RET, RPA1, PAFAH1B2, RORA, ROM1, SNORD15A, BRD2, RNASE1, RHO, RHD, PAK3, TRIM27, PTPN11, PENK, PTN, PMM2, PLAUR, PLCL1, PLEK, PRKCE, PRKCD, PLP1, PRKAR1B, PRKACB, PRKACA, PLXNB1, PML, PRG2, PLAT, PMP22, PRB1, PPT1, PPP2R5E, POLG, PPP2R1A, PPP1CB, PPL, PPIC, PPIB, POR, MAP2K3, PLAG1, PFDN5, PSMD2, PFKFB3, PTGER2, PTGER1, PGD, PTGDR, PTCH1, PGR, PHB, PSMD9, PSMD7, PSMD3, PSMB2, PITX2, SERPINE2, SERPINI1, KLK10, PIK3C3, PIK3R1, KLK7, PIK3R2, PRS, PROS2P, PIN4, PROC, S100A10, OXT, OXA1L, SQLE, STAR, ST14, ST2, NDUFA6, SSTR3, SSTR2, NDUFA9, NDUFB8, SRM, SRF, NEDD4, SEPTIN2, STC1, SP4, NEU1, SOX5, SOX3, SOS2, SOS1, SOD3, NFE2L1, NFKB2, SNRPG, SNRNP70, NDUFA5, STIM1, NME1, MYH9, TRBV20OR9-2, TCP1, TCN2, MMUT, MUTYH, TCF4, ELOC, TBX2, MX1, MYH6, TARBP2, MAP3K7, STK11, MYO6, TACR2, NACA, VAMP2, VAMP1, SURF1, ABCC8, SUOX, NDP, STXBP1, STX1A, NINJ2, NME2, SAA2, OMP, SFTPC, TRA2B, SRSF6, SRSF5, SRSF3, SRSF1, SFRP1, OCA2, MAP2K4, ODF1, SELE, OPA1, OAS3, CXCL11, CCL21, CCL20, CCL19, CCL8, CCL1, SCP2, SCN1A, ORM2, OSM, TSPAN31, OAT, SGSH, SUMO2, SLC8A3, SMPD2, SLN, SLIT3, SLC22A5, SLC22A2, NQO2, SLC18A1, SLC16A1, SLC12A3, SLC11A1, SLC10A2, SLC8A1, NUP98, SLC6A12, NPHP1, SLC6A1, SLC5A2, NRCAM, NRDC, SLC1A1, NRF1, PMEL, YBX1, NT5E, NAT8, SEMA5A, ESRRA, RAB31, MACF1, HEY2, BRD4, TRAM1, CBX5, ANGPTL2, OPN1MW, GRIP1, KCNH4, MSTN, GFER, GFRA1, SIRT5, COTL1, GFRA3, GHR, ZNF629, UBR4, GHSR, WASHC4, GLI1, NUP160, CLUH, GLI3, SCFD1, KCTD2, CLCF1, SEC14L2, NR5A1, SLC24A2, PRPF6, TFIP11, MAFF, EID1, RAB38, FSHR, TMEFF2, PLA2G15, SLC7A11, FTH1, SNHG1, TSPAN15, GAST, ACKR1, G6PD, GAB1, NTSR2, GABBR1, GAD2, GALNS, DDAH1, PADI4, GART, NBEAL2, GMPR, PLEKHM2, WDHD1, GPR39, CARD8, ARHGEF15, AAK1, SYNPO, GPX4, ECD, PARK7, KLF8, TREX1, WIF1, WDR45, ATF6, CORO1A, TBC1D8, SLC7A9, GRIA4, FAF1, GRIK4, RER1, GRM1, STMN2, RAPGEF4, ADRM1, MSRB2, RAB3GAP1, GNA12, ZNF423, ATG4B, UBXN4, RCOR1, SEPTIN8, STAB1, GNAI1, MAPK8IP3, GRAMD4, GNB3, NFASC, KIF1B, GOLGA2, GPER1, SETX, GOLGA4, PDZD2, SAMD4A, KDM1A, GPM6A, RAB21, GPR6, P2RX2, GPR20, SNW1, FRK, FBXO7, BRI3, SNX12, SOCS7, CD209, FABP6, TBX21, NOP53, FABP7, SLC2A8, UBQLN2, A1CF, PSAT1, FANCG, HOOK2, DELEC1, FASN, SNX8, NPC1L1, BLNK, MS4A2, FCGR1A, FCGR2A, MYLIP, SCG3, DROSHA, TMEM230, NOX4, PCA3, SPCS1, VRK3, ETFA, SLC25A37, TLR8, SLC22A17, ECSIT, CD320, EZH2, DNAJC27, CLEC1B, NT5C3A, MZB1, F2RL2, HP1BP3, F3, F9, IRAK4, SAR1B, UTP11, F13B, SH3GLB1, SIDT2, SHANK1, TRAT1, F11R, RGCC, TMEM176B, NOCT, FBXO2, NPTN, TPK1, VCX, GREM1, FKBP1AP2, FKBP1AP3, AGO1, SEZ6L2, FKBP1AP4, FGF21, CLDN17, NOC2L, SND1, FOXM1, EPC2, ATRNL1, LRP10, FLNB, FMR1, POU2F3, TXN2, FBXL2, FOLR1, FOLR2, FKBP1AP1, B3GAT1, IGHV1-68, TNFRSF21, FEB1, FES, FGF9, RABGEF1, PRPF19, FGF13, FGFR1, FGFR4, PDLIM3, RND1, KLHL20, COQ2, CACYBP, HCAR1, FHL2, VPS4A, IL37, GLS2, NAAA, CYTH4, DKK2, DKK3, BBC3, SDCBP2, GRM3, IL24, SPAG9, CXCL2, PCLAF, IGFBP1, ACAP1, IGFBP5, SART3, KDM4A, IGHG3, SDC3, SH3PXD2A, RGS6, SNCAIP, TCL1B, IL4R, IL7, BCAR1, CCL4L2, CXCR1, BAG2, IL12B, BAG5, TMEM59, TBPL1, GAL3ST1, AKAP5, STX8, PIEZO1, BMS1, PTDSS1, IDH1, SH2D3C, GNE, SH2B3, IRF8, SRA1, TANK, KCNE3, HNRNPDL, CCS, NUP153, MED12, HS3ST1, TOMM20, RBM8A, IDH2, CFI, SV2B, TECPR2, IFI27, TOMM70, KIAA0319, IFIT3, IFNAR1, IGBP1, INSRR, PCYT1B, IL27RA, CCNE2, NOLC1, TIAF1, JUND, ZMYM3, KCNC4, KCNJ13, HGS, SYNGR3, ATG12, CBFA2T2, RABEP1, P2RX6, RAB11B, SLC16A3, SLC16A4, ATP6V0D1, RGN, USP10, USP2, USP14, DNAJA3, CLDN1, CLDN8, ARTN, JUNB, GPR50, PICK1, ITPKB, IRAK1, HOMER2, IREB2, IRF3, IRF6, IRF7, ITGAV, CYP7B1, ITGB3, NRXN1, SLC22A8, ITPR2, AIMP1, JAG2, ITGBL1, LHX2, SLIT2, TAOK2, CD163, JAK2, GPR37L1, PIWIL1, MAPKAPK2, PDLIM7, IARS1, TNC, IL18BP, CCT2, HCK, NRG3, USP39, DCTN6, CD226, HDC, HDLBP, CAMKK2, HIP1, TXNRD2, NPC2, SLC35A1, HBG2, PRDX4, ZNRD2, HYOU1, HLA-DQA1, SEMA4D, HLA-DQB1, NXF1, HLA-DRA, ATP5PD, COG5, GPNMB, CHL1, HAS3, FAM3C, GYPA, GSK3A, COPS5, GSM1, GSTM2, EBNA1BP2, PRSS21, PRDX3, GSTZ1, GTS, GUSB, C1QL1, GYPB, HAS1, GYPC, CCL27, ALDH1L1, GYPE, HAGH, WASF3, HSPH1, GJB6, HARS1, ARPP19, DHS, HLA-DRB4, HLA-G, PQBP1, MPHOSPH6, STAM2, GLYAT, HOXA@, RABEPK, HPCA, CALCOCO2, HRC, OLIG2, DDX39A, TOPORS, EIF1, HSD17B1, RAMP2, WASF2, HSD17B4, HSPA2, HSP90AB1, DNAJB1, NAMPT, BCAP31, CTDSP2, TSPAN3, ACTR2, CERT1, ABCC4, HNRNPK, HMBS, NPM3, CFDP1, PRMT5, HMGB2, YAP1, IFITM3, SPAG11B, PEMT, RACK1, SYCP2, TUBB4B, SEMA3A, WARS2, HNRNPC, FOXA1, CCL26, TLR6, FOXA2, LAMC3, LANCL1, HNF4A, TCIRG1, APBB3, APC2, HNRNPA2B1, MTCH2

Pustular Psoriasis Wikipedia

This skin eruption is often accompanied by a fever , muscle aches , nausea , and an elevated white blood cell count . [1] Annular pustular psoriasis (APP), a rare form of GPP, is the most common type seen during childhood. [6] APP tends to occur in women more frequently than in men, and is usually less severe than other forms of generalized pustular psoriasis such as impetigo herpetiformis. [6] This form of psoriasis is characterized by ring-shaped plaques with pustules around the edges and yellow crusting. [6] APP most often affects the torso, neck, arms, and legs. [6] Diagnosis [ edit ] Classification [ edit ] Pustular psoriasis is classified into two major forms: localized and generalized pustular psoriasis . [1] Within these two categories there are several variants: Classification of Localized and Generalized Pustular Psoriasis Localized pustular psoriasis Palmoplantar pustulosis (acute and chronic) Acrodermatitis continua (of Hallopeau) Generalized pustular psoriasis (von Zumbusch) acute generalized pustular psoriasis Acute generalized pustular psoriasis of pregnancy ( impetigo herpetiformis ) Infantile and juvenile Subacute circinate and annular Management [ edit ] injection of methotrexate This section is empty.

IL36RN, IL1B, CARD14, IL1A, IL1RL2, IL17A, PI3, TNF, IL22, AP1S3, TLR3, TNFAIP3, MOG, TNIP1, LDHA, IL23A, NOD2, IL1F10

Problematic Smartphone Use Wikipedia

For 3-4 year-old children: 180 minutes physical activity, 1 hour screen time, 10–13 hours of sleep time per day. [81] Phone settings [ edit ] Many smartphone addiction activists (such as Tristan Harris) recommend turning one's phone screen to grayscale mode, which helps reduce time spent on mobile phones by making them boring to look at. [82] Other phone settings alterations for mobile phone non-use included turning on airplane mode, turning off cellular data and/or Wi-Fi, turning off the phone, removing specific apps, and factory resetting. [83] Phone apps [ edit ] German psychotherapist and online addiction expert Bert te Wildt recommends using apps such as Offtime and Menthal to help prevent mobile phone overuse. [84] In fact, there are many apps available on Android and iOS stores which help track mobile usage. ... In Android a similar feature called "digital wellbeing" has been implemented to keep track of cell phone usage. [85] These apps usually work by doing one of two things: increasing awareness by sending user usage summaries, or notifying the user when he/she has exceeded some user-defined time-limit for each app or app category. ... The researchers implement an Android app that combined these three intervention types and found that users reduced their time with the apps they feel are a poor use of time by 21% while their use of the apps they feel are a good use of time remained unchanged. [86] AppDetox allows users to define rules that limit their usage of specific apps. [87] PreventDark detects and prevents problematic usage of smartphones in the dark. [88] Using vibrations instead of notifications to limit app usage has also been found to be effective. [89] Further, researchers have found group-based interventions that rely on users sharing their limiting behaviors with others to be effective. [90] Bans on mobile phone use [ edit ] See also: Mobile phone use in schools In some places in the world the use of mobile phones was banned in classes during instructional time, for example, in France , Ontario . ... PMID 27736736 . ^ Young, Kimberly (27 February 1998). Caught in the net : how to recognize the signs of Internet addiction--and a winning strategy for recovery . ... International Journal of Interactive Mobile Technologies . 11 (6): 103–111. doi : 10.3991/ijim.v11i6.7453 . ^ Gardner, Howard; Davis, Katie (22 October 2013). The App Generation: How Today's Youth Navigate Identity, Intimacy, and Imagination in a Digital World .

Fraxe Intellectual Disability Orphanet

A rare X-linked syndromic intellectual disability characterized by a variable clinical picture including developmental delay, mild to moderate intellectual disability, learning difficulties, communication deficits, and behavioral problems (such as aggression, attention deficit, hyperactivity, and autistic features). Personality disorder and psychotic behavior have also been reported.

AFF2, FMR1, APP, SERPINA1, FRAXE, AFM, FRAXA, GTF2A1L, STON1, KIAA1109, STON1-GTF2A1L

Fragile Xe Syndrome MedlinePlus

Fragile XE syndrome is a genetic disorder that impairs thinking ability and cognitive functioning. Most affected individuals have mild intellectual disability. In some people with this condition, cognitive function is described as borderline, which means that it is below average but not low enough to be classified as an intellectual disability. Females are rarely diagnosed with fragile XE syndrome, likely because the signs and symptoms are so mild that the individuals function normally. Learning disabilities are the most common sign of impaired cognitive function in people with fragile XE syndrome. The learning disabilities are likely a result of communication and behavioral problems, including delayed speech, poor writing skills, hyperactivity, and a short attention span.
Mental Retardation, X-Linked, Associated With Fragile Site Fraxe OMIM

A number sign (#) is used with this entry because this form of X-linked mental retardation is caused by disruption of the FMR2 gene (AFF2; 300806), either by expansion of a CCG repeat in the 5-prime untranslated region or by deletion. Description FRAXE mental retardation is a form of mild to moderate mental retardation associated with learning difficulties, communication deficits, attention problems, hyperactivity, and autistic behavior (summary by Bensaid et al., 2009). FRAXE is associated with a fragile site on chromosome Xq28 and is the cause of nonsyndromic X-linked mental retardation in 1 of 50,000 newborn males. The disorder can be caused either by silencing of the FMR2 gene as a consequence of a CCG expansion located upstream of this gene or by deletion within the gene (Stettner et al., 2011). Clinical Features Knight et al. (1996) provided clinical details of 1 FRAXE male identified through a screening study as well as 3 other FRAXE individuals identified through previous referrals for fragile X syndrome testing.
Fragile Xe Syndrome GARD

Fragile XE syndrome (FRAXE) is a genetic condition associated with mild to borderline intellectual disabilities with physical features differing from person to person. The characteristic features are learning difficulties, often a consequence of communication problems (speech delay, poor writing skills), hyperactivity, and a shortened attention span. Nearly all cases of FRAXE are caused by a specific type of mutation, called a trinucleotide repeat expansion , in the AFF2 gene, which is located on the X chromosome. A trinucleotide repeat expansion occurs when there is an abnormally large number of repeats of a specific sequence of three nucleotides (building block of DNA) within our DNA. The repeating nucleotides in FRAXE syndrome are CCG. When the number of CCG repeats is over 200, people typically have the signs and symptoms seen in FRAXE.

Fragile X Syndrome GARD

Fragile X syndrome is a genetic condition involving changes in part of the X chromosome. This condition causes a range of developmental problems including learning disabilities and cognitive impairment. It is the most common form of inherited intellectual disability in males and a significant cause of intellectual disability in females. Other signs and symptoms may include symptoms of autism spectrum disorders , seizures, and characteristic physical features. Fragile X syndrome is caused by a change (mutation) in the FMR1 gene and is inherited in an X-linked dominant manner.

FMR1, APP, AFF2, FMR1-IT1, NUFIP2, GRM5, FRAXA, FRAXE, MMP9, ACTB, ARSD, PVALB, BDNF, FXN, FXR1, FMR1-AS1, G6PD, FXR2, PGD, RBMS3, CYFIP2, SRRM2, PNO1, MFAP1, MAK16, EIF4E, F9, PIK3CA, APRT, PIK3CD, PIK3CG, PTBP1, LINC01672, RAC1, PIK3CB, MECP2, IGF2, IL6, ST14, NCS1, SDC2, MLH1, CYFIP1, RPS6KB1, MSH2, NR1H4, VEGFA, PDE4D, SHANK1, FOSL1, IDS, LIMK1, SOD1, BMPR2, GRIK1, RIC8A, CD44, GRM1, CPEB1, PCSK9, DLG3, RABEP2, KIAA1109, HSPG2, C9orf72, RSS, SLC36A1, ST8SIA4, DGKK, WNT7A, PTPN5, VIP, USF2, MIR219A1, PKP4, USF1, UBE3A, TWIST1, MIR510, ICAM5, SYN1, STXBP1, STATH, C20orf181, SRY, SPARC, MAGT1, YTHDF2, WASF1, DICER1, CHMP4A, INPP5K, MED18, CHD7, MBD5, NBEA, SHC2, TWNK, SNRPN, BRD4, TARDBP, SIRT1, ARHGEF9, TOP3B, ADARB1, KCNT1, CLSTN1, DSTN, RAI1, CTCF, PDLIM5, ABCB6, HDAC6, MED12, PCA3, NRXN1, TDRD3, APOA1, SMS, HTC2, GRN, GRIN2A, ADCYAP1, GSK3B, GSN, HTT, NRG1, HTR2A, SLC12A2, IAPP, IGF1, IGFALS, IRF6, KCNH1, KCNQ2, LGALS4, GRIA2, GABRD, GABPA, AKT1, AVP, BCR, BRCA2, CAT, CD47, CRHR1, DLD, DLG4, DSCAM, RCAN1, ELAVL2, FBN1, ANG, ALPP, ALPI, LMNA, CAPRIN1, MAOA, PDE2A, ADAM10, PPP2R5E, MAPK3, PTEN, ANXA1, RANGAP1, REST, RGS4, ATXN8OS, SCN2A, SHBG, SKI, SLC1A2, SLC6A4, SLC6A8, CFP, PAX3, MAS1, PAK1, MBS1, MDM2, MEF2A, ATXN3, ADCY1, PPP1R12A, NF1, NFE2L1, NFE2L2, NHS, NNAT, NOS1, NRF1, NTRK2, NUP98, PLCG1

Fragile X Syndrome Wikipedia

X-linked dominant genetic disorder Fragile X syndrome Other names Martin–Bell syndrome, [1] Escalante syndrome Boy with protruding ears characteristic of fragile X syndrome Specialty Medical genetics , pediatrics , psychiatry Symptoms Intellectual disability , long and narrow face, large ears, flexible fingers, large testicles [1] Complications Autism features, seizures [1] Usual onset Noticeable by age 2 [1] Duration Lifelong [2] Causes Genetic ( X-linked dominant ) [1] Diagnostic method Genetic testing [2] Treatment Supportive care , early interventions [2] Frequency 1 in 4,000 (males), 1 in 8,000 (females) [1] Fragile X syndrome ( FXS ) is a genetic disorder characterized by mild-to-moderate intellectual disability . [1] The average IQ in males is under 55, while about two thirds of affected females are intellectually disabled. [3] [4] Physical features may include a long and narrow face, large ears, flexible fingers, and large testicles . [1] About a third of those affected have features of autism such as problems with social interactions and delayed speech. [1] Hyperactivity is common, and seizures occur in about 10%. [1] Males are usually more affected than females. [1] This disorder and finding of Fragile X syndrome has an X-linked dominant inheritance. [1] It is typically caused by an expansion of the CGG triplet repeat within the FMR1 (fragile X mental retardation 1) gene on the X chromosome . [1] This results in silencing ( methylation ) of this part of the gene and a deficiency of the resultant protein (FMRP), which is required for the normal development of connections between neurons . [1] Diagnosis requires genetic testing to determine the number of CGG repeats in the FMR1 gene. [5] Normally, there are between 5 and 40 repeats; fragile X syndrome occurs with more than 200. [1] A premutation is said to be present when the gene has between 40 and 200 repeats; women with a premutation have an increased risk of having an affected child. [1] Testing for premutation carriers may allow for genetic counseling . [5] There is no cure. [2] Early intervention is recommended, as it provides the most opportunity for developing a full range of skills. [6] These interventions may include special education , speech therapy , physical therapy , or behavioral therapy . [2] [7] Medications may be used to treat associated seizures , mood problems, aggressive behavior, or ADHD . [8] Fragile X syndrome is estimated to occur in 1.4 per 10,000 males and 0.9 per 10,000 females. [9] Contents 1 Signs and symptoms 1.1 Physical phenotype 1.2 Intellectual development 1.3 Autism 1.4 Social interaction 1.5 Mental health 1.6 Vision 1.7 Neurology 1.8 Working memory 1.9 Fertility 2 Causes 2.1 Inheritance 3 Pathophysiology 4 Diagnosis 5 Management 5.1 Medication 6 Prognosis 7 Research 8 History 9 References 10 External links Signs and symptoms [ edit ] Prominent characteristics of the syndrome include an elongated face and large or protruding ears. Most young children do not show any physical signs of FXS. [10] It is not until puberty that physical features of FXS begin to develop. [10] Aside from intellectual disability, prominent characteristics of the syndrome may include an elongated face, large or protruding ears , flat feet, larger testes ( macroorchidism ), and low muscle tone . [11] [12] Recurrent otitis media (middle ear infection) and sinusitis is common during early childhood. Speech may be cluttered or nervous. Behavioral characteristics may include stereotypic movements (e.g., hand-flapping) and atypical social development, particularly shyness, limited eye contact, memory problems, and difficulty with face encoding. Some individuals with fragile X syndrome also meet the diagnostic criteria for autism . Males with a full mutation display virtually complete penetrance and will therefore almost always display symptoms of FXS, while females with a full mutation generally display a penetrance of about 50% as a result of having a second, normal X chromosome. [13] Females with FXS may have symptoms ranging from mild to severe, although they are generally less affected than males.
Fragile X Syndrome Orphanet

A rare genetic disease associated with mild to severe intellectual deficit that may be associated with behavioral disorders and characteristic physical features including a high forehead, prominent and large ears, hyperextensible finger joints, flat feet with pronation and, in adolescent and adult males, macroorchidism. Epidemiology Prevalence is estimated at approximately 1/2400-1/6000 although the prevalence may vary, depending on where the screening is carried out in the world. Clinical description Fragile X syndrome (FXS) presents with a variable clinical phenotype. In males, the disease presents during childhood with delayed developmental milestones. Intellectual deficit can be of variable severity and may include problems with working and short-term memory, executive function, language, mathematics and visuospatial abilities.
Fragile X Syndrome OMIM

A number sign (#) is used with this entry because fragile X (FXS) is caused by mutation in the FMR1 gene (309550). The vast majority of cases are caused by a trinucleotide (CGG)n repeat expansion (309550.0004) of greater than 200 repeats. See also fragile X tremor/ataxia syndrome (FXTAS; 300623), which is caused by expanded FMR1 (CGG)n repeats that range in size from 55 to 200 repeats and are referred to as 'premutations.' Description Fragile X syndrome is characterized by moderate to severe mental retardation, macroorchidism, and distinct facial features, including long face, large ears, and prominent jaw. In most cases, the disorder is caused by the unstable expansion of a CGG repeat in the FMR1 gene and abnormal methylation, which results in suppression of FMR1 transcription and decreased protein levels in the brain (Devys et al., 1993).

Hereditary Cerebral Hemorrhage With Amyloidosis GARD

Based on the region in which they were first described, the subtypes include: The Dutch , Arctic , Piedmont , Iowa , Flemish , Italian types are caused by mutations in the APP gene The British and Danish types are caused by mutations in the ITM2B gene The Icelandic type is caused by mutations in the CST3 gene All types of HCHWA currently described are inherited in an autosomal dominant manner.

CST3, ITM2B, APP, CTSD, APOE, ACTB, PTPRC, TSHZ1, SYP, SPP1, SDC2, HSPG2, SMAD2, ITGAX, GFAP, FN1, FAP, CD68, HSPB8

Cerebral Amyloid Angiopathy, Cst3-Related OMIM

A critical piece of evidence indicating a difference between the 2 diseases is the finding by van Duinen et al. (1987) that in the Dutch form of the disease the vascular amyloid deposits have immunohistochemical characteristics of Alzheimer disease-related beta-protein (APP; 104760). Molecular Genetics In Icelandic patients with hereditary cerebral hemorrhage with amyloidosis, Abrahamson et al. (1987) identified a heterozygous mutation in the CST3 gene (L68Q; 604312.0001).
Hereditary Cerebral Hemorrhage With Amyloidosis Orphanet

Etiology Most forms of HCHWA (Dutch, Arctic, Piedmont, Iowa, Flemish and Italian) are due to a point-mutation in the APP gene on chromosome 21q21.2, which encodes the beta-amyloid precursor protein.
Cerebral Amyloid Angiopathy Wikipedia

Abnormalities in each of these identified clearance pathways have been linked to CAA. [12] [13] In familial forms of CAA, the cause of Aβ build up is likely due to increased production rather than poor clearance. [14] Mutations in the amyloid precursor protein (APP), Presenilin (PS) 1 and PS2 genes can result in increased rates of cleavage of the APP into Aβ. ... External links [ edit ] Classification D ICD - 10 : I68.0 MeSH : D016657 DiseasesDB : 32874 External resources MedlinePlus : 000719 eMedicine : neuro/628 Scholia has a topic profile for Cerebral amyloid angiopathy . v t e Amyloidosis Common amyloid forming proteins AA ATTR Aβ2M AL Aβ / APP AIAPP ACal APro AANF ACys ABri Systemic amyloidosis AL amyloidosis AA amyloidosis Aβ2M/Haemodialysis-associated AGel/Finnish type AA/Familial Mediterranean fever ATTR/Transthyretin-related hereditary Organ-limited amyloidosis Heart AANF/Isolated atrial Brain Familial amyloid neuropathy ACys+ABri/Cerebral amyloid angiopathy Aβ/Alzheimer's disease Kidney AApoA1+AFib+ALys/Familial renal Skin Primary cutaneous amyloidosis Amyloid purpura Endocrine Thyroid ACal/Medullary thyroid cancer Pituitary APro/Prolactinoma Pancreas AIAPP/Insulinoma AIAPP/Diabetes mellitus type 2 v t e Medicine Specialties and subspecialties Surgery Cardiac surgery Cardiothoracic surgery Colorectal surgery Eye surgery General surgery Neurosurgery Oral and maxillofacial surgery Orthopedic surgery Hand surgery Otolaryngology ENT Pediatric surgery Plastic surgery Reproductive surgery Surgical oncology Transplant surgery Trauma surgery Urology Andrology Vascular surgery Internal medicine Allergy / Immunology Angiology Cardiology Endocrinology Gastroenterology Hepatology Geriatrics Hematology Hospital medicine Infectious disease Nephrology Oncology Pulmonology Rheumatology Obstetrics and gynaecology Gynaecology Gynecologic oncology Maternal–fetal medicine Obstetrics Reproductive endocrinology and infertility Urogynecology Diagnostic Radiology Interventional radiology Nuclear medicine Pathology Anatomical Clinical pathology Clinical chemistry Cytopathology Medical microbiology Transfusion medicine Other Addiction medicine Adolescent medicine Anesthesiology Dermatology Disaster medicine Diving medicine Emergency medicine Mass gathering medicine Family medicine General practice Hospital medicine Intensive care medicine Medical genetics Narcology Neurology Clinical neurophysiology Occupational medicine Ophthalmology Oral medicine Pain management Palliative care Pediatrics Neonatology Physical medicine and rehabilitation PM&R Preventive medicine Psychiatry Addiction psychiatry Radiation oncology Reproductive medicine Sexual medicine Sleep medicine Sports medicine Transplantation medicine Tropical medicine Travel medicine Venereology Medical education Medical school Bachelor of Medicine, Bachelor of Surgery Bachelor of Medical Sciences Master of Medicine Master of Surgery Doctor of Medicine Doctor of Osteopathic Medicine MD–PhD Related topics Alternative medicine Allied health Dentistry Podiatry Pharmacy Physiotherapy Molecular oncology Nanomedicine Personalized medicine Public health Rural health Therapy Traditional medicine Veterinary medicine Physician Chief physician History of medicine Book Category Commons Wikiproject Portal Outline

Numerophobia Wikipedia

ISBN 978-1-4381-2098-0 . v t e Superstition Main topics Amulet Evil eye Luck Omen Talismans Myth and ritual Lists List of superstitions List of lucky symbols List of bad luck signs Sailors' superstitions Theatrical superstitions Africa Buda Gris-gris Sampy Sleeping child Americas Ascalapha odorata Carranca Cooties Curupira Djucu Fortune cookie Groundhog Day I'noGo tied Oscar love curse Susto White lighter myth Witch window Asia Superstition in India Superstition in Pakistan Japanese superstitions Bhoot (ghost) Chhaupadi Churel Ghosts in Bengali culture Jackal's horn Kuai Kuai culture Muhurta Navaratna Nazar battu Pichal Peri Puppy pregnancy syndrome Akabeko Kanai Anzen Maneki-neko Okiagari-koboshi Omamori Fan death Agimat Arbularyo Barang Kulam Lihi Pagtatawas Pasma Usog Kuman Thong Palad khik Takrut Nang Kwak White elephant Curse of 39 Jin Chan Numbers in Chinese culture Superstitions of Malaysian Chinese Europe August curse Barbary macaques in Gibraltar Bayern-luck Blarney Stone Cimaruta Cornicello The Goodman's Croft Himmelsbrief Icelandic magical staves In bocca al lupo Kitchen witch Klabautermann Mooncalf Nazar Need-fire Painted pebbles Powder of sympathy Rabbit rabbit rabbit Ravens of the Tower of London Russian traditions and superstitions Spilling water for luck The Scottish Play Troll cross Tycho Brahe days Witch post Wolfssegen General 11:11 4 ( Four-leaf clover , Tetraphobia ) 7 ( Seventh son of a seventh son ) 8 9 13 ( Friday the 13th , The Thirteen Club , Thirteenth floor , Triskaidekaphobia ) 108 111 666 ( Number of the Beast ) Ace of spades Auspicious wedding dates Baseball superstition Beginner's luck Black cat Bread and butter Break a leg Chain letter Cramp-ring Curse Davy Jones' Locker Dead man's hand End-of-the-day betting effect Fear of frogs Fear of ghosts First-foot Flying Dutchman Four Eleven Forty Four Gambler's conceit Good luck charm Human sacrifice Jinx Knocking on wood Law of contagion Literomancy Lock of hair Maternal impression Miasma theory Nelson Numismatic charm Penny Rabbit's foot Rainmaking Ship sponsor Shoes on a table Sign of the horns Something old Spilling salt Statue rubbing Three on a match Threshold Toi toi toi 27 Club Wishing well Witch ball Witching hour Related Apotropaic magic Astrology and science Coincidence Debunker Divination Folk religion Fortune-telling Magic and religion Magical thinking Numerology Perceptions of religious imagery in natural phenomena Post hoc ergo propter hoc Traditional medicine Urban legend Jew Muslim This article about a mental disorder is a stub .

Estrogen And Neurodegenerative Diseases Wikipedia

In addition, estrogen deprivation is likely to initiate or enhance degenerative changes caused by oxidative stress , and to reduce the brain's ability to maintain synaptic connectivity and cholinergic integrity leading to the cognitive decline seen in aged and disease-afflicted individuals. [5] There is sufficient evidence that estradiol is a powerful neuroprotectant which might have use against AD, stroke and Parkinson's disease both in women and men. [5] Estrogen and Alzheimer's disease [ edit ] This figure shows how APP cleavage produces toxic Abeta in Alzheimer's disease. Amyloid plaques formed by amyloid-β (Aβ) deposition and neurofibrillary tangles formed by tau protein phosphorylation are dominant physiological features of Alzheimer's disease. Amyloid precursor protein (APP) proteolysis is fundamental for production of Aβ peptides implicated in AD pathology. [6] By using a cell line that contains high levels of estrogen receptors, scientists found that treatment with physiological concentrations of 17 beta-estradiol is associated with accumulation in the conditioned medium of an amino-terminal cleavage product of APP (soluble APP or protease nexin-2), indicative of non-amyloidogenic processing. [7] Estrogen and Parkinson's disease [ edit ] Recommendations on the use of postmenopausal hormonal replacement therapy in women with Parkinson's disease or those genetically at risk. [8] But another group of scientists found a positive association between estrogen use and lower symptom severity in women with early PD not yet taking L-dopa . [9] Estrogen and Huntington's disease [ edit ] Huntington's disease (HD) is a polyglutamine disorder based on an expanded CAG triplet repeat [10] leading to cerebral and striatal neurodegeneration. [11] Potential sex differences concerning the age of onset and the course of the disease are poorly defined, as the difficulties of matching female and male HD patients regarding their CAG repeat lengths limit comparability. [12] Estrogen and Amyotrophic lateral sclerosis [ edit ] ALS occurs more commonly in men than in women, and women get the disease later in life compared to men. [13] This suggested the possible protective role of estrogen in ALS. ... "Octyl Gallate Markedly Promotes Anti-amyloidogenic Processing of APP through Estrogen Receptor-Mediated ADAM10 Activation" .

Costochondritis Wikipedia

"Towards evidence based emergency medicine: best BETs from the Manchester Royal Infirmary. BET 3: The use of corticosteroids in the management of costochondritis".

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Tietze Syndrome GARD

Tietze syndrome is an inflammatory condition characterized by chest pain and swelling of the cartilage around the ribs. Specifically, people with Tietze syndrome have swelling of the cartilage that joins the upper ribs to the breastbone. This is called the costochondral junction. Signs and symptoms of this condition usually develop in people who are under the age of 40. Symptoms include mild to severe chest pain that may extend into the arms and shoulders. The chest, shoulders, and arms may also have redness and warmth. In some cases, Tietze syndrome may resolve on its own without treatment, while other people experience patterns of pain followed by some relief of pain.
Costochondritis Mayo Clinic

Overview Costochondritis (kos-toe-kon-DRY-tis) is an inflammation of the cartilage that connects a rib to the breastbone (sternum). Pain caused by costochondritis might mimic that of a heart attack or other heart conditions. Costochondritis Costochondritis most commonly affects the upper ribs on the left-hand side of your body. Pain is often worst where the rib cartilage attaches to the breastbone (sternum), but it can also occur where the cartilage attaches to the rib. Costochondritis is sometimes known as chest wall pain syndrome, costosternal syndrome or costosternal chondrodynia.
Tietze Syndrome Wikipedia

Not to be confused with Tietz syndrome . This article needs additional citations for verification . Please help improve this article by adding citations to reliable sources . Unsourced material may be challenged and removed. Find sources: "Tietze syndrome" – news · newspapers · books · scholar · JSTOR ( August 2010 ) ( Learn how and when to remove this template message ) Tietze syndrome Other names Chondropathia tuberosa, costochondral junction syndrome Sternocostals and interchondral articulations. Anterior view. ( Costal cartilages visible on diagram.) Specialty Rheumatology Tietze syndrome (also called costochondral junction syndrome ) is a benign inflammation of one or more of the costal cartilages . [1] It was first described in 1921 by the German surgeon Alexander Tietze (1864–1927). [2] [3] Tietze syndrome is not the same as costochondritis . [4] Tietze syndrome is differentiated from costochondritis by swelling of the costal cartilages, which does not appear in costochondritis. Like costochondritis, it was at one time thought to be associated with, or caused by, a viral infection acquired during surgery.

Microvasculature Remodeling Wikipedia

What makes vessels grow with exercise training? J App Physiol 97: 1119–28, 2004. This cardiovascular system article is a stub .