Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Atrophia areata (AA) is an early onset autosomal dominant helicoid peripapillary chorioretinal degeneration, which was first demonstrated to be hereditary in an Icelandic family. It is characterized by bilateral wing-shaped atrophic areas of the retina, radiating from the optic disk. Primary complaints of affected individuals are due to refractive errors and scotomata associated with myopia which increases with age. A genome linkage search with 112 microsatellite DNA markers resulted in the highest probability of location for AA on chromosome 11. We genotyped 18 polymorphic markers on chromosome 11 and seven showed significant linkage to AA. The markers D11S1323 and D11S902 on 11p15 flank the region encompassing the gene for AA.
Hum Mol Genet 1995 Mar
PMID:Mapping the locus of atrophia areata, a helicoid peripapillary chorioretinal degeneration with autosomal dominant inheritance, to chromosome 11p15. 779 6

Kniest dysplasia is a moderately severe chondrodysplasia phenotype that results from mutations in the gene for type II collagen, COL2A1. Characteristics of the disorder include a short trunk and extremities, mid-face hypoplasia, cleft palate, myopia, retinal detachment, and hearing loss. Recently, deletions of all or part of exon 12 have been identified in individuals with Kniest dysplasia, suggesting that mutations within this region of the protein may primarily result in the Kniest dysplasia phenotype. We used SSCP to analyze an amplified genomic DNA fragment containing exon 12 from seven individuals with Kniest dysplasia. An abnormality was identified in one patient. DNA sequence analysis demonstrated that the patient was heterozygous for a G to A transition that implied substitution of glycine103 of the triple helical domain by aspartate. The mutation was not observed in DNA from either of the clinically unaffected parents of the proband. Protein microsequencing demonstrated expression of the abnormal allele in cartilage. These data demonstrate that point mutations which result in single amino acid substitutions can produce Kniest dysplasia and further support the hypothesis that alteration of a domain, which includes the region encoded by exon 12, in the type II collagen protein leads to this disorder.
Hum Mol Genet 1994 Nov
PMID:A single amino acid substitution (G103D) in the type II collagen triple helix produces Kniest dysplasia. 787 17

Knobloch syndrome (KS), characterized by high myopia, vitreoretinal degeneration with retinal detachment, macular abnormalities and occipital encephalocele, was recently confirmed as autosomal recessive. Here we report the assignment of the gene for this syndrome to 21q22.3 with the marker D21S171 through homozygosity mapping in a highly inbred Brazilian family with 11 affected individuals. A total of nine markers spanning a region of 15.2 cM of the chromosome 21q22.3 were tested and the candidate region was restricted to an interval of 4.3 cM.
Hum Mol Genet 1996 Jun
PMID:A gene which causes severe ocular alterations and occipital encephalocele (Knobloch syndrome) is mapped to 21q22.3. 877 1

The possible changes in protein structures of the cataractous human lens capsules of the immature patients with myopia and/or systemic hypertension have been investigated using Fourier transform infrared (FT-IR) microspectroscopy. Second-derivative and deconvolution methods have been applied to obtain the position of the overlapping components of the amide I band and assign them to different secondary structures. Changes in the protein secondary structure and composition of amide I band were estimated quantitatively from Fourier self-deconvolution and curve fitting algorithms. The results indicate that myopia and/or systemic hypertension were found to significantly modify the protein secondary structure of the cataractous human lens capsules to increase the beta-type structure and random coil and decrease the alpha-helix structure. Myopia-induced conformational change in triple helix structure was more pronounced. In conclusion, myopia and/or systemic hypertension seem to modify the conformation of the protein structures in cataractous human lens capsule to change ionic permeation through lens capsule to accelerate the cataract formation of senile patients.
Spectrochim Acta A Mol Biomol Spectrosc 1997 Aug
PMID:Fourier transform infrared spectral evidences for protein conformational changes in immature cataractous human lens capsules accelerated by myopia and/or systemic hypertension. 925 66

Knobloch syndrome (KS) is an autosomal recessive disorder defined by the occurrence of high myopia, vitreoretinal degeneration with retinal detachment, macular abnormalities and occipital encephalocele. The KS causative gene had been assigned to a 4.3 cM interval at 21q22.3 by linkage analysis of a large consanguineous Brazilian family. We reconstructed the haplotypes of this family with ten additional markers (five were novel) and narrowed the candidate interval to a region of <245 kb, which contains 24 expressed sequence tags, the KIAA0958 gene and the 5' end of the COL18A1 gene. We identified a homozygous mutation at the AG consensus acceptor splice site of COL18A1 intron 1 exclusively among the 12 KS patients, which was not found among 140 control chromosomes. This mutation predicts the creation of a stop codon in exon 4 and therefore the truncation of the alpha1(XVIII) collagen short form, which was expressed in human adult retina. These findings provide evidence that KS is caused by mutations in COL18A1 which, therefore, has a major role in determining the retinal structure as well as in the closure of the neural tube. Therefore, we show for the first time that the absence of a collagen isoform impairs embryonic cell proliferation and/or migration as a primary or secondary effect.
Hum Mol Genet 2000 Aug 12
PMID:Collagen XVIII, containing an endogenous inhibitor of angiogenesis and tumor growth, plays a critical role in the maintenance of retinal structure and in neural tube closure (Knobloch syndrome). 1094 34

Compensatory hyperinsulinemia stemming from peripheral insulin resistance is a well-recognized metabolic disturbance that is at the root cause of diseases and maladies of Syndrome X (hypertension, type 2 diabetes, dyslipidemia, coronary artery disease, obesity, abnormal glucose tolerance). Abnormalities of fibrinolysis and hyperuricemia also appear to be members of the cluster of illnesses comprising Syndrome X. Insulin is a well-established growth-promoting hormone, and recent evidence indicates that hyperinsulinemia causes a shift in a number of endocrine pathways that may favor unregulated tissue growth leading to additional illnesses. Specifically, hyperinsulinemia elevates serum concentrations of free insulin-like growth factor-1 (IGF-1) and androgens, while simultaneously reducing insulin-like growth factor-binding protein 3 (IGFBP-3) and sex hormone-binding globulin (SHBG). Since IGFBP-3 is a ligand for the nuclear retinoid X receptor alpha, insulin-mediated reductions in IGFBP-3 may also influence transcription of anti-proliferative genes normally activated by the body's endogenous retinoids. These endocrine shifts alter cellular proliferation and growth in a variety of tissues, the clinical course of which may promote acne, early menarche, certain epithelial cell carcinomas, increased stature, myopia, cutaneous papillomas (skin tags), acanthosis nigricans, polycystic ovary syndrome (PCOS) and male vertex balding. Consequently, these illnesses and conditions may, in part, have hyperinsulinemia at their root cause and therefore should be classified among the diseases of Syndrome X.
Comp Biochem Physiol A Mol Integr Physiol 2003 Sep
PMID:Hyperinsulinemic diseases of civilization: more than just Syndrome X. 1452 33

Myopia is a refractive error of the eye that has a significant socioeconomic impact due to its increasing prevalence and the fact that it causes visual impairment. Its aetiology is complex and is likely to involve the interaction of environmental and genetic influences. Tight environmental influence is exemplified by defocus-induced myopia produced in animal models, while genetic factors predominate in familial occurrence of myopia with a Mendelian inheritance pattern. The involvement of numerous mediators, such as cytokines, neurotransmitters and transcription factors, in myopia development has been indicated through various lines of investigation, particular interest focussing on scleral extracellular matrix proteins and developmental genes of the eye. As high-throughput technology for large-scale genotyping and RNA expression analysis enters the field of myopia research, a productive avenue will open up for deciphering the aetiological heterogeneity of myopia and the biological pathways underlying its development.
Cell Mol Life Sci 2005 Apr
PMID:A genetic perspective on myopia. 1586 5

Good visual acuity requires that the axial length of the ocular globe is matched to the refractive power of the cornea and lens to focus the images of distant objects onto the retina. During the growth of the juvenile eye, this is achieved through the emmetropization process that adjusts the ocular axial length to compensate for the refractive changes that occur in the anterior segment. A failure of the emmetropization process can result in either excessive or insufficient axial growth, leading to myopia or hyperopia, respectively. Emmetropization is mainly regulated by the retina, which generates two opposite signals: "GO/GROW" signals to increase axial growth and "STOP" signals to block it. The presence of GO/GROW and STOP signals was investigated by a proteomics analysis of the retinas from chicken with experimental myopia and hyperopia. Of 18 differentially expressed proteins that were identified, five displayed an expression profile corresponding to GO/GROW signals, and two corresponded to STOP signals. Western blotting confirmed that apolipoprotein A-I (apoA-I) has the characteristics of a STOP signal both in the retina as well as in the fibrous sclera. In accordance with this, intraocular application of the peroxisome proliferator-activated receptor alpha agonist GW7647 resulted in up-regulation of apoA-I levels and in a significant reduction of experimental myopia. In conclusion, using a comprehensive functional proteomics analysis of chicken ocular growth models we identified targets for ocular growth control. The correlation of elevated apoA-I levels with reduced ocular axial growth points toward a functional relationship with the observed morphological changes of the eye.
Mol Cell Proteomics 2006 Nov
PMID:Identification of apolipoprotein A-I as a "STOP" signal for myopia. 1692 Nov 68

Myopia, or short-sightedness, is the most common form of vision disorder worldwide. Higher levels of myopia, usually defined as an axial eye length of >26 mm or a refractive error of < -5.00 diopters are often designated as 'pathologic' myopia, because of the predisposition to develop further eye disorders such as retinal detachment, macular degeneration, cataract, or glaucoma. Many distinct forms of autosomal dominant non-syndromic high-grade myopia are described in humans. While the underlying chromosomal locations and critical disease intervals have been identified and located to physical map positions, the gene defects and causative mutations responsible for autosomal dominant myopia remain elusive to date. Examination of a German six-generation kindred by 10K whole genome chips led to the identification of a 19-cM map segment as being the most likely familial myopia candidate region spanning from chromosomal band 12q14.3 to 12q21.31 (MYP3). In our family, a maximum multi-point LOD score of 3.9 was obtained between rs1373877 and rs717996. The recombination breakpoints in this family and the interval of the originally reported German/Italian family defining the MYP3 locus on chromosome 12 (OMIM 603221, two-point LOD score 3.85 for markers D12S1706 and D12S327 at 12q21-23) allowed us to significantly refine a minimum consensus region. This new composite region is located between microsatellite marker D12S1684 at 75.8 K and SNP_A-1509586 (alias rs717996) at position 82,636,288 bp, and narrows the original 30.1 cM of the MYP3 interval to 6.8 cM. The refined MYP3 interval allowed us to restrict the list of database-indexed genes to 25, several of which are promising MYP3 candidates based on similarities with genes and proteins involved in vision physiology and eye disease. While autosomal dominant high-grade myopia is recognized to be genetically heterogeneous, our results suggest genetic homogeneity of the MYP3-based condition in families that share the same ethnic and geographical background. The future identification of this MYP3 gene may provide insights into the pathophysiology of myopia and eye development.
Int J Mol Med 2008 Apr
PMID:Refinement of the MYP3 locus on human chromosome 12 in a German family with Mendelian autosomal dominant high-grade myopia by SNP array mapping. 1836 Jun 88

Mutations in the gene LRP2 have recently been identified as the cause of Donnai-Barrow and Facio-oculo-acoustico-renal (DB/FOAR) syndrome. More than two dozen cases, the first reported more than 30 years ago by Holmes, have been published. Summarizing available information, we highlight the cardinal features of the disorder found in >or=90% of published cases. These features include: agenesis of the corpus callosum, developmental delay, enlarged anterior fontanelle, high myopia, hypertelorism, proteinuria, and sensorineural hearing loss. Congenital diaphragmatic hernia and omphalocele are reported in only half of the patients. There is no evidence for genotype-phenotype correlation, though the sample size is too small to preclude this with certainty. Although several conditions to consider in the differential diagnosis are highlighted, the diagnosis of DB/FOAR syndrome should not be difficult to establish as its constellation of findings is strikingly characteristic.
Birth Defects Res A Clin Mol Teratol 2009 Jan
PMID:A review of Donnai-Barrow and facio-oculo-acoustico-renal (DB/FOAR) syndrome: clinical features and differential diagnosis. 1908 58


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