Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.4.21.69 (APC)
16,337 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have applied single-strand conformation polymorphism (SSCP) to the analysis of exon 7 of the anticoagulant protein C (PC) gene, in 13 PC-deficient Spanish families. Abnormal patterns were visualized in three samples from type I or quantitative PC deficient proposita. A previously undescribed mutation due to a TT insertion after nucleotide 6139, between codons Gly-142 and Arg-143 was found in one family. The mutation (6139,ins TT) should result in a frameshift with a stop at codon 156, which agrees with the presence of a type I or quantitative PC deficiency in the affected members of the family. The second mutation identified was a C to T transition at nucleotide 6274, 9 base pairs into intron G. This mutation (6274,C-->T), found for the first time in a Spanish family, is identical to the previously characterized PC Sant Louis. The third mutation was a G to A transition that replaces arginine 178 with glutamine (178,R-->Q). This is the third case of 178,R-->Q mutation in 17 apparently unrelated Spanish families with type I PC deficiency. Furthermore, SSCP analysis allowed the detection of another previously described mutation in a PC-deficient Spanish family (178,R-->W).
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PMID:Protein C deficiency: identification of a novel two-base pair insertion and two point mutations in exon 7 of the protein C gene in Spanish families. 130 54

We utilized quantitative electron microscopic immunogold labeling procedures to follow changes in the intragranular content of five secretory proteins of the rat submandibular gland (SMG) during and after chronic treatment with the beta-adrenergic agonist isoproterenol (IPR). Labeling intensities (gold particles/microns2) of acinar cell secretory granules for mucin and glutamine/glutamic acid-rich proteins, major secretory proteins of the normal SMG, showed opposite responses to IPR. Labeling intensities increased for mucin and decreased for glutamine/glutamic acid-rich proteins immediately after IPR injections began, then rapidly returned to control levels after cessation of IPR treatment. SMG Protein C immunoreactivity, found in both acinar and intercalated duct granules, was less affected by IPR. However, opposite changes in labeling intensity were observed between acinar and intercalated duct granules. Labeling intensities for proline-rich proteins, IPR-inducible secretory proteins, increased only after 10 days of stimulation and maintained a high level even after cessation of drug treatment. Type 2 cystatin, another IPR-inducible protein, increased gradually with chronic IPR treatment and decreased slowly during the recovery phase. These results suggest that chronic beta-adrenergic stimulation affects the expression of genes for several rat SMG secretory proteins in a different manner.
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PMID:Quantitative immunocytochemistry of rat submandibular secretory proteins during chronic isoproterenol administration and recovery. 186 12

Class II MHC (Ia) molecules have been shown to be critical as restriction elements in the T helper/inducer cell recognition of antigen. Efforts to determine the role of allelic variation in MHC restricted antigen presentation have included the use of serologically selected mutants to correlate structural variations in Class II molecules with changes in the antigen presenting function of Ia bearing cells. Such studies have revealed that serologically selected mutations tend to occur in a single immunodominant region and that even a single amino acid substitution can alter T cell recognition of Ia molecules. We report here the characterization of two more serologically selected Class II A beta chain mutations. Each is due to a single base change which alters a single amino acid. One of these mutations is in the third hypervariable region (amino acid 64--glutamine to arginine) and alters the antigen presenting function. The second mutation at amino acid 48, though a relatively non-conservative change (arginine to cysteine), has no effect on APC phenotype. Such a result would be predicted based on comparisons made with the proposed three dimensional crystallographic structure of Class I molecules and models proposed for Class II molecules based on Class I structure. The amino acid change at position 48 is in a portion of the molecule that is most likely unavailable to bind antigen or interact with T cell receptor whereas the mutation at amino acid 64 is on an exposed face of the alpha helix, a region which could affect interaction with either antigen and/or the T cell receptor.
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PMID:Functional and molecular characterization of I-A kappa beta mutants is consistent with the predicted three dimensional structure of class II MHC molecules. 239 36

Homologous "propeptide" regions are present in a family of vitamin K-dependent mammalian proteins, including clotting factors II, VII, IX, X, protein C, protein S and bone "gla" proteins. To test the hypothesis that the propeptide is a signal for the correct gamma-carboxylation of the adjacent gamma-carboxy region, we have mutated amino acid -4 of human factor IX from an arginine to a glutamine residue, by M13-directed site-specific mutagenesis of a cDNA clone. After expression of mutant factor IX in dog kidney cells, we find that it is secreted into the medium in a precursor form containing the propeptide, and is inefficiently gamma-carboxylated compared to the control, wild-type, recombinant factor IX. This result supports the hypothesis that the propeptide region is required for efficient gamma-carboxylation of factor IX in dog kidney cells. Furthermore, it confirms previous results that arginine at amino acid -4 is required for correct propeptide processing.
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PMID:The propeptide region of clotting factor IX is a signal for a vitamin K dependent carboxylase: evidence from protein engineering of amino acid -4. 368 2

The complete primary structure of a calcium-binding "proline-rich phosphoprotein" named salivary Protein C was determined from peptides obtained by enzymatic and chemical cleavages of the protein. The protein consists of a single polypeptide chain of 150 residues. It contains the entire primary structure of a previously isolated salivary Protein A in its NH2-terminal 106 residues. The COOH-terminal 44 residues consist mostly of glycine, glutamine, and proline, including a hexaproline sequence, but no polyproline structure could be detected by CD spectroscopy. There is extensive repetition of sequences in the protein, suggesting gene multiplication and recurrent folding. Comparison of the primary structure of salivary Proteins A and C with known protein sequences indicate that the salivary proteins constitute a new family. A mouse submaxillary protease will cleave salivary Protein C between residues 106 and 107 only, giving rise to salivary Protein A and a 44-residue COOH-terminal peptide. This cleavage and the sequence data suggest that salivary Protein C may be a precursor of salivary Protein A.
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PMID:The primary structure of a salivary calcium-binding proline-rich phosphoprotein (protein C), a possible precursor of a related salivary protein A. 738 Aug 45

Inherited resistance to activated protein C (APC) is a frequent cause of familial thrombosis. It is associated with a factor V gene point mutation replacing arginine506 in the APC-cleavage site with a glutamine. Thrombotic events are rare during childhood even in patients with homozygous APC-resistance. We now wish to report on a case of severe venous thrombosis, in a 10-year-old boy. He was found to have pronounced APC-resistance due to homozygous factor V gene mutation in combination with inherited type I protein S deficiency. The two traits were independently inherited in the family. The APC-resistance was partially corrected by adding factor V, whereas added protein S was without effect. This is the first reported case of homozygous APC-resistance combined with another inherited prothrombotic disorder. It illustrates how multiple genetic defects may provoke thrombosis at young age and emphasizes the need of complete evaluation of thrombotic patients in order to determine whether multiple risk factors exist.
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PMID:Homozygous APC-resistance combined with inherited type I protein S deficiency in a young boy with severe thrombotic disease. 748 96

A point mutation in coagulation factor V which causes resistance to cleavage of factor Va by activated protein C (APC), was recently found to underlie thrombotic events. We examined 20 consecutive patients, under the age of 40, who suffered from idiopathic venous or arterial thrombosis. In 8 (40%) there was resistance to APC manifested by absence of the expected prolongation of activated partial thromboplastin time (aPTT). In 3, the addition of normal plasma corrected the anomaly in the patient's plasma, although the addition of factor V- deficient plasma caused no change. In a family of a 17-year-old boy with idiopathic deep venous thrombosis we found a mutation in factor V which was responsible for APC resistance. The patient and 4 family members showed a single G to A transition in position 1691 in their cDNA, resulting in substitution of arginine (506) for glutamine. The mutation in this area, which is the cleavage site for APC, is associated with thrombotic episodes and is frequently observed in patients with familial thrombophilia.
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PMID:[Resistance to activated protein C--a novel cause of thrombophilia]. 755 99

Aberrations of the APC gene, which plays an important role in the genesis of familial adenomatous polyposis and colorectal carcinoma, were investigated in 31 surgical specimens of primary breast carcinoma. These studies utilized the polymerase chain reaction followed by restriction-fragment-length polymorphism and single-strand-conformation polymorphism analyses combined with tumor cell enrichment by cell sorting. Loss of heterozygosity at the APC locus was detected in 8 (38%) of 21 informative cases, but only 2 (6%) of 31 tumors carried a mutated APC gene. Direct DNA sequencing analysis confirmed mutations at codon 1081 (AGC to ATC) resulting in an amino acid substitution of serine for isoleucine, and at codon 1096 (CAG to CAT) resulting in a substitution of glutamine for histidine. There were no significant correlations between the loss of heterozygosity or mutation at the APC locus and any clinicopathological characteristics. Our present observations suggest that the mutations of the APC gene may play an important role in the genesis of certain breast carcinomas, and that another tumor-suppressor gene, which is the true target of frequent loss of heterozygosity, may exist near the APC gene.
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PMID:Aberrations of the APC gene in primary breast carcinoma. 779 98

Venous thromboembolism is often familial, suggesting that genetic risk factors are involved. Until recently, genetic defects known to predispose for thrombosis (deficiencies of antithrombin III, protein C, and protein S) had not been shown to account for more than 5-10% of the cases. Inherited resistance to the anticoagulant function of activated protein C (APC) in the last year has been identified as a major basis for familial thrombosis. Unlike other genetic risk factors for thrombosis, APC resistance is highly prevalent in the general population (2-5%). In more than 90% of cases, the APC-resistance phenotype is associated with a point mutation in the factor V gene, which predicts replacement of arginine at position 506 with a glutamine. As APC inhibits factor Va by cleavage at arginine 506, mutated factor V is resistant to APC. In its heterozygous state, the mutation is associated with a 5-10-fold increased risk of thrombosis. Homozygocity is associated with more severe APC resistance, and with a higher risk of thrombosis. Because of its high prevalence in the population, individuals with deficiencies of other anticoagulant proteins occasionally carry the factor V gene mutation. People with such combinations of mutations have a higher risk of thrombosis than those with the single mutations. In conclusion, in the majority of familial thrombosis cases it is now possible to identify an underlying genetic risk factor. APC resistance caused by a single, factor V gene mutation, is the most frequent risk factor and it is at least ten times more common than any of the other genetic defects associated with thrombosis.
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PMID:Factor V gene mutation causing inherited resistance to activated protein C as a basis for venous thromboembolism. 789 Oct 43

Our laboratory recently found a novel mechanism for thrombophilia, which is characterized by an inherited resistance to activated protein C (APC). The APC-resistance test, which measures the anticoagulant response to APC in an activated partial thromboplasin time (APTT) reaction, was devised and used to screen a cohort of consecutive thrombosis patients. APC-resistance was found in approximately 40% of the cases. Other known causes for thrombosis, such as deficiencies of protein C, protein S or antithrombin, were found in another 5% of the patients. Our results, which have recently been confirmed from other laboratories, suggest APC-resistance to be highly prevalent in thrombosis patients. In a majority of cases, APC-resistance was demonstrated to be inherited and family studies revealed an autosomal dominant mode of inheritance. In the investigated families, APC-resistance was associated with thrombosis, which suggests a causal relationship between APC-resistance and thrombosis. An anticoagulant cofactor activity, which corrected APC-resistance, was found in normal plasma, whereas plasma from an individual with pronounced APC-resistance was devoid of this activity. Purification and characterization of the novel APC-cofactor suprisingly revealed that it was identical to coagulation factor V. Thus, factor V is not only an important procoagulant, but also expresses anticoagulant properties as a cofactor to APC. Our present data suggest the anticoagulant function to be a property of unactivated factor V, whereas the procoagulant activity is expressed after activation to Va. APC-resistant individuals have normal levels of procoagulant V-activity, it is now known that APC-resistance is caused by mutation in the factor V gene changing arginine 506 to a glutamine, thus affecting the APC-cleavage site.
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PMID:Inherited resistance to activated protein C, a major cause of venous thrombosis, is due to a mutation in the factor V gene. 795 62


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