UNIPROT:P00790 - FACTA Search

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Query: UNIPROT:P00790 (PGA)
2,475 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. The literature on molecular properties and physiological role of aspartic proteinases in fishes and aquatic invertebrates has been reviewed. 2. Pepsins have not been detected in invertebrates, and apparently cathepsin D, as well as other cathepsins, act both as digestive and lysosomal enzymes in many of these animals. The molecular properties of invertebrate cathepsin D correspond with cathepsin D in fishes and mammalians. 3. Fishes with a true stomach have pepsinogen secretion. Fish pepsins have higher pH optimum and are less stable in strong acid conditions than mammalian pepsins. They are very efficient at low temperatures, but less thermostable than mammalian pepsins. 4. Many fishes have two significantly different pepsins: Pepsin I and Pepsin II, which digest haemoglobin at a maximal rate in the pH ranges 3-4 and 2-3 respectively. Usually the pI of Pepsin I is in the range 6.5-7, whereas pI of Pepsin II is about 4. 5. Fish Pepsin I and cathepsin D have very similar molecular properties, and a hypothesis proposing that cathepsin D is the ancestor enzyme of aspartic proteinases in higher animals is presented.
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PMID:Aspartic proteinases in fishes and aquatic invertebrates. 314 85

Precursors of the gastric proteases pepsinogen A (pepsinogen I) and pepsinogen C (pepsinogen II) and slow-moving protease were demonstrated in biopsy specimens from Barrett's epithelium in 21 of 22 patients with Barrett's esophagus; in 14 of them, in variable combinations at different sites. In 13 of 19 patients (68.4%) with detectable pepsinogen A, different isozymogen patterns were found between the Barrett's epithelium and the gastric corpus mucosa. Discrepancies consisted mainly of a stronger pepsinogen 5 band in the Barrett's epithelium, with a higher incidence in biopsy specimens with features of dysplasia than with no or indefinite dysplasia; the difference was, however, not statistically significant. Zymograms of 69 biopsy specimens from Barrett's epithelium were correlated with the histologic type: pepsinogen A and C were most frequently found in the fundic type, least often in the specialized intestinal type. In control gastric corpus biopsy specimens, pepsinogen A and C as well as slow-moving protease were always detectable. The observed variability of gastric protease patterns, in particular of pepsinogen A isozymograms, may be due to differences in expression within the pepsinogen A cluster, suggesting a deregulation of gene expression or partial deletion of the pepsinogen A gene cluster.
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PMID:Gastric proteases in Barrett's esophagus. 330 35

Pepsin is a potent proteolytic enzyme stored and secreted by chief cells in an inactive precursor form, pepsinogen. Its secretion is modulated by both cAMP and calcium-dependent mechanisms. Abnormalities in levels of pepsinogen and its various isozymogens have been linked clinically, epidemiologically, and experimentally to peptic ulcer disease and gastric carcinoma. The ulcerogenesis of pepsin stems from its ability to breach gastroduodenal mucosal barriers. Furthermore, certain isozymogens seems abundant and hyperactive in patients with peptic ulcer disease. The etiology and significance of low pepsinogen levels with disproportionate elevations of pepsinogen II and pepsin 5 in gastric cancer and its precursors is less clear. Further exploration of the patho-physiologic role of pepsin is likely to be of considerable importance in initiating further advances in the understanding and treatment of upper gastrointestinal disease.
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PMID:Pepsinogen. Prolate ellipsoid or unrecognized pathogen? 330 25

In this paper the role of pepsinogen has been reviewed in its physiological and clinical aspects. Although acid secretion has traditionally received far more attention clinically and has therefore been studied in great detail, the development of cellular systems has recently seen a revival in interest of pepsinogen secretion. These systems have made it possible to study pepsinogen secretion in more detail. Although many questions remain unanswered, a picture of a stimulus-secretion coupling mechanism of the chief cell has emerged that resembles in many aspects the pancreatic acinar cell, but also possesses some unique features of its own. The chief cell monolayer culture has also made it possible to study pepsinogen synthesis, and these studies seem to have solved the old controversy of whether or not modulation of pepsinogen synthesis occurs as a result of increased secretion. It now seems that pepsinogen synthesis does indeed increase in response to stimulated secretion. In addition to physiological studies, this review has discussed clinical aspects of the human pepsinogens in various gastric disorders. The clinical implications of genetic heterogeneity of the human pepsinogens are especially intriguing. Relationships between certain PGA phenotypes and certain gastric disorders have been described and some studies have tried to evaluate the relevance of these findings for diagnostic purposes. So far, it seems that PGA phenotyping alone has only limited diagnostic value, but, in combination with serum PGA determinations, could be of additional help in the diagnosis of gastric malignancy. In addition, various studies suggest that the ratio of serum PGA and PGC levels may be helpful in determining the histological status of the gastric mucosa. A very promising possibility in solving the many problems involved in exact genotype determinations through phenotyping is the recent availability of cDNA probes. With this technique, the question of whether the association between PGA phenotypes and gastric malignancy is primary or secondary may be solved in the near future. In view of the very poor prognosis for gastric cancer, further studies concerning the relationships between gastric cancer, serum pepsinogen levels, and PGA phenotypes or genotypes will hopefully lead to the possibility of an earlier diagnosis for gastric malignancy.
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PMID:Pepsinogens: an update of biochemical, physiological, and clinical aspects. 332 41

The genes coding for human pepsinogen (PGA3, PGA4, and PGA5) were assigned to chromosome region 11q13 by in situ hybridization. Previously we localized the PGA gene complex to a centromeric region of chromosome 11 (p11----q13) by Southern blot analysis of mouse-human somatic cell hybrids. Our in situ hybridization results confirm this assignment and further localize the genes to a smaller region on the long arm.
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PMID:Assignment of the pepsinogen gene complex (PGA) to human chromosome region 11q13 by in situ hybridization. 346 2

The determination of serum pepsinogen A (= pepsinogen I) levels is of clinical importance in the study of duodenal ulcer, atrophic gastritis and gastric cancer. In the present study two different quantitative immunological techniques for serum pepsinogen A were compared: a radioimmunoassay (RIA) (Helsinki) and an enzyme-linked immunosorbent assay (ELISA) (Amsterdam). Serum samples of 177 subjects with various gastric diseases were tested in a double blind study. The correlation was excellent (r = 0.954 in the range 0-760 micrograms/l and r = 0.971 in the range 0-100 micrograms/l). The functional relationship between ELISA (x) and RIA (y), determined by weighted model II regression, was y = 1.12x-0.54. Initially the use of goat anti-PGA in the ELISA resulted in falsely high values in about 10% of the individuals. This was caused by circulating antibodies cross-reacting with goat IgG. This artefact was eliminated by pre-incubation of all samples with non-immune goat serum.
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PMID:Enzyme-linked immunosorbent assay and radioimmunoassay of serum pepsinogen A. 355 88

Serum pepsinogen A (pepsinogen I) levels and urinary pepsinogen A phenotypes were studied in relation to ABO blood group, age and sex in 700 healthy blood donors. There was no relation between urinary pepsinogen A phenotypes and serum pepsinogen A levels. It is concluded that serum PGA levels and PGA phenotypes are independent factors in predisposition to gastroduodenal disorders. Serum pepsinogen A levels were higher in males than in females and rose with increasing age. The ABO blood groups were not related to pepsinogen A phenotypes. Blood group O individuals showed higher serum pepsinogen A levels compared with blood group A. Pepsinogen A phenotypes with intensity of fraction 5 were more frequent in males compared with females.
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PMID:Relations between serum pepsinogen levels, pepsinogen phenotypes, ABO blood groups, age and sex in blood donors. 406 35

Total human pepsinogen (PG) was isolated from gastric fundic mucosa and PGA (formerly called PGI) from urine, using standard ion-exchange and gel filtration techniques. Gastric PGA was separated from PGC (formerly called PGII) either by immunoaffinity or high resolution ion-exchange chromatography (fast protein liquid chromatography, Pharmacia, Uppsala, Sweden). The individual PGA isozymogens 2, 3, 4 and 5 could be isolated to homogeneity with the aid of the same ion-exchanger. Evidence was obtained for the existence of secondary modifications of the PGA fractions 3, 4 and 5, electrophoretically overlapping the primary (genetic) isozymogens.
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PMID:Purification of the pepsinogen A isozymogens by means of high resolution ion-exchange chromatography. Evidence for post-translational modifications. 407 Sep 62

Methods are described for the isolation and purification of pepsin D, an enzyme which accounts for about 10% of the enzymic activity in commercial preparations of pepsin. Pepsin D is similar to pepsin in having a molecular weight of about 35000, the same C-terminal amino acid sequence, and an N-terminal isoleucine residue. It differs in having no phosphate residue. Pepsin D is similar to pepsin in its ability to digest haemoglobin, acetyl-l-phenylalanyl-l-di-iodotyrosine and gelatin but it is twice as active as pepsin in the clotting of milk. It has the same specificity as pepsin in its action on the B-chain of oxidized insulin. It is probable that the pepsin D in commercial preparations of pepsin arises from the activation of gastric pepsinogen D.
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PMID:Pepsin D. A minor component of commercial pepsin preparations. 486 Jun 38

Population frequencies of the two patterns of pepsinogen excretion (with and without pepsinogen 5) and family studies indicate that pepsinogen 5 is controlled by a pair of genes, Pg(a) and Pg(b), at a single autosomal locus and that Pg(a) is dominant.
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PMID:Pepsinogens: genetic polymorphism in man. 490 86

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