| 11. |
- Abrahamson, Magnus
(author)
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Cystatins
- 1994
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In: Methods in Enzymology. - : Elsevier. - 0076-6879. ; 244, s. 685-700
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Journal article (peer-reviewed)
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| 12. |
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| 13. |
- Abrahamson, Magnus, et al.
(author)
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Hereditary cystatin C amyloid angiopathy: Identification of the disease causing mutation and specific diagnosis by polymerase chain reaction based analysis
- 1992
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In: Human Genetics. - 1432-1203. ; 89:4, s. 377-380
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Journal article (peer-reviewed)abstract
- Hereditary cystatin C amyloid angiopathy (HCCAA) is a dominantly inherited disease characterized by amyloidosis, dementia and fatal cerebral hemorrhage of young adults. A method for rapid and simple diagnosis of HCCAA is described. It is based upon oligonucleotide-directed enzymatic amplification of a 275-bp genomic DNA segment containing exon 2 of the cystatin C gene from a blood sample, followed by digestion of the amplification product with AluI. Loss of an AluI recognition site in the amplified DNA segment from HCCAA patients results in a deviating band-pattern at agarose gel electrophoresis, compared with that obtained from normal subjects or unaffected HCCAA family members. In a population of 9 patients with manifest HCCAA, 14 patients with other causes of brain hemorrhage and 16 healthy individuals, the diagnostic procedure displayed a sensitivity and specificity for HCCAA of 100%. Amplified DNA segments from 4 HCCAA patients of four different families were analyzed by nucleotide sequencing; the HCCAA-causing mutation in all families was found to be a single TrarrA substitution in the codon for amino acid residue 68 of cystatin C.
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| 14. |
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| 15. |
- Abrahamson, Magnus, et al.
(author)
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Human cystatin C: Role of the N-terminal segment in the inhibition of human cysteine proteinases and in its inactivation by leucocyte elastase
- 1991
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In: Biochemical Journal. - 0264-6021. ; 273:3, s. 621-626
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Journal article (peer-reviewed)abstract
- Leucocyte elastase in catalytic amounts was observed to rapidly cleave the Val-10-Gly-11 bond of the human cysteine-proteinase inhibitor cystatin C at neutral pH. The resulting modified inhibitor had size and amino acid composition consistent with a cystatin C molecule devoid of the N-terminal Ser-1-Val-10 decapeptide. Leucocyte-elastase-modified cystatin C had more than 240-fold lower affinity than native cystatin C for papain. Removal of the N-terminal decapeptide of human cystatin C also decreased inhibition of human cathepsins B and L by three orders of magnitude, but decreased inhibition of cathepsin H by only 5-fold. A tripeptidyldiazomethane analogue of of the N-terminal portion of cystatin C was a good inhibitor of cathepsins B and L but a poor inhibitor of cathepsin H. It therefore appears that amino acid side chains of the N-terminal segment of cystatin C bind in the substrate-binding pockets of cathepsins B and L but not in those of cathepsin H. It is argued that the N-terminal cystatin C interaction with cathepsin B is physiologically important and hence that leucocyte elastase could have a function as a regulator of extracellular cysteine-proteinase inhibitory activity at sites of inflammation.
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| 16. |
- Abrahamson, Magnus, et al.
(author)
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Increased body temperature accelerates aggregation of the (Leu-68–>Gln) mutant cystatin C, the amyloid-forming protein in hereditary cystatin C amyloid angiopathy
- 1994
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In: Proceedings of the National Academy of Sciences. - 1091-6490. ; 91:4, s. 1416-1420
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Journal article (peer-reviewed)abstract
- Hereditary cystatin C amyloid angiopathy is a dominantly inherited disorder, characterized by dementia, paralysis, and death from cerebral hemorrhage in early adult life. A variant of the cysteine proteinase inhibitor, cystatin C, is deposited as amyloid in the tissues of the patients and their spinal-fluid level of cystatin C is abnormally low. The disease-associated Leu-68-->Gln mutant (L68Q) cystatin C has been produced in an Escherichia coli expression system and isolated by use of denaturing buffers, immunosorption, and gel filtration. Parallel physicochemical and functional investigations of L68Q-cystatin C and wild-type cystatin C revealed that both proteins effectively inhibit the cysteine proteinase cathepsin B (equilibrium constants for dissociation, 0.4 and 0.5 nM, respectively) but differ considerably in their tendency to dimerize and form aggregates. While wild-type cystatin C is monomeric and functionally active even after prolonged storage at elevated temperatures, L68Q-cystatin C starts to dimerize and lose biological activity immediately after it is transferred to a nondenaturing buffer. The dimerization of L68Q-cystatin C is highly temperature-dependent, with a rise in incubation temperature from 37 to 40 degrees C resulting in a 150% increase in dimerization rate. The aggregation at physiological concentrations is likewise increased at 40 compared to 37 degrees C, by approximately 60%. These properties of L68Q-cystatin C have bearing upon our understanding of the pathophysiological process of hereditary cystatin C amyloid angiopathy. They might also be of clinical relevance, since medical intervention to abort febrile periods of carriers of the disease trait may reduce the in vivo formation of L68Q-cystatin C aggregates.
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| 17. |
- Abrahamson, Magnus, et al.
(author)
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Modification of cystatin C activity by bacterial proteinases and neutrophil elastase in periodontitis
- 1997
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In: Molecular Pathology. - 1366-8714. ; 50:6, s. 291-297
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Journal article (peer-reviewed)abstract
- AIM: To study the interaction between the human cysteine proteinase inhibitor, cystatin C, and proteinases of periodontitis associated bacteria. METHODS: Gingival crevicular fluid samples were collected from discrete periodontitis sites and their cystatin C content was estimated by enzyme linked immunosorbent assay (ELISA). The interaction between cystatin C and proteolytic enzymes from cultured strains of the gingival bacteria Porphyromonas gingivalis, Prevotella intermedia, and Actinobacillus actinomycetemcomitans was studied by measuring inhibition of enzyme activity against peptidyl substrates, by detection of break down patterns of solid phase coupled and soluble cystatin C, and by N-terminal sequence analysis of cystatin C products resulting from the interactions. RESULTS: Gingival crevicular fluid contained cystatin C at a concentration of approximately 15 nM. Cystatin C did not inhibit the principal thiol stimulated proteinase activity of P gingivalis. Instead, strains of P gingivalis and P intermedia, but not A actinomycetemcomitans, released cystatin C modifying proteinases. Extracts of five P gingivalis and five P intermedia strains all hydrolysed bonds in the N-terminal region of cystatin C at physiological pH values. The modified cystatin C resulting from incubation with one P gingivalis strain was isolated and found to lack the eight most N-terminal residues. The affinity of the modified inhibitor for cathepsin B was 20-fold lower (Ki 5 nM) than that of full length cystatin C. A 50 kDa thiol stimulated proteinase, gingipain R, was isolated from P gingivalis and shown to be responsible for the Arg8-bond hydrolysis in cystatin C. The cathepsin B inhibitory activity of cystatin C incubated with gingival crevicular fluid was rapidly abolished after Val10-bond cleavage by elastase from exudate neutrophils, but cleavage at the gingipain specific Arg8-bond was also demonstrated. CONCLUSIONS: The physiological control of cathepsin B activity is impeded in periodontitis, owing to the release of proteinases from infecting P gingivalis and neutrophils, with a contribution to the tissue destruction seen in periodontitis as a probable consequence.
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| 18. |
- Abrahamson, Magnus
(author)
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Molecular basis for amyloidosis related to hereditary brain hemorrhage
- 1996
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In: Scandinavian journal of clinical and laboratory investigation. Supplementum. - 0085-591X. ; 56:226, s. 47-56
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Journal article (peer-reviewed)abstract
- The aim of the project has been to elucidate molecular events leading to amyloidosis in Hereditary Cystatin C Amyloid Angiopathy (HCCAA) patients, to enable simple diagnosis of the disease and with the ultimate goal to understand the amyloid formation process in detail, in order to develop inhibitors to the process. At the DNA level, a point mutation segregating with HCCAA was identified in the cystatin C gene on chromosome 20, after basic characterization of cDNA and gene for the wildtype protein. The mutation results in the amino acid substitution Leu-68-Gin (L68Q) and abolishes a recognition site for Alu I. This information was used to design a PCR based assay for simple and rapid mutation detection in DNA from blood samples to allow routine diagnosis of HCCAA. Studies at the protein level, allowed through E. coli expression of wildtype and L68Q mutated cystatin C genes, revealed that both protein variants effectively inhibit the cysteine proteinase cathepsin B (equilibrium constants for dissociation: 0.4 and 0.3 nM, respectively), but differ considerably in their tendency to dimerize and form aggregates. The initial dimerization of L68Q-cystatin C results in complete loss of biological activity and is highly temperature-dependent, with a rise in incubation temperature from 37 to 40 degrees C resulting in a 150% increase in dimerization rate. This result might be of clinical relevance, since medical intervention to abort febrile periods of carriers of the disease trait may reduce the in vivo formation of L68Q-cystatin C aggregates. The three-dimensional structure of normal cystatin C, crystallized in a complex with cathepsin B, was elucidated by X-ray analysis and subsequent refinement of the structure to 3.0 A resolution. Besides pinpointing the cystatin C structures resulting in efficient target enzyme inhibition, the results demonstrated that the Leu-68 residue is buried in the hydrophobic core of the protein. Studies of the three-dimensional solution structure of wildtype cystatin C by NMR spectroscopy revealed that cystatin C dimers can be formed as a result of slight, localized structural changes under conditions preceding complete defolding and denaturation of the protein. Dimers of L68Q-cystatin C are likely similar but are formed at temperatures nearly 30 degrees C lower than needed for the wildtype protein, indicating that the Leu-68-Gln substitution lowers the transition temperature for unfolding. Thus, the results presented suggest that cystatin C provides a system where decreased stability of a mutant protein correlates with its amyloidogenic nature. The NMR results furthermore imply that the hydrophobic proteinase-binding region of cystatin C is directly involved in dimer formation and that compounds designed to interact with this region could serve as inhibitors to the dimerization, and likely also the subsequent amyloid formation process, of cystatin C in HCCAA patients.
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| 19. |
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| 20. |
- Abrahamson, Magnus, et al.
(author)
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Structure and expression of the human cystatin C gene
- 1990
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In: Biochemical Journal. - 1470-8728. ; 268:2, s. 287-294
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Journal article (peer-reviewed)abstract
- The structural organization of the gene for the human cysteine-proteinase inhibitor cystatin C was studied. Restriction-endonuclease digests of human genomic DNA hybridized with human cystatin C cDNA and genomic probes produced patterns consistent with a single cystatin C gene and, also, the presence of six closely related sequences in the human genome. A 30 kb restriction map covering the genomic region of the cystatin C gene was constructed. The positions of three polymorphic restriction sites, found at examination of digests of genomic DNA from 79 subjects, were localized in the flanking regions of the gene. The gene was cloned and the nucleotide sequence of a 7.3 kb genomic segment was determined, containing the three exons of the cystatin C structural gene as well as 1.0 kb of 5'-flanking and 2.0 kb of 3'-flanking sequences. Northern-blot experiments revealed that the cystatin C gene is expressed in every human tissue examined, including kidney, liver, pancreas, intestine, stomach, antrum, lung and placenta. The highest cystatin C expression was seen in seminal vesicles. The apparently non-tissue-specific expression of this cysteine-proteinase inhibitor gene is discussed with respect to the structure of its 5'-flanking region, which shares several features with those of housekeeping genes.
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