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
Query: UMLS:C1389183 (
autodigestion
)
317
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Bacillus neutral proteases were purified using bacitracin-silica as an affinity medium. Several chromatographic procedures were investigated, including high speed runs on columns with 40- to 60-microns silica particles. The high speed procedure enabled the purification of 4.9 mg of B. subtilis neutral protease directly from 165-ml culture supernatant within 1.5 h. The neutral proteases of B. polymyxa and B. stearothermophilus were also purified. The latter enzyme was further concentrated by a second affinity chromatography step, using Sepharose with glycyl-D-
phenylalanine
as a ligand. During the purification procedures isopropanol was used to prevent
autodigestion
of the enzymes.
...
PMID:High performance affinity chromatography of Bacillus neutral proteases. 177 13
LexA repressor of Escherichia coli is inactivated by a specific cleavage reaction that requires activated RecA protein in vivo. This cleavage reaction can proceed in vitro in the presence of activated RecA or as an intramolecular RecA-independent reaction, termed
autodigestion
, that is stimulated by alkaline pH. Here we describe a set of LexA mutant proteins that undergo a greatly increased rate of specific cleavage in vivo, compared with wild-type LexA. Efficient in vivo cleavage of these mutant proteins also took place without RecA. Several lines of evidence suggest that cleavage occurred via a mechanism similar to
autodigestion
. These mutations changed Gln-92, which lies near the cleavage site, to tyrosine,
phenylalanine
, or tryptophan. The latter mutation increased the rate of cleavage approximately 500-fold. These findings imply that the rate of wild-type LexA cleavage has been optimized during evolution to make the SOS system properly responsive to DNA-damaging treatments. Availability of these mutants will aid in the understanding of rate-limiting steps in intramolecular reactions.
...
PMID:Mutant LexA proteins with an increased rate of in vivo cleavage. 190 93
The role of Tyr264 in nucleotide binding and hydrolysis catalyzed by the RecA protein of Escherichia coli was investigated by constructing Gly, Ser, and
Phe
substitution mutations using oligonucleotide-directed mutagenesis. The corresponding mutant recA genes neither restored resistance to killing by ultraviolet irradiation nor increased homologous recombination in a recA strain. The purified RecA(Gly264) protein was unable to bind nucleotide, hydrolyze ATP, or form stable ternary complexes with adenosine 5'-O-thiotriphosphate and DNA although the mutant protein bound DNA normally in the absence of nucleotide. The RecA (Phe264) and RecA(Ser264) proteins hydrolyzed ATP poorly and the rates were reduced approximately 8- and 18-fold, respectively. Although capable of low levels of ATP hydrolysis, neither the RecA(Phe264) nor the RecA(Ser264) protein promoted DNA pairing or strand exchange reactions in vitro. Furthermore, these mutant RecA proteins were impaired in their ability to form salt-resistant ternary complexes with adenosine 5'-O-thiotriphosphate) and DNA as judged by filter binding. Nevertheless, nucleoprotein complexes formed with either RecA(Phe264) or RecA(Ser264) protein directed efficient cleavage of LexA repressor in vitro. These results demonstrate that Tyr264 is required for efficient ATP hydrolysis and for homologous pairing of DNA but does not participate in activating RecA protein for LexA repressor
autodigestion
.
...
PMID:Site-directed mutagenesis of the RecA protein of Escherichia coli. Tyrosine 264 is required for efficient ATP hydrolysis and strand exchange but not for LexA repressor inactivation. 201 15
Nutritional factors, especially the protein and fat content of the diet, may alter the likelihood of pancreatic injury after a number of insults, including chronic ethanol intake. This issue was studied experimentally by match-feeding rats liquid diets of varying protein content with and without ethanol. Protein synthesis and enzyme secretion were investigated, because these parameters are believed to increase the capacity for pancreatic
autodigestion
. Protein synthesis was assessed by determining the incorporation of tritiated
phenylalanine
into trichloroacetic acid precipitated protein 10 minutes after IP injection and then corrected for the size of the precursor pool. Enzyme secretion was studied using pancreatic acini, which were prepared using clostripain-poor collagenase. Chronic ethanol feeding stimulated protein synthesis and lipase secretion and content in rats receiving adequate amounts of protein. These stimulatory effects of ethanol were markedly attenuated in rats administered protein poor diets. Protein deficiency per se significantly decreased the weight, protein, and enzyme content of the rat pancreas as well as increased the percentage release of lipase from acini. Although extrapolation from animal studies may be tenuous, the present findings may explain the link between nutrition and the occurrence of alcoholic pancreatitis.
...
PMID:Interactive effects of dietary protein and ethanol on rat pancreas. Protein synthesis and enzyme secretion. 198 46
The concentration of bradykinin in human plasma depends on its relative rates of formation and destruction. Bradykinin is destroyed by two enzymes: a plasma carboxypeptidase (anaphylatoxin inactivator) removes the COOH-terminal arginine to yield an inactive octapeptide, and a dipeptidase (identical to the angiotensin-converting enzyme) removes the COOH-terminal
Phe
-Arg to yield a fragment of seven amino acids that is further fragmented to an end product of five amino acids. Formation of bradykinin is initiated on binding of Hageman factor (HF) to certain negatively charged surfaces on which it autoactivates by an
autodigestion
mechanism. Initiation appears to depend on a trace of intrinsic activity present in HF that is at most 1/4000 that of activated HF (HFa); alternatively traces of circulating HFa could subserve the same function. HFa then converts coagulation factor XI to activated factor XI (XIa) and prekallikrein to kallikrein. Kallikrein then digests high-molecular-weight kininogen (HMW-kininogen) to form bradykinin. Prekallikrein and factor XI circulate bound to HMW-kininogen and surface binding of these complexes is mediated via this kininogen. In the absence of HMW-kininogen, activation of prekallikrein and factor XI is much diminished; thus HMW-kininogen has a cofactor function in kinin formation and coagulation. Once a trace of kallikrein is generated, a positive feedback reaction occurs in which kallikrein rapidly activates HF. This is much faster than the HF autoactivation rate; thus most HFa is formed by a kallikrein-dependent mechanism. HMW-kininogen is also therefore a cofactor for HF activation, but its effect on HF activation is indirect because it occurs via kallikrein formation. HFa can be further digested by kallikrein to form an active fragment (HFf), which is not surface bound and acts in the fluid phase. The activity of HFf on factor XI is minimal, but it is a potent prekallikrein activator and can therefore perpetuate fluid phase bradykinin formation until it is inactivated by the C1 inhibitor. In the absence of C1 inhibitor (hereditary angioedema) HFf may also interact with C1 and activate it enzymatically. The resultant augmented bradykinin formation and complement activation may account for the pathogenesis of the swelling characteristic of hereditary angioedema and the serologic changes observed during acute attacks.
...
PMID:Hageman factor-dependent pathways: mechanism of initiation and bradykinin formation. 655 44
