Inhibition of protein synthesis by aminoglycoside antibiotics in polyamine-requiring bacteria

The effect of streptomycin and other aminoglycosides on protein synthesis has been studied using various streptomycin-sensitive strains unable to synthesize polyamines. We have confirmed and extended our previous results showing that the strong inhibition of translation caused by the antibiotic in polyamine-supplemented bacteria was markedly reduced in polyamine-starved cells. The analysis of polypeptides synthesized in the absence and presence of streptomycin in bacteria grown with and without putrescine has shown that the antibiotic provoked the accumulation of low molecular weight peptides partially bound to ribosomes in polyamine-unstarved cells. On the contrary, the drug did not induce major alterations in the patterns of proteins obtained from polyamine-depleted bacteria. The addition of the antibiotic did not evoke any change of proteolytic activity.     

Protein degradation during sporulation ofBacillus megaterium: Effect of actinomycin D

The first acceleration of protein degradation in cells ofBacillus megaterium was found at the stage 0–I of sporulation, the second one at the stage II–III, where the sporulation process became irreversible. These accelerations were reduced by actinomycin D inhibiting RNA and protein syntheses by more than 95%. In the presence of the antibiotic, only 8% of prelabeled proteins were degraded. Actinomycin D did not lower either the concentration of ATP or the proteolytic activity in the homogenate prepared from sporulating cells. This indicates that the inhibition of protein catabolism by actinomycin D was not owing to the absence of ATP or proteolytic enzymes. Actinomycin probably inhibited an unknown step preceding the proteolytic attack of the protein molecules during sporulation, because it had no significant effect on proteolysis during vegetative growth.     

Proteolytic activity in relationship to senescence and cotyledonary development in Pisum sativum L.

Changes in the weight and in the chlorophyll, free amino-acid and protein content of developing and senescing, vegetative and reproductive organs of Pisum sativum L. (cv. Burpeeana) were measured, and the proteolytic activity in extracts from the senescing leaf and the subtended pod was followed in relation to these changes. Protein content decreased in the ageing leaf and pod while it increased in the developing cotyledon. The proteolytic activity of the leaf did not increase as the leaf protein content decreased. In contrast, proteolytic activity in the subtended pod increased while the protein level decreased. The proteolytic activity in the extracts from the ageing organs was greater than the rates of protein loss. The proteolytic activity of leaf and pod extracts was greater on protein prepared from the respective organ than on non-physiological substrates. Proteolysis was increased by 2-mercaptoethanol and ethylenediaminetetraacetate but was not influenced by addition of ATP to the reaction mixture. The pH optimum was at 5.0. Free amino acids did not accumulate in the senescing leaf or pod when protein was degraded in each organ. It is suggested that these amino acids were quickly metabolized in situ or translocated to sink areas in the plant, especially to the developing seeds.     

Proteolytic activity of viper venoms

Proteolytic activities of venoms of vipers kept in a serpentarium for three years or captured in various environmental regions were estimated. Gurza venom contained considerable amounts of protein (830-930 micrograms/mg venom) and displayed a high proteolytic activity by tyrosine (80-140 micrograms/min mg protein). The proteolytic activity did not depend on season, as well as age or physiological state of snakes in the reproductive period. The proteolytic activity of venom in gurza offspring was similar to that in parent specimens. Proteolytic activities (by tyrosine) of venoms produced by Radde's vipers and common vipers were 77-90 and 18-36 micrograms/min mg protein, respectively. The proteolytic activity of venom in common vipers native to the north European part of Russia was 20-30% higher than that in common vipers inhabiting southern European Russia. An inhibition assay found various ratios of metalloendopeptidase and serine endopeptidase activities in venoms of gurza, Radde's viper, and common viper.     

Plasma fibronectin-binding glycosaminoglycans in the substratum adhesion sites of neural tumor cells

The metabolism of high-density lipoprotein (HDL) in cells of five human cancer cell lines maintained in monolayer culture was investigated. In cells of some of the lines there was evidence of high-affinity binding sites for HDL, whereas in others this could not be demonstrated. However, in one cell line, viz., HEC-B-296 (human endometrial carcinoma), degradation of the protein component of HDL was demonstrated. The proteolytic activity was specific for HDL in so far as human serum albumin was not degraded by these cells. However, this degradative process did not involve internalization of the HDL molecule and degradation was not mediated by lysosomal proteolytic enzymes. HDL, when present in the medium, did not affect the degradation of low-density lipoprotein and low-density lipoprotein did not affect the degradation of HDL. HDL did not affect significantly cholesterol biosynthesis or cholesteryl ester biosynthesis as estimated from the activity of the regulatory enzymes, 3-hydroxy-3-methylglutaryl coenzyme A reductase and acyl-CoA:cholesterol acyltransferase. The degradation of HDL by HEC-B-296 cells was inhibited, to various degrees, when trypsin inhibitor or a protease inhibitor such as leupeptin, was present in the culture medium. It is concluded that degradation of the protein component of HDL by human neoplastic cells of the HEC-B-296 line was the result of activity of a proteolytic enzyme that is present on the external surface of the cells.     

Campylobacter pyloridis degrades mucin and undermines gastric mucosal integrity

The role of Campylobacter pyloridis, a spiral bacteria associated with gastritis and peptic ulcers in weakening the mucus component of gastric mucosal barrier was investigated. The colonies of bacteria, cultured from antral mucosal biopsies of patients undergoing gastroscopy, were washed with saline, passed through sterilization filter and the filtrate was examined for protease and glycosylhydrolase activities. The obtained results revealed that the filtrate exhibited a strong proteolytic activity not only towards the typical protein substrates such as albumin but also towards gastric mucin. Optimum enzymatic activity for degradation of mucin was attained at pH 7.0 and the protease activity was found in a low m.w. (less than 50K) protein fraction. The filtrate showed little glycosylhydrolase activity and did not cause the hydrolysis of mucin carbohydrates. The data suggest that C pyloridis infection weakens the gastric mucosal defense by causing proteolytic degradation of mucin component of the protective mucus layer.     

Branched‐chain amino acids: A role in skeletal muscle proteolysis in catabolic states?

A 48-h starvation period resulted in a great increase in muscle proteolysis-as measured following the release of tyrosine into the medium-in incubated isolated rat extensor digitorum longus (EDL) muscles. We have quantified the contribution of the different proteolytic systems to the increased protein degradation and observed a considerable activation in the ATP-dependent proteolytic (60%) and in the calcium-dependent (125%) systems, while no increases were observed in lysosomal proteolysis. The addition of 10 mM leucine to the incubation medium did not result in any changes in either total proteolytic rate or the activity rates of any of the different systems studied. In addition, the presence of the amino acid did not influence the levels of mRNA for the different genes studied-ubiquitin, C8 proteasome subunit, E2 conjugating enzyme, m-calpain, and cathepsin B. In a similar way, as observed during starvation, tumor growth resulted in increased protein degradation in incubated isolated EDL muscles from animals bearing the Yoshida AH-130 ascites hepatoma. The increased rate of protein degradation affected all the proteolytic systems studied: ATP- and calcium-dependent and lysosomal. Finally, leucine addition (10 mM), although not able to revert the increased proteolytic rate, resulted in a decrease in the gene expression for ubiquitin, C8 proteasome subunit and cathepsin B.     

Neutral protease activity in lymphocytes of lewis rats with acute experimental allergic encephalomyelitis

Lymphocytes from popliteal and inguinal lymph nodes of Lewis rats with acute EAE as a result of injection of lyophilized guinea pig myelin in Freund's complete adjuvant exerted strong proteolytic activity at neutral pH toward myelin basic protein. After injection of myelin the level of proteolytic activity remained about the same as that in lymphocytes from Freund's adjuvant-injected controls until about day 10 after injection, just before the onset of paralytic symptoms; then the proteolytic activity increased to approximately double its former level. Myelin basic protein was hydrolyzed by whole lymphocytes, but more activity was unmasked by homogenization. Similar results were also obtained using lymphocytes from thymus of EAE and control animals. Lymphocytes with high levels of proteolytic activity were not absorbed by glass wool, did not stain with neutral red, nor did they phagocytose antibody-coated sheep red blood cells. Thymus and lymph node lymphocytes cleaved myelin basic protein to three major peptides and a fourth minor peptide, while spleen lymphocytes hydrolyzed basic protein at only one point resulting in two peptides whose molecular weights added up to that of myelin basic protein. The protease activity was inhibited by 5×10^–3 Mp-chloromercuribenzoate and by phenylmethyl sulfonyl fluoride, TPCK, and soybean trypsin inhibitor, therefore the enzymatic activity probably depends on a serine residue and a sulfhydryl group. The bulk of the enzymatic activity is mostly membrane bound with the highest specific activity and total activity contained in a lysosomal-mitochondrial fraction. In view of the infiltration of lymphocytes into the brain substance in acute EAE, it is suggested that these cells may contribute to the destruction of myelin which is usually attributed to the monocyte or macrophage.     

A protease complex in the Escherichia coli plasma membrane: HflKC (HflA) forms a complex with FtsH (HflB), regulating its proteolytic activity against SecY.

Escherichia coli FtsH (HflB), a membrane-bound ATPase is required for proteolytic degradation of uncomplexed forms of the protein translocase SecY subunit. We have now isolated SecY-stabilizing mutations that cause an amino acid substitution in the HflK-HflC membrane protein complex. Although HflKC protein was believed to have a proteolytic activity against lambda cII protein, deletion of hflK-hflC did not stabilize SecY. Instead, the mutant alleles were partially dominant and overexpression of ftsH suppressed the mutational effects, suggesting that the mutant proteins antagonized the degradation of SecY. These results raise the possibility that even the wild-type HflKC protein acts to antagonize FtsH. Consistent with this notion, the hflkC null mutation accelerated degradation of the SecY24 protein. Furthermore cross-linking, co-immunoprecipitation, histidine-tagging and gel filtration experiments all indicated that FtsH and HflKC form a complex in vivo and in vitro. Finally, purified HflKC protein inhibited the SecY-degrading activity of purified FtsH protein in vitro. These results indicate that the proteolytic activity of FtsH is modulated negatively by its association with HflKC.     

Antibiotic activity of epiphytic bacteria isolated from intertidal seaweeds

A survey of antibiotic-producing bacteria from the microbial flora attached to seaweeds and the study of their antibiotic capacities were carried out. From 5 species of green and brown marine algae, 224 bacterial strains were isolated and tested for antibiotic production. A total of 38 strains displayed antibiotic activity, withEnteromorpha intestinalis being the source of the highest number of producer strains. All epiphytic bacteria with antibiotic activity were assigned to thePseudomonas-Alteromonas group. Antagonism assays among the isolates demonstrated that each producer strain inhibits the growth of the other producers, as well as of some nonproducer strains also isolated from seaweeds. Likewise, an autoinhibitory effect was observed in all antibiotic-producing strains. Antibacterial spectra of all the strains include activity againstStaphylococcus, Alcaligenes, Pseudomonas, Vibrio, Pasteurella, andAchromobacter. A preliminary characterization of the antibiotic substances produced by these epiphytic bacteria demonstrated that they are low molecular weight compounds, thermolabile, and anionic and are not affected by proteolytic enzymes. The role that these inhibitory substances can play in the natural environment is discussed.     

Biosynthetic activity of cultures of different species of the genus Actinomadura

The ability to synthesize antibiotics and exoproteases was studied in 13 species belonging to the Actinomadura genus. The antibiotic and proteolytic activities were found only in A. fulvescens INA-3321 and A. citrea INA-1849. Glycerol was shown to be the best carbon source for the growth and biosynthetic activity of A. fulvescens. A. citrea had a wider spectrum of carbon sources used for the growth and a higher proteolytic and antibiotic activity. A. citrea exerted the maximal biosynthetic activity and the best growth in a medium with starch and xylose. The effect of different nitrogen sources on the growth and biosynthetic activity of A. citrea was also studied.     

Proteolytic activity of viper venoms

Proteolytic activities of venoms of vipers kept in a serpentarium for three years or captured in various environmental regions were estimated. Gurza venom contained considerable amounts of protein (830-930 μg/mg venom) and displayed a high proteolytic activity by tyrosine (80-140 μg/m in mg protein). The proteolytic activity did not depend on season or the age or physiological state of snakes in the reproductive period. The proteolytic activity of venom in gurza offspring was similar to that in parent specimens. Proteolytic activities (by tyrosine) of venoms produced by Radde’s vipers and common vipers were 77–90 and 18–36 μg/m in mg protein, respectively. The proteolytic activity of venom in common vipers native to the north European part of Russia was 20–30% higher than that in common vipers inhabiting southern European Russia. An inhibition assay found various ratios of metalloendopeptidase and serine endopeptidase activities in venoms of gurza, Radde’s viper, and common viper.     

Plasminogen activator in prostatic tumors of Nb rats

Using a fluorometric assay, nonspecific proteolytic activity and plasminogen activator were measured in transplantable tumors of the dorsal prostate of Nb rats. Nonspecific proteolytic activity in prostatic tumors did not differ significantly from that measured in normal dorsal prostate, whereas plasminogen activator activity, undetectable in the latter tissue, was readily measurable in the tumors. Furthermore, plasminogen activator in prostatic tumors characterized by hormone-insensitive growth was 8-fold higher than in tumors characterized by androgen-stimulated growth. In both types of tumors, the plasminogen activator activity per mg protein was highest in the lysosomal fractions. The result indicate that plasminogen activator may be a useful marker for discriminating between androgen-stimulated and autonomous prostatic tumors.     

Purification and characterization of an antibiotic substance produced from Rhizopus oligosporus IFO 8631.

We obtained a purified antibiotic protein from the submerged cultivation broth of Rhizopus oligosporus IFO 8631 by using CM-Cellulofine chromatography and HPLC. The antibiotic did not show a broad spectrum of activity, but it was very active against some of the Bacillus species, especially against Bacillus subtillis (B. natto) at a very low concentration (less than 1 ppm). It also showed activity against other gram-positive bacteria, including Staphylococcus aureus and Streptococcus cremoris. The purified antibiotic was a simple protein of about 5,500 in molecular weight, the amino acid component being characteristically high in cystine content. This high cystine content contributed to the stability of the antibiotic over a wide pH range and against strong heating (50% of the activity remained after boiling for 1 hr).     

Reconstitution of human azurocidin catalytic triad and proteolytic activity by site-directed mutagenesis

Azurocidin belongs to the serprocidin family, but it is devoid of proteolytic activity due to a substitution of His and Ser residues in the catalytic triad. The aim of this study was to reconstitute the active site of azurocidin by site-directed mutagenesis, analyze its processing and restored proteolytic activity. Azurocidin expressed in Sf9 insect cells possessing the reconstituted His41-Asp89-Ser175 triad exhibited significant proteolytic activity toward casein with a pH optimum of approximately 8-9, but a reconstitution of only one active site amino acid did not result in proteolytically active protein. Enzymatically active recombinant azurocidin caused cleavage of the C-terminal fusion tag with the primary cleavage site after lysine at Lys-Leu and after alanine at Ala-Ala, and the secondary cleavage site after arginine at Arg-Gln, as well as with low efficiency caused cleavage of insulin chain B after leucine at Leu-Tyr and Leu-Cys, and after alanine at Ala-Leu. We demonstrate that cleavage of the azurocidin C-terminal tripeptide is not necessary for its enzymatic activity. The first isoleucine present in mature azurocidin can be replaced by similar amino acids, such as leucine or valine, but its substitution by histidine or arginine decreases proteolytic activity.     

Methylene blue-mediated hexose monophosphate shunt stimulation in human red blood cells in vitro: independence from intracellular oxidative injury

The red blood cell hexose monophosphate shunt (HMS) and proteolytic responses to several concentrations of Methylene Blue or sodium nitrite were measured. The results suggested two distinct mechanisms for activation of the HMS: (1) nitrite treatment increased HMS activity in response to oxidative challenge to red cell protein; (2) Methylene Blue treatment activated HMS without injurious oxidative challenge. Nitrite-treated cells actively degraded protein, whereas Methylene Blue-treated red cells did not activate proteolytic systems that degrade oxidized red cell protein. These observations are relevant to proposed in vitro systems for evaluation of drug hemolytic toxicity potential on the basis of HMS stimulation capacity.     

The ubiquitin-proteasome proteolytic pathway in heart vs skeletal muscle: effects of acute diabetes

The ubiquitin-proteasome system is thought to play a major role in normal muscle protein turnover and to contribute to diabetes-induced protein wasting in skeletal muscle. However, its importance in cardiac muscle is not clear. We measured heart muscle mRNA for ubiquitin and for the C2 and C8 proteasomal subunits, the amount of free ubiquitin and the proteasome chymotrypsin-like proteolytic activity in control and diabetic rats. Results were compared to those in skeletal muscle (rectus). Heart ubiquitin, C2 and C8 subunit mRNA and proteolytic activity were significantly greater than in skeletal muscle (P 相似文献   

Effect of Carob Pod Extract on Cellulolysis, Proteolysis, Deamination, and Protein Biosynthesis in an Artificial Rumen

Carob pod extract and its tannin and sugar fractions were compared with gallotannic acid and sucrose for their effect on the cellulolytic, proteolytic, protein biosynthetic, and deaminative activities of rumen microorganisms. The inhibitory effects of carob pod extract upon the cellulolysis and deamination were correlated mainly with its sugar, rather than its tannin components. On the other hand, proteolytic activity and protein biosynthesis were more significantly affected by the tannin fraction. In contrast to the tannin fraction of carob pod extract, gallotannic acid inhibited cellulolytic activity. The harmful effect of a low concentration of tannins on protein biosynthesis could be prevented by the addition of carbohydrates to the reaction mixture. At high tannin concentration (40 μg/ml), however, the addition of carbohydrates did not prevent the inhibition.     

Overproduction of the Escherichia coli recA protein without stimulation of its proteolytic activity.

Plasmid pBEU14, which carries the Escherichia coli recA+ gene and which can be amplified by manipulation of growth temperature, was constructed. When pBEU14 deoxyribonucleic acid was amplified, a high rate of synthesis and accumulation of recA protein resulted. Amplification of the recA gene and protein did not cause induction of prophage lambda, indicating that the proteolytic activity of the recA protein was not stimulated.     

Cell adhesion and spreading factor. Chemical modification studies

The purified fetal calf serum factor that promotes cell adhesion and spreading of baby hamster kidney cells on tissue culture substrata has been subjected to a variety of chemical modifications and then tested for activity. These studies have shown that modification of the carbohydrate portions of the factor by glycosidic enzymes or by periodate oxidation did not alter its ability to promote cell spreading. On the other hand, modification of some protein portions of the factor by proteolytic enzymes or by specific modification of —COOH groups, tyrosine residues, or tryptophan residues resulted in a marked inhibition of factor activity. Modification of protein —SH groups, —NH₂ groups, or methionine residues did not affect factor activity. Control experiments indicate that the various modifications were directed at the activity of the factor and not its adsorption onto the substrata.