Arginine deiminase system and acid adaptation of oral streptococci.

Streptococcus rattus FA-1 and Streptococcus sanguis NCTC 10904 underwent phenotypic acid adaptation in batch cultures toward the end of sugar-fueled growth after the culture pH had dropped to triggering values. The bacteria could be derepressed or induced for arginine deiminase independently of acid adaptation, and arginolysis afforded protection against acid killing over and above that of acid adaptation.     

Role of the arginine deiminase system in protecting oral bacteria and an enzymatic basis for acid tolerance

The arginine deiminase system was found to function in protecting bacterial cells against the damaging effects of acid environments. For example, as little as 2.9 mM arginine added to acidified suspensions of Streptococcus sanguis at a pH of 4.0 resulted in ammonia production and protection against killing. The arginine deiminase system was found to have unusual acid tolerance in a variety of lactic acid bacteria. For example, for Streptococcus rattus FA-1, the pH at which arginolysis was reduced to 10% of the maximum was between 2.1 and 2.6, or more than 1 full pH unit below the minimum for glycolysis (pH 3.7), and more than 2 units below the minimum for growth in complex medium (pH 4.7). The acid tolerance of the arginine deiminase system appeared to be primarily molecular and to depend on the tolerance of individual enzymes rather than on the membrane physiology of the bacteria; pH profiles for the activities of arginine deiminase, ornithine carbamoyltransferase, and carbamate kinase in permeabilized cells showed that the enzymes were active at pHs of 3.1 or somewhat lower. Overall, it appeared that ammonia could be produced from arginine at low pH values, even by cells with damaged membranes, and that the ammonia could then protect the cells against acid damage until the environmental pH value rose sufficiently to allow for the reestablishment of a difference in pH (delta pH) across the cell membrane.     

Role of the arginine deiminase system in protecting oral bacteria and an enzymatic basis for acid tolerance.

The arginine deiminase system was found to function in protecting bacterial cells against the damaging effects of acid environments. For example, as little as 2.9 mM arginine added to acidified suspensions of Streptococcus sanguis at a pH of 4.0 resulted in ammonia production and protection against killing. The arginine deiminase system was found to have unusual acid tolerance in a variety of lactic acid bacteria. For example, for Streptococcus rattus FA-1, the pH at which arginolysis was reduced to 10% of the maximum was between 2.1 and 2.6, or more than 1 full pH unit below the minimum for glycolysis (pH 3.7), and more than 2 units below the minimum for growth in complex medium (pH 4.7). The acid tolerance of the arginine deiminase system appeared to be primarily molecular and to depend on the tolerance of individual enzymes rather than on the membrane physiology of the bacteria; pH profiles for the activities of arginine deiminase, ornithine carbamoyltransferase, and carbamate kinase in permeabilized cells showed that the enzymes were active at pHs of 3.1 or somewhat lower. Overall, it appeared that ammonia could be produced from arginine at low pH values, even by cells with damaged membranes, and that the ammonia could then protect the cells against acid damage until the environmental pH value rose sufficiently to allow for the reestablishment of a difference in pH (delta pH) across the cell membrane.     

Control of expression of the arginine deiminase operon of Streptococcus gordonii by CcpA and Flp

In Streptococcus gordonii DL1, inactivation of the ccpA gene and a gene encoding an Fnr-like protein (Flp) demonstrated that CcpA was essential for carbohydrate catabolite repression and that Flp was required for optimal expression and anaerobic induction of the arginine deiminase system.     

Enzymes of arginine utilization and their formation in Aeromonas formicans NCIB 9232

In Aeromonas formicans two inducible catabolic pathways of L-arginine have been characterized. The arginine decarboxylase is induced by arginine which also induces the three enzymes of the arginine deiminase pathway but only in stress conditions such as a shift from aerobic growth conditions to very low oxygen tension. Addition of glucose to medium containing arginine leads to repression of the enzymes involved in the arginine deiminase pathway while exogenous cAMP prevents that repression of enzyme synthesis by glucose. This suggests that the induction of arginine deiminase pathway is regulated by carbon catabolite repression and the energetic state of the cell.     

Regulation of enzyme synthesis in the arginine deiminase pathway of Pseudomonas aeruginosa.

The three enzymes of the arginine deiminase pathway in Pseudomonas aeruginosa strain PAO were induced strongly (50- to 100-fold) by a shift from aerobic growth conditions to very low oxygen tension. Arginine in the culture medium was not essential for induction, but increased the maximum enzyme levels twofold. The induction of the three enzymes arginine deiminase (EC 3.5.3.6), catabolic ornithine carbamoyltransferase (EC 2.1.3.3), and carbamate kinase (EC 2.7.2.3) appeared to be coordinate. Catabolic ornithine carbamoyltransferase was studied in most detail. Nitrate and nitrite, which can replace oxygen as terminal electron acceptors in P. aeruginosa, partially prevented enzyme induction by low oxygen tension in the wild-type strain, but not in nar (nitrate reductase-negative) mutants. Glucose was found to exert catabolite repression of the deiminase pathway. Generally, conditions of stress, such as depletion of the carbon and energy source or the phosphate source, resulted in induced synthesis of catabolic ornithine carbamoyltransferase. The induction of the deiminase pathway is thought to mobilize intra- and extracellular reserves of arginine, which is used as a source of adenosine 5'-triphosphate in the absence of respiration.     

Enzymes of agmatine degradation and the control of their synthesis in Streptococcus faecalis.

Streptococcus faecalis ATCC 11700 uses agmatine as its sole energy source for growth. Agmatine deiminase and putrescine carbamoyltransferase are coinduced by growth on agmatine. Glucose and arginine were found to exert catabolite repression on the agmatine deiminase pathway. Four mutants unable to utilize agmatine as an energy source, isolated from the wild-type strain, exhibited three distinct phenotypes. Two of these strains showed essentially no agmatine deiminase, one mutant showed negligible activity of putrescine carbamoyltransferase, and one mutant was defective in both activities. Two carbamate kinases are present in S. faecalis, one belonging to the arginine deiminase pathway, the other being induced by growth on agmatine. These two enzymes have the same molecular weight, 82,000, and seem quite different in size from the kinases isolated from other streptococci.     

Control of enzyme synthesis in the arginine deiminase pathway of Streptococcus faecalis

The formation of the arginine deiminase pathway enzymes in Streptococcus faecalis ATCC 11700 was investigated. The addition of arginine to growing cells resulted in the coinduction of arginine diminase (EC 3.5.3.6), ornithine carbamoyltransferase (EC 2.1.3.3), and carbamate kinase (EC 2.7.2.3). Growth on glucose-arginine or on glucose-fumarate-arginine produced a decrease in the specific activity of the arginine fermentation system. Aeration had a weak repressing effect on the arginine deiminase pathway enzymes in cells growing on arginine as the only added substrate. By contrast, depending on the growth phase, a marked repression of the pathway by oxygen was observed in cells growing on glucose-arginine. We hypothesize that, in S. faecalis, the ATP pool is an important signal in the regulation of the arginine deiminase pathway. Mutants unable to utilize arginine as an energy source, isolated from the wild type, exhibited four distinct phenotypes. In group I the three enzymes of the arginine deiminase pathway were present and probably affected in the arginine uptake system. Group II mutants had no detectable arginine deiminase, whereas group III mutants had low levels of ornithine carbamoyltransferase. Group IV mutants were defective for all three enzymes of the pathway.     

Arginine metabolism in lactic streptococci.

Streptococcus lactis metabolizes arginine via the arginine deiminase pathway producing ornithine, ammonia, carbon dioxide, and ATP. In the four strains of S. lactis examined, the specific activities of arginine deiminase and ornithine transcarbamylase were 5- to 10-fold higher in galactose-grown cells compared with glucose- or lactose-grown cells. The addition of arginine increased the specific activities of these two enzymes with all growth sugars. The specific activity of the third enzyme involved in arginine metabolism (carbamate kinase) was not altered by the composition of the growth medium. In continuous cultures arginine deiminase was not induced, and arginine was not metabolized, until glucose limitation occurred. In batch cultures the metabolism of glucose and arginine was sequential, whereas galactose and arginine were metabolized concurrently, and the energy derived from arginine metabolism was efficiently coupled to growth. No arginine deiminase activity was detected in the nine Streptococcus cremoris strains examined, thus accounting for their inability to metabolize arginine. All nine strains of S. cremoris had specific activities of carbamate kinase similar to those found in S. lactis, but only five S. cremoris strains had ornithine transcarbamylase activity.     

Analysis of an agmatine deiminase gene cluster in Streptococcus mutans UA159

An operon encoding enzymes of the agmatine deiminase system (AgDS) has been identified in the cariogenic bacterium Streptococcus mutans UA159. The AgDS is regulated by agmatine induction and carbohydrate catabolite repression. Ammonia is produced from agmatine at low pH, suggesting that the AgDS could augment acid tolerance.     

Regulation of the arginine dihydrolase pathway in Clostridium sporogenes.

Arginine deiminase activity was induced during the vegetative growth of Clostridium sporogenes. The enzyme was sensitive to catabolite repression. The other enzymes of the arginine dihydrolase pathway, namely, ornithine carbamoyl-transferase and carbamate kinase, did not show such variation.     

Regulation of arginine-ornithine exchange and the arginine deiminase pathway in Streptococcus lactis.

Streptococcus lactis metabolizes arginine by the arginine deiminase (ADI) pathway. Resting cells of S. lactis grown in the presence of galactose and arginine maintain a high intracellular ornithine pool in the absence of arginine and other exogenous energy sources. Addition of arginine results in a rapid release of ornithine concomitant with the uptake of arginine. Subsequent arginine metabolism results intracellularly in high citrulline and low ornithine pools. Arginine-ornithine exchange was shown to occur in a 1-to-1 ratio and to be independent of a proton motive force. The driving force for arginine uptake in intact cells is supplied by the ornithine and arginine concentration gradients formed during arginine metabolism. These results confirm studies of arginine and ornithine transport in membrane vesicles of S. lactis (A. J. M. Driessen, B. Poolman, R. Kiewiet, and W. N. Konings, Proc. Natl. Acad. Sci. USA, 84:6093-6097). The activity of the ADI pathway appears to be affected by the internal concentration of (adenine) nucleotides. Conditions which lower ATP consumption (dicyclohexylcarbodiimide, high pH) decrease the ADI pathway activity, whereas uncouplers and ionophores which stimulate ATP consumption increase the activity. The arginine-ornithine exchange activity matches the ADI pathway most probably by adjusting the intracellular levels of ornithine and arginine. Regulation of the ADI pathway and the arginine-ornithine exchanger at the level of enzyme synthesis is exerted by glucose (repressor, antagonized by cyclic AMP) and arginine (inducer). An arginine/ornithine antiport was also found in Streptococcus faecalis DS5, Streptococcus sanguis 12, and Streptococcus milleri RH1 type 2.     

Co-induction of beta-galactosidase and the lactose-P-enolpyruvate phosphotransferase system in Streptococcus salivarius and Streptococcus mutans.

The addition of lactose, galactose, or isopropyl-beta-D-thiogalactoside (IPTG) to glucose-grown cells of Streptococcus salivarius 25975 resulted in the co-induction of both the lactose-P-enolpyruvate phosphotransferase system (lactose-PTS) and beta-galactosidase, with the latter the predominant metabolic system. With various strains of Streptococcus mutans and Streptococcus sanguis 10556, on the other hand, the lactose-PTS was the major metabolic pathway with beta-galactosidase induced either to low or negligible levels. In all cases, induction of the lactose-PTS resulted in the concomitant induction of 6-P-beta-galactosidase. The induction by lactose of both the lactose-PTS and beta-galactosidase in all strains was repressed by glucose and other catabolites, notably, fructose. Induction of beta-galactosidase in S. salivarius 25975 by IPTG was, however, relatively resistant to glucose repression. Induction experiments with IPTG and lactose suggested that a cellular metabolite of lactose metabolism was a repressor of enzyme activity. Exogenous cAMP was shown to reverse the transient repression by glucose of beta-galactosidase induction in cells of S. salivarius 25975 receiving lactose, provided the cells were grown with small amounts of toluene to overcome the permeability barrier to this nucleotide, cAMP, was however, unable to overcome the permanent repression of beta-galactosidase activity to a significant extent under these conditions.     

Barotolerant variant of Streptococcus faecalis with reduced sensitivity to glucose catabolite repression

Physiological characterization of the APR-11 variant of Streptococcus faecalis ATCC 9790 revealed that the variant has reduced sensitivity to glucose catabolite repression. This reduced sensitivity was indicated by the synthesis of enzymes for catabolism of lactose or arginine in cultures growing at 0.1, 40, or 70 MPa in media with levels of glucose highly repressive for the parent strain. Reduced catabolite repression appeared to be due to reduced activity of the glucose-specific, phosphotransferase system in APR-11 cells. Conversion of pyruvate to lactate or to acetate and ethanol did not appear to be altered in the variant. The APR-11 variant produced a greater final yield of biomass than the parent at all pressures tested, and its barotolerance was especially marked in media with low levels of glucose and high levels of lactose in which derepression of the lactose catabolic system was necessary for full growth. Overall, the greater barotolerance of the APR-11 strain appeared to be due to its enhanced capacity for catabolism related to its reduced sensitivity to catabolite repression by glucose.     

Effect of catabolite repression on the mer operon

The plasmid-determined mer operon, which provides resistance to inorganic mercury compounds, was subject to a 2.5-fold decrease in expression when glucose was administered at the same time as the inducer HgCl2. This glucose-mediated transient repression of the operon was overcome by the addition of cyclic AMP. Permanent catabolite repression of the operon was observed in the 1.6- to 1.9-fold decrease in expression in mutants lacking either adenyl cyclase (cya) or the catabolite activator protein (crp). The effect of the cya mutation on mer expression could be overcome by the addition of cyclic AMP at the time of induction, In addition to these effects on the whole cells of a wild-type strains, we examined the effect of catabolite repression on the expression of the mercuric ion [Hg(II)] reductase enzyme, assayable in cell extracts, and on the Hg(II) uptake system, assayable in a mutant strain which lacked reductase activity. There was a two- to threefold effect of repression on the Hg(II) reductase enzyme assayable in vitro after induction under catabolite repressing conditions (either with glucose or in the crp and cya mutants). We did not find a similar repressing effect on the induction of the Hg(II) uptake system, which is also determined by the mer operon.     

Effect of utilization of substrates on the composition of dental plaque

Abstract The microbiota in the mouth is subjected to substrate limitations. In this study we have evaluated the role of competition for carbon and energy substrates on the proportions of 2 microbial species in a simplified plaque ecosystem in gnotobiotic rats. Germ-free rats were inoculated with a combination of Streptococcus sanguis and Streptococcus mutans , or with a combination of Streptococcus milleri and S. mutans . The available carbon and energy sources were varied through the host's diet. 3 Experimental diets were tested: (i) a basal diet low in soluble carbohydrates; (ii) an arginine-supplemented diet; (iii) a sucrose-supplemented diet. Arginine is used for growth by S. sanguis and S. milleri , but not by S. mutans . Sucrose is rapidly fermented by all 3 species.
The total number of viable organisms on the dentition increased when arginine or sucrose were supplied in the diet. With the arginine-supplemented diet, S. sanguis and S. milleri increased while S. mutans decreased. With the sucrose-supplemented diet, S. mutans increased while S. sanguis and S. milleri decreased. These results were explained by assuming that the organism with the highest growth rate on the supplementary substrate competes most favourably. Changes in the environmental pH, due to breakdown of sucrose and arginine, might also have affected the competition between the streptococci. In addition, production of extracellular glucans from sucrose could be a competitive advantage for S. mutans .     

Production of mutacin-like substances by Streptococcus mutans

Production of inhibitory substances by strains of the Streptococcus mutans group is well documented, but the nature of the substances implied is often unknown. Of nine laboratory strains known to produce inhibitory substances, the optimal conditions for producing inhibition zones on solid media were found to vary between strains but good production was generally obtained on all-purpose media with Tween 80 at 37 degrees C after 2-4 days of aerobic incubation. Streptococcus sanguis Ny101 was found to be more sensitive than Streptococcus rattus LG-1 to all inhibitory substances produced by the S. mutans strains tested. While all strains showed some inhibition, only six showed inhibition after neutralization; arginine incorporated in agar at 0.75% completely eliminated all inhibition zones. However 1% arginine in the overlays did not affect the production of inhibition zones by strains of S. mutans C67-1, Ny257, Ny266, and T8. These strains were shown to elaborate (in a reproducible fashion) inhibitory substances which were not organic acids. Inhibitory activity was never obtained in liquid preparations, except for strains Ny257 and T8 where it was found to be very unstable.