Arthrobacter Pyridinolis Research Articles

A deficiency of citrate synthase results in constitutive expression of the glyoxylate pathway in Arthrobacter pyridinolis.

Previous studies of Arthrobacter pyridinolis indicated that during the first half of the growth cycle on D-fructose, the organism utilizes a respiration-coupled transport system and exhibits glyoxylate pathway activity; during the second half of the growth cycle, a phosphoenolypyruvate:D-fructose phosphotransferase system is used for transport and no glyoxylate pathway activity is found [Pelliccione et al. (1979) Eur. J. Biochem. 95, 69--75]. A citrate-synthase-deficient mutant had the following properties: (a) high constitutive levels of glyoxylate pathway enzymes on various substrates, while such levels were only found in the wild type when it was grown on acetate; (b) acetyl-CoA levels much higher than in the wild type grown on several different substrates, whereas other metabolite levels were similar in the two strains; and (c) under conditions for induction of the phosphotransferase system, the wild type exhibited at least twice as much phosphotransferase activity as the mutant strain. A mutant lacking acetyl-CoA synthetase exhibited no induction of the glyoxylate pathway in the presence of acetate, although acetate uptake was normal. The results indicate a role for acetyl-CoA as inducer of the glyoxylate pathway. They further suggest a possible role, perhaps indirect, in repression of the phosphotransferase system.

Application of Polyacrylamide Gel Electrophoresis to the Characterization and Identification of Arthrobacter Species

When polyacrylamide gel electrophoretic profiles of soluble proteins of seven Arthrobacter strains were compared with those of seven coryneform and coryneform-like species, the arthrobacters were delineated from the latter species. Comparisons were made from a composite gel by calculating similarity coefficients. When Arthrobacter globiformis was used as a reference, similarity coefficients for the other Arthrobacter species ranged from 20.7 to 34.5, but the similarity coefficients for the other genera tested were only 7.9 to 18.5. In addition to a separation of arthrobacters from other coryneforms by this method, Arthrobacter crystallopoites and Arthrobacter pyridinolis had a similarity coefficient of approximately 95, which set these two apart from the other Arthrobacter species studied and furthermore suggested that they represent one species. Gel electrophoresis of soluble proteins may provide a good alternative to the use of rod to coccoid transition for identifying arthrobacters since it is faster and simpler to perform than chemical analyses of cell wall components.

D-Gluconate transport in Arthrobacter pyridinolis. Metabolic trapping of a protonated solute

d-Gluconate uptake was studied in whole cells of Arthrobacter pyridinolis; the uptake activity was inducible, mutable and showed saturation kinetics ( K m = 5 μM ). Uptake of d-gluconate was not mediated by a phospho enolpyruvate: hexose phosphotransferase system, nor was it directly energized by ATP. A transmembrane pH gradient, ΔpH, of −63 mV was generated by A. pyridinolis cells at pH 6.5, while at pH 7.5, ΔpH = 0. Addition of 8 μM d-gluconate significantly reduced the ΔpH. The transmembrane electrical potential, Δψ, which was −87 mV over a range of pH from 5.5 to 7.5, was unaffected by the presence of substrate. d-Gluconate accumulated at the same rate and as the protonated solute, at both pH 6.5 and 7.5. Experiments in which a diffusion potential was generated in cyanide-treated cells, indicated that the Δψ did not energize transport. Rather, the rate of d-gluconate uptake correlated with and appeared to be determined by the rate of d-gluconate metabolism: (a) treatment of cells with valinomycin or nigericin, under conditions in which there was a loss of intracellular potassium, inhibited both d-gluconate uptake and the metabolism of pre-accumulated d-gluconate; (b) the effects of cyanide and azide on d-gluconate uptake were much more severe at pH 6.5 than pH 7.5, a pattern which paralleled the effects of these inhibitors on d-gluconate metabolism; (c) extraction and chromatography of intracellular label from d-gluconate uptake revealed that accumulation of unaltered d-gluconate was negligible; (d) a series of mutant strains with lower d-gluconate kinase activities also exhibited low rates of d-gluconate uptake; (e) spontaneous revertants of these mutant strains consistently regained both d-gluconate kinase activity and wild type levels of uptake.

Induction of the Phosphoenolpyruvate: Hexose Phosphotransferase System Associated with Relative Anaerobiosis in an Obligate Aerobe

Arthrobacter pyridinolis possesses alternative transport systems for D-fructose: a respiration-coupled transport system whereby D-fructose transport occurs with concomitant oxidation of L-malate, and a phosphoenolpyruvate: D-fructose phosphotransferase system. Studies of D-fructose uptake by whole cells in the presence and absence of cyanide demonstrate that respiration-coupled transport is used almost exclusively during the first half of logarithmic growth, after which it accounts for only 15-20% of D-fructose uptake. Phosphotransferase levels are low during log phase, peak during late log, and then slowly decline. In a mutant of A. pyridinolis which requires delta-aminolevulinic acid for growth, the growth rate, cell cytochrome content, and activity of the respiration-coupled transport system increased with increasing concentrations of delta-aminolevulinic acid up to 50 microgram/ml. By contrast, phosphotransferase activity was highest in cells grown on limiting delta-aminolevulinic acid. L-Malate, which stimulates respiration-coupled transport, repressed the phosphotransferase system. The respiratory activity and the ability to release CO2 from internalized d-fructose was consistently low in D-fructose-grown cells. A cyanide-resistant cytochrome, tentatively identified as cytochrome d, appeared in the late exponential phase of growth. Isocitrate lyase activity, required for aerobic growth of this organism, declined markedly during the late exponential phase. Thus the phosphotransferase system is maximally induced, in this obligate aerobe, under conditions of relative anaerobiosis during which metabolism is primarily fermentative.

Amino acid transport in whole cells and membrane vesicles of Arthrobacter pyridinolis

Arginine, and several other amino acids, can only support growth of Arthrobacter pyridinolis if malate is also present in the medium. Arginine is transported by a high affinity lysine-arginine-ornithine-type transport system which is stimulated by malate in both whole cells and vesicles, is respiration-coupled, and appears to depend upon a respiration-generated membrane potential but not on a ΔpH. Arginine is also transported by a low-affinity system which transports canavanine. Studies of an arginine auxotroph suggest that the lysine-arginine-ornithine system may be the system of major physiological significance for arginine transport. Phenylalanine is one of a few amino acids which can act as sole source of carbon for A. pyridinolis. Transport of phenylalanine occurs by two kinetically distinct systems. Both of these transport systems are respiration-coupled, are not appreciably stimulated by malate either in cells or vesicles, but are markedly stimulated by ascorbate-phenazine methosulfate. Studies with inhibitors indicate that the transport systems for phenylalanine utilize both a ΔpH and a membrane potential.

Growth and pigment production by Arthrobacter pyridinolis n. sp.

A new bacterium capable of growing on 2-hydroxypyridine as sole source of carbon and nitrogen was isolated from soil. During its growth on solid medium, approximately 50% of this substrate was converted to a brilliant blue crystalline pigment which was deposited extracellularly in the colony mass. The pigment was identical to that produced by Arthrobacter crystallopoietes during its growth on 2-hydroxypyridine. The new isolate exhibited the typical cycle of morphogenesis characteristic of the genus Arthrobacter. The organism is different from all other reported species of Arthrobacter. It is proposed that the organism be named Arthorbacter pyridinolis n. sp.

Metabolism of L-Rhamnose in Arthrobacter pyridinolis

In Arthrobacter pyridinolis, a respiration-coupled transport system for L-rhamnose caused accumulation of free L-rhamnose, while a phosphoenolpyruvate: L-rhamnose phosphotransferase system caused accumulation of L-rhamnose I-phosphate (Levinson & Krulwich, 1974). The pathways for subsequent metabolism of L-rhamnose and L-rhamose I-phosphate have now been investigated. Arthrobacter pyridinolis contains an inducible L-rhamnose isomerase and L-rhamnulokinase, as well as a constitutive L-rhamnulose I-phosphate aldolase. Results with mutants which are unable to metabolize L-rhamnose suggest the presence of an L-rhamnose I-phosphate phosphatase, which forms free L-rhamnose by hydrolysis of L-rhamnose I-phosphate produced by the phosphotransferase system. Mutants which lack this enzyme exhibited severe inhibition of growth in the presence of L-rhamnose plus any of a variety of carbon sources. There is some evidence that this inhibition was due to accumulation of L-rhamnose I-phosphate at toxic concentrations within the bacteria. The metabolism of L-rhamnose transported by the phosphotransferase system therefore appears to occur by hydrolysis of L-rhamnose I-phosphate to free L-rhamnose by a phosphatase. Metabolism of the L-rhamnose thus produced, and of that accumulated by the respiration-coupled transport system, the proceeds by the sequence of reactions: L-rhamnose leads to L-rhamnulose leads to L=rhamnulose I-phosphate leads to dihydroxyacetone phosphate plus L-lactaldehyde.

Natural paucity of anaplerotic enzymes: basis for dependence of Arthrobacter pyridinolis on L-malate for growth.

Previous work has shown that in Arthrobacter pyridinolis the transport systems for glucose and several amino acids are respiration coupled, with malate oxidation occurring concomitantly with transport. The requisite malate has to be supplied exogenously, so that growth on glucose or certain amino acids only occurs if malate is also present in the medium. These and other data suggested that A. pyridinolis might be deficient in anaplerotic enzymes, which maintain intracellular levels of dicarboxylic acids. A comparative study was undertaken of anaplerotic enzymes in A. pyridinolis and in a closely related species, A. crystallopoietes, which has respiration-coupled transport of glucose but can grow on glucose without added malate. The paucity of anaplerotic enzymes in A. pyridinolis and its probable relationship to the malate requirement for growth on glucose were documented as follows: (i) A. crystallopoietes, but not A. pyridinolis, possesses phosphoenolpyruvate carboxylase activity, and neither species contains pyruvate carboxylase; (ii) both A. pyridinolis and A. crystallopoietes possess glyoxylate pathways that are induced by acetate but not by hexoses; (iii) isocitrate lyase-deficient mutants of A. pyridinolis fail to grow on rhamnose and fructose as well as acetate; and (iv) mutants of A. crystallopoietes that require malate for growth on glucose are deficient in phosphoenolpyruvate carboxylase.

Pathways of d-fructose transport in Arthrobacter pyridinolis

Previous work indicated that Arthrobacter pyridinolis can transport d-fructose by either a phosphoenolpyruvate: d-fructose phosphotransferase system or by a respiration-coupled system. The respiration-coupled transport system for d-fructose, which is stimulated by the addition of l-malate, has been characterized in membrane vesicles from d-fructose-grown cells. Such vesicles carry out malate-dependent uptake of d-fructose but not of d-glucose or l-rhamnose, indicating that there is a sugar-specific component to the respiration-coupled transport system. A mutant which is deficient in the d-fructose-specific component was isolated. Vesicles from fructose-glutamate-grown cells of a phosphotransferase-negative strain (AP100) exhibited malate-dependent d-fructose uptake, while phosphoenolpyruvate-dependent uptake was reduced to a small fraction of that seen with vesicles from wild-type cells. Inhibitors of electron transport, carbonyl cyanide m-chlorophenyl hydrazone, 2,4-dinitrophenol and N-ethylmaleimide caused marked inhibition of malate-dependent d-fructose uptake while exerting little or no effect on phosphoenolpyru-vate-dependent transport of the sugar in vesicles from wild-type cells. Activity of a flavin adenine dinucleotide-linked l-malic dehydrogenase was detected in membrane vesicles as well as in whole cells.

Abolition of crypticity of Arthrobacter pyridinolis toward glucose and alpha-glucosides by tricarboxylic acid cycle intermediates.

Arthrobacter pyridinolis cannot grow on glucose as sole carbon source, although the cells possess catabolic enzymes of the Embden-Meyerhof and pentose phosphate pathways as well as a complete tricarboxylic acid cycle. Crypticity toward glucose is abolished by a period of growth in a medium containing malate, succinate, citrate, or fumarate in addition to glucose. Other carbon sources, which support as rapid growth as does malate (e.g. asparagine), do not enable the cells to use glucose. Malate, succinate, citrate, and fumarate abolish crypticity toward glucose only in the second phase of diauxic growth after the tricarboxylic acid cycle intermediate has been depleted. This sequence of events, first observed in growth curves, has been verified by experiments in which the incorporation of radioactive substrates into trichloroacetic acid-insoluble cellular material was followed. The tricarboxylic acid cycle intermediates which confer the ability to utilize glucose also enhance the utilization of the alphaglucosides sucrose and maltose. The mechanism whereby growth on certain tricarboxylic acid cycle intermediates confers the subsequent ability to grow on glucose is related to a transport system for glucose and alpha-glucosides. This transport system has been assayed by measuring the uptake of [1-(14)C]-2-deoxyglucose. Cells grown for varying periods of time in asparagine, asparagine plus glucose, or malate do not transport 2-deoxyglucose. Cells from malate-glucose cultures that are in the exponential phase of growth on glucose can transport 2-deoxyglucose. Transport of 2-deoxyglucose shows Michaelis-Menten kinetics with a K(m) of 2.9 x 10(-4) M. It is competitively inhibited by glucose, alpha-methylglucopyranoside, and maltose. The transport of 2-deoxyglucose is inhibited by cyanide, dinitrophenol, azide, and N-ethylmaleimide, but not by malonate or fluoride. No phosphoenolpyruvate: d-glucose phosphotransferase activity has been detected, and the 2-deoxyglucose transported into the cell is not phosphorylated.

Phosphoenolpyruvate:Fructose phosphotransferase activity in whole cells and membrane vesicles of Arthrobacter pyridinolis

Mutants of Arthrobacter pyridiolis which were deficient in phosphoenol-pyruvate:fructose phosphotransferase activity were studied using in vitro complementation assays. In this way the strains were divided into those deficient in the inducible membrane-bound component and into thre groups which were deficient in different soluble components. One of the soluble components was inducible. Phosphoenolpyruvate:fructose phosphotransferase activity was also demonstrated in membrane vesicles prepared from fructose-grown A. pyridinolis. The activity was correlated with transport of fructose into the vesicles. Some kinetics parameters and temperature optima for the transport process in vesicles were studied.

Alternate pathways of D-fructose transport and metabolism in [formula omitted

Phosphoenolpyruvate: fructose phosphotransferase negative mutants of Arthrobacter pyridinolis used fructose in the presence of malate. In isolated membrane vesicles from fructose-grown wild type cells, fructose uptake was stimulated by malate, but not by a variety of other compounds, to almost the same extent as by phosphoenolpyruvate. The stimulation by malate but not that by phosphoenolpyruvate was prevented by 2,4-dinitrophenol or potassium cyanide. D-Fructokinase activity was elevated in cells grown in malate plus fructose or sucrose.

Metabolism of D-fructose by Arthrobacter pyridinolis.

Previous studies showed that Arthrobacter pyridinolis can transport and utilize d-glucose only after prior growth on certain Krebs cycle intermediates. In contrast, we found that d-fructose was taken up and metabolized by A. pyridinolis without special prior conditions of growth. d-Fructose was first converted to d-fructose-1-phosphate by a phosphoenolpyruvate (PEP):D-fructose phosphotransferase. This activity required both supernatant and pellet fractions from d-fructose-grown cells centrifuged at 150,000 x g. The d-fructose-1-phosphate formed was converted to d-fructose-1, 6-diphosphate. Mutants deficient in PEP:d-fructose phosphotransferase and d-fructose-1-phosphate kinase, or d-fructose-1, 6-diphosphatase (FDPase) were unable to grow on d-fructose but retained the normal ability to use d-glucose. Mutants forming reduced amounts of FDPase were completely unable to grow on d-fructose but were still capable of limited growth on Krebs cycle intermediates. A requirement for higher levels of FDPase for growth on d-fructose than for growth on Krebs cycle intermediates was also indicated by the higher specific activities of FDPase in d-fructose-grown cells than in cells grown on l-malate or amino acids.