Sphere-Rod Morphogenesis in Arthrobacter crystallopoietes I. Cell Wall Composition and Polysaccharides of the Peptidoglycan

Cell walls of Arthrobacter crystallopoietes were prepared from cells grown as spheres and from peptone- and succinate-induced rod stage cells. Undegraded polysaccharide backbones of the peptidoglycans were isolated from myxobacter AL-1 protease digests by ECTEOLA cellulose and Sephadex G-50 chromatography. The polysaccharide backbones of the sphere cell wall peptidoglycan are heterogeneous in their size, and average less than 40 hexosamines per chain. Those of the rod cell walls are homogeneous in size and average 114 to 135 hexosamines per chain.     

Gram Characteristics and Wall Ultrastructure of Arthrobacter crystallopoietes During Coccus-Rod Morphogenesis

Arthrobacter crystallopoietes growing exponentially as cocci were changed to rods by adding succinate to the medium. Cells were sampled before, during, and after this transition for Gram-staining and ultrastructural studies. Cells were Gram stained by the standardized method of Bartholomew, and all samples were fixed and prepared for thin sectioning in an identical manner. Cocci were gram positive, and thin sections demonstrated a gram-positive type of cell wall having an average thickness of 31 nm. Cells sampled during morphogenesis appeared as cocci with most having a single rodlike projection. The coccus portion of these transition cells was gram positive and bound by a gram-positive type of wall having an average thickness of 29 nm. The rodlike projection of the transition cells appeared to be gram negative; it was also surrounded by a gram-positive type of wall, but its average thickness was only 22 nm. Gram-negative rods of the type species, Arthrobacter globiformis, were also examined and found to produce a gram-positive type of wall with a 19-nm average thickness. Evidence for the trilaminar region, characteristic of most gram-negative bacterial cell walls, was totally lacking in both species. These results suggest that variations in cell wall thickness may be an important contributing factor to the variable Gram-staining characteristics of this genus.     

Stability of enzymes in starving Arthrobacter crystallopoietes.

Cell-free extracts prepared from spherical and rod-shaped cells of Arthrobacter crystallopoietes were assayed for enzymes during various periods of starvation. The level of NADH oxidase dropped to 20 and 30%, respectively, in spherical and rod-shaped cells during the first 1 to 2 days of starvation and then remained constant for 9 days. Catalase activity decreased continuously and reached a low level in 9 days. Enzymes involved in glucose metabolism and the tricarboxylic acid cycle were stable for the duration of the experiment (about 1 week). Succinic dehydrogenase, fumarase and aconitase were stable during 21 days of starvation, which is the longest time enzymes have been shown to be stable in any bacterium under conditions of total starvation.     

Isolation and characterization of morphogenetic mutants of Arthrobacter crystallopoietes

Mutants of Arthrobacter crystallopoietes that exhibited altered ability to undergo the normal sphere-to-rod-to-sphere morphogenetic cycle were isolated. The procedure used to isolate these mutants involved velocity sedimentation in a sterile sucrose gradient to separate morphogenesis-deficient spherical cells from rod-shaped cells capable of normal morphogenesis. Three classes of mutants were obtained: (i) those that cannot form rods, (ii) those that cannot form long rods, and (iii) those that form long rods but exhibit more extensive rudimentary branching than the wild type. The isolation and characterization of these mutants are described, and the use of these mutants in the study of the morphogenetic cycle of arthrobacters is discussed.     

Lipid Composition of Growing and Starving Cells of Arthrobacter crystallopoietes

The lipid composition of growing and starving cells of Arthrobacter crystallopoietes was compared. Although the lipid composition of the two cell types was similar, the amount of total lipids recovered from the starving cells was 30.4% less than that recovered from the growing cells. The loss of lipids, as compared to the loss of total cell mass during starvation, was (i) proportional to the loss of the cell mass (phosphatidylinositol, phosphatidylglycerol-2, and cardiolipin), (ii) greater than the loss in cell mass (neutral lipids, "glycophospholipids," and phosphatidic acid), or (iii) less than the loss in cell mass (coenzyme Q, glycolipids, and phosphatidylglycerol-1).     

Survival of Arthrobacter crystallopoietes During Prolonged Periods of Extreme Desiccation

Cells of Arthrobacter crystallopoietes mixed in sand and air-dried have survived for up to 6 months after an initial period in which approximately half the cells lost their viability. Comparative survival curves have been obtained from inoculated sands maintained under CaSO(4) or P(2)O(5). Selections for more desiccation-resistant progeny capable of surviving the initial period were unsuccessful. Both the coccoid and rod-shaped forms are equally resistant to several months of desiccation. Desiccated spherical cells converted 0.0005% of their cell carbon to carbon dioxide per hr, which corresponds to a half-life for self-consumption of approximately 12 years.     

Macromolecular synthesis and cell division during morphogenesis of Arthrobacter crystallopoietes

The sphere-rod-sphere morphology cycle of Arthrobacter crystallopoietes was accompanied by changes in the rate of growth and the rates of DNA, RNA and protein synthesis. The patterns of macromolecule synthesis resembled those found in other bacteria during a step-up followed by a step-down in growth rate. During the step-up in growth spherical cells grew into rods and macromolecules were synthesized in the absence of cell division. During stepdown, successive rounds of septation produced progressively smaller cells which did not separate and remained in chains. The morphology of the cells was dependent on the growth rate and could be altered by changing the dilution rate in a malate-limited chemostat. Gradual transitions in morphology and gradual increases in macromolecule content of the cells occurred as the growth rate was increased in the chemostat. Sphere to rod morphogenesis occurred when DNA synthesis was inhibited by treatment with mitomycin C or by thymine starvation. The DNA-deficient rods did not divide and eventually lysed. DNA, RNA and protein synthesis were continuously required for the reductive division of rods to spheres.Abbreviations MS mineral salts - GS mineral salts plus glucose - CA casamino acids - GSCA mineral salts plus glucose plus casamino acids - cAMP cyclic adenosine-3,5-monophosphate - RNA ribonucleic acid - DNA deoxyribonucleic acid     

Degradation of pyridine by Arthrobacter crystallopoietes and Rhodococcus opocus strains

Abstract Two pyridine-degrading microorganisms Arthrobacter crystallopoietes (VKM Ac-1334D) and Rhodococcus opacus (VKM Ac-1333D) were isolated from soil. The Gas chromatography-mass spectroscopy analysis showed that the former species formed 3-hydroxypyridine, 2,3- and 2,6-dihydroxypyridines during its growth in media containing pyridine, while the latter formed 2-hydroxy- and 2,6-dihydroxypyridines as degradation intermediates. Products of the pyridine ring cleavage (5-amino-2-oxo-4-pentenoic acid and 3-pentenoic acid monoamide) were also detected.     

Regulation of cyclic AMP levels in Arthrobacter crystallopoietes and a morphogenetic mutant.

The extracellular levels of cyclic AMP (cAMP), cAMP phosphodiesterase activity, and adenylate cyclase activity were measured at various intervals during growth and morphogenesis of Arthrobacter crystallopoietes. There was a significant rise in the extracellular cAMP level at the onset of stationary phase, and this rise coincided with a decrease in intracellular cAMP. The phosphodiesterase activity measured in vitro increased in the early exponential phase of growth as intracellular cAMP decreased, and, conversely, prior to the onset of stationary phase the phosphodiesterase activity decreased as the intracellular cAMP levels increased. Adenylate cyclase activity was greater in cell extracts prepared from cells grown in a medium where morphogenesis was observed. Pyruvate stimulated adenylate cyclase activity in vitro. A morphogenetic mutant, able to grow only as spheres in all media tested, was shown to have altered adenylated cyclase activity, whereas no significant difference compared to the parent strain was detectable in either the phosphodiesterase activity or the levels of extracellular cAMP. The roles of the two enzymes, adenylate cyclase and phosphodiesterase, and excretion of cAMP are discussed with regard to regulation of intracellular cAMP levels and morphogenesis.     

Long-Term Starvation Survival of Rod and Spherical Cells of Arthrobacter crystallopoietes

Spherical and rod-shaped cells of Arthrobacter crystallopoietes, harvested during exponential growth, were subjected to total starvation for periods of time as long as 80 days. Viability measurements were made by plate count and slide culture procedures. Both cell forms remained 100% viable for 30 days. Thereafter, viability of rods and spheres decreased equally at a slow rate. After 60 days of starvation, more than 65% of both cell forms were viable. No significant cell lysis occurred as evidenced by microscopic examination, the small amount of 260-nm absorbing material found in the starvation buffer, and stability of radioactively labeled deoxyribonucleic acid in the cells. Endogenous respiration decreased 80-fold during the first 2 days of starvation, accompanied by a 30% decrease in dry weight of the cells. Thereafter, cellular carbon was oxidized to CO(2) at the constant level of 0.03%/hr over the remaining 78-day starvation period.     

Susceptibilities of Yeasts to Yeast Cell Wall Lytic Enzyme of Arthrobacter luteus

The susceptibilities of various strains of yeast to a yeast cell wall lytic enzyme produced by Arthrobacter lutens were examined. Twenty six strains of yeasts, mainly in the genera Saccharomyces and Candida were tested. They were tested after growth attained to the logarithmic or to the resting stage in different media (malt extract medium or n-paraffin medium) and various culture conditions (shaking or stationary liquid cultures or agar slopes).

The effects of various treatments, such as heating, or treatment with 2-mercaptoethanol or sodium dodecylsulfate on their susceptibility were also examined.

These various conditions and treatments greatly influenced the susceptibilities of the yeast cells, suggesting that they affected the composition and/or structure of the yeast cell walls.     

A d-specific hydantoin amidohydrolase: properties of the metalloenzyme purified from Arthrobacter crystallopoietes

A d-specific hydantoinase has been purified to homogeneity from Arthrobacter crystallopoietes DSM 20117 with a yield of 5% related to the crude extract. The active enzyme is a tetramer of 257 kDa consisting of four identical subunits, each with a molecular mass of 60 kDa. Incubation of the enzyme with the metal-chelating agent EDTA had no inhibitory effect, while 8-hydroxyquinoline-5-sulfonic acid resulted in a complete and irreversible inactivation. The purified enzyme contains zinc as cofactor, which could be detected by subjection to direct analysis using inductive/coupled plasma-atomic emission spectrometry. The hydantoinase has a wide substrate specificity for the d-selective cleavage of 5-monosubstituted hydantoin derivatives with aliphatic and aromatic side chains. The V_max-value for phenylhydantoin is 217 U/mg, the K_m-value is 8 mM. Dihydrouracil was found to be a natural substrate (V_max=35 U/mg). The N-terminal amino acid sequence of the enzyme shows distinct homologies to other metal-dependent cyclic amidases involved in the nucleotide metabolism especially to dihydropyrimidinases as well as to ureases, l- and unselective hydantoinases. Due to these findings, this enzyme has to be considered as a possible link in the evolution to related l-selective and unselective hydantoinases from the genus of Arthrobacter.     

Sphere-rod morphogenesis in Arthrobacter crystallopoietes. II. Peptides of the cell wall peptidoglycan

Cell walls of Arthrobacter crystallopoietes grown as spheres and as rods were solubilized by treatment with the B enzyme from Chalaropsis, an N-acetylmuramidase. The neutral glycopeptides were then isolated by chromatography on ECTEOLA cellulose. The glycopeptides, consisting of disaccharide-peptide units interlinked by peptide cross-bridges, were fractionated by gel filtration on Sephadex columns into oligomers of various sizes. The size distribution ranged from monomers with no cross-bridges to polymers with a high degree of polymerization, but did not differ significantly between cell walls from cells grown as spheres or rods. Some small differences in the distribution of C- and N-terminal amino acids were found. Analyses revealed that all the peptide bridges in the glycopeptide fractions from rod cell walls were formed by one l-alanine residue. In sphere cell walls, l-alanine was also found, but, in addition, higher oligomers of the glycopeptide contained glycine in their cross-bridges. These results were confirmed by determinations of C- and N-terminal amino acids released after lysostaphin and AL-1 enzyme digestions and by Edman degradations. Models representing the structures of the sphere and rod cell walls are presented. These structures indicate that the sphere cell wall is probably a more loosely knit macromolecule than is the rod cell wall.     

Alteration of glucose metabolism of Arthrobacter crystallopoietes by compounds which induce sphere to rod morphogenesis

Succinate and several other compounds which induce sphere to rod morphogenesis of A. crystallopoietes were found to suppress both catabolism and assimilation of glucose. Diauxic growth patterns resulted from growth on glucose plus any one of these compounds. Glutamate stimulated growth but was not an inducer of morphogenesis. With this compound, diauxic growth and suppression of glucose catabolism or assimilation did not occur. Glucose permease was studied with alpha-methylglucoside as substrate. The entry system for glucose was found to involve active transport and to have a K(m) of 8 x 10(-4)m. It was inducible, was repressed in succinate-grown cells, and was also inhibited by succinate. The exit system was constitutive and appeared to be less sensitive than the entry system to inhibition by azide. The properties of the glucose permease system may account for the slow growth of the organism on glucose and the preferred use of other substrates for growth. Studies of metabolic pathways for glucose metabolism indicated the operation of the Embden-Meyerhof-Parnas (EMP) and pentose phosphate pathways and of the tricarboxylic acid cycle. Cells grown on glucose plus limiting amounts of succinate or other inducers of morphogenesis metabolized the glucose only after exhaustion of the inducers. Under these circumstances, the organisms employed the EMP pathway to a greater extent than when growing on glucose as sole carbon source.     

Intracellular Substrates for Endogenous Metabolism During Long-Term Starvation of Rod and Spherical Cells of Arthrobacter crystallopoietes

Cells of Arthrobacter crystallopoietes, harvested during growth as spheres and as rods, were starved by shaking at 30 C in phosphate buffer for 30 days, during which time they maintained 100% viability. Changes in cellular components and the activity of specific enzyme pathways were monitored. A glycogen-like polysaccharide comprised 40% of the dry weight of growing spherical cells and 10% of the dry weight of rod cells. This material was utilized at approximately the same rate, on a percentage basis, during starvation of both cell forms. The rods degraded intracellular protein at approximately twice the rate of the spheres. At the end of 30 days, the rods had degraded 40% and the spheres 20% of their initial content of protein. Ribonucleic acid (RNA) was degraded significantly more rapidly in the rods. After 30 days starvation, 85 and 32% of the initial RNA of rods and spheres, respectively, had been depleted. Magnesium ion followed this same general pattern; the rods lost 65% and the spheres 45% of their initial content during 28 days of starvation. Deoxyribonucleic acid increased by 20% during the first few hours of starvation of both cell forms and then remained constant. The ability of glucose-, succinate-, and 2-hydroxypyridine (2-HP)-grown cells to oxidize glucose remained constant during 14 days of starvation. The ability of succinate-grown cells to oxidize succinate decreased rapidly during the first few hours of starvation to a rate which remained constant for 14 days. Cells adapted to growth on 2-HP completely lost their ability to oxidize this substrate after 3 days starvation.     

Electron microscopic study of cell surface rings during cell division and morphogenesis of Arthrobacter crystallopoietes.

The whole cell ultrastructure during cell division and morphogenesis of Arthrobacter crystallopoietes was monitored using electron microscopic techniques. Glucose-grown spherical cells were inoculated into succinate-based medium. In this medium, the organism undergoes a morphogenetic cycle consisting of elongation of spheres to rods, exponential growth as rods, and fragmentation of rods to spherical cells. Raised bands or rings that encircled the cells were evident on the cell surface of both sphere- and rod-shaped cells. Many rod-shaped cells possessed two or more rings arranged adjacent to each other in a parallel orientation. At each cell division a new ring was formed on both siblings. However, as predicted by the proposed model of unidirectional cell growth and by maintaining a ring from the previous generation, unequal numbers of rings were observed on sibling cells. Only one ring was visible on most of the spherical inoculum cells, but in some cases a second ring perpendicular to the other ring was observed. Parallel rings were found on spherical cells resulting from fragmentation or reductive cell division of rods during the stationary growth phase. Thus, these spheres could be distinguished from inoculum spheres containing a single ring or perpendicular orientation of rings. The number of rings per cell and arrangement of rings on the cell surface of sibling cells after cell division, but before cell separation, are discussed with respect to cell age, cell division, and sphere-rod-sphere morphogenesis of A. crystallopoietes.