Stable Messenger Ribonucleic Acid and Germination of Myxococcus xanthus Microcysts

We have examined germination, protein synthesis and ribonucleic acid (RNA) synthesis by microcysts of the fruiting myxobacterium Myxococcus xanthus. The morphological aspects of microcyst formation were completed at about 2 hr after induction had begun. In such microcysts, germination, RNA synthesis, and protein synthesis were inhibited by actinomycin D (Act D). At 6 hr after induction, germination and protein synthesis had become relatively resistant to Act D, whereas RNA synthesis was inhibited by about 95%. Experiments with (3)H-Act D indicated that the deoxyribonucleic acids of both young and old microcysts bind Act D equally. Resistance of germination to Act D was acquired 4 to 5 hr after induction of microcyst formation, and was due to an Act D-sensitive synthesis at that time. Vegetative cells and microcysts were pulsed with uridine-5-(3)H and chased for 60 min; the RNA was extracted and analyzed by means of sucrose density gradient centrifugation and gel electrophoresis. Both microcysts and vegetative cells were found to contain grossly the same types of RNA in the same proportions. RNA pulse-labeled in microcysts was more stable than that in vegetative cells. No particular portions of the microcyst pulse-labeled RNA were selectively stabilized. These data indicate that a stable messenger RNA required for synthesis of germination proteins was synthesized during microcyst formation. This may be the same as the RNA synthesized 4 to 5 hr after initiation of microcyst formation. We suggest that the existence of such stable messenger RNA in microcysts is consistent with the limited biosynthetic activities of such cells.     

A bacteriophage for Myxococcus xanthus: isolation, characterization and relation of infectivity to host morphogenesis

Burchard, Robert P. (University of Minnesota, Minneapolis), and M. Dworkin. A bacteriophage for Myxococcus xanthus: isolation, characterization and relation of infectivity to host morphogenesis. J. Bacteriol. 91:1305-1313. 1966.-A bacteriophage (MX-1) infecting Myxococcus xanthus FB(t) has been isolated from cow dung. The bacteriophage particle is approximately 175 mmu long. A tail about 100 mmu in length is encased in a contractile sheath and terminates in a tail plate. The head is polyhedral with a width of about 75 mmu. The nucleic acid of the bacteriophage is deoxyribonucleic acid and has a guanine plus cytosine content of 55.5%. The bacteriophage requires 10(-3)m Ca(++) and 10(-2)m monovalent cation for optimal adsorption. Grown on vegetative cells of M. xanthus FB(t) at 30 C in 2% Casitone medium, the bacteriophage has a latent period of 120 min and a burst size of approximately 100. Host range studies indicate that three strains of M. xanthus including a morphogenetic mutant are sensitive to the bacteriophage, whereas M. fulvus, Cytophaga, Sporocytophaga myxococcoides, and a fourth strain of M. xanthus are not. Of the two cellular forms characteristic of the Myxococcus life cycle, the bacteriophage infect only the vegetative cells; they do not adsorb to microcysts. Ability to adsorb bacteriophage is lost between 65 and 75 min after initiation of the relatively synchronous conversion of vegetative cells to microcysts. The bacteriophage does not adsorb to spheroplasts. After the appearance of visible morphogenesis and before the loss of bacteriophage receptor sites, addition of bacteriophage results in the formation of microcysts which give rise to infective centers only upon germination. The possibility that the infected microcysts are harboring intact bacteriophages has been eliminated.     

Linkages between deoxyribonucleic acid synthesis and cell division in Myxococcus xanthus.

Addition of chloramphenicol or 0.5 M glycerol to growing Myxococcus xanthus resulted in an immediate cessation of cell division and 40% net increase in deoxyribonucleic acid (DNA). Although the chloramphenicol-treated cells divided in the presence of nalidixic acid after chloramphenicol was removed, glycerol-induced myxospores required DNA synthesis for subsequent cell division. Myxospores prepared from chloramphenicol-treated cells lost this potential to divide in the presence of nalidixic acid. The "critical period" of DNA synthesis necessary for cell division after germination overlapped in time (3 to 5 h) with initiation of net DNA synthesis. The length of the critical period of DNA synthesis was estimated at 12 min, or 5% of the M. xanthus chromosome. The requirement for cell division during germination also involved ribonucleic acid and protein synthesis after DNA synthesis. The data suggest that replication at or near the origin of the chromosome triggers the formation of a protein product that is necessary but not sufficient for subsequent cell division; DNA termination is also required. During myxospore formation, the postulated protein is destroyed, thereby reestablishing and making apparent this linkage between early DNA synthesis and cell division.     

Ribonucleic Acid Synthesis During Morphogenesis in Myxococcus xanthus

Ribonucleic acid synthesis was measured during the morphogenesis of Myxococcus xanthus. After induction of microcyst formation by the addition of glycerol to an exponential culture, net ribonucleic acid (RNA) synthesis was immediately terminated (measured either chemically or by the accumulation of acid-insoluble radioactivity). Extensive RNA turnover did take place, however, including RNA made both before and after induction. Sucrose gradient centrifugation revealed that ribosomes and ribosomal RNA were synthesized during microcyst formation even though there was no net RNA synthesis. Base analyses of the total RNA of vegetative cells and 120-min microcysts were indistinguishable.     

Resistance of Vegetative Cells and Microcysts of Myxococcus xanthus

The resistance of vegetative cells and of microcysts of Myxococcus xanthus to several destructive agents was compared. Fruiting-body microcysts were 300 times more resistant to 60 C, 5.4 times more resistant to ultraviolet light, and 19.3 times more resistant to sonic vibration than were vegetative cells. Whereas resistance to sonic vibration developed during the conversion of rods to refractile spheres, resistance to heat did not appear until after the conversion was complete. Both vegetative cells and microcysts of the yellow variant of this strain were more resistant to ultraviolet irradiation than was the tan variant.     

Deoxyribonucleic Acid Synthesis During Microcyst Germination in Myxococcus xanthus

Deoxyribonucleic acid (DNA) synthesis was measured during microcyst germination in Myxococcus xanthus by radioactive thymidine incorporation, autoradiography, and chemical analysis. Microcysts contained an average of 6.6 conserved units of DNA, corresponding to 3 to 4 chromosomes per cell. Correlation of the DNA content and chromosome number of microcysts indicated that the molecular weight of the nonreplicating M. xanthus chromosome is 4.9 x 10(9) daltons. DNA synthesis was initiated 3.5 to 4 hr after induction of germination. From 4 to 6 hr, the rate of synthesis was constant and the accumulation was linear. After a lag period (6 to 6.5 hr), the rate of DNA synthesis increased, reaching a second plateau at 9 hr. From 9 to 11 hr, the rate was again constant and the accumulation was linear. Cellular division during germination showed an unusual kind of synchrony. A model is presented that accounts for chromosomal replication and cell division during microcyst germination.     

Deoxyribonucleic Acid Synthesis During Exponential Growth and Microcyst Formation in Myxococcus xanthus

Myxococcus xanthus in exponential phase with a generation time of 270 min contained a period of 50 min during which deoxyribonucleic acid (DNA) synthesis did not take place. After induction of microcysts by the glycerol technique, the DNA content increased 19%. Autoradiographic experiments demonstrated that the DNA made after glycerol induction was not evenly distributed among the microcysts. The distribution of grains per microcyst fits the following model of chromosome replication: in exponential phase, each daughter cell receives two chromosomes which are replicated sequentially during 80% of the divison cycle; after microcyst induction, no chromosomes are initiated. Mathematical formulas were derived which predict the kinetics and discrete probability distribution for several chromosome models.     

Synthesis and salvage of purines during cellular morphogenesis of Myxococcus xanthus.

Intact cells of Myxococcus xanthus were examined for de novo purine synthesis and salvage utilization. The cellular uptake rates of radioactive glycine (de novo purine precursor), adenine, and guanine were measured, and thin-layer chromatography and radioautography were used to examine cell extracts for de novo synthesized purine nucleotides. Intact vegatative cells, glycerol-induced myxospores, and germinating cells of M. xanthus CW-1 were able to carry out de novo purine and salvage synthesis. Germinating cells and glycerol-induced myxospores were metabolically more active or as active as vegetative cells with respect to purine anabolism. We conclude that M. xanthus is capable of synthesizing purine nucleotides and salvaging purines throughout the glycerol version of its life cycle.     

Peptidoglycan of Myxococcus xanthus: structure and relation to morphogenesis

The chemical nature and distribution of the peptidoglycan in Myxococcus xanthus at various stages of the cellular life cycle were investigated. Vegetative cells and microcysts contained approximately 0.6% by weight of peptidoglycan. The overall composition of the peptidoglycan was similar in both cell types and was approximately 1 glutamic acid, 1 diaminopimelic acid, 1.7 alanine, 0.75 N-acetylglucosamine, and 0.75 N-acetylmuramic acid. (We have assumed that all the hexosamines are N-acetylated.) The sizes of the subunits (estimated by gel filtration) solubilized by muramidases were considerably larger (tetramer and oligomer) in the microcysts than in the vegetative cells (mostly dimer). There was a transient decrease in cross-linking (measured as an increase in the amount of free amino group of diaminopimelic acid) during the stage of microcyst formation when the cells converted from ovoids to spheres. At the same time, there occurred a large and rapid increase in a galactosamine derivative which may have reflected the synthesis of capsular material. Immediately prior to this period of morphogenesis, the cells became resistant to penicillin but remained sensitive to d-cycloserine. The walls of vegetative cells were completely disaggregated by trypsin and sodium lauryl sulfate, suggesting a discontinuous peptidoglycan layer. This was no longer apparent after the ovoid-sphere stage of microcyst formation. The relationship to morphogenesis of the chemical changes in the cell wall is discussed.     

Induction of morphogenesis by methionine starvation in Myxococcus xanthus: polyamine control

The induction of mycrocyst formation by methionine starvation was demonstrated in Myxococcus xanthus by several methods. Growing in a defined medium (M(1)), M. xanthus had a doubling time of 6.5 hr. Four amino acids-leucine, isoleucine, valine, and glycine-were required for growth under these conditions. When the concentration of several amino acids in the medium was reduced (M(2)), the doubling time increased to 10 to 12 hr, and a requirement for methionine was observed. Methionine starvation led to a slow conversion of the population to microcysts. Under conditions of methionine prototrophy (M(1)), microcyst formation could still be triggered in exponentially growing cells by the addition of either 5 mm ethionine or 0.1 m isoleucine plus 0.1 m threonine, feedback inhibitors of methionine biosynthesis. Vegetative growth in the absence of methionine was obtained in medium M(2) if the leucine concentration was raised to its level in medium M(1). Thus, methionine biosynthesis is controlled by the exogenous concentration of the required amino acid, leucine. During an examination of the effects of methionine metabolites on microcyst formation, the involvement of polyamines in morphogenesis was uncovered. Putrescine (0.05 m) induced the formation of microcysts; spermidine (2 to 5 mm) inhibited induction by methionine starvation, ethionine, or high isoleucine-threonine. Spermidine was the only polyamine detected in M. xanthus (16.0 mug/10(9) cells). Its concentration decreased by more than 50% shortly after microcyst induction by high isoleucine-threonine. It is postulated that spermidine is an inhibitor of microcyst induction; when spermidine formation is blocked by methionine starvation, morphogenesis is induced.     

Gene expression during development of Myxococcus xanthus. Analysis of the genes for protein S

Protein S is an abundant spore coat protein produced during fruiting body formation (development) of the bacterium Myxococcus xanthus. We have cloned the DNA which codes for protein S and have found that this DNA hybridizes to three protein S RNA species from developmental cells but does not hybridize to RNA from vegetative cells. The half-life of protein S RNA was found to be unusually long, about 38 minutes, which, at least in part, accounts for the high level of protein S synthesis observed during development. Hybridization of restriction fragments from cloned M. xanthus DNA to the developmental RNAs enabled us to show that M. xanthus has two directly repeated genes for protein S (gene 1 and gene 2) which are separated by about 10(3) base-pairs on the bacterial chromosome. To study the expression of the protein S genes in M. xanthus, eight M. xanthus strains were isolated with Tn5 insertions at various positions in the DNA which codes for protein S. The strains which contained insertions in gene 1 or between gene 1 and gene 2 synthesized all three protein S RNA species and exhibited normal levels of protein S on spores. In contrast, M. xanthus strains exhibited normal levels of protein S on spores. In contrast, M. xanthus strains with insertions in gene 2 had no detectable protein S on spores and lacked protein S RNA. Thus, gene 2 is responsible for most if not all of the production of protein S during M. xanthus development. M. xanthus strains containing insertions in gene 1, gene 2 or both genes, were found to aggregate and sporulate normally even though strains bearing insertions in gene 2 contained no detectable protein S. We examined the expression of gene 1 in more detail by constructing a fusion between the lacZ gene of Escherichia coli and the N-terminal portion of protein S gene 1 of M. xanthus. The expression of beta-galactosidase activity in an M. xanthus strain containing the gene fusion was shown to be under developmental control. This result suggests that gene 1 is also expressed during development although apparently at a much lower level than gene 2.     

Division Cycle of Myxococcus xanthus III. Kinetics of Cell Growth and Protein Synthesis

The kinetics of cell growth and protein synthesis during the division cycle of Myxococcus xanthus was determined. The distribution of cell size for both septated and nonseptated bacteria was obtained by direct measurement of the lengths of 8,000 cells. The Collins-Richmond equation was modified to consider bacterial growth in two phases: growth and division. From the derived equation, the growth rate of individual cells was computed as a function of size. Nondividing cells (growth phase) comprised 91% of the population and took up 87% of the time of the division cycle. The absolute and specific growth rates of nondividing cells were observed to increase continually throughout the growth phase; the growth rate of dividing cells could not be determined accurately by this technique because of changes in the geometry of cells between the time of septation and physical separation. The rate of protein synthesis during the division cycle was measured by pulselabeling an exponential-phase culture with radio-active valine or arginine and then preparing the cells for quantitative autoradiography. By measuring the size of individual cells as well as the number of grains, the rate of protein synthesis as a function of cell size was obtained. Nondividing cells showed an increase in both the absolute and specific rates of protein synthesis throughout the growth phase; the specific rate of protein synthesis for dividing cells was low when compared to growthphase cells. Cell growth and protein synthesis are compared to the previously reported kinetics of deoxyribonucleic acid and ribonucleic acid synthesis during the division cycle.     

Microcyst Germination in Myxococcus xanthus

Germination of glycerol-prepared microcysts of Myxococcus xanthus was studied. The sequence of morphological events during germination resembled that of germinating fruiting body-microcysts. The turbidity drop of a culture of germinating microcysts could be described by McCormick's formula derived for germinating Bacillus spores. The rate of uptake of labeled glycine and acetate did not change during germination. Temperature, aeration, and pH optima for germination were the same as for vegetative cell growth. Germination was induced by protein hydrolysates and the individual amino acids glycine, alanine, valine, aspartic acid, and glutamic acid. A number of organic compounds, including sugars, alcohols, aldehydes, ketones, organic acids, and chelating agents, did not induce germination. The inorganic ions HPO(4) (2-), Mg(++), Ca(++), and NH(4) (+) induced germination, although ionic strength was not a factor. Microcysts incubated in distilled water at concentrations greater than about 10(9) cells/ml germinated; supernatant fluid from such suspensions (germination factor) induced germination of less concentrated suspensions. The activity of germination factor was resistant to boiling, but was lost on charring and dialysis. Germination of microcysts and growth of vegetative cells was equally sensitive to a variety of metabolic inhibitors, including penicillin and chloramphenicol. Germination was more resistant than vegetative growth to inhibition by antibiotics of the streptomycin family and by actinomycin D.     

Glucan common to the microcyst walls of cyst-forming bacteria.

Chemical analysis indicated that D-glucose is tha major neutral monosaccharide present in the microcysts of a range of gram-negative bacteria. Varying amounts of other neutral sugars were found. The glucose was mainly present as a glucan that could be extracted from microcysts of representative strains with alkali or mild acid treatment. The glucan could be identified as an alpha-1,3-linked polymer on the basis of (i) periodate resistance of the extracted polymer and the material present in microcysts; (ii) lectin agglutination of the microcysts; (iii) lectin precipitation of the extracted glucans; and (iv) susceptibility of the glucan either in the walls or after extraction to a specific alpha-1,3-glucanase from Aspergillus nidulans, yielding glucose as the sole hydrolysis product. The galactosamine found in microcysts of Myxococcus xanthus by other workers is clearly a component of another polymer, distinct from the glucan. The presence of an alpha 1,3-linked glucan, common to microcyst walls of various bacterial genera, probably contributes to the rigidity of the walls of these forms and, inter alia, to their resistance to ultrasonic treatment. Preliminary experiments indicate that the gulcan is discarded on germination of the microcysts rather than being broken down by specific enzymes.     

Comparative Intermediary Metabolism of Vegetative Cells and Microcysts of Myxococcus xanthus

Crude extracts of both vegetative cells and glycerol-induced microcysts of Myxococcus xanthus contained the following enzyme activities: phosphofructokinase, phosphoglucoisomerase, fructose-1,6-diphosphatase, fructosediphosphate aldolase, glyceraldehyde-3-phosphate dehydrogenase, phosphopyruvate carboxylase, citrate synthase, isocitrate dehydrogenase, alpha-ketoglutarate dehydrogenase, succinate dehydrogenase, malate dehydrogenase, glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, phosphoglucomutase, and uridine diphosphate glucose pyrophosphorylase. With the exception of isocitrate dehydrogenase, which was present at a fivefold higher concentration in microcysts, all activities in extracts from both types of cells were essentially equal. Hexokinase and pyruvate kinase could not be detected in extracts from either type of cell. Microcysts metabolized acetate at a lower rate than did vegetative cells. Most of this decrease was reflected in a substantial decrease in ability of microcysts to oxidize acetate to CO(2). In addition, microcysts and vegetative cells showed a different distribution of (14)C-label from incorporated acetate.     

Carbohydrate accumulation during myxospore formation in Myxococcus xanthus.

During glycerol-induced myxospore formation in Myxococcus xanthus, cellular neutral polysaccharide increases by approximately 200%, respiration decreases by 80%, and net phospholipid synthesis ceases.     

Potassium uptake during microcyst formation in Myxococcus xanthus

The kinetics of (42)K uptake by Myxococcus xanthus during vegetative growth and microcyst formation were determined. In the medium studied, growing cells concentrated potassium about 100-fold, yielding an intracellular concentration of 147 mm. The influx of K(+) in growing cells was 17 +/- 3 pmoles of K(+)/cm(2) min. About 5 hr after induction of vegetative cells to microcysts, the K(+) influx decreased and the intracellular concentration fell. By 18 hr after induction, there was no measurable influx of K(+), and the intracellular concentration of potassium was less than 29 mm. There was, however, considerable binding of K(+) to the "surface" of microcysts. It is postulated that the greatly reduced intracellular concentration of potassium helps to maintain the microcyst in its dormant state and protects it against enzymatic break-down.