Evidence for a defective protein synthesizing system in dormant spores of Bacillus cereus

RNA and ribosomal protein patterns during aerial spore germination in Streptomyces granaticolor

Disruption of the external sheath of Streptomyces granaticolor aerial spores and subsequent cultivation in a rich medium result in a synchronous germination. This method was used to analyze RNA and protein patterns during the germination. The germination process took place through a sequence of time-ordered events. RNA and protein synthesis started during the first 5 min and net DNA synthesis at 60-70 min of germination. Within the first 10 min of germination, synthesis of RNA was not sensitive to the inhibitory effect of rifamycin. During this period rRNA and other species including 4-5-S RNA were synthesized. Dormant spores contained populations of ribosomes or ribosomal precursors that were structurally and functionally defective. The ribosomal particles bound a sporulation pigment(s) of the melanine type. The ribosomal proteins complexed to the pigments formed insoluble aggregates which were easily removed from the ribosomes by one wash with 1 M NH4Cl. During the first 10 min of germination, pigment(s) were liberated from the complexes with the ribosomes and protein extracts of the washed ribosomes had essentially the same pattern as the extracts of ribosomes of vegetative cells. These structural alterations were accompanied by enhancement of the ribosome activities in polypeptide synthesis in vivo and in vitro. When the spores were incubated with a 14C-labelled amino acid mixture in the presence of rifamycin, only three proteins (GS1, GL1 and GS9) were identified to be radiolabelled in the extracts from the washed ribosomes. These experiments indicate that liberation of the sporulation pigment(s) from the complexes with ribosomal proteins and assembly of de novo synthesized proteins and proteins from a preexisting pool in the spore are involved in the reactivation of the ribosomes of dormant spores of S. granaticolor.

[Molecular biology of the germination of Bacillus spores]

The review deals with recent results and problems of gene expression during germination of Bacillus spores. Three problems were selected: 1. The activation of metabolism as a prerequisite for the synthesis of nucleic acids and proteins. 2. The activation of nucleic acid and protein synthesis during germination. 3. The gene expression programme of germinating spores. Using the highly sensitive two-dimensional polyacrylamide gel analysis three major classes of proteins were distinguished, depending on the time of onset and duration of their syntheses: a) proteins made throughout germination (main class), b) proteins whose synthesis started only after a lag phase and then continued throughout germination, and c) proteins which are synthesized only during the early phases of germination. The programme of protein synthesis is an indicator for the control of gene expression during germination. The regulation of expression of these major gene groups during spore outgrowth is discussed.

Protein synthesizing systems from spores and vegetative cells of Bacillus cereus

A system of polyphenylalanine synthesis was optimized for a comparison of the polymerizing activities of ribosomes from spores and vegetative cells of Bacillus cereus T. Ribosomes of both types react similarly, showing a magnesium optimum of about 6mM and spermidine optima of about 5mM and 4mM for vegative and spore ribosomes, respectively. These lead to optimum mono- to multivalent cation rations of 9 and 10 respectively at 100 mM ammonium ion. A comparison of the response of these ribosomes to suboptimal concentrations of magnesium and spermidine show that they differ qualitatively from each other, suggesting that they possess different structure, macromolecular or ionic components.

Antibiotic-resistant mutants of Bacillus subtilis conditional for sporulation

Among spontaneously occurring antibiotic-resistant mutants of Bacillus subtilis 168 we have identified a sub-class that is conditionally sporulative. Mutants in this sub-class are resistant to antibiotic during vegetative growth but are sensitive during sporulation. Mutants conditionally-resistant to erythromycin, kanamycin, spectinomycin, and streptomycin have been isolated and characterized by phase contrast microscopy and with respect to their ability to synthesize heat-resistant endospores or the sporulation-associated enzyme alkaline phosphatase. The results suggest that several entirely different genetic lesions may result in this single phenotype. This group includes mutants whose properties suggest that both th 30S and 50S ribosomal subunits may be altered concomitant with early spore specific metabolism. The blockage imposed by antibiotic may be at or near Stage 2 of sporulation.

Spores of microorganisms. XXVI. Synthetic activities of germinating spores of Bacillus cereus prevented from outgrowth

Spores of Bacillus cereus were germinated in a germination limited medium (GL-medium) which facilitates only germination but not the postgerminative development of spores. Under these conditions a limited protein synthesis occurs. However, this protein synthesis is stopped after a short time interval. The rate of synthesis of new proteins, as well as their total amount, is influenced by the length of the activation heat shock. Synthesis of the wall material continues for several hours and thick-walled cells with a changed ultrastructure are formed. Synthesis of the diaminopimelic acid (dap) containing material of the cell wall is sensitive to actinomycin D and relatively resistant to chloramphenicol. Similarly, protein synthesis is relatively chlorapmhenicol-resistant but is fully inhibited by azauracil or spiramycin. Whereas RNA formed in the control culture is partially decomposed after 30 min of incubation, chloramphenicol accelerates its synthesis and prevents its decay. Exudate components apparently stimulate synthesis of ribonucleic acid, proteins and the wall material. The 14-C-dap containing material released by prelabelled spores in the form of the exudate during the germination is not re-utilized by the spores germinated in the GL-medium. The results are discussed with respect to the atypical primary synthetic activities of spores under conditions when the postgerminative development is prevented and from the point of view of participation of the germination exudate during these syntheses.

Messenger ribonucleic acid of dormant spores of Bacillus subtilis

Evidence of the presence of messenger ribonucleic acid (mRNA) in dormant spores of Bacillus subtilis has been obtained. The bulk RNA from spores was isolated and labeled in vitro with tritiated dimethyl sulfate. The spore RNA hybridized to 2.4 to 3.2% of the B. subtilis genome. The RNA hybridized to both the complementary heavy and light fractions of deoxyribonucleic acid (DNA). Bulk RNA from log-phase cells competed with virtually all the spore RNA for the heavy DNA fraction and with part of the spore RNA for the light DNA fraction. Bulk RNA from stage IV cells in sporulation also competed with all of the spore RNA for the heavy DNA fraction and with essentially all the spore RNA for the light DNA fraction. These results indicate that dormant spores contain mRNA species present in both log-phase cells and stage IV cells of sporulation. The RNA polymerase in the developing forespore must be able to recognize promotor sites for both log-phase and sporulation genes.

Polyamine levels during growth, sporulation, and spore germination of Bacillus megaterium

Spermidine was the major (>95%) polyamine of Bacillus megaterium in all stages of growth, although it could be replaced completely by spermine. Log-phase cells had 40 to 50% as much spermidine, based on ribonucleic acid (RNA) content, as did either stationary-phase cells or dormant spores; similar results were obtained in three other bacilli including an asporogenous mutant. Polyamine levels were essentially the same in B. megaterium grown in rich or poor media, or in media of high or low ionic strength. Polyamine levels were elevated three- to sixfold by exogenous spermidine without a major effect on growth, sporulation, or subsequent spore germination. During germination, the absolute amount of spermidine remained constant for almost 2 h until net RNA synthesis had lowered the polyamine/RNA ratio to a value close to that in log-phase cells. At this time, the spermidine level began to rise, and thereafter spermidine and RNA increased in parallel. This parallel relationship between the spermidine and RNA levels was abolished by actinomycin D, but not by chloramphenicol.

Nature of deoxyribonucleic acid synthesis and its relationship to protein synthesis during outgrowth of Bacillus cereus T

Deoxyribonucleic acid (DNA) synthesis during early outgrowth of spores of Bacillus cereus T (thy(-)) has been examined. (14)C-thymidine incorporated begins 2 to 5 min after germination and continues at a slow rate up to 30 min, after which the rate of (14)C-thymidine incorporation increases considerably. Early DNA synthesis up to 30 min after germination is dependent upon simultaneous protein synthesis. The examination of the stability of proteins synthesized soon after germination shows that they are susceptible to intracellular degradation. The evidence provided here indicates that protein degradation is the cause of observed dependence of DNA synthesis on simultaneous protein synthesis. The DNA synthesis occurring soon after germination is primarily a repair type synthesis which is followed by the onset of normal replication approximately 30 min after germination.

Regulation of protein synthesis in zoospores of Blastocladiella

The factors responsible for the regulation of protein synthesis in the zoospores of Blastocladiella emersonii were studied by means of cell fractionation and in vitro assays. Charged transfer ribonucleic acid (tRNA) and aminoacyl-tRNA synthetases were found both inside the membrane-bound, ribosomal nuclear cap, and in the extracap cytoplasm. Ribosomes isolated from zoospore nuclear caps in low salt buffer failed to support polyuridylic acid-dependent phenylalanine incorporation. After washing with high salt buffer, the cap ribosomes were equivalent in activity to similarly prepared plant ribosomes. Both the high-salt wash from cap ribosomes and the extracap supernatant fraction contained an unidentified material which inhibited aminoacyl-tRNA binding and peptide bond formation by ribosomes. Ribosomal binding of polyuridylic acid was not inhibited. Washed cap ribosomes supported very low incorporation rates without added messenger RNA, and were highly dependent upon added poly U for phenylalanine incorporation, indicating a low level of messenger in nuclear caps. It is concluded that enclosure of the ribosomes in the nuclear cap does not in itself prevent protein synthesis, and that the lack of activity may be due to the presence of a ribosome inhibitor.

Peptide synthesis by extracts from Bacillus subtilis spores

Cell-free peptide synthesis by extracts from vegetative cells and spores of Bacillus subtilis was analyzed and compared. The initial rate of phenylalanine incorporation in a polyuridylate-directed system was found to be in a similar range for the two extracts. However, spore extracts frequently incorporated less total phenylalanine as did the vegetative cell system. Optimal conditions for amino acid incorporation by spore extracts were found to be similar to those of vegetative cell extracts. Polyphenylalanine synthesis was stimulated by preincubation of both extracts prior to the addition of polyuridylic acid (poly U) and labeled phenylalanine. Both systems showed a dependence on an energy-generating system and were inhibited by chloramphenicol and puromycin. Ribonuclease, but not deoxyribonuclease, inhibited the reaction significantly. The presence of methionine transfer ribonucleic acid (tRNA(F)) and methionyl-tRNA(F) transformylase was demonstrated in spore extracts. An analysis of several aminoacyl-tRNAs in spores revealed that the relative amounts of these tRNAs were similar to those found in vegetative cells. Only lysine tRNA was found to be present in relatively greater amounts in spores. These results indicate that dormant spores of B. subtilis contain the machinery for the translation of genetic information.

Relationship between protein and ribonucleic acid synthesis during outgrowth of spores of Bacillus cereus

The rate of protein and ribonucleic acid (RNA) synthesis was examined during the outgrowth of spores of Bacillus cereus T in a chemically defined medium. RNA synthesis started 2.5 min after the initiation of germination, and protein synthesis after 4 min. Addition of a complete amino acid supplement and uracil supported high rates of RNA and protein synthesis throughout outgrowth. To determine the relationship between the rate of protein (k) and RNA synthesis, the kinetics of formation of various classes of RNA were followed during outgrowth. Ribosomal RNA (rRNA) comprised a relatively constant fraction of the total RNA throughout outgrowth (71 to 78%). The classes of RNA synthesized during this period were determined by germinating spores in radioactive uracil and then at intervals following their stability to actinomycin D. Initially, labile RNA comprised the largest fraction of newly formed RNA (DeltaRNA), and this proportion decreased during outgrowth. The ratio of k/rRNA or k/Delta stable RNA varied considerably during outgrowth, whereas the ratio of k/labile RNA remained constant. The data suggest that the rate of protein synthesis is not rigidly coupled to either total or newly synthesized rRNA (ribosomes) during the early stages of outgrowth.