Nucleic acid synthesis was studied during germination and outgrowth of normal spores of Bacillus subtilis, as well as of spores carrying the genome of phage oe. In a system in which development was restricted to the spore-darkening phase, synthesis of ribonucleic acid (RNA), but not deoxyribonucleic acid (DNA), was detected. The extent of RNA synthesis and turnover during this phase was similar for the two types of spores. In a partially darkened population of spores of either type, there was little RNA degradation, whereas there was considerable turnover in a fully darkened population. The DNA-dependent RNA polymerase of dormant or dark spores was not active in vitro with the DNA as template, although a sigma-like factor could be separated from the polymerizing activity by zone centrifugation. Within 40 min after resuspension of dark spores in a medium that allows outgrowth, the enzyme acquired the ability to transcribe the phage DNA efficiently. During outgrowth, both normal and carrier spores synthesized DNA, but in carrier spores this DNA was almost entirely phage specific. The pattern of RNA accumulation in normal spores was in two distinct phases (0 to 60 min and 90 to 180 min). The second phase was absent in outgrowing carrier spores. The burst of phage in carrier spores occurred at 160 to 180 min.Among prokaryotic developmental phenomena, the process of spore germination and outgrowth is particularly interesting to study since it is naturally synchronous and characterized by sequential changes in cell structure and gene expression (7). To study the control of gene expression during outgrowth in a simplified system, we have taken advantage of the finding that infection of sporulating cells of Bacillus subtilis by the virulent bacteriophage oe results not only in lack of phage reproduction but also in trapping of the phage genome within the developing spore (23). The resultant carrier spores can produce phage only during outgrowth. An analogous system has been described for Bacillus cereus (5).Control at the level of ribonucleic acid (RNA) synthesis during outgrowth is suggested by the finding of Armstrong et al. (1, 2) that transcription of the B. subtilis chromosome is ordered in time. They observed the synthesis of 16S and 23S ribosomal RNA before RNA of heterogeneous size (taken to be messenger RNA) began to be synthesized. In addition, others have shown that RNA synthesis is required for successful outgrowth (11), that different RNA species are found in outgrowing spores than in either vegetative or sporulating cells (8), that the appearance of certain bacterial proteins is ordered (9,24,28), and that deoxyribonucleic acid (DNA) replication is delayed during outgrowth (12,20,25,29). As a result, we have placed particular emphasis on comparing nucleic acid synthesis in germinating and outgrowing normal and carrier spores in the hope of finding when the carried phage genome begins to be expressed.Since Oe-induces little or no detectable synthesis of phage-specific proteins or DNA in infected sporulating ...
The tonA gene codes for an outer membrane protein, a receptor of phage T5, the TonA protein. Strains harboring pLG513, a multicopy plasmid in which the tonA gene has been cloned, overproduced TonA protein, which appeared in sodium dodecyl sulfate-polyacrylamide gel electrophoresis of cell envelope proteins as a 78,000-molecular-weight protein. Identical results have been observed by Plastow et al. (FEBS Lett. 131:262-264, 1981) with plasmid pLC19-19, in which the tonA gene has also been cloned. The activity of the TonA protein, measured by its capacity to inactivate phage T5, increased by five- to sixfold in purified envelopes of cells harboring pLG513 compared with cells lacking the plasmid. Solubilization of the cytoplasmic membrane by Triton-Mg2+ treatment did not increase this activity. However, partial solubilization of outer membrane proteins by Triton-EDTA unmasked further T5 receptor activity, resulting in a final increase of around 50-fold, a value more consistent with the expected gene dosage effect. Treatment of whole cells by trypsin in conditions in which trypsin is allowed to enter the outer membrane revealed that part of the overproduced T5 receptors were embedded in the outer membrane and masked by a trypsin-sensitive protein. In addition, no T5 receptor activity was detected in either the periplasmic space or the cytoplasm. These results suggest that all of the overproduced TonA molecules were synthesized in an active form and integrated in the outer membrane, but only a small fraction could be reached or recognized by phage T5 in vivo.
The thiomethylation of Bacillus subtilis tyrosine transfer ribonucleic acid (tRNATyr) (i6A) has been shown to occur during the slowing-down of growth. The extent of this modification in stationary-phase cells grown in defined medium has been determined in parallel with the sporulation frequency. We observed that the presence of phosphate repressed sporulation and also inhibited the thiomethylation of tRNATyr (i6A) of B. subtilis W168. These effects were partially eliminated by decreasing the glucose concentration until it was growth limiting. In the case of strain W23S, in which sporulation is insensitive to glucose repression, sporulation and tRNATyr thiomethylation were not inhibited by nonlimiting concentrations of phosphate. These results suggest that both sporulation and tRNATyr hyper-modification share some common regulatory process.
The CDC25 gene from S. cerevisiae encodes an activator of Ras proteins. The C-terminal part of a structurally-related protein encoded by the SDC25 gene is characterised by a Ras-guanine nucleotide exchange activity in vitro whereas the C-terminal part of CDC25 gives no detectable exchange activity. A chimera between the 3' regions of these two genes was constructed by homeologous recombination. This chimeric gene suppresses cdc25 mutations. When expressed in E. coli, the chimeric product is detectable by antibodies directed against the carboxy-terminal CDC25 peptide and has an exchange-factor activity on the Ras2 protein. Therefore, the carboxy-terminal parts of both the CDC25 and the SDC25 gene products are structurally and functionally similar. The CDC25 part of the chimeric protein contains an intrinsic guanine exchange factor which does not require an additional cofactor.
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