Protein Difference Between Competent and Noncompetent Cultures of a Group H Streptococcus

Acidified phenol extracts prepared from competent cultures of a group H Streptococcus strain Wicky made competent with competence factor derived from cultures of another group H Streptococcus, strain Challis, showed a difference in polyacrylamide-gel protein patterns when compared to extracts prepared from noncompetent cultures of strain Wicky. The prominent single protein band difference did not appear when Wicky cells were simultaneously treated with competence factor and chloramphenicol, an inhibitor of the development of competence. Chloramphenicol had no effect on transformation nor the appearance of the "new" protein band when added to fully competent cells. This new protein, which is associated with the appearance of competence, seems to be synthesized as a result of induction by competence factor; its exact role, however, is as yet unknown.     

Development of Competence in Thymine-starved Bacillus subtilis with Chromosomes Arrested at the Terminus

Tryptophan- and thymine-requiring cells of Bacillus subtilis, emerging from an amino acid starvation treatment which causes arrest of the chromosomes at the terminus, were not transformable. During subsequent incubation in a thymineless medium supplemented with amino acids, the cultures developed competence while retaining chromosome arrest. The competent subpopulation apparently shares the synchronous chromosome arrest of the bulk population. This was shown by different methods. The principal method was marker frequency analysis of the deoxyribonucleic acid extracted from a population enriched for competent cells by a column-chromatographic method. It is concluded that development of the competent state can occur in nondividing cells, and that the presence of a replication fork actively engaged in synthesis of deoxyribonucleic acid is not required for the development of this state.     

Intercellular Effects on Development of Competence in Bacillus subtilis

The intercellular transfer of competence during growth under the conditions specified by the transformation procedure of Spizizen was investigated with Bacillus subtilis 168. The rate of competence development as assayed uniformly in medium B was not affected by variations in the cell concentration, although the first appearance of transformants occurred earlier with high cell densities in medium A, approximately in proportion to the onset of the stationary phase in the culture. Growth in the presence of Pronase enhanced the frequency of transformation, but did not detectably alter the kinetics of competence development. The rate of competence increase in physiologically noncompetent cultures was not changed by mixing with competent cultures either in medium A or in medium B; however, an early appearance of transformants was noted in mixed cultures in which the proportion of competent to noncompetent cells prevented exponential growth of the noncompetent strain. These experiments indicate that the normal development of competence in B. subtilis is not mediated by a soluble or loosely bound protein factor capable of transmitting competence directly via cell contact. The onset of competence is thus a function of internal physiological changes which are induced by the overall metabolic state of the culture.     

Modulation of competence for genetic transformation in Streptococcus pneumoniae

The spontaneous development of competence by cultures of Streptococcus pneumoniae in casein hydrolysate medium was strongly dependent on the initial pH of the culture medium. Cells growing in cultures beginning with a wide range of initial pH values (6.8 to 8.0) all developed competence, as measured by [3H]DNA uptake, [3H]DNA degradation and genetic transformation; but the initial pH of the medium affected both the timing of the occurrence of competence and the number of times the culture became competent. In cultures grown in media of lower initial pH, competence occurred only once, at high population densities, while in more alkaline media a succession of competence cycles occurred, beginning at lower cell densities. The critical population density required for the initiation of competence varied tenfold over the pH range studied. Successive competence cycles in an alkaline medium were not equivalent: while the percentage of competent cells in the first competence cycle was high (approximately 80%), that in the second competence cycle was lower (approximately 12%). Correspondingly, competence-specific proteins were less prominent in the labelled-protein pattern of the second competence cycle than in that of the first. These features of the physiology of competence control make it possible to adjust the expression of competence to suit various experimental requirements.     

Competence related proteins in the supernatant of competent cells of Bacillus subtilis

Summary We report that centrifugation at relatively high g-forces reduces the ability of competent cells of Bacillus subtilis to bind and take up DNA, and to be transformed. The centrifugation supernatant from competent cells restores this reduction of competence; the supernatant from non-competent cells is inactive. Phosphocellulose chromatography of centrifugation supernatants from radioactive competent cultures gave rise to six sharp peaks, together, these were shown by subsequent SDS polyacrylamide gel electrophoresis to contain over 60 different polypeptide bands. Peak II, which showed competence restoring activity, produced three polypeptides. When these bands were further examined, one of these exhibited DNA binding activity and the other two each contained a different endonuclease. Competence restoring activity was not recovered from the SDS polyacrylamide gel of peak II. The three peaks from non-competent cultures produced altogether five faint bands in gel electrophoresis. None of these bands were similar to those found in peak II.This work was performed in partial fulfillment of the requirements of Georgetown University for the degree of Doctor of Philosophy     

Cloning and Molecular Characterization of a SERK Gene Transcriptionally Induced During Somatic Embryogenesis in Ananas comosus cv. Shenwan

A somatic embryogenesis receptor-like kinase (SERK) gene, designated as AcSERK1, was isolated from pineapple (Ananas comosus cv. Shenwan). AcSERK1 shared all the characteristic domains of the SERK family, including five leucine-rich repeats, one proline-rich region motif, transmembrane domain, and kinase domains. Somatic embryogenic cultures of pineapple were established following transfer of callus cultures to Murashige and Skoog (1962) medium containing 2,4-dichlorophenoxyacetic acid. The role of AcSERK1 during establishment of somatic embryogenesis in culture was investigated. The AcSERK1 was highly expressed during embryogenic competence acquisition and global embryo formation in culture. These findings were obtained along with morphological changes in callus cultures exhibiting embryogenic potential. Overall, levels of expression of AcSERK1 were lower in nonembryogenic tissues and organs than in embryogenic callus. In situ hybridization analysis revealed that AcSERK1 expression was detected in embryogenic tissues, including single competent cells, meristematic centers wherein embryogenic structures are formed, and global embryos. These results suggested that AcSERK1 expression was associated with induction of somatic embryogenesis and that it could be used as a potential marker gene to monitor the transition of pineapple callus tissues into competent and embryogenic cells and tissues.     

Model for the mechanism controlling the expression of competent state in Pneumococcus cultures

Tomasz, Alexander (The Rockefeller University, New York, N.Y.). Model for the mechanism controlling the expression of competent state in pneumococcus cultures. J. Bacteriol. 91:1050-1061. 1966.-The phenotypic expression of competence allowing the cells to absorb genetically active deoxyribonucleic acid molecules from their environment was examined in pneumococcal cultures growing under a variety of environmental conditions. The most important single parameter affecting the time course of this expression process was found to be the cell concentration. Constant high levels of competence could be maintained in cultures growing in a continuous-dilution device. The expression of competence seems to occur through a specific induction process "catalyzed" by a macromolecular cell product-the activator substance. Under most growth conditions, the availability of endogenous activator seems to limit the expression of competence. An "autocatalytic" production of activator ensues during the activation of cells to the competent state. Evidence is presented for physiological influences affecting the cell's capacity to react with the activator. A physiological model is proposed for the control of the competent state in pneumococcus.     

Heat sensitivity of Azotobacter vinelandii genetic transformation

Heating competent Azotobacter vinelandii at 37 or 42 degrees C resulted in a total loss of competence with no loss of viability. The transformation process was relatively insensitive to heating at either temperature once DNase-resistant DNA binding was nearly complete. Although competent and 42 degrees C-treated cells bound equivalent amounts of [32P]DNA in a DNase-resistant state, no donor DNA marker (nif) or radioactivity was detected in the envelope-free cell lysate of heated cells, suggesting that DNA transport across the cell envelope was a heat-sensitive event. Competence was reacquired in a 42 degrees C-treated culture after 2 h of incubation at 30 degrees C by a process which required RNA and protein syntheses. The release of a surface glycoprotein, required for competence, from cells treated at 42 degrees C occurred in an insufficient amount to account for the total loss of competence. Recovery of competence in 42 degrees C-treated cells and further transformation of competent cells were prevented by the exposure of cells to saturating amounts of transforming DNA. Further DNase-resistant DNA binding, however, still occurred, suggesting that there were two types of receptors for DNase-resistant DNA binding to competent A. vinelandii. DNase-resistant DNA binding was dependent on magnesium ions, and at least one receptor type did not discriminate against heterologous DNA.     

DNA replication during development of competence in Bacillus subtilis

Summary A new technique for studying DNA synthesis in competent cells of Bacillus subtilis has been developed.During competence development, the transformable cells are probably synthetizing DNA with a duplication time of approximately 90 min at 30° C; only when the maximum of competence is reached, does synthesis stop.     

Spontaneous Transformation and Its Use for Genetic Mapping in Bacillus subtilis

Using a simple semi-synthetic competence and sporulation medium (CSM), we found evidence that Bacillus subtilis cells transformed in the competence phase can sporulate, indicating that genetic information acquired during the competence phase is inherited by the next generation after germination of the transformed spores. Moreover, the results from mixed cell culture experiments suggest that spontaneous genetic transformation can occur between competent cells and DNA released from lysed cells in the natural environment. We also found evidence that the spontaneous transformation system can be used for genetic mapping in B. subtilis.     

Formation of competent Bacillus subtilis cells.

The process of competent cell formation for transformation has been studied with early-stationary-phase (T1) cells of Bacillus subtilis which had been grown in an enriched Spizizen minimal medium and transferred to a second synthetic medium. Rifampin, chloramphenicol, and tunicamycin were strong inhibitors of competent cell formation, as well as vegetative growth. After formation, competent cells were no longer sensitive to the above agents. Methicillin and an inhibitor of chromosomal replication, hydroxyphenylazouracil, did not inhibit the development of competence. A D-alanine-requiring mutant strain developed competence even in the absence of D-alanine in the second medium. A T1-stage culture showed the activity of extracellular serine protease which is necessary for sporulation. Competent cell formation was completely blocked by 0.7 M ethanol, which is a specific inhibitor of early events during sporulation, including forespore septum formation. Competent cells were formed even in media which supported sporulation. The development of competence was also studied with spo0 mutants at 10 different loci. Most spo0 mutations repressed the development of competence except for spo0C, spo0G, and spo0J. These results suggest that competent cells are formed from early sporulating cells with the synthesis of cell wall materials and by factors whose genes are activated by the supply of nutrients. It is suggested that common steps are involved both in forespore septation and in competent cell formation.     

Competence without a competence pheromone in a natural isolate of Streptococcus infantis

Many streptococcal species belonging to the mitis and anginosus phylogenetic groups are known to be naturally competent for genetic transformation. Induction of the competent state in these bacteria is regulated by a quorum-sensing mechanism consisting of a secreted peptide pheromone encoded by comC and a two-component regulatory system encoded by comDE. Here we report that a natural isolate of a mitis group streptococcus (Atu-4) is competent for genetic transformation even though it has lost the gene encoding the competence pheromone. In contrast to other strains, induction of competence in Atu-4 is not regulated by cell density, since highly diluted cultures of this strain are still competent. Interestingly, competence in the Atu-4 strain is lost if the gene encoding the response regulator ComE is disrupted, demonstrating that this component of the quorum-sensing apparatus is still needed for competence development. These results indicate that mutations in ComD or ComE have resulted in a gain-of-function phenotype that allows competence without a competence pheromone. A highly similar strain lacking comC was isolated independently from another individual, suggesting that strains with this phenotype are able to survive in nature in competition with wild-type strains.     

Calcium regulation of growth and differentiation in Streptococcus pneumoniae.

Streptococcus pneumoniae requires 0.15 mM-Ca2+ in the medium for optimal growth. Increasing the Ca2+ concentration to 1 mM triggers either a differentiative state, competence for genetic transformation during exponential growth, or partial lysis as soon as the cultures enter stationary phase. Genetic and physiological data both suggest that these responses are under the control of activator(s), excreted in the presence of high Ca2+ concentrations. 45Ca2+ transport is also stimulated by the activator(s). The amiloride derivative 2',4'-dimethylbenzamil (DMB) inhibits 45Ca2+ transport and prevents lysis and competence development. This provides evidence in favour of the involvement of Ca2+ transport in competence and culture lysis. On the other hand, addition of DNA to a competent culture prevents lysis of wild-type bacteria while a mutant, defective for DNA uptake, is not protected from lysis by exogenous DNA. An hypothesis is proposed for competence induction as a global metabolic response to Ca2+, under the control of competence factor.     

Review: Seaweed tissue culture as applied to biotechnology: Problems,achievements and prospects

Advances have been made in cell and tissue culture of seaweeds to define a unique branch of in vitro techniques; however, they are lagging far behind those of land plants and have limited applications. Explants can be cultivated axenically in enriched or artificial seawater culture media, and regeneration and even callus formation are achieved. In this state of the art technique, seaweed tissue culture may be already useful for certain biotechnological applications, such as clonal propagation of seed material for mariculture. Nevertheless, the absolute control of growth and development as it is exerted in higher plant tissue culture is lacking, and it is required for more complex biotechnological applications in seaweeds. Definitively, we need appropriate cells (competent cells) to induce growth with the most effective chemical regulators in culture medium adjusted towards the addition of carbon sources. Still, free cells and protoplast isolation and regeneration in marine seaweeds constitute the most developed topic in seaweed tissue culture. The regulation of growth and development of seaweed free cell and protoplast cultures may sustain a purposeful use of techniques in the era of genomic applications.     

Effect of pH on competence development and deoxyribonucleic acid uptake in Streptococcus sanguis (Wicky).

Streptococcus sanguis (Wicky) cells, strain WE4, developed little or no competence and failed to autolyze in permissive conditions when treated with competence factor (CF) below PH 7.0. This lack of activity was directly correlated with the inability of the cells to bind or take up CF at pH values of 5.5, 6.0, and 6.5. On the other hand, competent cells bound deoxyribonucleic acid molecules maximally below pH 7.0 and transformed maximally at pH 6.5. Deoxyribonucleic acid was optimally bound to cells in a deoxyribonuclease-resistant form at pH values between 7.0 and 8.5. Concomitant with this binding, undefined acid-soluble DNA fragments appeared in the culture menstrua. CF binding and uptake by cells was not only influenced by low pH but also by low temperature. At 0 C, WE4 cells bound only 4% of the input CF and took up less than 1% into a trypsin-insensitive state compared to cells treated at 37 C. Cells treated with CF at 0 C did not autolyze when transferred to permissive conditions. The results presented in this report extend earlier findings that showed that competence development and autolysis are related to the uptake of CF.     

Factors affecting transformation of Bacillus licheniformis

Thorne, Curtis B. (Fort Detrick, Frederick, Md.), and Harold B. Stull. Factors affecting transformation of Bacillus licheniformis. J. Bacteriol. 91:1012-1020. 1966.-Transformation systems involving two types of transformable mutants of Bacillus licheniformis 9945A were compared. Each system required its specific growth medium, but a single transformation medium could be used for both. Cells from a culture of optimal age were not competent, at least to any great extent, but they developed competence during incubation in a transformation medium. With each system, 3 to 5% of the recipient cells were transformed upon exposure to wild-type deoxyribonucleic acid (DNA) for 2 to 3 hr. When competent cells were exposed to DNA for 30 min, 1 to 2% of them were transformed. The data are interpreted to mean that cells were heterogeneous with respect to development of competence, and when properly grown cells were incubated in transformation medium some of them gained competence, whereas others lost it. If DNA was present during the entire period, the cells were transformed as they became competent and the transformants accumulated. However, during any short period of exposure to DNA, only those cells that were competent at the time were potential transformants. The high frequencies of transformation obtained in these studies made it feasible to prepare marked strains by transforming markers into recipient cells. These experiments demonstrated that the characteristics of the two transformation systems could not be attributed to specific nutritional markers. Presumably, each of the two series of highly transformable auxotrophic mutants also carried at least one other mutation that resulted in development of competence under the specific conditions.     

Transformation and transduction of a large deletion mutation in Bacillus subtilis

Summary Large arsenate sensitive deletion mutations of B. subtilis 168 are transformed to wild type at least 100 times less efficiently than they are transduced by PBS1 phage. The lower transformation efficiency is apparently due to the degradation of the donor DNA by competent cells to fragments ineffective for repair of long deletions. The efficiency of transduction of deletion mutations is also reduced when competent cells, rather than logarithmically growing cells are used as recipients. An endonuclease activity specifically associated with the physiological state of competence is proposed to explain these observation.     

Competence for Deoxyribonucleic Acid Uptake and Deoxyribonuclease Action External to Cells in the Genetic Transformation of Diplococcus pneumoniae

A mutant of Diplococcus pneumoniae that apparently does not require activator can become competent for uptake of deoxyribonucleic acid (DNA) when grown in dilute cultures or in the presence of trypsin. Development of competence in both mutant and wild strains is temperature dependent, being 10-fold greater at 30 C than at 37 C. Induction of competence on a shift from 37 to 30 C requires protein synthesis and the presence of Mg(2+) and Ca(2+); uptake of DNA does not require protein synthesis. Competence decays exponentially at higher temperatures. As well as taking up DNA, competent cells release oligonucleotide fragments of donor DNA in the medium external to the cells. Normal strains release fragments comparable in amount to the DNA taken up; but, in a mutant selected for inability to degrade DNA in agar, the amount of fragments formed external to the cells is only 40% of DNA uptake. Requirements for external deoxyribonuclease action are identical to those for DNA uptake: prior development of competence and the presence during treatment with DNA of Mg(2+) ions and a source of energy.