Genetic recombination in DNA-induced transformation of Pneumococcus. IV. The pattern of transmission and phenotypic expression of high and low-efficiency donor sites in the amiA locus

Unbiased homeologous recombination during pneumococcal transformation allows for multiple chromosomal integration events

The spread of antimicrobial resistance and vaccine escape in the human pathogen Streptococcus pneumoniae can be largely attributed to competence-induced transformation. Here, we studied this process at the single-cell level. We show that within isogenic populations, all cells become naturally competent and bind exogenous DNA. We find that transformation is highly efficient and that the chromosomal location of the integration site or whether the transformed gene is encoded on the leading or lagging strand has limited influence on recombination efficiency. Indeed, we have observed multiple recombination events in single recipients in real-time. However, because of saturation and because a single-stranded donor DNA replaces the original allele, transformation efficiency has an upper threshold of approximately 50% of the population. The fixed mechanism of transformation results in a fail-safe strategy for the population as half of the population generally keeps an intact copy of the original genome.

Direct Visualization of Horizontal Gene Transfer by Transformation in Live Pneumococcal Cells Using Microfluidics

Natural genetic transformation is a programmed mechanism of horizontal gene transfer in bacteria. It requires the development of competence, a specialized physiological state during which proteins involved in DNA uptake and chromosomal integration are produced. In Streptococcus pneumoniae, competence is transient. It is controlled by a secreted peptide pheromone, the competence-stimulating peptide (CSP) that triggers the sequential transcription of two sets of genes termed early and late competence genes, respectively. Here, we used a microfluidic system with fluorescence microscopy to monitor pneumococcal competence development and transformation, in live cells at the single cell level. We present the conditions to grow this microaerophilic bacterium under continuous flow, with a similar doubling time as in batch liquid culture. We show that perfusion of CSP in the microfluidic chamber results in the same reduction of the growth rate of individual cells as observed in competent pneumococcal cultures. We also describe newly designed fluorescent reporters to distinguish the expression of competence genes with temporally distinct expression profiles. Finally, we exploit the microfluidic technology to inject both CSP and transforming DNA in the microfluidic channels and perform near real time-tracking of transformation in live cells. We show that this approach is well suited to investigating the onset of pneumococcal competence together with the appearance and the fate of transformants in individual cells.

Long- and short-patch gene conversions in Streptococcus pneumoniae transformation

In pneumococcal transformation some point mutations are integrated by an excision-repair pathway which switches the heteroduplex DNA into homoduplex. This transfer of information is a gene conversion. We have reviewed some of the properties of this system especially those relating to heteroduplex specificity and given evidence that this extends over several kilobases of DNA. We then describe a new process of conversion in pneumococcal transformation which occurs over a very short distance (5 to 27 base-pairs) and is triggered by a single site mutation resulting from the transversion 5'-ATTCAT...to 5'...ATTAAT... Only one of the two heteroduplexes 5'...A...3'/3'...G...5', is converted.

Excision and repair of mismatched base pairs in transformation of Streptococcus pneumoniae

The use of heteroduplex DNA molecules as donors in pneumococcal transformation makes it possible to follow the fate of each DNA strand. The integration efficiency of each strand depends strongly upon the single base changes it carries. The function (hex) which reduces drastically the transformation yield of markers referred to as low efficiency (LE) tends to remove either donor strand without respect ot which one is introduced. In the case of high efficiency (HE) markers the reduction in the transformation yield involves the elimination of only one donor strand. For a given locus it can be either one depending upon the mutation. The reduction in transformation yield can be less drastic for HE markers than for both strands of the LE markers. These data are discussed in terms of differences in the affinity for mismatched base pairs. We have studied the transfer of information from each donor DNA strand to the recipient genome, on the basis of differences in the rates of phenotypic expression of a given marker introduced on opposite strands. Results show that, as in the case of LE markers, the information from HE markers, when introduced on the strand recognized by the hex function, is transmitted to both strands of the recipient molecule. Correction of the recipient strand to homozygosis probably accounts for this information transfer. These results, together with earlier investigations, strongly suggest that the hex function is an excision-repair system acting on donor-recipient base pair mismatches.

Multiple interactions of a DNA-binding protein in vivo. III. Phage T4 gene-32 mutations differentially affect insertion-type recombination and membrane properties

We have investigated in in vivo roles of T4 gene-32 protein in recombination. We have studied the effects of gene-32 mutations under conditions that allow normal DNA replication and are permissive for progeny production. Under these conditions, certain gene-32 mutations specifically reduce insertion-type (short-interval) recombination but none affect crossover-type (long-interval) recombination (see Figure 5). Heterozygote frequencies in all gene-32 mutants are similar to or higher than in a gene-32+ background and are not correlated with recombination deficiencies. "Recombination-deficient" alleles are dominant or codominant over the "recombination-proficient" gene 32 mutation tsL171. This explains apparent discrepancies between a gene-32 map deduced from two-factor crosses and the map derived from three-factor crosses. We have also found that the "recombination proficient" mutation tsL171 and it homdoalleles suppress the characteristic plaque morphology of rII mutants. Under restrictive conditions, tsL171 is partially suppressed by rII mutations, which allow the use of host ligase in recombination. Our present and previous results are discussed in terms of current recombination models. We conclude that gene-32 protein functions in recombination by forming a complex with DNA, with recombination enzymes and with membrane components. Since gene-32 protein interacts with many components of this recombination complex, gene-32 mutations may differentially affect various recombination steps.

Mismatch correction in pneumococcal transformation: donor length and hex-dependent marker efficiency

A hypothesis that preferential rejection of donor markers by the hex system of pneumococcus is due to lethal double-strand breaks has been examined in terms of its implications for the extent of the excision required. Experiments reported here were directed at asking whether hex-dependent marker efficiency depends on the length of the donor deoxyribonucleic acid (DNA). In the absence of intracellular competition for hex function, there was no detectable effect of DNA size on hex-dependent marker efficiency as donor DNA was sheared from greater than 1 x 107 daltons to 3.6 x 105 daltons. The latter DNA was purified by two successive velocity fractionations to ensure that the activity seen was representative of DNA of that size. Quantitative examination of the system shows that, for the lethal event hypothesis to be true, the excision step has to remove an average of 7,000 to 10,000 nucleotides. This figure is so much greater than that seen in other excision processes that alternate hypotheses should be considered. The presently known properties of the hex system can be accounted for by a model invoking the migratory features of type I restriction enzymes.

Marker discrimination in deoxyribonucleic acid-mediated transformation of various Pneumococcus strains

The function responsible for discrimination among markers (point mutations) in Pneumococcus (hex) was traced back to the early strains used to demonstrate the chemical basis of transformation in the early 1940s. Those currently used laboratory strains failing to manifest this function arose from a single subline of the original strain. The function was also evident in other independently isolated strains including a number of different serological types. The hex function was not evident in transformation between heterologous pneumococcal strains probably as a result of the sensitivity of the function to saturation in the presence of deoxyribonucleic acid from closely related but nonisogenic strains.

Transforming ability of bacterial deoxyribonucleic acid in relation to the marker efficiencies in Diplococcus pneumoniae during thymidine starvation

Thymidine starvation induces a decrease in transforming activity of pneumococcus deoxyribonucleic acid. The integration of low- and high-efficiency markers seems to be equally affected.