Isolation and characterization of the nucleoid of non-complementing diploids from protoplast fusion in Bacillus subtilis

GENETIC EXCHANGE BETWEEN BACILLUS SUBTILIS AND BACILLUS LICHENIFORMIS: VARIABLE HYBRID STABILITY AND THE NATURE OF BACTERIAL SPECIES

Experiments employing both broth and soil cultures demonstrated the capacity for bidirectional genetic exchange between the eubacterial species Bacillus subtilis and Bacillus licheniformis. The process was studied using standard laboratory strains and wild isolates of these species. The genetic exchange in soil occurs spontaneously. The interspecific recombination involved markers for antibiotic resistance and for the use of specific carbon sources (API characters). Hybrids frequently had unstable phenotypes, i.e., lacked a consistent expression of foreign genes over repeated transfer and growth. This instability often involved a "correction" back toward the phenotype of one or the other of the parental species for many differentiating characters; the final phenotype was always that of the more probable or actually known recipient species. This "correction" process is reminiscent of phenomena associated with the instability of artificial fusion protoplasts or noncomplementing diploids of B. subtilis, as well as the merodiploids formed by intergeneric crosses with enteric bacteria. The hybrids observed here must also be diploid, in some manner, because they sequentially express traits of both parental species at rates well above the frequency of mutation. Among the unstable changes in hybrids of the wild strains there was a 3:1 bias in favor of "correction." The dynamics of the hybridization process in soil are described. It appears that the hybrids are formed most rapidly following outgrowth from spores and during the early growth of parental vegetative cell populations. Later on, the hybrids are much less frequent in the soil cultures, suggesting that they are competitively inferior to the parental species. It is argued that the capacity for recombination found between B. subtilis and B. licheniformis could locally erase their distinctness, even though they possess only about 15% DNA sequence homology. Yet they remain distinct in the wild. The methods and results of these experiments prepare the way for detailed studies of the nature of species and species boundaries throughout the genus Bacillus.

Reciprocal and nonreciprocal recombination in diploid clones from Bacillus subtilis protoplast fusion: Association with the replication origin and terminus

The primary heterodiploid bacteria regenerated after Bacillus subtilis fusion, although generally noncomplementing diploids, behave in pedigree analysis as multipotential systems. Individual diploid colonies yielding complete reciprocal recombinant (RR) progeny-often accompanied by one or both parents-constitute 10-30% of the total recombinant-forming units. The RR (reciprocal for 8-11 genes) usually occur in equivalent numbers both among and within individual colonies. Novel for bacteria, they demonstrate that entire parental genomes brought together within a diploid protoplast are retained as two independent replicons able to undergo classical recombination characteristic of eukaryotic gametogenesis. Parental or recombinant genomes are also subject to multiple rounds of recombination without obligate segregation and often not reciprocal. Diploid recombinant clones, sharing streptomycin resistance but reciprocal for auxotrophic markers, have displayed a partial ability to make a facultative shift in chromosome expression. They have also produced two types of prototrophs: a stable one (presumably haploid and recombinant) and an unstable one, (diploid and temporarily complementing at low frequency). It follows that chromosome extinction may affect both parental and recombinant chromosomes and does not interfere with recombination. Analysis of the number and chromosomal distribution of crossovers in all recombinants and those from single diploid clones shows increased frequency of exchange in the regions of the replication origin and terminus, possibly a result of the association of these sites with the cell wall or membrane.

The MG1363 and IL1403 laboratory strains of Lactococcus lactis and several dairy strains are diploid

Bacteria are normally haploid, maintaining one copy of their genome in one circular chromosome. We have examined the cell cycle of laboratory strains of Lactococcus lactis, and, to our surprise, we found that some of these strains were born with two complete nonreplicating chromosomes. We determined the cellular content of DNA by flow cytometry and by radioactive labeling of the DNA. These strains thus fulfill the criterion of being diploid. Several dairy strains were also found to be diploid while a nondairy strain and several other dairy strains were haploid in slow-growing culture. The diploid and haploid strains differed in their sensitivity toward UV light, in their cell size, and in their D period, the period between termination of DNA replication and cell division.

Protoplast fusion: A tool for intergeneric gene transfer in bacteria

Protoplasts can be isolated from bacterial cells by digestion of the cell wall with the help of lysozyme in presence of osmotic stabilizers. Fusion of protoplasts can be induced by chemical fusogens like polyethylene glycol. The electrofusion technique has been reported in bacteria in which the fusion frequency is much higher than that obtained by PEG induced protoplast fusion. This technology allows recombination to take place not only between related species but also between unrelated genera and is of great potential in the breeding and improvement of industrial strains. This review includes the information and developments on the protoplast fusion in bacteria with special reference to genetic recombination by protoplast fusion between phylogenetically unrelated bacteria.

Expression of positional information during cell differentiation of Caulobacter

The asymmetric targeting of proteins to the Caulobacter predivisional cell poles yields dissimilar progeny. We show that the products of transcriptional reporter gene fusions to a flagellin gene and to the flagellar hook operon are segregated to the progeny swarmer cell. This segregation does not depend on sequences within the mRNA, but on the upstream regulatory region. The subset of developmentally regulated flagellar genes that exhibit mRNA segregation has the same upstream cis-acting elements: an activator-binding site known as the ftr sequence and an IHF-binding site. We propose that these genes are preferentially transcribed from the chromosome in the incipient swarmer cell pole of the predivisional cell.

Organization of the bacterial chromosome

Recent progress in studies on the bacterial chromosome is summarized. Although the greatest amount of information comes from studies on Escherichia coli, reports on studies of many other bacteria are also included. A compilation of the sizes of chromosomal DNAs as determined by pulsed-field electrophoresis is given, as well as a discussion of factors that affect gene dosage, including redundancy of chromosomes on the one hand and inactivation of chromosomes on the other hand. The distinction between a large plasmid and a second chromosome is discussed. Recent information on repeated sequences and chromosomal rearrangements is presented. The growing understanding of limitations on the rearrangements that can be tolerated by bacteria and those that cannot is summarized, and the sensitive region flanking the terminator loci is described. Sources and types of genetic variation in bacteria are listed, from simple single nucleotide mutations to intragenic and intergenic recombinations. A model depicting the dynamics of the evolution and genetic activity of the bacterial chromosome is described which entails acquisition by recombination of clonal segments within the chromosome. The model is consistent with the existence of only a few genetic types of E. coli worldwide. Finally, there is a summary of recent reports on lateral genetic exchange across great taxonomic distances, yet another source of genetic variation and innovation.

Complementation and genetic inactivation: two alternative mechanisms leading to prototrophy in diploid bacterial clones

Evidence for diploidy at loci located all around the Bacillus subtilis chromosome previously led us to refer to the prototrophic bacterial clones produced by fusion of polyauxotrophic protoplasts as complementing diploid clones (Lévi-Meyrueis et al. 1980; Sanchez-Rivas 1982). In this paper, evidence is presented that gene inactivation may occur in such clones, as judged from the unequal expression of three unselected markers and their low transforming activity in cell lysates, an established property of inactivated genes (Bohin et al. 1982). The insensitivity to protease treatment of the lysates and also the low transforming activity observed with purified DNA may indicate that chromosome inactivation does not necessarily result from the mere attachment of proteins to DNA. Cotransfer by transformation of similarly expressed genes, initially located on separate chromosomes, suggests that genetic recombination has taken place, resulting in the reassortment of active and inactive genes on separate chromosomes. Several genetic structures compatible with the observations are presented which illustrate that prototrophy may result from such reassortment as well as from functional complementation.

Absence of functional RNA encoded by a silent chromosome in non-complementing diploids obtained from protoplast fusion in Bacillus subtilis

The molecular basis for lack of phenotypic expression of one chromosome in Bacillus subtilis non-complementing diploid clones (Ncd cells) was investigated. Correlations between chromosomal inactivation and absence of functional transcripts were determined with wild-type prophage phi 105 or a thermoinducible mutant phi 105 cts23, on either the expressed or the silent chromosome. It appears that no significant amount of phage mRNA is detectable in Ncd cells carrying the prophage in the inactive chromosome. However, phi 105 mRNA represents 0.23% of total cellular mRNA in an Ncd strain with the prophage in the expressed chromosome and 0.28% in the parental lysogenic strain. The lack of an mRNA repressor of phi 105 prophage from the silent chromosome was confirmed by the absence of repressor activity in Ncd clones with a temperature sensitive mutant phi 105 located in the silent chromosome. After heat induction, no phage production was observed. As expected these clones do not exhibit phi 105 immunity when superinfected with the same phage. The combined data of the present and previous work suggest that control of phenotypic suppression of Ncd strains should, at the transcription level, involve a different DNA tertiary organisation in one of the two chromosomes.

Chromosome interactions and expression in fused Bacillus protoplasts

Heterodiploid bacteria can be regenerated from fused mixed protoplasts. In both B. megaterium and B. subtilis, early selective effects during regeneration may strongly affect the phenotype of the products. Among the products are diploid prototrophs, whose stability is still in doubt. It is not known whether the prototrophy results from complementation or from recombination during the selection. In the case of B. subtilis, regeneration in a permissive, uncrowded and non-selective environment leads to production of rather large yields of heterodiploids, either biparental or recombinant. These seem to be only partially stable, but while remaining diploid they give rise to a wide variety of genetic recombinants. In general rather few prototrophs are found when selection is applied to the bacterial diploids. The phenotypic properties of B. subtilis diploids reveal incomplete expression of the demonstrable gene inventory. Biparental diploids appear commonly to show the phenotype of only one of the contained parent types, as if one chromosome remains unexpressed. For diploid recombinants data are insufficient to reveal the status of the chromosomes. Non-expression is believed to be due to structural complexity of particular chromosomes, or their parts. Recombination occurring within bacterial heterodiploid clones appears to satisfy many of the expectations for genetic recombination in eukaryotes--including that of being in part at least classically reciprocal, with intraclonal reciprocals in equivalent numbers. While short map intervals show reduced recombination, large numbers of recombinations (one to two thirds) involve exchanges at or near the terminus and origin of bidirectional replication.(ABSTRACT TRUNCATED AT 250 WORDS)