Induction and Transmission of a Merodiploid Condition near the Terminal Area of the Chromosome of BACILLUS SUBTILIS

A small fraction (about 0.5%) of the transformants for a particular marker of B. subtilis (ilvA4; most probably a deletion) were found to be relatively unstable merodiploids. They possess a redundancy of the metB–ilvA chromosome segment. When their DNA is used as donor in transformation a merodiploid condition for the whole of this segment is created in all ilvA4⁺ transformants. For several of the duplicated loci both copies often are of recipient strain origin. Markers originally belonging to different copies of the diploidized region can be contransferred in PBS1-mediated transduction. The data are well in agreement with the hypothesis that the merodiploids carry a tandem duplication. An alternative hypothesis which does not call for integration of the exogenote within the recipient chromosome was also considered. Models are proposed for interpreting the segregation of the merodiploids, the transmission of the diploid state and its generation during transformation of the ilvA4 marker by wild-type DNA.     

Bacteriophage infection of minicells

Summary Off the transconjugants formed in theR. lupini conjugation 0.5 to 5% are merodiploids. When two differently pigmented parents are used in the crossing experiment the diploid transconjugants can be differentiated from the haploid recombinants by their additive pigmentation type. The segregation patterns of these diploid clones were analyzed. The results are in agreement with the theory that the exogenotic donor DNA can be integrated at different sites of the homologous recipient chromosomal region forming a tandem sequence. Consequently the segregants of these merodiploid clones are formed by endochromosomal recombination. This work was supported by the Deutsche Forschungsgemeinschaft and Stiftung Volkswagenwerk.     

Natural Genetic Transformation Generates a Population of Merodiploids in Streptococcus pneumoniae

Partial duplication of genetic material is prevalent in eukaryotes and provides potential for evolution of new traits. Prokaryotes, which are generally haploid in nature, can evolve new genes by partial chromosome duplication, known as merodiploidy. Little is known about merodiploid formation during genetic exchange processes, although merodiploids have been serendipitously observed in early studies of bacterial transformation. Natural bacterial transformation involves internalization of exogenous donor DNA and its subsequent integration into the recipient genome by homology. It contributes to the remarkable plasticity of the human pathogen Streptococcus pneumoniae through intra and interspecies genetic exchange. We report that lethal cassette transformation produced merodiploids possessing both intact and cassette-inactivated copies of the essential target gene, bordered by repeats (R) corresponding to incomplete copies of IS861. We show that merodiploidy is transiently stimulated by transformation, and only requires uptake of a ∼3-kb DNA fragment partly repeated in the chromosome. We propose and validate a model for merodiploid formation, providing evidence that tandem-duplication (TD) formation involves unequal crossing-over resulting from alternative pairing and interchromatid integration of R. This unequal crossing-over produces a chromosome dimer, resolution of which generates a chromosome with the TD and an abortive chromosome lacking the duplicated region. We document occurrence of TDs ranging from ∼100 to ∼900 kb in size at various chromosomal locations, including by self-transformation (transformation with recipient chromosomal DNA). We show that self-transformation produces a population containing many different merodiploid cells. Merodiploidy provides opportunities for evolution of new genetic traits via alteration of duplicated genes, unrestricted by functional selective pressure. Transient stimulation of a varied population of merodiploids by transformation, which can be triggered by stresses such as antibiotic treatment in S. pneumoniae, reinforces the plasticity potential of this bacterium and transformable species generally.     

Studies on the size of the diploid region inBacillus subtilis merozygotes from strains carrying thetrpE26 mutation

Summary Simultaneous selection of transformants fortrpE26 and a second unlinked marker ofB. subtilis in many cases yields double heterogenotic clones. Several chromosome areas analyzed in this way found to be involved in the diploid condition. Diploids for areas on the left hand side oftrpE26 on the map (and as near as thearo B locus) are in general unstable while stable merodiploids can be obtained for areas on the right hand side of this marker (as far as theilvA locus). Merozygotes for regions other than the aromatic segment are also formed by transformation of already diploid (stable and unstable) clones. Stable diploids give rise to new heterogenotes only for markers on the right hand side oftrpE26. Through reversion of untransformed markers in unstable and stable diploids it was found that these clones are homodiploid for loci situated at a long distance from (or between) the areas which were involved in the transformation. This indicates that the diploid state covers a continuous segment of the chromosome, the length of which can be determined. The segregation pattern of unstable multiple merodiploids suggests that exchange of genetic material must take place between the two homologous regions. The data presented are in agreement with the hypothesis that the merodiploids possess a very long duplication on their chromosome. In the case of the stable clones this duplication is shorter.     

Merodiploidy in ESCHERICHIA COLI-SALMONELLA TYPHIMURIUM Crosses: The Role of Unequal Recombination between Ribosomal RNA Genes

Previous workers have shown that intergeneric crosses between Salmonella typhimurium and Escherichia coli produce a high proportion of merodiploid recombinants among the viable progeny. We have examined the unequal cross-over event that was responsible for a number of intergeneric merodiploids. The merodiploids that we studied were all heterozygous for the metB-argH interval and were the products of intergeneric conjugal crosses. We found that when the S. typhimurium donor had its transfer origin closely linked to metB and argH, all recombinants examined were merodiploid, and they generally arose as F-prime factors. Many of these F-prime factors had been created by recombination between flanking rrn genes in the donor. When the S. typhimurium Hfr transfer origin was more distant from the selected markers, quite different results were obtained. Depending on the donor, 19-47% of the recombinants that acquired the donor argH+ or metB+ genes were merodiploid for these loci, but none of the recombinants were F-prime. A majority of the merodiploids had a novel (nonparental) rrn gene, indicating that unequal recombination between nonidentical rrn genes was a prevalent mechanism for establishing the merodiploidy. Both tandem and nontandem duplications were found. Some of the merodiploids duplicated E. coli genes in addition to acquiring S. typhimurium genes. Some merodiploids contained the oriC region from each parent. Of a total of 118 intergeneric merodiploids characterized from all donors, 48 different genotypes were observed, and 38 of the 48 had one or more nonparental rrn operons.     

Genetical analysis of merodiploidy in Rhizobium lupini

Summary The cytology of transfer diploidy produced in R. lupini by conjugation has been investigated. Since merodiploid donor strains transfer the diploid region as one transfer unit it is concluded that in merodiploid strains the two homologous regions are inserted in tandem sequence.It has been discussed that the segregation patterns of diploid clones indicate that in this conjugation system the exogenote insertion always occurs in the zygote after transfer and before recombination.     

Identification of Recombinant Chromosomes and F-Merogenotes in Merodiploids of Escherichia coli

Segregants from merodiploids heterozygous at two or more sites in the lac region were selected on the basis of containing a recombinant F-merogenote. Such recombinants frequently contained a recombinant chromosome as well. When the merodiploid was heterozygous at two sites, the frequency at which reciprocally recombinant chromosomes were present in the selected population was lower when the two marked sites were in the same gene and close together than when the sites were more widely separated. When the merodiploid was heterozygous at four sites and selection was made for an intragenic recombinational event, the recombinant chromosome was the reciprocal type about half the time and about half the time was not. Among the latter genotypes, most were nonrecombinant for the intragenic pair of markers. The data are consistent with a model in which recombination leads to the formation of two recombinant products, each containing a region of hybrid deoxyribonucleic acid.     

Duplication of the bacteriophage lambda cohesive end site: genetic studies

A derivative of bacteriophage λ has been isolated that contains a duplication of the cohesive end site. To support this conclusion, the duplicated region has bean recovered by segregation from a lysogen of the duplication strain, and a derivative of the duplication strain was constructed that is heterozygous for the λ genes R and A, which bracket the cohesive end site. Duplication strains show no instability during lysogenization, suggesting that the virus particles each contain a single DNA molecule. During lytic growth, however, the strain is unstable and the duplication is frequently lost, even in the absence of all known recombination systems. Loss of the duplication is ascribed to cleavage of both cohesive end sites by the chromosome maturation system. Thus both cohesive end sites are functional, i.e. capable of being cleaved. No transfer of the duplicated region occurs in the absence of the known recombination systems. Thus, during λ chromosome maturation, cleavage of DNA molecules occurs but rejoining of cleaved molecules does not.     

Unequal crossing-over in Escherichia coli

Unequal crossing-over between sister chromosomes in the process of DNA replication in Escherichia coli leads to the formation of tandem duplications, thus enhancing the activity of certain genes. In conjugational matings between genetically marked E. coli strains, unequal crossing-over leads to the formation of heterozygous tandem duplications. Studying these duplications as model systems allowed the conclusion that unequal crossing-over between direct DNA repeats of sister chromosomes is the main pathway of the formation of selected recombinants in E. coli strains carrying duplications. This was inferred from the data on the segregation of homozygous diploid recombinants by heterozygous duplications. Unequal crossing-over between sister chromosomes occurs as adaptive exchange providing the survival of the greater part of bacterial cells on a selective medium. The known phenomenon of adaptive mutagenesis may also be a consequence of unequal exchanges at the level of DNA mononucleotide repeats.     

A requirement for phosphoenolpyruvate carboxylase in the cyanobacterium Synechococcus PCC 7942

The gene encoding phosphoenolpyruvate carboxylase (PEPCase) in the cyanobacterium Synechococcus PCC 7942 has been isolated and characterized. As a first step in determining the role of this enzyme in cyanobacterial carbon metabolism we have attempted to generate PEPCase deficient mutants by insertional inactivation of the PEPCase gene (ppc) and recombination into the wild-type genome. Transformants generated by these constructs appear to be merodiploids in which some copies of ppc remain intact and PEPCase activity is present. Successful insertional inactivation of regions of the genome on either side of ppc suggest that the merodiploid state is a result of a requirement for PEPCase activity by the cyanobacteria. Attempts to select for ppc mutants by nutritional complementation during segregation are also described.Abbreviations PEPCase phosphenolpyruvate carboxylase - ppc gene coding for PEPCase - amp ampicillin - spec spectinomycin     

Coliphage P1-mediated transduction of cloned DNA from Escherichia coli to Myxococcus xanthus: use for complementation and recombinational analyses.

We have found that coliphage P1 can be used to transduce cloned DNA from Escherichia coli to Myxococcus xanthus. Transduction occurred at a high efficiency, and no evidence for DNA restriction was observed. The analysis of the transductants showed that they fall into three general categories: (i) haploid cells which contain portions of the cloned DNA substituted for homologous chromosomal DNA; (ii) heterozygous merodiploids which contain the recombinant plasmid integrated into the chromosome at a region of homology; and (iii) homozygous merodiploids which contain two copies of a portion of the cloned DNA with the loss of the chromosomal copy of the genes. The merodiploids, once formed, are relatively stable. They were used to analyze two genes necessary for aggregation and thus fruiting body formation. P1 transduction also permits the reintroduction and substitution of mutated regions of cloned DNA into M. xanthus for the analysis of the role of the DNA in cellular physiology and development.     

Transduction of Merodiploidy: Induced Duplication of Recipient Genes

Escherichia coli PB160, which carries a tandem duplication with the gene order metB(+)argH(-)su(159) (+)thi(+): metB(+)argH(+)su(159) (-)thi(+), was used to study the mechanism of P1 transduction of genes in the duplicated region. Transduction of the su(159) (+) allele contained within the duplicated segment yields two kinds of su(159) (+) recombinants: 91% are haploid su(159) (+) and 9% are su(159) (+)/su(159) (-) merodiploids. The duplication in these merodiploid transductants includes the metB locus; however, both copies of the metB locus usually are derived from the recipient. Thus, the requirements for transduction of the "condition of merodiploidy" appear to be the cotransduction of the repeat point (the region where the duplication begins to repeat itself) and, of course, the selected marker (in this case su(159) (+)). A mechanism whereby two recipient chromosomes interact with the transduced "repeat point" region to regenerate the tandem duplication is implicated. It appears that a duplication much larger than the quantity of genetic material carried by a P1 phage can be produced in a transductant.     

CENP-B is not critical for meiotic chromosome segregation in male mice

Centromere protein B (CENP-B) is a constitutive protein that binds to a highly conserved 17 bp motif located at most mammalian centromeres. To determine whether disruption of this gene affects chromosome segregation in male germ cells, we evaluated the frequencies of disomic and diploid sperm in CENP-B heterozygous and homozygous null mice using the mouse epididymal sperm aneuploidy (m-ESA) assay, a multicolor FISH method with probes for chromosomes X, Y and 8. The specificity and sensitivity of the m-ESA assay was demonstrated using Robertsonian (2.8) translocation heterozygotes as positive controls for sperm aneuploidy. Our results show that the frequencies of disomic and diploid sperm did not differ significantly between CENP-B heterozygous and homozygous null mice (P≥0.5) or from 129/Swiss isogenic mice (P≥0.5) and B6C3F1 mice (P≥0.2). These findings indicate that CENP-B does not have an essential role during chromosome segregation in male meiosis.     

Genomic, regulatory and epigenetic mechanisms underlying duplicated gene evolution in the natural allotetraploid Oryza minuta

Background

Polyploid species contribute to Oryza diversity. However, the mechanisms underlying gene and genome evolution in Oryza polyploids remain largely unknown. The allotetraploid Oryza minuta, which is estimated to have formed less than one million years ago, along with its putative diploid progenitors (O. punctata and O. officinalis), are quite suitable for the study of polyploid genome evolution using a comparative genomics approach.

Results

Here, we performed a comparative study of a large genomic region surrounding the Shattering4 locus in O. minuta, as well as in O. punctata and O. officinalis. Duplicated genomes in O. minuta have maintained the diploid genome organization, except for several structural variations mediated by transposon movement. Tandem duplicated gene clusters are prevalent in the Sh4 region, and segmental duplication followed by random deletion is illustrated to explain the gene gain-and-loss process. Both copies of most duplicated genes still persist in O. minuta. Molecular evolution analysis suggested that these duplicated genes are equally evolved and mostly manipulated by purifying selection. However, cDNA-SSCP analysis revealed that the expression patterns were dramatically altered between duplicated genes: nine of 29 duplicated genes exhibited expression divergence in O. minuta. We further detected one gene silencing event that was attributed to gene structural variation, but most gene silencing could not be related to sequence changes. We identified one case in which DNA methylation differences within promoter regions that were associated with the insertion of one hAT element were probably responsible for gene silencing, suggesting a potential epigenetic gene silencing pathway triggered by TE movement.

Conclusions

Our study revealed both genetic and epigenetic mechanisms involved in duplicated gene silencing in the allotetraploid O. minuta.     

Assessment of gene copy number in the homosporous fernsCeratopteris thalictroides andC. richardii (Parkeriaceae) by restriction fragment length polymorphisms

Homosporous ferns are generally considered polyploid due to high chromosome numbers, but genetically diploid since the expression of isozymes is generally controlled by a single locus. Gene silencing over evolutionary time is one means by which this apparent contradiction can be explained. A prediction of this hypothesis is that silenced gene sequences still reside in the genomes of homosporous ferns. We examined the genomes ofCeratopteris richardii andC. thalictroides for sequences which are similar to expressed gene sequences. Genomic DNA blots hybridized withC. richardii cDNA clones showed that the majority of these clones detected multiple fragments, suggesting that most gene-like sequences are duplicated inCeratopteris. Hybridization signal intensity often varied between fragments of the same size between accessions, sometimes dramatically, which indicates that not all sequences are equivalent, and may represent the products of silenced genes. Observed reciprocal differences in intensity could be due to reciprocally silenced genes. In addition, an unusual segregation pattern for one locus followed by one probe may indicate homeologous chromosome pairing and segregation.     

Study of chromosome rearrangements associated with the trpE26 mutation of Bacillus subtilis

Chromosome rearrangements involved in the formation of merodiploid strains in the Bacillus subtilis 168-166 system were explained by postulating the existence of intrachromosomal homology regions. This working hypothesis was tested by analysing sequences and restriction patterns of the, as yet uncharacterized, junctions between chromosome segments undergoing rearrangements in parent, 168 trpC2 and 166 trpE26, as well as in derived merodiploid strains. Identification, at the Ia/Ib chromosome junction of both parent strains, of a 1.3 kb segment nearly identical to a segment of prophage SPbeta established the existence of one of the postulated homology sequences. Inspection of relevant junctions revealed that a set of different homology regions, derived from prophage SPbeta, plays a key role in the formation of so-called trpE30, trpE30+, as well as of new class I merodiploids. Analysis of junctions involved in the transfer of the trpE26 mutation, i.e. simultaneous translocation of chromosome segment C and rotation of the terminal relative to the origin moiety of the chromosome, did not confirm the presence of any sequence suitable for homologous recombination. We propose a model involving simultaneous introduction of four donor DNA molecules, each comprising a different relevant junction, and their pairing with the junction regions of the recipient chromosome. The resolution of this structure, resting on homologous recombination, would confer the donor chromosome structure to the recipient, achieving some kind of 'transstamping'. In addition, a rather regular pattern of inverse and direct short sequence repeats in regions flanking the breaking points could be correlated with the initial, X-ray-induced, rearrangement.     

Parasexuality in Race 65 Colletotrichum lindemuthianum Isolates

ABSTRACT. Heterokaryosis is the initial step of the parasexual cycle, a process that provides genetic variability in filamentous fungi through the production of heterozygous diploid nuclei. To characterize the parasexual cycle in Colletotrichum lindemuthianum, we evaluated the presence of heterokaryosis, vegetative compatibility reactions, and diploid formation among isolates of Race 65 collected from different Brazilian states. Vegetative compatibility groups were identified among the isolates according to their ability to form heterokaryons. Two heterozygous diploids were selected from compatible heterokaryons, which were characterized by the segregation of the parental auxotrophic markers and by RAPD profiles.     

Regional Control of Chromosome Segregation in Pseudomonas aeruginosa

Chromosome segregation in bacteria occurs concomitantly with DNA replication, and the duplicated regions containing the replication origin oriC are generally the first to separate and migrate to their final specific location inside the cell. In numerous bacterial species, a three-component partition machinery called the ParABS system is crucial for chromosome segregation. This is the case in the gammaproteobacterium Pseudomonas aeruginosa, where impairing the ParABS system is very detrimental for growth, as it increases the generation time and leads to the formation of anucleate cells and to oriC mispositioning inside the cell. In this study, we investigate in vivo the ParABS system in P. aeruginosa. Using chromatin immuno-precipitation coupled with high throughput sequencing, we show that ParB binds to four parS site located within 15 kb of oriC in vivo, and that this binding promotes the formation of a high order nucleoprotein complex. We show that one parS site is enough to prevent anucleate cell formation, therefore for correct chromosome segregation. By displacing the parS site from its native position on the chromosome, we demonstrate that parS is the first chromosomal locus to be separated upon DNA replication, which indicates that it is the site of force exertion of the segregation process. We identify a region of approximatively 650 kb surrounding oriC in which the parS site must be positioned for chromosome segregation to proceed correctly, and we called it “competence zone” of the parS site. Mutant strains that have undergone specific genetic rearrangements allow us to propose that the distance between oriC and parS defines this “competence zone”. Implications for the control of chromosome segregation in P. aeruginosa are discussed.     

Integration of linear, heterologous DNA molecules into the Bacillus subtilis chromosome: mechanism and use in induction of predictable rearrangements.

Linear DNA molecules composed of a central region nonhomologous with the Bacillus subtilis chromosome and two flanking regions homologous with the chromosome can integrate into the chromosome, provided that the homologous regions have the same relative orientation. The resulting chromosome can be maintained in a haploid or in a merodiploid cell together with a parental chromosome. This can most easily be explained by supposing that the integration occurs by crossing over at each homologous region and that a part of the chromosome between these regions is deleted and replaced by the central nonhomologous region of the integrating molecule. If no essential genes were replaced during that process a haploid cell would be obtained; if essential genes were replaced a merodiploid cell would be obtained. The use of appropriate linear molecules therefore should allow the induction of deletions, extending from a given chromosomal site in a predetermined direction, and defined duplications in the B. subtilis chromosome.