Spatiotemporal choreography of chromosome and megaplasmids in the Sinorhizobium meliloti cell cycle

A considerable share of bacterial species maintains multipartite genomes. Precise coordination of genome replication and segregation with cell growth and division is vital for proliferation of these bacteria. The α‐proteobacterium Sinorhizobium meliloti possesses a tripartite genome composed of one chromosome and the megaplasmids pSymA and pSymB. Here, we investigated the spatiotemporal pattern of segregation of these S. meliloti replicons at single cell level. Duplication of chromosomal and megaplasmid origins of replication occurred spatially and temporally separated, and only once per cell cycle. Tracking of FROS (fluorescent repressor operator system)‐labelled origins revealed a strict temporal order of segregation events commencing with the chromosome followed by pSymA and then by pSymB. The repA2B2C2 region derived from pSymA was sufficient to confer the spatiotemporal behaviour of this megaplasmid to a small plasmid. Altering activity of the ubiquitous prokaryotic replication initiator DnaA, either positively or negatively, resulted in an increase in replication initiation events or G1 arrest of the chromosome only. This suggests that interference with DnaA activity does not affect replication initiation control of the megaplasmids.     

Characterization of chromosomal and megaplasmid partitioning loci in Thermus thermophilus HB27

Background

In low-copy-number plasmids, the partitioning loci (par) act to ensure proper plasmid segregation and copy number maintenance in the daughter cells. In many bacterial species, par gene homologues are encoded on the chromosome, but their function is much less understood. In the two-replicon, polyploid genome of the hyperthermophilic bacterium Thermus thermophilus, both the chromosome and the megaplasmid encode par gene homologues (parABc and parABm, respectively). The mode of partitioning of the two replicons and the role of the two Par systems in the replication, segregation and maintenance of the genome copies are completely unknown in this organism.

Results

We generated a series of chromosomal and megaplasmid par mutants and sGFP reporter strains and analyzed them with respect to DNA segregation defects, genome copy number and replication origin localization. We show that the two ParB proteins specifically bind their cognate centromere-like sequences parS, and that both ParB-parS complexes localize at the cell poles. Deletion of the chromosomal parAB genes did not apparently affect the cell growth, the frequency of cells with aberrant nucleoids, or the chromosome and megaplasmid replication. In contrast, deletion of the megaplasmid parAB operon or of the parB gene was not possible, indicating essentiality of the megaplasmid-encoded Par system. A mutant expressing lower amounts of ParABm showed growth defects, a high frequency of cells with irregular nucleoids and a loss of a large portion of the megaplasmid. The truncated megaplasmid could not be partitioned appropriately, as interlinked megaplasmid molecules (catenenes) could be detected, and the ParBm-parSm complexes in this mutant lost their polar localization.

Conclusions

We show that in T. thermophilus the chromosomal par locus is not required for either the chromosomal or megaplasmid bulk DNA replication and segregation. In contrast, the megaplasmid Par system of T. thermophilus is needed for the proper replication and segregation of the megaplasmid, and is essential for its maintenance. The two Par sets in T. thermophilus appear to function in a replicon-specific manner. To our knowledge, this is the first analysis of Par systems in a polyploid bacterium.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1523-3) contains supplementary material, which is available to authorized users.     

A consensus linkage map for rapeseed (Brassica napus L.): construction and integration of three individual maps from DH populations

A framework consensus map for rapeseed (Brassica napus L.) was constructed from the integration of three DH mapping populations derived from crosses between or within spring- and winter-type parents. Several sources of genetic markers were used: isozymes, RFLPs, RAPDs, and AFLPs. A total of 992 different markers were mapped to at least one population, of which 540 were included in the consensus map and 253 were common to at least two populations. Markers were distributed over 19 linkage groups, thus reflecting the basic chromosome number of rapeseed and covered 2,429 cM, which was in the mean confidence-interval estimates of genome length (2,127–2,480) cM. Markers were evenly spaced on the entire genome even if, for several linkage groups, both RAPD and AFLP markers were not uniformly distributed. In the population resulting from a cross between two spring lines, a higher recombination rate was observed and a translocation was identified. The consensus approach allowed to map a larger number of markers, to obtain a near-complete coverage of the rapeseed genome, to fill the number of gaps, and to consolidate the linkage groups of the individual maps. Received: 19 July 2000 / Accepted: 31 October 2000     

Genome and Chromosome Dimensions of Lotus japonicus

Lotus Japonicus , Miyakojima MG-20 and Gifu B-129. The genome sizes of Miyakojima and Gifu were determined as 472.1 and 442.8 Mbp, respectively. Both the accessions were diploid (2n=12) and six chromosomes were identified and characterized based on the condensation patterns and the locations of rDNA loci. The obvious polymorphism observed in the genome size and the chromosome morphology between the two accessions, revealed specific accumulation of heterochromatin in Miyakojima or elimination in Gifu. The chromosomes L. japonicus were numbered according to their length. A quantitative chromosome map was also developed by the imaging methods using the digital data of the condensation pattern. 45S rDNA loci were localized on chromosomes A and F, and 5S rDNA locus was localized on chromosome A by fluorescence in situ hybridization (FISH). Identification of the chromosome and genome sizes and development of the quantitative chromosome map represent significant contribution to the L. japonicus genome project as the basic information. Received 29 August 2000/ Accepted in revised form 17 October 2000     

Genome size variation and species relationships in the genus Hydrangea

Genome size and base composition in 16 species and subspecies of the Hydrangea, a woody ornamental genus of Hydrangeaceae, were evaluated by flow cytometry in relation to their chromosome number. This is the first such study concerning the genome size of these species together with a karyotype study of the most important species, Hydrangea macrophylla subsp. macrophylla (Hortensia), from an economical point of view. The 2C DNA content ranged from 1.95 pg in Hydrangea quercifolia to 5.00 pg in Hydrangea involucrata. The base composition ranged from 39.9% GC in Hydrangea aspera subsp. sargentiana to 41.1% in Hydrangea scandens subsp. scandens (significant difference at p < 0.05). The smallest genome sizes were those of the three species originating from North or South America. Most of the species studied presented a chromosome number of 2n = 2x = 36, except for those of the section Aspereae which showed 2n = 30, 34 and 36. A primary karyotype has been made for the first time for H. macrophylla subsp. macrophylla. Phylogenetic relationships between species, the origin of chromosome number and an exploration of the genetic diversity within the genus are discussed. Received: 24 July 2000 / Accepted: 31 October 2000     

Alu-PCR Approach to Isolating NotI-Linking Clones from the 3p14-p21 Region Frequently Deleted in Renal Cell Carcinoma

In the mammalian genome CpG islands are associated with functional genes and cloning of these islands could be an alternative approach for cloning functional genes. Recently we have developed a new approach for cloning CpG islands and constructing NotI linking libraries. We have initiated the construction of a NotI restriction map for chromosome 3, especially focusing on the rearrangements in the 3p14-p21 region, which are associated with different malignancies. CpG islands from this region are useful for isolation of candidate tumor suppressor genes that map to this region and for isolating NotI-linking clones from 3p14-p21 for mapping purposes. Here we suggest a modification of Alu-PCR as an approach to isolating Not I sites (e.g., CpG islands) from defined regions of the chromosome. Instead of using whole chromosomal DNA for Alu-PCR, we have used representative NotI-linking libraries from hybrid cell lines containing either whole or deleted human chromosome 3 (MCH903.1 and MCH924.4, respectively). This decreases the complexity of the Alu-PCR products 10-100 times compared to the whole human genome. Using this modification, we can isolate NotI-linking clones, which are natural markers on the chromosome, rather than random genomic fragments. Among eight clones selected by this method, seven were from the region deleted in MCH924.4. The results clearly demonstrate the feasibility of Alu-PCR for isolating CpG islands from defined regions of the genome.     

A standard photomap of ovarian nurse cell chromosomes in the European malaria vector Anopheles atroparvus

Anopheles atroparvus (Diptera: Culicidae) is one of the main malaria vectors of the Maculipennis group in Europe. Cytogenetic analysis based on salivary gland chromosomes has been used in taxonomic and population genetic studies of mosquitoes from this group. However, a high‐resolution cytogenetic map that could be used in physical genome mapping in An. atroparvus is still lacking. In the present study, a high‐quality photomap of the polytene chromosomes from ovarian nurse cells of An. atroparvus was developed. Using fluorescent in situ hybridization, 10 genes from the five largest genomic supercontigs on the polytene chromosome were localized and 28% of the genome was anchored to the cytogenetic map. The study established chromosome arm homology between An. atroparvus and the major African malaria vector Anopheles gambiae, suggesting a whole‐arm translocation between autosomes of these two species. The standard photomap constructed for ovarian nurse cell chromosomes of An. atroparvus will be useful for routine physical mapping. This map will assist in the development of a fine‐scale chromosome‐based genome assembly for this species and will also facilitate comparative and evolutionary genomics studies in the genus Anopheles.     

Genetic snapshots of the Rhizobium species NGR234 genome

Background  

In nitrate-poor soils, many leguminous plants form nitrogen-fixing symbioses with members of the bacterial family Rhizobiaceae. We selected Rhizobium sp. NGR234 for its exceptionally broad host range, which includes more than 112 genera of legumes. Unlike the genome of Bradyrhizobium japonicum, which is composed of a single 8.7 Mb chromosome, that of NGR234 is partitioned into three replicons: a chromosome of about 3.5 Mb, a megaplasmid of more than 2 Mb (pNGR234b) and pNGR234a, a 536,165 bp plasmid that carries most of the genes required for symbioses with legumes. Symbiotic loci represent only a small portion of all the genes coded by rhizobial genomes, however. To rapidly characterize the two largest replicons of NGR234, the genome of strain ANU265 (a derivative strain cured of pNGR234a) was analyzed by shotgun sequencing.     

RFLP linkage map of the Ethiopian cereal tef [Eragrostis tef (Zucc) Trotter]

Tef [Eragrostis tef (Zucc)Trotter] is one of the most important cereal crops in Ethiopia. It is an allotetraploid species with a genome size of 720 Mbp. In this paper we report results of genetic linkage-map construction for E. tef using tef and heterologous cDNA probes for the first time. One hundred and sixteen F₈ recombinant inbred lines (RILs) from the cross E. tef cv Kaye Murri×Eragrostis pilosa (accession30–5) were used for mapping. Parental lines were digested with nine restriction enzymes and screened using 159 tef cDNA and 162 heterologous probes including the grass genome anchor probes. The polymorphism level between parental lines was 66.9%. One hundred and thirty nine polymorphic probes were hybridized against 116 RILs. Both the tef and the heterologous probes hybridized well against tef genomic DNA. The linkage map defined 1,489 cM of the tef genome comprising 149 marker loci distributed among 20 linkage groups. The average interval between markers was 9.99 cM. A fraction (14.8%) of the markers deviated significantly from the expected segregation. Such a genetic linkage map is useful for tagging economically useful genes in tef because a wide range of agronomically important traits is segregating within this population. This would enable the use of a marker assisted breeding strategy which, in turn, will enhance breeding efficiency. Alignment of the tef RFLP map with the rice RFLP map indicates that a number of syntenic chromosomal fragments exist between tef and rice in which the gene order was for the most part collinear. The comparative mapping information should enable tef scientists to take advantage of whatever genetic progress is made on the cereal model species rice. Received: 9 June 2000 / Accepted: 31 August 2000     

Comparative physical mapping of targeted regions of the rat genome

The comparative mapping and sequencing of vertebrate genomes is now a key priority for the Human Genome Project. In addition to finishing the human genome sequence and generating a `working draft' of the mouse genome sequence, significant attention is rapidly turning to the analysis of other model organisms, such as the laboratory rat (Rattus norvegicus). As a complement to genome-wide mapping and sequencing efforts, it is often important to generate detailed maps and sequence data for specific regions of interest. Using an adaptation of our previously described approach for constructing mouse comparative and physical maps, we have established a general strategy for targeted mapping of the rat genome. Specifically, we constructed a framework comparative map of human Chromosome (Chr) 7 and the orthologous regions of the rat genome, as well as two large (>1-Mb) P1-derived artificial chromosome (PAC)-based physical maps. Generation of these physical maps involved the use of mouse-derived probes that cross-hybridized with rat PAC clones. The first PAC map encompasses the cystic fibrosis transmembrane conductance regulator gene (Cftr), while the second map allows a three-species comparison of a genomic region containing intra- and inter-chromosomal evolutionary rearrangements. The studies reported here further demonstrate that cross-species hybridization between related animals, such as rat and mouse, can be readily used for the targeted construction of clone-based physical maps, thereby accelerating the analysis of biologically interesting regions of vertebrate genomes. Received: 5 December 2000 / Accepted: 27 February 2001     

Simple sequence repeats and compositional bias in the bipartite <Emphasis Type="Italic">Ralstonia solanacearum</Emphasis> GMI1000 genome

Background

Ralstonia solanacearum is an important plant pathogen. The genome of R. solananearum GMI1000 is organised into two replicons (a 3.7-Mb chromosome and a 2.1-Mb megaplasmid) and this bipartite genome structure is characteristic for most R. solanacearum strains. To determine whether the megaplasmid was acquired via recent horizontal gene transfer or is part of an ancestral single chromosome, we compared the abundance, distribution and compositon of simple sequence repeats (SSRs) between both replicons and also compared the respective compositional biases.

Results

Our data show that both replicons are very similar in respect to distribution and composition of SSRs and presence of compositional biases. Minor variations in SSR and compositional biases observed may be attributable to minor differences in gene expression and regulation of gene expression or can be attributed to the small sample numbers observed.

Conclusions

The observed similarities indicate that both replicons have shared a similar evolutionary history and thus suggest that the megaplasmid was not recently acquired from other organisms by lateral gene transfer but is a part of an ancestral R. solanacearum chromosome.

     

High-density physical maps reveal that the dominant male-sterile gene Ms3 is located in a genomic region of low recombination in wheat and is not amenable to map-based cloning

In wheat it is essential to know whether a gene is located in a high or low recombination region of the genome before initiating a map-based cloning approach. The objective of this study was to explore the potential feasibility of map-based cloning of the dominant male-sterile gene Ms3 of wheat. High-density physical maps of the short arms of the group-5 chromosomes (5AS, 5BS, and 5DS) of Triticum aestivum L. were constructed by mapping 40 DNA markers on a set of 17 homozygous deletion lines. One hundred RFLP loci were mapped: 35 on 5AS, 37 on 5BS, and 28 on 5DS. A consensus physical map was colinearly aligned with a consensus genetic map of the group-5 short arms. Sixteen of the 17 markers in the consensus genetic map encompass a genetic distance of 25 cM and correspond to the distal region (FL 0.56–0.97) of the consensus physical map. Two rice probes, RG463 and RG901, previously identified to be linked to markers CDO344 and CDO749 (group-5 short arm of wheat), respectively, in the genetic map of rice chromosome 12, map between FL 0.56 and 0.63 in the consensus map. Thus at least a part of the group-5 short arm is homoeologous to a region of chromosome 12 of rice. The genetic map of chromosome arm 5AS was constructed using a population of 139 BC₁ plants derived from a cross between the euploid wheat ”Chris” carrying a dominant male-sterile gene Ms3 and a disomic substitution line in which chromosome 5A of T. aestivum cv Chinese Spring was substituted by chromosome 5A from Triticum turgidum ssp. dicoccoides. The map has a genetic length of 53.4 cM with 11 DNA markers. The initial map showed that the gene Ms3 cosegregated with three markers, WG341, BCD1130 and CDO677. High-resolution mapping using an additional 509 BC₁ plants indicated that the marker WG341 was closely linked to Ms3 at a genetic distance of 0.8 cM. The Ms3 was mapped physically in the region spanning 40% of the arm length from the centromere of 5AS. Therefore, map-based cloning of the Ms3 is not feasible, although WG341 can be used as a useful tag for the Ms3 gene for breeding purposes. Received: 12 December 2000 / Accepted: 26 January 2001     

A COSII genetic map of the pepper genome provides a detailed picture of synteny with tomato and new insights into recent chromosome evolution in the genus Capsicum

We report herein the development of a pepper genetic linkage map which comprises 299 orthologous markers between the pepper and tomato genomes (including 263 conserved ortholog set II or COSII markers). The expected position of additional 288 COSII markers was inferred in the pepper map via pepper–tomato synteny, bringing the total orthologous markers in the pepper genome to 587. While pepper maps have been previously reported, this is the first complete map in the sense that all markers could be placed in 12 linkage groups corresponding to the 12 chromosomes. The map presented herein is relevant to the genomes of cultivated C. annuum and wild C. annuum (as well as related Capsicum species) which differ by a reciprocal chromosome translocation. This map is also unique in that it is largely based on COSII markers, which permits the inference of a detailed syntenic relationship between the pepper and tomato genomes—shedding new light on chromosome evolution in the Solanaceae. Since divergence from their last common ancestor is approximately 20 million years ago, the two genomes have become differentiated by a minimum number of 19 inversions and 6 chromosome translocations, as well as numerous putative single gene transpositions. Nevertheless, the two genomes share 35 conserved syntenic segments (CSSs) within which gene/marker order is well preserved. The high resolution COSII synteny map described herein provides a platform for cross-reference of genetic and genomic information (including the tomato genome sequence) between pepper and tomato and therefore will facilitate both applied and basic research in pepper. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Re-orientation and integration of the classical and interspecific linkage maps of the long arm of tomato chromosome 7

To obtain reliable classical and integrated interspecies maps of the long arm of chromosome 7 of tomato, detailed mapping work was undertaken and several phenotypic and molecular markers were assigned loci on both maps to provide reliable cross-reference points. To maximise the value of the new maps, pair-wise segregation data for classical genetic markers from the literature were included, based on large segregating populations with readily scorable phenotypes. In addition, to increase confidence in these maps, introgression lines were used to confirm important map locations. The revised classical map is based on two- and three-point test-cross data from a number of F₂ and BC₁ mapping populations. The integrated interspecies map is based on F₂ mapping populations derived from crosses of Lycopersicon esculentum with Lycopersicon pennellii (LA716). The genetic analyses for both maps were performed using the computer package JoinMap. The revised composite classical map indicates that some of the map positions reported in the literature are incorrect. The linear order of the classical markers common to both the revised classical and integrated interspecies maps are in complete agreement. Production of the integrated interspecies map resulted in re-orientation of the existing molecular map. Received: 13 September 2000 / Accepted: 20 December 2000     

AFLP and STS tagging of Lr19, a gene conferring resistance to leaf rust in wheat

Amplified fragment length polymorphism (AFLP) markers were used to enrich the map of the wheat chromosomal region containing the Thinopyrum-derived Lr19 leaf rust resistance gene. The region closest to Lr19 was targeted through the use of deletion and recombinant lines of the translocated segment. One of the AFLP bands thus identified was converted into a sequence-tagged-site (STS) marker. This assay generated a 130-bp PCR fragment in all Lr19-carrying lines tested, except for one deletion mutant, while non-carrier template failed to amplify any product. This sequence represents the first marker to map on the distal side of Lr19 on chromosome 7el₁. The conversion process of AFLP fragments to STS markers was technically difficult, mainly because of the presence of contaminating fragments. Various approaches were taken to reduce the frequency of false positives and to identify the correct clone. We were able to formulate a general verification strategy prior to clone sequencing. Various other factors causing problems with converting AFLP bands to an STS assays are also discussed. Received: 15 September 2000 / Accepted: 5 January 2001     

Mapping of ripening-related or -specific cDNA clones of tomato (Lycopersicon esculentum)

Summary Nineteen ripening-related or -specific clones from Lycopersicon esculentum were mapped via RFLP analysis using an F₂ population from the cross L. esculentum x L. pennellii and cDNA or genomic clones of known map location. The map produced using cDNA and genomic clones of known map location corresponded well with previously published maps of tomato. The number of loci detected for each ripening-related or-specific clone varied from one to seven. These loci were located on all 12 chromosomes of the tomato genome. There was no significant clustering of ripening-related or-specific genes. Regions of very low recombination were observed. The clone for polygalacturonase (TOM6) mapped to a single region on chromosome 10, the same chromosome as the nor and alc ripening mutants. To fine map this chromosome, two backcross populations were produced from the cross of L. esculentum x L. pimpenillifolium, in which the esculentum parents used were homozygous for either the alc or the nor. The coding region for polygalacturonase is functionally unlinked to either of these two ripening mutants.     

黄藤染色体核型及基因组大小分析

为探究黄藤(Daemonoropsjenkinsiana)染色体核型和基因组的大小,采用体细胞染色体常规制片法与显微摄影技术相结合的方法,对黄藤染色体进行了核型分析,同时以番茄(Lycopersicon esculentum)为内标,应用流式细胞术对黄藤叶片基因组大小、DNA含量和DNA倍性进行了测定。结果表明,黄藤茎尖是理想的染色体制片材料;黄藤的染色体数为2n=24,核型公式为K(2n)=1M+17m+5sm+1st,核型类型为2C;核型不对称系数61.20%;黄藤的DNA含量为1.57 pg,基因组大小为1 539.53 Mb,黄藤的DNA倍性为二倍体(2n)。这是首次报道黄藤的核型和基因组大小,为深入开展黄藤属及其近缘属植物的核型和基因组比较分析提供了参考依据。     

Genetic dissection of a modern sugarcane cultivar (Saccharum spp.). I. Genome mapping with AFLP markers

Sugarcane cultivars are polyploid, aneuploid clones derived from interspecific hybridization between Saccharum officinarum and S. spontaneum. Their genome has recently started to be unravelled as a result of the development of molecular markers. We constructed an AFLP genetic map based on a selfing population of a specific cultivar, R570.Using 37 AFLP primer pairs, we detected 1,185 polymorphic markers of which 939 were simplex (segregated 3:1); these were used to construct the map. Of those 939, 887 were distributed on 120 cosegregation groups (CGs) based on linkages in coupling, while 52 remained unlinked. The cumulative length of all the groups was 5,849 cM, which is probably around one-third of the total genome length. Comparison with reference S. officinarum clones enabled us to assign 11 and 79 CGs to S. spontaneum and S. officinarum,respectively, whereas 11 CGs were probably derived from recombination between chromosomes of the two ancestral species. The patchy size of the groups, which ranges from 1 to 232 cM, illustrates the difficulty to access large portions of chromosomes, particularly those inherited from S. officinarum. Repulsion phase linkages suggested a high preferential pairing for 13 CG pairs. Out of the 120 CGs, 34 could be assigned to one of the 10 homo(eo)logy groups already defined in a previous RFLP map owing to the use of a small common marker set. The genome coverage was significantly increased in the map reported here. Implications for quantitative trait loci (QTL) research and marker-assisted breeding perspectives are discussed. Received: 31 August 2000 / Accepted: 16 October 2000     

Genome size evolution in Sapindaceae at subfamily level: a case study of independence in relation to karyological and palynological traits

Sapindaceae s.l. is a moderately large family of trees, shrubs and lianas. Current knowledge on genome size and how it varies in this family is scarce. This research aims to characterize the DNA content in 39 species of Sapindaceae, mainly in tribe Paullinieae s.s., by the analysis of the variation in genome size relative to karyotypic and palynological features. Nuclear DNA amount was measured by flow cytometry, and linear regression analyses were conducted to analyse the relationship between genome size variation and various karyotypic and palynological features. Genome size varied nine‐fold among species, ranging from 1C = 0.305 pg (Lophostigma plumosum) to 2.710 pg (Cardiospermum heringeri). The low regression coefficients obtained suggest that genome size mainly varies independently of karyotypic and palynological features. With regard to karyotype evolution, the constant chromosome number but variable genome size in Houssayanthus, Paullinia and Serjania suggest that structural changes mainly caused by changes in the amounts of repetitive DNA are more important than numerical change. In contrast, in Cardiospermum and Urvillea, variation in chromosome number and genome size supports the suggestion that numerical and structural changes are important in the karyotype evolution of these genera. © 2014 The Linnean Society of London, Botanical Journal of the Linnean Society, 2014, 174 , 589–600.