Size and complexity of the nuclear genome of the ectomycorrhizal fungus Paxillus involutus

The basidiomycete Paxillus involutus is forming ectomycorrhizal symbiosis with a broad range of forest trees. Reassociation kinetics on P. involutus nuclear DNA indicated a haploid genome size of 23 Mb including 11% of repetitive DNA. A similar genome size (20 Mb) was estimated by genomic reconstruction analysis using three single copy genes. To assess the gene density in the P. involutus genome, a cosmid containing a 33-kb fragment of genomic DNA was sequenced and used to identify putative open reading frames (ORFs). Twelve potential ORFs were predicted, eight displayed significant sequence similarities to known proteins found in other organisms and notably, several homologues to the Podospora anserina vegetative incompatibility protein (HetE1) were found. By extrapolation, we estimate the total number of genes in the P. involutus haploid genome to approximately 7700.     

The gut fungus Basidiobolus ranarum has a large genome and different copy numbers of putatively functionally redundant elongation factor genes

Fungal genomes range in size from 2.3 Mb for the microsporidian Encephalitozoon intestinalis up to 8000 Mb for Entomophaga aulicae, with a mean genome size of 37 Mb. Basidiobolus, a common inhabitant of vertebrate guts, is distantly related to all other fungi, and is unique in possessing both EF-1α and EFL genes. Using DNA sequencing and a quantitative PCR approach, we estimated a haploid genome size for Basidiobolus at 350 Mb. However, based on allelic variation, the nuclear genome is at least diploid, leading us to believe that the final genome size is at least 700 Mb. We also found that EFL was in three times the copy number of its putatively functionally overlapping paralog EF-1α. This suggests that gene or genome duplication may be an important feature of B. ranarum evolution, and also suggests that B. ranarum may have mechanisms in place that favor the preservation of functionally overlapping genes.     

Comparisons with Caenorhabditis (approximately 100 Mb) and Drosophila (approximately 175 Mb) using flow cytometry show genome size in Arabidopsis to be approximately 157 Mb and thus approximately 25% larger than the Arabidopsis genome initiative estimate of approximately 125 Mb

Recent genome sequencing papers have given genome sizes of 180 Mb for Drosophila melanogaster Iso-1 and 125 Mb for Arabidopsis thaliana Columbia. The former agrees with early cytochemical estimates, but numerous cytometric estimates of around 170 Mb imply that a genome size of 125 Mb for arabidopsis is an underestimate. In this study, nuclei of species pairs were compared directly using flow cytometry. Co-run Columbia and Iso-1 female gave a 2C peak for arabidopsis only approx. 15 % below that for drosophila, and 16C endopolyploid Columbia nuclei had approx. 15 % more DNA than 2C chicken nuclei (with >2280 Mb). Caenorhabditis elegans Bristol N2 (genome size approx. 100 Mb) co-run with Columbia or Iso-1 gave a 2C peak for drosophila approx. 75 % above that for 2C C. elegans, and a 2C peak for arabidopsis approx. 57 % above that for C. elegans. This confirms that 1C in drosophila is approx. 175 Mb and, combined with other evidence, leads us to conclude that the genome size of arabidopsis is not approx. 125 Mb, but probably approx. 157 Mb. It is likely that the discrepancy represents extra repeated sequences in unsequenced gaps in heterochromatic regions. Complete sequencing of the arabidopsis genome until no gaps remain at telomeres, nucleolar organizing regions or centromeres is still needed to provide the first precise angiosperm C-value as a benchmark calibration standard for plant genomes, and to ensure that no genes have been missed in arabidopsis, especially in centromeric regions, which are clearly larger than once imagined.     

Genome size estimation with quantitative real‐time PCR in two Tephritidae species: Ceratitis capitata and Bactrocera oleae

The medfly Ceratitis capitata and the olive fruit fly Bactrocera oleae belong to the Tephritidae family of Diptera, a family whose members cause severe damages in agriculture worldwide. For such insect pests, the utmost concern is their population control. The sterile insect technique (SIT) has been used in the Tephritidae family with varying degrees of success. Its efficient use usually depends on the development of genetic sexing strains and the release of only male flies. However, such advances are based on modern genetic, molecular and genomic tools. The medfly is clearly the prototype of the family, since such tools have advanced considerably, which has resulted in effective SIT efforts around the world. A whole‐genome sequencing project of this insect is already underway. In contrast, similar tools in the olive fly lag behind, even though the insect is considered a promising candidate for a next SIT target. An accurate estimate of genome size provides a preliminary view of genome complexity and indicates possible difficulties in genome assembly in whole‐genome projects. Taking advantage of a quantitative real‐time PCR approach, we determined the genome size of these two species C. capitata and B. oleae as 591 Mb (CI range: 577–605 Mb) and 322 Mb (CI range: 310–334 Mb) respectively.     

Reshuffling of the Bacillus subtilis 168 genome by multifold inversion

The genome of Bacillus subtilis 168 was modified to yield a genome vector for the cloning of DNA several Mb in size. Unlike contemporary plasmid-based vectors, this 4.2 Mb genome vector requires specific in vivo handling protocols because of its large size. Inversion mutagenesis, a method to modify local genome structure without gain or loss of genes, was applied intensively to the B. subtilis genome; this technique made possible both exchange and translocation of designated regions of the genome. This method not only reshuffles the genome of B. subtilis, but can provide insight into the biologic principles underlying genome plasticity.     

Chromosome‐level genome assembly of a cyprinid fish Onychostoma macrolepis by integration of nanopore sequencing,Bionano and Hi‐C technology

Onychostoma macrolepis is an emerging commercial cyprinid fish species. It is a model system for studies of sexual dimorphism and genome evolution. Here, we report the chromosome‐level assembly of the O.macrolepis genome obtained from the integration of nanopore long‐read sequencing with physical maps produced using Bionano and Hi‐C technology. A total of 87.9 Gb of nanopore sequence provided approximately 100‐fold coverage of the genome. The preliminary genome assembly was 883.2 Mb in size with a contig N50 size of 11.2 Mb. The 969 corrected contigs obtained from Bionano optical mapping were assembled into 853 scaffolds and produced an assembly of 886.5 Mb with a scaffold N50 of 16.5 Mb. Finally, using the Hi‐C data, 881.3 Mb (99.4% of genome) in 526 scaffolds were anchored and oriented in 25 chromosomes ranging in size from 25.27 to 56.49 Mb. In total, 24,770 protein‐coding genes were predicted in the genome, and ~96.85% of the genes were functionally annotated. The annotated assembly contains 93.3% complete genes from the BUSCO reference set. In addition, we identified 409 Mb (46.23% of the genome) of repetitive sequence, and 11,213 non‐coding RNAs, in the genome. Evolutionary analysis revealed that O. macrolepis diverged from common carp approximately 24.25 million years ago. The chromosomes of O. macrolepis showed an unambiguous correspondence to the chromosomes of zebrafish. The high‐quality genome assembled in this work provides a valuable genomic resource for further biological and evolutionary studies of O. macrolepis.     

Bacterial phytopathogens and genome science

There are now fourteen completed genomes of bacterial phytopathogens, all of which have been generated in the past six years. These genomes come from a phylogenetically diverse set of organisms, and range in size from 870 kb to more than 6Mb. The publication of these annotated genomes has significantly helped our understanding of bacterial plant disease. These genomes have also provided important information about bacterial evolution. Examples of recently completed genomes include: Pseudomonas syringae pv tomato, which is notable for its large repertoire of effector proteins; Leifsonia xyli subsp. xyli, the first Gram-positive bacterial genome to be sequenced; and Phytoplasma asteris, the small genome that lacks important functions previously thought to be essential in a bacterium.     

Genome size and ploidy level: new insights for elucidating relationships in Zygosaccharomyces species

Ploidy is a fundamental genetic trait with important physiological and genomic implications. We applied complementary molecular tools to highlight differences in genome size and ploidy between Zygosaccharomyces rouxii strain CBS 732T and other related wild strains (ATCC 42981, ABT 301, and ABT 601). The cell cycle analysis by flow cytometry revealed a genome size of 12.7+/-0.2 Mb for strain CBS 732T, 21.9+/-0.2 Mb for ATCC 42981, 28.1+/-1.3 Mb for ABT 301, and 39.00+/-0.3 Mb for ABT 601. Moreover, karyotyping analysis showed a high variability, with wild strains having a higher number of chromosomal bands than CBS 732T. The ploidy level was assessed comparing genome size from flow cytometry with the average haploid size from electrophoretic karyotyping. Strain CBS 732T showed an haploid DNA content, whereas the wild strains a diploid DNA content. In addition gene probe-chromosome hybridization targeted to ZSOD genes showed that wild strains with a diploid DNA content have two ZSOD copies located on different chromosomes.     

Electrophoretic karyotyping of the lignin-degrading basidiomycete Phanerochaete chrysosporium

Electrophoretic karyotyping of the two most widely studied strains of Phanerochaete chrysosporium, BKMF-1767 and ME-446, has been determined using transverse alternating field etectrophoresis. The genomic DNA of BKMF-1767 was resolved into 10 chromosomes ranging in size from 1.8–5.0 Mb, amounting to a total genome size of about 29 Mb. The genomic DNA of strain ME-446, on the other hand, was resolved into 11 chromosomes, amounting to a total genome size of about 32Mb. Lignin peroxidase genes have been localized to five chromosomes in strain BKMF-1767 and to four chromosomes in strain ME-446.     

The arbuscular mycorrhizal fungus Glomus intraradices is haploid and has a small genome size in the lower limit of eukaryotes

The genome size, complexity, and ploidy of the arbuscular mycorrhizal fungus (AMF) Glomus intraradices was determined using flow cytometry, reassociation kinetics, and genomic reconstruction. Nuclei of G. intraradices from in vitro culture, were analyzed by flow cytometry. The estimated average length of DNA per nucleus was 14.07+/-3.52 Mb. Reassociation kinetics on G. intraradices DNA indicated a haploid genome size of approximately 16.54 Mb, comprising 88.36% single copy DNA, 1.59% repetitive DNA, and 10.05% fold-back DNA. To determine ploidy, the DNA content per nucleus measured by flow cytometry was compared with the genome estimate of reassociation kinetics. G. intraradices was found to have a DNA index (DNA per nucleus per haploid genome size) of approximately 0.9, indicating that it is haploid. Genomic DNA of G. intraradices was also analyzed by genomic reconstruction using four genes (Malate synthase, RecA, Rad32, and Hsp88). Because we used flow cytometry and reassociation kinetics to reveal the genome size of G. intraradices and show that it is haploid, then a similar value for genome size should be found when using genomic reconstruction as long as the genes studied are single copy. The average genome size estimate was 15.74+/-1.69 Mb indicating that these four genes are single copy per haploid genome and per nucleus of G. intraradices. Our results show that the genome size of G. intraradices is much smaller than estimates of other AMF and that the unusually high within-spore genetic variation that is seen in this fungus cannot be due to high ploidy.     

Prediction of effective genome size in metagenomic samples

We introduce a novel computational approach to predict effective genome size (EGS; a measure that includes multiple plasmid copies, inserted sequences, and associated phages and viruses) from short sequencing reads of environmental genomics (or metagenomics) projects. We observe considerable EGS differences between environments and link this with ecologic complexity as well as species composition (for instance, the presence of eukaryotes). For example, we estimate EGS in a complex, organism-dense farm soil sample at about 6.3 megabases (Mb) whereas that of the bacteria therein is only 4.7 Mb; for bacteria in a nutrient-poor, organism-sparse ocean surface water sample, EGS is as low as 1.6 Mb. The method also permits evaluation of completion status and assembly bias in single-genome sequencing projects.     

The utility of amplified fragment length polymorphisms in phylogenetics: a comparison of homology within and between genomes

The amplified fragment length polymorphism (AFLP) technique is being increasingly used in phylogenetic studies, especially in groups of rapidly radiating taxa. One of the key issues in the phylogenetic suitability of this technique is whether the DNA fragments generated via the AFLP method are homologous within and among the taxa being studied. We used a bioinformatics approach to assess homology based on both chromosomal location and sequence similarity of AFLP fragments. The AFLP technique was electronically simulated on genomes from eight organisms that represented a range of genome sizes. The results demonstrated that within a genome, the number of fragments is positively associated with genome size, and the degree of homology decreases with increasing numbers of fragments generated. The average homology of fragments was 89% for small genomes (< 400 Mb) but decreased to 59% for large genomes (> 2 Gb). Fragment homology for large genomes can be increased by excluding smaller fragments, although there is no clear upper limit for the size of fragments to exclude. A second approach is to increase the number of selective nucleotides in the final selective amplification step. For strains of the same organism, homology based on chromosome location and sequence similarity of fragments was 100%. Fragment homology for more distantly related taxa, however, decreased with greater time since divergence. We conclude that AFLP data are best suited for examining phylogeographic patterns within species and among very recently diverged species.     

Multicellular Ascomycetous Fungal Genomes Contain More Than 8000 Genes

Fungi comprise a large monophyletic group of uni- and multicellular eukaryotic organisms in which many species are of economic or medical importance. Fungal genomes are variable in size (13–42 Mb), and multicellular species support true spatial and temporal cell-type-specific regulation of gene expression. In a 38.8-kbAspergillus nidulanscontiguous genomic DNA region, a transposable element and 12 potential genes were identified, 7 similar to genes in other organisms. This observation is consistent with the prediction that multicellular ascomycetous fungi harbor 8000–9000 genes in a 36-Mb average genome. Thus, the genomic DNA sequence of filamentous fungi will provide substantial amounts of genetic and functional information that is not available in yeast, for the human and other metazoan minimal gene complement.     

Use of pulsed-field agarose gel electrophoresis to size genomes of Campylobacter species and to construct a SalI map of Campylobacter jejuni UA580.

To determine the physical length of the chromosome of Campylobacter jejuni, the genome was subjected to digestion by a series of restriction endonucleases to produce a small number of large restriction fragments. These fragments were then separated by pulsed-field gel electrophoresis with the contour-clamped homogeneous electric field system. The DNA of C. jejuni, with its low G+C content, was found to have no restriction sites for enzymes NotI and SfiI, which cut a high-G+C regions. Most of the restriction enzymes that were used resulted in DNA fragments that were either too numerous or too small for genome size determination, with the exception of the enzymes SalI (5' ... G decreases TCGAG ... 3'), SmaI (5' .... CCC decreases GGG .... 3'), and KpnI (5' ... GGTAC decreases C .... 3'). With SalI, six restriction fragments with average values of 48.5, 80, 110, 220, 280, and 980 kilobases (kb) were obtained when calibrated with both a lambda DNA ladder and yeast Saccharomyces cerevisiae chromosome markers. The sum of these fragments yielded an average genome size of 1.718 megabases (Mb). With SmaI, nine restriction fragments with average values ranging from 39 to 371 kb, which yielded an average genome size of 1.726 Mb were obtained. With KpnI, 11 restriction fragments with sizes ranging from 35 to 387.5 kb, which yielded an average genome size of 1.717 Mb were obtained. A SalI restriction map was derived by partial digestion of the C. jejuni DNA. The genome sizes of C. laridis, C. coli, and C. fetus were also determined with the contour-clamped homogeneous electric field system by SalI, SmaI, and KpnI digestion. Average genome sizes were found to be 1.714 Mb for C. coli, 1.267 Mb for C. fetus subsp. fetus, and 1.451 Mb for C. laridis.     

Genome size and chromatin condensation in vertebrates

Cell membrane-dependent chromatin condensation was studied by flow cytometry in erythrocytes of 36 species from six classes of vertebrates. A positive relationship was found between the degree of condensation and genome size. The distribution of variances among taxonomic levels is similar for both parameters. However, chromatin condensation varied relatively more at the lower taxonomic levels, which suggests that the degree of DNA packaging might serve for fine-tuning the skeletal and/or buffering function of noncoding DNA (although the range of this fine-tuning is smaller than the range of genome size changes). For two closely related amphibian species differing in genome size, change in chromatin condensation under the action of elevated extracellular salinity was investigated. Condensation was steadier and its reaction to changes in solvent composition was more inertial in the species with a larger genome, which is in agreement with the buffering function postulated for redundant DNA. The uppermost genome size in vertebrates (and in living beings in general) was updated using flow cytometry and was found to be about 80 pg (78,400 Mb). The widespread opinion that the largest genome occurs in unicellular organisms is rejected as being based on artifacts.     

Determination of Gardnerella vaginalis Genome Size by Pulsed-Field Gel Electrophoresis

The chromosomal DNA of four strains of Gardnerella vaginaliswere digested with rare cutting restriction enzymes and analyzedby pulsed-field gel electrophoresis (PFGE). The four strainsstudied were two clinical isolates (GVP 004 & GVP 007) andtwo American Type Culture Collection strains (ATCC 14018 &ATCC 14019). The restriction enzyme SfiI generated two DNA fragmentsof about 0.6 Mb and 1.1 Mb in all four strains giving a G. vaginalisgenome size of about 1.7 Mb. A similar genome size was calculatedutilizing two more GC-rich sequence specific restriction endonucleases,NotI and AscI. When digested with AscI, the chromosomal DNAof all four strains gave rise to 11 to 12 DNA fragments rangingbetween 0.01 Mb to 0.43 Mb. DNA from the two clinical isolateswere digested by NotI (yielding 7 to 9 fragments), while theDNA from the two ATCC strains were resistant to NotI digestion.In contrast to the clinical isolates, DNA from the two ATCCstrains gave an identical profile for all restriction endonucleasestested. From double digestion experiments, the two SfiI sitescould be localized on two AscI fragments. From these PFGE studies,it is concluded that the G. vaginalis genome is a circular DNAthat ranges between 1.67 Mb and 1.72 Mb in size.     

基于流式细胞术和K-mer分析的银缕梅属(Parrotia C.A.Mey.)植物基因组大小测定

金缕梅科(Hamamelidaceae)银缕梅属(Parrotia C.A.Mey.)仅包含银缕梅(Parrotia subaequalis(H.T.Chang)R.M.Hao&H.T.Wei)和波斯铁木(Parrotia persica(DC.)C.A.Mey.)两种落叶阔叶乔木,其中银缕梅是我国华东地区特有的Ⅰ级濒危珍稀保护植物,属东亚第三纪孑遗成分;其姊妹种波斯铁木则间断分布于伊朗北部,属北极第三纪孑遗植物类群。本研究首次利用流式细胞术和K-mer分析方法对银缕梅属两姊妹种的基因组大小进行了测定,建立和优化了以萝卜(Raphanus sativus L.‘Saxa’)为内标、WPB(Woody plant buffer)为细胞核解离液的两种植物单倍体基因组的DNA含量(DNA C值)流式测定的适宜体系,旨在为金缕梅科银缕梅属植物的全基因组测序、基因组学研究、种质资源开发和利用以及物种保育等提供前期基础数据参考;同时也可为金缕梅科其他属、种的基因组大小测定提供借鉴。主要研究结果如下:(1)通过流式测定银缕梅基因组大小约为971.45±13.91 Mb,波斯铁木基因组大小约为890.52±24.69 Mb;(2)K-mer分析估测银缕梅基因组大小为951.70 Mb,杂合率为1.740%,重复序列比例为77.50%;波斯铁木基因组大小为858.50 Mb,杂合率为0.695%,重复序列占74.30%;(3)银缕梅属于高杂合和高重复基因组,波斯铁木则属于微杂合和高重复基因组。本研究的结果为银缕梅属植物后续基于DNA三代高通量测序技术的全基因组测序、组装及去冗余处理等工作提供了重要的数据参考。     

Electrophoretic separation of the three Rhizobium meliloti replicons.

The megaplasmids and the chromosome from the bacterium Rhizobium meliloti 1021 were separated in preparative quantities by using transverse alternating-field gel electrophoresis. The genetic content of each electrophoretically separated band was determined by Southern hybridization with replicon-specific probes and by comparison with Agrobacterium tumefaciens transconjugants harboring either pSym-a or pSym-b megaplasmids. Pulsed-field gel electrophoresis analyses of PacI (5'-TTAATTAA-3') and SwaI (5'-ATTTAAAT-3') digests of the whole genome and of the separated replicons were used to calculate genome sizes in two R. meliloti strains. In these strains, PacI digestion yielded only four fragments for the entire genome. The sizes of the PacI fragments from R. meliloti 1021 in megabase pairs (Mb) were 3.32 +/- 0.30, 1.42 +/- 0.13, 1.21 +/- 0.10, and 0.55 +/- 0.08, for a total genome size of 6.50 +/- 0.61 Mb. Southern hybridization with replicon-specific probes assigned one PacI fragment to the chromosome of R. meliloti 1021, one to pRme1021a, and two to pRme1021b. PacI digestion of A. tumefaciens pTi-cured, pSym transconjugants confirmed these assignments. In agreement with PacI data, the addition of the six SwaI fragments from R. meliloti 1021 gave a genome size of 6.54 +/- 0.43 Mb. pRme1021a was calculated to be 1.42 +/- 0.13 Mb, 1.34 +/- 0.09 Mb, and 1.38 +/- 0.12 Mb on the basis of PacI digestion, SwaI digestion, and the migration of uncut pRme1021a, respectively. pRme1021b was calculated to be 1.76 +/- 0.18 Mb, 1.65 +/- 0.10 Mb, and 1.74 +/- 0.13 Mb on the basis of PacI digestion, SwaI digestion, and the migration of uncut pRme1021B, respectively. The R. meliloti 1021 chromosome was calculated to be 3.32 +/- 0.30 Mb, 3.55 +/- 0.24 Mb, and 3.26 +/- 0.46 Mb on the basis of PacI data, SwaI data, and the migration of uncut chromosome, respectively.