Uniqueness of the Gossypium mustelinum Genome Revealed by GISH and 45S rDNA FISH

Gossypium mustelinum ((AD)₄) is one of five disomic species in Gossypium. Three 45S ribosomal DNA (rDNA) loci were detected in (AD)₄ with 45S rDNA as probe, and three pairs of brighter signals were detected with genomic DNA (gDNA) of Gossypium D genome species as probes. The size and the location of these brighter signals were the same as those detected with 45S rDNA as probe, and were named GISH-NOR. One of them was super-major, which accounted for the fact that about one-half of its chromosome at metaphase was located at chromosome 3, and other two were minor and located at chromosomes 5 and 9, respectively. All GISH-NORs were located in A sub-genome chromosomes, separate from the other four allopolyploid cotton species. GISH-NOR were detected with D genome species as probe, but not A. The greatly abnormal sizes and sites of (AD)₄ NORs or GISH-NORs indicate a possible mechanism for 45S rDNA diversification following (AD)₄ speciation. Comparisons of GISH intensities and GISH-NOR production with gDNA probes between A and D genomes show that the better relationship of (AD)₄ is with A genome. The shortest two chromosomes of A sub-genome of G. mustelinum were shorter than the longest chromosome of D sub-genome chromosomes. Therefore, the longest 13 chromosomes of tetraploid cotton being classified as A sub-genome, while the shorter 13 chromosomes being classified as D sub-genome in traditional cytogenetic and karyotype analyses may not be entirely correct.     

中国17种蔷薇属植物45S和5S的rDNA分布研究

为了探寻蔷薇属植物亲缘关系及系统发育研究的分子细胞遗传学证据,该研究采用双色FISH(荧光原位杂交)技术,对原产中国7个组的17种蔷薇属植物的45S和5S rDNA进行了定位分析。结果表明:(1)多数蔷薇属植物1组染色体对应1个45S rDNA位点和1个或2个5S rDNA位点,偶尔出现1~2个rDNA位点的丢失,但复伞房蔷薇(Rosa brunonii)的1组染色体对应了2个45S rDNA位点。(2)二倍体的蔷薇属植物至少有1对5S rDNA位点与45S rDNA位点共定位,而四倍体材料的5S rDNA位点与45S rDNA位点没有共定位,但所有四倍体材料均至少有1种rDNA信号纯合,表明它们应为二倍体直接加倍产生的同源四倍体。(3)绝大多数材料45S rDNA位于染色体短臂、5S rDNA位于染色体长臂,但缫丝花(R. roxburghii f. roxburghii)有1个5S rDNA信号位于染色体的短臂上,表明它与蔷薇属其他种的亲缘关系较远。(4)阿克苏地区和伊犁地区的疏花蔷薇的核型不同,且45S和5S rDNA的数量和位置不同,分子细胞遗传学证据也支持阿克苏地区的疏花蔷薇应为疏花蔷薇的新变种。(5)该研究中共有8个二倍体和6个四倍体蔷薇属植物的双色FISH为首次报道。研究认为,无论二倍体还是四倍体蔷薇属植物中出现的异形同源染色体、rDNA信号位置在同源染色体上的差异以及rDNA信号的增加和丢失,可能都与染色体结构变异和染色体重组有关,在分子细胞遗传学水平上证明染色体结构变异和染色体重组在蔷薇属植物演化过程中具有重要的作用。     

Entire nucleotide sequences of Gossypium raimondii and G. arboreum mitochondrial genomes revealed A‐genome species as cytoplasmic donor of the allotetraploid species

• Cotton (Gossypium spp.) is commonly grouped into eight diploid genomic groups, designated A–G and K, and an allotetraploid genomic group, AD. Gossypium raimondii (D₅) and G. arboreum (A₂) are the putative contributors to the progenitor of G. hirsutum (AD₁), the economically important fibre‐producing cotton species.
• Mitochondrial DNA from week‐old etiolated seedlings was extracted from isolated organelles using discontinuous sucrose density gradient method. Mitochondrial genomes were sequenced, assembled, annotated and analysed in orderly.
• Gossypium raimondii (D₅) and G. arboreum (A₂) mitochondrial genomes were provided in this study. The mitochondrial genomes of two diploid species harboured circular genome of 643,914 bp (D₅) and 687,482 bp (A₂), respectively. They differ in size and number of repeat sequences, both contain illuminating triplicate sequences with 7317 and 10,246 bp, respectively, demonstrating dynamic difference and rearranged genome organisations. Comparing the D₅ and A₂ mitogenomes with mitogenomes of tetraploid Gossypium species (AD₁, G. hirsutum; AD₂, G. barbadense), a shared 11 kbp fragment loss was detected in allotetraploid species, three regions shared by G. arboreum (A₂), G. hirsutum (AD₁) and G. barbadense (AD₂), while eight regions were specific to G. raimondii (D₅). The presence/absence variations and gene‐based phylogeny supported that A‐genome is a cytoplasmic donor to the progenitor of allotetraploid species G. hirsutum and G. barbadense.
• The results present structure variations and phylogeny of Gossypium mitochondrial genome evolution.

     

Distribution of 5S and 18S–28S rDNA loci in a tetraploid cotton (Gossypium hirsutum L.) and its putative diploid ancestors

The most widely cultivated species of cotton,Gossypium hirsutum, is a disomic tetraploid (2n=4x=52). It has been proposed previously that extant A- and D-genome species are most closely related to the diploid progenitors of the tetraploid. We used fluorescent in situ hybridization (FISH) to determine the distribution of 5S and 18S-28S rDNA loci in the A-genome speciesG. herbaceum andG. arboreum, the D-genome speciesG. raimondii andG. thurberi, and the AD tetraploidG. hirsutum. High signal-to-noise, single-label FISH was used to enumerate rDNA loci, and simultaneous, dual-label FISH was used to determine the syntenic relationships of 5S rDNA loci relative to 18S–28S rDNA loci. These techniques provided greater sensitivity than our previous methods and permitted detection of six newG. hirsutum 18S–28S rDNA loci, bringing the total number of observed loci to 11. Differences in the intensity of the hybrizization signal at these loci allowed us to designate them as major, intermediate, or minor 18–28S loci. Using genomic painting with labeled A-genome DNA, five 18S–28S loci were localized to theG. hirsutum A-subgenome and six to the D-subgenome. Four of the 11 18S–28S rDNA loci inG. hirsutum could not be accounted for in its presumed diploid progenitors, as both A-genome species has three loci and both D-genome species had four.G. hirsutum has two 5S rDNA loci, both of which are syntenic to major 18S–28S rDNA loci. All four of the diploid genomes wer examined contained a single 5S locus. InG. herbaceum (A₁) andG. thurberi (D₁), the 5S locus is syntenic to a major 18S–28S locus, but inG. arboreum (A₂) andG. raimondii (D₅), the proposed D-genome progenitor ofG. hirsutum, the 5S loci are syntenic tominor and intermediate 18S–28S loci, respecitively. The multiplicity, variation in size and site number, and lack of additivity between the tetraploid species and its putative diploid ancestors indicate that the behavior of rDNA loci in cotton is nondogmatic, and considerably more complex and dynamic than previously envisioned. The relative variability of 18S–28S rDNA loci versus 5S rDNA loci suggests that the behavior of tandem repearts can differ widely. Edited by: R. Appels     

The use of double fluorescence in situ hybridization to physically map the positions of 5S rDNA genes in relation to the chromosomal location of 18S-5.8S-26S rDNA and a C genome specific DNA sequence in the genus Avena.

A physical map of the locations of the 5S rDNA genes and their relative positions with respect to 18S-5.8S-26S rDNA genes and a C genome specific repetitive DNA sequence was produced for the chromosomes of diploid, tetraploid, and hexaploid oat species using in situ hybridization. The A genome diploid species showed two pairs of rDNA loci and two pairs of 5S loci located on both arms of one pair of satellited chromosomes. The C genome diploid species showed two major pairs and one minor pair of rDNA loci. One pair of subtelocentric chromosomes carried rDNA and 5S loci physically separated on the long arm. The tetraploid species (AACC genomes) arising from these diploid ancestors showed two pairs of rDNA loci and three pairs of 5S loci. Two pairs of rDNA loci and 2 pairs of 5S loci were arranged as in the A genome diploid species. The third pair of 5S loci was located on one pair of A-C translocated chromosomes using simultaneous in situ hybridization with 5S rDNA genes and a C genome specific repetitive DNA sequence. The hexaploid species (AACCDD genomes) showed three pairs of rDNA loci and six pairs of 5S loci. One pair of 5S loci was located on each of two pairs of C-A/D translocated chromosomes. Comparative studies of the physical arrangement of rDNA and 5S loci in polyploid oats and the putative A and C genome progenitor species suggests that A genome diploid species could be the donor of both A and D genomes of polyploid oats. Key words : oats, 5S rDNA genes, 18S-5.8S-26S rDNA genes, C genome specific repetitive DNA sequence, in situ hybridization, genome evolution.     

Chromosomal localization of 45S and 5S rDNA in 14 species and the implications for genome evolution of genus Epimedium

Studying the genome structure of Epimedium has been hindered by the large genomes and uniform karyotypes. Consequently our understanding of the genome organization and evolutionary changes of Epimedium is extremely limited. In the present study, the 45S and 5S rDNA loci of 14 Epimedium species were physically mapped by double-probe FISH for the first time. Results showed the following: (1) Chromosomes I and II of all 14 species examined, except for E. shuichengense, hosted one pair of 45S rDNA sites, respectively. Most of the 45S rDNA sites gave clear signals and were positioned in the distal regions of the short arms. (2) All species studied of section Diphyllon were found to have one pair of 5S rDNA sites localized in the interstitial regions of the long arm of chromosome IV, and the two species of section Epimedium, E. alpinum and E. pubigerum, had two pairs of 5S rDNA sites localized in the interstitial regions of the long arm of chromosomes IV and V, respectively. (3) In section Diphyllon, all species of small flower taxa, except E. shuichengense, had three pairs of 45S rDNA sites, clearly more than species of big flower taxa, except E. davidii, with two pairs of 45S rDNA sites. Based on the 45S and 5S rDNA distribution patterns and other chromosomal morphological characteristics, six pairs of chromosomes can be unambiguously identified in all 14 Epimedium species. The stable differentiation in 45S and 5S rDNA FISH patterns between the two sections suggests that chromosomal rearrangements and transpositional events played a role in the splitting of the two sections, and section Diphyllon may be more primitive than section Epimedium. In the same way, big flower taxa may be more primitive than small flower taxa in section Diphyllon.     

A comparative cytogenetic study of the tetraploid oat species with the A and C genomes: <Emphasis Type="Italic">Avena insularis,A. magna</Emphasis>, and <Emphasis Type="Italic">A. murphyi</Emphasis>

C-banding of chromosomes and in situ hybridization with the probes pTa71 and pTa794 were used for a comparative cytogenetic study of the three tetraploid oat species with the A and C genomes: Avena insularis, A. magna, and A. murphyi. These species were similar in the structure and C-banding patterns of several chromosomes as well as in the location of the loci 5S rRNA genes and major NOR sites; however, they differed in the number and localization of minor 45S rDNA loci as well as in the morphology and distribution of heterochromatin in some chromosomes. According to the data obtained, A. insularis is closer to A. magna, whereas A. murphyi is somewhat separated from these two species. Presumably, all the three studied species originated from the same tetraploid ancestor, and their divergence is connected with various species-specific chromosome rearrangements. The evolution of A. murphyi is likely to have occurred independently of the other two species.     

Genome differentiation in Aegilops. 3. Evolution of the D-genome cluster

 Six polyploid Aegilops species containing the D genome were studied by C-banding and fluorescence in situ hybridization (FISH) using clones pTa71 (18S-5.8S-26S rDNA), pTa794 (5S rDNA), and pAs1 (non-coding repetitive DNA sequence) as probes. The C-banding and pAs1-FISH patterns of Ae. cylindrica chromosomes were identical to those of the parental species. However, inactivation of the NOR on chromosome 5D with a simultaneous decrease in the size of the pTa71-FISH site was observed. The N^v and D^v genomes of Ae. ventricosa were somewhat modified as compared with the N genome of Ae. uniaristata and the D genome of Ae. tauschii. Modifications included minor changes in the C-banding and pAs1-FISH patterns, complete deletion of the NOR on chromosome 5D^v, and the loss of several minor 18S-5.8S-26S rDNA loci on N^v genome chromosomes. According to C-banding and FISH analyses, the D^cr1 genome of Ae. crassa is more similar to the D^v genome of Ae. ventricosa than to the D genome of Ae. tauschii. Mapping of the 18S-5.8S-26S rDNA and 5S rDNA loci by multicolor FISH suggests that the second (X^cr) genome of tetraploid Ae. crassa is a derivative of the S genome (section Emarginata of the Sitopsis group). Both genomes of Ae. crassa were significantly modified as the result of chromosomal rearrangements and redistribution of highly repetitive DNA sequences. Hexaploid Ae. crassa and Ae. vavilovii arose from the hybridization of chromosomal type N of tetraploid Ae. crassa with Ae. tauschii and Ae. searsii, respectively. Chromosomal type T1 of tetraploid Ae. crassa and Ae. umbellulata were the ancestral forms of Ae. juvenalis. The high level of genome modification in Ae. juvenalis indicates that it is the oldest hexaploid species in this group. The occurrence of hexaploid Ae. crassa was accompanied by a species-specific translocation between chromosomes 4D^cr1 and 7X^cr. No chromosome changes relative to the parental species were detected in Ae. vavilovii, however, its intraspecific diversity was accompanied by a translocation between chromosomes 3X^cr and 3D^cr1. Received July 24, 2001 Accepted October 1, 2001     

Distribution of 45S and 5S rDNA sites in 23 species of Eleocharis (Cyperaceae)

Studies of rDNA location in holocentric chromosomes of the Cyperaceae are scarce, but a few reports have indicated the occurrence of multiple 45S rDNA sites at terminal positions, and in the decondensed state of these regions in prometaphase/metaphase. To extend our knowledge of the number 45S and 5S rDNA sites and distribution in holocentric chromosomes of the Cyperaceae, 23 Brazilian species of Eleocharis were studied. FISH showed 45S rDNA signals always located in terminal regions, which varied from two (E. bonariensis with 2n = 20) to ten (E. flavescens with 2n = 10 and E. laeviglumis with 2n = 60). 5S rDNA showed less variation, with 16 species exhibiting two sites and 7 species four sites, preferentially at terminal positions, except for four species (E. subarticulata, E. flavescens, E. sellowiana and E. geniculata) that showed interstitial sites. The results are discussed in order to understand the predominance of terminal rDNA sites, the mechanisms involved in the interstitial positioning of 5S rDNA sites in some species, and the events of amplification and dispersion of 45S rDNA terminal sites.     

Extensive and Biased Intergenomic Nonreciprocal DNA Exchanges Shaped a Nascent Polyploid Genome,Gossypium (Cotton)

Genome duplication is thought to be central to the evolution of morphological complexity, and some polyploids enjoy a variety of capabilities that transgress those of their diploid progenitors. Comparison of genomic sequences from several tetraploid (A_tD_t) Gossypium species and genotypes with putative diploid A- and D-genome progenitor species revealed that unidirectional DNA exchanges between homeologous chromosomes were the predominant mechanism responsible for allelic differences between the Gossypium tetraploids and their diploid progenitors. Homeologous gene conversion events (HeGCEs) gradually subsided, declining to rates similar to random mutation during radiation of the polyploid into multiple clades and species. Despite occurring in a common nucleus, preservation of HeGCE is asymmetric in the two tetraploid subgenomes. A_t-to-D_t conversion is far more abundant than the reciprocal, is enriched in heterochromatin, is highly correlated with GC content and transposon distribution, and may silence abundant A-genome-derived retrotransposons. D_t-to-A_t conversion is abundant in euchromatin and genes, frequently reversing losses of gene function. The long-standing observation that the nonspinnable-fibered D-genome contributes to the superior yield and quality of tetraploid cotton fibers may be explained by accelerated D_t to A_t conversion during cotton domestication and improvement, increasing dosage of alleles from the spinnable-fibered A-genome. HeGCE may provide an alternative to (rare) reciprocal DNA exchanges between chromosomes in heterochromatin, where genes have approximately five times greater abundance of D_t-to-A_t conversion than does adjacent intergenic DNA. Spanning exon-to-gene-sized regions, HeGCE is a natural noninvasive means of gene transfer with the precision of transformation, potentially important in genetic improvement of many crop plants.     

Molecular cytogenetics studies in Reichardia tingetana: Physical mapping of heterochromatin,telomere repeats,and 5S and 45S rDNA by 4′, 6‐diamidino‐2‐phenylindole and fluorescence in situ hybridization

Abstract Molecular cytogenetics studies of A‐T‐rich regions, telomeres, and 5S and 45S rDNA sites on the chromosomes of Reichardia tingetana Roth (2n= 16; diploid) were done using 4′, 6‐diamidino‐2‐phenylindole (DAPI) and fluorescence in situ hybridization (FISH). The species were collected from three geographically isolated populations at Borg El Arab (salt marsh habitat), and Rashed and Shosha (sandy clay habitats) in Egypt. The three populations showed the chromosome number of all plants are diploid except for two tetraploid samples from Shosha. Plants from both Rashed and Shosha showed similarity in the distribution of six DAPI bands on six chromosomes, whereas those of Borg El Arab showed a distribution of 16 bands on 14 chromosomes. The FISH signals of the telomeres, and 5S and 45S rDNA, were at the telomeres of all chromosomes, two interstitial, and four terminal, respectively. The combination of DAPI and FISH showed colocalization of the DAPI bands with two 5S and two 45S rDNA loci. The increased number of DAPI bands in the cytotypes from the salt marsh habitat could indicate natural genetic adaptation through increasing the heterochromatin of A‐T‐rich regions.     

Analysis of complete nucleotide sequences of 12 gossypium chloroplast genomes: origin and evolution of allotetraploids

Background

Cotton (Gossypium spp.) is a model system for the analysis of polyploidization. Although ascertaining the donor species of allotetraploid cotton has been intensively studied, sequence comparison of Gossypium chloroplast genomes is still of interest to understand the mechanisms underlining the evolution of Gossypium allotetraploids, while it is generally accepted that the parents were A- and D-genome containing species. Here we performed a comparative analysis of 13 Gossypium chloroplast genomes, twelve of which are presented here for the first time.

Methodology/Principal Findings

The size of 12 chloroplast genomes under study varied from 159,959 bp to 160,433 bp. The chromosomes were highly similar having >98% sequence identity. They encoded the same set of 112 unique genes which occurred in a uniform order with only slightly different boundary junctions. Divergence due to indels as well as substitutions was examined separately for genome, coding and noncoding sequences. The genome divergence was estimated as 0.374% to 0.583% between allotetraploid species and A-genome, and 0.159% to 0.454% within allotetraploids. Forty protein-coding genes were completely identical at the protein level, and 20 intergenic sequences were completely conserved. The 9 allotetraploids shared 5 insertions and 9 deletions in whole genome, and 7-bp substitutions in protein-coding genes. The phylogenetic tree confirmed a close relationship between allotetraploids and the ancestor of A-genome, and the allotetraploids were divided into four separate groups. Progenitor allotetraploid cotton originated 0.43–0.68 million years ago (MYA).

Conclusion

Despite high degree of conservation between the Gossypium chloroplast genomes, sequence variations among species could still be detected. Gossypium chloroplast genomes preferred for 5-bp indels and 1–3-bp indels are mainly attributed to the SSR polymorphisms. This study supports that the common ancestor of diploid A-genome species in Gossypium is the maternal source of extant allotetraploid species and allotetraploids have a monophyletic origin. G. hirsutum AD1 lineages have experienced more sequence variations than other allotetraploids in intergenic regions. The available complete nucleotide sequences of 12 Gossypium chloroplast genomes should facilitate studies to uncover the molecular mechanisms of compartmental co-evolution and speciation of Gossypium allotetraploids.     

Localization of high level of sequence conservation and divergence regions in cotton

In a previous study, we observed that the variations in chromosome size are due to uneven expansion and contraction by comparing the structures and sizes of a pair of homoeologous high-resolution cytogenetic maps of chromosomes 12A and 12D in tetraploid cotton. To reveal the variation at the sequence level, in the present paper, we sequenced two pairs of homoeologous bacterial artificial chromosomes derived from high- to low-variable genomic regions. Comparisons of their sequence variations confirmed that the highly conserved and divergent sequences existed in the distal and pericentric regions, e.g., high- and low-variable genome size regions in these two pairs of cotton homoeologous chromosomes. Sequence analysis also confirmed that the differential accumulation of Gossypium retrotransposable gypsy-like element (Gorge3) accounted for the main contributions for the size difference between the pericentric regions. By fluorescence in situ hybridization analysis, we found that Gorge3 has a bias distribution in the A_T/A proximal regions and is associated with the heterochromatin along the chromosomes in the entire Gossypium genome. These results indicate that, between A_T/A and D_T/D genomes, the distal and pericentric regions usually possess high level of sequence conservation and divergence, respectively, in cotton.     

Incipient Genome Differentiation in Gossypium. I. Chromosomes 14, 15, 16, 19 and 20 Assessed in G. HIRSUTUM, G. RAIMONDII and G. LOBATUM by Means of Seven a-D Translocations

The genus Gossypium is favorable for study of genome divergence at several levels. Early stages of divergence have been studied among four D genomes by comparing chiasma frequencies (reciprocal exchanges) between pairs of genomes and between individual counterpart chromosomes marked by heterozygous translocations. D₅ (G. raimondii) shows barely detectable differentiation from from D_h (G. hirsutum), whereas D₇ (G. lobatum) is considerably less closely related to D_h than is D₅. Fragmentary data suggest that D_2–2 (G. harknessii) falls between D₅ and D₇ in its relationship to D_h. Since chiasma frequencies in individual chromosomes and marked regions exhibit the same order of relationships as their corresponding whole genomes, it is concluded that the genome differentiation is generalized (i.e., nucleus-wide) rather than localized in specific chromosomes or chromosome regions. Estimates of relationships based on reciprocal exchange frequencies agree with those based upon preferential synapsis in allohexaploids reported previously. Since preferential synapsis and reciprocal exchange frequencies reveal the same order of relationships, it is concluded that to some extent they reflect common underlying changes in chromosome properties, despite recent evidence that synapsis and crossing over are under independent genetic control.     

FISH-aimed karyotype analysis in <Emphasis Type="Italic">Aconitum</Emphasis> subgen. <Emphasis Type="Italic">Aconitum</Emphasis> reveals excessive rDNA sites in tetraploid taxa

The location of 5S and 35S rDNA sequences in chromosomes of four Aconitum subsp. Aconitum species was analyzed after fluorescence in situ hybridization (FISH). Both in diploids (2n?=?2x?=?16; Aconitum variegatum, A. degenii) and tetraploids (2n?=?4×?=?32; A. firmum, A. plicatum), rDNA repeats were localized exclusively on the shorter arms of chromosomes, in subterminal or pericentromeric sites. All analyzed species showed similar basal genome size (Cx?=?5.31–5.71 pg). The most striking features of tetraploid karyotypes were the conservation of diploid rDNA loci and emergence of many additional 5S rDNA clusters. Chromosomal distribution of excessive ribosomal sites suggests their role in the secondary diploidization of tetraploid karyotypes.     

Individual chromosome assignment and chromosomal collinearity in Gossypium thurberi, G. trilobum and D subgenome of G. barbadense revealed by BAC-FISH

The experiment on individual chromosome assignments and chromosomal diversity was conducted using a multi-probe fluorescence in situ hybridization (FISH) system in D subgenome of tetraploid Gossypium barbadense (D(b)), G. thurberi (D(1)) and G. trilobum (D(8)), which the later two were the possible subgenome donors of tetraploid cottons. The FISH probes contained a set of bacterial artificial chromosome (BAC) clones specific to 13 individual chromosomes from D subgenome of G. hirsutum (D(h)), a D genome centromere-specific BAC clone 150D24, 45S and 5S ribosomal DNA (rDNA) clones, respectively. All tested chromosome orientations were confirmed by the centromere-specific BAC probe. In D(1) and D(8), four 45S rDNA loci were found assigning at the end of the short arm of chromosomes 03, 07, 09 and 11, while one 5S rDNA locus was successfully marked at pericentromeric region of the short arm of chromosome 09. In D(b), three 45S rDNA loci and two 5S rDNA loci were found out. Among them, two 45S rDNA loci were located at the terminal of the short arm of chromosomes D(b)07 and D(b)09, whilst one 5S rDNA locus was found situating near centromeric region of the short arm of chromosome D(b)09. The positions of the BAC clones specific to the 13 individual chromosomes from D(h) were compared between D(1), D(8) and D(b). The result showed the existence of chromosomal collinearity within D(1) and D(8), and as well between them and D(b). The results will serve as a base for understanding chromosome structure of cotton and polyploidy evolution of cotton genome and will provide bio-information for assembling the sequences of finished and the on-going cotton whole genome sequencing projects.     

Localization of 5S and 25S rRNA genes on Somatic and meiotic chromosomes in <Emphasis Type="Italic">Capsicum</Emphasis> species of chili pepper

The loci of the 5S and 45S rRNA genes were localized on chromosomes in five species of Capsicum, namely, an-nuum, chacoense, frutescens, baccatum, and chinense by FISH. The 5S rDNA was localized to the distal region of one chromosome in all species observed. The number of 45S rDNA loci varied among species; one in annuum, two in chacoense, frutescens, and chinense, and four in baccatum, with the exceptions that ‘CM334’ of annuum had three loci and ‘tabasco’ of frutescens had one locus. ‘CM334’-derived BAC clones, 384B09 and 365P05, were screened with 5S rDNA as a probe, and BACs 278M03 and 262A23 were screened with 25S rDNA as a probe. Both ends of these BAC clones were sequenced. FISH with these BAC probes on pachytenes from ‘CM334’ plant showed one 5S rDNA locus and three 45S rDNA loci, consistent with the patterns on the somatic chromosomes. The 5S rDNA probe was also applied on extended DNA fibers to reveal that its coverage measured as long as 0.439 Mb in the pepper genome. FISH techniques applied on somatic and meiotic chromosomes and fibers have been established for chili to provide valuable information about the copy number variation of 45S rDNA and the actual physical size of the 5S rDNA in chili.     

Chromosome Localization of 5S and 45S Ribosomal DNA in the Genomes of Linum L. Species of the Section Linum (Syn. Protolinum and Adenolinum)

Fluorescence in situ hybridization (FISH) was for the first time used to study the chromosomal location of the 45S (18S–5.8S–26S) and 5S ribosomal genes in the genomes of five flax species of the section Linum (syn. Protolinum and Adenolinum). In L. usitatissimum L. (2n = 30), L. angustifolium Huds. (2n = 30), and L. bienne Mill. (2n = 30), a major hybridization site of 45S rDNA was observed in the pericentric region of a large metacentric chromosome. A polymorphic minor locus of 45S rDNA was found on one of the small chromosomes. Sites of 5S rDNA were colocalized with those of 45S rDNA, but direct correlation between signal intensities from the 45S and 5S rDNA sites was observed only in some cases. Other 5S rDNA sites mapped to two chromosomes in these flax species. In L. grandiflorum Desf. (2n = 16) and L. austriacum L. (2n = 18), large regions of 45S and 5S rDNA were similarly located on a pair of homologous satellite-bearing chromosomes. An additional large polymorphic site of 45S and 5S rDNA was found in the proximal region of one arm of a small chromosome in the L. usitatissimum, L. angustifolium, and L. bienne karyotypes. The other arm of this chromosome contained a large 5S rDNA cluster. A similar location of the ribosomal genes in the pericentric region of the pair of satellite-bearing metacentrics confirmed the close relationships of the species examined. The difference in chromosomal location of the ribosomal genes between flax species with 2n = 30 and those with 2n = 16 or 18 testified to their assignment to different sections. The use of ribosomal genes as chromosome markers was assumed to be of importance for comparative genomic studies in cultivated flax, a valuable crop species of Russia, and in its wild relatives.     

Contrasting patterns of the 5S and 45S rDNA evolutions in the <Emphasis Type="Italic">Byblis liniflora</Emphasis> complex (Byblidaceae)

To clarify the evolutionary dynamics of ribosomal RNA genes (rDNAs) in the Byblis liniflora complex (Byblidaceae), we investigated the 5S and 45S rDNA genes through (1) chromosomal physical mapping by fluorescence in situ hybridization (FISH) and (2) phylogenetic analyses using the nontranscribed spacer of 5S rDNA (5S-NTS) and the internal transcribed spacer of 45S rDNA (ITS). In addition, we performed phylogenetic analyses based on rbcL and trnK intron. The complex was divided into 2 clades: B. aquatica–B. filifolia and B. guehoi–B. liniflora–B. rorida. Although members of the complex had conservative symmetric karyotypes, they were clearly differentiated on chromosomal rDNA distribution patterns. The sequence data indicated that ITS was almost homogeneous in all taxa in which two or four 45S rDNA arrays were frequently found at distal regions of chromosomes in the somatic karyotype. ITS homogenization could have been prompted by relatively distal 45S rDNA positions. In contrast, 2–12 5S rDNA arrays were mapped onto proximal/interstitial regions of chromosomes, and some paralogous 5S-NTS were found in the genomes harboring 4 or more arrays. 5S-NTS sequence type-specific FISH analysis showed sequence heterogeneity within and between some 5S rDNA arrays. Interlocus homogenization may have been hampered by their proximal location on chromosomes. Chromosomal location may have affected the contrasting evolutionary dynamics of rDNAs in the B. liniflora complex.     

Incipient Genome Differentiation in Gossypium. III. Comparison of Chromosomes of G. HIRSUTUM and Asiatic Diploids Using Heterozygous Translocations

Hybrids between upland cotton (G. hirsutum, genome constitution 2A_hD_h) and either A-genome or D-genome diploid species exhibit 26 paired and 13 unpaired chromosomes at metaphase I. The A_h and D_h genomes are therefore considered homoeologous with those of the respective diploids. Previous studies, nevertheless, revealed a low level of ("incipient") differentiation between D_h and various diploid D genomes. The diploid A genomes have been regarded as more closely homologous to A_h on the basis of low preferential pairing and autotetraploid segregation ratios in allohexaploids.—The present study addressed the following questions: Are the diploid A genomes differentiated from A_h in meiotic homology? If so, is the differentiation manifested equally by all 13 chromosomes or is it localized in certain chromosomes?—Three diploid A-genome lines representing G. herbaceum and G. arboreum were hybridized by in ovulo culture of embryos (1) with a standard line of G. hirsutum, which differs from G. herbaceum by two and from G. arboreum by three naturally occurring reciprocal translocations involving chromosomes 1–5, and (2) with six lines homozygous for experimental translocations involving chromosomes 6, 7, 10, 11, 12 and 13. Chiasma frequencies in hybrids were compared with those in appropriate G. hirsutum controls. In every comparison overall chiasma frequencies were slightly lower in the hybrids. Therefore A_h appears to be differentiated from the diploid A genomes. No localized differentiation was detected in chromosomes marked by experimental translocations. The differentiation may be localized mainly in chromosomes 4 and 5.