Identification of C-genome chromosomes involved in intergenomic translocations in Avena sativa L., using cloned repetitive DNA sequences

Four anonymous non-coding sequences were isolated from an Avena strigosa (A genome) genomic library and subsequently characterized. These sequences, designated As14, As121, As93 and As111, were 639, 730, 668, and 619 bp long respectively, and showed different patterns of distribution in diploid and polyploid Avena species. Southern hybridization showed that sequences with homology to sequences As14 and As121 were dispersed throughout the genome of diploid (A genome), tetraploid (AC genomes) and hexaploid (ACD genomes) Avena species but were absent in the C-genome diploid species. In contrast, sequences homologous to sequences As93 and As111 were found in diploid (A and C genomes), tetraploid (AC genomes) and hexaploid (ACD genomes) species. The chromosomal locations of the 4 sequences in hexaploid oat species were determined by fluorescent in situ hybridization and found to be distributed over the length of the 28 chromosomes (except in the telomeric regions) of the A and D genomes. Furthermore, 2 C-genome chromosome pairs with the As14 sequence, and 4 with As121, were discovered to beinvolved in intergenomic translocations. These chromosomes were identified as 1C, 2C, 4C and 16C by combining the As14 or As121 sequences with two ribosomal sequences and a C-genome-specific sequence as probes in fluorescence in situ hybridization. These sequences offer new tools for analyzing possible intergenomic translocations in other hexaploid oat species. Received: 8 April 1999 / Accepted: 30 July 1999     

Differentiation and inter-genomic relationships among C, E and D genomes in the Oryzaofficinalis complex (Poaceae) as revealed by multicolor genomic in situ hybridization

The multicolor genomic in situ hybridization (McGISH) method was used to study differentiation and relationships among the C, D and E genomes in the officinalis complex of the genus Oryza. The chromosomes of Oryza alta (CCDD genomes) were hybridized with labelled probes of the C genome (from diploid Oryza eichingeri and Oryza officinalis) and the E genome (from Oryza australiensis) simultaneously. By adjusting the post-hybri- dization washing stringency in a gradual series, differentiation between the genomes was detected according to the homology between the target genomes and the probes. The McGISH results indicate that the C, D and E genomes share a substantial amount of similar sequences, and differentiation between the D and C genomes of O. alta is less than that between the E genome and each of the C and D genomes. The differentiation within the C genomes of the diploid species (O. officinalis and O. eichingeri) and the C genome of O. alta was clearly discerned by McGISH, suggesting strongly that neither O. officinalis nor O. eichingeri was the direct C-genome donor of O. alta. The evidence of the GISH results also indicates that the E genome was considerably differentiated from the C and D genomes. Therefore, the E genome should not be the direct donor of O. alta; on the contrary, the E genome is closer to the C than to the D genome. McGISH is an efficient method in revealing the relationships among the genomes in question, particularly under the gradual stringent-washing condition. Received: 14 February 2000 / Accepted: 14 November 2000     

Phylogeny of the a genomes of wild and cultivated wheat species

Diploid species of the genus Triticum L. are its most ancient representatives and have the A genome, which was more recently inherited by all polyploid species. Studies of the phylogenetic relationships among diploid and polyploid wheat species help to identify the donors of elementary genomes and to examine the species specificity of genomes. In this study, molecular analysis of the variable sequences of three nuclear genes (Acc-1, Pgk-1, and Vrn-1) was performed for wild and cultivated wheat species, including both diploids and polyploids. Based on the sequence variations found in the genes, clear differences were observed among elementary genomes, but almost no polymorphism was detected within each genome in polyploids. At the same time, the regions of the three genes proved to be rather heterogeneous in the diploid species Triticum boeoticum Boiss., T. urartu Thum. ex Gandil., and T. monococcum L., thus representing mixed populations. A genome variant identical to the A genome of polyploid species was observed only in T. urartu. Species-specific molecular markers discriminating the diploid species were not found. Analysis of the inheritance of morphological characters also failed to identify a species-specific character for the three diploid wheat species apart from the hairy leaf blade type, described previously.     

Spatial and temporal expression of the two sucrose synthase genes in maize: immunohistological evidence

Summary The DNAs of two diploid species of Gossypium, G. herbaceum var. africanum (A₁ genome) and G. raimondii (D₅ genome), and the allotetraploid species, G. hirsutum (A_h and D_h genomes), were characterized by kinetic analyses of single copy and repetitive sequences. Estimated haploid genome sizes of A₁ and D₅ were 1.04 pg and 0.68 pg, respectively, in approximate agreement with cytological observations that A genome chromosomes are about twice the size of D genome chromosomes. This differences in genome size was accounted for entirely by differences in the major repetitive fraction (0.56 pg versus 0.20 pg), as single copy fractions of the two genomes were essentially identical (0.41 pg for A₁ and 0.43 pg for D₅). Kinetic analyses and thermal denaturation measurements of single copy duplexes from reciprocal intergenomic hybridizations showed considerable sequence similarity between A₁ and D₅ genomes (77% duplex formation with an average thermal depression of 6 °C). Moreover, little sequence divergence was detectable between diploid single copy sequences and their corresponding genomes in the allotetraploid, consistent with previous chromosome pairing observations in interspecific F₁ hybrids.Journal paper No. 4461 of the Arizona Agricultural Experiment Station     

Phylogenetic analysis of Oryza species, based on simple sequence repeats and their flanking nucleotide sequences from the mitochondrial and chloroplast genomes

Simple sequence repeats (SSR) and their flanking regions in the mitochondrial and chloroplast genomes were sequenced in order to reveal DNA sequence variation. This information was used to gain new insights into phylogenetic relationships among species in the genus Oryza. Seven mitochondrial and five chloroplast SSR loci equal to or longer than ten mononucleotide repeats were chosen from known rice mitochondrial and chloroplast genome sequences. A total of 50 accessions of Oryza that represented six different diploid genomes and three different allopolyploid genomes of Oryza species were analyzed. Many base substitutions and deletions/insertions were identified in the SSR loci as well as their flanking regions. Of mononucleotide SSR, G (or C) repeats were more variable than A (or T) repeats. Results obtained by chloroplast and mitochondrial SSR analyses showed similar phylogenetic relationships among species, although chloroplast SSR were more informative because of their higher sequence diversity. The CC genome is suggested to be the maternal parent for the two BBCC genome species (O. punctata and O. minuta) and the CCDD species O. latifolia, based on the high level of sequence conservation between the diploid CC genome species and these allotetraploid species. This is the first report of phylogenetic analysis among plant species, based on mitochondrial and chloroplast SSR and their flanking sequences.     

Divergence of the polytene chromosome banding sequences as a reflection of evolutionary rearrangements of the genome linear structure

Banding sequences of five chromosomal arms (A, C, D, E, and F), accounting for about 70% of the total genome size in 63 Chironomus species, were used as markers to analyze divergence patterns of the linear genome structure during the evolution. The number of chromosomal breakpoints between the pairs of banding sequences compared served as a measure of divergence. It was demonstrated that the greater the divergence between the species compared, the higher the number of chromosomal breakpoints and the smaller the size of the conserved chromosomal segments. A banding sequences comparison in sibling species demonstrated a lower number of chromosomal breakpoints; the breakpoint number was maximum in a comparison of the banding sequences in the subgenera Chironomus and Camptochironomus. The use of the number of chromosomal breakpoints as a genome divergence measure provided establishment of phylogenetic relationships between 63 Chironomus species and discrimination of sibling species groups and cytocomplexes on a phylogenetic tree.Translated from Genetika, Vol. 41, No. 2, 2005, pp. 187–195.Original Russian Text Copyright © 2005 by Gunderina, Kiknadze, Istomina, Gusev, Miroshnichenko.     

Patterns of genome duplication within the Brassica napus genome.

The progenitor diploid genomes (A and C) of the amphidiploid Brassica napus are extensively duplicated with 73% of genomic clones detecting two or more duplicate sequences within each of the diploid genomes. This comprehensive duplication of loci is to be expected in a species that has evolved through a polyploid ancestor. The majority of the duplicate loci within each of the diploid genomes were found in distinct linkage groups as collinear blocks of linked loci, some of which had undergone a variety of rearrangements subsequent to duplication, including inversions and translocations. A number of identical rearrangements were observed in the two diploid genomes, suggesting they had occurred before the divergence of the two species. A number of linkage groups displayed an organization consistent with centric fusion and (or) fission, suggesting this mechanism may have played a role in the evolution of Brassica genomes. For almost every genetically mapped locus detected in the A genome a homologous locus was found in the C genome; the collinear arrangement of these homologous markers allowed the primary regions of homoeology between the two genomes to be identified. At least 16 gross chromosomal rearrangements differentiated the two diploid genomes during their divergence from a common ancestor.     

Rapid proliferation and nucleolar organizer targeting centromeric retrotransposons in cotton

Centromeric chromatin in most eukaryotes is composed of highly repetitive centromeric retrotransposons and satellite repeats that are highly variable even among closely related species. The evolutionary mechanisms that underlie the rapid evolution of centromeric repeats remain unknown. To obtain insight into the evolution of centromeric repeats following polyploidy, we studied a model diploid progenitor (Gossypium raimondii, D‐genome) of the allopolyploid (AD‐genome) cottons, G. hirsutum and G. barbadense. Sequence analysis of chromatin‐immunoprecipitated DNA showed that the G. raimondii centromeric repeats originated from retrotransposon‐related sequences. Comparative analysis showed that nine of the 10 analyzed centromeric repeats were absent from the centromeres in the A‐genome and related diploid species (B‐, F‐ and G‐genomes), indicating that they colonized the centromeres of D‐genome lineage after the divergence of the A‐ and D‐ ancestral species or that they were ancestrally retained prior to the origin of Gossypium. Notably, six of the nine repeats were present in both the A‐ and D‐subgenomes in tetraploid G. hirsutum, and increased in abundance in both subgenomes. This finding suggests that centromeric repeats may spread and proliferate between genomes subsequent to polyploidization. Two repeats, Gr334 and Gr359 occurred in both the centromeres and nucleolar organizer regions (NORs) in D‐ and AD‐genome species, yet localized to just the NORs in A‐, B‐, F‐, and G‐genome species. Contained within is a story of an established centromeric repeat that is eliminated and allopolyploidization provides an opportunity for reinvasion and reestablishment, which broadens our evolutionary understanding behind the cycles of centromeric repeat establishment and targeting.     

Multidisciplinary approach to genome analysis in the diploid species,Thinopyrum bessarabicum and Th. elongatum (Lophopyrum elongatum), of the Triticeae

Summary The J and E genome species of the Triticeae are invaluable sources of salt tolerance. The evidence concerning the phyletic relatedness of the J genome of diploid Thinopyrum bessarabicum and the E genome of diploid Th. elongatum (=Lophopyrum elongatum) is discussed. Low level of chromosome pairing between J and E at different ploidy levels, suppression of J-E pairing by the Ph1 pairing regulator that inhibits homoeologous pairing, complete sterility of the diploid hybrids (JE), karyotypic divergence of the two genomes, differences in total content and distribution of heterochromatin along their chromosomes, and marked differences in gliadin proteins, isozymes, 5S DNA, and rDNA indicate that J and E are distinct genomes. Well-defined biochemical markers have been identified in the two genomes and may be useful in plant breeding. The level of distinction between J and E is comparable to that among the universally accepted homoeologous genomes A, B, and D of wheat. Therefore, the J and E genomes are homoeologous and not homologous, although some workers continue to call them homologous. The previous workers' data on chromosome pairing in diploid hybrids and/ or karyotypic differences in the conventionally stained chromosomes do not provide sufficient evidence for the proposed merger of J and E genomes (and, hence, of the genera Thinopyrum and Lophopyrum) specifically and for establishing genome relationships generally. Extra precautions should be exercised before changing the designation of an established genome and before merging two genera. A uniform, standardized system of genomic nomenclature for the entire Triticeae is proposed, which should benefit cytogeneticists, plant breeders, taxonomists, and evolutionists.Cooperative investigations of the USDA-Agricultural Research Service and the Utah Agricultural Experiment Station, Logan, UT 84322, USA. Approved as Journal Paper no. 3832     

Repetitive DNA, Genome and Species Relationships in Avena and Arrhenatherum(Poaceae)

Repetitive sequences have been widely used for examining genomeand species relationships by in situ and Southern hybridization.In the present study, double-stranded DNA sequences, from denaturedDNA reannealed to Cot = 1, from Avena strigosa(2 n = 2x = 14;A genome; referred to as CotA) and Avena sativa(2n = 6 x =42; ACD genome; referred to as CotACD) were isolated with ahydroxyapatite column, and were used for in situ hybridizationon hexaploid A. sativa chromosomes. Probe CotACD labelled allchromosomes evenly throughout their length at the same intensity.Probe CotA labelled the 28 A and D genome chromosomes stronglyand the 14 C genome chromosomes weakly. Three cloned repetitivesequences, pAvKB9 (126 bp), pAvKB26 (223 bp) and pAvKB32 (721bp) were characterized in the A, B, C and D Avena genomes andthe genus Arrhenatherum using molecular and cytological methods.Clones pAvKB9 and pAvKB26 were absent from the Avena C genome,while both could identify the presence of the D genome by Southernhybridization. In situ hybridization to diploid and tetraploidAvena species revealed that the probes showed a dispersed genomicorganization and that they are present on both arms of all chromosomes.These sequences were excluded from areas where tandem repeats,such as rRNA genes and telomeres, are present. These resultsindicate the close relationship between A and D genomes andthe presence of common DNA sequences between A and C Avena genomes.All three clones hybridized to Southern blots containingArrhenatherumdigested genomic DNA, indicating Arrhenatherum’s closeaffinity to A, B and D Avena genomes. Copyright 2000 Annalsof Botany Company Cereals, DNA, hydroxyapatite, in situ hybridization, oats, reassociation kinetics, repetitive DNA     

Evolutionary analysis of the CACTA DNA-transposon Caspar across wheat species using sequence comparison and in situ hybridization

Mobile elements constitute a considerable part of the eukaryotic genome. This work is focused on the distribution and evolution of DNA-transposons in the genomes of diploid and allopolyploid Triticeae species and their role in the formation of functionally important chromosomal subtelomeric regions. The Caspar family is among the most abundant of CACTA DNA-transposons in Triticeae. To study the evolution of Caspar-like elements in Triticeae genomes, we analyzed their sequences and distribution in chromosomes by in situ hybridization. In total, 46 Caspar-like elements from the wheat and barley Caspar, Clifford, and Donald families were analyzed after being extracted from databases using the transposase consensus sequence. Sequence alignment and subsequent phylogenetic analyses revealed that the transposase DNA sequences formed three major distinct groups: (1) Clifford, (2) Caspar_Triticinae, and (3) Caspar_Hordeinae. Additionally, in situ hybridization demonstrated that Caspar_Triticinae transposons are predominantly compartmentalized in the subtelomeric chromosomal regions of wheat and its progenitors. Analysis of data suggested that compartmentalization in the subtelomeric chromosomal region was a characteristic feature of all the main groups of Caspar-like elements. Furthermore, a dot plot analysis of the terminal repeats demonstrated that the divergence of these repeats strictly correlated with the divergence of Caspar coding sequences. A clear distinction in the Caspar DNA sequences among the species Triticum/Aegilops (Caspar_Triticinae), Hordeum (Caspar_Hordeinae), and different distributions in individual hexaploid wheat genomes (A/B and D) suggest an independent proliferation of these elements in wheat (or its progenitors) and barley genomes. Thus, Caspar-like transposons can significantly contribute to the formation and differentiation of subtelomeric regions in Triticeae species.     

The evolution pattern of rDNA ITS in Avena and phylogenetic relationship of the Avena species (Poaceae: Aveneae)

Ribosomal ITS sequences are commonly used for phylogenetic reconstruction because they are included in rDNA repeats, and these repeats often undergo rapid concerted evolution within and between arrays. Therefore, the rDNA ITS copies appear to be virtually identical and can sometimes be treated as a single gene. In this paper we examined ITS polymorphism within and among 13 diploid (A and C genomes), seven tetraploid (AB, AC and CC genomes) and four hexaploid (ACD genome) to infer the extent and direction of concerted evolution, and to reveal the phylogenetic and genome relationship among species of Avena. A total of 170 clones of the ITS1-5.8S-ITS2 fragment were sequenced to carry out haplotype and phylogenetic analysis. In addition, 111 Avena ITS sequences retrieved from GenBank were combined with 170 clones to construct a phylogeny and a network. We demonstrate the major divergence between the A and C genomes whereas the distinction among the A and B/D genomes was generally not possible. High affinity among the A(d) genome species A. damascena and the ACD genome species A. fatua was found, whereas the rest of the ACD genome hexaploids and the AACC tetraploids were highly affiliated with the A(l) genome diploid A. longiglumis. One of the AACC species A. murphyi showed the closest relationship with most of the hexaploid species. Both C(v) and C(p) genome species have been proposed as paternal donors of the C-genome carrying polyploids. Incomplete concerted evolution is responsible for the observed differences among different clones of a single Avena individual. The elimination of C-genome rRNA sequences and the resulting evolutionary inference of hexaploid species are discussed.     

Transferability of wheat microsatellites to diploid Triticeae species carrying the A, B and D genomes

Hexaploid wheat (Triticum aestivum L em Thell) is derived from a complex hybridization procedure involving three diploid species carrying the A, B and D genomes. In this study, we evaluated the ability of microsatellite sequences from T. aestivum to be revealed on different ancestral diploid species more or less closely related, i.e. to test for their transferability. Fifty five primer pairs, evenly distributed all over the genome, were investigated. Forty three of them mapped to single loci on the hexaploid wheat genetic map although only 20 (46%) gave single PCR products; the 23 others (54%) gave more than one band with either only one being polymorphic, the others remaining monomorphic, or with several co-segregating polymorphic bands. The other 12 detected two (9) or three (3) different loci. From the 20 primer pairs which gave one amplification pro- duct on hexaploid wheat, nine (45%) also amplified products on only one of the diploid species, and seven (35%) on more than one. Four microsatellites (20%) which mapped to chromosomes from the B genome of wheat, did not give any amplification signal on any of the diploid species. This suggests that some regions of the B genome have evolved more rapidly compared to the A or D genomes since the emergence of polyploidy, or else that the donor(s) of this B genome has(have) not yet been identified. Our results confirm that Triticum monococcum ssp. urartu and Triticum tauschii were the main donors of the A and D genomes respectively, and that Aegilops speltoides is related to the ancestor(s) of the wheat polyploid B genome. Received: 21 June 2000 / Accepted: 15 November 2000     

Comparative Sequence Analysis of the <Emphasis Type="Italic">Phytochrome C</Emphasis> Gene and its Upstream Region in Allohexaploid Wheat Reveals New Data on the Evolution of its Three Constituent Genomes

Bread wheat is an allohexaploid with genome composition AABBDD. Phytochrome C is a gene involved in photomorphogenesis that has been used extensively for phylogenetic analyses. In wheat, the PhyC genes are single copy in each of the three homoeologous genomes and map to orthologous positions on the long arms of the group 5 chromosomes. Comparative sequence analysis of the three homoeologous copies of the wheat PhyC gene and of some 5 kb of upstream region has demonstrated a high level of conservation of PhyC, but frequent interruption of the upstream regions by the insertion of retroelements and other repeats. One of the repeats in the region under investigation appeared to have inserted before the divergence of the diploid wheat genomes, but was degraded to the extent that similarity between the A and D copies could only be observed at the amino acid level. Evidence was found for the differential presence of a foldback element and a miniature inverted-repeat transposable element (MITE) 5′ to PhyC in different wheat cultivars. The latter may represent the first example of an active MITE family in the wheat genome. Several conserved non-coding sequences were also identified that may represent functional regulatory elements. The level of sequence divergence (K_s) between the three wheat PhyC homoeologs suggests that the divergence of the diploid wheat ancestors occurred some 6.9 Mya, which is considerably earlier than the previously estimated 2.5–4.5 Mya. K_a/K_s ratios were <0.15 indicating that all three homoeologs are under purifying selection and presumably represent functional PhyC genes. RT-PCR confirmed expression of the A, B and D copies. The discrepancy in evolutionary age of the wheat genomes estimated using sequences from different parts of the genome may reflect a mosaic origin of some of the Triticeae genomes.     

Genome and species relationships in genus<Emphasis Type="Italic"> Avena</Emphasis> based on RAPD and AFLP molecular markers

Species and genome relationships among 11 diploid (A and C genomes), five tetraploid (AB and AC genomes) and two hexaploid (ACD genome) Avena taxa were investigated using amplified fragment length polymorphisms (AFLPs) and random amplified polymorphic DNA (RAPD) markers. The two primer pairs used for the AFLP reactions produced a total of 354 polymorphic bands, while 187 reproducible bands were generated using ten RAPD primers. Genetic similarities amongst the entries were estimated using the Jaccard and Dice algorithms, and cluster analyses were performed using UPGMA and neighbor joining methods. Principle coordinate analysis was also applied. The highest cophenetic correlation coefficient was obtained for the Jaccard algorithm and UPGMA clustering method (r=0.99 for AFLP and r=0.94 for RAPD). No major clustering differences were present between phenograms produced with AFLPs and RAPDs. Furthermore, data produced with AFLPs and RAPDs were highly correlated (r=0.92), indicating the reliability of our results. All A genome diploid taxa are clustered together according to their karyotype. The AB genome tetraploids were found to form a subcluster within the A_s genome diploids (AFLPs), indicating their near-autoploid origin. The AC genome tetraploids are clustered to the ACD genome hexaploids. Finally, the C genome diploids form an outer branch, indicating the major genomic divergence between the A and C genomes in Avena.Communicated by J.S. Heslop-Harrison     

Evolutionary insights inferred by molecular analysis of the ITS1-5.8S-ITS2 and IGS Avena sp. sequences

In an attempt to clarify phylogenetic and genome relationships among 35 diploid (A and C genomes), 13 tetraploid (AB and AC genomes) and 6 hexaploid (ACD genome) Avena taxa, 71 clones of the ITS1-5.8S-ITS2 fragment were sequenced, aligned and a network was constructed. In addition, the intergenic spacer (IGS) fragment was fingerprinted by means of a RFLP analysis using three different restriction enzymes. Both approaches led to comparable results. Clustering among the 54 Avena sp. entries was according to karyotype. Major genic divergence between the A and C genomes was revealed, while distinction among the A and B/D genomes was not possible. High affinity among the AB genome tetraploids and the A(s) genome diploid A. lusitanica was found, while AC genome tetraploids and ACD hexaploids were highly affiliated with the A(l) genome diploid A. longiglumis. The possible role of A. longiglumis in Avena sp. evolution is discussed.     

Molecular evolution and nucleotide diversity of nuclear plastid phosphoglycerate kinase (PGK) gene in Triticeae (Poaceae)

Levels of nucleotide divergence provide key evidence in the evolution of polyploids. The nucleotide diversity of 226 sequences of pgk1 gene in Triticeae species was characterized. Phylogenetic analyses based on the pgk1 gene were carried out to determine the diploid origin of polyploids within the tribe in relation to their A^u, B, D, St, Ns, P, and H haplomes. Sequences from the Ns genome represented the highest nucleotide diversity values for both polyploid and diploid species with π = 0.03343 and θ = 0.03536 for polyploid Ns genome sequences and π = 0.03886 and θ = 0.03886 for diploid Psathyrostachys sequences, while Triticum urartu represented the lowest diversity among diploid species at π = 0.0011 and θ = 0.0011. Nucleotide variation of diploid Aegilops speltoides (π = 0.2441, presumed the B genome donor of Triticum species) is five times higher than that (π = 0.00483) of B genome in polyploid species. Significant negative Tajima's D values for the St, A^u, and D genomes along with high rates of polymorphisms and low sequence diversity were observed. Origins of the A^u, B, and D genomes were linked to T. urartu, A. speltoides, and A. tauschii, respectively. Putative St genome donor was Pseudoroegneria, while Ns and P donors were Psathyrostachys and Agropyron. H genome diploid donor is Hordeum.     

Molecular characterisation and origin of the Coffea arabica L. genome

Restriction fragment length polymorphism (RFLP) markers were used in combination with genomic in situ hybridisation (GISH) to investigate the origin of the allotetraploid species Coffea arabica (2n = 44). By comparing the RFLP patterns of potential diploid progenitor species with those of C. arabica, the sources of the two sets of chromosomes, or genomes, combined in C. arabica were identified. The genome organisation of C. arabica was confirmed by GISH using simultaneously labelled total genomic DNA from the two putative genome donor species as probes. These results clearly suggest that C. arabica is an amphidiploid formed by hybridisation between C. eugenioides and C. canephora, or ecotypes related to these diploid species. Our results also indicate low divergence between the two constituent genomes of C. arabica and those of its progenitor species, suggesting that the speciation of C. arabica took place relatively recently. Precise localisation in Central Africa of the site of the speciation of C. arabica, based on the present distribution of the coffee species, appears difficult, since the constitution and extent of tropical forest has varied considerably during the late Quaternary period. Received: 6 June 1998 / Accepted: 10 November 1998     

Species relations among wild Arachis species with the A genome as revealed by FISH mapping of rDNA loci and heterochromatin detection

Section Arachis of the homonymous genus includes 29 wild diploid species and two allotetraploids (A. monticola and the domesticated peanut, A. hypogaea L.). Although, three different genomes (A, B and D) have been proposed for diploid species with x = 10, they are still not well characterized. Moreover, neither the relationships among species within each genome group nor between diploids and tetraploids (AABB) are completely resolved. To tackle these issues, particularly within the A genome, in this study the rRNA genes (5S and 18S–26S) and heterochromatic bands were physically mapped using fluorescent in situ hybridization (FISH) in 13 species of Arachis. These molecular cytogenetic landmarks have allowed individual identification of a set of chromosomes and were used to construct detailed FISH-based karyotypes for each species. The bulk of the chromosome markers mapped revealed that, although the A genome species have a common karyotype structure, the species can be arranged in three groups (La Plata River Basin, Chiquitano, and Pantanal) on the basis of the variability observed in the heterochromatin and 18S–26S rRNA loci. Notably, these groups are consistent with the geographical co-distribution of the species. This coincidence is discussed on the basis of the particular reproductive traits of the species such as autogamy and geocarpy. Combined with geographic distribution of the taxa, the cytogenetic data provide evidence that A. duranensis is the most probable A genome ancestor of tetraploid species. It is expected that the groups of diploid species established, and their relation with the cultigen, may aid to rationally select wild species with agronomic traits desirable for peanut breeding programs.     

Characterization of the gene <Emphasis Type="Italic">Mre11</Emphasis> and evidence of silencing after polyploidization in <Emphasis Type="Italic">Triticum</Emphasis>

The MRE11 protein is a component of the highly conserved MRN complex, along with RAD50 and NBS1. This complex is crucial in the repair of breaks in double stranded DNA, and is involved in many other cell processes. The present paper reports the molecular characterization of Mre11 gene in all three genomes of wheat, making use of the diploid species Triticum monococcum (genome A) and Aegilops Tauschii (genome D), the tetraploid T. turgidum (genomes A and B), and the hexaploid T. aestivum (genomes A, B and D). The genomic sequences characterized ranged from 4,662 to 4,766 bp in length; the cDNA corresponding to the processed mRNA was 2,440–2,510 bp long. In all cases, Mre11 coded for a highly conserved protein of 699 amino acids with a structure involving 22 exons. Mre11 expression was determined by real-time PCR in all the species analysed. The tetraploid species showed an expression similar to that of the diploid Ae. tauschii and lower than that of T. monococcum. Stronger expression was detected in the hexaploid T. aestivum. The SSCP technique was modified by introducing fluorescent labelling to the procedure in order to analyse the expression of the different Mre11 genes (i.e., those belonging to the different genomes) in the polyploid species. In both polyploids, the Mre11 gene belonging to the B genome was the least expressed. This probably reflects a first step in the process of silencing duplicate genes after polyploidization.