Microheterogeneity of the primary structure of the short repeated 5S DNA unit in diploid wheat Triticum monococcum L

Nucleotide sequences of two 5S rRNA genes located in repeated 327 bp long units were determined in diploid wheat Triticum monococcum. They were compared with sequences of 5S rRNA genes of Tr. monococcum and Tr. aestivum which were earlier determined. The differences were revealed in two localizations of the nucleotide sequence in 5S DNA coding regions of Tr. monococcum and - in nine localizations in nontranscribed spacer. It was established that the nucleotide sequence of 5S rRNA gene cloned in pTm5S9 plasmid and 5S DNA coding region in Tr. aestivum have significant homology. Diploid wheat Tr. monococcum was supposed to have 5S rRNA genes with different functional activity within one multigene family.     

Ribosomal RNA Multigene Loci: Nomads of the Triticeae Genomes

The nucleolus organizing regions (NORs) on the short arms of chromosomes 1A(m) and 5A(m) of diploid wheat, Triticum monococcum L., are at the most distal loci in the linkage maps of these two chromosome arms. This distal location differs from the interstitial location of the Nor loci on chromosome arms 1BS of tetraploid Triticum turgidum L. and hexaploid T. aestivum L., 5DS of T. aestivum and diploid Ae. tauschii Coss., and 5HS of barley. Moreover, the barley 5HS locus is at a different location than the 5DS locus. However, other markers, including the centromeres, are colinear. These findings showed that the major Nor loci have repeatedly changed position in the chromosome arms during the radiation of species in the tribe Triticeae without rearrangements of the linkage groups. It is suggested that Nor loci may change position via dispersion of minor loci, that are shown here to exist in the T. monococcum genome, magnification of gene copy numbers in these minor loci, and subsequent deletion of the original major loci. Implications of these findings for the use of rRNA nucleotide sequences in phylogenetic reconstructions are pointed out.     

The amino-acid sequence of a purothionin from Triticum monococcum, a diploid wheat

Purothionins were extracted and purified from the diploid wheat Triticum monococcum. Two proteins were obtained, one of which was present in only very small amounts. The major purothionin of T. monococcum was sequenced and it had an amino acid sequence identical with that of the beta-purothionin of Triticum aestivum (hexaploid bread wheat). It is known that T. monococcum contains the wheat A genome, so the structural gene coding for the beta-purothionin must comprise a part of the A genome. There have been no observable (as amino acid replacements) changes in the DNA comprising either the beta-purothionin gene of T. aestivum or the purothionin gene of T. monococcum, since T. monococcum (or its wild equivalent, Triticum boeoticum) hybridized with the diploid wheat B genome progenitor and started the evolution from diploid to allohexaploid wheat. All of the investigated characteristics of the purothionin-like protein isolated in small amounts suggested that it was essentially identical in amino acid sequence with the T. monococcum purothionin. It may be a dimerized form of beta-purothionin.     

ITS1 and ITS2 Sequences of Four Possible Donors to Bread Wheat Genome and Their Phylogenetic Relationships

The 1TS1 and ITS2 of rDNA of four diploid species, newly Triticum urartu Thum. (AA), T. monococcum var. boeoticum (Boiss.) MK (AA),Aegilops speltoides Tausch. (BB) and Ae. taus&ii Coss. (DD), the most possible donors of A, B and D genomes to broad wheat ( T. aestivum), were amplified by PCR, cloned and sequenced. Some published sequences were discussed and rectified. The length of ITS1 sequences in four species was 221 to 223 bp, and that of 1TS2 was 216 to 217 bp. In pairwise sequence comparisons among four species, divergence ranged from 0.029 0 to 0.064 0 in ITS1, and from 0.009 3 to 0.058 0 in ITS2. Based on ITS1, ITS2 and 1TS1 + ITS2 data respectively, the same most parsimony tree that is congruent with the phylogenetic relationships was generated which was concordant with their morphological and cytological characteristics. In the trees, T. urartu and T. monococcum var. boeoticum constituted one monophyly, whereas two species of the genus Aegilops, Ac. speltoides and Ac. tauschii, fortmed another mono- phyly but with lower bootstrap value than the first clade. This study suggests that ITS region is a useful molecular marker in the studies on the origin and evolution of Triticum.     

普通小麦基因组最可能的4个供体的ITS1和ITS2序列及其亲缘关系

对普通小麦（ＴｒｉｔｉｃｕｍａｅｓｔｉｖｕｍＬ．）基因组（ＡＡＢＢＤＤ）最可能的供体－Ｔ．ｕｒａｔｒｔｕＴｈｕｍ．（ＡＡ）、Ｔ．ｍｏｎｏｃｃｕｍｖａｒ．ｂｏｅｏｔｉｃｕｍ（Ｂｏｉｓｓ．）ＭＫ（ＡＡ）、ＡｅｇｉｌｏｐｓｓｐｅｌｔｏｉｄｅｓＴａｕｓｃｈ．和Ａｅ．ｔａｕｓｃｈｉｉ（Ｃｏｓｓ．（ＤＤ）的核糖体ＲＮＡ基因ＩＴＳ区进行了ＰＣＲ扩增和克隆,并测定了ＩＴＳ１和ＩＴＳ２的ＤＮＡ序列,讨论和纠正了前人     

Genetic and cytogenetic analyses of the A genome of Triticum monococcum. VIII. Localization of rDNAs and characterization of 5S rRNA genes.

In situ hybridization with [3H]dCTP labelled pScT7 (5S rDNA) and pTa80 (18S + 26S rDNA) indicated that both hybridized to the terminal regions of two pairs of chromosomes in Triticum monococcum. When the hybridization was performed with a mixture of both probes, only two pairs of chromosome arms were labelled, which suggested that the loci of both genes were located in juxtaposition to one another. Both probes labelled one pair of sites more heavily than the other. Southern analysis of 5S with BamHI-digested DNA from 12 accessions of T. monococcum (including T. urartu) produced two superimposed ladders of approximate sizes of 500 and 330 bp, which differ from T. aestivum in which 500- and 420-bp ladders were found. The 500-bp ladder is derived from chromosome 5A (5SDna-A2) and the 330-bp ladder from chromosome 1A (5SDna-A1). The recognition site for SstI was present in the long spacer region but absent in the short spacer as in T. aestivum; however, unlike T. aestivum, there were HaeIII (GGCC) and HindIII (AAGCTT) recognition sites in the short spacer region. The TaqI recognition sites (TCGA) in the long and short spacer regions are probably more highly methylated in T. monococcum than in T. aestivum. The results have implications regarding the evolutionary changes that occurred in the A genome of the hexaploid compared with the diploid.     

Genetic Map of Diploid Wheat, Triticum Monococcum L., and Its Comparison with Maps of Hordeum Vulgare L

A genetic map of diploid wheat, Triticum monococcum L., involving 335 markers, including RFLP DNA markers, isozymes, seed storage proteins, rRNA, and morphological loci, is reported. T. monococcum and barley linkage groups are remarkably conserved. They differ by a reciprocal translocation involving the long arms of chromosomes 4 and 5, and paracentric inversions in the long arm of chromosomes 1 and 4; the latter is in a segment of chromosome arm 4L translocated to 5L in T. monococcum. The order of the markers in the inverted segments in the T. monococcum genome is the same as in the B and D genomes of T. aestivum L. The T. monococcum map differs from the barley maps in the distribution of recombination within chromosomes. The major 5S rRNA loci were mapped on the short arms of T. monococcum chromosomes 1 and 5 and the long arms of barley chromosomes 2 and 3. Since these chromosome arms are colinear, the major 5S rRNA loci must be subjected to positional changes in the evolving Triticeae genome that do not perturb chromosome colinearity. The positional changes of the major 5S rRNA loci in Triticeae genomes are analogous to those of the 18S-5.8S-26S rRNA loci.     

The evolution of polyploid wheats: identification of the A genome donor species.

Cytogenetic work has shown that the tetraploid wheats, Triticum turgidum and T. timopheevii, and the hexaploid wheat T. aestivum have one pair of A genomes, whereas hexaploid T. zhukovskyi has two. Variation in 16 repeated nucleotide sequences was used to identify sources of the A genomes. The A genomes of T. turgidum, T. timopheevii, and T. aestivum were shown to be contributed by T. urartu. Little divergence in the repeated nucleotide sequences was detected in the A genomes of these species from the genome of T. urartu. In T. zhukovskyi one A genome was contributed by T. urartu and the other was contributed by T. monococcum. It is concluded that T. zhukovskyi originated from hybridization of T. timopheevii with T. monococcum. The repeated nucleotide sequence profiles in the A genomes of T. zhukovskyi showed reduced correspondence with those in the genomes of both ancestral species, T. urartu and T. monococcum. This differentiation is attributed to heterogenetic chromosome pairing and segregation among chromosomes of the two A genomes in T. zhukovskyi.     

Biochemical data bearing on the relationship between the genome of Triticum urartu and the A and B genomes of the polyploid wheats

To determine whether the Triticum urartu genome is more closely related to the A or B genome of the polyploid wheats, the amino acid sequence of its purothionin was compared to the amino acid sequences of the purothionins in Triticum monococcum, Triticum turgidum, and Triticum aestivum. The residue sequence of the purothionin from T. urartu differs by five and six amino acid substitutions respectively from the alpha 1 and alpha 2 forms coded for by genes in the B and D genomes, and is identical to the beta form specified by a gene in the A genome. Therefore, the T. urartu purothionin is either coded by a gene in the A genome or a chromosome set highly homologous to it. The results demonstrate that at least a portion of the T. urartu and T. monococcum genomes is homologous and probably identical. A variety of other studies have also shown that T. urartu is very closely related to T. monococcum and, in all likelihood, also possesses the A genome. Therefore, it could be argued that either T. urartu and T. monococcum are the same species or that T. urartu rather than T. monococcum is the source of the A genome in T. turgidum and T. aestivum. Except for Johnson's results, our data and that of others suggest a revised origin of polyploid wheats. Specifically, the list of six putative B genome donor species is reduced to five, all members of the Sitopsis section of the genus Aegilops.     

小麦A，B和D基因组同源DNA序列在进化过程中的演变研究

选取已定位的大麦1H染色体的STS标记NWG913为引物,在普通小麦（Tritium aestivum L.）及其4个可能的起源种乌拉尔图小麦（T.urartu T.)、栽培一粒小麦（T.monococcum.L)栽培二粒小麦（T.dicoccum S.）、方穗山羊草（Ae.squarrosa L.)上特异性扩增。扩增产物克隆测序后对其进行序列分析,由序列差异的程度来确定这几个物种之间的亲缘关系。实验结果表明,普通小麦（Tritium aestivum L.)的A基因组此段序列与乌拉尔图小麦（T.urartu T.)、栽培一粒小麦（T.monococcum L.)、栽培二粒小麦（T.dicoccum S.)A基因组此段序列完全相同;普通小麦的D基因组此段序列与方穗山羊草（Ae.squarrosa L.)也完全相同;普通小麦的B基因组此段序列和栽培二粒小麦B基因组此段序列有0．61％的差异。研究结果一方面对现有的普通小麦A、B、D基因组起源和进化理论给予了分子水平上的证明,同时也揭示了同一物种不同的基因组化进化速度存在差异。     

灌浆期水分亏缺条件下二、四、六倍体小麦收获指数和水分利用效率的演化

为揭示不同倍性小麦生长发育、产量性状及水分利用对灌浆期水分亏缺响应的差异,选用二倍体野生一粒小麦(Triticum boeoticum)、栽培一粒小麦(T.monococcum),四倍体野生二粒小麦(T.dicoccoides)、栽培二粒小麦(T.dicoccon),和两个普通六倍体小麦(T.aestivum)品种‘长武134’和‘陕253’6个小麦品种作为供试材料。采用盆栽控水的方法,测定和分析了不同灌浆期土壤水分条件下小麦株高、旗叶叶面积、穗长、根干重、地上生物量、根冠比、千粒重、粒数、产量、收获指数、蒸腾耗水量和水分利用效率等性状的变化。在小麦染色体倍体由二倍体向六倍体进化的过程中,小麦地上生物量、千粒重、穗粒数、产量、收获指数和水分利用效率都显著增加。随着土壤水分从正常→中度亏缺→重度亏缺的减少,收获指数先增大后减小,分别为41.26%、42.48%和38.19%;生物量水分利用效率逐渐增大,分别为2.39、2.43和2.53g·kg–1;产量水分利用效率分别为1.05、1.10和1.04g·kg–1。在灌浆期水分条件是影响收获指数和水分利用效率的关键因素之一。灌浆期的水分亏缺有利于六倍体小麦的收获指数和四倍体的生物量水分利用效率的提高。中度的水分亏缺有利于四倍体和六倍体产量水分利用效率的提高。     

Studies on the origin and evolution of tetraploid wheats based on the internal transcribed spacer (ITS) sequences of nuclear ribosomal DNA

In this study, the internal transcribed spacer (ITS) sequences of nuclear ribosomal DNA in the tetraploid wheats, Triticum turgidum (AABB) and Triticum timopheevii (AAGG), their possible diploid donors, i.e., Triticum monococcum (AA), Triticum urartu (AA), and five species in Aegilops sect. Sitopsis (SS genome), and a related species Aegilops tauschii were cloned and sequenced. ITS1 and ITS2 regions of 24 clones from the above species were compared. Phylogenetic analysis demonstrated that Aegilops speltoides was distinct from other species in Aegilops sect. Sitopsis and was the most-likely donor of the B and G genomes to tetraploid wheats. Two types of ITS repeats were cloned from Triticum turgidum ssp. dicoccoides, one markedly similar to that from T. monococcum ssp. boeoticum (AA), and the other to that from Ae. speltoides (SS). The former might have resulted from a recent integression event. The results also indicated that T. turgidum and T. timopheevii might have simultaneously originated from a common ancestral tetraploid species or be derived from two hybridization events but within a very short interval time. ITS paralogues in tetraploid wheats have not been uniformly homogenized by concerted evolution, and high heterogeneity has been found among repeats within individuals of tetraploid wheats. In some tetraploid wheats, the observed heterogeneity originated from the same genome (B or G). Three kinds of ITS repeats from the G genome of an individual of T. timopheevii ssp. araraticum were more divergent than that from inter-specific taxa. This study also demonstrated that hybridization and polyploidization might accelerate the evolution rate of ITS repeats in tetraploid wheats.     

45S rDNA在小麦及其近缘物种染色体上的分布

将染色体C-分带和原位杂交技术相结合,系统研究了45S rDNA在栽培一粒小麦、野生二粒小麦、普通小麦、大麦、簇毛麦、硬簇麦、六倍体燕麦及鹅观草等物种染色体上的分布情况。这些物种染色体的次缢痕区都有45S rDNA位点, 某些非随体染色体上也有45S rDNA位点分布。以小麦—鹅观草1Rk^#1二体附加系为材料,通过顺序C分带-FISH技术首次将一个45S rDNA定位到1Rk^#1染色体短臂末端。     

Repetitive, genome-specific probes in wheat (Triticum aestivum L. em Thell) amplified with minisatellite core sequences

The detection and analysis of DNA polymorphisms in crops is an essential component of marker-assisted selection and cultivar identification in plant breeding. We have explored the direct amplification of minisatellite DNA by PCR (DAMD-PCR) as a means for generating DNA probes that are useful for detecting DNA polymorphisms and DNA fingerprinting in wheat. This technique was facilitated by high-stringency PCR with known plant and animal minisatellite core sequences as primers on wheat genomic DNA. The products of DAMD-PCR from Triticum aestivum, T. durum, T. monococcum, T. speltoides and T. tauschii showed a high degree of polymorphism and the various genomes could be identified. Cloning of the DAMD-PCR products and subsequent Southern hybridization frequently revealed polymorphic probes showing a good degree of genome specificity. In addition, polymorphic, single locus, and moderately dispersed PCR products were cloned that may have a potential for DNA fingerprinting. Our experiments were limited primarily to diploid wheats and the results indicated that DAMD-PCR may isolate genome-specific probes from wild diploid wheat species that could be used to monitor genome introgression into hexaploid wheat.This paper reports the results of research only. Mention of a proprietary product does not constitute an endorsement or a recommendation for its use by the USDA or the University of Missouri. Contribution from the University of Missouri, the Agricultural Experimental Station and U.S. Department of Agriculture-Agricultural Research Service, Plant Genetics Research Unit, journal series No. 12523     

Determination of phylogenetic relationships between some wild wheat species using amplified fragment length polymorphism (AFLP) markers

This study reports the molecular characterization, polymorphism, and phylogenetic relationships of Triticum aestivum , T. dicoccoides , T. urartu , and T. monococcum ssp. boeoticum , obtained from different locations in Anatolia, using 33 primer combinations to generate amplified fragment length polymorphism (AFLP) patterns in 31 individual plant samples. The objectives of this work were to estimate the phylogenetic relationships between these species and to investigate the genetic distance as a result of ecological and climatic factors. The origin of the A genome of polyploid wheats is also discussed. Eight hundred and seventy-five AFLP fragments had polymorphic loci, 133 of which were unique to T. monococcum ssp. boeoticum , 66 were unique to T. urartu , and 141 were unique to T. dicoccoides . Analysis using the program POPGENE showed polymorphism levels of T. monococcum ssp. boeoticum , T. urartu , and T. dicoccoides of 42.63, 32.34, and 27.71%, respectively. No correlation between genetic distance and ecological or climatic factors was recorded in this study. Our results support the hypothesis that T. urartu is a diploid ancestor of T. dicoccoides and T. aestivum .  © 2007 The Linnean Society of London, Botanical Journal of the Linnean Society , 2007, 153 , 67–72.     

Molecular Variation in Chloroplast DNA Regions in Ancestral Species of Wheat

Restriction map variation in two 5-6-kb chloroplast DNA regions of five diploid Aegilops species in the section Sitopsis and two wild tetraploid wheats, Triticum dicoccoides and Triticum araraticum, was investigated with a battery of four-cutter restriction enzymes. A single accession each of Triticum durum, Triticum timopheevi and Triticum aestivum was included as a reference. More than 250 restriction sites were scored, of which only seven sites were found polymorphic in Aegilops speltoides. No restriction site polymorphisms were detected in all of the other diploid and tetraploid species. In addition, six insertion/deletion polymorphisms were detected, but they were mostly unique or species-specific. Estimated nucleotide diversity was 0.0006 for A. speltoides, and 0.0000 for all the other investigated species. In A. speltoides, none of Tajima's D values was significant, indicating no clear deviation from the neutrality of molecular polymorphisms. Significant non-random association was detected for three combinations out of 10 possible pairs between polymorphic restriction sites in A. speltoides. Phylogenetic relationship among all the plastotypes (plastid genotype) suggested the diphyletic origin of T. dicoccoides and T. araraticum. A plastotype of one A. speltoides accession was identical to the major type of T. araraticum (T. timopheevi inclusively). Three of the plastotypes found in the Sitopsis species are very similar, but not identical, to that of T. dicoccoides, T. durum and T. aestivum.     

Characterization of waxy proteins and waxy genes of Triticum timopheevii and T. zhukovskyi and implications for evolution of wheat.

The granule-bound starch (GBSS I, waxy protein) in Triticum timopheevii (AtAtGG) and T. zhukovskyi (AtAtAzAzGG) and a diagnostic section of the genes encoding GBSS-I from the Wx-TtA and Wx-G loci of T. timopheevii and the Wx-TtA, Wx-G, and Wx-TzA loci of T. zhukovskyi were investigated in this study. The waxy proteins in these two polyploid wheats could not be separated into distinct bands, in contrast to those in the T. turgidum (AABB)-T. aestivum (AABBDD) lineage. Alignment of sequences of the section covering exon4-intron4-exon5 of the various waxy genes led to the identification of gene-specific sequences in intron 4. The sequences specific to the Wx-TtA and Wx-G genes of T. timopheevii were different from those of the Wx-A1 gene and Wx-B1 genes of T. turgidum and T. aestivum. A surprising observation was that the Wx-TzA of T. zhukovskyi did not match with the Wx-TmA of T. monococcum, a putative donor of the Az genome, but matched unexpectedly and perfectly with the Wx-B1 gene on chromosome 4A, which is proposed to have translocated from the chromosome 7B of T. aestivum. The possible genetic mechanism explaining these observations is discussed.     

Sequence Variations and Haplotype Identification of Wheat Dimeric α-Amylase Inhibitor Genes in Einkorn Wheats

This study characterizes 80 dimeric alpha-amylase inhibitor genes from 68 accessions of the einkorn wheats Triticum urartu, T. boeoticum, and T. monococcum. The mature protein coding sequences of WDAI genes were analyzed. Nucleotide sequence variations in these regions resulted from base substitution and/or indel mutations. Most of the WDAI gene sequences from T. boeoticum and all sequences from T. monococcum had one nucleotide insertion in the coding region, such that these alpha-amylase inhibitor sequences could not encode the correct mature proteins. We identified 21 distinct haplotypes from the diploid wheat WDAI gene sequences. A main haplotype was found in 15 gene samples from the A(u) genome and 35 gene samples from the A(m) genome. The T. monococcum and T. boeoticum accessions shared the same main haplotype, with 25 samples from T. monococcum and 10 from T. boeoticum. The WDAI gene sequences from the A(u) and A(m) genomes could be obviously clustered into two clades, but the sequences from the A(m) genome of T. boeoticum and T. monococcum could not be clearly distinguished. The phylogenetic analysis revealed that the WDAI gene sequences from the A(m) genome had accumulated fewer variations and evolved at a slower rate than the sequences from the A(u) genome. Although some accessions from only one or two areas had unique mutations at the same position, the diversity of WDAI gene sequences in diploid wheat showed little relationship to the origin of the accessions.