Molecular analysis of the D-genome of the Triticeae

Summary The chromosome of three tetraploid Aegilops L. species containing the D-genome were analyzed by in situ hybridization with a repeated DNA sequence clone pAS1 isolated from Aegilops squarrosa and observed to be D-genome specific. This sequence is found on all seven D-genome chromosome pairs of A. squarrosa and hexaploid wheat. Two distinct D-genome patterns were observed in the tetraploid species. The D-genome of A. cylindrica was similar to hexaploid wheat. Seven pairs of chromosomes having large amounts and numerous sites of the sequence were observed. Five chromosome pairs with fewer and smaller sites of the repetitive sequence were observed in the D-genomes of A. crassa and A. ventricosa. In addition to these major repeated sequence differences, chromosomal modifications appear to have occurred between T. aestivum and A. cylindrica and between A. crassa and A. ventricosa resulting in changes with respect to location of the sequence between the respective species. D-genome divergence with respect to pAS1 sequence appears to have occurred at least in two forms, one characterized by the changes in amount of repetitive sequence and the second by changes in location of the sequence.     

Construction of a subgenomic BAC library specific for chromosomes 1D, 4D and 6D of hexaploid wheat

The analysis of the hexaploid wheat genome (Triticum aestivum L., 2n=6x=42) is hampered by its large size (16,974 Mb/1C) and presence of three homoeologous genomes (A, B and D). One of the possible strategies is a targeted approach based on subgenomic libraries of large DNA inserts. In this work, we purified by flow cytometry a total of 10⁷ of three wheat D-genome chromosomes: 1D, 4D and 6D. Chromosomal DNA was partially digested with HindIII and used to prepare a specific bacterial artificial chromosome (BAC) library. The library (designated as TA-subD) consists of 87,168 clones, with an average insert size of 85 kb. Among these clones, 53% had inserts larger than 100 kb, only 29% of inserts being shorter than 75 kb. The coverage was estimated to be 3.4-fold, giving a 96.5% probability of identifying a clone corresponding to any sequence on the three chromosomes. Specificity for chromosomes 1D, 4D and 6D was confirmed after screening the library pools with single-locus microsatellite markers. The screening indicated that the library was not biased and gave an estimated coverage of sixfold. This is the second report on BAC library construction from flow-sorted plant chromosomes, which confirms that dissecting of the complex wheat genome and preparation of subgenomic BAC libraries is possible. Their availability should facilitate the analysis of wheat genome structure and evolution, development of cytogenetic maps, construction of local physical maps and map-based cloning of agronomically important genes.     

Isolation of A/D and C genome specific dispersed and clustered repetitive DNA sequences from Avena sativa.

DNA gel-blot and in situ hybridization with genome-specific repeated sequences have proven to be valuable tools in analyzing genome structure and relationships in species with complex allopolyploid genomes such as hexaploid oat (Avena sativa L., 2n = 6x = 42; AACCDD genome). In this report, we describe a systematic approach for isolating genome-, chromosome-, and region-specific repeated and low-copy DNA sequences from oat that can presumably be applied to any complex genome species. Genome-specific DNA sequences were first identified in a random set of A. sativa genomic DNA cosmid clones by gel-blot hybridization using labeled genomic DNA from different Avena species. Because no repetitive sequences were identified that could distinguish between the A and D gneomes, sequences specific to these two genomes are refereed to as A/D genome specific. A/D or C genome specific DNA subfragments were used as screening probes to identify additional genome-specific cosmid clones in the A. sativa genomic library. We identified clustered and dispersed repetitive DNA elements for the A/D and C genomes that could be used as cytogenetic markers for discrimination of the various oat chromosomes. Some analyzed cosmids appeared to be composed entirely of genome-specific elements, whereas others represented regions with genome- and non-specific repeated sequences with interspersed low-copy DNA sequences. Thus, genome-specific hybridization analysis of restriction digests of random and selected A. sativa cosmids also provides insight into the sequence organization of the oat genome.     

Repeated DNA sequences isolated by microdissection. II. Comparative analysis in Hordeum vulgare and Triticum aestivum

The genomic organization of two satellite DNA sequences, pHvMWG2314 and pHvMWG2315, of barley (Hordeum vulgare, 2n=14, HH) was studied by comparative in situ hybridization (ISH) and PCR analysis. Both sequences are members of different RsaI families. The sequence pHvMWG2314 is a new satellite element with a monomer unit of 73 bp which is moderately amplified in different grasses and occurs in interstitial clusters on D-genome chromosomes of hexaploid wheat (Triticum aestivum, 2n=42, AABBDD). The 331-bp monomer pHvMWG2315 belongs to a tandemly amplified repetitive sequence family that is present in the Poaceae and preferentially amplified in Aegilops squarrosa (2n=14, DD), H. vulgare and Agropyron elongatum. (2n=14, EE). The first described representative of this family was pAs 1 from Ae. squarrosa. Different sequences of one satellite DNA family were amplified from Ae. squarrosa, A. elongatum and H. vulgare using PCR. Characteristic differences between members of the D and H genome occurred in a variable region which is flanked by two conserved segments. The heterogeneity within this element was exploited for the cytogenetic analysis of Triticeae genomes and chromosomes. Comparative ISH with pHvMWG2315 identified individual wheat and barley chromosomes under low (75%) and high (85%) hybridization stringency in homologous and heterologous systems. We propose the designation Tas330 for the Triticeae amplified sequence (Tas) satellite family with a 330 bp average monomer length.     

Rapid genome evolution revealed by comparative sequence analysis of orthologous regions from four triticeae genomes

Bread wheat (Triticum aestivum) is an allohexaploid species, consisting of three subgenomes (A, B, and D). To study the molecular evolution of these closely related genomes, we compared the sequence of a 307-kb physical contig covering the high molecular weight (HMW)-glutenin locus from the A genome of durum wheat (Triticum turgidum, AABB) with the orthologous regions from the B genome of the same wheat and the D genome of the diploid wheat Aegilops tauschii (Anderson et al., 2003; Kong et al., 2004). Although gene colinearity appears to be retained, four out of six genes including the two paralogous HMW-glutenin genes are disrupted in the orthologous region of the A genome. Mechanisms involved in gene disruption in the A genome include retroelement insertions, sequence deletions, and mutations causing in-frame stop codons in the coding sequences. Comparative sequence analysis also revealed that sequences in the colinear intergenic regions of these different genomes were generally not conserved. The rapid genome evolution in these regions is attributable mainly to the large number of retrotransposon insertions that occurred after the divergence of the three wheat genomes. Our comparative studies indicate that the B genome diverged prior to the separation of the A and D genomes. Furthermore, sequence comparison of two distinct types of allelic variations at the HMW-glutenin loci in the A genomes of different hexaploid wheat cultivars with the A genome locus of durum wheat indicates that hexaploid wheat may have more than one tetraploid ancestor.     

USE OF REPEATED DNA SEQUENCES AS CYTOLOGICAL MARKERS

The majority of DNA that is found in most of the flowering plants appears to be non-coding DNA. Much of this excess DNA consists of nucleotide sequences which exist as multiple copies throughout the genome and are designated as repetitive sequences. Those sequences which are found in moderately high to high numbers of copies are observed to be of the greatest value as cytological markers. Moderately high copies may exist as sequences which are dispersed throughout the chromosomes of some species and not dispersed in other more distantly related species. By taking advantage of this characteristic and the technique of in situ hybridization with biotinylated probes, breakpoints of chromosomal translocations may be observed between species such as wheat and rye. Many of the high copy number repetitive sequences are organized in a tandem fashion in specific loci in the chromosome. Chromosomal identification may be accomplished by using the in situ hybridization technique. Upon in situ hybridization with a repetitive sequence isolated from Aegilops squarrosa, the patterns of the sites of hybridization allowed the D-genome chromosomes to be identified. The sequence was also observed only on the D-genome chromosomes of several polyploid species indicating its usefulness as a genome specific marker. Using this genome specificity, assessment of the orientation of the D-genome chromosomal segments of hexaploid wheat carrying the sequence during interphase and prophase of mitotic root tip cells was possible. Repetitive DNA sequences, therefore, provide cytological markers necessary for studies of chromosomal identification, genome allocation, and genome orientation. The use of biotin-labeled DNA probes allows the technique of in situ hybridization to be performed much more rapidly and with a greater degree of safety and reliability.     

BAC-FISH in wheat identifies chromosome landmarks consisting of different types of transposable elements

Fluorescence in situ hybridization (FISH) has been widely used in the physical mapping of genes and chromosome landmarks in plants and animals. Bacterial artificial chromosomes (BACs) contain large inserts making them amenable for FISH mapping. We used BAC-FISH to study genome organization and evolution in hexaploid wheat and its relatives. We selected 56 restriction fragment length polymorphism (RFLP) locus-specific BAC clones from libraries of Aegilops tauschii (the D-genome donor of hexaploid wheat) and A-genome diploid Triticum monococcum. Different types of repetitive sequences were identified using BAC-FISH. Two BAC clones gave FISH patterns similar to the repetitive DNA family pSc119; one BAC clone gave a FISH pattern similar to the repetitive DNA family pAs1. In addition, we identified several novel classes of repetitive sequences: one BAC clone hybridized to the centromeric regions of wheat and other cereal species, except rice; one BAC clone hybridized to all subtelomeric chromosome regions in wheat, rye, barley and oat; one BAC clone contained a localized tandem repeat and hybridized to five D-genome chromosome pairs in wheat; and four BAC clones hybridized only to a proximal region in the long arm of chromosome 4A of hexaploid wheat. These repeats are valuable markers for defined chromosome regions and can also be used for chromosome identification. Sequencing results revealed that all these repeats are transposable elements (TEs), indicating the important role of TEs, especially retrotransposons, in genome evolution of wheat.Communicated by P.B. Moens     

Evaluation of “sequence-tagged-site” PCR products as molecular markers in wheat

The polymerase chain reaction (PCR) is an attractive technique for many genome mapping and characterization projects. One PCR approach which has been evaluated involves the use of randomly amplified polymorphic DNA (RAPD). An alternative to RAPDs is the sequence-tagged-site (STS) approach, whereby PCR primers are designed from mapped low-copy-number sequences. In this study, we sequenced and designed primers from 22 wheat RFLP clones in addition to testing 15 primer sets that had been previously used to amplify DNA sequences in the barley genome. Our results indicated that most of the primers amplified sequences that mapped to the expected chromosomes in wheat. Additionally, 9 of 16 primer sets tested revealed polymorphisms among 20 hexaploid wheat genotypes when PCR products were digested with restriction enzymes. These results suggest that the STS-based PCR analysis will be useful for generation of informative molecular markers in hexaploid wheat.Contribution no. J-2833 of the Montana Agric Exp Stn     

Salt Tolerance in the Triticeae: The Contribution of the D Genome to Cation Selectivity in Hexaploid Wheat

Inorganic cation concentrations were measured in shoots of hexaploidbread wheat (Triticum aestivum L.) and its presumed ancestorsgrown at 100 mol m^–3 external NaCl. Aegilops squarrosaand T. aestivum had high K/Na ratios while T. dicoccoides andAe. speltoides had low K/Na ratios. T. monococcum although havinga high K/Na ratio, had the highest total salt load of the fivespecies tested. The effect of the D genome (from Ae. squarrosa)was further investigated in seedlings of synthetic hexaploidwheats, and was again found to improve cation selectivity. Differentresponses were obtained from root and shoot tissue in this experiment.One synthetic hexaploid and its constituent parents were grownto maturity at 100 mol m^-3 NaCl and the yields recorded. Despitecomplications due to increased tillering in the stressed hexaploid,it was possible to show that the addition of the D genome enhancedyield characteristics in the hexaploid wheat. An experimentwith synthetic hexaploids derived from the tetraploid wheatvariety "Langdon" and several Ae. squarrosa accessions revealeddifferences in vegetative growth rates between the differentsynthetic hexaploids in the presence or absence of 150 or 200mol m^–3 external NaCl. The possibility of transferringsalt tolerance genes from Ae. squarrosa to hexaploid wheat usingsynthetic hexaploids as bridging species is discussed. Key words: Salt stress, wheat, D genome, Aegiops squarrosa, synthetic hexaploids     

Rapid Elimination of Low-Copy DNA Sequences in Polyploid Wheat: A Possible Mechanism for Differentiation of Homoeologous Chromosomes

To study genome evolution in allopolyploid plants, we analyzed polyploid wheats and their diploid progenitors for the occurrence of 16 low-copy chromosome- or genome-specific sequences isolated from hexaploid wheat. Based on their occurrence in the diploid species, we classified the sequences into two groups: group I, found in only one of the three diploid progenitors of hexaploid wheat, and group II, found in all three diploid progenitors. The absence of group II sequences from one genome of tetraploid wheat and from two genomes of hexaploid wheat indicates their specific elimination from these genomes at the polyploid level. Analysis of a newly synthesized amphiploid, having a genomic constitution analogous to that of hexaploid wheat, revealed a pattern of sequence elimination similar to the one found in hexaploid wheat. Apparently, speciation through allopolyploidy is accompanied by a rapid, nonrandom elimination of specific, low-copy, probably noncoding DNA sequences at the early stages of allopolyploidization, resulting in further divergence of homoeologous chromosomes (partially homologous chromosomes of different genomes carrying the same order of gene loci). We suggest that such genomic changes may provide the physical basis for the diploid-like meiotic behavior of polyploid wheat.     

A chromosome region-specific mapping strategy reveals gene-rich telomeric ends in wheat

A strategy is described for rapid chromosome region-specific mapping in hexaploid wheat (Triticum aestivum L. em. Thell., 2n=6x=42, AABBDD). The method involves allocation of markers to specific chromosome regions by deletion mapping and ordering of probes by high resolution genetic mapping in Triticum tauschii, the D-genome progenitor species. The strategy is demonstrated using 26 chromosome deletion lines for wheat homoeologous group-6. Twenty-five DNA probes from the T. tauschii genetic linkage map and six wheat homoeologous group-6 specific probes were mapped on the deletion lines. Twenty-four of the 25 probes from 6D of T. tauschii also mapped on wheat homoeologous group-6 chromosomes, and their linear order in wheat is the same as in T. tauschii. A consensus physical map of wheat group-6 was constructed because the linear order and the relative position of the probe loci was the same among the three group-6 chromosomes. Comparison of the consensus physical map with the genetic map demonstrated that most of the recombination occurs in the distal ends of the wheat chromosomes. Most of the loci mapped in the distal regions of the chromosomes. The probes were mostly either PstI genomic clones or cDNA clones indicating that the undermethylated single-copy sequences are concentrated in the distal ends of the wheat chromosomes. Fifteen loci are uniformly distributed in the distal 11% of the group-6 chromosomes. Physically, the region spans only 0.58 m, which in wheat translates to about 40 Mb of DNA. The average distance between the markers is, therefore, less than 2.7 Mb and is in the range of PFGE (pulsed-field gel electrophoresis) resolution. Any gene present in the region can be genetically ordered with respect to the markers since the average recombination frequency in the region is very high (>90 cM genetic distance).     

Chromosomal location of genes for Rubisco small subunit and Rubisco-binding protein in common wheat

Summary The genes coding for the Rubisco small subunit (SSU) and for the -subunit of the Rubisco-binding protein were located to chromosome arms of common wheat. HindIII-digested total DNA from the hexaploid cultivar Chinese Spring and from ditelosomic and nullisomic-tetrasomic lines was probed with these two genes, whose chromosomal location was deduced from the disappearance of or from changes in the relative intensity of the relevant band(s). The Rubisco SSU pattern consisted of 14 bands, containing at least 21 different types of DNA fragments, which were allocated to two homoeologous groups: 15 to the short arm of group 2 chromosomes (4 to 2AS, 7 to 2BS, and 4 to 2DS) and 6 to the long arm of group 5 chromosomes (2 on each of arms 5AL, 5BL, and 5DL). The pattern of the Rubisco-binding protein consisted of three bands, each containing one type of fragment. These fragments were located to be on the short arm of group 2 chromosomes. The restriction fragment length polymorphism (RFLP) patterns of several hexaploid and tetraploid lines were highly conserved, whereas the patterns of several of their diploid progenitors were more variable. The variations found in the polyploid species were mainly confined to the B genome. The patterns of the diploids T. monococcum var. urartu and Ae. squarrosa were similar to those of the A and D genome, respectively, in polyploid wheats. The pattern of T. monococcum var. boeoticum was different from the patterns of the A genome, and the patterns of the diploids Ae. speltoides, Ae. longissima, and Ae. Searsii differed from that of the B genome.     

Mapping‐by‐sequencing in complex polyploid genomes using genic sequence capture: a case study to map yellow rust resistance in hexaploid wheat

Previously we extended the utility of mapping‐by‐sequencing by combining it with sequence capture and mapping sequence data to pseudo‐chromosomes that were organized using wheat–Brachypodium synteny. This, with a bespoke haplotyping algorithm, enabled us to map the flowering time locus in the diploid wheat Triticum monococcum L. identifying a set of deleted genes (Gardiner et al., 2014). Here, we develop this combination of gene enrichment and sliding window mapping‐by‐synteny analysis to map the Yr6 locus for yellow stripe rust resistance in hexaploid wheat. A 110 MB NimbleGen capture probe set was used to enrich and sequence a doubled haploid mapping population of hexaploid wheat derived from an Avalon and Cadenza cross. The Yr6 locus was identified by mapping to the POPSEQ chromosomal pseudomolecules using a bespoke pipeline and algorithm (Chapman et al., 2015). Furthermore the same locus was identified using newly developed pseudo‐chromosome sequences as a mapping reference that are based on the genic sequence used for sequence enrichment. The pseudo‐chromosomes allow us to demonstrate the application of mapping‐by‐sequencing to even poorly defined polyploidy genomes where chromosomes are incomplete and sub‐genome assemblies are collapsed. This analysis uniquely enabled us to: compare wheat genome annotations; identify the Yr6 locus – defining a smaller genic region than was previously possible; associate the interval with one wheat sub‐genome and increase the density of SNP markers associated. Finally, we built the pipeline in iPlant, making it a user‐friendly community resource for phenotype mapping.     

Flow karyotyping and chromosome sorting in bread wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

Previously, we reported on the development of procedures for chromosome analysis and sorting using flow cytometry (flow cytogenetics) in bread wheat. That study indicated the possibility of sorting large quantities of intact chromosomes, and their suitability for analysis at the molecular level. However, due to the lack of sufficient differences in size between individual chromosomes, only chromosome 3B could be sorted into a high-purity fraction. The present study aimed to identify wheat stocks that could be used to sort other chromosomes. An analysis of 58 varieties and landraces demonstrated a remarkable reproducibility and sensitivity of flow cytometry for the detection of numerical and structural chromosome changes. Changes in flow karyotype, diagnostic for the presence of the 1BL·1RS translocation, have been found and lines from which translocation chromosomes 5BL·7BL and 4AL·4AS-5BL could be sorted have been identified. Furthermore, wheat lines have been identified which can be used for sorting chromosomes 4B, 4D, 5D and 6D. The ability to sort any single arm of the hexaploid wheat karyotype, either in the form of a ditelosome or a isochromosome, has also been demonstrated. Thus, although originally considered recalcitrant, wheat seems to be suitable for the development of flow cytogenetics and the technology can be applied to the physical mapping of DNA sequences, the targeted isolation of molecular makers and the construction of chromosome- and arm-specific DNA libraries. These approaches should facilitate the analysis of the complex genome of hexaploid bread wheat.     

Tomato genome is comprised largely of fast-evolving, low copy-number sequences

Summary Fifty random clones (350–2300 bp), derived from sheared, nuclear DNA, were studied via Southern analysis in order to make deductions about the organization and evolution of the tomato genome. Thirty-four of the clones were mapped genetically and determined to represent points on 11 of the 12 tomato chromosomes. Under moderate stringency conditions (80% homology required) 44% of the clones were classified as single copy. Under higher stringency, the majority of the clones (78%) behaved as single copy. Most of the remaining clones belonged to multicopy families containing 2–20 copies, while a few contained moderately or highly repeated sequences (10% at moderate stringency, 4% at high stringency). Divergence rates of sequences homologous to the 50 random genomic clones were compared with those corresponding to 20 previously described cDNA (coding sequence) clones. Rates were measured by probing each clone (random genomics and cDNAs) onto filters containing DNA from various species from the family Solanaceae (including potato, Datura, petunia and tobacco) as well as one species (watermelon) from another plant family, Cucurbitaceae. Under moderate stringency conditions, the majority of the random clones (single copy and repetitive) failed to detect homologous sequences in the more distantly related species, whereas approximately 90% of the 20 coding sequences analyzed could still be detected in all solanaceous species. The most highly repeated sequences appear to be the fastest evolving and homologous copies could be detected only in species most closely related to tomato. Dispersion of repetitive sequences, as opposed to tandem clustering, appears to be the rule for the tomato genome. None of the repetitive sequences discovered by this random sampling of the genome were tandemly arranged — a finding consistent with the notion that the tomato genome contains only a small fraction of satellite DNA. This study, along with a companion paper (Ganal et al. 1988), provides the first general sketch of the tomato genome at the molecular level and indicates that it is comprised largely of single copy sequences and these sequences, together with repetitive sequences are evolving at a rate faster than the coding portion of the genome. The small genome and paucity of highly repetitive DNA are favourable attributes with respect to the possibilities of conducting chromosome walking experiments in tomato and the fact that coding regions are well conserved among solanaceous species may be useful for distinguishing clones that contain coding regions from those that do not.     

N-banded karyotypes of wheat species

Nine of the twenty-one chromosome pairs of the hexaploid wheat Triticum aestivum var. Chinese Spring (genome constitution AABBDD) show distinctive N-banding patterns. These nine chromosomes are 4A, 7A and all of the B genome chromosomes. The remaining chromosomes show either faint bands or no bands at all. Tetraploid wheat, T. dicoccoides (AABB), showed banded chromosomes similar to those observed in the hexaploid. Of the diploid species T. monococcum, T. boeoticum, T. urartu and Aegilops sauarrosa showed little or no banding as would be expected of donors of the A and D genomes. Ae. speltoides had a number of N-banded chromosomes as would be expected of a candidate for the B genome donor. Since N-bands are not evident on some nucleolar organiser chromosomes, the staining specificity cannot be correlated with the presence of nucleolar organiser regions.     

Nucleolar behaviour in Triticum

The maximum number of major nucleoli (macronucleoli) per nucleus of hexaploid, tetraploid and diploid wheat, Aegilops speltoides and Ae. squarrosa corresponded to the number of satellited chromosomes of each species. Smaller nucleoli (micronucleoli) were rare or absent in all of these species except the hexaploid, in which they were predominantly organized on chromosome arm 5D^s. — Fewer than the maximum number of macronucleoli in a mitotic interphase nucleus resulted from fusion of developing nucleoli. Enforced proximity of nucleolus-organizing regions resulted in more frequent fusion of nucleoli. — Analyses of related interphase nuclei showed that nucleoli, and hence probably chromosomes, undergo limited movement during mitotic interphase. These observations also indicate that specific chromosomes do not occupy specific sites in the interphase nucleus.     

DNA condensation with polyamines. II. Electron microscopic studies

Approximately 75% of the wheat and rye genomes consist of repeated sequence DNA. Three-quarters of the non-repeated or few copy sequences in wheat are less than 1000 base-pairs long, whilst in rye approximately half of the non-repeated or few copy sequences are in this size class. Most of the remaining non-repeated or few copy sequences appear to be a few thousand base-pairs long.In this paper a somewhat novel approach has been used to quantitatively analyse the linear organisation of the large proportion of repeated sequence DNA as well as the non-repeated DNA in the wheat and rye genomes. Repeated sequences in the genomes of oats, barley, wheat and rye have been used as probes to distinguish and isolate four different groups of repeated sequences and their neighbouring sequences from the wheat and rye genomes. Radioactively labelled wheat or rye DNA fragments ranging from 200 to over 9000 nucleotides long were incubated separately with large excesses of denatured unlabelled oats, barley, wheat and rye DNAs to C_ot values which enable all the repeated sequences of the unlabelled DNA to renature. The following parameters were then determined from the proportions of total labelled DNA in fragments which had at least partially renatured. (1) The proportions of the repeated sequences in the labelled DNAs that were able to hybridise to each unlabelled DNA; (2) the mean distance apart of the hybridising sequences on the longer labelled fragments; and (3) the proportion of the genome in which the hybridising sequences were concentrated. Analysis of these results, together with those of separate experiments designed to quantitatively estimate the nature of sequences unable to reanneal with the repeated sequences of each of the probe DNAs, have enabled schematic maps to be drawn which show how the repeated and non-repeated sequences are arranged in the wheat and rye genomes.Both genomes are constructed from millions of relatively short sequences, most of them considerably shorter than 3000 base-pairs. This structure was recognised because adjacent sequences can be distinguished by their frequency of repetition (i.e. repeated or non-repeated) or by their evolutionary origin. Approximately 40 to 45% of the wheat genome and 30 to 35% of the rye genome consists of short non-repeated sequences interspersed between short repeated sequences. Approximately 50% of the wheat genome and 60% of the rye genome consists of tandemly arranged repeated sequences of different evolutionary origins. It is postulated that much of this complex repeated sequence DNA could have arisen from amplification of compound sequences, each containing repeated and non-repeated sequence DNA.Short repeated sequences with a number average length of around 200 base-pairs and which occupy about 20% of the wheat and rye genomes are related to repeated sequences also found in oats and barley. They are concentrated in 60 to 70% of the wheat and rye genomes, being interspersed with different short repeated sequences and a significant proportion of the short non-repeated sequences.Rye chromosomes contain more DNA than wheat chromosomes. This is principally, but not entirely, due to additional repeated sequence DNA. Many quantitative changes appear to have occurred in both genomes, possibly affecting most families of repeated sequences, since wheat and rye diverged from a common ancestor. Both species contain species-specific repeated sequences (24% of rye genome; 16% of wheat genome) but a large proportion of these are closely interspersed with repeated sequences found in both genomes.