Evolutionary change at the5S Dna loci of species in theTriticeae

Previous studies have shown that two separate loci for 5S DNA sequences may exist within a species. Two size classes have been tentatively assigned in the ranges 327–468 bp (chromosome 1), and 469–500 bp (chromosome 5) and the entire data-base was subjected to various numerical taxonomic analyses. The results confirm the existence of two lineages of 5S DNA sequences represented by the two size classes.Hordeum vulgare is separate from the species known also asCritesion and, together withDasypyrum, occupy an intermediate position between the two size classes. The 5S DNA units fromTriticum spp. that have also been namedAegilops spp. in other classifications appear as a distinct group withinTriticum spp. at both loci. The consensus 5S DNA sequence fromPsathyrostachys is remote fromHordeum s.l. in contrast to opinions based on morphology. Other aspects are detailed and discussed, including the inadequacy of the computing methods used as well as the need for more data in view of the large amount of homoplasy. The merit of using the spacer for phylogenetic inference is also discussed.     

CHy-banding patterns and chromatin organization inAegilops andTriticum species (Poaceae)

The distribution of CHy-banded heterochromatin was studied in the chromosomes ofAegilops longissima, Ae. speltoides, Triticum monococcum, andT. turgidum. Interphase nuclei were measured after Feulgen staining at different thresholds of optical density; the curves so obtained indicated the relationship among the species with respect to the different fractions of the genomic DNA. The karyological and cytophotometric analyses indicate differences betweenAe. speltoides andAe. longissima, the latter species being enriched in heterochromatin. Similar results were demonstrated for the genusTriticum, in whichT. turgidum showed more heterochromatin when compared withT. monococcum. The results suggest that the B genome of the cultivated wheats possesses a type of heterochromatin that resembles the type present inAe. longissima.     

An NADH nitrate reductase gene copy appears to have been deleted in barley

Cultivated barley,Hordeum vulgare L., has a single NADH nitrate reductase (NR) gene while diploid wheat,Triticum monococcum, and cultivated hexaploid wheat,Triticum aestivum L., have two NADH NR genes. To determine whether the NADH NR gene was duplicated since the divergence ofTriticum fromHordeum or was deleted from barley, theT. Monococcum NADH NR gene heme-hinge regions were sequenced and compared with the barley NADH NR gene sequence. Sequence identity and phylogenetic analyses showed that one of theT. Monococcum NADH NR genes is more-closely related to the barley NADH NR gene than to the otherT. Monococcum NADH NR gene. The heme-hinge region of all three NR genes appeared to have evolved at a constant rate. These results suggest that the NADH NR gene duplicated before the divergence ofTriticum andHordeum and that a deletion resulted in the loss of one NADH NR gene from cultivated barley.     

Analysis of 5S rDNA changes in synthetic allopolyploids <Emphasis Type="Italic">Triticum</Emphasis> × <Emphasis Type="Italic">Aegilops</Emphasis>

Changes of 5S rDNA at the early stage of allopolyploidization were investigated in three synthetic allopolyploids: Aegilops sharonensis × Ae. umbellulata (2n = 28), Triticum urartu × Ae. tauschii (2n = 28), and T. dicoccoides × Ae. tauschii (2n = 42). Fluorescent in situ hybridization (FISH) revealed quantitative changes affecting separate loci of one of the parental genomes in S₃ plants of each hybrid combination. Southern hybridization with genomic DNA of the allopolyploid T. urartu × Ae. tauschii (TMU38 × TQ27) revealed a lower intensity of signals from Ae. tauschii fragments compared with those derived from T. urartu. This confirmed the signal reduction revealed for chromosome 1D of this hybrid by FISH. Neither Southern hybridization nor PCR testing of 5–15 plants of the S₂-S₃ generations revealed an appearance of new 5S rDNA fragments or a complete disappearance of parental fragments from the allopolyploids under study. No changes were found by aligning nine 5S rDNA sequences of the allopolyploid TMU38 × TQ27 with corresponding sequences of the parental species. The similarity between one of the synthetic allopolyploids examined and a natural allopolyploid with the same genome composition points to an early formation of the 5S rDNA organization unique for each allopolyploid.     

Relationships betweenNor-loci from differentTriticeae species

TheNor-loci of polyploid wheats and their putative diploid progenitor species were assayed by probing isolated nuclear DNA with ribosomal DNA spacer sequences (spacer rDNA sequences, isolated by cloning), from theNor-loci of genomes B (Triticum aestivum), G (T. timopheevi), B (syn. S,T. speltoides), A (T. monococcum) and V (Dasypyrum villosum). DNA samples for analysis were digested with the restriction endonuclease Taq 1 and assayed by DNA-DNA hybridization under standard (37°C) and high stringency (64°C) conditions. The assay procedure emphasized differences between the divergent spacer sequences of the polyploid species and allowed relative homologies to the respective sequences in diploid species to be established. — The studies indicated thatT. timopheevi andT. speltoides contain different sets of spacer rDNA sequences which were readily distinguishable and, in the case ofT. timopheevi, assigned toNor-loci on different chromosomes. This contrast with the spacer rDNA sequences of the majorNor-loci on chromosomes 1 B and 6 B inT. aestivum, which were difficult to distinguish and were deduced to contain very similar sequences. Among the diploid progenitor species only the spacer rDNA fromT. speltoides shared close homology with polyploid wheat species. OneNor-locus inT. timopheevi (on chromosome 6 G) did not show close homology with any of the rDNA spacer probes available. — The data suggestsT. speltoides was the origin of someNor-loci for both theT. timopheevi andT. turgidum lines of tetraploid wheats. The possibility that the 6GNor-locus inT. timopheevi may have derived from an unknown diploid species by introgressive hybridization is discussed. The spacer rDNA sequence probe fromT. monococcum shared good homology with some accessions ofD. villosum and a line ofT. dicoccoides; the implications of this finding for evolution of present-day wheats are discussed.     

Acetyl coenzyme A carboxylase in species of Triticum of different ploidy

The cellular amounts and cellular activities of acetyl CoA carboxylase (ACC; EC 6.4.1.2.) were determined in the first leaves of diploid, tetraploid and hexaploid species of Triticum (wheat). Per leaf the ACC activities were very similar in T. monococcum (2 ), T. dicoccum (4 ) and T. aestivum (6 ). The ACC activity per chloroplast also showed little variation between species of different ploidy but since chloroplast number increases with ploidy, the ACC activities and ACC amounts per cell also increased with ploidy. These cellular increases in ACC amounts associated with increases in gene dosage were highly co-ordinated in the diploids T. monococcum and T. tauschii and their respective autotetraploids so the specific activity of ACC was highly conserved in these plants. The relevance of these findings to attempts to genetically manipulate lipid biosynthesis in chloroplasts is discussed.Abbreviation ACC acetyl CoA carboxylase We are very grateful to Dr. Kevin Pyke and Miss Jo Marrison for many helpful discussions and to Dr. Collin Law for the generous gift of seeds.     

Early crop diversity: A “new” glume wheat from northern Greece

At three Neolithic sites and one Bronze Age site in northern Greece, spikelet bases of a new type of glume wheat have been recovered. These spikelet bases are morphologically distinct from the typicalTriticum monococcum L. (einkorn),T. dicoccum Schübl. (emmer) andT. spelta L. (spelt) types previously recorded from Greece and they have also been observed at Neolithic and Bronze Age sites in Turkey, Hungary, Austria and Germany. their taxonomic identification remains uncertain but it seems likely that they are tetraploid, and they have morphological features in common withT. timopheevi Zhuk. Various possibilities exist for the origin of this type but, whatever its origin and exact identity, its cultivation has ceased over large geographical areas since the Bronze Age. At the northern Greek sites, at least, the new type may have been cultivated as a maslin (mixed crop) with einkorn.     

A comparative study of the mitochondrial genome organization in in vitro cultures of diploid, tetraploid, and hexaploid Triticum species

Southern-blot hybridizations of total DNA to mitochondrial DNA (mtDNA) probes were used to investigate the extent of mtDNA variability in cultures derived from immature embryos of diploid (Triticum monococcum, genomic formula: AA, T. tauschii, genomic formula: DD), allotetraploid (T. durum cv Creso, genomic formula: AABB), and allohexaploid (T. aestivum, genomic formula: AABBDD) wheat species. Similar distinct changes in mtDNA organization were observed in in vitro cultures of the derived tetraploid and the hexaploid species with related genomes. The tetraploid and hexaploid species share the B genome and mtDNA variability in in vitro culture is known to be under nuclear control. These results suggest that a study of B genome diploids and other polyploid combinations would now shed light on whether or not mtDNA variability in tissue cultures is under B-genome control.     

Relationships between species ofLeymus,Psathyrostachys, andHordeum (Poaceae,Triticeae) inferred from Southern hybridization of genomic and cloned DNA probes

We have used total genomic DNA as a probe to size-fractionated restriction enzyme digests of genomic DNA from a range ofTriticeae species from the generaLeymus Hochst.,Psathyrostachys Nevski, andHordeum L., and hybrids betweenHordeum andLeymus to investigate their taxonomic relationships. Genomic Southern hybridization was found to be an effective and simple way to assess the distribution and diversity of essentially species-specific and common, repetitive DNA sequences, and is hence especially useful in evolutionary studies. The DNA sequences ofH. vulgare seem to diverge substantially from those ofH. brachyantherum, H. lechleri, H. procerum, andH. depressum. The genome ofThinopyron bessarabicum shows little homology to those of theLeymus species investigated, confirming thatT. bessarabicum is not an ancestral genome inLeymus. Although the genomes ofLeymus andPsathyrostachys share substantial proportions of DNA sequences, they include divergent repeated sequences as well. Hybridization with a ribosomal DNA probe (pTa 71) showed that the coding regions containing structural genes encoding the 18 S, 5.8 S, and 26 S ribosomal RNA were conserved among the species investigated, whereas the intergenic spacer region was more variable, presenting different sizes of restriction fragments and enabling a classification of the species. The rye heterochromatin probe pSc 119.2 hybridized to DNA fromH. lechleri andT. bessarabicum, but not to DNA from the other species investigated.     

Three sucrose transporter genes are expressed in the developing grain of hexaploid wheat

A family of three cDNAs, designated TaSUT1A, 1B and 1D, encoding sucrose transporter (SUT) proteins was isolated from a hexaploid wheat (Triticum aestivum) endosperm library. The cDNA sequences are 96% identical but are distinguishable from one another by virtue of a size polymorphism in the 3-untranslated region (UTR). The predicted amino acid sequences are 98% identical and are highly similar to the sucrose transporters from rice, maize and barley. A gene for TaSUT1 was isolated from genomic libraries of Aegilops tauschii (the donor of the D genome of wheat) and the coding sequence found to be identical to that of TaSUT1D cDNA. There is only one copy of each TaSUT1 gene in hexaploid wheat and it is located on chromosome 4. Genomic Southern analysis and PCR analysis across the 3 polymorphic region of hexaploid, tetraploid and progenitor diploid wheat DNAs established that the TaSUT1A gene was present in the putative A-genome progenitor, T. monococcum, and that the TaSUT1B gene was present in the putative B-genome progenitor, T. searsii. All three TaSUT1 genes are expressed at high levels in filling grain, showing a good correlation with the developmental time course of growth. This reinforces the view that in cereals a major role of SUT1 is in the post-phloem sugar transport pathway associated with seed filling.     

What is happening to the monocotyledons?

An attempt is made to elucidate some of the more pronounced departures from traditional classifications in the book The families of the monocotyledons byDahlgren and collaborators, which embodies the latest opinions of the lateRolf Dahlgren on the subject. Consideration is given to the treatment of theLiliiflorae (especiallyLiliales andAsparagales) andBromeliiflorae, and to the theory offered for the origin of the monocots which identifies theDioscoreales as the most primitive order of the subclass.Dahlgren aimed at an eclectic classification (one based on a combination of similarity criteria and phylogenetic criteria) and the results of his use of cladistic methods (in association withF. N. Rasumssen) to supply the phylogenetic input are assessed. The resulting system itself is considered in the light of the distinction drawn byJ. S. L. Gilmour between natural and artificial classifications and their respective uses.Dedicated to the memory of JohnS. L. Gilmour.     

Isolation and nucleotide sequence of an autonomously replicating sequence (ARS) element functional in Candida albicans and Saccharomyces cerevisiae

Summary An 8.6-kb fragment was isolated from an EcoRI digest of Candida albicans ATCC 10261 genomic DNA which conferred the property of autonomous replication in Saccharomyces cervisiae on the otherwise non-replicative plasmid pMK155 (5.6 kb). The DNA responsible for the replicative function was subcloned as a 1.2-kb fragment onto a non-replicative plasmid (pRC3915) containing the C. albicans URA3 and LEU2 genes to form plasmid pRC3920. This plasmid was capable of autonomous replication in both S. cerevisiae and C. albicans and transformed S. cerevisiae AH22 (leu2 ^–) to Leu⁺ at a frequency of 2.15 × 10³ transformants per pg DNA, and transformed C. albicans SGY-243 (ura3) to Ura⁺ at a frequency of 1.91 × 10³ transformants per g DNA. Sequence analysis of the cloned DNA revealed the presence of two identical regions of eleven base pairs (5TTTTATGTTTT3) which agreed with the consensus of autonomously replicating sequence (ARS) cores functional in S. cerevisiae. In addition there were two 10/11 and numerous 9/11 matches to the core consensus. The two 11/11 matches to the consensus, CaARS1 and CaARS2, were located on opposite strands in a non-coding AT-rich region and were separated by 107 bp. Also present on the C. albicans DNA, 538 by from the ARS cores, was a gene for 5S rRNA which showed sequence homology with several other yeast 5S rRNA genes. A sub-fragment (494 bp) containing the 5S rRNA gene (but not the region containing the ARS cores) hybridized to genomic DNAs from a number of yeast species, including S. cerevisiae, C. tropicalis, C. pseudotropicalis, C. parapsilosis, C. kruseii, C. (Torulopsis) glabrata and Neurospora crassa. The 709-bp ARS element (but not the 5S rRNA gene) was necessary for high-frequency transformation and autonomous plasmid replication in both S. cerevisiae and C. albicans.EMBL/GenBank database accession number: X16634 (5S rRNA)     

5S and 5.8S ribosomal RNA evolution in the suborder tetrahymenina (Ciliophora: Hymenostomatida)

Summary The nucleotide sequences of the 5S and 5.8S rRNAs of eight strains of tetrahymenine ciliates have been determined. The sequences indicate a clear distinction betweenTetrahymena paravorax and its suggested conspecificT. vorax, but leave the taxonomic distinction betweenT. vorax andT. leucophrys in doubt. The rRNA sequences of sixTetrahymena species and of three other species of the suborder Tetrahymenina have been used to deduce evolutionary schemes in which ancestral rRNA sequences and changes are proposed. These schemes suggest the predominant acceptance of GA and CT transitions in the 5S rDNA during the evolution of the suborder.     

Relationships betweenOryza species (Poaceae) based on 5S DNA sequences

Relationships between 9Oryza species, covering 6 different genomes, have been studied using hybridization and nucleotide sequence information from the5S Dna locus. Four to five units of the major size class of 5S DNA in each species, 55 units in all, were cloned and sequenced. Both hybridization and sequence data confirmed the basic differences between the A and B, C, D genome species suggested by morphological and cytological data. The 5S DNA units of the A genome species were very similar, as were the ones from the B, C, and D genome-containing species. The 5S DNA ofO. australiensis (E genome) grouped with the B, C, D cluster, while the units ofO. brachyantha (F genome) were quite different and grouped away from all other species. 5S DNA units fromO. minuta, O. latifolia, O. australiensis, andO. brachyantha hybridized strongly, and preferentially, to the genomic DNA from which the units were isolated and hence could be useful as species/genome specific probes. The 5S DNA units fromO. sativa, O. nivara, andO. rufipogon provided A genome-specific probes as they hybridized preferentially to A genome DNA. The units fromO. punctata andO. officinalis displayed weaker preferential hybridization toO. punctata DNA, possibly reflecting their shared genome (C genome).     

Aspartate aminotransferase and alcohol dehydrogenase isoenzymes: Intraspecific differentiation inAegilops tauschii and the origin of the D genome polyploids in the wheat group

Polyacrylamide gel electrophoresis of aspartate aminotransferase (AAT, EC 2.6.1.1) and alcohol dehydrogenase (ADH, EC 1.1.1.1) isoenzymes reveals intraspecific differentiation ofAegilops tauschii Coss. (=Ae. squarrosa auct., non L.) into two groups of biotypes which essentially correspond to its two morphological subspecies, subsp.tauschii and subsp.strangulata (Eig)Tzvel. Subsp.tauschii which is characterized by a slower electromorph of AAT-B and a faster electromorph of ADH-A is identified as the contributor of its D genome to the tetraploidAe. cylindrica Host and the hexaploidAe. crassa Boiss. subsp.crassa. Subsp.strangulata, being distinguished by a faster electromorph of AAT-B and a slower electromorph of ADH-A, has contributed the D genome to the hexaploid bread wheats (Triticum aestivum L. emend.Thell.), the tetraploidsAe. crassa subsp.macrathera (Boiss.)Zhuk. andAe. ventricosa Tausch, and the hexaploidAe. juvenalis (Thell.)Eig. —Aegilops comosa Sibth. etSm. s. lat. is questioned as the contributor of the M genome toAe. crassa. Furthermore, the S genome diploidsAe. bicornis (Forsk.)Jaub. & Spach,Ae. longissima Schweinf. & Muschl. s. lat. andAe. searsii Feldman & Kislev are all considered unsuitable as the wheat B genome donors on the basis of the AAT isoenzyme data.     

Hybridization between South American Jarilla and North American diploid creosotebush (Larrea,Zygophyllaceae)

Different strains of the two diploidLarrea speciesL. divaricata (S. America) andL. tridentata (N. America), are compared morphologically, cytologically, and in their seed proteins. There are minor differences, also in chiasma frequencies. Experimental F₁ hybrids have near-normal meiosis but are semisterile. The parental species, therefore, biologically may be considered allopatric semispecies.     

The phylogenetic relationships ofByblis andRoridula (Byblidaceae-Roridulaceae) inferred from partial 18S ribosomal RNA sequences

The phylogenetic relationships of the angiosperm generaByblis andRoridula have been the subject of ongoing taxonomic controversy. Twenty-eight taxa of varying degrees of alleged relationship, including 3 members of theWinteraceae (as an outgroup), were investigated using partial sequences of 18S rRNA (small subunit) and also compared against the morphological data set fromHufford's (1992) cladistic treatment of 80 members of theRosidae-Asteridae. The morphological analysis placed the two genera in a clade with theSarraceniaceae in theCorniflorae-Asterid group as a sister taxon to anEricales-Hydrangeales clade. The 18S rRNA analysis supports the recently publishedrbcL DNA analysis ofAlbert & al. (1992), withRoridula joined to taxa in the lowerRosidae, butByblis joining instead to members of theAsteridae near theSolanaceae. Comparisons for congruence between the three analyses placeByblis in the higher Asterid group near theSolanaceae, andRoridula possibly nearer theSarraceniaceae andEricales. These results imply that the traditional morphological characters used to relate the two genera are possibly the result of convergence towards similar ecological and life-history strategies rather than synapomorphies.     

Species relationships and genetic variation in the diploid wheats (Triticum,Aegilops) as revealed by starch gel electrophoresis

Twenty enzyme loci were examined in the diploid species ofTriticum andAegilops for allelic variation by starch gel electrophoresis. SectionSitopsis, including the five species,Ae. speltoides, Ae. lingissima, Ae. sharonensis, Ae. bicornis andAe. searsii form a close subgroup withAe. speltoides slightly removed from the others.T. monococcum s. lat., was found to be closest to the species of theSitopsis group.Ae. comosa, Ae. umbellulata andAe. uniaristata form a second subgroup withAe. caudata most closely related to these species.Ae. squarrosa appears almost equally related to all of the species, showing no special affinity for any one species group. Nineteen out of twenty loci examined were polymorphic with a mean of 6.7 alleles per locus. Species could be, for most loci, characterized by the presence of predominant alleles. A conspicious genetic characteristic ofTriticum-Aegilops is the sharing of these predominant alleles between species. Within species variation is characterized by a diffuse distribution of secondary alleles.     

Studies on theStellaria longipes complex (Caryophyllaceae): Isozyme variability and the relationship betweenStellaria longipes andS. longifolia

Genetic variation within and the relationship betweenStellaria longipes Goldie andS. longifolia Muhl. were studied. Ten enzyme systems were assessed in eight natural populations ofS. longipes (25 loci) and three ofS. longifolia (20 loci) using starch and polyacrylamide gel electrophoresis. Patterns of population differentiation corresponded to geographic distance. There was no evidence that polyploidS. longipes had greater electrophoretic variability than diploidS. longipes. The isozyme data confirmed extensive population differentiation in these species and, within that context, a relatively close relationship betweenS. longipes andS. longifolia. It was postulated that diploids of these two species might be the progenitors of tetraploidS. longipes.     

Inhibitory activities against heterologous α-amylases and in vitro allergenic reactivity of Einkorn wheats

Salt extracts from seeds of 36 lines of Einkorn wheats were analyzed for their inhibitory activity towards two insect (Tenebrio molitor, Coleoptera, and Ephestia kuehniella, Lepidoptera) and one mammalian (human salivary) -amylases. Whereas all ten T. monococcum accessions tested were active towards the lepidopteran enzyme, they had no effect on the coleopteran or the mammalian ones. More variability was found among the 21 lines of T. boeticum analyzed, although none of them inhibited human -amylase. The five accessions of T. urartu showed even greater diversity. Among all Einkorn accessions tested, only two urartu lines affected the three -amylases. These lines displayed inhibition patterns similar to those of T. aestivum and T. turgidum cultivars. Since several breadwheat -amylase inhibitors are major allergens associated with baker's asthma, we also studied the in vitro allergenic activity of salt extracts from the Einkorn wheats under study. No significant differences in IgE-binding were found between these accessions and theT. aestivum or T. turgidum cultivars. Furthermore, putative allergens with molecular sizes in the range of 20–60 kDa were detected in these Einkorn wheats.