A Fragment of the rpoC2 Chloroplast RNA Polymerase Gene in Perennial and Annual Rye

A 1397-bp fragment corresponding to the rpoC2 chloroplast RNA polymerase gene was obtained by direct rye DNA amplification. Two rye species, Secale montanum Guss. and S. cereale L., did not practically differ in the structure of this DNA fragment (the nucleotide sequences were 99% identical). The corresponding nucleotide sequences in rye and wheat (Triticum aestivum L., Genbank accession no. AB027572) were 97–98% similar. The extent of the homology of various stretches of the rpoC2 rye gene with the corresponding sequences in maize and rice was 81–95%, whereas the deduced amino acid sequences of rpoC2 in rye, wheat, maize, and rice were considerably identical (96–97% of homology). The rye fragment of the rpoC2 gene differed from the corresponding sequences in three other grass species primarily by a short (49 bp) insert into the region of numerous short repeats corresponding to nucleotides 15750/15751, 28728/28729, and 27472/27473 in wheat, maize, and rice, respectively.     

Homologs of the Genes for Receptor-Like Kinase Proteins Conferring Plant Resistance to Pathogens: Resistance Gene Homologs in Solanum Species

Direct amplification of the genomic DNA from cultivated and wild Solanum species was used to synthesize three groups of NBS-LRR homologs of the genes which encode the pathogen-recognizing receptor-like serine/threonine kinases (RLK): (1) the NBS-kinase regions homologous to the arabidopsis RPS2 gene, the tobacco N gene, and the flax L6 gene (the corresponding GenBank accession nos. U14158, U15605, and U27081); (2) full-size sequences homologous to the Pto gene of Lycopersicon pimpinellifolium (AF220602); and (3) LRR regions homologous to potato genesGpa2/Rx1 (AJ249449 and AJ011801) and the tomato gene Mi1 (AF091048). The nucleotide and deduced amino acid sequences of the cloned fragments of the genes and pseudogenes were compared to the already known genes and their homologs within the family Solanaceae.     

Two Homologs of the FLOWERING LOCUS C Gene from Leaf Mustard (Brassica juncea)

Using the direct amplification of genomic DNA from two cultivars of leaf mustard (Brassica juncea), we obtained two homologs of the MADS-box gene FLOWERING LOCUS C(FLC), which regulates flowering time in arabidopsis. Nucleotide and deduced amino acid sequences of two cloned FLC fragments (from exon 2 to exon 7) were compared to the previously characterized FLC genes in arabidopsis and FLC homologs in other Brassicaceae species. The homolog AY266265 is an ortholog of the FLC3 gene from Brassica rapa (95% identity), whereas the function of the homolog AY268931 has not been established conclusively. The FLC gene and its homologs were used to compare the variability in the primary structures of exons and introns.     

K-Box Sequence of the Apetala1-Class MADS-Box Genes in Hexaploid Wheat

Direct amplification of genomic DNA from four wheat species produced DNA fragments corresponding to the K-box sequence of the apetala1/squamosa class of the MADS-box genes. Exons 3 to 5 were highly conserved within the tribe Triticeae and very similar to the apetala1 genes of darnel ryegrass, rice, and maize. Most of the variations observed were due to synonymous substitutions: the deduced amino acid sequences were 89–99% similar within the Triticeae and 88–94% within the entire family Poaceae. Introns 3 and 4 of the apetala1 class genes were similar in wheat and rye and differed from those in other MADS-box genes presently known.     

Structure of the <Emphasis Type="Italic">TADHN</Emphasis> gene for dehydrin-like protein of soft wheat and activation of its expression by ABA and 24-epibrassinolide

The structure of the cloned fragment of wheat (Triticum aestivum L.) TADHN gene encoding dehydrin-like protein was examined. A comparative analysis of nucleotide and deduced amino acid sequences revealed a high homology of this fragment with sequences of the barley dhn8 gene and wheat wcor gene family. In deduced amino acid sequence of the TADHN fragment, a 15-residue region EKKGFLEKIKEKLPG was found, which corresponded to a highly conserved K-segment of dehydrins. Wheat seedling treatment with 3.7 μM ABA and 0.4 μM 24-epibrassinolide exerted similar stimulatory effects on expression of the TADHN gene, which indicates the involvement of dehydrins in the protective action of these phytohormones in wheat plants.     

Isolation and Characterization of Two Saccharomyces Cerevisiae Genes Encoding Homologs of the Bacterial Hexa and Muts Mismatch Repair Proteins

Homologs of the Escherichia coli (mutL, S and uvrD) and Streptococcus pneumoniae (hexA, B) genes involved in mismatch repair are known in several distantly related organisms. Degenerate oligonucleotide primers based on conserved regions of E. coli MutS protein and its homologs from Salmonella typhimurium, S. pneumoniae and human were used in the polymerase chain reaction (PCR) to amplify and clone mutS/hexA homologs from Saccharomyces cerevisiae. Two DNA sequences were amplified whose deduced amino acid sequences both shared a high degree of homology with MutS. These sequences were then used to clone the full-length genes from a yeast genomic library. Sequence analysis of the two MSH genes (MSH = mutS homolog), MSH1 and MSH2, revealed open reading frames of 2877 bp and 2898 bp. The deduced amino acid sequences predict polypeptides of 109.3 kD and 109.1 kD, respectively. The overall amino acid sequence identity with the E. coli MutS protein is 28.6% for MSH1 and 25.2% for MSH2. Features previously found to be shared by MutS homologs, such as the nucleotide binding site and the helix-turn-helix DNA binding motif as well as other highly conserved regions whose function remain unknown, were also found in the two yeast homologs. Evidence presented in this and a companion study suggest that MSH1 is involved in repair of mitochondrial DNA and that MSH2 is involved in nuclear DNA repair.     

Characterisation of two gene subunits on the 1R chromosome of rye as orthologs of each of the Glu-1 genes of hexaploid wheat

The visco-elastic properties of bread flour are firmly associated with the presence or absence of certain HMW subunits coded by the Glu-1 genes. Identifying allelic specific molecular markers (AS-PCR) associated with the presence of Glu-1 genes can serve as a valuable tool for the selection of useful genotypes. This paper reports the use of primers designed from nucleotide sequences of the Glu-D1 gene of wheat (AS-PCR for Glu-D1y10) that recognise and amplify homologous sequences of the Glu-R1 gene subunits of rye. The primers amplify the complete coding regions and provided two products of different size in rye, in wheats carrying the substitution 1R(1D) and in rye-wheat aneuploid lines carrying the long arm of chromosome 1R. The location, the molecular characterisation of these sequences and their expression during grain ripening seem to demonstrate that the amplification products correspond to structural genes encoding the high-molecular-weight (HMW) glutenins of rye. The homology of the rye gene to subunits encoding HMW glutenins in wheat was confirmed by Southern blots and sequencing. The amplification-products were cloned, sequenced and characterised, and the sequences compared with the main glutenin subunits of wheat and related species. Further, an RT-PCR experiment was performed using primers designed from the sequence of both amplified products. This assay demonstrated that both sequences are expressed in endosperm during grain ripening. The results of these analyses suggest that both gene subunits correspond to x- and y-type genes of the Glu-R1 locus of rye. Received: 11 December 2000 / Accepted: 17 April 2001     

Cloning and characterisation of a family of disease resistance gene analogs from wheat and barley

 The most common class of plant disease resistance (R) genes cloned so far belong to the NBS-LRR group which contain nucleotide-binding sites (NBS) and a leucine-rich repeat (LRR). Specific primer sequences derived from a previously isolated NBS-LRR sequence at the Cre3 locus, which confers resistance to cereal cyst nematode (CCN) in wheat (Triticum aestivum L.) were used in isolating a family of resistance gene analogs (RGA) through a polymerase chain reaction (PCR) cloning approach. The cloning, analysis and genetic mapping of a family of RGAs from wheat (cv ‘Chinese Spring’) and barley (Hordeum vulgare L. cvs ‘Chebec’ and ‘Harrington’) are presented. The wheat and barley RGAs contain other conserved motifs present in known R genes from other plants and share between 55–99% amino acid sequence identity to the NBS-LRR sequence at the Cre3 locus. Phylogenetic analysis of the RGAs with other cloned R genes and RGAs from various plant species indicate that they belong to a superfamily of NBS-containing genes. Two of the barley derived RGAs were mapped onto loci on chromosomes 2H (2), 5H (7) and 7H (1) using barley doubled haploid (DH) mapping populations. Some of these loci identified are associated with regions carrying resistance to CCN and corn leaf aphid. Received: 6 January 1998 / Accepted: 1 April 1998     

Polymorphism of the Stamina pistilloida Gene in Pea Plants

Using the direct amplification of genomic DNA from two pea (Pisum sativum) cultivars, we obtained four new homologs of the Stamina pistilloida (Stp) gene, an ortholog of the UNUSUAL FLORAL ORGANS (UFO) and Fimbriata (Fim) of arabidopsis and snapdragon. The UFO/Fim gene is involved in cell determination in the shoot apical meristem and the floral meristem and controls the expression of B- and C-class genes of flower organ differentiation; in addition, in pea plants, the Stp gene controls leaf shape, plant height, and the number of internodes to the first inflorescence. The nucleotide and deduced amino acid sequences of the Stp homologs characterized in this study were very similar to the prototype gene from pea cv. Torsdag (98%) and significantly differed between cvs. Filby and Sebeco 59-61-65-6 contrasting in the compound-leaf architecture.