Spontaneous spectinomycin resistance mutations of the chloroplast <Emphasis Type="Italic">rrn16</Emphasis> gene in <Emphasis Type="Italic">Daucus carota</Emphasis> callus lines

Bioballistic transformation of carrot (Daucus carota L.) callus cultures with a plasmid containing the aadA (aminoglycoside 3′-adenyltransferase) gene and subsequent selection of transformants on a selective medium containing spectinomycin (100–500 mg/l) yielded ten callus lines resistant to this antibiotic. PCR analysis did not detect exogenous DNA in the genomes of spectinomycin-resistant calluses. Resistance proved to be due to spontaneous mutations that occurred in two different regions of the chloroplast rrn16 gene, which codes for the 16S rRNA. Six lines displayed the G > T or G > C transverions in position 1012 of the rrn16 gene, and three lines had the A > G transition in position 1138 of the gene. Chloroplast mutations arising during passages of callus cultures in the presence of spectinomycin were described in D. carota for the first time. The cause of spectinomycin resistance was not identified in one line. The mutations observed in the D. carota plastid genome occurred in the region that is involved in the formation of a double-stranded region at the 3′ end of the 16S rRNA and coincided in positions with the nucleotide substitutions found in spectinomycin-resistant plants of tobacco Nicotiana tabacum L. and bladderpod Lesquerella fendleri L.     

A <Emphasis Type="Italic">gyrB</Emphasis>-targeted PCR for Rapid Identification of <Emphasis Type="Italic">Salmonella</Emphasis>

Salmonella causes the majority of infections in humans and homeothermic animals. This article describes a specific polymerase chain reaction (PCR) method developed for a rapid identification of Salmonella. A gyrB-targeted species-specific primer pair, S-P-for (5′-GGT GGT TTC CGT AAA AGT A-3′) and S-P-rev (5′-GAA TCG CCT GGT TCT TGC-3′), was successfully designed. PCR with all the Salmonella strains produced a 366- bp DNA fragment that was absent from all the non-Salmonella strains tested. The detection limit of the PCR was 0.01 ng with genomic DNA or 3.2 cells per assay. Good specificity was also demonstrated by fecal samples, from which only the gyrB gene of Salmonella was amplified. Using the culture-PCR method, 27 isolates on Salmonella-Shigella (SS) medium were rapidly identified as Salmonella, which was confirmed by the sequencing of the gyrB gene.     

Cytological and molecular characterization of a novel monogenic dominant GMS in <Emphasis Type="Italic">Brassica napus</Emphasis> L.

A novel genic male sterile (GMS) line in Brassica napus L., which was identified in 1999, was found to be controlled by a monogenic dominant gene, which we have designated as MDGMS. The microspores of the MDGMS abort before the degradation of the tapetal cell layer. The F1 fertility from any fertile lines crossed with MDGMS segregated and the ratio was close to 1:1. Bulked segregation analysis (BSA) was employed to identify random amplified polymorphic DNA (RAPD) markers linked to the Ms gene in MDGMS. Among 880 random 10-mer oligonucleotide primers screened against the bulk DNA of sterile and fertile, one primer S243 (5′-CTATGCCGAC-3′) gave a repeatable 1500-bp DNA polymorphic segment S243₁₅₀₀ between the two bulks. Analysis of individual plants of each bulks and other types of GMS and cytoplasmic male sterility (CMS) lines suggest that the RAPD marker S243₁₅₀₀ is closely linked to the MDGMS locus in rapeseed. This RAPD marker has been converted into sequence characterized amplified region (SCAR) marker to aid identification of male-fertility genotypes in segregating progenies of MDGMS in marker-assisted selection (MAS) breeding programs.     

Significance of Stereochemistry of 3′-Terminal Phosphorothioate-modified Primer in DNA Polymerase-mediated Chain Extension

Influence of stereochemistry of the 3′-terminal phosphorothioate (PS)-modified primers was studied in a single base extension (SBE) assay to evaluate any improvements in specificity. SBE reactions were catalyzed by members of the high fidelity Pfu family of DNA polymerases with (exo+) or without (exo−) 3′ → 5′ exonucleolytic activity. The diastereomerically pure PS-labeled primers used in these studies were obtained either by the stereospecific chemical synthesis invented in our laboratory or by the more conventional ion-exchange chromatographic method for separation of a mixture of diastereomers (R_P and S_P). When the SBE reaction was performed in the presence of mispaired 2′-deoxyribonucleoside triphosphates (dNTPs), the “racemic” 3′-phosphorothioate primer mixture resulted in a lower level of 3′ → 5′ exonuclease-mediated cleavage products in comparison to the SBE reactions carried out with the corresponding unmodified primer. When the diastereomerically pure R_P 3′-phosphorothioate primer was examined, the results were largely the same as for the racemic 3′-phosphorothioate primer mixture. In contrast, a 3′-PS primer of S_P configuration displayed significantly improved performance in the SBE reaction. This included the lack of 3′ → 5′ proofreading products, less mispriming, and improved yield of incorporation of the correct nucleotide.     

Use of 16S rDNA Sequences as Signature Characters to Identify Xylella fastidiosa

The nucleotide sequences of 16S rDNAs (coding for the small subunit ribosomal RNAs) were used to identify Xylella fastidiosa, a nutritionally fastidious plant pathogenic bacterium. The near-complete 16S rDNAs from nine strains of Xyl. fastidiosa, including seven pathotypes and one strain of Xanthomonas campestris pv. campestris, were amplified through PCR with two conserved primers (forward primer 5′-AGA GTT TGA TCC TGG CTC AG-3′ and reverse primer 5′-AAG GAG GTG ATC CAG CC-3′) and sequenced. The 16S sequences were compared with all eukaryote and prokaryote DNA entries in GenBank database. A Xyl. fastidiosa 16S rDNA sequence, M26601, was determined to be the most similar to all the near-complete (1537 bp) and partial 5′ end sequences from Xyl. fastidiosa, but not those from the Xanthomonas strain. A 20-bp oligonucleotide (5′-TTG GTA GTA ATA CCA TGG GT-3′) was found to be highly characteristic of Xyl. fastidiosa. Since the 16S rDNA of Xyl. fastidiosa strains are highly homologous and characteristically different from other bacteria, including the most closely related Xanthomonas, 16S rDNA sequences can be used as signature characters to identify this bacterium. Received: 22 June 1999 / Accepted: 2 August 1999     

Development of a molecular marker specific to a novel CMS line in radish (Raphanus sativus L.)

In this study, we have investigated the cytoplasmic male sterility (CMS) of a novel male sterile radish line, designated NWB CMS. The NWB CMS was crossed with 16 fertile breeding lines, and all the progenies were completely male sterile. The degree of male sterility exhibited by NWB CMS is more than Ogura CMS from the Cruciferae family. The NWB CMS was found to induce 100% male sterility when crossed with all the tested breeding lines, whereas the Ogura CMS did not induce male sterility with any of the breeding lines. PCR analysis revealed that the molecular factor that influenced Ogura CMS, the orf138 gene, was absent in the NWB CMS line, and that the orf138 gene was not also expressed in this CMS line. In order to identify the cytoplasmic factors that confer male sterility in the NWB CMS line, we carried out RFLP analyses with 32 mitochondrial genes, all of which were used as probes. Fourteen genes exhibited polymorphisms between the NWB CMS line and other radish cultivars. Based on these RFLP data, intergenic primers were developed in order to amplify the intergenic regions between the polymorphic genes. Among these, a primer pair at the 3′ region of the atp6 gene (5′-cgcttggactatgctatgtatga-3′) and the 5′ region of the nad3 gene (5′-tcatagagaaatccaatcgtcaa-3′) produced a 2 kbp DNA fragment as a result of PCR. This DNA fragment was found to be specific to NWB CMS and was not present in other CMS types. It appears that this fragment could be used as a DNA marker to select NWB CMS line in a radish-breeding program.     

Analysis of transitive RNA silencing after grafting in transgenic plants with the coat protein gene of <Emphasis Type="Italic">Sweet potato feathery mottle virus</Emphasis>

We have previously reported the graft transmission of target specificity for RNA silencing using transgenic Nicotiana benthamiana plants expressing the coat protein gene (CP, including the 3′ non-translated region) of Sweet potato feathery mottle virus. Transgenic plants carrying the 5′ 200 and 400 bp regions of CP were newly produced. From these plants, two silenced and two non-silenced lines were selected to investigate the manifestation of transitive RNA silencing by graft experiments. Non-silenced scions carrying the entire transgene were grafted onto either 5′ or 3′ silencing inducer rootstocks. When non-silenced scions were grafted onto 5′ silencing inducer rootstocks, RNA silencing was induced in the non-silenced scions and spread toward the 3′ region of the transgene mRNA. Similarly, when non-silenced scions were grafted onto 3′ silencing inducer rootstocks, RNA silencing was induced in the non-silenced scions, but was restricted to the 3′ region of the transgene and did not spread to the 5′ region. In addition, results from crossing experiments, involving non-silenced and 3′ silencing inducer plants, confirmed the above finding. This indicates that RNA silencing spreads in the 5′–3′ direction, not in the 3′–5′ direction, along the transgene mRNA.     

Strategies for Amplification by Polymerase Chain Reaction of the Complete Sequence of the Gene Encoding Nuclear Large Subunit Ribosomal RNA in Corals

The nearly complete nuclear large subunit ribosomal RNA (LSU rRNA) gene in corals was amplified by primers designed from polymerase chain reaction (PCR) strategies. The motif of the putative 3′-terminus of the LSU rRNA gene was sequenced and identified from intergenic spacer (IGS) clones obtained by PCR using universal primers designed for corals. The 3′-end primer was constructed in tandem with the universal 5′-end primer for the LSU rRNA gene. PCR fragments of 3500 bp were amplified for octocorals and non-Acropora scleractinian corals. More than 80% of the Acropora LSU rRNA gene (3000 bp) was successfully amplified by modification of the 5′-end of the IGS primer. Analysis of the 5′-end of LSU rDNA sequences, including the D1 and D2 divergent domains, indicates that the evolutionary rate of the LSU rDNA differs among these taxonomic groups of corals. The genus Acropora showed the highest divergence pattern in the LSU rRNA gene, and the presence of a long branch of the Acropora clade from the other scleractinian corals in the phylogenetic tree indicates that the evolutionary rate of Acropora LSU rDNA might have accelerated after divergence from the common ancestor of scleractinian corals. Received February 17, 2000; accepted June 12, 2000.     

Genetic structure of the Far Eastern population of Eurasian wigeon <Emphasis Type="Italic">Anas penelope</Emphasis> inferred from sequencing of the mitochondrial DNA control region

Sequence variation of the 5′ end of the mitochondrial DNA control region (600 bp) was examined in the population samples of Eurasian wigeon Anas penelope from Anadyr’ and Primorye. A total of 11 different mtDNA haplotypes were identified, with one of these belonging to American wigeon Anas americana. The presence of the mtDNA haplotype from the species closely relative to A. penelope in the Anadyr’ sample can be considered as the genetic evidence in favor of interspecific hybridization. This suggestion is in the good agreement with ornithological data. Genetic differentiation of the Primorye and Anadyr’ populations was low (Φ_st = 0.096). The phylogeographic structure was not pronounced.     

Characterization of MspNI (G/GWCC) and MspNII (R/GATCY), novel thermostable Type II restriction endonucleases from <Emphasis Type="Italic">Meiothermus</Emphasis> sp., isoschizomers of AvaII and BstYI

MspNI and MspNII, isoschizomers of prototype Type II restriction endonucleases AvaII and BstYI, were extracted from an extreme thermophile bacterium belonging to the genus Meiothermus, isolated from the hot sulphur springs in north Himalayan region of India where temperature and pH ranged from 60 to 80°C and 7.5 to 8.5, respectively. The two enzymes were purified to homogeneity using Cibacron-Blue 3GA Agarose, Q-Sepharose and SP-Sepharose chromatography and were homodimers with subunit molecular weights of 27 and 45 kDa, respectively. Restriction mapping and run-off sequencing of MspNI and MspNII cleaved pBR322 DNA showed that they recognized and cleaved 5′-G/GWCC-3′ and 5′-R/GATCY-3′ sites, respectively. MspNI and MspNII worked optimally at 60 and 70°C, 6 and 5 mM MgCl₂, respectively and showed no star activity in organic solvents. Both were resistant to sequence methylation and were stable up to 25 PCR cycles.     

RACE using only a gene-specific primer

This article describes a simple method for accurate rapid amplification of complementary deoxyribonucleic acid (cDNA) ends (RACE), the distinctive feature being that only a gene-specific primer is used, without an anchor or adapter primer. Under these conditions, Thermus aquaticus (Taq) polymerase synthesizes cDNA ends exactly, so that amplified products obtain a characteristic structure: a terminal inverted repeat composed of a gene-specific primer and occasionally several nucleotides from its 3′ flanking sequence. These structures suggest a hypothetical mechanism of cDNA end synthesis in which Taq DNA polymerase synthesizes a sequence complementary to the gene-specific primer at the 3′ end of the daughter strand by switching the template to the 5′ terminal region through circularization of the DNA. As a result, the targeted cDNA will be efficiently amplified with only a single gene-specific primer. This technique, which provides highly specific amplification of the 5′ and 3′ ends of a cDNA, is especially useful for isolation of cDNA when the corresponding messenger ribonucleic acid is scarce.     

Identification of a codominant amplified polymorphic DNA marker linked to the verticillium wilt resistance gene in tomato

Resistance to verticillium wilt, a vascular disease causing yield losses in many crops, is conferred in tomato by a single dominant allele, Ve. A population segregating for the Ve allele was generated using near-isogenic tomato lines. Analysis of the parental tomato DNA using the polymerase chain reaction and 400 random primers, each 10 deoxyribonucleotides in length, produced 1,880 amplified DNA fragments. Of the four polymorphisms observed between the resistant and susceptible parental genotypes, only one was linked to the Ve gene. No recombination was observed between this DNA marker and the Ve locus, indicating that the linkage is less than 3.5±2.7 cM. The marker detected both the susceptible and resistant alleles, producing amplified DNA fragments of approximately 1,300 and 1,350 bp, respectively. The sequence of the primer, determined from cloned amplified products, was 5 CTCACATGCA 3 instead of the expected 5 CTCACATGCC 3. The marker will be of value to tomato breeding programs because of the tight linkage, Codominant nature, and analytical procedure utilized.     

Linkage of a RAPD marker with powdery mildew resistance <Emphasis Type="Italic">er-1</Emphasis> gene in <Emphasis Type="Italic">Pisum sativum</Emphasis> L.

The aim of this study was to investigate the inheritance of powdery mildew disease and to tag it with a DNA marker to utilize for the marker-assisted selection (MAS) breeding program. The powdery mildew resistant genotype Fallon ^er and susceptible genotype 11760-3 ^ER were selected from 177 genotypes by heavy infestation of germplasm with Erysiphe pisi through artificial inoculation The F₁ plants of the cross Fallon/11760-3 indicated the dominance of the susceptible allele, while F₂ plants segregated in 3: 1 ratio (susceptible: resistant) that fit for goodness of fitness by χ² (P > 0.07), indicating monogenic recessive inheritance for powdery mildew resistance in Pisum sativum. A novel RAPD marker OPB18 (5′-CCACAGCAGT-3′) was linked to the er-1 gene with 83% probability with a LOD score of 4.13, and was located at a distance of 11.2 cM from the er-1 gene.     

Analysis and validation of genome-specific DNA variations in 5′ flanking conserved sequences of wheat low-molecular-weight glutenin subunit genes

The thirty-three 5′ flanking conserved sequences of the known low-molecular-weight subunit (LMW-GS) genes have been divided into eight clusters, which was in agreement with the classification based on the deduced N-terminal protein sequences. The DNA polymorphism between the eight clusters was obtained by sequence alignment, and a total of 34 polymorphic positions were observed in the approximately 200 bp regions, among which 18 polymorphic positions were candidate SNPs. Seven cluster-specific primer sets were designed for seven out of eight clusters containing cluster-specific bases, with which the genomic DNA of the ditelosomic lines of group 1 chromosomes of a wheat variety ‘Chinese Spring’ was employed to carry out chromosome assignment. The subsequent cloning and DNA sequencing of PCR fragments validated the sequences specificity of the 5′ flanking conserved sequences between LMW-GS gene groups in different genomes. These results suggested that the coding and 5′ flanking regions of LMW-GS genes are likely to have evolved in a concerted fashion. The seven primer sets developed in this study could be used to isolate the complete ORFs of seven groups of LMW-GS genes, respectively, and therefore possess great value for further research in the contributions of a single LMW-GS gene to wheat quality in the complex genetic background and the efficient selections of quality-related components in breeding programs.     

Molecular cloning and characterization of a flavonoid 3′-hydroxylase gene from purple-fleshed sweet potato (Ipomoea batatas)

Flavonoid 3′-hydroxylase (F3′H: EC 1.14.13.21) is an important enzyme which determines the hydroxylation pattern of anthocyanins. In this study, the full-length cDNA and genomic DNA of F3′H were isolated and characterized from the purple-fleshed sweet potato (Ipomoea batatas). IbF3’′H was 1,789 bp containing a 1,554 bp open reading frame (ORF) encoding 518 amino acids. Comparative and bioinformatic analysis revealed that IbF3′H was highly homologous with F3′Hs from other plant species. Conserved domain search revealed that IbF3′H was a cytochrome P450 dependent enzyme. Three F3′H-specific motifs (V₇₅VVAAS₈₀, G₄₂₇GEK₄₃₀ and V₄₃₃DVKG₄₃₇) were conserved in IbF3′H. Phylogenetic analysis revealed that IbF3′H was clustered into the same subgroup with the homologues from I. purpurea, I. tricolor and I. nil. There were multiple copies of the IbF3′H gene in the genome of I. batatas. IbF3′H was constitutively expressed in all tested tissues including fibrous roots, thick roots, storage roots, stems and leaves. During storage root formation, IbF3′H was expressed most abundantly in the storage roots, suggesting that the anthocyanin biosynthesis is also active in the under-ground organs. IbF3′H expression was associated with anthocyanin accumulation in five different sweet potato cultivars tested. Complementative analysis implied that the full-length cDNA of IbF3′H could encode a functional protein and had a special catalytic activity of flavonoid 3′-hydroxylase.     

Recombinant DNA-methyltransferase M1.BspACI from <Emphasis Type="Italic">Bacillus psychrodurans</Emphasis> AC: Purification and properties

A restriction-modification system from Bacillus psychrodurans AC (recognition sequence 5′-CCGC-3′) comprises two DNA methyltransferases: M1.BspACI and M2.BspACI. The bspACIM1 gene was cloned in the pJW2 vector and expressed in Escherichia coli cells. High-purity M1.BspACI preparation has been obtained by chromatography on different carriers. M1.BspACI has a temperature optimum of 30°C and demonstrates maximum activity at pH 8.0. M1.BspACI modifies the first cytosine in the recognition sequence 5′-CCGC-3′. The kinetic parameters of M1.BspACI DNA methylation are as follows: K _m for phage λ DNA is 0.053 μM and K _m for S-adenosyl-L-methionine is 5.1 μM. The catalytic constant (k _cat) is 0.095 min⁻¹.