The wheat Lr34 multipathogen resistance gene confers resistance to anthracnose and rust in sorghum

The ability of the wheat Lr34 multipathogen resistance gene (Lr34res) to function across a wide taxonomic boundary was investigated in transgenic Sorghum bicolor. Increased resistance to sorghum rust and anthracnose disease symptoms following infection with the biotrophic pathogen Puccinia purpurea and the hemibiotroph Colletotrichum sublineolum, respectively, occurred in transgenic plants expressing the Lr34res ABC transporter. Transgenic sorghum lines that highly expressed the wheat Lr34res gene exhibited immunity to sorghum rust compared to the low‐expressing single copy Lr34res genotype that conferred partial resistance. Pathogen‐induced pigmentation mediated by flavonoid phytoalexins was evident on transgenic sorghum leaves following P. purpurea infection within 24–72 h, which paralleled Lr34res gene expression. Elevated expression of flavone synthase II, flavanone 4‐reductase and dihydroflavonol reductase genes which control the biosynthesis of flavonoid phytoalexins characterized the highly expressing Lr34res transgenic lines 24‐h post‐inoculation with P. purpurea. Metabolite analysis of mesocotyls infected with C. sublineolum showed increased levels of 3‐deoxyanthocyanidin metabolites were associated with Lr34res expression, concomitant with reduced symptoms of anthracnose.     

Bioprospecting of Saprobe Fungi from the Semi‐Arid North‐East of Brazil for the Control of Anthracnose on Sorghum

Anthracnose, caused by the hemiotrophic fungus Colletotrichum sublineolum, is one of the most important diseases affecting sorghum production worldwide. The main goal of this study was to select saprobe fungi from the semi‐arid north‐east of Brazil that could increase sorghum resistance to anthracnose and investigate this increased resistance at both physiological and biochemical levels. Plants were sprayed with Curvularia inaequalis, Gonytrichum macroladum, Memnoniella levispora, Pithomyces chartarum, Periconia hispidula, Phaeoisaria clematidia, Dictyochaeta heteroderae, Sarcopodium circinatum, Periconia byssoides, Moorella speciosa, Stachybotrys chartarum, Pseudobotrytis terrestres, Memnoniella echinata, Stachybotrys globosa and Gonytrichum clamydosporium 24 h before inoculation with C. sublineolum. Plants sprayed with water served as the control treatment. The area under the anthracnose progress curve was significantly reduced in comparison with the control treatment only for plants sprayed with C. inaequalis. Therefore, C. inaequalis was selected for physiological and biochemical evaluations. The peroxidases, chitinases and β‐1,3‐glucanases activities were significantly higher for plants sprayed with C. inaequalis and inoculated with C. sublineolum than for plants not sprayed with C. inaequalis and inoculated with C. sublineolum. There was no apparent decrease in the values of net carbon assimilation rate, stomatal conductance to water vapour or transpiration rate for plants sprayed with C. inaequalis and infected by C. sublineolum in comparison with plants not sprayed with C. inaequalis and infected by C. sublineolum. In conclusion, sorghum resistance against C. sublineolum infection was greatly potentiated by C. inaequalis without any apparent change in the photosynthetic capacity of the infected plants.     

Colletotrichum sublineolum genetic instability assessed by mutants resistant to chlorate

The fungus Colletotrichum sublineolum, causal agent of sorghum anthracnose, presents high variability, genetic instability and host specialization. The aims of the present work were to investigate the mechanisms involved in the genetic instability in this species. Mutants resistant to chlorate and unable to use nitrate (Nit mutants), were obtained spontaneously, isolated and characterized for complementation pattern, reversion frequency and RAPD profile. The results showed that chlorate-resistant mutants could be divided into six phenotypic classes that probably represented mutations in the structural nitrate reductase locus (nit1), in the structural nitrite reductase locus (nit6 and niiA of Neurospora and Aspergillus, respectively), in the specific regulator locus (nit3), in the main regulator locus (nit2), in loci that codified the cofactor containing molybdenum necessary for nitrate reductase activity (NitM), and one or more genes responsible for nitrate intake (crn). In addition, the genetic control of this metabolism in C. sublineolum seems to be similar to other fungi species such as Aspergillus, Neurospora and Fusarium. The high reversion frequency (10⁻⁴ to 10⁻⁵) presented by nit1 mutants suggests that the instability in evaluated strains could be a result of transposable elements activity. The RAPD analysis enabled confirmation that the Nit mutants have a similar genetic background to original strain, and that polymorphism exists among wild-type strains, nit1 mutants and revertants of C. sublineolum. These are important aspects for the later direction of molecular analysis, where these mutants will be used as a tool to isolate the active transposable elements in the C. sublineolum genome.     

Cloning and characterization of the ribosomal protein L3 (<Emphasis Type="Italic">RPL3</Emphasis>) gene family from <Emphasis Type="Italic">Triticum aestivum</Emphasis>

Plant pathogenic fungi of the genus Fusarium can cause severe diseases on small grain cereals and maize. The contamination of harvested grain with Fusarium mycotoxins is a threat to human and animal health. In wheat production of the toxin deoxynivalenol (DON), which inhibits eukaryotic protein biosynthesis, is a virulence factor of Fusarium, and resistance against DON is considered to be part of Fusarium resistance. Previously, single amino acid changes in RPL3 (ribosomal protein L3) conferring DON resistance have been described in yeast. The goal of this work was to characterize the RPL3 gene family from wheat and to investigate the potential role of naturally existing RPL3 alleles in DON resistance by comparing Fusarium-resistant and susceptible cultivars. The gene family consists of three homoeologous alleles of both RPL3A and RPL3B, which are located on chromosomes 4A (RPL3-B2), 4B (RPL3-B1), 4D (RPL3-B3), 5A (RPL3-A3), 5B (RPL3-A2) and 5D (RPL3-A1). Alternative splicing was detected in the TaRPL3-A2 gene. Sequence comparison revealed no amino acid differences between cultivars differing in Fusarium resistance. While using developed SNP markers we nevertheless found that one of the genes, namely, TaRPL3-A3 mapped close to a Fusarium resistance QTL (Qfhs.ifa-5A). The potential role of the RPL3 gene family in DON resistance of wheat is discussed.     

Chromosomal Localization of the Human Genes for α1A, α1B, and α1E Voltage-Dependent Ca Channel Subunits

The α₁ subunit genes encoding voltage-dependent Ca²⁺ channels are members of a gene family. We have used human brain cDNA probes to localize the neuronal isoform genes CACNL1A4 (α_1A), CACNL1A5 (α_1B), and CACNL1A6 (α_1E) to 19p13, 9q34, and 1q25-q31, respectively, using fluorescence in situ hybridization on human chromosomes. These genes are particularly interesting gene candidates in the pathogenesis of neuronal disorders. Although genetic disorders have been linked to loci 9q34 and 19p13, no genetic disease related to Ca²⁺ signaling defects has yet been linked to these loci.     

A novel <Emphasis Type="Italic">FAD2</Emphasis>-<Emphasis Type="Italic">1 A</Emphasis> allele in a soybean plant introduction offers an alternate means to produce soybean seed oil with 85% oleic acid content

The alteration of fatty acid profiles in soybean to improve soybean oil quality has been a long-time goal of soybean researchers. Soybean oil with elevated oleic acid is desirable because this monounsaturated fatty acid improves the nutrition and oxidative stability of soybean oil compared to other oils. In the lipid biosynthetic pathway, the enzyme fatty acid desaturase 2 (FAD2) is responsible for the conversion of oleic acid precursors to linoleic acid precursors in developing soybean seeds. Two genes encoding FAD2-1A and FAD2-1B were identified to be expressed specifically in seeds during embryogenesis and have been considered to hold an important role in controlling the seed oleic acid content. A total of 22 soybean plant introduction (PI) lines identified to have an elevated oleic acid content were characterized for sequence mutations in the FAD 2-1A and FAD2-1B genes. PI 603452 was found to contain a deletion of a nucleotide in the second exon of FAD2-1A. These important SNPs were used in developing molecular marker genotyping assays. The assays appear to be a reliable and accurate tool to identify the FAD 2-1A and FAD2-1B genotype of wild-type and mutant plants. PI 603452 was subsequently crossed with PI 283327, a soybean line that has a mutation in FAD2-1B. Interestingly, soybean lines carrying both homozygous insertion/deletion mutation (indel) FAD2-1A alleles and mutant FAD2-1B alleles have an average of 82–86% oleic acid content, compared to 20% in conventional soybean, and low levels of linoleic and linolenic acids. The newly identified indel mutation in the FAD2-1A gene offers a simple method for the development of high oleic acid commercial soybean varieties.     

Polymorphism and Expression of cDNAs Encoding Glycinin Subunits

The nucleotide sequence of cDNA encoding the glycinin A₂B_1a subunit from var. Shirotsurunoko was determined and compared with that in the case of var. Bonminori. The comparison showed six nucleotide substitutions in the coding sequence, one of which results in one amino acid replacement, and three in the 3'-noncoding region. These differences indicate the occurrence of polymorphism of the glycinin A₂B_1a subunit gene between the cultivars. The present data together with the previous results indicating the polymorphism of the A_1aB_1b subunit gene [(Utsumi et al., J. Agric. Food Chem., 35, 210 (1987)] suggest that the polymorphism is a general property of glycinin subunit genes. The expression of cDNAs encoding the A₂B_1a and A_1aB_1b subunits was examined. The results obtained in both in vivo- and in vitro-expression experiments indicate that the resultant products were readily degraded.     

Infection induced defence responses in sorghum,with special emphasis on accumulation of reactive oxygen species and cell wall modifications

Hemibiotrophic plant pathogens pass both biotrophic and necrotrophic phases during their infection cycle. Colletotrichum spp. exhibits two types of hemibiotrophy, i.e. intracellular and subcuticular intramural. Colletotrichum sublineolum infecting sorghum exhibits a typical intracellular type of hemibiotrophy. During the biotrophic stage of C. sublineolum infection in sorghum, several cell wall-associated defence reactions are activated and efficiently participate in stopping pathogen development. Among these defence reactions, generation and accumulation of reactive oxygen species (ROS) and cell wall barrier formation are key factors in resistance. This review focuses on the infection processes of C. sublineolum in sorghum and the defence responses activated, with special emphasis on accumulation of ROS and hydroxy-rich glyco-proteins (HRGPs).     

Conservation of XYN11A and XYN11B xylanase genes in Bipolaris sorghicola,Cochliobolus sativus,Cochliobolus heterostrophus,and Cochliobolus spicifer

Two types of xylanase gene, XYN11A (XYL1) and XYN11B (XYL2), were amplified by PCR and partially sequenced in four phytopathogenic species of the ascomycete fungal genus Cochliobolus (anamorph genus Bipolaris). Three of the species, C. heterostrophus (B. maydis), C. sativus (B. sorokiniana), and Bipolaris sorghicola (no teleomorph known), are interrelated; the fourth, C. spicifer (B. spicifera), was found, through analysis of the 5.8S RNA and internal transcribed spacer (ITS) sequences of its ribosomal DNA, to be more distantly related to the other three. Isolates from all four species contain orthologous XYN11A and XYN11B genes, but a set of laboratory strains of C. heterostrophus gave no product corresponding to the XYN11B gene. The patterns of evolution of the two xylanase genes and ribosomal DNA sequences are mutually consistent; the results indicate that the two genes were present in the common ancestor of all Cochliobolus species and are evolving independently of each other. Received: 12 July 2001 / Accepted: 6 March 2002     

Expression of Arabidopsis acyl‐CoA‐binding proteins AtACBP1 and AtACBP4 confers Pb(II) accumulation in Brassica juncea roots

In Arabidopsis thaliana, the expression of two genes encoding acyl‐CoA‐binding proteins (ACBPs) AtACBP1 and AtACBP4, were observed to be induced by lead [Pb(II)] in shoots and roots in qRT‐PCR analyses. Quantitative GUS (β‐glucuronidase) activity assays confirmed induction of AtACBP1pro::GUS by Pb(II). Electrophoretic mobility shift assays (EMSAs) revealed that Pas elements in the 5′‐flanking region of AtACBP1 were responsive to Pb(II) treatment. AtACBP1 and AtACBP4 were further compared in Pb(II) uptake using Brassica juncea, a potential candidate for phytoremediation given its rapid growth, large roots, high biomass and good capacity to accumulate heavy metals. Results from atomic absorption analyses on transgenic B. juncea expressing AtACBP1 or AtACBP4 indicated Pb(II) accumulation in roots. Subsequent Pb(II)‐tracing assays demonstrated Pb(II) accumulation in the cytosol of root tips and vascular tissues of transgenic B. juncea AtACBP1‐overexpressors (OXs) and AtACBP4‐OXs and transgenic Arabidopsis AtACBP1‐OXs. Transgenic Arabidopsis AtACBP1‐OXs sequestered Pb(II) in the trichomes and displayed tolerance to hydrogen peroxide (H₂O₂) treatment. In addition, AtACBP1 and AtACBP4 were H₂O₂‐induced in the roots of wild‐type Arabidopsis, while lipid hydroperoxide (LOOH) measurements of B. juncea AtACBP1‐OX and AtACBP4‐OX roots suggested that AtACBP1 and AtACBP4 can protect lipids against Pb(II)‐induced lipid peroxidation.     

A VIGS screen identifies immunity in the Arabidopsis Pla‐1 accession to viruses in two different genera of the Geminiviridae

Geminiviruses are DNA viruses that cause severe crop losses in different parts of the world, and there is a need for genetic sources of resistance to help combat them. Arabidopsis has been used as a source for virus‐resistant genes that derive from alterations in essential host factors. We used a virus‐induced gene silencing (VIGS) vector derived from the geminivirus Cabbage leaf curl virus (CaLCuV) to assess natural variation in virus–host interactions in 190 Arabidopsis accessions. Silencing of CH‐42, encoding a protein needed to make chlorophyll, was used as a visible marker to discriminate asymptomatic accessions from those showing resistance. There was a wide range in symptom severity and extent of silencing in different accessions, but two correlations could be made. Lines with severe symptoms uniformly lacked extensive VIGS, and lines that showed attenuated symptoms over time (recovery) showed a concomitant increase in the extent of VIGS. One accession, Pla‐1, lacked both symptoms and silencing, and was immune to wild‐type infectious clones corresponding to CaLCuV or Beet curly top virus (BCTV), which are classified in different genera in the Geminiviridae. It also showed resistance to the agronomically important Tomato yellow leaf curl virus (TYLCV). Quantitative trait locus mapping of a Pla‐1 X Col‐0 F₂ population was used to detect a major peak on chromosome 1, which is designated gip‐1 (geminivirus immunity Pla‐1‐1). The recessive nature of resistance to CaLCuV and the lack of obvious candidate genes near the gip‐1 locus suggest that a novel resistance gene(s) confers immunity.