The Cladosporium fulvum resistance gene Cf-ECP3 is part of the Orion cluster on the short arm of tomato Chromosome 1

The resistance of tomato to the pathogenic fungus Cladosporiumfulvum complies with the gene-for-gene relationship. Race specificresistance is based on Cf-gene mediated recognition ofsecreted avirulence products, resulting in a hypersensitive response (HR).Besides the avirulence gene products, C. fulvum secretes anumber of extra cellular proteins (ECPs) into the apoplast. Two L.esculentum accessions have previously been identified that reactedwith a HR upon injection with purified ECP3. The corresponding resistance genedesignated Cf-ECP3 was mapped by using an F₂population composed of 192 plants from the cross of susceptible MoneyMaker toresistant L. esculentum G1.1153.Cf-ECP3 inherited monogenically, cosegragated with theChromosome 1 Cleaved Amplified Polymorphic Sequence (CAPS) marker CT116 and wasmapped accurately at Orion, a locus harbouring Cf-ECP2 inother genotypes. RFLP anaysis with a Cf-9 probe furtherdemonstrated cosegregation of Cf-ECP3 with anHcr9 (Homologue of Cladosporiumfulvumresistance gene Cf-9) indicating that this gene is likelyan Hcr9. Thus in addition to the Milky Way locusharbouringthe Cf-4, Cf-4A andCf-9 resistance genes targeted against AVR4, AVR4A andAVR9, Orion is another complex locus on the short arm of Chromosome 1 thatharbours at least two functional Cf-genes,Cf-ECP2 and Cf-ECP3, targeted againstthe fungal excreted proteins ECP2 and ECP3.     

The Cf-ECP2 gene is linked to, but not part of, the Cf-4/Cf-9 cluster on the short arm of chromosome 1 in tomato

A gene has been identified in tomato, which confers resistance to Cladosporium fulvum through recognition of the pathogenicity factor ECP2. Segregation analysis of F₂ and F₃ populations showed monogenic dominant inheritance, as for previously reported Cf resistances. The gene has been designated Cf-ECP2. Using several mapping populations, Cf-ECP2 was accurately mapped on chromosome 1, 7.7 cM proximal to TG236 and 6.0 cM distal to TG184. Although Cf-ECP2 is linked to Cf-4, it is not located in the Hcr9 cluster “Milky Way”. Therefore, Cf-ECP2 is the first functional Cf homologue on chromosome 1 that does not belong to this Hcr9 cluster. No recombination events between Cf-ECP2 and CT116 have been observed in three populations tested, representing 282 individuals. The low value for the physical distance per cM around CT116 reported previously and the high probability that Cf-ECP2 is also a member of a Hcr9 cluster will facilitate cloning of the locus. Received: 15 June 1999 / Accepted: 24 August 1999     

Identification and fine mapping of <Emphasis Type="Italic">Pi33</Emphasis>, the rice resistance gene corresponding to the Magnaporthe grisea avirulence gene <Emphasis Type="Italic">ACE1</Emphasis>

Rice blast disease is a major constraint for rice breeding. Nevertheless, the genetic basis of resistance remains poorly understood for most rice varieties, and new resistance genes remain to be identified. We identified the resistance gene corresponding to the cloned avirulence gene ACE1 using pairs of isogenic strains of Magnaporthe grisea differing only by their ACE1 allele. This resistance gene was mapped on the short arm of rice chromosome 8 using progenies from the crosses IR64 (resistant) × Azucena (susceptible) and Azucena × Bala (resistant). The isogenic strains also permitted the detection of this resistance gene in several rice varieties, including the differential isogenic line C101LAC. Allelism tests permitted us to distinguish this gene from two other resistance genes [Pi11 and Pi-29(t)] that are present on the short arm of chromosome 8. Segregation analysis in F₂ populations was in agreement with the existence of a single dominant gene, designated as Pi33. Finally, Pi33 was finely mapped between two molecular markers of the rice genetic map that are separated by a distance of 1.6 cM. Detection of Pi33 in different semi-dwarf indica varieties indicated that this gene could originate from either one or a few varieties.Communicated by D.J. Mackill     

Gene duplication and gene conversion in class II MHC genes of New Zealand robins (Petroicidae)

In contrast to mammals, the evolution of MHC genes in birds appears to be characterized by high rates of gene duplication and concerted evolution. To further our understanding of the evolution of passerine MHC genes, we have isolated class II B sequences from two species of New Zealand robins, the South Island robin (Petroica australis australis), and the endangered Chatham Island black robin (Petroica traversi). Using an RT-PCR based approach we isolated four transcribed class II B MHC sequences from the black robin, and eight sequences from the South Island robin. RFLP analysis indicated that all class II B loci were contained within a single linkage group. Analysis of 3-untranslated region sequences enabled putative orthologous loci to be identified in the two species, and indicated that multiple rounds of gene duplication have occurred within the MHC of New Zealand robins. The orthologous relationships are not retained within the coding region of the gene, instead the sequences group within species. A number of putative gene conversion events were identified across the length of our sequences that may account for this. Exon 2 sequences are highly diverse and appear to have diverged under balancing selection. It is also possible that gene conversion involving short stretches of sequence within exon 2 adds to this diversity. Our study is the first report of putative orthologous MHC loci in passerines, and provides further evidence for the importance of gene duplication and gene conversion in the evolution of the passerine MHC.Nucleotide sequence data reported in this paper are available in the GenBank database under the accession numbers AY258333–AY258335, AY428561–AY428570, and AY530534–AY530535     

Organization of the Hox gene cluster of the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis>: a split of the Hox cluster in a non-<Emphasis Type="Italic">Drosophila</Emphasis> insect

A bacterial artificial chromosome (BAC) contig was constructed by chromosome walking, starting from the Hox genes of the silkworm, Bombyx mori. Bombyx orthologues of the labial (lab) and zerknült (zen) genes were newly identified. The size of the BAC contig containing the Hox gene cluster—except the lab and Hox 2 genes—was estimated to be more than 2 Mb. The Bombyx Hox cluster was mapped to linkage group (LG) 6. The lab gene was mapped on the same LG, but far apart from the cluster. Fluorescence in situ hybridization analysis confirmed that the major Hox gene cluster and lab were at different locations on the same chromosome in B. mori.Edited by M. Akam     

Mapping strategy for resistance genes against Cladosporium fulvum on the short arm of Chromosome 1 of tomato: Cf-ECP5 near the Hcr9 Milky Way cluster

In the past, numerous Lycopersicon accessions have been described that harbor resistance genes to Cladosporium fulvum (Cf genes). Several Cf genes have been isolated, like Cf-4, Cf-4A and Cf-9, which are present on the short arm of Chromosome 1, and Cf-2 and Cf-5, which reside on Chromosome 6. To identify Cf genes linked to the Hcr9 cluster ”Milky Way” on the short arm of Chromosome 1, we test-crossed 66 resistant Lycopersicon accessions to the near-isogenic line Moneymaker-Cf4, and the F₁s were crossed to the susceptible tomato cultivar Moneymaker. Putative linkage between an unknown Cf gene and Cf-4 was concluded based on small-scale allelic tests from an under-representation of susceptible genotypes in the progenies of 24 plants after inoculation with race 0 of C. fulvum. In this way, of the 21 resistant lines tested, 10 harbored a Cf gene that was linked to the Hcr9 Milky Way cluster. Moreover, one of the lines harboring a Cf gene closely linked to Cf-4 specifically recognizes the extracellular protein ECP5 of C. fulvum and was designated Cf-ECP5. Using a testcross population of 338 plants, we mapped Cf-ECP5 more accurately at 4 cM proximal to the Hcr9 Milky Way locus. This report shows that the method of small-scale allelic tests provides a useful tool to rapidly screen for Cf genes on the short arm of Chromosome 1. Further analysis of these Cf genes will elucidate the complex genetic organization of Cf genes on Chromosome 1 of tomato. Received: 23 August 1999 / Accepted: 12 January 2000     

Identification of SNPs and development of functional markers for LMW-GS genes at <Emphasis Type="Italic">Glu-D3</Emphasis> and <Emphasis Type="Italic">Glu-B3</Emphasis> loci in bread wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

Low-molecular-weight glutenin subunits (LMW-GS) have great effect on wheat processing quality, but were numerous and difficult to dissect by SDS-PAGE. The development of functional markers may be the most effective way for a clear discrimination of different LMW-GS genes. In the present study, three different approaches were used to identify SNPs of different genes at Glu-D3 and Glu-B3 loci in bread wheat for the development of six STS markers (3 for Glu-D3 and 3 for Glu-B3 genes) that were validated with distinguished wheat cultivars. Firstly, seven LMW-GS gene sequences ( AY585350, AY585354, AY585355, AY585356, AY585349, AY585351 and AY585353 ) from Aegilops tauschii, the diploid donor of the D-genome of bread wheat, were chosen to design seven pairs of AS-PCR primers for Glu-D3 genes. By amplifying the corresponding genes from five bread wheat cultivars with different Glu-D3 alleles (a, b, c, d and e) and Ae. tauschii, a primer set, S13F2/S13R1, specific to the gene AY585356, was found to be positive to cultivars with alleles Glu-D3c and d. Nevertheless, the other five pairs of primers designed from AY585350, AY585349, AY585353, AY585354 and AY585355, respectively, did not produce specific PCR products to the cultivars tested. Secondly, all the PCR products from the five primer sets without specific characteristics were sequenced and an SNP from the gene AY585350 was detected in the cultivar Hartog, which resulted in the second STS marker S1F1/S1R3 specific to the allelic variant of AY585350. Thirdly, three Glu-D3 sequences (AB062851, AB062865 and AB062872) and three Glu-B3 sequences (AB062852, AB062853 and AB062860) defined by Ikeda et al. (2002) were chosen to query wheat EST and NR databases, and DNA markers were developed based on the putative SNPs among the sequences. Using this approach, four STS markers were developed and validated with 16-19 bread wheat cultivars. The primer set T1F4/T1R1 was also a Glu-D3 gene-specific marker for AB062872, while T2F2/T2R2, T5F3/T5R1 and T13F4/T13R3 were all Glu-B3 gene specific markers for AB062852, BF293671 and AY831800, respectively. The chromosomal locations of the six markers were verified by amplifying the genomic DNA of Ae. tauschii (DD), T. monococcum (AA) and T. turgidum (AABB) entries, as well as Chinese Spring and its group 1 chromosome nulli-tetrasomic lines. The results are useful to discriminate the corresponding Glu-D3 and Glu-B3 genes in wheat breeding programs.     

Characterization of the horse (<Emphasis Type="Italic">Equus caballus</Emphasis>)<Emphasis Type="Italic"> IGHA</Emphasis> gene

Nucleotide sequences of the immunoglobulin constant heavy chain genes of the horse have been described for IGHM, IGHG and IGHE genes, but not for IGHA. Here, we provide the nucleotide sequence of the genomic IGHA gene of the horse (Equus caballus), including its secretion region and the transmembrane exon. The equine IGHA gene shows the typical structure of a mammalian IGHA gene, with only three exons, separated by two introns of similar size. The hinge exon is located at the 5 end of the CH2 exon and encodes a hinge region of 11 amino acids, which contains five proline residues. The coding nucleotide sequence of the secreted form of the equine IGHA gene shares around 72% identity with the human IGHA1 and IGHA2 genes, as well as the bovine, ovine, porcine and canine IGHA genes, without distinct preference for any of these species. The same species also cluster together in a phylogenetic tree of the IGHA coding regions of various mammals, whereas rodent, rabbit, marsupial and monotreme IGHA genes each build a separate cluster.The nucleotide sequences reported in this paper have been assigned the EMBL/GenBank accession numbers AY247966 and AY351982     

Molecular markers linked to the blast resistance gene <Emphasis Type="Italic">Pi-z</Emphasis> in rice for use in marker-assisted selection

Rice blast, caused by the fungal pathogen Pyricularia grisea, is a serious disease affecting rice-growing regions around the world. Current methods for identification of blast-resistant germplasm and progeny typically utilize phenotypic screening. However, phenotypic screens are influenced by environmental conditions and the presence of one resistance gene can sometimes phenotypically mask other genes conferring resistance to the same blast race. Pi-z is a dominant gene located on the short arm of chromosome 6 that confers complete resistance to five races of blast. Using sequence data found in public databases and degenerate primer pairs based on the P-loop, nucleotide binding sites and kinase domain motifs of previously cloned resistance genes, we have developed PCR-based DNA markers that cosegregate with the gene. These markers are polymorphic in a wide range of germplasm, including the narrow crosses characteristic of applied rice-breeding programs. They can now be used as a low cost, high-throughput alternative to conventional phenotypic screening for direct detection of blast resistance genes, allowing rapid introgression of genes into susceptible varieties as well as the incorporation of multiple genes into individual lines for more-durable blast resistance.Electronic Supplementary Material Supplementary material is available in the online version of this article at Communicated by D. Mackill     

Identification and fine mapping of <Emphasis Type="Italic">Pi39</Emphasis>(t), a major gene conferring the broad-spectrum resistance to <Emphasis Type="Italic">Magnaporthe oryzae</Emphasis>

Blast, caused by the ascomycete fungus Magnaporthe oryzae, is one of the most devastating diseases of rice worldwide. The Chinese native cultivar (cv.) Q15 expresses the broad-spectrum resistance to most of the isolates collected from China. To effectively utilize the resistance, three rounds of linkage analysis were performed in an F₂ population derived from a cross of Q15 and a susceptible cv. Tsuyuake, which segregated into 3:1 (resistant/susceptible) ratio. The first round of linkage analysis employing simple sequence repeat (SSR) markers was carried out in the F₂ population through bulked-segregant assay. A total of 180 SSR markers selected from each chromosome equally were surveyed. The results revealed that only two polymorphic markers, RM247 and RM463, located on chromosome 12, were linked to the resistance (R) gene. To further define the chromosomal location of the R gene locus, the second round of linkage analysis was performed using additional five SSR markers, which located in the region anchored by markers RM247 and RM463. The locus was further mapped to a 0.27 cM region bounded by markers RM27933 and RM27940 in the pericentromeric region towards the short arm. For fine mapping of the R locus, seven new markers were developed in the smaller region for the third round of linkage analysis, based on the reference sequences. The R locus was further mapped to a 0.18 cM region flanked by marker clusters 39M11 and 39M22, which is closest to, but away from the Pita/Pita ² locus by 0.09 cM. To physically map the locus, all the linked markers were landed on the respective bacterial artificial chromosome clones of the reference cv. Nipponbare. Sequence information of these clones was used to construct a physical map of the locus, in silico, by bioinformatics analysis. The locus was physically defined to an interval of ≈37 kb. To further characterize the R gene, five R genes mapped near the locus, as well as 10 main R genes those might be exploited in the resistance breeding programs, were selected for differential tests with 475 Chinese isolates. The R gene carrier Q15 conveys resistances distinct from those conditioned by the carriers of the 15 R genes. Together, this valuable R gene was, therefore, designated as Pi39(t). The sequence information of the R gene locus could be used for further marker-based selection and cloning. Xinqiong Liu and Qinzhong Yang contributed equally to this work.     

Two unusual chlorocatechol catabolic gene clusters in <Emphasis Type="Italic">Sphingomonas</Emphasis> sp. TFD44

The genes responsible for the degradation of 2,4-dichlorophenoxyacetate (2,4-D) by -Proteobacteria have previously been difficult to detect by using gene probes or polymerase chain reaction (PCR) primers. PCR products of the chlorocatechol 1,2-dioxygenase gene, tfdC, now allowed cloning of two chlorocatechol gene clusters from the Sphingomonas sp. strain TFD44. Sequence characterization showed that the first cluster, tfdD,RFCE, comprises all the genes necessary for the conversion of 3,5-dichlorocatechol to 3-oxoadipate, including a presumed regulatory gene, tfdR, of the LysR-type family. The second gene cluster, tfdC2E2F2, is incomplete and appears to lack a chloromuconate cycloisomerase gene and a regulatory gene. Purification and N-terminal sequencing of selected enzymes suggests that at least representatives of both gene clusters (TfdD of cluster 1 and TfdC2 of cluster 2) are induced during the growth of strain TFD44 with 2,4-D. A mutant constructed to contain an insertion in the chloromuconate cycloisomerase gene tfdD still was able to grow with 2,4-D, but more slowly and with a longer lag phase. This, and the detection of additional activity peaks during protein purification suggest that strain TFD44 harbors at least another chloromuconate cycloisomerase gene. The sequence of the tfdCE region was almost identical to that of a partially characterized chlorocatechol catabolic gene cluster of Sphingomonas herbicidovorans MH, whereas the sequence of the tfdC2E2F2 cluster was different. The similarity of the predicted proteins of the tfdD,RFCE and tfdC2E2F2 clusters to known sequences of other Proteobacteria in the database ranged from 42 to 61% identical positions for the first cluster and from 45.5 to 58% identical positions for the second cluster. Between both clusters, the similarities of their predicted proteins ranged from 44.5 to 64% identical positions. Thus, both clusters (together with those of S. herbicidovorans MH) represent deep-branching lines in the respective dendrograms, and the sequence information will help future primer design for the detection of corresponding genes in the environment.     

Archaea-Like Genes for C<Subscript>1</Subscript>-<Emphasis Type="Bold">Transfer Enzymes</Emphasis> in <Emphasis Type="Italic">Planctomycetes</Emphasis>: Phylogenetic Implications of Their Unexpected Presence in This Phylum

The unexpected presence of archaea-like genes for tetrahydromethanopterin (H₄MPT)-dependent enzymes in the completely sequenced genome of the aerobic marine planctomycete Pirellula sp. strain 1 (Rhodopirellula baltica) and in the currently sequenced genome of the aerobic freshwater planctomycete Gemmata obscuriglobus strain UQM2246 revives the discussion on the origin of these genes in the bacterial domain. We compared the genomic arrangement of these genes in Planctomycetes and methylotrophic proteobacteria and performed a phylogenetic analysis of the encoded protein sequences to address the question whether the genes have been present in the common ancestor of Bacteria and Archaea or were transferred laterally from the archaeal to the bacterial domain and therein. Although this question could not be solved using the data presented here, some constraints on the evolution of the genes involved in archaeal and bacterial H₄MPT-dependent C₁-transfer may be proposed: (i) lateral gene transfer (LGT) from Archaea to a common ancestor of Proteobacteria and Planctomycetes seems more likely than the presence of the genes in the common ancestor of Bacteria and Archaea; (ii) a single event of interdomain LGT can be favored over two independent events; and (iii) the archaeal donor of the genes might have been a representative of the Methanosarcinales. In the bacterial domain, the acquired genes evolved according to distinct environmental and metabolic constraints, reflected by specific rearrangements of gene order, gene recruitment, and gene duplication, with subsequent functional specialization. During the course of evolution, genes were lost from some planctomycete genomes or replaced by orthologous genes from proteobacterial lineages.Reviewing Editor: Dr. W. Ford Doolittle     

Mapping of a broad-spectrum brown planthopper resistance gene, <Emphasis Type="Italic">Bph3</Emphasis>, on rice chromosome 6

The brown planthopper (BPH) is one of the most destructive insect pests of rice in Thailand. We performed a cluster analysis that revealed the existence of four groups corresponding to the variation of virulence against BPH resistance genes in 45 BPH populations collected in Thailand. Rice cultivars Rathu Heenati and PTB33, which carry Bph3, showed a broad-spectrum resistance against all BPH populations used in this study. The resistant gene Bph3 has been extensively studied and used in rice breeding programs against BPH; however, the chromosomal location of Bph3 in the rice genome has not yet been determined. In this study, a simple sequence repeat (SSR) analysis was performed to identify and localize the Bph3 gene derived from cvs. Rathu Heenati and PTB33. For mapping of the Bph3 locus, we developed two backcross populations, BC₁F₂ and BC₃F₂, from crosses of PTB33 × RD6 and Rathu Heenati × KDML105, respectively, and evaluated these for BPH resistance. Thirty-six polymorphic SSR markers on chromosomes 4, 6 and 10 were used to survey 15 resistant (R) and 15 susceptible (S) individuals from the backcross populations. One SSR marker, RM190, on chromosome 6 was associated with resistance and susceptibility in both backcross populations. Additional SSR markers surrounding the RM190 locus were also examined to define the location of Bph3. Based on the linkage analysis of 208 BC₁F₂ and 333 BC₃F₂ individuals, we were able to map the Bph3 locus between two flanking SSR markers, RM589 and RM588, on the short arm of chromosome 6 within 0.9 and 1.4 cM, respectively. This study confirms both the location of Bph3 and the allelic relationship between Bph3 and bph4 on chromosome 6 that have been previously reported. The tightly linked SSR markers will facilitate marker-assisted gene pyramiding and provide the basis for map-based cloning of the resistant gene.     

H9, H10, and H11 compose a cluster of Hessian fly-resistance genes in the distal gene-rich region of wheat chromosome 1AS

H9, H10, and H11 are major dominant resistance genes in wheat, expressing antibiosis against Hessian fly [(Hf) Mayetiola destructor (Say)] larvae. Previously, H9 and H10 were assigned to chromosome 5A and H11 to 1A. The objectives of this study were to identify simple-sequence-repeat (SSR) markers for fine mapping of these genes and for marker-assisted selection in wheat breeding. Contrary to previous results, H9 and H10 did not show linkage with SSR markers on chromosome 5A. Instead, H9, H10, and H11 are linked with SSR markers on the short arm of chromosome 1A. Both H9 and H10 are tightly linked to flanking markers Xbarc263 and Xcfa2153 within a genetic distance of 0.3–0.5 cM. H11 is tightly linked to flanking markers Xcfa2153 and Xbarc263 at genetic distances of 0.3 cM and 1.7 cM. Deletion bin mapping assigned these markers and genes to the distal 14% of chromosome arm 1AS, where another Hf-resistance gene, Hdic (derived from emmer wheat), was also mapped previously. Marker polymorphism results indicated that a small terminal segment of chromosome 1AS containing H9 or H10 was transferred from the donor parent to the wheat lines Iris or Joy, and a small intercalary fragment carrying H11 was transferred from the resistant donor to the wheat line Karen. Our results suggest that H9, H10, H11, Hdic, and the previously identified H9- or H11-linked genes (H3, H5, H6, H12, H14, H15, H16, H17, H19, H28, and H29) may compose a cluster (or family) of Hf-resistance genes in the distal gene-rich region of wheat chromosome 1AS; and H10 most likely is the same gene as H9.Mention of commercial or proprietary product does not constitute an endorsement by the USDA.     

Nitrogen limitation induces expression of the avirulence gene avr9 in the tomato pathogen Cladosporium fulvum

The avirulence gene avr9 of the fungal tomato pathogen Cladosporium fulvum encodes a race-specific peptide elicitor that induces the hypersensitive response in tomato plants carrying the complementary resistance gene Cf9. The avr9 gene is not expressed under optimal growth conditions in vitro, but is highly expressed when the fungus grows inside the tomato leaf. In this paper we present evidence for the induction of avr9 gene expression in C. fulvum grown in vitro under conditions of nitrogen limitation. Only growth medium with very low amounts of nitrogen (nitrate, ammonium, glutamate or glutamine) induced the expression of avr9. Limitation of other macronutrients or the addition of plant factors did not induce the expression of avr9. The induced expression of avr9 is possibly mediated by a positive-acting nitrogen regulatory protein, homologous to the Neurospora crassa NIT2 protein, which induces the expression of many genes under conditions of nitrogen limitation. The avr9 promoter contains several putative NIT2 binding sites. The expression of avr9 during the infection process was explored cytologically using transformants of C. fulvum carrying an avr9 promoter--glucuronidase reporter gene fusion. The possibility that expression of avr9 in C. fulvum growing in planta is caused by nitrogen limitation in the apoplast of the tomato leaf is discussed.     

Hessian fly resistance genes <Emphasis Type="Italic">H16</Emphasis> and <Emphasis Type="Italic">H17</Emphasis> are mapped to a resistance gene cluster in the distal region of chromosome 1AS in wheat

Hessian fly [Mayetiola destructor (Say)] is one of the major insect pests of wheat (Triticum aestivum L.) worldwide. Hessian fly (Hf)-resistance genes H16 and H17 were reported to condition resistance to Hf biotype L that is prevalent in many wheat-growing areas of eastern USA, and both of them were previously assigned to wheat chromosome 5A by their linkage to H9. The objectives in this study were to (1) map H16 and H17 independent of their linkage with H9 and (2) identify DNA markers that co-segregate with H16 or H17, and that are useful for selection of these genes in segregating populations and to combine these genes with other Hf-resistance genes in wheat cultivars. Contrary to previously reported locations, H16 and H17 did not show linkage with the molecular markers on chromosome 5A. Instead, both of them are linked with the molecular markers on the short arm of chromosome 1A (1AS). The simple sequence repeat (SSR) marker Xpsp2999 and EST-derived SSR (eSSR) marker Xwem6b are two flanking markers that are linked to H16 at genetic distances of 3.7 and 5.5 cM, respectively. Similarly, H17 is located between markers Xpsp2999 and Xwem6b at genetic distances of 6.2 and 5.1 cM, respectively. Five other SSR and eSSR markers including Xcfa2153, Xbarc263, Xwem3a, Xwmc329, and Xwmc24 were also linked to H16 and H17 at close genetic distances. These closely linked molecular markers should be useful for pyramiding H16 and H17 with other Hessian fly resistance genes in a single wheat genotype. In addition, using Chinese Spring deletion line bin mapping we positioned all of the linked markers and the Hf-resistance genes (H16 and H17) to the distal 14% of chromosome 1AS, where Hf-resistance genes H9, H10, and H11 are located. Our results together with previous studies suggest that Hf-resistance genes H9, H10, H11, H16, and H17 along with the pathogen resistance genes Pm3 and Lr10 appear to occupy a resistance gene cluster in the distal region of chromosome 1AS in wheat. Contribution from Purdue Univ. Agric. Res. Programs Journal Article No. 2007-18105.     

Two new species of <Emphasis Type="Italic">Trichoderma</Emphasis> from Yunnan,China

Two new species of the fungal genus Trichoderma, Trichoderma compactum and Trichoderma yunnanense, isolated from rhizosphere of tobacco in Yunnan Province, China are described based on morphological characters and phylogenetic analyses of nucleotide sequences. Our DNA sequences included the internal transcribed spacer (ITS) regions of the rDNA cluster (ITS1 and ITS2), and partial sequences of the translation elongation factor 1-alpha (tef1) and a fragment of the gene coding for endochitinase 42 (ech42). The analyses show that T. compactum belongs to the Harzianum clade, and T. yunnanense belongs to the Hamatum clade.     

Characterisation and genetic mapping of resistance and defence gene analogs in cocoa (Theobroma cacao L.)

Disease resistance and defence gene analog (RGA/DGA) sequences were isolated in cocoa using a PCR approach with degenerate primers designed from conserved domains of plant resistance and defence genes: the NBS (nucleotide binding site) motif present in a number of resistance genes such as the tobacco N, sub-domains of plant serine/threonine kinases such as the Pto tomato gene, and conserved domains of two defence gene families: pathogenesis-related proteins (PR) of classes 2 and 5. Nucleotide identity between thirty six sequences isolated from cocoa and known resistance or defence genes varied from 58 to 80%. Amino acid sequences translated from corresponding coding sequences produced sequences without stop codons, except for one NBS –like sequence. Most of the RGAs could be mapped on the cocoa genome and three clusters of genes could be observed : NBS-like sequences clustered in two regions located on chromosomes 7 and 10, Pto-like sequences mapped in five genome regions of which one, located on chromosome 4, corresponded to a cluster of five different sequences. PR2-like sequences mapped in two regions located on chromosome 5 and 9 respectively. An enrichment of the genetic map with microsatellite markers allowed us to identify several co-localisations of RGAs, DGAs and QTL for resistance to Phytophthora detected in several progenies, particularly on chromosome 4 where a cluster of Pto-like sequences and 4 QTL for resistance to Phytophthora were observed. Many other serious diseases affect cocoa and the candidate genes, isolated in this study, could be of broader interest in cocoa disease management.