Identification of genes contributing to quantitative disease resistance in rice

Despite the importance of quantitative disease resistance during a plant’s life, little is known about the molecular basis of this type of host-pathogen interaction, because most of the genes underlying resistance quantitative trait loci (QTLs) are unknown. To identify genes contributing to resistance QTLs in rice, we analyzed the colocalization of a set of characterized rice defense-responsive genes and resistance QTLs against different pathogens. We also examined the expression patterns of these genes in response to pathogen infection in the parents of the mapping populations, based on the strategy of validation and functional analysis of the QTLs. The results suggest that defense-responsive genes are important resources of resistance QTLs in rice. OsWRKY45-1 is the gene contributing to a major resistance QTL.NRR,OsGH3-1,and OsGLP members on chromosome 8 contribute alone or collectively to different minor resistance QTLs. These genes function in a basal resistance pathway or in major disease resistance gene-mediated race-specific pathways.     

Expression of two soybean resistance gene candidates shows divergence of paralogous single-copy genes

The cloning of several plant genes directly involved in triggering a disease resistance response has shown that numerous resistance genes in the nucleotide binding site (NBS)/leucine-rich repeat (LRR) class have similar conserved amino acid sequences. In this study, we used a short soybean DNA sequence, previously cloned based on its conserved NBS, as a probe to identify full-length resistance gene candidates. Two homologous, but genetically independent genes were identified. One gene maps to the soybean molecular linkage group (MLG) F and a second is coded on MLG E. The first gene contains a 3,279 nucleotide open reading frame (ORF) sequence and possesses all the functional motifs characteristic of previously cloned NBS/LRR resistance genes. The N-terminal sequence of the deduced gene product is highly characteristic of other resistance genes in the subgroup of NBS/LRR genes which show homology to the Toll/Interleukin-1 receptor genes. The C-terminal region is somewhat more divergent as seen in other cloned disease resistance genes. This region of the F-linked gene contains an LRR region that is characterized by two alternatively spliced products which produce gene products with either a four-repeat or a ten-repeat LRR. The second cloned gene that maps to soybean MLG E contains 1,565 nucleotides of ORF in the N-terminal domain. Despite strong homology, however, the 3′ region of this gene contains several in-frame stop codons and apparent frame shifts compared to the F-linked gene, suggesting that its functionality as a disease resistance gene is questionable. These two disease resistance gene candidates are shown to be closely related to one another and to the members of the NBS/LRR class of disease resistance genes. Received: 29 November 1999 / Accepted: 22 December 1999     

黑素皮质素受体1——哺乳动物黑色素形成中的关键基因MC1R——the Key Gene in Mammalian Melanin Synthesis

黑色素的形成与产生在动物的生长发育过程中受到许多基因的调控。本文综述了近年来被广泛研究的哺乳动物黑色素形成调控中的一个关键基因——黑素皮质素受体1（melanocortin-1-receptor, MC1R）基因的作用机制、DNA序列变异与黑色素性状之间的关系,并且对另一重要的脊椎动物类群——鸟类中MC1R基因的确定与突变情况作以概述,此外对乌骨鸡富含黑色素的原因和鸟类的黑色素形成机制也进行了探讨。Abstract: The study of the molecular regulation mechanism of melanin synthesis during animal development has become a new focus recently .The synthesis and production of melanin during animal development are regulated by many genes. This paper summarized the molecular function mechanism of melanocortin-1-receptor (MC1R) gene and the relationship between the consequences of polymorphic variation of the gene and melanin traits, in addition to summarized the identification and mutation of MC1R gene in birds. Furthermore, the reason of abundant melanin in silkies and melanin synthesis mechanism in birds are all also discussed here.     

基因聚合提高了水稻对白叶枯病的抗性 Performance of Resistance Gene Pyramids to Races of RiceBacterial Blight in Zhejiang Province

研究了含有单个抗性基因的水稻近等基因系和抗性基因聚合品系对浙江省白 叶枯病菌4个主要小种的抗性,单个基因对这些小种的抗性均不高,对新近流行的小种大 多感病;基因聚合品系对这些小种的抗性普遍提高,说明基因聚合是培育具有持久抗性品 种的有效策略。 Abstract:The resistance of rice near isogenic lines containing single bacterial blight resistance genes and the gene pyramids to four races in Zhejiang Province were studied.The single resistance genes showed moderate resistance to most of the races.All the single genes were susceptible to the newly emerging race.The resistance of all the pyramids were enhanced to almost all the races,indicating that gene pyramiding is an effective strategy in developing varieties with durable resistance.     

Identification and characterization of 177 unreported genes associated with liver regeneration

The mammalian liver has a very strong regeneration capacity after partial hepatectomy (PH). To further learn the genes participating in the liver regeneration (LR), 551 cDNAs selected from subtracted cDNA libraries of the regenerating rat liver were screened by microarray, and their expression profiles were studied by cluster and generalization analyses. Among them, 177 genes were identified unreported and up-or down-regulated more than twofold at one or more time points after PH, of which 62 genes were down-regulated to less than 0.5; 99 genes were up-regulated to 2-10 folds, and 16 genes were either up- or down-regulated at different time points during LR. By using BLAST and GENSCAN, these genes were located on responsible chromosomes with 131 genes on the long arms of the chromosomes. The cluster and generalization analyses showed that the gene expression profiles are similar in 2 and 4, 12 and 16, 96 and 144 h respectively after PH, suggesting that the actions of the genes expressed in the same profiles are similar, and those expressed in different profiles have less similarity. However, the types,characteristics and functions of the 177 genes remain to be further studied.     

Expression of PIN Genes in Rice （Oryza sativa L.）： Tissue Specificity and Regulation by Hormones

Twelve genes of the PIN family in rice were analyzed for gene and protein structures and an evolutionary relationship with reported AtPINs in Arabidopsis. Four members of PIN1 （designated as OsPINla-d）, one gene paired with AtPIN2 （OsPIN2）, three members of PIN5 （OsPIN5a-c）, one gene paired with AtPIN8 （OsPIN8）, and three monocot-specific PINs （OsPIN9, OsPINIOa, and b） were identified from the phylogenetic analysis. Tissue-specific expression patterns of nine PIN genes among them were investigated using RT-PCR and GUS reporter. The wide variations in the expression domain in different tissues of the PIN genes were observed. In general, PIN genes are up-regulated by exogenous auxin, while different responses of different PIN genes to other hormones were found.     

植物——病原互作系统中基因对基因识别研究

从自然植物种群对Ｒ基因的选择和淘汰、对属和种的专化性、抗病基因的复杂性、抗病基因的分子专化性、信号传导中基因的相互作用,以及Ｒ基因的开发利用与持久抗性战略等方面总结评述了当前在植物－病原互作系统中基因对基因识别研究领域的新进展,并且提出了需进一步研究的问题。     

Frequent sequence exchanges between homologs of RPP8 in Arabidopsis are not necessarily associated with genomic proximity

Disease resistance (R) genes are often clustered in plant genomes and may exhibit heterogeneous rates of evolution. Some (type I R genes) have evolved rapidly through frequent sequence exchanges, while others (type II R genes) have evolved independently and tend to be conserved in different genotypes or related species. The RPP8 resistance gene in Arabidopsis thaliana is located at a complex locus that also harbors the sequence-related resistance genes HRT and RCY1 in different ecotypes. We sequenced 98 homologs of RPP8 from A. thaliana, Arabidopsis arenosa and Arabidopsis lyrata. Three lineages of type II and one lineage of type I RPP8 homologs were identified. Two of the three lineages of type II genes are each represented by a single-copy locus on either chromosomes I or V. Chromosome V contains two small clusters of RPP8 paralogs. One cluster contains both type I and type II genes and the other comprises only type I genes. These multi-copy loci have expanded and contracted through unequal crossovers, which have generated chimeric genes as well as variations in copy number. Sequence exchanges, most likely gene conversions, were detected between RPP8 homologs that are spatially separated by 2.2 Mb and 12 cM. The sequence exchanges between type I homologs within a locus have been more frequent than sequence exchanges between homologs from two different loci, indicating the influence of chromosomal position on the evolution of these R genes. However, physical distance was not the only factor determining the frequency of sequence exchange, because some closely linked paralogs exhibited little sequence exchange. At least two distinct lineages of type II RPP8 homologs were identified in different species, with obvious allelic/orthologous relationships within each lineage. Therefore, the differentiation of type I and type II RPP8 homologs seems to have occurred before speciation of A. thaliana, A. arenosa and A. lyrata.     

Illegitimate recombination is a major evolutionary mechanism for initiating size variation in plant resistance genes

Current models for the evolution of plant disease resistance (R) genes are based on mechanisms such as unequal crossing-over, gene conversion and point mutations as sources for genetic variability and the generation of new specificities. Size variation in leucine-rich repeat (LRR) domains was previously mainly attributed to unequal crossing-over or template slippage between LRR units. Our analysis of 112 R genes and R gene analogs (RGAs) from 16 different gene lineages from monocots and dicots showed that individual LRR units are mostly too divergent to allow unequal crossing-over. We found that illegitimate recombination (IR) is the major mechanism that generates quasi-random duplications within the LRR domain. These initial duplications are required as seeds for subsequent unequal crossing-over events which cause the observed rapid increase or decrease in LRR repeat numbers. Ten of the 16 gene lineages studied contained such duplications, and in four of them the duplications served as a template for subsequent repeat amplification. Our analysis of Pm3-like genes from rice and three wheat species showed that such events can be traced back more than 50 million years. Thus, IR represents a major new evolutionary mechanism that is essential for the generation of molecular diversity in evolution of RGAs.     

Genetic mapping in sugarcane, a high polyploid, using bi-parental progeny: identification of a gene controlling stalk colour and a new rust resistance gene

Modern sugarcane cultivars (Saccharum spp) are highly polyploïd and aneuploid interspecific hybrids (2n=100–130). Two genetic maps were constructed using a population of 198 progeny from a cross between R570, a modern cultivar, and MQ76-53, an old Australian clone derived from a cross between Trojan (a modern cultivar) and SES528 (a wild Saccharum spontaneum clone). A total of 1,666 polymorphic markers were produced using 37 AFLP primer combinations, 46 SSRs and 9 RFLP probes. Linkage analysis led to the construction of 86 cosegregation groups for R570 and 105 cosegregation groups for MQ76-53 encompassing 424 and 536 single dose markers, respectively. The cumulative length of the R570 map was 3,144 cM, while that of the MQ76-53 map was 4,329 cM. Here, we integrated mapping information obtained on R570 in this study with that derived from a previous map based on a selfed R570 population. Two new genes controlling Mendelian traits were localized on the MQ76-53 map: a gene controlling the red stalk colour was linked at 6.5 cM to an AFLP marker and a new brown rust resistance gene was linked at 23 cM to an AFLP marker. Besides another previously identified brown rust resistance gene (Bru1), these two genes are the only other major genes to be identified in sugarcane so far.     

植物抗病基因结构、功能及其进化机制研究进展

植物与病原菌在长期的共进化和相互选择的过程中,逐渐形成了组织障碍、非寄主抗性和小种专化抗性等有效的防御机制。小种专化抗性(基因对基因抗性)主要是由植物抗病基因识别相应的病原菌无毒基因并激活植物体内抗病信号进而抵御病原菌的侵染。从目前已克隆的 70 多个抗病基因来看,它们在结构上具有高度保守性,主要包括核苷酸结合位点(NBS),亮氨酸重复结构(LRR), 蛋白激酶结构域(PK), 果蝇蛋白 Toll 和哺乳动物蛋白质白细胞介素 1 受体[interleukin(IL)-1 receptor]类似结构域(TIR), 双螺旋结构(CC)或亮氨酸拉链(LZ)和跨膜结构域(TM)等,其在抗病基因与病原菌无毒(效应)蛋白互作以及植物内部免疫信号传导中起着重要的作用。同时,抗病基因又通过基因复制、遗传重组等进化机制形成多基因家族,为植物抗病的专化性和多样性提供了重要的遗传基础。本文主要讨论了近来已克隆抗病基因的结构特征、功能以及抗病基因进化机制研究的进展。     

The R1 gene for potato resistance to late blight (Phytophthora infestans) belongs to the leucine zipper/NBS/LRR class of plant resistance genes

Late blight caused by the oomycete Phytophthora infestans is the most destructive disease in potato cultivation worldwide. New, more virulent P. infestans strains have evolved which overcome the genetic resistance that has been introgressed by conventional breeding from wild potato species into commercial varieties. R genes (for single-gene resistance) and genes for quantitative resistance to late blight are present in the germplasm of wild and cultivated potato. The molecular basis of single-gene and quantitative resistance to late blight is unknown. We have cloned R1, the first gene for resistance to late blight, by combining positional cloning with a candidate gene approach. The R1 gene is member of a gene family. It encodes a protein of 1293 amino acids with a molecular mass of 149.4 kDa. The R1 gene belongs to the class of plant genes for pathogen resistance that have a leucine zipper motif, a putative nucleotide binding domain and a leucine-rich repeat domain. The most closely related plant resistance gene (36% identity) is the Prf gene for resistance to Pseudomonas syringae of tomato. R1 is located within a hot spot for pathogen resistance on potato chromosome V. In comparison to the susceptibility allele, the resistance allele at the R1 locus represents a large insertion of a functional R gene.     

水稻全基因组编码抗病基因同源序列分析

利用模糊搜索的方法,在TIGR水稻日本晴基因组数据库(TIGR Rice Genome Annotation-Release5)中识别出565个编码抗病蛋白质的同源序列;利用识别出565个编码抗病蛋白质序列分别与籼稻基因组数据库进行BLASTP联配,共确定320个对应的等位基因。通过在线生物信息学软件,识别了这565个抗病基因的保守结构域、保守模体和DNA序列内转座子元件,其中有14个抗病基因同源序列注释错误。同时绘出了这些基因的基因组分布,并基于这些基因的同源树分析和基因组物理分布,认为基因的原位和远程复制事件产生了抗病基因的现存分布和多样性,其中转座子在复制过程中扮演了重要角色。这些对抗病机制研究和抗病基因进化研究以及抗病基因的转育具有重要意义。     

A paralog of the MtN3/saliva family recessively confers race-specific resistance to Xanthomonas oryzae in rice

Approximately one third of the identified 34 rice major disease resistance (R) genes conferring race-specific resistance to different strains of Xanthomonas oryzae pv. oryzae (Xoo), which causes rice bacterial blight disease, are recessive genes. However, only two of the recessive resistance genes have been characterized thus far. Here we report the characterization of another recessive resistance gene, xa25, for Xoo resistance. The xa25, localized in the centromeric region of chromosome 12, mediates race-specific resistance to Xoo strain PXO339 at both seedling and adult stages by inhibiting Xoo growth. It encodes a protein of the MtN3/saliva family, which is prevalent in eukaryotes, including mammals. Transformation of the dominant Xa25 into a resistant rice line carrying the recessive xa25 abolished its resistance to PXO339. The encoding proteins of recessive xa25 and its dominant allele Xa25 have eight amino acid differences. The expression of dominant Xa25 but not recessive xa25 was rapidly induced by PXO339 but not other Xoo strain infections. The nature of xa25-encoding protein and its expression pattern in comparison with its susceptible allele in rice-Xoo interaction indicate that the mechanism of xa25-mediated resistance appears to be different from that conferred by most of the characterized R proteins.     

Virus-induced gene silencing in Solanum species

Virus-induced gene silencing (VIGS) has been used routinely in Nicotiana benthamiana to assess functions of candidate genes and as a way to discover new genes required for diverse pathways, especially disease resistance signalling. VIGS has recently been shown to work in Arabidopsis thaliana and in tomato. Here, we report that VIGS using the tobacco rattle virus (TRV) viral vector can be used in several Solanum species, although the choice of vector and experimental conditions vary depending on the species under study. We have successfully silenced the phytoene desaturase (PDS) gene in the diploid wild species Solanum bulbocastanum and S. okadae, in the cultivated tetraploid S. tuberosum and in the distant hexaploid relative S. nigrum (commonly known as deadly nightshade). To test whether the system could be utilised as a rapid way to assess gene function of candidate resistance (R) genes in potato and its wild relatives, we silenced R1 and Rx in S. tuberosum and RB in S. bulbocastanum. Silencing of R1, Rx and RB successfully attenuated R-gene-mediated disease resistance and resulted in susceptible phenotypes in detached leaf assays. Thus, the VIGS system is an effective method of rapidly assessing gene function in potato.