Western Flower Thrips (Frankliniella occidentalis) Transmits Maize Chlorotic Mottle Virus

Maize chlorotic mottle virus (MCMV) is one of the co‐infection pathogens that cause corn (maize) lethal necrosis, but the transmission mechanism of MCMV is not yet clear. In order to determine the ability of western flower thrips (Frankliniella occidentalis; WFT) to transmit MCMV, imported maize seeds from Thailand were germinated in an insect‐free greenhouse and the seedlings were tested for the transmission by WFT of chlorotic mottle virus disease. The thrips (WFT), starved for 48 h then allowed to feed for 30 min on maize plants infected with MCMV or asymptomatic maize plants, were transferred to healthy seedlings. After 35 days, the seedlings with WFT from diseased maize plants showed chlorotic mottle symptoms, whereas seedlings with WFT from asymptomatic maize plants remained healthy. A single band of 711 bp was amplified by RT‐PCR using primers MCMV‐F/MCMV‐R from the MCMV‐infected plants and WFT collected from the diseased plants. Sequencing of the amplified product and further sequence comparison indicated that the two viruses from both sources showed 99% similarity of nucleotides and they should be regarded as identical. In addition, isometric particles c. 30 nm in diameter, characteristic of MCMV, were found in the WFT samples from diseased maize plants. Thus, it is concluded that WFT transmits MCMV. Our findings suggest that corn lethal necrosis disease can be controlled or minimized by the eradication of WFT from the field or greenhouses.     

The complete nucleotide sequence of the maize chlorotic mottle virus genome.

The complete nucleotide sequence of the maize chlorotic mottle virus (MCMV) genome has been determined to be 4437 nucleotides. The viral genome has four long open reading frames (ORFs) which could encode polypeptides of 31.6, 50, 8.9 and 25.1 kd. If the termination codons, for the polypeptides encoded by the 50 and 8.9 kd ORFs are suppressed, readthrough products of 111 and 32.7 kd result. The 31.6 and 50 kd ORFs overlap for nearly the entire length of the 31.6 kd ORF. Striking amino acid homology has been observed between two potential polypeptides encoded by MCMV and polypeptides encoded by carnation mottle virus (CarMV) and turnip crinkle virus (TCV). The 25.1 kd ORF most likely encodes the capsid protein. The similar genome organization and amino acid sequence homology of MCMV with CarMV and TCV suggest an evolutionary relationship with these members of the carmovirus group.     

玉米核糖体失活蛋白基因的克隆及序列分析

将提取的玉米RNA反转录成Cdna,以此为模板,合成特异性引物,应用多聚酶链式反应(PCR)技术扩增出目的片段。对PCR片段直接进行序列分析,测定并克隆玉米的核糖体失活蛋白(RIP)基因。序列分析表明,已测定的玉米RIP基因序列长为983bp,其中编码区长828bp,共编码有275个氨基酸和一个终止密码子,GC含量为58.3%。与已发表的序列相比较其核苷酸序列及推导的氨基酸序列的同源性分别为98.4%和97.4%。     

Molecular genetic characterization of the distal NKC recombination hotspot and putative murine CMV resistance control locus

The NK gene complex (NKC) controls murine cytomegalovirus (MCMV) immunity through Cmv1-dependent natural killer (NK) cell responses. Ly49H expression correlates with Cmv1 phenotypes in different inbred strains, is required for MCMV resistance in C57BL/6 (B6) mice, and its interaction with the MCMV encoded m157 protein leads to NK cell-mediated destruction of virus-infected cells. However, genetic mapping studies have previously indicated that Cmv1 should reside in the D6Wum9–16 NKC interval, distal to Ly49h. Since these data suggested that multiple NKC-linked loci could regulate viral immunity, a putative MCMV resistance control (Mrc) locus was pinpointed to within the D6Wum9–16 interval on a NKC-aligned bacterial artificial chromosome (BAC). Sequence analysis of BAC 151 revealed several novel G-protein coupled receptor genes, an HMG-1 remnant and many additional polymorphic microsatellites that were useful in determining the minimal genetic interval for the Mrc locus. Moreover, comparison of B6, BALB/c, A/J and recombinant Mrc alleles restricted the genetic interval to approximately 470 bp and showed that it was also a hotspot for recombination. MCMV challenge of novel NKC recombinant mice demonstrated that Mrc^B6 was not required for MCMV resistance nor could it directly complement the Ly49^BALB haplotype to rescue MCMV susceptibility. Taken together, these data show that while Mrc apparently guides recombination, Ly49H expression is sufficient for MCMV resistance in B6 mice. A direct role for Mrc^B6 in virus resistance is excluded in the novel mice.The nucleotide sequence data reported in this paper were assigned GenBank accession numbers AF462604, AY145449 and AY145450.     

Black Rot in Zea mays Caused by Olpitrichum tenellum in China

Since 1997, severe epidemics of a black rot disease of maize (Zea mays) have occurred at Yuanmou County, Yunnan Province, China. Olpitrichum tenellum, identified by morphology of conidia and conidiophores was recovered from infected plant material. Its strong infectivity on maize and causal role in inducing black rot was confirmed by pathogenicity tests in the greenhouse. This is the first report of black rot of maize caused by O. tenellum in China.     

Molecular Characterization of a Distinct Begomovirus Infecting Crassocephalum crepidioides in China

A Begomovirus isolate JH1 was obtained from Crassocephalum crepidioides showing yellow vein symptoms in Jinghong of Yunnan province, China. The complete sequence of Begomovirus DNA‐A‐like molecule of JH1 was determined to be 2745 nucleotides long. When compared with other begomoviruses, JH1 DNA‐A has the highest nucleotide sequence identity (86.4%) with that of Tobacco curly shoot virus. Comparisons of individual encoded proteins with other begomoviruses show that different parts of JH1 DNA‐A have different ancestors. The molecular data show that JH1 is a distinct Begomovirus species, for which the name Crassocephalum yellow vein virus is proposed.     

Identification of maize lethal necrosis disease causal viruses in maize and suspected alternative hosts through small RNA profiling

Maize lethal necrosis disease (MLND) is a devastating viral disease of maize caused by double infection with Maize chlorotic mottle virus (MCMV) and any one of the Potyviridae family members. Management of MLND requires effective resistance screening and surveillance tools. In this study, we report the use of small RNA (sRNA) profiling to detect MLND causal viruses and further the development of alternative detection markers for use in routine surveillance of the disease-causing viruses. Small RNAs (sRNAs) originating from five viruses namely MCMV, Sugarcane mosaic virus (SCMV), Maize streak virus (MSV), Maize-associated totivirus (MATV) and Maize yellow mosaic virus (MYMV) were assembled from infected maize samples collected from MLND hot spots in Kenya. The expression of the identified viral domains was further validated using quantitative real-time PCR. New markers for the detection of some of the MLND causal viruses were also developed from the highly expressed domains and used to detect the MLND-causative viruses in maize and alternative hosts. These findings further demonstrate the potential of using sRNAs especially from highly expressed viral motifs in the detection of MLND causal viruses. We report the validation of new sets of primers for use in detection of the most common MLND causal viruses MCMV and SCMV in East Africa.     

Genetic Diversity and Molecular Evolution of Chinese Waxy Maize Germplasm

Waxy maize (Zea mays L. var. certaina Kulesh), with many excellent characters in terms of starch composition and economic value, has grown in China for a long history and its production has increased dramatically in recent decades. However, the evolution and origin of waxy maize still remains unclear. We studied the genetic diversity of Chinese waxy maize including typical landraces and inbred lines by SSR analysis and the results showed a wide genetic diversity in the Chinese waxy maize germplasm. We analyzed the origin and evolution of waxy maize by sequencing 108 samples, and downloading 52 sequences from GenBank for the waxy locus in a number of accessions from genus Zea. A sharp reduction of nucleotide diversity and significant neutrality tests (Tajima’s D and Fu and Li’s F*) were observed at the waxy locus in Chinese waxy maize but not in nonglutinous maize. Phylogenetic analysis indicated that Chinese waxy maize originated from the cultivated flint maize and most of the modern waxy maize inbred lines showed a distinct independent origin and evolution process compared with the germplasm from Southwest China. The results indicated that an agronomic trait can be quickly improved to meet production demand by selection.     

玉米逆境诱导型启动子克隆及其植物表达载体构建

设计特异引物,利用PCR方法从玉米(Zea mays)基因组DNA中克隆低温和盐相应蛋白(low temperature andsalt responsive protein,LS)基因上游1 735 bp,命名为Lsp。利用在线启动子预测工具PlantCARE分析表明,序列中含有TATA-box和CAAT-box等核心元件,还包含各种胁迫响应元件。以植物表达载体pCAMBIA1301为基础,将克隆得到的启动子片段与GUS报告基因融合构建了重组表达载体pCAM-Lsp,并用反复冻融法将其导入农杆菌EHA105,通过农杆菌介导法转化烟草,GUS组织化学染色显示出Lsp驱动GUS基因表达。结果表明,该Lsp启动子片段具备一定的启动活性,为探明玉米逆境胁迫启动子表达调控序列及其调控机制的研究奠定基础。     

Analysis on Peroxidase Isozymes of Waxy Maize from South China

In this experiment, we have tried to make a comparison of analytical peroxidase isozyme of waxy maize from South China, using vertical polyacrylamide gel electrophoretic method. 70 cultivars (lines) of the waxy maize and other materials were examined. The main results were summarized as follows. 1. Eighteen of the nineteen waxy maize cultivars from the original region of "Menghai four-row Wax" showed the fifth band of peroxidase isozyme, and one showed mixed band having fourth and fifth band. 2 Among 15 tested waxy maize cultivars from Yunnan Sheng, eleven of them showed the fifth band of peroxidase isozyme, two showed the fourth band and two showed the mixed band. 3. Seventeen of the nineteen waxy maize cultivars from Guangxi Zhuangzu Zizhi- qu showed the fifth band and two showed the mixed band of peroxidase isozyme. Accordingly, conclusion might be drawn that the most (86.8%) of waxy maize cultivars from South China showed the fifth band of peroxidase isozymc. That is similar to Coix which is originated from China. On the contrary, the dent maize from America showed the fourth band. The experimental results further demonstrated that Chinese waxy maize (Zea mays ) might be originated in South China. China is not only one of maize secondary origin centre, but also might be one of primery origin centre of maize.     

RNA Interference-Based Transgenic Maize Resistant to Maize Dwarf Mosaic Virus

Maize dwarf mosaic virus (MDMV) is a widespread pathogenic virus that causes serious loss of yield in maize (Zea mays). RNA interference (RNAi) triggered by hairpin RNA (hpRNA) transcribed from a transgenic inverted-repeat sequence is an effective way to defend against viruses in plants. In this study, an hpRNA expression vector containing a sense arm and an antisense arm of 150 bp separated by an intron of the maize actin gene was constructed to target the P1 protein (protease) gene of MDMV and used to transform Agrobacterium tumefaciens strain EHA105. The transformed Agrobacterium strain was used to transform maize embryonic calli isolated from immature embryos by an improved culture technique. In all, 46 plants were regenerated after stringent hygromycin B selection, and 18 of them were certified to be positive by PCR amplification. Of these positive plants, 13 were grown to produce offspring, and nine were identified by Southern blotting to have the transgene integrated with one or two copies. The resistance of three T₂ lines was evaluated in a field trial of dual MDMV inoculation in two environments and was found to be improved compared with the non-transformed control. The disease indexes of the transgenic plant lines h2, 13, and h1 were not significantly different from the highly resistant control line H9-21. The viral titers of the inoculated plants were detected by double antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA), and the result was in accord with the resistance evaluated in the field trial. The addition of uniconazole S3307 (0.25 mg l⁻¹) and ABT root-promoting powder (0.5 mg l⁻¹) showed a significant improvement of hardening in regenerated plantlets, which were stronger and generated a better fibrous root system than the control. This improvement could facilitate the transgenic operation of maize.     

DNA Sequence Variation within Maize and Melon: Observations from Polymerase Chain Reaction Amplification and Direct Sequencing

While compiling genetic linkage maps in several plant species based upon restriction fragment length polymorphisms (RFLPs), it was noted that the incidence of polymorphism differs among species. The basis of this disparity was investigated in this study by examining the nucleotide sequence at homologous loci among distinct cultivars within two species which exhibit considerably different levels of RFLPs. Using the polymerase chain reaction, homologous regions from different cultivars were first amplified and the nucleotide sequence of the products were determined. Four genomic regions of seven maize cultivars and three genomic regions of eight melon cultivars were examined to compare the respective levels of sequence variation between the two species. Levels of variation for both base substitutions and insertions/deletions varied widely among the maize sequences and between maize and melon for base substitutions. Estimates of theta (a measure of polymorphism) ranged from 0 to 0.002 in melon and from 0.006 to 0.040 for base substitutions and from 0.002 to 0.023 for insertions/deletions in maize. Critical value tests and chi-squared tests suggested that in maize the underlying processes generating and maintaining neutral mutations differ among the regions. The results not only suggest that several mechanisms are necessary to explain the variation seen in these two species, but also point to some basic dissimilarities in the organization and maintenance of the genomes of different plant species.     

Maize Sh2 gene is constrained by natural selection but escaped domestication

In Zea mays L., we studied the molecular evolution of Shrunken2 (Sh2), a gene that encodes the large subunits of a major enzyme in endosperm starch biosynthesis, ADP-glucose pyrophosphorylase. We compared 4669 bp of the Sh2 coding region on 50 accessions of maize and teosinte. Very few nucleotide polymorphisms were found when compared with other genes in Z. mays, revealing an effect of purifying selection in the whole species that predates domestication. Additionally, the comparison of Sh2 sequences in all Z. mays subspecies and outgroups Z. diploperennis and Tripsacum dactyloides suggests the occurrence of an ancient selective sweep in the Sh2 3' region. The amount and nature of nucleotide diversity are similar in both maize and teosinte, confirming previous results that suggested that Sh2 has not been involved in maize domestication. The very low level of nucleotide diversity as well as the highly conserved protein sequence suggest that natural selection retained effective Sh2 allele(s) long before agriculture started, making human selection inefficient on this gene.     

Knob heterochromatin homology in maize and its relatives

Summary We have characterised the major DNA sequence component of knob heterochromatin in maize, teosinte andTripsacum. Sequence analysis of this DNA gives strong support to the proposal that maize originated by selection of variants in teosinte. In situ hybridization has confirmed that this repeating DNA sequence, which is the major component of maize knob heterochromatin, is also the major component of knobs in teosinte,Zea diploperennis andTripsacum. In Southern blot hybridizations the repeat has a similar basic organization in all taxa;Tripsacum, however, is differentiated from maize and teosinte by a number of sequence features. Maize and teosinte knob heterochromatin are indistinguishable with regard to the distribution of mutations in the 180-bp repeat and the presence and organization of a 202-bp variant sequence. The knob DNA sequence was not detectable in three species ofCoix, an Old World genus of the Maydeae.Within the repeat unit is a 27-bp region that shows no sequence changes in maize, teosinte orTripsacum. The remainder of the repeat unit has randomly distributed nucleotide changes. The presence of the conserved sequence region suggests that knob DNA may have a functional role in the nucleus.     

Maize genetic diversity and association mapping using transposable element insertion polymorphisms

Transposable elements are the major component of the maize genome and presumably highly polymorphic yet they have not been used in population genetics and association analyses. Using the Transposon Display method, we isolated and converted into PCR-based markers 33 Miniature Inverted Repeat Transposable Elements (MITE) polymorphic insertions. These polymorphisms were genotyped on a population-based sample of 26 American landraces for a total of 322 plants. Genetic diversity was high and partitioned within and among landraces. The genetic groups identified using Bayesian clustering were in agreement with published data based on SNPs and SSRs, indicating that MITE polymorphisms reflect maize genetic history. To explore the contribution of MITEs to phenotypic variation, we undertook an association mapping approach in a panel of 367 maize lines phenotyped for 26 traits. We found a highly significant association between the marker ZmV1-9, on chromosome 1, and male flowering time. The variance explained by this association is consistent with a flowering delay of +123 degree-days. This MITE insertion is located at only 289 nucleotides from the 3′ end of a Cytochrome P450-like gene, a region that was never identified in previous association mapping or QTL surveys. Interestingly, we found (i) a non-synonymous mutation located in the exon 2 of the gene in strong linkage disequilibrium with the MITE polymorphism, and (ii) a perfect sequence homology between the MITE sequence and a maize siRNA that could therefore potentially interfere with the expression of the Cytochrome P450-like gene. Those two observations among others offer exciting perspectives to validate functionally the role of this region on phenotypic variation.