小麦长链非编码RNA的预测及功能分析

生物体有部分基因被转录成RNA,但是不编码相应蛋白质,称为长链非编码RNA(lncRNA)。它们参与基因的表观调控,这一过程对动物、植物的生长发育都有重要作用,但是,目前植物中发现和研究的lncRNA较少。为了研究lncRNA在植物中的功能,本研究建立了基于小麦全长cDNA的lncRNA识别程序。从6162条小麦全长cDNA中发现了231条lncRNAs,并从中鉴定出两个新miRNAs,这表明lncRNAs可以通过形成miRNAs前体基因形成其功能。此外,通过序列富集分析,我们从小麦lncRNAs中鉴定出三个保守的调控元件,结果显示小麦lncRNAs可能通过和其它蛋白质或DNA等分子作用,进而参与小麦生长、发育等过程的调控,这些结果对进一步研究植物体内的lncRNA的功能和作用机制具有重要意义。     

A new multiplex PCR test for the determination of Vrn-B1 alleles in bread wheat (Triticum aestivum L.)

Winter wheat requires vernalization, a long exposure to low but non-freezing temperatures, to promote reproductive development. The vernalization requirement in bread wheat (Triticum aestivum L.) is mainly controlled by the Vrn-1 genes that are located on chromosomes 5A, 5B and 5D. Dominant alleles confer spring habit and are epistatic to the recessive winter alleles which means that spring varieties carry at least one dominant allele. To date, two dominant and one recessive Vrn-B1 alleles have been described. Vrn-B1a (formerly designated as Vrn-B1) differs from the winter vrn-B1 allele by a large deletion in intron 1. Vrn-B1b has an additional small deletion and is probably derived from Vrn-B1a. The novel allele described here and designated as Vrn-B1c also has a large deletion within intron 1 but with different breakpoints from Vrn-B1a or b, and sequence duplication, showing that this is an independently derived spring allele. By combining an exon 1 primer with previously published PCR primers it was possible to develop a multiplex PCR that distinguished all four alleles simultaneously. The multiplex PCR was validated by testing 320 winter wheat and 137 spring wheat varieties. This demonstrated that the novel Vrn-B1c allele was present in 25 spring varieties of diverse origin, showing this allele to be widely distributed.     

RFLP patterns of gliadin alleles in Triticum aestivum L.: implications for analysis of the organization and evolution of complex loci

A correspondence between RFLP patterns and gliadin alleles at the Gli-1 and Gli-2 loci was established in a set of 70 common wheat (T.aestivum L.) cultivars using -gliadin (K32) and -gliadin (pTU1) specific probes. All Gli-B1 and Gli-D1 alleles which differed in encoded -gliadins showed definite RFLP patterns after hybridization with the K32 probe. Two groups of Gli-B1 alleles, Gli-B1b-like and Gli-B1e-like, were identified, and these could originate from distinct genotypes of the presumptive donor of the B-genome. Intralocus recombination and/or gene conversion as well as small deletions, gene silencing and gene amplification were assumed to be responsible for the origin of new gliadin alleles. Silent -gliadin sequences were shown to exist in all of the genotypes studied. K32 also differentiated Gli-A1a from all other Gli-A1 alleles as well as the Gli-B11 allele in cultivars carrying the 1B/1R (wheat/rye) translocation. PTU1 was shown to recognize several Gli-A2 alleles, but not the Gli-B2 or Gli-D2 alleles. Moreover, this probe hybridized to chromosome 1R sequences suggesting the existence of rye gene(s), probably silent, for -gliadin-like proteins on chromosome 1R.     

Pollen callus culture in Triticum aestivum

Summary Pollen shed between 4–8 d from anthers of Triticum aestivum cultured in liquid medium gave rise to calluses. Tillers were harvested at the mid-to late-unicellular pollen stages and chilled for 8 d at 4–5 °C before the anthers were dissected out. Pollen cultures gave about 6 times as many calluses on a per anther basis as anthers cultured on solid medium. With the most productive of 5 cultivars tested, pollen culture results in roughly one callus for each anther used, though the calluses formed by pollen culture were less productive for the regeneration of shoots than calluses derived from anthers cultured on solid medium. The ratio of green to albino shoots is roughly 1 1 for anther cultures but considerably less for pollen cultures.     

Leaf wax of Triticum aestivum

Leaf waxes from spring wheat varieties Selkirk and Manitou contain hydrocarbons (6%, 10%), long chain esters (14%, 13%), free acids (5%, 8%), free alcohols (19%, 21%), β-diketone (16%, 20%), hydroxy β-diketones (8%, 10%), unidentified gum (29%, 16.5%) and minor amounts of diol diesters, glycerides and aldehydes. The major hydrocarbon is nonacosane and major esters are octacosyl esters of C₁₄–C₃₂ acids but C₂₀ and C₂₂ alcohol esters of trans 2-docosenoic and tetracosenoic acids are also present (Selkirk 20%, Manitou 10% of total esters). Previously unknown trans 2-docosen-1-ol is present as an ester (Selkirk 5%, Manitou 2.5% of total esters). Free acids are C₁₄–C₃₂ acids and trans 2-docosenoic and tetracosenoic acids (Selkirk 30%, Manitou 9% of free acids). Octacosanol is the principal free alcohol. Hentriacontane-14,16-dione is the β-diketone and the hydroxy β-diketones are a 1:1 mixture of 8- and 9- hydroxyhentriacontane-14,16-diones.     

The effect of Ph gene alleles on synaptonemal complex formation in Triticum aestivum × T. kotschyi hybrids

Summary Chromosome pairing at zygotene-pachytene was studied in Triticum aestivum × T. kotschyi hybrids (2n=5x=35, genomic constitution ABDC^US^v) by electron microscopy of synaptonemal complexes in spread microsporocyte nuclei. Hybrids carrying either the Ph allele or the ph allele, which differ markedly in metaphase I pairing, are both capable of greater than 90% pachytene pairing, although pairing in the Ph hybrids appeared slower or less synchronised. In both genotypes branched synaptonemal complexes were formed by intra-and interchromosomal pairing. The Ph gene control on homoeologous pairing does not act on the ability to pair into synaptonemal complexes. It may act on the rate of pairing or the time of crossing over.     

小麦TaHDA19基因的克隆及胁迫表达分析

利用基因克隆技术从小麦（Triticum aestivum L.）品种‘科农199’中扩增得到一个RPD3/HDA1型组蛋白去乙酰化酶基因TaHDA19,采用生物信息学方法对该基因序列的结构特征进行分析,并对植株不同组织及不同胁迫条件下该基因的表达量进行检测。结果显示：TaHDA19的开放阅读框长1560 bp,共编码519个氨基酸;该基因的氨基酸序列存在组蛋白去乙酰化酶（HDAC）家族典型的结构域Hist-deacety1。该基因上游启动子区含有多种响应元件,如：光响应元件I-box和G-box,脱落酸响应元件ABRE和低温响应元件LTR等。‘科农199’TaHDA19基因的表达结果表明：该基因在根、茎、叶片和幼穗中均有表达,其中在叶片中表达量最高;采用脱落酸、氯化钠和PEG分别处理植株0、1、3、6、12、24 h后,基因的表达水平出现差异;在对植株的12个生育时期进行35℃和42℃热胁迫处理1 h后,该基因表达量均出现上调。研究结果表明TaHDA19可能在小麦响应非生物胁迫过程中发挥重要作用。     

N-banding in Triticum aestivum following feulgen hydrolysis

Summary Terminal and/or interstitial N-bands were produced on the seven B-genome chromosomes and chromosomes 4 and 7 of the A-genome of Triticum aestivum cv. Chinese Spring by a modified BSG technique following a standard Feulgen preparation. The banding was accomplished by modifying the barium hydroxide treatment.     

Allelopathy in wheat (Triticum aestivum)

Wheat (Triticum aestivum) allelopathy has potential for the management of weeds, pests and diseases. Both wheat residue allelopathy and wheat seedling allelopathy can be exploited for managing weeds, including resistant biotypes. Wheat varieties differ in allelopathic potential against weeds, indicating that selection of allelopathic varieties might be a useful strategy in integrated weed management. Several categories of allelochemicals for wheat allelopathy have been identified, namely, phenolic acids, hydroxamic acids and short‐chain fatty acids. Wheat allelopathic activity is genetically controlled and a multigenic model has been proposed. Research is underway to identify genetic markers associated with wheat allelopathy. Once allelopathic genes have been located, a breeding programme could be initiated to transfer the genes into modern varieties for weed suppression. The negative impacts of wheat autotoxicity on agricultural production systems have also been identified when wheat straws are retained on the soil surface for conservation farming purposes. A management package to avoid such deleterious effects is discussed. Wheat allelopathy requires further study in order to maximise its allelopathic potential for the control of weeds, pests and diseases, and to minimise its detrimental effects on the growth of wheat and other crops.     

Identification,characterization and expression profiling of cation-proton antiporter superfamily in Triticum aestivum L. and functional analysis of TaNHX4-B

The monovalent cation proton antiporter (CPA) superfamily comprises Na⁺/H⁺ exchanger (NHX), K⁺ efflux antiporter (KEA), and cation/H⁺ exchanger (CHX) family proteins, which play vital functions in plants. A total of 107 TaCPA proteins were identified in Triticum aestivum, and phylogenetically classified into 35 TaNHX, 24 TaKEA and 48 TaCHX proteins. These families had representatives derived from all three sub-genomes. TaKEA genes consisted of higher number of exons, followed by TaNHXs and TaCHXs. The occurrence of about 10 transmembrane regions and higher composition of helices and coils support their membrane-bound and hydrophobic nature. Diverse expression in various tissues and modulated expression under stress conditions suggested their role in development and in response to stress. Co-expression analyses revealed their complex interaction networks. Expression of TaNHX4-B.1 and TaNHX4-B.4 facilitated differential abiotic stress tolerance to Escherichia coli. Our study provides comprehensive information about CPA genes, which would be useful in their future functional characterization.     

小麦分蘖角度TaTAC1基因同源克隆及表达分析

分蘖角度影响植物群体结构、光合效率以及植株的形态建成,最终影响其产量及品质。小麦中关于分蘖角度的研究鲜有报道。前人研究显示,水稻OsTAC1正向调控分蘖角度的大小,玉米Zm TAC1与叶片角度呈正相关。本研究的目的是解析Ta TAC1的表达模式并初步了解该基因的分子遗传机制及其与分蘖角度的遗传关系。本研究以CN16、SM969、Lan2399、SHW-1为材料,利用同源克隆分离获得Ta TAC1,利用生物信息学软件对Ta TAC1进行序列特征分析,应用实时荧光定量PCR对其表达模式进行分析,并进行Ta TAC1蛋白的亚细胞定位分析。结果显示,Ta TAC1长度约1.1~1.2 kb,包括780 bp的完整开放阅读框和320~370 bp的3'-UTR。Ta TAC1的c DNA序列分为2类,其中CN16-2、SM969-2的第10号碱基发生突变,引起终止子提前,导致Ta TAC1表达受阻;Lan2399-2和SHW-1-2在109~115碱基位置有"CGCGCG"片段插入,导致蛋白质β-折叠片减少。表达分析表明,Ta TAC1在分蘖期的叶鞘、茎高效表达,分蘖节其次,叶与根表达量最低。相关分析表明该基因在分蘖节各时期表达量与分蘖角度呈显著正相关,Pearson相关系数为0.677,其他组织表达量与分蘖角度无显著相关性。亚细胞定位分析显示Ta TAC1定位于细胞膜。从上述结果可以推测Ta TAC1在mRNA水平上正向调控分蘖角度,且可能参与生长素极性运输过程从而改变分蘖角度大小。     

Isolation and analysis of endophytic microorganisms in wheat (Triticum aestivum L.) leaves

The present investigation was undertaken in order to select the surface-sterilization technique most efficient for eliminating epiphytes, to document the spectrum of endophytes of healthy leaves from three wheat cultivars in Buenos Aires Province (Argentina) and to determine their infection frequencies at three growth stages. Surface-sterilization with undiluted commercial solution of sodium hypochlorite was reaffirmed as adequate for removing epiphytes on wheat leaves. From the 450 wheat leaf segments incubated, three bacterial isolates and 130 fungal isolates were obtained. From all the isolates, 19 fungal species were identified. Bacterial isolates were characterized as Bacillus sp. There were significant differences between microorganisms, stages of growth, and stages × microorganisms interaction. Differences between cultivars, stages × cultivars, microorganisms × cultivars and for the triple interaction were not significant. Frequency of microorganisms isolated increased with crop age, but it was statistically similar for the three wheat cultivars tested (Klein Centauro, Klein Dragón and Buck Ombú). Rhodotorula rubra, Alternaria alternata, Cladosporium herbarum and Epicoccum nigrum were isolated in the highest frequency. The other microorganisms were present at intermediate or low values. The species isolated may be assigned to three groups: (a) well-known and economically important pathogens of wheat, (b) commonly abundant phylloplane fungi considered to be primary saprobic and minor pathogens and (c) species occasionally present in wheat.     

小麦TaCRC基因的克隆及表达分析

以小麦心皮为材料,利用RT-PCR方法分离出一个新的YABBY基因TaCRC,并利用Northern杂交对TaCRC在不同组织中的表达模式进行分析.结果显示:该基因全长1 105 bp,编码199个氨基酸.TaCRC具有YABBY家族典型的结构域,即N端含有C2C2锌指结构域,C端含有YABBY结构域.其氨基酸序列与水稻的 DROOPING LEAF(DL)、拟南芥的CRABS CLAW(CRC)和金鱼草的AmCRC的氨基酸具有较高的一致性.TaCRC在心皮中特异表达,类似于拟南芥的CRC的表达模式.研究表明,TaCRC是小麦中的CRC同源基因.     

小麦种子基因的表达序列标签分析(英文)

以授粉后12d的小麦(TriticumaestivumL.)种子为材料,构建起cDNA文库。从中随机挑选10000个克隆,利用Biomek2000核酸工作站制成高密度cDNA阵列。然后分别以未受精子房、胚和胚乳中提取的RNA为模板,反转录合成探针与膜杂交,进行差示筛选。根据筛选结果,选取800个在胚、胚乳或胚和胚乳中表达的克隆进行表达序列标签(EST)分析,鉴定出216个不同的基因序列。其中24个ESTs属于已知的小麦基因;122个ESTs为推测的小麦新基因,它们编码的产物与种子贮藏蛋白或与生化代谢、发育等其他的生物学过程有关;70个ESTs的序列特征尚未确定。本研究为研究种子发育和小麦品质改良等提供了基础资料。     

Diallelic analysis of quantitative traits in hexaploid wheat (Triticum aestivum L.)

Abstract

A complete diallel study of crosses between eight wheat varieties was carried out to determine the relative magnitude of components of genetic variation and heritability for important grain yield, quality and drought‐related traits. The data appeared adequate for the additive‐dominance model. The additive effects predominated for most traits, and consequently the narrow‐sense heritability was high to moderately high for flag leaf area, weight and venation, stomatal frequency and size, epidermal cell size, biomass, protein content, number of tillers, spike length, spike density, 1000‐grain weight and grain yield. These results appear promising for selecting better plants in the segregating populations with some degree of improvement for yield, quality and physiological efficiency.     

Monosomic analysis of tissue culture response in wheat (Triticum aestivum L.)

Summary The ability of immature embryos of wheat (Triticum aestivum L.) to respond in cell culture was examined in crosses between the Wichita monosomic series and a highly regenerable line, ND7532. Segregation in disomic controls and 13 monosomic families showed a good fit to a monogenic ratio indicating a qualitative mode of inheritance. Segregation in the cross involving monosomic 2D showed a high frequency of regeneration (93.6%) and high callus growth rate (1.87 g/90 days) indicating that 2D is a critical chromosome. Modifying genes may be located on other chromosomes. Substitution of chromosomes from a low regenerable cultivar Vona further indicated that the group 2 chromosomes, in particular chromosome 2D, possess genetic factors promoting callus growth and regeneration.