Mapping one of the 2 genes controlling lemon ray flower color in sunflower (Helianthus annuus L.)

In an F2 population of 120 plants derived from a cross between 2 breeding lines with yellow ray flowers, we observed 111 plants with yellow-colored and 9 plants with lemon-colored ray flowers. The segregation pattern fits a 15:1 (chi2(15:1) = 0.32, P > 0.5) ratio, suggesting that the lemon ray flower color is conditioned by 2 independent recessive genes that had been contributed individually by each of the parents. We sampled 111 plants from the 3 F(2:3) families displaying a 3 to 1 segregating ratio for genotyping with molecular markers. One of the genes, Yf(1), was mapped onto linkage group 11 of the public sunflower map. A targeted region amplified polymorphism marker (B26P17Trap13-68) had a genetic distance of 1.5 cM to Yf(1), and one simple sequence repeat marker (ORS733) and one expressed sequence tag (EST)-based marker (HT167) previously mapped to linkage group 11 were linked to Yf(1) with distances of 9.9 and 2.3 cM, respectively.     

一个新水稻温敏感叶色突变体的遗传分析及其基因分子定位

在粳稻品种嘉花1号（Oryza sativa L.ssp.japonica＇ Jiahua No.1＇）种子经60Coγ射线辐照处理的后代中,发现了1个低温敏感叶色突变体mr21。在较低温度（〈25.0°C）条件下,该突变体幼苗叶色呈黄色;随着温度逐渐升高,叶色由黄转绿,其临界温度约为27.5°C;在低温条件下,突变体幼苗总叶绿素含量以及叶绿素a、b的含量均较野生型嘉花1号明显下降,表明该突变体的叶色性状具有明显的温敏感性。遗传分析表明,该突变体叶色性状受1对隐性核基因控制,暂将该突变基因命名为thermo-sensitive leaf-color1（tsl-1）。以该突变体与籼稻9311（Oryza sativa L.ssp.indica＇ 9311＇）杂交的F2代分离群体作为定位群体,利用SSR分子标记将tsl-1基因初步定位在水稻（Oryza sativa）第1号染色体短臂上的MM1799与RM8132分子标记之间,其遗传距离分别为2.4cM和3.0cM;然后,进一步利用扩大F2代群体及新发展的分子标记将tsl-1基因定位在分子标记InDel2与InDel4之间的198kb内。研究结果为今后对该基因的克隆和功能分析奠定了基础。     

Development and utilization of a new chemically‐induced soybean library with a high mutation density

Mutagenized populations have provided important materials for introducing variation and identifying gene function in plants. In this study, an ethyl methanesulfonate (EMS)‐induced soybean (Glycine max) population, consisting of 21,600 independent M₂ lines, was developed. Over 1,000 M_{4 (5)} families, with diverse abnormal phenotypes for seed composition, seed shape, plant morphology and maturity that are stably expressed across different environments and generations were identified. Phenotypic analysis of the population led to the identification of a yellow pigmentation mutant, gyl, that displayed significantly decreased chlorophyll (Chl) content and abnormal chloroplast development. Sequence analysis showed that gyl is allelic to MinnGold, where a different single nucleotide polymorphism variation in the Mg‐chelatase subunit gene (ChlI1a) results in golden yellow leaves. A cleaved amplified polymorphic sequence marker was developed and may be applied to marker‐assisted selection for the golden yellow phenotype in soybean breeding. We show that the newly developed soybean EMS mutant population has potential for functional genomics research and genetic improvement in soybean.     

金叶连翘叶片色素含量和解剖结构研究

金叶连翘不同冠层的成熟叶片呈现为不同颜色。以朝鲜连翘深绿色叶为对照,观察金叶连翘冠层上、中、下位叶色,测定其叶片大小和叶绿素a、叶绿素b、总叶绿素及类胡萝卜素含量,同时观察分析叶片横切面解剖结构,旨在阐明叶片色素含量和解剖结构对叶色的影响。研究表明:上层黄色、中层黄绿色、下层浅绿色,黄、黄绿、浅绿色叶总叶绿素含量分别是对照组的0.51%、4.44%和66.47%,均极显著低于对照(P <0.01),但黄绿叶的叶绿素a/b比值显著升高(P <0.05),黄、黄绿叶的总叶绿素/类胡萝卜素比值极显著降低(P <0.01)。黄、黄绿叶的叶绿体发育停滞于单片层时期,类囊体分化程度低,浅绿叶类囊基粒片层肿胀;黄叶细胞器降解,栅栏组织细胞形状难以辨别,黄绿叶上表皮细胞凸起。金叶连翘属于总叶绿素及叶绿素b合成减少型突变体,表现为叶绿素严重缺失,类胡萝卜素相对含量升高;其叶绿体发育停滞,类囊体结构异常,是金叶连翘叶片呈现不同颜色的主要因素,与其叶片解剖显微结构无关。     

谷子雄性不育系1066A不育基因和黄苗基因的染色体定位

以谷子(Setaria italica (L.) Beauv.)雄性不育系1066A为母本,豫谷1号三体(1～7)及四体8和四体9作父本进行杂交,应用初级三体分析法,进行了谷子雄性不育基因和黄苗基因的染色体定位研究.通过配置大量杂交组合和反复授粉,利用豫谷1号三体的极少量花粉,获得了三体2～9的F1代杂种,各杂种三体的形态与豫谷1号三体基本相似,略有差异,苗色呈绿色且可育.杂种F2植株的苗色和育性都产生分离.结果是三体3、5、7、8、9的F2代分离出的可育株与不育株之比为3∶1,三体6的可育株与不育株之比为14∶1 (χ2=0.012,P=0.01).杂种F2分离出的绿苗与黄苗之比只有三体7为12∶1 (χ2=0.36, P=0.01),其他均为3∶1.因此,可以确定1066A的不育基因为隐性单基因,位于第6号染色体上,该品系的黄苗基因也是隐性单基因,位于第7号染色体上.     

3个玉米黄叶突变体的光合特性研究

在农业生产中光合作用是作物积累生物量的主要方式,其主要依赖于多种光合色素和完整的叶绿体结构与功能。而玉米叶色突变体对于研究叶绿体发育、提高玉米光合作用能力和产量具有重要意义。以两个玉米自交系郑58(Z58)和B73为对照,对从甲基磺酸乙酯(ethyl methanesulphonate,EMS)处理后的不同玉米诱变群体中筛选到的2株黄叶突变体yl-1(yellow leaf-1,Z58背景)、yl-2(yellow leaf-2,B73背景)以及从玉米自交系Z58中发现的1株自然黄叶突变体yl-3(yellow leaf-3)等3个表型相似的玉米黄叶突变体的形态特征、光合色素含量、叶绿素合成前体物质含量进行了比较研究。结果表明,与对照相比,3个突变体在整个生长周期内均呈现不同程度的黄叶表型、不复绿、植株矮小、发育迟缓;叶片总叶绿素、叶绿素a和叶绿素b含量均显著降低(P<0.05),叶绿素a/叶绿素b比值显著升高(P<0.05);不同突变体的各类叶绿素合成前体物质含量有不同程度的降低。3个突变体的黄叶表型可能是由不同基因的突变导致相关四吡咯化合物合成异常引起的。研究结果为定位...     

Inheritance of seed coat color genes in <Emphasis Type="Italic">Brassica napus</Emphasis> (L.) and tagging the genes using SRAP,SCAR and SNP molecular markers

Seed coat color inheritance in Brassica napus was studied in F₁, F₂, F₃ and backcross progenies from crosses of five black seeded varieties/lines to three pure breeding yellow seeded lines. Maternal inheritance was observed for seed coat color in B. napus, but a pollen effect was also found when yellow seeded lines were used as the female parent. Seed coat color segregated from black to dark brown, light brown, dark yellow, light yellow, and yellow. Seed coat color was found to be controlled by three genes, the first two genes were responsible for black/brown seed coat color and the third gene was responsible for dark/light yellow seed coat color in B. napus. All three seed coat color alleles were dominant over yellow color alleles at all three loci. Sequence related amplified polymorphism (SRAP) was used for the development of molecular markers co-segregating with the seed coat color genes. A SRAP marker (SA12BG18388) tightly linked to one of the black/brown seed coat color genes was identified in the F₂ and backcross populations. This marker was found to be anchored on linkage group A9/N9 of the A-genome of B. napus. This SRAP marker was converted into sequence-characterized amplification region (SCAR) markers using chromosome-walking technology. A second SRAP marker (SA7BG29245), very close to another black/brown seed coat color gene, was identified from a high density genetic map developed in our laboratory using primer walking from an anchoring marker. The marker was located on linkage group C3/N13 of the C-genome of B. napus. This marker also co-segregated with the black/brown seed coat color gene in B. rapa. Based on the sequence information of the flanking sequences, 24 single nucleotide polymorphisms (SNPs) were identified between the yellow seeded and black/brown seeded lines. SNP detection and genotyping clearly differentiated the black/brown seeded plants from dark/light/yellow-seeded plants and also differentiated between homozygous (Y2Y2) and heterozygous (Y2y2) black/brown seeded plants. A total of 768 SRAP primer pair combinations were screened in dark/light yellow seed coat color plants and a close marker (DC1GA27197) linked to the dark/light yellow seed coat color gene was developed. These three markers linked to the three different yellow seed coat color genes in B. napus can be used to screen for yellow seeded lines in canola/rapeseed breeding programs.     

转基因金叶银中杨叶色及生长变异分析

转PaGLK基因银中杨抑制表达株系叶绿素含量显著降低,叶片呈现黄色（命名为金叶银中杨）,以转PaGLK基因的银中杨为材料,测定其叶色参数和叶绿素含量的时序变化规律、分析生长特性。结果显示,转PaGLK基因的银中杨使叶片颜色发生改变,抑制表达株系整个生长期叶绿素含量显著低于WT（P<0.05）,叶色亮度显著高于WT（P<0.05）,并且在生长发育期叶片一直呈现深黄绿色。抑制表达株系中的Y2速生期内苗高日生长量（GD）高于对照株系,苗期株高不受影响。而过表达转基因银中杨的当年高生长都显著低于对照株系 （P<0.05）,其速生期内苗高日生长量均值（GD）也低于对照株系,其均值为对照株系的22.19%。PaGLK抑制表达株系在城市园林绿化具有潜在的应用价值。     

花青素调节基因VlmybA2对番茄遗传转化

以小型番茄 Micro-Tom 为材料,利用农杆菌介导法导入花青素调节基因VlmybA2。对抗性筛选出的再生植株进行 GUS 组织染色和 PCR 检测,证明外源基因已经整合到 Micro-Tom 中,转基因番茄根、茎、叶脉、果皮均呈紫色,花色为黄紫嵌合。而野生型的根为白色,茎、叶脉呈绿色,果皮为红色,花为黄色。对转基因番茄的花青素含量、叶片叶绿素含量和光合速率等生理指标进行测定,花青素含量有显著增加,叶绿素含量降低,VlmybA2基因过量表达会降低植株的光合效率,但对植株正常生长影响并不显著。VlmybA2 基因既可增加抗衰老物质花青素含量,又可作为转基因植株的报告基因。     

Marking the Vrd1 gene in the bread winter wheat

PCR analysis was used to create DNA markers to the Vrd1 gene. DNA of almost isogenic lines with respect to Vrd genes of the cultivars Mironovskaya 808 and Erytrospermum 604 was used. It was shown that in the monogenic Vrd1 dominant genotypes the product of amplification (280 b.p.) is absent in comparison with the DNA of the vrd recessive and monogenic Vrd2 dominant genotypes. The linkage of the marker with the Vrd1 gene has been determined using DNA analysis of plant population obtained as a result of crossing of Erytrospermum 604 (vrd recessive) and Triple Dirk C (Vrd1vrd2). F2 population segragated in two groups on the character of 280 b.p. amplification product "presence/absence". The segregation significantly coincided to the theoretical one (by ?2 test) with 1:3 expectation. The revealed molecular marker identified homozygous dominant Vrd1 plants only. The DNA-marker to Vrd1 gene is nulle-allelic 280(-).     

The genetic interpretation of the electrophoregrams of the helianthin in F1 sunflower seeds

It has been shown, that in most cases the fertile plants of maternal line and F1 plants of respective hybrid are present among sterile plants of sunflower female lines in crossing plots. As a result, 16 various genotypes of seeds are ascertained in crossing plots at monogenic differences in marker trait. Only two classes are F1 seeds. In such cases specific share of 5 genotype groups may be distinguished by phenotypes of heliantin electrophoregrammes. Seeds of biological admixture may be attributed to the 6th distinguishing type.     

Association of the yellow leaf (y10) mutant to soybean chromosome 3

At least 19 single recessive gene yellow leaf mutants and one duplicate recessive gene mutant have been described in soybean. This study was conducted to associate a yellow leaf mutant, y10, with a specific soybean chromosome by using primary trisomics (2n = 41). Seven soybean primary trisomics were hybridized as female parent with genetic stock strain, T161, carrying y10. F(1) disomic and primary trisomic plants were identified cytologically. One disomic (control) and all primary trisomic plants were allowed to self-pollinate and F(2) populations were classified for green versus yellow leaf mutant. The F(2) population of Triplo 3 segregated in a 17:1 ratio, while a disomic (3:1) ratio was observed with Triplo 8-, 17-, 18-, and 20-derived F(2) populations, suggesting that the y10 locus is on chromosome 3. The y10 locus was examined with four simple sequence repeat (SSR) markers (Satt584, Sat_033, Satt387, and Satt022) from molecular linkage group (MLG) N and y10 was found linked with Satt022. Therefore we confirmed the association of MLG N with chromosome 3. The possible association of y10 with Triplo 16 and Triplo 19 are discussed.     

金叶银杏半同胞子代无性系的叶色和色素含量变化及呈色机制分析

对4月份至11月份金叶银杏‘万年金'( Ginkgo biloba ‘Wannianjin')32个半同胞子代无性系与亲本的叶色差异进行比较;比较了不同色系叶片的色素含量和比值及叶色参数(L*、a*和b*)的变化,分析了叶色参数与叶片色素含量的相关性;并观察了不同色系的叶绿体超微结构。结果表明：32个半同胞子代无性系可被分为金黄、浅黄、草绿和蓝绿4个色系。随时间推移,草绿和蓝绿色系叶片的总叶绿素( Chl)、叶绿素a( Chla)、叶绿素b( Chlb)和类胡萝卜素( Car)含量均呈“双峰型”变化趋势,Car/Chl和Car/Chla比值的变幅均较小;而金黄和浅黄色系叶片的上述色素含量呈“升高—降低—升高”变化趋势,Car/Chl和Car/Chla比值总体呈“迅速下降—相对稳定—缓慢升高”的变化趋势。各色系叶片的上述色素含量在夏季均不同程度下降,Car/Chlb比值变化差异较大,且金黄和浅黄色系的各色素含量均低于草绿和蓝绿色系。随时间推移,金黄和浅黄色系叶片的L*、a*和b*值以及草绿和蓝绿色系叶片的L*和b*值均先降低后升高,后2个色系的a*值则先升高后下降;并且,前2个色系的L*和b*值总体上显著高于后2个色系,而a*值则总体上低于后2个色系。金黄色系的Chla和Chl含量与L*和a*值显著负相关,而其Car/Chl和Car/Chla比值则与L*、a*和b*值显著或极显著正相关;浅黄色系的Chlb含量与a*值显著负相关,其Car/Chla比值与L*和b*值以及Car/Chlb比值与a*值均显著正相关;草绿色系的Chla含量与L*值显著负相关,其Car/Chla比值与L*和b*值以及Car/Chlb比值与a*值均显著正相关;这3个色系叶片的其余指标间以及蓝绿色系叶片的各指标间均无显著相关性。观察结果显示：金黄和浅黄色系的叶绿体基粒片层发育不健全,基粒片层可见但排列较疏松,且无明显垛叠,分布范围小而稀疏;蓝绿和草绿色系叶绿体的基粒类囊体垛叠层数均较多,基粒片层发达且排列紧致、整齐,分布范围大而稠密。综合分析结果表明：‘万年金'4个色系半同胞子代无性系叶片的呈色差异和叶色变化由多种因素控制,其中,Car/Chl和Car/Chla比值高且叶绿体基粒片层发育不健全是叶片呈黄色的主要原因。     

玉米黄绿叶突变体表型鉴定及基因初步定位

叶色突变体是研究光合作用及叶绿体发育的重要材料。开展玉米叶色突变体的相关研究,对光形态建成、光合作用、基因功能注释、蛋白质功能及抗逆性机制的阐述具有重要的理论意义。本研究以黄绿叶突变体ygl-F17138为材料,与玉米自交系B73进行杂交,构建F2分离群体,进行遗传效应分析和基因初步定位。遗传分析表明,该突变性状由单个隐性核基因控制,且能稳定遗传。利用BSR-seq结合连锁分析的方法将该基因初步定位在第3条染色体上一个约9.2 Mb的区间内(chr.3:173087201~182203992),查询该区间内已知基因功能注释,未发现类似前人报道的调控黄绿叶性状基因,说明YGL-F17138基因可能是一个控制玉米黄绿叶发育未被挖掘的候选基因。     

一个新水稻温敏感叶色突变体的遗传分析及其基因分子定位

在粳稻品种嘉花1号(Oryza sativa L. ssp. japonica ‘Jiahua No.1’)种子经⁶⁰Co γ射线辐照处理的后代中, 发现了1个低温敏感叶色突变体mr21。在较低温度(<25.0°C)条件下, 该突变体幼苗叶色呈黄色; 随着温度逐渐升高, 叶色由黄转绿,其临界温度约为27.5°C; 在低温条件下, 突变体幼苗总叶绿素含量以及叶绿素a、b的含量均较野生型嘉花1号明显下降, 表明该突变体的叶色性状具有明显的温敏感性。遗传分析表明, 该突变体叶色性状受1对隐性核基因控制, 暂将该突变基因命名为thermo-sensitive leaf-color 1(tsl-1)。以该突变体与籼稻9311(Oryza sativa L. ssp. indica ‘9311’)杂交的F₂代分离群体作为定位群体, 利用SSR分子标记将tsl-1基因初步定位在水稻(Oryza sativa)第1号染色体短臂上的MM1799与RM8132分子标记之间, 其遗传距离分别为2.4 cM和3.0 cM; 然后, 进一步利用扩大F₂代群体及新发展的分子标记将tsl-1基因定位在分子标记InDel2与InDel4之间的198 kb内。研究结果为今后对该基因的克隆和功能分析奠定了基础。     

White yellow virescent pattern in winter rye: inheritance, plant growth, and ultrastructure of plastids

Inbred lines from different varieties of cultivated plants characterized by a white yellow irregular pattern on the leaves obtained after selection in the inbred generation (S3) of winter rye (Secale cereale L.) were the object of the present studies. The feature of a white yellow irregular pattern in all lines was monomeric and recessive. This trait in L158b, wch, and zp was determined by the same recessive gene marked with the symbol wyv1, "white yellow virescent." The gene responsible for the appearance of the above feature in line L24 was nonallelic to the gene wyv1, therefore it was designated as the sequent gene of the same series--wyv2. The studied forms of plants were characterized by a diminution in the number of plastids and in chlorophyll (a plus b) content in mesophyll cells of leaves. Contrary to typical ultrastructure of chloroplasts in dark green plants (control), plastids in lines with the white yellow virescent pattern on the leaves showed variations in ultrastructure from numerous granal and intergranal thylakoids to a reduced number.     

Genetic analysis and molecular mapping of a novel gene for zebra mutation in rice （Oryza sativa L.）

A novel zebra mutant, zebra-15, derived from the restorer line JinhuilO （Oryza sativa L. ssp. indica） treated by EMS, displayed a distinctive zebra leaf from seedling stage to jointing stage. Its chlorophyll content decreased （55.4%） and the ratio of Chla/Chlb increased （90.2%） significantly in the yellow part of the zebra-15, compared with the wild type. Net photosynthetic rate and fluorescence kinetic parameters showed that the decrease of chlorophyll content significantly influenced the photosynthetic efficiency of the mutant. Genetic analysis of F2 segregation populations derived from the cross of XinonglA and zebra-15 indicated that the zebra leaf trait is controlled by a single recessive nuclear gene. Ninety-eight out of four hundred and eighty pairs of SSR markers showed the diversity between the XinonglA and the zebra-15, their F2 population was then used for gene mapping. Zebra-15 （Z-15） gene was primarily restricted on the short arm of chromosome 5 by 150 F2 recessive individuals, 19.6 cM from marker RM3322 and 6.0 cM from marker RM6082. Thirty-six SSR markers were newly designed in the restricted location, and the Z-15 was finally located between markers nSSR516 and nSSR502 with the physical region 258 kb by using 1,054 F2 recessive individuals.     

Gene mapping related to yellow green leaf in a mutant line in rice (Oryza sativa L.)

A mutant, which derived from the restorer line Jinhui10 treated with EMS, showed completely yellow green leaves, and it had low chlorophyll content and poor agronomic characteristics during the growing stage. The F1 plants from the cross between normal × the mutant showed normal green leaves, and the segregation ratio of normal to yellow green leaves was 3 : 1 in F₂ population. It indicated that the trait was controlled by a single recessive nuclear gene, temporarily designated asygl3. The geneygl3 was mapped between RM468 and RM3684 with genetic distances 8.4 cM and 1.8 cM on chromosome 3. This result would be used as genetic information for fine mapping and map-based cloning ofygl3 gene.