水稻紫色柱头的遗传分析与基因定位

rdh是四川农业大学水稻研究所通过组织培养和连续自交得到的一个具有红色籽粒和紫色柱头,遗传上稳定的籼稻材料。抽穗期在rdh与3个无色柱头品种蜀恢527、蜀恢368和蜀恢168之间分别做正反交,结果显示F1群体在柱头颜色上正反交之间没有明显区别,全部是紫色的。F2群体发生分离成为两组,一组具有紫色柱头,另一组具有无色柱头。每一个F2群体的紫色柱头对无色柱头均适合3：1的比例,表明rdh紫色柱头性状的遗传是由一对显性核基因控制的。组合rdh／蜀恢527 F2分离群体中40个具有紫色柱头的显性单株和284个具有无色柱头的隐性单株构成定位群体。从两个亲本rdh和蜀恢527提取的基因组DNA,用涵盖水稻整个基因组的252对微卫星标记作引物扩增片段。结果发现有78对微卫星标记在两亲本之间具有多态性。然后用这78对标记作引物,扩增亲本、F1、F2显性单株和F2隐性单株、,结果显示位于水稻第6染色体的RM276、RM253以及RM111与rdh紫色柱头基因有连锁关系。再用RM276、RM253以及RM111作引物扩增剩余的全部具有无色柱头的隐性单株。结果表明：在RM276的扩增产物中,有20个单交换和2个双交换;在RM253中有2个单交换：在RM111中有3个单交换。因此,rdh紫色柱头基因被定位于水稻第6染色体。根据公式P=（h＋2b）／2n,计算得到微卫星标记RM276,RM253和RM111与rdh紫色柱头基因的遗传距离分别是4．2cM、0．35cM以及0．53cM。根据已经发表的RM276、RM253和RM111在第6染色体上的位置以及计算得到的rdh与RM276、RM253和RM111之间的遗传距离,构建了部分连锁图谱,并暂时将这个紫色柱头基因命名为Ps-4。     

水稻亚种间杂种F1光合特性研究

用绵恢725、蜀恢527和蜀恢881三个籼型恢复系、1个美国稻Lemont和1个爪哇稻香大粒作母本,与1个日本特早熟粳稻Kitaake杂交,研究了5个杂种F1及其亲本的光合生理表现.结果表明,在高光通量密度(Photosynthetic flux density,PFD)条件下,5个杂种F1净光合速率(Pn)明显高于双亲或双亲之一,推测亲本与杂种F1之间不同的Pn同叶片中Rubsico活性有关.杂种F1的比较中,在表观量子效率(ψ)、羧化效率(CE)、CO2补偿点(T)等方面,籼粳亚种间杂种F1(绵恢725/Kitaake、蜀恢527/Kitaake、蜀恢881/Kitaake)对2个亚种内杂种F1香大粒/Kitaake(粳爪交)、Lemont/Kitaake(不同生态型的粳粳交,美国稻属于特殊粳稻)具有明显的优势,而蜀恢881含有粳型血缘,蜀恢881/Kitaake也比典型籼粳亚种间杂种F1绵恢725/Kitaake、蜀恢527/Kitaake优势稍逊一筹.5个杂种F1因为具有不同的遗传差异而表现出不同的光合优势,在这方面,典型籼粳亚种间杂交蜀恢527/Kitaake、绵恢725/Kitaake要优于其他杂交种,说明亲本间遗传差异越大,其杂种F1的光合优势越强.     

水稻亚种间杂种F1 光合特性研究

用绵恢725、蜀恢527和蜀恢881三个籼型恢复系、1个美国稻Lemont和1个爪哇稻香大粒作母本, 与1个日本特早熟粳稻Kitaake杂交, 研究了5个杂种F1及其亲本的光合生理表现。结果表明, 在高光通量密度(Photosynthetic flux density, PFD)条件下, 5个杂种F1净光合速率(Pn)明显高于双亲或双亲之一, 推测亲本与杂种F1之间不同的Pn同叶片中Rubsico活性有关。杂种F1的比较中, 在表观量子效率(j)、羧化效率(CE)、CO2补偿点(G)等方面, 籼粳亚种间杂种F1(绵恢725/Kitaake、蜀恢527/Kitaake、蜀恢881/Kitaake)对2个亚种内杂种F1香大粒/Kitaake(粳爪交)、Lemont/Kitaake(不同生态型的粳粳交, 美国稻属于特殊粳稻)具有明显的优势, 而蜀恢881含有粳型血缘, 蜀恢881/Kitaake也比典型籼粳亚种间杂种F1 绵恢725/Kitaake、蜀恢527/Kitaake优势稍逊一筹。5个杂种F1因为具有不同的遗传差异而表现出不同的光合优势, 在这方面, 典型籼粳亚种间杂交蜀恢527/Kitaake、绵恢725/Kitaake要优于其他杂交种, 说明亲本间遗传差异越大, 其杂种F1的光合优势越强。     

杂草稻红色果皮基因的遗传分析

以江苏扬中红色果皮杂草稻W16、粳型广亲和品种02428(S5n)及以它们为亲本的衍生世代F1、F2和F3为材料,研究了杂草稻红色果皮性状的遗传特征;根据已克隆的普通野生稻(O.rufipogen)红色果皮Rc与白色果皮rc等位基因第6外显子的差异,设计了InDel标记RID14,利用RID14标记对F2群体、江淮流域所收集到的24份红色果皮杂草稻、3份普通野生稻以及423份品种资源进行了标记基因型分析;选取5份江淮流域杂草稻的RID14标记PCR产物进行测序分析.结果显示:以白色果皮02428为母本的杂交种F1的颜色为白色,而以红色果皮杂草稻W16为母本,杂交种F1的果皮颜色为红色;正反交杂种F1所结F2种子都是红色,F2植株所结F3种子果皮颜色发生分离,符合3∶1分离比例;在F2群体中,RID14标记与果皮颜色共分离,在450份材料中,红色果皮均为非缺失带型,而白色果皮和紫色果皮为缺失带型;5份江淮流域杂草稻的RID14标记PCR产物序列与已登录的普通野生稻序列完全一致.研究表明,扬中杂草稻红色果皮为单基因控制的显性性状,并由母体基因型决定,是典型的延迟遗传,由Rc基因控制;在白色果皮材料资源中都存在14 bp缺失的等位基因rc,RID14标记可以作为准确鉴定红色果皮杂草稻的分子标记.     

2003年国际生物学奥林匹克竞赛实验考试试题(5)

第四实验室:遗传学实验实验1菜豆种皮颜色遗传方式的遗传分析完成本题的时间是25min材料与设备亲代种子(P1)——(样品No.1)亲代种子(P2)——(样品No.2)杂交种子(F1)——(样品No.3)分析用品系种子(La)——(样品No4)Fa带种子——(样品No.5)盛种子的盘子2个白纸1张菜豆种皮颜色由一系列基因控制,这些基因分别控制色素的合成,种皮颜色的分布,以及增色、淡化或者以某种方式改变颜色的修饰基因。在预实验中,两种种皮颜色不同菜豆(P1和P2)的杂交育种实验。用杂交子1代的种子进行栽培实验,长成的杂合个体(F1)得F1表型种子。下一阶段实验用子一…     

紧穗野生稻（O．eichingeriA．Peter）控制红色果皮基因的定位

将绿色果皮的紧穗野生稻与白色果皮的栽培稻(Oryza sativa L.)中花九号杂交,在以中花九号为轮回亲本的回交后代中分离出具有红色果皮的种子,自交后获得BC4F3分离群体,经卡平方测验,红、白子粒单株比例符合3∶1分离比例,初步确定该红色果皮性状来自于紧穗野生稻的单片段代换系且受一对显性基因控制.利用123对SSR引物对其中1个分离群体的115个隐性单株进行基因定位,将该基因初步定位于第7染色体短臂上的RM1253和RM8262标记之间,其遗传距离分别是2.61cM和3.48cM,初步命名为Rf.     

一个水稻显性高秆突变体的遗传分析和基因定位

从水稻(Oryza sativa L.)的两个半矮秆籼稻品种6442S-7和蜀恢881杂交F2代群体中发现一个高秆突变体D111,其株高和秆长分别比亲本蜀恢881增加63.0%和87.0%.用205个微卫星标记分析D¨1及其原始亲本6442S-7和蜀恢881之间的基因组DNA多态性,结果未发现D111具有2个原始亲本都没有的新带型,证明D1¨的确是6442S-7和蜀恢881的杂交后代发生基因突变产生的.将D111分别与蜀恢881、蜀恢527、明恢63、9311、IR68、G46B等6个半矮秆品种和高秆对照品种南京6号杂交,分析F1和F2代株高的遗传行为,结果表明D1¨的高秆性状由一对显性基因控制,且该基因与南京6号的高秆基因紧密连锁或等位.以蜀恢527/D111 F2群体为定位群体,运用微卫星标记将D111显性高秆突变基因定位于水稻第一染色体长臂,与RM212、RM302和RM472的遗传距离分别是27.7 cM、25.5 cM和6.0 cM,该基因暂命名为LC(t).认为D111是首例从半矮秆品种自然突变产生的水稻显性高秆突变体,LC(t)为首次定位的水稻显性高秆突变基因.此外,将上述基因定位结果与Causse等(1994)和Temnykh等(2000,2001)发表的水稻分子连锁图谱进行比较,发现LC(t)基因恰巧位于与水稻"绿色革命基因"sd1相同或十分相近的染色体区域,因此,还就LC(t)基因与sd1基因之间的可能关系进行了讨论.     

毛竹种子形成过程中形态解剖学特征

为揭示毛竹(Phyllostachys edulis)种子生长过程中胚、胚乳、果皮及种皮的发育规律,以桂林海洋山一带的开花毛竹为材料,采集并固定不同时期的开花毛竹种子,使用石蜡制片法制片,显微镜观察胚、胚乳、果皮与种皮的结构变化。结果表明：(1)毛竹花后1 d完成受精并形成合子,合子休眠时长约为5 d。经过原胚阶段、胚芽鞘阶段、幼胚生长阶段及成熟胚阶段,花后40 d的胚发育基本成熟,其发育类型为禾本型。(2)胚乳发育早于胚的发育,其发育类型为核型胚乳,历经游离核、细胞化、细胞分化及成熟4个阶段。在细胞分化阶段胚乳细胞分化形成淀粉胚乳细胞以及糊粉层细胞,淀粉胚乳细胞主要积累淀粉粒,糊粉层细胞主要积累矿质元素、脂类及蛋白质等。(3)花后1 d的果皮细胞及珠被细胞形状规则、内含物丰富、结构完整;花后10～20 d,内、外果皮及珠被细胞层数递减,形状发生改变,中果皮细胞开始出现淀粉粒;花后20～60 d,随着胚乳细胞营养物质的积累及体积的增大,向外产生机械压力,中果皮细胞逐步消解仅剩残留的细胞壁;外果皮细胞呈长条形,细胞壁加厚,与残留的中果皮细胞壁组成保护结构;皮层在种子发育过程中主要起到合成...     

一个水稻显性高秆突变体的遗传分析和基因定位

从水稻(Oryza sativa L.)的两个半矮秆籼稻品种6442S-7和蜀恢881杂交F2代群体中发现一个高秆突变体D111,其株高和秆长分别比亲本蜀恢881增加63.0%和87.0%。用205个微卫星标记分析D111及其原始亲本6442S-7和蜀恢881之间的基因组DNA多态性,结果未发现D111具有2个原始亲本都没有的新带型,证明D111的确是6442S-7和蜀恢881的杂交后代发生基因突变产生的。将D111分别与蜀恢881、蜀恢527、明恢63、9311、IR68、G46B等6个半矮秆品种和高秆对照品种南京6号杂交,分析F1和F2代株高的遗传行为,结果表明D111的高秆性状由一对显性基因控制,且该基因与南京6号的高秆基因紧密连锁或等位。以蜀恢527/D111 F2群体为定位群体,运用微卫星标记将D111显性高秆突变基因定位于水稻第一染色体长臂,与RM212、RM302和RM472的遗传距离分别是27.7 cM、25.5 cM和6.0 cM,该基因暂命名为LC(t)。认为D111是首例从半矮秆品种自然突变产生的水稻显性高秆突变体,LC(t)为首次定位的水稻显性高秆突变基因。此外,将上述基因定位结果与Causse等(1994)和Temnykh等(2000; 2001)发表的水稻分子连锁图谱进行比较,发现LC(t)基因恰巧位于与水稻“绿色革命基因”sd1相同或十分相近的染色体区域,因此,还就LC(t)基因与sd1基因之间的可能关系进行了讨论。     

小麦种子成熟和萌发过程中的假萌发素活性

用SDS-PAGE方法研究了假萌发素(ψG)在小麦种子成熟和萌发过程中活性的变化.结果表明:在种子成熟过程中只有ψG表达,扬花后10 d,在颖壳、内外桴、种皮和果皮中皆可检测到ψG的草酸氧化酶活性,随着发育进程的推进,ψG的活性增大.在种子萌发过程中,在小麦品种中育5号的维管束过渡区中除了萌发素G和G'外,还可检测到ψG的草酸氧化酶活性.由于ψG在种子成熟过程中主要存在于颖壳、内外桴、果皮及种皮这些保护组织中,且开始大量表达的时间正是生长接近停止时,于是推测ψG很可能通过降解草酸产生H2O2而推动这些组织细胞壁的木质化.     

Genetic Analysis and Histological Study of Red Seed in Rice

Reciprocal crosses between red and achromatic rice revealed that the seed color of F₁ was determined by its female parent. According to the seed color and plant segregation ratio of F₁, F₂, and F₃ generations, the red phenotype of red double-haploid seed was determined by a dominant, monogene with maternal effect. Histological study showed that the red pigments accumulated in the pericarp layer only. The assay of developmental timing of pigment accumulation showed that the red color accumulated from desiccation stage to perfectly maturation stage of the seeds.     

Identification of a characteristic antioxidant,anthrasesamone F,in black sesame seeds and its accumulation at different seed developmental stages

Assay-guided fractionation of the methanol extract from black seeds of sesame (Sesamum indicum L.) led to the isolation of an active compound that had a 1,1-diphenyl-2-picrylhydrazyl radical scavenging activity. This antioxidant was confirmed to be anthrasesamone F, an anthraquinone derivative previously isolated from different black sesame seeds and biogenetically related to other anthrasesamones in sesame roots. The radical scavenging assay showed that anthrasesamone F had more potent activity than Trolox. The content of anthrasesamone F in different parts and at different developmental stages of black sesame seeds was investigated to clarify the accumulation pattern of this antioxidant in the black seeds. Anthrasesamone F was localized in the seed coat of black seeds and accumulated after the seed coat color changed to black. The content of anthrasesamone F increased gradually with seed maturation and drastically on air-drying, the final stage in sesame cultivation.     

红白花斑种皮高油酸花生种质材料的创制

本研究利用粉色种皮高油酸花生G63与紫白花斑种皮普通油酸花生VG-01配置杂交组合。利用等位基因特异性扩增(AS-PCR,allele-specific PCR)鉴定出16个F_1真杂种。在F_2中筛选到_ol1_ol_2单株,并对64个F_2:3家系间的种皮色泽分离进行χ~2检测。结果表明,纯色花生∶花斑花生在0.05水平上符合9∶7,花生种皮花斑性状由2对互补基因控制,当2对基因同时处于显性时,种皮表现为纯色;当2对基因至少有1对为隐性纯合时,种皮表现为花斑。利用AS-PCR技术对334株花斑种皮F_3单株进行基因型鉴定,筛选到29株ol_1ol_1ol_2ol_2基因型的单株。利用气相色谱测定结果表明,F4种子油酸GC值介于70.77%~82.87%,油酸/亚油酸介于8.15~26.30。F4群体植株主茎高12.4~87.3 cm,平均57.2 cm,较对照冀花2号增高34.97%;第1对侧枝长91.6~196.3 cm,平均134.1 cm,较对照冀花2号增长34.28%。F5新种质的单株果重、单株果数、单株仁重、单株仁数分别为(27.16±9.51)g、(22.11±10.26)个、(20.10±7.17)g和(31.94±15.16)个。新种质9-7、14-2、14-3、17-3和17-7均为红白花斑种皮,在单株果重方面较对照冀花2号增加230.02%、165.80%、210.66%、200.65%和160.26%,在单株果数方面增加280.00%、340.00%、450.00%、210.00%和150.00%,其油酸GC值分别为80.54%、81.75%、80.63%、81.3%和81.56%。该批种质材料不仅油酸含量高,而且具有医疗保健价值,对丰富我国高油酸花生遗传多样性具有重要的现实意义。     

白色种皮花生皮色及农艺性状遗传的研究

为育成白色种皮的高产花生品种,了解白色种皮的遗传规律,用自育的白皮1号品种与在福建省生产上推广的红皮良种粤油116、汕油对和泉花10号进行杂交,杂种F1植株的种皮全为红色．F2红皮植株与白皮植株的分离比例符合15:1的分离规律,红皮F2代的F3代株系中,有4/15株系符合红：白为3:1的分离比例。由此推断白皮性状是两对隐性基因控制,白皮性状与产量性状没有连锁。主要农艺性状的遗传力顺序为：单株结果数＞单株饱果重和生物产量＞单株饱果数。经F3代、F4和F5代的株系鉴定,选出稳定、综合性状优良的重组类型;再经过产量鉴定和多点比较试验,选出了丰产性较好的二个品种参加福建省花生新品种区域试验．     

杂交兰花色花香生物合成途径的转录组分析

该研究以杂交兰(Cymbidium hybrid)不同花色花香品种‘玉凤’(K18,黄色)和‘福韵丹霞’(K24,紫红色)为材料,采用RNA-Seq技术获得杂交兰不同花期的花朵转录组数据,分析杂交兰不同时期花色/花香相关基因的表达变化,探讨杂交兰花色花香形成的分子机理,为杂交的定向改良和新品种选育提供依据.结果表明:(...     

红花桉种子繁殖研究

对红花桉 ( Eucalyptusficifolia.F.Muell.)的种子发芽与育苗技术进行了研究。结果表明 ,种子为黑色类型的发芽势最高 ,为 4 8% ;发芽率为 75% ,种子的质量最好。播种时间最好在 4～ 5月份 ;播种采用种子基部直立向下插入基质中 ,然后覆盖土 0 .5cm的方法可提高出苗率。它生长最快的时间是在 7～ 8月份。培育红花桉最好的基质配方是 :腐叶土∶砂∶红土∶滇池草炭 =1∶ 1∶ 1∶ 1。     

BANYULS, a novel negative regulator of flavonoid biosynthesis in the Arabidopsis seed coat

A mutant of Arabidopsis that accumulates a high level of red pigments within the seed coat has been isolated from a population of T-DNA-transformed plants. Genetic analysis revealed that the mutation is recessive and affects maternal seed tissues only. Due to the color of the immature seeds, this mutation was named banyuls ( ban ). Pigments accumulated continuously from early seed development to the desiccation stage in the seed coat of the mutant. The phenotype of the double mutant banyuls/transparent testa confirmed the flavonoid nature of the pigments and enabled assignment of the regulatory TT ( Transparent Testa ) genes to two groups according to their epistatic relationship to ban . The flavonoid content of germinated ban and wild-type seedlings was similar. Plants harbouring the ban mutation had a normal formation of trichomes and root hairs and were not affected in their responses to light. The seeds of ban plants exhibited reduced germination compared to wild-type which may be a direct consequence of the high level of pigments. These results suggest that BANYULS functions as a negative regulator of flavonoid biosynthesis that prevents accumulation of pigments in the seed coat during early embryogenesis in Arabidopsis .     

The inheritance of seed color in a resynthesizedBrassica napus line No. 2127-17 including a new epistatic locus

Yellow seed is an important trait inBrassica napus. To know the genet ic basis of yellow seed color inBrassica napus, we carried out genetic studies by using conventional genetics analyses. The conventional genetics was studied in generations (F1 F2 reciprocal F2, BC1, and F23) ofB. napus derived from crosses between a yellow-seeded (No. 2127-17) and nine different black-seeded parents. The results indicated that seed color was mainly controlled by the maternal genotype but influenced by the interact ion between the maternal and endosperm and/or embryonic genotypes. In the combinations which included black-seeded lines SW0780, 94560, 94545 and 1141B, the yellow seed is partially dominant over black with two or three dominance epistasis ratio. A dominant yellow-seeded gene Y which exhibits epistatic effects on the two independent dominant black-seeded genes B and C was ident ified in DH line No. 2127-17. These observations are in agreement with our previous reports. But in the rests, including the crosses with HS No.4, HS No. 3, XY No. 15, 94570 and ZS No. 10, the black seed color was dominant over yellow seed color. The inheritance of this trait in the segregating populations fits the model of a digenic dominance epistasis or triplicate dominance epistasis. A new locus was identified and designated as D: the dominant gene D for black seed color inhibits the dominant gene Y. Therefore, in combination with the Y, B and C, we found that the seed color was influenced by at least four genes. Identifying seed color genes and defining their inheritance should further our understanding of yellow seed color trait and facilitate development of new and better yellow-seeded cult ivars ofBrassics napus.     

Genetic control of white flower color in scarlet rosemallow (Hibiscus coccineus Walter)

Scarlet rosemallow (Hibiscus coccineus Walter) is a diploid, perennial, erect, and woody shrub. The species is a desirable inclusion in home landscapes because it is a native plant with attractive flowers and unusual foliage. The objective of these experiments was to determine the number of loci, number of alleles, and gene action controlling flower color (red vs. white) in scarlet rosemallow. Three white-flowered and 1 red-flowered parental lines were used to create S(1) and F(1) populations, which were self-pollinated or backcrossed to generate S(2), F(2), and BC(1) populations. Evaluation of these generations showed that flower color in these populations was controlled by a single diallelic locus with red flower color completely dominant to white. I propose that this locus be named "white flower" with alleles W and w.