松毛虫DpKettin基因片段的克隆与初步定位研究

对于ZW型鳞翅目昆虫, 雄性为ZZ, 雌性为ZW; 细胞内Z染色体数与常染色体组数之比在雌雄间存在差异, 雄性为2Z∶2A=1.0, 雌性为Z∶2A=0.5, 如果某物种一个基因(假如K基因)位于Z染色体上, 另一个基因(假如N基因)位于常染色体上, 则雄体中2K∶2N=1.0, 雌体中K∶2N=0.5。研究利用家蚕、棉铃虫等昆虫Kettin基因序列, 克隆了松毛虫的同源基因(DpKettin)片段, 并采用荧光定量PCR技术, 以松毛虫的ANT基因为参照基因, 检测松毛虫雌雄不同个体间DpKettin基因与腺苷酸转移酶基因(ANT)的拷贝数之比, 结果表明: 雄体DpKettin∶ANT=1.0, 雌体DpKettin∶ANT=0.5, 说明DpKettin基因位于松毛虫Z染色体上。     

棉铃虫性染色体两种分子标记的克隆及序列分析

为了建立棉铃虫Helicoverpa armigera性染色体的特异性分子标记,利用RAPD-PCR技术对雌雄棉铃虫基因组DNA进行筛选,从500种随机引物中筛选到1 条引物（Operon编号为AF-18）,可扩增出1条约450 bp 的雌性特异片段。经克隆测序并合成特异引物进行验证,表明该片段为棉铃虫雌性特异分子标记,位于W染色体上。利用家蚕、果蝇等昆虫Kettin基因序列,克隆了棉铃虫的同源基因HaKettin片段,并采用荧光定量PCR技术,以棉铃虫的DH-PBAN基因为参照基因,检测棉铃虫雌雄不同个体间HaKettin基因与DH-PBAN基因的拷贝数之比,结果表明：雄体HaKettin∶DH-PBAN=1.0,雌体HaKettin∶DH-PBAN=0.5,据此推断HaKettin基因位于棉铃虫Z染色体上。     

一种新的家蚕体形突变体——短体蚕（Sq）的遗传分析与基因定位

作为重要经济昆虫和鳞翅目昆虫模式的家蚕Bombyx mori,其突变体是生理学、遗传学、功能基因组学等研究的宝贵资源。作者在家蚕资源保存和遗传分析中发现一种新的体形突变体——短体蚕（Squab,Sq）,其特征是：杂合体（Sq /+）成活,蚕体长只有正常型的约4/5,腹中部略肥大,胸部稍狭小;纯合体（Sq / Sq）胚胎期致死。遗传分析结果表明该突变为显性遗传。通过与各染色体标记基因进行连锁分析,发现突变基因Sq在家蚕第14染色体上;通过与同一染色体上的标记基因青熟油蚕基因（oa）、不洁蚕基因（Di）进行三点测验,将Sq定位在家蚕连锁图谱第14连锁群的34.6 cM位点,表示为Sq（14-34.6）。本研究结果为深入研究和利用该突变体奠定了重要基础。     

家蚕血细胞特异表达新基因Bm04862的鉴定及表达

通过家蚕组织芯片数据筛选得到家蚕血细胞特异表达基因Bm04862,并首次对该基因进行了克隆与鉴定。应用RACE技术获得该基因全长,并对其进行生物信息学分析。Bm4862基因开放阅读框819 bp,共编码273个氨基酸残基,预测其为跨膜蛋白;通过q RT-PCR技术对其时空表达情况进行分析;结果显示Bm04862基因在家蚕血细胞中特异高表达,并在4龄眠期和预蛹2 d时达到表达高峰;构建Bm04862真核表达载体,转染Sf9细胞分析其蛋白的亚细胞定位情况,结果表明其定位于细胞核膜和部分细胞质中。此外,用大肠杆菌刺激蚕体24 h后,Bm04862基因表达水平显著上调,表明大肠杆菌可以诱导该基因的表达,由此推测该基因可能参与家蚕的免疫应答。这为深入研究该基因在家蚕免疫反应中的功能提供了参考。     

荧光定量PCR检测家蚕核型多角体病毒在其宿主体内的增殖动态

为了研究家蚕核型多角体病毒(Bombyx mori nuclear polyhedrosis virus,BmNPV)在其宿主幼虫体内不同组织中的增殖动态,对敏感性家蚕品种306幼虫进行经口定量滴注病毒。在接种后9个时间点,对中肠、血淋巴和脂肪体进行取样。以BmNPV DNA 聚合酶基因(dnapol)指示病毒拷贝数,同时以家蚕细胞质肌动蛋白A3(actin A3)基因作为参比基因,用荧光定量PCR的方法分别检测各个时间点的中肠、血淋巴和脂肪体中病毒的拷贝数。结果表明经口感染2 h,病毒进入中肠;12 h,病毒已经到达血淋巴和脂肪体;再经过约12 h的潜伏期,病毒在各组织中开始快速增殖,到84 h各组织中病毒增殖达到平台期。     

家蚕Z染色体遗传图谱的构建及W染色体特异性标记的鉴定

家蚕的雌性为异配性别(ZW),雄性为同配性别(ZZ),这种性别决定机制在鳞翅目昆虫中是普遍存在的。尽管雌家蚕是由W染色体决定的,但还没有发现控制雌家蚕形态学特点的基因位于W染色体上。目前已知控制家蚕多种表型和重要经济性状的基因位于Z染色体上,但这也仅仅是了解了Z染色体DNA分子信息的2%。印度的科学家迄今为止的研究表明雄家蚕Z染色体没有剂量补偿效应。他们利用回交作图群体和RAPD、SSR、FISSR标记,以od隐性基因位点为锚定位点标记,构建了含有16个遗传标记总距离为334.5cM的家蚕Z染色体连锁图谱;该距离表明这些标记遍布在Z…     

家蚕性连锁平衡致死系致死基因的SSR定位

家蚕性连锁平衡致死系(S-14)雄蚕的两条Z染色体分别携带有一个非等位、紧密连锁的隐性胚胎期致死基因l1(lethal gene1)和l2(lethal gene2)。两个致死基因的致死时期分别是转青期和G2期。将S-14品系的雄蚕和家蚕P50品系的野生型雌蚕杂交,F1代雄蚕和P50品系雌蚕回交,即P50×(P50×S14)。回交后代雌蛾根据父本(F1代雄蚕)携带l1或l2基因分成两类BC1-l1和BC1-l2,分别用来做l1和l2基因定位。利用公布的家蚕全基因组序列筛选l1基因和l2基因所在Z染色体与P50品系Z染色体间的差异SSR标记,分别获得16个和18个差异性SSR标记,用差异性标记检测BC1-l1和BC1-l2,最终将l1基因定位在Z染色体物理图谱中的19.79Mb位点到染色体末端约2.60Mb范围内,将l2基因定位在Z染色体物理图谱的17.86Mb位点到18.55Mb位点约0.69Mb范围内。     

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.     

家蚕保存系统红色卵的遗传分析

用遗传背景清楚的家蚕Bombyx mori红卵（re）、白卵(w-2、pe)、第4褐卵（b-4）的标志基因系统和正常型黑卵系统与我国家蚕基因库保存的20个红色卵系统杂交,进行顺反测验,分析了它们的卵色支配基因及遗传规律。结果发现：①在03-310系统中存在家蚕卵色新突变pink egg,与红卵re 等位,基因符号为re^p,表型特征为：卵淡红色,成虫蛾眼也为淡红色;②6个系统为红卵（re）的纯合系统,还有５个系统除具有re／re基因型外,还具有支配白色卵或浅红色或橙红色卵的突变基因;③２个系统为第4褐卵（b4）的纯合系统; ④6个系统的红褐色卵为母性影响遗传;⑤发现家蚕卵色基因b-4和r-e的互补关系,b-4/b-4 re/re基因型表现为新的卵色——橙黄色。     

不同启动子驱动下马铃薯蛋白酶抑制剂PinⅡ转基因水稻的遗传、表达和对粘虫抗性分析

以不同启动子驱动的马铃薯蛋白酶抑制剂Ⅱ基因(PinⅡ-2x ,PinⅡ-4x)转基因水稻为材料,经潮霉素抗性、PCR和Southern blot等检测对转基因水稻后代进行了遗传分析。结果显示：外源基因在68.4%的转基因植株中符合孟德尔遗传模式,单拷贝植株率为63.6%。转基因植株后代的PinⅡ蛋白活性测定结果表明：ActI和Ubi驱动的PinⅡ-2x转基因水稻植株中,每克鲜叶片的PinⅡ蛋白含量为160μg和176μg,而由PIN5′驱动的PinⅡ-4x为104μg,对照水稻仅为20μg。ActI和Ubi驱动的PinⅡ表达产物对胰蛋白酶活性抑制程度分别达到37.7%和43.1%,明显高于PinⅡ自身启动子PIN5′（29.2%）。叶片饲养粘虫幼虫的实验表明：转基因植株叶片对粘虫有抗性,但抗性达不到显著水平,且启动子效率、PinⅡ表达量与抗粘虫      

Dosage analysis of Z chromosome genes using microarray in silkworm,Bombyx mori

In many organisms, dosage compensation is needed to equalize sex-chromosome gene expression in males and females. Several genes on silkworm Z chromosome were previously detected to show a higher expression level in males and lacked dosage compensation. Whether silkworm lacks global dosage compensation still remains poorly known. Here, we analyzed male:female (M:F) ratios of expression of chromosome-wide Z-linked genes in the silkworm using microarray data. The expression levels of genes on Z chromosome in each tissue were significantly higher in males compared to females, which indicates no global dosage compensation in silkworm. Interestingly, we also found some genes with no bias (M:F ratio: 0.8–1.2) on the Z chromosome. Comparison of male-biased (M:F ratio more than 1.5) and unbiased genes indicated that the two sets of the genes have functional differences. Analysis of gene expression by sex showed that M:F ratios were, to some extent, associated with their expression levels. These results provide useful clues to further understanding roles of dosage of Z chromosome and some Z-linked sexual differences in silkworms.     

Novel non-autonomous transposable elements on W chromosome of the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis>

The sex chromosomes of the silkworm Bombyx mori are designated ZW(XY) for females and ZZ (XX) for males. Numerous long terminal repeat (LTR) and non-LTR retrotransposons, retroposons and DNA transposons have accumulated as strata on the W chromosome. However, there are nucleotide sequences that do not show the characteristics of typical transposable elements on the W chromosome. To analyse these uncharacterized nucleotide sequences on the W chromosome, we used whole-genome shotgun (WGS) data and assembled data that was obtained using male genome DNA. Through these analyses, we found that almost all of these uncharacterized sequences were non-autonomous transposable elements that do not fit into the conventional classification. It is notable that some of these transposable elements contained the Bombyx short interspersed element (Bm1) sequences in the elements. We designated them as secondary-Bm1 transposable elements (SBTEs). Because putative ancestral SBTE nucleotide sequences without Bm1 do not occur in the WGS data, we suggest that the Bm1 sequences of SBTEs are not carried on each element merely as a package but are components of each element. Therefore, we confirmed that SBTEs should be classified as a new group of transposable elements.     

Duplicated plastid and triplicated cytosolic isozymes of triosephosphate isomerase in maize (Zea mays L.)

We studied electrophoretic variation and inheritance of triosephosphate isomerase (TPI) isozymes in maize (Zea mays L.). In contrast to most diploid plants, in maize, TPI exists as multiple isozymes in both the plastid and cytosolic subcellular compartments. Phenotypes result from the overlay of two independent sets of isozymes and allozymes, representing the plastid (encoded by the nuclear genes Tpi1 and Tpi2) and cytosolic (encoded by Tpi3, Tpi4, and Tpi5) systems. All possible intragenic and intergenic dimeric enzymes are formed between polypeptides within each subcellular compartment. No heterodimers are formed between plastid and cytosolic polypeptides. Extensive surveys of accessions of land races and inbred lines revealed 22 allelic variants for the five loci. Most alleles have been formally validated by segregation analysis. We describe two null alleles at Tpi4, distinguished by their relative abilities to form intergenic heterodimers with polypeptides specified by Tpi3 and Tpi5. Linkage analyses and crosses with B-A translocation stocks were effective in determining the chromosome locations of all five loci. Duplicated genes for both the plastid and cytosolic isozymes were localized to genomic regions that possess numerous other redundant sequences. We placed Tpi1 on the long arm of chromosome 7, approximately 23 centimorgans (cM) distal to g11; we localized its duplicate--Tpi2--17 cM distal to v4 on the long arm of chromosome 2. The triplicate loci encoding cytosolic TPIs reside on chromosomes 3 and 8. Tpi4 is approximately equidistant (11 cM) from d1 and Lg3, near the centromere of chromosome 3. Tpi3 and Tpi5 are located on distal ends of the most poorly marked maize chromosome; Tpi3 is 29 cM distal to Idh 1 on 8L, and Tpi5 is on 8S or near the centromere on 8L. In contrast to most duplicated maize sequences, which often occur in parallel linkages on different chromosomes, Tpi3 and Tpi5 provide an example of intrachromosomal gene duplication. Several of the Tpi loci are located in sparsely mapped regions of the genome, and Tpi1 is the first isozyme marker for chromosome 7.     

On the prospects of using balanced sex-linked lethals for insect pest control

Summary A new method is suggested for controlling species of insect pests in which the female is heterogametic. This method, involving the use of balanced lethals on the Z chromosome, causes the death of females in the embryonic stage. The method has already been tested in practical sericulture for the production of entirely male progeny of the silkworm. The method requires the construction of two strains of the pest, one carrying two balanced nonallelic but closely located lethals on the Z chromosome, and another with two other pairs of lethals of the same type. In the hybrid progeny from the crosses between the two strains, 100% of the female embryos would die, thus making it possible to release only males without any laborious procedure for sex discrimination. In the progeny from the crosses between the released males and females from the natural population, again 100% of females would die, but the males would survive and when they mated — 62.5% of the female progeny would die. This rate would decline to 34.4 and 16.6% in the sons and grandsons respectively. The repeated release of hybrid males would lead to a progressive increase, with each successive generation, in the percentage of female mortality in the natural population until its total extinction.     

Postintegration stability of the silkworm piggyBac transposon

The piggyBac transposon is the most widely used vector for generating transgenic silkworms. The silkworm genome contains multiple piggyBac-like sequences that might influence the genetic stability of transgenic lines. To investigate the postintegration stability of piggyBac in silkworms, we used random insertion of the piggyBac [3 × p3 EGFP afm] vector to generate a W chromosome-linked transgenic silkworm, named W-T. Results of Southern blot and inverse PCR revealed the insertion of a single copy in the W chromosome of W-T at a standard TTAA insertion site. Investigation of 11 successive generations showed that all W-T females were EGFP positive and all males were EGFP negative; PCR revealed that the insertion site was unchanged in W-T offspring. These results suggested that endogenous piggyBac-like elements did not affect the stability of piggyBac inserted into the silkworm genome.