Identification and expression analysis of 11 MADS-box genes in peach (Prunus persica var. nectarina ‘Luxing’)

MADS-box genes play a central role in the development of flowers in plants. In this study, 11 PpMADSs were isolated from ‘Luxing’ peach, and the expression levels were detected in different tissues and fruit development. Eleven PpMADSs, designated as PpMADS13, 14, 18, 23, 24, 25, 32, 33, 34, 35, and 39 were isolated. Phylogenetic analysis revealed that PpMADS13, 14, and 18 belonged to SVP, AGL15, and MIKC* group respectively; PpMADS23, 24, 25, and 39 were in the Mα group; PpMADS32, 33, 34, and 35 belonged to the Mγ group. Predictions from subcellular localization showed that 10 PpMADS were located in the nucleus. RT-PCR revealed that PpMADS13 was expressed in stems, leaves, and during fruit development (70d); PpMADS14 was expressed in sepals, stamens, petals, and during flower development; PpMADS18 was expressed in roots, stems, leaves, sepals, ovaries, stamens, petals, and during flower and fruit development; all MADS-box genes (expect for PpMADS33) in the Mα and Mγ group were expressed in roots, stems, leaves, sepals, ovaries, stamens, petals, and during flower development; few genes were expressed during fruit development. These results indicated that PpMADS may play a crucial regulatory role in vegetative growth and development processes of flowers and fruits in peaches.     

茶树小分子量热激蛋白基因CsHSP17.2的克隆与表达分析

[目的]进一步了解茶树小分子量热激蛋白基因CsHSP17.2在逆境胁迫条件下的分子生物学功能.[方法]利用RT-PCR技术从茶树‘迎霜’中克隆得到CsHSP1 7.2基因,运用生物信息学软件分析其核苷酸和编码蛋白,通过Real-timePCR分析其表达模式.[结果]该基因开放阅读框长度为453 bp,编码150个氨基酸,蛋白质相对分子质量为17.2×10a,理论等电点5.56;无信号肽位点,属于非分泌型蛋白;被定位于细胞质中.系统发育树分析表明,茶树CsHSP1 7.2与水稻(GenBank登录号:P27777)和花生(ABC41131)的进化关系较近,属于小分子量热激蛋白基因家族第Ⅰ亚族.qRT-PCR分析发现,茶树CsHSP17.2属于组成型基因;高温(38℃)处理1h能显著提高CsHSP17.2 mRNA的相对表达量(P＜0.05);干旱(100 g·L-1 PEG 6000)、高盐(200 mmol· L-1 NaCl)和外源脱落酸(200 mg· L-1 ABA)处理条件下,该基因的转录水平均出现不同程度的上调.[结论]克隆得到茶树‘迎霜’小分子量热激蛋白基因CsHSP17.2,其在花中表达量最高,且响应高温、干旱、高盐和外源脱落酸胁迫.     

芹菜水孔蛋白基因AgPIP2;1的克隆及其对非生物胁迫的响应

为了研究芹菜质膜内在蛋白基因的序列特征及其在非生物胁迫条件下的表达特性,探讨其抗逆功能,以芹菜品种六合黄心芹为试验材料,通过RT-PCR技术克隆AgPIP2;1基因,通过生物信息学软件分析其核苷酸和氨基酸序列特征,并采用荧光定量PCR技术检测其在不同组织的表达及其对非生物胁迫的响应。结果表明,AgPIP2;1基因含有1个861 bp的开放阅读框,编码286个氨基酸,其编码的蛋白属于PIP2类蛋白。氨基酸序列分析显示,AgPIP2;1含有高度保守的NPA基序以及高等植物PIP蛋白的保守序列,与其他物种PIP2类蛋白具有较高的同源性,与胡萝卜DcPIP2;1的氨基酸序列同源性达到97.90%。在亲缘关系上与大豆GmPIP2;1、胡萝卜DcPIP2;1和绿豆VrPIP2;1较为接近。实时荧光定量PCR技术分析表明,AgPIP2;1基因在芹菜根、叶柄和叶片中均有表达,其中在叶片中的表达量最高,在根中的表达量最低,呈现比较明显的组织特异性。此外,AgPIP2;1基因受到高温、低温、干旱和盐等非生物胁迫的诱导,说明该基因可能参与芹菜抵御非生物胁迫的过程。本研究为进一步了解AgPIP2;1基因的功能及其在非生物胁迫中的作用奠定了基础。     

猪hnRNPUL1基因克隆及变异剪接体鉴定

旨在克隆民猪hnRNPUL1基因全长编码区（complete coding sequence，CDS）序列并进行可变剪接分析，研究其组织表达和亚细胞定位情况。本研究以3头3月龄民猪为试验材料，利用RT-PCR技术克隆hnRNPUL1基因CDS及可变剪接体，应用qRT-PCR检测其在心、肝、脾、肺、肾、胃、大肠、小肠、背肌、腿肌等组织中的表达情况，同时，在生物信息学预测的基础上，通过融合表达绿色荧光蛋白的方法鉴定核定位序列。研究结果表明，猪hnRNPUL1基因（GenBank accession No.：MN399154）CDS全长2 580 bp，预期编码的多肽链存在着hnRNPs家族的特征性结构域——SAP、SPRY和AAA；猪hnRNPUL1普遍表达于所检测的各组织中，其中在脾脏中表达量最高，在腿肌中表达量最低；核定位序列（NLS）位于多肽链的133~430 aa处，与生物学信息学预测的结果存在着偏差；同时获得了2个变异剪接体和11种可变剪接片段。本研究结果对进一步揭示猪hnRNPUL1基因功能及转录调控机制提供了基础。     

Somatic embryogenesis and regeneration of five multipurpose cassava landraces extensively integrated in African cropping system

Successful development and adoption of transgenic cassava (Manihot esculenta Crantz) varieties in Africa depend on in vitro regeneration of landraces because of their agronomic value and amenability to genetic modification. The study investigated somatic embryogenesis from axillary bud and immature leaf-lobe explant and regeneration via shoot organogenesis in five cassava landraces. Landraces exhibited significant (P < 0.05) differences in frequencies of primary somatic embryo production, number of embryos per explant, and frequency of secondary embryos. The frequency of primary somatic embryogenesis ranged from 7.8 to 14.5%, whereas the number of embryos per explant varied from 5.3 to 10.6. However, only frequency of primary somatic embryos and number of embryos per explant showed significant (P < 0.05) differences when immature leaf lobe was used as explant. The frequency of primary somatic embryogenesis ranged from 42.7 to 49.2%, whereas number of embryos per immature leaf-lobe explant varied from 9.5 to 15.2 per explant. Secondary embryogenesis was cultivar-independent in the case of immature leaf-lobe explant. Cyclic and green (mature) embryogenesis showed no significant (P < 0.05) landrace differences in both axillary bud and immature leaf-lobe explants. Shoot regeneration from cotyledon of somatic embryos had significant (P < 0.05) landrace differences. The mean shoot-bud formation frequency of axillary bud and immature leaf-lobe explants was 51.4% and 37.2%, respectively. Root formation was efficient, with greater than 70% of shoots forming root in all landraces. Similarly, landrace differences were detected for the survival of acclimatized regenerated plants, with a mean of 94.7% for both explants. In conclusion, somatic embryos were produced from immature leaf and axillary bud explants of the landraces and the embryos were converted to plantlets via shoot organogenesis.     

奶山羊CIDEa基因的克隆、序列分析与组织表达

为获得奶山羊CIDEa基因序列并检测其在乳腺组织中的表达,采用RT-PCR技术从奶山羊乳腺组织扩增CIDEa基因序列,利用生物信息学软件对其进行预测分析,并采用荧光定量PCR检测CIDEa在干奶期和不同泌乳时期乳腺组织中的表达。结果表明:通过克隆测序得到奶山羊CIDEa基因CDS区660 bp,编码219个氨基酸,与GenBank公布的绵羊、牛、人和猪的核苷酸序列同源性分别为99%、96%、85%、85%。奶山羊CIDEa蛋白属于碱性、不稳定亲水蛋白,不存在跨膜结构和信号肽;蛋白主要定位在细胞质、线粒体和细胞核。CIDEa蛋白结构主要由α螺旋、β折叠和不规则卷曲组成。奶山羊CIDEa在泌乳前期、盛期和中期乳腺组织中表达量均显著高于干奶期(P<0.05)。说明CIDEa可能参与奶山羊乳腺的泌乳过程,为进一步研究其在奶山羊乳腺组织中的功能及对乳品质的调控作用奠定基础。     

月季bHLH基因的克隆、表达及其与MYB和WD40的互作分析

以月季‘月月红’(Rosa chinensis‘Slater’s Crimson China’)花瓣为材料,利用同源克隆法鉴定到1个Rcb HLH基因的c DNA全长序列,并研究了其生物信息学特征、组织特异性表达及其与MYB和WD40的互作关系。序列分析表明,Rcb HLH的开放阅读框长2 112 bp,编码703个氨基酸,基因登录号为KY783912。结构域序列分析显示,Rcb HLH为一个保守的N端含有碱性氨基酸的DNA结合区、C端含有α螺旋–环–α螺旋的b HLH蛋白。对Rcb HLH进行系统进化分析发现,Rcb HLH与草莓及其他蔷薇科植物的b HLH蛋白具有较高的同源性。组织特异性实时定量RT-PCR分析揭示Rcb HLH基因主要在花瓣中表达。酵母双杂交结果显示,Rcb HLH能与Pav MYB和Pav WD40相互作用形成MYB-b HLH-WD40复合物。以上结果为进一步研究Rcb HLH的功能鉴定奠定了基础。