甘薯盐胁迫响应基因IbMYB3的表达特征及生物信息学分析

MYB转录因子具有多种生物学功能,在植物响应生物和非生物胁迫中发挥重要作用。该文从盐胁迫后的甘薯(Ipomoea batatas)水培苗转录组数据(RNA-seq)中筛选出2个受盐胁迫显著上调表达的MYB基因,分别命名为IbMYB3和IbMYB4。多种非生物胁迫和植物生长物质处理下的基因表达分析显示,IbMYB3受逆境诱导显著上调表达,暗示其可能参与甘薯非生物胁迫响应。生物信息学分析表明,IbMYB3开放阅读框长度为1059 bp,编码353个氨基酸残基,蛋白分子量为39.41 kDa,理论等电点(PI)为5.26,为酸性带负电的亲水性蛋白。亚细胞定位结果表明,IbMYB3蛋白定位于细胞核,具有较强的转录激活活性。上述结果表明,IbMYB3转录因子可能在甘薯非生物胁迫响应过程中发挥重要调控作用,研究结果为进一步探明IbMYB3基因的功能奠定了基础。     

Biochemical and molecular analysis of a temperature-sensitive albino mutant in kale named “White Dove”

“White Dove” is a mutant in kale (Brassica oleracea var. acephala f. tricolor), which exhibits a mutant albino phenotype in the interior of the plant under low temperature conditions. Chlorophyll content in “White Dove” was dramatically reduced under low temperature conditions, while the content in “Green Dove” decreased slightly under the same conditions. The levels of five chlorophyll precursors suggested that chlorophyll biosynthesis in white kale was inhibited by low temperature stress at the step of Pchlide. However, Mg-Proto IX was not inhibited in white kale grown under low temperature conditions. The results of quantitative RT-PCR illustrated that the chlorophyll biosynthetic genes in the white cultivar were dramatically down-regulated by low temperature stress from the step of POR, while CISC and DBB1B in the white cultivar were dramatically induced under low temperature conditions. The results of transmission electron microscopy analysis showed that there were normal chloroplasts in the young leaves of white kale grown at 20 °C, whereas proplastids were observed in white kale grown at 5 °C. These results strongly suggested that low-temperature stress significantly inhibited plastid development in the young leaves of white kale, and repressed chlorophyll biosynthesis at the step of Pchlide by down-regulating the expression of downstream chlorophyll biosynthetic genes, resulting in undifferentiated proplastids and the albino phenotype observed in young leaves. Several genes associated with chlorophyll accumulation were also affected by low temperature conditions in white kale, especially CISC and DBB1B.     

The abiotic stress-responsive NAC transcription factor SlNAC11 is involved in drought and salt response in tomato (<Emphasis Type="Italic">Solanum lycopersicum</Emphasis> L.)

Efficient and genotype-independent in vitro regeneration is an essential prerequisite for incremental trait improvement in peanut (Arachis hypogaea L.) via genetic transformation. We have optimized a facile and rapid method to obtain direct shoot organogenesis from cotyledonary node (CN) explants excised from peanut seedlings germinated on cytokinin-supplemented Murashige and Skoog (MS) basal salt medium. Starting with mature embryos, shoot induction occurred in approximately 7 weeks, followed by 4 weeks for rooting of excised shoots and 3 weeks of acclimatization of regenerated plantlets in soil. The regeneration and transformation system described here is time-efficient, yielding greenhouse-acclimatized plantlets within 14 weeks, in contrast to 12–14 months required for initiating and regenerating somatic embryogenic cultures, currently the most tractable method available for peanut transformation. The highest shoot induction frequency and shoot quality was obtained with 6.66 μM 6-benzylaminopurine, followed by adequate root induction at 5.37 μM α-Naphthaleneacetic acid. New Mexican Valencia A was chosen for Agrobacterium-mediated transformation. Stable GUS expression from pWBvec10a was obtained at a transformation rate of 1.25?%. Furthermore, results from genomic PCR and Southern blot analyses showed that 14 out of 576 putative transgenic regenerants contained transgene pSag12::IPT, therefore yielding a total transformation rate of 2.43?%. The cotyledonary node-based direct regeneration system described here is time-efficient and amenable to Agrobacterium-mediated transformation, and therefore should be further explored for peanut transgenic improvement.