Patterns of nucleotide variation in homoeologous regulatory genes in the allotetraploid Hawaiian silversword alliance (Asteraceae)

Genome-wide duplication (polyploidization) is prevalent in a large number of eukaryotic organisms and is particularly widespread in flowering plants. Polyploid species appear to vary from their diploid progenitors in a variety of ecologically important traits, suggesting that genome duplications provide a mechanism for ecological diversification. Studies of nucleotide variation at duplicate genes that arise via polyploidization allow us to infer the evolutionary forces that act on these polyploid loci. In an effort to examine the evolutionary dynamics of homoeologous loci, molecular population genetic analyses were undertaken for duplicate regulatory genes in the allopolyploid Hawaiian silversword alliance, a premier example of adaptive radiation. The levels and patterns of nucleotide variation for the floral homeotic genes ASAPETALA1 (ASAP1) and ASAPETALA3/TM6 (ASAP3/TM6) were studied in two species representing different lineages within the Hawaiian silversword alliance: Argyroxiphium sandwicense ssp. macrocephalum and Dubautia ciliolata ssp. glutinosa. Homoeologueous copies of ASAP1 and ASAP3/TM6 show differing levels and patterns of nucleotide polymorphism. Duplicate ASAP1 copies have similar levels of nucleotide diversity and haplotype structure in both species; by contrast, duplicate ASAP3/TM6 genes display different levels and patterns of variation in D. ciliolata ssp. glutinosa. Additionally, D. ciliolata ssp. glutinosa appears to be segregating for a moderate frequency null allele in one ASAP3/TM6 homoeologue. These results suggest that differing evolutionary forces can affect duplicate loci arising from allopolyploidization.     

Characterization of the potato MADS-box gene STMADS16 and expression analysis in tobacco transgenic plants

A new MADS-box gene, STMADS16, has been cloned in Solanum tuberosum L. that is expressed in all vegetative tissues of the plant, mainly in the stem, but not in flower organs. STMADS16 expression is established early during vegetative development and is not regulated by light. Sequence similarity besides the spatial and temporal expression patterns allow to define a novel MADS-box subfamily comprising STMADS16 and the gene STMADS11. Expression of the STMADS16 sense cDNA under the control of the 35S cauliflower mosaic virus promoter modifies the inflorescence structure by increasing both internode length and flower proliferation of the inflorescence meristems, and confers vegetative features to the flower. Moreover, STMADS16 ectopic expression overcomes the increase in flowering time and node number produced under short-day photoperiod, while the flowering time is not affected in long-day conditions. These results are discussed in terms of a possible role for STMADS16 in promoting vegetative development.     

棉花MADS框基因GhMADS3的克隆及其组成型表达对烟草花器官决定的影响

MADS框基因在植物花器官发育中发挥着关键性作用。为研究棉花花器官发育的机理,以徐州142花蕾为材料,利用EST数据库资料,通过EST序列整合,克隆出了一个MADS域蛋白的编码区段,GenBank登录号为AY083173。该片段(GhMADS3)包含一个732 bp的开放阅读框,推导的氨基酸序列(244氨基酸)与可可,黄瓜,烟草,矮牵牛,金鱼草等的AG亚家族基因的序列相似性高。进化树重建分析将GhMADS3基因归入MADS框基因AG亚家族C功能分支的euAG分支。RT-PCR分析显示,该基因在雄蕊和心皮中表达,在根、茎、叶等营养器官,萼片,花瓣,花器官变异体chv1(所有花器官均变为苞叶状器官)的花蕾中不表达。将GhMADS3与35S启动子融合构建成嵌合基因转化烟草,转基因烟草植株花朵出现萼片(轮1)向心皮,花瓣(轮2)向雄蕊的转变,花器官表现明显的白化倾向。同时,在轮1观察到丝状结构的出现,该结构在此前类似的研究中尚无报道。这些结果说明,实验中克隆了一个有生物学功能的棉花的AG亚家族MADS框基因,该基因可能在棉花花器官发育中有重要的功能。     

西红花MADS-box基因家族的生物信息学分析

西红花是中国传统中药材,以花柱入药,被誉为"植物黄金"。MADS-box转录因子家族在显花植物的花器官形成和分化过程中发挥重要作用,其有极大的可能影响西红花花器官的形成进而影响花柱发育。本研究采用生物信息学方法,对来自西红花转录组数据库中的17条MADS-box转录因子的核苷酸进行解读,及对其编码的氨基酸序列的组成成分、理化性质、信号肽、导肽、跨膜结构域、亚细胞定位、亲疏水性、蛋白质的二级、三级结构及功能域进行预测分析,并将西红花和其他植物的MADS-box蛋白进行同源比对,同时构建了西红花和模式植物拟南芥MADS-box蛋白家族的系统进化树。结果表明,西红花MADS-box基因的开放阅读框在630~750 bp左右,分子量在24~29 kD之间,理论等电点(pI)均大于7,介于8.69~9.54之间,表现为碱性疏水蛋白,既不含有信号肽也没有跨膜结构,二级结构主要原件为α-螺旋和无规则卷曲,含有一个MADS-MEF结构域和K-box结构域。氨基酸同源性比对结果表明西红花和石刁柏的MADS-box蛋白同源性较高。与拟南芥的进化树分析结果显示,西红花MADS-box蛋白可聚为两大类,分属于MIKC和Mβ亚家族。本工作可为今后进一步深入研究西红花MADS-box蛋白的生物学功能提供可靠的参考依据。     

Evolution of the inflated calyx syndrome in Solanaceae

Species that express the inflated calyx syndrome (ICS) are found in several genera of the Solanaceae. The MADS-box protein MPF2, together with the plant hormones cytokinin and gibberellin, has been shown to be responsible for this trait in Physalis floridana. We have used sequence data from 114 species belonging to 35 genera to construct a molecular phylogeny of Solanaceae. Apart from the 2 Witheringia species analyzed, species within a given genus cluster together on the resulting cladogram. Witheringia solanacea is embedded within the Physalinae, but Witheringia coccoloboides is placed basal to the Iochrominae. The ICS trait seems to be of multiple origins both within the Solanaceae and the Physaleae. Surprisingly, expression of MPF2-like genes in floral organs appears to be plesiomorphic in both the Physaleae and the Capsiceae. Some species in these tribes that show neither ICS nor calyx accrescence fail to express the MPF2-like gene in floral organs. Among those that do express this gene in the calyx are the species Capsicum baccatum, Lycianthes biflora, Tubocapsicum anomalum, W. solanacea, and Vassobia breviflora, all of which form small calyces that do not respond to externally applied hormones. The plesiomorphic nature of MPF2-like gene expression in the calyx of the Physaleae and Capsiceae raises the possibility that originally ICS also was actually a plesiomorphic character in these 2 groups. However, this trait might have undergone changes in a number of species due to secondary loss of components in ICS formation, like hormone response of calyx development. These findings are discussed in an evolutionary context of a molecular pathway leading to ICS.     

The D-lineage MADS-box gene OsMADS13 controls ovule identity in rice

Genes that control ovule identity were first identified in Petunia. Co-suppression of both FLORAL BINDING PROTEIN 7 (FBP7) and FBP11, two D-lineage genes, resulted in the homeotic transformation of ovules into carpelloid structures. Later in Arabidopsis it was shown that three genes, SHATTERPROOF1 (SHP1), SHP2, and SEEDSTICK (STK), redundantly control ovule identity, because in the stk shp1 shp2 triple mutant ovules lose identity and are transformed into carpel and leaf-like structures. Of these three Arabidopsis genes STK is the only D-lineage gene, and its expression, like FBP7 and FBP11, is restricted to ovules. OsMADS13 is the rice ortholog of STK, FBP7, and FBP11. Its amino acid sequence is similar to the Arabidopsis and Petunia proteins, and its expression is also restricted to ovules. We show that the osmads13 mutant is female sterile and that ovules are converted into carpelloid structures. Furthermore, making carpels inside carpels, the osmads13 flower is indeterminate, showing that OsMADS13 also has a function in floral meristem determinacy. OsMADS21 is most likely to be a paralog of OsMADS13, although its expression is not restricted to ovules. Interestingly, the osmads21 mutant did not show any obvious phenotype. Furthermore, combining the osmads13 and the osmads21 mutants did not result in any additive ovule defect, indicating that osmads21 does not control ovule identity. These results suggest that during evolution the D-lineage gene OsMADS21 has lost its ability to determine ovule identity.