The duplicated B-class MADS-box genes display dualistic characters in orchid floral organ identity and growth

Orchidaceae are an excellent model to examine perianth development because of their sophisticated floral architecture. In this study, we identified 24 APETALA3 (AP3)-like and 13 PISTILLA (PI)-like genes from 11 species of orchids and characterized them into four AP3- and two PI-duplicated homologs. The first duplication event in AP3 homologs occurring in the early evolutionary history of the Orchidaceae gave rise to AP3A and AP3B clades. Further duplication events resulted in four subclades, namely AP3A1, AP3A2, AP3B1 and AP3B2, during the evolution of Orchidaceae. The AP3 paralogous genes were expressed throughout inflorescence and floral bud development. From the in situ hybridization results, we noticed that the transition timings from ubiquitous to constrained expression in floral organs for both clades are different. The transition point of expression of the AP3A clade (clades 3 and 4) was at the late floral organ primordia stage. In contrast, that for the AP3B clade (clades 1 and 2) was not observed until the late inflorescence and floral bud stages. In addition, the AP3 orthologous genes revealed diverse expression patterns in various species of orchids, whereas the PI homologs were uniformly expressed in all floral whorls. AP3A2 orthologs play a noticeable role in lip formation because of their exclusive expression in the lip. Further evidence comes from the ectopic expression of AP3A2 detected in the lip-like petals extending from the lip in four sets of peloric mutants. Finally, a Homeotic Orchid Tepal (HOT) model is proposed, in which dualistic characters of duplicated B-class MADS-box genes are involved in orchid perianth development and growth.     

Functional analysis of the promoters of B-class MADS-box genes in London plane tree and their application in genetic engineering of sterility

Breeding flowerless and/or fruitless varieties are highly desirable for London plane tree because it can prevent pollen- and fruit-mediated environmental contamination. Floral tissue-specific cell ablation is an efficient method to create such sterile plants. Here we isolated and characterized APETALA3 (AP3)-like and PISTILLATA (PI)-like genes and the promoters of PaAP3 and PaPI, in London plane tree respectively. The promoter fragments were fused to GUS (β-glucuronidase) and BARNASE gene, respectively, and transformed into tobacco plants. In pPaAP3::GUS transgenic plants, the GUS activity could be detected in various organs, including leaves, stems and all floral organs. Furthermore, most tobacco plants transformed with pPaAP3::BARNASE were dead and the survivals showed abortion of inflorescence. In contrast, heterologous expression of pPaPI::GUS in tobacco plants led to specific GUS activity in the inner three whorls of flowers. Accordingly, tobacco plants transformed with pPaPI::BARNASE lack petal, stamen and pistil, with only sepal left. The results suggest that sterile lines of P. acerifolia may be obtained by genetic engineering with pPaPI::BARNASE construct, which might solve the problems of shedding fruit hairs and disseminative pollens, reducing air pollution and reducing the allergens that harmful to human health.     

黄金树B类MADS-box基因表达特征分析

采用同源克隆技术, 从黄金树(Catalpa speciosa)花芽中克隆得到B类MADS-box基因CaspAP3和CaspPI的cDNA序列。序列分析表明, CaspAP3基因cDNA序列的完整开放阅读框(ORF)为696 bp, 编码231个氨基酸残基; CaspPI基因cDNA序列的ORF为639 bp, 编码212个氨基酸残基。蛋白质序列相似性比对和分子系统发生分析表明, CaspAP3属于AP3/DEF进化支, 其C末端包含保守的euAP3基序和PI-derived基序, 而CaspPI聚类于PI/GLO进化支, 其C末端包含保守的PI基序。半定量RT-PCR分析结果表明, CaspAP3和CaspPI基因均仅在花瓣和雄蕊中表达。实时荧光定量PCR分析表明, CaspAP3和CaspPI基因在花瓣和雄蕊原基分化期至成熟期均有表达, 这2个基因在雄蕊中表达高峰出现的时间均早于花瓣; 且花瓣中的CaspAP3和CaspPI基因表达高峰均出现在快速伸长阶段; 这与花瓣和雄蕊的形态发育阶段相吻合。     

Functional resolution of duplicated hoxb5 genes in teleosts

The duplication-degeneration-complementation (DDC) model predicts that subfunctionalization of duplicated genes is a common mechanism for their preservation. The additional Hox complexes of teleost fish constitute a good system in which to test this hypothesis. Zebrafish have two hoxb complexes, with two hoxb5 genes, hoxb5a and hoxb5b, the expression patterns of which suggest subfunctionalization of an ancestral hoxb5 gene. We characterized conserved non-coding elements (CNEs) near the zebrafish hoxb5 genes. One CNE, J3, is only retained in the hoxb5a locus, whereas the others, J1 and J2, are present in both hoxb5 loci. When tested individually, the enhancer activity of individual CNEs, including J3, extensively overlapped and did not support a role in subfunctionalization. By contrast, reporter transgene constructs encompassing multiple CNEs were able to target reporter gene expression to unique domains of hoxb5a and hoxb5b expression. The deletion of J3 from the hoxb5a locus resulted in expression that approached that of hoxb5b, whereas its insertion in the hoxb5b locus increased reporter expression and rendered it more similar to that of hoxb5a. Our results highlight the importance of interactions between CNEs in the execution of complementary subfunctions of duplicated genes.     

MADS-box genes active in developing pollen cones of Norway spruce (Picea abies) are homologous to the B-class floral homeotic genes in angiosperms.

The reproductive organs of conifers, the pollen cones and seed cones, differ in morphology from the angiosperm flower in several fundamental respects. In this report we present evidence to suggest that the two plant groups, in spite of these morphological differences and the long evolutionary distance between them, share important features in regulating the development of the reproductive organs. We present the cloning of three genes, DAL11, DAL12, and DAL13, from Norway spruce, all of which are related to the angiosperm B-class of homeotic genes. The B-class genes determine the identities of petals and stamens. They are members of a family of MADS-box genes, which also includes C-class genes that act to determine the identity of carpels and, in concert with B genes specify stamens in the angiosperm flower. Phylogenetic analyses and the presence of B-class specific C-terminal motifs in the DAL protein sequences imply homology to the B-class genes. Specific expression of all three genes in developing pollen cones suggests that the genes are involved in one aspect of B function, the regulation of development of the pollen-bearing organs. The different temporal and spatial expression patterns of the three DAL genes in the developing pollen cones indicate that the genes have attained at least in part distinct functions. The DAL11, DAL12, and 13 expression patterns in the pollen cone partly overlap with that of the previously identified DAL2 gene, which is structurally and functionally related to the angiosperm C-class genes. This result supports the hypothesis that an interaction between B- and C-type genes is required for male organ development in conifers like in the angiosperms. Taken together, our data suggests that central components in the regulatory mechanisms for reproductive organ development are conserved between conifers and angiosperms and, thus, among all seed plants.     

Functional divergence of two duplicated D-lineage MADS-box genes BdMADS2 and BdMADS4 from Brachypodium distachyon

MADS-box genes are core members of the ABCDE model for flower development where D-lineage genes play essential roles in ovule identity determination. We report here the cloning and functional characterization of two duplicated MADS-box genes, BdMADS2 and BdMADS4 from Brachypodium distachyon, the model plant of temperate grasses. BdMADS2 and BdMADS4 were highly similar to grass D-lineage MADS-box genes on the protein level and they fell in a distinctive clade on the phylogenetic tree, with conserved intron/exon structures to their rice and maize orthologues. Quantitative real time PCR revealed comparable expression levels were detected in all floral organs of Brachypodium for both genes, except for the carpel where the expression level of BdMADS2 was five times higher than that of BdMADS4. Over expression of these two genes in Arabidopsis caused curly rosette leaves, small sepals and petals, and early flowering. However, BdMADS4 showed stronger phenotypic effects than BdMADS2, suggesting functional divergence between the two genes. Cis-regulatory element prediction showed that the promoter region (including the first intron) of BdMADS4 possesses much less class I BPC protein binding motifs than that of BdMADS2 which may be responsible for the specific expression in carpels. Yeast two-hybrid assays showed that both BdMADS2 and BdMADS4 can interact with BdSEP3, but BdMADS2 can additionally interact with the putative APETALA1 orthologue (BdAP1), suggesting a deviation in their protein interaction patterns. Taken together, our data demonstrate a significant divergence between the two Brachypodium D-lineage MADS-box genes and provide evidences for their sub-functionalization.     

Functional specialization of duplicated AP3‐like genes in Medicago truncatula

The B–class of MADS box genes has been studied in a wide range of plant species, but has remained largely uncharacterized in legumes. Here we investigate the evolutionary fate of the duplicated AP3‐like genes of a legume species. To obtain insight into the extent to which B‐class MADS box gene functions are conserved or have diversified in legumes, we isolated and characterized the two members of the AP3 lineage in Medicago truncatula: MtNMH7 and MtTM6 (euAP3 and paleoAP3 genes, respectively). A non‐overlapping and complementary expression pattern of both genes was observed in petals and stamens. MtTM6 was expressed predominantly in the outer cell layers of both floral organs, and MtNMH7 in the inner cell layers of petals and stamens. Functional analyses by reverse genetics approaches (RNAi and Tnt1 mutagenesis) showed that the contribution of MtNMH7 to petal identity is more important than that of MtTM6, whereas MtTM6 plays a more important role in stamen identity than its paralog MtNMH7. Our results suggest that the M. truncatula AP3‐like genes have undergone a functional specialization process associated with complete partitioning of gene expression patterns of the ancestral gene lineage. We provide information regarding the similarities and differences in petal and stamen development among core eudicots.     

Functional divergence within class B MADS-box genes TfGLO and TfDEF in Torenia fournieri Lind

Homeotic class B genes GLOBOSA (GLO)/PISTILLATA (PI) and DEFICIENS (DEF)/APETALA3 (AP3) are involved in the development of petals and stamens in Arabidopsis. However, functions of these genes in the development of floral organs in torenia are less well known. Here, we demonstrate the unique floral phenotypes of transgenic torenia formed due to the modification of class B genes, TfGLO and TfDEF. TfGLO-overexpressing plants showed purple-stained sepals that accumulated anthocyanins in a manner similar to that of petals. TfGLO-suppressed plants showed serrated petals and TfDEF-suppressed plants showed partially decolorized petals. In TfGLO-overexpressing plants, cell shapes on the surfaces of sepals were altered to petal-like cell shapes. Furthermore, TfGLO- and TfDEF-suppressed plants partially had sepal-like cells on the surfaces of their petals. We isolated putative class B gene-regulated genes and examined their expression in transgenic plants. Three xyloglucan endo-1,4-beta-d-glucanase genes were up-regulated in TfGLO- and TfDEF-overexpressing plants and down-regulated in TfGLO- and TfDEF-suppressed plants. In addition, 10 anthocyanin biosynthesis-related genes, including anthocyanin synthase and chalcone isomerase, were up-regulated in TfGLO-overexpressing plants and down-regulated in TfGLO-suppressed plants. The expression patterns of these 10 genes in TfDEF transgenic plants were diverse and classified into several groups. HPLC analysis indicated that sepals of TfGLO-overexpressing plants accumulate the same type of anthocyanins and flavones as wild-type plants. The difference in phenotypes and expression patterns of the 10 anthocyanin biosynthesis-related genes between TfGLO and TfDEF transgenic plants indicated that TfGLO and TfDEF have partial functional divergence, while they basically work synergistically in torenia.     

The duplicated B-class heterodimer model: whorl-specific effects and complex genetic interactions in Petunia hybrida flower development

In both Antirrhinum (Antirrhinum majus) and Arabidopsis (Arabidopsis thaliana), the floral B-function, which specifies petal and stamen development, is embedded in a heterodimer consisting of one DEFICIENS (DEF)/APETALA3 (AP3)-like and one GLOBOSA (GLO)/PISTILLATA (PI)-like MADS box protein. Here, we demonstrate that gene duplications in both the DEF/AP3 and GLO/PI lineages in Petunia hybrida (petunia) have led to a functional diversification of their respective members, which is reflected by partner specificity and whorl-specific functions among these proteins. Previously, it has been shown that mutations in PhDEF (formerly known as GREEN PETALS) only affect petal development. We have isolated insertion alleles for PhGLO1 (FLORAL BINDING PROTEIN1) and PhGLO2 (PETUNIA MADS BOX GENE2) and demonstrate unique and redundant properties of PhDEF, PhGLO1, and PhGLO2. Besides a full homeotic conversion of petals to sepals and of stamens to carpels as observed in phglo1 phglo2 and phdef phglo2 flowers, we found that gene dosage effects for several mutant combinations cause qualitative and quantitative changes in whorl 2 and 3 meristem fate, and we show that the PHDEF/PHGLO1 heterodimer controls the fusion of the stamen filaments with the petal tube. Nevertheless, when the activity of PhDEF, PhGLO1, and PhGLO2 are considered jointly, they basically appear to function as DEF/GLO does in Antirrhinum and to a lesser extent as AP3/PI in Arabidopsis. By contrast, our data suggest that the function of the fourth B-class MADS box member, the paleoAP3-type PETUNIA HYBRIDA TM6 (PhTM6) gene, differs significantly from the known euAP3-type DEF/AP3-like proteins; PhTM6 is mainly expressed in the developing stamens and ovary of wild-type flowers, whereas its expression level is upregulated in whorls 1 and 2 of an A-function floral mutant; PhTM6 is most likely not involved in petal development. The latter is consistent with the hypothesis that the evolutionary origin of the higher eudicot petal structure coincided with the appearance of the euAP3-type MADS box genes.     

Functional analysis of a duplicated linked pair of ribosomal protein genes in Saccharomyces cerevisiae.

Ribosomal protein genes RP28 and S16A (RP55) are closely linked. Another set of this pair of genes exists in the genome (copy 2), genetically unlinked to copy 1. By using gene replacement techniques, we have shown that RP28 from copy 1 is required for vegetative growth and that the cells need S16A from copy 2 to achieve maximum growth rate.