Are Petals Sterile Stamens or Bracts? The Origin and Evolution of Petals in the Core Eudicots

BACKGROUND: The aim of this paper is to discuss the controversial origins of petals from tepals or stamens and the links between the morphological expression of petals and floral organ identity genes in the core eudicots. SCOPE: I challenge the widely held classical view that petals are morphologically derived from stamens in the core eudicots, and sepals from tepals or bracts. Morphological data suggest that tepal-derived petals have evolved independently in the major lineages of the core eudicots (i.e. asterids, Santalales and rosids) from Berberidopsis-like prototypes, and that staminodial petals have arisen only in few isolated cases where petals had been previously lost (Caryophyllales, Rosales). The clear correlation between continuous changes in petal morphology, and a scenario that indicates numerous duplications to have taken place in genes controlling floral organ development, can only be fully understood within a phylogenetic context. B-gene expression plays a fundamental role in the evolution of the petals by controlling petaloidy, but it does not clarify petal homology. CONCLUSIONS: An increased synorganization of the flower in the core eudicots linked with the establishment of floral whorls restricts the petaloid gene expression to the second whorl, reducing the similarities of petals with tepals from which they were originally derived. An increased flower size linked with secondary polyandry or polycarpelly may lead to a breakdown of the restricted gene expression and a reversal to ancestral characteristics of perianth development. An altered 'sliding boundary' hypothesis is proposed for the core eudicots to explain shifts in petaloidy of the perianth and the event of staminodial petals. The repetitive changes of function in the perianth of the core eudicots are linked with shifts in petaloidy to the outer perianth whorl, or losses of petal or sepal whorls that can be secondarily compensated for by the inclusion of bracts in the flower. The origin and evolution of petals appears to be as complex on a molecular basis as it is from a morphological point of view.     

More is better: the uses of developmental genetic data to reconstruct perianth evolution

The origin and evolution of the perianth remains enigmatic. While it seems likely that an undifferentiated perianth consisting of tepals arose early in angiosperm evolution, it is unclear when and how differentiated perianths consisting of distinct organs, such as petals and sepals, arose. Phylogenetic reconstructions of ancestral perianth states across angiosperms have traditionally relied on morphological data from extant species, but these analyses often produce equivocal results. Here we describe the use of developmental genetic data as an additional strategy to infer the ancestral perianth character state for different angiosperm clades. By assessing functional data in combination with expression data in a maximum likelihood framework, we provide a novel approach for investigating the evolutionary history of the perianth. Results of this analysis provide new insights into perianth evolution and provide a proof of concept for using this strategy to explore the incorporation of developmental genetic data in character state reconstructions. As the assumptions outlined here are tested and more genetic data are generated, we hope that ancestral state reconstructions based on multiple lines of evidence will converge.     

蝴蝶兰花发育的分子生物学研究进展

蝴蝶兰花非常独特且高度进化,如萼片瓣化、瓣片特化为唇瓣、雌雄蕊合生成合蕊柱及子房发育须由授粉启动等,是单子叶植物花发育研究的理想材料。近年来蝴蝶兰花发育分子生物学取得了重要进展。该文就近年来国内外有关蝴蝶兰开花转换及花器官发育相关基因研究以及B类基因与兰花花被的进化发育关系方面的研究进展进行综述。研究表明:MADS基因在蝴蝶兰开花转换及花器官发育过程中起重要作用,推测其中的DEF(DE-FICIENS)-like基因早期经过2轮复制,形成了4类不同的DEF-like基因,进而决定兰花花被属性。蝴蝶兰花发育分子生物学的深入研究,将极大地利于通过基因工程手段提高蝴蝶兰花品质如花色改良及花期调控等,推动分子育种进程。     

The evolution of the novel Sdic gene cluster in Drosophila melanogaster

The origin of new genes and of new functions for existing genes are fundamental processes in molecular evolution. Sdic is a newly evolved gene that arose recently in the D. melanogaster lineage. The gene encodes a novel sperm motility protein. It is a chimeric gene formed by duplication of two other genes followed by multiple deletions and other sequence rearrangements. The Sdic gene exists in several copies in the X chromosome, and is presumed to have undergone several duplications to form a tandemly arrayed gene cluster. Given the very recent origin of the gene and the gene cluster, the analysis of the composition of this gene cluster represents an excellent opportunity to study the origin and evolution of new gene functions and the fate of gene duplications. We have analyzed the nucleotide sequence of this region and reconstructed the evolutionary history of this gene cluster. We found that the cluster is composed by four tandem copies of Sdic; these duplicates are very similar but can be distinguished by the unique pattern of insertions, deletions, and point mutations in each copy. The oldest gene copy in the array has a 3' exon that has undergone accelerated diversification, and also shows divergent regulatory sequences. Moreover, there is evidence that this might be the only gene copy in the tandem array that is transcribed at a significant level, expressing a novel sperm-specific protein. There is also a retrotransposon located at the 3' end of each Sdic gene copy. We argue that this gene cluster was formed in the last two million years by at least three tandem duplications and one retrotransposition event.     

APETALA3 and PISTILLATA homologs exhibit novel expression patterns in the unique perianth of Aristolochia (Aristolochiaceae)

Several lines of evidence suggest that sterile floral organs, collectively known as the perianth, have evolved multiple times during the evolution of the angiosperms. In the family Aristolochiaceae, the perianth is formed by two whorls of organs in the genus Saruma but by only one whorl in the remaining genera, including Aristolochia. Although the morphology of Saruma is similar in appearance to the core eudicot perianth, with leaf-like sepals and showy colored petals, the unipartite perianth of Aristolochia combines morphological aspects of both calyx and corolla. To investigate the organ identity program functioning in the novel perianth of Aristolochia, we identified homologs of the B-class genes APETALA3 (AP3) and PISTILLATA (PI) in both Saruma and Aristolochia. The expression patterns of these genes in Saruma indicate they are functioning in the development of the second whorl petaloid organs and third whorl stamens. In Aristolochia, however, the expression of AP3 and PI homologs in the perianth does not suggest a role in organ identity but, rather, in promoting late aspects of cell differentiation. The implications of these findings for the evolution of both petaloidy and B gene function are discussed.     

Impact of gene gains,losses and duplication modes on the origin and diversification of vertebrates

The study of the evolutionary origin of vertebrates has been linked to the study of genome duplications since Susumo Ohno suggested that the successful diversification of vertebrate innovations was facilitated by two rounds of whole-genome duplication (2R-WGD) in the stem vertebrate. Since then, studies on the functional evolution of many genes duplicated in the vertebrate lineage have provided the grounds to support experimentally this link. This article reviews cases of gene duplications derived either from the 2R-WGD or from local gene duplication events in vertebrates, analyzing their impact on the evolution of developmental innovations. We analyze how gene regulatory networks can be rewired by the activity of transposable elements after genome duplications, discuss how different mechanisms of duplication might affect the fate of duplicated genes, and how the loss of gene duplicates might influence the fate of surviving paralogs. We also discuss the evolutionary relationships between gene duplication and alternative splicing, in particular in the vertebrate lineage. Finally, we discuss the role that the 2R-WGD might have played in the evolution of vertebrate developmental gene networks, paying special attention to those related to vertebrate key features such as neural crest cells, placodes, and the complex tripartite brain. In this context, we argue that current evidences points that the 2R-WGD may not be linked to the origin of vertebrate innovations, but to their subsequent diversification in a broad variety of complex structures and functions that facilitated the successful transition from peaceful filter-feeding non-vertebrate ancestors to voracious vertebrate predators.     

Perianth evolution in the sandalwood order Santalales

Flowers of Santalales remain largely unexplored with several questions of homology unanswered despite the large size of the order. Morphological and ontogenetic floral studies have the potential to identify new informative characters. We studied floral development in species of Loranthaceae, Santalaceae, Opiliaceae, and "Olacaceae" with scanning electron microscopy to clarify the origin and evolution of the perianth in Santalales. The perianth is either dichlamydeous or when monochlamydeous interpreted as sepals, petals, or tepals. A girdling calyculus of debatable origin is found in some clades. We show that species of Diogoa and Heisteria in "Olacaceae" have a dichlamydeous perianth, unlike Olax in which the calyx is replaced by a calyculus. The calyculus arises by development of two lateral primordia, supporting the hypothesis of bracteole origin. A calyculus with similar development is present in species of Loranthaceae and possibly of Opiliaceae, suggesting a position of Olax closer to these families than to traditional genera of "Olacaceae". The monochlamydeous perianth in Santalaceae is shown to correspond to petals of other members of Santalales. Flower ontogenetic evidence suggests a repeated loss of the calyx, replacement by a calyculus, and further loss, leading to monochlamydeous perianths in Santalaceae.     

Induction of Continuous Tepal Differentiation from in Vitro Regenerated Flower Buds of Hyacinthus orientalis

Continuous differentiation of tepals was successively induced from regenerated flower buds in Hyacinthus orientalis L. cv. White Pearl by controlling the exogenous hormones and explant ages. In 250 days of subculture, each flower bud differentiated an average of more than 70 tepals, with a maximum of over 140 tepals. Studies on the morphogenesis and characteristics of growth and development of the flower buds indicate that the first whorled organ of the flower bud was perianth which consisted of perianth tube and tepals grown at the top of the perianth tube, which is the same as the flower bud of the wild type in H. orentalis. The second and third whorls of the flower bud, which should be stamen and pistil in the wild type, but remained as the tepals in the regenerated flower bud. Growth of the regenerated flower bud was faster in the first several months of culture, then slowed down gradually with time. After 150 days in culture the flower bud growth and organ differentiation became very slow. Other than the tepal differentiation the regenerated flower buds also differentiated at random positions some small flower buds that also differentiated the tepals only. Histological observation revealed that the origin of the regenerated flower buds was jointly participated by some cells in the epidermal and subepidermal layers at the inner surface of the perianth explant, and the inner small flower buds were originated from the meristem which was formed by the transformation of the parenchyma at the base of the very young tepal. The authors also compared and discussed the similarities and differences of the phenotypes between the regenerated flower bud in Hyacinthus and agamous flower in Arabidopsis, from which, they have hypothesized on the role of the hormones in the promotion and termination of the gene expressions by an order of development in plant.     

'Living stones' reveal alternative petal identity programs within the core eudicots

Petals, defined as the showy laminar floral organs in the second floral whorl, have been shown to be under similar genetic control in distantly related core eudicot model organisms. On the basis of these findings, it is commonly assumed that the petal identity program regulated by B-class MADS-box gene homologs is invariant across the core eudicot clade. However, the core eudicots, which comprise >70% of angiosperm species, exhibit numerous instances of petal and sepal loss, transference of petal function between floral whorls, and recurrent petal evolution. In the face of these complex patterns of perianth evolution, the concept of a core eudicot petal identity program has not been tested. We therefore examined the petal identity program in the Caryophyllales, a core eudicot clade in which perianth differentiation into sepals and petals has evolved multiple times. Specifically, we analyzed the expression patterns of B- and C-class MADS-box homologs for evidence of a conserved petal identity program between sepal-derived and stamen-derived petaloid organs in the 'living stone' family Aizoaceae. We found that neither sepal-derived nor stamen-derived petaloid organs exhibit gene expression patterns consistent with the core eudicot petal identity program. B-class gene homologs are not expressed during the development of sepal-derived petals and are not implicated in petal identity in stamen-derived petals, as their transient expression coincides with early expression of the C-class homolog. We therefore provide evidence for petal development that is independent of B-class genes and suggest that different genetic control of petal identity has evolved within this lineage of core eudicots. These findings call for a more comprehensive understanding of perianth variation and its genetic causes within the core eudicots--an endeavor that will have broader implications for the interpretation of perianth evolution across angiosperms.     

Extensive duplications of phototransduction genes in early vertebrate evolution correlate with block (chromosome) duplications

Many gene families in mammals have members that are expressed more or less uniquely in the retina or differentially in specific retinal cell types. We describe here analyses of nine such gene families with regard to phylogenetic relationships and chromosomal location. The families are opsins, G proteins (alpha, beta, and gamma subunits), phosphodiesterases type 6, cyclic nucleotide-gated channels, G-protein-coupled receptor kinases, arrestins, and recoverins. The results suggest that multiple new gene copies arose in all of these families very early in vertebrate evolution during a period with extensive gene duplications. Many of the new genes arose through duplications of large chromosome regions (blocks of genes) or even entire chromosomes, as shown by linkage with other gene families. Some of the phototransduction families belong to the same duplicated regions and were thus duplicated simultaneously. We conclude that gene duplications in early vertebrate evolution probably helped facilitate the specialization of the retina and the subspecialization of different retinal cell types.     

Why are orchid flowers so diverse? Reduction of evolutionary constraints by paralogues of class B floral homeotic genes

Background

The nearly 30 000 species of orchids produce flowers of unprecedented diversity. However, whether specific genetic mechanisms contributed to this diversity is a neglected topic and remains speculative. We recently published a theory, the ‘orchid code’, maintaining that the identity of the different perianth organs is specified by the combinatorial interaction of four DEF-like MADS-box genes with other floral homeotic genes.

Scope

Here the developmental and evolutionary implications of our theory are explored. Specifically, it is shown that all frequent floral terata, including all peloric types, can be explained by monogenic gain- or-loss-of-function mutants, changing either expression of a DEF-like or CYC-like gene. Supposed dominance or recessiveness of mutant alleles is correlated with the frequency of terata in both cultivation and nature. Our findings suggest that changes in DEF- and CYC-like genes not only underlie terata but also the natural diversity of orchid species. We argue, however, that true changes in organ identity are rare events in the evolution of orchid flowers, even though we review some likely cases.

Conclusions

The four DEF paralogues shaped floral diversity in orchids in a dramatic way by modularizing the floral perianth based on a complex series of sub- and neo-functionalization events. These genes may have eliminated constraints, so that different kinds of perianth organs could then evolve individually and thus often in dramatically different ways in response to selection by pollinators or by genetic drift. We therefore argue that floral diversity in orchids may be the result of an unprecedented developmental genetic predisposition that originated early in orchid evolution.Key words: Orchidaceae, orchid evolution, evo-devo; perianth, class B genes, DEFICIENS, subfunctionalization, neofunctionalization, gene duplication, peloria, modularization     

Functional diversification of B MADS-box homeotic regulators of flower development: Adaptive evolution in protein-protein interaction domains after major gene duplication events

B-class MADS-box genes have been shown to be the key regulators of petal and stamen specification in several eudicot model species such as Arabidopsis thaliana, Antirrhinum majus, and Petunia hybrida. Orthologs of these genes have been found across angiosperms and gymnosperms, and it is thought that the basic regulatory function of B proteins is conserved in seed plant lineages. The evolution of B genes is characterized by numerous duplications that might represent key elements fostering the functional diversification of duplicates with a deep impact on their role in the evolution of the floral developmental program. To evaluate this, we performed a rigorous statistical analysis with B gene sequences. Using maximum likelihood and Bayesian methods, we estimated molecular substitution rates and determined the selective regimes operating at each residue of B proteins. We implemented tests that rely on phylogenetic hypotheses and codon substitution models to detect significant differences in substitution rates (DSRs) and sites under positive adaptive selection (PS) in specific lineages before and after duplication events. With these methods, we identified several protein residues fixed by PS shortly after the origin of PISTILLATA-like and APETALA3-like lineages in angiosperms and shortly after the origin of the euAP3-like lineage in core eudicots, the 2 main B gene duplications. The residues inferred to have been fixed by positive selection lie mostly within the K domain of the protein, which is key to promote heterodimerization. Additionally, we used a likelihood method that accommodates DSRs among lineages to estimate duplication dates for AP3-PI and euAP3-TM6, calibrating with data from the fossil record. The dates obtained are consistent with angiosperm origins and diversification of core eudicots. Our results strongly suggest that novel multimer formation with other MADS proteins could have been crucial for the functional divergence of B MADS-box genes. We thus propose a mechanism of functional diversification and persistence of gene duplicates by the appearance of novel multimerization capabilities after duplications. Multimer formation in different combinations of regulatory proteins can be a mechanistic basis for the origin of novel regulatory functions and a gene regulatory mechanism for the appearance of morphological innovations.     

风信子花器官中HAP2基因的分离与表达研究(英文)

在离体条件下,以风信子花被片为外植体,通过控制激素的浓度可诱导花被片、雄蕊或胚珠的再生。近年来,在拟南芥和金鱼草等模式植物中已经分离出了许多控制花器官发育的同源异形基因,如AG,AP1,AP2,AP3等,其中AP2在控制花萼和花瓣形成过程中起重要作用,因此本文从风信子中分离AP2的同源基因,并对它在风信子再生系统中的表达进行了分析。根据AP2同源基因功能域的保守序列设计一对简并引物：5'-TGGGA（A/G）TC（G/T/C）CA（C/T）AT（C/T）TGGA-3'和5'-TCCCA(AGC)(CT)(GT)(AG)CC(AG) CA(CT)TT(AG)TG-3', 以再生的花被片为材料进行RT-PCR,扩增出大小约300bp的片段,序列分析表明该片段的氨基酸序列与AP2同源性高达89%。进而,利用5’和3’Race PCR,得到全长的cDNA。该基因命名为HAP2,GenBank登记号为AF134116,该基因全长1597bp,编码368个氨基酸(Fig.1）。与AP2相比,HAP2也含有10个氨基酸长的碱性功能域,其中KKSR为核定位信号。此外,HAP2也含有两个序列重复的68个氨基酸长的功能域（HAP2-R1,HAP2-R2）,HAP2-R1也含有能形成(-螺旋结构的核心区域,且与AP2-R1中的核心序列100%同源,而HAP2-R2中的核心区域与AP2-R2相比, 缺少9个氨基酸(Fig.2）。RT-PCR结合Southern 杂交结果表明(Fig.3）,HAP     

Evolution of the APETALA3 and PISTILLATA lineages of MADS-box-containing genes in the basal angiosperms

The B class genes, including homologs of the Arabidopsis loci APETALA3 (AP3) and PISTILLATA (PI ), appear to play a conserved role in the determination of petal and stamen identity across core eudicot angiosperms. Understanding how and when these functions evolved is a critical component of elucidating the evolution of flowers, particularly the appearance of petaloid perianth organs. Before comparisons of gene expression patterns or functions can be made, however, it is necessary to establish the orthology of AP3 and PI homologs from basal angiosperms. Here, we report the identification and analysis of 29 new representatives of the B gene lineage from basal ANITA and magnoliid dicot angiosperms. These studies indicate that gene duplications have occurred at every phylogenetic level, both before and after the duplication that produced the separate AP3 and PI lineages. Comparison of genomic structure among PI homologs indicates that a 12-nucleotide deletion that had been considered synapomorphic for the whole PI lineage actually arose within the ANITA grade, after the split of the Nymphaeales but before the separation of the Austrobaileyales. Evidence for alternative splicing of the Nymphaea AP3 homolog is also presented. The implications of these findings for angiosperm systematics, the conservation of AP3 and PI gene function, and the evolution of the ABC program are discussed.     

Rhox homeobox gene cluster: recent duplication of three family members

We recently reported the discovery of a homeobox gene cluster on the mouse X chromosome, Rhox, whose 12 members are selectively expressed in specific cell types in reproductive organs. Here we report the existence of 20 additional Rhox homeobox genes in this gene cluster. Most of the newly identified Rhox paralogs retain the same order and relative orientation as three of the originally described Rhox genes, suggesting that they arose from recent duplications of this trimer unit. Many of these new Rhox family members are expressed in the testis and placenta. Analysis of synonymous and nonsynonymous substitutions in their homeodomain region suggests that these new Rhox paralogs duplicated so recently that their encoded proteins have not yet acquired distinct DNA-binding specificities. The existence of these new Rhox genes provides an opportunity to examine the initial stages of gene cluster evolution.