舌瓣鼠尾草退化杠杆雄蕊的相关花部特征及传粉机制

杠杆状雄蕊是鼠尾草属(Salvia)物种形成的关键性状, 背部杠杆传粉模式作为该属植物与传粉者精确互作的经典案例被广泛深入研究, 但是在该属物种中还存在许多非典型的杠杆结构和传粉模式。雄蕊结构及其与传粉者互作的多样性, 使得鼠尾草属成为研究植物传粉模式转变的模式材料, 舌瓣鼠尾草(S. liguliloba)即是一种具非典型的退化杠杆状雄蕊结构和传粉特征的代表性物种。该文着重对舌瓣鼠尾草的花器官结构和传粉特征进行研究, 并与具有短药隔杠杆的毛地黄鼠尾草 (S. digitaloides)做比较分析, 以期揭示退化杠杆可能的进化选择压力及其生态学意义。结果表明, 舌瓣鼠尾草具有较短的花冠、更窄的冠筒和较短的雄、雌蕊(p < 0.05)。退化萎缩的雄蕊下臂, 冠筒内的狭小空间限制了唯一的有效传粉昆虫——三条熊蜂(Bombus trifasciatus)推动雄蕊做杠杆状运动, 而是靠近花药直接利用头部完成授粉。相比经典的杠杆状雄蕊结构及其传粉过程, 小型花冠和退化杠杆雄蕊是对专一性和活跃度较高传粉昆虫的适应, 可能具有完全不同的进化途径和繁殖策略。     

杠杆状雄蕊及其进化生态学意义

对被子植物一类特化雄蕊——杠杆状雄蕊的结构多样性及其进化生态学意义进行了归纳总结。植物的花在进化过程中, 常会发生雄蕊群的改变, 包括雄蕊数目及其形态结构的变化, 同时雄蕊功能也会发生相应的适应性转变。杠杆状雄蕊是指结构特化为杠杆状或距状, 在传粉过程中具有类似杠杆功能的一类特化的雄蕊类型。目前, 已在唇形科不同亚科以及姜科6个属中发现杠杆状雄蕊, 根据其结构和形态发生方式总体上可分为2大类: 一类是唇形科中以鼠尾草属(Salvia)为代表的, 由2个可育雄蕊平行发育、药隔组织增长所形成的杠杆状雄蕊; 另一类是姜科植物中由一个可育雄蕊特化形成的带有距状附属体的雄蕊类型。在生态功能上, 两类雄蕊均能通过传粉者推动其距状下臂做杠杆运动进行传粉, 被认为是一种促进异交的传粉机制, 可通过精确传粉和花粉分发等途径影响植物的繁殖成功。杠杆状雄蕊在不同的类群中是独立起源与进化的; 仅在唇形科鼠尾草属中, 杠杆状雄蕊发生了3次独立进化, 而且它可能是触发该属物种适应性辐射的关键性状。将来需在宏观进化和微观进化两个水平深入探讨杠杆状雄蕊的进化生态学意义。     

鼠尾草属东亚分支的传粉模式

简述了世界鼠尾草属传粉模式多样性,从宏观层面对东亚鼠尾草属分布中心———中国的鼠尾草属传粉模式进行归纳与总结。研究补充了以往所缺乏的东亚鼠尾草属核心类群的雄蕊结构和传粉模式,并提出雄蕊结构的可能进化方向。根据花器官形态、内部结构、雄蕊特征、花粉接触传粉昆虫的部位,将中国分布的鼠尾草属植物划分为3种模式类型:TypeⅠ,短药隔杠杆传粉模式(short-lever type),主要发生在弧隔鼠尾草亚属(subg.Salvia Benth.),其雄蕊药隔短,属原始结构类型;TypeⅡ,长药隔杠杆传粉模式(long-lever type),主要发生在荔枝草亚属(subg.Sclarea Benth.),雄蕊药隔明显伸长,是典型的背部杠杆传粉结构;TypeⅢ,退化杠杆传粉模式(degraded-lever type),主要发生在鼠尾草亚属(subg.Allagospadonopsis Briq.),花冠筒变短变窄,雄蕊下臂明显退化,传粉者无需进入冠筒即可取食花蜜,花粉触碰昆虫头部,进而杠杆作用弱化。研究表明,鼠尾草属传粉模式的进化趋向于提高传粉者的专一性,同时保证传粉过程的有效性、精确性和忠实性,推测具有退化雄蕊下臂的TypeⅢ模式可能更为进化。比较美洲和地中海2个进化分支的雄蕊结构和进化趋势,东亚多样性中心可能是一个独立的进化分支。毫无疑问,雄蕊结构与花器官和传粉功能高度相关,是适应传粉者的进化表型,它的进化对东亚分支的物种辐射与多样性形成可能具有关键作用。     

榕树-传粉者共生体系的协同进化与系统学研究进展及展望

 榕树-传粉者共生体系是目前植物与昆虫协同进化研究中的典型模式之一。国内外已经开展了大量的相关研究,从不同方面探讨了其特殊的一一对应的共生关系。榕树-传粉者的专一性互惠共生关系中蕴含了与系统发育有关的多因子协同进化的机理,因此,进行系统发育研究将有助于更好地揭示榕树-传粉者的协同进化历史和理解二者的专一性互惠共生关系。本文简单地介绍了目前榕树及其传粉者共生体系的研究状况之后,论述了榕树-传粉者协同进化的系统发育分子生物学研究成果。同时针对国际上在榕属植物的传统的系统与分类研究中存在的一些分歧及榕树传粉者亚科分类不匹配等问题,回顾了榕属的分类研究进展及其与传粉者的关系。最后,结合我国榕树与传粉者共生体系的研究状况对我国榕属的重新分类和系统发育研究作了展望。     

种间专性协同进化关系对榕属分类的影响

榕与榕小蜂的专性共生系统为人们提供了研究生物协同进化规律和进化历史的完美范例,已成为国际上研究植物与昆虫相互作用的一个热点。这也给仅根据外部形态等传统方法进行的榕属经典分类带来了极大的影响和冲击。为了进一步研究榕属的系统与进化,介绍了该属分类学研究的历史、主要分类系统和存在的问题,并对今后榕属分类的发展趋势进行展望。     

Functional implications of the staminal lever mechanism in Salvia cyclostegia (Lamiaceae)

Background and Aims

Flower morphology and inflorescence architecture affect pollinator foraging behaviour and thereby influence the process of pollination and the reproductive success of plants. This study explored possible ecological functions of the lever-like stamens and the floral design in Salvia cyclostegia.

Methods

Flower construction was experimentally manipulated by removing either the lower lever arms or the upper fertile thecae of the two stamens from a flower. The two types of manipulated individuals were intermixed with the control ones and randomly distributed in the population.

Key Results

Removing the sterile lower lever arms significantly reduced handling time per flower of the main pollinator, Bombus personatus. Interestingly, this manipulation did not increase the number of flowers probed per plant visit, but instead reduced it, i.e. shortened the visit sequence of the bumble-bees. Both loss of staminal lever function by removing lower lever arms and exclusion of self pollen by removing upper fertile thecae significantly reduced seed set per flower and seed set per plant. Both the manipulations interacted significantly with inflorescence size for the effect on female reproductive output.

Conclusions

Though the intact flowers demand a long handling time for pollinators, the reversible staminal lever is of advantage by promoting dispersal of pollen and thus the male function. The particular floral design in S. cyclostegia contributes to the floral constancy of B. personatus bumble-bees, with the lower lever arms acting as an optical cue for foraging cognition.     

Staminal evolution in the genus Salvia (Lamiaceae): molecular phylogenetic evidence for multiple origins of the staminal lever

BACKGROUND AND AIMS: The genus Salvia has traditionally included any member of the tribe Mentheae (Lamiaceae) with only two stamens and with each stamen expressing an elongate connective. The recent demonstration of the non-monophyly of the genus presents interesting implications for staminal evolution in the tribe Mentheae. In the context of a molecular phylogeny, the staminal morphology of the various lineages of Salvia and related genera is characterized and an evolutionary interpretation of staminal variation within the tribe Mentheae is presented. METHODS: Two molecular analyses are presented in order to investigate phylogenetic relationships in the tribe Mentheae and the genus Salvia. The first presents a tribal survey of the Mentheae and the second concentrates on Salvia and related genera. Schematic sketches are presented for the staminal morphology of each major lineage of Salvia and related genera. KEY RESULTS: These analyses suggest an independent origin of the staminal elongate connective on at least three different occasions within the tribe Mentheae, each time with a distinct morphology. Each independent origin of the lever mechanism shows a similar progression of staminal change from slight elongation of the connective tissue separating two fertile thecae to abortion of the posterior thecae and fusion of adjacent posterior thecae. A monophyletic lineage within the Mentheae is characterized consisting of the genera Lepechinia, Melissa, Salvia, Dorystaechas, Meriandra, Zhumeria, Perovskia and Rosmarinus. CONCLUSIONS: Based on these results the following are characterized: (1) the independent origin of the staminal lever mechanism on at least three different occasions in Salvia, (2) that Salvia is clearly polyphyletic, with five other genera intercalated within it, and (3) staminal evolution has proceeded in different ways in each of the three lineages of Salvia but has resulted in remarkably similar staminal morphologies.     

Evolutionary consequences of human disturbance in a rainforest bird species from Central Africa

Relatively little attention has been directed towards understanding the impacts of human disturbance on evolutionary processes that produce and maintain biodiversity. Here, we examine the influence of anthropogenic habitat changes on traits typically associated with natural and sexual selection in the little greenbul (Andropadus virens), an African rainforest bird species. Using satellite remote-sensing and field survey data, we classified habitats into nonhuman-altered mature and human-altered secondary forest. Mature rainforest consisted of pristine rainforest, with little or no human influence, and secondary forest was characterized by plantations of coffee and cacao and high human impacts. Andropadus virens abundance was higher in secondary forest, and populations inhabiting mature rainforest were significantly larger in wing and tarsus length and bill size; characters often correlated with fitness. To assess the extent to which characters important in sexual section and mate choice might be influenced by habitat change, we also examined differences in plumage colour and song. Plumage colour and the variance in plumage luminance were found to differ between forest types, and song duration was found to be significantly longer in mature forest. The possible adaptive significance of these differences in traits is discussed. Despite relatively high levels of gene flow across habitats, amplified fragment length polymorphism analysis revealed that a small proportion of high-F(ST) loci differentiated mature from secondary forest populations. These loci were significant outliers against neutral expectations in a simulation analysis, suggesting a role for divergent selection in differentiation across habitats. A distance-based redundancy analysis further showed that forest type as defined by remote-sensing variables was significantly associated with genetic dissimilarities between habitats, even when controlling for distance. The observed shifts in morphology, plumage and song were consistent with divergent selection on heritable variation, but a role for plasticity cannot be ruled out. Results suggest that anthropogenic habitat changes may have evolutionary consequences, with implications for conservation and restoration.     

Dispersal is associated with morphological innovation,but not increased diversification,in Cyphostemma (Vitaceae)

Multiple processes − including dispersal, morphological innovation, and habitat change − are frequently cited as catalysts for increased diversification. We investigate these processes and the causal linkages among them in the genus Cyphostemma (Vitaceae), a clade comprising ∼200 species that is unique in the Vitaceae for its diversity of growth habits. We reconstruct time‐calibrated evolutionary relationships among 64 species in the genus using five nuclear and chloroplast markers and infer the group's morphological and biogeographic history. We test for changes in speciation rate and evaluate the temporal association and sequencing of events with respect to dispersal, habitat change, and morphological evolution using a Monte Carlo simulation approach. In Cyphostemma, neither dispersal nor morphological evolution is associated with shifts in speciation rate, but dispersal is associated with evolutionary shifts in growth form. Evolution of stem succulence, in particular, is associated with adaptation to local, pre‐existing conditions following long‐distance dispersal, not habitat change in situ. We suggest that the pattern of association between dispersal, morphological innovation, and diversification may depend on the particular characters under study. Lineages with evolutionarily labile characters, such as stem succulence, do not necessarily conform to the notion of niche conservatism and instead demonstrate remarkable morphological adaptation to local climate and edaphic conditions following dispersal.     

Geographic variation in phenotypic plasticity in response to dissolved oxygen in an African cichlid fish

Genetic adaptation and phenotypic plasticity are two ways in which organisms can adapt to local environmental conditions. We examined genetic and plastic variation in gill and brain size among swamp (low oxygen; hypoxic) and river (normal oxygen; normoxic) populations of an African cichlid fish, Pseudocrenilabrus multicolor victoriae. Larger gills and smaller brains should be advantageous when oxygen is low, and we hypothesized that the relative contribution of local genetic adaptation vs. phenotypic plasticity should be related to potential for dispersal between environments (because of gene flow’s constraint on local genetic adaptation). We conducted a laboratory‐rearing experiment, with broods from multiple populations raised under high‐oxygen and low‐oxygen conditions. We found that most of the variation in gill size was because of plasticity. However, both plastic and genetic effects on brain mass were detected, as were genetic effects on brain mass plasticity. F₁ offspring from populations with the highest potential for dispersal between environments had characteristically smaller and more plastic brains. This phenotypic pattern might be adaptive in the face of gene flow, if smaller brains and increased plasticity confer higher average fitness across environment types.     

The genetic architecture of novel trophic specialists: larger effect sizes are associated with exceptional oral jaw diversification in a pupfish adaptive radiation

The genetic architecture of adaptation is fundamental to understanding the mechanisms and constraints governing diversification. However, most case studies focus on loss of complex traits or parallel speciation in similar environments. It is still unclear how the genetic architecture of these local adaptive processes compares to the architecture of evolutionary transitions contributing to morphological and ecological novelty. Here, we identify quantitative trait loci (QTL) between two trophic specialists in an excellent case study for examining the origins of ecological novelty: a sympatric radiation of pupfishes endemic to San Salvador Island, Bahamas, containing a large‐jawed scale‐eater and a short‐jawed molluscivore with a skeletal nasal protrusion. These specialized niches and trophic traits are unique among over 2000 related species. Measurements of the fitness landscape on San Salvador demonstrate multiple fitness peaks and a larger fitness valley isolating the scale‐eater from the putative ancestral intermediate phenotype of the generalist, suggesting that more large‐effect QTL should contribute to its unique phenotype. We evaluated this prediction using an F2 intercross between these specialists. We present the first linkage map for pupfishes and detect significant QTL for sex and eight skeletal traits. Large‐effect QTL contributed more to enlarged scale‐eater jaws than the molluscivore nasal protrusion, consistent with predictions from the adaptive landscape. The microevolutionary genetic architecture of large‐effect QTL for oral jaws parallels the exceptional diversification rates of oral jaws within the San Salvador radiation observed over macroevolutionary timescales and may have facilitated exceptional trophic novelty in this system.