Autonomous self‐pollination in the nectarless orchid Pogonia minor

The pollination biology of the nectarless orchid Pogonia minor was investigated in central Japan. The investigation revealed that the solitary flowers failed to attract pollinators, while high rates of fruit set were observed in the natural population. Comparable levels of fruit set were obtained in bagged, artificial self‐pollinated and artificial cross‐pollinated plants, indicating that the species is not pollinator‐limited for fruit set under natural conditions. Autonomous self‐pollination in P. minor resulted from a reduced rostellum, which allowed contact between the pollinia and the stigma. Self‐pollination is thought to be an adaptive response that provides reproductive assurance under conditions of pollinator limitation. Since pollen limitation is generally known to be frequent among deceptive orchids, strong pollen limitation is probably a driving force in the autonomous self‐pollination mechanism in the nectarless orchid P. minor.     

Evolution towards self‐compatibility when mates are limited

Theory of plant mating system evolution predicts the spread of self‐compatibility (SC) in a predominantly self‐incompatible population when inbreeding depression (ID; the decline in fitness because of selfing) is small and when compatible mates are limited. I tested these two predictions by measuring the occurrence of SC in 13 natural populations of Ranunculus reptans L. that varied in ID and frequency of cross‐incompatible mates. Enforced selfing experiments were conducted in 2 years. In the first year, self‐pollination was applied at two flower ages to investigate the occurrence of delayed SC. I found that SC was not uncommon across all populations, but self‐compatible plants usually produced few seeds. There was no evidence for delayed SC. The occurrence of SC was not associated with population‐level ID, but populations with more limited availability of compatible mates had a significantly higher frequency of plants that were at least partially self‐compatible. The results indicate that, in R. reptans, a shortage of available mates in small populations may cause the evolution of partial SC and mixed mating.     

Do inefficient selfing and inbreeding depression challenge the persistence of the rare Dianthus guliae Janka (Caryophyllaceae)? Influence of reproductive traits on a plant's proneness to extinction

The yellow carnation Dianthus guliae Janka is a rare endemic of the Italian peninsula. As numerous extinctions have occurred in the past, very few populations are still present. Two years of field surveys revealed high mortality and an absence of recruitment in the southernmost populations of this species. Work in a botanical garden, under semi-natural conditions, revealed the occurrence of proterandrous hermaphroditism and self-compatibility. The durable flower lifespan, the competitive effects among flowers and the different outcomes from spontaneous and hand-performed pollinations (with both self- and cross-pollen) suggested low pollination rates in the experimental stand. Pollinator exclusion experiments revealed a low frequency of delayed autonomous selfing, suggesting that self-fertilization in D. guliae relies mainly on facilitated selfing and geitonogamy. Studies of inbreeding depression during the early life-history stages revealed significant differences between selfed and crossed progenies in terms of seed mass, germination rates, developmental vigour and mortality rates. Therefore, when pollen delivery is scarce, the plant may fail reproductive assurance via autonomous selfing. The influence of inbreeding depression contributes to a further reduction in recruitment chances in very small D. guliae populations. Experimental reintroductions are urgent to avoid local extinction at the southern periphery of its range.     

Autogamy in Boronia falcifolia: consequences for inbreeding and persistence in fragmented coastal heaths

Coastal heath is becoming increasingly fragmented, resulting in reduced pollinator abundance affecting species viability. The reproductive ecology and inbreeding of a common coastal heath species, Boronia falcifolia (Rutaceae), was investigated. Pollination observations and experiments were carried out at one site, and inbreeding was assessed using genetic markers at eight populations. Four pollination treatments were assessed: cross-pollination, self-pollination, autogamous pollination and open (insect) pollination. Boronia falcifolia was found to be highly self-compatible, frequently setting seeds from autogamous pollination. There were no significant differences between the autogamous, self and cross pollen treatments for any measures of reproductive success (pollen tube growth, fruit set, swollen locules and seed production). Insect activity resulted in fewer seeds per fruit than hand cross pollination, although pollinator visits were few. All populations studied were highly inbred. Autogamous self-pollination is widespread in B. falcifolia and this combined with its ability to vegetatively regenerate enhances its potential for survival when pollinators are few.     

Pollen limitation and inbreeding depression in an 'old rare' bumblebee-pollinated grassland herb

Habitat fragmentation and reduction of population size have been found to negatively affect plant reproduction in 'new rare' species that were formerly common. This has been attributed primarily to effects of increased inbreeding but also to pollen limitation. In contrast, little is known about the reproduction of 'old rare' species that are naturally restricted to small and isolated habitats and thus may have developed strategies to cope with long-term isolation and small population size. Here we study the effects of pollen source and quantity on reproduction of the 'old rare' bumblebee-pollinated herb, Astragalus exscapus. In two populations of this species, we tested for pollen autodeposition, inbreeding depression and outbreeding depression. Caged plants were left unpollinated or were pollinated with pollen from the same plant, from the same population or from a distant population (50 km). Additionally, we tested for pollen limitation by pollen supplementation in four populations of different size and density. In the absence of pollinators, plants did not produce seed whereas self-pollinated plants did. This indicates a self-compatible breeding system dependent on insect pollination. Both self-pollination and, in one of the two populations, cross-pollination with pollen from plants from the distant population resulted in a lower number of seeds per flower than cross-pollination with pollen from plants from the resident population, indicating inbreeding and outbreeding depression. Pollen addition enhanced fruit set and number of seeds per flower in three of the four populations, indicating pollen limitation. The degree of pollen limitation was lowest in the smallest but densest population. Our results suggest that, similar to 'new rare' plant species, also 'old rare' species may be at risk of inbreeding depression and pollen limitation.     

The different forms of flowers – what have we learned since Darwin?

Darwin's book, The Different Forms of Flowers on Plants of the Same Species, has stimulated an extraordinary amount of original research since its publication in 1877. In his book, Darwin focused primarily on heterostylous reproductive systems in flowering plants, in which two or three reproductive morphs with reciprocal placement of anthers and stigmas occur in populations. These morphs are usually self‐incompatible and cross‐incompatible with individuals possessing the same reproductive morph. Many of the papers on heterostyly published since Forms of Flowers appeared have focused on the questions raised by Darwin about the evolution and function of heterostyly. Darwin's hypothesis that heterostyly promotes cross‐pollination between different morphs has been largely substantiated, despite the difficulties in finding the ideal experimental system to address this question. Heterostyly is now known to occur in many more plant families than at the time Forms of Flowers was published and, as expected, the heterostylous syndrome is now defined more broadly than in Darwin's time. The origin of heterostyly remains an area of active research, with hypotheses stressing either the evolution of heteromorphic self‐incompatibility as the first step in the evolution of this reproductive system or, alternatively, the evolution of the reciprocal features of floral morphology. Phylogenetic approaches, combined with studies on the physiological and molecular genetic basis of heterostyly, offer promise in helping to resolve questions about the origin of heterostyly. There is no doubt that heterostyly has evolved on multiple occasions and that self‐incompatibility associated with heterostyly is unrelated to the more common multi‐allelic self‐incompatibility systems found in monomorphic species. Further progress in understanding conditions favouring evolution of heterostyly will depend on an increased understanding of the relation between the reciprocal morphological features of the breeding system and the nature of self‐incompatibility. Almost a century and a half after the appearance of The Different Forms of Flowers on Plants of the Same Species, heterostyly remains an active area of research. © 2009 The Linnean Society of London, Botanical Journal of the Linnean Society, 2009, 160 , 249–261.