Chloroplast DNA and the determination of species status in the Disa tripetaloides complex (Orchidaceae), and its relationships to three species Racemosae, section Disa

Disa cardinalis and three populations within the D. tripetaloides species complex contain variation in their chloroplast DNA (cpDNA) variability. All four taxa possessed unique cpDNAs and sequence divergence values ranged from 0.34 to 1.03%. A phylogeny of these genomes was reconstructed, along with the genomes of three other species, D. racemosa, D. uniflora and D. venosa, all of which are also section Disa and series RAcemosae, to determine the relationship of these closely related species to the D. tripetaloides complex. A phylogeny of the taxa using morphological data was also reconstructed. Outgroup comparison was made with D. sagittalis, a member of section Coryphaea. Although the molecular and morphological data were not completely congruent, both data types revealed D. cardinalis, rather than D. tripetaloides ssp. aurata, to be more closely allied with D. tripetaloides ssp. tripetaloides, suggesting that D. tripetaloides ssp. aurata should be elevated to species rank. Additionally, the high sequence divergence observed between the Natal and Cape populations, coupled with their geographical isolation and alternate flowering seasons, suggests that these two D. tripetaloides ssp. tripetaloides populations may, in fact, be more appropriately ranked as subspecies.     

Diversity of mycorrhizal fungi of terrestrial orchids: compatibility webs, brief encounters, lasting relationships and alien invasions

The diversity of mycorrhizal fungi associated with an introduced weed-like South African orchid (Disa bracteata) and a disturbance-intolerant, widespread, native West Australian orchid (Pyrorchis nigricans) were compared by molecular identification of the fungi isolated from single pelotons. Molecular identification revealed both orchids were associated with fungi from diverse groups in the Rhizoctonia complex with worldwide distribution. Symbiotic germination assays confirmed the majority of fungi isolated from pelotons were mycorrhizal and a factorial experiment uncovered complex webs of compatibility between six terrestrial orchids and 12 fungi from Australia and South Africa. Two weed-like (disturbance-tolerant rapidly spreading) orchids — D. bracteata and the indigenous Australian Microtis media, had the broadest webs of mycorrhizal fungi. In contrast, other native orchids had relatively small webs of fungi (Diuris magnifica and Thelymitra crinita), or germinated exclusively with their own fungus (Caladenia falcata and Pterostylis sanguinea). Orchids, such as D. bracteata and M. media, which form relationships with diverse webs of fungi, had apparent specificity that decreased with time, as some fungi had brief encounters with orchids that supported protocorm formation but not subsequent seedling growth. The interactions between orchid mycorrhizal fungi and their hosts are discussed.     

Contribution to the orchid flora of South Central Africa

11 new taxa (8 new species, 3 new varieties) ofOrchidaceae are described from South Central Africa, including data on their habitat and distribution and discussions of their systematic affinities.     

Transfer of pollinaria on birds’ feet: a new pollination system in orchids

We report the discovery of a new mechanism of pollination in orchids: transfer of pollinaria on the feet of birds. Observations carried out in South Africa and Malawi showed that the orchids Disa chrysostachya Sw. and Disa satyriopsis Kraenzl. are pollinated by sunbirds. Pollinaria of these orchids become attached firmly to the birds toes when they perch on the tall narrow inflorescences which are packed tightly with numerous small orange flowers. Birds typically perch on the lower part of an inflorescence while reaching up to feed on nectar in flowers on the upper part, but occasionally reverse this position to probe the lower flowers. The nectar is contained within a short bulbous spur with a narrow entrance that permits entrance of a sunbirds slender tongue. Contrary to expectation, the pollination mechanism in D. chrysostachya is remarkably efficient with about 6.1% of pollen reaching stigmas on other plants and fruit set occurring in 95% of flowers at one site. Birds seldom move their feet once perched, thus minimizing the incidence of self-pollination, either within or between flowers on an inflorescence.     

Phylogeny and radiation of pollination systems in DISA (Orchidaceae)

We studied the patterns of adaptive radiation in Disa, a large orchid genus in southern Africa. A cladogram for 27 species was constructed using 44 morphological characters. Pollination systems were then mapped onto the phylogeny in order to analyze pathways of floral evolution. Shifts from one pollination system to another have been a major feature of the evolutionary diversification of Disa. Unlike many plant genera that are pollinated mainly by a single group of insects, radiation in Disa has encompassed nearly all major groups of pollinating insects; in all, 19 different specialized pollination systems have been found in the 27 species included in this analysis. Another striking pattern is the repeated evolution of broadly similar pollination systems in unrelated clades. For example, butterfly-pollinated flowers have evolved twice; showy deceptive flowers pollinated by carpenter bees, twice; long-spurred flowers pollinated by long-tongued flies, four times; night-scented flowers pollinated by moths, three times; and self-pollination, three times. This suggests that a few dominant pollinator species in a region may be sufficient to generate diversification in plants through repeated floral shifts that never retrace the same pathways.     

Flower colour adaptation in a mimetic orchid

Although the tremendous variability in floral colour among angiosperms is often attributed to divergent selection by pollinators, it is usually difficult to preclude the possibility that floral colour shifts were driven by non-pollinator processes. Here, we examine the adaptive significance of flower colour in Disa ferruginea, a non-rewarding orchid that is thought to attract its butterfly pollinator by mimicking the flowers of sympatric nectar-producing species. Disa ferruginea has red flowers in the western part of its range and orange flowers in the eastern part--a colour shift that we hypothesized to be the outcome of selection for resemblance to different local nectar-producing plants. Using reciprocal translocations of red and orange phenotypes as well as arrays of artificial flowers, we found that the butterfly Aeropetes tulbaghia, the only pollinator of the orchid, preferred both the red phenotype and red artificial flowers in the west where its main nectar plant also has red flowers, and both the orange phenotype and orange artificial flowers in the east, where its main nectar plant has orange flowers. This phenotype by environment interaction demonstrates that the flower colour shift in D. ferruginea is adaptive and driven by local colour preference in its pollinator.     

Lack of floral nectar reduces self-pollination in a fly-pollinated orchid

One explanation for the widespread absence of floral nectar in many orchids is that it causes pollinators to visit fewer flowers on a plant, and thus reduces self-pollination. This, in turn, could increase fitness by reducing inbreeding depression in progeny and promoting pollen export. The few previous investigations of this hypothesis have all involved bee-pollinated orchids and some have given contradictory results. We studied the effects of adding artificial nectar (sucrose solution) to the spurs of a non-rewarding long-proboscid fly-pollinated orchid, Disa pulchra. Addition of nectar significantly increased the number of flowers probed by flies (2.6-fold), the time spent on a flower (5.4-fold), the number of pollinia removed per inflorescence (4.8-fold) and the proportion of removed pollen involved in self-pollination (3.5-fold). The level of self-pollination increased dramatically with the number of flowers probed by flies. Experimental self-pollination resulted in fruits with only half as many viable seeds as those arising from cross-pollination. Pollinators were more likely to fly long distances (>40 cm) when departing from non-rewarding inflorescences than when departing from rewarding ones. These findings provide support for the idea that floral deception serves to reduce pollinator-mediated self-pollination.     

Pollen fates and the limits on male reproductive success in an orchid population

Male reproductive success in higher plants depends largely on the fates of pollen, but current methodologies have given only partial insights into this important aspect of plant mating. We present a detailed analysis of the proportions and absolute amounts of stained pollen involved in six key fates for the hawkmoth-pollinated African orchid Disa cooperi . Despite being packaged into pollinaria, high proportions (> 0.95) of the pollen removed from anthers were lost during transport by hawkmoths in both years. The proportion of pollen lost correlated positively with the number of pollinaria removed from a plant, so that pollen export did not vary with pollen removal. Most pollen was dispersed to neighbouring plants, with rare long-distance dispersal up to 65 m. Of the pollen that reached stigmas during both years, roughly equal amounts were involved in facilitated self-pollination vs. cross-pollination, but the relative proportions of these fates differed between years. Contrary to expectation, we found that self-pollination between flowers did not increase with the number of open flowers, even though moths probed significantly more flowers on larger plants. However, during both years the fraction of removed pollen exported to other plants declined significantly with increasing self-pollination on the source plant, indicating that once self-pollination occurred it reduced (discounted) subsequent pollen export opportunities. The packaging of pollen into pollinaria in orchids appears to increase overall transfer efficiency by at least an order of magnitude relative to plants with granular pollen. Nevertheless, considerable uncertainties remain in the male reproductive success of individual orchids. © 2005 The Linnean Society of London, Biological Journal of the Linnean Society , 2005, 86 , 175–190.     

Evidence for Bastesian mimicry in a butterfly-pollinated orchid

Observations in the Cape Province, South Africa, showed that Disa ferruginea (Orchidaceae) is dependent on a single butterfly species— Meneris tulbaghia (Nymphalidae: Satyrinae)—for pollination. The flowers of D. ferruginea contain no food reward and, instead, appear to secure pollinator visits by imitating flowers which are nectar sources for the butterfly. A red-flowered form of D. ferruginea appears to mimic the red nectar-producing flowers of Tritoniopsis triticea (Iridaceae) in the south-western Cape, while an orange-flowered form of D. ferruginea appears to mimic the orange nectar-producing flowers of Kniphofia uvaria (Asphodelaceae) in the Langeberg Mountains. Reflectance spectra of the orchid's flowers closely match those of its putative models. Analysis of foraging movements of the butterfly in a mixed stand of D. ferruginea and T. triticea indicated that it does not discriminate between the nectarless orchid and the nectar-producing model. Populations of D. ferruginea which are sympatric with T. triticea have relatively high levels of pollination and fruit production, compared with populations where the orchid grows alone. Although other studies have reported relatively low fecundity in deceptive orchids, pollination and fruiting success in D. ferruginea compares favourably with a nectar-producing congener, Disa uniflora , which is also pollinated solely by M. tulbaghia.