Phenotypic plasticity in size of ant-domatia.

Ant-plants produce hollow structures called domatia to host protecting ants. Although size variation in domatia is well documented between related species, intraspecific variation is little explored. The central African ant-plant Barteria dewevrei exibits strong variation in domatium size, giving the opportunity to explore the mechanism underlying variation in a mutualistic trait. We showed that domatium size in Barteria dewevrei varies between sites. We transplanted individual plants between two sites in Gabon where plants have different domatium sizes. Domatium size of transplanted plants changed, revealing that variation in this mutualistic trait is driven by phenotypic plasticity. The two sites differed in their environmental conditions: highland open savanna on sandy soil vs lowland closed tropical rain forest on sandy-loam soil. However, as stomatal density and δ13C of leaves did not differ between sites or between branches produced before and after transplantation, we have no cue on the role of abiotic stress (such as light intensity and water availability) in domatium size variation. As the obligate Tetraponera ant symbionts are too large to fit in the small domatia, variation of the mutualistic trait in response to environmental change through phenotypic plasticity may impact this specialized mutualism.

Behavioral and life-history evidence for interspecific competition in the larvae of two heliconian butterflies.

Interspecific competition in herbivorous insects remains a controversial issue. To date, many studied systems have not met assumptions of the traditional competition theory, and a new paradigm has been emerging. We examined the behavioral and life-history consequences of common host plant use of Heliconius erato and Dryas iulia (Nymphalidae) in relation to Passiflora suberosa (Passifloraceae). Larvae of the former use the apical portion of this host; the latter is presumably able to explore all plant parts. We assessed host use pattern in relation to leaf age, when reared either alone (D. iulia) or together (D. iulia and H. erato). Larval feeding choice tests with respect to leaf age were performed, and performance was recorded. Observations were made to assess antagonistic behavior of H. erato and D. iulia towards each other, if any. Similarly to H. erato, D. iulia fed on the young leaves significantly more than the mature ones; larvae were not induced to prefer mature leaves. First instars of H. erato used only the apical parts of P. suberosa and displayed aggressive behavior towards D. iulia, which moved to the lower shoot portions. Larval mortality and development time of both species significantly increased when reared together; such performance costs were more pronounced in D. iulia than H. erato. Our study gathers evidences that use of P. suberosa by these heliconian butterflies represent a case of competitive exclusion resulting in niche differentiation, where costs are higher for D. iulia than H. erato.

Pollinator-mediated selection on floral morphology: evidence for transgressive evolution in a derived hybrid lineage.

Hybridization between closely related lineages is a mechanism that might promote substantive changes in phenotypic traits of descendants, resulting in transgressive evolution. Interbreeding between divergent but morphologically similar lineages can produce exceptional phenotypes, but the potential for transgressive variation to facilitate long-term trait changes in derived hybrid lineages has received little attention. We compare pollinator-mediated selection on transgressive floral traits in both early-generation and derived hybrid lineages of the Piriqueta cistoides ssp. caroliniana complex. The bowl-shaped flowers of morphotypes in this complex have similar gross morphologies and attract a common suite of small insect pollinators. However, they are defined by significant differences in characters that generate pollinator interest and visitation, including floral area and petal separation. In common garden experiments, patterns of pollen deposition in early-generation recombinant hybrids indicate that Piriqueta's pollinators favour flowers with greater area and reduced petal separation. Changes in floral morphology in derived hybrid lineages are consistent with predictions from selection gradients, but the magnitude of change is limited relative to the range of transgressive variation. These results suggest that hybridization provides variation for evolution of divergent floral traits. However, the potential for extreme transgressive variants to contribute to phenotypic shifts may be limited due to reduced heritability, evolutionary constraints or fitness trade-offs.

Multi-locus phylogenies of the genus Barteria (Passifloraceae) portray complex patterns in the evolution of myrmecophytism.

The four species of the central African genus Barteria show variation in habitat and in degree of association with ants. Whereas B. solida, restricted to submontane forests, attracts opportunistic ants to extrafloral nectar, the three other species, found in lowland rainforests (B. fistulosa, B. dewevrei) and in littoral scrub (B. nigritana), possess stem domatia of varying shapes and degrees of specialisation, hosting either non-specific arboreal ants (B. nigritana, some B. dewevrei) or two large species of ants of the genus Tetraponera Smith, 1852 that are specific to some species of Barteria (B. fistulosa, some B. dewevrei). We aimed to investigate whether this variation represents an evolutionary trend toward increasing specialisation of mutualism or the reduction or loss of myrmecophytic traits. For this, we determined phylogenetic relationships within the genus using DNA sequences (primarily nuclear ITS) and microsatellite genotypes (11 loci) on a large sample of individuals, mostly from Cameroon and Gabon. The two types of markers support an initial dichotomy that groups B. dewevrei with B. nigritana and B. fistulosa with B. solida respectively. Within these pairs, species do not appear reciprocally monophyletic. At microsatellite loci, B. nigritana forms a clade embedded within B. dewevrei; and within both B. solida and B. fistulosa, geographical populations show levels of differentiation similar to that observed between populations of B. solida and B. fistulosa. Geographic distance alone does not account for genetic differentiation between species, which indicates reproductive isolation. Divergence in each of the two pairs implies evolutionary transitions in habitat and in myrmecophytism. Specialised mutualism with specific ant species of the genus Tetraponera has been lost in species found in more marginal habitats.

Plant-ants use symbiotic fungi as a food source: new insight into the nutritional ecology of ant-plant interactions.

Usually studied as pairwise interactions, mutualisms often involve networks of interacting species. Numerous tropical arboreal ants are specialist inhabitants of myrmecophytes (plants bearing domatia, i.e. hollow structures specialized to host ants) and are thought to rely almost exclusively on resources derived from the host plant. Recent studies, following up on century-old reports, have shown that fungi of the ascomycete order Chaetothyriales live in symbiosis with plant-ants within domatia. We tested the hypothesis that ants use domatia-inhabiting fungi as food in three ant-plant symbioses: Petalomyrmex phylax/Leonardoxa africana, Tetraponera aethiops/Barteria fistulosa and Pseudomyrmex penetrator/Tachigali sp. Labelling domatia fungal patches in the field with either a fluorescent dye or (15)N showed that larvae ingested domatia fungi. Furthermore, when the natural fungal patch was replaced with a piece of a (15)N-labelled pure culture of either of two Chaetothyriales strains isolated from T. aethiops colonies, these fungi were also consumed. These two fungi often co-occur in the same ant colony. Interestingly, T. aethiops workers and larvae ingested preferentially one of the two strains. Our results add a new piece in the puzzle of the nutritional ecology of plant-ants.

Respuesta in vitro de diferentes biotipos y explantos de Passiflora caerulea L / In vitro response of different biotypes and explants of Passiflora caerulea L

Passiflora caerulea L., al igual que otras especies de la familia Passifloraceae, es utilizada en la medicina popular por sus propiedades antiespasmódicas y para el tratamiento de la ansiedad, el insomnio y el nerviosismo. La belleza de sus flores les otorga valor ornamental, mientras que sus frutos son apreciados por su importancia alimenticia. Se evaluó la respuesta in vitro de diferentes explantos y tres biotipos de P. caerulea: Corral de Bustos (provincia de Córdoba), Zavalla (provincia de Santa Fe) y Neuquén (provincia de Neuquén). Se utilizaron dos tipos de explantos: entrenudos y segmentos nodales, y como medio de cultivo Murashige y Skoog (1962) (MS), suplementado con vitaminas de Gamborg (1976) y 1 mg/L-1 de benciladenina (BA). Las respuestas fueron diferentes según el genotipo y el explanto. Los entrenudos ubicados tanto horizontal como verticalmente en medio de cultivo generaron callos como única respuesta. El biotipo de Neuquén mostró los mayores porcentajes de segmentos nodales con brotes. A través de estudios histológicos se determinó que en medio de cultivo MS con 1 mg/L-1 de BA, los segmentos nodales de P. caerulea originan brotes a partir de las yemas axilares preformadas y raíces que parten de callos en la base de los mismos. En iguales condiciones, los entrenudos originan callo como única respuesta.

As other species of the Passifloraceae family, Passiflora caerulea L. is used in popular medicine for its antispasmodic properties and as a remedy for anxiety, insomnia and nervousness. It is also highly prized for the ornamental value of its beautiful flowers, as well as for the nutritional importance of its fruits. The in vitro response of different explants and three biotypes of P. caerulea: the Corral de Bustos (Province of Córdoba), the Zavalla (Province of Santa Fe) and the Neuquén (Province of Neuquén) genotypes, was evaluated using two types of explants: internodes and nodal segments on Murashige and Skoog (1962) (MS) culture medium supplemented with Gamborg’s vitamins (1976) and 1 mg.L-1 of benzyladenine (BA). There were different responses depending on the genotype and the explant. The internodes placed both horizontally and vertically in the culture medium produced callus as sole response. The Neuquén biotype showed the highest percentages of nodal segments with shoots. Histological tests allowed to establish that in MS culture medium with 1 mg.L-1 of BA, the nodal segments of P. caerulea produce shoots from the preformed axillary buds and roots that develop from the callus situated on its base. Under similar conditions, the internodes produce callus as sole response.