Pablo Guitián

Reproductive biology of twoPrunus species (Rosaceae) in the Northwest Iberian Peninsula

We studied the reproductive biology ofPrunus spinosa andPrunus mahaleb (Prunoideae, Rosaceae) in the northwest Iberian Peninsula. The two species flowered at the same time (peaking on March 9 and 11, respectively in 1990) but differ significantly in their fruit maturation times. Nectar volume peaked in the early morning in both species, and was ten times greater inP. spinosa than inP. mahaleb. Neither species shows apomixis, nor does fruit-set occur if pollinators are excluded. In both species self-pollination resulted in fewer fruits than open pollination. The principal pollinators belong to theApidae family (79% and 63% of visits toP. spinosa andP. mahaleb, respectively). Results are compared with those for other rosaceous plants with fleshy fruits.

Reproductive biology of Corema album (L.) D. Don (Empetraceae) in the northwest Iberian Peninsula

Summary We report a study of the reproductive biology of the dioecious shrub Corema album in Galicia (N-W Spain). Male flowers were larger and heavier than female flowers, though the overall investment in sexual reproduction by females was higher. Population pollen-to-ovule ratio was very high (about 173 000:1). Flowering phenology was synchronous between males and females. The relative spatial distribution of the sexes appears to be random. Fruit set was not significantly dependent on either distance to the nearest male or sum of distances to the nearest five males. However, our results suggest that fruit set is higher in population nuclei with high population densities. Furthermore, mean single—fruit weight was higher in the population nucleus with highest fruit set than in the other nuclei studied.

Breeding system and temporal variation in fecundity of Pancratium maritimum L. (Amaryllidaceae): Reproductive ecology of Pancratium maritimum

Summary Flowering phenology, breeding system and temporal variation in reproductive success were studied over two consecutive years in a population of Pancratium maritimum L. (Amaryllidaceae) on coastal sand-dunes in northwest Spain. The population flowering period was late June to early September, with the flowering peak in mid-July. Fruit set did not vary significantly between years. However, plants which flowered in July and August had higher fruit set than plants which flowered in June, though no such differences were observed in mean number of seeds per fruit or mean seed-to-ovule ratio. Pollen transfer experiments indicated that the plants of the study population are self-compatible and capable of spontaneous selfing: the value of the Schoen and Lloyd self-compatibility index was 0.91, indicating that the fertilization capacity of self pollen ist almost as high as that of nonself pollen. This contrasts with the results of a study of populations of P. maritimum in Israel, where plants were found to be self-incompatible; it thus seems possible that the breeding system of this species varies among populations.

Latitudinal variation in the fruiting phenology of a bird-dispersed plant (shape Crataegus monogyna) in Western Europe

A number of fleshy-fruit-bearing plants of temperate regions are dispersed by migratory frugivorous birds. It has been suggested that the more southerly populations of such species should produce ripe fruits later than more northerly populations, to ensure that fruit is available when the birds arrive. I will call this the ‘adaptive delay’ hypothesis. To test this hypothesis, I monitored fruiting phenology of Crataegus monogyna Jacq. at ten sites (in all of which fruit consumption is very largely by redwings, Turdus iliacus, and fieldfares, Turdus pilaris) between northern Spain (42° N) and northern Scotland (59° N). There was no negative correlation between latitude and date of fruit ripening (earliest recorded date on which ripe fruits had appeared, or earliest recorded date by which all fruits had ripened). My results thus argue against the adaptive delay hypothesis.

Selective Pressures Explain Differences in Flower Color among Gentiana lutea Populations.

Flower color variation among plant populations might reflect adaptation to local conditions such as the interacting animal community. In the northwest Iberian Peninsula, flower color of Gentiana lutea varies longitudinally among populations, ranging from orange to yellow. We explored whether flower color is locally adapted and the role of pollinators and seed predators as agents of selection by analyzing the influence of flower color on (i) pollinator visitation rate and (ii) escape from seed predation and (iii) by testing whether differences in pollinator communities correlate with flower color variation across populations. Finally, (iv) we investigated whether variation in selective pressures explains flower color variation among 12 G. lutea populations. Flower color influenced pollinator visits and differences in flower color among populations were related to variation in pollinator communities. Selective pressures on flower color vary among populations and explain part of flower color differences among populations of G. lutea. We conclude that flower color in G. lutea is locally adapted and that pollinators play a role in this adaptation.

Are pollinators and seed predators selective agents on flower color in Gentiana lutea

Animals which interact with plants often cause selective pressures on plant traits. Flower color variation within a species might be shaped by the action of animals feeding on the plant species. Pollinators might exert natural selection on color if flower color is related to their foraging efficiency. For example, some pollinator species might require more time to detect particular colors. If that is the case, flower color might have evolved as a pollination exploitation barrier—ensuring that flowers are more visited by the most efficient pollinators. In addition, non-pollinator agents such as predispersal seed predators may select on flower color, if color indicates food resources (seeds) or if color is related to deterrent compounds. We address selection on flower color in a population of Gentiana lutea where color varies among individuals from yellow to orange. We hypothesize that opposed selection from mutualists (pollinators) and antagonists (predispersal seed predators) maintains flower color variation in this population. By means of path analysis we addressed the role of both interactors in flower color selection. We found that selection acts on flower color, mediated by both pollinators and seed predators. Both agents favored yellow-flowered individuals, thus selection by pollinators and seed predators does not maintain flower color variation in this population.

Seed dispersal in Erythronium dens-canis L. (Liliaceae): variation among habitats in a myrmecochorous plant

Erythronium dens-canis is a geophyte which produces a single flower each season. The fruits produce small seeds with relatively large elaiosomes. We performed experiments to investigate primary and secondary seed dispersal mechanisms of this species in different habitats in the western part of the Cantabrian Range in northwest Spain. Sticky traps were used to measure primary dispersal of seeds up to 0.5 m from mother plants. Seed cafeteria experiments were performed in different habitats to examine the role of ants and rodents in secondary seed transport and seed predation. Our results indicate that: (a) primary seed dispersal is positively skewed (99% of seeds fall within 20 cm of the mother plant) and seed dispersal distances vary significantly among plants; (b) secondary dispersal is exclusively by myrmecochory, although the proportion of seeds removed by ants differs significantly among habitats; (c) ant species composition and abundances vary among habitats; and (d) freshly dropped seeds are more likely to be removed than seeds that have begun to dry out. We conclude that secondary dispersal of seeds is greatly influenced by habitat but not by small-scale microhabitat.

Selective Pressure along a Latitudinal Gradient Affects Subindividual Variation in Plants

Individual plants produce repeated structures such as leaves, flowers or fruits, which, although belonging to the same genotype, are not phenotypically identical. Such subindividual variation reflects the potential of individual genotypes to vary with micro-environmental conditions. Furthermore, variation in organ traits imposes costs to foraging animals such as time, energy and increased predation risk. Therefore, animals that interact with plants may respond to this variation and affect plant fitness. Thus, phenotypic variation within an individual plant could be, in part, an adaptive trait. Here we investigated this idea and we found that subindividual variation of fruit size of Crataegus monogyna, in different populations throughout the latitudinal gradient in Europe, was explained at some extent by the selective pressures exerted by seed-dispersing birds. These findings support the hypothesis that within-individual variation in plants is an adaptive trait selected by interacting animals which may have important implications for plant evolution.

Small-scale spatial variation in the interactions between Prunus mahaleb and fruit-eating birds

We studied fleshy fruit consumption by birds on individualPrunus mahaleb trees in four plots in northwestern Spain.We found large variation among trees in the relative contribution of differentbird species to fruit removal. This variation, which occurred on a scale ofmeters, was correlated with the distance from the tree to nests ofPhoenicurus ochruros, a major fruit consumer, and with thekind of microhabitat surrounding each tree. In the four plots studied, treeslocated farther away from P. ochruros nests receivedrelatively fewer visits by this species, and relatively more byTurdusmerula and Sylvia atricapilla. These three mainconsumer species differed in the kinds of microhabitats (rocks, loose stones,bare or grassy soil, and woody vegetation) where they flew after visitingP. mahaleb, and thus they probably created differentpatterns of seedfall. This study adds to the evidence that environmentalfactorsextrinsic to plants, and acting at different spatial scales, greatly influencethe identity of the fruit consumers visiting individual trees. This influenceundermines the chances that fruit traits become evolutionary modified so as toattract those consumers providing the “best” seed dispersalservicesto the plants.

Seed predators exert selection on the subindividual variation of seed size

Subindividual variation among repeated organs in plants constitutes an overlooked level of variation in phenotypic selection studies, despite being a major component of phenotypic variation. Animals that interact with plants could be selective agents on subindividual variation. This study examines selective pressures exerted during post-dispersal seed predation and germination on the subindividual variation of seed size in hawthorn (Crataegus monogyna). With a seed offering experiment and a germination test, we estimated phenotypic selection differentials for average and subindividual variation of seed size due to seed predation and germination. Seed size affects germination, growth rate and the probability of an individual seed of escaping predation. Longer seeds showed higher germination rates, but this did not result in significant selection on phenotypes of the maternal trees. On the other hand, seed predators avoided wider seeds, and by doing so exerted phenotypic selection on adult average and subindividual variation of seed size. The detected selection on subindividual variation suggests that the levels of phenotypic variation within individual plants may be, at least partly, the adaptive consequence of animal-mediated selection.