Your search keyword '"Podos J"' showing total 4 results

1. Darwin's finches and their diet niches: the sympatric coexistence of imperfect generalists.

Author

De León, L. F., Podos, J., Gardezi, T., Herrel, A., and Hendry, A. P.

Subjects

*FINCHES, *ECOLOGICAL niche, *DIETARY supplements, *ADAPTIVE radiation, *COMPETITION (Biology), *BIOLOGICAL variation, *GENETIC speciation

Abstract

Adaptive radiation can be strongly influenced by interspecific competition for resources, which can lead to diverse outcomes ranging from competitive exclusion to character displacement. In each case, sympatric species are expected to evolve into distinct ecological niches, such as different food types, yet this expectation is not always met when such species are examined in nature. The most common hypotheses to account for the coexistence of species with substantial diet overlap rest on temporal variation in niches (often diets). Yet spatial variation in niche overlap might also be important, pointing to the need for spatiotemporal analyses of diet and diet overlap between closely related species persisting in sympatry. We here perform such an analysis by characterizing the diets of, and diet overlap among, four sympatric Darwin's ground finch species at three sites and over 5 years on a single Galápagos island (Santa Cruz). We find that the different species have broadly similar and overlapping diets - they are to some extent generalists and opportunists - yet we also find that each species retains some 'private' resources for which their morphologies are best suited. Importantly, use of these private resources increased considerably, and diet overlap decreased accordingly, when the availability of preferred shared foods, such as arthropods, was reduced during drought conditions. Spatial variation in food resources was also important. These results together suggest that the ground finches are 'imperfect generalists' that use overlapping resources under benign conditions (in space or time), but then retreat to resources for which they are best adapted during periods of food limitation. These conditions likely promote local and regional coexistence. [ABSTRACT FROM AUTHOR]

Published

2014

2. A geometric morphometric appraisal of beak shape in Darwin’s finches.

Author

FOSTER, D. J., PODOS, J., and HENDRY, A. P.

Subjects

*SONGBIRDS, *BEAKS, *MANDIBLE, *ANATOMY, *ANIMAL populations

Abstract

Beak size and shape in Darwin’s finches have traditionally been quantified using a few univariate measurements (length, depth, width). Here we show the improved inferential resolution of geometric morphometric methods, as applied to three hierarchical levels: (i) among seven species on Santa Cruz Island, (ii) among different sites on Santa Cruz for a single species ( Geospiza fortis), and (iii) between large and small beak size morphs of G. fortis at one site (El Garrapatero). Our results support previous studies in finding an axis of shape variation (long/shallow/pointy vs. short/deep/blunt) that separates many of the species. We also detect additional differences among species in the relative sizes and positions of the upper and lower mandibles and in curvature of the mandibles. Small-scale, but potentially relevant, shape variation was also detected among G. fortis from different sites and between sympatric beak size morphs. These results suggest that adaptation to different resources might contribute to diversification on a single island. [ABSTRACT FROM AUTHOR]

Published

2008

3. Evolution of bite force in Darwin's finches: a key role for head width.

Author

Herrel, A., Podos, J., Huber, S. K., and Hendry, A. P.

Subjects

*BIOLOGICAL evolution, *GROUND finches, *EMBERIZIDAE, *BIRDS, *HEAD, *BIOLOGICAL variation

Abstract

Studies of Darwin's finches of the Galápagos Islands have provided pivotal insights into the interplay of ecological variation, natural selection, and morphological evolution. Here we document, across nine Darwin's finch species, correlations between morphological variation and bite force capacity. We find that bite force correlates strongly with beak depth and width but only weakly or not at all with beak length, a result that is consistent with prior demonstrations of natural selection on finch beak morphology. We also find that bite force is predicted even more strongly by head width, which exceeds all beak dimensions in predictive strength. To explain this result we suggest that head width determines the maximum size, and thus maximum force generation capacity of finch jaw adductor muscles. We suggest that head width is functionally relevant and may be a previously unrecognized locus of natural selection in these birds, because of its close relationship to bite force capacity. [ABSTRACT FROM AUTHOR]

Published

2005

4. Bite performance and morphology in a population of Darwin's finches: implications for the evolution of beak shape.

Author

Herrel, A., Podos, J., Huber, S. K., and Hendry, A. P.

Subjects

*MORPHOLOGY, *PASSERIFORMES, *REGRESSION analysis, *ENVIRONMENTAL sciences, *POPULATION biology, *MUSCLES

Abstract

1. Previous studies of the Medium Ground Finch,Geospiza fortis, have documented that selection is most severe under drought conditions, which generally favour beaks that are comparatively deep and narrow. Deep beaks are presumed to enhance a bird's ability to crack hard seeds, and narrow beaks have been proposed to enhance a bird's efficiency in manipulating seeds.2. In the present study, we make the first direct measurements of bite force in Darwin's finches. We used 147G. fortisfrom Isla Santa Cruz, Galápagos, to document the influence of beak, head and body dimensions on bite force.3. Among the various beak dimensions, depth, width and shape were all significant predictors of bite force. Among the various head dimensions, width was the best predictor of bite force. Generally low predictive values of multiple regression models including all morphological variables, as well as positive allometric scaling of bite force on head width, suggest an important additional role for variation in muscle architecture or jaw biomechanics in bite force generation.Functional Ecology(2005)19, 43 –48 [ABSTRACT FROM AUTHOR]

Published

2005