Evolution of reduced minimum critical size as a response to selection for rapid pre-adult development in Drosophila melanogaster
Adult body size in holometabolous insects is directly proportional to the time spent during the larval period. The larval duration can be divided into two parts- (i) pre-critical duration-time required to attain a critical size/critical weight that would result in successful completion of developmen...
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Zusammenfassung: | Adult body size in holometabolous insects is directly proportional to the
time spent during the larval period. The larval duration can be divided
into two parts- (i) pre-critical duration-time required to attain a
critical size/critical weight that would result in successful completion
of development and metamorphosis even under non-availability of nutrition
beyond the time of attainment of critical size, and (ii) post-critical
duration-the time duration from attainment of critical size till pupation.
It is of interest to decipher the relative contribution of the two larval
growth phases (from the hatching of the egg to attainment of critical size
or from the attainment of critical size to pupation- post-critical
duration) to the final adult size. Many studies using Drosophila
melanogaster have shown that, selecting populations for faster development
result in the emergence of small adults. Some of these studies have
indirectly reported the evolution of smaller critical size. Using two
kinds of D. melanogaster populations, one of which is selected for
faster/accelerated pre-adult development and the other their ancestral
control, we demonstrate that the final adult size is determined by the
time spent as larvae post the attainment of critical size despite having
increased growth rate during the second larval instar. Our populations
under selection for faster per-adult development are exhibiting
adaptive-bail out due to intrinsic food limitation as against extrinsic
food limitation in the yellow dung fly. |
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DOI: | 10.5061/dryad.k6djh9w32 |