Sequence differentiation among inversion rearrangement are revealed by random amplified polymorphic DNA markers in the grasshopper Trimerotropis pallidipennis (Orthoptera: Acrididae: Oedipodinae)
South American populations of Trimerotropis pallidipennis Burmeister are polymorphic for pericentric inversions. In this species, rearrangement frequencies follow repetitive patterns of distributions along different geographic areas, which are determined by altitude, minimum temperature, and humidit...
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2002
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| Acceso en línea: | https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00138746_v95_n2_p201_Confalonieri http://hdl.handle.net/20.500.12110/paper_00138746_v95_n2_p201_Confalonieri |
| Aporte de: |
| Sumario: | South American populations of Trimerotropis pallidipennis Burmeister are polymorphic for pericentric inversions. In this species, rearrangement frequencies follow repetitive patterns of distributions along different geographic areas, which are determined by altitude, minimum temperature, and humidity variables. The current article reports the analysis of random amplified polymorphic DNA (RAPDs) in five populations of T. pallidipennis and shows the possible relationships of this kind of molecular variability with inversion and enzyme polymorphisms. Both comparisons of RAPDs versus chromosome and RAPDs versus enzyme genetic distances yielded significant results, indicating that the degree of differentiation between pairs of populations is significantly similar when all three types of variability are compared with each other. Specifically, the differentiation for loci amplified by some of the primers is significantly correlated with the differentiation in humidity conditions. Therefore, RAPD loci frequencies tend to follow similar patterns of variations as chromosome and enzymatic variability. Inversions are of evolutionary significance because they can generate supergenes that preserve special genetic sequences. A population of T. pallidipennis at high altitudes, which is monomorphic for basic sequences at all chromosomes, will not have the same allele sequence as a population at low altitudes with fixed inverted chromosomes. Because all seven inversions involve a good portion of the genome, a variation between supergenes that differentiate populations is expected to be observed when many random fragments of DNA are amplified, because an eventual recognition sequence of the primers sited into the inversion may be altered. The significance of the congruence between enzymatic and RAPD variability is also discussed. |
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