Distribution Of C-heterochromatin Research Articles

“Homologies” between non-homologous chromosomes in the grasshopper Caledia captiva

Cytological studies of hybrids between three chromosomal forms of the grasshopper, Caledia captiva, have revealed a clear case of pairing and exchange between non-homologous chromosomes. The genomes of each of the three chromosomal forms are readily identifiable by their marked differences in morphology and in the pattern of C-heterochromatin distribution. The testes of inter-racial F1 hybrid males contain both diploid and tetraploid meiocytes within the same individual. Multiple chromosome associations are a regular feature of all diploid cells. In many cases, these multiples involve two or more non-homologous chromosomes from within the same haploid genome. Such associations reveal unambiguous evidence of meiotic exchange and “chiasmata”. The X chromosome is frequently observed to associate with an autosome, and anaphase I cells provide evidence of X/autosome exchanges. A correlation exists between the position of the exchange event in non-homologous pairs and the location of heterochromatin. In tetraploid meiocytes, pairing is by strict homology only, giving rise to cells with 22 bivalents plus an XX bivalent or two univalent X chromosomes. Segregation patterns in tetraploid cells are entirely normal and result in the production of diploid gametes. In the male, the increased ploidy level was observed to arise following an endoreduplication process which takes place pre-meiotically in the spermatogonial cells. The finding that non-homologous chromosomes from within the same haploid genome can pair and cross over during meiosis clearly shows that some caution must be taken when interpreting multiple associations as evidence of interchange heterozygosity in hybrids.