The lethal(1)TW-6cs mutation of Drosophila melanogaster is a dominant antimorphic allele of nod and is associated with a single base change in the putative ATP-binding domain.

The l(1)TW-6cs mutation is a cold-sensitive recessive lethal mutation in Drosophila melanogaster, that affects both meiotic and mitotic chromosome segregation. We report the isolation of three revertants of this mutation. All three revert both the meiotic and mitotic effects as well as the cold sensitivity, demonstrating that all three phenotypes are due to a single lesion. We further show that these revertants fail to complement an amorphic allele of the nod (no distributive disjunction) locus, which encodes a kinesin-like protein. These experiments demonstrate that l(1)TW-6cs is an antimorphic allele of nod, and we rename it nodDTW. Sequencing of the nod locus on a nodDTW-bearing chromosome reveals a single base change in the putative ATP-binding region of the motor domain of nod. Recessive, loss-of-function mutations at the nod locus specifically disrupt the segregation of nonexchange chromosomes in female meiosis. We demonstrate that, at 23.5 degrees, the meiotic defects in nodDTW/+ females are similar to those observed in nod/nod females; that is, the segregation of nonexchange chromosomes is abnormal. However, in nodDTW/nodDTW females, or in nodDTW/+ females at 18 degrees, we observe a more severe meiotic defect that apparently affects the segregation of both exchange and nonexchange chromosomes. In addition, nodDTW homozygotes and hemizygous males have previously been shown to exhibit mitotic defects including somatic chromosome breakage and loss. We propose that the defective protein encoded by the nodDTW allele interferes with proper chromosome movement during both meiosis and mitosis, perhaps by binding irreversibly to microtubules.

Effects of the lethal yellow (Ay) mutation in mouse aggregation chimeras

The Ay allele is a recessive lethal mutation at the mouse agouti locus, which results in embryonic death around the time of implantation. In the heterozygous state, Ay produces several dominant pleiotropic effects, including an increase in weight gain and body length, a susceptibility to hepatic, pulmonary and mammary tumors, and a suppression of the agouti phenotype, which results in a yellow coat color. To investigate the cellular action of Ay with regard to its effects upon embryonic viability and adult-onset obesity, we generated a series of aggregation chimeras using embryos that differ in their agouti locus genotype. Embryos derived from Ay/a × Ay/a matings were aggregated with those derived from A/A × A/A matings, and genotypic identification of the resultant chimeras was accomplished using a molecular probe at the Emv-15 locus that distinguishes among the three different alleles, Ay, A, and a. Among 50 chimeras, 25 analyzed as liveborns and 25 as 9.5 day embryos, 29 were a/a in equilibrium A/A and 21 were Ay/a in equilibrium A/A. The absence of Ay/Ay in equilibrium A/A chimeras demonstrates that Ay/Ay cells cannot be rescued in a chimeric environment, and the relative deficiency of Ay/a in equilibrium A/A chimeras suggests that, under certain conditions, Ay heterozygosity may partially affect cell viability or proliferation. In the 25 liveborn chimeras, Ay/a in equilibrium A/A animals became obese as adults and a/a in equilibrium A/A animals did not. There was no correlation between genotypic proportions and rate of weight gain, which shows that, with regard to its effects on weight gain, Ay heterozygosity is cell non-autonomous.