92 ÍSLENZKAR LANDBÚNAÐARRANNSOKNIR at a given locus might thus show a specific affinity to each other and re- pulsion towards the two chromatids carry- ing a different allele at the same iocus. This might lead to active double nondis- junction which would result in somatic segregation without tetraploidy. The active retention of the A5-allele of an A2A5-ovum by A5-carrying sperm could be assumed to operate in a comparable way, the A5-carry- ing chromosome of the sperm attracting the A5-carrying chromatid of the egg and showing repulsion towards the A2-carrying clnomatid. It is of interest to note in this connec- tion that nonwhite spots in white sheep are relatively frequent. If the nonwhite spots were to be regarded as arising from mutations, one has to assume an unusually liigh mutation frequency in order to ac- count for the nonwhite spots according to Brooker and Dolling (1965). The sanre authors found higher frequency of black spot aninrals arnong known white hetero- zygotes than among the remainder of the population. More recent results by the same authors (Brooker and Dolltng, 1969 b) on Piebald Merinos show that nrany of their Piebald ranrs have been honrozygous wlrite. They conclude that heterozygosity for the gene for white does not affect the occurrence of black spots. On the other hand, one Pie- bald ram known to be heterozygous for the gene for white nrated to heterozygous white ewes gave significantly nrore Piebald off- spring than the Piebald ranrs lronrozygous for the gene for white, when they were nrated to nonwhite ewes. The lack of distinction between tlre dif- ferent recessive A-alleles carried by the wlrite lreterozygotes in their study does not ex- clude tlre possibility that a relation exists between black spots and the A^Aj-geno- type. Somatic segregation in the follicle fornr- ing tissue of AxA5-genotype would be ex- pected to result in black spots. Thus it seems possible that a connection might exist between selective retention of the A5- allele in the A2A5-egg and the frequent black spots in white A^A^-sheep, botlr phenonrena being related to a particular effect of the A5-allele. It nrust be stressed, however, that tlris type of connection is highly speculative and the correct explana- tion of the mechanism leading to selective retention of a chromatid may be of a conr- pletely different nature. K. GENE FREOUENCIES AT THE A-LOCUS The data in the present study have not been collected as a randonr sanrple of colour data fronr the Icelandic sheep population. Calculation of gene frequencies fronr the data on the whole would therefore not give unbiassed estinrates of the true frequencies of the different genes in question. Matings in the present matérial are also known to deviate widely fronr randonrness with re- spect to colour, so any nrethod of estinra- tion which is based on the assumption that the nratings are randonr could not be appli- ed to this material. It was felt, however, tlrat one might ob- tain a picture of one aspect of gene frequ- encies in the present material which would not be appreciably biassed. This consists of counting tlre progeny of each colour obtained from white ewes when matecl to A5A5-sires. The results of this count are shown in table 53, where progeny showing both black and brown pigment have been added for each allele. As table 53 shows, 67.9 per cent of the lanrbs out of the mating in question have been white and the remaining 32.1 per cent nonwlrite. Under assumption of random segregation, the heterozygous white ewes

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