Abstract
In the bracket mushroom, Schizophyllum commune, a recessive genetic alteration, mnd, causes abnormally hyperplastic three‐dimensional mounds of hyphae to rise from the surface of both haploid and dikaryotic mycelia. mnd, although not a genetic block in the fruiting body developmental pathway, is at least partially epistatic to fruiting. Within dikaryons containing both mutant and wild‐type nuclei, [mnd + mnd+], a nonreciprocal somatic recombination event can lead to stable conversion of the mnd+ region of the wild‐type nucleus to mnd. This transformation to the homoallelic [mnd + mnd] condition involves no genomic areas other than the mnd region and permanently prevents any further fruiting. Studies relating to the recombination mechanism have ruled out a diploid intermediate state and other concomitants of orthodox somatic recombination, as well as whole chromosome transfer. Instead, a novel form of internuclear genetic transfer is postulated whereby a nearby locus, mob+, controls the mobilization of the mnd chromosomal region alone from one nucleus to the other within the binucleate cells of dikaryotic mycelia.