Mutations inactivating mitochondrial genes in Chlamydomonas reinhardtii

Chlamydomonas reinhardtii is now becoming a useful model for the study of mitochondrial genetics in a photosynthetic organism. The small (15.8 kb) mitochondrial genome C. reinhardtii has been sequenced completely and all the genes have been identified. Several mutants inactivated in mitochondrial genes encoding components of the respiratory complexes I, III and IV have been characterized at the molecular level. Assembly of complex I in several mutant strains and mapping of mitochondrial mutations by recombinational analysis are also described.

Molecular and Recombinational Mapping of Mutations in the Ace Locus of Drosophila melanogaster

ABSTRACT The Ace locus in Drosophila melanogaster is known to be the structural gene for acetylcholinesterase. Ace is located in a region of chromosome arm 3R which has been subjected to intensive genetic and molecular analysis. Previous deletion mapping studies have identified a 40-kb region within which the Ace gene resides. This report focuses on the further localization of Ace within this 40-kb interval. Within this region, selective fine structure recombinational analysis was employed to localize three recessive Ace lethals relative to unselected restriction site variations. These three mutations fall into a segment of 7 kb within the Ace interval. Fine structure recombinational analysis was also used to confirm that the Ace - phenotype of one deletion, Df(3R)AceHD1, co-segregated with the molecular deletion. This deletion does not fully remove Ace activity, but it behaves as a recessive Ace lethal. Df(3R)AceHD1is the most distal Ace lesion identified and indicates that the Ace locus must extend at least 16 kb. Several poly(A)transcripts are detectable in the region defined by the Ace lesions. The position and extent of the Ace locus, as well as the types of transcripts found, is consistent with the recent findings which identified Torpedo-AChE homologous cDNA sequences in this region.

Fine Structure Recombinational Analysis of Cloned Genes Using Yeast Transformation

ABSTRACT We describe a general method for analyzing the genetic fine structure of plasmid-borne genes in yeast. Previously we had reported that a linearized plasmid is efficiently rescued by recombination with a homologous restriction fragment when these are co-introduced by DNA-mediated transformation of yeast. Here, we show that a mutation can be localized to a small DNA interval when members of a deletion series of wild-type restriction fragments are used in the rescue of a linearized mutant plasmid. The resolution of this method is to at least 30 base pairs and is limited by the loss of a wild-type marker with proximity to a free DNA end. As a means for establishing the nonidentity of two mutations, we determined the resolution of two-point crosses with a mutant linearized plasmid and a mutant homologous restriction fragment. Recombination between mutations separated by as little as 100 base pairs was detected. Moreover, the results indicate that exchange within a marked interval results primarily from one of two single crossovers that repair the linearized plasmid. These approaches to mapping the genetic fine structure of plasmids should join existing methods in a robust approach to the mutational analysis of gene structure in yeast.