Electrophoretic behaviour of yeast mitochondrial translation products.

We have studied the mobility of yeast mitochondrial translation products during electrophoresis on polyacrylamide gels of different composition and found that these polypeptides can be divided into two groups. One, to which subunit II of cytochrome c oxidase belongs, behaves normal as all water-soluble reference proteins. The other, to which cytochrome b and subunits I and III of cytochrome c oxidase belong, shows a free electrophoretic mobility about twice as fast as the first group. Conditions have been found to separate cytochrome c1 from cytochrome b.

Rapid screening of multiple forensic stains by SSCP analysis of HLA-DQ alpha amplification products.

Single strand conformation polymorphism (SSCP) analysis was performed with HLA-DQ alpha amplification products. The various HLA-DQ alpha genotypes reveal different SSCP patterns. These are reproducible in DNA preparations from unrelated persons with identical HLA-DQ alpha genotype. However, in one of the more frequent HLA-DQ alpha genotypes (1.1/4) two variant SSCP patterns were observed. SSCP analysis allows rapid low-cost screening of many specimens and is an alternative discrimination test of stains beside reverse dot blot hybridization.

Genetic analysis of forest tree populations: isolation of DNA from spruce and fir apices.

A method is described for the isolation of DNA from spruce and fir, starting with 3 to 5 apices (5 mg material). Apices are prepared manually from dormant buds harvested in summer and autumn, which are homogenized in 30 microliters buffer containing 1% SDS. The DNA is extracted with phenol and precipitated with ethanol. Agarose gel electrophoresis and Southern hybridization show that its molecular length is ca. 30-40 kb and that it is readily digested with various restriction enzymes. The method is very fast, it does not need CsCl centrifugation and is therefore suited for the analysis of large numbers of individual trees. Moreover, the buds can be collected all over the year. The yield of the method is up to 30 micrograms of high molecular weight DNA, enough to do several digests and hybridizations.

Sex determination and DNA competition in the analysis of forensic mixed stains by PCR.

Sex determination of pure and mixed blood samples and stains was performed by amplification of the X-specific and Y-specific alphoid sequences by PCR (XY-PCR). From mixed blood samples with female DNA present in large excess of male DNA, the Y-specific sequence still amplified efficiently. In the analysis of vaginal secretions in a case of sexual assault, XY-PCR was performed to test the efficiency of the selective lysis procedure in order to investigate whether alleles found with other PCR systems were of male or female origin. Our studies with mixed blood samples revealed pronounced DNA competition in the HLA-DQ alpha and D1S80 PCR systems: the alleles from a minor DNA component could not be detected in the presence of a large excess of DNA from a second person.

Isolation and characterization of human DNA from mosquitoes (Culicidae).

Human DNA was prepared from mosquitoes (Culicidae) which were collected in a room shared by four human individuals. Several insects did not contain human blood and DNA preparation from them was not successful. However, high molecular weight human genomic DNA could be isolated from four insects. HLA-DQalpha and D1S80 analysis showed that the blood from one insect was a mixture from two persons, whereas the others contained blood from single individuals. Human DNA isolated 26 h after ingestion was still suitable for typing. These results showed that DNA isolated from mosquitoes is qualitatively and quantitatively sufficient for DNA typing and could be helpful to identify individuals involved in certain cases of body violence or captivity.

A yeast nuclear gene, MRS1, involved in mitochondrial RNA splicing: nucleotide sequence and mutational analysis of two overlapping open reading frames on opposite strands.

We have cloned a 1.6-kb fragment of yeast nuclear DNA, which complements pet- mutant MK3 (mrs1). This mutant was shown to be defective in mitochondrial RNA splicing: the excision of intron 3 from the mitochondrial COB pre-RNA is blocked. The DNA sequence of the nuclear DNA fragment revealed two open reading frames (ORF1 with 1092 bp; ORF2 with 735 bp) on opposite strands, which overlap by 656 bp. As shown by in vitro mutagenesis, ORF1, but not ORF2, is responsible for complementation of the splice defect. Hence, ORF1 represents the nuclear MRS1 gene. Disruption of the gene (both ORFs) in the chromosomal DNA of the respiratory competent yeast strain DBY747 (long form COB gene) leads to a stable pet- phenotype and to the accumulation of the same mitochondrial RNA precursors as in strain MK3. The amino acid sequence of the putative ORF1 product does not exhibit any homology with other known proteins, except for a small region of homology with the gene product of another nuclear yeast gene involved in mitochondrial RNA splicing, CBP2. The function of the MRS1 (ORF1) gene in mitochondrial RNA splicing and the significance of the overlapping ORFs in this gene are discussed.

Molecular cloning of the yeast nuclear genes CBS1 and CBS2.

The yeast nuclear genes CBS1 and CBS2 are both required for translation of the mitochondrial COB transcripts. Here we report on the identification of two unique chromosomal DNA-sequences of 2 kb and 2.3 kb from yeast wild type gene banks which functionally complement cbs1 and cbs2 mutants, respectively. Disruption of the homologous DNA-fragments by insertion of the URA3 gene generates respiratory deficient cells which fail to complement the original mutants. Cells with these gene disruptions are phenotypically identical to the original cbs1 and cbs2 mutants with respect to cytochrome spectra and mitochondrial translation products. The results exclude the possibility that suppressor genes have been cloned and confirm the conclusion that both genes, CBS1 and CBS2, specifically are involved in translation of mitochondrial COB RNA.

Cloning of a nuclear gene MRS1 involved in the excision of a single group I intron (bI3) from the mitochondrial COB transcript in S. cerevisiae.

The respiratory deficient yeast nuclear mutant MK3 is defective in the synthesis of the mature transcripts of the mitochondrial COB and OX13 genes, which code for apocytochrome b and subunit I of cytochrome c oxidase, resp. Introns 3 and 4 of the COB transcript (bI3 and bI4) and intron 4 (aI4) of the OXI3 transcript can not be excised (Pillar et al. 1983a, b). When combined with mitochondrial genomes lacking introns bI1, bI2 and bI3, or lacking intron bI3 alone the mutant is respiratory competent. Thus, the non-excision of bI4 and aI4 turns out to be an indirect effect of the mutation. From a wild type yeast genebank a plasmid has been isolated with a 3.3 kb DNA insert, which complements the mutant. Subcloning experiments assigned the functional gene to a 1.6 kb HaeIII-Sau3A fragment. Hybridization experiments showed, that it is (i) a single copy gene, (ii) also present in strain D273-10B, containing the "short form" mitochondrial genome (lacking the COB introns bI1-bI3), and (iii) located on chromosome IX. The nuclear gene defective in mutant MK3, was named MRS1 (Mitochondrial RNA Splicing). The involvement of this nuclear gene in the excision of a single group I mitochondrial intron (bI3) of the COB transcript is discussed.

The biosynthesis of the ubiquinol-cytochrome c reductase complex in yeast. DNA sequence analysis of the nuclear gene coding for the 14-kDa subunit.

The nuclear gene coding for the imported 14-kDa subunit of the ubiquinol-cytochrome c reductase of yeast mitochondria has been sequenced in an attempt to define regulatory and protein topogenic elements. The gene has a length of 381 base pairs and is potentially capable of encoding a polypeptide of 14561 Da. It is transcribed into a single low-abundance RNA of 680 nucleotides whose 5' and 3' termini map, respectively, 30-35 nucleotides upstream and 180-190 nucleotides downstream of the initiator and termination codons. Consistent with the estimated low level of the mRNA, codon usage in the gene is not strongly biased and other features, characteristic of highly expressed genes in yeast, are absent. The 14-kDa protein is predicted to be a predominantly hydrophilic protein, with only a single, short hydrophobic stretch located between positions 19-38. Comparison with other imported mitochondrial proteins so far sequenced has failed to reveal unifying features that might serve as targeting elements. Steady-state levels of the 14-kDa and 11-kDa subunits are reduced in mit- mutants which synthesize truncated forms of apocytochrome b and in these, newly synthesized subunits exhibit a specifically increased turnover rate. We suggest that association of these two subunits with the complex may be mediated or enhanced by interaction with other subunits, in particular cytochrome b.

Identification of a RAPD marker linked to the pendula gene in Norway spruce (Picea abies (L.) Karst. f. pendula).

The pendula phenotype of Norway spruce [Picea abies (L.) Karst f. pendula] is characterized by narrow crowns and strong apical dominance and is controlled by a single dominant gene (P). This defined genetic control presents one of the few opportunities to map a single gene controlling a morphological trait in a forest tree. We used random amplified polymorphic DNA (RAPD) markers and bulked segregant analysis to identify one locus OPH10_720, linked to the pendula gene. The estimated recombination frequency (r) between OPH10_720 and P was 0.046 (SE r =0.032). Mapping of the pendula gene is an important first step towards the ultimate identification and cloning of this gene.

The identification of apocytochrome b as a mitochondrial gene product and immunological evidence for altered apocytochrome b in yeast strains having mutations in the COB region of mitochondrial DNA.

The yeast mitochondrial translation product of Mr 30 000 is identical with apocytochrome b. After labelling in vivo with [35S]sulphate in the presence of cycloheximide, the radioactivity in this product present in solubilized submitochondrial particles, was completely recovered in pure cytochrome bc1 complex as a single polypeptide. We show that this translation product is identical with apocytochrome b using peptide mapping by limited proteolysis according to Cleveland et al. [J. Biol. Chem. 250 (1977) 8236-8242] and by immunoprecipitation with a specific antiserum against apocytochrome b. New mitochondrial translation products in 36 strains of Saccharomyces cerevisiae having mutations in the COB region of the mitochondrial DNA, are precipitated by this antiserum. This is consistent with the assumption that many of the cob mutations are localized in the structural gene for apolcytochrome b on mitochondrial DNA. Mutations in two intervening sequences can give rise to products related to apocytochrome b that are considerably longer than normal apocytochrome b. We discuss the hypothesis that in these mutants splicing of the messenger RNA does not occur correctly and that, as a consequence of this, ribosomes read through in an intervening sequence.

Biosynthesis of the ubiquinol-cytochrome c reductase complex in yeast. Characterization of precursor forms of the 44-kDa, 40-kDa and 17-kDa subunits and identification of individual messenger RNAs for these and other imported subunits of the complex.

The mitochondrial ubiquinol--cytochrome c reductase complex (complex III or cytochrome bc1 complex) is thought to consist of eight subunits, seven of which are specified by nuclear genes and synthesized in the cytoplasm. We have studied the synthesis of five of the nuclear-encoded subunits both in vivo and in vitro and show that of these the 44-kDa, 40-kDa and 17-kDa subunits are synthesized with cleavable extensions, while the 14-kDa and 11-kDa proteins are synthesized without detectable extra sequences. The sizes of the pre-sequences, as determined by the relative mobility of the precursor proteins in sodium dodecyl sulphate/polyacrylamide gels, range from 0.5-kDa for the 44-kDa and 40-kDa subunits to 9-kDa for the 17-kDa subunit. The existence in vivo of precursor forms to the 44-kDa, 40-kDa and 17-kDa subunits implies that import is at least partially a post-translational process. The precursor of the 44-kDa subunit can be processed post-translationally in vitro by isolated mitochondria. The messenger RNAs for subunits of the complex have been studied. Those coding for the 44-kDa, 40-kDa, 14-kDa and 11-kDa proteins and cytochrome c1 are of different sizes, indicating that each of these subunits is synthesized as a separate protein, rather than as part of a polyprotein precursor.