Biogenesis of mitochondria. 52

Summary The characteristics of recombination of several petite (rho ^-) mutants of S. cerevisiae that retain the -influenced region of the mitochondrial genome, identified by the markers cap1-r, ery1-r and tsr1, are described. The petites were derived from an ^– grande (rho ⁺) strain and those petites which retain all three markers show recombination properties similar to those of the ^- parental strain. However, other rho ^- mutants that retain the cap1 and ery1 loci but have lost the tsr1 locus, which is located between cap1 and ery1, show markedly different properties of mitochondrial transmission and recombination, consistent with the presence of ⁺ alleles. The association of an internal deletion between the cap1 and ery1 loci with a change in phenotype provides additional evidence for the location of between these two loci.Although the petites deleted for the tsr1 locus exhibited the recombination properties of ⁺ strains, it was not possible to transmit this characteristic to rho ⁺ recombinant cells. Experiments on the kinetics of elimination by ethidium bromide of the cap1 and eryl markers from the petites and measurements of the buoyant densities of their mtDNA species did not indicate major changes (such as selective sequence repetition) in the sequences of the mtDNAs. The possible nature of the changes in the mtDNAs of these petites is discussed in light of recent studies on the physical nature of the alleles.     

Biogenesis of mitochondria. 53

Summary As shown by gel electrophoresis analysis, E. coli mutant 219 is mutated on the gene coding for S4. This mutant and the parental strain have been studied at the permissive (30°) and the non-permissive temperature (42°) for ribosome assembly and r-protein biosynthesis.The extracts of cells grown at the non-permissive temperature were analyzed by sucrose gradients: Particles sedimenting more slowly (28S) than normal 30S accumulate while 50S precursors undergo maturation and attach to the preformed 30S subunits yielding 70S ribosomes. In addition a small but detectable amount of 30S is also synthesized at 42°. The 28S particles contain all 30S r-proteins except S1, S2 and S12; S5, S7 and S21 are present in reduced amount.The relative rate of biosynthesis of individual r-proteins was determined by pulse-labelling the cells with radioactive leucine. Individual r-proteins were purified from cell extract by the three-dimensional gel electrophoresis technique. The relative rate of biosynthesis of 50S proteins is unchanged in mutant cells grown at 42°. Only the rate of synthesis of five 30S proteins is modified by the temperature shift: S10, S13, S20 and S21 have an increased rate, while S18 is synthesized at a reduced rate. Thus in cells deficient in the assembly of 30S subunits, although the biosynthesis of a few 30S r-proteins is specifically altered, the synthesis of most r-proteins appears to be controlled in the same way as are total cell proteins.     

Biogenesis of mitochondria. 30

Summary Mitchondrial gene recombination in S. cerevisiae was investigated using four combinations of mitochondrial markers: [oli1-r ery1-r], [oli1-r spi2-r], [oli1-r spi3-r] and [oli1-r spi4-r] in cis bifactorial crosses to [oli-s ery-s spi-s] strains. A number of sensitive strains including representatives of both mating types and of diverse origin were used. The crosses were analysed for frequency and polarity of mitochondrial gene recombination as well as the frequency of transmission into the diploid progeny of individual mitochondrial determinants.The results show that the polarity of recombination varied markedly in crosses between a single pair of mitochondrial markers and many unrelated sensitive strains. For example, one series of crosses included polarity values of 1.7,0.34,0.081, and 0.021. Furthermore, there was also considerable variability in frequency of recombination and frequency of transmission of individual markers and these frequencies were not correlated in many cases with polarity values. However, in certain other crosses involving different marker combinations there was a correlation between extreme polarity, high recombination frequency and high transmission frequency of one marker. The results are not compatible with polarity being determined by a simple mitochondrial sex factor and suggest that several different interactions are operating which might include nuclear phenomena.     

Protein sorting in mitochondria.

Most polypeptides that are imported into the mitochondrial matrix use a common translocation machinery. By contrast, proteins of the other mitochondrial compartments are imported by a variety of different mechanisms. Some of these proteins completely bypass the common translocation machinery, others use only the outer membrane components of this machinery, and still others use components of this machinery from both the outer and inner membranes. Import to the intermembrane space compartment provides examples of all three possibilities.     

Interaction theory of mammalian mitochondria.

We generated mice with deletion mutant mtDNA by its introduction from somatic cells into mouse zygotes. Expressions of disease phenotypes are limited to tissues expressing mitochondrial dysfunction. Considering that all these mice share the same nuclear background, these observations suggest that accumulation of the mutant mtDNA and resultant expressions of mitochondrial dysfunction are responsible for expression of disease phenotypes. On the other hand, mitochondrial dysfunction and expression of clinical abnormalities were not observed until the mutant mtDNA accumulated predominantly. This protection is due to the presence of extensive and continuous interaction between exogenous mitochondria from cybrids and recipient mitochondria from embryos. Thus, we would like to propose a new hypothesis on mitochondrial biogenesis, interaction theory of mitochondria: mammalian mitochondria exchange genetic contents, and thus lost the individuality and function as a single dynamic cellular unit.     

Origins of mitochondria and hydrogenosomes.

Complete genome sequences for many mitochondria, as well as for some bacteria, together with the nuclear genome sequence of yeast have provided a coherent view of the origin of mitochondria. In particular, conventional phylogenetic reconstructions with genes coding for proteins active in energy metabolism and translation have confirmed the simplest version of the endosymbiosis hypothesis. In contrast, the hydrogen and the syntrophy hypotheses for the origin of mitochondria do not receive support from the available data. It remains to be seen how the evolution of hydrogenosomes is related to that of mitochondria.     

Preparation of rat enterocyte mitochondria.

Rat enterocyte mitochondria were prepared with respiratory control ratios of 4 or 5 and occasionally 6. When EGTA was excluded from the mitochondrial incubation medium the calculated P/O ratios were high, especially those based on the first addition of ADP. These ratios were lowered by increasing the EGTA concentration from 1 mM to 2 mM in the mitochondrial preparation medium and including 1 mM-EGTA in the incubation medium. The use of EDTA in the enterocyte isolation medium led to the mitochondria requiring added cytochrome c. Substituting EGTA for EDTA abolished this requirement. The mitochondrial fraction consisted of two components, an upper cream-coloured layer rich in DNA and a lower brown-coloured layer poor in DNA. Both components were capable of oxidative phosphorylation with succinate or the glutamate/malate couple as substrates. The mitochondrial yield was assessed by assaying succinate dehydrogenase activity, and the contamination of the mitochondrial fraction by other cell organelles was assessed by assays for appropriate marker enzymes.     

Population dynamics of mitochondria II. Turnover and ageing of rat liver mitochondria

Membrane-bound multi-protein complexes in mitochondria are provisionally classified into four categories based on possible mechanism of their assembly and degradation. These mechanisms may be investigated by the use of pulse-labeled radioactive markers which are not re-utilizable. Age dependent assembly is defined as that mechanism by which one or more of the pulse-labeled subunits are assembled into a complex, only while this complex is assembled. If the labeled sub-units can be taken up by the complex randomly during its life-span, then the mechanism is called age-independent assembly. Age-dependent degradation was defined as that mechanism by which the labeled subunits are decomposed, only when the complex is being degraded as an entity. If the labeled subunits are decomposed randomly, the mechanism is called age-independent degradation. Four categories are made by combining each of the assembly and degradation mechanisms. A differential equation was obtained to describe the fate of labeled sub-units that follow the age-dependent assembly and age-dependent degradation. Also derived was an equation for the age-independent assembly and age-dependent degradation. The other two categories which involve the age-independent degradation after age-dependent or age-independent assembly are described by single exponential kinetics. Practical application of the equations is illustrated with the use of experimental data on mitochondrial turnover found in the literature which suggests that the pulse-labeled proteins in rat liver mitochondria may follow the age-dependent assembly and degradation. The present attempts to introduce the concept of ageing into multi-protein complexes in mitochondria are the extensions of the steady state theory of mutation by Eyring & Stover (1970).