Increase of proton electrochemical potential and ATP synthesis in rat liver mitochondria irradiated in vitro by helium-neon laser

Particulate adenylate cyclase (AC) and guanylate cyclase (GC) activities localized in the ciliary membrane from Paramecium were solubilized by a two-step procedure using the detergents Brij 56 and Lubrol PX. The enzymes remained in the supernatant after a 100 000 × g centrifugation. Upon gel chromatography, AC and GC were almost completely separated proving that each enzyme is a distinct molecular entity. Solubilization of GC was achieved with the calmodulin subunit remaining firmly attached to the catalytic part. Antibodies against calmodulin inhibited the enzyme as did La³⁺ and EGTA. AC activity appeared to be regulated specifically by K⁺, enzyme activity being enhanced up to 100% by 15 mM K⁺. Na⁺ and Li⁺ were inactive.     

Characterization of protein synthesis by isolated rice mitochondria

Summary Bacteria-free mitochondria were isolated from aseptically grown, etiolated and green seedlings of both cytoplasmic male-sterile (WA-type) and male-fertile rice (Oryza sativa L.). Protein synthesis in these isolated mitochondria was characterized by gel electrophoresis/fluorography and by the incorporation of [³⁵S]-methionine into protein. In the presence of cycloheximide, a set of some 25 discrete polypeptides and an electrophoretically unresolved population were synthesized. This pattern of protein synthesis in organello was essentially the same in mitochondria isolated from both male-fertile and malesterile cytoplasms. Our data does not preclude the possibility, however, that the WA-type CMS possesses a tissue-specific and/or a low abundance mitochondrial protein(s), whose synthesis eluded detection under our experimental conditions. The synthesis of the mitochondria-encoded polypeptides by isolated rice mitochondria was inhibited by chloramphenicol and incompletely inhibited by erythromycin. A minor chloramphenicol-insensitive, cycloheximide-sensitive translation activity was found consistently to copurify with the mitochondria. This activity generated a reproducible electrophoretic profile of a poorly resolved, weakly labelled population of polypeptides and of a few conspicuous polypeptides, including a 42 kDa species.     

Ribosomal RNA synthesis in mitochondria of Neurospora crassa

Ribosomal RNA synthesis in Neurospora crassa mitochondria has been investigated by continuous labeling with [5-³H]uracil and pulse-chase experiments. A short-lived 32 S mitochondrial RNA was detected, along with two other short-lived components; one slightly larger than large subunit ribosomal RNA, and the other slightly larger than small subunit ribosomal RNA. The experiments give support to the possibility that 32 S RNA is the precursor of large and small subunit ribosomal RNA's. Both mature ribosomal RNA's compete with 32 S RNA in hybridization to mitochondrial DNA. Quantitative results from such hybridization-competition experiments along with measurements of electrophoretic mobility have been used to construct a molecular size model for synthesis of mitochondrial ribosomal RNA's. The large molecular weight precursor (32 S) of both ribosomal RNA's appears to be 2.4 × 10⁶ daltons in size. Maturation to large subunit RNA (1.28 × 10⁶ daltons) is assumed to involve an intermediate ~1.6 × 10⁶ daltons in size, while cleavage to form small subunit RNA (0.72 × 10⁶ daltons) presumably involves a 0.9 × 10⁶ dalton intermediate. In the maturation process ~22% of the precursor molecule is lost. As is the case for ribosomal RNA's, the mitochondrial precursor RNA has a strikingly low G + C content.     

Interferon inhibition of protein synthesis by isolated mitochondria.

Exogenously added EMC-RNA can stimulate the incorporation of [³H] leucine into protein carried out by mitochondria isolated from L cells, and this stimulation is reduced very significantly if the mitochondria are isolated from cells previously treated with interferon.     

Termination of protein synthesis in mammalian mitochondria

All mechanisms of protein synthesis can be considered in four stages: initiation, elongation, termination, and ribosome recycling. Remarkable progress has been made in understanding how these processes are mediated in the cytosol of many species; however, details of organellar protein synthesis remain sketchy. This is an important omission, as defects in human mitochondrial translation are known to cause disease and may contribute to the aging process itself. In this minireview, we focus on the recent advances that have been made in understanding how one of these processes, translation termination, occurs in the human mitochondrion.