Cloning and Expression of Mitochondrial Translational Elongation Factor Ts from Bovine and Human Liver

The sequences of the cDNAs for the mitochondrial translational elongation factor Ts (EF-Tsmt) from bovine and human liver have been obtained. The deduced amino acid sequence of bovine liver EF-Tsmt is 338 residues in length and includes a 55-amino acid signal peptide and a mature protein of 283 residues. The sequence of the mature form of bovine EF-Tsmt is 91% identical to that of human EF-Tsmt and 29% identical to Escherichia coli EF-Ts. Southern analysis indicates that there are two genes for EF-Tsmt in bovine liver chromosomal DNA. A 224-base pair intron is located near the 5'-end of at least one of these genes. Northern analysis using a human multiple tissue blot indicates that EF-Tsmt is expressed in all tissues, with the highest levels of expression in skeletal muscle, liver, and kidney. Both the mature and precursor forms of bovine liver EF-Tsmt have been expressed in E. coli as histidine-tagged proteins. The mature form of EF-Tsmt forms a complex with E. coli elongation factor Tu. This complex is active in poly(U)-directed polymerization of phenylalanine. The precursor form is expressed as a 42-kDa protein, which is rapidly degraded in the cell

A unique tRNA recognition mechanism of Caenorhabditis elegans mitochondrial EF-Tu2

Nematode mitochondria expresses two types of extremely truncated tRNAs that are specifically recognized by two distinct elongation factor Tu (EF-Tu) species named EF-Tu1 and EF-Tu2. This is unlike the canonical EF-Tu molecule that participates in the standard protein biosynthesis systems, which basically recognizes all elongator tRNAs. EF-Tu2 specifically recognizes Ser-tRNA(Ser) that lacks a D arm but has a short T arm. Our previous study led us to speculate the lack of the D arm may be essential for the tRNA recognition of EF-Tu2. However, here, we showed that the EF-Tu2 can bind to D arm-bearing Ser-tRNAs, in which the D–T arm interaction was weakened by the mutations. The ethylnitrosourea-modification interference assay showed that EF-Tu2 is unique, in that it interacts with the phosphate groups on the T stem on the side that is opposite to where canonical EF-Tu binds. The hydrolysis protection assay using several EF-Tu2 mutants then strongly suggests that seven C-terminal amino acid residues of EF-Tu2 are essential for its aminoacyl-tRNA-binding activity. Our results indicate that the formation of the nematode mitochondrial (mt) EF-Tu2/GTP/aminoacyl-tRNA ternary complex is probably supported by a unique interaction between the C-terminal extension of EF-Tu2 and the tRNA

An evolutionary ‘intermediate state’ of mitochondrial translation systems found in Trichinella species of parasitic nematodes: co-evolution of tRNA and EF-Tu

EF-Tu delivers aminoacyl-tRNAs to ribosomes in the translation system. However, unusual truncations found in some animal mitochondrial tRNAs seem to prevent recognition by a canonical EF-Tu. We showed previously that the chromadorean nematode has two distinct EF-Tus, one of which (EF-Tu1) binds only to T-armless aminoacyl-tRNAs and the other (EF-Tu2) binds to D-armless Ser-tRNAs. Neither of the EF-Tus can bind to canonical cloverleaf tRNAs. In this study, by analyzing the translation system of enoplean nematode Trichinella species, we address how EF-Tus and tRNAs have evolved from the canonical structures toward those of the chromadorean translation system. Trichinella mitochondria possess three types of tRNAs: cloverleaf tRNAs, which do not exist in chromadorean nematode mitochondria; T-armless tRNAs; and D-armless tRNAs. We found two mitochondrial EF-Tu species, EF-Tu1 and EF-Tu2, in Trichinella britovi. T.britovi EF-Tu2 could bind to only D-armless Ser-tRNA, as Caenorhabditis elegans EF-Tu2 does. In contrast to the case of C.elegans EF-Tu1, however, T.britovi EF-Tu1 bound to all three types of tRNA present in Trichinella mitochondria. These results suggest that Trichinella mitochondrial translation system, and particularly the tRNA-binding specificity of EF-Tu1, could be an intermediate state between the canonical system and the chromadorean nematode mitochondrial system

Unconventional decoding of the AUA codon as methionine by mitochondrial tRNAMet with the anticodon f5CAU as revealed with a mitochondrial in vitro translation system

Mitochondrial (mt) tRNAMet has the unusual modified nucleotide 5-formylcytidine (f5C) in the first position of the anticodon. This tRNA must translate both AUG and AUA as methionine. By constructing an in vitro translation system from bovine liver mitochondria, we examined the decoding properties of the native mt tRNAMet carrying f5C in the anticodon compared to a transcript that lacks the modification. The native mt Met-tRNA could recognize both AUA and AUG codons as Met, but the corresponding synthetic tRNAMet lacking f5C (anticodon CAU), recognized only the AUG codon in both the codon-dependent ribosomal binding and in vitro translation assays. Furthermore, the Escherichia coli elongator tRNAMetm with the anticodon ac4CAU (ac4C = 4-acetylcytidine) and the bovine cytoplasmic initiator tRNAMet (anticodon CAU) translated only the AUG codon for Met on mt ribosome. The codon recognition patterns of these tRNAs were the same on E. coli ribosomes. These results demonstrate that the f5C modification in mt tRNAMet plays a crucial role in decoding the nonuniversal AUA codon as Met, and that the genetic code variation is compensated by a change in the tRNA anticodon, not by a change in the ribosome. Base pairing models of f5C-G and f5C-A based on the chemical properties of f5C are presented

A Study on Fractal Morphogenesis in Bacteria as a Response to Environmental Stress

Bacteria respond to the biochemical and physiochemical stimuli within their environment by formation of fractal colonies. This phenomenon has been studied and is thought to be the result of chemical signaling between single cells, as well as activation or deactivation of genes and even conjugation. This study was performed to demonstrate fractal morphogenesis in Escherichia coli, a gram negative bacterium, and Micrococcus luteus, a gram positive bacterium, as a response to herbal mixtures and diffusion-limited agar. Actively growing Micrococcus luteus and Escherichia coli were surface plated on standard 12% LB agar, 8% LB agar, 17% LB agar, standard agar + garlic, standard agar + golden seal, standard agar + sage, and differential media eosin methylene blue agar, selective for E. coli, and mannitol salt agar, selective for M. luteus, for 24 to 48 hours at 37?C and 25?C, respectively. Non-fractal colony growth ranged in size from 0.1-1.0mm and fractal colony growth ranged from 3.0-7.5mm in size. All herbs tested: goldenseal, garlic, and sage, proved to encourage fractal growth in hard and soft agar with hard agar being the more promising fractal growth medium. Therefore, hard agar limits the amount of nutrient diffused throughout the agar, promoting fractal growth and development. On all media tested the death rate for bacterium with garlic administered was 50% for M. luteus and 100% for E. coli at 24 hrs. Sage and goldenseal had far less of an effect, with bacterial death rate on all media not overcoming 50% for either E. coli or M. luteus using sage and goldenseal at 24 hrs and 48 hrs, respectively. Colonies surviving displayed fractal growth as well as non-fractal growth. The fractal colonies formed were tested for their viability which showed them remaining viable up to 30 days without refrigeration. These results indicate that bacterial fractal growth and development was promoted as an adaptive response to the use of retardant nutrient dispersal agar and the presence of herbal tinctures as unusual and irregular environment situations

The yeast counterparts of human 'MELAS' mutations cause mitochondrial dysfunction that can be rescued by overexpression of the mitochondrial translation factor EF-Tu

We have taken advantage of the similarity between human and yeast (Saccharomyces cerevisiae) mitochondrial tRNA(Leu)(UUR), and of the possibility of transforming yeast mitochondria, to construct yeast mitochondrial mutations in the gene encoding tRNA(Leu)(UUR) equivalent to the human A3243G, C3256T and T3291C mutations that have been found in patients with the neurodegenerative disease MELAS (for mitochondrial 'myopathy, encephalopathy, lactic acidosis and stroke-like episodes'). The resulting yeast cells (bearing the equivalent mutations A14G, C26T and T69C) were defective for growth on respiratory substrates, exhibited an abnormal mitochondrial morphology, and accumulated mitochondrial DNA deletions at a very high rate, a trait characteristic of severe mitochondrial defects in protein synthesis. This effect was specific at least in the pathogenic mutation T69C, because when we introduced A or G instead of C, the respiratory defect was absent or very mild. All defective phenotypes returned to normal when the mutant cells were transformed by multicopy plasmids carrying the gene encoding the mitochondrial elongation factor EF-Tu. The ability to create and analyse such mutated strains and to select correcting genes should make yeast a good model for the study of tRNAs and their interacting partners and a practical tool for the study of pathological mutations and of tRNA sequence polymorphisms