scholarly journals A novel small-subunit ribosomal protein of yeast mitochondria that interacts functionally with an mRNA-specific translational activator.

1990 ◽  
Vol 10 (9) ◽  
pp. 4590-4595 ◽  
Author(s):  
T W McMullin ◽  
P Haffter ◽  
T D Fox
Keyword(s):  
Ribosomal Protein ◽  
Ribosomal Proteins ◽  
Mitochondrial Gene ◽  
Ribosomal Subunit ◽  
Nuclear Gene ◽  
Small Subunit ◽  
Rrna Gene ◽  
Mitochondrial Translation ◽  
Activator Proteins ◽  
Translational Activator

Mitochondrial translation of the mRNA encoding cytochrome c oxidase subunit III (coxIII) specifically requires the action of three position activator proteins encoded in the nucleus of Saccharomyces cerevisiae. Some mutations affecting one of these activators, PET122, can be suppressed by mutations in an unlinked nuclear gene termed PET123. PET123 function was previously demonstrated to be required for translation of all mitochondrial gene products. We have now generated an antibody against the PET123 protein and have used it to demonstrate that PET123 is a mitochondrial ribosomal protein of the small subunit. PET123 appears to be present at levels comparable to those of other mitochondrial ribosomal proteins, and its accumulation is dependent on the presence of the 15S rRNA gene in mitochondria. Taken together with the previous genetic data, these results strongly support a model in which the mRNA-specific translational activator PET122 works by directly interacting with the small ribosomal subunit to promote translation initiation on the coxIII mRNA.

A novel small-subunit ribosomal protein of yeast mitochondria that interacts functionally with an mRNA-specific translational activator

1990 ◽  
Vol 10 (9) ◽  
pp. 4590-4595
Author(s):  
T W McMullin ◽  
P Haffter ◽  
T D Fox
Keyword(s):  
Ribosomal Protein ◽  
Ribosomal Proteins ◽  
Mitochondrial Gene ◽  
Ribosomal Subunit ◽  
Nuclear Gene ◽  
Small Subunit ◽  
Rrna Gene ◽  
Mitochondrial Translation ◽  
Activator Proteins ◽  
Translational Activator

Mitochondrial translation of the mRNA encoding cytochrome c oxidase subunit III (coxIII) specifically requires the action of three position activator proteins encoded in the nucleus of Saccharomyces cerevisiae. Some mutations affecting one of these activators, PET122, can be suppressed by mutations in an unlinked nuclear gene termed PET123. PET123 function was previously demonstrated to be required for translation of all mitochondrial gene products. We have now generated an antibody against the PET123 protein and have used it to demonstrate that PET123 is a mitochondrial ribosomal protein of the small subunit. PET123 appears to be present at levels comparable to those of other mitochondrial ribosomal proteins, and its accumulation is dependent on the presence of the 15S rRNA gene in mitochondria. Taken together with the previous genetic data, these results strongly support a model in which the mRNA-specific translational activator PET122 works by directly interacting with the small ribosomal subunit to promote translation initiation on the coxIII mRNA.

scholarly journals Functional interactions among two yeast mitochondrial ribosomal proteins and an mRNA-specific translational activator.

Genetics ◽  
1991 ◽  
Vol 127 (2) ◽  
pp. 319-326
Author(s):  
P Haffter ◽  
T W McMullin ◽  
T D Fox
Keyword(s):  
Ribosomal Proteins ◽  
Mitochondrial Gene ◽  
Nuclear Gene ◽  
Small Subunit ◽  
Mitochondrial Ribosomes ◽  
Gene Coding ◽  
Allele Specific ◽  
Carboxyl Terminal ◽  
Translational Activator ◽  
Carboxy Terminal

Abstract Expression of the Saccharomyces cerevisiae mitochondrial gene coding cytochrome c oxidase subunit III is specifically activated at the level of translation by at least three nuclear genes, PET122, PET494 and PET54. We have shown previously that carboxy-terminal deletions of PET122 are allele-specifically suppressed by mutations in an unlinked nuclear gene, termed PET123, that encodes a small subunit ribosomal protein. Here we describe additional pet122 suppressors generated by mutations in a second gene which we show to be the previously identified nuclear gene MRP1. Like PET123, MRP1 encodes a component of the small subunit of mitochondrial ribosomes. Our mrp1 mutations are allele-specific suppressors of carboxyl-terminal truncations of the PET122 protein and do not bypass the requirement for residual function of PET122. None of our mrp1 mutations has an intrinsic phenotype in an otherwise wild-type background. However, some of the mrp1 mutations cause a non-conditional respiratory-defective phenotype in combination with certain pet123 alleles. This synthetic defective phenotype suggests that the ribosomal proteins PET123 and MRP1 interact functionally with each other. The fact that they can both mutate to suppress certain alleles of the mRNA-specific translational activator PET122 strongly suggests that the PET122 protein promotes translation of the coxIII mRNA via an interaction with the small subunit of mitochondrial ribosomes.

Reduced dosage of genes encoding ribosomal protein S18 suppresses a mitochondrial initiation codon mutation in Saccharomyces cerevisiae.

Genetics ◽  
1994 ◽  
Vol 137 (2) ◽  
pp. 369-379 ◽  
Author(s):  
L S Folley ◽  
T D Fox
Keyword(s):  
Ribosomal Protein ◽  
Translation Initiation ◽  
Ribosomal Proteins ◽  
Ribosomal Subunit ◽  
Initiation Codon ◽  
Cold Sensitivity ◽  
Mitochondrial Translation ◽  
Ribosomal Subunits ◽  
Translational Accuracy ◽  
Codon Mutation

Abstract A yeast mitochondrial translation initiation codon mutation affecting the gene for cytochrome oxidase subunit III (COX3) was partially suppressed by a spontaneous nuclear mutation. The suppressor mutation also caused cold-sensitive fermentative growth on glucose medium. Suppression and cold sensitivity resulted from inactivation of the gene product of RPS18A, one of two unlinked genes that code the essential cytoplasmic small subunit ribosomal protein termed S18 in yeast. The two S18 genes differ only by 21 silent substitutions in their exons; both are interrupted by a single intron after the 15th codon. Yeast S18 is homologous to the human S11 (70% identical) and the Escherichia coli S17 (35% identical) ribosomal proteins. This highly conserved family of ribosomal proteins has been implicated in maintenance of translational accuracy and is essential for assembly of the small ribosomal subunit. Characterization of the original rps18a-1 missense mutant and rps18a delta and rps18b delta null mutants revealed that levels of suppression, cold sensitivity and paromomycin sensitivity all varied directly with a limitation of small ribosomal subunits. The rps18a-1 mutant was most affected, followed by rps18a delta then rps18b delta. Mitochondrial mutations that decreased COX3 expression without altering the initiation codon were not suppressed. This allele specificity implicates mitochondrial translation in the mechanism of suppression. We could not detect an epitope-tagged variant of S18 in mitochondria. Thus, it appears that suppression of the mitochondrial translation initiation defect is caused indirectly by reduced levels of cytoplasmic small ribosomal subunits, leading to changes in either cytoplasmic translational accuracy or the relative levels of cytoplasmic translation products.

scholarly journals Ribosome Biogenesis in African Trypanosomes Requires Conserved and Trypanosome-Specific Factors

2014 ◽  
Vol 13 (6) ◽  
pp. 727-737 ◽  
Author(s):  
Khan Umaer ◽  
Martin Ciganda ◽  
Noreen Williams
Keyword(s):  
Ribosomal Protein ◽  
Ribosomal Proteins ◽  
Ribosome Biogenesis ◽  
Large Subunit ◽  
Ribosomal Subunit ◽  
Small Subunit ◽  
5S Rrna ◽  
Content Type ◽  
African Trypanosomes ◽  
Ribosomal Protein L5

ABSTRACTLarge ribosomal subunit protein L5 is responsible for the stability and trafficking of 5S rRNA to the site of eukaryotic ribosomal assembly. InTrypanosoma brucei, in addition to L5, trypanosome-specific proteins P34 and P37 also participate in this process. These two essential proteins form a novel preribosomal particle through interactions with both the ribosomal protein L5 and 5S rRNA. We have generated a procyclic L5 RNA interference cell line and found that L5 itself is a protein essential for trypanosome growth, despite the presence of other 5S rRNA binding proteins. Loss of L5 decreases the levels of all large-subunit rRNAs, 25/28S, 5.8S, and 5S rRNAs, but does not alter small-subunit 18S rRNA. Depletion of L5 specifically reduced the levels of the other large ribosomal proteins, L3 and L11, whereas the steady-state levels of the mRNA for these proteins were increased. L5-knockdown cells showed an increase in the 40S ribosomal subunit and a loss of the 60S ribosomal subunits, 80S monosomes, and polysomes. In addition, L5 was involved in the processing and maturation of precursor rRNAs. Analysis of polysomal fractions revealed that unprocessed rRNA intermediates accumulate in the ribosome when L5 is depleted. Although we previously found that the loss of P34 and P37 does not result in a change in the levels of L5, the loss of L5 resulted in an increase of P34 and P37 proteins, suggesting the presence of a compensatory feedback loop. This study demonstrates that ribosomal protein L5 has conserved functions, in addition to nonconserved trypanosome-specific features, which could be targeted for drug intervention.

Structural organization of escherichia coli ribosomes as determined by immuno electron microscopy

1978 ◽  
Vol 36 (2) ◽  
pp. 166-167 ◽  
Author(s):  
G. Stöffler ◽  
R.W. Bald ◽  
J. Dieckhoff ◽  
H. Eckhard ◽  
R. Lührmann ◽  
...  
Keyword(s):  
Electron Microscopy ◽  
Escherichia Coli ◽  
Ribosomal Proteins ◽  
Structural Organization ◽  
Three Dimensional ◽  
Ribosomal Subunit ◽  
Spatial Arrangement ◽  
Small Subunit ◽  
Antibody Binding ◽  
Immuno Electron Microscopy

A central step towards an understanding of the structure and function of the Escherichia coli ribosome, a large multicomponent assembly, is the elucidation of the spatial arrangement of its 54 proteins and its three rRNA molecules. The structural organization of ribosomal components has been investigated by a number of experimental approaches. Specific antibodies directed against each of the 54 ribosomal proteins of Escherichia coli have been performed to examine antibody-subunit complexes by electron microscopy. The position of the bound antibody, specific for a particular protein, can be determined; it indicates the location of the corresponding protein on the ribosomal surface.The three-dimensional distribution of each of the 21 small subunit proteins on the ribosomal surface has been determined by immuno electron microscopy: the 21 proteins have been found exposed with altogether 43 antibody binding sites. Each one of 12 proteins showed antibody binding at remote positions on the subunit surface, indicating highly extended conformations of the proteins concerned within the 30S ribosomal subunit; the remaining proteins are, however, not necessarily globular in shape (Fig. 1).

scholarly journals Halobacterium cutirubrum ribosomes. Properties of the ribosomal proteins and ribonucleic acid

1972 ◽  
Vol 130 (1) ◽  
pp. 103-110 ◽  
Author(s):  
L. P. Visentin ◽  
C. Chow ◽  
A. T. Matheson ◽  
M. Yaguchi ◽  
F. Rollin
Keyword(s):  
Ribosomal Protein ◽  
Ribosomal Proteins ◽  
Soluble Fraction ◽  
Ribosomal Subunit ◽  
23S Rrna ◽  
Core Particle ◽  
Fractionation Procedure ◽  
Additional Protein ◽  
70S Ribosome ◽  
Low Ionic Strength

1. The 30S ribosomal subunit of the extreme halophile Halobacterium cutirubrum is unstable and loses 75% of its ribosomal protein when the 70S ribosome is dissociated into the two subunits. A stable 30S subunit is obtained if the dissociation of the 70S particle is carried out in the presence of the soluble fraction. 2. A fractionation procedure was developed for the selective removal of groups of proteins from the 30S and 50S subunits. When the ribosomes, which are stable in 4m-K+ and 0.1m-Mg2+, were extracted with low-ionic-strength buffer 75–80% of the 30S proteins and 60–65% of the 50S proteins as well as the 5S rRNA were released. The proteins in this fraction are the most acidic of the H. cutirubrum ribosomal proteins. Further extraction with Li+–EDTA releases additional protein, leaving a core particle containing either 16S rRNA or 23S rRNA and about 5% of the total ribosomal protein. The amino acid composition, mobility on polyacrylamide gels at pH4.5 and 8.7, and the molecular-weight distribution of the various protein fractions were determined. 3. The s values of the rRNA are 5S, 16S and 23S. The C+G contents of the 16S and 23S rRNA were 56.1 and 58.8% respectively and these are higher than C+G contents of the corresponding Escherichia coli rRNA (53.8 and 54.1%).

Ribosomal protein S14 is altered by two-step emetine resistance mutations in Chinese hamster cells

1983 ◽  
Vol 3 (2) ◽  
pp. 190-197
Author(s):  
J J Madjar ◽  
M Frahm ◽  
S McGill ◽  
D J Roufa
Keyword(s):  
Ribosomal Protein ◽  
Ribosomal Proteins ◽  
Ribosomal Subunit ◽  
Chinese Hamster ◽  
Complementation Group ◽  
Resistance Mutations ◽  
Cho Cell ◽  
Ribosomal Subunits ◽  
40S Ribosomal Subunit ◽  
One Step

Four two-dimensional polyacrylamide gel electrophoresis systems were used to identify 78 Chinese hamster cell ribosomal proteins by the uniform nomenclature based on rat liver ribosomal proteins. The 40S ribosomal subunit protein affected by Chinese hamster ovary (CHO) cell one-step emetine resistance mutations is designated S14 in the standard nomenclature. To seek unambiguous genetic evidence for a cause and effect relationship between CHO cell emetine resistance and mutations in the S14 gene, we mutagenized a one-step CHO cell mutant and isolated second-step mutant clones resistant to 10-fold-higher concentrations of emetine. All of the highly resistant, two-step CHO cell mutants obtained displayed additional alterations in ribosomal protein S14. Hybridization complementation tests revealed that the two-step CHO cell emetine resistance mutants were members of the same complementation group defined by one-step CHO cell mutants, EmtB. Two-step mutants obtained from a Chinese hamster lung cell emetine-resistant clone belong to the EmtA complementation group. The two-step and EmtB mutants elaborated 40S ribosomal subunits, which dissociated to 32S and 40S core particles in buffers containing 0.5 M KCl at 4 degrees C. In contrast, 40S ribosomal subunits purified from all EmtA, one-step EmtB EmtC mutants, and wild-type CHO and lung cells were stable at this temperature in buffers containing substantially higher concentrations of salt. Thus, two-step emtB mutations affect the structure of S14 protein directly and the stability of the 40S ribosomal subunit indirectly.

scholarly journals The ribosome receptors Mrx15 and Mba1 jointly organize cotranslational insertion and protein biogenesis in mitochondria

2018 ◽  
Vol 29 (20) ◽  
pp. 2386-2396 ◽  
Author(s):  
Braulio Vargas Möller-Hergt ◽  
Andreas Carlström ◽  
Katharina Stephan ◽  
Axel Imhof ◽  
Martin Ott
Keyword(s):  
Membrane Protein ◽  
Mitochondrial Gene ◽  
Ribosomal Subunit ◽  
Mitochondrial Translation ◽  
Protein Insertion ◽  
Mitochondrial Ribosomes ◽  
Protein Biogenesis ◽  
Membrane Bound ◽  
Highly Hydrophobic ◽  
Soluble C

Mitochondrial gene expression in Saccharomyces cerevisiae is responsible for the production of highly hydrophobic subunits of the oxidative phosphorylation system. Membrane insertion occurs cotranslationally on membrane-bound mitochondrial ribosomes. Here, by employing a systematic mass spectrometry–based approach, we discovered the previously uncharacterized membrane protein Mrx15 that interacts via a soluble C-terminal domain with the large ribosomal subunit. Mrx15 contacts mitochondrial translation products during their synthesis and plays, together with the ribosome receptor Mba1, an overlapping role in cotranslational protein insertion. Taken together, our data reveal how these ribosome receptors organize membrane protein biogenesis in mitochondria.

A genetic link between an mRNA-specific translational activator and the translation system in yeast mitochondria.

Genetics ◽  
1990 ◽  
Vol 125 (3) ◽  
pp. 495-503 ◽  
Author(s):  
P Haffter ◽  
T W McMullin ◽  
T D Fox
Keyword(s):  
Mitochondrial Gene ◽  
Mitochondrial Protein ◽  
Open Reading Frame ◽  
Null Alleles ◽  
Translation System ◽  
Amino Acid Residues ◽  
Mitochondrial Translation ◽  
Reading Frame ◽  
Large Deletions ◽  
Translational Activator

Abstract Translation of the Saccharomyces cerevisiae mitochondrial mRNA encoding cytochrome c oxidase subunit III (coxIII) specifically requires the products of at least three nuclear genes, PET122, PET494 and PET54. pet122 mutations that remove 24-67 amino acid residues from the carboxyterminus of the gene product were found to be suppressed by unlinked nuclear mutations. These unlinked suppressors fail to suppress both a pet122 missense mutation and a complete pet122 deletion. One of the suppressor mutations causes a heat-sensitive nonrespiratory growth phenotype in an otherwise wild-type strain and reduces translation of all mitochondrial gene products in cells grown at high temperature. This suppressor maps to a newly identified gene on chromosome XV termed PET123. The sequence of a DNA fragment carrying PET123 contains one major open reading frame encoding a basic protein of 318 amino acids. Inactivation of the chromosomal copy of PET123 by interruption of this open reading frame causes cells to become rho- (sustain large deletions in their mtDNA). This phenotype is characteristic for null alleles of genes whose products are essential for general mitochondrial protein synthesis. Thus our data strongly suggest that the PET123 protein is a component of the mitochondrial translation apparatus that interacts directly with the coxIII-mRNA-specific translational activator PET122.

Translational regulation of mitochondrial gene expression by nuclear genes of Saccharomyces cerevisiae

1988 ◽  
Vol 319 (1193) ◽  
pp. 97-105 ◽  
Keyword(s):  
Gene Expression ◽  
Mitochondrial Gene ◽  
Nuclear Gene ◽  
Mitochondrial Genes ◽  
Nuclear Genes ◽  
Mitochondrial Gene Expression ◽  
Wild Type ◽  
Mitochondrial Translation ◽  
Coding Sequence ◽  
Sites Of Action

We describe several yeast nuclear mutations that specifically block expression of the mitochondrial genes encoding cytochrome c oxidase subunits II (COXII) and III (COXIII). These recessive mutations define positive regulators of mitochondrial gene expression that act at the level of translation. Mutations in the nuclear gene PET111 completely block accumulation of COXII, but the COXII mRNA is present in mutant cells at a level approximately one-third of that of the wild type. Mitochondrial suppressors of pet 111 mutations correspond to deletions in mtDNA that result in fusions between the cox II structural gene and other mitochondrial genes. The chimeric mRNAs encoded by these fusions are translated in pet 111 mutants; this translation leads to accumulation of functional COXII. The PET111 protein probably acts directly on cox II translation, because it is located in mitochondria. Translation of the mitochondrially coded mRNA for COXIII requires the action of at least three nuclear genes, PET 494, and a newly discovered gene, provisionally termed PET 55. Both the PET494 and PET54 proteins are located in mitochondria and therefore probably act directly on the mitochondrial translation system. Mutations in all three genes are suppressed in strains that contain chimeric cox III mRNAs with the 5'-untranslated leaders of other mitochondrial transcripts fused to the cox III coding sequence. The products of all three nuclear genes may form a complex and carry out a single function. A direct demonstration that the wild-type nuclear gene products act in the cox III 5'-leader has been obtained by showing that they are all required for translation of apocytochrome b from a novel mRNA consisting of the cox lIl 5'-leader attached to the cytochrome b coding sequence. The site (or sites) of action maps at least 172 bases upstream from the cox lll initiation codon in the 600 base cox III leader. Others have reported evidence which suggests that cox Ill translation is repressed by glucose. Consistently with the possibility that the nuclear genes described here may play a role in modulating mitochondrial gene expression, we have found that PET 494 expression is glucose-repressed.

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