scholarly journals TheS. cerevisiaeHAP Complex, a Key Regulator of Mitochondrial Function, Coordinates Nuclear and Mitochondrial Gene Expression

2003 ◽  
Vol 4 (1) ◽  
pp. 37-46 ◽  
Author(s):  
S. Buschlen ◽  
J-M Amillet ◽  
B. Guiard ◽  
A. Fournier ◽  
C. Marcireau ◽  
...  
Keyword(s):  
Gene Expression ◽  
Respiratory Chain ◽  
Mitochondrial Gene ◽  
Nuclear Gene ◽  
Negative Control ◽  
Nuclear Genes ◽  
Wild Type ◽  
Mitochondrial Translation ◽  
Respiratory Chain Complexes ◽  
In The Wild

We have comparedSaccharomyces cerevisiaeglobal gene expression in wild-type and mutants (Δhap2 and Δhap4) of the HAP transcriptional complex, which has been shown to be necessary for growth on respiratory substrates. Several hundred ORFs are under positive or negative control of this complex and we analyse here in detail the effect of HAP on mitochondria. We found that most of the genes upregulated in the wild-type strain were involved in organelle functions, but practically none of the downregulated ones. Nuclear genes encoding the different subunits of the respiratory chain complexes figure in the genes more expressed in the wild-type than in the mutants, as expected, but in this group we also found key components of the mitochondrial translation apparatus. This control of mitochondrial translation may be one of the means of coordinating mitochondrial and nuclear gene expression in elaborating the respiratory chain. In addition, HAP controls the nuclear genes involved in several other mitochondrial processes (import, mitochondrial division) that define the metabolic state of the cell, but not mitochondrial DNA replication and transcription. In most cases, a putative CCAAT-binding site is present upstream of the ORF, while in others no such sites are present, suggesting the control to be indirect. The large number of genes regulated by the HAP complex, as well as the fact that HAP also regulates some putative transcriptional activators of unknown function, place this complex at a hierarchically high position in the global transcriptional regulation of the cell.

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.

scholarly journals Role of Sigma Factors in Controlling Global Gene Expression in Light/Dark Transitions in the Cyanobacterium Synechocystis sp. Strain PCC 6803

2007 ◽  
Vol 189 (21) ◽  
pp. 7829-7840 ◽  
Author(s):  
Tina C. Summerfield ◽  
Louis A. Sherman
Keyword(s):  
Gene Expression ◽  
Global Gene Expression ◽  
Growth Conditions ◽  
Day Length ◽  
Regulation Of Transcription ◽  
Wild Type ◽  
Protein Levels ◽  
In The Wild ◽  
Altered Gene ◽  
Pcc 6803

ABSTRACT We report on differential gene expression in the cyanobacterium Synechocystis sp. strain PCC 6803 after light-dark transitions in wild-type, ΔsigB, and ΔsigD strains. We also studied the effect of day length in the presence of glucose on a ΔsigB ΔsigE mutant. Our results indicated that the absence of SigB or SigD predominately altered gene expression in the dark or in the light, respectively. In the light, approximately 350 genes displayed transcript levels in the ΔsigD strain that were different from those of the wild type, with over 200 of these up-regulated in the mutant. In the dark, removal of SigB altered more than 150 genes, and the levels of 136 of these were increased in the mutant compared to those in the wild type. The removal of both SigB and SigE had a major impact on gene expression under mixotrophic growth conditions and resulted in the inability of cells to grow in the presence of glucose with 8-h light and 16-h dark cycles. Our results indicated the importance of group II σ factors in the global regulation of transcription in this organism and are best explained by using the σ cycle paradigm with the stochastic release model described previously (R. A. Mooney, S. A. Darst, and R. Landick, Mol. Cell 20:335-345, 2005). We combined our results with the total protein levels of the σ factors in the light and dark as calculated previously (S. Imamura, S. Yoshihara, S. Nakano, N. Shiozaki, A. Yamada, K. Tanaka, H. Takahashi, M. Asayama, and M. Shirai, J. Mol. Biol. 325:857-872, 2003; S. Imamura, M. Asayama, H. Takahashi, K. Tanaka, H. Takahashi, and M. Shirai, FEBS Lett. 554:357-362, 2003). Thus, we concluded that the control of global transcription is based on the amount of the various σ factors present and able to bind RNA polymerase.

Rpm2, the Protein Subunit of Mitochondrial RNase P in Saccharomyces cerevisiae, Also Has a Role in the Translation of Mitochondrially Encoded Subunits of Cytochrome c Oxidase

Genetics ◽  
2001 ◽  
Vol 158 (2) ◽  
pp. 573-585
Author(s):  
Vilius Stribinskis ◽  
Guo-Jian Gao ◽  
Steven R Ellis ◽  
Nancy C Martin
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Cytochrome C ◽  
Cytochrome C Oxidase ◽  
Mitochondrial Biogenesis ◽  
Mitochondrial Protein ◽  
Nuclear Gene ◽  
Rnase P ◽  
Wild Type ◽  
Protein Subunit ◽  
Mitochondrial Translation

Abstract RPM2 is a Saccharomyces cerevisiae nuclear gene that encodes the protein subunit of mitochondrial RNase P and has an unknown function essential for fermentative growth. Cells lacking mitochondrial RNase P cannot respire and accumulate lesions in their mitochondrial DNA. The effects of a new RPM2 allele, rpm2-100, reveal a novel function of RPM2 in mitochondrial biogenesis. Cells with rpm2-100 as their only source of Rpm2p have correctly processed mitochondrial tRNAs but are still respiratory deficient. Mitochondrial mRNA and rRNA levels are reduced in rpm2-100 cells compared to wild type. The general reduction in mRNA is not reflected in a similar reduction in mitochondrial protein synthesis. Incorporation of labeled precursors into mitochondrially encoded Atp6, Atp8, Atp9, and Cytb protein was enhanced in the mutant relative to wild type, while incorporation into Cox1p, Cox2p, Cox3p, and Var1p was reduced. Pulse-chase analysis of mitochondrial translation revealed decreased rates of translation of COX1, COX2, and COX3 mRNAs. This decrease leads to low steady-state levels of Cox1p, Cox2p, and Cox3p, loss of visible spectra of aa3 cytochromes, and low cytochrome c oxidase activity in mutant mitochondria. Thus, RPM2 has a previously unrecognized role in mitochondrial biogenesis, in addition to its role as a subunit of mitochondrial RNase P. Moreover, there is a synthetic lethal interaction between the disruption of this novel respiratory function and the loss of wild-type mtDNA. This synthetic interaction explains why a complete deletion of RPM2 is lethal.

scholarly journals Mitochondrial OXPHOS Biogenesis: Co-Regulation of Protein Synthesis, Import, and Assembly Pathways

2020 ◽  
Vol 21 (11) ◽  
pp. 3820 ◽  
Author(s):  
Jia Xin Tang ◽  
Kyle Thompson ◽  
Robert W. Taylor ◽  
Monika Oláhová
Keyword(s):  
Gene Expression ◽  
Protein Synthesis ◽  
Protein Import ◽  
Acyl Carrier Protein ◽  
Early Stage ◽  
Mitochondrial Gene ◽  
Mitochondrial Protein ◽  
Fine Tuning ◽  
Mitochondrial Translation ◽  
Oxphos Complex

The assembly of mitochondrial oxidative phosphorylation (OXPHOS) complexes is an intricate process, which—given their dual-genetic control—requires tight co-regulation of two evolutionarily distinct gene expression machineries. Moreover, fine-tuning protein synthesis to the nascent assembly of OXPHOS complexes requires regulatory mechanisms such as translational plasticity and translational activators that can coordinate mitochondrial translation with the import of nuclear-encoded mitochondrial proteins. The intricacy of OXPHOS complex biogenesis is further evidenced by the requirement of many tightly orchestrated steps and ancillary factors. Early-stage ancillary chaperones have essential roles in coordinating OXPHOS assembly, whilst late-stage assembly factors—also known as the LYRM (leucine–tyrosine–arginine motif) proteins—together with the mitochondrial acyl carrier protein (ACP)—regulate the incorporation and activation of late-incorporating OXPHOS subunits and/or co-factors. In this review, we describe recent discoveries providing insights into the mechanisms required for optimal OXPHOS biogenesis, including the coordination of mitochondrial gene expression with the availability of nuclear-encoded factors entering via mitochondrial protein import systems.

scholarly journals Mrpl36 Is Important for Generation of Assembly Competent Proteins during Mitochondrial Translation

2009 ◽  
Vol 20 (10) ◽  
pp. 2615-2625 ◽  
Author(s):  
Martin Prestele ◽  
Frank Vogel ◽  
Andreas S. Reichert ◽  
Johannes M. Herrmann ◽  
Martin Ott
Keyword(s):  
Protein Synthesis ◽  
Respiratory Chain ◽  
Large Subunit ◽  
Critical Role ◽  
Mitochondrial Translation ◽  
Respiratory Chain Complexes ◽  
Ribosomal Subunits ◽  
Terminal Domain ◽  
Chain Complexes ◽  
Mitochondrial Ribosome

The complexes of the respiratory chain represent mosaics of nuclear and mitochondrially encoded components. The processes by which synthesis and assembly of the various subunits are coordinated remain largely elusive. During evolution, many proteins of the mitochondrial ribosome acquired additional domains pointing at specific properties or functions of the translation machinery in mitochondria. Here, we analyzed the function of Mrpl36, a protein associated with the large subunit of the mitochondrial ribosome. This protein, homologous to the ribosomal protein L31 from bacteria, contains a mitochondria-specific C-terminal domain that is not required for protein synthesis per se; however, its absence decreases stability of Mrpl36. Cells lacking this C-terminal domain can still synthesize proteins, but these translation products fail to be properly assembled into respiratory chain complexes and are rapidly degraded. Surprisingly, overexpression of Mrpl36 seems to even increase the efficiency of mitochondrial translation. Our data suggest that Mrpl36 plays a critical role during translation that determines the rate of respiratory chain assembly. This important function seems to be carried out by a stabilizing activity of Mrpl36 on the interaction between large and small ribosomal subunits, which could influence accuracy of protein synthesis.

PPR (pentatricopeptide repeat) proteins in mammals: important aids to mitochondrial gene expression

2008 ◽  
Vol 416 (1) ◽  
pp. e5-e6 ◽  
Author(s):  
Robert N. Lightowlers ◽  
Zofia M. A. Chrzanowska-Lightowlers
Keyword(s):  
Respiratory Chain ◽  
Mitochondrial Gene ◽  
Gene Families ◽  
Complex Iii ◽  
Ultrastructural Changes ◽  
Mitochondrial Rna ◽  
Pentatricopeptide Repeat ◽  
Respiratory Chain Complexes ◽  
Apparent Lack ◽  
Apocytochrome B

Genes encoding PPR (pentatricopeptide repeat)-containing proteins constitute one of the largest gene families in plants. The majority of these proteins are predicted to target organelles and to bind to RNA. Strikingly, there is a dearth of these proteins in mammals, although genomic searches reveal six candidates, all of which are also predicted to target the mitochondrion. Two of these proteins, POLRMT (the mitochondrial RNA polymerase) and MRPS27, a mitoribosomal protein, are involved in transcription and translation respectively. PTCD1 (pentatricopeptide repeat domain protein 1) and PTCD3 are predicted to be involved in the assembly of respiratory chain complexes, whereas mutations in one other protein, LRPPRC (leucine-rich pentatricopeptide repeat cassette), have been shown to cause defects in the levels of cytochrome c oxidase, the terminal member of the respiratory chain. In this issue of the Biochemical Journal, Xu et al. turn their attention to the remaining candidate, PTCD2. Depletion in a mouse model led to deficiencies of the third complex of the respiratory chain that caused profound ultrastructural changes in the heart. The exact molecular function of PTCD2 remains unclear, but depletion leads to an apparent lack of processing of the mitochondrial transcript encoding apocytochrome b, a critical member of complex III. These data are consistent with PTCD2 playing an important role in the post-transcriptional expression of the mitochondrial genome.

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.

scholarly journals Effects of Chloramphenicol on the Mitochondrial Respiratory Chain in the Wild Strain and in a Cytoplasmic Chloramphenicol-Resistant Mutant ofTetrahymena pyriformis

1982 ◽  
Vol 2 (6) ◽  
pp. 715-719 ◽  
Author(s):  
Roland Perasso ◽  
Jean-Jacques Curgy ◽  
Nicole Stelly ◽  
Jean Andre
Keyword(s):  
Oxygen Consumption ◽  
Cytochrome Oxidase ◽  
Oxidase Activity ◽  
Wild Strain ◽  
Resistant Mutant ◽  
Wild Type ◽  
Mitochondrial Translation ◽  
Cytochrome Oxidase Activity ◽  
In The Wild ◽  
Mitochondrial Respiratory

The effects of chloramphenicol (CAP) on mitochondrial respiratory activity in the wild strain (ST) and in a cytoplasmic CAP-resistant mutant (STR1) ofTetrahymena pyriformiswere studied by determining oxygen consumption, by spectrophotometry, and by cytochemistry. In the absence of CAP both strains had the same respiration capacity, and the low-temperature spectra of their isolated mitochondria were similar. Furthermore, the mitochondria of both strains showed a positive reaction with diaminobenzidine, denoting a similar cytochrome oxidase activity. However, when cells were grown in CAP for 24 or 48 h, the peaks of cytochrome oxidase and cytochromebwere almost absent in the wild type. In this type the oxygen consumption was greatly decreased, and the mitochondria were no longer stained by diaminobenzidine. In the mutant, the peaks of cytochrome oxidase and cytochromebwere decreased only; respiration was less affected than in the wild type, and cytochrome oxidase activity was still disclosed by the diaminobenzidine reaction. These results show that CAP inhibits the synthesis of two cytochromes (band oxidase) which are partially translated into the mitochrondria ofT. pyriformis.In the mutant, CAP reduces only the mitochondrial translation, resulting in reduced mitochondrial activity and reduced growth rate of the cell. These results are compared with the nucleo-mitochondrial regulation mechanisms discussed in our previous works.

Carvedilol Induces Changes In Gene Expression In The Wild-Type Rat Heart

2012 ◽  
Author(s):  
Jennifer I. Drake ◽  
Ramesh Natarajan ◽  
Harm J. Bogaard ◽  
Donatas Kraskauskas ◽  
Norbert F. Voelkel
Keyword(s):  
Gene Expression ◽  
Rat Heart ◽  
Wild Type ◽  
In The Wild
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