Inhibition of mitochondrial protein synthesis in regenerating rat liver stimulates mitochondrial transcription.

Partially hepatectomized rats were treated in vivo with thiamphenicol for 3 days to block mitochondrial protein synthesis. Protein synthesis, RNA synthesis and the steady-state levels of individual transcripts were measured in mitochondria in vitro in the absence of thiamphenicol. Incorporation of [35S]methionine and [3H]UTP into protein and RNA, respectively, was increased 2-3-fold in isolated mitochondria from thiamphenicol-treated animals, indicating increased rates of synthesis of both. Electrophoretic analysis of transcripts labelled with [32P]UTP suggests that synthesis of all the transcripts is increased. The steady-state concentrations of mitochondrial transcripts, measured by Northern blotting using nick-translated cloned EcoRI fragments of rat liver mtDNA, were also elevated 2-4-fold in thiamphenicol-treated animals. The data suggest that mitochondrial transcription is under control of a mitochondrial factor which, in turn, is dependent upon mitochondrial protein synthesis.

NSP1 depletion in yeast affects nuclear pore formation and nuclear accumulation.

The essential yeast nuclear pore protein NSP1 was placed under the control of the regulatable GAL10 promoter. GAL::NSP1 cells grow normally in galactose medium, but arrest in growth upon glucose-induced repression of the GAL::nsp1 gene. During NSP1 depletion, nuclear accumulation of two reporter proteins Mat alpha 2-lacZ and PHO2-lacZ is inhibited, and the chimeric proteins appear in the cytoplasm of GAL::nsp1 cells. Furthermore, the nuclear pore density decreases within the nuclear membrane during early NSP1 depletion. Upon reinduction of the NSP1 gene after NSP1 depletion, NSP1 is targeted to the nuclear envelope, the nuclear pore density increases, and nuclear accumulation of reporter proteins is restored.

Non-canonical Notch signaling activates IL-6/JAK/STAT signaling in breast tumor cells and is controlled by p53 and IKKα/IKKß.

Notch signaling is frequently hyperactivated in breast cancer, but how the enhanced signaling contributes to the tumor process is less well understood. In this report, we identify the proinflammatory cytokine interleukin-6 (IL-6) as a novel Notch target in breast tumor cells. Enhanced Notch signaling upregulated IL-6 expression, leading to activation of autocrine and paracrine Janus kinase/signal transducers and activators of transcription signaling. IL-6 upregulation was mediated by non-canonical Notch signaling, as it could be effectuated by a cytoplasmically localized Notch intracellular domain and was independent of the DNA-binding protein CSL. Instead, Notch-mediated IL-6 upregulation was controlled by two proteins in the nuclear factor (NF)-κB signaling cascade, IKKα and IKKß (inhibitor of nuclear factor kappa-B kinase subunit alpha and beta, respectively), as well as by p53. Activation of IL-6 by Notch required IKKα/IKKß function, but interestingly, did not engage canonical NF-κB signaling, in contrast to IL-6 activation by inflammatory agents such as lipopolysaccharide. With regard to p53 status, IL-6 expression was upregulated by Notch when p53 was mutated or lost, and restoring wild-type p53 into p53-mutated or -deficient cells abrogated the IL-6 upregulation. Furthermore, Notch-induced transcriptomes from p53 wild-type and -mutated breast tumor cell lines differed extensively, and for a subset of genes upregulated by Notch in a p53-mutant cell line, this upregulation was reduced by wild-type p53. In conclusion, we identify IL-6 as a novel non-canonical Notch target gene, and reveal roles for p53 and IKKα/IKKß in non-canonical Notch signaling in breast cancer and in the generation of cell context-dependent diversity in the Notch signaling output.

The response of individual polypeptides of the mammalian respiratory chain to thyroid hormone.

The effects of thyroid hormone on the accumulation of inner membrane polypeptides in rat liver mitochondria have been investigated using Western blot analysis. Respiration and mitochondrial protein synthesis were also measured. Levels of the subunits of cytochrome oxidase, the cytochrome bc1 complex, and the beta-subunit of F1-ATPase increase relatively late, requiring 3-6 days of treatment and high doses of hormone. In contrast, respiration increases under conditions in which no significant accumulation of individual subunits is observed. Our results indicate that increased oxidative capacity of mitochondria can be divided into an early response which probably involves metabolic regulation of mitochondrial respiration by hormone and a later response which is due to elevated mitochondrial protein synthesis and the accumulation of polypeptides of the respiratory chain.

Control of mitochondrial transcription by thyroid hormone.

Thyroid hormone regulation of rat liver mitochondrial transcription was investigated. Steady-state levels of mitochondrial transcripts were measured by Northern blot analysis using cloned fragments of rat mtDNA. Thyroid hormone increased the steady-state concentrations of all mitochondrial mRNAs by 2-8 fold after 1-3 days of hormone treatment, whereas no significant change in the mitochondrial rRNA was observed. Analysis of transcript synthesis in isolated mitochondria shows that part or all of this increase is accounted for by elevated synthesis. Mechanisms by which thyroid hormone regulates transcription of the mitochondrial genome are discussed.

Thyroid hormone and not growth hormone is the principle regulator of mammalian mitochondrial biogenesis.

T3 and GH have been implicated in the regulation of mitochondrial biogenesis. Since thyroid hormone promotes the synthesis of growth hormone, its control of human mitochondrial biogenesis could arise through a permissive action on GH biosynthesis. This was studied in hypophysectomized rats treated with T3 and/or human GH by the continuous infusion of hormone for 6 days from mini-infusion pumps implanted sc. Increases in mitochondrial respiration, enzyme activities, and protein synthesis were found in isolated liver mitochondria from rats receiving T3. In contrast, GH alone had no effect, nor did it increase the response to T3. Since it has been argued that mitochondrial biogenesis results from a direct interaction (binding) of GH with mitochondria, GH-specific binding sites were measured with 125I-bGH, a specific somatogenic receptor ligand, in isolated mitochondrial membranes in vitro. In addition, the intracellular endocytic uptake of 125I-bGH injected in vivo was compared in purified subcellular membrane fractions and mitochondria. No evidence in favour of specific GH interaction on mitochondrial membranes was found by either test. It is concluded that T3 exerts a direct, rather than permissive, effect on mitochondrial biogenesis, and that high affinity binding sites for GH are not present in rat liver mitochondria.

Regulation of biosynthesis of the rat liver inner mitochondrial membrane by thyroid hormone.

Regulation of mitochondrial protein synthesis by thyroid hormone has been studied in isolated rat hepatocytes and liver mitochondria. Small doses (5 micrograms/100 g body wt) of triiodothyronine (T3) injected into hypothyroid rats increased both state 3 and 4 respiration by approximately 100%, while the ADP:O ratio remained constant. This suggests that T3 increases the numbers of functional respiratory chain units. T3 also induces mitochondrial protein synthesis by 50-100%. Analysis of the mitochondrial translation products show that all of the products were induced. No differential translation of the peptides involved in the respiratory chain was found. Regulation of the cytoplasmically made inner membrane peptides was also investigated in isolated hepatocytes. The majority of these peptides were not influenced by T3, in contrast to the finding with mitochondrial translation products. Those found to be regulated by T3 belong to two subsets, which were either induced or repressed by hormone. Thus, T3 stimulated a general increase in the synthesis of mitochondrially translated inner membrane peptides, but regulates selectively those inner membrane peptides translated on cytoplasmic ribosomes. The findings suggest that hormone regulation of the respiratory chain is exerted through a few selective proteins, perhaps those which require subunits made from both nuclear and mitochondrial genes.

NSP1: a yeast nuclear envelope protein localized at the nuclear pores exerts its essential function by its carboxy-terminal domain.

NSP1 is located at the nuclear periphery in yeast and is essential for cell growth. Employing immunoelectron microscopy on yeast cells, we show that NSP1 is located at the nuclear pores. The molecular analysis of the NSP1 protein points to a two domain model: a nonessential domain (the first 603 amino acids) composed of repetitive sequences common to other nuclear proteins and an essential, carboxy-terminal domain (residues 604-823) mediating the vital function of NSP1. The NSP1 carboxy-terminal domain, which shows a heptad repeat organization, affected the correct location of two nuclear proteins: site-specific amino acid substitutions within a predicted alpha-helical structure of this domain caused a temperature-sensitive growth arrest at 37 degrees C and the appearance of NSP1 and NOP1, a nucleolar protein, in the cytosol.