Translation fidelity is the limiting factor in the accuracy of gene expression. With an estimated frequency of 10−4, errors in mRNA decoding occur in a mostly stochastic manner. Little is known about the response of higher eukaryotes to chronic loss of ribosomal accuracy as per an increase in the random error rate of mRNA decoding. Here, we present a global and comprehensive picture of the cellular changes in response to translational accuracy in mammalian ribosomes impaired by genetic manipulation. In addition to affecting established protein quality control pathways, such as elevated transcript levels for cytosolic chaperones, activation of the ubiquitin-proteasome system, and translational slowdown, ribosomal mistranslation led to unexpected responses. In particular, we observed increased mitochondrial biogenesis associated with import of misfolded proteins into the mitochondria and silencing of the unfolded protein response in the endoplasmic reticulum.
The main source of error in gene expression is messenger RNA decoding by the ribosome. Translational accuracy has been suggested on a purely correlative basis to positively coincide with maximum possible life span among different rodent species, but causal evidence that translation errors accelerate aging in vivo and limit life span is lacking. We have now addressed this question experimentally by creating heterozygous knock-in mice that express the ribosomal ambiguity mutation RPS9 D95N, resulting in genome-wide error-prone translation. Here, we show that
Rps9
D95N knock-in mice exhibit reduced life span and a premature onset of numerous aging-related phenotypes, such as reduced weight, chest deformation, hunchback posture, poor fur condition, and urinary syndrome, together with lymphopenia, increased levels of reactive oxygen species–inflicted damage, accelerated age-related changes in DNA methylation, and telomere attrition. Our results provide an experimental link between translational accuracy, life span, and aging-related phenotypes in mammals.
A series of derivatives of the 4,5-disubstituted class of
2-deoxystreptamine aminoglycoside antibiotics neomycin, paromomycin, and
ribostamycin have been prepared and assayed for i) their ability to inhibit
protein synthesis by bacterial ribosomes and by engineered bacterial ribosomes
carrying eukaryotic decoding A sites; ii) antibacterial activity against wild
type Gram negative and positive pathogens, and iii) overcoming resistance due to
the presence of aminoacyl transferases acting at the 2’-position. The
presence of five suitably-positioned residual basic amino groups was found to be
necessary for activity to be retained upon removal or alkylation of the
2’-position amine. As alkylation of the 2’-amino group overcomes
the action of resistance determinants acting at that position and in addition
results in increased selectivity for the prokaryotic over eukaryotic ribosomes,
it constitutes an attractive modification for introduction into next generation
aminoglycosides. In the neomycin series the installation of small (formamide) or
basic (glycinamide) amido groups on the 2’-amino group is tolerated.
Proteostasis is a challenge for cellular organisms, as all known protein synthesis machineries are error-prone. Here we show by cell fractionation and microscopy studies that misfolded proteins formed in the endoplasmic reticulum can become associated with and partly transported into mitochondria, resulting in impaired mitochondrial function. Blocking the endoplasmic reticulum-mitochondria encounter structure (ERMES), but not the mitochondrial sorting and assembly machinery (SAM) or the mitochondrial surveillance pathway components Msp1 and Vms1, abrogated mitochondrial sequestration of ER-misfolded proteins. We term this mitochondria-associated proteostatic mechanism for ER-misfolded proteins ERAMS (ER-associated mitochondrial sequestration). We testify to the relevance of this pathway by using mutant α-1-antitrypsin as an example of a human disease-related misfolded ER protein, and we hypothesize that ERAMS plays a role in pathological features such as mitochondrial dysfunction.
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