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1.
Host Subunit of Qβ Replicase is Translation Control Factor i 总被引:9,自引:0,他引:9
THE tetrameric phage Qβ replicase is composed of three pre-existing E. coli proteins in addition to the phage coded synthetase1,2. The host subunits also appear to form part of the f2 replicase3. We have found that the cistron specific factor i4 cross reacts immunologically and coelectrophoresis on SDS-acrylamide gel with the largest replicase subunit. 相似文献
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Influenza Virus mRNA Translation Revisited: Is the eIF4E Cap-Binding Factor Required for Viral mRNA Translation? 总被引:1,自引:0,他引:1
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Influenza virus mRNAs bear a short capped oligonucleotide sequence at their 5' ends derived from the host cell pre-mRNAs by a "cap-snatching" mechanism, followed immediately by a common viral sequence. At their 3' ends, they contain a poly(A) tail. Although cellular and viral mRNAs are structurally similar, influenza virus promotes the selective translation of its mRNAs despite the inhibition of host cell protein synthesis. The viral polymerase performs the cap snatching and binds selectively to the 5' common viral sequence. As viral mRNAs are recognized by their own cap-binding complex, we tested whether viral mRNA translation occurs without the contribution of the eIF4E protein, the cellular factor required for cap-dependent translation. Here, we show that influenza virus infection proceeds normally in different situations of functional impairment of the eIF4E factor. In addition, influenza virus polymerase binds to translation preinitiation complexes, and furthermore, under conditions of decreased eIF4GI association to cap structures, an increase in eIF4GI binding to these structures was found upon influenza virus infection. This is the first report providing evidence that influenza virus mRNA translation proceeds independently of a fully active translation initiation factor (eIF4E). The data reported are in agreement with a role of viral polymerase as a substitute for the eIF4E factor for viral mRNA translation. 相似文献
4.
Takuya B. Hiyama Takuhiro Ito Hiroaki Imataka Shigeyuki Yokoyama 《Journal of molecular biology》2009,392(4):937-951
Eukaryotic translation initiation factor 2B (eIF2B) is the heteropentameric guanine-nucleotide exchange factor specific for eukaryotic initiation factor 2 (eIF2). Under stressed conditions, guanine-nucleotide exchange is strongly inhibited by the tight binding of phosphorylated eIF2 to eIF2B. Here, we report the crystal structure of the α subunit of human eIF2B at 2.65 Å resolution. The eIF2Bα structure consists of the N-terminal α-helical domain and the C-terminal Rossmann-fold-like domain. A positively charged pocket, whose entrance is about 15-17 Å in diameter, resides at the boundary between the two domains. A sulfate ion is located at the bottom of the pocket (about 16 Å in depth). The residues comprising the sulfate-ion-binding site are strictly conserved in eIF2Bα. Since this deep, wide pocket with the sulfate-ion-binding site is not conserved in distant homologues, including 5-methylthioribose 1-phosphate isomerases, these characteristics may be distinctive of eIF2Bα. Interestingly, the yeast eIF2Bα missense mutations that reduce the eIF2B sensitivity to phosphorylated eIF2 are mapped on the other side of the pocket. One of the three human eIF2Bα missense mutations that induce the lethal brain disorder vanishing white matter or childhood ataxia with central nervous system hypomyelination is mapped inside the pocket. The β and δ subunits of eIF2B are homologous to eIF2Bα and may have tertiary structures similar to the present eIF2Bα structure. The sulfate-ion-binding residues of eIF2Bα are well conserved in eIF2Bβ/δ. The abovementioned yeast and human missense mutations of eIF2Bβ/δ were also mapped on the eIF2Bα structure, which revealed that the human mutations are clustered on the same side as the pocket, while the yeast mutations reside on the opposite side. As most of the mutated residues are exposed on the surface of the eIF2B subunit structure, these exposed residues are likely to be involved in either the subunit interactions or the interaction with eIF2. 相似文献
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Increased Expression of Saccharomyces Cerevisiae Translation Elongation Factor 1α Bypasses the Lethality of a Tef5 Null Allele Encoding Elongation Factor 1β
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Translation elongation factor 1β (EF-1β) catalyzes the exchange of bound GDP for GTP on EF-1α. The lethality of a null allele of the TEF5 gene encoding EF-1β in Saccharomyces cerevisiae was suppressed by extra copies of the TEF2 gene encoding EF-1α. The strains with tef5::TRP1 suppressed by extra copies of TEF2 were slow growing, cold sensitive, hypersensitive to inhibitors of translation elongation and showed increased phenotypic suppression of +1 frameshift and UAG nonsense mutations. Nine dominant mutant alleles of TEF2 that cause increased suppression of frameshift mutations also suppressed the lethality of tef5::TRP1. Most of the strains in which tef5::TRP1 is suppressed by dominant mutant alleles of TEF2 grew more slowly and were more antibiotic sensitive than strains with tef5::TRP1 suppressed by wild-type TEF2. Two alleles, TEF2-4 and TEF2-10, interact with tef5::TRP1 to produce strains that showed doubling times similar to tef5::TRP1 strains containing extra copies of wild-type TEF2. These strains were less cold sensitive, drug sensitive and correspondingly less efficient suppressors of +1 frameshift mutations. These phenotypes indicate that translation and cell growth are highly sensitive to changes in EF-1α and EF-1β activity. 相似文献
7.
Michael M. Yue Kaosheng Lv Stephen C. Meredith Jennifer L. Martindale Myriam Gorospe Lucia Schuger 《The Journal of biological chemistry》2014,289(49):33971-33983
P311, a conserved 8-kDa intracellular protein expressed in brain, smooth muscle, regenerating tissues, and malignant glioblastomas, represents the first documented stimulator of TGF-β1-3 translation in vitro and in vivo. Here we initiated efforts to define the mechanism underlying P311 function. PONDR® (Predictor Of Naturally Disordered Regions) analysis suggested and CD confirmed that P311 is an intrinsically disordered protein, therefore requiring an interacting partner to acquire tertiary structure and function. Immunoprecipitation coupled with mass spectroscopy identified eIF3 subunit b (eIF3b) as a novel P311 binding partner. Immunohistochemical colocalization, GST pulldown, and surface plasmon resonance studies revealed that P311-eIF3b interaction is direct and has a Kd of 1.26 μm. Binding sites were mapped to the non-canonical RNA recognition motif of eIF3b and a central 11-amino acid-long region of P311, here referred to as eIF3b binding motif. Disruption of P311-eIF3b binding inhibited translation of TGF-β1, 2, and 3, as indicated by luciferase reporter assays, polysome fractionation studies, and Western blot analysis. RNA precipitation assays after UV cross-linking and RNA-protein EMSA demonstrated that P311 binds directly to TGF-β 5′UTRs mRNAs through a previously unidentified RNA recognition motif-like motif. Our results demonstrate that P311 is a novel RNA-binding protein that, by interacting with TGF-βs 5′UTRs and eIF3b, stimulates the translation of TGF-β1, 2, and 3. 相似文献
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《Structure (London, England : 1993)》2014,22(6):923-930
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10.
《Nucleosides, nucleotides & nucleic acids》2013,32(5-8):1557-1561
Abstract All eukaryotic nuclear transcribed mRNAs possess the cap structure, consisting of 7-methylguanosine linked by the 5′-5′ triphosphate bridge to the first nucleoside. The goal of the present study is to dissect the enthalpy and entropy changes of association of the mRNA 5′ cap with eIF4E into contributions originating from the interaction of 7-methylguanosine with tryptophan. The model results are discussed in the context of the thermodynamic parameters for the association of eIF4E with synthetic cap analogues. 相似文献
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Nicole Kloft Claudia Neukirch Gisela von Hoven Wiesia Bobkiewicz Silvia Weis Klaus Boller Matthias Husmann 《The Journal of biological chemistry》2012,287(42):35299-35317
The constitutive reverter of eIF2α phosphorylation (CReP)/PPP1r15B targets the catalytic subunit of protein phosphatase 1 (PP1c) to phosphorylated eIF2α (p-eIF2α) to promote its dephosphorylation and translation initiation. Here, we report a novel role and mode of action of CReP. We found that CReP regulates uptake of the pore-forming Staphylococcus aureus α-toxin by epithelial cells. This function was independent of PP1c and translation, although p-eIF2α was involved. The latter accumulated at sites of toxin attack and appeared conjointly with α-toxin in early endosomes. CReP localized to membranes, interacted with phosphomimetic eIF2α, and, upon overexpression, induced and decorated a population of intracellular vesicles, characterized by accumulation of N-(lissamine rhodamine B sulfonyl)phosphatidylethanolamine (N-Rh-PE), a lipid marker of exosomes and intralumenal vesicles of multivesicular bodies. By truncation analysis, we delineated the CReP vesicle induction/association region, which comprises an amphipathic α-helix and is distinct from the PP1c interaction domain. CReP was also required for exocytosis from erythroleukemia cells and thus appears to play a broader role in membrane traffic. In summary, the mammalian traffic machinery co-opts p-eIF2α and CReP, regulators of translation initiation. 相似文献
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Apart from its canonical function in translation elongation, eukaryotic translation elongation factor 1A (eEF1A) has been shown to interact with the actin cytoskeleton. Amino acid substitutions in eEF1A that reduce its ability to bind and bundle actin in vitro cause improper actin organization in vivo and reduce total translation. Initial in vivo analysis indicated the reduced translation was through initiation. The mutant strains exhibit increased levels of phosphorylated initiation factor 2α (eIF2α) dependent on the presence of the general control nonderepressible 2 (Gcn2p) protein kinase. Gcn2p causes down-regulation of total protein synthesis at initiation in response to increases in deacylated tRNA levels in the cell. Increased levels of eIF2α phosphorylation are not due to a general reduction in translation elongation as eEF2 and eEF3 mutants do not exhibit this effect. Deletion of GCN2 from the eEF1A actin bundling mutant strains revealed a second defect in translation. The eEF1A actin-bundling proteins exhibit changes in their elongation activity at the level of aminoacyl-tRNA binding in vitro. These findings implicate eEF1A in a feedback mechanism for regulating translation at initiation. 相似文献
15.
Yvette R. Pittman Kimberly Kandl Marcus Lewis Louis Valente Terri Goss Kinzy 《The Journal of biological chemistry》2009,284(7):4739-4747
Eukaryotic translation elongation factor 1A (eEF1A) both shuttles
aminoacyl-tRNA (aa-tRNA) to the ribosome and binds and bundles actin. A single
domain of eEF1A is proposed to bind actin, aa-tRNA and the guanine nucleotide
exchange factor eEF1Bα. We show that eEF1Bα has the ability to
disrupt eEF1A-induced actin organization. Mutational analysis of eEF1Bα
F163, which binds in this domain, demonstrates effects on growth, eEF1A
binding, nucleotide exchange activity, and cell morphology. These phenotypes
can be partially restored by an intragenic W130A mutation. Furthermore, the
combination of F163A with the lethal K205A mutation restores viability by
drastically reducing eEF1Bα affinity for eEF1A. This also results in a
consistent increase in actin bundling and partially corrected morphology. The
consequences of the overlapping functions in this eEF1A domain and its unique
differences from the bacterial homologs provide a novel function for
eEF1Bα to balance the dual roles in actin bundling and protein
synthesis.The final step of gene expression takes place at the ribosome as mRNA is
translated into protein. In the yeast Saccharomyces cerevisiae,
elongation of the polypeptide chain requires the orchestrated action of three
soluble factors. The eukaryotic elongation factor 1
(eEF1)2 complex
delivers aminoacyl-tRNA (aa-tRNA) to the empty A-site of the elongating
ribosome (1). The eEF1A subunit
is a classic G-protein that acts as a “molecular switch” for the
active and inactive states based on whether GTP or GDP is bound, respectively
(2). Once an anticodon-codon
match occurs, the ribosome acts as a GTPase-activating factor to stimulate GTP
hydrolysis resulting in the release of inactive GDP-bound eEF1A from the
ribosome. Because the intrinsic rate of GDP release from eEF1A is extremely
slow (3,
4), a guanine nucleotide
exchange factor (GEF) complex, eEF1B, is required
(5,
6). The yeast S.
cerevisiae eEF1B complex contains two subunits, the essential catalytic
subunit eEF1Bα (5) and
the non-essential subunit eEF1Bγ
(7).The co-crystal structures of eEF1A:eEF1Bα C terminus:GDP:
Mg2+ and eEF1A:eEF1Bα C terminus:GDPNP
(8,
9) demonstrated a surprising
structural divergence from the bacterial EF-Tu-EF-Ts
(10) and mammalian
mitochondrial EF-Tumt-EF-Tsmt
(11). While the G-proteins
have a similar topology and consist of three well-defined domains, a striking
difference was observed in binding sites for their GEFs. The C terminus of
eEF1Bα interacts with domain I and a distinct pocket of domain II eEF1A,
creating two binding interfaces. In contrast, the bacterial counterpart EF-Ts
and mammalian mitochondrial EF-Tsmt, make extensive contacts with
domain I and III of EF-Tu and EF-Tumt, respectively. The altered
binding interface of eEF1Bα to domain II of eEF1A is particularly
unexpected given the functions associated with domain II of eEF1A and EF-Tu.
The crystal structure of the EF-Tu:GDPNP:Phe-tRNAPhe complex
reveals aa-tRNA binding to EF-Tu requires only minor parts of both domain II
and tRNA to sustain stable contacts
(12). That eEF1A employs the
same aa-tRNA binding site is supported by genetic and biochemical data
(13-15).
Interestingly, eEF1Bα contacts many domain II eEF1A residues in the
region hypothesized to be involved in the binding of the aa-tRNA CCA end
(8). Because, the shared
binding site of eEF1Bα and aa-tRNA on domain II of eEF1A is
significantly different between the eukaryotic and bacterial/mitochondrial
systems, eEF1Bα may play a unique function aside from guanine nucleotide
release in eukaryotes.In eukaroytes, eEF1A is also an actin-binding and -bundling protein. This
noncanonical function of eEF1A was initially observed in Dictyostelium
amoebae (16). It is
estimated that greater than 60% of Dictyostelium eEF1A is associated
with the actin cytoskeleton
(17). The eEF1A-actin
interaction is conserved among species from yeast to mammals, suggesting the
importance of eEF1A for cytoskeleton integrity. Using a unique genetic
approach, multiple eEF1A mutations were identified that altered cell growth
and morphology, and are deficient in bundling actin in vitro
(18,
19). Intriguingly, most
mutations localized to domain II, the shared aa-tRNA and eEF1Bα binding
site. Previous studies have demonstrated that actin bundling by eEF1A is
significantly reduced in the presence of aa-tRNA while eEF1A bound to actin
filaments is not in complex with aa-tRNA
(20). Therefore, actin and
aa-tRNA binding to eEF1A is mutually exclusive. In addition, overexpression of
yeast eEF1A or actin-bundling deficient mutants do not affect translation
elongation (18,
19,
21), suggesting
eEF1A-dependent cytoskeletal organization is independent of its translation
elongation function (18,
20). Thus, while aa-tRNA
binding to domain II is conserved between EF-Tu and eEF1A, this actin bundling
function associated with eEF1A domain II places greater importance on its
relationship with the “novel” binding interface between eEF1A
domain II and eEF1Bα.Based on this support for an overlapping actin bundling and eEF1Bα
binding site in eEF1A domain II, we hypothesize that eEF1Bα modulates
the equilibrium between actin and translation functions of eEF1A and is
perhaps the result of evolutionary selective pressure to balance the
eukaryotic-specific role of eEF1A in actin organization. Here, we present
kinetic and biochemical evidence using a F163A mutant of eEF1Bα for the
importance of the interactions between domain II of eEF1A and eEF1Bα to
prevent eEF1A-dependent actin bundling as well as promoting guanine nucleotide
exchange. Furthermore, altered affinities of eEF1Bα mutants for eEF1A
support that this complex formation is a determining factor for eEF1A-induced
actin organization. Interestingly, the F163A that reduces eEF1A affinity is an
intragenic suppressor of the lethal K205A eEF1Bα mutant that displays
increased affinity for eEF1A. This, along with a consistent change in the
actin bundling correlated with the affinity of eEF1Bα for eEF1A,
indicates that eEF1Bα is a balancer, directing eEF1A to translation
elongation and away from actin, and alterations in this balance result in
detrimental effects on cell growth and eEF1A function. 相似文献
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JeeNa Hwang Seonhee Lee Joung-Ho Lee Won-Hee Kang Jin-Ho Kang Min-Young Kang Chang-Sik Oh Byoung-Cheorl Kang 《PloS one》2015,10(5)
The eukaryotic translation elongation factor 1 (eEF1) has two components: the G-protein eEF1A and the nucleotide exchange factor eEF1B. In plants, eEF1B is itself composed of a structural protein (eEF1Bγ) and two nucleotide exchange subunits (eEF1Bα and eEF1Bβ). To test the effects of elongation factors on virus infection, we isolated eEF1A and eEF1B genes from pepper (Capsicum annuum) and suppressed their homologs in Nicotiana benthamiana using virus-induced gene silencing (VIGS). The accumulation of a green fluorescent protein (GFP)-tagged Potato virus X (PVX) was significantly reduced in the eEF1Bβ- or eEF1Bɣ-silenced plants as well as in eEF1A-silenced plants. Yeast two-hybrid and co-immunoprecipitation analyses revealed that eEF1Bα and eEF1Bβ interacted with eEF1A and that eEF1A and eEF1Bβ interacted with triple gene block protein 1 (TGBp1) of PVX. These results suggest that both eEF1A and eEF1Bβ play essential roles in the multiplication of PVX by physically interacting with TGBp1. Furthermore, using eEF1Bβ deletion constructs, we found that both N- (1-64 amino acids) and C-terminal (150-195 amino acids) domains of eEF1Bβ are important for the interaction with PVX TGBp1 and that the C-terminal domain of eEF1Bβ is involved in the interaction with eEF1A. These results suggest that eEF1Bβ could be a potential target for engineering virus-resistant plants. 相似文献
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