Hybridization selection of nucleic acid-protein complexes. 1. Detection of proteins cross-linked to specific mRNAs and DNA sequences by irradiation of intact Escherichia coli cells with ultraviolet light

A method is presented for the detection in crude lysates of subnanogram amounts of proteins covalently bound to a specific nucleic acid sequence. The sensitivity of this method enabled us to study proteins cross-linked to specific DNA and mRNA sequences by irradiation of intact Escherichia coli cells with ultraviolet light. Among the proteins cross-linked to pBR322 DNA, the single strand binding protein, the HU-proteins, and the RNA polymerase beta and sigma subunits were present. Some, but not all proteins were cross-linked to 5-bromodeoxyuridine-substituted DNA more efficiently than to normal DNA. Ribosomal protein S1 is by far the most prominent protein cross-linked to mRNAs. Among the proteins cross-linked in smaller amounts to mRNAs are translation initiation factor IF 1, and at least six proteins of the 30 S ribosomal subunit, among which is S21. No 50 S proteins, nor IF-2, IF-3 or any of the elongation factors could be detected. Some UV-induced nucleic acid-protein cross-links were found to be heat-labile. It is concluded that the method employed may be used to compare the proteins interacting with different mRNAs, as well as single-copy DNA sequences from bacteria and eucaryotes with low complexity genomes.     

HIV-I TAT inhibits PKR activity by both RNA-dependent and RNA-independent mechanisms

Replication of the human immunodeficiency virus type 1 (HIV-1) is inhibited by interferons (IFNs), in part through activity of the IFN-inducible protein kinase PKR. To escape this antiviral effect, HIV-1 has developed strategies for blocking PKR function. We have previously shown that the HIV-1 Tat protein can associate with PKR in vitro and in vivo and inhibit PKR activity. Here we present evidence that Tat can inhibit PKR activity by both RNA-dependent and RNA-independent mechanisms. Tat inhibited PKR activation by the non-RNA activator heparin, and also suppressed PKR basal level autophosphorylation in the absence of RNA. However, when Tat and dsRNA were preincubated, the amount of Tat required to inhibit PKR activation by dsRNA depended on the dsRNA concentration. In addition to its function in vitro, Tat can also reverse translation inhibition mediated by PKR in COS cells. The Tat amino acid sequence required for interaction with PKR was mapped to residues 40-58, overlapping the hydrophobic core and basic region of HIV-1 Tat. Alignment of amino acid sequences of Tat and eIF-2alpha indicates similarity between the Tat-PKR binding region and the residues around the eIF-2alpha phosphorylation site, suggesting that Tat and eIF-2alpha may bind to the same site on PKR.     

An archaeal protein with homology to the eukaryotic translation initiation factor 5A shows ribonucleolytic activity

To identify proteins that are involved in RNA degradation and processing in Halobacterium sp. NRC-1, we purified proteins with RNA-degrading activity by classical biochemical techniques. One of these proteins showed strong homology to the eukaryotic initiation factor 5A (eIF-5A) and was accordingly named archaeal initiation factor 5A (aIF-5A). Eukaryotic IF-5A is known to be involved in mRNA turnover and to bind RNA. Hypusination of eIF-5A is required for sequence-specific binding of RNA. This unique post-translational modification is restricted to Eukarya and Archaea. The exact function of eIF-5A in RNA turnover remained obscure. Here we show for the first time that aIF-5A from Halobacterium sp. NRC-1 exhibits RNA cleavage activity, preferentially cleaving adjacent to A nucleotides. Detectable RNA binding could be shown for aIF-5A purified from Halobacterium sp. NRC-1 but not from Escherichia coli, while both proteins possess RNA cleavage activity, indicating that hypusination of aIF-5A is required for RNA binding but not for its RNA cleavage activity. Furthermore, we show that the hypusinated form of eIF-5A also shows RNase activity while the unmodified protein does not. Charged amino acids in the N-terminal domain of aIF-5A as well as in the C-terminal domain, which is highly similar to the cold shock protein A (CspA), an RNA chaperone of E. coli, are important for RNA cleavage activity. Moreover our results reveal that activity of aIF-5A depends on its oligomeric state.     

GCN20, a novel ATP binding cassette protein, and GCN1 reside in a complex that mediates activation of the eIF-2 alpha kinase GCN2 in amino acid-starved cells.

GCN2 is a protein kinase that phosphorylates the alpha-subunit of translation initiation factor 2 (eIF-2) and thereby stimulates translation of GCN4 mRNA in amino acid-starved cells. We isolated a null mutation in a previously unidentified gene, GCN20, that suppresses the growth-inhibitory effect of eIF-2 alpha hyperphosphorylation catalyzed by mutationally activated forms of GCN2. The deletion of GCN20 in otherwise wild-type strains impairs derepression of GCN4 translation and reduces the level of eIF-2 alpha phosphorylation in vivo, showing that GCN20 is a positive effector of GCN2 kinase function. In accordance with this conclusion, GCN20 was co-immunoprecipitated from cell extracts with GCN1, another factor required to activate GCN2, and the two proteins interacted in the yeast two-hybrid system. We conclude that GCN1 and GCN20 are components of a protein complex that couples the kinase activity of GCN2 to the availability of amino acids. GCN20 is a member of the ATP binding cassette (ABC) family of proteins and is closely related to ABC proteins identified in Caenorhabditis elegans, rice and humans, suggesting that the function of GCN20 may be conserved among diverse eukaryotic organisms.     

Evidence that the 5'-untranslated leader of mRNA affects the requirement for wheat germ initiation factors 4A, 4F, and 4G

The efficiency of translation of alfalfa mosaic virus (AMV) RNA 4, barley alpha-amylase (B alpha A) mRNA, and two chimeric mRNAs, AMV 4-B alpha A and B alpha A-AMV 4 (in which the 5' leader sequences of the two mRNAs were interchanged), was measured in an S30 extract from wheat germ and a fractionated system from wheat germ in which translation could be made dependent upon initiation factor (eIF) 3, 4A, 4F, or 4G. In the S30 system, AMV RNA 4 and the chimeric mRNA AMV 4-B alpha A are translated much more efficiently than B alpha A mRNA and the chimeric mRNA B alpha A-AMV 4. When the S30 system was supplemented with high amounts of purified eIF-3, eIF-4A, eIF-4F, and eIF-4G, B alpha A and B alpha A-AMV 4 mRNAs were translated as efficiently as AMV RNA 4 and AMV 4-B alpha A mRNA. These findings indicated that the mRNAs containing the B alpha A leader sequence required higher amounts of one or more of the initiation factors (eIF-3, eIF-4A, eIF-4F, and eIF-4G) for efficient translation. Determination of the amounts of the initiation factors required for translation in the fractionated system showed that AMV RNA 4 required 2-4-fold lower amounts of eIF-3, eIF-4A, eIF-4F, and eIF-4G than did B alpha A mRNA. Replacement of the B alpha A leader sequence with that of AMV RNA 4 decreased the amounts of eIF-4A, eIF-4G, and eIF-3 required, but did not affect the amount of eIF-4F required. Replacement of the AMV RNA 4 leader sequence with that of B alpha A mRNA increased the amounts of eIF-4F, eIF-4G, and eIF-3 required, but did not affect the amount of eIF-4A required. These data strongly suggest that the amounts of the factors required are affected not only by the 5' leader itself but also by interactions between the 5' leader and a region(s) of the mRNA 3' to the initiation codon.     

Genomic RNA of mengovirus V. Recognition of common features by ribosomes and eucaryotic initiation factor 2.

Binding of ribosomes to the 32P-labeled genomic RNA of mengovirus was studied in lysates of mouse L929 and Krebs ascites cells under conditions for initiation of translation. Upon total digestion with RNase T1, the 32P-labeled RNA protected in either 40S or 80S initiation complexes yielded four unique, large oligonucleotides. Each of these oligonucleotides occurred once in the viral RNA molecule. The same four oligonucleotides were recovered from 80S initiation complexes formed in lysates in which unlabeled mengovirus RNA had been translated extensively, indicating that recognition by ribosomes was not modulated detectably by a viral translation product. The recognition of intact, 32P-labeled mengovirus RNA by eucaryotic initiation factor 2 (eIF-2) was examined by direct complex formation. Fingerprint analysis of the RNA protected by eIF-2 against RNase T1 digestion yielded three T1 oligonucleotides that were identical to three of the four oligonucleotides protected in either 40S or 80S initiation complexes. A physical map of the large T1 oligonucleotides of the mengovirus RNA molecule was constructed, and the four protected oligonucleotides were found to map internally, within the region between the polycytidylate tract and the 3' end. For either ribosomes or eIF-2, the protected oligonucleotides could not be arranged in a continuous sequence, suggesting that they constitute at least two widely separated domains. These results show that ribosomes recognize and blind to more than a single sequence in mengovirus RNA, located internally in regions that are far removed from the 5' end of the molecule. eIF-2 itself binds with high specificity to mengovirus RNA, recognizing apparently three of the four sequences recognized by ribosomes.     

Euglena gracilis chloroplast initiation factor 2. Identification and initial characterization

The chloroplast protein synthesis factor responsible for the binding of fMet-tRNAMeti to chloroplast 30 S ribosomal subunits (IF-2chl) has been identified in whole cell extracts of Euglena gracilis. The IF-2chl activity is present in considerably higher amounts in extracts of light-grown cells than in extracts of dark-grown cells. About 90% of this activity is found in the postribosomal supernatant of the cell. Chromatography on phosphocellulose results in the partial purification of IF-2chl and separates the chloroplast factor from the cytoplasmic factor eIF-2A. The binding of fMet-tRNAMeti to chloroplast 30 S subunits is message-dependent as observed for prokaryotic systems. In addition, GTP stimulates the IF-2chl-dependent reaction 3-fold. The binding reaction shows broad monovalent and divalent cation optima. The activity of IF-2chl is stimulated 2-fold by the addition of either Escherichia coli IF-1 or IF-3, and 4-fold by the inclusion of both factors. Chloroplast IF-2 is quite active on the homologous 30 S ribosomal subunits but shows little activity on E. coli 30 S or wheat germ 40 S subunits.     

Involvement of ribosomal protein S1 in the assembly of the initiation complex.

Antibodies against ribosomal protein S1 (anti-S1) have been used to determine the function of S1 in the partial reactions involved in the translation of MS2 RNA in vitro. Vacant ribosomes are fully sensitive to the antibodies, whereas elongating ribosomes are resistant. We have determined at which stage of translation the resistance to anti-S1 is acquired. We find that insensitivity to anti-S1 already arises upon mixing 30-S subunits with MS2 RNA. Apparently the two particles form a complex in which S1 is functionally protected against its antibody. Complex formation depends on elevated temperature, a suitable ionic environment and it is stimulated by the initiation factor IF-3. It does not depend on IF-1, IF-2 or fMet-tRNA. Thus ribosomes have the potential to recognize the messenger in the absence of fMet-tRNA. Protein S1 appears directly involved in this primary recognition reaction.     

Growth arrest and DNA damage-inducible protein GADD34 targets protein phosphatase 1 alpha to the endoplasmic reticulum and promotes dephosphorylation of the alpha subunit of eukaryotic translation initiation factor 2

The growth arrest and DNA damage-inducible protein, GADD34, associates with protein phosphatase 1 (PP1) and promotes in vitro dephosphorylation of the alpha subunit of eukaryotic translation initiation factor 2, (eIF-2 alpha). In this report, we show that the expression of human GADD34 in cultured cells reversed eIF-2 alpha phosphorylation induced by thapsigargin and tunicamycin, agents that promote protein unfolding in the endoplasmic reticulum (ER). GADD34 expression also reversed eIF-2 alpha phosphorylation induced by okadaic acid but not that induced by another phosphatase inhibitor, calyculin A (CA), which is a result consistent with PP1 being a component of the GADD34-assembled eIF-2 alpha phosphatase. Structure-function studies identified a bipartite C-terminal domain in GADD34 that encompassed a canonical PP1-binding motif, KVRF, and a novel RARA sequence, both of which were required for PP1 binding. N-terminal deletions of GADD34 established that while PP1 binding was necessary, it was not sufficient to promote eIF-2 alpha dephosphorylation in cells. Imaging of green fluorescent protein (GFP)-GADD34 proteins showed that the N-terminal 180 residues directed the localization of GADD34 at the ER and that GADD34 targeted the alpha isoform of PP1 to the ER. These data provide new insights into the mode of action of GADD34 in assembling an ER-associated eIF-2 alpha phosphatase that regulates protein translation in mammalian cells.     

Requirement of chain initiation factor 3 and ribosomal protein S1 in translation of synthetic and natural messenger RNA.

Amino acid incorporation directed by poly(A), poly(U) or R17 RNA has been examined in S1-depleted protein synthesizing systems. We observe that the translation of either synthetic or natural messenger RNA is strictly dependent on the presence of chain initiation factor 3 and ribosomal protein S1. With poly(A) or poly(U) both IF-3 and S1 stimulate amino acid incorporation at least 25-fold, and with R17 RNA the stimulation is approximately 15-fold. More than one copy of S1 per ribosome decreases amino acid incorporation directed by poly(U) or R17 RNA. Initiation complex formation with R17 RNA is also stimulated optimally by the addition of one copy of S1 per ribosome. The function of IF-3 and S1 in protein synthesis is considered.     

Chloroplast translational initiation factor 3. Purification and characterization of multiple forms from Euglena gracilis.

The chloroplast translational initiation factor 3 (IF-3chl) has been purified by a combination of gravity and high pressure liquid chromatographic steps. IF-3chl activity has been resolved into three forms designated alpha, beta, and gamma. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicates that the alpha form corresponds to a single polypeptide with a molecular mass of approximately 34 kDa. The beta and gamma forms have been purified to near homogeneity, and both forms appear to function as monomers with molecular masses of about 39-42 kDa. All three forms are heat stable. All the forms of IF-3chl detected enhance the poly (A,U,G)-dependent binding of the initiator tRNA to chloroplast 30 S ribosomal subunits in the presence of Escherichia coli IF-1 and IF-2. The chloroplast factor, unlike the corresponding bacterial factor, does not have a strong RNA binding activity.     

Eukaryotic initiation factor 5A is a cellular target of the human immunodeficiency virus type 1 Rev activation domain mediating trans- activation

Expression of human immunodeficiency virus type 1 (HIV-1) structural proteins requires the presence of the viral trans-activator protein Rev. Rev is localized in the nucleus and binds specifically to the Rev response element (RRE) sequence in viral RNA. Furthermore, the interaction of the Rev activation domain with a cellular cofactor is essential for Rev function in vivo. Using cross-linking experiments and Biospecific Interaction Analysis (BIA) we identify eukaryotic initiation factor 5A (eIF-5A) as a cellular factor binding specifically to the HIV-1 Rev activation domain. Indirect immunofluorescence studies demonstrate that a significant fraction of eIF-5A localizes to the nucleus. We also provide evidence that Rev transactivation is functionally mediated by eIF-5A in Xenopus oocytes. Furthermore, we are able to block Rev function in mammalian cells by antisense inhibition of eIF-5A gene expression. Thus, regulation of HIV-1 gene expression by Rev involves the targeting of RRE-containing RNA to components of the cellular translation initiation complex.     

Dominant negative mutants of mammalian translation initiation factor eIF-4A define a critical role for eIF-4F in cap-dependent and cap-independent initiation of translation.

Eukaryotic translation initiation factor-4A (eIF-4A) plays a critical role in binding of eukaryotic mRNAs to ribosomes. It has been biochemically characterized as an RNA-dependent ATPase and RNA helicase and is a prototype for a growing family of putative RNA helicases termed the DEAD box family. It is required for mRNA-ribosome binding both in its free form and as a subunit of the cap binding protein complex, eIF-4F. To gain further understanding into the mechanism of action of eIF-4A in mRNA-ribosome binding, defective eIF-4A mutants were tested for their abilities to function in a dominant negative manner in a rabbit reticulocyte translation system. Several mutants were demonstrated to be potent inhibitors of translation. Addition of mutant eIF-4A to a rabbit reticulocyte translation system strongly inhibited translation of all mRNAs studied including those translated by a cap-independent internal initiation mechanism. Addition of eIF-4A or eIF-4F relieved inhibition of translation, but eIF-4F was six times more effective than eIF-4A, whereas eIF-4B or other translation factors failed to relieve the inhibition. Kinetic experiments demonstrated that mutant eIF-4A is defective in recycling through eIF-4F, thus explaining the dramatic inhibition of translation. Mutant eIF-4A proteins also inhibited eIF-4F-dependent, but not eIF-4A-dependent RNA helicase activity. Taken together these results suggest that eIF-4A functions primarily as a subunit of eIF-4F, and that singular eIF-4A is required to recycle through the complex during translation. Surprisingly, eIF-4F, which binds to the cap structure, appears to be also required for the translation of naturally uncapped mRNAs.     

Translational control by messenger RNA competition for eukaryotic initiation factor 2

Translation of globin mRNA in a micrococcal nuclease-treated reticulocyte lysate was studied in the presence of increasing amounts of Mengovirus RNA, under conditions in which the number of translation initiation events remains constant as judged by the transfer of label from N-formyl[35S]methionyl-tRNAf into protein. The translation of globin mRNA is progressively inhibited by low concentrations of Mengovirus RNA, free of detectable traces of double-stranded RNA, concomitant with the increasing synthesis of Mengovirus RNA-directed products. On a molar basis, Mengovirus RNA apparently competes about 35 times more effectively than globin mRNA for a critical component in translation. The competition is relieved by the addition of highly purified eukaryotic initiation factor 2 (eIF-2). Addition of eIF-2 does not stimulate overall protein synthesis, but shifts it in favor of globin synthesis. No stimulation of globin mRNA translation by eIF-2 is seen when Mengovirus RNA is absent. These experiments show that Mengovirus RNA competes, directly or indirectly, with globin mRNA for eIF-2. In direct binding experiments using isolated mRNA and eIF-2, Mengovirus RNA is shown to compete with globin mRNA for eIF-2 and to exhibit a 30-fold higher affinity for this factor. The binding of Mengovirus RNA to eIF-2 is much more resistant to increasing salt concentrations than is the binding of globin mRNA, again reflecting its high affinity. These results reveal a direct correlation between the ability of these mRNA species to compete in translation and their ability to bind to initiation factor eIF-2. They suggest that the affinity of a given mRNA species for eIF-2 is essential in determining its translation, relative to that of other mRNA species. Messenger RNA competition for eIF-2 may contribute significantly to the selective translation of viral RNA in infected cells.