Michael Altmann

Crystal structure of the yeast eIF4A-eIF4G complex: An RNA-helicase controlled by protein–protein interactions

Translation initiation factors eIF4A and eIF4G form, together with the cap-binding factor eIF4E, the eIF4F complex, which is crucial for recruiting the small ribosomal subunit to the mRNA 5′ end and for subsequent scanning and searching for the start codon. eIF4A is an ATP-dependent RNA helicase whose activity is stimulated by binding to eIF4G. We report here the structure of the complex formed by yeast eIF4Gs middle domain and full-length eIF4A at 2.6-Å resolution. eIF4A shows an extended conformation where eIF4G holds its crucial DEAD-box sequence motifs in a productive conformation, thus explaining the stimulation of eIF4As activity. A hitherto undescribed interaction involves the amino acid Trp-579 of eIF4G. Mutation to alanine results in decreased binding to eIF4A and a temperature-sensitive phenotype of yeast cells that carry a Trp579Ala mutation as its sole source for eIF4G. Conformational changes between eIF4As closed and open state provide a model for its RNA-helicase activity.

A novel inhibitor of cap-dependent translation initiation in yeast: p20 competes with eIF4G for binding to eIF4E

In the yeast Saccharomyces cerevisiae a small protein named p20 is found associated with translation initiation factor eIF4E, the mRNA cap‐binding protein. We demonstrate here that p20 is a repressor of cap‐dependent translation initiation. p20 shows amino acid sequence homology to a region of eIF4G, the large subunit of the cap‐binding protein complex eIF4F, which carries the binding site for eIF4E. Both, eIF4G and p20 bind to eIF4E and compete with each other for binding to eIF4E. The eIF4E–p20 complex can bind to the cap structure and inhibit cap‐dependent but not cap‐independent translation initiation: the translation of a mRNA with the 67 nucleotide Ω sequence of tobacco mosaic virus in its 5′ untranslated region (which was previously shown to render translation cap‐independent) is not inhibited by p20. Whereas the translation of the same mRNA lacking the Ω sequence is strongly inhibited by p20. Disruption of CAF20, the gene encoding p20, stimulates the growth of yeast cells, overexpression of p20 causes slower growth of yeast cells. These results show that p20 is a regulator of eIF4E activity which represses cap‐dependent initiation of translation by interfering with the interaction of eIF4E with eIF4G, e.g. the formation of the eIF4F–complex.

A Saccharomyces cerevisiae homologue of mammalian translation initiation factor 4B contributes to RNA helicase activity.

The TIF3 gene of Saccharomyces cerevisiae was cloned and sequenced. The deduced amino acid sequence shows 26% identity with the sequence of mammalian translation initiation factor eIF‐4B. The TIF3 gene is not essential for growth; however, its disruption results in a slow growth and cold‐sensitive phenotype. In vitro translation of total yeast RNA in an extract from a TIF3 gene‐disrupted strain is reduced compared with a wild‐type extract. The translational defect is more pronounced at lower temperatures and can be corrected by the addition of wild‐type extract or mammalian eIF‐4B, but not by addition of mutant extract. In vivo translation of beta‐galactosidase reporter mRNA with varying degree of RNA secondary structure in the 5′ leader region in a TIF3 gene‐disrupted strain shows preferential inhibition of translation of mRNA with more stable secondary structure. This indicates that Tif3 protein is an RNA helicase or contributes to RNA helicase activity in vivo.

mRNA cap-binding protein: cloning of the gene encoding protein synthesis initiation factor eIF-4E from Saccharomyces cerevisiae.

We have isolated genomic and cDNA clones encoding protein synthesis initiation factor eIF-4E (mRNA cap-binding protein) of the yeast Saccharomyces cerevisiae. Their identity was established by expression of a cDNA in Escherichia coli. This cDNA encodes a protein indistinguishable from purified eIF-4E in terms of molecular weight, binding to and elution from m7GDP-agarose affinity columns, and proteolytic peptide pattern. The eIF-4E gene was isolated by hybridization of cDNA to clones of a yeast genomic library. The gene lacks introns, is present in one copy per haploid genome, and encodes a protein of 213 amino acid residues. Gene disruption experiments showed that the gene is essential for growth.

The Saccharomyces cerevisiae translation initiation factor Tif3 and its mammalian homologue, eIF-4B, have RNA annealing activity.

The Saccharomyces cerevisiae TIF3 gene encodes the yeast homologue of mammalian translation initiation factor eIF‐4B. We have added six histidine residues to the C‐terminus of Tif3 protein (Tif3‐His6p) and purified the tagged protein by affinity chromatography. Tif3‐His6p stimulates translation and mRNA binding to ribosomes in a Tif3‐dependent in vitro system. Furthermore, it binds to single‐stranded RNA and catalyses the annealing of partially complementary RNA strands in vitro. In parallel experiments, RNA annealing activity could also be demonstrated for mammalian eIF‐4B. A role for Tif3/eIF‐4B and RNA annealing activity in the scanning process is proposed.

Selective Pharmacological Targeting of a DEAD Box RNA Helicase

RNA helicases represent a large family of proteins implicated in many biological processes including ribosome biogenesis, splicing, translation and mRNA degradation. However, these proteins have little substrate specificity, making inhibition of selected helicases a challenging problem. The prototypical DEAD box RNA helicase, eIF4A, works in conjunction with other translation factors to prepare mRNA templates for ribosome recruitment during translation initiation. Herein, we provide insight into the selectivity of a small molecule inhibitor of eIF4A, hippuristanol. This coral-derived natural product binds to amino acids adjacent to, and overlapping with, two conserved motifs present in the carboxy-terminal domain of eIF4A. Mutagenesis of amino acids within this region allowed us to alter the hippuristanol-sensitivity of eIF4A and undertake structure/function studies. Our results provide an understanding into how selective targeting of RNA helicases for pharmacological intervention can be achieved.

Functional analysis of seven genes encoding eight translation initiation factor 4E (eIF4E) isoforms in Drosophila

The Drosophila genome-sequencing project has revealed a total of seven genes encoding eight eukaryotic initiation factor 4E (eIF4E) isoforms. Four of them (eIF4E-1,2, eIF4E-3, eIF4E-4 and eIF4E-5) share exon/intron structure in their carboxy-terminal part and form a cluster in the genome. All eIF4E isoforms bind to the cap (m7GpppN) structure. All of them, except eIF4E-6 and eIF4E-8 were able to interact with Drosophila eIF4G or eIF4E-binding protein (4E-BP). eIF4E-1, eIF4E-2, eIF4E-3, eIF4E-4 and eIF4E-7 rescued a yeast eIF4E-deficient mutant in vivo. Only eIF4E-1 mRNAs and, at a significantly lower level, eIF4E3 and eIF4E-8 are expressed in embryos and throughout the life cycle of the fly. The transcripts of the remaining isoforms were detected from the third instar larvae onwards. This indicates the cap-binding activity relies mostly on eIF4E-1 during embryogenesis. This agrees with the proteomic analysis of the eIF4F complex purified from embryos and with the rescue of l(3)67Af, an embryonic lethal mutant for the eIF4E-1,2 gene, by transgenic expression of eIF4E-1. Overexpression of eIF4E-1 in wild-type embryos and eye imaginal discs results in phenotypic defects in a dose-dependent manner.

Translation in Saccharomyces cerevisiae: initiation factor 4E-dependent cell-free system.

The gene encoding translation initiation factor 4E (eIF-4E) from Saccharomyces cerevisiae was randomly mutagenized in vitro. The mutagenized gene was reintroduced on a plasmid into S. cerevisiae cells having their only wild-type eIF-4E gene on a plasmid under the control of the regulatable GAL1 promoter. Transcription from the GAL1 promoter (and consequently the production of wild-type eIF-4E) was then shut off by plating these cells on glucose-containing medium. Under these conditions, the phenotype conferred upon the cells by the mutated eIF-4E gene became apparent. Temperature-sensitive S. cerevisiae strains were identified by replica plating. The properties of one strain, 4-2, were further analyzed. Strain 4-2 has two point mutations in the eIF-4E gene. Upon incubation at 37 degrees C, incorporation of [35S]methionine was reduced to 15% of the wild-type level. Cell-free translation systems derived from strain 4-2 were dependent on exogenous eIF-4E for efficient translation of certain mRNAs, and this dependence was enhanced by preincubation of the extract at 37 degrees C. Not all mRNAs tested required exogenous eIF-4E for translation.

High-level synthesis in Escherichia coli of functional cap-binding eukaryotic initiation factor eIF-4E and affinity purification using a simplified cap-analog resin

Numerous studies have established the important role that eukaryotic initiation factor-4E (eIF-4E) plays during protein biosynthesis. However, biochemical characterization of eIF-4E has proved difficult, mainly because of its low abundance in cells. To facilitate studies on eIF-4E, we have overexpressed Saccharomyces cerevisiae eIF-4E in Escherichia coli. The isolation of eIF-4E was simplified by using a cap-analog affinity matrix (agarose resin) that is considerably less demanding to prepare than those previously reported. We describe a simple and rapid purification scheme that can yield 2-5 micrograms of a homogenous and active preparation of eIF-4E from 1 ml of E. coli culture. E. coli-expressed eIF-4E is active as determined by its ability to bind the cap structure. The results demonstrate that the cap-binding activity of eIF-4E is not dependent on the presence of other proteins that are present at low levels in eIF-4E preparations isolated from eukaryotic cells.

Internal initiation drives the synthesis of Ure2 protein lacking the prion domain and affects [URE3] propagation in yeast cells

The [URE3] phenotype in Saccharomyces cerevisiae is caused by the inactive, altered (prion) form of the Ure2 protein (Ure2p), a regulator of nitrogen catabolism. Ure2p has two functional domains: an N‐terminal domain necessary and sufficient for prion propagation and a C‐terminal domain responsible for nitrogen regulation. We show here that the mRNA encoding Ure2p possesses an IRES (internal ribosome entry site). Internal initiation leads to the synthesis of an N‐terminally truncated active form of the protein (amino acids 94–354) lacking the prion‐forming domain. Expression of the truncated Ure2p form (94–354) mediated by the IRES element cures yeast cells of the [URE3] phenotype. We assume that the balance between the full‐length and truncated (94–354) Ure2p forms plays an important role in yeast cell physiology and differentiation.