The HRIGRXXR region of the DEAD box RNA helicase eukaryotic translation initiation factor 4A is required for RNA binding and ATP hydrolysis

Overexpression, purification, and properties of Escherichia coli ribonuclease II

Ribonuclease II (RNase II) is a major exonuclease in Escherichia coli that hydrolyzes single-stranded polyribonucleotides processively in the 3' to 5' direction. To understand the role of RNase II in the decay of messenger RNA, a strain overexpressing the rnb gene was constructed. Induction resulted in a 300-fold increase in RNase II activity in crude extracts prepared from the overexpressing strain compared to that of a non-overexpressing strain. The recombinant polypeptide (Rnb) was purified to apparent homogeneity in a rapid, simple procedure using conventional chromatographic techniques and/or fast protein liquid chromatography to a final specific activity of 4,100 units/mg. Additionally, a truncated Rnb polypeptide was purified, solubilized, and successfully renatured from inclusion bodies. The recombinant Rnb polypeptide was active against both [3H]poly(A) as well as a novel (synthetic partial duplex) RNA substrate. The data show that the Rnb polypeptide can disengage from its substrate upon stalling at a region of secondary structure and reassociate with a new free 3'-end. The stalled substrate formed by the dissociation event cannot compete for the Rnb polypeptide, demonstrating that duplexed RNAs lacking 10 protruding unpaired nucleotides are not substrates for RNase II. In addition, RNA that has been previously trimmed back to a region of secondary structure with purified Rnb polypeptide is not a substrate for polynucleotide phosphorylase-like activity in crude extracts. The implications for mRNA degradation and the proposed role for RNase II as a repressor of degradation are discussed.

Comparison of the replication of positive-stranded RNA viruses of plants and animals

It is clear from the experimental data that there are some similarities in RNA replication for all eukaryotic positive-stranded RNA viruses—that is, the mechanism of polymerization of the nucleotides is probably similar for all. It is noteworthy that all mechanisms appear to utilize host membranes as a site of replication. Membranes appear to function not only as a way of compartmentalizing virus RNA replication but also appear to have a central role in the organization and functioning of the replication complex, and further studies in this area are needed. Within virus supergroups, similarities are evident between animal and plant viruses—for example, in the nature and arrangements of replication genes and in sequence similarities of functional domains. However, it is also clear that there has been considerable divergence, even within supergroups. For example, the animal alpha-viruses have evolved to encode proteinases which play a central controlling function in the replication cycle, whereas this is not common in the plant alpha-like viruses and even when it occurs, as in the tymoviruses, the strategies that have evolved appear to be significantly different. Some of the divergence could be host-dependent and the increasing interest in the role of host proteins in replication should be fruitful in revealing how different systems have evolved. Finally, there are virus supergroups that appear to have no close relatives between animals and plants, such as the animal coronavirus-like supergroup and the plant carmo-like supergroup.

ROK1, a high-copy-number plasmid suppressor of kem1, encodes a putative ATP-dependent RNA helicase in Saccharomyces cerevisiae

The KEM1 gene is involved in nuclear fusion during conjugation, and chromosome transmission and spindle pole body duplication/or separation during mitotic cell division in the yeast Saccharomyces cerevisiae. KEM1 was also independently identified as DST2, SEP1, XRN1 and RAR5 on the basis of DNA strand transferase or exoribonuclease activity in vitro or mutations affecting plasmid stability. To understand the various functions suggested for KEM1 and to identify other genes with functions similar or related to those of KEM1, we have characterized the ROK1 gene which was isolated as a high-copy-number plasmid suppressor of the kem1 null mutation. Sequence analysis of the smallest subclone with the suppression activity revealed an open reading frame of 564 amino acids. The ROK1 aa sequence contains highly conserved domains found in the DEAD protein family of ATP-dependent RNA helicases. ROK1 is essential for viability and is closely linked to KEM1 on chromosome VII.

Cloning and characterization of an ATBF1 isoform that expresses in a neuronal differentiation-dependent manner

The human ATBF1 cDNA reported previously, now termed ATBF1-B, encodes a 306-kDa protein containing 4 homeodomains and 18 zinc fingers including one pseudo zinc finger motif. Here, we report the isolation of a second ATBF1 cDNA, 12 kilobase pairs long, termed ATBF1-A. The deduced ATBF1-A protein is 404 kDa in size and differs from ATBF1-B by a 920-amino acid extention at the N terminus. Analysis of 5'-genomic sequences showed that the 5'-noncoding sequences specific to ATBF1-A and ATBF1-B transcripts were contained in distinct exons that could splice to a downstream exon common to the ATBF1-A and ATBF1-B mRNAs. The expression of ATBF1-A transcripts increased to high levels when P19 and NT2/D1 cells were treated with retinoic acid to induce neuronal differentiation. Preferential expression of ATBF1-A transcripts was also observed in developing mouse brain. Transient transfection assays showed that the 5.5-kilobase pair sequence upstream of the ATBF1-A-specific exon (exon 2) supported expression of the linked chloramphenicol acetyltransferase gene in neuronal cells derived from P19 cells but not in undifferentiated P19 or in F9 cells, which do not differentiate into neurons. These results showed that ATBF1-A and ATBF1-B transcripts are generated by alternative promoter usage combined with alternative splicing and that the ATBF1-A-specific promoter is activated during neuronal differentiation.

Molecular cloning of the gene encoding nuclear DNA helicase II. A bovine homologue of human RNA helicase A and Drosophila Mle protein

Nuclear DNA helicase II (NDH II) unwinds both DNA and RNA (Zhang, S., and Grosse, F. (1994) Biochemistry 33, 3906-3912). Here, we report on the molecular cloning and sequence determination of the complementary DNA (cDNA) coding for this DNA and RNA helicase. The full-length cDNA sequence was derived from overlapping clones that were detected by immunoscreening of a calf thymus cDNA library in bacteriophage lambda gt11. This cDNA was 4,528 bases in length, which corresponded well with a 4.5-4.7-kilobase-long mRNA as detected by Northern blot analysis. The open reading frame of NDH II cDNA predicts a polypeptide of 1287 amino acids and a calculated molecular mass of 141,854 daltons. NDH II is related to a group of nucleic acid helicases from the DEAD/H box family II, with the signature motif DEIH in domain II. Two further proteins of this family, i.e. human RNA helicase A and Drosophila Maleless (Mle) protein, were found to be highly homologous to NDH II. With RNA helicase A, there was 91.5% identity and 95.5% similarity between the amino acid residues; with Mle protein, we observed a 50% identity and an 85% similarity. Antibodies against human RNA helicase A cross-reacted with NDH II, further supporting that NDH II is the bovine homologue of human RNA helicase A. Immunofluorescence studies revealed a mainly nuclear localization of NDH II. A role for NDH II in nuclear DNA and RNA metabolism is suggested.

Poliovirus protein 2C contains two regions involved in RNA binding activity

Poliovirus protein 2C is involved in poliovirus RNA replication, although the exact function of 2C is still unknown. Recently, it was shown that 2C can be purified to high levels when expressed as a fusion protein with maltose-binding protein (MBP). Evidence was presented that 2C has ATPase and GTPase activities; preliminary results also indicated that 2C interacts with RNA (Rodríguez, P.L., and Carrasco, L. (1993) J. Biol. Chem. 268, 8105-8110). In the present study, 20 variants of 2C have been generated, and their NTPase and RNA binding activities were analyzed. Moreover, an easy procedure to obtain genuine 2C after factor Xa cleavage of an MBP2-2C fusion protein is described. This work has determined that 2C has two regions involved in RNA binding: a NH2-terminal region located between amino acids 21 and 45 and a COOH-terminal region involving an Arg-rich region located between amino acids 312 and 319. Deletion of either the NH2- or COOH-terminal RNA-binding region abolishes RNA binding. Deletion of an internal region of protein 2C that includes the nucleotide-binding motif does not affect RNA binding, whereas this deletion destroys ATPase and GTPase activities. Therefore, the NTPase activity and the RNA binding capacity of protein 2C are located in different regions of the molecule.

Highly conserved genes coding for eukaryotic translation initiation factor eIF-4A of tobacco have specific alterations in functional motifs

Eukaryotic translation initiation factor eIF-4A is an ATP-dependent RNA helicase that is required for the binding of mRNA to ribosomes. Plant eIF-4A-like proteins are highly homologous to eIF-4As from yeast, mouse and Drosophila melanogaster. The pattern of intron-exon boundaries in eIF-4A-like genes are conserved within tobacco, but are not conserved with other organisms. Fixed spacings between the functionally important sequence motifs, GKT-PTRELA (72 bp), DEAD-SAT (81 bp) and SAT-HRIGR (426 bp), are conserved between plants, mouse, Drosophila and yeast.

Cloning and expression of a yeast gene encoding a protein with ATPase activity and high identity to the subunit 4 of the human 26 S protease

The cloning, expression, and biochemical characterization of an essential gene of Saccharomyces cerevisiae that encodes for a new member of the TBP1-like subfamily of putative ATPases are described. The protein is 72% identical at the amino acid level to subunit four (S4) of the human 26 S protease and 73% identical to Schizosaccharomyces pombe MTS2 gene product. The purified, recombinant protein, designated Yhs4p, has an estimated molecular mass of 49 kDa and exhibits a Mg(2+)-dependent ATPase activity with nucleotide specificity and Km for ATP similar to those exhibited by the human 26 S protease. The observed ATPase activity was reduced by 73% upon the introduction of point mutation K229Q in the "P-loop" domain of the ATP-binding site relative to the nonmutated form of the protein. This is the first direct biochemical evidence supporting the putative ATPase activity of a member of the TBP1-like subfamily. Furthermore, the experimental results demonstrate a regulatory function for the amino-terminal region of the molecule. The amino-terminal truncated form of Yhs4p lacking two clusters of positively charged amino acids exhibits a greater ATPase activity. The ATPase activity of both the truncated and complete forms of Yhs4p is stimulated by polyanions. Polylysine partially inhibits the ATPase activity of the amino-terminal truncated form having no observable effect on the complete protein. N-Ethylmaleimide inhibits the ATPase activity of both forms of Yhs4p. We propose that Yhs4p ATPase may play an essential role in the regulatory function of the proteolytic activity of the yeast 26 S protease.

The BAT1 gene in the MHC encodes an evolutionarily conserved putative nuclear RNA helicase of the DEAD family

The BAT1 gene has previously been identified about 30 kb upstream from the tumor necrosis factor (TNF) locus and close to a NF kappa b-related gene of the nuclear factor family in the major histocompatibility complex (MHC) of human, mouse, and pig. We now show that the BAT1 translation product is the homolog of the rat p47 nuclear protein, the WM6 Drosophila gene product, and probably also Ce08102 of Caenorhabditis elegans, all members of the DEAD protein family of ATP-dependent RNA helicases. This family has more than 40 members, including the eukaryotic translation initiation factor-4A (eIF-4A), the human nuclear protein p68, and the Drosophila oocyte polar granule component vasa. BAT1 spans about 10 kb, is split into 10 exons of varying length, and encodes a protein of 428 amino acids (approximately 48 kDa). Human and pig BAT1 cDNAs display 95.6% identity in the coding region and 80% identity in the 5' and 3' noncoding regions. Several repeat sequences of different types were identified in introns of the porcine BAT1 gene. Three different mRNAs, 4.1, 1.7, and 0.9 kb, respectively, were detected in all tissues analyzed upon hybridization with porcine BAT1 cDNA. Transfection and expression of human BAT1 cDNA after tagging with a heterologous antibody recognition epitope revealed a nuclear localization of the hybrid protein. An MspI RFLP was detected in an SLA class I typed family, confirming the localization of the BAT1 gene in the porcine MHC. BAT1 thus encodes a putative nuclear ATP-dependent RNA helicase and is likely to have an indispensable function.

mRNAs can be stabilized by DEAD-box proteins

Eubacterial messenger RNAs are synthesized and translated simultaneously; moreover the speed of ribosomes usually matches that of RNA polymerase. We report here that when in Escherichia coli the host RNA polymerase is replaced by the eightfold faster bacteriophage T7 enzyme for the transcription of the lacZ gene, the beta-galactosidase yield per transcript is depressed 100-fold. But the overexpression of DEAD-box proteins greatly improves this low yield by stabilizing the corresponding transcripts. More generally, it stabilizes inefficiently translated E. coli mRNAs. Ribosome-free mRNA regions, such as those lying behind the fast T7 enzyme or between successive ribosomes on inefficiently translated transcripts, are often unstable and we propose that DEAD-box proteins protect them from endonucleases. These results pinpoint the importance of transcription-translation synchronization for mRNA stability, and reveal an undocumented property of DEAD-box RNA helicases. These proteins have been implicated in a variety of processes involving RNA but not mRNA stability.

Control of gene expression at the level of translation initiation

Protein synthesis is controlled at the level of translation initiation. Cells rapidly respond to environmental changes by disassembly of polysomes and recruitment of specific mRNAs from inactive ribonucleoprotein particles into polysomes active in translation. Recent insights have elucidated specific protein and RNA sequence interactions that are required to mobilize translation of selective mRNAs. The specificity of translational control provides a unique target to inhibit synthesis of specific polypeptides to control infectious disease as well as to control aberrant cell growth. In addition, greater understanding of the factors that limit protein synthesis is enabling the design of novel strategies to optimize protein expression and engineer host cells for enhanced growth and protein synthesis capacity.

Characterization of NTPase, RNA-binding and RNA-helicase activities of the cytoplasmic inclusion protein of tamarillo mosaic potyvirus

The 66-kDa cytoplasmic inclusion protein of tamarillo mosaic potyvirus was purified to near homogeneity using organic solvent clarification, differential centrifugation and sucrose density gradient centrifugation. ATPase and GTPase activities were shown to co-purify with the 66-kDa protein. ATPase activity was stimulated up to fivefold in the presence of 20 microM poly(A). The Km value for ATP hydrolysis (18 microM), was minimally affected upon addition of poly(A). In contrast, the Vmax value for ATP hydrolysis was increased fivefold by the addition of poly(A). Binding of RNA by the cytoplasmic inclusion protein was demonstrated by gel electrophoresis of ultraviolet cross-linked enzyme-RNA complexes. In the absence of added NTP, complexes between the cytoplasmic inclusion protein and single-stranded RNA species formed rapidly in the pH range 3-7, but not at pH 8 or 9. Binding to single-stranded RNA was markedly decreased by the addition of NaCl (10 mM), suggesting a weak association between RNA and enzyme. The cytoplasmic inclusion protein bound single-stranded RNA or partially double-stranded RNA duplexes with single-stranded overhangs of 35 bases and 81 bases, respectively, but did not bind 16-bp blunt-ended double-stranded RNA. RNA binding occurred in the absence of NTP (ATP, GTP, CTP or UTP), whereas dissociation of bound RNA occurred only in the presence of NTP. RNA duplex unwinding (helicase) activity of the enzyme was demonstrated in the presence of any of the above four NTPs using partially double-stranded RNA duplexes with 3' single-stranded overhangs. We propose that the cytoplasmic inclusion protein of tamarillo mosaic virus is an RNA helicase, which translocates in the 3' to 5' direction in an energy-dependent manner, unwinding double-stranded regions.

Initiation of protein synthesis in eukaryotes

The study of the regulation of initiation of protein synthesis has recently gained momentum because of the established relationship between translation initiation, cell growth and tumorigenesis. Therefore much effort is devoted to the role of protein kinases which are activated in signal transduction cascades and which are responsible for the phosphorylation of a number of initiation factors. These specific factors are mainly involved in the binding of messenger RNA to the 40S ribosome, a process that makes the unwinding of the 5' untranslated region necessary. It appears that the phosphorylation of these factors increases their ability for cap recognition and helicase activity. The enhanced phosphorylation of the messenger binding factors results not only in an overall stimulation of translation, but especially weak messengers are positively discriminated. The above mechanisms mainly deal with qualitative control of translation, i.e., messenger selection, but phosphorylation also plays a role in quantitative regulation of protein synthesis. The generation of active eIF-2, the initiation factor that binds the Met-tRNA(i) and GTP, is dependent on a factor involved in the GDP-GTP exchange. Phosphorylation of eIF-2 results in sequestration of the exchange factor and a slowing down of the rate of initiation.