The DEAD box proteins encoded by the genes ddx5 (p68) and ddx17 (isoforms p72 and p82) are more closely related to each other than to any other member of their family. We found that p68 negatively controls p72/p82 gene expression but not vice versa. Knocking down of either gene does not affect cell proliferation, in case of p68 suppression, however, only on condition that p72/p82 overexpression was granted. In contrast, co-silencing of both genes causes perturbation of nucleolar structure and cell death. In mutant studies, the apparently redundant role(s) of p68 and p72/p82 correspond to their ability to catalyze RNA rearrangement rather than RNA unwinding reactions. In search for possible physiological targets of this RNA rearrangement activity it is shown that the nucleolytic cleavage of 32S pre-rRNA is reduced after p68 subfamily knock-down, most probably due to a failure in the structural rearrangement process within the pre-60S ribosomal subunit preceding the processing of 32S pre-rRNA.
The human gene ddx42 encodes a human DEAD box protein highly homologous to the p68 subfamily of RNA helicases. In HeLa cells, two ddx42 poly(A)+ RNA species were detected both encoding the nuclear localized 938 amino acid Ddx42p polypeptide. Ddx42p has been heterologously expressed and its biochemical properties characterized. It is an RNA binding protein, and ATP and ADP modulate its RNA binding affinity. Ddx42p is an NTPase with a preference for ATP, the hydrolysis of which is enhanced by various RNA substrates. It acts as a non-processive RNA helicase. Interestingly, RNA unwinding by Ddx42p is promoted in the presence of a single-strand (ss) binding protein (T4gp32). Ddx42p, particularly in the ADP-bound form (the state after ATP hydrolysis), also mediates efficient annealing of complementary RNA strands thereby displacing the ss binding protein. Ddx42p therefore represents the first example of a human DEAD box protein possessing RNA helicase, protein displacement and RNA annealing activities. The adenosine nucleotide cofactor bound to Ddx42p apparently acts as a switch that controls the two opposing activities: ATP triggers RNA strand separation, whereas ADP triggers annealing of complementary RNA strands.
p68 and p72 are two highly related DEAD box proteins with similar biochemical activities in the nucleus of vertebrate cells; it is unknown whether they have redundant or differential in vivo functions. We report on a third member of this subfamily that is alternatively expressed from p72 mRNA. A detailed analysis of HeLa p72 mRNA was performed. It has an overall length of more than 5 kb and contains a 0.75-kb 5-untranslated region and a 3-untranslated region of 2.5 kb. Its open reading frame extends to nucleotide ؊243 upstream of the first in-frame AUG (A in the AUG triplet is ؉1) which serves as the p72 translation initiator codon. We provide evidence that alternative translation at a non-AUG within the extra coding region of this mRNA yields an 82-kDa protein (p82). Immunological studies substantiate that p82 is a naturally existing p72 variant and that both proteins are expressed at similar concentrations. p82 purified from HeLa cells is an ATP-dependent RNA helicase with biochemical properties almost identical to those of p72.Control of transcription is generally considered the main regulation level of mammalian gene expression, although mRNA maturation and modulation of mRNA stability or translational efficiency also contribute to expression control (1). Generation of protein variants by alternative pre-mRNA splicing or alternative initiation of mRNA translation enlarges the coding capacity and may explain the relatively low number of genes actually found in the human genome. According to recent estimations, on average one gene encodes three proteins (2).Although the 5Ј-untranslated leader sequences (UTRs) 1 of most vertebrate mRNAs are less than 100 nucleotides (nt) long (3), those of tightly controlled genes usually are longer and are GC-rich. Such structure-prone 5Ј-UTRs can modulate translation by the presence of upstream (up) open reading frames (ORFs) in addition to the main ORF, by formation of secondary structures, and/or by RNA-protein interactions (4). Indeed, they appear particularly characteristic of mRNAs encoding growth factors, receptor proteins, transcription factors, signal transduction components, proto-oncogenes, tumor suppressor proteins, and even proteins that mostly are constitutively expressed at a low level ("housekeeping" proteins).DEAD/DEXH box proteins belonging to superfamily II of RNA helicases play a universal role in RNA metabolism of proand eukaryotes. Not surprisingly, they are involved in gene expression control, for instance during germ cell and embryonic development or in cell proliferation and differentiation (5). This in turn requires tight control of at least some DEAD/DEXH box proteins like CsdA of Escherichia coli, which is regulated by an 11-nt "cold box" sequence in its 5Ј-UTR (6), or the Saccharomyces cerevisiae Dbp2, the gene of which contains an unusually large intron that is part of a post-transcriptional autoregulatory feedback loop (7). A similarly complex transcription regulation has been shown for nuclear p68 (8), a mammalian homologue of Dbp2. In addition,...
Non-sense-mediated mRNA decay (NMD) is a mechanism of translation-dependent mRNA surveillance in eukaryotes: it degrades mRNAs with premature termination codons (PTCs) and contributes to cellular homeostasis by downregulating a number of physiologically important mRNAs. In the NMD pathway, Upf proteins, a set of conserved factors of which Upf1 is the central regulator, recruit decay enzymes to promote RNA cleavage. In mammals, the degradation of PTC-containing mRNAs is triggered by the exon–junction complex (EJC) through binding of its constituents Upf2 and Upf3 to Upf1. The complex formed eventually induces translational repression and recruitment of decay enzymes. Mechanisms by which physiological mRNAs are targeted by the NMD machinery in the absence of an EJC have been described but still are discussed controversially. Here, we report that the DEAD box proteins Ddx5/p68 and its paralog Ddx17/p72 also bind the Upf complex by physical interaction with Upf3, thereby interfering with the binding of EJC. By activating the NMD machinery, Ddx5 is shown to regulate the expression of its own, Ddx17 and Smg5 mRNAs. For NMD triggering, the adenosine triphosphate-binding activity of Ddx5 and the 3′-untranslated region of substrate mRNAs are essential.
Mitochondrial cytochromes P450 are essential for biosynthesis of steroid hormones, vitamin D and bile acids. In mammals, the electrons needed for these reactions are provided via adrenodoxin and adrenodoxin reductase (AdR). Recently, Schizosaccharomyces pombe was introduced as a new host for the functional expression of human mitochondrial steroid hydroxylases without the coexpression of their natural redox partners. This fact qualifies S. pombe for the biotechnological production of steroids and for application as inhibitor test organism of heterologously expressed cytochromes P450. In this paper, we present evidence that the S. pombe ferredoxin reductase, arh1, and ferredoxin, etp1fd provide mammalian class I cytochromes P450 with reduction equivalents. The recombinant reductase showed an unusual weak binding of flavin adenine dinucleotide (FAD), which was mastered by modifying the FAD-binding region by site-directed mutagenesis yielding a stable holoprotein. The modified reductase arh1_A18G displayed spectroscopic characteristics similar to AdR and was shown to be capable of accepting electrons with no evident preference for NADH or NADPH, respectively. Arh1_A18G can substitute for AdR by interacting not only with its natural redox partner etp1fd but also with the mammalian homolog adrenodoxin. Cytochrome P450-dependent substrate conversion with all combinations of the mammalian and yeast redox proteins was evaluated in a reconstituted system.
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