Characterization and purification of a mammalian endoribonuclease specific for the alpha -globin mRNA

Purification and properties of the vaccinia virus mRNA processing factor

The mRNAs encoding the vaccinia virus F17 protein and the cowpox A-type inclusion protein are known to possess sequence-homogeneous 3' ends, generated by a post-transcriptional cleavage event. By using partially purified extracts, we have previously shown that the same factor probably cleaves both the F17 and A-type inclusion protein transcripts and that the cleavage factor is either virus-coded or virus-induced during the post-replicative phase of virus replication. In this study, we have purified the cleavage factor from vaccinia-infected HeLa cells using column chromatography and gel filtration. The factor eluted from the gel filtration column with an apparent molecular mass of approximately 440 kDa. Mass spectrometric analyses of the proteins present in the peak active fractions revealed the presence of at least one vaccinia protein with a high degree of certainty, the H5R gene product. To extend this finding, extracts were prepared from HeLa cells infected with vaccinia virus overexpressing His-tagged H5, chromatographed on a nickel affinity column, and eluted using an imidazole gradient. Cleavage activity eluted with the peak of His-tagged H5. Gel filtration of the affinity-purified material further demonstrated that cleavage activity and His-tagged H5 co-chromatographed with an apparent molecular mass of 463 kDa. We therefore conclude that H5 is specifically associated with post-transcriptional cleavage of F17R transcripts. In addition, we show that dephosphorylation of a cleavage competent extract with a nonspecific phosphatase abolishes cleavage activity implying a role for phosphorylation in cleavage activity.

Regulation and function of maternal mRNA destabilization during early Drosophila development

Early embryonic development in all animals depends on maternally provided gene products. Posttranscriptional and posttranslational processes control spatial and temporal readout of the maternal information. This review focuses on the control of maternal transcript stability in the early Drosophila embryo and how transcript destabilization is necessary for normal development. The molecular pathways that regulate transcript stability are often intimately linked with other posttranscriptional mechanisms such as mRNA localization and translational regulation. These additional mechanisms are explored here with an emphasis on their relationship to transcript decay.

Purification and characterization of a novel mammalian endoribonuclease

Endonuclease-mediated mRNA decay appears to be a common mode of mRNA degradation in mammalian cells, but yet only a few mRNA endonucleases have been described. Here, we report the existence of a second mammalian endonuclease that is capable of cleaving c-myc mRNA within the coding region in vitro. This study describes the partial purification and biochemical characterization of this enzyme. Five major proteins of approximately 10-35 kDa size co-purified with the endonuclease activity, a finding supported by gel filtration and glycerol gradient centrifugation analysis. The enzyme is an RNA-specific endonuclease that degrades single-stranded RNA, but not double-stranded RNA, DNA or DNA-RNA duplexes. It preferentially cleaves RNA in between the pyrimidine and purine dinucleotides UA, UG, and CA, at the coding region determinant (CRD) of c-myc RNA. The enzyme generates products with a 3'hydroxyl group, and it appears to be a protein-only endonuclease. It does not possess RNase A-like activity. The enzyme is capable of cleaving RNAs other than c-myc CRD RNA in vitro. It is Mg(2+)-independent and is resistant to EDTA. The endonuclease is inactivated at and above 70 degrees C. These properties distinguished the enzyme from other previously described vertebrate endonucleases.

A nucleolin-binding 3' untranslated region element stabilizes beta-globin mRNA in vivo

The normal expression of human beta globin is critically dependent upon the constitutively high stability of its encoding mRNA. Unlike with alpha-globin mRNA, the specific cis-acting determinants and trans-acting factors that participate in stabilizing beta-globin mRNA are poorly described. The current work uses a linker-scanning strategy to identify a previously unknown determinant of mRNA stability within the beta-globin 3' untranslated region (3'UTR). The new determinant is positioned on an mRNA half-stem opposite a pyrimidine-rich sequence targeted by alphaCP/hnRNP-E, a factor that plays a critical role in stabilizing human alpha-globin mRNA. Mutations within the new determinant destabilize beta-globin mRNA in intact cells while also ablating its 3'UTR-specific interaction with the polyfunctional RNA-binding factor nucleolin. We speculate that 3'UTR-bound nucleolin enhances mRNA stability by optimizing alphaCP access to its functional binding site. This model is favored by in vitro evidence that alphaCP binding is enhanced both by cis-acting stem-destabilizing mutations and by the trans-acting effects of supplemental nucleolin. These studies suggest a mechanism for beta-globin mRNA stability that is related to, but distinct from, the mechanism that stabilizes human alpha-globin mRNA.

Blockade of murine erythroleukemia cell differentiation by hypomethylating agents causes accumulation of discrete small poly(A)- RNAs hybridized to 3'-end flanking sequences of beta(major) globin gene

Induction of murine erythroleukemia (MEL) cell differentiation is accompanied by transcriptional activation of globin genes and biosynthesis of hemoglobin. In this study, we observed cytoplasmic accumulation of relatively small RNAs of different size (150-600 nt) hybridized to alpha1 and beta(major) globin DNA probes in MEL cells blocked to differentiate by hypomethylating agents (neplanocin A, 3-deazaneplanocin A and cycloleucine). These RNAs lack poly(A) tail and appear to be quite stable. Search within the 3'-end flanking sequences of beta(major) globin gene revealed the presence of a B1 repeat element, several ATG initiation codons, a GATA-1 consensus sequence and sequences recognized by AP-1/NF-E2 and erythroid Krüppel-like factor (EKLF) transcription factors. These data taken together indicate that exposure of MEL cells to hypomethylating agents promotes accumulation of relatively small discrete RNA transcripts lacking poly(A) tail regardless of the presence or absence of inducer dimethylsulfoxide (DMSO). However, the relative steady-state level of small RNAs was comparatively higher in cells co-exposed to inducer and each one of the hypomethylating agents. Although the orientation of these RNAs has not been established as yet, the possibility these small poly(A)- RNAs which are induced by hypomethylating agents may be involved in the blockade of MEL cell differentiation program is discussed.

Messenger RNA turnover in eukaryotes: pathways and enzymes

The control of mRNA degradation is an important component of the regulation of gene expression since the steady-state concentration of mRNA is determined both by the rates of synthesis and of decay. Two general pathways of mRNA decay have been described in eukaryotes. Both pathways share the exonucleolytic removal of the poly(A) tail (deadenylation) as the first step. In one pathway, deadenylation is followed by the hydrolysis of the cap and processive degradation of the mRNA body by a 5' exonuclease. In the second pathway, the mRNA body is degraded by a complex of 3' exonucleases before the remaining cap structure is hydrolyzed. This review discusses the proteins involved in the catalysis and control of both decay pathways.

Nucleolin is a second component of the CD154 mRNA stability complex that regulates mRNA turnover in activated T cells

CD154 (CD40L) mRNA turnover is regulated in part at the posttranscriptional level by a protein complex (termed Complex I) that binds to a highly CU-rich region of the 3'UTR. Polypyrimidine tract-binding protein (PTB) has previously been identified as a major RNA-binding protein in Complex I. Nondenaturing gel filtration of total extract from Jurkat T cells demonstrated that the CD154 mRNA-binding activity migrates as a approximately 200-kDa complex, indicating the presence of multiple complex-associated proteins. We have currently undertaken a biochemical approach to further characterize Complex I and observed that it segregates over DEAE-Sepharose into two subcomplexes (termed I-L and I-U). Furthermore, nucleolin was identified as a component of both subcomplexes and was shown that it is the major RNA-binding protein in I-U. To directly demonstrate the biological significance of Complex I binding to the CD154 transcript, cytoplasm from human Jurkat cells was fractionated over a sucrose gradient and the different cellular fractions subjected to immunoprecipitation with anti-PTB and anti-nucleolin Abs. RT-PCR of the immunoprecipitated products using CD154-specific primers clearly demonstrated that nucleolin and PTB are associated with CD154 mRNA in both the ribonucleoprotein and polysome fractions. These data strongly support a model whereby nucleolin and PTB are integral to the stability of CD154 mRNA and are components of the CD154 ribonucleoprotein particle associated with actively translating ribosomes.

Functional characterization of the mammalian mRNA decapping enzyme hDcp2

Regulation of decapping is a critical determinant of mRNA stability. We recently identified hDcp2 as a human decapping enzyme with intrinsic decapping activity. This activity is specific to N(7)-methylated guanosine containing RNA. The hDcp2 enzyme does not function on the cap structure alone and is not sensitive to competition by cap analog, suggesting that hDcp2 requires the RNA for cap recognition. We now demonstrate that hDcp2 is an RNA-binding protein and its recognition and hydrolysis of the cap substrate is dependent on an initial interaction with the RNA moiety. A biochemical characterization of hDcp2 revealed that a 163 amino acid region containing two evolutionarily conserved regions, the Nudix fold hydrolase domain and the adjacent Box B region contained methyl-cap-specific hydrolysis activity. Maximum decapping activity for wild-type as well as truncation mutants of hDcp2 required Mn(2+) as a divalent cation. The demonstration that hDcp2 is an RNA-binding protein with an RNA-dependent decapping activity will now provide new approaches to identify specific mRNAs that are regulated by this decapping enzyme as well as provide novel avenues to control mRNA decapping and turnover by influencing the RNA-binding property of hDcp2.

Regulation of alpha-globin mRNA stability

mRNA stability is a critical determinant of normal red blood cell development and function. The long half-life of globin mRNA is central to the continued synthesis of globin proteins throughout all stages of erythropoiesis, even as the cells undergo programmed transcriptional arrest during terminal differentiation. Studies of a naturally occurring alpha-thalassemic mutation that triggers marked destabilization of alpha-globin mRNA first led investigators to search for a stability determinant in the 3'-untranslated region (3'UTR). Analysis of this region identified three cytosine-rich (C-rich) segments that contributed to alpha-globin mRNA stability when studied in transfected erythroid cells. Subsequently, in vitro studies demonstrated assembly of a sequence-specific ribonucleic-protein (RNP) complex at this site. Mutations in the 3'UTR that blocked formation of this "alpha-complex" in vitro resulted in a parallel destabilization of alpha-globin mRNA in transfected cells. Members of the alpha-globin poly(C)-binding protein (alphaCP) subfamily of heteronuclear (hn) RNP K homology (KH) domain RNA-binding proteins have been identified as essential protein components of the alpha-complex. In vitro studies suggested that additional proteins may also contribute to alpha-complex structure and/or function. Surveys of additional highly stable mRNAs point to a general function for the alpha-complex in mRNA stabilization. In vitro and in vivo analyses indicated that the alpha-complex stabilizes alpha-globin mRNA by two mechanisms: control of 3'-terminal deadenylation and steric protection of an endoribonuclease-sensitive site. Confirmation of these pathways, determination of their relative importance, and generalization of these findings to additional systems await future studies.

The KH-domain protein alpha CP has a direct role in mRNA stabilization independent of its cognate binding site

Previous studies suggest that high-level stability of a subset of mammalian mRNAs is linked to a C-rich motif in the 3' untranslated region (3'UTR). High-level expression of human alpha-globin mRNA (h alpha-globin mRNA) in erythroid cells has been specifically attributed to formation of an RNA-protein complex comprised of a 3'UTR C-rich motif and an associated 39-kDa poly(C) binding protein, alpha CP. Documentation of this RNA-protein alpha-complex has been limited to in vitro binding studies, and its impact has been monitored by alterations in steady-state mRNA. Here we demonstrate that alpha CP is stably bound to h alpha-globin mRNA in vivo, that alpha-complex assembly on the h alpha-globin mRNA is restricted to the 3'UTR C-rich motif, and that alpha-complex assembly extends the physical half-life of h alpha-globin mRNA selectively in erythroid cells. Significantly, these studies also reveal that an artificially tethered alpha CP has the same mRNA-stabilizing activity as the native alpha-complex. These data demonstrate a unique contribution of the alpha-complex to h alpha-globin mRNA stability and support a model in which the sole function of the C-rich motif is to selectively tether alpha CP to a subset of mRNAs. Once bound, alpha CP appears to be fully sufficient to trigger downstream events in the stabilization pathway.

MRNA stability and the control of gene expression: implications for human disease

Regulation of gene expression is essential for the homeostasis of an organism, playing a pivotal role in cellular proliferation, differentiation, and response to specific stimuli. Multiple studies over the last two decades have demonstrated that the modulation of mRNA stability plays an important role in regulating gene expression. The stability of a given mRNA transcript is determined by the presence of sequences within an mRNA known as cis-elements, which can be bound by trans-acting RNA-binding proteins to inhibit or enhance mRNA decay. These cis-trans interactions are subject to a control by a wide variety of factors including hypoxia, hormones, and cytokines. In this review, we describe mRNA biosynthesis and degradation, and detail the cis-elements and RNA-binding proteins known to affect mRNA turnover. We present recent examples in which dysregulation of mRNA stability has been associated with human diseases including cancer, inflammatory disease, and Alzheimer's disease.

The scavenger mRNA decapping enzyme DcpS is a member of the HIT family of pyrophosphatases

We recently demonstrated that the major decapping activity in mammalian cells involves DcpS, a scavenger pyrophosphatase that hydrolyzes the residual cap structure following 3' to 5' decay of an mRNA. The association of DcpS with 3' to 5' exonuclease exosome components suggests that these two activities are linked and there is a coupled exonucleolytic decay-dependent decapping pathway. We purified DcpS from mammalian cells and identified the cDNA encoding a novel 40 kDa protein possessing DcpS activity. Consistent with purified DcpS, the recombinant protein specifically hydrolyzed methylated cap analog but did not hydrolyze unmethylated cap analog nor did it function on intact capped RNA. Sequence alignments of DcpS from different organisms revealed the presence of a conserved hexapeptide, containing a histidine triad (HIT) sequence with three histidines separated by hydrophobic residues. Mutagenesis analysis revealed that the central histidine within the DcpS HIT motif is critical for decapping activity and defines the HIT motif as a new mRNA decapping domain, making DcpS the first member of the HIT family of proteins with a defined biological function.

mRNA degradation machines in eukaryotic cells

The steady-state levels of mRNAs depend upon their combined rates of synthesis and processing, transport from the nucleus to cytoplasm, and decay in the cytoplasm. In eukaryotic cells, the degradation of mRNA is an essential determinant in the regulation of gene expression, and it can be modulated in response to developmental, environmental, and metabolic signals. This level of regulation is particularly important for proteins that are active for a brief period, such as growth factors, transcription factors, and proteins that control cell cycle progression. The mechanisms by which mRNAs are degraded and the sequence elements within the mRNAs that affect their stability are the subject of this review. We will summarize the current state of knowledge regarding cis-acting elements in mRNA and trans-acting factors that contribute to mRNA regulation decay. We will then consider the mechanisms by which specific signaling proteins seem to contribute to a dynamic organization of the mRNA degradation machinery in response to physiological stimuli.