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.     

Detection and characterization of a 3' untranslated region ribonucleoprotein complex associated with human alpha-globin mRNA stability.

The highly stable nature of globin mRNA is of central importance to erythroid cell differentiation. We have previously identified cytidine-rich (C-rich) segments in the human alpha-globin mRNA 3' untranslated region (alpha-3'UTR) which are critical in the maintenance of mRNA stability in transfected erythroid cells. In the present studies, we have detected trans-acting factors which interact with these cis elements to mediate this stabilizing function. A sequence-specific ribonucleoprotein (RNP) complex is assembled after incubation of the alpha-3'UTR with a variety of cytosolic extracts. This so-called alpha-complex is sequence specific and is not formed on the 3'UTR of either beta-globin or growth hormone mRNAs. Furthermore, base substitutions within the C-rich stretches which destabilize alpha-globin mRNA in vivo result in a parallel disruption of the alpha-complex in vitro. Competition studies with a series of homoribopolymers reveals a striking sensitivity of alpha-complex formation to poly(C), suggesting the presence of a poly(C)-binding activity within the alpha-complex. Three predominant proteins are isolated by alpha-3'UTR affinity chromatography. One of these binds directly to poly(C). This cytosolic poly(C)-binding protein is distinct from previously described nuclear poly(C)-binding heterogeneous nuclear RNPs and is necessary but not sufficient for alpha-complex formation. These data suggest that a messenger RNP complex formed by interaction of defined segments within the alpha-3'UTR with a limited number of cytosolic proteins, including a potentially novel poly(C)-binding protein, is of functional importance in establishing high-level stability of alpha-globin mRNA.     

Assembly of the α-Globin mRNA Stability Complex Reflects Binary Interaction between the Pyrimidine-Rich 3′ Untranslated Region Determinant and Poly(C) Binding Protein αCP

Globin mRNAs accumulate to 95% of total cellular mRNA during terminal erythroid differentiation, reflecting their extraordinary stability. The stability of human alpha-globin mRNA is paralleled by formation of a sequence-specific RNA-protein (RNP) complex at a pyrimidine-rich site within its 3' untranslated region (3'UTR), the alpha-complex. The proteins of the alpha-complex are widely expressed. The alpha-complex or a closely related complex also assembles at pyrimidine-rich 3'UTR segments of other stable mRNAs. These data suggest that the alpha-complex may constitute a general determinant of mRNA stability. One or more alphaCPs, members of a family of hnRNP K-homology domain poly(C) binding proteins, are essential constituents of the alpha-complex. The ability of alphaCPs to homodimerize and their reported association with additional RNA binding proteins such as AU-rich binding factor 1 (AUF1) and hnRNP K have suggested that the alpha-complex is a multisubunit structure. In the present study, we have addressed the composition of the alpha-complex. An RNA titration recruitment assay revealed that alphaCPs were quantitatively incorporated into the alpha-complex in the absence of associated AUF1 and hnRNP K. A high-affinity direct interaction between each of the three major alphaCP isoforms and the alpha-globin 3'UTR was detected, suggesting that each of these proteins might be sufficient for alpha-complex assembly. This sufficiency was further supported by the sequence-specific binding of recombinant alphaCPs to a spectrum of RNA targets. Finally, density sedimentation analysis demonstrated that the alpha-complex could accommodate only a single alphaCP. These data established that a single alphaCP molecule binds directly to the alpha-globin 3'UTR, resulting in a simple binary structure for the alpha-complex.     

Identification of AUF1 (heterogeneous nuclear ribonucleoprotein D) as a component of the alpha-globin mRNA stability complex.

mRNA turnover is an important regulatory component of gene expression and is significantly influenced by ribonucleoprotein (RNP) complexes which form on the mRNA. Studies of human alpha-globin mRNA stability have identified a specific RNP complex (alpha-complex) which forms on the 3' untranslated region (3'UTR) of the mRNA and appears to regulate the erythrocyte-specific accumulation of alpha-globin mRNA. One of the protein activities in this multiprotein complex is a poly(C)-binding activity which consists of two proteins, alphaCP1 and alphaCP2. Neither of these proteins, individually or as a pair, can bind the alpha-globin 3'UTR unless they are complexed with the remaining non-poly(C) binding proteins of the alpha-complex. With the yeast two-hybrid screen, a second alpha-complex protein was identified. This protein is a member of the previously identified A+U-rich (ARE) binding/degradation factor (AUF1) family of proteins, which are also known as the heterogeneous nuclear RNP (hnRNP) D proteins. We refer to these proteins as AUF1/hnRNP-D. Thus, a protein implicated in ARE-mediated mRNA decay is also an integral component of the mRNA stabilizing alpha-complex. The interaction of AUF1/hnRNP-D is more efficient with alphaCP1 relative to alphaCP2 both in vitro and in vivo, suggesting that the alpha-complex might be dynamic rather than a fixed complex. AUF1/hnRNP-D could, therefore, be a general mRNA turnover factor involved in both stabilization and decay of mRNA.     

Identification of two KH domain proteins in the alpha-globin mRNP stability complex.

Accumulation of globin mRNAs during erythroid differentiation is dependent on their extraordinary stability. The longevity of human alpha-globin mRNA is associated with a ribonucleoprotein complex (alpha-complex) formed on the 3' untranslated region (3'UTR). One or more of the proteins within this alpha-complex contain strong polycytosine [poly(C)] binding (alpha PCB) activity. In the present report we purify alpha PCB activity from human erythroid K562 cells. Although not able to bind the alpha-globin 3'UTR directly, alpha PCB activity is sufficient to complement alpha-complex formation in a cytosolic extract depleted of poly(C) binding activity. Peptide microsequencing demonstrates that alpha PCB activity contains two structurally related poly(C) binding proteins. These two proteins, alpha-complex protein (alpha CP)-1 and -2, have an overall structural identity of 80% and contain three repeats of the K homology (KH) domain which is found in a subset of RNA binding proteins. Epitope-tagged recombinant alpha CP-1 and alpha CP-2 expressed in cells are each incorporated into the alpha-complex. We conclude that alpha CP-1 and alpha CP-2, members of the KH domain RNA binding protein family, are involved in formation of a sequence-specific alpha-globin mRNP complex associated with alpha-globin mRNA stability. As such this represents the first example of a specific function for this class of proteins and suggests potential roles for other members of this protein family.     

Purification and RNA binding properties of the polycytidylate-binding proteins alphaCP1 and alphaCP2

Regulation of mRNA turnover is a critical control mechanism of gene expression and is influenced by ribonucleoprotein (RNP) complexes that form on cis elements. All mRNAs have an intrinsic half-life and in many cases these half-lives can be altered by a variety of stimuli that are manifested through the formation or disruption of an RNP structure. The stability of alpha-globin mRNA is determined by elements in the 3' untranslated region that are bound by an RNP complex (alpha-complex) which appears to control the erythroid-specific accumulation of alpha-globin mRNA. The alpha-complex could consist of up to six distinct proteins or protein families. One of these families is a prominent polycytidylate binding activity which consists of two highly homologous proteins, alpha-complex proteins 1 and 2 (alphaCP1 and alphaCP2). This article focuses on various methodologies for the detection and manipulation of alphaCP1 and alphaCP2 binding to RNA and details means of isolating and characterizing mRNA bound by these proteins to study mRNA turnover and its regulation.     

An mRNA Stability Complex Functions with Poly(A)-Binding Protein To Stabilize mRNA In Vitro

The stable globin mRNAs provide an ideal system for studying the mechanism governing mammalian mRNA turnover. alpha-Globin mRNA stability is dictated by sequences in the 3' untranslated region (3'UTR) which form a specific ribonucleoprotein complex (alpha-complex) whose presence correlates with mRNA stability. One of the major protein components within this complex is a family of two polycytidylate-binding proteins, alphaCP1 and alphaCP2. Using an in vitro-transcribed and polyadenylated alpha-globin 3'UTR, we have devised an in vitro mRNA decay assay which reproduces the alpha-complex-dependent mRNA stability observed in cells. Incubation of the RNA with erythroleukemia K562 cytosolic extract results in deadenylation with distinct intermediates containing a periodicity of approximately 30 nucleotides, which is consistent with the binding of poly(A)-binding protein (PABP) monomers. Disruption of the alpha-complex by sequestration of alphaCP1 and alphaCP2 enhances deadenylation and decay of the mRNA, while reconstitution of the alpha-complex stabilizes the mRNA. Similarly, PABP is also essential for the stability of mRNA in vitro, since rapid deadenylation resulted upon its depletion. An RNA-dependent interaction between alphaCP1 and alphaCP2 with PABP suggests that the alpha-complex can directly interact with PABP. Therefore, the alpha-complex is an mRNA stability complex in vitro which could function at least in part by interacting with PABP.     

Phosphorylation of the spinach chloroplast 24 kDa RNA-binding protein (24RNP) increases its binding to petD and psbA 3' untranslated regions

The chloroplast 24 kDa RNA binding protein (24RNP) from Spinacea oleracea is a nuclear encoded protein that binds the 3' untranslated region (3'UTR) of some chloroplast mRNAs and seems to be involved in some processes of mRNA metabolism, such as 3'UTR processing, maturation and stabilization. The 24RNP is similar to the 28RNP which is involved in the correct maturation of petD and psbA 3'UTRs, and when phosphorylated, decreases its binding affinity for RNA. In the present work, we determined that the recombinant 24RNP was phosphorylated in vitro either by an animal protein kinase C, a plant Ca(2+)-dependent protein kinase, or a chloroplastic kinase activity present in a protein extract with 3'-end processing activity in which the 24RNP is also present. Phosphorylation of 24RNP increased the binding capacity (B(max)) 0.25 time for petD 3'UTR, and three times for psbA 3'UTR; the affinity for P-24RNP only increased when the interaction with petD was tested. Competition experiments suggested that B(max), not K(d), might be a more important factor in the P-24RNP-3'UTR interaction. The data suggested that the 24RNP role in chloroplast mRNA metabolism may be regulated in vivo by changes in its phosphorylation status carried out by a chloroplastic kinase.     

Regulated alpha-globin mRNA decay is a cytoplasmic event proceeding through 3'-to-5' exosome-dependent decapping

The alpha-globin mRNA contains a C-rich stability element (CRE) in its 3' untranslated region (3' UTR) which is critical for the stability of this long-lived mRNA. A protein complex, termed the alpha-complex, forms on the CRE and has been shown to contribute to stabilization of the mRNA by at least two mechanisms, first by interacting with the poly(A)-binding protein (PABP) to prevent deadenylation, and second by protecting the mRNA from attack by an erythroid endoribonuclease. In this report, we demonstrate that the alpha-globin 3' UTR can confer stability on a heterologous mRNA in cells, and this stability is dependent on the alpha-complex. Moreover, the stability was exclusively detected with cytoplasmic mRNA, suggesting that the regulation of alpha-globin mRNA stability is a cytoplasmic event. An additional mechanism by which the alpha-complex can confer stability on an RNA in vitro was also identified and shown to involve inhibition of 3' to 5' exonucleolytic degradation. Furthermore, using an in vitro mRNA decay system, we were able to follow the demise of the alpha-globin RNA and demonstrate that the decay was initiated by deadenylation followed by 3'-to-5' decay carried out by the exosome and ultimately hydrolysis of the residual cap structure.     

The poly(A)-binding protein and an mRNA stability protein jointly regulate an endoribonuclease activity

We previously identified a sequence-specific erythroid cell-enriched endoribonuclease (ErEN) activity involved in the turnover of the stable alpha-globin mRNA. We now demonstrate that ErEN activity is regulated by the poly(A) tail. The unadenylated alpha-globin 3' untranslated region (3'UTR) was an efficient substrate for ErEN cleavage, while the polyadenylated 3'UTR was inefficiently cleaved in an in vitro decay assay. The influence of the poly(A) tail was mediated through the poly(A)-binding protein (PABP) bound to the poly(A) tail, which can inhibit ErEN activity. ErEN cleavage of an adenylated alpha-globin 3'UTR was accentuated upon depletion of PABP from the cytosolic extract, while addition of recombinant PABP reestablished the inhibition of endoribonuclease cleavage. PABP inhibited ErEN activity indirectly through an interaction with the alphaCP mRNA stability protein. Sequestration of alphaCP resulted in an increase of ErEN cleavage activity, regardless of the polyadenylation state of the RNA. Using electrophoretic mobility shift assays, PABP was shown to enhance the binding efficiency of alphaCP to the alpha-globin 3'UTR, which in turn protected the ErEN target sequence. Conversely, the binding of PABP to the poly(A) tail was also augmented by alphaCP, implying that a stable higher-order structural network is involved in stabilization of the alpha-globin mRNA. Upon deadenylation, the interaction of PABP with alphaCP would be disrupted, rendering the alpha-globin 3'UTR more susceptible to endoribonuclease cleavage. The data demonstrated a specific role for PABP in protecting the body of an mRNA in addition to demonstrating PABP's well-characterized effect of stabilizing the poly(A) tail.     

Identification of an erythroid-enriched endoribonuclease activity involved in specific mRNA cleavage

Stability of the human alpha-globin mRNA is conferred by a ribonucleoprotein complex termed the alpha-complex, which acts by impeding deadenylation. Using our recently devised in vitro decay assay, we demonstrate that the alpha-complex also functions by protecting the 3'-untranslated region (3'-UTR) from an erythroid-enriched, sequence-specific endoribonuclease activity. The cleavage site was mapped to a region protected by the alpha-complex and is regulated by the presence of the alpha-complex. Similar endoribonuclease cleavage products were also detected in erythroid cells expressing an exogenous alpha-globin gene. Nucleotide substitution of the target sequence renders the RNA refractory to the endoribonuclease activity. Insertion of the target sequence onto a heterologous RNA confers sequence-specific cleavage on the chimeric RNA, demonstrating the sequence specificity of this activity. We conclude that the alpha-complex stabilizes the alpha-globin mRNA in erythroid cells by a multifaceted approach, one aspect of which is to protect the 3'-UTR from specific endoribonuclease cleavage.     

Multiple instability-regulating sites in the 3'' untranslated region of the urokinase-type plasminogen activator mRNA.

In LLC-PK1 cells urokinase-type plasminogen activator (uPA) mRNA has a short half-life. It is stabilized by inhibition of protein synthesis and by downregulation of protein kinase C (PKC). In the present study on uPA mRNA metabolism, we focused our attention on the 3' untranslated region (3'UTR) of the uPA mRNA, as this region is long and highly conserved among several mammalian species, including mice and humans. To investigate the possible role of the 3'UTR of uPA mRNA in mRNA metabolism, we inserted this region into the 3'UTR of the rabbit beta-globin gene that is linked to the cytomegalovirus promoter and stably transfected it into LLC-PK1 cells. While the parental globin mRNA was stable, the chimeric mRNA was degraded as rapidly as endogenous uPA mRNA, suggesting that the 3'UTR of uPA mRNA contains most of the information required for its rapid turnover. Further analysis showed that there are at least three independent determinants of instability in the 3'UTR; one is an AU-rich sequence located immediately 3' of the poly(A) addition signal, and one is a sequence containing a stem structure. One determinant seems to require ongoing RNA synthesis for its activity. All chimeric unstable globin mRNAs became stable in the presence of cycloheximide, a protein synthesis inhibitor, suggesting that the stabilization of mRNA by protein synthesis inhibition is not through a specific sequence in the mRNA. In PKC-downregulated cells, globin mRNAs with the complete 3'UTR or the AU-rich sequence were stabilized, suggesting that PKC downregulation stabilizes uPA mRNA through the AU-rich sequence. Here we discuss the significance of multiple, independently acting instability determinants in the regulation of uPA mRNA metabolism.