More than 1 + 2 in mRNA decapping

Decapping of messenger RNA was thought to involve a complex of only Dcp1 and Dcp2, but new data suggest that a larger multisubunit decapping complex exists in mammals. The larger complex includes a protein that facilitates the association of the two Dcp proteins and can be recruited by specific factors that promote mRNA decay.     

Mechanistic and kinetic analysis of the DcpS scavenger decapping enzyme

Decapping is an important process in the control of eukaryotic mRNA degradation. The scavenger decapping enzyme DcpS functions to clear the cell of cap structure following decay of the RNA body by catalyzing the hydrolysis of m(7)GpppN to m(7)Gp and ppN. Structural analysis has revealed that DcpS is a dimeric protein with a domain-swapped amino terminus. The protein dimer contains two cap binding/hydrolysis sites and displays a symmetric structure with both binding sites in the open conformation in the ligand-free state and an asymmetric conformation with one site open and one site closed in the ligand-bound state. The structural data are suggestive of a dynamic decapping mechanism where each monomer could alternate between an open and closed state. Using transient state kinetic studies, we show that both the rate-limiting step and rate of decapping are regulated by cap substrate. A regulatory mechanism is established by the intrinsic domain-swapped structure of the DcpS dimer such that the decapping reaction is very efficient at low cap substrate concentrations yet regulated with excess cap substrate. These data provide biochemical evidence to verify experimentally a dynamic and mutually exclusive cap hydrolysis activity of the two cap binding sites of DcpS and provide key insights into its regulation.     

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.     

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.     

Transcript-specific decapping and regulated stability by the human Dcp2 decapping protein

mRNA decapping is a critical step in the control of mRNA stability and gene expression and is carried out by the Dcp2 decapping enzyme. Dcp2 is an RNA binding protein that must bind RNA in order to recognize the cap for hydrolysis. We demonstrate that human Dcp2 (hDcp2) preferentially binds to a subset of mRNAs and identify sequences at the 5' terminus of the mRNA encoding Rrp41, a core subunit component of the RNA exosome, as a specific hDcp2 substrate. A 60-nucleotide element at the 5' end of Rrp41 mRNA was identified and shown to confer more efficient decapping on a heterologous RNA both in vitro and upon transfection into cells. Moreover, reduction of hDcp2 protein levels in cells resulted in a selective stabilization of the Rrp41 mRNA, confirming it as a downstream target of hDcp2 regulation. These findings demonstrate that hDcp2 can specifically bind to and regulate the stability of a subset of mRNAs, and its intriguing regulation of the 3'-to-5' exonuclease exosome subunit suggests a potential interplay between 5'-end mRNA decapping and 3'-end mRNA decay.     

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.