Specific RNA binding by amino-terminal peptides of alfalfa mosaic virus coat protein.

Specific RNA-protein interactions and ribonucleoprotein complexes are essential for many biological processes, but our understanding of how ribonucleoprotein particles form and accomplish their biological functions is rudimentary. This paper describes the interaction of alfalfa mosaic virus (A1MV) coat protein or peptides with viral RNA. A1MV coat protein is necessary both for virus particle formation and for the initiation of replication of the three genomic RNAs. We have examined protein determinants required for specific RNA binding and analyzed potential structural changes elicited by complex formation. The results indicate that the amino-terminus of the viral coat protein, which lacks primary sequence homology with recognized RNA binding motifs, is both necessary and sufficient for binding to RNA. Circular dichroism spectra and electrophoretic mobility shift experiments suggest that the RNA conformation is altered when amino-terminal coat protein peptides bind to the viral RNA. The peptide--RNA interaction is functionally significant because the peptides will substitute for A1MV coat protein in initiating RNA replication. The apparent conformational change that accompanies RNA--peptide complex formation may generate a structure which, unlike the viral RNA alone, can be recognized by the viral replicase.     

Poly (rC) binding protein 2 forms a ternary complex with the 5'-terminal sequences of poliovirus RNA and the viral 3CD proteinase.

Poly(rC) binding protein 2 (PCBP2) forms a specific ribonucleoprotein (RNP) complex with the 5'-terminal sequences of poliovirus genomic RNA, as determined by electrophoretic mobility shift assay. Mutational analysis showed that binding requires the wild-type nucleotide sequence at positions 20-25. This sequence is predicted to localize to a specific stem-loop within a cloverleaf-like secondary structure element at the 5'-terminus of the viral RNA. Addition of purified poliovirus 3CD to the PCBP2/RNA binding reaction results in the formation of a ternary complex, whose electrophoretic mobility is further retarded. These properties are consistent with those described for the unidentified cellular protein in the RNP complex described by Andino et al. (Andino R, Rieckhof GE, Achacoso PL, Baltimore D, 1993, EMBO J 12:3587-3598). Dicistronic RNAs containing mutations in the 5' cloverleaf-like structure of poliovirus that abate PCBP2 binding show a decrease in RNA replication and translation of gene products directed by the poliovirus 5' noncoding region in vitro, suggesting that the interaction of PCBP2 with these sequences performs a dual role in the virus life cycle by facilitating both viral protein synthesis and initiation of viral RNA synthesis.     

Ribosomal protein L6: structural evidence of gene duplication from a primitive RNA binding protein.

In all cells, protein synthesis is coordinated by the ribosome, a large ribonucleoprotein particle that is composed of > 50 distinct protein molecules and several large RNA molecules. Here we present the crystal structure of ribosomal protein L6 from the thermophilic bacterium Bacillus stearothermophilus solved at 2.6 A resolution. L6 contains two domains with almost identical folds, implying that it was created by an ancient gene duplication event. The surface of the molecule displays several likely sites of interaction with other components of the ribosome. The RNA binding sites appear to be localized in the C-terminal domain whereas the N-terminal domain contains the potential sites for protein-protein interactions. The domain structure is homologous with several other ribosomal proteins and to a large family of eukaryotic RNA binding proteins.     

Human hnRNP protein A1: A model polypeptide for a structural and genetic investigation of a broad family of RNA binding proteins

The hnRNP fiber is the substrate on which pre-mRNA processing occurs. The protein moiety of the fiber (hnRNP proteins) constitutes a broad family of RNA binding proteins that revealed, upon molecular analysis, a number of interesting features.Heterogeneous nuclear ribonucleoprotein A1 is a major component of the human hnRNP complex. In recent years this protein has attracted great attention because of several emerging evidences of its direct involvement in pre-mRNA processing and it has become one of the best characterized RNA binding proteins. Detailed knowledge of the structure of protein A1 has laid the basis for the understanding of its function, and for this reason A1 can be considered as a model polypeptide for the investigation of a large number of RNA binding proteins.In this work we report recent findings regarding the binding properties of protein A1 as well as new data on the gene structure of A1 and of its closely related hnRNP protein A2. Our results show that a single A1 molecule contains the determinants for simultaneous binding of two single-stranded nucleic acid molecules and we demonstrate that the glycine-rich domain of A1, isolated from the rest of the molecule, is capable of sustaining protein-protein interactions. These features probably account for the reannealing activity of the protein and for its capacity to modulate the binding of snRNPs to intron sequencesin vitro. Comparison of A1 and A2 gene sequences revealed a remarkable conservation of the overall structural organization, suggesting important functions for the different structural elements.     

The MDM2 oncoprotein binds specifically to RNA through its RING finger domain.

BACKGROUND: The cellular mdm2 gene has transforming activity when overexpressed and is amplified in a variety of human tumors. At least part of the transforming ability of the MDM2 protein is due to binding and inactivating the p53 tumor suppressor protein. Additionally, this protein forms a complex in vivo with the L5 ribosomal protein and its associated 5S ribosomal RNA and may be part of a ribosomal complex. MATERIALS AND METHODS: A RNA homopolymer binding assay and a SELEX procedure have been used to characterize the RNA-binding activity of MDM2. RESULTS: The MDM2 protein binds efficiently to the homopolyribonucleotide poly(G) but not to other homopolyribonucleotides. This binding is independent of the interaction of MDM2 with the L5 protein, which occurs through the central acidic domain of MDM2. An RNA SELEX procedure was performed to identify specific RNA ligands that bind with high affinity to the human MDM2 (HDM2) protein. After 10 rounds of selection and amplification, a subset of RNA molecules that bound efficiently to HDM2 was isolated from a randomized pool. Sequencing of these selected ligands revealed that a small number of sequence motifs were selected. The specific RNA binding occurs through the RING finger domain of the protein. Furthermore, a single amino acid substitution in the RING finger domain, G446S, completely abolishes the specific RNA binding. CONCLUSIONS: These observations, showing that MDM2 binds the L5/5S ribosomal ribonucleoprotein particle and can also bind to specific RNA sequences or structures, suggest a role for MDM2 in translational regulation in a cell.     

A critical role of LFA-1 in the development of Th17 cells and induction of experimental autoimmune encephalomyelytis

Snu13p is a Saccharomyces cerevisiae protein essential for pre-messenger RNA splicing and pre-ribosomal RNA processing. Snu13p binds U4 snRNA of the spliceosome and box C/D snoRNAs of the pre-ribosomal RNA processing machinery to induce assembly of each ribonucleoprotein complex. Here, we present structural and biochemical analysis of Snu13p. The crystal structure of Snu13p reveals a region of the protein which could be important for protein interaction during ribonucleoprotein assembly. Using the structure of Snu13p we have designed the first temperature-sensitive mutants in Snu13p, L67W and I102A. Wild-type and mutant Snu13p proteins were assayed for binding to U4 snRNA and U3 snoRNA. Both temperature-sensitive mutants displayed significantly reduced RNA binding compared to wild-type protein. As the temperature-sensitive mutations are not in the known RNA binding region of Snu13p this indicates that these mutants indirectly influence the RNA binding properties of Snu13p. This work provides insight into Snu13p function during ribonucleoprotein assembly.     

Isolation and characterization of a novel,low abundance hnRNP protein: A0.

Pre-messenger RNA is bound by a variety of proteins to form large heterogeneous nuclear ribonucleoprotein (hnRNP) complexes. As defined by immunoprecipitation and two-dimensional gel electrophoresis, there appear to be more than 20 abundant hnRNP proteins ranging in size from 34 kDa to 120 kDa. One major class, the A/B family, is typified by its characteristic primary structure containing two RNA binding domains followed by a glycine-rich C-terminus. We report the cloning and characterization of a novel, low-abundance member of the A/B family named hnRNP A0. This protein was affinity isolated using a biotinylated RNA probe [G4(AU3)4A] designed to select a 32-kDa protein implicated in mRNA stability in mammalian cells. hnRNP A0 is a basic protein with a predicted mass of 31.7 kDa and an isoelectric point of 10.1. Comparative protease mapping shows that it is not the AUUUA binding protein we intended to clone. A0 is present in hnRNP complexes and is encoded by a gene distinct from that of any previously cloned A/B family member.     

Sequence-specific single-strand RNA binding protein encoded by the human LINE-1 retrotransposon.

Previous experiments using human teratocarcinoma cells indicated that p40, the protein encoded by the first open reading frame (ORF) of the human LINE-1 (L1Hs) retrotransposon, occurs in a large cytoplasmic ribonucleoprotein complex in direct association with L1Hs RNA(s), the p40 RNP complex. We have now investigated the interaction between partially purified p40 and L1Hs RNA in vitro using an RNA binding assay dependent on co-immunoprecipitation of p40 and bound RNA. These experiments identified two p40 binding sites on the full-length sense strand L1Hs RNA. Both sites are in the second ORF of the 6000 nt RNA: site A between residues 1999 and 2039 and site B between residues 4839 and 4875. The two RNA segments share homologous regions. Experiments involving UV cross-linking followed by immunoprecipitation indicate that p40 in the in vitro complex is directly associated with L1Hs RNA, as it is in the p40 RNP complex found in teratocarcinoma cells. Binding and competition experiments demonstrate that p40 binds to single-stranded RNA containing a p40 binding site, but not to single-stranded or double-stranded DNA, double-stranded RNA or a DNA-RNA hybrid containing a binding site sequence. Thus, p40 appears to be a sequence-specific, single-strand RNA binding protein.     

Drosophila snRNP associated protein P11 which specifically binds to heat shock puff 93D reveals strong homology with hnRNP core protein A1.

We have isolated cDNAs coding for a ribonucleoprotein of Drosophila melanogaster that is distinguished by its nearly exclusive presence at only one of the several heat shock puffs in polytene chromosomes of third instar larvae. We determined the nucleotide sequence and deduced the corresponding amino acid sequence. Its coding capacity for a 39 kDa protein is consistent with the size of the protein detected by the monoclonal antibody P11 used for expression cloning. Our results show that the P11 protein belongs to the category of hnRNP proteins of bipartite structure: the amino-terminal half contains two RNA binding domains and the carboxyterminal half is rich in glycine residues. Analysis of the genomic structure revealed two introns located within the coding portion of the gene and a third one in the 3'untranslated region. We detect two different polyadenylation sites as a result of alternative termination-polyadenylation. Its strong sequence homology with hnRNP A1 protein and its previously shown association with snRNP particles indicates that a typical hnRNP protein may also exist in a complex with snRNP particles. The P11 sequence corresponds to the Hrb87F sequence that was recently described by Haynes et al. (1) as hnRNP A related gene.     

Structural basis of RNA recognition by the SARS-CoV-2 nucleocapsid phosphoprotein

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is the causative agent of the coronavirus disease 2019 (COVID-19). SARS-CoV-2 is a single-stranded positive-sense RNA virus. Like other coronaviruses, SARS-CoV-2 has an unusually large genome that encodes four structural proteins and sixteen nonstructural proteins. The structural nucleocapsid phosphoprotein N is essential for linking the viral genome to the viral membrane. Both N-terminal RNA binding (N-NTD) and C-terminal dimerization domains are involved in capturing the RNA genome and, the intrinsically disordered region between these domains anchors the ribonucleoprotein complex to the viral membrane. Here, we characterized the structure of the N-NTD and its interaction with RNA using NMR spectroscopy. We observed a positively charged canyon on the surface of the N-NTD that might serve as a putative RNA binding site similarly to other coronaviruses. The subsequent NMR titrations using single-stranded and double-stranded RNA revealed a much more extensive U-shaped RNA-binding cleft lined with regularly distributed arginines and lysines. The NMR data supported by mutational analysis allowed us to construct hybrid atomic models of the N-NTD/RNA complex that provided detailed insight into RNA recognition.     

Functional roles of protein splicing factors

RNA splicing is one of the fundamental processes in gene expression in eukaryotes. Splicing of pre-mRNA is catalysed by a large ribonucleoprotein complex called the spliceosome, which consists of five small nuclear RNAs and numerous protein factors. The spliceosome is a highly dynamic structure, assembled by sequential binding and release of the small nuclear RNAs and protein factors. DExD/H-box RNA helicases are required to mediate structural changes in the spliceosome at various steps in the assembly pathway and have also been implicated in the fidelity control of the splicing reaction. Other proteins also play key roles in mediating the progression of the spliceosome pathway. In this review, we discuss the functional roles of the protein factors involved in the spliceosome pathway primarily from studies in the yeast system.     

Poliovirus RNA synthesis utilizes an RNP complex formed around the 5'-end of viral RNA.

The structure of a ribonucleoprotein complex formed at the 5'-end of poliovirus RNA was investigated. This complex involves the first 90 nucleotides of poliovirus genome which fold into a cloverleaf-like structure and interact with both uncleaved 3CD, the viral protease-polymerase precursor, and a 36 kDa ribosome-associated cellular protein. The cellular protein is required for complex formation and interacts with unpaired bases in one stem-loop of the cloverleaf RNA. Amino acids within the 3C protease which are important for RNA binding were identified by site-directed mutagenesis and the crystal structure of a related protease was used to model the RNA binding domain within the viral 3CD protein. The physiologic importance of the ribonucleic-protein complex is suggested by the finding that mutations that disrupt complex formation abolish RNA replication but do not affect RNA translation or stability. Based on these structural and functional findings we propose a model for the initiation of poliovirus RNA synthesis where an initiation complex consisting of 3CD, a cellular protein, and the 5'-end of the positive strand RNA catalyzes in trans the initiation of synthesis of new positive stranded RNA.     

Crystal structure of the conserved subdomain of human protein SRP54M at 2.1 A resolution: evidence for the mechanism of signal peptide binding.

Protein SRP54 is an integral part of the mammalian signal recognition particle (SRP), a cytosolic ribonucleoprotein complex which associates with ribosomes and serves to recognize, bind, and transport proteins destined for the membrane or secretion. The methionine-rich M-domain of protein SRP54 (SRP54M) binds the SRP RNA and the signal peptide as the nascent protein emerges from the ribosome. A focal point of this critical cellular function is the detailed understanding of how different hydrophobic signal peptides are recognized efficiently and transported specifically, despite considerable variation in sequence. We have solved the crystal structure of a conserved functional subdomain of the human SRP54 protein (hSRP54m) at 2.1 A resolution showing a predominantly alpha helical protein with a large fraction of the structure available for binding. RNA binding is predicted to occur in the vicinity of helices 4 to 6. The N-terminal helix extends significantly from the core of the structure into a large but constricted hydrophobic groove of an adjacent molecule, thus revealing molecular details of possible interactions between alpha helical signal peptides and human SRP54.     

Mammalian heterogeneous nuclear ribonucleoprotein A1. Nucleic acid binding properties of the COOH-terminal domain

A1 is a core protein of the eukaryotic heterogeneous nuclear ribonucleoprotein complex and is under study here as a prototype single-stranded nucleic acid-binding protein. A1 is a two-domain protein, NH2-terminal and COOH-terminal, with highly conserved primary structure among vertebrate homologues sequenced to date. It is well documented that the NH2-terminal domain has single-stranded DNA and RNA binding activity. We prepared a proteolytic fragment of rat A1 representing the COOH-terminal one-third of the intact protein, the region previously termed COOH-terminal domain. This purified fragment of 133 amino acids binds to DNA and also binds tightly to the fluorescent reporter poly(ethenoadenylate), which is used to access binding parameters. In solution with 0.41 M NaCl, the equilibrium constant is similar to that observed with A1 itself, and binding is cooperative. The purified COOH-terminal fragment can be photochemically cross-linked to bound nucleic acid, confirming that COOH-terminal fragment residues are in close contact with the polynucleotide lattice. These binding results with isolated COOH-terminal fragment indicate that the COOH-terminal domain in intact A1 can contribute directly to binding properties. Contact between both COOH-terminal domain and NH2-terminal domain residues in an intact A1:poly(8-azidoadenylate) complex was confirmed by photochemical cross-linking.     

Analysis of substrate recognition by the ribonucleoprotein endonuclease RNase P

Ribonuclease P (RNase P), is a ribonucleoprotein complex that catalyzes the site-specific cleavage of pre-tRNA and a wide variety of other substrates. Although RNase P RNA is the catalytic subunit of the holoenzyme, the protein subunit plays a critical role in substrate binding. Thus, RNase P is an excellent model system for studying ribonucleoprotein function. In this review we describe methods applied to the in vitro study of substrate recognition by bacterial RNase P, covering general considerations of reaction conditions, quantitative measurement of substrate binding equilibria, enzymatic and chemical protection, cross-linking, modification interference, and analysis of site-specific substitutions. We describe application of these methods to substrate binding by RNase P RNA alone and experimental considerations for examining the holoenzyme. The combined use of these approaches has shown that the RNA and protein subunits cooperate to bind different portions of the substrate structure, with the RNA subunit predominantly interacting with the mature domain of tRNA and the protein interacting with the 5(') leader sequence. However, important questions concerning the interface between the two subunits and the coordination of RNA and protein subunits in binding and catalysis remain.     

The structure of the RNA binding site of ribosomal proteins S8 and S15.

Proteins S8 and S15 from the 30 S ribosomal subunit of Escherichia coli were bound to 16 S RNA and digested with ribonuclease A. A ribonucleoprotein complex was isolated which contained the two proteins and three noncontiguous RNA subfragments totaling 93 nucleotides, that could be unambiguously located in the 16 S RNA sequence. We present a secondary structural model for the RNA moiety of the binding site complex, in which the two smaller fragments are extensively base-paired, respectively, to the two halves of the large fragment, to form two disconnected duplexes. Each of the two duplexes is interrupted by a small internal loop. This model is supported by (i) minimum energy considerations, (ii) sites of cleavage by ribonuclease A, and (iii) modification by the single strand-specific reagent kethoxal. The effect of protein binding on the topography of the complex is reflected in the kethoxal reactivity of the RNA moiety. In the absence of the proteins, 5 guanines are modified; 4 of these, at positions 663, 732, 733, and 741, are strongly protected from kethoxal when protein S15 is bound.