Substrate recognition by ribonucleoprotein ribonuclease MRP

The ribonucleoprotein complex ribonuclease (RNase) MRP is a site-specific endoribonuclease essential for the survival of the eukaryotic cell. RNase MRP closely resembles RNase P (a universal endoribonuclease responsible for the maturation of the 5' ends of tRNA) but recognizes distinct substrates including pre-rRNA and mRNA. Here we report the results of an in vitro selection of Saccharomyces cerevisiae RNase MRP substrates starting from a pool of random sequences. The results indicate that RNase MRP cleaves single-stranded RNA and is sensitive to sequences in the immediate vicinity of the cleavage site requiring a cytosine at the position +4 relative to the cleavage site. Structural implications of the differences in substrate recognition by RNases P and MRP are discussed.     

RNA-protein interactions in the human RNase MRP ribonucleoprotein complex

The eukaryotic nucleolus contains a large number of small RNA molecules that, in the form of small nucleolar ribonucleoprotein complexes (snoRNPs), are involved in the processing and modification of pre-rRNA. One of the snoRNPs that has been shown to possess enzymatic activity is the RNase MRP. RNase MRP is an endoribonuclease involved in the formation of the 5' end of 5.8S rRNA. In this study the association of the hPop1 protein with the RNase MRP complex was investigated. The hPop1 protein seems not to be directly bound to the RNA component, but requires nt 1-86 and 116-176 of the MRP RNA to associate with the RNase MRP complex via protein-protein interactions. UV crosslinking followed by ribonuclease treatment and immunoprecipitation with anti-Th/To antibodies revealed three human proteins of about 20, 25, and 40 kDa that can associate with the RNase MRP complex. The 20- and 25-kDa proteins appear to bind to stem-loop I of the MRP RNA whereas the 40-kDa protein requires the central part of the MRP RNA (nt 86-176) for association with the RNase MRP complex. In addition, we show that the human RNase P proteins Rpp30 and Rpp38 are also associated with the RNase MRP complex. Expression of Vesicular Stomatitis Virus- (VSV) tagged versions of these proteins in HeLa cells followed by anti-VSV immunoprecipitation resulted in coprecipitation of both RNase P and RNase MRP complexes. Furthermore, UV crosslinking followed by anti-Th/To and anti-Rpp38 immunoprecipitation revealed that the 40-kDa protein we detected in UV crosslinking is probably identical to Rpp38.     

Mutual interactions between subunits of the human RNase MRP ribonucleoprotein complex

The eukaryotic ribonuclease for mitochondrial RNA processing (RNase MRP) is mainly located in the nucleoli and belongs to the small nucleolar ribonucleoprotein (snoRNP) particles. RNase MRP is involved in the processing of pre-rRNA and the generation of RNA primers for mitochondrial DNA replication. A closely related snoRNP, which shares protein subunits with RNase MRP and contains a structurally related RNA subunit, is the pre-tRNA processing factor RNase P. Up to now, 10 protein subunits of these complexes have been described, designated hPop1, hPop4, hPop5, Rpp14, Rpp20, Rpp21, Rpp25, Rpp30, Rpp38 and Rpp40. To get more insight into the assembly of the human RNase MRP complex we studied protein–protein and protein–RNA interactions by means of GST pull-down experiments. A total of 19 direct protein–protein and six direct protein–RNA interactions were observed. The analysis of mutant RNase MRP RNAs showed that distinct regions are involved in the direct interaction with protein subunits. The results provide insight into the way the protein and RNA subunits assemble into a ribonucleoprotein particle. Based upon these data a new model for the architecture of the human RNase MRP complex was generated.     

Rational scanning mutagenesis of a protein kinase identifies functional regions involved in catalysis and substrate interactions

A systematic mutagenesis strategy was used to identify the functional regions and residues of a protein kinase. Clusters of the charged amino acids in the catalytic subunit of Saccharomyces cerevisiae cAMP-dependent protein kinase, were systematically mutated to alanine, producing a set of mutations that encompassed the entire molecule. Residues indispensable for enzyme activity were identified by testing the ability of the mutants to function in vivo. Active mutants were assayed in vitro, and mutants with reduced specific activity were subsequently analyzed by steady-state kinetics to determine the effects of the mutation on kcat and on Km for MgATP and for a peptide substrate. Specific residues and regions of the enzyme were identified that are likely to be important in catalysis and in binding of MgATP, functions that are common to all protein kinases. Additional regions were identified that are likely to be important in binding a peptide substrate, the recognition of which is likely to be specific to the serine/threonine protein kinases that have a requirement for basic residues around the target hydroxyamino acid. The properties of mutants defective in substrate recognition were consistent with an ordered sequential reaction mechanism. This represents the first comprehensive analysis of a protein kinase by a rational mutagenesis strategy.     

Conserved amino acid networks involved in antibody variable domain interactions

Engineered antibodies are a large and growing class of protein therapeutics comprising both marketed products and many molecules in clinical trials in various disease indications. We investigated naturally conserved networks of amino acids that support antibody V_H and V_L function, with the goal of generating information to assist in the engineering of robust antibody or antibody‐like therapeutics. We generated a large and diverse sequence alignment of V‐class Ig‐folds, of which V_H and V_L domains are family members. To identify conserved amino acid networks, covariations between residues at all possible position pairs were quantified as correlation coefficients (?‐values). We provide rosters of the key conserved amino acid pairs in antibody V_H and V_L domains, for reference and use by the antibody research community. The majority of the most strongly conserved amino acid pairs in V_H and V_L are at or adjacent to the V_H–V_L interface suggesting that the ability to heterodimerize is a constraining feature of antibody evolution. For the V_H domain, but not the V_L domain, residue pairs at the variable‐constant domain interface (V_H–C_H1 interface) are also strongly conserved. The same network of conserved V_H positions involved in interactions with both the V_L and C_H1 domains is found in camelid V_HH domains, which have evolved to lack interactions with V_L and C_H1 domains in their mature structures; however, the amino acids at these positions are different, reflecting their different function. Overall, the data describe naturally occurring amino acid networks in antibody Fv regions that can be referenced when designing antibodies or antibody‐like fragments with the goal of improving their biophysical properties. Proteins 2009. © 2008 Wiley‐Liss, Inc.     

Electrostatic interactions guide the active site face of a structure-specific ribonuclease to its RNA substrate

Restrictocin, a member of the alpha-sarcin family of site-specific endoribonucleases, uses electrostatic interactions to bind to the ribosome and to RNA oligonucleotides, including the minimal specific substrate, the sarcin/ricin loop (SRL) of 23S-28S rRNA. Restrictocin binds to the SRL by forming a ground-state E:S complex that is stabilized predominantly by Coulomb interactions and depends on neither the sequence nor structure of the RNA, suggesting a nonspecific complex. The 22 cationic residues of restrictocin are dispersed throughout this protein surface, complicating a priori identification of a Coulomb interacting surface. Structural studies have identified an enzyme-substrate interface, which is expected to overlap with the electrostatic E:S interface. Here, we identified restrictocin residues that contribute to binding in the E:S complex by determining the salt dependence [partial differential log(k 2/ K 1/2)/ partial differential log[KCl]] of cleavage of the minimal SRL substrate for eight point mutants within the protein designed to disrupt contacts in the crystallographically defined interface. Relative to the wild-type salt dependence of -4.1, a subset of the mutants clustering near the active site shows significant changes in salt dependence, with differences of magnitude being >or=0.4. This same subset was identified using calculated salt dependencies for each mutant derived from solutions to the nonlinear Poisson-Boltzmann equation. Our findings support a mechanism in which specific residues on the active site face of restrictocin (primarily K110, K111, and K113) contribute to formation of the E:S complex, thereby positioning the SRL substrate for site-specific cleavage. The same restrictocin residues are expected to facilitate targeting of the SRL on the surface of the ribosome.     

Conserved amino acid residues within and outside of the N-terminal ribonucleoprotein motif of U1A small nuclear ribonucleoprotein involved in U1 RNA binding

By the use of hybrids between a U1 small nuclear ribonucleoprotein (snRNP: U1A) and a U2 snRNP (U2B") we have identified regions containing 29 U1A-specific amino acid residues scattered throughout the 117 N-terminal residues of the protein, which are involved in binding to U1 RNA. The U1A-specific amino acid residues have been arbitrarily divided into seven contiguous groups. None of these groups is sufficient for U1 binding when transferred singly into the U2B" context, and none of the groups is essential for U1 binding in U1A. Several different combinations of two or more groups can, however, confer the ability to bind U1 RNA to U2B", suggesting that most or all of the U1A-specific amino acid residues contribute incrementally to the strength of the specific binding interaction. Further evidence for the importance of the U1A-specific amino acid residues, some of which lie outside the region previously shown to be sufficient for U1 RNA binding, is obtained by comparison of the sequence of human and Xenopus laevis U1A cDNAs. These are extremely similar (94.4% identical) between amino acid residues 7 and 114 but much less conserved immediately upstream and downstream from this region.     

Identification of adenosine functional groups involved in substrate binding by the ribonuclease P ribozyme

The RNA component of bacterial ribonuclease P (RNase P) binds to substrate pre-tRNAs with high affinity and catalyzes site-specific phosphodiester bond hydrolysis to generate the mature tRNA 5' end. Herein we describe the use of biotinylated pre-tRNA substrates to isolate RNase P ribozyme-substrate complexes for nucleotide analogue interference mapping of ribozyme base functional groups involved in substrate recognition. By using a series of adenosine base analogues tagged with phosphorothioate substitutions, we identify specific chemical groups involved in substrate binding. Only 10 adenosines in the Escherichia coli ribozyme show significant sensitivity to interference: A65, A66, A136, A232-234, A248, A249, A334, and A347. Most of these adenosine positions are universally conserved among all bacterial RNase P RNAs; however, not all conserved adenosines are sensitive to analogue substitution. Importantly, all but one of the sensitive nucleotides are located at positions of intermolecular cross-linking between the ribozyme and the substrate. One site of interference that did not correlate with available structural data involved A136 in J11/12. To confirm the generality of the results, we repeated the interference analysis of J11/12 in the Bacillus subtilis RNase P ribozyme, which differs significantly in overall secondary structure. Notably, the B. subtilis ribozyme shows an identical interference pattern at the position (A191) that is homologous to A136. Furthermore, mutation of A136 in the E. coli ribozyme gives rise to a measurable increase in the equilibrium binding constant for the ribozyme-substrate interaction, while mutation of a nearby conserved nucleotide (A132) that is not sensitive to analogue incorporation does not. These results strongly support direct participation of nucleotides in the P4, P11, J5/15, and J18/2 regions of ribozyme structure in pre-tRNA binding and implicate an additional region, J11/12, as involved in substrate recognition. In aggregate, the interference results provide a detailed chemical picture of how the conserved nucleotides adjacent to the pre-tRNA substrate contribute to substrate binding and provide a framework for subsequent identification of the specific roles of these chemical groups in substrate recognition.     

Identification of regions of alpha-thrombin involved in its interaction with hirudin

The contributions of various regions of human alpha-thrombin to the formation of the tight complex with hirudin have been assessed by using derivatives of thrombin. alpha-Thrombin in which the active-site serine was modified with diisopropyl fluorophosphate was able to bind hirudin, but its affinity for hirudin was decreased by 10(3)-fold compared to unmodified alpha-thrombin. Modification of the active-site histidine with D-Phe-Pro-Arg-CH2Cl resulted in a form of thrombin with a 10(6)-fold reduced affinity for hirudin. gamma-Thrombin is produced by proteolytic cleavage of alpha-thrombin in two surface loops corresponding to residues 65-83 and 146-150 in alpha-chymotrypsin [Berliner, L. J. (1984) Mol. Cell. Biochem. 61, 159-172; Birktoft, J. J., & Blow, D. M. (1972) J. Mol. Biol. 68, 187-240]. The gamma-thrombin-hirudin complex had a dissociation constant that was 10(6)-fold higher than that of alpha-thrombin. Treatment of alpha-thrombin with pancreatic elastase resulted in a form of thrombin only cleaved in the loop corresponding to residues 146-150 in alpha-chymotrypsin, and this form of thrombin had only a slightly reduced affinity for hirudin. By using limited proteolysis with trypsin, it was possible to isolate beta-thrombin which contained a single cleavage in the loop corresponding to residues 65-83 in alpha-chymotrypsin. This form of thrombin had a 100-fold decrease in affinity for hirudin. Kinetic analysis of the binding of hirudin to beta-thrombin indicated that the 100-fold decrease in affinity was predominantly due to a decrease in the rate of association of the two molecules.(ABSTRACT TRUNCATED AT 250 WORDS)     

At least two regions of the oncoprotein Tre2 are involved in its lack of GAP activity

The product of the human Tre2 oncogene is structurally related to the Ypt/Rab GTPase-activating proteins (Ypt/Rab GAPs). Particularly, the oncoprotein shares with the yeast proteins Msb3p and Msb4p, and with the human protein RN-tre the highly conserved TBC domain, forming the catalytically active domain of Ypt/Rab GAPs. Yet, the Tre2 oncogene seems to encode a nonfunctional Rab GAP. As regions flanking the TBC domain may be crucial for catalytic activity, regions located N- and C-terminally with respect to this domain were explored. For this, chimeric proteins created by sequence exchanges between the Tre2 oncoprotein and RN-tre were tested for their ability to replace functionally the Msb3p and Msb4p proteins in double-mutant yeast cells. These complementation experiments revealed, in addition to the TBC domain, a second Tre2 region involved in the oncoprotein's lack of GAP activity: a 93-aa region flanking the TBC domain on the C-terminal side.     

Arginine residues 47 and 70 of human flap endonuclease-1 are involved in DNA substrate interactions and cleavage site determination

Flap endonuclease-1 (FEN-1) is a critical enzyme for DNA replication and repair. Intensive studies have been carried out on its structure-specific nuclease activities and biological functions in yeast cells. However, its specific interactions with DNA substrates as an initial step of catalysis are not defined. An understanding of the ability of FEN-1 to recognize and bind a flap DNA substrate is critical for the elucidation of its molecular mechanism and for the explanation of possible pathological consequences resulting from its failure to bind DNA. Using human FEN-1 in this study, we identified two positively charged amino acid residues, Arg-47 and Arg-70 in human FEN-1, as candidates responsible for substrate binding. Mutation of the Arg-70 significantly reduced flap endonuclease activity and eliminated exonuclease activity. Mutation or protonation of Arg-47 shifted cleavage sites with flap substrate and significantly reduced the exonuclease activity. We revealed that these alterations are due to the defects in DNA-protein interactions. Although the effect of the single Arg-47 mutation on binding activities is not as severe as R70A, its double mutation with Asp-181 had a synergistic effect. Furthermore the possible interaction sites of these positively charged residues with DNA substrates were discussed based on FEN-1 cleavage patterns using different substrates. Finally data were provided to indicate that the observed negative effects of a high concentration of Mg(2+) on enzymatic activity are probably due to the competition between the arginine residues and metal ions with DNA substrate since mutants were found to be less tolerant.     

Multiple regions of MAP kinase phosphatase 3 are involved in its recognition and activation by ERK2

Mitogen-activated protein kinase phosphatase 3 (MKP3) is a specific regulator of extracellular signal-regulated protein kinase 2 (ERK2). Association of ERK2 with MKP3 results in a powerful increase in MKP3 phosphatase activity. To determine the molecular basis of the specific ERK2 recognition by MKP3 and the ERK2-induced MKP3 activation, we have carried out a systematic mutational and deletion analysis of MKP3. Using activation-based and competition-based assays, we are able to quantitatively evaluate the contributions that residues/regions within MKP3 make to ERK2 binding and ERK2-induced MKP3 activation. Our results show that recognition and activation of MKP3 by ERK2 involves multiple regions of MKP3. Thus, the kinase interaction motif (KIM; residues 61--75) in MKP3 plays a major role (135-fold) for high affinity ERK2 binding. The most important residue in the KIM sequence of MKP3 is Arg(65), which probably interacts with Asp(319) in ERK2. In addition to KIM, a unique sequence conserved in cytosolic MKPs (residues 161--177 in MKP3) also contributes to ERK2 binding (15-fold). However, these two regions are not essential for ERK2-induced MKP3 activation. A third ERK2 binding site is localized in the C terminus of MKP3 (residues 348--381). Although deletion of this region or mutation of the putative ERK specific docking sequence (364)FTAP(367) in this region reduces MKP3's affinity for ERK2 by less than 10-fold, this region is absolutely required for ERK2-induced MKP3 activation.     

Conserved pore-forming regions in polypeptide-transporting proteins

Transport of solutes and polypeptides across membranes is an essential process for every cell. In the past, much focus has been placed on helical transporters. Recently, the beta-barrel-shaped transporters have also attracted some attention. The members of this family are found in the outer bacterial membrane and the outer membrane of endosymbiotically derived organelles. Here we analyze the features and the evolutionary development of a specified translocator family, namely the beta-barrel-shaped polypeptide-transporters. We identified sequence motifs, which characterize all transporters of this family, as well as motifs specific for a certain subgroup of proteins of this class. The general motifs are related to the structural composition of the pores. Further analysis revealed a defined distance of two motifs to the C-terminal portion of the proteins. Furthermore, the evolutionary relationship of the proteins and the motifs are discussed.     

Conserved interactions with cytoskeletal but not signaling elements are an essential aspect of Drosophila WASp function

Wiskott-Aldrich Syndrome proteins (WASp) serve as important regulators of cytoskeletal organization and function. These modular proteins, which are well-conserved among eukaryotic species, act to promote actin filament assembly in response to cues from various signal transduction pathways. Genetic analysis has revealed a requirement for the single Drosophila homolog, Wasp (Wsp), in cell-fate decisions governing specific neuronal lineages. We have used this unique developmental context to assess the contributions of established signaling and cytoskeletal partners of WASp. We present biochemical and genetic evidence that, as expected, Drosophila Wsp performs its developmental role via the Arp2/3 complex, indicating conservation of the cytoskeletal aspect of Wsp function in vivo. In contrast, we find that association with the key signaling molecules CDC42 and PIP2 is not an essential requirement, implying that activation of Wsp function in vivo depends on additional or alternative signaling pathways.     

Mapping of the regions involved in homotypic interactions of Tula hantavirus N protein

Hantavirus nucleocapsid (N) protein has been suggested to form homodimers and homotrimers that are further integrated into the nucleocapsid filaments around the viral RNA. Here we report detailed mapping of the regions involved in the homotypic N protein interactions in Tula hantavirus (TULV). Peptide scan screening was used to define the interaction regions, and the mammalian two-hybrid assay was used for the functional analysis of N protein mutants. To study linear regions responsible for N protein interaction(s), we used peptide scanning in which N peptides synthesized on membranes recognize recombinant TULV N protein. The data showed that the N protein bound to membrane-bound peptides comprising amino acids 13 to 30 and 41 to 57 in the N-terminal part and 340 to 379, 391 to 407, and 410 to 419 in the C-terminal part of the molecule. Further mapping of the interaction regions by alanine scanning indicated the importance of basic amino acids along the N protein and especially asparagine-394, histidine-395, and phenyalanine-396 in forming the binding interface. Analysis of truncated mutants in the mammalian two-hybrid assay showed that N-terminal amino acids 1 to 43 are involved in and C-terminal amino acids 393 to 398 (VNHFHL) are absolutely crucial for the homotypic interactions. Furthermore, our data suggested a tail-to-tail and head-to-head binding scheme for the N proteins.     

Conserved asparagine residue located in binding pocket controls cation selectivity and substrate interactions in neuronal glutamate transporter

Transporters of the major excitatory neurotransmitter glutamate play a crucial role in glutamatergic neurotransmission by removing their substrate from the synaptic cleft. The transport mechanism involves co-transport of glutamic acid with three Na(+) ions followed by countertransport of one K(+) ion. Structural work on the archeal homologue Glt(Ph) indicates a role of a conserved asparagine in substrate binding. According to a recent proposal, this residue may also participate in a novel Na(+) binding site. In this study, we characterize mutants of this residue from the neuronal transporter EAAC1, Asn-451. None of the mutants, except for N451S, were able to exhibit transport. However, the K(m) of this mutant for l-aspartate was increased ～30-fold. Remarkably, the increase for d-aspartate and l-glutamate was 250- and 400-fold, respectively. Moreover, the cation specificity of N451S was altered because sodium but not lithium could support transport. A similar change in cation specificity was observed with a mutant of a conserved threonine residue, T370S, also implicated to participate in the novel Na(+) site together with the bound substrate. In further contrast to the wild type transporter, only l-aspartate was able to activate the uncoupled anion conductance by N451S, but with an almost 1000-fold reduction in apparent affinity. Our results not only provide experimental support for the Na(+) site but also suggest a distinct orientation of the substrate in the binding pocket during the activation of the anion conductance.     

Quantitative analysis of regions of adenovirus E1A products involved in interactions with cellular proteins.

Human adenovirus E1A proteins and oncogene products of several other DNA tumour viruses derive much of their oncogenic potential from interactions with cellular polypeptides. E1A proteins form complexes with p105Rb and a related p107 polypeptide, and with at least three other proteins (p60cycA, p130, and p300); all may be required for cell transformation. Using a series of E1A deletion mutants, we have carried out a quantitative analysis of the binding patterns of cellular proteins to E1A products. Binding of most of the proteins was affected at least partially by mutations within the amino terminal 25 residues, amino acids 36-69 within conserved region 1 (CR1), and residues 121-138 in conserved region 2 (CR2). However, the specific binding characteristics of each protein varied considerably. p300 was the only species for which binding was totally eliminated by deletions at the amino terminus. Removal of regions within CR1 eliminated binding of all species except p107 and p60cycA. Deletion of portions of CR2 reduced or eliminated binding of all proteins except p300. Thus, whereas cellular polypeptides generally were found to interact with the same three regions of E1A proteins, specific interactions varied considerably.     

Sulfhydryl groups are involved in the interaction of FSH with its receptor

FSH has recently been reported to possess thioredoxin-like activity, presumably explained by the homology between a region of FSH-beta subunit and the active site of thioredoxin. The homologous sequence lies within a receptor binding region, which suggests a possible role for sulfhydryl groups in the formation of an active hormone-receptor complex and subsequent signal transduction. In order to determine the relevance of sulfhydryl groups on FSH-receptor interaction, we studied the effect of N-ethylmaleimide (NEM) and glutathione on FSH binding. The results indicate that free sulfhydryl groups, probably derived from the FSH receptor, are involved in ligand-receptor interaction.     

Delineating the regions of human transferrin involved in interactions with transferrin binding protein B from Neisseria meningitidis

Pathogenic bacteria in the Neisseriaceae possess a surface receptor mediating iron acquisition from human transferrin (hTf) that consists of a transmembrane iron transporter (TbpA) and a surface‐exposed lipoprotein (TbpB). In this study, we used hydrogen/deuterium exchange coupled to mass spectrometry (H/DX‐MS) to elucidate the effects on hTf by interaction with TbpB or derivatives of TbpB. An overall conserved interaction was observed between hTf and full‐length or N‐lobe TbpB from Neisseria meningitidis strains B16B6 or M982 that represent two distinct subtypes of TbpB. Changes were observed exclusively in the C‐lobe of hTf and were caused by the interaction with the N‐lobe of TbpB. Regions localized to the ‘lip’ of the C1 and C2 domains that flank the interdomain cleft represent sites of direct contact with TbpB whereas the peptides within the interdomain cleft that encompass iron binding ligands are inaccessible in the closed (holo) conformation. Although substantial domain separation upon binding TbpB cannot be excluded by the H/DX‐MS data, the preferred model of interaction involves binding hTf C‐lobe in the closed conformation. Alternate explanations are provided for the substantial protection from deuteration of the peptides encompassing iron binding ligands within the interdomain cleft but cannot be differentiated by the H/DX‐MS data.