The N-terminal arm of small heat shock proteins is important for both chaperone activity and substrate specificity

Small heat shock proteins (sHSPs) are a ubiquitous class of molecular chaperones that interacts with substrates to prevent their irreversible insolubilization during denaturation. How sHSPs interact with substrates remains poorly defined. To investigate the role of the conserved C-terminal alpha-crystallin domain versus the variable N-terminal arm in substrate interactions, we compared two closely related dodecameric plant sHSPs, Hsp18.1 and Hsp16.9, and four chimeras of these two sHSPs, in which all or part of the N-terminal arm was switched. The efficiency of substrate protection and formation of sHSP-substrate complexes by these sHSPs with three different model substrates, firefly luciferase, citrate synthase, and malate dehydrogenase (MDH) provide new insights into sHSP/substrate interactions. Results indicate that different substrates have varying affinities for different domains of the sHSP. For luciferase and citrate synthase, the efficiency of substrate protection was determined by the identity of the N-terminal arm in the chimeric proteins. In contrast, for MDH, efficient protection clearly required interactions with the alpha-crystallin domain in addition to the N-terminal arm. Furthermore, we show that sHSP-substrate complexes with varying stability and composition can protect substrate equally, and substrate protection is not correlated with sHSP oligomeric stability for all substrates. Protection of MDH by the dimeric chimera composed of the Hsp16.9 N-terminal arm and Hsp18.1 alpha-crystallin domain supports the model that a dimeric form of the sHSP can bind and protect substrate. In total, results demonstrate that sHSP-substrate interactions are complex, likely involve multiple sites on the sHSP, and vary depending on substrate.     

8-Nitroxanthine,a product of myeloperoxidase,peroxynitrite, and activated human neutrophils,enhances generation of superoxide by xanthine oxidase

In biology, chiral recognition usually implies the ability of a protein, such as an enzyme or a drug receptor, to distinguish between the two enantiomeric forms of a chiral substrate or drug. Both diastereoisomerism and specific contacts between enzyme/receptor and substrate/drug are necessary. The minimum requirement is for four contact points including four nonplanar atoms (or groups of atoms) in both probe and target. The molecular models described by Easson and Stedman and by Ogston require three binding sites in a plane. A modified model with three binding sites in three dimensions is described. Under certain circumstances this model allows binding of both enantiomeric forms of a substrate or a drug. Enantiomer superposition of two enantiomers at an active site occurs in some specific cases (e.g., phenylalanine ammonia-lyase, isocitrate dehydrogenase) and is likely in others. The nature of enantiomer binding to racemase enzymes is discussed.     

Stereoselectivity of Mucorales lipases toward triradylglycerols--a simple solution to a complex problem

The lipases from Rhizopus and Rhizomucor are members of the family of Mucorales lipases. Although they display high sequence homology, their stereoselectivity toward triradylglycerols (sn-2 substituted triacylglycerols) varies. Four different triradylglycerols were investigated, which were classified into two groups: flexible substrates with rotatable O'-C1' ether or ester bonds adjacent to C2 of glycerol and rigid substrates with a rigid N'-C1' amide bond or a phenyl ring in sn-2. Although Rhizopus lipase shows opposite stereopreference for flexible and rigid substrates (hydrolysis in sn-1 and sn-3, respectively), Rhizomucor lipase hydrolyzes both groups of triradylglycerols preferably in sn-1. To explain these experimental observations, computer-aided molecular modeling was applied to study the molecular basis of stereoselectivity. A generalized model for both lipases of the Mucorales family highlights the residues mediating stereoselectivity: (1) L258, the C-terminal neighbor of the catalytic histidine, and (2) G266, which is located in a loop contacting the glycerol backbone of a bound substrate. Interactions with triradylglycerol substrates are dominated by van der Waals contacts. Stereoselectivity can be predicted by analyzing the value of a single substrate torsion angle that discriminates between sn-1 and sn-3 stereopreference for all substrates and lipases investigated here. This simple model can be easily applied in enzyme and substrate engineering to predict Mucorales lipase variants and synthetic substrates with desired stereoselectivity.     

Asymmetric interactions of ATP with the AAA+ ClpX6 unfoldase: allosteric control of a protein machine

ATP hydrolysis by AAA+ ClpX hexamers powers protein unfolding and translocation during ClpXP degradation. Although ClpX is a homohexamer, positive and negative allosteric interactions partition six potential nucleotide binding sites into three classes with asymmetric properties. Some sites release ATP rapidly, others release ATP slowly, and at least two sites remain nucleotide free. Recognition of the degradation tag of protein substrates requires ATP binding to one set of sites and ATP or ADP binding to a second set of sites, suggesting a mechanism that allows repeated unfolding attempts without substrate release over multiple ATPase cycles. Our results rule out concerted hydrolysis models involving ClpX(6)*ATP(6) or ClpX(6)*ADP(6) and highlight structures of hexameric AAA+ machines with three or four nucleotides as likely functional states. These studies further emphasize commonalities between distant AAA+ family members, including protein and DNA translocases, helicases, motor proteins, clamp loaders, and other ATP-dependent enzymes.     

Phosphorylation by LAMMER protein kinases: determination of a consensus site, identification of in vitro substrates, and implications for substrate preferences

LAMMER protein kinases are ubiquitous throughout eukaryotes, including multiple paralogues in mammals. Members are characterized by similar overall structure and highly identical amino acid sequence motifs in catalytic subdomains essential for phosphotransfer and interaction with substrates. LAMMER kinases phosphorylate and regulate the activity of the SR protein class of pre-mRNA splicing components, both in vitro and in vivo. In this study, we define an optimum in vitro consensus phosphorylation site for three family members using an oriented degenerate peptide library approach. We also examine the substrate specificity and interactions of several LAMMER protein kinases from widely diverged species with potential substrates, including their own N-termini, predicted to be substrates by the peptide-based approach. Although the optimal in vitro consensus phosphorylation site for these kinases is remarkably similar for short peptides, distinct substrate preferences are revealed by in vitro phosphorylation of intact proteins. This finding suggests that these kinases may possess varied substrates in vivo, and thus the multiple LAMMER kinases present in higher eukaryotes may perform differentiable functions. These results further demonstrate that these kinases can phosphorylate a number of substrates in addition to SR proteins, suggesting that they may regulate multiple cellular processes, in addition to the alternative splicing of pre-mRNAs.     

Dual recognition of the bacterial chemoreceptor by chemotaxis-specific domains of the CheR methyltransferase

Adaptation to persisting stimulation is required for highly sensitive detection of temporal changes of stimuli, and often involves covalent modification of receptors. Therefore, it is of vital importance to understand how a receptor and its cognate modifying enzyme(s) modulate each other through specific protein-protein interactions. In the chemotaxis of Escherichia coli, adaptation requires methylation of chemoreceptors (e.g. Tar) catalyzed by the CheR methyltransferase. CheR binds to the C-terminal NWETF sequence of a chemoreceptor that is distinct from the methylation sites. However, little is known about how CheR recognizes its methylation sites or how it is distributed in a cell. In this study, we used comparative genomics to demonstrate that the CheR chemotaxis methyltransferase contains three structurally and functionally distinct modules: (i) the catalytic domain common to a methyltransferase superfamily; (ii) the N-terminal domain; and (iii) the beta-subdomain of the catalytic domain, both of which are found exclusively in chemotaxis methyltransferases. The only evolutionary conserved motif specific to CheR is the positively charged face of helix alpha2 in the N-terminal domain. The disulfide cross-linking analysis suggested that this face interacts with the methylation helix of Tar. We also demonstrated that CheR localizes to receptor clusters at cell poles via interaction of the beta-subdomain with the NWETF sequence. Thus, the two chemotaxis-specific modules of CheR interact with distinct regions of the chemoreceptor for targeting to the receptor cluster and for recognition of the substrate sites, respectively.     

Bivalent tethering of SspB to ClpXP is required for efficient substrate delivery: a protein-design study

SspB homodimers deliver ssrA-tagged substrates to ClpXP for degradation. SspB consists of a substrate binding domain and an unstructured tail with a ClpX binding module (XB). Using computational design, we engineered an SspB heterodimer whose subunits did not form homodimers. Experiments with the designed molecule and variants lacking one or two tails demonstrate that both XB modules are required for strong binding and efficient substrate delivery to ClpXP. Assembly of stable SspB-substrate-ClpX delivery complexes requires the coupling of weak tethering interactions between ClpX and the SspB XB modules as well as interactions between ClpX and the substrate degradation tag. The ClpX hexamer contains three XB binding sites, one per N domain dimer, and thus binds strongly to just one SspB dimer at a time. Because different adaptor proteins use the same tethering sites in ClpX, those which employ bivalent tethering, like SspB, will compete more effectively for substrate delivery to ClpXP.     

Directed evolution of transketolase activity on non-phosphorylated substrates

We have used active-site targeted directed evolution by saturation mutagenesis to improve the activity of E. coli transketolase towards non-phosphorylated substrates. Residues were selected for each set based on either structural proximity to substrate, or on phylogenetic variation. Each library was screened towards the reaction between hydroxypyruvate (HPA) and glycolaldehyde (GA) to form L-erythrulose, and the location of improved mutants related to the natural sequence entropy at each residue. A number of mutants from the phylogenetically defined library were found to outperform the wild-type with up to 3-fold specific activity under biocatalytically relevant conditions, though interestingly with substituted residues that differed from those found in nature. Conserved residues which interact with the phosphate group in natural substrates also yielded mutants with almost 5-fold improved specific activity on the non-phosphorylated substrates. These results suggest that phylogenetically variant active-site residues are useful for modulating activity on natural or structurally-homologous substrates, and that conserved residues which no longer interact with modified target substrates are useful sites to apply saturation mutagenesis for improvement of activity.     

SR splicing factors serve as adapter proteins for TAP-dependent mRNA export

The only mammalian RNA binding adapter proteins known to partner with TAP/NXF1, the primary receptor for general mRNA export, are members of the REF family. We demonstrate that at least three shuttling SR (serine/arginine-rich) proteins interact with the same domain of TAP/NXF1 that binds REFs. Included are 9G8 and SRp20, previously shown to promote the export of intronless RNAs. A peptide derived from the N terminus of 9G8 inhibits the binding of both REF and SR proteins to TAP/NXF1 in vitro, and this finding argues for competitive interactions. In Xenopus oocytes, the N terminus of 9G8 exhibits a dominant-negative effect on mRNA export from the nucleus, while addition of excess TAP/NXF1 overcomes this inhibition. Thus, multiple adapters including SR proteins most likely cooperate to recruit multiple copies of TAP/NXF1 for efficient mRNA export.     

Gin-mediated recombination of catenated and knotted DNA substrates: implications for the mechanism of interaction between cis-acting sites

The Gin DNA-inversion system of bacteriophage Mu normally requires a substrate containing two inverted recombination sites (gix) and an enhancer sequence on the same supercoiled DNA molecule. The reaction mechanism was investigated by separating these sites on catenated rings. Catenanes with the gix sites on one circle and the enhancer on the other recombined efficiently. Thus, the enhancer was fully functional even though it was located in trans to the gix sites. Multiple links between the rings are required for recombination. Multiply linked catenanes with gix sites on separate circles, one of which contained the enhancer, were also efficient substrates. Knotted constructs carrying directly repeated gix sites were recombined. Catenated and knotted substrates must also be supercoiled. These experiments eliminate simple tracking or looping models as explanations for why the enhancer and gix sites must be in cis with standard substrates. Rather, the Gin synaptic complex requires the three sites to be mutually intertwined in a right-handed fashion with a unique polarity of the gix sites. This geometry is achieved by branching of the DNA substrate and requires the energy and structure of supercoiling, catenation, or knotting.     

Molecular modeling of cytochrome P450 1A1: enzyme-substrate interactions and substrate binding affinities

Human cytochrome P450 1A1, which is present in lungs, plays an important role in the metabolic activation of chemical carcinogens, and in particular, is thought to be linked to lung cancer. The mechanism of carcinogenesis is related to the enzyme's ability to oxidize highly toxic compounds, such as polycyclic aromatic hydrocarbons (PAHs), to their carcinogenic derivatives. In order to better understand P450 1A1 function, a homology model of this enzyme has been constructed. The model has been based on the structure of P450 2C5, the first mammalian P450 to be crystallized. The coordinates of the model have been calculated using a consensus strategy, and the resulting structure has been evaluated with the ProStat and Profiles-3D programs. P450 1A1 substrates, such as benzo[a]pyrene, ethoxyresorufin and methoxyresorufin, were then docked into the active site of the model, and key amino acid residues able to interact with the substrate, have been identified. The analysis of enzyme-substrate interactions indicated that hydrophobic interactions are mainly responsible for binding of these substrates in the active site. Moreover, the non-bond enzyme-substrate interaction energy for ethoxyresorufin was lower than that for methoxyresorufin, which is consistent with higher activity of 1A1 towards the former substrate. Key residue Val-382 may play an important role in these interactions. Additionally, we performed binding free energy calculations for the three substrates. The obtained values were similar to those observed experimentally, which suggests that this approach might be useful for prediction of binding constants.     

A peptide model system for processive phosphorylation by Src family kinases

The Src homology 2 (SH2) and Src homology 3 (SH3) domains of Src family kinases are involved in substrate recognition in vivo. Many cellular substrates of Src kinases contain a large number of potential phosphorylation sites, and the SH2 and SH3 domains of Src are known to be required for phosphorylation of these substrates. In principle, Src could phosphorylate these substrates by either a processive mechanism, in which the enzyme remains bound to the peptide substrate during multiple phosphorylation events, or a nonprocessive (distributive) mechanism, where each phosphorylation requires a separate binding interaction between enzyme and substrate. Here we use a synthetic peptide system to demonstrate that Hck, a Src family kinase, can phosphorylate substrates containing an SH2 domain ligand by a processive mechanism. Hck catalyzes the phosphorylation of these sites in a defined order. Furthermore, we show that addition of an SH3 domain to a peptide can enhance its phosphorylation both by activating Hck and by increasing the affinity of the substrate. On the basis of our observations on the role of the SH2 and SH3 domains in substrate recognition, we present a model for substrate targeting in vivo.     

The role of U2AF35 and U2AF65 in enhancer-dependent splicing.

Splicing enhancers are RNA sequence elements that promote the splicing of nearby introns. The mechanism by which these elements act is still unclear. Some experiments support a model in which serine-arginine (SR)-rich proteins function as splicing activators by binding to enhancers and recruiting the splicing factor U2AF to an adjacent weak 3' splice site. In this model, recruitment requires interactions between the SR proteins and the 35-kDa subunit of U2AF (U2AF35). However, more recent experiments have not supported the U2AF recruitment model. Here we provide additional evidence for the recruitment model. First, we confirm that base substitutions that convert weak 3' splice sites to a consensus sequence, and therefore increase U2AF binding, relieve the requirement for a splicing activator. Second, we confirm that splicing activators are required for the formation of early spliceosomal complexes on substrates containing weak 3' splice sites. Most importantly, we find that splicing activators promote the binding of both U2AF65 and U2AF35 to weak 3' splice sites under splicing conditions. Finally, we show that U2AF35 is required for maximum levels of activator-dependent splicing. We conclude that a critical function of splicing activators is to recruit U2AF to the weak 3' splice sites of enhancer-dependent introns, and that efficient enhancer-dependent splicing requires U2AF35.     

Structurally unique yeast and mammalian serine-arginine protein kinases catalyze evolutionarily conserved phosphorylation reactions

The mammalian serine-arginine (SR) protein, ASF/SF2, contains multiple contiguous RS dipeptides at the C terminus, and approximately 12 of these serines are processively phosphorylated by the SR protein kinase 1 (SRPK1). We have recently shown that a docking motif in ASF/SF2 specifically interacts with a groove in SRPK1, and this interaction is necessary for processive phosphorylation. We previously showed that SRPK1 and its yeast ortholog Sky1p maintain their active conformations using diverse structural strategies. Here we tested if the mechanism of ASF/SF2 phosphorylation by SRPK is evolutionarily conserved. We show that Sky1p forms a stable complex with its heterologous mammalian substrate ASF/SF2 and processively phosphorylates the same sites as SRPK1. We further show that Sky1p utilizes the same docking groove to bind yeast SR-like protein Gbp2p and phosphorylates all three serines present in a contiguous RS dipeptide stretch. However, the mechanism of Gbp2p phosphorylation appears to be non-processive. Thus, there are physical attributes of SR and SR-like substrates that dictate the mechanism of phosphorylation, whereas the ability to processively phosphorylate substrates is inherent to SR protein kinases.     

GroEL stability and function. Contribution of the ionic interactions at the inter-ring contact sites

The chaperonin GroEL consists of a double ring structure made of identical subunits that display different modes of allosteric communication. The protein folding cycle requires the simultaneous positive intra-ring and negative inter-ring cooperativities of ATP binding. This ensures GroES binding to one ring and release of the ligands from the opposite one. To better characterize inter-ring allosterism, the thermal stability as well as the temperature dependence of the functional and conformational properties of wild type GroEL, a single ring mutant (SR1) and two single point mutants suppressing one interring salt bridge (E434K and E461K) were studied. The results indicate that ionic interactions at the two interring contact sites are essential to maintain the negative cooperativity for protein substrate binding and to set the protein thermostat at 39 degrees C. These electrostatic interactions contribute distinctly to the stability of the inter-ring interface and the overall protein stability, e.g. the E434K thermal inactivation curve is shifted to lower temperatures, and its unfolding temperature and activation energy are also lowered. An analysis of the ionic interactions at the inter-ring contact sites reveals that at the so called "left site" a network of electrostatic interactions involving three charged residues might be established, in contrast to what is found at the "right site" where only two oppositely charged residues interact. Our data suggest that electrostatic interactions stabilize protein-protein interfaces depending on both the number of ionic interactions and the number of residues engaged in each of these interactions. In the case of GroEL, this combination sets the thermostat of the protein so that the chaperonin distinguishes physiological from stress temperatures.     

Applying the SPOT peptide synthesis procedure to the study of protein tyrosine phosphatase substrate specificity: probing for the heavenly match in vitro

This section provides detailed protocols for peptide synthesis on membrane (SPOT) and describes the application of this technology to protein tyrosine phosphatase (PTPs) substrate selectivity studies. Applications include PTP binding and dephosphorylation assays on phosphotyrosine peptides derived from known substrates, such as the insulin receptor (IR) autophosphorylation site, and on peptides from focused or random SPOT peptide libraries, to discover consensus binding motifs. Weak or transient interactions that cannot be revealed by regular SPOT binding can be uncovered using SPOT double synthesis (SPOT-DS), whereby two different peptides are synthesized on the same spot. In SPOT-DS, one peptide is a substrate for the enzyme, whose conversion is indicative of a transient interaction of the enzyme with the other (variable) peptide. Using SPOT-DS, three IR regions that interact with full-length PTP-1B in a non-phosphorylation-dependent manner were revealed. In order to further study multiple interaction sites, we have developed a strategy to synthesize up to four peptides per spot: "SPOT(4)". Finally, several examples are provided that illustrate how the SPOT technology can be used in kinase and protease selectivity studies as well.     

19F NMR studies of the D-galactose chemosensory receptor. 1. Sugar binding yields a global structural change.

The Escherichia coli D-galactose and D-glucose receptor is an aqueous sugar-binding protein and the first component in the distinct chemosensory and transport pathways for these sugars. Activation of the receptor occurs when the sugar binds and induces a conformational change, which in turn enables docking to specific membrane proteins. Only the structure of the activated receptor containing bound D-glucose is known. To investigate the sugar-induced structural change, we have used 19F NMR to probe 12 sites widely distributed in the receptor molecule. Five sites are tryptophan positions probed by incorporation of 5-fluorotryptophan; the resulting 19F NMR resonances were assigned by site-directed mutagenesis. The other seven sites are phenylalanine positions probed by incorporation of 3-fluorophenylalanine. Sugar binding to the substrate binding cleft was observed to trigger a global structural change detected via 19F NMR frequency shifts at 10 of the 12 labeled sites. Two of the altered sites lie in the substrate binding cleft in van der Waals contact with the bound sugar molecule. The other eight altered sites, specifically two tryptophans and six phenylalanines distributed equally between the two receptor domains, are distant from the cleft and therefore experience allosteric structural changes upon sugar binding. The results are consistent with a model in which multiple secondary structural elements, known to extend between the substrate cleft and the protein surface, undergo shifts in their average positions upon sugar binding to the cleft. Such structural coupling provides a mechanism by which sugar binding to the substrate cleft can cause structural changes at one or more docking sites on the receptor surface.     

The role of hydrogen bond acceptor groups in the interaction of substrates with Pdr5p, a major yeast drug transporter

The yeast ABC (ATP-binding cassette protein) multidrug transporter Pdr5p transports a broad spectrum of xenobiotic compounds, including antifungal and antitumor agents. Previously, we demonstrated that substrate size is an important factor in substrate-transporter interaction and that Pdr5p has at least three substrate-binding sites. In this study, we use a combination of whole cell transport assays and photoaffinity labeling of Pdr5p with [(125)I]iodoarylazidoprazosin in purified plasma membrane vesicles to study the behavior of two series of novel substrates: trityl (triphenylmethyl) and carbazole derivatives. The results indicate that site 2, defined initially by tritylimidazole efflux, requires at least a single hydrogen bond acceptor group (electron pair donor). In contrast, complete inhibition of rhodamine 6G efflux and [(125)I]iodoarylazidoprazosin binding at site 1 requires substrates with three electronegative groups. Carbazole and trityl substrates with two groups show saturating, incomplete inhibition at this site. This type of inhibition is frequently observed in bacterial multidrug-binding proteins that use a pocket with multiple binding sites. The presence of multiple sites with different requirements for substrate-Pdr5p interaction may explain the broad specificity of xenobiotic compounds transported by this protein.     

Stereoselectivity of Pseudomonas cepacia lipase toward secondary alcohols: a quantitative model

The lipase from Pseudomonas cepacia represents a widely applied catalyst for highly enantioselective resolution of chiral secondary alcohols. While its stereopreference is determined predominantly by the substrate structure, stereoselectivity depends on atomic details of interactions between substrate and lipase. Thirty secondary alcohols with published E values using P. cepacia lipase in hydrolysis or esterification reactions were selected, and models of their octanoic acid esters were docked to the open conformation of P. cepacia lipase. The two enantiomers of 27 substrates bound preferentially in either of two binding modes: the fast-reacting enantiomer in a productive mode and the slow-reacting enantiomer in a nonproductive mode. Nonproductive mode of fast-reacting enantiomers was prohibited by repulsive interactions. For the slow-reacting enantiomers in the productive binding mode, the substrate pushes the active site histidine away from its proper orientation, and the distance d(H(N epsilon) - O(alc)) between the histidine side chain and the alcohol oxygen increases, d(H(N epsilon) - O(alc)) was correlated to experimentally observed enantioselectivity: in substrates for which P. cepacia lipase has high enantioselectivity (E > 100), d(H(N epsilon) - O(alc)) is >2.2 A for slow-reacting enantiomers, thus preventing efficient catalysis of this enantiomer. In substrates of low enantioselectivity (E < 20), the distance d(H(N epsilon) - O(alc)) is less than 2.0 A, and slow- and fast-reacting enantiomers are catalyzed at similar rates. For substrates of medium enantioselectivity (20 < E < 100), d(H(N epsilon) - O(alc)) is around 2.1 A. This simple model can be applied to predict enantioselectivity of P. cepacia lipase toward a broad range of secondary alcohols.     

From signal transduction to signal interpretation: an alternative model for the molecular function of insulin receptor substrates

The insulin receptor (IR) recruits adaptor proteins, so-called insulin receptor substrates (IRS), to connect with downstream signalling pathways. A family of IRS proteins was defined based on three major common structural elements: Amino-terminal PH and PTB domains that mediate protein-lipid or protein-protein interactions, mostly carboxy-terminal multiple tyrosine residues that serve as binding sites for proteins that contain one or more SH2 domains and serine/threonine-rich regions which may be recognized by negative regulators of insulin action. The current model for the role of IRS proteins therefore combines an adaptor function with the integration of mostly negative input from other signal transduction cascades allowing for modulation of signalling amplitude. In this review we propose an extended version of the adaptor model that can explain how signalling specificity could be implemented at the level of IRS proteins.