Beta-branched residues adjacent to GG4 motifs promote the efficient association of glycophorin A transmembrane helices

Protein transmenembrane (TM) segments participating in helix-helix packing commonly contain small residue patterns (termed GG4 or "small-xxx-small" motifs) at i and i + 4 positions. Within many TM segments - such as the glycophorin A (GpA) sequence L75IxxGVxxGVxxT87- the G17y-xxx-Gly83 motif often occurs in combination with large, usually beta3-branched aliphatic residues at adjacent positions, typified here by Val30 and Val84 residues. To explore the importance of local P-branched character on GpA dimerization, we made systematic replacements to all 16 combinations of single or double Ile, Leu, and AIa residues at GpA TM Val/Val positions 80 and 84. Using the TOXCAT system to assay self-oligomerization in the Escherichia coli inner membrane--we observed that (i) combinations of Val and lie residues maintained, or improved dimerization levels; (ii) single Ala or Leu mutant combinations with Val or Ile maintained near-wild type dimerization affinities; and (iii) in the absence of beta-branching, i.e., Leu/Leu, Ala/Ala and Ala/Leu combinations, GpA dimerization was significantly diminished. An apparent capacity of lle-containing mutants to increase GpA dimerization versus WT likely arises from improved van der Waals packing (vs. Val) within the locus of helix contact, consistent with correlations we noted in lipid accessibility measurements. Examination of several synthetic peptides with sequences corresponding to selected GpA mutants (VV VI, IV II, and LL) confirmed their dimerization on sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS-PAGE). The overall results reinforce the importance of a beta-branch-containing "ridge" residue to complement a "small-xxx-small groove" in promotion of TM-TM interactions.     

Processing of Escherichia coli alkaline phosphatase. Sequence requirements and possible conformations of the -6 to -4 region of the signal peptide

Analysis of the precursors of bacterial exported proteins revealed that those having bulky hydrophobic residues at position -5 have a high incidence of Pro residues at positions -6 and -4, Val at position -3, and Ser at positions -4 and -2. This led to a hypothesis that the previously observed inhibition of processing by bulky residues at position -5 can be suppressed by introduction of Pro, Ser, or Val in the corresponding nearby positions. Subsequent mutational analysis of Escherichia coli alkaline phosphatase showed that, as it was predicted, Pro on either side of bulky hydrophobic -5 Leu, Ile, or Tyr completely restores efficiency of the maturation. Introduction of Val at position -3 also partially suppresses the inhibition imposed by -5 Leu, while a Ser residue at position -4 or -2 does not restore processing. In addition, effective maturation of a mutant with Pro residues at positions from -6 throughout -4 proved that polyproline conformation of this region is permissive for processing. To understand the effects of the mutations, we modeled a peptide substrate into the active site of the signal peptidase using the known position of the beta-lactam inhibitor. The inhibitory effect of the -5 residue and its suppression by either Pro -6 or Pro -4 can be explained if we assume that Pro-containing -6 to -4 regions adopt a polyproline conformation whereas the region without Pro residues has a beta-conformation. These results permit us to specify sequence requirements at -6, -5, and -4 positions for efficient processing and to improve the prediction of yet unknown cleavage sites.     

Immunosuppressive analogues of hexapeptide Tyr-Val-Pro-Leu-Phe-Pro, an immune system stimulant

It was found that substitution of Val2 and/or Leu4 residue in a hexapeptide Tyr-Val-Pro-Leu-Phe-Pro (I) transforms this peptide immunostimulant into analogues possessing the immunosuppressor activity--Tyr-Gly-Pro-Leu-Phe-Pro (II), Tyr-Val-Pro-Gly-Phe-Pro (III), and Tyr-Gly-Pro-Gly-Phe-Pro (IV). Biological effects of peptides I-IV were studied using PFC (plaque forming cell) test, GvH (graft vs host) reaction in mice, and ARFC (autologous rosette forming cell) test. The strongest immunosuppressor activity was observed for III--in this case the immunosuppressor effect was observed even in PFC test in vitro in which II and IV showed no such activity. These results suggest that simultaneous presence of both Val2 and Leu4 residues is necessary for the generation of immunostimulation. The CD study of I-IV in methanol solution suggests that the conformational preferences of II-IV change towards stabilization of the beta-turn structure, whereas in the case of I the gamma-turn on Leu4 and cis' orientation of the Pro3 carbonyl (distorted beta-turn of type I) was found as the preferred conformation. Competition in biological effects observed for I and III in PFC in vitro test suggests that these analogues may interact with the same cellular receptor. Drastic changes in the activity which accompany changes in the sequence are discussed in the terms of our stereochemical hypothesis.     

Solution conformation of a tetradecapeptide stabilized by two di‐n‐propyl glycine residues

The solution conformation of a designed tetradecapeptide Boc‐Val‐Ala‐Leu‐Dpg‐Val‐Ala‐Leu‐Val‐Ala‐Leu‐Dpg‐Val‐Ala‐Leu‐OMe (Dpg‐14) containing two di‐n‐propyl glycine (Dpg) residues has been investigated by ¹H NMR and circular dichroism in organic solvents. The peptide aggregates formed at a concentration of 3 mM in the apolar solvent CDCl₃ were broken by the addition of 12% v/v of the more polar solvent DMSO‐d₆. Successive N_iH N_i+1H NOEs observed over the entire length of the sequence in this solvent mixture together with the observation of several characteristic medium‐range NOEs support a major population of continuous helical conformations for Dpg‐14. Majority of the observed coupling constants ( ) also support ? values in the helical conformation. Circular dichroism spectra recorded in methanol and propan‐2‐ol give further support in favor of helical conformation for Dpg‐14 and the stability of the helix at higher temperature. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Packing and hydrophobicity effects on protein folding and stability: effects of beta-branched amino acids, valine and isoleucine, on the formation and stability of two-stranded alpha-helical coiled coils/leucine zippers.

The aim of this study was to examine the differences between hydrophobicity and packing effects in specifying the three-dimensional structure and stability of proteins when mutating hydrophobes in the hydrophobic core. In DNA-binding proteins (leucine zippers), Leu residues are conserved at positions "d," and beta-branched amino acids, Ile and Val, often occur at positions "a" in the hydrophobic core. In order to discern what effect this selective distribution of hydrophobes has on the formation and stability of two-stranded alpha-helical coiled coils/leucine zippers, three Val or three Ile residues were simultaneously substituted for Leu at either positions "a" (9, 16, and 23) or "d" (12, 19, and 26) in both chains of a model coiled coil. The stability of the resulting coiled coils was monitored by CD in the presence of Gdn.HCl. The results of the mutations of Ile to Val at either positions "a" or "d" in the reduced or oxidized coiled coils showed a significant hydrophobic effect with the additional methylene group in Ile stabilizing the coiled coil (delta delta G values range from 0.45 to 0.88 kcal/mol/mutation). The results of mutations of Leu to Ile or Val at positions "a" in the reduced or oxidized coiled coils showed a significant packing effect in stabilizing the coiled coil (delta delta G values range from 0.59 to 1.03 kcal/mol/mutation). Our results also indicate the subtle control hydrophobic packing can have not only on protein stability but on the conformation adopted by the amphipathic alpha-helices. These structural findings correlate with the observation that in DNA-binding proteins, the conserved Leu residues at positions "d" are generally less tolerant of amino acid substitutions than the hydrophobic residues at positions "a."     

Two parts of the T3S4 domain of the hook-length control protein FliK are essential for the substrate specificity switching of the flagellar type III export apparatus

The switch in export specificity of the type III flagellar protein export apparatus from rod/hook type to filament type is believed to occur upon completion of hook assembly by way of an interaction of the type III secretion substrate specificity switch (T3S4) domain of the hook-length control protein FliK, with the integral membrane export apparatus component FlhB. The T3S4 domain of FliK (FliKT3S4) consisting of amino acid residues 265-405 has an unstable and flexible conformation in its last 35 residues (FliKCT). To investigate the role of FliKT3S4 in substrate specificity switching, we studied the effect of deletions and point mutations within this domain and characterized suppressor mutations. Deletions of ten amino acid residues within the region of residues 301-350 and five amino acids of residues 401-405 abolished switching of export specificity. Site directed mutagenesis showed that highly conserved residues, Val302, Ile304, Leu335, Val401 and Ala405, are essential, and that the five C terminal residues (401-405) are restricted in conformation for the switching process. Suppressor mutant analysis of the fliK(S319Y) mutant, which produces extended hooks with filaments attached due to delayed switching, suggested that FliKT3S4 interacts with the C terminal half of the cytoplasmic domain of FlhB (FlhBC). We propose a two step binding model of FliKT3S4 and FlhBC, in which residues 301-350 of FliK bind to FlhBC upon hook assembly completion at about 55 nm, and then unfolded FliKCT binds to FlhBC to trigger the switch in substrate specificity.     

Investigations on unconventional hydrogen bonds in RNA binding proteins: the role of CH...O=C interactions

We have investigated the roles played by C-H...O=C interactions in RNA binding proteins. There was an average of 78 CH...O=C interactions per protein and also there was an average of one significant CH...O=C interactions for every 6 residues in the 59 RNA binding proteins studied. Main chain-Main chain (MM) CH...O=C interactions are the predominant type of interactions in RNA binding proteins. The donor atom contribution to CH...O=C interactions was mainly from aliphatic residues. The acceptor atom contribution for MM CH...O=C interactions was mainly from Val, Phe, Leu, Ile, Arg and Ala. The secondary structure preference analysis of CH...O=C interacting residues showed that, Arg, Gln, Glu and Tyr preferred to be in helix, while Ala, Asp, Cys, Gly, Ile, Leu, Lys, Met, Phe, Trp and Val preferred to be in strand conformation. Most of the CH...O=C interacting polar amino acid residues were solvent exposed while, majority of the CH...O=C interacting non polar residues were excluded from the solvent. Long and medium-range CH...O=C interactions are the predominant type of interactions in RNA binding proteins. More than 50% of CH...O=C interacting residues had a higher conservation score. Significant percentage of CH...O=C interacting residues had one or more stabilization centers. Sixty-six percent of the theoretically predicted stabilizing residues were also involved in CH...O=C interactions and hence these residues may also contribute additional stability to RNA binding proteins.     

Statistical analysis of amino acid patterns in transmembrane helices: the GxxxG motif occurs frequently and in association with beta-branched residues at neighboring positions

To find motifs that mediate helix-helix interactions in membrane proteins, we have analyzed frequently occurring combinations of residues in a database of transmembrane domains. Our analysis was performed with a novel formalism, which we call TMSTAT, for exactly calculating the expectancies of all pairs and triplets of residues in individual sequences, taking into account differential sequence composition and the substantial effect of finite length in short segments. We found that the number of significantly over and under-represented pairs and triplets was much greater than the random expectation. Isoleucine, glycine and valine were the most common residues in these extreme cases. The main theme observed is patterns of small residues (Gly, Ala and Ser) at i and i+4 found in association with large aliphatic residues (Ile, Val and Leu) at neighboring positions (i.e. i+/-1 and i+/-2). The most over-represented pair is formed by two glycine residues at i and i+4 (GxxxG, 31.6 % above expectation, p<1x10(-33)) and it is strongly associated with the neighboring beta-branched residues Ile and Val. In fact, the GxxxG pair has been described as part of the strong interaction motif in the glycophorin A transmembrane dimer, in which the pair is associated with two Val residues (GVxxGV). GxxxG is also the major motif identified using TOXCAT, an in vivo selection system for transmembrane oligomerization motifs. In conjunction with these experimental observations, our results highlight the importance of the GxxxG+beta-branched motif in transmembrane helix-helix interactions. In addition, the special role for the beta-branched residues Ile and Val suggested here is consistent with the hypothesis that residues with constrained rotameric freedom in helical conformation might reduce the entropic cost of folding in transmembrane proteins. Additional material is available at http://engelman.csb.yale. edu/tmstat and http://bioinfo.mbb.yale. edu/tmstat.     

Solution Structure of the N-terminal RNP Domain of U1A Protein: The Role of C-terminal Residues in Structure Stability and RNA Binding

The solution structure of a fragment of the human U1A spliceosomal protein containing residues 2 to 117 (U1A117) determined using multi-dimensional heteronuclear NMR is presented. The C-terminal region of the molecule is considerably more ordered in the free protein than thought previously and its conformation is different from that seen in the crystal structure of the complex with U1 RNA hairpin II. The residues between Asp90 and Lys98 form an α-helix that lies across the β-sheet, with residues Ile93, Ile94 and Met97 making contacts with Leu44, Phe56 and Ile58. This interaction prevents solvent exposure of hydrophobic residues on the surface of the β-sheet, thereby stabilising the protein. Upon RNA binding, helix C moves away from this position, changing its orientation by 135° to allow Tyr13, Phe56 and Gln54 to stack with bases of the RNA, and also allowing Leu44 to contact the RNA. The new position of helix C in the complex with RNA is stabilised by hydrophobic interactions from Ile93 and Ile94 to Ile58, Leu 41, Val62 and His10, as well as a hydrogen bond between Ser91 and Thr11. The movement of helix C mainly involves changes in the main-chain torsion angles of Thr89, Asp90 and Ser91, the helix thereby acting as a "lid" over the RNA binding surface.     

Specificity of memapsin 1 and its implications on the design of memapsin 2 (beta-secretase) inhibitor selectivity

Memapsin 1 is closely homologous to memapsin 2 (BACE), or beta-secretase, whose action on beta-amyloid precursor protein (APP) leads to the production of beta-amyloid (A beta) peptide and the progression of Alzheimer's disease. Memapsin 2 is a current target for the development of inhibitor drugs to treat Alzheimer's disease. Although memapsin 1 hydrolyzes the beta-secretase site of APP, it is not significantly present in the brain, and no direct evidence links it to Alzheimer's disease. We report here the residue specificity of eight memapsin 1 subsites. In substrate positions P(4), P(3), P(2), P(1), P(1)', P(2)', P(3)', and P(4)', the most preferred residues are Glu, Leu, Asn, Phe, Met, Ile, Phe, and Trp, respectively, while the second preferred residues are Gln, Ile, Asp, Leu, Leu, Val, Trp, and Phe, respectively. Other less preferred residues can also be accommodated in these subsites of memapsin 1. Despite the broad specificity, these residue preferences are strikingly similar to those of human memapsin 2 [Turner et al. (2001) Biochemistry 40, 10001-10006] and thus pose a serious problem to the design of differentially selective inhibitors capable of inhibiting memapsin 2. This difficulty was confirmed by the finding that several potent memapsin 2 inhibitors effectively inhibited memapsin 1 as well. Several possible approaches to overcome this problem are discussed.     

Exploring deltorphin II binding to the third extracellular loop of the delta-opioid receptor

The third extracellular loop of the human delta-opioid receptor (hDOR) is known to play an important role in the binding of delta-selective ligands. In particular, mutation of three amino acids (Trp(284), Val(296), and Val(297)) to alanine significantly diminished delta-opioid receptor affinity for delta-selective ligands. To assess the changes in conformation accompanying binding of the endogenous opioid peptide deltorphin II to the delta-opioid receptor at both the receptor and ligand levels as well as to determine points of contact between the two, an in-depth spectroscopic study that addressed these points was initiated. Fragments of the delta-opioid receptor of variable length and containing residues in the third extracellular loop were synthesized and studied by NMR and CD spectroscopy in a membrane-mimetic milieu. The receptor peptides examined included hDOR-(279-299), hDOR-(283-299), hDOR-(281-297), and hDOR-(283-297). A helical conformation was observed for the longest receptor fragment between Val(283) and Arg(291), whereas a nascent helix occurred in a similar region for hDOR-(281-297). Further removal of N-terminal residues Val(281) and Ile(282) abolished helical conformation completely. Binding of the delta-selective ligand deltorphin II to hDOR-(279-299) destabilized the helix at the receptor peptide N terminus. Dramatic changes in the alpha-proton chemical shifts for Trp(284) and Leu(286) in hDOR-(279-299) also accompanied this loss of helical conformation. Large upfield displacement of alpha-proton chemical shifts was observed for Leu(295), Val(296), and Val(297) in hDOR-(279-299) following its interaction with deltorphin II, thus identifying a gain in beta-conformation at the receptor peptide C terminus. Similar changes did not occur for the shorter peptide hDOR(281-297). A hypothesis describing the conformational events accompanying selective deltorphin II binding to the delta-opioid receptor is presented.     

NMR conformational analysis of proadrenomedullin N-terminal 20 peptide, a proangiogenic factor involved in tumor growth

The preferred conformation of Proadrenomedullin N-Terminal 20 Peptide (PAMP; ARLDVASEFRKKWNKWALSR-amide) has been determined using 1H and 13C two-dimensional nuclear magnetic resonance (NMR) spectroscopy and molecular modeling. PAMP is a peptide that has various physiological functions, including its role as a proangiogenic factor in facilitating tumor growth and its inhibitory effect on catecholamine secretion at nicotinic receptors. The preferred conformation of PAMP was determined in a helix-inducing trifluoroethanol and water (TFE/H2O) solution, and in a membrane-mimetic sodium dodecylsulfate-d25 (SDS) micellar solution. The secondary structure consists of an alpha-helix for residues Arg2 to Arg20 in TFE/H2O solution and an alpha-helix for residues Arg2 to Ala17 in SDS solution. We postulate that the polar charged residues Arg2, Lys12, and Arg20 are responsible for the initial interaction of the peptide with the micelle, and that this is followed by the binding of the hydrophobic residues Leu3, Val5, Phe9, Trp13, and Trp16 to the micellar core. The three C-terminal amino acid residues adopt an extended structure in SDS, suggesting that they are important in receptor recognition and binding. This is supported by truncation studies done by Mahata et al. (Hypertension, 1998, Vol. 32, pp. 907-916), which show the importance of the C-terminal in physiological activity. Furthermore, Belloni et al. (Hypertension, 1999, Vol. 33, pp. 1185-1189), and Martinez et al. (Cancer Research, 2004, Vol. 64, pp. 6489-6494) suggested that the N-terminal was also important in PAMP activity. However, no differences in conformational preference of the N-terminal were observed between the two solvent systems.     

Conformational modification of the PRP-hexapeptide by a direct covalent attachment of aromatic side chain groups

PRP-hexapeptide possessing the azo-bridge between Tyr1 and Phe5 residues, called azo-PRP-hexapeptide: (formula; see text), was synthesized and tested for immunoregulatory activity. High biological activity of the synthesized azo-PRP-hexapeptide suggests that the biologically active conformation of PRP-hexapeptide must be such that both aromatic rings (Tyr and Phe) are apparently close to each other.     

The steady-state kinetics of the enzyme reaction tested by site-directed mutagenesis of hydrophobic residues (Val, Leu, and Cys) in the C-terminal alpha-helix of human adenylate kinase

To elucidate whether the C-terminal region in human adenylate kinase participates in the interaction with the substrate (MgATP(2-) and/or AMP(2-)), hydrophobic residues (Val182, Val186, Cys187, Leu190, and Leu193) were substituted by site-directed mutagenesis and the steady-state kinetics of fifteen mutants were analyzed. A change in the hydrophobic residues in the C-terminal domain affects the affinity for substrates (K(m)), that is, not only for MgATP(2-) but also for AMP(2-), and the catalytic efficiency (k(cat)). The results obtained have led to the following conclusions: (i) Val182 may interact with both MgATP(2-) and AMP(2-) substrates, but to a greater extent with MgATP(2-), and play a role in catalysis. (ii) Val186 appears to play a functional role in catalysis by interacting with both MgATP(2-) and AMP(2-) to nearly the same extent. (iii) Cys187 appears to play a functional role in catalysis. (iv) Leu190 appears to interact with both MgATP(2-) and AMP(2-) substrates but to a greater extent with AMP(2-). (v) Leu193 appears to interact with both MgATP(2-) and AMP(2-) but to a greater extent with AMP(2-). The activity of all mutants decreased due to the change in substrate-affinity. The closer the residue is located to the C-terminal end, the more its mutation affects not only MgATP(2-) but also AMP(2-) substrate binding. The hydrophobic alterations disrupt hydrophobic interactions with substrates and that might destabilize the conformation of the active site. The more C-terminal part of the alpha-helix appears to interact with AMP, as if it has swung out and rotated to cover the adenine moieties. The C-terminal alpha-helix of human adenylate kinase appears to be essential for the interaction with adenine substrates by swinging out during catalysis.     

Factorizing the role of a critical leucine residue in the binding of substrate to human 20α-hydroxysteroid dehydrogenase (AKR1C1): Molecular modeling and kinetic studies of the Leu308Val mutant enzyme

A comparison of the structures and kinetic properties of human 20α-hydroxysteroid dehydrogenase (AKR1C1) and its mutant enzymes (Leu308Val and Leu308Ala) indicates that Leu308 is a selectivity determinant for substrate binding. While the Leu308Val mutation improved the catalytic efficiency (k_cat/K_m) of AKR1C1 towards the two substrates 5α-pregnane-3α,20α-diol (PregA) and 5β-pregnan-3α-ol-20-one (PregB), the Leu308Ala mutation rendered the enzyme inactive. In the docked model of PregA the conformation of the steroid molecule was similar to that of 20α-hydroxyprogesterone in the crystal structure of the AKR1C1 complex where the steroid did not interact with the catalytic residues Tyr55 and His117. In the case of PregB the steroid interacted with the catalytic residue His117 and formed close contacts with Leu308, suggesting that the binding mechanism of 3α-hydroxysteroids in the active site of AKR1C1 is different from that of 20α-hydroxysteroids.     

Lysine 5 and phenylalanine 9 of the factor IX omega-loop interact with phosphatidylserine in a membrane-mimetic environment

The binding of factor IX to cell membranes requires a structured N-terminal omega-loop conformation that exposes hydrophobic residues for a highly regulated interaction with a phospholipid. We hypothesized that a peptide comprised of amino acids Gly4-Gln11 of factor IX (fIX(G4)(-)(Q11)) and constrained by an engineered disulfide bond would assume the native factor IX omega-loop conformation in the absence of Ca(2+). The small size and freedom from aggregation-inducing calcium interactions would make fIX(G4)(-)(Q11) suitable for structural studies for eliciting details about phospholipid interactions. fIX(G4)(-)(Q11) competes with factor IXa for binding sites on phosphatidylserine-containing membranes with a K(i) of 11 microM and inhibits the activation of factor X by the factor VIIIa-IXa complex with a K(i) of 285 microM. The NMR structure of fIX(G4)(-)(Q11) reveals an omega-loop backbone fold and side chain orientation similar to those found in the calcium-bound factor IX Gla domain, FIX(1-47)-Ca(2+). Dicaproylphosphatidylserine (C(6)PS) induces HN, Halpha backbone, and Hbeta chemical shift perturbations at residues Lys5, Leu6, Phe9, and Val10 of fIX(G4)(-)(Q11), while selectively protecting the NHzeta side chain resonance of Lys5 from solvent exchange. NOEs between the aromatic ring protons of Phe9 and specific acyl chain protons of C(6)PS indicate that these phosphatidylserine protons reside 3-6 A from Phe9. Stabilization of the phosphoserine headgroup and glycerol backbone of C(6)PS identifies that phosphatidylserine is in a protected environment that is spatially juxtaposed with fIX(G4)(-)(Q11). Together, these data demonstrate that Lys5, Leu6, Phe9, and Val10 preferentially interact with C(6)PS and allow us to correlate known hemophilia B mutations of factor IX at Lys5 or Phe9 with impaired phosphatidylserine interaction.     

Substrate specificity of cucumisin on synthetic peptides

The substrate specificity of cucumisin [EC 3.4.21.25] was identified by the use of the synthetic peptide substrates Leu(m)-Pro-Glu-Ala-Leu(n) (m = 0-4, n = 0-3). Neither Pro-Glu-Ala-Leu (m = 0) nor Leu-Pro-Glu-Ala (n = 0) was cleaved by cucumisin, however other analogus peptides were cleaved between Glu-Ala. The hydrolysis rates of Leu(m)-Pro-Glu-Ala-Leu increased with the increase of m = 1 to 2 and 3, but was however, essentially same with the increase of m = 3 to 4. Similarly, the hydrolysis rates of Leu-Leu-Pro-Glu-Ala-Leu(n) increased with the increase of n = 0 to 1 and 2, but was essentially same with the increase of n = 2 to 3. Then, it was concluded that cucumisin has a S5-S3' subsite length. In order to identify the substrate specificity at P1 position, Leu-Leu-Pro-X-Ala-Leu (X; Gly, Ala, Val, Leu, Ile, Pro, Asp, Glu, Lys, Arg, Asn, Gln, Phe, Tyr, Ser, Thr, Met, Trp, His) were synthesized and digested by cucumisin. Cucumisin showed broad specificity at the P1 position. However, cucumisin did not cleave the C-terminal side of Gly, Ile, Pro, and preferred Leu, Asn, Gln, Thr, and Met, especially Met. Moreover, the substrates, Leu-Leu-Pro-Glu-Y-Leu (Y; Gly, Ala, Ser, Leu, Val, Glu, Lys, Phe) were synthesized and digested by cucumisin. Cucumisin did not cleave the N-terminal side of Val but preferred Gly, Ser, Ala, and Lys especially Ser. The specificity of cucumisin for naturally occurring peptides does not agree strictly with the specificity obtained by synthetic peptides at the P1 or P1' position alone, but it becomes clear that the most of the cleavage sites on naturally occurring peptides by cucumisin contain suitable amino acid residues at P1 and (or) P1' positions. Moreover, cucumisin prefers Pro than Leu at P2 position, indicating that the specificity at P2 position differs from that of papain.     

Sequence and structural features of binding site residues in protein-protein complexes: comparison with protein-nucleic acid complexes

Background

Protein-protein interactions are important for several cellular processes. Understanding the mechanism of protein-protein recognition and predicting the binding sites in protein-protein complexes are long standing goals in molecular and computational biology.

Methods

We have developed an energy based approach for identifying the binding site residues in protein–protein complexes. The binding site residues have been analyzed with sequence and structure based parameters such as binding propensity, neighboring residues in the vicinity of binding sites, conservation score and conformational switching.

Results

We observed that the binding propensities of amino acid residues are specific for protein-protein complexes. Further, typical dipeptides and tripeptides showed high preference for binding, which is unique to protein-protein complexes. Most of the binding site residues are highly conserved among homologous sequences. Our analysis showed that 7% of residues changed their conformations upon protein-protein complex formation and it is 9.2% and 6.6% in the binding and non-binding sites, respectively. Specifically, the residues Glu, Lys, Leu and Ser changed their conformation from coil to helix/strand and from helix to coil/strand. Leu, Ser, Thr and Val prefer to change their conformation from strand to coil/helix.

Conclusions

The results obtained in this study will be helpful for understanding and predicting the binding sites in protein-protein complexes.

     

Redesign of artificial globins: effects of residue replacements at hydrophobic sites on the structural properties

Artificial sequences of the 153 amino acids have been designed to fit the main-chain framework of the sperm whale myoglobin (Mb) structure based on a knowledge-based 3D-1D compatibility method. The previously designed artificial globin (DG1) folded into a monomeric, compact, highly helical and globular form with overall dimensions similar to those of the target structure, but it lacked structural uniqueness at the side-chain level [Isogai, Y., Ota, M., Fujisawa, T. , Izuno, H., Mukai, M., Nakamura, H., Iizuka, T., and Nishikawa, K. (1999) Biochemistry 38, 7431-7443]. In this study, we redesigned hydrophobic sites of DG1 to improve the structural specificity. Several Leu and Met residues in DG1 were replaced with beta-branched amino acids, Ile and Val, referring to the 3D profile of DG1 to produce three redesigned globins, DG2-4. These residue replacements resulted in no significant changes of their compactness and alpha-helical contents in the absence of denaturant, whereas they significantly affected the dependence of the secondary structure on the concentration of guanidine hydrochloride. The analyses of the denaturation curves revealed higher global stabilities of the designed globins than that of natural apoMb. Among DG1-4, DG3, in which 11 Leu residues of DG1 are replaced with seven Ile and four Val residues, and one Met residue is replaced with Val, displayed the lowest stability but the most cooperative folding-unfolding transition and the most dispersed NMR spectrum with the smallest line width. The present results indicate that the replacements of Leu (Met) with the beta-branched amino acids at appropriate sites reduce the freedom of side-chain conformation and improve the structural specificity at the expense of stability.     

Melain G, a cysteine protease from green fruits of the bead tree, Melia azedarach: a protease affected by specific amino acids at P3 position

A protease (melain G) was isolated from the greenish fruits of the bead tree, Melia azedarach var. japonica Makino. Melain G shares 110 identical amino acid residues (50%) with papain, 112 (51%) with actinidain, and 91 (41%) with stem bromelain. From the sites cleaved in the oxidized insulin B-chain and synthetic oligopeptide substrates by melain G, the enzyme preferred small amino acid residues such as Gly or Ser at the P2 position and negatively charged residues such as glutamic or cysteic acid at the P3 position. This is clearly different from the specificity of papain, which prefers the large hydrophobic amino acid residues such as Phe, Val, and Leu at the P2 position. Accordingly, it is presumed that the bottom of the S2 pocket of melain G is shallow due to the presence of a Phe residue, and a bulky P2 substrate (for example Phe residue) is not preferred by the enzyme. Negatively charged residues at the P3 position of substrates well suited the S3 site of melain G for making a salt bridge. It is likely that Arg61 is the S3 position of melain G by analogy with papain.