Identification, synthesis and bioassay for the metabolites of P6A

The metabolites Ala-Arg-Pro-Ala-OH, Ala-Arg-Pro-OH, Arg-Pro-Ala-Lys-OH and Pro-Ala-Lys-OH were identified by HPLC/ESI/MS from the in vivo blood of Ala-Arg-Pro-Ala-Lys-OH (P6A) received mice. The in vitro incubation of P6A in the blood of mice the same metabolites were also found by use of the Prep LC System. The protective intermediates of these metabolites were prepared via the solution method using the stepwise synthesis in 77.4, 90, 88, and 80% yield, respectively. After deprotection with catalytic hydrogenation the intermediates were converted into the corresponding sequences Arg-Pro-Ala-Lys-OH, Pro-Ala-Lys-OH, Ala-Arg-Pro-Ala-OH, and Ala-Arg-Pro-OH in 90, 95, 85% and 86% yield, respectively. In the thrombolysis in vivo assay the synthetic Ala-Arg-Pro-Ala-OH, and Ala-Arg-Pro-OH exhibited no activity. On the other hand the thrombolytic activity of Arg-Pro-Ala-Lys-OH was comparable to P6A, and an enhanced thrombolytic activity was observed for Pro-Ala-Lys-OH. In the in vitro fibrinolytic lysis tests the approximate results were obtained and an enhanced activity was also observed for Pro-Ala-Lys-OH. In the euglobulin clot lysis time tests P6A, Arg-Pro-Ala-Lys-OH and Pro-Ala-Lys-OH gave significantly shorter time than that given by UK, demonstrating their fast action.     

Reactivity of Lys(NH2)-containing peptides toward endopeptidases.

Lys(NH2)-containing peptides were subjected to various proteolytic enzymes which were selected for their well-documented specificity for arginyl and/or lysyl peptide bonds. Lys(NH2)-containing peptides were cleaved more rapidly by clostripain than the corresponding lysyl peptides. On the other hand, they proved to be resistant to Achromobacter protease I hydrolysis. The modified peptides synthesized in this study were more stable than the arginyl and lysyl analogues when incubated with trypsin or thrombin. The same tendency was observed when Lys(NH2)-containing peptides were incubated in diluted human serum, suggesting that the replacement of Arg or Lys by Lys(NH2) could be used to increase the stability of peptides in vivo.     

Investigating the cationic side chains of the antimicrobial peptide tritrpticin: hydrogen bonding properties govern its membrane-disruptive activities

The positively charged side chains of cationic antimicrobial peptides are generally thought to provide the initial long-range electrostatic attractive forces that guide them towards the negatively charged bacterial membranes. Peptide analogs were designed to examine the role of the four Arg side chains in the cathelicidin peptide tritrpticin (VRRFPWWWPFLRR). The analogs include several noncoded Arg and Lys derivatives that offer small variations in side chain length and methylation state. The peptides were tested for bactericidal and hemolytic activities, and their membrane insertion and permeabilization properties were characterized by leakage assays and fluorescence spectroscopy. A net charge of +5 for most of the analogs maintains their high antimicrobial activity and directs them towards preferential insertion into model bacterial membrane systems with a similar extent of burial of the Trp side chains. However the peptides exhibit significant functional differences. Analogs with methylated cationic side chains cause lower levels of membrane leakage and are associated with lower hemolytic activities, making them potentially attractive pharmaceutical candidates. Analogs containing the Arg guanidinium groups cause more membrane disruption than those containing the Lys amino groups. Peptides in the latter group with shorter side chains have increased membrane activity and conversely, elongating the Arg residue causes slightly higher membrane activity. Altogether, the potential for strong hydrogen bonding between the four positive Arg side chains with the phospholipid head groups seems to be a determinant for the membrane disruptive properties of tritrpticin and many related cationic antimicrobial peptides.     

Dissecting structural basis of the unique substrate selectivity of human enteropeptidase catalytic subunit

Enteropeptidase is a key enzyme in the digestion system of higher animals. It initiates enzymatic cascade cleaving trypsinogen activation peptide after a unique sequence DDDDK. Recently, we have found specific activity of human enteropeptidase catalytic subunit (L-HEP) being significantly higher than that of its bovine ortholog (L-BEP). Moreover, we have discovered that L-HEP hydrolyzed several nonspecific peptidic substrates. In this work, we aimed to further characterize species-specific enteropeptidase activities and to reveal their structural basis. First, we compared hydrolysis of peptides and proteins lacking DDDDK sequence by L-HEP and L-BEP. In each case human enzyme was more efficient, with the highest hydrolysis rate observed for substrates with a large hydrophobic residue in P2-position. Computer modeling suggested enzyme exosite residues 96 (Arg in L-HEP, Lys in L-BEP) and 219 (Lys in L-HEP, Gln in L-BEP) to be responsible for these differences in enteropeptidase catalytic activity. Indeed, human-to-bovine mutations Arg96Lys, Lys219Gln shifted catalytic properties of L-HEP toward those of L-BEP. This effect was amplified in case of the double mutation Arg96Lys/Lys219Gln, but still did not cover the full difference in catalytic activities of human and bovine enzymes. To find a missing link, we studied monopeptide benzyl-arginine-β-naphthylamide hydrolysis. L-HEP catalyzed it with an order lower K (m) than L-BEP, suggesting the monopeptide-binding S1 site input into catalytic distinction between two enteropeptidase species. Together, our findings suggest structural basis of the unique catalytic properties of human enteropeptidase and instigate further studies of its tentative physiological and pathological roles.     

Analysis of the Epitopes Recognized by Mouse Monoclonal Antibodies Directed to Yersinia enterocolitica Heat-Shock Protein 60

To determine amino acid sequences of the epitopes recognized by monoclonal antibodies (mAbs) 3C8 and 5C3 directed against Yersinia enterocolitica heat-shock protein (HSP60), a dot blot analysis was perfomed using synthesized peptides of Y. enterocolitica HSP60 such as peptides p316-342, p327-359, p340-366, p316-326, p316-321, p319-323, and p321-326 which represent positions of amino acids in Y. enterocolitica HSP60. The dot blot analysis revealed that 5C3 mAb reacted with p316-342, p316-326 and p321-326, and 3C8 mAb p316-342 and p316-326. These results indicate that the epitopes recognized by the mAbs were associated with eleven amino acids, Asp Leu Gly Gln Ala Lys Arg Val Val Ile Asn, of p316-326. The sequence homology between p316-326 of Y. enterocolitica HSP60 and the rest of the HSP60 family suggests that the five amino acids of Lys, Arg, Val, Ile and Asn, which are highly conserved in the HSP60 family, might be related with the epitope recognized by 3C8. In contrast, it was also demonstrated that three amino acids of Leu, Gly and Val, which are not well conserved in the HSP60 family, might be related to the epitope recognized by 5C3.     

Dissecting structural basis of the unique substrate selectivity of human enteropeptidase catalytic subunit

Enteropeptidase is a key enzyme in the digestion system of higher animals. It initiates enzymatic cascade cleaving trypsinogen activation peptide after a unique sequence DDDDK. Recently, we have found specific activity of human enteropeptidase catalytic subunit (L-HEP) being significantly higher than that of its bovine ortholog (L-BEP). Moreover, we have discovered that L-HEP hydrolyzed several nonspecific peptidic substrates. In this work, we aimed to further characterize species-specific enteropeptidase activities and to reveal their structural basis. First, we compared hydrolysis of peptides and proteins lacking DDDDK sequence by L-HEP and L-BEP. In each case human enzyme was more efficient, with the highest hydrolysis rate observed for substrates with a large hydrophobic residue in P2-position. Computer modeling suggested enzyme exosite residues 96 (Arg in L-HEP, Lys in L-BEP) and 219 (Lys in L-HEP, Gln in L-BEP) to be responsible for these differences in enteropeptidase catalytic activity. Indeed, human-to-bovine mutations Arg96Lys, Lys219Gln shifted catalytic properties of L-HEP toward those of L-BEP. This effect was amplified in case of the double mutation Arg96Lys/Lys219Gln, but still did not cover the full difference in catalytic activities of human and bovine enzymes. To find a missing link, we studied monopeptide benzyl-arginine-β-naphthylamide hydrolysis. L-HEP catalyzed it with an order lower K _m than L-BEP, suggesting the monopeptide-binding S1 site input into catalytic distinction between two enteropeptidase species. Together, our findings suggest structural basis of the unique catalytic properties of human enteropeptidase and instigate further studies of its tentative physiological and pathological roles.     

A putative prohormone processing protease in bovine adrenal medulla specifically cleaving in between Lys-Arg sequences

Paired basic residues, particularly Lys-Arg, are known as a typical site for proteolytic processing of prohormones. In this study, we confirmed the presence of a novel protease exhibiting substrate specificity toward Lys-Arg sequence. It was partially purified from the soluble fraction of bovine adrenomedullary chromaffin granules by using an affinity chromatography on soybean trypsin inhibitor-Sepharose. The enzyme, with optimal pH around 7.5-9.5, is classified into a serine-protease family by its inhibition spectrum. The enzyme specifically cleaves in between the Lys-Arg bonds of the peptides related to proenkephalins, but the sequences of Arg-Arg, Arg-Lys and a single basic residue (Arg or Lys) in the substrates are not affected by the enzyme. The unique substrate specificity of the enzyme suggests that it is distinct from pancreatic trypsin and may be physiologically involved in proenkephalin processing.     

Inhibition of fibronectin binding to platelets by proteolytic fragments and synthetic peptides which support fibroblast adhesion

To define regions within fibronectin (Fn) recognized by platelet binding sites, inhibition of Fn binding by an Fn fragment and synthetic peptides has been analyzed. A highly purified 120-kDa chymotryptic fragment, which has cell attachment activity but did not bind to insolubilized heparin or gelatin, inhibited Fn binding to platelets with an ID50 approximately 3 microM. Previous work indicates that fibroblasts attach to an 11.5-kDa subfragment of this 120-kDa fragment, and that one of four 30-residue synthetic peptides containing sequences from this region supports cell attachment. Only the peptide containing the COOH terminus of the 11.5-kDa fragment inhibited Fn binding to platelets, with an ID50 approximately 10 microM and is the peptide which supports fibroblast attachment. Of the smaller peptides studied from this sequence, all peptides containing the Arg-Gly-Asp-Ser sequence, including the tetrapeptide itself, were active in inhibiting Fn binding to platelets (ID50 values approximately 10-20 microM). The same peptides support fibroblast attachment. Those which lacked this sequence including Gly-Asp-Ser-Pro and Thr-Gly-Arg-Gly (immediately adjacent tetrapeptides) lacked both activities. Further evidence for specificity of inhibition was provided by structurally modified peptides in which substitution of a Glu for Asp abolished inhibitory activity and substitution of Lys for Arg or Ala for Gly reduced activity 6- and 8-fold, respectively. In addition, Arg-Gly-Asp-Ser-containing peptides inhibited the rate and extent of thrombin-induced platelet aggregation. These data suggest that the Arg-Gly-Asp-Ser tetrapeptide contains a recognition specificity involved in the binding of Fn to platelets and that platelets share features of this recognition specificity with fibroblasts.     

Mannan-binding lectin-associated serine protease 3 cleaves synthetic peptides and insulin-like growth factor-binding protein 5

Mannan-binding lectin-associated serine proteases (MASPs) are secreted as single-chain precursors and processed into two disulfide bond-linked chains. MASP-3 and MASP-1, derived from the same gene, contain identical A chains, but entirely different catalytic domain-containing B chains. In contrast to MASP-1 and MASP-2, the proteinase activity of MASP-3 has not been described previously. We show here the proteolytic activity of the purified recombinant human MASP-3 catalytic domain toward peptides and protein substrates. Among the fluorogenic peptides tested, it specifically cleaved peptides with Arg at the P1 position. Among seven insulin-like growth factor-binding proteins, it selectively cleaved IGFBP-5, which is the first protein substrate identified for MASP-3. All three cleavage sites identified contained Arg or Lys at the P1 position and Pro at the P2 position. As compared to MASP-1 and MASP-2, MASP-3 has distinct substrate specificity and inhibitor profile. These results should be useful for further studies of the structure and function of human MASP-3.     

Evidence that endogenous 6-(ARG or LYS)-opioid peptides can interact with kappa-receptors as agonists

Evidence is provided for the abilities of endogenous 6-(Arg or Lys)-opioid peptides to interact with kappa-receptors as agonists. Dynorphin-(1-17) and -(1-8), alpha- and beta-neo-endorphin, [Met5]-enkephalin-Arg6-Phe7 and des acetyl salmon endorphin I significantly inhibited the electrically-evoked contractions of rabbit vas deferens which had been shown to contain kappa-receptors exclusively, indicating that endogenous 6-(Arg or Lys)-opioid peptides could act on kappa-receptors as agonists. Additionally, the inhibition of contractions of rabbit vas deferens by 6-(Arg or Lys)-opioid peptides was antagonized more effectively by Mr 2266 which had a high affinity to both mu- and kappa-receptors, than naloxone which had a high affinity only to mu-receptors. This also suggested that 6-(Arg or Lys)-opioid peptides acted as kappa-receptor agonists. The rank order of the inhibitory potency of 6-(Arg or Lys)-opioid peptides against contractions of rabbit vas deferens was as follows: dynorphin-(1-17) greater than alpha-neo-endorphin greater than beta-neo-endorphin .=. dynorphin-(1-8) greater than des acetyl salmon endorphin I greater than [Met5]-enkephalin-Arg6-Phe7. Since other endogenous opioid peptides such as [Met5]- and [Leu5]-enkephalin and beta-endorphin have been shown not to act on kappa-receptors as agonist, data in the present study suggest that endogenous opioid peptides can be classified into two groups in terms of an ability to interact with kappa-receptors as an agonist.     

Effect of His-Gly-Lys motif derived from domain 5 of high molecular weight kininogen on suppression of cancer metastasis both in vitro and in vivo

We have demonstrated previously that kinin-free high molecular weight kininogen, its domain 5 (D5H, Gly402-Lys502), and peptides derived from D5H inhibited vitronectin-mediated migration and invasion of cancer cells in vitro (Kamiyama, F., Maeda, T., Yamane, T., Li, Y. H., Ogikubo, O., Otsuka, T., and Ohkubo, I. (2001) Biochem. Biophys. Res. Commun. 288, 975-980). In this study, we found that the amino acid sequence His-Gly-Lys (HGK) in D5H is the core motif for inhibition of adhesion and invasion of MDA-MB-231 cells in vitro. P-5m (484GHGKHKNK491, Gly484-Lys491), an octapeptide including the HGK motif derived from D5H, and HGK, a tripeptide, inhibited both cell adhesion and invasion in vitro. However, an octapeptide designated P-5m (K487R), in which Lys487 was changed to Arg, did not inhibit either cell adhesion or invasion, and peptides HGR and HGG also had no inhibitory effect. Recombinant GST-D5H expressed in Escherichia coli had a stronger inhibitory effect on cell adhesion and invasion in vitro than did GST-D5H (K487R) in which Lys487 was changed to Arg. Furthermore, P-5m (Gly484-Lys491) peptide clearly suppressed lung metastasis in mice experimentally induced by using B16-F10 cells, but P-5m (G487R) had no effect. These data strongly indicate that both the HGK motif and lysine residue (Lys487) play essential roles in inhibition of cell adhesion and invasion in vitro and in prevention of metastasis of cancer cells in vivo. We tried to identify the HGK motif binding protein on the surface of cancer cells. A 95-kDa surface biotin-labeled membrane protein was specifically detached from GST-D5H by P-5 (His479-Lys493) peptide but not by P-1 (Gly402-Lys420) peptide originating from the N-terminal region of D5H.     

Contribution of basic residues of the autolysis loop to the substrate and inhibitor specificity of factor IXa

The autolysis loop (residues 143-154 in chymotrypsinogen numbering) plays a pivotal role in determining the macromolecular substrate and inhibitor specificity of coagulation proteases. This loop in factor IXa (FIXa) has 3 basic residues (Arg143, Lys147, and Arg150) whose contribution to the protease specificity of factor IXa has not been studied. Here, we substituted these residues individually with Ala in Gla-domainless forms of recombinant factor IX expressed in mammalian cells. All mutants exhibited normal amidolytic activities toward a FIXa-specific chromogenic substrate. However, Arg143 and Lys147 mutants showed a approximately 3- to 6-fold impairment in FX activation, whereas the Arg150 mutant activated factor X normally both in the absence and presence of factor VIIIa. By contrast, Arg143 and Lys147 mutants reacted normally with antithrombin (AT) in both the absence and presence of the cofactor, heparin. However, the reactivity of the Arg150 mutant with AT was impaired 6.6-fold in the absence of heparin and 33- to 70-fold in the presence of pentasaccharide and full-length heparins. These results suggest that Arg143 and Lys147 of the autolysis loop are recognition sites for FX independent of factor VIIIa, and Arg150 is a specific recognition site for AT that can effectively interact with AT only if the serpin is in the heparin-activated conformation.     

Toward understanding the cationicity of defensins. Arg and Lys versus their noncoded analogs

Human defensins are a family of small antimicrobial proteins found predominantly in leukocytes and epithelial cells that play important roles in the innate and adaptive immune defense against microbial infection. The most distinct molecular feature of defensins is cationicity, manifested by abundant Arg and/or Lys residues in their sequences. Sequence analysis indicates that Arg is strongly selected over Lys in alpha-defensins but not in beta-defensins. To understand this Arg/Lys disparity in defensins, we chemically synthesized human alpha-defensin 1 (HNP1) and several HNP1 analogs where three Arg residues were replaced by each of the following six alpha-amino acids: Lys, ornithine (Orn), diaminobutyric acid (Dab), diaminopropionic acid (Dap), N,N-dimethyl-Lys ((diMe)Lys), and homo-Arg ((homo)Arg). In addition, we prepared human beta-defensin 1 (hBD1) and (Lys-->Arg)hBD1 in which all four Lys residues were substituted for Arg. Bactericidal activity assays revealed the following. 1) Arg-containing HNP1 and (Lys-->Arg)hBD1 are functionally better than Lys-HNP1 and hBD1, respectively; the difference between Arg and Lys is more evident in the alpha-defensin than in the beta-defensin and is more evident at low salt concentrations than at high salt concentrations. 2) For HNP1, the Arg/Lys disparity is much more pronounced with Staphylococcus aureus than with Escherichia coli, and the Arg-rich HNP1 kills bacteria faster than its Lys-rich analog. 3) Arg and Lys appear to have optimal chain lengths for bacterial killing as shortening Lys or lengthening Arg in HNP1 invariably becomes functionally deleterious. Our findings provide insights into the Arg/Lys disparity in defensins, and shed light on the cationicity of defensins with respect to their antimicrobial activity and specificity.     

Mutational analysis of the human immunodeficiency virus type 1 env gene product proteolytic cleavage site.

The structural requirements for proteolytic cleavage of the human immunodeficiency virus type 1 env gene product, gp160, to gp120 and gp41 have been assessed by specific mutagenesis of the sequence Lys Ala Lys Arg Arg Val Val Glu Arg Glu Lys Arg located between amino acids 500 and 511, i.e., at the putative C terminus of gp120. The basic amino acids underlined have been mutated, individually and in combination, to neutral amino acids, and the cleavability of the mutated env gene products was examined after expression in CV-1 cells. The results show that the replacement of Arg-511 (cleavage presumably occurs C terminal to this amino acid) with Ser completely abolishes recognition and cleavage by the cellular protease(s), i.e., the remaining basic amino acids in the vicinity do not serve as alternative substrates. However, Arg-508 and Lys-510 are important features of the recognition site since, when they are individually changed to neutral amino acids, cleavage is severely impaired. The basic amino acids 500, 502, and 504 are, individually, not important for cleavage, since their individual replacement by neutral amino acids does not impair cleavage. However, when all four basic amino acids 500, 502, 503, and 504 are changed to neutral amino acids, cleavage is almost completely abolished. This shows that the sequence Arg Glu Lys Arg at the cleavage site is alone not sufficient for cleavage but that a contribution of other amino acids is required, whether the other amino acids provide a basic character or a certain structure in the vicinity of the cleavage site. When noncleavable or poorly cleavable mutant env genes are expressed from the infectious plasmid pNL4-3 in CD4+ human lymphoblastoid cells, noninfectious virus, incapable of spread throughout the culture, is produced.     

Internalisation and degradation of histatin 5 by Candida albicans

Histatins, salivary antimicrobial peptides, are susceptible to proteolytic degradation, often ascribed to host proteinases. In this study, we addressed the question whether proteolytic activity from microbial sources can contribute to this degradation. Candida albicans, an opportunistic yeast that is susceptible to the histatins, was used as target organism. The most potent histatin (histatin 5: sequence: DSHAKRHHGYKRKFHEKHHSHRGY), two histatin 5 fragments (dh-5: sequence: KRKFHEKHHSHRGY; P-113: sequence: AKRHHGYKRKFH) and an all-D isomer of the latter (P-113D) were used as model peptides. All L-peptides were susceptible to degradation by C. albicans. Cleavage was established at Lys5 and His19 of histatin 5, Lys11, Arg12, Phe14, Glu16, Lys17, His18 and Ser20 of dh-5 and Ala4 and Lys11 of P-113. In addition, it was found that secreted C. albicans enzymes are not involved in the degradation process and that blocking cell entry of the peptides greatly impedes degradation. Moreover, P-113D, which is biologically as active as P-113, was hardly susceptible to proteolysis. These data imply that proteolysis occurs mainly intracellularly and is not used as a protective mechanism against histatin activity. Together, our results suggest that, besides host proteinases, microbial enzymes play an important role in histatin degradation.     

An analysis of the substrate specificity of insulin-stimulated protein kinase-1, a mammalian homologue of S6 kinase-II

The specificity determinants for insulin-stimulated protein kinase-I (ISPK-1) have been investigated with synthetic peptides based on naturally-occurring protein phosphoacceptor sequences. Peptides (Arg-Arg-Xaa-Ser-Xaa) that fulfill the consensus sequence for cyclic-AMP-dependent protein kinase (PK-A) are also phosphorylated readily by ISPK-1. The phosphorylation efficiency is improved by increasing the number of N-terminal arginine residues and by moving the arginyl cluster one residue further away from the serine, the nonapeptide (Arg)₄-Ala-Ala-Ser-Val-Ala being the best substrate among all the short peptides tested (K_m = 15 μM). Conversely, the substitution of either Thr for Ser or Lys for Arg is detrimental. Likewise, two flanking Pro residues and an Arg immediately N-terminal to the Ser act as negative specificity determinants. While the specificity of ISPK-1 shows several similarities to that of PK-A, including an absolute requirement for basic residues on the N-terminal side of the target Ser, it differs in several other respects including (1), the detrimental effect of a Lys for Arg substitution which is still compatible with some phosphorylation by ISPK-1, but not PK-A; (2), the presence of C-terminal acidic residues which are tolerated very well by ISPK-1, but are detrimental to PK-A; (3), the effect of substituting Phe for Val in the peptide Arg-Arg-Ala-Ser-Val-Ala, which improves the efficiency of phosphorylation by PK-A (lowering the K_m 4-fold), but has no effect on phosphorylation by ISPK-1. These differences in peptide substrate specificity may account in part for the different rates of phosphorylation of physiological substrates for ISPK-1 and PK-A, such as the G subunit of protein phosphatase-1.     

A unique sequence of the laminin alpha 3 G domain binds to heparin and promotes cell adhesion through syndecan-2 and -4

Laminin-5, consisting of the alpha 3, beta 3, and gamma 2 chains, is localized in the skin basement membrane and supports the structural stability of the epidermo-dermal linkage and regulates various cellular functions. The alpha chains of laminins have been shown to have various biological activities. In this study, we identified a sequence of the alpha 3 chain C-terminal globular domain (LG1-LG5 modules) required for both heparin binding and cell adhesion using recombinant proteins and synthetic peptides. We found that the LG3 and LG4 modules have activity for heparin binding and that LG4 has activity for cell adhesion. Studies with synthetic peptides delineated the A3G75aR sequence (NSFMALYLSKGR, residues 1412--1423) within LG4 as a major site for both heparin and cell binding. Substitution mutations in LG4 and A3G75aR identified the Lys and Arg of the A3G75aR sequence as critical for these activities. Cell adhesion to LG4 and A3G75aR was inhibited by heparitinase I treatment of cells, suggesting that cell binding to the A3G75aR site was mediated by cell surface heparan sulfate proteoglycans. We showed by affinity chromatography that syndecan-2 from fibroblasts bound to LG4. Solid-phase assays confirmed that syndecan-2 interacted with the A3G75aR peptide sequence. Stably transfected 293T cells with expression vectors for syndecan-2 and -4, but not glypican-1, specifically adhered to LG4 and A3G75aR. These results indicate that the A3G75aR sequence within the laminin alpha 3 LG4 module is responsible for cell adhesion and suggest that syndecan-2 and -4 mediate this activity.     

Isolation and partial characterization of three histone-specific acetyltransferases from Artemia

The specificity of the histone-H4-specific, protease-activated protein kinase (H4-PK) was examined using two series of synthetic peptides corresponding to the phosphorylation sites in histone H4 and pyruvate kinase. Optimum kinetic constants for phosphorylation were observed using the peptide Val-Lys-Arg-Ile-Ser-Gly-Leu. Peptides in which the Lys was replaced by Arg or the Lys-Arg sequence was transposed were phosphorylated with less favorable kinetics. Peptides with either basic residue deleted did not serve as substrates. Only the H4 peptide, containing an Arg-Arg sequence, was phosphorylated by the cyclic-AMP-dependent protein kinase (CA-PK). Distinct specificity determinants for H4-PK and CA-PK were also observed using the pyruvate kinase peptide (Leu-Arg-Arg-Ala-Ser-Leu-Gly). Collectively the data indicated that the primary substrate specificity determinants for H4-PK are Lys-Arg-Xaa-Ser whereas the CA-PK selectively phosphorylates the sequence Arg-Arg-Xaa-Ser.     

Long-range effects in protein--ligand interactions mediate peptide specificity in the human major histocompatibilty antigen HLA-B27 (B*2701).

B*2701 differs from all other HLA-B27 subtypes of known peptide specificity in that, among its natural peptide ligands, arginine is not the only allowed residue at peptide position 2. Indeed, B*2701 is unique in binding many peptides with Gln2 in vivo. However, the mutation (Asp74Tyr) responsible for altered selectivity is far away from the B pocket of the peptide binding site to which Gln/Arg2 binds. Here, we present a model that explains this effect. It is proposed that a new rotameric state of the conserved Lys70 is responsible for the unique B*2701 binding motif. This side chain should be either kept away from pocket B through its interaction with Asp74 in most HLA-B27 subtypes, or switched to this pocket if residue 74 is Tyr as in B*2701. Involvement of Lys70 in pocket B would thus allow binding of peptides with Gln2. Binding of Arg2-containing peptides to B*2701 is also possible because Lys70 could adopt another conformation, H-bonded to Asn97, which preserves the same binding mode of Arg2 as in B*2705. This model was experimentally validated by mutating Lys70 into Ala in B*2701. Edman sequencing of the B*2701(K70A) peptide pool showed only Arg2, characteristic of HLA-B27-bound peptides, and no evidence for Gln2. This supports the computational model and demonstrates that allowance of B*2701 for peptides with Gln2 is due to the long-range effect of the polymorphic residue 74 of HLA-B27, by inducing a conformational switch of the conserved Lys70.