Induction of vascular leakage through release of bradykinin and a novel kinin by cysteine proteinases from Staphylococcus aureus.

Staphylococcus aureus is a major pathogen of gram-positive septic shock and frequently is associated with consumption of plasma kininogen. We examined the vascular leakage (VL) activity of two cysteine proteinases that are secreted by S. aureus. Proteolytically active staphopain A (ScpA) induced VL in a bradykinin (BK) B(2)-receptor-dependent manner in guinea pig skin. This effect was augmented by staphopain B (SspB), which, by itself, had no VL activity. ScpA also produced VL activity from human plasma, apparently by acting directly on kininogens to release BK, which again was augmented significantly by SspB. Intravenous injection of ScpA into a guinea pig caused BK B(2)-receptor-dependent hypotension. ScpA and SspB together induced the release of leucyl-methionyl-lysyl-BK, a novel kinin with VL and blood pressure-lowering activities that are equivalent to BK. Collectively, these data suggest that production of BK and leucyl-methionyl-lysyl-BK by staphopains is a new mechanism of S. aureus virulence and bacterial shock. Therefore, staphopain-specific inhibitors and kinin-receptor antagonists could be used to treat this disease.

Maintenance of ribosomal protein S19 in plasma by complex formation with prothrombin.

We have demonstrated that the cross-linking of ribosomal protein S19 (RP S19) on platelets by activated factor XIII provides chemotactic potency to monocytes/macrophages for a resolution of coagulum. Factor XIII is activated by an active form of prothrombin, thrombin. We here report that RP S19 is present as a complex with prothrombin in the blood stream. Formation of this complex was blocked by a mutation of the glycosaminoglycan-binding basic cluster (Lys(23) -Lys(29) ) in RP S19. Prothrombin-RP S19 interaction was enhanced by an absence of Ca(2+) and the plasma RP S19 concentration was significantly low in the patient treated with warfarin, indicating participation of the γ-carboxyl glutamic acid domain of prothrombin making a salt bridge with the basic cluster. The complex formation likely explains why a protein as small as RP S19 can prevent from a filtering system of renal glomeruli at a steady state. The translocation of RP S19 from prothrombin to platelets during blood coagulation seems to be also advantageous for RP S19 from the perspective of oligomerisation by activated factor XIII, which should have been activated by thrombin.

Extensive expansion and diversification of the chemokine gene family in zebrafish: identification of a novel chemokine subfamily CX.

BACKGROUND: The chemokine family plays important roles in cell migration and activation. In humans, at least 44 members are known. Based on the arrangement of the four conserved cysteine residues, chemokines are now classified into four subfamilies, CXC, CC, XC and CX3C. Given that zebrafish is an important experimental model and teleost fishes constitute an evolutionarily diverse group that forms half the vertebrate species, it would be useful to compare the zebrafish chemokine system with those of mammals. Prior to this study, however, only incomplete lists of the zebrafish chemokine genes were reported. RESULTS: We systematically searched chemokine genes in the zebrafish genome and EST databases, and identified more than 100 chemokine genes. These genes were CXC, CC and XC subfamily members, while no CX3C gene was identified. We also searched chemokine genes in pufferfish fugu and Tetraodon, and found only 18 chemokine genes in each species. The majority of the identified chemokine genes are unique to zebrafish or teleost fishes. However, several groups of chemokines are moderately similar to human chemokines, and some chemokines are orthologous to human homeostatic chemokines CXCL12 and CXCL14. Zebrafish also possesses a novel species-specific subfamily consisting of five members, which we term the CX subfamily. The CX chemokines lack one of the two N-terminus conserved cysteine residues but retain the third and the fourth ones. (Note that the XC subfamily only retains the second and fourth of the signature cysteines residues.) Phylogenetic analysis and genome organization of the chemokine genes showed that successive tandem duplication events generated the CX genes from the CC subfamily. Recombinant CXL-chr24a, one of the CX subfamily members on chromosome 24, showed marked chemotactic activity for carp leukocytes. The mRNA was expressed mainly during a certain period of the embryogenesis, suggesting its role in the zebrafish development. CONCLUSION: The phylogenic and genomic organization analyses suggest that a substantial number of chemokine genes in zebrafish were generated by zebrafish-specific tandem duplication events. During such duplications, a novel chemokine subfamily termed CX was generated in zebrafish. Only two human chemokines CXCL12 and CXCL14 have the orthologous chemokines in zebrafish. The diversification observed in the numbers and sequences of chemokines in the fish may reflect the adaptation of the individual species to their respective biological environment.

Comparative DNA sequence analysis of mouse and human CC chemokine gene clusters.

The CC chemokines are a closely related subfamily of the chemokine superfamily. Most of the CC chemokine genes form a cluster on chromosome 11 in mice and chromosome 17 in humans. To date, 11 and 16 functional genes have been localized within the mouse and human clusters, respectively. Notably, some of the genes within these clusters appear to have no counterparts between the two species, and the orthologous relationships of some of the genes are difficult to establish solely on the basis of amino acid similarity. In this study, we have taken a comparative genomic approach to reveal some of the features that may be involved in the dynamic evolution of these gene clusters. We sequenced a 122-kb region containing five chemokine genes of the mouse CC cluster. This mouse sequence was combined with those determined by the Mouse Genome Sequencing Project, and the entire sequence of the mouse CC cluster was compared with that of the corresponding cluster in the human genome by percent identity plot and dot-plot analyses. Although no additional chemokine genes have been found in these clusters, our analysis has revealed that numerous gene rearrangements have occurred even after the diversification of rodents and primates, resulting in several species-specific chemokine genes and pseudogenes. In addition, phylogenetic analysis and comparison of the genomic sequences unambiguously identified the orthologous relationships of some of the chemokine genes in the mouse and human CC gene clusters.

Primary structures of guinea pig high- and low-molecular-weight kininogens.

Guinea pig high-molecular-weight and low-molecular-weight (HMW and LMW) kininogen cDNA were amplified from liver mRNA by RT-PCR. Their nucleotide sequences were analyzed and deduced to amino acid sequences. The HMW kininogen, composed of 607 amino acid residues with a 18-residue signal sequence, possessed the cysteine protease inhibitor domains I and II, the bradykinin domain, the histidine-rich region, and the prekallikrein-binding region. The amino acid sequence preceding the bradykinin domain was found not to be -Leu-Met-Lys- but -Leu-Thr-Arg-. Therefore, kallidin (Lys-bradykinin) and Met-kallidin are not liberated from the guinea pig kininogens. We purified the HMW kininogen protein from plasma and prepared the kinin-free form using guinea pig plasma kallikrein. Although the amino-terminal of the HMW kininogen was modified, the 25 amino-terminal residues of the light chain of the kinin-free kininogen corresponded to the deduced sequence just after the bradykinin moiety of the HMW kininogen. With regard to the LMW kininogen, the nucleotide sequence down to T(1200) as well as the amino acid sequence till Thr(382) was identical to that of the HMW kininogen. We also examined the localization of the guinea pig kininogen gene on the prometaphase lymphocyte chromosomes by fluorescence in situ hybridization method. Two pair signals were observed on a pair of homologous chromosomes, each of which is composed of two chromatids. Based on these findings, we concluded that HMW and LMW kininogens are produced from the single kininogen gene in guinea pig as in the cases of the other mammalian species reported so far.

Genome diversification mechanism of rodent and Lagomorpha chemokine genes.

Chemokines are a large family of small cytokines that are involved in host defence and body homeostasis through recruitment of cells expressing their receptors. Their genes are known to undergo rapid evolution. Therefore, the number and content of chemokine genes can be quite diverse among the different species, making the orthologous relationships often ambiguous even between closely related species. Given that rodents and rabbit are useful experimental models in medicine and drug development, we have deduced the chemokine genes from the genome sequences of several rodent species and rabbit and compared them with those of human and mouse to determine the orthologous relationships. The interspecies differences should be taken into consideration when experimental results from animal models are extrapolated into humans. The chemokine gene lists and their orthologous relationships presented here will be useful for studies using these animal models. Our analysis also enables us to reconstruct possible gene duplication processes that generated the different sets of chemokine genes in these species.

Esmond E. Snell--the pathfinder of B vitamins and cofactors.

Esmond E. Snell (1914-2003) was a giant of B-vitamin and enzyme research. His early research in bacterial nutrition had lead to the discovery of vitamins such as lipoic acid and folic acid, and an anti-vitamin avidin. He developed microbiological assay methods for riboflavin and other vitamins and amino acids, which are still used today. He also investigated the metabolism of vitamins, discovered pyridoxal and pyridoxamine as the active forms of vitamin B(6) and revealed the mechanism of transamination and other reactions catalysed by vitamin B(6) enzymes. His research in later years on pyruvoyl-dependent histidine decarboxylase unveiled the biogenesis mechanism of this first built-in cofactor. Throughout his career, he was a great mentor of many people, all of whom are inspired by his philosophy of science.

Recombinant human serum albumin dimer has high blood circulation activity and low vascular permeability in comparison with native human serum albumin.

PURPOSE: Human serum albumin (HSA) is used clinically as an important plasma expander. Albumin infusion is not recommended for critically ill patients with hypovolemia, burns, or hypoalbuminemia because of the increased leakage of albumin into the extravascular spaces, thereby worsening edema. In the present study, we attempted to overcome this problem by producing a recombinant HSA (rHSA) dimer with decreased vascular permeability and an increased half-life. METHODS: Two molecules of rHSA were genetically fused to produce a recombinant albumin dimer molecule. The pharmacokinetics and biodistribution of the recombinant proteins were evaluated in normal rats and carrageenin-induced paw edema mouse model. RESULTS: The conformational properties of this rHSA dimer were similar to those for the native HSA (the HSA monomer), as evidenced by the Western blot and spectroscopic studies. The biological half-life and area under the plasma concentration-time curve of the rHSA dimer were approximately 1.5 times greater than those of the monomer. Dimerization has also caused a significant decrease in the total body clearance and distribution volume at the steady state of the native HSA. rHSA dimer accumulated to a lesser extent in the liver, skin, muscle, and fat, as compared with the native HSA. Up to 96 h, the vascular permeability of the rHSA dimer was less than that of the native HSA in paw edema mouse models. A prolonged plasma half-life of the rHSA dimer was also observed in the edema model rats. CONCLUSIONS: rHSA dimer has a high retention rate in circulating blood and a lower vascular permeability than that of the native HSA.

S19 ribosomal protein dimer augments metal-induced apoptosis in a mouse fibroblastic cell line by ligation of the C5a receptor.

To analyze the role of S19 ribosomal protein (RP S19) in apoptosis, murine NIH3T3 were transfected with either hemagglutinin peptide-tagged (HA) wild-type human RP S19 or a mutant (Gln137Asn) that is resistant to transglutaminase-catalyzed cross-linked-dimerization. Transfection with the mutant HA-RP S19 inhibited manganese (II) (Mn II)-induced apoptosis whereas the wild-type HA-RP S19 augmented apoptosis and a mock transfection had no effect. Release of the wild-type HA-RP S19 dimer but not the mutant HA-RP S19 was observed during the apoptosis. The reduced rate of apoptosis of the cells transfected with the mutant HA-RP S19 was overcome by addition of extracellular wild-type RP S19 dimer. The apoptosis rates in cells transfected with either form of human HA-RP S19 and in mock transfectants were reduced to about 40% by the presence of anti-RP S19 antibody in the culture medium. Immunofluorescence staining and fluorescence-activated cell sorting (FACS) analysis showed that the cell surface expression of the receptor for cross-linked RP S19 dimer, C5a receptor, increased during apoptosis, concomitant with phosphatidylserine exposure. The expression of the C5a receptor gene also increased twofold. Apoptosis rates in the transfected and control cell lines were also reduced by the presence of an anti-mouse C5a receptor monoclonal antibody or of a peptide C5a receptor antagonist. These results indicated the presence of an RP S19 dimer- and C5a receptor-mediated autocrine-type augmentation mechanism during Mn II-induced apoptosis in the mouse fibroblastic cell line. In contrast to the RP S19 dimer, C5a actually inhibited apoptosis, suggesting that signaling through the C5a receptor varies depending on the ligand bound.

Release of a new vascular permeability enhancing peptide from kininogens by human neutrophil elastase.

Stimulated neutrophils produced vascular permeability enhancing (VPE) activity in the presence of high molecular weight kininogen (HMWK), which was inhibited mainly by a neutrophil elastase (NE) inhibitor or a bradykinin (BK) B(2)-receptor antagonist. NE (>3 nM) generated VPE activity from kininogens at normal plasma concentrations with the smaller protein being several fold more responsive than the larger protein, through releasing a new VPE peptide (E-kinin), SLMKRPPGFSPFRSSRI. Synthetic E-kinin, SLMKRPPGFSPFRSS and SLMKRPPGFSPFR had VPE and blood pressure lowering activities, which were comparable to the activities of BK and completely inhibited by B(2)-receptor antagonists. Interestingly, E-kinin and SLMKRPPGFSPFRSS did not induce smooth muscle contraction. These results suggest that E-kinin formed in vivo may be processed at the carboxy-terminus to give a peptide that can bind to the B(2)-receptor. The molecular mechanism for neutrophil-associated VPE may be explained by excision of E-kinin from kininogens by NE, followed by further processing of the peptide.

Bacterial chaperone protein, Skp, induces leukocyte chemotaxis via C5a receptor.

C5a receptor has been identified as a leukocyte chemotactic receptor to two intrinsic chemical mediators, C5a and the S19 ribosomal protein dimer, so far. We found an Escherichia coli protein that also induced the chemotactic responses of monocytes and polymorphonuclear leukocytes via the C5a receptor. We identified the E. coli-derived chemoattractant to be Skp by the molecular size and the N-terminal amino acid sequence. Skp is a periplasmic chaperone protein widely present in gram-negative bacterial species. Immunoabsorption experiments indicated that Skp was the major leukocyte chemotactic factor in the E. coli extract. Receptor-antagonizing experiments with analogue peptides of S19 ribosomal protein and of C5a suggested that Skp induced the receptor activation by the two-step binding mechanism as in the cases of the intrinsic mediators, sharing the ligand-binding site of the receptor among them at each binding step. The C5a receptor would play a role in the host defense directly recognizing the bacteria-derived protein, besides identifying the signals of the intrinsic chemical mediators.

Functional analysis of recombinant human serum albumin domains for pharmaceutical applications.

PURPOSE: Functional analysis of the three recombinant human serum albumin (rHSA) domains and their potential as stand-alone proteins for use as drug delivery protein carriers. METHODS: Protein structure was examined by fluorescence and CD spectroscopy. Ligand binding was estimated by ultrafiltration. Antioxidant activity was estimated by measuring the quenching of dihydrorhodamine 123. Esterase-like activity and enolase-like activity were estimated from the rate of hydrolysis of p-nitrophenyl acetate and conversion of dihydrotestosterone from the 3-keto to 3-enol form, respectively. The domains of human serum albumin (HSA) were radiolabeled with 111In to evaluate their pharmacokinetics. RESULTS: The ligand binding ability of subsites Ia and Ib could not be detected in domain II. However, the binding of ligands to subsite Ic and site II were preserved in domain II and domain III, respectively. Domain III retained about 45% of its esterase-like activity, and weaker esterase-like activity was also observed in domain I. All domains showed low enolase-like activity in a pH 7.4 phosphate buffer, but domain II had higher activity in a pH 9.2 carbonate buffer. Domain I exhibited antioxidant activity comparable to that of rHSA. All three of the 111In-radiolabeled domains were rapidly eliminated from HSA, with high accumulation in the kidneys. CONCLUSION: Domain I of HSA has great potential for further development as a drug delivery protein carrier, due to its favorable properties and the presence of a free cysteine residue.