A 10-kDa cyanogen bromide fragment from the epidermal growth factor homology domain of rabbit thrombomodulin contains the primary thrombin binding site

We have isolated a fragment (approximately equal to 10 kDa) of thrombomodulin containing the fifth and sixth epidermal growth factor (EGF)-like regions which retains thrombin binding capacity. The amino-terminal sequence of a 50-kDa active fragment of thrombomodulin derived from elastase proteolysis begins 11 residues before the first EGF-like structure of native thrombomodulin. Subsequent digestion with cyanogen bromide yields a 10-kDa thrombin binding fragment. The amino-terminal sequence of this fragment starts at the fifth EGF-like structure (Phe407). The amino acid composition suggests that this fragment contains the fifth and sixth EGF-like structures with a total of approximately 77 residues. This fragment lacks cofactor activity, but acts as a competitive inhibitor for protein C activation (Ki = 8.6 +/- 1.4 nM). We propose that the fifth and sixth EGF-like structures contain the thrombin binding site of thrombomodulin.     

Topically applied capsaicin inhibits sensitivity to touch but not to warmth or heat-pain in the region of secondary mechanical hyperalgesia

The aim of this study was to investigate tactile sensitivity near the site of primary hyperalgesia evoked by capsaicin applied topically to the dorsolateral aspect of the hand. In the first experiment (N = 15), touch thresholds increased in the fifth finger ipsilateral to the topically applied capsaicin, but remained unchanged at greater distances from the site of capsaicin treatment. In a second experiment (N = 12), the effect of the capsaicin treatment on sensations evoked not only by light touch but also by warmth, heat-pain, and pressure-pain to a 2-mm diameter steel probe was investigated in the fifth finger. Again, tactile sensitivity was inhibited at the fifth finger, even though stimulation with a cotton bud evoked no discomfort; moreover, sensitivity to warmth and heat-pain were unimpaired. However, sensitivity to pressure-pain increased in the fifth finger after the capsaicin treatment, possibly due to activation of nociceptors sandwiched between the probe tip and bone that normally responded to sharp stimuli. These findings suggest that the central mechanisms that mediate secondary mechanical hyperalgesia suppress sensitivity to innocuous tactile sensations. This effect may contribute to tactile hypoesthesia in chronic pain conditions.     

Origin and development of unusual insect muscle tension receptors

This work describes the origin and development of about 200 tension receptor cells located around the anterior attachment site of the locust ovipositor muscle and their migration to their final position on the muscle fibres. The locust ovipositor muscle is the only insect system in which more than 100 tension receptor cells are associated with a single muscle. Neuronal precursors of tension receptors are first detectable by horseradish peroxidase immunohistochemistry in fourth instar larvae. Precursors consist of cell clusters (doublets, triplets and quadruplets) located on the anterior attachment site of the muscle. In the early fifth larval stage, cell clusters are absent, although a few sensory neurons that lie embedded between the muscle fibres are apparent. These neurons send their dendrites towards the anterior end of the muscle fibres and their axons posteriorly. By the fourth day of the fifth larval stage, a large number of cell clusters appears on the anterior muscle attachment site. In addition to these assemblies, cells have been identified that extend long processes running exactly along the lateral margin of the attachment site. These cells are thought to provide navigating cues for migrating tension receptors, since they are absent in later stages. By the end of the fifth larval stage, most of the clusters gradually disappear and increasing numbers of differentiated neurons embedded between the muscle fibres become visible. We conclude that the majority of tension receptors develop during the last larval stage from precursors situated on the muscle apodeme. They then migrate from the apodeme to their final place on the muscle fibres where they assume an appropriate orientation.     

Effects of mutation at a conserved N-glycosylation site in the bovine retinal cyclic nucleotide-gated ion channel

Bovine retinal cyclic nucleotide-gated (CNG) ion channel contains an evolutionary conserved N-glycosylation site in the external loop between the fifth transmembrane segment and the pore-forming region. The effect of tunicamycin treatment and the site-specific mutation suggested that the channel is glycosylated when expressed in Xenopus oocytes. To test the role of glycosylation in this channel, N-glycosylation was abolished by mutation, and the detailed permeation and the gating characteristics of the mutant channel were investigated. The charge contribution turned out to be detectable, although the mutation of the N-glycosylation site did not affect expression and functionality of the CNG channel in oocytes.     

Évolution de l’exploitation des ressources animales dans la région cantabrique entre 4500 et 2000 cal BC : la grotte de Los Gitanos (Cantabrie,Espagne)

The archaeozoological remains found in the four Neolithic and Chalcolithic sub-levels at the archaeological site of Los Gitanos Cave are analysed. Continuity is seen in the exploitation of the marine environment, while the percentage of domestic ungulates, in comparison with hunted animals, progressively increases. Finally, the site is contextualised in an overview of the use of animal resources in Cantabrian Spain from the fifth to the third millennia.     

The relationship between the chromophore moiety and the cation binding sites in bacteriorhodopsin

Bleaching of the purple membrane strongly reduces the number of divalent cation binding sites as well as their affinities. Conversely, deionization of the bleached membrane drastically inhibits the chromophore regeneration. Proteolysis experiments using bromelain show that the bleached membrane has an additional cleavage site probably located at the fifth loop, whereas in the blue membrane, the C-terminal tail is no longer susceptible to proteolysis. It is suggested that there exists a close relationship between the retinal environment and one or more of the cation binding sites.     

On the structure-function relationship of peroxidases and peroxygenase

The structure-function relationship of two kinds of hemoproteins, peroxidases and peroxygenase, is discussed and a tentative model for the active site (heme vicinity) structure of each hemoprotein is proposed. The mechanism of Compound I formation from peroxidases is presumed to involve an electrophilic attack of hydroperoxide, the electrophilicity of which is increased by forming a hydrogen bond to a distal acid group (with β-equatorial arrangement) on the heme iron, the basicity of which is being increased by electron donation from the anionic fifth ligand. On the other hand, the mechanism for peroxygenase is presumed to involve a nucleophilic attack of hydroperoxide, the nucleophilicity of which is increased by forming a hydrogen bond to a distal base group (with α-axial arrangement) to the heme iron ligating the neutral fifth ligand. It is presumed that Compound I of peroxidases, which consists of porphyrin π cation radical and ferryl iron, is stabilized by a π-π type charge transfer interaction between the radical, and stacking imidazolate group (not necessarily different from the distal group) which then ionizes, and by electron donation from the anionic fifth ligand. On the other hand, Compound I of peroxygenase, which is postulated to be an oxene complex, is presumed to be stabilized by an electrostatic interaction with a strongly negative environment, and by ionization of the fifth ligand, if such can happen.     

The evolution of the reptilian hindfoot and the homology of the hooked fifth metatarsal

The homology of the fifth metatarsal in turtles and in diapsid reptiles is reassessed in the light of new phylogenetic studies. The two nearest outgroups to turtles — pareiasaurs and procolophonoids — both lack a fifth distal tarsal but retain a normal fifth metatarsal. The fifth distal tarsal was therefore lost at the base of the clade that contains turtles. Thus, the hooked fifth metatarsal in turtles must consist entirely of a modified fifth metatarsal: it does not include contributions from the fifth distal tarsal, as commonly supposed. In diapsids, loss of the fifth distal tarsal appears to have occurred at the base of crown-clade diapsids, hooking of the fifth metatarsal subsequently occurring within lepidosauromorphs, and in archosauromorphs. If so, the hooked fifth metatarsal in archosauromorphs, and some lepidosauromorphs, consists entirely of a modified fifth metatarsal. In both turtles and diapsids, integration of the elements distal to the mesotarsal joint precedes evolution of the hooked fifth metatarsal, supporting the view that the latter element evolved to perform a lever function (analogous to the “heel bone” of mammals).     

N-linked oligosaccharides on chondroitin 6-sulfotransferase-1 are required for production of the active enzyme, Golgi localization, and sulfotransferase activity toward keratan sulfate

We have shown previously that purified chondroitin 6-sulfotransferase-1 (C6ST-1) was a glycoprotein abundant in N-linked oligosaccharides and could sulfate both chondroitin (C6ST activity) and keratan sulfate (KSST activity); however, functional roles of the N-glycans have remained unclear. In the present study, we show essential roles of N-glycans attached to C6ST-1 in the generation of the active enzyme and in its KSST activity. Treatment with tunicamycin of COS-7 cells transfected with C6ST-1 cDNA totally abolished production of the active C6ST-1. A nearly complete removal of N-glycans of the recombinant C6ST-1 by peptide N-glycosidase F increased the C6ST activity but decreased the KSST activity. Among six potential N-glycosylation sites, deletion of the fourth or sixth site from the amino terminus inhibited production of the active C6ST-1, whereas deletion of the fifth site resulted in a marked loss of the KSST activity. Wild-type recombinant C6ST-1 showed a typical Golgi localization, whereas M-4 recombinant C6ST-1, in which the fourth N-glycosylation site was deleted, colocalized with calnexin, an endoplasmic reticulum-resident protein. Unlike wildtype recombinant C6ST-1, M-4 recombinant C6ST-1 showed a weak affinity toward wheat germ agglutinin and was converted completely to the nonglycosylated form by endoglycosidase H. These observations suggest that N-glycan attached to the fourth N-glycosylation site may function in the proper processing of N-glycans required for the Golgi localization, thereby causing the production of the active C6ST-1, and that N-glycan attached to the fifth N-glycosylation site may contribute to the KSST activity of C6ST-1.     

Monoclonal antibodies for human thrombomodulin which recognize binding sites for thrombin and protein C

Monoclonal antibodies for human thrombomodulin, a cofactor for thrombin-catalyzed activation of protein C, were prepared and their epitopes characterized. All six antibodies (MFTM-1-MFTM-6) bound to an elastase-digested active fragment of thrombomodulin, which contains six consecutive EGF domains. Binding of thrombomodulin to these antibodies did not depend on Ca2+ concentration. MFTM-4, MFTM-5, and MFTM-6 strongly inhibited protein C activation by thrombin and thrombomodulin. MFTM-4 and MFTM-5 inhibited thrombin binding to fixed thrombomodulin and bound to a recombinant mutant EGF456 protein, which contained the fourth, fifth, and sixth EGF domains of thrombomodulin. However, MFTM-6 did not inhibit thrombin binding to thrombomodulin and did not bind to EGF456 protein. Binding of thrombomodulin to fixed MFTM-4 or MFTM-5 was competitively inhibited by a recombinant mutant EGF45 protein which contained the fifth and sixth EGF-domains. These results suggest that epitopes of MFTM-4 and MFTM-5 are located in the fifth EGF domain of thrombomodulin. Thus, the binding site for thrombin is located in the fifth EGF domain. These results also suggest that an epitope for MFTM-6 is located at a region near the binding site for gamma-carboxyglutamic acid residues of protein C via Ca2+ on thrombomodulin.     

Contribution of individual histidines to prion protein copper binding

The prion protein is well-established as a copper binding protein. The N-terminus of the protein contains an octameric repeat region with each of the four repeats containing a histidine. The N-terminus has two additional histidines distal to the repeat region that has been commonly known as the fifth site. While binding of copper by the protein has been extensively studied, the contribution of each histidine to copper binding in the full-length protein has not. Here we used a battery of mutants of the recombinant mouse prion protein to assess copper binding with both isothermal titration calorimetry and cyclic voltammetry. The findings indicate that there is extensive cooperativity between different binding sites in the protein. The two highest-affinity binding events occur at the fifth site and at the octameric repeat region. However, the first binding is that to the octameric repeat region. Subsequent binding events after the two initial binding events have lower affinities within the octameric repeat region.     

A New Surgical Technique for Polysyndactyly of the Toes without Skin Graft

Reconstruction for polysyndactyly of the toes aims at cosmetic improvement. A previous method that uses a skin graft has inherent disadvantages of mismatched pigmentation between the graft and the surrounding skin and scar formation at the donor site. The authors' new improved surgical technique for the treatment of polysyndactyly of the toes does not require a skin graft and therefore avoids these problems. The authors designed a subcutaneous flap from the distal portion of a rectangular flap of skin from the dorsal side of the interdigital webbing and moved the former flap to the sidewall of the base of a toe. Both flaps are the same size; therefore, an interdigital space had to be of sufficient size to accommodate both of them. To ensure an adequate blood supply to the flap, careful handling of the subcutaneous flap is essential for success. This procedure can apply to polysyndactyly of the fourth, fifth, and sixth toes when the fourth and fifth toes adhere over the distal side of the distal interphalangeal joint and when the skin on the dorsal side of the fifth toe, regarded as the excessive one, is at lease twice the size of the dorsal rectangular flap. Ten patients with polysyndactyly of the toe were treated with this method. Aesthetically good results were obtained.     

Identification of the fifth axial heme ligand of chloroperoxidase

Chloroperoxidase from Caldariomyces fumago catalyzes the peroxidative chlorination of organic acceptor molecules. From a variety of spectroscopic data, it had long been thought that chloroperoxidase possessed an active site structure similar to that of cytochrome P-450cam. Resonance Raman studies conducted with isotopically substituted enzyme proved conclusively that the fifth axial ligand to the ferriprotoporphyrin IX moiety of chloroperoxidase is indeed a cysteine thiolate (Bangcharoenpaurpong, O., Champion, P. M., Hall, K. S., and Hager, L. P. (1986) Biochemistry 25, 2374-2378). In this study, Ellman's reagent, 5,5'-dithiobis(2-nitrobenzoic acid), was used to ascertain which of the 3 cysteine residues in the primary structure of chloroperoxidase serves as the fifth axial heme ligand; two of the cysteine residues were earlier shown to be involved in a disulfide linkage. Apoprotein was labeled under denaturing conditions with 5,5'-dithiobis(2-nitrobenzoic acid). A unique peptide, containing the thionitrobenzoate adduct, was isolated via reverse phase HPLC following digestion with endoproteinase Glu-C. Amino acid and Edman sequence analysis revealed the fifth axial ligand in chloroperoxidase to be cysteine 29. Under reducing and denaturing conditions, incubation of apochloroperoxidase with Ellman's reagent resulted in 3 labeled residues. Proteolysis and isolation of the labeled peptides using reverse phase HPLC and subsequent Edman sequence analysis detected and identified the thionitrobenzoate adducts of each of the three cysteinyl peptides of chloroperoxidase.     

High affinity binding between copper and full-length prion protein identified by two different techniques

The cellular prion protein is known to be a copper-binding protein. Despite the wide range of studies on the copper binding of PrP, there have been no studies to determine the affinity of the protein on both full-length prion protein and under physiological conditions. We have used two techniques, isothermal titration calorimetry and competitive metal capture analysis, to determine the affinity of copper for wild type mouse PrP and a series of mutants. High affinity copper binding by wild type PrP has been confirmed by the independent techniques indicating the presence of specific tight copper binding sites up to femtomolar affinity. Altogether, four high affinity binding sites of between femto- and nanomolar affinities are located within the octameric repeat region of the protein at physiological pH. A fifth copper binding site of lower affinity than those of the octameric repeat region has been detected in full-length protein. Binding to this site is modulated by the histidine at residue 111. Removal of the octameric repeats leads to the enhancement of affinity of this fifth site and a second binding site outside of the repeat region undetected in the wild type protein. High affinity copper binding allows PrP to compete effectively for copper in the extracellular milieu. The copper binding affinities of PrP have been compared with those of proteins of known function and are of magnitudes compatible with an extracellular copper buffer or an enzymatic function such as superoxide dismutase like activity.     

Crystal structure of the human adenovirus proteinase with its 11 amino acid cofactor.

The three-dimensional structure of the human adenovirus-2 proteinase complexed with its 11 amino acid cofactor, pVIc, was determined at 2.6 A resolution by X-ray crystallographic analysis. The fold of this protein has not been seen before. However, it represents an example of either subtly divergent or powerfully convergent evolution, because the active site contains a Cys-His-Glu triplet and oxyanion hole in an arrangement similar to that in papain. Thus, the adenovirus proteinase represents a new, fifth group of enzymes that contain catalytic triads. pVIc, which extends a beta-sheet in the main chain, is distant from the active site, yet its binding increases the catalytic rate constant 300-fold for substrate hydrolysis. The structure reveals several potential targets for antiviral therapy.     

Amino acid sequence at the allosteric site of sheep heart phosphofructokinase

Covalent modification of sheep heart phosphofructokinase with the affinity labeling reagent p-fluorosulfonyl[14C]benzoyl-5'-adenosine caused a loss of allosteric properties. This modification appears to occur at the binding site that is specific for the allosteric activators AMP, cAMP, and ADP (Mansour, T.E., and Colman, R.F. (1978) Biochem. Biophys. Res. Commun. 81, 1370-1376). In the current study, the site of modification has been demonstrated to be a lysine residue. A nonapeptide containing a covalently bound [14C]carboxybenzenesulfonyl group attached to alysine residue has been isolated following tryptic digestion. The amino acid sequence of the peptide is Asn-Phe-Ala-Thr-Lys-Met-Gly-Ala-Lys. The fifth residue in this sequence, lysine, contained the covalently bonded reagent.