Yuji Nishiuchi

Nocistatin, a peptide that blocks nociceptin action in pain transmission

Prolonged tissue damage or injury often leads to chronic pain states such that noxious stimuli evoke hyperalgesia and innocuous tactile stimuli evoke pain (allodynia),. The neuropeptide nociceptin,, also known as orphanin FQ (ref. 5), is an endogenous ligand for the orphan opioid-like receptor which induces both hyperalgesia and allodynia when administered by injection through the theca of the spinal cord into the subarachnoid space (that is, intrathecally),. Here we show that the nociceptin precursor, contains another biologically active peptide which we call nocistatin. Nocistatin blocks nociceptin-induced allodynia and hyperalgesia, and attenuates pain evoked by prostaglandin E2. It is the carboxy-terminal hexapeptide of nocistatin (Glu-Gln-Lys-Gln-Leu-Gln), which is conserved in bovine, human and murine species, that possesses allodynia-blocking activity. We have also isolated endogenous nocistatin from bovine brain. Furthermore, intrathecal pretreatment with anti-nocistatin antibody decreases the threshold for nociceptin-induced allodynia. Although nocistatin does not bind to the nociceptin receptor, it binds to the membrane of mouse brain and of spinal cord with high affinity. Our results show that nocistatin is a new biologically active peptide produced from the same precursor as nociceptin and indicate that these two peptides may play opposite roles in pain transmission.

Binding of ω-conotoxin to receptor sites associated with the voltage-sensitive calcium channel

Abstract The binding of radioiodinated ω-conotoxin GVIA, a probable Ca channel antagonist, to synaptic plasma membranes of rat brain was examined. Two kinds of specific binding sites were found with apparent dissociation constants of 10 pM and 0.5 nM and maximum binding capacities of 0.5 and 3.4 pmol/mg prot., respectively. The binding of the toxin was not affected by high concentrations of Ca antagonists or an agonist, indicating distinct binding sites of the toxin from those of these drugs. Divalent and trivalent metal ions strongly inhibited the binding. The order of their inhibitory potencies was similar to that for inhibition of the Ca current through certain Ca channels. These results suggest that the binding sites of ω-conotoxin GVIA are functionally related to the Ca 2+ -binding site postulated to be in the pore of the Ca channel.

Primary and secondary structure of conotoxin GI, a neurotoxic tridecapeptide from a marine snail

To determine the mode of disulphide bond formation in conotoxin GI, a tridecapeptide amide with 4 Cys residues, all 3 of its peptides having different modes of disulphide‐bond formation were synthesized by solution procedure using selectively removable protective groups at the Cys residues. After deprotection with HF, one pair of acetamidomethyl groups was left unremoved, and then two sets of disulphide bonds were formed selectively. The toxic potency in mice of one product was comparable with that reported for native conotoxin GI and was almost 10‐fold as high as that of the other two products. The toxicity of the native toxin reportedly is not regenerated upon reduction and reoxidation, but this study showed that the most toxic product was the most readily formed one.

Effects of synthetic ω-conotoxin on synaptic transmission

Abstract The effects of chemically synthesized ω-conotoxin GVIA (a neurotoxic peptide from Conus geographus ) on synaptic transmission at the bullfrog sympathetic ganglion, frog neuromuscular junction and electric organ of the ray, Narke japonica , were studied. The synthetic toxin irreversibly suppressed synaptic transmission at these synapses by arresting the release of transmission from the nerve terminals without showing postsynaptic effects. This action of the toxin was effectively antagonized by high concentrations of extracellular Ca 2+ . The synthetic toxin irreversibly blocked the Ca 2+ -dependent action potential of bullfrog sympathetic ganglion cells. These results suggest that ω-conotoxin GVIA blocks synaptic transmission by interfering with the Ca 2+ influx through the voltage-sensitive Ca 2+ channel of the nerve terminal. These results indicate that the chemically synthesized ω-conotoxin GVIA acts exactly like the natural ω-conotoxin GVIA. Thus, the synthetic toxin can be used in place of the natural toxin as a useful probe for the voltage-sensitive Ca 2+ channel in the nervous system.

Synthesis and structure-activity relationships of elafin, an elastase-specific inhibitor.

Elafin, an elastase-specific inhibitor isolated from human skin, and its related peptides were synthesized by the solution procedure, and their inhibitory activities were measured against various enzymes. During the oxidative folding reactions of the reduced peptides, the ratio of the active product to the inactive product was varied by changing the concentration of guanidine HCl and the amount of redox reagents. The disulfide structures of fully active synthetic elafin and the inactive product were determined by amino acid analysis, gas-phase sequencing and mass spectrometry of their proteolytic fragments. The relationship between structure and inhibitory activities and/or the folding reaction was examined and the amino terminal part of the elafin molecule was found to have a great influence on the folding reactions, but not on the inhibitory activities.

Optimal oxidative folding of the novel antimicrobial cyclotide from Hedyotis biflora requires high alcohol concentrations.

Hedyotide B1, a novel cyclotide isolated from the medicinal plant Hedyotis biflora, contains a cystine knot commonly found in toxins and plant defense peptides. The optimal oxidative folding of a cystine knot encased in the circular peptide backbone of a cyclotide poses a challenge. Here we report a systematic study of optimization of the oxidative folding of hedyotide B1, a 30-amino acid cyclic peptide with a net charge of +3. The linear precursor of hedyotide B1, synthesized as a thioester by solid phase synthesis, was cyclized quantitatively by a thia-zip cyclization to form the circular backbone and then subjected to oxidative folding in a thiol-disulfide redox system under 38 different conditions. Of the oxidative conditions examined, the nature of the organic cosolvent appeared to be critical, with the use of 70% 2-propanol affording the highest yield (48%). The disulfide connectivity of the folded hedyotide was identical to that of the native form as determined by partial acid hydrolysis. The use of such a high alcohol concentration suggests that a partial denaturation may be necessary for the oxidative folding of a cyclotide with the inverse orientation of hydrophobic side chains that are externalized to the solvent face to permit the formation of the interior cystine core in the circularized backbone. We also show that synthetic hedyotide B1 is an antimicrobial, exhibiting minimal inhibitory concentrations in the micromolar range against both Gram-positive and -negative bacteria.

Anti-nociceptive responses produced by human putative counterpart of nocistatin

b‐nocistatin is a heptadecapeptide produced from bovine prepronociceptin and blocks the induction of hyperalgesia and touch‐evoked pain (allodynia) by intrathecal administration of nociceptin or prostaglandin E2 (PGE2). Human prepronociceptin may generate a 30‐amino acid peptide different in length from b‐nocistatin. Here, we examine whether the human putative counterpart of nocistatin (h‐nocistatin) possessed the same biological activities as b‐nocistatin. Simultaneous intrathecal injection of h‐nocistatin in mice blocked the induction of allodynia by nociceptin and PGE2 in a dose‐dependent manner with ID50 values of 329 pg kg−1 and 16.6 ng kg−1, respectively. h‐nocistatin was about 10 times less potent than b‐nocistatin. h‐nocistatin also attenuated the nociceptin‐ and PGE2‐induced hyperalgesia. These results demonstrate that h‐nocistatin is biologically active and may be involved in the processing of pain at the spinal level in humans.

Crystal structure of basic 7S globulin, a xyloglucan-specific endo-β-1,4-glucanase inhibitor protein-like protein from soybean lacking inhibitory activity against endo-β-glucanase

β‐Linked glucans such as cellulose and xyloglucan are important components of the cell walls of most dicotyledonous plants. These β‐linked glucans are constantly exposed to degradation by various endo‐β‐glucanases from pathogenic bacteria and fungi. To protect the cell wall from degradation by such enzymes, plants secrete proteinaceous endo‐β‐glucanases inhibitors, such as xyloglucan‐specific endo‐β‐1,4‐glucanase inhibitor protein (XEGIP) in tomato. XEGIPs typically inhibit xyloglucanase, a member of the glycoside hydrolase (GH)12 family. XEGIPs are also found in legumes, including soybean and lupin. To date, tomato XEGIP has been well studied, whereas XEGIPs from legumes are less well understood. Here, we determined the crystal structure of basic 7S globulin (Bg7S), a XEGIP from soybean, which represents the first three‐dimensional structure of XEGIP. Bg7S formed a tetramer with pseudo‐222 symmetry. Analytical centrifugation and size exclusion chromatography experiments revealed that the assembly of Bg7S in solution depended on pH. The structure of Bg7S was similar to that of a xylanase inhibitor protein from wheat (Tritinum aestivum xylanase inhibitor) that inhibits GH11 xylanase. Surprisingly, Bg7S lacked inhibitory activity against not only GH11 but also GH12 enzymes. In addition, we found that XEGIPs from azukibean, yardlongbean and mungbean also had no impact on the activity of either GH12 or GH11 enzymes, indicating that legume XEGIPs generally do not inhibit these enzymes. We reveal the structural basis of why legume XEGIPs lack this inhibitory activity. This study will provide significant clues for understanding the physiological role of Bg7S.

Structure-activity relationships of α-human atrial natriuretic peptide

Abstract The spasmolytic activity of synthetic α-human atrial natriuretic peptide (α-hANP) and its related peptides was determined in vitro using the chick rectum and the rat aorta. Natriuretic activity was also measured in the anesthetized rat. α-hANP-(7–28), with the NH 2 -terminal hexapeptide truncated, had grater spasmolytic and natriuretic effect than did α-hANP-(1–28). These responses were reduced by truncation of the COOH-terminal residues. α-hANP-(7–23), the cyclic structure of α-hANP-(1–28), exhibited weak aortic relaxation and natriuretic activities. However, α-hANP-(7–23) produced a greater relaxation than did α-hANP-(1–28) in the chick rectum. Elimination of Gly at position 9 reduced the spasmolytic and natriuretic activity. Substitution of amino acid residues at position 8, 12 and 13 changed these activities. Analogues containing the ethylene linkage instead of the disulphide bond had weak biological activity. These results indicate that the size of the 17-amino acid ring and the COOH-terminal residues of α-hANP are important for the expression of spasmolytic and natriuretic activity.

Synthesis, Solution Structure, and Phylum Selectivity of a Spider δ-Toxin That Slows Inactivation of Specific Voltage-gated Sodium Channel Subtypes

Magi 4, now renamed δ-hexatoxin-Mg1a, is a 43-residue neurotoxic peptide from the venom of the hexathelid Japanese funnel-web spider (Macrothele gigas) with homology to δ-hexatoxins from Australian funnel-web spiders. It binds with high affinity to receptor site 3 on insect voltage-gated sodium (NaV) channels but, unlike δ-hexatoxins, does not compete for the related site 3 in rat brain despite being previously shown to be lethal by intracranial injection. To elucidate differences in NaV channel selectivity, we have undertaken the first characterization of a peptide toxin on a broad range of mammalian and insect NaV channel subtypes showing that δ-hexatoxin-Mg1a selectively slows channel inactivation of mammalian NaV1.1, NaV1.3, and NaV1.6 but more importantly shows higher affinity for insect NaV1 (para) channels. Consequently, δ-hexatoxin-Mg1a induces tonic repetitive firing of nerve impulses in insect neurons accompanied by plateau potentials. In addition, we have chemically synthesized and folded δ-hexatoxin-Mg1a, ascertained the bonding pattern of the four disulfides, and determined its three-dimensional solution structure using NMR spectroscopy. Despite modest sequence homology, we show that key residues important for the activity of scorpion α-toxins and δ-hexatoxins are distributed in a topologically similar manner in δ-hexatoxin-Mg1a. However, subtle differences in the toxin surfaces are important for the novel selectivity of δ-hexatoxin-Mg1a for certain mammalian and insect NaV channel subtypes. As such, δ-hexatoxin-Mg1a provides us with a specific tool with which to study channel structure and function and determinants for phylum- and tissue-specific activity.