High-Affinity Receptor Sites and Rapid Proteolytic Inactivation of Neurotensin in Primary Cultured Neurons

The present article describes the interaction of neurotensin with specific receptors in pure primary cultured neurons and the mechanisms by which this peptide is inactivated by these cells. Neurotensin binding sites are not detectable in nondifferentiated neurons and appear during maturation. The binding at 37 degrees C of [monoiodo-Tyr3]neurotensin to monolayers of neurons 96 h after plating is saturable and characterized by a dissociation constant of 300 pM and a maximal binding capacity of 178 fmol/mg of protein. The binding parameters as well as the specificity of these receptors toward neurotensin analogues reveal close similarities between the binding sites present in primary cultured neurons and those described in other membrane preparations or cells. Neurotensin is rapidly degraded by primary cultured neurons. The sites of primary inactivating cleavages are the Pro7-Arg8, Arg8-Arg9, and Pro10-Tyr11 bonds. Proline endopeptidase is totally responsible for the cleavage at the Pro7-Arg8 bond and contributes to the hydrolysis mainly at the Pro10-Tyr11 site. However, the latter breakdown is also generated by a neurotensin-degrading neutral metallopeptidase. The cleavage at the Arg8-Arg9 bond is due to a peptidase that can be specifically inhibited by N-[1(R,S)-carboxy-2-phenylethyl]-alanyl-alanyl-phenylalanyl-p- aminobenzoate. The secondary processing occurring on neurotensin degradation products are: a bestatin-sensitive aminopeptidasic conversion of neurotensin11-13 to free Tyr11, and a rapid cleavage of neurotensin8-13 by proline endopeptidase. A model for the inactivation of neurotensin in primary cultured neurons is proposed and compared to that previously described for purified rat brain synaptic membranes.     

Expression and purification of recombinant neurotensin in Escherichia coli

An expression system has been designed for the rapid and economic expression of recombinant neurotensin for biophysical studies. A synthetic gene for neurotensin (Glu(1)-Leu(2)-Tyr(3)-Glu(4)-Asn(5)-Lys(6)-Pro(7)-Arg(8)-Arg(9)-Pro(1 0)-Tyr(11)-Ile(12)-Leu(13)) was cloned into the pGEX-5X-2 vector to allow expression of neurotensin as a glutathione S-transferase (GST) fusion protein. The inclusion of a methionine residue between the glutathione S-transferase and the neurotensin has facilitated the rapid cleavage of the neurotensin from its carrier protein. Purification of recombinant neurotensin was performed by reverse-phase HPLC. This method produced a relatively high yield of peptide and offers the potential for economic partial or uniform labeling of small peptides (<15 amino acids) with isotopes for NMR or other biophysical techniques.     

Neurotensin Binding to Dopamine

Rotating disk electrode voltammetry at glassy carbon electrodes and ultraviolet/visible spectroscopy were used to demonstrate that dopamine binds to neurotensin with a dissociation constant of 7.5 × 10^-8. By measuring the binding constants of various neurotensin analogs, it was found that the -Arg⁸-Arg⁹-portion of the neurotensin sequence is critical for binding dopamine. Neurotensin also formed a complex with 4-ethylcatechol, 4-methylcatechol, 3-methoxytyramine, and norepinephrine. Although changes in the side chain did not alter the binding constant, methoxylation of the catechol moiety significantly increased the dissociation constant. These data along with additional studies of dopamine interactions with arginine derivatives suggest that the guanidino groups of arginine and the catechol hydroxyls of dopamine are responsible for mediating the observed binding. It is hypothesized that the capacity of neurotensin to bind directly to dopamine may be partly responsible for its previously observed antagonism of dopamine-induced locomotor activity.     

Mechanism of degradation of LH-RH and neurotensin by synaptosomal peptidases

The products of degradation of LH-RH and neurotensin by synaptosomes isolated from rat hypothalamus and cortex have been identified. LH-RH is cleaved at Tyr5-Gly6 and Pro9-Gly10 giving rise to LH-RH (1-5), LH-RH (6-10) and LH-RH (1-9). Neurotensin is cleaved at Arg8-Arg9, Pro10-Tyr11 and Ile12-Leu13, giving neurotensin (1-8), neurotensin (1-10), neurotensin (1-12) and neurotensin (9-13) as major products. While most of the peptidase activity is localized in the cytoplasmic fraction, a small but significant proportion is membrane bound. For LH-RH, the specificity of the membrane-bound activity is similar to that in the cytosol fraction; for neurotensin, the membrane fraction preferentially gives rise to the (1-10) and (1-11) peptides. The most potent inhibitors of the LH-RH and neurotensin degrading enzymes in synaptosomes are heavy metal ions (mercury and copper), p-chloromercuribenzoate and 1,10 phenanthroline.     

Degradation of neurotensin by rabbit brain endo-oligopeptidase A and endo-oligopeptidase B (proline-endopeptidase)

The degradation of neurotensin and D-Tyr11 neurotensin by apparently homogeneous preparations of rabbit brain endo-oligopeptidase A and endo-oligopeptidase B (Proline-endopeptidase) was studied. Peptide fragments were isolated by high performance liquid chromatography and identified by amino acid analysis. Endo-oligopeptidase A cleaved neurotensin at the Arg8-Arg9 bond whereas D-Tyr11 neurotensin was not significantly hydrolysed. Endo-oligopeptidase B cleaved at the carboxyl side of Pro7, Pro10 in neurotensin and at Pro7 in D-Tyr11 neurotensin. The concentration dependent inhibition of neurotensin degradation by bradykinin and vice-versa represents additional evidence that endo-oligopeptidase A cleaves both Phe5-Ser6 bond of bradykinin and the Arg8-Arg9 bond of neurotensin.     

Characterization of Neurotensin Binding Sites in Intact and Solubilized Bovine Brain Membranes

Analysis of the equilibrium binding of [3H]-neurotensin(1-13) at 25 degrees C to its receptor sites in bovine cortex membranes indicated a single population of sites with an apparent equilibrium dissociation constant (KD) of 3.3 nM and a density (Bmax) of 350 fmol/mg protein (Hill coefficient nH = 0.97). Kinetic dissociation studies revealed the presence of a second class of sites comprising less than 10% of the total. KD values of 0.3 and 2.0 nM were obtained for the higher and lower affinity classes of sites, respectively, from association-dissociation kinetic studies. The binding of [3H]neurotensin was decreased by cations (monovalent and divalent) and by a nonhydrolysable guanine nucleotide analogue. Competition studies gave a potency ranking of [Gln4]neurotensin greater than neurotensin(8-13) greater than neurotensin(1-13). Smaller neurotensin analogues and neurotensin-like peptides were unable to compete with [3H]neurotensin. Stable binding activity for [3H]neurotensin in detergent solution (Kd = 5.5 nM, Bmax = 250 fmol/mg protein, nH = 1.0) was obtained in 2% digitonin/1 mM Mg2+ extracts of membranes which had been preincubated (25 degrees C, 1 h) with 1 mM Mg2+ prior to solubilization. Association-dissociation kinetic studies then revealed the presence of two classes of sites (KD1 = 0.5 nM, KD2 = 3.6 nM) in a similar proportion to that found in the membranes. The solubilized [3H]-neurotensin activity retained its sensitivity to cations and guanine nucleotide.     

Regulation of cyclic GMP levels by neurotensin in neuroblastoma clone N1E115

The binding of 125I-labeled [monoiodo-Tyr3]neurotensin to intact neuroblastoma N1E115 cells and the effect of neurotensin on the intracellular concentration of cyclic nucleotides were studied at 37 degrees C and under physiological conditions of pH and ionic strength. The radiolabeled neurotensin analogue bound specifically to differentiated cells with a dissociation constant of 0.75 nM and a maximal binding capacity of 45 fmol/10(6) cells. Incubation of neuroblastoma cells with neurotensin in the presence of calcium ions resulted in a transient increase of 10 fold over basal level of the intracellular cyclic GMP concentration. Half-maximal stimulation was obtained with 2 nM neurotensin. Under identical conditions the cyclic AMP concentration only decreased by 20-30%. These results suggest that cyclic GMP is a second messenger of neurotensin in neuroblastoma clone N1E115.     

Peptidases involved in the catabolism of neurotensin: inhibitor studies using superfused rat hypothalamic slices

In order to identify which peptidases are involved in the catabolism of neurotensin in the CNS, [3H-Tyr3,11]-neurotensin was superfused over rat hypothalamic slices in the presence and absence of peptidase inhibitors. The degree of degradation of the peptide was determined by reverse phase HPLC separation of 3H-labelled neurotensin from 3H-labelled products. Very little degrading activity was released from the slice into the medium during the superfusion. In the absence of inhibitors, 20 to 50% of 3H-neurotensin was degraded giving mainly 3H-Tyr along with other unidentified 3H-labelled products. Inhibitors of endopeptidase 24.11 (phosphoramidon) and proline endopeptidase (antibody) had no effect on the degradation. Captopril, an inhibitor of angiotensin converting enzyme, had a small inhibitory effect. In contrast, dynorphin(1-13), an inhibitor of a soluble, thiol dependent metallopeptidase which hydrolyses neurotensin at Arg8-Arg9, gave greater than 80% inhibition of 3H-neurotensin degradation in the slice preparation. 1,10-Phenanthroline, an inhibitor of metallopeptidases, was also an effective inhibitor. The dynorphin sequence responsible for the inhibition contains the Arg6-Arg7 bond. Other peptides (bradykinin and angiotensin) which are substrates of the soluble metallopeptidase also inhibited neurotensin breakdown by the slice. This evidence suggests that this thiol dependent metalloendopeptidase is the major neurotensin catabolizing enzyme in hypothalamic slices.     

Purification and characterization of a novel neurotensin-degrading peptidase from rat brain synaptic membranes

A peptidase that cleaved neurotensin at the Pro10-Tyr11 peptide bond, leading to the formation of neurotensin-(1-10) and neurotensin-(11-13), was purified nearly to homogeneity from rat brain synaptic membranes. The enzyme appeared to be monomeric with a molecular weight of about 70,000-75,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and high pressure liquid chromatography filtration. Isoelectrofocusing indicated a pI of 5.9-6. The purified peptidase could be classified as a neutral metallopeptidase with respect to its sensitivity to pH and metal chelators. Thiol-blocking agents and acidic and serine protease inhibitors had no effect. Studies with specific peptidase inhibitors clearly indicated that the purified enzyme was distinct from enzymes capable of cleaving neurotensin at the Pro10-Tyr11 bond such as proline endopeptidase and endopeptidase 24-11. The enzyme was also distinct from other neurotensin-degrading peptidases such as angiotensin-converting enzyme and a recently purified rat brain soluble metalloendopeptidase. The peptidase displayed a high affinity for neurotensin (Km = 2.6 microM). Studies on its specificity revealed that neurotensin-(9-13) was the shortest neurotensin partial sequence that was able to fully inhibit [3H]neurotensin degradation. Shortening the C-terminal end of the neurotensin molecule as well as substitutions in positions 8, 9, and 11 by D-amino acids strongly decreased the inhibitory potency of neurotensin. Among 20 natural peptides, only angiotensin I and the neurotensin-related peptides (xenopsin and neuromedin N) were found as potent as unlabeled neurotensin.     

Degradation of Neurotensin by Rat Brain Synaptic Membranes: Involvement of a Thermolysin-Like Metalloendopeptidase (Enkephalinase), Angiotensin-Converting Enzyme, and Other Unidentified Peptidases

Neurotensin was inactivated by membrane-bound and soluble degrading activities present in purified preparations of rat brain synaptic membranes. Degradation products were identified by HPLC and amino acid analysis. The major points of cleavage of neurotensin were the Arg8-Arg9, Pro10-Tyr11, and Tyr11-Ile12 peptide bonds with the membrane-bound activity and the Arg8-Arg9 and Pro10-Tyr11 bonds with the soluble activity. Several lines of evidence indicated that the cleavage of the Arg8-Arg9 bond by the membrane-bound activity resulted mainly from the conversion of neurotensin1-10 to neurotensin1-8 by a dipeptidyl carboxypeptidase. In particular, captopril inhibited this cleavage with an IC50 (5.7 nM) close to its K1 (7 nM) for angiotensin-converting enzyme. Thiorphan inhibited the cleavage at the Tyr11-Ile12 bond by the membrane-bound activity with an IC50 (17 nM) similar to its K1 (4.7 nM) for enkephalinase. Both cleavages were inhibited by 1,10-phenanthroline. These and other data suggested that angiotensin-converting enzyme and a thermolysin-like metalloendopeptidase (enkephalinase) were the membrane-bound peptidases responsible for cleavages at the Arg8-Arg9 and Tyr11-Ile12 bonds, respectively. In contrast, captopril had no effect on the cleavage at the Arg8-Arg9 bond by the soluble activity, indicating that the enzyme responsible for this cleavage was different from angiotensin-converting enzyme. The cleavage at the Pro10-Tyr11 bond by both the membrane-bound and the soluble activities appeared to be catalyzed by an endopeptidase different from known brain proline endopeptidases. The possibility is discussed that the enzymes described here participate in physiological mechanisms of neurotensin inactivation at the synaptic level.     

The Rat Neurotensin Receptor Expressed in Chinese Hamster Ovary Cells Mediates the Release of Inositol Phosphates

To study second messenger synthesis mediated by the cloned rat neurotensin receptor, we derived a cell line stably expressing this receptor. The cDNA clone of this receptor was subcloned into the pcDNA1neo expression vector. This construct was then used to transfect Chinese hamster ovary (CHO)-K1 cells. Colony clones, selected for resistance to antibiotic G-418 sulfate, were isolated and grown separately. Nineteen individual clones were screened for total [3H]neurotensin binding as an indication of neurotensin receptor expression. The clone (CHO-rNTR-10) showing the highest level of specific [3H]neurotensin binding was characterized further. With intact cells, the equilibrium dissociation constant (KD) for specific [3H]neurotensin binding was 18 nM, and the maximal number of binding sites (Bmax) was 900 fmol/mg of protein or 740 fmol/10(6) cells (approximately 4.4 x 10(5) sites on the cellular surface). Whereas the KD was similar to that found in other cellular systems, for example, the murine neuroblastoma clone N1E-115, the Bmax exceeded previously reported values. Incubation of intact CHO-rNTR-10 cells with neurotensin caused the release of inositol phosphates in a dose-dependent manner (EC50 = 3 nM), results indicating that the expressed transfected receptor was functional. Neurotensin did not inhibit cyclic AMP levels stimulated by forskolin. As with other systems, neurotensin (8-13) was more potent than neurotensin Neurotensin-mediated inositol phosphate release is the first report of second messenger synthesis for this receptor expressed in a transfected cell line. These results suggest that the relation between structure and function of the neurotensin receptor can be readily studied in transfected cell lines.     

High-resolution NMR studies of fibrinogen-like peptides in solution: interaction of thrombin with residues 1-23 of the A alpha chain of human fibrinogen

The interaction of the following human fibrinogen-like peptides with bovine thrombin was studied by use of one- and two-dimensional NMR techniques in aqueous solution: Ala(1)-Asp-Ser-Gly-Glu-Gly-Asp-Phe(8)-Leu-Ala-Glu-Gly-Gly-Gly-Val-Arg(16 )- Gly(17)-Pro-Arg(19)-Val(20)-Val-Glu-Arg (F10), residues 1-16 of F10 (fibrinopeptide A), residues 17-23 of F10 (F12), residues 1-20 of F10 (F13), residues 6-20 of F10 with Arg(16) replaced by a Gly residue (F14), and residues 6-19 of F10 with Arg(16) replaced by a Leu residue (F15). At pH 5.3 and 25 degrees C, the Arg(16)-Gly(17) peptide bonds of both peptides F10 and F13 were cleaved instantaneously in the presence of 0.6 mM thrombin, whereas the cleavage of the Arg(19)-Val(20) peptide bonds in peptides F12, F13, and F14 took over 1 h for completion. On the basis of observations of line broadening, fibrinopeptide A was found to bind to thrombin. While resonances from residues Ala(1)-Glu(5) were little affected, binding of fibrinopeptide A to thrombin caused significant line broadening of NH and side-chain proton resonances within residues Asp(7)-Arg(16). There is a chain reversal within residues Asp(7)-Arg(16) such that Phe(8) is brought close to the Arg(16)-Gly(17) peptide bond in the thrombin-peptide complex, as indicated by transferred NOEs between the aromatic ring protons of Phe(8) and the C alpha H protons of Gly(14) and the C gamma H protons of Val(15). A similar chain reversal was obtained in the isolated peptide F10 at a subzero temperature of -8 degrees C. The titration behavior of Asp(7) in peptide F13 does not deviate from that of the reference peptide, N-acetyl-Asp-NHMe at both 25 and -8 degrees C, indicating that no strong interaction exists between Asp(7) and Arg(16) or Arg(19). Peptides with Arg(16) replaced by Gly and Leu, respectively, i.e., F14 and F15, were also found to bind to thrombin but with a different conformation, as indicated by the absence of the long-range NOEs observed with fibrinopeptide A. Residues Asp(7)-Arg(16) constitute an essential structural element in the interaction of thrombin with fibrinogen.     

Preparation of a pure monoiodo derivative of the bee venom neurotoxin apamin and its binding properties to rat brain synaptosomes

The preparation and purification of an active monoiodo derivative of apamin is described. Radiolabeled monoiodoapamin (2000 Ci/mmol) binds specifically to rat brain synaptosomes at 0 degrees C and pH 7.5 with a second order rate constant of association (ka = 2.6 x 10(7) M-1 s-1) and a first order rate constant of dissociation (kd = 3.8 x 10(-4) s-1). The maximal binding capacity is 12.5 fmol/mg of protein and the dissociation constant is 15-25 pM for the monoiodo derivative and 10 pM for the native toxin. The apamin receptor is destroyed by proteases suggesting that it is of a proteic nature. Neurotensin and its COOH-terminal partial sequences are the only molecules unrelated to apamin that are able to displace monoiodoapamin from its receptor at low concentrations. Half-displacement occurs at 170 nM neurotensin. This property is due to the presence in the COOH-terminal sequence of neurotensin of two contiguous arginine residues, a structure analogous to that of the apamin active site. The binding of monoiodoapamin to its receptor is sensitive to cations. Increasing K+ or Rb+ concentrations from 10 microM to 5 mM selectively enhances the binding by a factor of 1.8. Increasing the concentration of any cation from 1 to 100 mM completely inhibits iodoapamin binding. Both effects are due to a cation-induced modulation of the affinity of monoidoapamin for its receptor without any change of the maximal toxin binding capacity of synaptosomes. Guanidinium and molecules containing a guanidinium group are better inhibitors of iodoapamin binding than other inorganic cations or positively charged organic molecules.     

The pH-dependent subunit dissociation and catalytic activity of bovine dopamine beta-hydroxylase

The soluble form of dopamine beta-hydroxylase from bovine adrenal medulla has previously been shown to exist as a tetrameric species of Mr = 290,000 composed of two disulfide-linked dimers. Here we report that this enzyme can also undergo a reversible tetramerdimer dissociation which is dependent on pH. Gel permeation chromatography of dopamine beta-hydroxylase at pH 5.0 demonstrates a Stokes radius of 5.8 nm. When the pH is shifted to 5.7, the Stokes radius changes to 6.9 nm. Sedimentation equilibrium analysis of the purified enzyme demonstrates that this change in molecular size is due to a change in molecular weight. At low protein concentration, the estimated Mr of the enzyme is 145,000 at pH 5.0 and at high protein concentration approaches 290,000 at pH 5.7. This change in Mr is consistent with the existence of a tetramer-dimer dissociation and a change in the equilibrium constant from 1.8 X 10(-6) M to 1.16 X 10(-9) M when the pH is increased from 5.0 to 5.7. This pH-dependent subunit dissociation is correlated with pH-dependent changes in enzyme activity. Purified bovine-soluble dopamine beta-hydroxylase activity is a hyperbolic function of tyramine concentration at pH 5.0. However, the hydroxylase activity displays non-hyperbolic kinetics at pH 6.0. The kinetic data obtained at pH 6.0 can be accounted for by fitting to a model containing two nonidentical catalytic forms of enzyme generated by the pH-dependent partial dissociation of tetrameric enzyme to dimeric subunits. The two catalytic forms have apparently identical maximal velocities; however, they differ in their Michaelis constants for the substrate; the dimeric form having a low Km and the tetrameric form having a high Km. Since the pH inside bovine adrenal medullary chromaffin granules is approximately 5.5, we conclude that the subunits of dopamine beta-hydroxylase are in dynamic dissociation in a physiologically important pH range.     

Interaction between cytochrome C and di- and tripeptides.

By observing changes in the absorbance spectrum between 340 and 650 nm, we found that tyrosyltyrosylphenylalanine (TTP) interacts with cytochrome C (CC). TTP caused the characteristic changes of CC reduction, namely, an increased optical density at 524 and 550 nm and a hyperchromic shift at 416 nm. The apparent dissociation constant (Kd) was 2.9 x 10(-3) M. Most of the reducible CC at 20 uM concentration was reduced by 10 mM TTP. TTP was more potent than all other peptides tested, including the previously reported tyrosylphenylalanine. That the carboxyl terminal phenyl group was essential for reduction was shown by comparing variously substituted di- and tripeptides. Reduction by TTP increased with increasing pH and buffer concentration at constant pH. A combination of superoxide dismutase and catalase failed to inhibit the reduction. We found no effect of TTP on O2 consumption of isolated intact mitochondria. Our data demonstrate that small peptides can serve as probes of the topography and electron density of CC and that the TTP-CC interaction may provide insight as an analog of in-vivo processes.     

Brain Endo-Oligopeptidase A, a Putative Enkephalin Converting Enzyme

Endo-oligopeptidase A, highly purified from the cytosol fraction of bovine brain by immunoaffinity chromatography, has been characterized as a thiol endopeptidase. This enzyme, known to hydrolyze the Phe5-Ser6 bond of bradykinin and the Arg8-Arg9 bond of neurotensin, has been shown to produce, by a single cleavage, Leu5-enkephalin or Met5-enkephalin from small enkephalin-containing peptides. Enkephalin formation could be inhibited in a concentration-dependent manner by the alternative substrate bradykinin. The optimal substrate size was found to be eight to 13 amino acids, with enkephalin the only product released from precursors in which this sequence is immediately followed by a pair of basic residues. However, the specificity constants (kcat/Km) obtained for endo-oligopeptidase A hydrolysis of bradykinin, neurotensin, and dynorphin B are of the same order, a result indicating that the substrate amino acid sequence is not the only factor determining the cleavage site of this enzyme.     

Structure-activity relationships in tryptophanyl transfer ribonucleic acid synthetase from beef pancreas. Influence of the alkylation of the sulfhydryl groups on the dimer-monomer equilibrium.

Upon reaction with N-ethylmaleimide, tryptophanyl-tRNA synthetase from beef pancreas dissociates into subunits. At pH7, the rate of the dissociation is close to both the reaction rate of the buried--SH groups and the rate of inactivation (Iborra, F., Mourgeon, G., Labouesse B., and Labouesse, J. (1973) Eur. J. Biochem. 39, 547-556). The pH and enzyme concnetration dependences of the reaction rate of the 16 cysteinyl residues of the enzyme as well as that of its inactivation support the idea that inactivation by alkylation of the--SH groups is due essentially to the dissociation of the protein into inactive subunits and not to the chemical blocking of a catalytic residue. This is confirmed by the independence on N-ethylmaleimide concentration of the reaction of the buried--SH groups and of the inactivation of the enzyme at high N-ethylmaleimide concentration. The dissociation becomes in this case the rate-limiting step of the chemical reaction. The monomeric structure is stabilized by the blocking of the--SH groups exposed during the dissociation. The dissociation constant of the dimeric enzyme is progressively increased during the alkylation. The tightness of the associated structure depends on the protonation of groups titrating between pH 7 and pH 9.     

Different Interactions of Prolyl Oligopeptidase and Neurotensin in Dopaminergic Function of the Rat Nigrostriatal and Mesolimbic Pathways

Prolyl oligopeptidase (PREP) is an intracellular enzyme digesting small proline-containing peptides. Since PREP resides the same brain areas as neurotensin in the nigrostriatal and mesolimbic dopaminergic pathways, we were interested to study if there is an intracellular interaction between them. A colocalization of PREP with neurotensin and neurotensin receptor 1 (NTS1) in the rat striatum, nucleus accumbens (NAcc), substantia nigra (SN) and ventral tegmental area (VTA) was studied with immunofluorescence. From the same brain areas, the levels of dopamine and its metabolites were measured 1 h after the injection of saline, NTS1 ligands (JMV-449; 5 μg) or antagonist (SR142948; 5 μg) to the rat striatum or NAcc. We also studied whether an intraperitoneal injection of a PREP inhibitor (KYP-2047; 5 mg/kg) affects the levels of dopamine and its metabolites alone or modifies the effects of the NTS1 ligands. PREP was highly colocalized with neurotensin and NTS1 in the VTA, and with NTS1 in the SN. Colocalization was moderate or low in other brain areas. When injected to the striatum, JMV-449 had a tendency to increase dopamine (p = 0.052) and metabolite levels in the striatum and SN, whereas SR142948 did not. After the injection to the NAcc, JMV-449 but not SR142948, increased dopamine levels in the VTA and dopamine metabolite levels in the NAcc and VTA. KYP-2047 decreased the dopamine levels in the striatum, but increased dopamine metabolite levels in the NAcc and VTA. Our results suggest a novel role for PREP in the modulation of dopaminergic transmission, which may be different in nigrostriatal and mesolimbic pathways.     

Probing the relationship between alpha-helix formation and calcium affinity in troponin C: 1H NMR studies of calcium binding to synthetic and variant site III helix-loop-helix peptides

Three 34-residue peptides corresponding to the high-affinity calcium-binding site III and two variant sequences from the muscle protein troponin C (TnC) were synthesized by solid-phase techniques. The two variant 34-residue peptides had amino acid modifications at either the coordinating positions or both the coordinating and noncoordinating positions, which corresponded to the residues found in the low-affinity calcium-binding site II of TnC. High-field 1H NMR spectroscopy was used to monitor calcium binding to each peptide to determine the effect these amino acid substitutions had on calcium affinity. The dissociation constant of the native site III peptide (SCIII) was 3 x 10(-6) M, smaller than that of the peptide incorporating the ligands from site II (LIIL), 8 x 10(-6) M, and that with the entire site II loop (LII), 3 x 10(-3) M, which bound calcium very weakly. These calcium dissociation constants demonstrate that very minor amino acid substitutions have a significant effect on the dissociation constant and give some insight into why the dissociation constants for site III and IV in TnC are 100-fold smaller than those for sites I and II. The results suggest that the differences in coordinating ligands between sites II and III have very little effect on Ca2+ affinity and that the noncoordinating residues in the site II loop are responsible for the low affinity of site II compared to the high affinity of site III in TnC.     

Synthesis of arginine-containing peptides and their conjugates with protohemin IX and tetraphenylporphyrin

Arg-containing peptides and their conjugates with protohemin IX were synthesized by the solid phase method using Merrifield resin. The conjugates of Arg-containing peptides with tetraphenylporphyrin were obtained by using phosphorus trichloride as an activating agent.