Dopaminergic Regulation of Enkephalin Release

The effects of dopamine receptor stimulation on enkephalin release were evaluated in vitro and in vivo by measuring the changes in the levels of [Met5]enkephalin (YGGFM) and Tyr-Gly-Gly (YGG), a characteristic extracellular enkephalin metabolite produced under the action of enkephalinase. In rat striatal slices, D1-receptor agonists or antagonists did not modify enkephalin release. By contrast, D2-receptor agonists enhanced the potassium-induced release of YGGFM and YGG without affecting spontaneous release from nondepolarized slices. This response was prevented by the D2-receptor antagonists haloperidol and RIV 2093, the latter compound being more potent, which suggested the involvement of a putative D2-receptor subtype. Acute administration of apomorphine or selective D2-receptor agonists, but not that of a D1-receptor agonist, enhanced the steady-state level of YGG without affecting the YGGFM level in rat striatum. The effect was blocked selectively by D2-receptor antagonists which, administered alone, had no effect. These observations indicate that D2-receptor stimulation in vitro or in vivo facilitates enkephalin release from striatal neurons, but that endogenous dopamine does not exert any tonic influence upon the opioid peptide neuron activity under basal conditions. However, chronic administration of haloperidol resulted in increases in striatal YGGFM and YGG, an effect presumably reflecting a long-term adaptive process.     

Changes in levels of the tripeptide Tyr-Gly-Gly as an index of enkephalin release in the spinal cord: effects of noxious stimuli and parenterally-active peptidase inhibitors

The tripeptide Tyr-Gly-Gly (YGG), representing the product of enkephalin hydrolysis by enkephalinase (EC 3.4.24.11), was characterized and its levels measured in spinal cord perfusates of halothane-anaesthetized rats. During noxious pinching of the muzzle, which is known to trigger enkephalin release, YGG levels were enhanced more markedly and for longer than were those of [Met5]enkephalin (YGGFM), in the same samples. By contrast, neither YGG nor YGGFM levels were affected by pinching the tail. Treatment with carbaphethiol, a parenterally-active aminopeptidase inhibitor, markedly increased YGG levels and lengthened the duration of the increase produced by pinching the muzzle. Treatment with acetorphan, a parenterally-active enkephalinase inhibitor, given alone or in combination with carbaphethiol, completely prevented the rise in YGG triggered by noxious stimulation. By contrast, [Met5]enkephalin levels in the perfusates were increased by the combined administration of the two peptidase inhibitors but these levels were not further enhanced by noxious stimulation. Thus, spinal cord YGG appears to be formed under the influence of enkephalinase and to constitute a sensitive index of enkephalin release.     

Haloperidol-Induced Increase in Striatal Concentration of the Tripeptide, Tyr-Gly-Gly, Provides an Index of Increased Enkephalin Release In Vivo

A sensitive and specific radioimmunoassay has been developed for the tripeptide, Tyr-Gly-Gly, which has been shown previously to be an extraneuronal metabolite of opioid peptides derived from proenkephalin A. Using this assay, we found a regional variation in Tyr-Gly-Gly immunoreactivity in rat brain, with highest levels in striatum and lowest in cerebral cortex. Intracerebroventricular administration of the aminopeptidase inhibitor, bestatin; produced a threefold increase in Tyr-Gly-Gly immunoreactivity in rat striatum, whereas thiorphan, an enkephalinase inhibitor, produced a 45% reduction in striatal Tyr-Gly-Gly immunoreactivity. These data suggest that the tripeptide, Tyr-Gly-Gly, is in a dynamic state in the brain, and provide further support for the hypothesis that its concentration in specific brain areas may reflect the release of endogenous enkephalins in these brain areas. Further confirmation of the validity of measurements of brain Tyr-Gly-Gly as indices of enkephalin release under conditions of altered neuronal activity was provided by our demonstration that chronic dopamine receptor blockade with haloperidol increased striatal concentrations of both Met-enkephalin and Tyr-Gly-Gly.     

Proteolytic conversion of [Met]enkephalin-Arg6-Gly7-Leu8 by brain synaptic membranes. Characterization of formed peptides and mechanism of proteolysis

The degradation of the enkephalin-containing octapeptide Tyr-Gly-Gly-Phe-Met-Arg-Gly-Leu (YGGFMRGL) was systematically investigated by incubating the peptide with synaptic membranes from rat striatum or with purified peptidases. The degradation products were derivatized with 4-dimethylamino-azobenzene-4'-isothiocyanate and then analyzed by high pressure liquid chromatography and by amino-terminal analysis. The incubation of YGGFMRGL with synaptic membranes yielded YGG, YGGF, YGGFM, and MR in a manner that was linear with respect to time. The corresponding carboxyl-terminal fragments FMRGL, MRGL, and RGL could not be detected, which suggests that the degradation of YGGFMRGL by synaptic membranes occurs by carboxypeptidase activity. The incubation of YGGFMRGL with different purified peptidases produced cleavage patterns unique from that seen with synaptic membranes. Enkephalinase recognized only the Gly-Phe bond to produce YGG and FMRGL. Thermolysin recognized the Gly-Phe bond and the Phe-Met bond to yield YGG, YGGF, FMRGL, and MRGL. Angiotensin-converting enzyme (ACE) produced primarily YGGF, MR, and lesser amounts of YGGFMR and YG. The formation of YGG, YGGF, and YGGFM by synaptic membranes could be stimulated 3-fold by the addition of 30 mM NaCl and inhibited by MK-422, an ACE inhibitor, with an IC50 of 3 nM. These data suggest that ACE, a dipeptidyl carboxypeptidase, is the primary enzyme involved in the degradation of YGGFMRGL in brain. ACE apparently works in concert with another carboxypeptidase in brain to yield YGGFM and YGG since the carboxyl-terminal peptides RGL and FMRGL could not be detected.     

Cyclic enkephalin analogs that are hybrids of DPDPE-related peptides and metenkephalin-Arg-Gly-Leu: prohormone analogs that retain good potency and selectivity for delta opioid receptors.

We report here on the binding affinity and bioassay results of cyclic enkephalin analogs comprising a cyclic moiety and C-terminal fragment of MERGL, where ME denotes methionine enkephalin. MERGL (YGGFMRGL) has been suggested to be cleaved enzymatically by membrane-bound enkephalinase 24.11 to leave ME and the tripeptide RGL. In our study we have synthesized hybrids of DPDPE or DPLCE and the C-terminal tripeptide RGL in order to mimic a prohormone able to cross the blood-brain barrier. The study has shown that of the homologs presented here, analogs of DPLCE often are more potent at delta opioid receptors both in binding affinity and in bioactivity at the MVD, than DPDPE. Our hypothesis that hybrids (consisting of the drug and the spacer for the carrier) could be designed which would either have no opioid activity or, alternatively, be by themselves very active, has been verified.     

Peptidases that terminate the action of enkephalins. Consideration of physiological importance for amino-, carboxy-, endo-, and pseudoenkephalinase

The term "enkephalinase" has been frequently applied to enzyme activity in a variety of tissue preparations. In some cases there has been the implication that cleavage of a specific peptide bond in the enkephalin molecule results from the action of a single enzyme with the major responsibility of inactivating synaptic enkephalin. It is not known to what extent diverse enkephalin-degrading enzymes, with differing peptide bond specificities, may act in concert at any given synapse. There do exist, however, enzymes having known characteristic specificities with respect both to peptide substrates, including enkephalins, and to identifiable peptide bonds. Thus, at any given site of enkephalin release there probably resides a characteristic assembly of peptidases concerned with inactivation of this neuromediator. We propose that the term "enkephalinase" be used to encompass the entire family of enkephalin-degrading enzymes, and that "aminoenkephalinase", "carboxyenkephalinase", "endoenkephalinase" and "pseudoenkephalinase" should designate enzymes of known specificities with respect to both peptide substrates and particular peptide bonds.     

Tyrosine Hydroxylase Regulation: Apparent Kinetic Alterations Following Incubation of Brain Slices in a Sodium-free Medium

In an attempt to determine if alterations in intraneuronal Ca2+ may regulate tyrosine hydroxylase activity, brain slices were subjected to experimental manipulations known to increase the intraneuronal concentration of free Ca2+ ions. Incubation of either striatal or olfactory tubercle slices in a Na+-free medium for 15 min at 37 degrees resulted in a marked increase in the activity of tyrosine hydroxylase present in the 20,000 g supernatant fraction of homogenates prepared from the slices. Tyrosine hydroxylase isolated from slices previously incubated in a Na+-free, choline-enriched medium or in a Na+-free, sucrose-enriched medium exhibited maximal activities when assayed at pH 6.0 and 7.0, respectively. However, the percentage stimulation of enzyme activity induced by incubation of the slices in a Na+-free medium was maximal when the enzyme assays were performed at pH 7.0. The observed increase in enzyme activity seems to be mediated by a decrease in the apparent Km of the enzyme for pteridine cofactor, regardless of whether the kinetic enzyme analyses were conducted at pH 6.0 or 7.0, and by an increase in the Ki of the enzyme for end-product inhibitor dopamine. The apparent kinetic changes in the enzyme do not seem to result from alterations in the endogenous dopamine content of the slices, and they are independent of any increase in dopamine release that might have occurred as a response to the augmented intraneuronal Ca2+ concentration. Furthermore, the activation of tyrosine hydroxylase produced by incubating slices in a Na+-free medium is observed even in slices depleted of dopamine by pretreatment of rats with reserpine 90 min before preparation of brain slices. The activation of tyrosine hydroxylase observed under these experimental conditions does not seem to be mediated by cAMP or by a cAMP-dependent phosphorylation process. It is suggested that the changes in tyrosine hydroxylase reported are mediated primarily by a rise in the free Ca2+ concentration within the nerve tissue. These observations are consistent with the hypothesis that the kinetic activation of tyrosine hydroxylase produced after depolarization of central dopaminergic neurons may occur through a Ca2+-dependent even other than transmitter release.     

GABA-opioid interactions in the globus pallidus: [D-Ala2]-Met-enkephalinamide attenuates potassium-evoked GABA release after nigrostriatal lesion

The motor signs of Parkinson's disease have been partly attributed to an overinhibition of the external globus pallidus (GP) that results from hyperactivity of striatopallidal GABA/enkephalinergic neurons. The goals of this study were to measure basal levels of extracellular fluid GABA in the GP of normal cats, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-treated parkinsonian cats and cats spontaneously recovered from MPTP-induced parkinsonism, and to examine the effects of opioid receptor activation on potassium (K+)-evoked GABA release in the GP in these animals. Basal GP GABA levels were increased 75% from normal in parkinsonian animals 1 week after MPTP administration and returned to control levels in recovered animals 6 weeks after MPTP administration. No significant differences were observed in K+-evoked GABA release across conditions. The opioid receptor agonist [D-Ala2]-Met-Enkephalinamide (DALA) significantly attenuated K+-evoked GABA release in the GP of MPTP-treated symptomatic and recovered cats, but had no significant effect on GABA release in normal animals. These data show that basal GP GABA levels are elevated coincident with expression of parkinsonian signs and return to normal in animals that have functionally compensated for a nigrostriatal lesion. DALA-induced inhibition of pallidal GABA release after a dopamine-depleting lesion, suggests that enkephalin may attenuate GABA release in the GP specifically after striatal dopamine loss.     

Regional release of [3H]dopamine from rat brain in vitro: effects of opioids on release induced by potassium, nicotine, and L-glutamic acid

Previous studies have suggested that the release of dopamine (DA) in the rat brain may be sensitive to modulation by opioid agents, including the endogenous opioid peptides (enkephalins and endorphins). The present study examined the effects of morphine and the enkephalin analogue D-Ala2-Met5-enkephalinamide (DALA) on the release of radiolabeled DA from superfused slices of rat brain regions. The release of preloaded [3H]DA was evoked from slices of the caudate-putamen (CP) by application of potassium (K+), nicotine (NIC), or L-glutamic acid (L-GLU). The release of [3H]DA from slices of the nucleus accumbens (NA), olfactory tubercle (OT), and substantia nigra (SN) was evoked by L-GLU. Both K+ and NIC evoked a concentration-related release of [3H]DA from CP slices. K+-induced release was only partially dependent on calcium (Ca2+), while NIC-evoked release was completely Ca2+ independent. Neither morphine nor DALA influenced the release of [3H]DA evoked by K+ or NIC. L-GLU produced a concentration-dependent release of [3H]DA from slices of CP, NA, OT, and SN. In all four brain regions, this release was (a) Ca2+-dependent, (b) strongly inhibited by low concentrations of magnesium (Mg2+), (c) greater than the release evoked by D-GLU, (d) attenuated by the putative L-GLU receptor antagonist glutamic acid diethylester (GDEE), and (e) insensitive to tetrodotoxin (TTX) except in the SN. Morphine produced a significant inhibition of L-GLU-evoked [3H]DA release from all four regions. Naloxone, which by itself had no significant effect on the L-GLU-evoked release of [3H]DA, blocked the inhibitory effect of morphine on this release in the CP but not in the other regions. Levorphanol and dextrorphan were equipotent in reducing the glutamate-stimulated release of [3H]DA from CP slices. DALA had no effect on L-GLU-induced release in any of the brain regions examined. The results indicate that L-GLU provokes regional release of DA by acting at a Mg2+-sensitive glutamate receptor. This release is selectively modified by morphine through a mechanism which is insensitive to naloxone.     

Sustained potentiation of NMDA receptor-mediated glutamate responses through activation of protein kinase C by a mu opioid.

mu opioids, such as morphine and certain enkephalin analogs, are known to modulate glutamate-evoked activity in dorsal horn neurons in the spinal cord and caudal brain stem. Yet the molecular mechanism by which this modulation occurs is not understood. We examined the interactions between glutamate and a selective mu opioid receptor agonist, D-Ala2-MePhe4-Gly-ol5-enkephalin (DAGO), in spinal trigeminal neurons in thin medullary slices of rats. DAGO caused a sustained increase in glutamate-activated currents that are mediated by N-methyl-D-aspartate receptors. Intracellularly applied protein kinase C (PKC) mimics the effect of DAGO, and a specific PKC inhibitor interrupts the sustained potentiation produced by DAGO. Thus, PKC plays a key role in mediating the action of mu opioid peptides.     

Degradation of enkephalins: the search for an enkephalinase

Summary The opioid peptides methionine-enkephalin and leucine-enkephalin appear to exert their biological effects through a receptor mediated mechanism. There appears to be three potential mechanisms for enkephalin degradation which could serve to control enkephalin levels in the vicinity of enkephalin receptors. These are, 1) cleavage of the tyrosyl-glycine bond by aminopeptidases, 2) cleavage of the glycyl-glycine bond by a dipeptidyl aminopeptidase, and 3) cleavage of the glycyl-phenylalanine bond by a dipeptidyl carboxypeptidase. In this review the biochemical properties of these potential enkephalinases are described, and the evidence for each acting as an enkephalinase is reviewed.     

Effect of inhibitors of enkephalin degradation in the isolated guinea-pig ileum

Bestatin and high concentration of puromycin increase the depressing effect of [Met] enkephalin on the twitch response of the electrically stimulated guinea-pig ileum. Thiorphan (enkephalinase A inhibitor) is hardly effective, but phelorphan (mercapto-acetyl-Phe-Phe) a newly synthesized enzyme-inhibitor which effectively inhibits the enkephalinase A, enkephalinase B and soluble aminopeptidase activity, potentiates the effect of enkephalin dose-dependently and in low concentrations (0.01-1 microM). Enkephalinase A, though present in these tissues, is not functional under the conditions of the test, because it is inhibited by the physiological buffer itself. These results demonstrate that enkephalinase B and the membrane bound aminopeptidase, but not the soluble aminopeptidase or enkephalinase A hydrolyse enkephalins in the isolated guinea-pig ileum.     

Alterations within the endogenous opioid system in mice with targeted deletion of the neutral endopeptidase ('enkephalinase') gene

The biological inactivation of enkephalins by neutral endopeptidase (enkephalinase, NEP, EC3.4.24.11) represents a major mechanism for the termination of enkephalinergic signalling in brain. A pharmacological blockade of NEP-activity enhances extracellular enkephalin concentrations and induces opioid-dependent analgesia. Recently, knockout mice lacking the enzyme NEP have been developed [Lu et al., J. Exp. Med. 1995;181:2271-2275]. The present study investigates the functional consequences and biochemical compensatory strategies of a systemic elimination of NEP activity in these knockout mice. Using biochemical and behavioural tests we found that the lack of NEP activity in brain is not compensated by enhanced activities of alternative enkephalin-degrading enzymes. Also no change in enkephalin biosynthesis was detectable by in situ methods quantifying striatal proenkephalin-mRNA levels in NEP-deficient mice compared with wildtype. Only a 21% reduction of mu receptor density in crude brain homogenates of NEP knockout mice was observed, while delta- and kappa-opioid receptor densities were unchanged. This receptor downregulation was also confirmed functionally in the hot-plate paradigm. NEP knockouts developed normally, but showed enhanced aggressive behaviour in the resident-intruder paradigm, and altered locomotor activity as assessed in the photobeam system. Thus, although NEP plays a substantial role in enkephalinergic neurotransmission, the biochemical adaptations within the opioid system of NEP-deficient mice are of only modest nature.     

Comparison of dipeptidyl carboxypeptidase and endopeptidase activities in the three enkephalin-hydrolysing metallopeptidases: "angiotensin-converting enzyme", thermolysin and "enkephalinase"

Angiotensin-converting enzyme (ACE), thermolysin and "enkephalinase", three metallopeptidases cleaving the Gly3-Phe4 amide bond of enkephalins, were compared regarding substrate specificity and effects of butanedione, an arginyl-directed reagent. The hydrolysis of enkephalins and analogues was more affected by the nature of P1 and P2 residues in the case of thermolysin than in those of ACE or "enkephalinase"; amidation of the C-terminal carboxylate decreased drastically the hydrolysis by ACE but only marginally by thermolysin and the effect was intermediate for "enkephalinase". With adequate model substrates, the ratio of dipeptidylcarboxypeptidase to tripeptidylcaroxypeptidase (endopeptidase) activities were of 25 for ACE, 3 for "enkephalinase" and only 0.3 for thermolysin. Finally a butanedione treatment increased thermolysin activity, but abolished ACE activity; it reduced "enkephalinase" activity by 80% when measured with a free C-terminal carboxylate enkephalin analogue but only slightly with the corresponding amidated derivative. A critical role of an Arg residue in ACE and, to a lesser extent, in "enkephalinase" (but not in thermolysin) is suggested to be responsible for the preferential dipeptidylcarboxypeptidase activity of these two enzymes.     

Ontogenesis of enkephalinergic systems in rat brain: Post-natal changes in enkephalin levels,receptors and degrading enzyme activities

The post-natal changes in enkephalin (ENK) levels, ENK receptor density and ENK degrading enzyme activities have been established in cerebral cortex and striatum. Met- and Leu-ENK levels both increase by 7- to 11-fold, but in an independent manner compatible with their presence in distinct neuronal systems. ³H-ENK binding sites increase only 4-fold in striatum, as reported for receptor sites labeled with ³H-opiate antagonists.The development of striatal “enkephalinase” i.e. of the particulate enzyme activity cleaving the Gly-Phe bond of ENKs is more of less parallel in time-course to that of ENK levels and receptors, with a 6-fold increase from birth. In contrast total ENK hydrolysing activity shows little change. The developmental pattern of angiotensin-converting enzyme (ACE) is clearly distinct from that of “enkephalinase”, thus confirming that the two enzymes are different species.     

Evidence that enzymatic conversion of N-[1(R,S)-carboxy-3-phenylpropyl]-Ala-Ala-Phe-p-aminobenzoate, a specific inhibitor of endopeptidase 24.15, to N-[1 (R,S)-carboxy-3-phenylpropyl]-Ala-Ala is necessary for inhibition of angiotensin converting enzyme

N-[1 (R,S)-Carboxy-3-phenylpropyl]-Ala-Ala-Phe-p-aminobenzoate (cFP-AAF-pAB) is a potent, substrate-related, specific inhibitor of endopeptidase 24.15, an enzyme involved in the metabolism of bioactive peptides including bradykinin, neurotensin, and proenkephalin, and prodynorphin-derived enkephalin precursors. The observation that this inhibitor causes a pronounced decrease in blood pressure after intravenous infusion into normotensive rats posed the question of the mechanism of this hypotensive response. It was suggested previously that cFP-AAF-pAB is an inhibitor of angiotensin converting enzyme (ACE) and that this function can account for the hypotensive response to the inhibitor. We present here evidence that cFP-AAF-pAB has no intrinsic ACE-inhibitory activity. The previously observed inhibition is shown to be dependent on cleavage of the Ala-Phe bond in the inhibitor by endopeptidase 24.11 (enkephalinase, EC 3.4.24.11), a contaminant of some ACE preparations.     

Opioid peptide effects on insulin release and c-AMP in islets of Langerhans

The time course and specificity of the effect of opioid peptides on c-AMP production in the islets of Langerhans was examined. An enkephalin analogue, d-Ala2Me Phe4 Met(O)-ol enkephalin (DAMME, Sandoz) produced a significant stimulation of basal c-AMP levels, with a peak of stimulation at 5 minutes and a decline thereafter. These changes in intracellular c-AMP levels were of the same order of magnitude as those induced by other secretagogues, but did not coincide in time with the more rapid peak of enkephalin-induced insulin release. The rise in islet c-AMP and insulin secretion induced by DAMME and alpha-endorphin but not leu enkephalin was antagonised by naloxone. The effects of high and low concentrations of a variety of opioid peptides and naloxone on insulin release and islet c-AMP levels were determined, alpha-endorphin, dynorphin, leu enkephalin and met enkephalin all stimulated insulin secretion significantly, though not to the same extent. Higher concentrations of alpha-endorphin, dynorphin and met enkephalin inhibited insulin release relative to effects at low opiate concentrations. However, higher concentrations of leu enkephalin stimulated insulin release further. We conclude from these results that the mode of action of opioid peptides in stimulating insulin release is not via increased islet c-AMP exclusively. Furthermore, the results obtained with different classes of opioid suggest the presence of distinctive types of opiate receptor in islets of Langerhans.     

Localization of the thiorphan-sensitive endopeptidase, termed enkephalinase A, on glial cells

Degradation of tritiated Leu-enkephalin was studied in cultures of primary astrocytes from rat brain. The incubation experiments with a cell suspension revealed Tyr as the main tritiated metabolite; however, Tyr-Gly-Gly and Tyr-Gly were detectable as well. Using a crude membrane preparation of the astrocytes, we found about equal amounts of Tyr and Tyr-Gly-Gly but only trace quantities of Tyr-Gly. The production of Tyr was completely inhibited by bestatin, an inhibitor of aminopeptidases, that of Tyr-Gly-Gly by thiorphan, a specific inhibitor of enkephalinase A. The results prove the ability of glial cells to degrade enkephalin by aminopeptidase and a membrane-bound enkephalinase A.     

Propioxatins A and B, new enkephalinase B inhibitors. IV. Characterization of the active site of the enzyme using synthetic propioxatin analogues

Propioxatins A and B are inhibitors of enkephalinase B, which hydrolyzes enkephalin at the Gly-Gly bond. In order to clarify the structure-activity relationships of propioxatin, several compounds were synthesized and their inhibitory activity for not only enkephalinase B but also enkephalinase A was examined. The hydroxamic acid group in propioxatin was primarily essential for coordinating the metal ion in the active site of the enzyme. Among devalyl propioxatin A derivatives, the proline-containing compounds inhibited enkephalinase B and others inhibited both enzymes. An alteration of the character of the P3' amino acid valine in propioxatin A, e.g. amidation of carboxylic acid or replacement of the side chain, caused a 2 to 400-fold decrease of the inhibitory activity for enkephalinase B or an appearance of enkephalinase A inhibition with Ki values in the micromolar range. Substitution of the proline by alanine also resulted in a 1,000-fold loss of inhibitory activity for enkephalinase B. Propioxatin A was the most potent and specific inhibitor of enkephalinase B among the synthesized compounds. These potent and specific inhibitory effects were caused by the P2' proline residue, the P3' valine side chain and its free carboxylic acid. Each of the S1', S2', and S3' subsites in an enkephalinase B active site has a large and hydrophobic pocket, but the arrangement might be unique. The results could explain why enkephalinase B does not hydrolyze longer peptides.     

Detection of the tripeptide Tyr-Gly-Gly, a putative enkephalin metabolite in brain, using a sensitive radioimmunoassay

A sensitive and specific radioimmunoassay has been developed for YGG. The tripeptide was previously derivatised with p-benzoquinone to prepare the immunogen and the 125I tracer as well as in samples submitted to the RIA. The sensitivity is about 1 nM as compared with 8000 nM for underivatised YGG. Measurable amounts of endogenous YGG immunoreactivity, co-eluting in HPLC with authentic YGG, were detected in mouse striatal extracts.