Nazarius S. Lamango

l-Dopa Upregulates the Expression and Activities of Methionine Adenosyl Transferase and Catechol-O-Methyltransferase

High nonphysiological doses of l-dopa are administered to Parkinsons disease (PD) patients, to replenish the depleted dopamine (DA). A large portion of the administered L-dopa and the newly formed DA undergoes methylation by reacting with S-adenosyl-L-methionine (SAM). In the process SAM, as well as L-dopa and DA, is utilized and great demands are placed on the transmethylation system. In this study we investigated whether L-dopa increases the transmethylation process by inducing methionine adenosyl transferase (MAT), the enzyme that produces SAM, and catechol-O-methyl transferase (COMT), the enzyme that transfers the methyl group from SAM to L-dopa and DA. Swiss Webster mice were injected with L-dopa, four times/day, for 1 to 16 days. Brain DA, 3-O-methyldopa (3-OMD), SAM, S-adenosylhomocysteine (SAH), MAT, and COMT were measured following a 24-h withdrawal period. An increase of 264% of brain DA occurred at days 2 and 3 after which it tapered to about 164% of control. The brain level of 3-OMD increased to 870% of the control. SAM was increased by 44% after the sixth day and SAH level was about double after the second day. After day 3, MAT activity was increased by about 35%. Western blot analysis showed that MAT is more clearly characterized in 10% mercaptoethanol reducing buffer in which 31.5-, 38- (beta), and 48-kDa (alpha1/alpha2) subunits were distinctly revealed. The induction of the 38-kDa and, more prominently, the 48-kDa subunits of MAT and the potential transactivator proteins of MAT, c-Jun/AP-1, was evident by day 6. The 31.5-kDa subunit was downregulated. COMT was detected as 24.7-, 30-, and 47.5-kDa bands in the brain, consistent with the membrane-bound COMT I (MB-COMT) and the dimeric COMT II. The 24.7- and the 30-kDa MB-COMT bands were induced in the brain by day 6 and peaked on day 9. The highlight of the study is the fact that L-dopa induces the enzymes MAT and COMT. In addition, the downturn in brain DA after the sixth day coincides with the increase in SAM and the 48-kDa MAT protein. Thus, during PD treatment with L-dopa the induction of MAT and COMT is likely to occur and in turn increase the methylation and reduction of L-dopa and DA that may help cause the tolerance or the wearing-off effect developed to L-dopa.

The potentiating effects of 1-methyl-4-phenyl-1,2,3,6 -tetrahydropyridine (MPTP) on paraquat-induced neurochemical and behavioral changes in mice

Although the etiology of Parkinsons disease (PD) is not fully understood, there are numerous studies that have linked the increased risk for developing PD to pesticides exposure including paraquat (PQ). Moreover, the exposure to a combination of compounds or chemical mixtures has been suggested to further increase this risk. In the current study, the effects of PQ on the nigrostriatal dopaminergic system in male C57BL6 mice exposed to 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) were examined to assess the impact of toxic substance mixtures exposure on neurochemical and behavioral changes. In this study, a low non-toxic dose of MPTP (10mg/kg) was injected once a day for 5 days and was followed by PQ (7 mg/kg) once a day for 6 days (subacute protocol) or once a week for 10 weeks (chronic protocol). The results from the subacute protocol showed that PQ reduced the turnover of dopamine (DA) as indicated by a 21% and a 22.3% decrease in dihydroxyphenyl acetic acid (DOPAC), homovanillic acid and increased S-adenosyl methionine/S-adenosyl homocysteine index (SAM/SAH) by 100%. However, the administration of PQ to MPTP primed mice resulted in the decrease of DOPAC, HVA, DA, by 35.8%, 35.2% and 22.1%, respectively. In addition, PQ decreased the total number of movements (TM) by 28% but MPTP plus PQ decreased TM by 41%. The SAM/SAH index showed that MPTP increased methylation by 33.3%, but MPTP plus PQ increased methylation by 81%. In the chronic protocol, the data showed that MPTP administration did not affect DA, DOPAC, and HVA levels. The administration of PQ led to significant decrease in DOPAC, HVA, and TD by 31.6%, 19.9%, and 21.2% respectively with no effect on DA levels. The MPTP plus PQ group showed reduced DA, DOPAC, HVA, and total distance traveled by 58.4%, 82.8%, 55.8%, and 83.9%, respectively. Meanwhile, PQ administration caused a reduction in tyrosine hydroxylase immunoreactivity in the substantia nigra, and this effect was more pronounced in MPTP pretreated mice. It was concluded from this study that prior treatment with MPTP potentiated the effects of PQ in reducing DA, DOPAC, HVA, TH immunoreactivity, locomotor activity, and increasing the methylation index. The enhanced effects of PQ following MPTP administration further support the role of toxic substance mixtures in causing Parkinsons disease.

S‐adenosyl‐methionine‐induced apoptosis in PC12 cells

Our previous studies showed that S‐adenosyl‐methionine (SAM) induced Parkinsons disease‐like changes in rat. It caused death to dopamine neurons in the substantia nigra, which appeared shrunken and fragmented, indicative of apoptosis‐like changes (Charlton and Crowell [ 1995 ] Mol. Chem. Neuropathol. 26:269–284; Charlton [ 1997 ] Life Sci. 61:495–502). In this study, we investigated whether SAM causes apoptosis in both undifferentiated PC12 (PC12) cells and nerve growth factor (NGF)‐differentiated PC12 (D‐PC12) cells. S‐adenosyl‐homocysteine (SAH), the nonmethyl analog of SAM, was also tested. SAM and SAH (1.0 nM to 10.0 μM) caused lactate dehydrogenase (LDH) release from the PC12 cells and D‐PC12 cells; cells with morphological changes and fluorescent DNA fragmentation staining were detected among both PC12 cell and D‐PC12 cell. Compared with the PC12 cell, the D‐PC12 cell, a postmitotic cell, was more sensitive to the toxic effects of SAM or SAH and presented much greater LDH release, suggesting a lethal effect; surprisingly, the amounts of apoptotic cells did not differ significantly between the two kinds of cells. In medium deprived of exogenous methionine, a decline in LDH release was observed in PC12 and D‐PC12 cells. Also, lower levels of intracellular SAM and SAH were observed in the methionine‐deleted media, which were reversed by the addition of either SAM or SAH. An antivitamin B12 monoclonal antibody was added to methionine‐depleted medium, resulting in deficiency of both endogenous and exogenous methionine, which caused further decreases in LDH release and reduction in the levels of intracellular SAM and SAH. The preliminary data showed different sensitivities to SAM or SAH between PC12 cell and D‐PC12 cells, which suggests that PC12 cell may be more stable as a metabolic model. Apoptosis of PC12 cells was also assessed by PARP cleavage detection, Western blot analysis of Bax and Bcl‐2 proteins, and DNA laddering on agarose gel electrophoresis. The proapoptoic protein Bax was dominantly expressed, whereas Bcl‐2 was slightly down‐regulated by SAM. SAH weakly induced the expression of Bax and slightly decreased Bcl‐2 levels. The effects of SAM and its analog, SAH, were demonstrated conclusively to induce apoptosis in PC12 cells.

Farnesyl-l-Cysteine Analogs Block SAM-Induced Parkinson's Disease-Like Symptoms in Rats

Injection of the endogenous methyl donor, S-adenosyl methionine (SAM), into rat brain induces Parkinsons disease (PD)-like symptoms possibly by stimulating deleterious protein methylation. Gel-filtration chromatography of rat brain extracts treated with [3H-methyl]-SAM revealed the presence of radioactive peaks with apparent molecular weights of about 5 kDa. Treatment with guanidine HCl altered the elution volumes of the labeled peaks. Lyophilized peak fractions released volatile 3H-methanol on incubation with NaOH, indicating the presence of carboxyl methyl esters. Because prenylated proteins are avid methyl acceptors at the terminal carboxylic acid groups, 1 micromol S-farnesylcysteine (FC) analogs blocked the SAM-induced tremors in the experimental rats. FC analogs did not only reverse the associated rigidity, abnormal posture, and hypokinesia, but stimulated hyperactivity in the animals. This amphetamine-like effect was monitored for 20 min in an animal activity monitor and movement times between 400 +/- 100 and 560 +/- 125 s covering distances between 78 +/- 29 to 125 +/- 35 m were recorded for rats treated with FC analogs with or without SAM. Control animals moved only for 60 +/- 13 s covering about 6 +/- 1 m, indicating a 7-9-fold and 13-21-fold increase in duration of movement and distance covered, respectively. N-Acetyl-S-farnesylcysteine (AFC) potentiated amphetamine-induced ipsiversive rotation of 6-hydroxydopamine-lesioned rats from 390 +/- 130 to 830 +/- 110, with AFC alone having no significant effect on net rotation compared to controls. These data indicate that intracerebroventricular injection of SAM may induce PD symptoms by interfering with the methylation/demethylation homeostasis of prenylated proteins that function in the dopaminergic and other signaling pathways, and that the FC analogs may counteract the SAM effects by acting synergistically on events subsequent to neurotransmitter release.

6-Hydroxydopamine induces cystatin C-mediated cysteine protease suppression and cathepsin D activation

Alteration in the lysosomal system (LS) may represent a central mechanism in neurodegeneration. 6-Hydroxydopamine (6-OHDA) induces oxidative stress and cell death in catecholaminergic cells. The LS and caspases participate in apoptosis, although the mechanism(s) that is involved is not completely understood. Here, we show that Pheochromocytoma (PC12) cells exposed to 6-OHDA results in lysosomal dysregulation, caspase activation and cell death. Cells exposed to 6-OHDA increased expression and release of cystatin C (CC) and suppressed cathepsin B (CB). CB activity significantly declined 24h following exposure to 6-OHDA, however neutralization of CC restored CB activity. Cathepsin D (CD) and caspase-3 activity also increased following exposure to 6-OHDA. Inhibition of CD and caspase-3 with pepstatin A (PA) and DEVD-Cho, respectively, attenuated the 6-OHDA induced cell death at 48 and 72 h. However, the CB inhibitor CA-074 Me failed to protect cells. Additionally, poly-ADP-ribose polymerase (PARP) cleavage was evaluated after exposure to 6-OHDA and PA, CA-074 Me, and DEVD-Cho. Only DEVD-Cho significantly decreased PARP cleavage following exposure to 6-OHDA. Hence, caspase-3 mediated PARP cleavage following exposure to 6-OHDA appears independent of CB and CD alterations. These studies suggest alternate pathways and potential therapeutic targets of cell death associated with oxidative stress, CC, and lysosomal dysregulation.

Liver prenylated methylated protein methyl esterase is the same enzyme as Sus scrofa carboxylesterase.

The C‐terminal COOH of prenylated proteins is methylated to COOCH3. The COOCH3 ester forms are hydrolyzed by prenylated methylated protein methyl esterase (PMPMEase) to the original acid forms. This is the only reversible step of the prenylation pathway. PMPMEase has not been purified and identified and is therefore understudied. Using a prenylated‐L‐cysteine methyl ester as substrate, PMPMEase was purified to apparent homogeneity from porcine liver supernatant. SDS‐PAGE analysis revealed an apparent mass of 57 kDa. Proteomics analyses identified 17 peptides (242 amino acids). A Mascot database search revealed these as portions of the Sus scrofa carboxylesterase, a 62‐kDa serine hydrolase with the C‐terminal HAEL endoplasmic reticulum‐retention signal. It is at least 71% identical to such mammalian carboxylesterases as human carboxylesterase 1 with affinities toward hydrophobic substrates and known to activate prodrugs, metabolize active drugs, as well as detoxify various substances such as cocaine and food‐derived esters. The purified enzyme hydrolyzed benzoyl‐Gly‐farnesyl‐L‐cysteine methyl ester and hydrocinamoyl farnesyl‐L‐cysteine methyl ester with Michaelis–Menten constant (Km) values of 33 ± 4 and 25 ± 4 μM and Vmax values of 4.51 ± 0.28 and 6.80 ± 0.51 nmol/min/mg of protein, respectively. It was inhibited by organophosphates, chloromethyl ketones, ebelactone A and B, and phenylmethylsulfonyl fluoride.

The inhibitory role of methylation on the binding characteristics of dopamine receptors and transporter

Excess methylation has been suggested to play a role in the pathogenesis of Parkinsons disease (PD), since the administration of S-adenosylmethionine (SAM), a biological methyl donor, induces PD-like changes in rodents. It was proposed that SAM-induced PD-like changes might be associated with its ability to react with the dopaminergic system. In the present study the effects of SAM on dopamine receptors and transporters were investigated using rats and cloned dopamine receptor proteins. Autoradiographic examination of SAM indicated its tendency to be localized and accumulated in rat striatal region after the intracerebroventricular injection into rat brain. Moreover, results showed that SAM significantly decreased dopamine D1 and D2 receptor binding activities by decreasing the Bmax and increasing the Kd values. At concentrations of 0.1, 0.25 and 0.5 mM, SAM was able to reduce the Bmax from the control value of 848.1 for dopamine D1-specific ligand [3H] SCH 23390 to 760.1, 702.6 and 443.0 fmol/mg protein, respectively. At the same concentrations, SAM was able to increase the Kd values from 0.91 for the control to 1.06, 3.84 and 7.01 nM of [3H] SCH 23390, respectively. The effects of SAM on dopamine D2 binding were similar to those of dopamine D1 binding. SAM also decreased dopamine transporter activity. The interaction of SAM with dopamine receptor proteins produced methanol from methyl-ester formation and hydrolysis. We propose that the SAM effect might be related to its ability to react with dopamine receptor proteins through methyl-ester formation and methanol production following the hydrolysis of the carboxyl-methylated receptor proteins.

Inhibition mechanism of S-adenosylmethionine-induced movement deficits by prenylcysteine analogs.

We previously showed that S-adenosylmethionine (SAM) induces movement impairments similar to those observed in Parkinsons disease (PD) apparently by prenylated protein methylation; 5 kDa molecules being methylated and the symptoms being inhibited by prenylcysteine (PC) analogs. In the present study, we explore the biochemical mechanism of action of the PC analogs. N-acetylgeranylcysteine (AGC), N-acetylfarnesylcysteine (AFC), N-acetylgeranylgeranylcysteine (AGGC), farnesylthioacetic acid (FTA), farnesyl-2-ethanesulfonic acid (FTE) and farnesylsuccinic acid (FMS), but not farnesylthiotriazole (FTT) and farnesylthiolactic acid (FTL), inhibited the SAM-induced motor impairments. Incubation of the respective analogs with rat brain membranes containing prenylated protein methyltransferase (PPMTase) resulted in the methylation of AGC, AFC and AGGC. FTA, FTE, FMS and FTT, but not FTL, inhibited the enzyme activity. A single injection of the active analogs remained effective for at least 3 days against repeated injections of 1 micromol SAM. Amphetamine-induced hyperactivity in rats was inhibited by SAM but potentiated by FTE. During 60 min, the movement time for amphetamine-treated rats was 1477 s compared with 633 and 1664 s for amphetamine+SAM- and amphetamine+FTE-treated rats, respectively. The total distance for amphetamine+FTE-treated rats was 82% higher than for amphetamine. The horizontal activity was 30,728 (amphetamine), 15,430 (FTE), 18,526 (amphetamine+SAM), 41,736 (amphetamine+FTE) and 7004 (SAM) as compared to the PBS control (4726). The intricate relationship between the actions of SAM, which speeds up prenylated protein methylation and impairs movement, amphetamine, which increases synaptic dopamine levels and movement, and the PC analogs, which prevent the SAM-induced movement impairments, suggests a SAM-induced defect on dopamine signaling as the likely cause of the symptoms. The data reveal that interaction of PC analogs with PPMTase may not be an indicator of anti-PD-like activity.

Porcine Liver Carboxylesterase Requires Polyisoprenylation for High Affinity Binding to Cysteinyl Substrates

The polyisoprenylation pathway enzymes have been the focus of numerous studies to better understand the roles of polyisoprenylated proteins in eukaryotic cells and to identify novel targets against diseases such as cancer. The final step of the pathway is a reversible reaction catalyzed by isoprenyl carboxylmethyl transferase (icmt) whose products are then hydrolyzed by polyisoprenylated methylated protein methyl esterase (PMPMEase). Unlike the other pathway enzymes, the esterase has received little attention. We recently purified PMPMEase from porcine liver using an S-polyisoprenylated cysteine methyl ester substrate-dependent screening assay. However, no data is available showing its relative interaction with structurally diverse substrates. As such, its role as the putative endogenous PMPMEase has not been demonstrated. A series of substrates with S-alkyl substituents ranging from 2 to 20 carbons, including the two moieties found in polyisoprenylated proteins, were synthesized. Enzyme kinetics analysis revealed a 33-fold increase in affinity (K(M) values) from ethyl- (C-2, 505+/-63 microM), prenyl- (C-5, 294+/-25 microM), trans-geranyl- (C-10, 87+/-12 microM), trans, trans-farnesyl- (C-15, 29+/-2.2 microM) to all trans-geranylgeranyl- (C-20-, 15+/-2.7 microM) based analogs. Comparative molecular field analysis of the data yielded a cross-validated q(2) of 0.863+/-0.365 and a final R(2) of 0.995. Since the substrates with the S-trans, trans-farnesyl and S-all trans-geranylgeranyl moieties that occur in proteins show the highest affinity towards PMPMEase and are not hydrolyzed by the cholinesterases, the results suggest that polyisoprenylated proteins are the endogenous substrates of this esterase. The results suggest design strategies for high affinity and selective inhibitors of PMPMEase.

Quantification of S-adenosylmethionine-induced tremors: a possible tremor model for Parkinson's disease.

Tremor is the most visible symptom of Parkinsons Disease (PD), and should be the appropriate parameter in models for its evaluation. Lack of reliable PD tremor models and methods to distinguish tremors from nontremor movements means that nontremor behavior such as rotation following basal ganglia damage are mostly used. Our laboratory has shown that S-adenosyl-methionine (SAM) injections into the brain of rats reliably produced tremors, rigidity, hypokinesia, and abnormal posture. Thus, SAM-induced tremors, when distinguished from nontremor activities, has the potential as a model for testing anti-PD agents. Tremor Monitor-recorded activity profiles of the rats injected with SAM showed low-amplitude signals interlaced with high-amplitude bursts of tremor episodes. Control activities were of low-medium amplitudes with no such patterns. The number of real and apparent episodes detected over 20 min were 92 +/- 12 and 84 +/- 14 lasting 470 +/- 50 and 210 +/- 50 s, indicating mean durations of 5.1, and 2.4 s, frequencies of 12 +/- 0.1 and 11 +/- 0.2 Hz, cycles (waves) per episode of 54 +/- 6 and 19 +/- 2 and amplitudes of 42.3 +/- 5 and 19.8 +/- 1 for the SAM-treated and control rats, respectively. The nontremor activities of rats injected with phosphate-buffered saline were distinguished and eliminated by raising the minimum amplitude and number of cycles to 20. This procedure is being enhanced for screening antitremor agents and for elucidating the possible mechanism for Parkinsonism.