,
*Department of Neurology, The 1st Affiliated Hospital of Sun Yat-sen University, Guangzhou, China
�Department of Neurology, Baylor College of Medicine, Houston, Texas, USA
�Technion-Rappaport Family Faculty of Medicine, Haifa, Israel
Parkinson’s disease (PD) is a progressive disorder in whichneurons producing dopamine (DA), norepinephrine, andserotonin degenerate and intracellular inclusions, Lewybodies, accumulate. Various abnormalities, such as mito-chondrial defects, oxidative stress, and ubiquitin-proteasomesystem (UPS) dysfunction have been suggested to contributeto the degenerative process underlying PD (Siderowf andStern 2003). Pharmacological strategies designed to interferewith these pathological mechanisms may effectively coun-teract the degeneration.
Proteasomes, are the primarily enzymes involved in thedegradation of unwanted proteins within cells, whichconsist of enzyme complexes mediating the rapid ATP-dependent degradation of abnormal intracellular proteinsafter they have been covalently bound to ubiquitin(Ciechanover et al. 2000). Several studies have described
the abnormal structure and dysfunction of proteasomes inthe brains of PD patients (McNaught and Olanow 2006).Furthermore, systemic or striatal inhibition of the UPSby carbobenzoxy-L-y-t-butyl-L-glutamyl-L-alanyl-leucinal
Received August 6, 2007; revised manuscript received January 31, 2008;accepted February 1, 2008.Address correspondence and reprint requests to Weidong Le, MD
PhD, Department of Neurology, NB 205, Baylor College of Medicine,Houston, TX 77030, USA. E-mail: [email protected] or MoussaB. H. Youdim, PhD, Technion-Rappaport Family Faculty of Medicine,Efron St., PO Box 9697, Haifa 31096, Israel.E-mail: [email protected] used: DA, dopamine; DOPAC, 4-dihydroxy-phenyla-
cetic acid; HVA, homovanillic acid; MAO, monoamine oxidase; MFB,medial forebrain bundle; PBS, phosphate-buffered saline; PD, Parkin-son’s disease; SN, substantia nigra; SOD, superoxide dismutase; TH,tyrosine hydroxylase; UPS, ubiquitin-proteasome system.
Abstract
Nigrostriatal neurodegeneration in Parkinson’s disease (PD)
has been postulated to be caused by various pathological
conditions, such as mitochondrial defects, oxidative stress,
and ubiquitin-proteasome system (UPS) dysfunction. Phar-
macological strategies designed to interfere with these
pathological pathways may effectively counteract the
degeneration. Rasagiline and selegiline are selective and
irreversible monoamine oxidase-B inhibitors that possess
significant protective properties on dopamine neurons in var-
ious pre-clinical models of PD. In the present study, the
neuroprotective and neurorestorative effects of rasagiline and
selegiline were compared in an animal model of PD produced
by inhibition of the UPS. C57BL/6 male mice were microin-
jected bilaterally with UPS inhibitor lactacystin (1.25 lg/side),
into the medial forebrain bundle. Administration of rasagiline
(0.2 mg/kg, i.p. once per day) or selegiline (1 mg/kg, i.p. once
per day), started 7 days before or after (up to 28 days) after
lactacystin microinjection. We found that both rasagiline and
selegiline exerted a significant neuroprotective effect against
lactacystin-induced neurodegeneration; but only rasagiline
managed to restore the nigrostriatal degeneration. Further-
more, rasagiline showed a modest protection against lacta-
cystin-induced inhibition of proteasomal activity. Our study
indicates that compared with selegiline, rasagiline is more
potent in protecting neurodegeneration induced by UPS
impairment and may, therefore, exert disease-modifying ef-
fects in PD.
Keywords: lactacystin, neuroprotection, neurorestoration,
rasagiline, selegiline, ubiquitin-proteasome system.
J. Neurochem. (2008) 105, 1970–1978.
JOURNAL OF NEUROCHEMISTRY | 2008 | 105 | 1970–1978 doi: 10.1111/j.1471-4159.2008.05330.x
1970 Journal Compilation � 2008 International Society for Neurochemistry, J. Neurochem. (2008) 105, 1970–1978� 2008 The Authors
(PSI) has been shown to cause parkinsonism, which ischaracterized by the formation of neuronal inclusions(Fornai et al. 2003 and McNaught et al. 2003; McNaughtand Olanow 2006). Our previous studies have documentedthat unilateral stereotaxic injection of proteasome inhibitorlactacystin into the medial forebrain bundle (MFB) of micecauses degeneration of DA neurons, protein aggregation,and inclusion body formation (Zhang et al. 2005). Inaddition, bilateral stereotaxic injection with lactacystin intothe MFB of mice induces behavioral deficits, nigrostriataldegeneration, protein aggregation, and proteasomal inhibi-tion, similar to PD (Zhu et al. 2007). Thus, impairment ofproteasome function may play an important role in proteinaggregation and neurodegeneration in PD.
Monoamine oxidase type B (MAO-B) inhibitors ofpropargylamine family have been extensively investigatedfor their potential neuroprotective properties (Blandini 2005).Selegiline, the prototype of this class of compounds, hasdemonstrated antioxidant and neuroprotective effects inexperimental studies (Le et al. 1997; Youdim and Bakhle2006), although the neuroprotective activity in PD patientshas remained controversial (Shoulson 1998, Palhagen et al.2006). Its restricted derivate, rasagiline, which is differentfrom selegiline in that it is not metabolized to amphetamineand/or methamphetamine and possesses the neuroprotectivemetabolite aminoindan (Bar-Am et al. 2007), has shown tobe the most potent propargylamine against a variety of insultsin both in vitro and in vivo PD models (Youdim et al. 2003,2005; Sagi et al. 2007). Recent clinical studies have reportedefficacy of rasagiline for PD treatment, either as adjuncttherapy to L-DOPA or as monotherapy in early PD (Bayeset al. 2006). Patients treated with rasagiline from onset showsignificantly less functional decline than those in whomtreatment is delayed (Bayes et al. 2006). These findingssuggest that rasagiline may possess disease-modifyingactivity, which is supported by numerous in vitro andin vivo studies (Weinreb et al. 2006; Sagi et al. 2007). Asinhibition of proteasomal function contributes to the neu-rodegeneration in PD, our goal is to explore and compare theneuroprotective and neurorestorative potentials of rasagilineand selegiline in mice against nigrostriatal DA neuronsdegeneration induced by the proteasome inhibitor lactacystin.
Materials and methods
Animals and treatmentsThe proposed animal study was approved by the Baylor College of
Medicine Animal Use and Care Committee and conducted in
accordance with the Guide for the Care and Use of Laboratory
Animals as adopted and promulgated by the National Institute of
Health. Male C57BL/6 mice, aged 12 weeks, were randomly
assigned into six groups: control, lactacystin, pre-Ras, post-Ras,
pre-Sel, and post-Sel, respectively. They were housed five animals
per cage in a colony room maintained at constant temperature and
humidity, with a 12-h light/dark cycle, and allowed at least 7 days to
acclimate before any treatment. Administration of rasagiline
(0.2 mg/kg, i.p. q.i.d.) or selegiline (1 mg/kg, i.p. q.i.d.) started
7 days before (pre-treatment) or after (post-treatment) microinjection
with lactacystin, up to the end of the study (28 days after
microinjection of lactacystin), while the administration of a same
volume saline was served as a control. The time point chosen for
post-treatment are based on our previous finding that there was
noticeable injury in nigrastriatal system 7 days after lactacystin
microinjection. The dosage regimens of rasagiline and selegiline
were elected according to several studies (Youdim and Tipton 2002;
Muralikrishnan et al. 2003; West et al. 2006) and they were
postulated to have same abilities on MAO-B inhibitory. For the
stereotaxic injection of lactacystin, mice were deeply anesthetized
and placed in a Kopf stereotaxic frame (Kopf Instruments, Tujunga,
CA, USA). An injection cannula was inserted through a hole drilled
in the skull, into MFB, using the following coordinates (in mm):
(1.34 posterior, ±1.17 lateral, and 5.1 ventral from bregma) of each
mouse. Two microliters of either phosphate-buffered saline (PBS;
0.1 M) as control or lactacystin (1.25 lg; A.G. Scientific, San Diego,CA, USA) in PBS was injected into the MFB of each mouse. All the
mice were healthy during the experiment period and were killed
28 days after microinjection of lactacystin by terminal anesthesia
followed by transcardial perfusion with ice-cold PBS. The mice were
decapitated and the brains were immediately removed, placed on ice,
and transected coronally at the infundibular stem. The midbrain
blocks were fixed with 4% p-formaldehyde in PBS 2 days and
cryoprotected in 30% sucrose for 2 days at 4�C followed by
histological analysis. Striatal tissues and ventral midbrains were
rapidly dissected out and stored at )80�C until analysis. The samples
were divided to perform different sets of experiments.
Locomotive activities and rotarod performanceLocomotive activities and rotarod performance were tested 1 day
prior and every 7 days after the microinjection of lactacystin.
Locomotive activities were monitored by the AccuScan Digiscan
system (AccuScan Instruments Inc., Columbus, OH, USA). Data
collected by computer included total distance traveled and moving
time. The measurements were carried out during the period between
9 AM and 11 AM in a dark room. Each mouse was placed in the
testing chamber for 30 min for adaptation, followed by a 60 min
recording by the computer-generated automatic analysis system.
Motor coordination was determined with an accelerating rotarod
treadmill (Columbus Instruments, Columbus, OH, USA). Initially,
the mice were required to perch on the stationary rod for 30 s to
accustom themselves to the environment. Then the animals were
trained at a constant speed of 5 rpm for 90 s. After this pre-training,
mice were tested three times at 1-h intervals on three consecutive
days for a total of nine tests, a mean of which undergoes statistical
analysis. During each test, the rotarod was set at a starting speed of
5 rpm for 30 s, and the speed was increased by 0.1 rpm per second.
All animals were tested three times for each experiment, and the
mean of the test results were subjected statistical analysis.
Immunohistochemistry and stereology-based cell countingMidbrain blocks were cut into 30 lm sections and systematically
picked at 150 lm intervals. This procedure yielded seven sections
� 2008 The AuthorsJournal Compilation � 2008 International Society for Neurochemistry, J. Neurochem. (2008) 105, 1970–1978
Neuroprotection and neurorescue of rasagiline and selegiline | 1971
for each animal covering the whole substantia nigra (SN). Free-
floating sections were incubated successively for 15 min with
0.05% H2O2 in 0.1 M PBS to remove endogenous peroxidase
activity, for 1 h with 2% goat serum/0.1% Triton X-100 in 0.1 M
PBS to block non-specific binding sites, and for 24 h 4�C with
the primary rabbit anti-tyrosine hydroxylase (TH, 1 : 1500; Protos
Biotech, New York, NY, USA) to detect DA neurons. Sections
were then incubated for 2 h at 25�C with the appropriate
biotinylated secondary antibody (anti-rabbit or anti-rat IgG,
1 : 200; Vector Laboratories Inc., Burlingame, CA, USA). The
avidin–biotin method was used to amplify the signal (ABC Kit;
Vector Laboratories Inc.) and 3, 3¢-diaminobenzidine tetrachloride
was used to visualize bound antibodies. Stereological methods
were used to evaluate the number of DA neurons (TH-positive
cells) in the SN. The stereological setup was composed of a
computer, a microscope (Axioskop 2; Carl Zeiss Inc., Thornwood,
NY, USA), a color camera (Olympus America Inc., Center Valley,
PA, USA), and an electronic microcator (Heidenhain Corp.,
Schaumburg, IL, USA). Counting of cell numbers was performed
with the computer-assisted stereological toolbox software program
Stereo Investigator 7.0 (MicroBrightField, Inc., Willston, VT,
USA). The total number of TH-positive neurons was estimated
using the optical fractionator method (Glaser and Glaser 2000).
For each tissue section analyzed, the guard zones of 3 lmthickness were used at the top and bottom of each section. The
SN was outlined under 2.5· magnification, and 50% of the
outlined region was analyzed using a sampling design generated
with the following stereologic parameters: grid size,
200 · 200 lm; counting frame size, 150 · 150 lm; and dissector
height, 14 lm. The neurons were counted under 40· magnifica-
tion and the total number was calculated by using the formula
previously described for this method (West et al. 1991).
Determination of striatal DA and its metabolitesThe concentration of DA, 4-dihydroxy-phenylacetic acid (DOPAC),
homovanillic acid (HVA), serotonin, and 5-hydroxyindolacetic acid
were quantified in striatal tissues by HPLC. Briefly, striatal tissues
were homogenized (10% wt/vol) by sonication in ice-cold 0.1 M
perchloric acid. Homogenates were centrifuged at 10 000 g for
10 min at 4�C and the supernatants were collected and filtered
through acro-disc filters (0.25 lm; Fisher Scientific, Pittsburgh, PA,
USA) and subjected to HPLC (HTEC-500; Eicom, Kyoto, Japan)
with the column (EICOMPAK SC-3ODS; Eicom) and detected by
an electrochemical detector (ADInstruments Pty Ltd., Castle Hill,
NSW, Australia). The mobile phase consisted of 0.1 mM citric acid,
0.1 M sodium acetate, 220 mg/L octane sulfate sodium, 5 mg/L
EDTA, and 20% methanol, pH 3.5.
Proteasome activity assayVentral midbrains were placed on ice and homogenized in lysis
buffer (50 mM HEPES, pH 7.5, 5 mM EDTA, 150 mM NaCl,
0.5 mM ATP, and 1% Triton X-100). The lysates were centrifuged at
14 000 g at 4�C for 20 min. The resulting supernatants were placed
on ice and assayed for protein concentrations by the Bradford’s
method (Bio-Rad, Hercules, CA, USA). The 20S Proteasome
Activity kit (Chemicon International Inc., Temecula, CA, USA) was
used to measure the chymotrypsin-like activity. Assays were carried
out with 50 lg of midbrain lysates and the appropriate substrate at
37�C for 90 min incubation. The activity was measured by detection
of the fluorophore 7-amido-4-methylcoumarin after cleavage from
the synthetic fluorogenic peptide: Leu-Leu-Val-Tyr-7-amido-4-
methylcoumarin, using a spectrofluorimeter (Cytofluor II; PerSep-
tive Biosystems, Framingham, MA, USA) at excitation/emission
wavelengths of 380/460 nm. The results are expressed as fluores-
cence units/mg protein.
Bcl-2 immunoblotTissues of mice were extracted with mammalian tissue lysis/
extraction reagent (Sigma-Aldrich, St Louis, MO, USA) supple-
mented with complete protease inhibitor cocktail (Sigma-Aldrich).
Equal amounts of lysate protein were denatured in sodium dodecyl
sulfate sample buffer, subjected onto a 12% sodium dodecyl sulfate–
polyacrylamide gel electrophoresis gel, and transferred onto a
polyvinyl difluoride membrane. After being blocked in 6% non-fat
dry milk, membranes were incubated in the presence of respective
primary antibodies, Bcl-2 (1 : 1000; Chemicon International Inc.),
or b-actin (1 : 5000; Sigma-Aldrich), and followed by incubation
with horseradish peroxidase-labeled secondary antibodies (1 : 2000;
Chemicon International Inc.). Signals were detected using enhanced
chemiluminescence (Amersham, Arlington Heights, IL, USA).
Statistical analysisAll the results of the study were from groups of 5–10 mice. Data
were analyzed using SPSS 11.0 software (SPSS Inc., Chicago, IL,
USA). Statistical significance of difference between parameters was
determined at the 0.05 level, using one- or two-way ANOVA as
appropriate. ANOVA were followed when allowed by post hoc t-testcorrected for multiple comparisons by the method of Tukey or
Bonferroni. Mean values were quoted with the respective standard
error.
Results
Rasagiline and selegiline improved behavioral performancein lactacystin-lesioned miceIn the mice injected with lactacystin on day 7, compared withthe control, locomotive activities (total distance traveled andmoving time) were significantly decreased by 67.9% and71.8%, respectively (Fig. 1), and the rotarod performance (thetime remaining on the rod) was significantly reduced by 86.2%(Fig. 2). The changes in the locomotive tests and rotarodperformance remained unchanged at the end of the study (day28). However, pre-treatment with rasagiline and selegilinesignificantly attenuated the behavioral impairments on day 7,by 76.4% and 94.4% in total distance traveled, by 95.1% and139.0% in moving time, and by 87.6% and 54.6% in rotarodtime, respectively [Figs 1(a and c) and 2a]. Marked recoverywas also seen in the mice post-treated with rasagiline (by54.4% in total distance traveled, by 70.7% inmoving time, andby 69.1% in rotarod time) as well as in the mice post-treatedwith selegiline in total distance traveled (by 45.5%) and inmoving time (by 59.8%), but not in rotarod performance(remaining at 39.3% of control) [Figs 1(b and d) and 2b].
Journal Compilation � 2008 International Society for Neurochemistry, J. Neurochem. (2008) 105, 1970–1978� 2008 The Authors
1972 | W. Zhu et al.
Effects of rasagiline and selegiline againstlactacystin-induced DA neuron loss in SNCompared with the vehicle control, the number of DAneurons was reduced in lactacystin-injected mice by 71.1%on day 28 (Fig. 3). Pre-treatment with either rasagiline orselegiline significantly protected the DA neurons againstlactacystin-induced injury at the end of the study with 72.8%and 59.3% reduction in the DA neuron loss, respectively(Fig. 3). Furthermore, compared with selegiline (1 mg/kg,i.p. once per day), rasagiline (0.2 mg/kg, i.p. once per day)was more potent in protecting DA neurons against lactacy-stin. Only rasagiline was associated with an apparent rescueof DA neurons after a 21-day post-treatment followingmicroinjection of lactacystin, preventing the loss by 55.2%(Fig. 3). In contrast, selegiline failed to restore DA neurons
when it was applied after the microinjection of lactacystin(Fig. 3).
Rasagiline and selegiline restored lactacystin-induceddepletion of DACompared with the control, the reduction of DA, DOPAC, andHVA induced by lactacystin was significant on day 28, whichwas 51.0%, 52.2%, and 66.4%, respectively (Fig. 4a and b). Atthe end of the study, we found that pre-treatment of rasagilineand selegiline significantly attenuated the lactacystin-inducedreduction of striatal DA by 86.7% and 46.5%, respectively.Post-treatment with rasagiline and selegiline also rescued up to78.7% and 58.3% of control striatal DA level, respectively(Fig. 4a), but only rasagiline was able to restore the depletionsof DOPAC and HVA induced by lactacystin (Fig. 4b).
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Fig. 1 Rasagiline and selegiline improved locomotive activities in
lactacystin-lesioned mice. Two microliters of either phosphate-buf-
fered saline (PBS; 0.1 M) as control or lactacystin (1.25 lg/side) in
PBS was injected into the MFB of each mouse. Administration of ra-
sagiline (0.2 mg/kg, i.p. per day) or selegiline (1 mg/kg, i.p. per day)
started 7 days before (pre-treatment) or after (post-treatment) micro-
injection with lactacystin, while the administration of a same volume
saline was served as control. The day of microinjection with lactacystin
was set to be day 0. The changes of locomotive activities were pre-
sented by total distance traveled (a and b) and moving time (c and d).
Data were expressed as mean ± SEM (n = 7). Two-way ANOVA was
applied to analysis the difference (F = 51.551 in total distance trav-
eled, F = 49.321 in total moving time, df for group = 5), followed by
post hoc tests corrected for multiple comparisons by the method of
Tukey. In general, there was no significant difference between ra-
sagiline and selegiline in improving the locomotive activities. *p < 0.05
versus control and #p < 0.05 versus lactacystin.
� 2008 The AuthorsJournal Compilation � 2008 International Society for Neurochemistry, J. Neurochem. (2008) 105, 1970–1978
Neuroprotection and neurorescue of rasagiline and selegiline | 1973
Rasagiline and selegiline failed to alleviatelactacystin-induced proteasome inhibitionA 40.6% inhibition caused by microinjection of lactacystinof the chymotrypsin-like proteasome activity in the ventralmidbrain was evident in the ventral midbrain 28 days afterlactacystin injection (Fig. 5). Neither rasagiline nor selegilinetreatment was able to alleviate the proteasome inhibitioninduced by lactacystin; although a modest, but insignificantrestoration of proteasome activity was seen after both pre-treatment and post-treatment with rasagiline (Fig. 5).
Rasagiline and selegiline reversed the reduction of Bcl-2protein level caused by proteasome inhibitionCompared with vehicle control, a significant reduction ofBcl-2 (38.5% of control) was observed in the ventralmidbrain on day 28 (Fig. 6). Protein level of Bcl-2 in micetreated with rasagiline (regardless of pre-treatment or post-treatment) was elevated to around 106% of control. While
selegiline seemed less effective in counteracting the Bcl-2reduction compared with rasagiline. Protein level of Bcl-2 inmice pre-treated and post-treated with selegiline was 98.8%and 95.4%, respectively (Fig. 6).
Discussion
Recently, we have shown that bilateral microinjection oflactacystin into the MFB of mice induces degeneration of DA
Control
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Fig. 2 Effects of rasagiline and selegiline on rotarod performance in
mice injected with lactacystin. Rotarod performance was represented
time staying on the rod. Data were expressed as mean ± SEM (n = 7).
Two-way ANOVA was applied to analysis the difference (F = 27.15, df
for group = 5), followed by post hoc tests corrected for multiple com-
parisons by the method of Tukey. *p < 0.05 versus control and#p < 0.05 versus lactacystin.
(a)
(b)
Fig. 3 Effects of rasagiline and selegiline against lactacystin-induced
loss of DA neurons in SN. Administration of rasagiline (0.2 mg/kg, i.p.
per day) or selegiline (1 mg/kg, i.p. per day) started 7 days before
(pre-treatment) or after (post-treatment) microinjection with lactacy-
stin, while the administration of a same volume saline was served as
control. (a) Representative photomicrographs of SN with TH-immu-
nohistochemistry. (b) Quantitative analysis of TH-immunopositive
neurons in the SN. Each value was presented by the mean ± SEM
based on the number of TH-immunopositive neurons in right SN
(n = 8). There was no difference in the number of TH-positive cells
between left and right SN (data not showed). Group differences were
assessed using one-way ANOVA (F = 105.662, df = 47), allowed by
post hoc tests corrected for multiple comparisons by the method of
Tukey. *p < 0.001 versus control, #p < 0.001 versus Lactacystin, and$p < 0.05 versus selegiline counterparts.
Journal Compilation � 2008 International Society for Neurochemistry, J. Neurochem. (2008) 105, 1970–1978� 2008 The Authors
1974 | W. Zhu et al.
neurons, which can be prevented by pre-treatment with noveliron chelator VK-28 (Varinel Inc.,Westtown, PA, USA) and itsderivate, a multifunctional drug, M30. Furthermore, post-lactacystin treatments with these drugs induce restoration ofDA neurons and alleviate the inhibition of proteasome activity(Zhu et al. 2007). The present study was undertaken todetermine and compare the neuroprotective and neurorestor-ative activities of two anti-Parkinson drugs, rasagiline (azilect)and selegiline, in the lactacystin parkinsonism model. Thiswas performed as rasagiline has been suggested to have adisease modifying activity in PD patients (Parkinson StudyGroup 2004). Our study provides evidence supporting bothneuroprotective and neurorestorative activities for rasagiline,
Fig. 4 Effects of rasagiline and selegiline against lactacystin-induced
depletion of DA and its metabolites. Administration of rasagiline
(0.2 mg/kg, i.p. per day) or selegiline (1 mg/kg, i.p. per day) started
7 days before (pre-treatment) or after (post-treatment) microinjection
with lactacystin, while the administration of a same volume saline was
served as control. The figures represented the abilities of rasagiline
and selegiline to restore the lactacystin-induced depletions of striatal
DA (a) and its metabolites DOPAC and HVA (b). The results were
expressed as mean ± SEM (n = 7). Group differences were assessed
using one-way ANOVA (F = 5.766, df = 41), allowed by post hoc tests
corrected for multiple comparisons by the method of Tukey. *p < 0.01
versus control; #p < 0.05 and ##p < 0.01 versus Lac lactacystin;$p < 0.05 versus selegiline.
Fig. 5 Rasagiline and selegiline failed to alleviate lactacystin-induced
proteasome inhibition. Proteasome activities were examined on day
28 and were indicated by the changes on chymotrypsin-like activity
induced in ventral midbrain. Both rasagiline and selegiline failed to
restore the proteasome activity. The results were expressed as
mean ± SEM (n = 5). Group differences were assessed using one-
way ANOVA (F = 18.532, df = 29), allowed by post hoc tests corrected
for multiple comparisons by the method of Tukey. *p < 0.001 versus
control.
Bcl-2
β-actin
Fig. 6 Rasagiline and selegiline reversed the reduction of Bcl-2
protein level caused by proteasome inhibition. Protein level of Bcl-2 in
the ventral midbrain was analyzed by western blot on day 28. (a)
Representative figures of changes of Bcl-2 in ventral midbrain in mice
of different group. The loading of the lanes was normalized to levels of
b-actin and the experiment is representative of five independent
experiments. (b) The calculated densitometry intensities of the
respective bands were presented as percentage of the control. The
results were expressed as mean ± SEM (n = 5). Group differences
were assessed using one-way ANOVA (F = 41.779, df = 29), allowed by
post hoc tests corrected for multiple comparisons by the
method of Tukey. *p < 0.001 versus control and #p < 0.05 versus
lactacystin.
� 2008 The AuthorsJournal Compilation � 2008 International Society for Neurochemistry, J. Neurochem. (2008) 105, 1970–1978
Neuroprotection and neurorescue of rasagiline and selegiline | 1975
but only neuroprotective effect for selegiline, against lactacy-stin-induced neurodegeneration. For neuroprotection, a con-tinuous 7-day administration together with a continuous 28-day administration of either rasagiline or selegiline followingthe lactacystin lesion improved behavioral deficits, attenuatedthe severe degeneration of DA neurons and increased striatalDA content, suggesting possible neuroprotective effects of thedrugs. Only rasagiline, however, was able to restore thedegeneration of DA neurons and the depletion of DA contentwhen administered for 21 days following the lactacystinlesion. Thus, although both rasagiline and selegiline may exertbeneficial effects against lactacystin-induced neurodegenera-tion, it is apparent that MAO-B inhibitory activity cannotexplain either the neuroprotective or neurorescue properties ofthese MAO-B inhibitors in the lactacystin-induced neurode-generation. In fact, MAO-B inhibitors have been reported topossibly enhance neurotoxicity by proteasome inhibition(Fornai et al. 2003). In addition, MAO-A is suggested to bethe only isoform involved in striatal DA oxidative metabolism(Gesi et al. 2001). Selegiline, at 1 mg/kg, failed to modify theextracellular DA concentration in rat (Tipton et al. 2004).Furthermore, the optical isomers of rasagiline and selegilineare devoid of MAO-B inhibitory activity, but they have thesame potency in neuroprotection (Youdim et al. 2001). Thus,both rasagiline and selegiline may protect DA neurons andrestore DA concentration against lactacystin-induced neu-rodegeneration through other mechanisms.
Proteasome dysfunction has been suggested to play a role inPD (Grunblatt et al. 2004; McNaught and Olanow 2006), andproteasome inhibitors have been shown to induce degenera-tion of DA neurons in some in vitro and in vivomodels (Fornaiet al. 2003; McNaught et al. 2003; Zhang et al. 2005). Themechanisms whereby proteasome dysfunction leads to deathof DA neurons are, however, are not well understood. PC12cells and DA neurons have been reported to undergo apoptosisfollowing proteasome inhibition (Rideout et al. 2005; Nairet al. 2006), and may be rescued by antiapoptotic agents(Rideout et al. 2005). In linewith these findings, we found thatstereotaxic injection of lactacystin into MFB of micedecreased protein levels of Bcl-2, the over-expression ofwhich has been shown to suppress apoptosis in a wide range ofcell types (Lee et al. 2001). These findings support thatapoptosis occurs in neurodegeneration induced by UPSimpairment and the possibility that antiapoptotic drugs mighthave neuroprotective effects.
Among the agents that have been demonstrated to haveantiapoptotic properties in PD model systems, propargylam-ines are considered to be the most potent and promising(Olanow 2006). Both rasagiline and selegiline are two of thepropargylamines that have been shown to have neuroprotec-tive and antiapoptotic effects and are currently used in theearly treatment of PD (Chen and Swope 2006). Bothrasagiline and selegiline promote free radical scavengingby enhancing superoxide dismutase (SOD1 and 2) and
catalase activities or by increasing the SOD protein levels(Tabakman et al. 2004), increase production of neurotro-phins such as nerve growth factor, brain-derived neurotroph-ic factor, glial cell line-derived neurotrophic factor, andprotect neurons from inflammatory process (Nagatsu andSawada 2006). Furthermore, rasagiline and selegiline areable to bind to glyceraldehyde-3-phosphate dehydrogenase todecrease synthesis of pro-apoptotic proteins like Bcl-2associated X protein (BAX), c-JUN, and glyceraldehyde-3-phosphate dehydrogenase and increase synthesis of anti-apoptotic proteins like Bcl-2, Cu-Zn-SOD, and heat-shockprotein 70 (Tatton et al. 2002). Moreover, rasagiline canprevent the collapse of the mitochondrial membrane potential(Akao et al. 2002) and activate Ras-PI3K-Akt survivalpathway (Sagi et al. 2007). As neurodegeneration inducedby proteasomal inhibition has been shown to be mediated byapoptotic mechanisms (Rideout et al. 2005; Nair et al. 2006)and down-regulation of Bcl-2 has been documented inventral midbrain following lactacystin lesion, aforemen-tioned neuroprotective, and antiapoptotic actions of rasagi-line and selegiline may contribute to the neuroprotection or/and rasagiline-mediated neurorescue in the UPS impairedmouse model.
Our results suggest that rasagiline is superior to selegiline inboth neuroprotection and neurorescue against lactacystin-induced nigrostriatal degeneration. Although both rasagilineand selegiline are propargylamine derivatives and have similarstructures, rasagiline is metabolized to its major metaboliteaminoindan, while selegiline’s major metabolite is L-meth-amphetamine (Finberg et al. 1999; Am et al. 2004). Thedifference of the metabolites of these two drugs may accountfor their different neuroprotective and neurorescue abilities.Aminoindan, the major metabolite of rasagiline, has beenshown to be neuroprotective under the condition of serum andnerve growth factor withdrawal in PC12 cells (Am et al.2004). Thus, the in vivo generation of aminoindan fromrasagiline may contribute to its synergetic neuroprotective andneurorestorative effects. In contract to rasagiline, selegiline isa sympathomimetic amine and its major metabolite L-meth-amphetamine has been shown to be neurotoxic to PC12 andneuroblastoma cells in culture andDAneurons in vivo (Gassenet al. 2003). In addiction, L-methamphetamine has beenshown to abolish the neuroprotective activity of selegilinein vitro (Am et al. 2004). Furthermore, several studies havereported that both in vitro and in vivo administration ofmethamphetamine can induce cytosolic inclusions sharingsimilar components with Lewy bodies occurring in PD (Fornaiet al. 2004) and cause a dose-dependant inhibition of protea-some activity (Fornai et al. 2006; Lazzeri et al. 2006). Theabove findings may explain the observed inferior ability ofselegiline compared with rasagiline in neuroprotection and itsinability to rescue against lactacystin-induced nigrostriataldegeneration, as well as the failure of selegiline in restoringproteasome inhibition induced by lactacystin. In contrast, the
Journal Compilation � 2008 International Society for Neurochemistry, J. Neurochem. (2008) 105, 1970–1978� 2008 The Authors
1976 | W. Zhu et al.
behavioral improvement documented after the treatment ofselegiline may be explained by its sympathomimetic proper-ties mediated via L-methamphetamine. Moreover, rasagilinehas been found to activate the UPS in DA-derived neuroblas-toma SH-SY5Y cells (Youdim et al. 2002), although only amodest restoration of proteasome activity was found in thecurrent study. This may be a dose-dependant effect, the studiesof which are on the way.
The lactacystin-induced inhibition of proteasome activity,demonstrated in the ventral midbrain, was moderately but notsignificantly reversed by the pre- or post-treatment withrasagiline, but was not counteracted by the treatment withselegiline. Thus, the degree of neuroprotection or rescueagainst DA neuron degeneration does not appear to correlatewith the recovery rate of proteasome activity after treatmentwith rasagiline or selegiline. These findings suggest thatrasagiline and selegiline may act relatively independent ofproteasome system. Instead, they may achieve their neuropro-tective and rescue effects though interfering with the down-stream pathways of proteasome system, such as by reversingthe lactacystin-induced Bcl-2 down-regulation as seen in ourstudy. On the other hand, inhibition of proteasome system innigrostriatal pathway inmice results in a significant increase ofiron concentration in ventralmidbrain (Zhu et al. 2007), whichhas been suggested to have a pivotal role in neurodegeneration(Zecca et al. 2004). Iron may further contribute to the processof neurodegeneration, via its ability to induce oxidative stressdependent inhibition of proteasome (Ding et al. 2006). Theinability of rasagiline and selegiline to fully protect againstlactacystin neurotoxicity indicates that chelation of iron maybe important for neuroprotection. This is born by the fact thatthe multifunctional neuroprotective iron chelator-brain selec-tive MAO inhibitor drug, M30, which possess the samepropargylamine moiety as rasagiline and selegiline (Zhanget al. 2005), is potent neuroprotective and neurorestorativeagent in the lactacystin-induced PD model (Zhu et al. 2007).Thus, additional studies into the neuroprotective and possiblydisease-modifying mechanisms are needed.
The present study has investigated the neuroprotective andneurorescue properties of rasagiline and selegiline in vivoagainst nigrostriatal degeneration induced by lactacystin. Ourfindings suggest that rasagiline is superior to selegiline inboth neuroprotection and neurorestoration against neurode-generation in nigrostriatal pathway induced by UPS impair-ment. As rasagiline has been approved by the Food and DrugAdministration for the treatment of PD, well designed long-term observational trials are needed to study its effects on theprogression of the disease.
Acknowledgements
This work was supported by research grants from NIH (NS043567)
and from Chinese 863 project (2007 AA022460). We are grateful for
the support of Teva Pharmaceurtical Co. (Israel).
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