Kenichi Kitani

Neuroprotection by propargylamines in Parkinson's disease: suppression of apoptosis and induction of prosurvival genes.

In Parkinsons disease (PD), therapies to delay or suppress the progression of cell death in nigrostriatal dopamine neurons have been proposed by use of various agents. An inhibitor of type B monoamine oxidase (MAO-B), (-)deprenyl (selegiline), was reported to have neuroprotective activity, but clinical trials failed to confirm it. However, the animal and cellular models of PD proved that selegiline protects neurons from cell death. Among selegiline-related propargylamines, (R)(+)-N-propargyl-1-aminoindan (rasagiline) was the most effective to suppress the cell death in in vivo and in vitro experiments. In this paper, the mechanism of the neuroprotection by rasagiline was examined using human dopaminergic SH-SY5Y cells against cell death induced by an endogenous dopaminergic neurotoxin N-methyl(R)salsolinol (NM(R)Sal). NM(R)Sal induced apoptosis (but not necrosis) in SH-SY5Y cells, and the apoptotic cascade was initiated by mitochondrial permeability transition (PT) and activated by stepwise reactions. Rasagiline prevented the PT in mitochondria directly and also indirectly through induction of antiapoptotic Bcl-2 and a neurotrophic factor, glial cell line-derived neurotrophic factor (GDNF). Long-term administration of propargylamines to rats increased the activities of antioxidative enzymes superoxide dismutase (SOD) and catalase in the brain regions containing dopamine neurons. Rasagiline and related propargylamines may rescue degenerating dopamine neurons through inhibiting death signal transduction initiated by mitochondria PT.

Age-related changes in antioxidant enzyme activities are region and organ, as well as sex, selective in the rat

Enzyme activities of superoxide dismutase (SOD), catalase (CAT) and glutathione peroxidase (GSH-Px) were determined in the liver as well as several specific brain regions of young and old Fischer-344 rats of both sexes. In the liver of male rats, activities of CAT as well as Mn-SOD were lower, while activities of Cu Zn-SOD were higher in old (30-month-old) rats than in young (7-month-old) ones. Activities of total SOD as well as GSH Px were comparable for young and old male rat livers. In contrast to male rats, in female rat livers, activities of CAT were significantly higher in old (28-months-old) rats, while activities of Mn-SOD were slightly (but significantly) higher in old rat livers. In old male rats, activities of Mn-SOD were significantly higher than in young males in several specific regions of the brain (the substantia nigra (s. nigra), striatum, hippocampus) but lower in the cerebellum. In particular, SOD activities in s. nigra, striatum and hippocampus in old male rats were several fold higher than corresponding values in young male rats. Activities of Cu Zn-SOD were generally unchanged with age. Activities of CAT as well as GSH-Px (both Se-dependent and non-Se-dependent forms) were also relatively unaffected by age. In female rat brains, activities of Mn-SOD as well as those of others all remained mostly unaffected by aging, although there was a general tendency of slightly higher activities in most cerebral regions for Mn-SOD in old female rats. Thus, age-related changes of these antioxidant enzymes in the liver and brain are markedly sex dependent and some enzyme activities (such as CAT in the liver) change in an opposite direction with age. Changes of Mn-SOD in the brain were markedly region-specific in male rats. Results suggest that the significance of the changes of these antioxidant enzyme activities during aging needs to be carefully interpreted, taking into consideration the fact that changes are markedly variable depending on sex as well as the organs and brain regions examined.

Tauroursodeoxycholate prevents taurocholate induced cholestasis

The nature of transport pathway(s) for the biliary excretion of taurocholate and tauroursodeoxycholate was examined by comparing the biliary transport maximum (Tm) value for taurocholate during the infusion of taurocholate alone with that of taurocholate combined with tauroursodeoxycholate. The combined infusion of tauroursodeoxycholate resulted in an appreciable excretion of tauroursodeoxycholate while the excretion rate of taurocholate was not reduced in comparison with the Tm value of taurocholate alone. Furthermore, the Tm state of taurocholate was maintained for a much longer period with the simultaneous infusion of tauroursodeoxycholate than by the infusion of taurocholate alone. The cholestasis usually produced by the excess infusion of taurocholate was also prevented when tauroursodeoxycholate was simultaneously infused. Since plasma taurocholate concentration was not significantly different from the two rat groups, the results suggest the presence of the facilitative interaction of tauroursodeoxycholate with the taurocholate excretion.

Mechanism underlying anti-apoptotic activity of a (−)deprenyl-related propargylamine, rasagiline

A potent inhibitor of type B monoamine oxidase, (-)deprenyl, is known to protect or rescue dying neurons, independent of inhibition of the enzyme activity. After long term administration to rodents, a propargylamine structurally related to (-)deprenyl, (R)(+)-N-propargyl-1-aminoindan (rasagiline) increased the activities of anti-oxidative enzymes, superoxide dismutase and catalase. Rasagiline protected in vitro dopamine cells from apoptosis induced by oxidative stress or neurotoxins. The mechanism of the anti-apoptotic effect was studied by in vitro experiments using human dopaminergic neuroblastoma, SH-SY5Y cells. Peroxynitrite-generating N-morpholino sydonimine (SIN-1) induced apoptosis in SH-SY5Y cells via disruption of mitochondrial membrane potential (DeltaPsim), followed by caspase 3 activation. Rasagiline prevented the loss of DeltaPsim, the initial step to apoptosis, and also following caspase 3-activation and DNA fragmentation. The results suggest that rasagiline may interact with the specific molecule in the mitochondria and suppress the death signal transduction. By the anti-apoptotic function, rasagiline may rescue or protect declining neurons in aging and neurodegenerative disorders, such as Parkinsons disease.

Effect of ursodeoxycholate on the bile flow in the rat.

Abstract The relationship between the bile flow and biliary excretion rate of bile salt was studied by a continuous infusion of ursodeoxycholate and its glycine conjugate in rats. Infusion of glycoursodeoxycholate produced a higher flow rate and higher bile salt concentration than previously reported values for taurocholate. The estimated biliary transport maximum value was 2.21±0.15 μmole/min/100g body weight (mean±SD, N=13). Furthermore, a linear relation was found between the bile flow and bile salt excretion rate for a wide range of bile salt excretion with a slope value of 4.10±0.64 μl/μmole (N=10). These values were close to values previously reported for tauroursodeoxycholate. In contrast, when free ursodeoxycholate was infused, a bile salt excretion rate increased at first to a level of around 1.0 μmole/min/100g body weight with a concomitant bile flow increase, but after one hr, the bile salt excretion dropped sharply and a lower plateau of about half of the initial maximum level was established in the following hr. On the other hand, the bile flow further increased even in the second hr. Consequently, the linear relationship initially observed between the bile flow and bile salt excretion rate became gradually distorted and after one hr even the positive correlation between the two parameters was completely lost. The sharp drop in the bile salt excretion rate was found to be due to the decrease in the taurine conjugate of ursodeoxycholate in the bile. The excretion rate of free ursodeoxycholate remained at a very low level (about 0.1 μmole/min/100g body weight) throughout the experiments. The concentration of ursodeoxycholate in the liver increased sharply in the second hr corresponding to the decrease in the bile salt excretion rate. These results appear to be most easily explained by the thesis that there is a fraction of bile independent of bile salt excretion but dependent on the bile salt concentration in the hepatocyte.

(−)Deprenyl increases activities of superoxide dismutase and catalase in striatum but not in hippocampus: The sex and age-related differences in the optimal dose in the rat

The dose of (-)deprenyl (2.0 mg/kg/day, sc, for 3 weeks) which significantly increased activities of superoxide dismutase (SOD) and catalase in the striatum of young male rats significantly reduced these activities in young female rats but did not change the SOD activity in old female rats. In order to clarify these effects, different doses of the drug were continuously infused sc for 3 weeks in three groups of rats (young males and young and old females). When a 10-fold smaller dose (0.2 mg/kg/day) was applied in young female rats, activities of both SOD and catalase were significantly increased, while a higher dose of 0.5 mg/kg/day was ineffective and a lower dose of 0.1 mg/kg/day was substantially less effective. In old female rats, doses of both 0.5 and 1.0 mg/kg/day were equally effective in elevating activities of SOD and catalase, while a lower dose of 0.1 mg/kg/day was less effective. The activity of glutathione peroxidase (GSH Px) remained unchanged in all groups, except for a significant decrease in the activity of non-selenium-dependent GSH Px in both young and old female rats given the highest drug dose (2.0 mg/kg/day). Furthermore, activities of all three enzymes remained unchanged in the hippocampus in most groups. The results indicate that (-)deprenyl significantly increases activities of both SOD and catalase in the striatum, but not in hippocampus of rats, and that the optimal dose is very different depending on the sex and age of the animal.

Age-dependent decrease of the lateral diffusion constant of proteins in the plasma membrane of hepatocytes as revealed by fluorescence recovery after photobleaching in tissue smears

When fresh liver is smeared on slides and incubated in Krebs-Henseleit Ringer solution containing 1 mM H2O2 at 37 degrees C, a yellowish-green autofluorescence develops in the hepatocyte plasma membrane. Indirect evidence shows that this peroxide-induced autofluorescence (PIAF) is due most probably to chemical reactions between proteins and the malondialdehyde produced by the membrane lipid peroxidation. Although the chemical nature of the PIAF has not been clarified yet, it is suitable under certain conditions for the measurement of the average lateral diffusion constant of the membrane proteins by means of the fluorescence recovery after photobleaching (FRAP) technique without the addition of any external fluorescent label. Analysis of four age groups for both sexes of Fischer 344 rats (3-5 rats per group, total 32) from 2 to 31 months of age revealed a significant negative linear correlation of the lateral diffusion constant of proteins with age in both sexes, with the slope of the females being somewhat smaller. Young males showed a diffusion constant about 2.8 X 10(-10) decreasing to 1.7 X 10(-10) cm2 X s-1 by 31 months of age at 37 degrees C, whereas the respective values in females were 2.7 X 10(-10) and 1.9 X 10(-10). The results are consistent with the predictions of the membrane hypothesis of aging, according to which an age-dependent loss of the passive permeability of the cell membrane for potassium (and probably for water) is the crucial point of the cellular aging.

Why (−)deprenyl prolongs survivals of experimental animals: Increase of anti-oxidant enzymes in brain and other body tissues as well as mobilization of various humoral factors may lead to systemic anti-aging effects

(--)Deprenyl, a monoamine oxidase B (MAO B) inhibitor is known to upregulate activities of anti-oxidant enzymes such as superoxide dismutase (SOD) and catalase (CAT) in brain dopaminergic regions. The drug is also the sole chemical which has been repeatedly shown to increase life spans of several animal species including rats, mice, hamsters and dogs. Further, the drug was recently found to enhance anti-oxidant enzyme activities not only in brain dopaminergic regions but also in extra-brain tissues such as the heart, kidneys, adrenal glands and the spleen. We and others have also observed mobilization of many humoral factors (interferone (INF)-gamma, tumor necrosis factor (TNF)-alpha, interleukine (IL)-1beta,2,6, trophic factors, etc.) and enhancement of natural killer (NK) cell functions by (-)deprenyl administration. An apparent extension of life spans of experimental animals reported in the past may be better explained by these new observations that (-)deprenyl upregulate SOD and CAT activities not only in the brain but also in extra-brain vital organs and involve anti-tumorigenic as well as immunomodulatory effect as well. These combined drug effects may lead to the protection of the homeostatic regulations of the neuro-immuno-endocrine axis of an organism against aging.

Anomalous accumulation of τ and ubiquitin immunoreactivities in rat brain caused by protease inhibition and by normal aging: a clue to PHF pathogenesis?

Rats received intraventricular infusion of leupeptin or saline and brain sections were immunostained with antibodies to tau (anti-HFoPHF) or ubiquitin. Results were compared with immunostaining on normal aged rat brains and Alzheimers disease (AD) brains. Both antibodies stained Purkinje cell perikarya and dendrites of leupeptin (but not saline)-treated and aged rat brains, as well as senile plaque neurites and neurofibrillary tangles in AD brains. The results are consistent with the hypothesis that paired helical filament (PHF) formation involves defective protein degradation.

Pharmacological modifications of endogenous antioxidant enzymes with special reference to the effects of deprenyl: a possible antioxidant strategy

Limited information is available on the upregulation of endogenous antioxidant enzymes by means of administering various pharmaceuticals and/or chemicals. It has been reported that ursodeoxycholic acid (UDCA), a bile acid originally identified from black bear bile (a Chinese medicine, Yutan) increased glutathione S-transferase (GST) activities in mouse livers, resulting in a decrease in systemic lethal toxicity of orally challenged 1-2-dichloro-4-nitrobenzene (DCNB). Also, ursolic acid found in herbal medicines (e.g. leaves of loquat) was reported to increase catalase (CAT) activities in mouse liver. Interestingly, the chemical structures of these two compounds are surprisingly similar to each other, despite the difference in their original sources. These results suggest that in the future, more and more compounds will be found to have effects on increasing endogenous antioxidant enzyme activities. Deprenyl is a monoamine oxidase B inhibitor but also possesses many other different pharmacological activities. Among these various pharmacological effects of deprenyl, a possible causal relationship between two effects of deprenyl, namely the prolongation of the survival of animals and upregulation of antioxidant enzymes in selective brain regions, has been postulated by the authors. In at least four different animal species (rats, mice, hamsters and dogs), a significant prolongation of survival by chronic administration of the drug has been reported by different groups including that of the authors. This group has reported that repeated administration of the drug for 2-3 weeks can significantly increase activities of both types of superoxide dismutase (SODs) (Cu, Zn-, and Mn-SODs) as well as of CAT selectively in brain dopaminergic regions. Both effects are dose dependent but excessive dosages become less effective and even cause an adverse effect (i.e. a decrease in enzyme activities and shortening of life span). The parallelism of the dose-effect relationship between the two phenomena suggests that modification of SOD and CAT levels is one possible mechanism for deprenyls ability to prolong the life span of animals.