Association between human paraoxonase 2 protein and efficacy of acetylcholinesterase inhibiting drugs used against Alzheimer's disease.

Serum Paraoxonase 2 (PON2) level is a potential biomarker owing to its association with a number of pathophysiological conditions such as atherosclerosis and cardiovascular disease. Since cholinergic deficiency is closely linked with Alzheimer's disease (AD) progression, acetylcholinesterase inhibitors (AChEIs) are the treatment of choice for patients with AD. However, there is a heterogenous response to these drugs and mostly the subjects do not respond to the treatment. Gene polymorphism, the simultaneous occurrence of two or more discontinuous alleles in a population, could be one of the important factors for this. Hence, we hypothesized that PON2 and its polymorphic forms may be hydrolyzing the AChEIs differently, and thus, different patients respond differently. To investigate this, two AChEIs, donepezil hydrochloride (DHC) and pyridostigmine bromide (PB), were selected. Human PON2 wildtype gene and four mutants, two catalytic sites, and two polymorphic sites were cloned, recombinantly expressed, and purified for in vitro analysis. Enzyme activity and AChE activity were measured to quantitate the amount of DHC and PB hydrolyzed by the wildtype and the mutant proteins. Herein, PON2 esterase activity and AChE inhibitor efficiency were found to be inversely related. A significant difference in enzyme activity of the catalytic site mutants was observed as compared to the wildtype, and subsequent AChE activity showed that esterase activity of PON2 is responsible for the hydrolysis of DHC and PB. Interestingly, PON2 polymorphic site mutants showed increased esterase activity; therefore, this could be the reason for the ineffectiveness of the drugs. Thus, our data suggested that the esterase activity of PON2 was mainly responsible for the hydrolysis of AChEI, DHC, and PB, and that might be responsible for the variation in individual response to AChEI therapy.

Protection studies of new bis quaternary 2-(hydroxyimino)-N-(pyridin-3yl) acetamide derivatives (HNK-series) oximes against acute poisoning by dichlorvos (DDVP) in Swiss albino mice.

The available antidotal therapy against acute poisoning by organophosphates involves the use of atropine alone or in combination with one of the oximes, e.g. 2-PAM, Obidoxime, TMB-4 or HI-6. Each of these oximes has some limitation, raising the question of the universal antidotal efficacy against poisoning by all OPs/nerve agents. In the present study, newly synthesized bis quaternary 2-(hydroxyimino)-N-(pyridin-3yl) acetamide derivatives (HNK-series) oximes were evaluated for their antidotal efficacy against DDVP intoxicated Swiss mice, in terms of the Protection Index (PI) and AChE reactivation in brain and serum. The inhibition concentration (IC50) was determined in brain and serum after optimizing the time point for maximum inhibition (60 min post DDVP exposure). AChE reactivation efficacy of the HNK series was evaluated at IC50 and compared with 2-PAM. HNK-102 showed a ~2 times better Protection Index (PI) as compared to 2-PAM against DDVP toxicity. IC50 at 60 min DDVP post exposure was found to be approximately one fifth and one half of the LD50 dose for brain and serum AChE, respectively. Out of three HNK oximes, HNK-102 & 106 at 0.20 LD50 dose significantly reactivated DDVP intoxicated brain AChE (p<0.05) as compared to 2-PAM at double IC50 dose of DDVP. In light of double PI and higher AChE reactivation, HNK 102 was found to be a better oxime than 2-PAM in the treatment of acute poisoning by DDVP.

Sub-acute toxicity of cultured mycelia of himalayan entomogenous fungus Cordyceps sinensis (Berk.) Sacc. in rats.

Oral administration of laboratory cultured mycelia powder of C. sinensis did not show any sign of toxicity as no significant change was observed in organ weight and serological parameters in rats. However, there was a significant increase in food intake, body weight gain and hematological parameters like WBC, RBC, Hb and lymphocytes in treated groups. Histopathology of vital organs also supported the non toxic effect of C. sinensis. The results conclude that laboratory cultured mycelia powder of C. sinensis is safe and non toxic up to 2 g/kg body weight dose.