Cannabinoid Receptor Modulation in the 3-Acetylpyridine Cerebellar Ataxia Mouse Model

Cerebellar ataxia is a neurodegenerative disorder leading to severe motor incoordination. Recently it has been suggested that cannabinoids play a role in modulation of ataxic symptoms. In order to understand the possible therapeutic effect of cannabinoids for management of cerebellar ataxia, we used cannabinoid agonist/antagonists to target the cannabinoid type 1 receptor (CB1R) in the 3 acetyl pyridine (3AP) mouse model of ataxia. The role of the CB1R was examined by using three different doses of the CB1R agonist, WIN55,212-2 (WIN; 0.1, 0.5, 1 mg/kg) administrated 30 min prior to 3AP (55 mg/kg, i.p.) which leads to motor impairment through destruction of the inferior olive. In some recordings, the CB1R antagonist AM251(1 mg/kg) was given in combination with WIN. Locomotor activity and motor coordination were impaired by 3AP, and the application of WIN did not ameliorate this effect. However, the abnormal gait, rearing and grooming caused by 3AP were prevented by co-administration of AM251 with WIN. While the addition of the CB1R antagonist inhibition improved some ataxic symptoms, there was no effect of AM251 on balance or locomotor activity when co-administrated with WIN. Behavioral testing indicated that not only did WIN fail to exert any protective effect on ataxic symptoms, it exacerbated ataxic symptoms, suggesting that CB1R agonists may not be the ideal therapeutic drug in this disorder. When taken together, the findings from the present study indicate that cannabinoid modulation of ataxia symptoms may not act solely through CB1Rs and other cannabinoid receptors should be consider in future studies.

A Phylogenetic Approach to the Uneven Global Distribution of the COVID-19 Pandemic

A possible role of Y chromosomal haplogroups in COVID-19 mortality is discussed without claiming causality. The mortality of COVID-19 seems unequally distributed in different populations and statistically significant regional covariation is presented between COVID-19 mortality and the haplogroup Y-R1b. Y-R1b is suggested as a possible marker for mortality in the first wave of the pandemic affecting the Western Europe. September 2020 the pandemic involved also Eastern Europe severely in a second wave, while South East Asia, with a very high frequency of Y-0, had strikingly low COVID-19 mortality rate. Eastern Europe is dominated by Y-haplogroups (i.e., Y-R1a), with close ancestry to Y-R1b. Molecular mechanisms mediated by the Y chromosome involved in COVID-19 mortality are discussed, presenting a possible role of KDM5D in androgen receptor modulation and regulation of TMPRSS2 known to enable SARS-CoV-2 binding to ACE2 and facilitating virus entrance into the cell and virus replication. Sex bias and comorbidities point at the role of variations in the Y-chromosomal phylogeny.

NMDA receptor modulation and severe acute respiratory syndrome treatment

N-Methyl-D-aspartate (NMDA) subtype of glutamate receptors is expressed in the human lungs and central nervous system. NMDA receptor potentiation could increase calcium ion influx and promote downstream signaling mechanisms associated with cellular contractions that are disrupted in severe acute respiratory syndrome. Pharmacological effects generated by triggering glutamate receptor function in the brain, coupled with concurrent stimulation of the respiratory tract, may produce a synergetic effect, improving the airway smooth muscle function. A novel multipronged intervention to simultaneously potentiate NMDA receptors expressed both in the central nervous system and airway muscles would be helpful for the treatment of severe acute respiratory syndrome that deteriorates peripheral and central nervous system function before causing death in humans.

Positive and Negative Selective Allosteric Modulators of α5 GABAA Receptors: Effects on Emotionality, Motivation, and Motor Function in the 5xFAD Model of Alzheimer’s Disease

Background: Positive and negative allosteric modulators of α5 GABAA receptors (PAM and NAM, respectively) are worthy of investigation as putative treatments of Alzheimer’s disease (AD). However, their potential to modify a dynamic range of behaviors in AD models needs to be systematically examined. Objective: The study aimed to assess effects of MP-III-022 as PAM and PWZ-029 as NAM on emotional reactivity, motivation, and motor function, as well as on gene expression of GABRA2, GABRA3 and GABRA5 subunit of GABAA receptors in prefrontal cortex (PFC) and hippocampus (HC) in 5xFAD mice, as an early-onset transgenic AD model. Methods: The 6-month-old 5xFAD transgenic and non-transgenic mice of both genders underwent a battery of reflexes and behavioral tests (sensorimotor tests, elevated plus maze, and open field) after 10-day intraperitoneal treatment with MP-III-022, PWZ-029, or solvent. The behavioral battery was followed by qPCR analysis of gene expression. Results: MP-III-022 induced a decline in motor function, while PWZ-029 further decreased emotionality of transgenic males, as compared to the transgenic control. No interfering effects on non-cognitive behavior were observed in female mice. In HC, both treatments reversed reciprocal GABRA2 and GABRA3 changes in transgenic females. In PFC, MP-III-022 decreased GABRA5 in both genders, while PWZ-029 increased GABRA2 in male transgenic animals. Conclusion: Gender-dependent protracted effects of PAMs and NAMs in AD model, with detrimental impact on motor capabilities of PAM, and attenuation of emotionality elicited by NAM in transgenic males, were revealed. This favors future research of α5 GABAA receptor modulation in females as more promising.