Background: fourth generation antipsychotics have been implicated in the blockade of calcium
signalling through inhibition of dopamine receptive sites on dopaminergic D2 Receptor (D2R). As a
result of the abnormal calcium signalling associated with D2R inhibition, changes occur in the motor
and memory neural axis leading to the observed behavioural deficits after prolonged haloperidol.
Thus, Vitamin D3 receptor (VD3R), a calcium controlling receptor in the striatum can be targeted
to relief the neurological symptoms associated with haloperidol (−D2R) induced PD. Aim:
This study sets to investigate the role of VD3R activation in vitro and in vivo after haloperidolinduced
Dopaminergic (D2R) blockade. In addition, we examined the associated neural activity
and behavioural changes in parkinsonian and VDRA intervention mice. Methods: Dopaminergic
D2R inhibition was investigated in vitro using Melanocytes isolated from the scale of a Tilapia. In
four separate set ups, the cells were cultured in calcium free Ringer’s solution as follows; 300 μM
haloperidol, 100 μM VD3, 100 mM calcium chloride and a combination of 300 μM haloperidol
and 100 μM VD3. Subsequently, dopaminergic vesicle accumulation and calcium signalling were observed in bright field microscopy using blue and green fluorescence probes. In the second phase,
PD was induced in adult BALB/c mice (−D2; n = 8) after 14 days of intraperitoneal haloperidol
treatment (10 mg/Kg). A set of n = 4 mice were untreated (−D2) while the other group (n = 4) received
100 mg/Kg of VD3 for 7 days (−D2/+VDR). The control groups (n = 4 each) were treated with
normal saline (NS) and VD3 (+VDR) for 14 days. At the end of the treatment phase, the animals
were assessed in Rotarod, parallel bar-, cylinder-, Y-Maze-, one trial place recognition- and novel
object recognition-(NOR) tests. Neural activity was measured using chronic electrode implants
placed in the M1 (motor cortex), CPu (striatum), CA1 (hippocampus) and PFC (prefrontal cortex).
Neural activity was compared with the outcomes of behavioural tests for memory and motor functions
and data was expressed as mean ± SEM (analysed using ANOVA with Tukey post-hoc test,
significant level was set at 0.05). Results/Discussion: in vitro outcomes show that VDR increase
calcium signalling and reverses the effect of haloperidol; specifically by reducing dopaminergic
vesicle accumulation in the cell body. Similarly, in vivo neural recordings suggest an increase in
calcium hyperpolarization currents in the CPu and PFC of intervention mice (−D2/+VDR) when
compared with the parkinsonian mice (−D2). These animals (−D2/+VDR) also recorded an improvement
in spatial working memory and motor function versus the Parkinsonian mice (−D2).
These outcomes suggest the role of CPu-PFC corticostriatal outputs in the motor-cognitive decline
seen in parkinsonian mice. Similarly, VDRA reduced the neural deficits through restoration of calcium
currents (burst activities) in the intervention mice (−D2/+VDR). Conclusion: VDRA treatment
reduced the motor-cognitive defects observed in haloperidol induced PD. Our findings suggest the
role of VDRA in restoration of calcium currents associated with PFC and CPu corticostriatal outputs
seen as burst frequencies in in vivo neural recording