Alleviation of cerebellar impairment,cognitive decline,and depression by a chlorzoxazone-folic acid combination in a Huntington's disease transgenic mouse model
Restricted accessResearch articleFirst published online 2026
Alleviation of cerebellar impairment,cognitive decline,and depression by a chlorzoxazone-folic acid combination in a Huntington's disease transgenic mouse model
Huntington's disease (HD) is a hereditary neurodegenerative condition, passed down in an autosomal dominant manner, characterized by the gradual decline of motor functions, such as chorea, along with psychiatric symptoms and cognitive deterioration. In HD, the striatum is the main area impacted, although cerebellar atrophy has also been observed independently of striatal degeneration. Consequently, HD patients may exhibit symptoms consistent with cerebellar cognitive affective syndrome (CCAS) due to cerebellar involvement. CCAS manifestations have been noted in various rodent models of motor dysfunctions linked to cerebellar atrophy. Previous research has identified anxiety, memory deficits, and depressive-like behavior in the YAC128 transgenic murine model of HD. This investigation examines the effects of prolonged administration of the small-conductance calcium-activated potassium channel (SK channel) positive modulator chlorzoxazone (CHZ), both alone and in combination with folic acid (FA), on cerebellar Purkinje cell (PC) electrophysiology and morphology, along with locomotor and memory decline and emotional state changes in YAC128 mice. The findings indicate that both CHZ alone and the mixture of CHZ and FA similarly ameliorated cerebellar-specific deficits, encompassing the precision of PC electrophysiological activity and beam walk performance in YAC128 mice. However, solely the mixture of CHZ and FA significantly alleviated depressive-like symptoms and improved recognition memory. These findings imply that a therapeutic approach addressing both motor and cognitive-affective deficits is essential for the holistic management of movement disorders associated with cerebellar atrophy, including HD.
CaillaudMLaisneyMBejaninA, et al.Social cognition profile in early Huntington disease: insight from neuropsychological assessment and structural neuroimaging. J Huntingtons Dis2024; 13: 467–477.
3.
PaulsenJS. Cognitive impairment in Huntington disease: diagnosis and treatment. Curr Neurol Neurosci Rep2011; 11: 474–483.
4.
SprengelmeyerROrthMMüllerHP, et al.The neuroanatomy of subthreshold depressive symptoms in Huntington's disease: a combined diffusion tensor imaging (DTI) and voxel-based morphometry (VBM) study. Psychol Med2014; 44: 1867–1878.
5.
van DuijnE. Medical treatment of behavioral manifestations of Huntington disease. Handb Clin Neurol2017; 144: 129–139.
6.
VonsattelJPMyersRHStevensTJ, et al.Neuropathological classification of Huntington's disease. J Neuropathol Exp Neurol1985; 44: 559–577.
RubUHocheFBruntER, et al.Degeneration of the cerebellum in Huntington's disease (HD): possible relevance for the clinical picture and potential gateway to pathological mechanisms of the disease process. Brain Pathol2013; 23: 165–177.
10.
WolfRCThomannPASambataroF, et al.Abnormal cerebellar volume and corticocerebellar dysfunction in early manifest Huntington's disease. J Neurol2015; 262: 859–869.
11.
Singh-BainsMKMehrabiNFSehjiT, et al.Cerebellar degeneration correlates with motor symptoms in Huntington disease. Ann Neurol2019; 85: 396–405.
12.
Santos-LobatoBLRochaJSSRochaLC. Case report: cerebellar sparing in juvenile Huntington's disease. Front Neurol2023; 13: 1089193.
13.
PatraKCShirolkarMS. Childhood-onset (Juvenile) Huntington's disease: a rare case report. J Pediatr Neurosci2015; 10: 276–279.
14.
LatimerCSFlanaganMECiminoPJ, et al.Neuropathological comparison of adult onset and juvenile Huntington's disease with cerebellar atrophy: a report of a father and son. J Huntingtons Dis2017; 6: 337–348.
15.
DoughertySEReevesJLLucasEK, et al.Disruption of Purkinje cell function prior to huntingtin accumulation and cell loss in an animal model of Huntington disease. Exp Neurol2012; 236: 171–178.
16.
DoughertySEReevesJLLesortM, et al.Purkinje cell dysfunction and loss in a knock-in mouse model of Huntington disease. Exp Neurol2013; 240: 96–102.
17.
EgorovaPAGavrilovaAVBezprozvannyIB. Ataxic symptoms in Huntington's disease transgenic mouse model are alleviated by chlorzoxazone. Front Neurosci2020; 14: 279.
18.
FranklinGLCamargoCHFMeiraAT, et al.The role of the cerebellum in Huntington's disease: a systematic review. Cerebellum2021; 20: 254–265.
RudolphSBaduraALutzuS, et al.Cognitive-Affective functions of the cerebellum. J Neurosci2023; 43: 7554–7564.
21.
AsherMRosaJGRainwaterO, et al.Cerebellar contribution to the cognitive alterations in SCA1: evidence from mouse models. Hum Mol Genet2020; 29: 117–131.
22.
MarininaKSBezprozvannyIBEgorovaPA. Cognitive decline and mood alterations in the mouse model of spinocerebellar ataxia type 2. Cerebellum2024; 23: 145–161.
23.
BohnePMourabitDBJostenM, et al.Cognitive deficits in episodic ataxia type 2 mouse models. Hum Mol Genet2021; 30: 1811–1832.
24.
MarininaKSBezprozvannyIBEgorovaPA. Memory decline, anxiety and depression in the mouse model of spinocerebellar ataxia type 3. Hum Mol Genet2024; 33: 299–317.
25.
BohnePRybarskiMMourabitDB, et al.Cerebellar contribution to threat probability in a SCA6 mouse model. Hum Mol Genet2022; 31: 3807–3828.
26.
EgorovaPABezprozvannyIB. Electrophysiological studies support utility of positive modulators of SK channels for the treatment of spinocerebellar ataxia type 2. Cerebellum2022; 21: 742–749.
27.
WomackMDKhodakhahK. Somatic and dendritic small-conductance calcium-activated potassium channels regulate the output of cerebellar Purkinje neurons. J Neurosci2003; 23: 2600–2607.
28.
BushartDDChopraRSinghV, et al.Targeting potassium channels to treat cerebellar ataxia. Ann Clin Transl Neurol2018; 5: 297–314.
29.
KasumuAWHougaardCRodeF, et al.Selective positive modulator of calcium-activated potassium channels exerts beneficial effects in a mouse model of spinocerebellar ataxia type 2. Chem Biol2012; 19: 1340–1353.
30.
ShakkottaiVGdo Carmo CostaMDell'OrcoJM, et al.Early changes in cerebellar physiology accompany motor dysfunction in the polyglutamine disease spinocerebellar ataxia type 3. J Neurosci2011; 31: 13002–13014.
31.
WalterJTAlvinaKWomackMD, et al.Decreases in the precision of Purkinje cell pacemaking cause cerebellar dysfunction and ataxia. Nat Neurosci2006; 9: 389–397.
32.
AlvinaKKhodakhahK. The therapeutic mode of action of 4-aminopyridine in cerebellar ataxia. J Neurosci2010; 30: 7258–7268.
33.
AlvinaKKhodakhahK. KCa channels as therapeutic targets in episodic ataxia type-2. J Neurosci2010; 30: 7249–7257.
34.
GaoZTodorovBBarrettCF, et al.Cerebellar ataxia by enhanced Ca(V)2.1 currents is alleviated by Ca2+-dependent K+-channel activators in Cacna1a(S218L) mutant mice. J Neurosci2012; 32: 15533–15546.
35.
RomanoSCoarelliGMarcotulliC, et al.Riluzole in patients with hereditary cerebellar ataxia: a randomised, double-blind, placebo-controlled trial. Lancet Neurol2015; 14: 985–991.
36.
MatschkeLARinneSSnutchTP, et al.Calcium-activated SK potassium channels are key modulators of the pacemaker frequency in locus coeruleus neurons. Mol Cell Neurosci2018; 88: 330–341.
37.
EgorovaPAZakharovaOAVlasovaOL, et al.In vivo analysis of cerebellar Purkinje cell activity in SCA2 transgenic mouse model. J Neurophysiol2016; 115: 2840–2851.
38.
MarininaKSBezprozvannyIBEgorovaPA. A chlorzoxazone-folic acid combination improves cognitive affective decline in SCA2-58Q mice. Sci Rep2023; 13: 12588.
39.
MarininaKSBezprozvannyIBEgorovaPA. A combination of chlorzoxazone and folic acid improves recognition memory, anxiety and depression in SCA3-84Q mice. Hum Mol Genet2024; 33: 1406–1419.
40.
SlowEJvan RaamsdonkJRogersD, et al.Selective striatal neuronal loss in a YAC128 mouse model of Huntington disease. Hum Mol Genet2003; 12: 1555–1567.
41.
Van LooPLVan ZutphenLFBaumansV. Male management: coping with aggression problems in male laboratory mice. Lab Anim2003; 37: 300–313.
42.
Van RaamsdonkJMPearsonJRogersDA, et al.Loss of wild-type huntingtin influences motor dysfunction and survival in the YAC128 mouse model of Huntington disease. Hum Mol Genet2005; 14: 1379–1392.
43.
El-SayedNSNamYWEgorovaPA, et al.Structure-Activity relationship study of subtype-selective positive modulators of KCa2 channels. J Med Chem2022; 65: 303–322.
44.
MansouriBHenneWMOommanSK, et al.Involvement of calpain in AMPA-induced toxicity to rat cerebellar Purkinje neurons. Eur J Pharmacol2007; 557: 106–114.
45.
KasumuAWLiangXEgorovaP, et al.Chronic suppression of inositol 1,4,5-triphosphate receptor-mediated calcium signaling in cerebellar purkinje cells alleviates pathological phenotype in spinocerebellar ataxia 2 mice. J Neurosci2012; 32: 12786–12796.
46.
EgorovaPAGavrilovaAVBezprozvannyIB. In vivo analysis of the spontaneous firing of cerebellar Purkinje cells in awake transgenic mice that model spinocerebellar ataxia type 2. Cell Calcium2021; 93: 102319.
47.
LueptowLM. Novel object recognition test for the investigation of learning and memory in mice. J Visualized Exp: JoVE2017; 126: 55718.
48.
MarininaKSBezprozvannyIBEgorovaPA. Anxiety, memory, and social impairments in the YAC128 mouse model of Huntington's disease. J Huntingtons Dis2024; 13: 431–448.
49.
PlacidoEGomes WelterPWinkA, et al.Beyond motor deficits: environmental enrichment mitigates Huntington's disease effects in YAC128 mice. Int J Mol Sci2023; 24: 12607.
50.
HoughtonLAGrayARRoseMC, et al.Long-term effect of low-dose folic acid intake: potential effect of mandatory fortification on the prevention of neural tube defects. Am J Clin Nutr2011; 94: 136–141.
51.
PugaAMRupertoMSamaniego-VaeskenML, et al.Effects of supplementation with folic acid and its combinations with other nutrients on cognitive impairment and Alzheimer's disease: a narrative review. Nutrients2021; 13: 2966.
52.
PouladiMAGrahamRKKarasinskaJM, et al.Prevention of depressive behaviour in the YAC128 mouse model of Huntington disease by mutation at residue 586 of huntingtin. Brain2009; 132: 919–932.
53.
ChenXWuJLvovskayaS, et al.Dantrolene is neuroprotective in Huntington's disease transgenic mouse model. Mol Neurodegener2011; 6: 81.
54.
YasuharaMLevyG. Kinetics of drug action in disease states. XXVII. Effect of experimental renal failure on the pharmacodynamics of zoxazolamine and chlorzoxazone. J Pharmacol Exp Ther1988; 246: 165–169.
55.
YasuharaMLevyG. Pharmacodynamics of zoxazolamine and chlorzoxazone in rats. Pharm Res1988; 5: 401–407.
56.
LinYDesboisAJiangS, et al.Group B vitamins protect murine cerebellar granule cells from glutamate/NMDA toxicity. Neuroreport2004; 15: 2241–2244.
57.
KoohpeymaHGoudarziIElahdadi SalmaniM, et al.Folic acid protects rat cerebellum against oxidative damage caused by homocysteine: the expression of Bcl-2, Bax, and caspase-3 apoptotic genes. Neurotox Res2020; 37: 564–577.
58.
BaiYMaX. Chlorzoxazone exhibits neuroprotection against Alzheimer's disease by attenuating neuroinflammation and neurodegeneration in vitro and in vivo. Int Immunopharmacol2020; 88: 106790.
59.
YoshikawaMSuemaruK. Prenatal folate deficiency impairs sociability and memory/recognition in mice offspring. Brain Res2024; 1822: 148639.
60.
MaFWuTZhaoJ, et al.Folic acid supplementation improves cognitive function by reducing the levels of peripheral inflammatory cytokines in elderly Chinese subjects with MCI. Sci Rep2016; 6: 37486.
61.
de Paula Nascimento-CastroCWinkelmann-DuarteECManciniG, et al.Temporal characterization of behavioral and hippocampal dysfunction in the YAC128 mouse model of Huntington's disease. Biomedicines2022; 10: 1433.
62.
SouthwellALFranciosiSVillanuevaEB, et al.Anti-semaphorin 4D immunotherapy ameliorates neuropathology and some cognitive impairment in the YAC128 mouse model of Huntington disease. Neurobiol Dis2015; 76: 46–56.
63.
McGregorALD'SouzaGKimD, et al.Varenicline improves motor and cognitive deficits and decreases depressive-like behaviour in late-stage YAC128 mice. Neuropharmacology2017; 116: 233–246.
64.
ReusGZMacielALAbelairaHM, et al.omega-3 and folic acid act against depressive-like behavior and oxidative damage in the brain of rats subjected to early- or late-life stress. Nutrition2018; 53: 120–133.
65.
FaladeJOnaolapoAYOnaolapoOJ. Evaluation of the behavioural, antioxidative and histomorphological effects of folic acid-supplemented diet in dexamethasone-induced depression in mice. Cent Nerv Syst Agents Med Chem2021; 21: 73–81.
66.
BenderAHaganKEKingstonN. The association of folate and depression: a meta-analysis. J Psychiatr Res2017; 95: 9–18.
67.
FavaMMischoulonD. Folate in depression: efficacy, safety, differences in formulations, and clinical issues. J Clin Psychiatry2009; 70: 12–17.
