Effects of folic acid combined with vitamin B12 on lipid metabolism in rats with high-fat diet

Abstract

Abstract:

Objective To explore the effects of folic acid combined with vitamin B₁₂ on lipid metabolism in rats with high-fat diet，and to provide a reference for the prevention and treatment of lipid metabolism-related diseases. Methods Totally 30 SD rats were divided into 2 groups randomly by body weight，10 SD male rats were fed by conventional diet as control group. After 28 days of high fat diet，the other 20 rats were allotted into 2 groups equally depending on total cholesterol and triglyceride，including folic acid combined with vitamin B₁₂ group（folic acid dose 1.00 mg/kg and vitamin B₁₂ dose 0.06 mg/kg） and high-fat diet group. All rats were oral gavaged daily for 40 days. The high-fat diet group and the control group were given an equivalent amount of 0.9% saline solution. The levels of total cholesterol，triglyceride，low density lipoprotein cholesterol（LDL-C） and high density lipoprotein cholesterol（HDL-C） in the serum were measured on 0th day，20th day and 40th day of intervention，and the body weight of rats were recorded. At the end of intervention，the levels of total cholesterol and triglyceride in liver tissue homogenate were detected，and the level of adiponectin，resistin and interleukin（IL）-6 were measured using ELISA method. The qPCR method were used to determine the hepatic mRNA expression of lipid metabolism enzymes including cholesterol 7α-hydroxylase（CYP7A1），3-hydroxy-3-methyl glutaryl coenzyme A reductase（HMGCR），fatty acid synthase（FAS） and acetylcoenzyme A carboxylase（ACC）. Results At 0th，20th and 40th day of intervention，the levels of serum total cholesterol，triglyceride and LDL-C in high-fat diet group were higher than those in the control group，and the differences were statistically significant（all P<0.05）. At 20th day and 40th day of intervention，the levels of serum total cholesterol，triglyceride and LDL-C in folic acid combined with vitamin B₁₂ group were lower than those in the high fat diet group，and the differences were statistically significant（all P<0.05）. At 40th day of intervention，the levels of hepatic total cholesterol and triglyceride in high fat diet group were higher than those in the control group，the level of serum adiponectin in high fat diet group was lower than that in the control group，the level of serum resistin and IL-6 in high fat diet group were higher than those in the control group，the hepatic mRNA expression of CYP7A1 in high fat diet group was lower than that in the control group，the hepatic mRNA expression of HMGCR，FAS and ACC in high fat diet group were higher than those in the control group，and the differences were statistically significant（all P<0.05）. The levels of hepatic total cholesterol and triglyceride in folic acid combined with vitamin B₁₂ group was significantly lower than that in high fat group，the levels of serum adiponectin in folic acid combined with vitamin B₁₂ group was significantly higher than that in high fat group，and the levels of serum resistin and IL-6 in folic acid combined with vitamin B₁₂ group were significantly lower than those in the high-fat group（all P<0.05），and the hepatic mRNA expression of HMGCR and FAS were significantly lower than those in the high-fat group（all P<0.05）. Conclusion Folic acid combined with vitamin B₁₂ can improve the lipid metabolism in rats with high-fat diet. The possible molecular mechanism may be related to inhibiting the expression of key lipid metabolic enzymes including FAS and ACC，and regulating the secretion of adipokines such as adiponectin，resistin and IL-6.

Key words: Folic acid, Vitamin B₁₂, Combined effect, High-fat diet, Lipid metabolism, Rats

CLC Number:

R-332

ZHANG Dalong, ZHOU Dianming, ZHANG Lu, LI Min, YUE Wenbo, QIAN Zhiyong. Effects of folic acid combined with vitamin B₁₂ on lipid metabolism in rats with high-fat diet. [J]OCCUPATION AND HEALTH, 2026, 42(4): 459-464.

Figures/Tables 8

References 21

[1]	DUTHIE S J, NARAYANAN S, BRAND G M, et al. Impact of folate deficiency on DNA stability[J]. J Nutr, 2002, 132(8 Suppl):2444S-2449S.
[2]	BOACHIE J, ADAIKALAKOTESWARI A, SAMAVAT J, et al. Low vitamin B12 and lipid metabolism:Evidence from pre-clinical and clinical studies[J]. Nutrients, 2020, 12(7):1925. DOI URL
[3]	FUKUOKA H, KUBOTA T. One-carbon metabolism and lipid metabolism in DOHaD[J]. Adv Exp Med Biol, 2018,1012:3-9.
[4]	LYON P, STRIPPOLI V, FANG B, et al. B vitamins and one-carbon metabolism:Implications in human health and disease[J]. Nutrients, 2020, 12(9):2867. DOI URL
[5]	XIA M F, BIAN H, ZHU X P, et al. Serum folic acid levels are associated with the presence and severity of liver steatosis in Chinese adults[J]. Clin Nutr, 2018, 37(5):1752-1758. DOI URL
[6]	SARASWATHY K N, JOSHI S, YADAV S, et al. Metabolic distress in lipid & one carbon metabolic pathway through low vitamin B-12:A population based study from North India[J]. Lipids Health Dis, 2018, 17(1):96. DOI
[7]	MAHALLE N, KULKARNI M V, GARG M K, et al. Vitamin B₁₂ deficiency and hyperhomocysteinemia as correlates of cardiovascular risk factors in Indian subjects with coronary artery disease[J]. J Cardiol, 2013, 61(4):289-294. DOI URL
[8]	张大龙, 张倩, 周晓丽, 等. 叶酸对高脂饮食大鼠血脂、脂肪细胞因子及脂质代谢酶的影响[J]. 职业与健康, 2019, 35(10):1321-1325.
[9]	张大龙, 周殿明, 张静, 等. 维生素B₁₂对高脂饮食大鼠血脂、肝脂及免疫球蛋白的影响[J]. 职业与健康, 2023, 39(15):2054-2058.
[10]	ZHANG D, ZHOU D, WANG X, et al. Selenium and vitamin B₂ cosupplementation alleviates high-fat-diet-induced nonalcoholic fatty liver disease in rats by regulating hepatic lipid metabolism[J]. Eur J Lipid Sci Technol, 2023, 126(1):2300020. DOI URL
[11]	刘天啸, 赵冬, 齐玥. 全球血脂异常流行病学现状[J]. 中国心血管杂志, 2023, 28(3):193-196.
[12]	ALVES-BEZERRA M, COHEN D E. Triglyceride metabolism in the liver[J]. Compr Physiol, 2017, 8(1):1-8. DOI URL
[13]	ZECHNER R, ZIMMERMANN R, EICHMANN T O, et al. FAT SIGNALS--lipases and lipolysis in lipid metabolism and signaling[J]. Cell Metab, 2012, 15(3):279-291. DOI PMID
[14]	WANG X, ZHANG S, LI Z. Adipokines in glucose and lipid metabolism[J]. Adipocyte, 2023, 12(1):2202976. DOI URL
[15]	JENSEN-URSTAD A P, SEMENKOVICH C F. Fatty acid synthase and liver triglyceride metabolism:housekeeper or messenger[J]Biochim Biophys Acta, 2012, 1821(5):747-753.
[16]	KIM C W, ADDY C, KUSUNOKI J, et al. Acetyl CoA carboxylase inhibition reduces hepatic steatosis but elevates plasma triglycerides in mice and humans:A bedside to bench investigation[J]. Cell Metab, 2017, 26(2):394-406. DOI URL
[17]	LIN H, WEI C, ZHANG X, et al. HMGR overexpression and interference affect the expression of steroidogenic genes and cholesterol content in bovine intramuscular adipocytes[J]. Sci Rep, 2020, 10(1):16606. DOI PMID
[18]	WAHLSTRÖM A, SAYIN S I, MARSCHALL H U, et al. Intestinal crosstalk between bile acids and microbiota and its impact on host metabolism[J]. Cell Metab, 2016, 24(1):41-50. DOI PMID
[19]	YANAI H, YOSHIDA H. Beneficial effects of adiponectin on glucose and lipid metabolism and atherosclerotic progression:Mechanisms and perspectives[J]. Int J Mol Sci, 2019, 20(5):1190. DOI URL
[20]	KIM J E, KIM J S, JO M J, et al. The roles and associated mechanisms of adipokines in development of metabolic syndrome[J]. Molecules, 2022, 27(2):334. DOI URL
[21]	CHEN C, HUO J S, ZHUO Q, et al. Lipid accumulation and IL-6 production in L02 hepatocytes induced by sodium oleate:Dose and time dependence[J]. Biomed Environ Sci, 2021, 34(12):998-1004.

组别	只数	第0 天	第20天	第40天
叶酸联合维生素B₁₂ 干预组	10	409.4±19.3	478.6±31.7	536.6±41.1
高脂饮食组	10	402.4±14.2	481.0±21.2	540.9±28.3
空白对照组	10	391.2±25.4	464.0±34.0	500.6±36.5
F值		1.773	0.985	2.321
P		>0.05	>0.05	>0.05

组别	只数	第0 天	第20天	第40天
叶酸联合维生素B₁₂ 干预组	10	409.4±19.3	478.6±31.7	536.6±41.1
高脂饮食组	10	402.4±14.2	481.0±21.2	540.9±28.3
空白对照组	10	391.2±25.4	464.0±34.0	500.6±36.5
F值		1.773	0.985	2.321
P		>0.05	>0.05	>0.05

组别	只数	第0天	第20天	第40天
叶酸联合维生素B₁₂ 干预组	10	2.24±0.40^a	2.39±0.44^ab	2.08±0.57^b
高脂饮食组	10	2.29±0.54^a	2.78±0.36^a	2.71±0.43^a
空白对照组	10	1.71±0.42	1.95±0.40	2.06±0.48
F值		5.002	10.767	5.553
P		<0.05	<0.01	<0.05

组别	只数	第0天	第20天	第40天
叶酸联合维生素B₁₂ 干预组	10	2.24±0.40^a	2.39±0.44^ab	2.08±0.57^b
高脂饮食组	10	2.29±0.54^a	2.78±0.36^a	2.71±0.43^a
空白对照组	10	1.71±0.42	1.95±0.40	2.06±0.48
F值		5.002	10.767	5.553
P		<0.05	<0.01	<0.05

组别	只数	第0天	第20天	第40天
叶酸联合维生素B₁₂ 干预组	10	0.80±0.16^a	0.59±0.19^b	0.59±0.23^b
高脂饮食组	10	0.81±0.13^a	0.80±0.18^a	0.84±0.33^a
空白对照组	10	0.59±0.10	0.54±0.17	0.54±0.18
F值		8.886	5.889	4.105
P		<0.01	<0.01	<0.05

Effects of folic acid combined with vitamin B₁₂ on lipid metabolism in rats with high-fat diet

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组别	只数	第0天	第20天	第40天
叶酸联合维生素B₁₂ 干预组	10	0.58±0.11^a	0.60±0.20^b	0.43±0.13^b
高脂饮食组	10	0.57±0.16^a	0.80±0.18^a	0.66±0.10^a
空白对照组	10	0.33±0.10	0.47±0.14	0.40±0.11
F值		13.461	8.696	15.718
P		<0.01	<0.01	<0.01

组别	只数	第0天	第20天	第40天
叶酸联合维生素B₁₂ 干预组	10	0.87±0.15	1.16±0.20	1.49±0.47
高脂饮食组	10	0.89±0.27	1.03±0.34	1.53±0.36
空白对照组	10	0.97±0.20	1.28±0.32	1.75±0.37
F值		0.623	1.824	1.215
P		>0.05	>0.05	>0.05

组别	只数	总胆固醇	三酰甘油
叶酸联合维生素B₁₂ 干预组	10	1.64±0.46^ab	5.63±0.99^ab
高脂饮食组	10	2.31±0.35^a	6.60±0.50^a
空白对照组	10	1.28±0.31	2.74±0.53
F值		18.540	79.804
P值		<0.01	<0.01

组别	只数	脂联素（mg/L）	抵抗素（pg/L）	IL-6（ng/L）
叶酸联合维生素B₁₂ 干预组	10	127.65±5.95^ab	203.25±8.48^ab	20.83±1.77^ab
高脂饮食组	10	116.10±12.98^a	257.87±37.27^a	27.71±1.07^a
空白对照组	10	131.90±6.49	174.55±34.17	16.73±4.67
F值		8.162	20.443	35.373
P值		<0.01	<0.01	<0.01

组别	只数	CYP7A1	HMGCR	FAS	ACC
叶酸联合维生素B₁₂ 干预组	5	0.59±0.21^a	2.41±0.56^b	3.22±1.14^ab	2.17±0.93^a
高脂饮食组	5	0.41±0.26^a	6.40±1.87^a	8.44±3.14^a	2.49±1.04^a
空白对照组	5	1.05±0.12	1.00±0.07	1.05±0.20	1.05±0.22
F值		12.668	30.932	19.293	4.329
P		<0.01	<0.01	<0.01	<0.05

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