Serine supplementation: Is it a new option for the treatment of diabetic polyneuropathy?

IF 3.2 3区 医学
Hiroki Mizukami
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Although it is also speculated that disturbances in aminoacidemia play a role in the development of diabetic complications, their pathogenesis has not been sufficiently elucidated in detail.</p><p>Diabetic peripheral neuropathy (DPN) is the most frequent complication among diabetic patients. Its symptoms are pain, hyperalgesia, hypoalgesia, and paralysis, which can decrease the quality of life of patients. In diabetic peripheral neuropathy, peripheral nerve fibers are affected from the prediabetic stage. Because diabetic peripheral neuropathy is a retrograde-type neuropathy, small nerve fibers located in the epidermis or cornea are first degraded. Small nerve fibers consist of myelinated Aδ fibers and unmyelinated C fibers. Small fiber neuropathy is a disorder of these nerve fibers, manifesting as spontaneous pain or loss of pain sensation with reduction of their density. As diabetic peripheral neuropathy progresses, large myelinated fibers are also decreased with segmental demyelination and microvascular changes, such as thickening of the vascular wall and stenosis of intraneuronal vessels. Without proper treatment, these patients develop paralysis or ulcer formation on the foot. To date, diabetic peripheral neuropathy is thought to be caused by aberrant glucose metabolism in neuronal cells, Schwann cells and endothelial cells in the peripheral nervous system. Abnormal glycemic metabolism elicits nerve dysfunction with activation of the polyol pathway, protein kinase C, advanced glycation end products and its receptor, the receptor for advanced glycation end product (RAGE) pathway, oxidative stress, and inflammation. Clinically, in addition to hyperglycemia, metabolic syndrome, including dyslipidemia, obesity and hypertension, is well known to be a contributor to the pathogenesis of diabetic peripheral neuropathy. In addition to glucose and fatty acid metabolism, recent metabolomics studies have revealed the involvement of another metabolite, glucosamine, in the pathogenesis of diabetic peripheral neuropathy. Lower baseline amino acid levels such as asparagine and glutamine were correlated with cardiovascular autonomic neuropathy in a small sample of subjects with type 1 diabetes<span><sup>3</sup></span>. Thus, today, it is recognized that the pathogenesis of diabetic peripheral neuropathy is not caused only by abnormal glucose metabolism but is a complex condition in which metabolic failure of other nutrients is involved. However, the full picture of the specific metabolic changes in diabetic peripheral neuropathy has not yet been elucidated.</p><p>In this context, Handzlik <i>et al</i>.<span><sup>4</sup></span> recently reported in <i>Nature</i> that the combination of serine deficiency and dyslipidemia can cause experimental diabetic peripheral neuropathy mainly consisting of small fiber neuropathy, in which serine supplementation can delay the onset (Figure 1). The <i>db/db</i> mouse model, which is a conventional obese type 2 diabetic model, showed reductions in hepatic and renal serine levels by approximately 30% relative to wild-type mice, and glycine pools were reduced by 30–50% in the liver, kidney, inguinal white adipose tissue, and plasma. The expression level of components encoding the glycine cleavage system was increased in <i>db/db</i> liver, whereas the expression of genes associated with <i>de novo</i> serine synthesis was significantly reduced. These results indicate that serine synthesis is limited in diabetic mice. Although streptozotocin (STZ)-induced type 1 diabetic model mice showed alterations in plasma glycine and BCAAs (but not serine) at 1 week after streptozotocin treatment, elevated serine disposal was confirmed by co-administration of glucose and serine 2 weeks after injection. Thus, insulin resistance or deficiency can both contribute to the acceleration of serine catabolism or the disposal and reduction of circulating serine in diabetic mice. Of note, weight gain caused by a high-fat diet (HFD) was attenuated by dietary serine and glycine restriction with a reduction in fat mass but not lean mass relative to the treatment with HFD alone, whereas food, calorie, and water intake; calorie absorption; insulin and glucose tolerance; and physical activity were all unaffected. Recent reports suggest that changes in the microbiome composition in the gut can be involved in the pathogenesis of small fiber neuropathy or diabetic peripheral neuropathy<span><sup>5</sup></span>. Investigation of the fecal microbiome revealed that the log ratios of the strains of microorganisms expressing complete serine biosynthesis were increased, while glycine cleavage pathways were decreased with a reduction in the strains expressing a complete fatty acid synthesis pathway by treatment with a serine- and glycine-restricted HFD.</p><p>Serine catabolism is associated with sphingolipid metabolism <i>via</i> serine palmitoyl transferase. Sphingolipids are abundantly contained in the myelin sheath in peripheral nerves. Restriction of dietary serine and glycine reduced hepatic palmitate synthesis by approximately 70% relative to serine-replete control diets. Hepatic cholesterol synthesis was increased in the serine-free HFD group compared with the HFD group, with a reduction in the expression of cholesterol biosynthesis enzymes and an increase or no change in the expression of cholesterol biosynthesis enzymes.</p><p>Recently, the involvement of insulin resistance in the peripheral nerves has been reported in diabetic peripheral neuropathy, in which proinflammatory macrophage infiltration activated by RAGE signaling elicits deficits in retrograde axonal transportation. Because serine and glycine levels were less associated with changes in protein kinase B phosphorylation than dietary fat and carbohydrate contents, serine restriction could evoke changes in fatty acid metabolism independent of insulin signaling.</p><p>Serine deficiency is known to be associated with peripheral neuropathy and various neurodegenerative disorders in previous clinical studies. Similarly, mice fed serine- and glycine-free low-fat chow diets for 12 months exhibited thermal hypoalgesia with intraepidermal nerve fiber reduction in the paw skin. Interestingly, a HFD accelerated the thermal hypoalgesia in mice fed a serine- and glycine-restricted diet for just 3 months. These findings indicate that a combination of low systemic serine and HFD feeding accelerates the onset of small fiber neuropathy in mice. The authors further explored the metabolic changes associated with neuropathy caused by serine restriction. 1-Deoxysphingolipids, including deoxydihydroceramides, are neurotoxic sphingolipids. A 1-deoxysphingolipid is produced when the first enzyme of the sphingolipid biosynthetic pathway, serine palmitoyltransferase, uses <span>l</span>-alanine as a substrate instead of its canonical amino acid substrate, serine. As expected, the contents of deoxydihydro-ceramides in the liver and paw skin increased in serine- and glycine-restricted mice fed HFD, while the canonical ceramide content was reduced. Administration of an inhibitor of serine palmitoyl transferase (myriocin) strongly reduced the levels of sphingolipids as well as of triglycerides and diacylglycerides. Myriocin ameliorated thermal hypoalgesia and the small fiber nerve density in serine- and glycine-restricted HFD mice, while myriocin had no impact on tactile sensing or nerve conduction velocities. Importantly, the administration of myriocin at 6 weeks of age prevented the manifestation of thermal hypoalgesia, tactile sensation, and small fiber density in the epidermis in <i>db/db</i> mice without affecting body weight gain, hyperglycemia, or plasma serine levels. Myriosin treatment strongly reduced canonical sphingolipids in the liver but showed limited effects on paw skin 1-deoxysphingolipids and ceramides. Finally, based on the results obtained thus far, the authors investigated whether a serine-supplemented diet prevents the development of neuropathy. A 3% serine-enriched diet starting at 6 weeks of age elevated levels of plasma and hepatic serine, but not glycine levels. The body weight was comparable, while a slight increase in circulating glucose levels was observed. Neuropathic manifestations, including both thermal and tactile hypoalgesia, were reduced in diabetic mice fed this serine-enriched diet. Canonical sphingolipid levels were similar across the tissues, while 1-deoxysphingolipids were robustly decreased in both liver and paw skin. Collectively, these data suggest that supplementation with serine can prevent the onset and progression of diabetic peripheral neuropathy.</p><p>The novel point of this research is that the onset of diabetic peripheral neuropathy could be prevented by correcting the intake of nutrients without affecting blood glucose levels. Currently, no radical therapy for diabetic peripheral neuropathy has been established. Although aldose reductase inhibitors and α-lipoic acid have been clinically applied, their effects are limited. This study suggests that the decrease in serine synthesis and the increase in serine disposal are due to insufficient action of insulin. Although the most important treatment for neuropathy is glycemic control of diabetes itself, it may be necessary to consider treatment of diabetic peripheral neuropathy with a focus on improving insulin action in more organs.</p><p>The results of this study also indicate that nutrient factors other than glucose and lipids will accelerate the onset and development of diabetic peripheral neuropathy. This explains one of the reasons why the progression of neuropathy cannot be suppressed by glycemic control alone. Conversely, serine supplementation can prevent the onset of neuropathy to some extent, but not completely in this report. These results reconfirm that diabetic peripheral neuropathy is a multifactorial disease. Therefore, it is conceivable that serine could be administered as an adjunctive therapy in addition to glycemic control.</p><p>Unfortunately, the results of this study only relate to the prevention of the onset and progression of experimental diabetic peripheral neuropathy by serine supplementation or myriocin administration, and they do not constitute a treatment. In the future, it will be necessary to evaluate whether correcting serine metabolism can alleviate diabetic peripheral neuropathy that has already developed and progressed or to confirm the efficacy in prospective clinical research.</p>","PeriodicalId":190,"journal":{"name":"Journal of Diabetes Investigation","volume":"14 10","pages":"1157-1159"},"PeriodicalIF":3.2000,"publicationDate":"2023-06-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/jdi.14047","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Diabetes Investigation","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/jdi.14047","RegionNum":3,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 1

Abstract

Subjects with diabetes develop marked disturbances in amino acid metabolism and the concentration in plasma and tissues. Most consistently, the levels of branched-chain amino acids (BCAAs) and aromatic amino acids are increased, and the levels of l-serine and glycine are decreased1. Aberrant nonessential amino acid metabolism is involved in the pathogenesis of diabetes. Elevated levels of plasma BCAAs have been associated with insulin resistance and type 2 diabetes since the 1960s2. A cluster of obesity-associated changes in the specific amino acid, acylcarnitine, and organic acid metabolites in obese compared with lean subjects was also associated with insulin resistance. Although it is also speculated that disturbances in aminoacidemia play a role in the development of diabetic complications, their pathogenesis has not been sufficiently elucidated in detail.

Diabetic peripheral neuropathy (DPN) is the most frequent complication among diabetic patients. Its symptoms are pain, hyperalgesia, hypoalgesia, and paralysis, which can decrease the quality of life of patients. In diabetic peripheral neuropathy, peripheral nerve fibers are affected from the prediabetic stage. Because diabetic peripheral neuropathy is a retrograde-type neuropathy, small nerve fibers located in the epidermis or cornea are first degraded. Small nerve fibers consist of myelinated Aδ fibers and unmyelinated C fibers. Small fiber neuropathy is a disorder of these nerve fibers, manifesting as spontaneous pain or loss of pain sensation with reduction of their density. As diabetic peripheral neuropathy progresses, large myelinated fibers are also decreased with segmental demyelination and microvascular changes, such as thickening of the vascular wall and stenosis of intraneuronal vessels. Without proper treatment, these patients develop paralysis or ulcer formation on the foot. To date, diabetic peripheral neuropathy is thought to be caused by aberrant glucose metabolism in neuronal cells, Schwann cells and endothelial cells in the peripheral nervous system. Abnormal glycemic metabolism elicits nerve dysfunction with activation of the polyol pathway, protein kinase C, advanced glycation end products and its receptor, the receptor for advanced glycation end product (RAGE) pathway, oxidative stress, and inflammation. Clinically, in addition to hyperglycemia, metabolic syndrome, including dyslipidemia, obesity and hypertension, is well known to be a contributor to the pathogenesis of diabetic peripheral neuropathy. In addition to glucose and fatty acid metabolism, recent metabolomics studies have revealed the involvement of another metabolite, glucosamine, in the pathogenesis of diabetic peripheral neuropathy. Lower baseline amino acid levels such as asparagine and glutamine were correlated with cardiovascular autonomic neuropathy in a small sample of subjects with type 1 diabetes3. Thus, today, it is recognized that the pathogenesis of diabetic peripheral neuropathy is not caused only by abnormal glucose metabolism but is a complex condition in which metabolic failure of other nutrients is involved. However, the full picture of the specific metabolic changes in diabetic peripheral neuropathy has not yet been elucidated.

In this context, Handzlik et al.4 recently reported in Nature that the combination of serine deficiency and dyslipidemia can cause experimental diabetic peripheral neuropathy mainly consisting of small fiber neuropathy, in which serine supplementation can delay the onset (Figure 1). The db/db mouse model, which is a conventional obese type 2 diabetic model, showed reductions in hepatic and renal serine levels by approximately 30% relative to wild-type mice, and glycine pools were reduced by 30–50% in the liver, kidney, inguinal white adipose tissue, and plasma. The expression level of components encoding the glycine cleavage system was increased in db/db liver, whereas the expression of genes associated with de novo serine synthesis was significantly reduced. These results indicate that serine synthesis is limited in diabetic mice. Although streptozotocin (STZ)-induced type 1 diabetic model mice showed alterations in plasma glycine and BCAAs (but not serine) at 1 week after streptozotocin treatment, elevated serine disposal was confirmed by co-administration of glucose and serine 2 weeks after injection. Thus, insulin resistance or deficiency can both contribute to the acceleration of serine catabolism or the disposal and reduction of circulating serine in diabetic mice. Of note, weight gain caused by a high-fat diet (HFD) was attenuated by dietary serine and glycine restriction with a reduction in fat mass but not lean mass relative to the treatment with HFD alone, whereas food, calorie, and water intake; calorie absorption; insulin and glucose tolerance; and physical activity were all unaffected. Recent reports suggest that changes in the microbiome composition in the gut can be involved in the pathogenesis of small fiber neuropathy or diabetic peripheral neuropathy5. Investigation of the fecal microbiome revealed that the log ratios of the strains of microorganisms expressing complete serine biosynthesis were increased, while glycine cleavage pathways were decreased with a reduction in the strains expressing a complete fatty acid synthesis pathway by treatment with a serine- and glycine-restricted HFD.

Serine catabolism is associated with sphingolipid metabolism via serine palmitoyl transferase. Sphingolipids are abundantly contained in the myelin sheath in peripheral nerves. Restriction of dietary serine and glycine reduced hepatic palmitate synthesis by approximately 70% relative to serine-replete control diets. Hepatic cholesterol synthesis was increased in the serine-free HFD group compared with the HFD group, with a reduction in the expression of cholesterol biosynthesis enzymes and an increase or no change in the expression of cholesterol biosynthesis enzymes.

Recently, the involvement of insulin resistance in the peripheral nerves has been reported in diabetic peripheral neuropathy, in which proinflammatory macrophage infiltration activated by RAGE signaling elicits deficits in retrograde axonal transportation. Because serine and glycine levels were less associated with changes in protein kinase B phosphorylation than dietary fat and carbohydrate contents, serine restriction could evoke changes in fatty acid metabolism independent of insulin signaling.

Serine deficiency is known to be associated with peripheral neuropathy and various neurodegenerative disorders in previous clinical studies. Similarly, mice fed serine- and glycine-free low-fat chow diets for 12 months exhibited thermal hypoalgesia with intraepidermal nerve fiber reduction in the paw skin. Interestingly, a HFD accelerated the thermal hypoalgesia in mice fed a serine- and glycine-restricted diet for just 3 months. These findings indicate that a combination of low systemic serine and HFD feeding accelerates the onset of small fiber neuropathy in mice. The authors further explored the metabolic changes associated with neuropathy caused by serine restriction. 1-Deoxysphingolipids, including deoxydihydroceramides, are neurotoxic sphingolipids. A 1-deoxysphingolipid is produced when the first enzyme of the sphingolipid biosynthetic pathway, serine palmitoyltransferase, uses l-alanine as a substrate instead of its canonical amino acid substrate, serine. As expected, the contents of deoxydihydro-ceramides in the liver and paw skin increased in serine- and glycine-restricted mice fed HFD, while the canonical ceramide content was reduced. Administration of an inhibitor of serine palmitoyl transferase (myriocin) strongly reduced the levels of sphingolipids as well as of triglycerides and diacylglycerides. Myriocin ameliorated thermal hypoalgesia and the small fiber nerve density in serine- and glycine-restricted HFD mice, while myriocin had no impact on tactile sensing or nerve conduction velocities. Importantly, the administration of myriocin at 6 weeks of age prevented the manifestation of thermal hypoalgesia, tactile sensation, and small fiber density in the epidermis in db/db mice without affecting body weight gain, hyperglycemia, or plasma serine levels. Myriosin treatment strongly reduced canonical sphingolipids in the liver but showed limited effects on paw skin 1-deoxysphingolipids and ceramides. Finally, based on the results obtained thus far, the authors investigated whether a serine-supplemented diet prevents the development of neuropathy. A 3% serine-enriched diet starting at 6 weeks of age elevated levels of plasma and hepatic serine, but not glycine levels. The body weight was comparable, while a slight increase in circulating glucose levels was observed. Neuropathic manifestations, including both thermal and tactile hypoalgesia, were reduced in diabetic mice fed this serine-enriched diet. Canonical sphingolipid levels were similar across the tissues, while 1-deoxysphingolipids were robustly decreased in both liver and paw skin. Collectively, these data suggest that supplementation with serine can prevent the onset and progression of diabetic peripheral neuropathy.

The novel point of this research is that the onset of diabetic peripheral neuropathy could be prevented by correcting the intake of nutrients without affecting blood glucose levels. Currently, no radical therapy for diabetic peripheral neuropathy has been established. Although aldose reductase inhibitors and α-lipoic acid have been clinically applied, their effects are limited. This study suggests that the decrease in serine synthesis and the increase in serine disposal are due to insufficient action of insulin. Although the most important treatment for neuropathy is glycemic control of diabetes itself, it may be necessary to consider treatment of diabetic peripheral neuropathy with a focus on improving insulin action in more organs.

The results of this study also indicate that nutrient factors other than glucose and lipids will accelerate the onset and development of diabetic peripheral neuropathy. This explains one of the reasons why the progression of neuropathy cannot be suppressed by glycemic control alone. Conversely, serine supplementation can prevent the onset of neuropathy to some extent, but not completely in this report. These results reconfirm that diabetic peripheral neuropathy is a multifactorial disease. Therefore, it is conceivable that serine could be administered as an adjunctive therapy in addition to glycemic control.

Unfortunately, the results of this study only relate to the prevention of the onset and progression of experimental diabetic peripheral neuropathy by serine supplementation or myriocin administration, and they do not constitute a treatment. In the future, it will be necessary to evaluate whether correcting serine metabolism can alleviate diabetic peripheral neuropathy that has already developed and progressed or to confirm the efficacy in prospective clinical research.

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补充丝氨酸:这是治疗糖尿病多发性神经病的新选择吗?
糖尿病患者的氨基酸代谢以及血浆和组织中的浓度出现明显紊乱。最一致的是,支链氨基酸(BCAAs)和芳香族氨基酸的水平增加,l-丝氨酸和甘氨酸的水平降低1。异常的非必需氨基酸代谢参与了糖尿病的发病机制。自20世纪60年代以来,血浆BCAAs水平升高一直与胰岛素抵抗和2型糖尿病有关2。与瘦受试者相比,肥胖受试者的特定氨基酸、酰基肉碱和有机酸代谢产物的一系列肥胖相关变化也与胰岛素抵抗有关。尽管也有人推测氨基酸血症的紊乱在糖尿病并发症的发展中起作用,但其发病机制尚未得到充分的详细阐明。糖尿病周围神经病变(DPN)是糖尿病患者中最常见的并发症。其症状是疼痛、痛觉过敏、痛觉减退和瘫痪,这会降低患者的生活质量。在糖尿病周围神经病变中,周围神经纤维从糖尿病前期就受到影响。由于糖尿病周围神经病变是一种退行性神经病变,位于表皮或角膜的小神经纤维首先退化。小神经纤维由有髓鞘的Aδ纤维和无髓鞘的C纤维组成。小纤维神经病是这些神经纤维的一种紊乱,表现为自发性疼痛或疼痛感丧失,其密度降低。随着糖尿病周围神经病变的进展,大的有髓鞘纤维也会减少,伴有节段性脱髓鞘和微血管变化,如血管壁增厚和神经内血管狭窄。如果没有适当的治疗,这些患者会出现足部瘫痪或溃疡形成。迄今为止,糖尿病周围神经病变被认为是由周围神经系统中神经元细胞、雪旺细胞和内皮细胞的异常葡萄糖代谢引起的。异常的血糖代谢通过激活多元醇途径、蛋白激酶C、晚期糖基化终产物及其受体、晚期糖基化终产物受体(RAGE)途径、氧化应激和炎症而引发神经功能障碍。临床上,除了高血糖外,代谢综合征,包括血脂异常、肥胖和高血压,也是糖尿病周围神经病变发病机制的一个因素。除了葡萄糖和脂肪酸代谢外,最近的代谢组学研究还揭示了另一种代谢产物葡糖胺参与糖尿病周围神经病变的发病机制。在一小部分1型糖尿病受试者中,较低的基线氨基酸水平(如天冬酰胺和谷氨酰胺)与心血管自主神经病变相关3。因此,今天人们已经认识到,糖尿病周围神经病变的发病机制不仅是由葡萄糖代谢异常引起的,而且是一种涉及其他营养物质代谢衰竭的复杂情况。然而,糖尿病周围神经病变的具体代谢变化的全貌尚未阐明。在这种情况下,Handzlik等人4最近在《自然》杂志上报道,丝氨酸缺乏和血脂异常的结合会导致实验性糖尿病周围神经病变,主要由小纤维神经病变组成,其中补充丝氨酸可以延缓发病(图1)。db/db小鼠模型是一种传统的肥胖2型糖尿病模型,与野生型小鼠相比,肝脏和肾脏丝氨酸水平降低了约30%,肝脏、肾脏、腹股沟白色脂肪组织和血浆中的甘氨酸库减少了30-50%。db/db肝脏中编码甘氨酸切割系统的成分的表达水平增加,而与从头丝氨酸合成相关的基因的表达显著降低。这些结果表明丝氨酸合成在糖尿病小鼠中是有限的。尽管链脲佐菌素(STZ)诱导的1型糖尿病模型小鼠在1 链脲佐菌素治疗一周后,通过葡萄糖和丝氨酸2的联合给药证实丝氨酸处理升高 注射后数周。因此,胰岛素抵抗或缺乏都有助于糖尿病小鼠中丝氨酸分解代谢的加速或循环丝氨酸的处置和减少。值得注意的是,高脂肪饮食(HFD)引起的体重增加通过饮食丝氨酸和甘氨酸限制而减弱,与单独使用HFD治疗相比,脂肪量减少,但瘦体重没有减少,而食物、卡路里和水的摄入;热量吸收;胰岛素和葡萄糖耐量;身体活动均未受影响。 最近的报告表明,肠道微生物组组成的变化可能参与小纤维神经病或糖尿病周围神经病变的发病机制5。对粪便微生物组的调查显示,表达完全丝氨酸生物合成的微生物菌株的对数比率增加,而甘氨酸切割途径随着用丝氨酸和甘氨酸限制性HFD处理表达完整脂肪酸合成途径的菌株的减少而减少。丝氨酸分解代谢通过丝氨酸棕榈酰转移酶与鞘脂代谢有关。鞘氨醇脂质大量存在于外周神经的髓鞘中。相对于富含丝氨酸的对照饮食,限制饮食中的丝氨酸和甘氨酸使肝脏棕榈酸的合成减少了约70%。与HFD组相比,不含丝氨酸的HFD组的肝胆固醇合成增加,胆固醇生物合成酶的表达减少,胆固醇生物合成酶类的表达增加或没有变化。最近,据报道,糖尿病周围神经病变涉及外周神经中的胰岛素抵抗,其中RAGE信号激活的促炎巨噬细胞浸润导致逆行轴突运输缺陷。由于丝氨酸和甘氨酸水平与蛋白激酶B磷酸化的变化的相关性小于膳食脂肪和碳水化合物含量,因此丝氨酸限制可以引起脂肪酸代谢的变化,而不依赖于胰岛素信号。在以前的临床研究中,丝氨酸缺乏与周围神经病变和各种神经退行性疾病有关。同样,喂食不含丝氨酸和甘氨酸的低脂肪食物的小鼠12 数月表现为热性痛觉减退,爪皮肤表皮内神经纤维减少。有趣的是,在喂食丝氨酸和甘氨酸限制性饮食仅3天的小鼠中,HFD加速了热痛觉减退 月。这些发现表明,低系统丝氨酸和HFD喂养的组合加速了小鼠小纤维神经病的发作。作者进一步探讨了与丝氨酸限制性神经病相关的代谢变化。1-脱氧鞘脂,包括脱氧二氢神经酰胺,是一种神经毒性鞘脂。当鞘脂生物合成途径的第一种酶丝氨酸棕榈酰转移酶使用l-丙氨酸作为底物而不是其经典氨基酸底物丝氨酸时,就会产生1-脱氧鞘脂。正如预期的那样,在喂食HFD的丝氨酸和甘氨酸限制性小鼠中,肝脏和爪皮肤中脱氧二氢神经酰胺的含量增加,而经典神经酰胺含量降低。丝氨酸棕榈酰转移酶抑制剂(肉豆蔻素)的施用大大降低了鞘脂以及甘油三酯和二酰甘油酯的水平。肉豆蔻素改善了丝氨酸和甘氨酸限制性HFD小鼠的热痛觉减退和小纤维神经密度,而肉豆蔻素对触觉或神经传导速度没有影响。重要的是,在6 周龄可防止db/db小鼠出现热痛觉减退、触觉和表皮小纤维密度,而不会影响体重增加、高血糖或血浆丝氨酸水平。肉豆蔻苷治疗强烈降低了肝脏中的典型鞘脂,但对爪皮1-脱氧鞘脂和神经酰胺的影响有限。最后,根据迄今为止获得的结果,作者研究了补充丝氨酸的饮食是否可以预防神经病变的发展。从6岁开始的富含3%丝氨酸的饮食 周龄时血浆和肝脏丝氨酸水平升高,但甘氨酸水平没有升高。体重相当,同时观察到循环葡萄糖水平略有增加。喂食这种富含丝氨酸的饮食的糖尿病小鼠的神经病变表现,包括热和触觉痛觉减退,都有所减少。各组织中的典型鞘脂水平相似,而肝脏和爪皮肤中的1-脱氧鞘脂显著降低。总之,这些数据表明,补充丝氨酸可以预防糖尿病周围神经病变的发作和进展。这项研究的新观点是,可以通过在不影响血糖水平的情况下纠正营养素的摄入来预防糖尿病周围神经病变的发作。目前,尚未建立糖尿病周围神经病变的根治性治疗方法。尽管醛糖还原酶抑制剂和α-硫辛酸已在临床上得到应用,但其效果有限。这项研究表明,丝氨酸合成的减少和丝氨酸处理的增加是由于胰岛素的作用不足。 尽管神经病变最重要的治疗方法是糖尿病本身的血糖控制,但可能有必要考虑糖尿病周围神经病变的治疗,重点是改善胰岛素在更多器官中的作用。这项研究的结果还表明,除葡萄糖和脂质外的营养因子会加速糖尿病周围神经病变的发生和发展。这解释了为什么神经病变的进展不能单独通过血糖控制来抑制的原因之一。相反,补充丝氨酸可以在一定程度上预防神经病变的发作,但在本报告中并非完全如此。这些结果再次证实了糖尿病周围神经病变是一种多因素疾病。因此,除了血糖控制外,丝氨酸还可以作为辅助治疗。不幸的是,这项研究的结果仅涉及通过补充丝氨酸或给予肉豆蔻素来预防实验性糖尿病周围神经病变的发作和进展,它们不构成治疗。未来,有必要评估纠正丝氨酸代谢是否可以缓解已经发展和进展的糖尿病周围神经病变,或者在前瞻性临床研究中确认其疗效。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Diabetes Investigation
Journal of Diabetes Investigation Medicine-Internal Medicine
自引率
9.40%
发文量
218
期刊介绍: Journal of Diabetes Investigation is your core diabetes journal from Asia; the official journal of the Asian Association for the Study of Diabetes (AASD). The journal publishes original research, country reports, commentaries, reviews, mini-reviews, case reports, letters, as well as editorials and news. Embracing clinical and experimental research in diabetes and related areas, the Journal of Diabetes Investigation includes aspects of prevention, treatment, as well as molecular aspects and pathophysiology. Translational research focused on the exchange of ideas between clinicians and researchers is also welcome. Journal of Diabetes Investigation is indexed by Science Citation Index Expanded (SCIE).
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