APMIS. 2019 Oct; 127(10): 655–659.
Published online 2019 Sep 2. doi:10.1111/apm.12987
PMCID: PMC6851881
PMID: 31344283
Laurits J. Holm
1 and Karsten Buschard1
Author information Article notes Copyright and License information PMC Disclaimer
Abstract
L‐serine is classified as a non‐essential amino acid; however, L‐serine is indispensable having a central role in a broad range of cellular processes. Growing evidence suggests a role for L‐serine in the development of diabetes mellitus and its related complications, with L‐serine being positively correlated to insulin secretion and sensitivity. L‐serine metabolism is altered in type 1, type 2, and gestational diabetes, and L‐serine supplementations improve glucose homeostasis and mitochondrial function, and reduce neuronal death. Additionally, L‐serine lowers the incidence of autoimmune diabetes in NOD mice. Dietary supplementations of L‐serine are generally regarded as safe (GRAS) by the FDA. Therefore, we believe that L‐serine should be considered as an emerging therapeutic option in diabetes, although work remains in order to fully understand the role of L‐serine in diabetes.
Keywords: Deoxysphingolipids, diabetes‐related complications, L‐serine, type 1 diabetes, type 2 diabetes
Diabetes mellitus is a group of metabolic disorders characterized by hyperglycaemia. This is caused by a lack of insulin in type 1 diabetes or a combination of insulin resistance and reduced insulin production in type 2 diabetes and gestational diabetes 1. The number of diabetes patients has according to The World Health Organization (WHO) almost quadrupled since 1980 to an estimated 422 million in 2014 2. The rise in type 2 and gestational diabetes can to a large degree be explained by increasing obesity rates while it remains elusive why type 1 diabetes incidence is rising 3. All forms of diabetes have tremendous effects on whole‐body metabolism, and tight control of blood glucose is needed to reduce the risk of diabetes‐related complications, for example, peripheral neuropathy including retinopathy, nephropathy, and heart attacks. However, even with tight control of blood glucose, most patients will develop complications, with diabetic neuropathy, 90% of all diabetes patients, being the most common 4. Thus, there is a high need for therapeutic approaches to reduce the incidence of diabetes and its related complications.
Amino acids have received attention in relation to diabetes with especially branched‐chain and aromatic amino acids being reported to affect type 2 diabetes risk 5. In this review, we will focus on the otherwise neglected amino acid L‐serine. L‐serine is a polar amino acid which was first discovered in 1865 by Cramer as a component of raw silk 6. Since then, L‐serine has been described as a vital amino acid in all living organism. L‐serine was originally classified as a non‐essential amino acid; however, it was quickly discovered that vertebrates under certain circ*mstances cannot synthesize enough to meet cellular demands 7, 8. A more appropriate term might, therefore, be ‘conditional non‐essential amino acid’. Dietary intake of L‐serine is consequently necessary even in healthy individuals. Our dietary intake of L‐serine is distributed among many types of food with the highest contributions coming from L‐serine rich foods such as eggs, soy, cheese, and nuts.
L‐serine can be derived from four sources: (i) dietary intake, (ii) biosynthesis from glycolytic intermediate 3‐phosphoglycerate, (iii) glycine, and (iv) turnover of protein and proteins and phospholipids (Fig.1) 9. The relative contribution of these sources is unknown and varies depending on tissue type and developmental stage 7. The liver, for instance, gets most of its L‐serine from glycine while the kidneys synthesize it from 3‐phosphoglycerate 10, 11.
Figure 1
L‐serine metabolism and activities. The pathways for the creation of L‐serine are shown with de novo synthesis by phosphoglycerate dehydrogenase (PGDH), phosphoserine aminotransferase (PSAT), and phosphoserine phosphatase (PSP). Other sources of L‐serine are through diet or from glycine or by the turnover of proteins and phospholipids. L‐serine has various biological effects, mentioned here are the ones with relation to diabetes. NOD, non‐obese diabetic.
Biosynthesis of L‐serine is catalysed by the enzymes phosphoglycerate dehydrogenase (PGDH), phosphoserine aminotransferase (PSAT), and phosphoserine phosphatase (PSP). Flux is mainly regulated by PSP, which is regarded as the rate‐limiting step in serine biosynthesis 12. Regulation of synthesis is controlled by cellular demands with upregulation of the enzymes in rapidly proliferating tissue and in cell cultures of L‐serine starved cells 13, 14. A protein‐restricted diet has in rats been shown to double L‐serine concentration in blood, due to increased de novo synthesis 15. Two enzymes in L‐serine biosynthesis have been linked to insulin sensitivity. PSAT expression and liver L‐serine levels are reduced in leptin receptor‐deficient (db/db) mice and high‐fat diet (HFD)‐induced diabetic mice 16. Insulin signalling and sensitivity were subsequently shown to be improved following overexpression of PSAT. Inhibition of PSP was similarly shown to cause inappropriate serine dephosphorylation of substrates resulting in insulin resistance in rat adipocytes 17.
Defects in L‐serine biosynthesis or transport have profound developmental consequences. Neu–Laxova syndrome is a rare disease caused by a mutation in the PGDH gene, if hom*ozygous it causes prenatal or early postnatal death limp malformation and neural tube defects 18. Other defects in L‐serine biosynthesis can cause other developmental and intellectual disabilities 8, 9. Treatment with L‐serine in these diseases improves some symptoms however not completely, suggesting that L‐serine deficiency can give lasting neurological damage 8, 19.
L‐serine is known to participate in various metabolic pathways besides being a constituent of proteins. For instance, D‐serine, an enantiomer of l‐serine, made by serine racemase is a ligand for the N‐methyl‐D‐aspartate (NMDA) receptor and mediates neuronal excitation 20. It should be noted that supplementation of D‐serine reduces insulin secretion in mice and that serine racemase is linked to the development of diabetic retinopathy 21, 22. L‐serine itself is a neuronal trophic factor promoting growth, differentiation, and elongation of cultured neurons 9. These beneficial effects might be connected to L‐serine being required for the synthesis of phosphatidylserine and sphingolipids, of which especially sphingolipids are suggested to play a major role in diabetes development 23, 24, 25. Additionally, then L‐serine is involved in the formation of NADPH, nucleotides, and as a carbon source for methylations 9, 15, 26. L‐serine participates in a metabolic network connected to cell proliferation with some cancer cells having increased PGDH expression, while L‐serine dietary restrictions have therapeutic effects on tumour growth 15, 26.
A recent study looking at amino acid concentration in 5181 non‐diabetic men aged between 45 and 73years from the Finnish town Kuopio in relation with the development of type 2 diabetes found that a high L‐serine concentration is correlated to improved insulin secretion and sensitivity 27. L‐Serine is also associated with an improved glucose tolerance after a 2‐h oral glucose tolerance test, although no correlation was found to the development of type 2 diabetes. Another link between L‐serine and blood glucose homeostasis comes from the non‐obese diabetic (NOD) mice, a type 1 diabetes mouse model, in which we found that L‐serine supplementation reduces insulitis and diabetes incidence (43%) compared to controls (71%) 28. This was associated with an improved glucose tolerance, reduced HOMA‐IR, and a small reduction in average glycemic level. Thus, suggesting that L‐serine supplementation could be used to both treat and prevent diabetes. We have identified two L‐serine transporters (SLC1A4 and SLC7A10) with reduced mRNA levels in islet from individuals with newly diagnosed type 1 diabetes, while polymorphisms in the promoter of L‐serine transporter SLC1A5 (odds ratio 1.16) are genetically linked to the risk of developing of type 1 diabetes 25.
L‐serine concentration has in several studies been found to be significantly altered in diabetes. A study of children with type 1 diabetes and non‐diabetic controls found that the concentration of L‐serine in plasma was decreased by 42% in patients 29. Similar studies of patients with type 2 diabetes have found reduced L‐serine concentration in blood 30, 31. The postprandial L‐serine concentration in response to a standardized meal differs between type 2 diabetes patients and non‐diabetic controls, with patients having a reduced concentration of L‐serine in blood, while controls have an increased concentration 32. Finally, then two studies have reported conflicting results showing a decreased or increased concentration of L‐serine in the blood of individuals with gestational diabetes 33, 34. Reduced L‐serine levels are likely not the result of reduced insulin production as treatment with streptozotocin (a beta‐cell toxin) leads to an increased L‐serine level 22weeks later in diabetic mice 35.
There is a lack of studies on how a disturbed L‐serine metabolism could affect the development of diabetes and related complications, and so we currently rely on studies of other diseases. An intriguing possibility is that an altered L‐serine metabolism could lead to the production of a novel type of sphingolipids, termed deoxysphingolipids 36. Deoxysphingolipids are known to induce apoptosis in a beta‐cell line and primary islets and to impair neuronal function 36. Deoxysphingolipids are formed during the first step of sphingolipid synthesis when the enzyme serine palmitoyltransferase (SPT) instead of L‐serine uses alanine or glycine as alternative amino acid substrates. Patients with primary L‐serine deficiency have increased amounts of deoxysphingolipids, and L‐serine supplementation is known to reduce the concentration of deoxysphingolipids 37, 38. Deoxysphingolipids are enriched in plasma from type 2 diabetes patients while there is no difference between controls and type 1 diabetes patients 39. It is in this regard interesting that the studies describing a reduced L‐serine concentration in type 2 diabetes patients did not report reductions in blood alanine (one study found increased alanine concentration 31) meaning that the alanine/L‐serine ratio in type 2 diabetes patients would favour the formation of deoxysphingolipids 30, 31. Mutations in SPT cause hereditary sensory neuropathy type 1 (HSAN1), in which patients have axonal neuropathy with many similarities to diabetic neuropathy 40. Reducing deoxysphingolipids concentration by increasing L‐serine concentration improved neuronal function in a mouse model of HSAN1 and relieved neuropathy in diabetic rats 40.
Another link to a possible role of L‐serine in preserving neurons comes from studies of Alzheimer's disease and amyotrophic lateral sclerosis (ALS), in which clinical trials with L‐serine are ongoing. 8 A phase 1 human trial for ALS showed that patients receiving the highest dose of 30g/day had a reduced rate of functional loss compared to control patients 41.
L‐serine is believed to protect neurons by upregulating the ER chaperone PDI (protein disulphide isomerase), which is involved in refolding misfolded proteins 42. Also, L‐serine seems to induce activation of the unfolded protein response (UPR) as a mechanism to adapt to ER stress by removal of accumulating and aggregating proteins 43. ER stress and the accumulation of misfolded proteins have otherwise been suggested to be involved in the development of type 1 diabetes 44. Another mechanism by which a lack of L‐serine could affect diabetes development is by affecting mitochondrial function, which is known to influence both insulin secretion and sensitivity 45. It was in cancer cells found that a lack of L‐serine leads to increased mitochondrial fragmentation and an altered mitochondrial metabolism with compromised fatty acid oxidation and reduced glucose and glutamine catabolism 26. This was likely the results of L‐serine deprivation causing an altered sphingolipid metabolism.
The US FDA has for human consumption classified L‐serine as generally regarded as safe (GRAS) for use as a food additive, under 8.4% of the total dietary protein (CFR Title 21 Section 17.230.18). As such, we propose that therapeutic options that restore L‐serine concentrations in individuals with diabetes should be considered as a safe way to prevent and treat diabetes and diabetes‐related outcomes.
The work was supported by Kirsten and Freddy Johannsen's fond.
Conflict of Interest
The authors declare that there is no duality of interest associated with this manuscript.
Authors Contributions
LJH wrote the manuscript with input from KB. LJH and KB revised the final version. Both authors have read and approved the final manuscript.
Notes
Holm LJ, Buschard K. L‐serine: a neglected amino acid with a potential therapeutic role in diabetes. APMIS2019;127:655–659. [PMC free article] [PubMed] [Google Scholar]
References
1. van Belle TL, Coppieters KT, von Herrath MG. Type 1 diabetes: etiology, immunology, and therapeutic strategies. Physiol Rev2011;91:79–118. [PubMed] [Google Scholar]
2. World Health Organization. Global report on diabetes. Geneva: World Health Organization, 2016. [Google Scholar]
3. Atkinson MA, Eisenbarth GS, Michels AW. Type 1 diabetes. Lancet2014;383:69–82. [PMC free article] [PubMed] [Google Scholar]
4. Vinik AI, Nevoret ML, Casellini C, Parson H. Diabetic neuropathy. Endocrinol Metab Clin North Am2013;42:747–87. [PubMed] [Google Scholar]
5. Würtz P, Soininen P, Kangas AJ, Rönnemaa T, Lehtimäki T, Kähönen M, etal. Branched‐chain and aromatic amino acids are predictors of insulin resistance in young adults. Diabetes Care2013;36:648–55. [PMC free article] [PubMed] [Google Scholar]
6. Cramer E. Ueber die bestandtheile der seide. J Prakt Chem1865;96:76–98. [Google Scholar]
7. de Koning TJ, Snell K, Duran M, Berger R, Poll‐The BT, Surtees R. L‐serine in disease and development. Biochem J2003;371:653–61. [PMC free article] [PubMed] [Google Scholar]
8. Metcalf JS, Dunlop RA, Powell JT, Banack SA, Cox PA. L‐serine: a naturally‐occurring amino acid with therapeutic potential. Neurotox Res2018;33:213–21. [PubMed] [Google Scholar]
9. El‐Hattab AW. Serine biosynthesis and transport defects. Mol Genet Metab2016;118:153–9. [PubMed] [Google Scholar]
10. Lowry M, Hall DE, Hall MS, Brosnan JT. Renal metabolism of amino acids in vivo: studies on serine and glycine fluxes. Am J Physiol1987;252:F304–9. [PubMed] [Google Scholar]
11. Narkewicz MR, Thureen PJ, Sauls SD, Tjoa S, Nikolayevsky N, Fennessey PV. Serine and glycine metabolism in hepatocytes from mid gestation fetal lambs. Pediatr Res1996;39:1085–90. [PubMed] [Google Scholar]
12. Fell DA, Snell K. Control analysis of mammalian serine biosynthesis. Feedback inhibition on the final step. Biochem J1988;256:97–101. [PMC free article] [PubMed] [Google Scholar]
13. Lockart RZ, Eagle H. Requirements for growth of single human cells:” nonessential” amino acids, notably serine, are necessary and sufficient nutritional supplements. Science1959;129:252–4. [PubMed] [Google Scholar]
14. Snell K, Natsumeda Y, Eble JN, Glover JL, Weber G. Enzymic imbalance in serine metabolism in human colon carcinoma and rat sarcoma. Br J Cancer1988;57:87–90. [PMC free article] [PubMed] [Google Scholar]
15. Kalhan SC, Hanson RW. Resurgence of serine: an often neglected but indispensable amino Acid. J Biol Chem2012;287:19786–91. [PMC free article] [PubMed] [Google Scholar]
16. Yu J, Xiao F, Guo Y, Deng J, Liu B, Zhang Q, etal. Hepatic phosphoserine aminotransferase 1 regulates insulin sensitivity in mice via tribbles hom*olog 3. Diabetes2015;64:1591–602. [PubMed] [Google Scholar]
17. Begum N, Sussman KE, Draznin B. Calcium‐induced inhibition of phosphoserine phosphatase in insulin target cells is mediated by the phosphorylation and activation of inhibitor 1. J Biol Chem1992;267:5959–63. [PubMed] [Google Scholar]
18. Acuna‐Hidalgo R, Schanze D, Kariminejad A, Nordgren A, Kariminejad MH, Conner P, etal. Neu‐Laxova syndrome is a heterogeneous metabolic disorder caused by defects in enzymes of the L‐serine biosynthesis pathway. Am J Hum Genet2014;95:285–93. [PMC free article] [PubMed] [Google Scholar]
19. de Koning TJ, Klomp LW, van Oppen AC, Beemer FA, Dorland L, van den Berg I, etal. Prenatal and early postnatal treatment in 3‐phosphoglycerate‐dehydrogenase deficiency. Lancet2004;364:2221–2. [PubMed] [Google Scholar]
20. Genchi G. An overview on D‐amino acids. Amino Acids2017;49:1521–33. [PubMed] [Google Scholar]
21. Suwandhi L, Hausmann S, Braun A, Gruber T, Heinzmann SS, Galvez EJC, etal. Chronic d‐serine supplementation impairs insulin secretion. Mol Metab2018;16:191–202. [PMC free article] [PubMed] [Google Scholar]
22. Ozaki H, Inoue R, Matsushima T, Sasahara M, Hayashi A, Mori H. Serine racemase deletion attenuates neurodegeneration and microvascular damage in diabetic retinopathy. PLoS ONE2018;13:e0190864. [PMC free article] [PubMed] [Google Scholar]
23. Boslem E, Meikle PJ, Biden TJ. Roles of ceramide and sphingolipids in pancreatic beta‐cell function and dysfunction. Islets2012;4:177–87. [PMC free article] [PubMed] [Google Scholar]
24. Veret J, Bellini L, Giussani P, Ng C, Magnan C, Le Stunff H. Roles of sphingolipid metabolism in pancreatic beta cell dysfunction induced by lipotoxicity. J Clin Med2014;3:646–62. [PMC free article] [PubMed] [Google Scholar]
25. Holm LJ, Krogvold L, Hasselby JP, Kaur S, Claessens LA, Russell MA, etal. Abnormal islet sphingolipid metabolism in type 1 diabetes. Diabetologia2018;61:1650–61. [PMC free article] [PubMed] [Google Scholar]
26. Gao X, Lee K, Reid MA, Sanderson SM, Qiu C, Li S, etal. Serine availability influences mitochondrial dynamics and function through lipid metabolism. Cell Rep2018;22:3507–20. [PMC free article] [PubMed] [Google Scholar]
27. Vangipurapu J, Stancakova A, Smith U, Kuusisto J, Nine Laakso M. Amino acids are associated with decreased insulin secretion and elevated glucose levels in a 7.4‐year follow‐up study of 5,181 Finnish men. Diabetes2019;68:1353–8. [PubMed] [Google Scholar]
28. Holm LJ, Haupt‐Jorgensen M, Larsen J, Giacobini JD, Bilgin M, Buschard K. L‐serine supplementation lowers diabetes incidence and improves blood glucose homeostasis in NOD mice. PLoS ONE2018;13:e0194414. [PMC free article] [PubMed] [Google Scholar]
29. Bervoets L, Massa G, Guedens W, Louis E, Noben J‐P, Adriaensens P. Metabolic profiling of type 1 diabetes mellitus in children and adolescents: a case–control study. Diabetol Metab Syndr2017;9:48. [PMC free article] [PubMed] [Google Scholar]
30. Bertea M, Rutti MF, Othman A, Marti‐Jaun J, Hersberger M, von Eckardstein A, etal. Deoxysphingoid bases as plasma markers in diabetes mellitus. Lipids Health Dis2010;9:84. [PMC free article] [PubMed] [Google Scholar]
31. Drábková P, Šanderová J, Kovařík J. An assay of selected serum amino acids in patients with type 2 diabetes mellitus. Adv Clin Exp Med2015;24:447–51. [PubMed] [Google Scholar]
32. Mook‐Kanamori DO, de Mutsert R, Rensen PC, Prehn C, Adamski J, den Heijer M, etal. Type 2 diabetes is associated with postprandial amino acid measures. Arch Biochem Biophys2016;589:138–44. [PubMed] [Google Scholar]
33. Enquobahrie DA, Denis M, Tadesse MG, Gelaye B, Ressom HW, Williams MA. Maternal early pregnancy serum metabolites and risk of gestational diabetes mellitus. J Clin Endocrinol Metab2015;100:4348–56. [PMC free article] [PubMed] [Google Scholar]
34. Bentley‐Lewis R, Huynh J, Xiong G, Lee H, Wenger J, Clish C, etal. Metabolomic profiling in the prediction of gestational diabetes mellitus. Diabetologia2015;58:1329–32. [PMC free article] [PubMed] [Google Scholar]
35. Rojas DR, Kuner R, Agarwal N. Metabolomic signature of type 1 diabetes‐induced sensory loss and nerve damage in diabetic neuropathy. J Mol Med2019;97:845–54. [PubMed] [Google Scholar]
36. Zuellig RA, Hornemann T, Othman A, Hehl AB, Bode H, Guntert T, etal. Deoxysphingolipids, novel biomarkers for type 2 diabetes, are cytotoxic for insulin‐producing cells. Diabetes2014;63:1326–39. [PubMed] [Google Scholar]
37. Garofalo K, Penno A, Schmidt BP, Lee HJ, Frosch MP, von Eckardstein A, etal. Oral L‐serine supplementation reduces production of neurotoxic deoxysphingolipids in mice and humans with hereditary sensory autonomic neuropathy type 1. J Clin Investig2011;121:4735–45. [PMC free article] [PubMed] [Google Scholar]
38. Ferreira CR, Goorden SMI, Soldatos A, Byers HM, Ghauharali‐van der Vlugt JMM, Beers‐Stet FS, etal. Deoxysphingolipid precursors indicate abnormal sphingolipid metabolism in individuals with primary and secondary disturbances of serine availability. Mol Genet Metab2018;124:204–9. [PMC free article] [PubMed] [Google Scholar]
39. Wei N, Pan J, Pop‐Busui R, Othman A, Alecu I, Hornemann T, etal. Altered sphingoid base profiles in type 1 compared to type 2 diabetes. Lipids Health Dis2014;13:161. [PMC free article] [PubMed] [Google Scholar]
40. Othman A, Bianchi R, Alecu I, Wei Y, Porretta‐Serapiglia C, Lombardi R, etal. Lowering plasma 1‐deoxysphingolipids improves neuropathy in diabetic rats. Diabetes2015;64:1035–45. [PubMed] [Google Scholar]
41. Levine TD, Miller RG, Bradley WG, Moore DH, Saperstein DS, Flynn LE, etal. Phase I clinical trial of safety of L‐serine for ALS patients. Amyotroph Lateral Scler Frontotemporal Degener2017;18:107–11. [PubMed] [Google Scholar]
42. Dunlop RA, Powell JT, Metcalf JS, Guillemin GJ, Cox PA. L‐serine‐mediated neuroprotection includes the upregulation of the ER stress chaperone protein disulfide isomerase (PDI). Neurotox Res2018;33:113–22. [PubMed] [Google Scholar]
43. Dunlop RA, Powell J, Guillemin GJ, Cox PA. Mechanisms of L‐serine neuroprotection in vitro include ER proteostasis regulation. Neurotox Res2018;33:123–32. [PubMed] [Google Scholar]
44. Brozzi F, Eizirik DL. ER stress and the decline and fall of pancreatic beta cells in type 1 diabetes. Upsala J Med Sci2016;121:133–9. [PMC free article] [PubMed] [Google Scholar]
45. Lowell BB, Shulman GI. Mitochondrial dysfunction and type 2 diabetes. Science2005;307:384–7. [PubMed] [Google Scholar]
