Literature DB >> 26159928

Low alpha-synuclein levels in the blood are associated with insulin resistance.

Gerardo Rodriguez-Araujo1, Hironori Nakagami2, Yoichi Takami3, Tomohiro Katsuya4, Hiroshi Akasaka5, Shigeyuki Saitoh5, Kazuaki Shimamoto5, Ryuichi Morishita4, Hiromi Rakugi3, Yasufumi Kaneda1.   

Abstract

Mutations in the protein alpha-synuclein (SNCA) have been linked to Parkinson's disease. We recently reported that non-mutated SNCA enhanced glucose uptake through the Gab1-PI3 kinase-Akt pathway and elucidated its effects on glucose regulation. Here, we examined the association of SNCA with insulin resistance (IR), a condition that is characterized by decreased tissue glucose uptake. Our observations include those from a population study as well as a SNCA-deficient mouse model, which had not previously been characterized in an IR scenario. In 1,152 patients, we found that serum SNCA levels were inversely correlated with IR indicators--body mass index, homeostatic model assessment for IR (HOMA-IR) and immunoreactive insulin (IRI)--and, to a lesser extent, with blood pressure and age. Additionally, SNCA-deficient mice displayed alterations in glucose and insulin responses during diet-induced IR. Moreover, during euglycemic clamp assessments, SNCA knock-out mice fed a high-fat diet (HFD) showed severe IR in adipose tissues and skeletal muscle. These findings provide new insights into IR and diabetes and point to SNCA as a potential candidate for further research.

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Year:  2015        PMID: 26159928      PMCID: PMC4498217          DOI: 10.1038/srep12081

Source DB:  PubMed          Journal:  Sci Rep        ISSN: 2045-2322            Impact factor:   4.379


Metabolic syndrome is one of the most common findings in the clinic and affects millions of patients worldwide, resulting in a substantial burden on healthcare systems around the globe123. This syndrome is characterized by the presence of several risk factors and conditions that can precipitate the appearance of metabolic disorders, including hypertension, type 2 diabetes mellitus, obesity and dyslipidemias4. One of these conditions is insulin resistance (IR), which may lead to type 2 diabetes mellitus3. The detailed mechanism of IR has yet to be elucidated. Among the hypothesized contributing factors are cytotoxic effects of palmitate in peripheral tissues5, Toll-like receptor-4-dependent NF-kB activation6, glycation damage7, and mitochondria dysfunction8. The first hypothesized contributing factor (palmitate), however, has drawn the most attention from researchers, giving rise to novel therapies such as G protein-coupled receptor (GPCR)-targeted therapies (i.e., GPR-40 agonists)9. Alpha-synuclein (SNCA) is a protein richly expressed in neurons and hematopoietic tissues, and is present in serum101112131415. Intriguingly, SNCA seems to function in some of the above-mentioned mechanisms underlying IR. SNCA interacts with lipids such as palmitate as a free acid-binding protein (FABP)-like transporter16, prevents glyoxalase I expression and glycation damage in neuron cells17, and has numerous extracerebral functions. SNCA was recently linked to glucose regulation as well as negative insulin secretion through K-channel modulation in beta cells of the pancreas18. The latter indicates that SNCA may have a role in decreasing hyperinsulinemia, which is observed in conditions such as IR. We also previously reported the function of SNCA in glucose metabolism in vitro and in vivo through a G-protein-coupled-receptor heterodimer lipo-phosphatidic acid receptor (LPAR2)- CD9019; however, how SNCA affects insulin is unclear. This question was the subject of our investigation. Interestingly, we observed a previously unreported SNCA profile related to IR in both humans and rodents.

Results

Serum SNCA and IR in humans

We measured serum SNCA levels in a transversal study of a Japanese population from medical checkups in 2006 (Tanno-Subetsu in Hokkaido, n = 1152). To investigate differences between the patients’ serum SNCA levels and their metabolic profile, we categorized the data into 4 groups according to the serum SNCA levels (Grade 1, 13.4 ± 0.4 ng/dL; Grade 2, 35.2 ± 0.3 ng/dL; Grade 3, 52.8 ± 0.3 ng/dL and Grade 4, 95.1 ± 1.6 ng/dL). The Grade 1 and Grade 4 groups were the lowest- and highest-serum groups, respectively. We compared the differences between these two groups, as well as those between the intermediate groups (Grade 2 and 3). Each prespecified group had a similar number of subjects and included data on anthropometric and metabolic patient profiles (Table 1). After a preliminary analysis, we detected significant differences between SNCA grades, especially between the Grade 1 (lowest) and Grade 4 (highest) groups for serum immunoreactive insulin levels (IRI), homeostatic model assessment for IR (HOMA-IR), hematocrit (Hct) and systolic blood pressure values (SBP) via ANOVA (p < 0.0001). Next, these variables were analyzed to investigate correlations with the serum SNCA concentration itself (and not the grades) to avoid artifacts in the data analysis. Univariate linear regression models were independently fit for each study variable. The dependent variable in the model was the plasma SNCA concentration (ng/dL). The results from these models are given in Table 2. The variables with a significant association with the dependent variable at the 0.20 level were included in the multivariate model; thus, all the variables were included. To assess collinearity, tolerance factors were obtained for each variable in the multivariate model. The variables with tolerance factors <0.10 were examined further. HOMA-IR, IRI, hemoglobin (Hb), and hematocrit (Hct) had tolerance factors <0.10, and standard error estimates were much larger in the multivariate model than the univariate models. Pearson correlation coefficients were obtained for the associations between the four variables. HOMA-IR and IRI were strongly correlated (r = 0.92), as were Hb and Hct (r = 0.96). Furthermore, multivariate models were examined to determine which of these variables to keep in the final multivariate model. HOMA-IR and Hb were excluded from the initial multivariate model. The parameter estimates for the initial multivariate model, with tolerance factors, are provided in Table 3. To determine the final multivariate model, a stepwise selection was used. Both the entry and keep criteria in the model were set to an alpha of 0.20. The results from the final multivariate model are displayed in Table 4. The variables included in the model were age, BMI, IRI, diastolic blood pressure (DBP), and Hct. There was an inverse relationship between the dependent variable and age, BMI, IRI, and DBP, and a positive relationship between the dependent variables and Hct. These results are consistent with the results of the correlation analysis.
Table 1

Anthropometric characteristics and metabolic profile in the studied population (n=1,152).

ProfileSNCA GradeP
1234
N288288288288 
Serum SNCA13.4 ± 0.435.2 ± 0.352.8 ± 0.395.1 ± 1.6<0.0001*
Age64.9 ± 0.863.2 ± 0.862.8 ± 0.861.1 ± 0.80.0057*
Gender (Masculine)40.8%40.3%40.6%40.6%0.9995
Height155.5 ± 9.3155.6 ± 9.3156.6 ± 8.9157.4 ± 9.10.1043
Weight58.9 ± 10.558.2 ± 11.358.4 ± 11.358.2 ± 11.10.633
BMI24.3 ± 3.723.9 ± 3.823.6 ± 3.323.4 ± 3.50.011*
Abdominal Circ.87.0 ± 9.684.5 ± 10.085.0 ± 9.484.7 ± 9.80.126
Glucose99.4 ± 20.196.9 ± 15.897.2 ± 19.496.2 ± 23.30.325
HbA1c5.44 ± 0.665.33 ± 0.615.41 ± 0.655.36 ± 0.690.608
IRI6.08 ± 3.95.36 ± 3.885.50 ± 4.624.77 ± 3.16<0.0001*
HOMA IR1.52 ± 1.01.35 ± 1.231.35 ± 1.261.16 ± 0.95<0.0001*
RBC442.4 ± 45.3440.8 ± 47.6450.6 ± 39.9453.2 ± 40.30.0019*
Hb13.49 ± 1.413.45 ± 1.413.74 ± 1.213.80 ± 1.30.0079*
Hct41.4 ± 4.041.2 ± 4.042.1 ± 3.442.5 ± 3.50.0005*
WBC5.41 ± 0.085.36 ± 0.085.19 ± 0.095.28 ± 0.090.273
Total Cholest202.4 ± 34.0197.4 ± 35.9201.7 ± 31.7203.6 ± 32.40.243
Triglycerides106.7 ± 50.6111.3 ± 72.1105.0 ± 74.8101.7 ± 69.60.628
HDL52.4 ± 15.453.0 ± 14.254.2 ± 13.655.6 ± 13.10.011
SBP143.5 ± 22.9138.9 ± 23.2137.7 ± 23.3134.9 ± 21.2<0.0001*
DBP78.6 ± 10.977.8 ± 12.676.3 ± 11.275.3 ± 10.70.0023*
TP7.32 ± 0.377.33 ± 0.397.34 ± 0.397.35 ± 0.390.0186*
Uric Acid5.33 ± 1.345.09 ± 1.255.14 ± 1.305.13 ± 1.360.1963
BUN15.8 ± 4.715.4 ± 4.015.3 ± 4.315.3 ± 3.60.676
Creatinine0.68 ± 0.200.66 ± 0.140.71 ± 0.630.66 ± 0.150.3078
AST26.1 ± 10.227.9 ± 13.324.0 ± 8.224.0 ± 8.20.0413*
ALT23.8 ± 13.225.1 ± 17.222.4 ± 13.222.4 ± 13.30.1258

Serum SNCA, alpha synuclein serum level (ng/dL); Age (years); Height (cm); Weight (kg); BMI, Body Mass Index (kg/cm2); Abdominal Circ, abdominal circumference (cm); Glucose, fasting blood glucose (mg/dL); HbA1c, glycated hemoglobin (%); IRI, Immunoreactive insulin (μU/mL); HOMA IR, Homeostatic model assessment insulin resistance (HOMAIR Units); RBC, red blood cells count (X10,000 cells/μL); Hb, hemoglobin (g/dL); Hct, hematocrit, Hct (%); WBC, white blood cells count (X1,000 cells/μL); Total Cholest, total cholesterol (mg/dL); Triglycerides (mg/dL), HDL, high density lipoproteins concentration (mg/dL); SBP, systolic blood pressure (mmHg); DBP, diastolic blood pressure (mmHg); TP, total serum protein (g/dL); Uric acid (mg/dL); BUN, blood urea nitrogen (mg/dL); Creatinine (mg/dL); AST, aspartate aminotranferase (U/L); ALT, alanine aminotransferase (U/L). Significant differences were assesed by ANOVA test. ± SD, plus/minus standard deviation, *P < 0.0019.

Table 2

Univariate Linear Regression Model Parameter Estimates.

VariableEstimate (β)StdErrtValueP-value
Age−0.277750.07460−3.720.0002
BMI−0.956870.27199−3.520.0005
HOMA IR−4.858290.88828−5.47<0001
IRI−1.468300.25754−5.70<0001
Glucose−0.093800.04657−2.010.0442
SBP−0.178480.04333−4.12<0001
DBP−0.306130.08728−3.510.0005
RBC0.072890.022943.180.0015
Hb1.914360.728832.630.0087
Hct0.951290.260843.650.0003

Dependent Variable: SNCA concentration (ng/dL).

Univariate linnear regression model for each study variable. HOMA- IR displayed high β values (−4.85, p < 0.0001) together with IRI (−1.46, p < 0.0001). Hb and Hct were also correlated with SNCA serum levels in a lower degree. SNCA, alpha synuclein; Age (years); BMI, Body Mass Index (kg/cm2); HOMA IR, Homeostatic model assessment for insulin resistance (HOMAIR Units); IRI, Immunoreactive insulin (μU/mL); Glucose, fasting blood glucose (mg/dL); SBP, systolic blood pressure (mmHg); DBP, diastolic blood pressure (mmHg); RBC, red blood cells count (X10,000 cells/μL); Hb, hemoglobin (g/dL); Hct, hematocrit, Hct (%). n = 1152.

Table 3

Initial Multivariate Linear Regression Model Parameter Estimates.

VariableEstimate (β)StdErrtValueP-valueToleranceVariance Inflation
Intercept39.9134213.531362.950.0032
Age−0.162490.08982−1.810.07070.660261.51455
BMI−0.381890.31258−1.220.22210.726021.37738
IRI−1.366870.28699−4.76<00010.777261.28656
Glucose−0.048430.04741−1.020.30720.911211.09744
SBP−0.014480.06661−0.220.82800.404332.47325
DBP−0.293490.12065−2.430.01510.497572.00978
RBC−0.004540.04609−0.100.92160.244734.08608
Hct1.593110.512903.110.00190.252403.96189

Dependent Variable: SNCA concentration (ng/dL).

Parameter estimates for the initial multivariate model using IRI. HOMA-IR was excluded from this model to avoid collinearities. SNCA, alpha synuclein; Age (years); BMI, Body Mass Index (kg/cm2); IRI, Immunoreactive insulin (μU/mL); Glucose, fasting blood glucose (mg/dL); SBP, systolic blood pressure (mmHg); DBP, diastolic blood pressure; RBC, red blood cells count (X10,000 cells/μL); Hct, hematocrit, Hct (%); (mmHg). n = 1152.

Table 4

Final Multivariate Linear Regression Model Parameter Estimates.

VariableEstimate (β)StdErrtValueP-valueToleranceVariance Inflation
Intercept37.5094913.043832.880.0041
Age−0.181830.07438−2.440.01470.961321.04024
BMI−0.422070.30801−1.370.17090.746491.33960
IRI−1.399920.28442−4.92<00010.790131.26561
DBP−0.307480.09060−3.390.00070.881031.13504
Hct1.523740.275125.54<00010.875821.14179

Dependent Variable: SNCA concentration (ng/dL).

Final multivariate linear regression model using IRI. In this model, stepwise selection was used. HOMA-IR was excluded from this model to avoid collinearities. Both the entry and keep criteria into the model was set at the alpha level of 0.20. SNCA, alpha synuclein; Age (years); BMI, Body Mass Index (kg/cm2); IRI, Immunoreactive insulin (μU/mL); Hct, hematocrit, Hct (%); DBP, diastolic blood pressure (mmHg). n = 1152.

Because there is clinical interest in the association between HOMA-IR and outcome (SNCA concentration), the multivariate models were fit but excluded IRI and Hb. The parameter estimates for the initial multivariate model, with tolerance factors, are provided in Table 5. A stepwise selection was used to create the final multivariate model. Both the entry and keep criteria in the model were set to an alpha of 0.20. The results from the final multivariate model are displayed in Table 6. The variables included in the model were age, BMI, HOMA-IR, DBP, and Hct. There was an inverse relationship between the dependent variable and age, BMI, HOMA-IR, and DBP, and a positive relationship between the dependent variables and Hct. These results are consistent with those of the correlation analysis.
Table 5

Initial Multivariate Linear Regression Model Parameter Estimates.

VariableEstimate (β)StdErrtValueP-valueToleranceVariance Inflation
Intercept34.3664913.915042.470.0137
Age−0.169300.08993−1.880.06000.660181.51474
BMI−0.456270.30940−1.470.14060.742611.34660
HOMA IR−4.953661.10339−4.49<00010.625471.59879
Glucose0.036280.053300.680.49620.722691.38373
SBP−0.015750.06671−0.240.81340.404082.47477
DBP−0.292850.12082−2.420.01550.497282.01095
RBC−0.006320.04613−0.140.89110.244824.08458
Hct1.585630.513453.090.00210.252413.96181

Dependent Variable: SNCA concentration (ng/dL).

Parameter estimates for the initial multivariate model using HOMA-IR. IRI was excluded from this model to avoid collinearities. SNCA, alpha synuclein; Age (years); BMI, Body Mass Index (kg/cm2); HOMA IR, Homeostatic model assessment for insulin resistance (HOMAIR Units); Glucose, fasting blood glucose (mg/dL); SBP, systolic blood pressure (mmHg); DBP, diastolic blood pressure; RBC, red blood cells count (X10,000 cells/μL); Hct, hematocrit, Hct (%); (mmHg). n = 1152.

Table 6

Final Multivariate Linear Regression Model Parameter Estimates.

VariableEstimate (β)StdErrtValueP-valueToleranceVariance Inflation
Intercept36.2209513.134912.760.0059
Age−0.169780.07445−2.280.02280.960981.04061
BMI−0.477020.30565−1.560.11890.759311.31698
HOMA IR−4.605000.97431−4.73<00010.800431.24932
DBP−0.314890.09063−3.470.00050.881881.13394
Hct1.548050.275855.61<00010.872611.14598

Dependent Variable: SNCA concentration (ng/dL).

Final multivariate linear regression model using HOMA- IR In this model, stepwise selection was used. IRI was excluded from this model to avoid collinearities. Both the entry and keep criteria into the model was set at the alpha level of 0.20. SNCA, alpha synuclein; Age (years); BMI, Body Mass Index (kg/cm2); HOMA IR, Homeostatic model assessment for insulin resistance (HOMAIR Units); DBP, diastolic blood pressure (mmHg); Hct, hematocrit, Hct (%). n=1152.

We found that Hb and Hct are positively correlated with SNCA levels, confirming the latter’s contribution to systemic SNCA serum levels as previously suggested12. Additionally, we found an inverse correlation with IR indicators (body mass index, HOMA-IR, and IRI) and a weaker correlation with DBP and age. These findings suggest that serum SNCA plays an important role in human metabolic disease, especially in insulin-glucose metabolism. Therefore, we further investigated SNCA’s metabolic implications in relation to IR and glucose metabolism.

SNCAKO mice display impairment in glucose metabolism during diet-induced IR

We used SNCA-deficient (SNCAKO) mice to perform the functional analysis of SNCA (Supplementary Fig. 1A and 1B). SNCAKO mice are viable and fertile, exhibit intact brain architecture, and have normal dopaminergic cell bodies, fibers and synapses20. We investigated the function of SNCA in Western diet-induced IR. We exposed SNCAKO mice to a high-fat diet (HFD). Under these conditions, the SNCAKO mice displayed a higher degree of IR compared with normal mice (WT) (C57/BL6), as indicated by an increased HOMA-IR index and higher levels of fasting blood glucose and serum insulin21222324 (Fig. 1A,C). Furthermore, SNCAKO mice displayed impairments in glucose and insulin responses as assessed via an intraperitoneal glucose tolerance test (ipGTT) and an intraperitoneal insulin tolerance test (ipITT), respectively. Additionally, SNCAKO mice presented increased insulinemia in ipGTT compared with their WT littermates, suggesting that SNCA plays an important role in glucose regulation and homeostasis during HFD-induced IR (Fig. 1D–I). Because SNCAKO demonstrated a poorer tissue insulin sensitivity profile during the ipITT and increased HOMA-IR, we decided to focus on IR in tissue. To address possible artifacts that may have affected our results, we performed all the experiments using animals with the same body weight and fat mass (Supplementary Fig. 1C and 1D).
Figure 1

SNCAKO mice display disturbances in glucose metabolism.

(a) Homeostatic model assessment index for insulin resistance (HOMA IR) in WT and SNCAKO mice after 5 weeks of a HFD. n = 10, each group. *P < 0.05 and **P < 0.01 via ANOVA. (b) Fasting blood glucose measurements in WT and SNCAKO mice fed a normal diet (ND) and a high-fat diet (HFD) for 5 weeks. n = 10, each group. (c) Fasting immunoreactive insulin measurements in WT and SNCAKO mice fed a ND or a HFD for 5 weeks. n = 10, each group. (d) Intraperitoneal glucose tolerance test (ipGTT, 2 g/kg) after 5 weeks of a ND in the WT and SNCAKO mice. n = 10, each group. (e) Intraperitoneal glucose tolerance test (ipGTT, 2 g/kg) after 5 weeks of a HFD in the WT and SNCAKO mice. n = 10, each group. (f) Serum insulin measurement (ELISA) during ipGTT in WT and SNCAKO mice fed a ND at 0, 30, 60 and 120 min. n = 10, each group.(g) Serum insulin measurement (ELISA) during ipGTT in WT and SNCAKO mice fed a HFD at 0, 30, 60 and 120 min. n = 10, each group. (h) Intraperitoneal insulin tolerance test (ipITT, 0.8 IU/kg) under a ND. n = 10, each group. (i) Intraperitoneal insulin tolerance test (ipITT, 0.8 IU/kg) after 5 weeks of a HFD. n = 10, each group. From (b) to (i): P < 0.05 was obtained for the area under the curve comparisons between the SNCAKO and WT groups (ANOVA test). In all the experiments: *P < 0.05; **P < 0.01.All histogram bars show the means ± s.d.

To determine whether SNCAKO mice are more sensitive to the development of IR under HFD, we applied hyperinsulinemic euglycemic clamps. Using this technique, we observed a significant increase in IR in the HFD-fed SNCAKO mice compared with the HFD-fed WT mice, with very modest changes (not statistically significant) between basal and insulin-hepatic glucose production (Fig. 2A,D). This IR was clearly noticeable in peripheral tissues, such as the adipose and skeletal tissues, of the SNCAKO mice (Fig. 2E,G). Taken together, our results indicate that SNCA plays an important role in diminishing insulin insensitivity in HFD-induced IR. Therefore, SNCA deletion results in a decreased tissue response to insulin; this is consistent with our initial findings in humans.
Figure 2

Hyperinsulinemic euglycemic clamp. SNCAKO mice display evident insulin resistance.

(a) Hyperinsulinemic euglycemic clamp (HEC) in WT and SNCAKO mice fed a ND or a HFD (after 5 weeks). n = 5 each group. GIR, glucose infusion rate (mg*kg−1min−1). (b) Percentage suppression of hepatic glucose production (HGP) in WT and SNCAKO mice fed a ND or a HFD (after 5 weeks) during the HEC. n = 5 each group. (c) Basal HGP in WT and SNCAKO mice fed a ND or a HFD (after 5 weeks). n = 5 each group. (d) Clamp HGP in WT and SNCAKO mice fed a ND and a HFD (after 5 weeks). n = 5 in each group. (e) Clamp rate of disappearance indicating peripheral insulin resistance, especially in the HFD group. WT and SNCAKO mice fed a ND or a HFD (after 5 weeks). n = 5 in each group. (f) Glucose uptake in white adipose tissues in WT and SNCAKO mice fed a ND or a HFD during the HEC. Rate of [3H] deoxyglucose uptake in eWAT (epididymal white adipose tissue). n = 5 in each group. (g) Glucose uptake in the skeletal muscle of WT and SNCAKO mice fed a ND or a HFD during the HEC. Rate of [3H] deoxyglucose uptake in the soleus muscle. n = 5 in each group. In (a), each of the group comparisons were made at the end of the HEC using the area under the curve and WT ND group as the baseline response. In all the experiments: **P < 0.05; ***P < 0.001 via ANOVA test and Bonferroni’s correction when appropriate. Graph bars show the means ± s.d.

Finally, we measured the serum SNCA levels in diabetic mice. Interestingly, the serum SNCA level was decreased in db/db mice and also decreased with age (10, 24 and 96 weeks old) in mice (Supplementary Fig. 2A and 2B), similarly to our results in humans (Supplementary Fig. 2C). These results indicate that declining serum SNCA levels with age may contribute to the development of IR or diabetes.

Discussion

This report elucidates the novel role of SNCA in IR. Ablation of SNCA exacerbates IR in tissues of rodents fed an HFD, and IR is also observed in patients with decreased SNCA serum levels. The higher the concentration of serum SNCA, the greater is the insulin sensitivity in both humans and rodents. SNCA demonstrated a clear benefit in terms of limiting IR in mice when exposed to HFD, as observed in our knock-out model and corroborated in the euglycemic clamp studies. The physiological function of glucose metabolism and regulation is to ensure effective energy substrate supplies for tissues. In the IR state, this mechanism is defective in transmitting signals to elicit sufficient energy substrate entry into the cell2526. This status can be induced by exposure to saturated fats through a HFD27. Our report is the first to describe the use of SNCA knock-out mice for studying glucose metabolism in a pathological model (HFD IR model). We hypothesize that SNCA acts as a dynamic stress buffer to protect insulin signaling from saturated-fat-related IR and, additionally, as a promoter of glucose metabolism in tissues. In vitro evidence supports our hypothesis regarding lipids and indicates that SNCA could participate in the inhibition of fatty acid-dependent tissue toxicity because this protein can bind to lipids, has a high affinity for them and can interact with them through direct or indirect mechanisms2829. Additionally, SNCA is important for glucose metabolism in tissues because it can elicit glucose uptake via the LPAR2-CD90 heterodimer (receptor), especially in adipose tissues and skeletal muscle19. In humans, the SNCA serum levels and HOMA- IR or IRI were significantly and strongly correlated. Low levels of serum SNCA clearly displayed a higher HOMA- IR and insulin serum levels, which is congruent with the glucose metabolism profile of the SNCA knock-out mice. Interestingly, DBP, BMI and age were also correlated (modest correlation); this may indicate that SNCA is interacting with other risk factors of the metabolic disease together with HOMA-IR and IRI in humans. These SNCA interactions with conditions other than HOMA-IR and IRI require further research and will be the subject of future investigations by our research team. The limitations of our population study include its transversal design. A prospective approach will give us a better understanding of the relationship between causality and serum SNCA over time as well as the cut-off points for normal serum SNCA levels. Additionally, because this study included only patients with Japanese ancestry, our findings cannot be generalized to other ethnicities. Another study in patients with metabolic disease or type 2 diabetes is needed to evaluate the possible associations between serum SNCA and disease severity or complications. The strengths of our study include a large population, a broad spectrum of patient clinical characteristics, medical personnel with extensive experience in previous parallel clinical trials in the Tanno and Subetsu project, a comprehensive design (human and in vivo approaches) and a robust statistical analysis. Currently, the narrow therapeutic arsenal against IR is a substantial challenge for physicians in attempts to reduce the risk of IR and/or type 2 diabetes onset in which tissue insulin response is greatly curtailed. As such, SNCA may provide new avenues to novel therapeutics in IR and diabetes.

Materials and Methods

Materials

We used recombinant SNCA (Atgen, South Korea) and insulin (Humulin-R100, Lilly, Japan). Anti-BSA (albumin) was purchased from Upstate Biotechnology (USA); all the other antibodies were purchased from Cell Signaling (USA).

Human study

This was an observational cross-sectional study performed with 1,152 patients residing in Tanno and Subetsu in Hokkaido, Japan, in 20063031. The study was approved by Sapporo Medical University’s Institutional Review Board and in accordance with the Declaration of Helsinki. We included patients aged 20 years or more who were willing to participate in the study; they gave informed consent. We excluded severely sick patients with or without previous myocardial infarction or stroke as well as those with symptomatic cognitive disorders. Severely sick patients were defined as those who were in the terminal stages of chronic or acute diseases, such as type 2 diabetes mellitus (microvascular damage, i.e., retinopathy, diabetic foot, diabetic nephropathy), oncological diseases (solid or hematological tumors), sepsis, multiple organ dysfunction, cardiovascular disease, renal insufficiency or any other life-threatening disease that in the opinion of the principal investigator would have had a substantial impact on life expectancy, patient deambulation or ability to come to the clinic for medical checkups. These patients were excluded because they have very different pathophysiology that could interfere in the characterization of SNCA as a glucoregulator in a population study. The participating patients were enrolled consecutively in a prospective fashion; at the time of our investigation, this count was 1,152. A total of 1,152 patients were included and assessed for serum SNCA using the Human α-Synuclein Kit (Invitrogen, USA.). HOMA-IR was assessed in these patients using the following formula: Fasting glucose (mg/dL) × Immunoreactive insulin (μU/mL) / 405.

Animal procedures

The experiments were approved by the Ethical Committee for Animal Experiments of the Osaka University Graduate School of Medicine. All the in vivo experiments were performed in compliance with Osaka University’s Animal Facility regulations. We used mice of the same body weight for the group comparisons. Serum insulin (Morinaga, Japan.), glucagon (R&D, USA.) and cortisol (Cayman Chemical Company, USA.) were quantified using ELISA.

Methods

Immunoblotting

The samples were processed with SDS-PAGE and transferred to PVDF membranes. Then, the membranes were blocked in 5% skim milk and incubated with their respective antibody. We assessed chemiluminescence using an Image Quant LAS4000 mini (GE, USA).

Intraperitoneal glucose and insulin tolerance test (ipGTT and ipITT)

After 5 weeks of exposure to an HFD32 and after 8 hr of fasting, the mice were injected with glucose (2 g/kg) or insulin (0.8 IU/kg). Blood samples were extracted at 0, 15, 30, 60, 90 and 120 min.

Glucose clamp

After cardiac catheterization and mice habituation, the mice were fasted for 5–6 h. Then, under euglycemic conditions, the WT and SNCAKO mice were assessed using radiolabeled tracers. Blood and tissue sampling was performed as previously reported (see Supplementary Materials)3334.

Statistical Analysis

The human data were analyzed using IBM SPSS Statistics 19. We used Stat View v5.0 for both the in vivo and in vitro data. We presented the data as the means ± s.d. We used Student’s t test and ANOVA for statistical significance.

Additional Information

How to cite this article: Rodriguez-Araujo, G. et al. Low alpha-synuclein levels in the blood are associated with insulin resistance. Sci. Rep. 5, 12081; doi: 10.1038/srep12081 (2015).
  34 in total

Review 1.  Critical nodes in signalling pathways: insights into insulin action.

Authors:  Cullen M Taniguchi; Brice Emanuelli; C Ronald Kahn
Journal:  Nat Rev Mol Cell Biol       Date:  2006-02       Impact factor: 94.444

2.  Palmitate induced mitochondrial deoxyribonucleic acid damage and apoptosis in l6 rat skeletal muscle cells.

Authors:  L I Rachek; S I Musiyenko; S P LeDoux; G L Wilson
Journal:  Endocrinology       Date:  2006-10-05       Impact factor: 4.736

3.  TLR4 links innate immunity and fatty acid-induced insulin resistance.

Authors:  Hang Shi; Maia V Kokoeva; Karen Inouye; Iphigenia Tzameli; Huali Yin; Jeffrey S Flier
Journal:  J Clin Invest       Date:  2006-10-19       Impact factor: 14.808

4.  Alpha-synuclein gene deletion decreases brain palmitate uptake and alters the palmitate metabolism in the absence of alpha-synuclein palmitate binding.

Authors:  Mikhail Y Golovko; Nils J Faergeman; Nelson B Cole; Paula I Castagnet; Robert L Nussbaum; Eric J Murphy
Journal:  Biochemistry       Date:  2005-06-14       Impact factor: 3.162

5.  Dominant-negative effects of a novel mutated Ins2 allele causes early-onset diabetes and severe beta-cell loss in Munich Ins2C95S mutant mice.

Authors:  Nadja Herbach; Birgit Rathkolb; Elisabeth Kemter; Lisa Pichl; Matthias Klaften; Martin Hrabé de Angelis; Philippe A Halban; Eckhard Wolf; Bernhard Aigner; Ruediger Wanke
Journal:  Diabetes       Date:  2007-02-15       Impact factor: 9.461

Review 6.  Fatty acid metabolism, energy expenditure and insulin resistance in muscle.

Authors:  Nigel Turner; Gregory J Cooney; Edward W Kraegen; Clinton R Bruce
Journal:  J Endocrinol       Date:  2014-01-15       Impact factor: 4.286

7.  Impact of the metabolic syndrome on mortality from coronary heart disease, cardiovascular disease, and all causes in United States adults.

Authors:  Shaista Malik; Nathan D Wong; Stanley S Franklin; Tripthi V Kamath; Gilbert J L'Italien; Jose R Pio; G Rhys Williams
Journal:  Circulation       Date:  2004-08-23       Impact factor: 29.690

8.  Influence of hypertension on the incidence of cardiovascular disease in two rural communities in Japan: the Tanno-Sobetsu [corrected] study.

Authors:  Fumio Obara; Shigeyuki Saitoh; Satoru Takagi; Kazuaki Shimamoto
Journal:  Hypertens Res       Date:  2007-08       Impact factor: 3.872

9.  Red blood cells are the major source of alpha-synuclein in blood.

Authors:  Robin Barbour; Kristin Kling; John P Anderson; Kelly Banducci; Tracy Cole; Linnea Diep; Michael Fox; Jason M Goldstein; Ferdie Soriano; Peter Seubert; Tamie J Chilcote
Journal:  Neurodegener Dis       Date:  2008-01-04       Impact factor: 2.977

10.  Identification and localization of alpha-synuclein in human cornea.

Authors:  Samin Hong; Hyung Keun Lee; Chan Yun Kim; Gong Je Seong
Journal:  Korean J Ophthalmol       Date:  2008-06
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  17 in total

Review 1.  The role of lipids in α-synuclein misfolding and neurotoxicity.

Authors:  Cathryn L Ugalde; Victoria A Lawson; David I Finkelstein; Andrew F Hill
Journal:  J Biol Chem       Date:  2019-05-07       Impact factor: 5.157

2.  Osteoporosis and Dementia: Establishing a Link.

Authors:  Christine W Lary; Clifford J Rosen; Douglas P Kiel
Journal:  J Bone Miner Res       Date:  2021-09-19       Impact factor: 6.741

3.  Metabolism and memory: α-synuclein level in children with obesity and children with type 1 diabetes; relation to glucotoxicity, lipotoxicity and executive functions.

Authors:  Nouran Yousef Salah; Sara Ibrahim Taha; Safeya Hassan; Mai Seif ElDin Abdeen; Mostafa Ahmad Hashim; Rana Mahmoud
Journal:  Int J Obes (Lond)       Date:  2022-09-24       Impact factor: 5.551

Review 4.  Mitochondrial control of cell bioenergetics in Parkinson's disease.

Authors:  Raquel Requejo-Aguilar; Juan P Bolaños
Journal:  Free Radic Biol Med       Date:  2016-04-16       Impact factor: 7.376

5.  Unveiling molecular signatures of preeclampsia and gestational diabetes mellitus with multi-omics and innovative cheminformatics visualization tools.

Authors:  Melanie T Odenkirk; Kelly G Stratton; Marina A Gritsenko; Lisa M Bramer; Bobbie-Jo M Webb-Robertson; Kent J Bloodsworth; Karl K Weitz; Anna K Lipton; Matthew E Monroe; Jeremy R Ash; Denis Fourches; Brandie D Taylor; Kristin E Burnum-Johnson; Erin S Baker
Journal:  Mol Omics       Date:  2020-09-23

6.  Altered Plasma Profile of Antioxidant Proteins as an Early Correlate of Pancreatic β Cell Dysfunction.

Authors:  Taiyi Kuo; Ja Young Kim-Muller; Timothy E McGraw; Domenico Accili
Journal:  J Biol Chem       Date:  2016-02-25       Impact factor: 5.157

Review 7.  Alpha-synuclein structure, functions, and interactions.

Authors:  Fatemeh Nouri Emamzadeh
Journal:  J Res Med Sci       Date:  2016-05-09       Impact factor: 1.852

8.  Metformin as a Potential Neuroprotective Agent in Prodromal Parkinson's Disease-Viewpoint.

Authors:  Carolina Sportelli; Daniele Urso; Peter Jenner; K Ray Chaudhuri
Journal:  Front Neurol       Date:  2020-06-12       Impact factor: 4.003

Review 9.  Alpha synuclein in hematopoiesis and immunity.

Authors:  Yu Pei; Robert W Maitta
Journal:  Heliyon       Date:  2019-10-18

Review 10.  Alpha-Synuclein Post-translational Modifications: Implications for Pathogenesis of Lewy Body Disorders.

Authors:  Nelson de Oliveira Manzanza; Lucia Sedlackova; Raj N Kalaria
Journal:  Front Aging Neurosci       Date:  2021-06-25       Impact factor: 5.750
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