Up‐regulation of FoxO1 contributes to adverse vascular remodelling in type 1 diabetic rats

Abstract Vascular complications from diabetes often result in poor outcomes for patients, even after optimized interventions. Forkhead box protein O1 (FoxO1) is a key regulator of cellular metabolism and plays an important role in vessel formation and maturation. Alterations of FoxO1 occur in the cardiovascular system in diabetes, yet the role of FoxO1 in diabetic vascular complications is poorly understood. In Streptozotocin (STZ)‐induced type 1 diabetic rats, FoxO1 expression was up‐regulated in carotid arteries at 8 weeks of diabetes that was accompanied with adverse vascular remodelling characterized as increased wall thickness, carotid medial cross‐sectional area, media‐to‐lumen ratio and decreased carotid artery lumen area. This adverse vascular remodelling induced by hyperglycaemia in diabetic rats required FoxO1 activation as pharmacological inhibition of FoxO1 with 50mg/kg AS1842856 (AS) reversed vascular remodelling in type 1 diabetic rats. The adverse vascular remodelling in type 1 diabetes mellitus (T1DM) occurred concomitantly with increases in pro‐inflammatory factors, adhesion factors, apoptosis, NOD‐like receptor family protein‐3 inflammasome activation and the phenotypic switch of arterial smooth muscle cells, which were all reversed by AS. In addition, FoxO1 inhibition counteracted the down‐regulation of its upstream mediator PDK1 in T1DM. PDK1 activator reduced FoxO1 nuclear translocation, which serves as the basis for subsequent transcriptional regulation during hyperglycaemia. Taken together, our data suggest that FoxO1 is a critical trigger for type 1 diabetes‐induced vascular remodelling in rats, and inhibition of FoxO1 thus offers a potential therapeutic option for diabetes‐associated cardiovascular diseases.


| INTRODUC TI ON
Diabetic vascular complications result in poor outcomes in diabetic patients, even after interventions from all medical disciplines, thereby posing a major challenge for today's healthcare practitioners. However, the precise molecular and cellular mechanisms underlying the pathogenesis of diabetic vascular complications are still not fully understood.
Hyperactivation of forkhead box-containing protein O subfamily (FoxOs) has been reported to be associated with overt diabetes hallmarks, such as hyperglycaemia, hypertriglyceridaemia and insulin resistance, as well as diabetic complications. 1-6 Forkhead box protein O1 (FoxO1), a member of forkhead box-containing protein O subfamily, is a transcription factor and acts in a cell-specific manner to modulate the genes that control gluconeogenesis, 7,8 blood vessel assembly, 9 muscle wasting 10 and adipocyte differentiation. 11 Its transcriptional activity is dependent on its phosphorylation state. 12 Vascular remodelling is an active process of structural alteration, depending on a dynamic interaction among locally generated growth factors, vasoactive substances and hemodynamic stimuli. 17,18 Highglucose condition directly impairs vascular smooth muscle cells (VSMCs) biology via promoting neo-intimal hyperplasia, yielding arterial narrowing or occlusion. This pathological process involves matrix production, inflammatory cell infiltration and smooth muscle cells (SMCs) phenotypic switching. 19 As extracellular matrix scaffold degradation enables tissue reshaping, the participation of specialized enzymes, called matrix metalloproteinases (MMPs), has become the object of intense interest in relation to vascular remodelling. 20 As demonstrated in early post-mortem studies, inflammation and apoptotic SMCs play a great role in the progression of artery complications in diabetic patients of sudden coronary death. 21 Increased apoptotic SMCs in atherosclerotic lesions, in turn, increases the propensity of plaque rupture. 22 Therefore, the progress of adverse diabetic vascular remodelling involves SMCs apoptosis, MMP expression as well as inflammatory cell infiltration and SMCs phenotypic switching.
3-phosphoinositide-dependent protein kinase 1 (PDK1) activates a group of protein kinases belonging to the protein kinase A (PKA)/PKG/PKC kinase family that play important roles in mediating diverse biological processes including vascular function. [23][24][25][26] Indeed, it has been found that endothelial cells-specific deletion of PDK1 enhances insulin sensitivity via reducing visceral fat and suppressing angiogenesis. 27 In addition, PDK1/FoxO1 pathway is important in regulating glucose and energy homeostasis, but little is known about its role in diabetic vascular remodelling.
This study was designed to shed light on the role of FoxO1 in diabetic vasculature alteration, as well as the underlying mechanisms. We showed that elevation of FoxO1 was a crucial factor associated with the increase of pro-inflammatory factors, MMP expression and SMCs phenotype switching, resulting in the development of pathological vascular remodelling in type 1 diabetes mellitus (T1DM). Subsequently, we demonstrated that FoxO1 inhibition reversed the phenotypic switch of SMCs and lowered the chronic inflammatory states, thereby preventing diabetes-driven tunica media dysfunction. Inhibition of FoxO1 may provide a valuable tool to alleviate the adverse vascular remodelling in T1DM progression. anaesthesia comprised of a combination of ketamine at 67.7 mg/ kg bodyweight and xylazine at 6.77 mg/kg. After 72 hours from injection, blood glucose was measured using a One Touch Ultra Glucose meter (Life Scan Inc USA); rats with blood glucose levels >15 mM were recognized as diabetic.

| Experimental procedure
Diabetic rats (n = 6) were treated with a selective FoxO1 inhibitor AS1842856 (AS), which has an IC50 of 0.033 mM to inhibit FoxO1, and can block FoxO1 expression at a final concentration of 0.05-1 mM without showing cytotoxicity. 28,29 At fourth week of diabetes induction, diabetic rats were administrated intragastrically with AS AS1842856 (50 mg/kg) or the same dose of β-cyclodextrin as control, twice daily with 12-hour intervals between each administration, for 8 days before termination. Before administered to animals, the drug AS1842856 was dissolved in 10% w/v β-cyclodextrin and underwent ultrasound homogenization until obtaining homogenous suspension liquid. 16 The rats were sacrificed at 8 weeks after diabetes induction. Carotid arteries were then sampled.
β-cyclodextrin has been widely used as solvent control of many pharmaceutical molecules as it increased the biocompatibility of the effect and also help release in a slow way. Our preliminary study showed that β-cyclodextrin did not affect target protein levels in liver/plasma. 30

| Frozen section preparation
Fresh vascular tissues were embedded in OCT compound and subsequently stored at −80°C. Sections at 8 µm thick were then cut and mounted on gelatin-coated slides. Before staining, slides were warmed at room temperature for 30-60 minutes, fixed in ice cold acetone as fixative for 10-15 minutes and then dried in air at room temperature for 30-60 minutes. After drying, slides were washed in PBS and subjected to standard staining procedure for immunofluorescence, as well as haematoxylin and eosin (HE) staining.

| H&E staining
Sample slides were stained with haematoxylin (H3136, Sigma) for 5 minutes; colour was checked under the microscope. Slides were then washed with tap water 3 times, followed by bluing in Scott's tap water (S5134, Sigma) for 30 seconds. After another 3 times of washing with tap water, slides were counterstained with Eosin Y (230 251, Sigma) for 40 seconds, followed by washing with tap water for another 3 times. After the final wash, slides were mounted with mountant (06 522, Sigma), covered with coverslip, dried overnight and checked with a microscope connected with computer using Olympus cellSens software (Version 2.1).

| Index of vascular structure
The artery wall was observed using a microscope (Leica, Wetzlar, Germany). Mean wall thickness, media-to-lumen ratio (M/L ratio), cross-sectional area (CSA) and lumen area were calculated using Image J.
To determine the specific role of PDK1 in cytoplasmic and nuclear FoxO1 regulation, 5 μM PS48 (PDK1 Activator, Sigma-Aldrich) as previous report 31 was applied following high-glucose (HG, 25 mmol/L) treatment.

| Nuclear and cytoplasmic protein separation
Frozen tissues were suspended in a buffer containing 10 mM Tris, pH 7.5, 1.5 mM MgCl 2 , 10 mM KCl and 0.1% Triton X-100, and lysed by homogenization. Nuclei were recovered by micro-centrifugation at 17 000 g for 5 min. The supernatant, containing cytoplasmic and membrane protein, was collected and stored at −80°C for further Western blot analysis. Nuclear proteins were extracted at 4°C by gently re-suspending the nuclei pellet in buffer containing 20 mM Tris, pH 7.5, 20% glycerol, 1.5 mM MgCl 2 , 420 mM NaCl, 0.2 mM EDTA and 0.1% Triton X-100, followed by 1 hour incubation at 4 o C with occasional vortexing. After micro-centrifugation at 13,000 x g for 15 minutes at 4°C, the supernatant containing the nuclear protein was collected.

| Real-time polymerase chain reaction
Total RNA was isolated using TRIzol. Equal amounts of RNA were reverse-transcribed and processed using the PrimeScript RT Master Mix Kit (Cat. number RR036Q, Takara, Shuzou, Japan), according to the manufacturer's instructions. Q uantitative real-time PCR was performed as described 32 using SYBR Green PCT master mix (RR820A, Takara) on an Applied Biosystems Prism 7000 sequence detection system (Applied Biosystems, Foster City, CA, USA). Amplification conditions were 30 seconds at 95°C for denaturation, 40 cycles of 5 seconds at 95°C and 30 seconds at 60°C. Gene-specific primers sequences used were listed in Table S1. mRNA levels of the different genes tested were normalized to those of β-actin.

| Statistics
For statistical analysis, SPSS version 25.0 software was used. Results were presented as mean ± standard deviation (SD). Comparison among groups was performed using one-way analysis of variance (ANOVA) followed by Duncan's multiple comparison post hoc tests.
Differences were considered statistically significant at P < .05.

| FoxO1 was elevated in the carotid arteries of diabetic rats that was attributable to adverse vascular remodelling in diabetes
We first investigated the expression of FoxO1 in the carotid arteries of Sprague-Dawley (SD) rats at 8 weeks of the diabetes. Western blot analysis showed that total FoxO1 expression was up-regulated in the carotid arteries of diabetic rats, which could be significantly attenuated by treatment with AS (a selective FoxO1 inhibitor AS1842856). On the other hand, the level of phosphorylated FoxO1 in the carotid arteries of diabetic rats was significantly reduced as compared to that in the control group (P < .05) and AS treatment partially restored the phosphorylated FoxO1 level in diabetic group (P < .05, DM + AS vs DM, Figure 1A,B).
Next, the vascular wall structure was assessed by measuring carotid artery wall thickness, carotid medial cross-sectional area (CSA), media-to-lumen ratio (M/L ratio) and lumen areas at 8 weeks after STZ injection ( Figure 1C-G). H&E staining showed that the wall thickness of carotid artery from diabetic rats was significantly greater than that in non-diabetic control group ( Figure 1D, P < .05).
T1DM was associated with arterial wall hypertrophy, with significant increases in CSA and M/L ratio as compared to those in non-diabetic control group ( Figure 1E-F, P < .05). In addition, the media thickened to encroach on the lumen and resulted in decreased carotid lumen areas in diabetic rats, as compared with non-diabetic control group ( Figure 1G, P < .05). AS treatment also prevented carotid wall morphological changes seen in diabetic rats (all P < .05 DM + AS vs DM, Figure 1E-G). These data showed that inward remodelling occurred in the carotid artery in diabetic rats, which was slowed down or prevented by FoxO1 inhibition, suggesting that FoxO1 contributed to the development of adverse vascular remodelling in T1DM.
To further investigate the role of FoxO1 in the pathological process of type 1 diabetes-induced vascular remodelling, we examined the expression of α-smooth muscle actin (α-SMA), a contractile state SMCs-specific protein marker in carotid arteries. H&E staining showed increased media of carotid occurred in diabetic rats that was consistent with the findings of immunofluorescence staining which showed that α-SMA expression was down-regulated in diabetic rat carotid media and was restored by AS treatment (Figure 2).
Thus, the results demonstrated that type 1 diabetes-induced vascular remodelling was associated with elevated FoxO1 and decreased phosphorylated FoxO1 levels, suggesting that high levels of FoxO1 nuclear translocation stimulated the transcription of certain genes involved in type 1 diabetes-induced vascular remodelling development.

| FoxO1 inhibition ameliorated NLPR3 inflammasome-dependent inflammation in the carotid artery of type 1 diabetic rats
The mechanism whereby inhibition of FoxO1 attenuated the development of diabetic vascular remoulding also needs to be further investigated. We, thus, observed the blood glucose of rats and the result showed that administration of AS did not affect blood glucose level (Table S2) and was decreased following treatment with AS ( Figure 3A). In the meantime, the levels of interleukin (IL)-1β, IL-6 and IL-8 were significantly elevated in carotid arteries in diabetic rats, and such increases were offset by AS ( Figure 3A). Given that monocyte attachment is involved in vascular remodelling, Immunofluorescence staining was performed to examine the protein levels of cell adhesion molecules VCAM-1 and ICAM-1. The results showed that both VCAM-1 and ICAM-1 levels were significantly increased in diabetic rat carotid and were reduced by AS treatment ( Figure 3B).
Following the finding that AS reduced diabetes-induced inflammation, we went on to further investigate the role of NLRP3 (NODlike receptor family, pyrin domain containing 3) inflammasome in this pathology, given that NLRP3 has emerged as a central regulator in the inflammatory process that contributes to the aggravation of DM and diabetic complications. 34 As expected, the expression of key inflammasome-associated enzymes NLRP3 and ASC (apoptosis-associated speck-like protein with a caspase-recruitment domain) protein levels in diabetic rat carotid artery were significantly increased as compared to those in the control group, and these increases were offset by AS ( Figure 3C, D).

| Inhibition of FoxO1 prevented cell apoptosis in the carotid artery of diabetic rats
Emerging evidence showed that, in addition to inflammation, vascular proliferation and apoptosis contribute significantly to inward vascular remodelling, with apoptosis localized to the outer periphery which reduces the vessel outer diameter while inward growth decreases lumen diameter despite it contributes to the maintenance of the media volume. Whether apoptosis is a growth-related compensatory mechanism, or a primary process involved in vessel growth, remains to be clarified. We wondered whether FoxO1 mediated vascular re-

| FoxO1 inhibition counteracted the phenotypic switch of SMCs in diabetic rats
Based on in vivo observation, we postulated that FoxO1 may have contributed to vascular remodelling in diabetes via its impact on cellular phenotypic switching. SMCs exist in a diverse range of phenotypes. In normal mature blood vessels, the predominant phenotype is the quiescent, also known as contractile or differentiated SMCs, whose major function is regulating blood vessel diameter (through vasodilation and vasoconstriction) and blood flow. During pathological vascular remodelling (ex. arteriosclerosis), SMCs with noncontractile or synthetic phenotype generate intimal vascular lesions.
The protein levels of α-SMA, SM-MHC and calpoinin-1, three widely used SMCs differentiation markers, were found to be significantly decreased in diabetic rat carotid arteries, which were all restored towards control levels by AS treatment (Figure 5A, B). Thus, these results indicated that AS treatment reverted the phenotypic switch of SMCs in type 1 diabetic rats and restored it to a contractile state.

| Elevation of FoxO1 contributed to the increase in MMP-2 and MMP-9 in the carotid arteries of type 1 diabetic rats
As degradation of the extracellular matrix scaffold enables tissue reshaping, participation of specialized enzymes, called matrix metalloproteinases (MMPs), has become the object of interest in relation to vascular remodelling. 20 Evidence indicates that the major drivers of vascular remodelling, such as haemodynamics, injury, inflammation and oxidative stress, regulate MMP expression and activation.
Diffuse wall thickening can be frequently seen in the carotid arteries of type 1 diabetic rats, which is found to be closely associated with MMP-2 and MMP-9 activation. 35 In an attempt to further confirm the changes in MMPs expression during inflammation, we measured MMP-2 and MMP-9 protein levels. Our results showed that levels of MMP-2 and MMP-9 protein expression were both increased in carotid arteries in type 1 diabetic rats, whereas AS treatment decreased those levels back towards control ones (P < .05, Figure 5C-D).

| PDK1 regulated FoxO1 nuclear translocation during type 1 diabetes-induced vascular remodelling
The 3-phosphoinositide-dependent protein kinase 1 (PDK1)/FoxO1 pathway is important in regulating glucose and energy homeostasis, 26,27 but little is known about its role in type 1 diabetes-induced vascular remodelling. We, thus, evaluated PDK1 protein level by Western blot in the diabetic rat carotid arteries. The results showed that PDK1 protein expression was markedly decreased in type 1 diabetic rats and restored by AS treatment (Figure 6A, B). To confirm whether PDK 1 was involved in FoxO1 nuclear translocation and the subsequent transcription, nuclear FoxO1 protein expression in cultured HASMCs in the presence of PS48 (PDK1 Activator) and HG were examined by Western blot. The results showed that nuclear protein level of FoxO1 was decreased after application of PS48 ( Figure 6C, D), suggesting that PDK1 regulated FoxO1 translocation in HG condition in HASMCs. These findings suggested that high glucose may affect the PDK1-FoxO1 signalling, resulting in F I G U R E 2 FoxO1 inhibition with AS1842856 restored down-regulated α-SMA in the carotid of diabetic rats. Representative immunofluorescence photomicrographs of FoxO1 (green) and α-smooth muscle actin (α-SMA, a smooth muscle cell-specific marker, red) in carotid arteries from STZ-treated rats with/without AS treatment. Nuclei are counter stained with DAPI (blue). Scale bars: 10 μm. Images are representative of n = 6 carotid arteries per group. Con: Control, DM: diabetic rats. DM + AS: diabetic rats with treatment of FoxO1-selective inhibitor AS1842856 down-regulation of PDK, along with the subsequent FoxO1 activation and the adverse type 1 diabetes-induced vascular remodelling ( Figure 6E).

| D ISCUSS I ON
The major finding of the current study is that FoxO1 is a novel promoter of vascular remodelling in type1 diabetic rats. We discovered that diabetes increases FoxO1 protein level in rat carotid arteries and the increase in FoxO1 protein is associated with vascular remodel- Along with other study, 36 we found that inhibition of FoxO1 with AS showed a dropping trend in blood glucose level (Table S2), while the differences between groups are not significant (partly because of the limited sample size).
Although great advances in cardiovascular therapy and prevention have reduced diabetes-related coronary mortality in developed countries, the overall cardiovascular morbidity and mortality are still high in diabetic patients. Moreover, cardiovascular disease (CVD) risk in diabetes remains high even after optimal treatment with statins. Abundant evidence suggests that FoxO1 is an important factor for cardiac metabolic regulation and for maintaining cardiac function. Physiologically, FoxO1 is known to be associated with fasting and cAMP-induced glycogenolysis and gluconeogenesis, 36 with respect to the regulation of various metabolic pathways in adapting to fasting and feeding states. 37 Interestingly, decreased circulating insulin in diabetes is associated with increased FoxO1 activation, 3 whereas mitochondrial reactive oxygen species (ROS) production was enhanced by altering redox balance and impacting the activity of redox-sensitive proteins, such as protein kinase C-ε. Furthermore, F I G U R E 3 FoxO1 is associated with increased pro-inflammatory factors in diabetic rat carotid artery. (A) mRNA expression profiles of TNF-α, IL-1β, IL-6 and IL-8 in carotid arteries derived from real-time (RT) qPCR from diabetic Sprague-Dawley rats with/without AS treatment (n = 6). Expression was normalized to housekeeping GAPDH mRNA. (B) Representative immunofluorescence photomicrographs of ICAM-1 and VCAM-1 (both in red) in carotid arteries from diabetic rats with/without AS treatment (n = 6, Scale bars: 20 μm). (C) Western blot analysis of NLRP3 (NOD-like receptor family protein-3) and ASC (apoptosis-associated speck-like protein with a caspaserecruitment domain) protein expression in carotid arteries from diabetic rats with/ without AS treatment. Protein expression was normalized to housekeeping protein GAPDH. (D) Mean values of normalized protein expression of NLRP3 and ASC in carotid arteries from STZ-treated rats with/without AS treatment (n = 6). Data are presented as mean ± SD. *P < .05 vs Control; #P < .05 vs Diabetes. Con: Control, DM: diabetic rats. DM + AS: diabetic rats with treatment of FoxO1selective inhibitor AS ROS reduces insulin signalling and induces subsequent insulin resistance, yielding elevated FoxO1 activation. On the other hand, FoxO1 is involved in angiogenesis through participating in the regulation of endothelial cell metabolism. 9 Therefore, we investigated the role of FoxO1 in the pathological progress of diabetic vascular complications. In the present study, FoxO1 was consistently found to be highly expressed in carotid arteries, accompanied by hyperglycaemia-induced vascular remodelling, while FoxO1 inhibitor ameliorated the hyperglycaemia-induced SMCs decrease in carotid medium of type 1 diabetic rats. This is suggestive of FoxO1 alteration as a major contributing factor to the development of diabetic vascular complications. Of note, diabetic db/db mice with acute administration of AS1842856 drastically decreased fasting plasma glucose. 38 In our previous study, 16 AS1842856 treatment reduced mitochondrial ROS content, cardiac apoptosis and improved cardiac performance, but do not have any significant effects on existing hyperglycaemia in STZ-induced diabetic rats. In this study, the value of random blood glucose rather than fasting plasma glucose was recorded and we found that AS1842856 treatment had no effects on elevated random blood glucose (Table S2) in STZ-induced diabetic rats model, suggesting the beneficial effects of AS1842856 treatment on diabetic vascular remodelling is not through lowering blood glucose.
Unlike the cardiovascular risk in T1D is mainly driven by hyperglycaemia, the cause of carotid arteries remodelling in T2D is multifactorial, featuring several factors largely absent in T1D such as obesity and hypertension. 39 Nevertheless, the pathological process involves in carotid arteries remodelling is similar to some extent in both diabetic groups, such as matrix metalloproteinases (MMPs) alteration, inflammatory cell infiltration and smooth muscle cells (SMCs) apoptosis. 19,21,22 MMPs promote arterial remodelling. 40 MMP-associated invasion and de-differentiation of VSMCs is an essential molecular and cellular event of diffuse IMT (intra medial thickness). Intracellularly activated MMP-2 cleaves SMCs calponin-1, a differentiation marker, shifting the cell phenotype to a de-differentiated state. 41 Extracellularly activated MMPs cleave collagen and basement membranes, releasing resident VSMCs from a non-permissive quiescent status to a permissive synthetic state. 42 Additionally, MMP-mediated VSMC synthetic phenotypes in vivo also contributes to arterial remodelling. 43,44 In this study, MMP-2 and MMP-9 protein levels were found to be increased in carotid arteries in diabetic rats compared to controls, but decreased in the FoxO1 inhibitor group. Thus, the current study demonstrates the necessity of FoxO1 activation for MMP-2 and MMP-9 dependent vascular remodelling. The fact that MMPs are a family of zinc-dependent endopeptidases highly activated by inflammatory signalling prompted us to investigate the role of inflammation on the vascular remodelling induced by hyperglycaemia.
Inflammation has long been considered as a major risk factor in diabetes, which is associated with development and progression of diabetic complications. Hyperglycaemia-induced oxidative stress promotes inflammation through increased endothelial cell damage, microvascular permeability and increased release of pro-inflammatory cytokines, including TNF-α, interlukin-1β (IL-1β) and interlukin-6 (IL-6). All these changes ultimately lead to decreased insulin sensitivity and diabetic complications. Hyperglycaemiainduced FoxO1 plays an important role in inducing pro-inflammatory cytokines. It is shown that FoxO1 directly binds to the IL-1β promoter, increasing its expression in macrophages. 45 Recent studies show that FoxO1 promotes inflammation during diabetes by enhancing TLR4-mediated signalling. 46 Our results showed that inflammation was induced in carotid arteries in type 1 diabetic rats, contributing to vascular remodelling that was prevented by Moreover, NLRP3 has been found in macrophage and foam cell cytoplasm, and is associated with cholesterol crystal clefts inside and outside the cells. 49 Furthermore, NLRP3 gene polymorphisms are strongly correlated with increased risk of macrovascular complications, particularly myocardial infarction, in diabetic patients. 34 Clinical verification on the role of NLRP3 and NLRP3 activation products in the development of macrovascular complications may serve as a basis to incorporate this inflammasome family as a useful clinical predictor for cardiovascular events in diabetic patients.
In addition, previously study found that increased FoxO1 could induced NLRP3 inflammasome expression. 50 This was confirmed by our data showing increases in NLRP3 inflammasome components, NLRP3 and ASC, in diabetic rat carotid arteries, and these increases were offset by AS treatment. These data strengthen the evidence for FoxO1 as a mediator of inflammasome-dependent inflammation in diabetes.
The PDK1/FoxO1 pathway is important in regulating glucose and energy homeostasis, but little is known about this pathway in carotid tissue under hyperglycaemic condition. It has reported that PDK1 contribute to increased serotonin-induced contraction in the carotid arteries of type 2 diabetic rats and the underlying mechanism is still unclear. 51,52 The insulin signalling has been reported to activate PDK1 in carotid artery. 52 In this way, plasma insulin level is absolutely deficient in our STZ-induced type 1 diabetic rats (data not shown), which is consistent with the decreased expression or activity of PDK1 in carotid artery of type 1 diabetic rats in our current study. We further demonstrated that PDK1 was involved in the upstream signalling response to hyperglycaemia. The disrupted PDK1/ FoxO1 pathway therefore promoted FoxO1 nuclear translocation for subsequent transcriptional regulation. These data may represent a novel mechanism to explain the role of PDK1 in carotid arteries remodelling of type 1 diabetes.
Collectively, we demonstrated that FoxO1 as a novel trigger for the progression of type 1 diabetes-induced vascular remodelling via its initiation of NLPR3 inflammasome-dependent inflammation.
The interaction between PDK1/FoxO1/NLPR3 inflammasome may have important therapeutic implication for diabetic cardiovascular diseases.

CO N FLI C T O F I NTE R E S T
The authors declared that they have no conflicts of interest to this work.