德克萨斯大学:健康人短暂的血浆游离脂肪酸增高,也会增加心血管风险

Elevated plasma free fatty acids increase cardiovascular risk by inducing plasma biomarkers of endothelial activation, myeloperoxidase and PAI-1 in healthy subjects

在健康的受试者中,血浆游离脂肪酸(FFA)的升高会通过诱导血浆内皮活化、髓过氧化物酶(MPO)和PAI-1的生物标志物而增加心血管风险
 
Manoj Mathew, Eric Tay和Kenneth CusiEmail作者
美国德克萨斯大学健康科学中心糖尿病部,圣安东尼奥


摘要


背景
肥胖和T2DM中的CVD与内皮激活、血浆血管炎症标志物升高和血栓形成前状态有关。我们检查了游离脂肪酸(FFA)对这些异常的作用,在一组健康的受试者中,血浆FFA在48小时内生理上增加到肥胖和糖尿病者的水平。
 
方法
 
40名非糖尿病受试者(年龄= 38±3年,体重指数= 28±1 kg / m2,空腹血糖= 95±1 mg / dl,糖化血红蛋白= 5.3±0.1%)都入院两次,48小时内接受注入生理盐水或低剂量脂质。血浆用于细胞内(ICAM-1)和血管内(VCAM-1)粘附分子-1、e-选择素(sE-S)、髓过氧化物酶(MPO)和总纤溶酶原抑制剂-1 (tPAI-1)。用高血糖钳(M/I)测量胰岛素敏感性。
 
结果
 
脂质输注增加了肥胖和T2DM患者的血浆FFA水平,降低了27%的胰岛素敏感性(p = 0.01)。升高血浆FFA增加等血浆标记物内皮激活ICAM-1(138±10和186±25 ng / ml),VCAM-1(1066±67和1204±65 ng / ml)和sE-S(20±1与24±1 ng / ml)13 - 35%和≥2倍血浆髓过氧化物酶水平(7.5±0.9至15 25±ng / ml),未来心血管疾病的炎症标志物,和tPAI-1(9.7±0.6,22.5±1.5 ng / ml),凝血状态的指标(p≤0.01)。FFA诱导的增加与肥胖程度无关,在瘦、超重和肥胖的受试者中也有相似的程度。
 
结论
 
在肥胖和T2DM的生理范围内,血浆中游离脂肪酸的增加会引起健康受试者内皮激活、血管炎症和血栓形成的标志物。这表明,即使是短暂的(48小时)和血浆游离脂肪酸的适度增加也可能引发早期血管异常,从而促进动脉粥样硬化和心血管疾病。
 
关键字
游离脂肪酸
脂质灌注
内皮细胞激活
血浆游离脂肪酸
凝血状态


背景
内皮细胞(endocells, ECs)在血液和组织间隙之间代谢基质和细胞的运输中起着关键作用,包括一个复杂的信号系统,它调节血管床的先天和免疫反应[1,2]。白细胞经内皮迁移受细胞间粘附分子如细胞间粘附分子-1 (ICAM-1)、血管粘附分子-1 (VCAM-1)和e-选择素等调节。表达增加ECs被激活的炎症刺激如木糖醇、Il-1b或TNF-α,CRP、氧化低密度脂蛋白或血流动力学部队与血流量(3、4)。EC激活涉及NF-Kβ和其他细胞内炎症通路和扮演着一个关键角色,炎症反应在动脉粥样硬化的早期发展(3、4、5、6、7)。肥胖、代谢综合征和T2DM中的动脉粥样硬化是由内皮细胞的损伤/活化引起的[2,4,8]。血浆中细胞粘附分子的测量被认为是内皮功能障碍和血管疾病的标志[9,10,11,12,13,14,15,16]。内皮激活具有促凝作用的后果,可以通过测量组织纤溶酶原激活物及其内源性抑制剂-1 (tpai1或pai1)[17]平衡的变化来衡量。纤溶酶原激活物抑制剂1是组织型纤溶酶原激活物和尿激酶样纤溶酶原激活物的主要生理抑制剂,同时抑制纤溶和蛋白水解[17,18]。胰岛素抵抗状态,如肥胖和T2DM,是已知的以PAI-1水平升高为特征的前血栓状态。在胰岛素抵抗动脉粥样硬化研究中,胰岛素抵抗者的血浆c反应蛋白和PAI-1水平在后来发展为糖尿病的人群中得到了增强,而PAI-1水平预测糖尿病独立于其他已知的危险因素[20]。然而,血浆游离脂肪酸在人类血栓形成中的作用尚不明确,也没有强有力的直接证据。
 
髓过氧化物酶(MPO)是从活化的中性粒细胞、单核细胞和一些组织巨噬细胞中的颗粒中提取出来的一种酶,它通过生成氯化、硝化和其他氧化物质[21]催化许多活性氧化剂(ROS)的形成。作为先天免疫反应的一部分,这些产物可能会引发脂质过氧化并促进靶蛋白的翻译后修饰。MPO及其活性氧(ROS)在人动脉粥样硬化斑块中富集[22,23,24,25,26],在急性心肌梗死后梗死范围内增加[24,27]。血浆MPO水平的升高独立预测了内皮功能障碍和冠心病(CAD)[21],即使在调整了传统的危险因素或hsCRP之后也是如此。在出现急性冠脉事件的受试者中,血清MPO水平是不良心脏结局的强有力预测因子[28,29,30]。循环MPO浓度也可以预测未来健康个体[31]中冠心病的发生。最后,特定MPO多态性引起的血浆MPO继发水平降低似乎对人类心脏有保护作用[28,32,33,34,35]。综上所述,现有的证据强调了MPO对心血管疾病的重要性,尽管调节其在人类中的活动的因素仍然知之甚少。
 
关于FFA在动脉粥样硬化中的潜在作用有越来越多的认识[36,37],尽管这一领域相对被忽视。已经指出,FFA可能会增加生产的多种细胞因子通过与代ROS和激活单核细胞炎性NF-κB通路在人类内皮细胞[8]。血浆FFA(即通过脂质输注引起内皮功能障碍,可能改变健康受试者的血浆欺诈浓度[38,39],但临床相关性尚不清楚,因为这些研究增加了血浆FFA,远远超出生理范围。
 
随着肥胖和糖尿病的广泛流行,我们进行了一项概念验证研究,以了解血浆FFA升高与内皮激活、血管炎症、MPO表达和促血栓形成状态的关系。FFA在动脉粥样硬化早期阶段的作用对于预防和治疗肥胖症和T2DM的心血管疾病具有深远的意义。
结论
我们已经证明,持续低剂量的脂质输注导致血浆FFA浓度适度增加,足以诱导内皮细胞活化,增加血浆髓过氧化物酶水平,并促进非糖尿病健康受试者的血栓形成状态。综上所述,这些结果为人类提供了直接证据,证明轻度的短期脂质过剩足以引发可能导致动脉粥样硬化和心血管疾病的早期血管异常。

 

Elevated plasma free fatty acids increase cardiovascular risk by inducing plasma biomarkers of endothelial activation, myeloperoxidase and PAI-1 in healthy subjects

 

Manoj Mathew, Eric Tay and Kenneth CusiEmail author

  • Diabetes Division, Department of Medicine, The University of Texas Health Science Center, San Antonio, Texas 78229, USA

 

Cardiovascular Diabetology20109:9

 

Abstract

Background

 

CVD in obesity and T2DM are associated with endothelial activation, elevated plasma vascular inflammation markers and a prothrombotic state. We examined the contribution of FFA to these abnormalities following a 48-hour physiological increase in plasma FFA to levels of obesity and diabetes in a group of healthy subjects.

 

Methods

 

40 non-diabetic subjects (age = 38 ± 3 yr, BMI = 28 ± 1 kg/m2, FPG = 95 ± 1 mg/dl, HbA1c = 5.3 ± 0.1%) were admitted twice and received a 48-hour infusion of normal saline or low-dose lipid. Plasma was drawn for intracellular (ICAM-1) and vascular (VCAM-1) adhesion molecules-1, E-selectin (sE-S), myeloperoxidase (MPO) and total plasminogen inhibitor-1 (tPAI-1). Insulin sensitivity was measured by a hyperglycemic clamp (M/I).

 

Results

 

Lipid infusion increased plasma FFA to levels observed in obesity and T2DM and reduced insulin sensitivity by 27% (p = 0.01). Elevated plasma FFA increased plasma markers of endothelial activation ICAM-1 (138 ± 10 vs. 186 ± 25 ng/ml), VCAM-1 (1066 ± 67 vs. 1204 ± 65 ng/ml) and sE-S (20 ± 1 vs. 24 ± 1 ng/ml) between 13-35% and by ≥ 2-fold plasma levels of myeloperoxidase (7.5 ± 0.9 to 15 ± 25 ng/ml), an inflammatory marker of future CVD, and tPAI-1 (9.7 ± 0.6 to 22.5 ± 1.5 ng/ml), an indicator of a prothrombotic state (all p ≤ 0.01). The FFA-induced increase was independent from the degree of adiposity, being of similar magnitude in lean, overweight and obese subjects.

 

Conclusions

 

An increase in plasma FFA within the physiological range observed in obesity and T2DM induces markers of endothelial activation, vascular inflammation and thrombosis in healthy subjects. This suggests that even transient (48-hour) and modest increases in plasma FFA may initiate early vascular abnormalities that promote atherosclerosis and CVD.

 

Keywords

Free Fatty Acid

Lipid Infusion

Endothelial Activation

Plasma Free Fatty Acid

Prothrombotic State

Background

Endothelial cells (ECs) play a key role in the transport of metabolic substrates and cells between the blood and the interstitial space, including a complex signalling system that regulates innate and immune responses of the vascular bed [1, 2]. Transendothelial migration of leukocytes is regulated by soluble cell adhesion molecules such as intercellular adhesion molecule-1 (ICAM-1), vascular adhesion molecule-1 (VCAM-1) and E-selectin. Their expression is increased as ECs are activated by proinflammatory stimuli such as bacterial endotoxins, Il-1b or TNF-α, CRP, oxidized LDL or hemodynamic forces related to blood flow [3, 4]. EC activation involves the NF-Kβ and other intracellular inflammatory pathways and play a key role in the early development of the inflammatory response in atherosclerosis [3, 4, 5, 6, 7]. Atherosclerosis in obesity, metabolic syndrome and T2DM is initiated by damage/activation of the endothelium [2, 4, 8]. Plasma measurement of cell adhesion molecules are accepted markers of endothelial dysfunction and vascular disease [9, 10, 11, 12, 13, 14, 15, 16]. Endothelial activation has procoagulant consequences that can be measured as a change in the balance of tissue plasminogen activator and its endogenous inhibitor, tissue plasminogen activation inhibitor-1 (tPAI-1 or PAI-1) [17]. Plasminogen activator inhibitor 1 is the primary physiological inhibitor of tissue-type plasminogen activator and urokinase-like plasminogen activator and inhibits both fibrinolysis and proteolysis [17, 18]. Insulin resistant states such as obesity and T2DM are known prothrombotic states characterized by elevated PAI-1 levels [19]. In the Insulin Resistance Atherosclerosis Study, plasma C-reactive protein and PAI-1 levels were enhanced in insulin-resistant subjects who later developed diabetes, and PAI-1 levels predicted diabetes independently of other known risk factors [20]. However, the role of plasma FFA in thrombogenesis in humans is poorly established and no strong direct evidence is available.

 

Myeloperoxidase (MPO) is an enzyme derived from granules in activated neutrophils, monocytes and some tissue macropahges that catalyzes the formation of a number of reactive oxidant species (ROS) by the generation of chlorinating, nitrating, and other oxidizing species [21]. These products may initiate lipid peroxidation and promote post-translational modification of target proteins as part of the innate immune response. MPO and its reactive oxygen species (ROS) are enriched in human atheroma plaques [22, 23, 24, 25, 26] and increase within the area of infarct after an acute myocardial infarction [24, 27]. Increased plasma levels of MPO independently predict endothelial dysfunction and coronary artery disease (CAD) [21], even after adjusting for traditional risk factors or hsCRP. In subjects presenting with acute coronary events, serum MPO levels is a strong predictor of adverse cardiac outcomes [28, 29, 30]. Circulating MPO concentrations also predict future CAD in otherwise healthy individuals [31]. Finally, decreased plasma levels of MPO secondary to specific MPO polymorphisms appear to be cardioprotective in humans [28, 32, 33, 34, 35]. Taken together, the available evidence highlights the importance of MPO to cardiovascular disease although the factors modulating its activity in humans remain poorly understood.

 

There is an increasing awareness about the potential role for FFA in atherosclerosis [36, 37], although this area has been relatively neglected in the field. It has been noted that FFA may increase the production of multiple cytokines by mononuclear cells with generation of ROS and activation of pro-inflammatory NF-κB pathways in human endothelial cells [8]. Pharmacologic increases of plasma FFA (i.e., 5-fold elevation) by lipid infusion cause endothelial dysfunction and may alter plasma sCAM concentrations in healthy subjects [38, 39], but the clinical relevance is not clear because these studies increased plasma FFA well beyond the physiological range.

 

With the widespread epidemic of obesity and diabetes, we carried out a proof-of-concept study to understand the role of elevated plasma FFA in relation to endothelial activation, vascular inflammation, MPO expression and the promotion of a prothrombotic state. The role of FFA on early steps of atherogenesis could have far reaching implications regarding the prevention and treatment of cardiovascular in obesity and T2DM.

 

Research Design & Methods

Subjects

 

Forty subjects participated in the study. Their clinical and laboratory characteristics are shown in Table 1. All subjects had a normal 75-gram oral glucose tolerance test (OGTT) performed at our clinical research unit. Physical activity was avoided in the days prior to testing or between study admissions. Body weight and degree of physical activity were stable in all subjects for at least 3 months prior to enrolment. No subjects had any evidence of cardiac, hepatic, renal or any other organ system disease, as determined by a complete medical history, physical examination, electrocardiogram, routine blood work, and urinalysis. No participants were receiving any medications known to affect carbohydrate metabolism. Tobacco users were excluded from participation because smoking alters insulin sensitivity and endothelial function. Each subject gave written informed consent before participation. The study protocol was approved by the Institutional Review Board of the University of Texas Health Science Center at San Antonio, Texas.

Table 1

Patient Characteristics

N (male/female)

40 (19/21)

Age (years)

38 ± 3

BMI (kg/m2)

28 ± 1

Fasting plasma glucose (mg/dl)

95 ± 1

2-hr plasma glucose (mg/dl)

120 ± 3

HbA1c (%)

5.3 ± 0.1

Fasting plasma insulin (μU/ml)

9 ± 1

2-hr insulin (μU/ml)

47 ± 7

Fasting plasma FFA (μU/ml)

544 ± 31

2-hr plasma FFA (μU/ml)

122 ± 7

Triglycerides (mg/dl)

104 ± 8

HDL-cholesterol (mg/dl)

44 ± 2

Systolic blood pressure (mmHg)

124 ± 3

Diastolic blood pressure (mmHg)

72 ± 2

Experimental design

 

After the initial screening visit, all subjects were admitted to the research unit at 0700 h on day 1, following a 12-hour fast. Subjects were admitted twice 2-4 weeks apart, for the infusion in random order of normal saline or lipid (Liposyn III, a 20% triglyceride emulsion largely composed of soybean oil). Lipid or saline were infused at a constant rate of 0.5 ml/min (30 ml/hour) during the entire 2-day admission through an antecubital forearm vein. The lipid infusion was set to achieve a target day-long plasma free fatty acid (FFA) concentration of ~600 μmol/l, similar to that of subjects who are obese or have T2DM. Participants received a weight-maintaining diet prepared by the research dietician, consisting of 50% carbohydrate, 30% fat, and 20% protein. Meals were given at 0800 h, 1200 h, 1800 h, and 2100 h with a caloric distribution of 30%, 30%, 30% and 10% of total daily calories in each meal, respectively. Subjects consumed identical meals during each hospital admission. Complete food intake was confirmed after each meal by a research nurse. During days 1 and 2, blood was drawn every 2 hours from 0800 h through midnight and overnight every 4 hours for the determination of plasma glucose, C-peptide, insulin and FFA concentrations. On day 3, starting at 0700 h patients underwent a 2-hour hyperglycemic clamp. Blood was drawn for the measurement of serum ICAM-1, VCAM-1, MPO, E-selectin, tPAI-1 fasting in 2 separate samples 10 minutes apart before the start of the hyperglycemic clamp. Patients were discharged after completion of the hyperglycaemic clamp test. All procedures were performed in an identical fashion in both admissions.

 

Hyperglycemic clamp

 

On day 3 and after an overnight fast, subjects underwent a hyperglycemic clamp as described previously by our group [40, 41] to assess insulin sensitivity as the metabolic clearance of glucose (M) divided by the plasma insulin concentration (I) (or M/I). In brief, a 20-gauge Teflon catheter was inserted into an antecubital vein at 0800 h for the infusion of 20% dextrose. A second vein on the dorsum of the hand is cannulated retrogradely for the collection of blood samples, and the hand placed in a thermoregulated box at 65°C to achieve arterialization of the venous blood. Both intravenous lines are kept patent with a slow infusion of normal saline. After the collection of baseline samples, plasma glucose concentration is acutely raised by 125 mg/dL above the basal level and the desired hyperglycemic level is maintained (± 5%) for the following 120 min by periodic adjustment of a 20% glucose infusion based upon the negative feedback principle.

 

Analytical determinations

 

The plasma glucose concentration was determined in duplicate by the glucose oxidase method with a Beckman Glucose Analyzer II (Beckman Instruments Inc, Fullerton, CA). Plasma insulin and C-peptide concentrations (Coat-A-Count Insulin, Diagnostic Products Corp., Los Angeles, CA) were determined by radioimmunoassay. Plasma FFA concentration was measured by standard colorimetric methods. Plasma ICAM-1, VCAM-1, MPO, E-selectin and tPAI-1 concentrations were assayed by enzyme linked immunosorbent assay (Lincoplex assay, Millipore Corp., MA).

 

Statistical analysis

 

All values presented as the mean ± standard error of the mean. Within-group differences were determined by the paired two-tailed Student's t test. Normal distribution was checked before all analyses, and nonparametric estimates were used when appropriate. Comparisons were considered statistically significant if the P value was < 0.05. Where appropriate regressions were calculated by least squares linear correlation coefficients analysis. Analysis were performed using JMP software for Macintosh (SAS institute INC, Cary, NC).

 

Results

Plasma glucose, FFA and hormone concentrations during the 48-hour saline and lipid infusion

 

The plasma glucose, FFA, C-peptide and insulin concentrations during the 48-hour saline or lipid infusions are shown in Table 2. Mean 48-hour plasma FFA concentration increased significantly during the lipid infusion from 422 ± 80 to 588 ± 111 μmol/L (p < 0.001). There was a small but significant increase in mean 48-hour plasma glucose during lipid infusion compared to saline infusion (94 ± 18 to 97 ± 18 mg/dl, p < 0.02). This was likely a consequence of FFA-induced insulin resistance as evidenced by the increase in the mean plasma insulin and C-peptide concentration during the 48-hour lipid infusion (p = 0.01 and p = 0.04, respectively; Table 2).

Table 2

Effect of Lipid Infusion on Metabolic Parameters

48-hour mean values

Saline

Lipid

Glucose (mg/dl)

94 ± 18

97 ± 18*

FFA (μmol/L)

422 ± 80

588 ± 111**

Insulin (μU/ml)

8 ± 1

12 ± 2†

C-peptide (ng/ml)

3.3 ± 0.6

3.9 ± 0.7††

*p = 0.02; **p < 0.001; †p = 0.01; ††p = 0.04

 

Effect of a 48-hour increase low-dose lipid infusion on insulin sensitivity (Figure 1)

 

Figure 1

Figure 1

Effect of a 48-hour increase low-dose lipid infusion on insulin sensitivity

Lipid infusion significantly decreased insulin sensitivity as shown in Figure 1 with a 27 ± 4% reduction as measured by the M/I index (p = 0.01). This observation made evident that a mild physiological increase in plasma FFA by a short-term (48-hours) low-dose lipid infusion is capable of profound metabolic effects in healthy humans, consistent with prior observations by our group [41, 42].

 

Effect of a 48-hour increase low-dose lipid infusion on plasma concentrations of markers of endothelial activation, MPO and tPAI-1

 

Compared to a 48-hour saline infusion, lipid infusion led to increased plasma ICAM-1 by 35 ± 5% (from 138 ± 10 vs. 186 ± 25 ng/ml), VCAM-1 by 13 ± 3% (1066 ± 67 vs. 1204 ± 65 ng/ml, both p < 0.001) and E-selectin by 17 ± 1% (20 ± 1 vs. 24 ± 1 ng/ml, p = 0.006) levels (Figure 2). The mean plasma FFA levels achieved with lipid infusion correlated closely with all plasma endothelial activation markers: ICAM (r = 0.38, p = 0.03), VCAM-1 (r = 0.48, p < 0.01) and E-selectin (r = 0.48, p < 0.01).

Figure 2

Figure 2

Effect of a 48-hour increase low-dose lipid infusion on plasma concentrations of markers of endothelial activation, MPO and tPAI-1

Plasma MPO and tPAI-1 levels were also altered by FFA elevation and to a greater extent. Compared to a saline, FFA increased doubled plasma MPO from 7.5 ± 0.9 to 15 ± 25 ng/ml (p = 0.01) and tPAI-1 by 132% from 9.7 ± 0.6 to 22.5 ± 1.5 ng/ml (p < 0.001) (Figure 3). Figure 4 summarizes the percent increase with lipid infusion of markers of endothelial activation, MPO and tPAI-1. The increase in plasma FFA achieved with lipid correlated very strongly (r = 0.69, p < 0.001) with the increase in plasma tPAI-1, suggesting a close relationship between FFA and induction of a prothrombotic state under these experimental conditions.

Figure 3

Figure 3

Compared to a saline, FFA increased doubled plasma MPO from 7.5 ± 0.9 to 15 ± 25 ng/ml (p = 0.01) and tPAI-1 by 132% from 9.7 ± 0.6 to 22.5 ± 1.5 ng/ml (p < 0.001)

Figure 4

Figure 4

This figure summarizes the percent increase with lipid infusion of markers of endothelial activation, MPO and tPAI-1

Finally, we explored if total body fat could modify or play a role in the marked increase in sCAM, MPO or tPAI-1 response to 48-hour FFA stimulation. Figure 5 describes the response in subjects divided by BMI as either lean (BMI <25 kg/m2), overweight (BMI >25 and <30 kg/m2) or obese (BMI >30 kg/m2). No significant differences were appreciated for any variable based on BMI, suggestive of a direct effect of FFA-induced endothelial activation independent of total adiposity.

Figure 5

Figure 5

Figure 5 describes the response in subjects divided by BMI as either lean (BMI <25 kg/m 2 ), overweight (BMI >25 and <30 kg/m 2 ) or obese (BMI >30 kg/m 2 )

Discussion

Few clinical studies have examined the role of FFA as a trigger for endothelial activation, inflammation and thrombosis. This has been overlooked in favour of a focus on traditional cardiovascular risk factors or detailed studies on lipoprotein metabolism. With obesity and T2DM reaching epidemic proportions, it is important to assess the role of excessive FFA supply regarding endothelial injury and inflammation because both conditions are characterized by increased rates of lipolysis and plasma FFA due to adipose tissue insulin resistance. In order to have clinical relevance, the study carefully mimicked the plasma FFA levels characteristic of obese and diabetic patients and assessed their impact by using validated plasma markers of endothelial activation, systemic inflammation and thrombosis.

 

Serum cellular adhesion molecule levels increase in association with cardiovascular risk factors and are associated with structural functional measures of atherosclerotic disease, as well as with adverse cardiovascular prognosis [9, 11, 15, 43, 44]. Serum VCAM-1, ICAM-1 and E-selectin concentrations are elevated in obesity [45, 46, 47], chronic renal failure [48], in lean and obese subjects genetically predisposed to T2DM [39, 49] and in T2DM [16, 50]. Recently, ICAM-1 and E-selectin were reported to predict future development of T2DM, even after accounting for classical risk factors such as age, BMI, family history of T2DM, hsCRP and others [51]. Taken together, these studies are an indication of the value of elevated plasma VCAM-1, ICAM-1 and E-selectin levels to assess early systemic inflammation and EC activation. Elevated plasma FFA offer a unifying mechanism as a cause not only for the development of insulin resistance, as reported in the literature (reviewed by Cusi in [52]) and observed in this study, but as a factor actively involved in the higher cardiovascular risk of obese and insulin-resistant populations. The results of this study also highlight the susceptibility of ECs to modest increases in plasma FFA, as endothelial activation was induced with just a 2-day low-dose lipid infusion. However, it must be recognized that future studies should examine the role of FFA using gold-standard techniques to assess endothelial function [11] and evaluate their long-term effect on the vascular bed. Finally, because the magnitude of the elevation of sCAM was independent of adiposity and pre-existing insulin resistance (i.e, overweight and obese vs. lean subjects; Figure. 5), this renders further support for the hypothesis of a direct effect of plasma FFA elevation to induce markers of endothelial activation and vascular inflammation. Indeed, there was a strong correlation between the plasma FFA level achieved by lipid infusion and the elevation on biomarkers of EC activation.

 

The novel finding that a mild elevation in plasma FFA may activate vascular MPO and tPAI-1 has important clinical implications. The mechanisms by which MPO may promote atherogenesis include conversion of LDL into more atherogenic oxidized particles (oxLDL), oxidative modification of apolipoprotein A-I that results in a dysfunctional HDL and reduction of EC nitric oxide availability resulting in endothelial dysfunction [21, 22, 23, 24, 26, 53, 54, 55]. These multiple mechanisms help explain the strong predictive value of plasma MPO levels for acute coronary syndromes (ACS) in humans even after adjusting for traditional cardiovascular risk factors, Framingham risk score, or hsCRP [28, 29, 30]. For instance, Zhang et al [28] in a case-control study in a tertiary care referral center, compared 158 patients with documented CAD against 175 patients without angiographically significant CAD (controls) and found that both leukocyte- and blood-MPO levels were significantly greater in patients with CAD with an odds ratio (OR) of 20.4 (95% CI, 8.9-47.2) for the highest vs. lowest quartiles of plasma MPO levels. Brennan et al [29] studied 604 patients who presented at the emergency room with ACS and reported that those with the highest MPO quartile has a 3.9-fold higher risk of having a CHD event and an even higher predictive value in the next 6 months. Similar results have been reported by Baldus et al [30]. Plasma MPO has been accepted to be a good biomarker of endothelial dysfunction [56] and predicted cardiovascular events even in 1,138 apparently healthy subjects in the EPIC-Norfolk Prospective population study [31]. MPO-triggered EC apoptosis, intracoronary erosions and thrombus formation has been proposed based on work by Sugiyama, Libby et al [24]. This link may be further strengthened by this report and may point to elevated FFA as a common pathogenic mechanism for endothelial dysfunction, inflammation and thrombogenesis.

 

Several mechanisms may explain how lipid infusion may induce endothelial activation and eventual damage. Elevation of plasma FFA by lipid infusion activates pro-inflammatory genes such as TNF-α, which is a potent stimulator of sCAMs and MPO secretion [8, 36, 37]. In vitro studies in endothelial and vascular smooth muscle cells have provided evidence that FFA increase oxidative stress and inflammation by activating the NF-κB pathway and increasing the formation of ROS by mononuclear cells, which initiate the inflammatory process involving the endothelium. Recent studies indicate that there is a clear fatty acid dose-response impairment of insulin signalling, inhibition of nitric oxide production and activation of NF-κB activity in bovine aortic endothelial cells [57] and in mononuclear cells of healthy subjects exposed to acute pharmacological increases in plasma FFA [38]. Human monocytes exposed for just 48 hours to excessive lipids have a dose-dependent increase in intercellular ROS and increased adhesion to ECs, mediated by an increase in integrin CD11b cell surface expression [58]. In healthy subjects, fatty acid-induced oxidative stress and endothelial activation with an increase in plasma TNF-α, IL-6, ICAM-1 and VCAM-1 can be induced by a single high-fat meal [59]. Endothelial dysfunction has been reported to be reversible with lifestyle changes [60], anti-inflammatory agents such as salicylates [61] or by insulin-sensitizers such as thiazolidinediones [62]. Thus, increased lipid infusion and/or plasma FFA appears to be an early trigger for multiple pathways leading to atherogenesis, independent of FFA-induction of muscle or liver insulin resistance. A limitation of the study is that there is no commercially available mixture that mimics the human fatty acid profile. We used Lypsoyn III that is 100% soybean oil, which is composed of largely unsaturated long chain fatty acids, with 55% linoleate, 22% oleate, 11% palmitate and 4% stearate while plasma is higher in more saturated fatty acids with 11% linoleate, 38% oleate, 28% palmitate and 12% stearate [63]. The overall impact of different fatty acids on the vascular bed has not been carefully characterized in humans but in skeletal muscle palmitate may induce insulin resistance to a greater extent than other fatty acids [64]. However, this has not been confirmed in others studies in which linoleate, oleate and palmitate had similar inhibitory effects on glycogen synthesis and insulin-stimulated muscle glucose uptake [65, 66]. Clearly more work is needed in this field but unfortunately plasma FFA have been poorly studied and overall neglected as relevant in the pathogenesis of atherosclerosis in humans. We believe that this proof-of concept study may be a provocative and valuable contribution to stimulate future work in this area.

 

Conclusions

We have demonstrated that a sustained low-dose lipid infusion leading to a modest increase in plasma FFA concentration is sufficient to induce endothelial activation, increase plasma myeloperoxdase levels and promote a prothrombotic state in non-diabetic healthy subjects. Taken together, these results provide direct evidence in humans that mild short-term lipid-oversupply is sufficient to initiate early vascular abnormalities that may lead to atherosclerosis and CVD.

 

Elevated plasma free fatty acids increase cardiovascular risk by inducing plasma biomarkers of endothelial activation, myeloperoxidase and PAI-1 in healthy subjects | Cardiovascular Diabetology | Full Text  https://cardiab.biomedcentral.com/articles/10.1186/1475-2840-9-9