Diabetes is one of the most prevalent disorders and recent estimations suggest that there is a worldwide population of 347 million diabetic individuals [1]. According to WHO, diabetes will be the 7th leading cause of death in 2030 [2]. As the investigation of diabetes intensifies, it has become more evident that there exists a strong correlation between diabetes, obesity, high fat diet (HFD), sedentarism and cardiac abnormalities. With regards to diabetes-associated mortality and morbidity, the major culprit is alterations in cardiac structure and function. In this context, coronary arterial disease presents a higher incidence among heart alterations due to the diabetic condition that leads to heart failure. Diabetic cardiomyopathy is another cardiac disturbance which can be found independent of any trace of hypertension or ischemia [3], and represents an increased risk of heart failure in type 2 diabetes (DM2) patients. This disease was first described in four diabetic patients that died from heart failure, independent of an ischemic event or hypertension [4].

Excess fat consumption increases the risk of obesity and DM2, which can be followed by heart disease. The greater supply of fatty acid available increases its metabolism and oxidation, simultaneously reducing glucose uptake and oxidation, which represents more oxygen consumption by the heart without improving cardiac efficiency due to mitochondrial dysfunction [5‐7]. DM2 and obesity are linked by different factors, such as production of pro-inflammatory cytokines and insulin resistance (IR) [8]. The inflammatory component of DM2 had also been demonstrated in experimental diabetes [9]. Several studies have suggested that the deterioration of cardiac function may be influenced by alterations in cytokine production, such as TGF-β, TNFα, IL-1β, IL-6 and IL-18 [10, 11], which participate in the formation of tissue fibrosis and inflammation. The hyperglycemia also worsens the cardiac function impairment due to an inflammatory process in the vascular endothelium, leading to micro- and macro-vascular complications [12‐14].

Beneficial lifestyle changes, including a healthy diet and regular physical activity, contribute to the prevention of cardiovascular complications observed in obesity and DM2, however these positive life choices have yet to demonstrate functional cardiac recovery in the chronic diabetic state [15]. Recently, investigations have centered on the therapeutic use of granulocyte colony-stimulating factor (G-CSF), a cytokine known to promote the mobilization of bone marrow-derived hematopoietic stem cells into the circulation [16, 17]. G-CSF has shown beneficial effects on myocardial regeneration, such as the acceleration of wound healing, prevention of myocardial apoptosis and reduced myocardial fibrosis [18‐21]. In addition, our laboratory has demonstrated in a mouse model of Chagas disease cardiomyopathy that treatment with G-CSF results in reduced fibrosis and inflammation in the heart, while improving electrocardiography (EKG) alterations and exercise capacity [22].

Based on our previous work, we hypothesized that G-CSF treatment would have beneficial effects in impaired cardiac function associated with obesity and DM2. In this study we investigated the therapeutic effect of G-CSF in a model of obese-diabetic C57Bl/6 mice generated by feeding with a HFD, which combines genetic susceptibility with environmental factors.

In the present study, we demonstrated that G-CSF administration contributed, at least partially, to the improvement of cardiac function in obese diabetic mice presenting concentric hypertrophy, characteristic of diabetic cardiomyopathy. This was reflected in the recovery of physical exercise capacity and the hypertrophy reversal measured by echocardiography. Additionally, we observed that G-CSF administration resulted in a reversion of fibrosis in the heart tissue, caused by HFD consumption.

The experimental strategy HFD removal was based on the American Diabetes Association recommendations that, at the onset of diabetes diagnosis, lifestyle changes (diet and exercise) with or without medication are needed to control blood glucose. Studies have demonstrated that the first step in treating DM2 is to limit the intake of saturated fatty acids, trans fatty acid and cholesterol, in order to reduce the cardiovascular risks [27‐29]. Aligned with this recommendation, this study submitted mice to a HFD that resulted in an obese state, followed by returning to a standard diet accompanied by administration of G-CSF or saline.

DM2 and obesity are related and severely effect a large worldwide population [30‐32]. Both conditions are associated with the development of hypertension, coronary disease, cardiomyopathy and micro- or macro-vascular injuries [33]. Diabetic cardiomyopathy was originally reported in diabetic patients, following heart failure-induced death while lacking evidence of hypertension, myocardial ischaemia or congenital or valvular heart disease [4]. Here, we used a model that presented pathophysiological characteristics of diabetic cardiomyopathy, using C57Bl/6 male mice fed with a HFD. This led to the induction of obesity-dependent diabetes, as well as myocardial disturbances, which resemble those found in humans.

Here we confirmed that the C57Bl/6 mouse strain is highly susceptible to develop DM2 following HFD exposure, also resulting in obesity, hyperglycemia and glucose intolerance, as previously reported [34‐36]. After returning to a standard diet, and independent of G-CSF administration, glycemia levels were normalized to the levels of mice only fed with a standard diet. Our data is supported by previous studies demonstrating healthier dietary habits can result in positive outcomes for DM2 patients [37, 38]. Although removal from HFD resulted in a significant reduction in body weight, G-CSF administration caused an accelerated weight loss when compared to saline administration. Finally, G-CSF administration also resulted in an improved exercise capacity when compared to saline-treated obese mice.

Hyperinsulinemia is a component of the pathogenesis in obesity and diabetes. In the current study, saline administered obese-diabetic mice presented a significant level of hyperinsulinemia compared to non-obese-diabetic mice, even after returning to a standard diet. G-CSF administration significantly reduced circulating concentrations of insulin in obese-diabetic mice. To the best of our knowledge, this is the first time that G-CSF has been implicated in regulating insulin secretion. This reduction in insulin concentration induced by G-CSF administration may contribute to the accelerated weight loss observed in the obese-diabetic mice [39].

Anti-obesity effects of G-CSF have been demonstrated, resulting in the reduction of inflammatory cytokines that led to a loss in body weight in a model of obese-diabetic rats [40]. The anti-inflammatory effect of G-CSF is well characterized and has been observed in different disease models, including chronic Chagas disease cardiomyopathy, which has been shown in previous studies from our group [26]. Based on the effect of G-CSF on insulin regulation, the reduction of insulin and, potentially, a decrease in pro-inflammatory cytokines induced by G-CSF [41], may lead to a reduction in body weight, however further studies are needed to clarify this possibility.

The direct actions of G-CSF in modulating negative cardiac outcomes have been intensely investigated, which include reducing cardiac fibrosis. In the present study, we observed that G-CSF administration significantly reduced fibrosis in the heart tissue. Studies have suggested different mechanisms by which G-CSF reduces fibrosis, including modulation of synthesis and degradation of components in the extracellular matrix [42] as well as G-CSF-mediated signaling regulation of collagenase [43]. Our group has previously demonstrated the anti-fibrotic effects of G-CSF in the heart in a model of chronic Chagas disease cardiomyopathy, which results in progressive collagen deposition and fibrosis [26]. Therefore our current results in the obese-diabetic mouse model reinforce the anti-fibrotic effects of G-CSF.

In this study, the structural and hemodynamic parameters evaluated by ECHO suggested the development of concentric hypertrophy. The fractional shortening and ejection fraction were elevated in HFD mice compared to mice fed a standard diet, which is supported by clinical evidence of obesity-induced LV hypertrophy [44]. Moreover, the LV diameter was reduced in HFD mice, which was in accordance with the lowest end diastolic volume and systolic volume observed in this group, suggesting a reduction in LV compliance. The elevated P wave and QRS amplitudes recorded in EKG reflects the loss of LV compliancy and hypertrophy. G-CSF administration resulted in the reversal of the hypertophic state of the obese mouse heart, normalizing LV mass, posterior wall thickness (during both systole and diastole) and intraventricular septum thickness (during both systole and diastole) to levels of non-obese standard diet fed mice. One of the factors that may contribute to the recovery of compliance following G-CSF administration is the reduction of the fibrosis. Previous studies have demonstrated that G-CSF administration has protective effects against cardiac remodeling and acts to reduce cardiac hypertrophy [45, 46]. Thus, we suggest that G-CSF acts as a mediator against cardiac hypertrophy, presenting a promising therapeutic option for individuals with diabetic cardiomyopathy.

HFD increases apoptotic susceptibility that can lead to elevated cardiac insult vulnerabilities [47]. Increased apoptosis leads to hypertrophy [48] and fibrosis deposition in the myocardium [49] leading to cardiac dysfunction. G-CSF has anti-apoptotic properties on cardiomyocytes [50], and demonstrates anti-fibrotic activity [26]. Therefore, G-CSF can act as a protective mediator, leading to cardiac preservation and, potentially, reversal of heart damage.

In summary, our results reinforce that G-CSF has a cardioprotective role, as well as acts as a modulator in diabetes and obesity. Evaluation of G-CSF during HFD administration needs to be performed in order to assess its effects during HFD consumption. Further studies are required in order to understand the molecular mechanisms involved in the protective actions of G-CSF.