Rationale Ischemic cardiovascular disease represents one of the largest epidemics currently facing the aging population. Current literature has illustrated the efficacy of autologous, stem cell therapies as novel strategies for treating these disorders. The CD34+ hematopoetic stem cell has shown significant promise in addressing myocardial ischemia by promoting angiogenesis that helps preserve the functionality of ischemic myocardium. Unfortunately, both viability and angiogenic quality of autologous CD34+ cells decline with advanced age and diminished cardiovascular health. Objective To offset age and health-related angiogenic declines in CD34+ cells, we explored whether the therapeutic efficacy of human CD34+ cells could be enhanced by augmenting their secretion of the known angiogenic factor, sonic hedgehog (Shh). Methods and Results When injected into the border zone of mice following acute myocardial infarction (AMI), Shh-modified CD34+ cells (CD34Shh) protected against ventricular dilation and cardiac functional declines associated with AMI. Treatment with CD34Shh also reduced infarct size and increased border zone capillary density compared to unmodified CD34 cells or cells transfected with the empty vector. CD34Shh primarily store and secrete Shh protein in exosomes and this storage process appears to be cell-type specific. In vitro analysis of exosomes derived from CD34Shh revealed that; 1) exosomes transfer Shh protein to other cell types and, 2) exosomal transfer of functional Shh elicits induction of the canonical Shh signaling pathway in recipient cells. Conclusions Exosome-mediated delivery of Shh to ischemic myocardium represents a major mechanism explaining the observed preservation of cardiac function in mice treated with CD34Shh cells.
Background Inflammation plays a critical role in adverse cardiac remodeling and heart failure. Therefore, approaches geared towards inhibiting inflammation may provide therapeutic benefits. We tested the hypothesis that genetic deletion of interleukin-10 (IL10), a potent anti-inflammatory cytokine, exacerbates pressure-overload induced adverse cardiac remodeling and hypertrophy and that IL10 therapy inhibits this pathology. Methods and Results Cardiac hypertrophy was induced in Wild-type (WT) and IL10-knockout (KO) mice by isoproterenol (ISO) infusion. ISO-induced left ventricular (LV) dysfunction and hypertrophic remodeling, including fibrosis and fetal gene expression, were further exaggerated in KO mice compared to WT. Systemic recombinant mouse IL10 administration markedly improved LV function and not only inhibited but also reversed ISO-induced cardiac remodeling. Intriguingly, very similar cardio-protective response of IL10 was found in transverse aortic constriction (TAC)-induced hypertrophy and heart failure model. In neonatal rat ventricular myocytes (NRCM) and H9c2 myoblasts, ISO activated NFκB while it inhibited STAT3 phosphorylation. Interestingly, IL10 suppressed ISO-induced NFκB activation and attenuated STAT3 inhibition. Moreover, pharmacological and genetic inhibition of STAT3 reversed the protective effects of IL10 while ectopic expression of constitutively active STAT3 mimicked the IL10 responses on the ISO effects, confirming that IL10 mediated inhibition of NFκB is STAT3 dependent. Conclusions Taken together our studies suggest IL10 treatment as a potential therapeutic approach to limit the progression of pressure overload-induced adverse cardiac remodeling.
Background Secretoneurin is a neuropeptide located in nerve fibers along blood vessels, is up-regulated by hypoxia and induces angiogenesis. We tested the hypothesis that secretoneurin gene therapy exerts beneficial effects in a rat model of myocardial infarction and evaluated the mechanism of action on coronary endothelial cells. Methods and Results In-vivo secretoneurin improved left ventricular function, inhibited remodeling and reduced scar formation. In the infarct border zone secretoneurin induced coronary angiogenesis as shown by increased density of capillaries and arteries. In-vitro secretoneurin induced capillary tubes, stimulated proliferation, inhibited apoptosis and activated Akt and ERK in coronary endothelial cells. Effects were abrogated by a VEGF-antibody and secretoneurin stimulated VEGF receptors in these cells. Secretoneurin furthermore increased binding of VEGF to endothelial cells and binding was blocked by heparinase indicating that secretoneurin stimulates binding of VEGF to heparan sulfate proteoglycan binding sites. Additionally, secretoneurin increased binding of VEGF to its co-receptor neuropilin 1. In endothelial cells secretoneurin also stimulated FGF receptor-3 and IGF-1 receptor and in coronary vascular smooth muscle cells we observed stimulation of VEGF receptor-1 and FGF receptor-3. Exposure of cardiac myocytes to hypoxia and ischemic heart after myocardial infarction revealed increased secretoneurin m-RNA and protein. Conclusions Our data show that secretoneurin acts as an endogenous stimulator of VEGF signaling in coronary endothelial cells by enhancing binding of VEGF to low affinity binding sites and neuropilin 1 and stimulates further growth factor receptors like FGF receptor-3. Our in-vivo findings indicate that secretoneurin might be a promising therapeutic tool in ischemic heart disease.
Vascular calcification (VC) is one of the major causes of cardiovascular morbidity and mortality in patients with chronic kidney disease (CKD). VC is a complex process expressing similarity to bone metabolism in onset and progression. VC in CKD is promoted by various factors not limited to hyperphosphatemia, Ca/Pi imbalance, uremic toxins, chronic inflammation, oxidative stress, and activation of multiple signaling pathways in different cell types, including vascular smooth muscle cells (VSMCs), macrophages, and endothelial cells. In the current review, we provide an in-depth analysis of the various kinds of VC, the clinical significance and available therapies, significant contributions from multiple cell types, and the associated cellular and molecular mechanisms for the VC process in the setting of CKD. Thus, we seek to highlight the key factors and cell types driving the pathology of VC in CKD in order to assist in the identification of preventative, diagnostic, and therapeutic strategies for patients burdened with this disease.
Diabetic kidney disease (DKD) is one of the most common complications of diabetes and is clinically featured by progressive albuminuria, consequent to glomerular destruction that involves podocyte senescence.Burgeoning evidence suggests that ketosis, in particular bhydroxybutyrate, exerts a beneficial effect on aging and on myriad metabolic or chronic diseases, including obesity, diabetes and chronic kidney diseases. Its effect on DKD is largely unknown. In vitro in podocytes exposed to a diabetic milieu, b-hydroxybutyrate treatment substantially mitigated cellular senescence and injury, as evidenced by reduced formation of gH2AX foci, reduced staining for senescence-associated-b-galactosidase activity, diminished expression of key mediators of senescence signaling like p16 INK4A and p21, and preserved expression of synaptopodin. This beneficial action of b-hydroxybutyrate coincided with a reinforced transcription factor Nrf2 antioxidant response. Mechanistically, b-hydroxybutyrate inhibition of glycogen synthase kinase 3b (GSK3b), a convergent point for myriad signaling pathways regulating Nrf2 activity, seems to contribute. Indeed, trigonelline, a selective inhibitor of Nrf2, or ectopic expression of constitutively active mutant GSK3b abolished, whereas selective activation of Nrf2 was sufficient for the antisenescent and podocyte protective effects of bhydroxybutyrate. Moreover, molecular modeling and docking analysis revealed that b-hydroxybutyrate is able to directly target the ATP-binding pocket of GSK3b and thereby block its kinase activity. In murine models of streptozotocin-elicited DKD, b-hydroxybutyrate therapy inhibited GSK3b and reinforced Nrf2 activation in glomerular podocytes, resulting in lessened podocyte senescence and injury and improved diabetic glomerulopathy and albuminuria. Thus, our findings may pave the way for developing a b-hydroxybutyrate-based novel approach of therapeutic ketosis for treating DKD.
Guidelines for management of normotensive patients with acute pulmonary embolism (PE) emphasize further risk stratification on the basis of right ventricular (RV) size and biomarkers of RV injury or strain; however, the prognostic importance of these factors on long-term mortality is not known. We performed a retrospective cohort study of subjects diagnosed with acute PE from 2010 to 2015 at a tertiary care academic medical center. The severity of initial PE presentation was categorized into three groups: massive, submassive, and low-risk PE. The primary endpoint of all-cause mortality was ascertained using the Centers for Disease Control National Death Index (CDC NDI). A total of 183 subjects were studied and their median follow-up was 4.1 years. The median age was 65 years. The 30-day mortality rate was 7.7% and the overall mortality rate through the end of follow-up was 40.4%. The overall mortality rates for massive, submassive, and low-risk PE were 71.4%, 44.5%, and 28.1%, respectively ( p < 0.001). Landmark analysis using a 30-day cutpoint demonstrated that subjects presenting with submassive PE compared with low-risk PE had increased mortality during both the short- and the long-term periods. The most frequent causes of death were malignancy, cardiac disease, respiratory disease, and PE. Independent predictors of all-cause mortality were cancer at baseline, age, white blood cell count, diabetes mellitus, liver disease, female sex, and initial presentation with massive PE. In conclusion, the diagnosis of acute PE was associated with substantial long-term mortality. The severity of initial PE presentation was associated with both short- and long-term mortality.
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