Isolation and Characterization of Extracellular Vesicles from Cell Culture Media.

Extracellular vesicles (EVs) were once believed to serve as a means of disposing of cellular waste. However, recent discoveries have identified their crucial roles in intercellular communication between neighboring and distant cells. Almost all cell types have now been identified to produce EVs, which play a vital role in transporting cellular cargo. The functional roles of EVs, along with their implications in (patho)physiology of various diseases, are still being explored. In the last decade, the identification of EV roles in pathophysiology, pharmacology, and diagnostics has gained significant interest, albeit the development of universal methods for the isolation and characterization of EVs has been the limiting factor. A further challenge is ensuring that EVs of various size categories, which are thought to be produced via independent cellular mechanisms and often differ in their cargo and physiological purpose, can be separated and studied in isolation.This protocol provides an efficient and accessible method for isolating and characterizing EV samples from conditioned cell culture media. The combination of differential centrifugation and the use of a commercial EV-precipitation kit allows for the rapid isolation of a highly pure sample of EVs separated by size. A microfluidic resistive pulse sensing (MRPS)-based method is then used to quantify the particles, as well as to assess the size distribution of the EV sample. As a result, this protocol provides a reproducible means to isolate and characterize EVs of a variety of sizes from nearly any cultured cells.

Uncovering the link between diabetes and cardiovascular diseases: insights from adipose-derived stem cells.

Cardiovascular diseases (CVDs) are the leading causes of morbidity and mortality worldwide. The escalating global occurrence of obesity and diabetes mellitus (DM) has led to a significant upsurge in individuals afflicted with CVDs. As the prevalence of CVDs continues to rise, it is becoming increasingly important to identify the underlying cellular and molecular mechanisms that contribute to their development and progression, which will help discover novel therapeutic avenues. Adipose tissue (AT) is a connective tissue that plays a crucial role in maintaining lipid and glucose homeostasis. However, when AT is exposed to diseased conditions, such as DM, this tissue will alter its phenotype to become dysfunctional. AT is now recognized as a critical contributor to CVDs, especially in patients with DM. AT is comprised of a heterogeneous cellular population, which includes adipose-derived stem cells (ADSCs). ADSCs resident in AT are believed to regulate physiological cardiac function and have potential cardioprotective roles. However, recent studies have also shown that ADSCs from various adipose tissue depots become pro-apoptotic, pro-inflammatory, less angiogenic, and lose their ability to differentiate into various cell lineages upon exposure to diabetic conditions. This review aims to summarize the current understanding of the physiological roles of ADSCs, the impact of DM on ADSC phenotypic changes, and how these alterations may contribute to the pathogenesis of CVDs.

Attenuation of Smooth Muscle Cell Phenotypic Switching by Angiotensin 1-7 Protects against Thoracic Aortic Aneurysm.

Thoracic aortic aneurysm (TAA) involves extracellular matrix (ECM) remodeling of the aortic wall, leading to reduced biomechanical support with risk of aortic dissection and rupture. Activation of the renin-angiotensin system, and resultant angiotensin (Ang) II synthesis, is critically involved in the onset and progression of TAA. The current study investigated the effects of angiotensin (Ang) 1-7 on a murine model of TAA. Male 8-10-week-old ApoEKO mice were infused with Ang II (1.44 mg/kg/day) and treated with Ang 1-7 (0.576 mg/kg/day). ApoEKO mice developed advanced TAA in response to four weeks of Ang II infusion. Echocardiographic and histological analyses demonstrated increased aortic dilatation, excessive structural remodelling, perivascular fibrosis, and inflammation in the thoracic aorta. Ang 1-7 infusion led to attenuation of pathological phenotypic alterations associated with Ang II-induced TAA. Smooth muscle cells (SMCs) isolated from adult murine thoracic aorta exhibited excessive mitochondrial fission, oxidative stress, and hyperproliferation in response to Ang II. Treatment with Ang 1-7 resulted in inhibition of mitochondrial fragmentation, ROS generation, and hyperproliferation. Gene expression profiling used for characterization of the contractile and synthetic phenotypes of thoracic aortic SMCs revealed preservation of the contractile phenotype with Ang 1-7 treatment. In conclusion, Ang 1-7 prevented Ang II-induced vascular remodeling and the development of TAA. Enhancing Ang 1-7 actions may provide a novel therapeutic strategy to prevent or delay the progression of TAA.