Exosomes are small lipid bilayer-surrounded extracellular vesicles released from cells into the extracellular space or biological fluids (1,2). The biological fluids exosomes are found in abundance in include blood, saliva, milk, urine, semen, and bile juice (3). These vesicles are carriers of active or non-autonomous function biomolecules, such as proteins, lipids, DNA, mRNA and non-coding regulatory RNA. Exosomal markers include microRNAs like miR-21 and miR-141, plus various proteins that belong in functional groups such as tetraspanins (CD9, CD63 and CD81), heat shock proteins (Hsp70, Hsp73 and Hsp90) and membrane transporters (GTPases) (4). Exosomes, via their cargo or surface composition, are signals/mediators of systemic homeostasis and stress for specific cell-to-cell or tissue-to-tissue communication (5). They are an integral part of the later phase of the cellular stress response, i.e. the stress-induced senescence-like phenotype, as well as the senescence-associated secretory phenotype. Because of their expanding roles in the endocrine regulation of homeostasis and stress, and their involvement in human pathophysiology, exosomes are now the epicenter of a new field, termed ‘exosomics’ (3).

Extracellular vesicles (EVs) comprise a large spectrum of lipid bilayer-covered micro-particles; based on their size-range, they can be broadly classified into three distinct classes: microvesicles (MVs), exosomes and apoptotic bodies (ABs) (Fig. 1) (6). Microvesicles have a diameter ranging from 100 nm to 1 µm and are released by cell membrane budding. Exosomes have a diameter in the range of 30–120 nm. They are derived by a targeted mechanism from the cell endocytic compartment and are formed and stored within the intracellular multivesicular bodies (MVBs). Lastly, apoptotic bodies have a diameter from 50 nm to 5 µm, the latter a dimension similar to that of platelets (2–3 µm). They originate from the blebbing of dying cells (1,7,8).

Exosomes have been heavily researched in the past few years. Numerous technologies have been developed both for the isolation and characterization of these vesicles (4). Exosome isolation methods include differential centrifugation, density gradient centrifugation, size exclusion chromatography, ultrafiltration, polymer-based precipitation, immunological separation and isolation by sieving (4). The characterization technologies used for exosomes make use of biophysical methods, such as optical particle tracking that measures from 10 nm to 2 µm, molecular methods, such as Raman spectrometry that provides the chemical structure of the exosomes, and microfluidic methods that make use of immunoisolation and targeted protein analysis of circulating exosomes (4,9). Exosomes appear to have major roles in both the physiology and pathophysiology of multicellular organisms (10). When they are released under physiological conditions, exosomes are essential for proper immune system function, while under pathological circumstances, they potentiate cellular stress and damage (11). Some of the diseases associated with exosomes are the cardiometabolic and neurodegenerative disorders and cancer (11). Finally, exosomes have a significant role in viral infections (12). Virus-infected cells release exosomes that contain a variety of viral and host cellular factors that can modify recipient host cell responses (12).

The research on exosomes is expanding the traditional view on endocrine and neuroendocrine signaling mechanisms. Traditionally, endocrine mechanisms include specialized groups of cells, the glands, their molecular mediators, which are secreted in the general circulation, i.e., the hormones and the distant target tissues of the latter (13). Hormones are unique chemical messengers that can be recognized by specific receptors in their target tissues (13). As exosomes carry bioactive molecules from donor cells and express surface proteins that allow them to transfer their contents into their target cells, they themselves or their cargo may function as ‘hormones’. They can, thus, participate as such in an autocrine, i.e., local signals between the same type of cells, paracrine, i.e., local signals between different types of cells, or endocrine, i.e., distant signals between any type of cell reaching their target cells via the systemic or local circulation (14,15).

Therefore, taking into consideration the involvement of exosomes in current endocrine research, we suggest that they can provide useful information and lead to a large number of potential clinical applications. Some of these applications include their use as biomarkers and as a novel method of message or drug delivery (16).

As already mentioned, the role of exosomes as generic or specific carriers of signals and regulatory molecules through a pathway of intercellular vesicle traffic is one of the main reasons for the explosion of exosome research (23). After their release, a number of set events characterize exosome function. First, they undergo a change in their environment, as they move from the cytoplasm and cell surface to the extracellular fluid. Subsequently, exosomes interact with the plasma and endocytic membranes of target cells. Last, the ensuing fusions between exosomes and cell membranes complete the exosome signaling pathway (24).

All EVs showcase a number of common attributes. On release, some extracellular vesicles cannot remain intact, their membranes break down, and their bioactive cargo is expelled into the extracellular space. The released contents-which may include bioactive molecules, such as interleukin-1β, growth factors, and tissue factors-bind their corresponding receptors in adjacent cells and activate rapid responses (25). Most EVs, though, maintain their structure and, therefore, survive in the extracellular fluid, even for long periods of time (24). Extracellular vesicles that persist in biological fluids may promote degradation of the extracellular matrix by their transmembrane proteases, an important mechanism for the circulation of macrophages and for tissue invasion by cancer cells (25). After their release, EVs can accumulate in the extracellular spaces close to intercellular junctions, moving between and through cells so they may leave the initial fluid and move to adjacent areas or tissues (24). Later on, these extracellular vesicles do not interact generally with any type of cell, but rather showcase a preference for specifically targeted cells (25). The mechanisms that dictate this ability of EVs are still under research.

A few mechanisms have been proposed specifically for exosome-mediated cell-to-cell interaction: i) exosome membrane proteins may interact with their corresponding membrane receptors on target cells, activating intracellular signaling; ii) exosome membrane proteins may be cleaved by proteases, and the resultant soluble fragments may act as ligands that bind to cell surface receptors; or iii) exosomes may be internalized by their target cells, releasing their cargo and activating downstream events within the receiving cells (26).

In the last-mentioned mechanism, exosome cargo delivery is responsible for the transport of genetic information between cells (27). Specifically, the RNA cargo of exosomes, including both mRNAs and noncoding (nc) RNAs, seems to be of high importance. This RNA appears to be functional in target cells and can modulate gene activity and/or protein production (28). Particularly, microRNAs, a class of regulatory small endogenous non-coding RNAs, have been thoroughly researched for their possible clinical applications (29–31).

Exosome function and heterogeneity depend on the cell of origin and the conditions at the time of exosome generation in the originating tissues or cells (32). Exosomes partake in a wide number of biological processes, beyond inter-cellular communication. Some of these processes include angiogenesis, antigen presentation, inflammation, cellular homeostasis, apoptosis, and cell differentiation (32).

Dysregulation of the endocrine system has been associated with a large number of pathological conditions. Some of these include obesity, type 2 diabetes mellitus (T2DM), disorders of the reproductive system, and various forms of cancer, such as breast, testicular, and ovarian cancer (64). Exosomes have been implicated in many of these and other pathological conditions.

Obesity is a chronic disorder characterized by excessive accumulation of body fat that increases health risks (65). Exosomes have a role in obesity and its metabolic complications through their action as mediators of communication between adipose tissue, skeletal muscle, liver and immune cells (66). Studies have shown that adipose-derived exosome microRNAs are differentially expressed between lean and obese individuals (66). Furthermore, research in animal models of obesity indicates that treatment of lean mice with exosomes containing obesity-associated microRNA mimics, induces central obesity and hepatic steatosis (67). A suggested mechanism via which obesity leads to health complications is through the induction of inflammation in major organs, including adipose tissue and tissues of the cardiovascular system (66). Exosomes may play a role in these mechanisms, as they have both pro-inflammatory and anti-inflammatory properties (55,56).

Type 2 diabetes mellitus is a metabolic disease that has been associated with both obesity and presence of exosomes (68). This disease is characterized by hyperglycemia, insulin resistance, and insulin deficiency (69). T2DM is associated with the metabolic syndrome, a condition related to obesity and characterized by insulin resistance, dyslipidemia, hypertension and blood hypercoagulability (70). Exosomes released from obesity-related adipose tissue contain different microRNA cargo compared to those secreted by healthy adipose tissue and seem to significantly decrease insulin sensitivity and glucose uptake (71). The mechanisms via which these abnormal exosomes influence T2DM may include activation of inflammation, downregulation of glucose transporter type 4, and disruption of insulin receptor signaling (72).

Exosomes have also been implicated in a number of reproduction-related pathologies, like endometriosis and the polycystic ovary syndrome (PCOS) (73). Endometriosis is a gynecological disorder characterized by the presence of tissue that resembles the endometrium outside the uterine cavity (74). In this condition, studies implicate stromal endometrial-derived exosomes, which modulate the immune surveillance response, and allow ectopic endometrial tissue to attach to peritoneal surfaces. This ectopic endometrial tissue may continue to release exosomes that help it evade the immune system and survive (75).

Polycystic ovary syndrome is a common gynecological metabolic and reproductive disorder associated with menstrual dysfunction, androgen excess and decreased fertility (76). Exosomes derived from human follicular fluid display differences in their microRNA cargo between PCOS patients and controls (77). Bioinformatic analyses indicate that these differences may result in alterations in amino acid biosynthesis and metabolism (77).

An increase in exosome release and alterations in their composition may promote cancer progression and metastases (78). Specifically, exosomes released from tumor cells seem to have an essential role in cancer. These exosomes induce oncogenesis, reprogram stromal cells, modulate the immune system, and, as already mentioned above, promote angiogenesis (79). Particularly, tumor-derived exosomes can carry oncogenic and anti-apoptotic molecules among cells, promoting oncogenesis (79). Additionally, tumor-derived exosomes play an essential role in transforming normal stromal cells to cancer-associated fibroblasts through transforming growth factor beta (TGFβ) signaling (80). Cancer-associated fibroblasts are key regulators of the tumor microenvironment and can modulate cancer metastases, immune system function, production of growth factors, and angiogenesis (81). Last, tumor-derived exosomes can act directly on immune cells to produce immunosuppression (80).

Precision medicine's goal is to provide the appropriate treatment to the fitting patient at the right time. In precision medicine, molecular factors may be used to provide precise diagnosis and, thus, lead to a more accurate treatment (82). Exosomes can be considered such factors with some of their potential applications, including their use as biomarkers or therapeutic biomolecule carriers (83). Biomarkers are cellular, biochemical, or molecular parameters that can be objectively measured to serve as accurate indicators of a biological state (84).

The key attribute exosomes showcase that can be exploited in therapeutic applications is that their origin dictates their cargo and role in cell signaling (85,86). Levels of exosome population subgroups can reflect many aspects of cell-to-cell communication, such as the state of cellular homeostasis, the targeted pathway and tissue, and the dynamics of the extracellular environment. Furthermore, exosome cargo contains a mixture of active signals and non-autonomous genetic information protected by the lipid bilayer of the vesicle. Finally, exosomes are highly stable and, thus, can regulate the stress response at a systemic level by storing and transferring enriched amounts of regulatory information, as well as markers of stress, while retaining a cell- and state-type of specificity for low abundant proteins and RNAs (86), which is related to their cell of origin and the function(s) that they mediate.

Exosomes can be used as therapeutic agents due to their exceptional biocompatibility and bio-specificity, both as vehicles and as cargo, especially when combined with patient-derived embryonic stem cells (hESCs) (87). A prime example of ESC-derived exosomes showcasing therapeutic abilities analogous to their cell of origin is that of mesenchymal stem cell derived exosomes (88). MSC-derived exosomes can be used in tissue injury repair and can reduce the inherent health risks related to administering viable cells (88). On the other hand, exosomes can be modified to deliver drugs and vaccines. A prime example is loading exosomes with anticancer agents, an approach that has been shown to have therapeutic effects in animal models (89). Last, it should be mentioned that the diverse abilities of exosomes should be taken into consideration when they are used as therapeutic agents, as they may have adverse effects on a patient's physiological mechanisms, including those of the immune system, intermediary metabolism, and others (90).

Exosomes have a vital and largely unknown role in inter-cellular signaling. These vesicles seem to partake in a large number of biological functions, while they have also been associated with several diseases. It is, therefore, not surprising that there has been a high interest in exosome research over the recent years. Endocrinology encompasses most branches of biology and medicine and we can now add exosomes as endocrine cell-to-cell communication components. Thus, exosomal endocrinology represents yet another aspect of endocrinology, an essential field of research that may help improve understanding, prognosis, diagnosis, and treatment of many diseases.