Exosomes are a class of cell-derived extracellular vesicles of endosomal origin and are typically 30-150 nm in diameter.

Nanovesicles for therapeutics and diagnostics

Exosomes are the smallest type of extracellular vesicle. Enveloped by a lipid bilayer, exosomes are released into the extracellular environment containing a complex cargo of contents derived from the original cell, including proteins, lipids, mRNA, miRNA, and DNA.

Exosomes are defined by how they are formed – through the fusion and exocytosis of multivesicular bodies into the extracellular space.

Multivesicular bodies are unique organelles in the endocytic pathway that function as intermediates between early and late endosomes. The main function of multivesicular bodies is to separate components that will be recycled elsewhere from those that will be degraded by lysosomes.

The vesicles that accumulate within multivesicular bodies are categorized as intraluminal vesicles while inside the cytoplasm – and exosomes when released from the cell.

Confusingly, there is inconsistency in the literature; while some sources differentiate multivesicular bodies from late endosomes, others use the two interchangeably.

Why are exosomes of interest and what roles do they have?

Exosomes are of general interest for their role in cell biology, and for their potential therapeutic and diagnostic applications. It was originally thought that exosomes were simply cellular waste products, however, their function is now known to extend beyond waste removal.

Exosomes represent a novel mode of cell communication and contribute to a spectrum of biological processes in health and disease.

One of the main mechanisms by which exosomes are thought to exert their effects is via the transfer of exosome-associated RNA to recipient cells, where they influence protein machinery.

There is growing evidence to support this, such as the identification of intact and functional exosomal RNA in recipient cells and certain RNA-binding proteins have been identified as likely players in the transfer of RNA to target cells.

MicroRNAs and long noncoding RNAs are shuttled by exosomes and alter gene expression while proteins (e.g. heat shock proteins, cytoskeletal proteins, adhesion molecules, membrane transporter, and fusion proteins) can directly affect target cells.

Exosomes have been described as messengers of both health and disease. While they are essential for normal physiological conditions, they also act to potentiate cellular stress and damage under disease states.

How are exosomes generated?

Multivesicular bodies are a specialized subset of endosomes that contain membrane-bound intraluminal vesicles. Intraluminal vesicles are essentially the precursors of exosomes and form by budding into the lumen of the multivesicular body.

Most intraluminal vesicles fuse with lysosomes for subsequent degradation, while others are released into the extracellular space. The intraluminal vesicles that are secreted into the extracellular space become exosomes. This release occurs when the multivesicular body fuses with the plasma membrane.

The formation and degradation of exosomes

This is an active area of research and it is not yet known how exosome release is regulated. However, recent advances in imaging protocols may allow exosome release events to be visualized at high spatiotemporal resolution.

What role do they play in disease?

Exosomes have been implicated in a diverse range of conditions including neurodegenerative diseases, cancer, liver disease, and heart failure. Like other microvesicles, the function of exosomes likely depends on the cargo they carry, which is dependent on the cell type in which they were produced. Researchers have studied exosomes in disease through a range of approaches, including:

  • isolating exosomes from cultured cells and observing their effect in different cell culture studies;
  • comparing exosomes in various healthy and diseased biofluids;
  • blocking exosome secretion and observing changes.

In cancer, exosomes have multiple roles in metastatic spread, drug resistance, and angiogenesis.

Through general cell crosstalk, exosomal miRNA and lncRNA affect the progression of lung diseases including chronic obstructive pulmonary disease (COPD), asthma, tuberculosis, and interstitial lung diseases.

Stressors such as oxidant exposure can influence the secretion and cargo of exosomes, which in turn affect inflammatory reactions. Altered exosomal profiles in diseased states also imply a role for exosomes in many other conditions such as in neurodegenerative diseases and mental disorders.

Cells exposed to bacteria release exosomes that act as decoys to toxins, suggesting a protective effect during infection. In neuronal circuit development, and in many other systems, exosomal signaling is likely to be a sum of overlapping and sometimes opposing signaling networks.

How can exosomes be used in diagnostics?

Exosomes can function as potential biomarkers, as their contents are molecular signatures of their originating cells. Due to the lipid bilayer, exosomal contents are relatively stable and protected against external proteases and other enzymes, making them attractive diagnostic tools.

There are increasing reports that profiles of exosomal miRNA and lncRNA differ in patients with certain pathologies, compared with those of healthy people. Consequently, exosome-based diagnostic tests are being pursued for the early detection of cancer, diabetes, and other diseases.

Many exosomal proteins, nucleic acids, and lipids are being explored as potential clinically relevant biomarkers. Phosphorylation proteins are promising biomarkers that can be separated from exosomal samples even after five years in the freezer, while exosomal microRNA also appears to be highly stable.

Exosomes are also highly accessible as they are present in a wide array of biofluids (including blood, urine, saliva, tears, ascites, semen, colostrum, breast milk, amniotic fluid, and cerebrospinal fluid), creating many opportunities for liquid biopsies.

Therapeutic applications of exosomes

Exosomes are being pursued for use in an array of potential therapeutic applications. While externally modified vesicles suffer from toxicity and rapid clearance, membranes of naturally occurring vesicles are better tolerated, offering low immunogenicity and high resilience in extracellular fluid.

These “naturally-equipped” nanovesicles could be therapeutically targeted or engineered as drug delivery systems. Exosomes bear surface molecules that allow them to be targeted to recipient cells, where they deliver their payload. This could be used to target them to diseased tissues or organs.

Exosomes may cross the blood-brain barrier, at least under certain conditions, and could be used to deliver an array of therapies including small molecules, RNA therapies, proteins, viral gene therapy, and CRISPR gene-editing.

Different approaches to creating drug-loaded exosomes include:

  • incorporating a drug into exosomes that have been purified from donor cells;
  • loading cells with a drug that is then contained within exosomes;
  • transfecting cells with DNA encoding therapeutically active compounds that are then contained within exosomes.

Exosomes hold huge potential as a way to complement chimeric antigen receptor T (CAR-T) cells in attacking cancer cells. CAR exosomes, which are released from CAR-T cells, carry CAR on their surface and express a high level of cytotoxic molecules and inhibit tumor growth.

Cancer cell-derived exosomes carrying associated antigens have also been shown to recruit an antitumor immune response.

Methods of isolation and detection of exosomes

The purification of exosomes is a key challenge in the development of translational tools. Exosomes must be differentiated from other distinct populations of extracellular vesicles, such as microvesicles (which shed from the plasma membrane, also referred to as ectosomes or shedding vesicles) and apoptotic bodies.

For additional concerns about exosome therapy and diagnostics, be sure to contact our team of experts.