Cargo-carrying red blood cells alleviate autoimmune diseases in mice

Design of red blood cell capable of carrying antigenic peptides

Design of red blood cell capable of carrying antigenic peptides—pieces of protein from cells that trigger the inappropriate immune responses behind autoimmune diseases. When these pieces of protein are released from the red blood cells, they help retrain the immune system to ignore antigens that would otherwise cause an inappropriate immune response.

Image: Courtesy of PNAS

March 6, 2017

Tags: Lodish LabImmune System

CAMBRIDGE, Mass. – Using red blood cells modified to carry disease-specific antigens, scientists in the laboratories of Hidde Ploegh (former Whitehead Member, currently Boston Children’s Hospital) and Harvey Lodish (Whitehead Founding Member) have prevented and alleviated two autoimmune diseases—multiple sclerosis (MS) and type 1 diabetes—in early stage mouse models. 

“This is a very promising step in the development of therapies for autoimmune diseases,” says Lodish, who is also a professor of biology and a professor of biological engineering at MIT. “If this type of response is also true in humans, then it could make a lot of these therapies possible for these diseases and similar conditions.”

Inappropriate immune responses cause scores of autoimmune diseases—from rheumatoid arthritis to systemic lupus erythematosus to inflammatory bowel disease—in which the body destroys its own cells. The National Institutes of Health estimates that autoimmune diseases affect more than 23 million Americans. These conditions are commonly treated with immunosuppressants to keep a patient’s overactive immune response in check.  However, these drugs also indiscriminately dull the immune response to pathogens.

Using bits of proteins from the offending cells—antigenic peptides— researchers have retrained the immune system to ignore the antigens that trigger inappropriate immune responses. This method, called tolerance induction, shows promise, but the technique is fraught with problems, including delivering the antigenic peptides to their destination before they are degraded or beset by immune cells.

To sidestep many of these issues, the labs of Lodish and Ploegh have pressed red blood cells into service.

Red blood cells are particularly well-suited for the delivery of molecules throughout the body. Not only do these cells quickly access almost every tissue, they are also recycled every month in mice and four months in humans without triggering an immune response against them. In previous research, the team attached biotin (a chemical tag) and antibodies to red blood cell using a method developed by Ploegh’s lab called “sortagging”.

The current work, which is described online this week in the journal PNAS, uses cargo-laden red blood cells to intercede in autoimmune diseases. Novalia Pishesha, an graduate student in the Lodish and Ploegh labs, drew blood from a mouse, used sortagging to decorate the red blood cells with the antigens that trigger the harmful immune response, and transfused the altered red blood cells back into mouse models of type 1 diabetes and MS. The entire process can be completed in about an hour.

In mice, the transfusions reduced symptoms of disease and even a single injection prior to the onset of disease could prevent further symptoms.

Although antigenic peptides can be effective in stimulating the induction of tolerance, the mechanism responsible is not well understood at the cellular and molecular levels. “Essentially what we’re doing is hijacking the red blood cell clearance pathway, such that the foreign antigen masquerades as the red blood cells’ own, such that these antigens are being tolerated in the process,” says Pishesha, who is also the first author of the PNAS paper.

For Ploegh, the research could lead to future insights into how the immune system regulates itself and how that sometimes goes awry. As a cautionary note, he points out that red blood cells used in the experiment are not “immunologically inert”.

“The Kell protein, which we use as an anchor point for many of our modifications, is a blood group antigen, and by its very nature shows that the immune system can distinguish red blood cells from genetically disparate individuals,” says Ploegh. “This [technique used by Pishesha] may be an interesting way to explore how the immune system distinguishes self from non-self.”

 

This work was supported by Defense Advanced Research Projects Agency Contract HR0011-12-2-0015, the Schlumberger Foundation Faculty for the Future, the Howard Hughes Medical Institute, and the Siebel Scholars Foundation.

 

Written by Nicole Giese Rura

* * *

Harvey Lodish’s primary affiliation is with Whitehead Institute for Biomedical Research, where his laboratory is located and all his research is conducted. He is also a professor of biology and a professor of biological engineering at Massachusetts Institute of Technology (MIT).  Hidde Ploegh, a former Whitehead member, is a Senior Investigator in the Program in Cellular and Molecular Medicine (PCMM) at Boston Children's Hospital. Lodish and Ploegh serve as paid consultants and own equity in Rubius, a biotech company that seeks to exploit the use of modified red blood cells for therapeutic applications.

* * *

Full Citation:

“Engineered erythrocytes covalently linked to antigenic peptides can protect against autoimmune disease”

PNAS, online the week of March 6, 2107.

Novalia Pishesha (1,2,3), Angelina M. Bilate (1), Marsha C. Wibowo (1,4), Nai-jia Huang (1), Zeyang Li (1,3), Rhogerry Dhesycka (1,2), Djenet Bousbaine (1,3,4), Hojun Li (1), Heide C. Patterson (1), Stephanie K. Dougan (1), Takeshi Maruyama (1), Harvey F. Lodish (1,2,4), and Hidde L. Ploegh (1,3,4)

1. Whitehead Institute for Biomedical Research, Cambridge, MA 02142

2. Department of Biological Engineering, Massachusetts Institute of Technology, Cambridge, MA 02142

3. Program in Cellular and Molecular Medicine, Boston Children’s Hospital, Boston, MA 02115

4. Department of Biology, Massachusetts Institute of Technology, Cambridge, MA 02142

Whitehead Institute is a world-renowned non-profit research institution dedicated to improving human health through basic biomedical research.
Wholly independent in its governance, finances, and research programs, Whitehead shares a close affiliation with Massachusetts Institute of Technology
through its faculty, who hold joint MIT appointments.

© Whitehead Institute for Biomedical Research              455 Main Street          Cambridge, MA 02142