Glia-enriched cultures were derived from a primary progressive multiple sclerosis iPSC line, showing astrocytes (yellow), oligodendrocytes (cyan), and neurons (magenta). Credit: New York Stem Cell Foundation

A team of scientists from The New York Stem Cell Foundation (NYSCF) Research Institute and Case Western Reserve University has created the largest reported collection of stem cell models from multiple sclerosis (MS) patients. They used these models to identify unique ways in which glia, which are integral support cells in the brain, contribute to the disease.

The study, published today in Cell Stem Cell, is the first to reveal that glial cells from MS patients show signs of the disease on their own without being influenced by the immune system. This highlights the potential of stem cells in uncovering new aspects of the disease and the necessity for novel MS treatments. 

The Hidden Roles of Glia in MS

MS is an autoimmune disease that occurs when the body’s immune system mistakenly attacks the protective myelin sheaths surrounding the nerves in the brain and spinal cord. This results in significant neurological disability.

“Most research and therapeutic strategies have focused on blocking the overactive immune system. However, it remained a mystery how cells in the brain itself, especially glia, contribute to the initiation and progression of MS,” explained Valentina Fossati, PhD, NYSCF Senior Research Investigator who led the study..

The team used NYSCF’s automation platforms to generate induced pluripotent stem cells (iPSCs) from skin biopsies taken from individuals with MS. This resulted in the largest collection of MS patient stem cell lines to date, which covered diverse clinical subtypes. Then, they transformed the iPSCs into glial cells, including oligodendrocytes and astrocytes, to study their involvement in the disease.

“By generating glia-enriched cultures from stem cells, we have been able to study their role in MS independently of the complex environment in the body, which is constantly altered by the presence of immune cells and inflammatory signals,” continued Dr. Fossati.

Sure, here is a clearer version of the text:”Using single-cell gene expression profiling, scientists discovered that stem cell-derived glia cultures from individuals with primary progressive MS (a particularly severe form of the disease) had fewer oligodendrocytes. Oligodendrocytes are responsible for producing myelin, the protective sheath around nerve fibers that is lost in MS.”

“This observation challenges the conventional understanding of MS as being purely driven by immune system dysfunction. It suggests that the disease may also be fueled by processes originating within the brain itself,” noted Paul Tesar, PhD, the Dr. Donald and Ruth Weber Goodman Professor of Innovative Therapeutics and director of the Institute for Glial Sciences at Case Western Reserve University School of Medicine and NYSCF – Robertson Stem Cell Investigator Alumnus, who co-led the study.

The team noticed that a group of genes linked to immune and inflammatory functions were highly active in glia cultures derived from stem cells of MS patients. This matched what they observed in brain samples from deceased individuals with MS. Additionally, NYSCF scientists used their latest developments in artificial intelligence to identify differences in astrocytes that are not easily visible to the naked eye.

“The fact that glia created from stem cells show similar features to glia in MS patient brains shows us that stem cell models provide a pretty accurate reflection of what happens in the brains of living patients. We can use them to gain important insights into this disease,” added Dr. Fossati.

A New Target for Therapeutic Intervention

Because of the autoimmune activity in multiple sclerosis (MS), many current therapies target the immune system. These drugs help reduce the frequency of immune attacks, but they unfortunately fall short in preventing the neurodegeneration that drives disease progression.

The findings of the study present new opportunities for treating MS. By pinpointing specific behaviors of glial cells that play a role in the disease, researchers can now investigate potential therapies that directly target these cells. This may result in more effective treatments that surpass mere suppression of the immune system, offering fresh hope for patients.

.“Our findings represent a significant leap forward in our understanding of MS and underscore the vast potential in glia as a target for therapeutic intervention that could transform the treatment landscape for many patients,” remarked Dr. Tesar.