This image shows induced pluripotent stem cells expressing a characteristic cell-surface protein called stage-specific embryonic antigen-4 (SSEA4) (green). [Stephen A. Duncan, Ph.D./Medical University of South Carolina]
This image shows induced pluripotent stem cells expressing a characteristic cell-surface protein called stage-specific embryonic antigen-4 (SSEA4) (green). [Stephen A. Duncan, Ph.D./Medical University of South Carolina]

A team of scientists reports that it has found a better way to purify liver cells made from induced pluripotent stem cells (iPSCs). The study (“Mapping the Cell-Surface N-Glycoproteome of Human Hepatocytes Reveals Markers for Selecting a Homogeneous Population of iPSC-Derived Hepatocytes”), published in Stem Cell Reports, is expected to aid work on liver disease for the National Heart, Lung, and Blood Institute (NHLBI)'s $80 million Next Generation Genetic Association Studies (Next Gen) Program.

The University of Minnesota, the Medical College of Wisconsin, and  Medical University of South Carolina (MUSC) were involved in the the study.

This new methodology could facilitate progress toward an important clinical goal—the treatment of patients with disease-causing mutations in their livers by transplantation of unmutated liver cells derived from their own stem cells. Previous attempts to generate liver-like cells from stem cells have yielded heterogeneous cell populations that bear little resemblance to diseased livers in patients. 

NHLBI's Next Gen was created to bank stem cell lines sourced from patients in genome-wide association studies (GWAS). The goal of the NHLBI Next Gen Lipid Conditions subsection is to help determine the genetic sources of heart, lung, or blood conditions that also encompass the liver. These GWAS studies map the genomes in hundreds of people as a way to look for genetic mutation patterns that differ from the genomes of healthy individuals.

A GWAS study becomes more powerful as more genomes are mapped. Once a panel of suspected mutations is built, stem cells from these individuals can be “pushed” in culture dishes to differentiate into any of the body's cells, as, for example, liver-, heart-, or vascular-like cells. The cells can be screened in high-throughput formats (i.e., cells are expanded and cultured in many dishes) to learn more about the mutations and to test panels of drugs that might ultimately help treat patients harboring a disease.

The problem arises during the “pushing.” For example, iPSCs stubbornly refuse to mature uniformly into liver-like cells when fed growth factors. Traditionally, antibodies have been used to recognize features of maturity on the surfaces of cells and purify cells that are alike. This approach has been crucial to stem cell research, but available antibodies that recognize mature liver cells are few and tend to recognize many different kinds of cells. The many types of cells in mixed populations have diverse characteristics that can obscure underlying disease-causing genetic variations, which tend to be subtle.

“Without having a pure population of liver cells, it was incredibly difficult to pick up these relatively subtle differences caused by the mutations, but differences that are important in the life of an individual,” said Stephan  A. Duncan, D. Phil., SmartState Chair of Regenerative Medicine at MUSC.

Instead of relying on antibodies, Dr. Duncan and his crew embraced a new technology called chemoproteomic cell-surface capture (CSC) technology, which allowed the group to map the proteins on the surface of liver cells that were most highly produced during the final stages of differentiation of stem cells into liver cells. The most abundant protein was targeted with an antibody labeled with a fluorescent marker and used to sort the mature liver cells from the rest. 

The procedure was successful. The team had a population of highly pure, homogeneous, and mature liver-like cells. Labeled cells had far more similar traits of mature hepatocytes than unlabeled cells. Pluripotent stem cells that had not differentiated were excluded from the group of labeled cells.

“That's important,” said Dr. Duncan. “If you're wanting to transplant cells into somebody that has liver disease, you really don't want to be transplanting pluripotent cells because pluripotent cells form tumors called teratocarcinomas.” 

He cautions that transplantation of iPSC-derived liver cells is not yet ready for translation to the clinic. But the technology for sorting homogeneous liver cells can be used now to  model and study disease successfully and accurately in the cell culture dish. 

“We think that by being able to generate pure populations, it will get rid of the variability, and therefore really help us combine with GWAS studies to identify allelic variations that are causative of a disease, at least in the liver,” added Dr. Duncan. 

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