Pancreatic blood vessel cell map reveals potential diabetes treatment pathways

The distinct population of endothelial cells that line blood vessels in the insulin-producing “islets” of the human pancreas have been notoriously difficult to study, but Weill Cornell Medicine investigators have now succeeded in comprehensively detailing the unique characteristics of these cells.

The resulting atlas advances basic research on the biology of the pancreas and could lead to new treatment strategies for diabetes and other pancreatic diseases.

In the study, published in Nature Communications, the researchers devised a set of methods for rapidly isolating and profiling endothelial cells called ISECs (islet-specific endothelial cells) from donor pancreases.

ISECs provide critical support for islet functions but die very quickly when separated from the pancreas using standard cell-isolation techniques. With their highly streamlined approach, the researchers were able, for the first time, to analyze large numbers of ISECs, mapping their molecular signatures and interactions with other pancreatic cell types.

“The dataset we generated in this study is the first to capture the full diversity of endothelial cells in the pancreas, and we expect it to be an important resource for our research group and many others,” said co-senior author David Redmond, Ph.D. ’17, assistant professor of computational biology at the Hartman Institute for Therapeutic Organ Regeneration at Weill Cornell Medicine.

The other senior author is Dr. Shahin Rafii ’82, chief of the division of regenerative medicine, director of the Hartman Institute and the Ansary Stem Cell Institute and the Arthur B. Belfer Professor in Genetic Medicine at Weill Cornell Medicine.

Although ISECs’ precise molecular signatures had been unknown, scientists have had evidence that these cells support the maturation, insulin-secreting activities and survival of islet cells. They are also important for the long-term survival of islet transplants—which are infrequently used to treat type 1 diabetes because of immune complications but could be a cure if current obstacles are overcome.

For the study, first author Dr. Rebecca Craig-Schapiro, an assistant professor of surgery at Weill Cornell Medicine and a transplant surgeon at NewYork-Presbyterian/Weill Cornell Medical Center who works closely with Hartman Institute investigators, obtained three deidentified pancreases from deceased organ donors.

“With our novel approach, and using what was already known about ISECs, we were able to isolate and process these cells in very large numbers—more than 30,000—as well as about 75,000 other pancreatic cells, keeping them all viable long enough to conduct single-cell RNA sequencing,” Craig-Schapiro said.

The RNA-sequencing data, which provides snapshots of gene activity in each cell, enabled the researchers to determine the characteristic gene activity signatures of ISECs as well as other pancreatic cells including endothelial cells from the non-islet portion of the pancreas.

“Using our RNA sequencing data we also were able to identify support cells that communicate with ISECs and other endothelial cells in their respective pancreatic compartments,” said co-author Kevin Chen, a research technician in the Rafii laboratory.

Although prior studies of pancreatic cells had been incomplete, especially for ISECs, the researchers found that prior data largely matched their findings wherever it overlapped.

“We were able to integrate our data with three other published datasets, extensively corroborating our findings and resulting in a much more complete cell atlas,” said co-author Ge Li, a research associate in the Rafii lab.

Since pancreatic islets are where insulin is produced, they are also a major focus for diabetes research. Using the new data, along with existing datasets on gene activity in diabetic pancreas tissue, the researchers catalogued endothelial genes and signaling pathways that appear to be disrupted in diabetes—and might be targets for future therapies.

“This comprehensive atlas gives us a strong foundation for the development of strategies to restore the function of ISECs and other cells in diabetes and other pancreatic diseases,” Rafii said.

Currently, the researchers are using their new atlas for several follow-on efforts, including the development of techniques to make ISECs from other cells, said Dr. Rafii, who is also a member of the Englander Institute for Precision Medicine and the Sandra and Edward Meyer Cancer Center at Weill Cornell Medicine.

The distinct population of endothelial cells that line blood vessels in the insulin-producing “islets” of the human pancreas have been notoriously difficult to study, but Weill Cornell Medicine investigators have now succeeded in comprehensively detailing the unique characteristics of these cells.

The resulting atlas advances basic research on the biology of the pancreas and could lead to new treatment strategies for diabetes and other pancreatic diseases.

In the study, published in Nature Communications, the researchers devised a set of methods for rapidly isolating and profiling endothelial cells called ISECs (islet-specific endothelial cells) from donor pancreases.

ISECs provide critical support for islet functions but die very quickly when separated from the pancreas using standard cell-isolation techniques. With their highly streamlined approach, the researchers were able, for the first time, to analyze large numbers of ISECs, mapping their molecular signatures and interactions with other pancreatic cell types.

“The dataset we generated in this study is the first to capture the full diversity of endothelial cells in the pancreas, and we expect it to be an important resource for our research group and many others,” said co-senior author David Redmond, Ph.D. ’17, assistant professor of computational biology at the Hartman Institute for Therapeutic Organ Regeneration at Weill Cornell Medicine.

The other senior author is Dr. Shahin Rafii ’82, chief of the division of regenerative medicine, director of the Hartman Institute and the Ansary Stem Cell Institute and the Arthur B. Belfer Professor in Genetic Medicine at Weill Cornell Medicine.

Although ISECs’ precise molecular signatures had been unknown, scientists have had evidence that these cells support the maturation, insulin-secreting activities and survival of islet cells. They are also important for the long-term survival of islet transplants—which are infrequently used to treat type 1 diabetes because of immune complications but could be a cure if current obstacles are overcome.

For the study, first author Dr. Rebecca Craig-Schapiro, an assistant professor of surgery at Weill Cornell Medicine and a transplant surgeon at NewYork-Presbyterian/Weill Cornell Medical Center who works closely with Hartman Institute investigators, obtained three deidentified pancreases from deceased organ donors.

“With our novel approach, and using what was already known about ISECs, we were able to isolate and process these cells in very large numbers—more than 30,000—as well as about 75,000 other pancreatic cells, keeping them all viable long enough to conduct single-cell RNA sequencing,” Craig-Schapiro said.

The RNA-sequencing data, which provides snapshots of gene activity in each cell, enabled the researchers to determine the characteristic gene activity signatures of ISECs as well as other pancreatic cells including endothelial cells from the non-islet portion of the pancreas.

“Using our RNA sequencing data we also were able to identify support cells that communicate with ISECs and other endothelial cells in their respective pancreatic compartments,” said co-author Kevin Chen, a research technician in the Rafii laboratory.

Although prior studies of pancreatic cells had been incomplete, especially for ISECs, the researchers found that prior data largely matched their findings wherever it overlapped.

“We were able to integrate our data with three other published datasets, extensively corroborating our findings and resulting in a much more complete cell atlas,” said co-author Ge Li, a research associate in the Rafii lab.

Since pancreatic islets are where insulin is produced, they are also a major focus for diabetes research. Using the new data, along with existing datasets on gene activity in diabetic pancreas tissue, the researchers catalogued endothelial genes and signaling pathways that appear to be disrupted in diabetes—and might be targets for future therapies.

“This comprehensive atlas gives us a strong foundation for the development of strategies to restore the function of ISECs and other cells in diabetes and other pancreatic diseases,” Rafii said.

Currently, the researchers are using their new atlas for several follow-on efforts, including the development of techniques to make ISECs from other cells, said Dr. Rafii, who is also a member of the Englander Institute for Precision Medicine and the Sandra and Edward Meyer Cancer Center at Weill Cornell Medicine.