Salk scientists have created successful patient-derived pancreatic beta
cells able to respond to sugar (glucagon, blue) and produce insulin
(red) accordingly. These cells (nuclei, blue) could be transplanted back
into patients for a potential new diabetes therapy. Credit: Salk
Institute
Salk scientists have solved a
longstanding problem in the effort to create replacement cells for diabetic
patients. The team uncovered a hidden energy switch that, when flipped, powers
up pancreatic cells to respond to glucose, a step that eluded previous
research. The result is the production of hundreds of millions of lab-produced
human beta cells—able to relieve diabetes in mice.
For more than a decade, scientists
across the globe strive to replace failing pancreatic beta cells linked to immune
destruction in children (type 1 diabetes)
or obesity-associated diabetes in adults (type 2 diabetes). Although cells made
in a dish were able to produce insulin, they were sluggish or simply unable to
respond to glucose.
"We found the missing energy
switch needed to produce robust and functional human beta cells, potentially
turning this discovery into a viable treatment for human diabetes," says
Ronald Evans, co-senior author and director of the Gene Expression Laboratory
at Salk. The new work was published in Cell Metabolism on April 12,
2016.
The Salk technology begins with
induced pluripotent cells (iPSC), a stem cell technique
where tissue from a patient—such as skin—is reprogrammed into other types of
cells, such as from the pancreas. This step yields the pre-beta cells, which
produce insulin but are not yet functional. While several research groups
reached this juncture, the road forward to functional cells was not clear.
"Pancreatic beta cells must be
able to do two things to work effectively: respond to glucose and produce
insulin," says Evans, who is also a Howard Hughes Medical Institute
investigator and the March of Dimes Chair in Molecular and Developmental
Biology. "No one had been able to figure out how to make pancreatic
cells from human patients that can do both until now."
The Salk team closely studied the
basic biology of a beta cell and uncovered several molecular switches, called
transcription factors, that were switched off but might control the transition
to a fully functional state. The 'secret sauce,' the Salk team found, was one
particular switch the Evans lab had studied for years for its role in cell
signaling. This protein switch, called ERR-gamma, turned out to be crucial to
awaken silent beta-like cells that could now respond to glucose and release
insulin accordingly.
"This advance will result in a
better controlled insulin response than currently available treatments,"
says Michael Downes, co-senior author and a Salk senior staff scientist.
"Previously there was nothing known about the maturation process in beta
cells. We peeked into that black box and now we know what's going on."
He
adds that the team's technique is an easy, fast and inexpensive way to make
transplantable human pancreatic beta cells in a dish that genetically match
patients.
This discovery allows the team to
grow patient-derived, functional beta cells for transplantation in a potential
new diabetes therapy. Credit: Salk Institute
"When we added ERR-gamma to
pre-diabetic beta cells in a dish, we successfully created a
glucose-responsive, beta-like cell," says Eiji Yoshihara, first author of
the paper and a Salk research associate. "And when we remove ERR-gamma
from animals, the glucose response is eliminated, proving that the factor is
the master regulator of maturation for the beta cell."
But can these beta cells
successfully treat diabetes? The Salk researchers found that, indeed, when the
matured beta cells were transplanted into type 1 diabetic
mice, the procedure quickly rescued their diabetes. "Hopefully, this
mirrors what would happen in the clinic—after someone is diagnosed with
diabetes they could potentially get this treatment," says Evans.
"It's exciting because it suggests that cells in a dish are ready to
go."
The researchers hope to move to
human trials within the next few years.
This visual abstract depicts the Yoshihara et al. report
that the postnatal maturation of pancreatic b cells necessary for maximal
glucosestimulated insulin secretion is coordinated by the estrogen-related
receptor g (ERRg). ERRg drives a transcriptional program promoting
mitochondrial oxidative metabolism, and its expression in iPSC-derived b-like
cells generates functional b cells in vitro. Credit: Yoshihara et al./Cell
Metabolism 2016
http://medicalxpress.com/news/2016-04-scientists-secret-sauce-personalized-functional.html
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