December 30, 2013
2 min read
Save

Researchers generate kidney tubular cells from stem cells

You've successfully added to your alerts. You will receive an email when new content is published.

Click Here to Manage Email Alerts

We were unable to process your request. Please try again later. If you continue to have this issue please contact customerservice@slackinc.com.

Researchers have successfully coaxed stem cells to become kidney tubular cells. The findings are published in the Journal of the American Society of Nephrology (JASN). The researchers said their findings are a significant advance toward one day using regenerative medicine, which involves rebuilding or repairing tissues and organs, to treat kidney failure, rather than the current method of dialysis or transplantation.

(Rheumatoid arthritis drug shows promise as targeted treatment for serious kidney disease)

Albert Lam, MD, Benjamin Freedman, PhD, Ryuji Morizane, MD, PhD, from Brigham and Women’s Hospital, and their colleagues have been working for the past five years to develop strategies to coax human pluripotent stem cells—particularly human embryonic stem (ES) cells and human induced pluripotent stem (iPS) cell—into kidney cells for the purposes of kidney regeneration.

“Our goal was to develop a simple, efficient, and reproducible method of differentiating human pluripotent stem cells into cells of the intermediate mesoderm, the earliest tissue in the developing embryo that is fated to give rise to the kidneys,” said Lam. He noted that these cells would be the “starting blocks” for deriving more specific kidney cells.

The researchers discovered a cocktail of chemicals which, when added to stem cells in a precise order, causes them to turn off genes found in ES cells and turn on genes found in kidney cells, in the same order that they turn on during embryonic kidney development.

(Arbor Research, NephCure to develop patient-powered research network for nephrotic syndrome)

The investigators were able to differentiate both human ES cells and human iPS cells into cells expressing PAX2 and LHX1, two key markers of the intermediate mesoderm. The iPS cells were derived by transforming fibroblasts obtained from adult skin biopsies to pluripotent cells, making the techniques applicable to personalized approaches where the starting cells can be derived from skin cells of a patient. The differentiated cells expressed multiple genes expressed in intermediate mesoderm and could spontaneously give rise to tubular structures that expressed markers of mature kidney tubules. The researchers could then differentiate them further into cells expressing SIX2, SALL1, and WT1, important markers of the metanephric cap mesenchyme, a critical stage of kidney differentiation. In kidney development, the metanephric cap mesenchyme contains a population of progenitor cells that give rise to nearly all of the epithelial cells of the kidney.

The cells also continued to behave like kidney cells when transplanted into adult or embryonic mouse kidneys, giving hope that investigators might one day be able to create kidney tissues that could function in a patient and would be 100% immunocompatible.

“We believe that the successful derivation of kidney progenitor cells or functional kidney cells from human pluripotent stem cells will have an enormous impact on a variety of clinical and translational applications, including kidney tissue bioengineering, renal assist devices to treat acute and chronic kidney injury, drug toxicity screening, screening for novel therapeutics, and human kidney disease modeling,” said Lam.