Recreating the adrenal gland in a petri dish

Sasaki says his team’s aim was to use human inducible pluripotent stem cells (iPSCs), which can give rise to a myriad of different cell types, to mimic the stages of normal human adrenal development. During this process, the cells would get directed to take on the characteristics of the adrenal gland.

To begin, the researchers used what’s known as an “organoid culture” system, in which cells grow first as a floating aggregate for three weeks, then on a membrane exposed to air on one side, promoting better survival and allowing them to proliferate in three dimensions. Utilizing a carefully selected growth medium, they prompted the iPSCs to elicit an intermediate tissue type in the adrenal development process, the posterior intermediate mesoderm (PIM).

After verifying they had cultured PIM-like cells, the researchers embarked on directing those cells to transition to the next stage, adrenocortical progenitor-like cells, during which cells turn on markers indicating they have “committed” to becoming adrenal gland cells.

Molecular assays to check for adrenal markers, as well as transmission electron microscope analyses, all told Sasaki and colleagues they were on the right track to recreating a tissue that resembled the early adrenal gland.

“The process we developed was highly efficient, with around 50% of cells in organoids acquiring adrenocortical cell fate,” says Michinori Mayama, a postdoc in Sasaki’s lab and a lead author on the study. “The ovoid cells with voluminous pink cytoplasm and relatively small nuclei that we saw in our cultures are very characteristic of human adrenal cells at that stage.”

Sasaki, Mayama, and the rest of the research team performed a number of tests to evaluate how closely the functionality of the cells they had cultivated mirrored that of a human adrenal gland. They found the lab-grown cells produced steroid hormones, like DHEA, just as the “real-life” equivalent would. “In vitro, we can produce much of the same steroids that are produced in vivo,” Mayama says.

They also showed that the cells they grew could respond to what’s known as the hypothalamic-pituitary-adrenal axis, a feedback loop that governs communication from the brain to the adrenal gland and back again. “We used drugs that normally suppress adrenal DHEA production and showed that our iPSC-derived adrenal cells respond similarly to these drugs, with a marked reduction of hormone production,” says Sasaki. “This means that you can use this system for screening drugs that target adrenal hormone production, which could benefit patients with excessive adrenal hormone production or with a prostate cancer that exploits adrenal hormones for their growth.”

As the researchers refine their system, they hope to generate more of the gradations in tissue type that occur in a mature adult adrenal gland.

Such a platform opens up opportunities to learn far more about the still-mysterious adrenal gland. In particular, Sasaki notes that it could be leveraged to probe the genetic basis of adrenal insufficiencies as well as other diseases, such as adrenal carcinomas. Ultimately, the approach used to create this gland-in-a-dish may one day work to reconstitute a functioning brain-adrenal gland feedback loop in people with adrenal gland disorders.

“This is a first-of-its kind study,” says Sasaki. “The field of cell therapy holds so much promise for treating not just adrenal insufficiencies but other hormone-driven diseases: hyperten

Source: University of Pennsylvania