The prostates of older mice contain more luminal progenitor cells—cells capable of generating new prostate tissue—than the prostates of younger mice, UCLA researchers have discovered.
The observation, published in Cell Reports, helps explain why, as people age, the prostate tends to grow, leading to an increased risk for prostate cancer and other conditions.
“Understanding what’s causing the prostate to grow with age helps us to consider strategies to prevent the expansion of these cells and possibly reduce a person’s risk for prostate growth or disease,” said Andrew Goldstein, member of the Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research at UCLA and a UCLA assistant professor of urology and of molecular, cell, and developmental biology.
Most organs in the body—including the kidneys, liver and spleen—lose mass as people age, and bone and muscle mass tend to decrease over time.
The prostate, however, typically grows with age, which is why more than half of men over age 60 have benign prostatic hyperplasia, or BPH, in which the enlarged prostate impinges on the urethra, the organ that carries urine out of the bladder.
Research had previously shown that the numbers of progenitor cells are also diminished in organs that shrink with age. Like stem cells, progenitor cells can differentiate into new cells, but they are more constrained in what type of cells they can become. For instance, prostate progenitor cells can only form prostate tissue.
Whether levels of stem cells or progenitor cells in the prostate changed with age was not previously known.
In the new work, Goldstein and his colleagues compared the prostates of two groups of mice: 3-month-olds (an age comparable to human young adults) and 24-month-olds (roughly equivalent to 80 human years). The prostates of the older mice were larger and heavier and had more cells than those of younger mice.
The researchers then isolated luminal cells—one subset of prostate cells—from the mice and grew them to form prostate organoids, or smaller, simplified versions of the prostates. They discovered that luminal cells from older animals formed prostate organoids just as effectively as cells from younger animals. In fact, the organoids formed from older cells tended to be larger.
When the team looked more closely at the luminal cells, they discovered that older prostates contained more luminal progenitor cells. While only six percent of luminal prostate cells were progenitors in the younger mice, 21 percent of luminal cells in older mice were prostate progenitors.
The higher concentration of luminal progenitors, coupled with their maintained ability to form new tissue, helps explain why the prostate grows with age and why the risk of prostate cancer and benign prostatic hyperplasia increase: Both are associated with the growth of cells.
“One of the biggest questions we have now is what is causing this age-related increase in the number of luminal progenitor cells,” Goldstein said. “We have a few hypotheses but it remains to be seen what’s really happening.”
Answering that question, he said, could help identify a way to curb the growth of luminal progenitor cells and, in turn, prevent or treat prostate cancer or benign prostatic hyperplasia. It also could inform scientists better about why other organs lose mass with age.