Building upon previous research,
scientists at the University of California, San Diego School of
Medicine and Veteran's Affairs San Diego Healthcare System report that
neurons derived from human induced pluripotent stem cells (iPSC) and
grafted into rats after a spinal cord injury produced cells with tens of
thousands of axons extending virtually the entire length of the
animals' central nervous system.
This image depicts extension of human axons into host adult rat white
matter and gray matter three months after spinal cord injury and
transplantation of human induced pluripotent stem cell-derived neurons.
Green fluorescent protein identifies human graft-derived axons, myelin
(red) indicates host rat spinal cord white matter and blue marks host
rat gray matter.
Writing in the August 7 early online edition of Neuron, lead
scientist Paul Lu, PhD, of the UC San Diego Department of Neurosciences
and colleagues said the human iPSC-derived axons extended through the
white matter of the injury sites, frequently penetrating adjacent gray
matter to form synapses with rat neurons. Similarly, rat motor axons
pierced the human iPSC grafts to form their own synapses.
The iPSCs used were developed from a healthy 86-year-old human male.
"These findings indicate that intrinsic neuronal mechanisms readily
overcome the barriers created by a spinal cord injury to extend many
axons over very long distances, and that these capabilities persist even
in neurons reprogrammed from very aged human cells," said senior author
Mark Tuszynski, MD, PhD, professor of Neurosciences and director of the
UC San Diego Center for Neural Repair.
For several years, Tuszynski and colleagues have been steadily
chipping away at the notion that a spinal cord injury necessarily
results in permanent dysfunction and paralysis.
Earlier work has shown that grafted stem cells reprogrammed to become
neurons can, in fact, form new, functional circuits across an injury
site, with the treated animals experiencing some restored ability to
move affected limbs. The new findings underscore the potential of
iPSC-based therapy and suggest a host of new studies and questions to be
asked, such as whether axons can be guided and how will they develop,
function and mature over longer periods of time.
While neural stem cell therapies are already advancing to clinical
trials, this research raises cautionary notes about moving to human
therapy too quickly, said Tuszynski.
"The enormous outgrowth of axons to many regions of the spinal cord and even deeply into the brain
raises questions of possible harmful side effects if axons are
mistargeted. We also need to learn if the new connections formed by
axons are stable over time, and if implanted human neural stem cells are
maturing on a human time frame -- months to years -- or more
rapidly. If maturity is reached on a human time frame, it could take
months to years to observe functional benefits or problems in human
clinical trials."
In the latest work, Lu, Tuszynski and colleagues converted skin cells
from a healthy 86-year-old man into iPSCs, which possess the ability to
become almost any kind of cell. The iPSCs were then reprogrammed to
become neurons in collaboration with the laboratory of Larry Goldstein,
PhD, director of the UC San Diego Sanford Stem Cell Clinical Center. The
new human neurons were subsequently embedded in a matrix containing
growth factors and grafted into two-week-old spinal cord injuries in
rats.
Three months later, researchers examined the post-transplantation
injury sites. They found biomarkers indicating the presence of mature
neurons and extensive axonal growth across long distances in the rats'
spinal cords, even extending into the brain. The axons traversed wound
tissues to penetrate and connect with existing rat neurons. Similarly,
rat neurons extended axons into the grafted material and cells. The
transplants produced no detectable tumors.
While numerous connections were formed between the implanted human
cells and rat cells, functional recovery was not found. However, Lu
noted that tests assessed the rats' skilled use of the hand. Simpler
assays of leg movement could still show benefit. Also, several iPSC
grafts contained scars
that may have blocked beneficial effects of new connections. Continuing
research seeks to optimize transplantation methods to eliminate scar
formation.
Tuszynski said he and his team are attempting to identify the most
promising neural stem cell type for repairing spinal cord injuries. They
are testing iPSCs, embryonic stem cell-derived cells and other stem cell types.
"Ninety-five percent of human clinical trials fail. We are trying to
do as much as we possibly can to identify the best way of translating
neural stem cell therapies for spinal cord injury to patients. It's easy
to forge ahead with incomplete information, but the risk of doing so is
greater likelihood of another failed
clinical trial. We want to determine as best we can the optimal cell
type and best method for human translation so that we can move ahead
rationally and, with some luck, successfully."
- Lu et al. Long-Distance Axonal Growth from Human Induced Pluripotent Stem Cells After Spinal Cord Injury. Neuron, 2014 (in press)
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