FUNCTIONAL HUMAN LIVER CELLS GROWN IN THE LAB.
In
new research appearing in the journal Nature
Biotechnology, an
international research team led by The Hebrew University of Jerusalem describes
a new technique for growing human hepatocytes in the laboratory. This
groundbreaking development could help advance a variety of liver-related
research and applications, from studying drug toxicity to creating
bio-artificial liver support for patients awaiting transplantations.
The liver is
the largest internal organ in the human body, serving as the main site of
metabolism. Human hepatocytes -- cells that comprise 85% of the liver -- are
routinely used by the pharmaceutical industry for study of hepatotoxicity, drug
clearance and drug-drug interactions. They also have clinical applications in
cell therapy to correct genetic defects, reverse cirrhosis, or support patients
with a liver-assist device.
Regrettably,
while the human liver can rapidly regenerate in vivo, recognized by the ancient
Greeks in the myth of Prometheus, this capability to proliferate is rapidly
lost when human cells are removed from the body. Thus far, attempts to expand
human hepatocytes in the laboratory resulted in immortalized cancer cells with
little metabolic function. The scarce supply of human hepatocytes and this
inability to expand them without losing function is a major bottleneck for
scientific, clinical and pharmaceutical development.
To address this
problem, Prof. Yaakov Nahmias, director of the Alexander Grass Center for
Bioengineering at the Hebrew University of Jerusalem, partnered with leading
German scientists at upcyte technologies GmbH (formerly Medicyte) to develop a
new approach to rapidly expand the number of human liver cells in the
laboratory without losing their unique metabolic function.
Based on early
work emerging from the German Cancer Research Center (DKFZ) on the Human
Papilloma Virus (HPV), the research team demonstrated that weak expression of
HPV E6 and E7 proteins released hepatocytes from cell-cycle arrest and allowed
them to proliferate in response to Oncostatin M (OSM), a member of the
interleukin 6 (IL-6) superfamily that is involved in liver regeneration.
Whereas previous studies caused hepatocytes to proliferate without control,
turning hepatocytes into tumor cells with little metabolic function, the
researchers carefully selected colonies of human hepatocytes that only
proliferate in response to OSM. Stimulation with OSM caused cell proliferation,
with doubling time of 33 to 49 hours. Removal of OSM caused growth arrest and
hepatic differentiation within 4 days, generating highly functional cells. The
method, described as the upcyte© process (upcyte technologies GmbH), allows
expanding human hepatocytes for 35 population doubling, resulting in 1015 cells
(quadrillion) from each liver isolation. By comparison, only 109 cells
(billion) can be isolated from a healthy organ.
"The
approach is revolutionary," said Dr. Joris Braspenning, who led the German
group. "Its strength lies in our ability to generate liver cells from
multiple donors, enabling the study of patient-to-patient variability and
idiosyncratic toxicity." The team generated hepatocyte lines from
ethnically diverse backgrounds that could be serially passaged, while
maintaining CYP450 activity, epithelial polarization, and protein expression at
the same level as primary human hepatocytes. Importantly, the proliferating
hepatocytes showed identical toxicology response to primary human hepatocytes
across 23 different drugs.
"This is
the holy grail of liver research," said Prof. Nahmias, the study's lead
author. "Our technology will enable thousands of laboratories to study
fatty liver disease, viral hepatitis, drug toxicity and liver cancer at a
fraction of the current cost." Nahmias noted that genetic modifications
preclude using the cells for transplantation, "but we may have found the
perfect cell source for the bio-artificial liver project."
The
proliferating hepatocyte library was recently commercialized by upcyte
technologies GmbH (Hamburg, Germany), which is expanding the scope of the
technology. "upcyte© hepatocytes represent the next generation of cell
technology," said Dr. Astrid Nörenberg, the company's managing director.
"We are poised to become the leading cell supplier for pharmaceutical
development and chemical toxicity testing."
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