Developing a Model System to Test Ketamine Toxicity

Figure 2. Ketamine induced morphological changes in neurons derived from iPSCs. Cells were treated with 0μM (Panel A), 20μM (Panel B), 100μM (Panel C) or 500μM (Panel D) ketamine for 24 hours. doi:10.1371/journal.pone.0128445.g002
Ketamine induced morphological changes in neurons derived from iPSCs.
Cells were treated with 0μM (Panel A), 20μM (Panel B), 100μM (Panel C) or 500μM (Panel D) ketamine for 24 hours. Scale bar = 50μm. From Ito, H., Uchida, T. and Makita, K. (2015) Ketamine causes mitochondrial dysfunction in human induced pluripotent stem cell-derived neurons. PLOS ONE 10, e0128445.
doi:10.1371/journal.pone.0128445.g002
When I consider that major surgery was performed long before anesthetics were developed, I am grateful to be alive in the anesthesia era. Just the thought of being subjected to various cutting and retracting instruments without general anesthesia calls to mind a phrase: The cure is worse than the disease. Despite the advantages of unconsciousness during surgery, anesthesia can have side effects. Studies in neonatal nonhuman primates have demonstrated that the anesthetic ketamine has toxic effects. However, the differences between humans and nonhuman primates mean the outcome in one species is not the same in another. In an article recently published in PLOS ONE, scientists were interested in creating an experimental model of developing human neurons and using the model to better understand the toxic effects of ketamine on human cells.

Creating an in vitro human neuronal cell model started with human induced pluripotent stem cells (iPSCs) cultured under conditions that produced neurons. After 14 days, the cells changed morphology from the initial progenitor cells and looked more like neurons. The iPSC-derived neurons were positive for βIII-tubulin and tyrosine hydroxylase staining, two markers for neuronal differentiation. Compared with a differentiated cortical neuronal cell line, the neurons differentiated from iPSCs had similar percent staining for βIII-tubulin.

Cell Morphology Effects

Next, Ito, Uchida and Makita wanted to test the system to see what kind of changes were induced in cells exposed to ketamine. When the IPC-derived neurons were exposed to ketamine in increasing concentrations (20, 100 and 500μM) for 24 hours, cells exposed to the highest dose showed distinct morphological changes. Seeing physical changes in iPSC-derived neurons exposed to 500μM ketamine, however, does not reveal what lower concentrations of ketamine might be doing at the cellular level.

Cell Health Effects

So how was cell health affected if at all? Using multiplexed cell viability and caspase-3/7 assays, the researchers looked at iPSC-derived neurons exposed to 20, 100 and 500μM ketamine for 6 and 24 hours. Regardless of the concentration of ketamine used, cells remained viable. However, for cells treated with 500μM ketamine, caspase-3/7 levels increased at both 6 and 24 hours, indicating that apoptosis was initiated. Similar to the apoptosis assay, H2O2 levels were elevated at 6 and 24 hours for iPSC-derived neurons treated with 500μM ketamine, but not for the lower concentrations. The differentiated cortical neuronal cell line showed the same increase in the levels of caspase-3/7 and reactive oxygen species (ROS) under the same conditions. To examine if there was a relationship between ROS activation and caspase-3/7 levels, iPSC-derived neurons were treated with 500µM ketamine for 6 hours with or without a ROS scavenger. For the cells treated with the ROS scavenger, both ROS levels and caspase-3/7 levels were reduced compared to cells treated with 500µM ketamine alone.

Mitochondrial Effects

Ito, Uchida and Makita next investigated whether ketamine cytotoxicity affected mitochondria. To test this, iPSC-derived neurons were treated with 20, 100 and 500μM ketamine for 6 and 24 hours, and the levels of cellular ATP assessed. Levels of ATP decreased in both a time- and dose-dependent manner for both 100 and 500µ ketamine. That is, cells treated with 500µM ketamine for 24 hours had the greatest reduction in ATP, while cells treated with 100µM ketamine for 6 hours had significant but more modest ATP reduction.

Oxidative Stress Effects

How did ketamine affect oxidative stress in neuronal cells? The researchers examined how the NADH:NAD+ ratio changed with increasing concentration of ketamine. Similar to ATP levels, the NADH:NAD+ ratios had increased when iPSC-derived neurons were treated with 100 and 500μM ketamine at both 6 and 24 hours. These same results were seen in the cortical neuronal cells. These results suggested that ketamine affected oxidative phosphorylation in mitochondria. Therefore, Ito, Uchida and Makita studied if ketamine directly affected the mitochondrial respiratory chain complex activities using an assay where NADH is oxidized to NAD+. Using ketamine-treated bovine heart mitochondrial respiratory chain complex (I, II, IV and V), researchers saw NADH dehydrogenase (complex I) and ATP synthase (complex V) significantly decreased when treated with 125 or 500μM ketamine while complex II (succinate dehydrogenase) and complex IV (cytochrome c oxidase) activities were unchanged.

Physical Effects on Mitochondria

Mitochondrial membrane potential and morphology were also examined after ketamine treatment. For both iPCS-derived neurons and cortical neuronal cells treated with 500µM ketamine for 6 or 24 hours, mitochondrial membrane potential significantly decreased compared with untreated cells. Confocal microscopy of neurons treated with ketamine showed shortened mitochondria in those cells exposed to 100µM and 500µM ketamine. Under a transmission electron microscope, neurons exposed to 100μM ketamine had fragmented mitochondria and autophagosomes present in the cytosol. Cells treated with 500µM ketamine had numerous autophagosomes in all cells scanned and had shortened mitochondria with irregular cristae.

To address neuronal functionality, iPSC-derived neurons were tested for monoamine neurotransmitter reuptake activity. Cells exposed to 100µM and 500µM ketamine had reduced reuptake activity compared to untreated cells.

Studying how medications affect humans can be difficult, and developing human model systems to study side effects is complicated. These researchers started with a known problem (ketamine cytotoxicity) and developed a potential model system to examine how ketamine was affecting neurons. Their system showed that ketamine affected both neuronal cell health and mitochondria morphology and functionality. Further study is needed to validate this model and the results of ketamine treatment.

To learn more about the cell health and metabolism assays used in this paper, visit our web site.

Reference
Ito, H., Uchida, T. and Makita, K. (2015) Ketamine causes mitochondrial dysfunction in human induced pluripotent stem cell-derived neurons. PLOS ONE 10, e0128445.

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Sara Klink

Technical Writer at Promega Corporation
Sara is a native Wisconsinite who grew up on a fifth-generation dairy farm and decided she wanted to be a scientist at age 12. She was educated at the University of Wisconsin—Parkside, where she earned a B.S. in Biology and a Master’s degree in Molecular Biology before earning her second Master’s degree in Oncology at the University of Wisconsin—Madison. She has worked for Promega Corporation for more than 15 years, first as a Technical Services Scientist, currently as a Technical Writer. Sara enjoys talking about her flock of entertaining chickens and tries not to be too ambitious when planning her spring garden.

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