Increasing Melanoma Cell Death Using Inhibitors of Protein Disulfide Isomerases to Abrogate Survival Responses to Endoplasmic Reticulum Stress
Penny E. Lovat,1 Marco Corazzari,3 Jane L. Armstrong,2 Shaun Martin,1 Vittoria Pagliarini,3
David Hill,1 Anna M. Brown,1 Mauro Piacentini,3,4 Mark A. Birch-Machin,1
and Christopher P.F. Redfern2
1Dermatological Sciences, School of Clinical and Laboratory Sciences and 2Northern Institute for Cancer Research, Newcastle University,
Newcastle upon Tyne, United Kingdom; 3L’Spallanzani, National Institute for Infectious Disease; and 4University of Tor Vergata, Rome, Italy
Summary:
In the present study, researchers looked to enhance the effect of such chemotherapy drugs (i.e., apoptosis of melanoma cells) by disrupting the homeostatic response to ER stress – specifically, the protein disulfide isomerase (PDI) domains of ER chaperone proteins. In the end, the researchers found that bacitracin, a PDI inhibitor, enhanced the apoptotic effect of chemotherapy drugs fenretinide and velcade.
The first step researchers took in reaching their conclusion was to confirm that the chemotherapy drugs fenretinide and velcade in fact caused ER stress. They exposed three melanoma cell lines (CHL-1, A375 and WM266-4) to various time-courses of each of the two chemotherapy drugs and measured levels of certain ER stress response proteins which are up-regulated during ER stress. Quantitative PCR was used to specifically probe mRNA levels of GADD34, a cellular stress response protein that mediates apoptosis, and ATF4, a stress response transcription factor. Also, DNA electrophoresis was used in tandem with PCR to monitor the mRNA splicing of transcription factor XBP-1, a protein up-regulated during ER stress. The results show that, relative to the control, cells exposed to the chemotherapy drugs had higher levels of GADD34 and ATF4 as well as increased XBP-1 mRNA splicing. This suggested that ER stress was induced by the chemotherapy drugs.
Once ER stress was confirmed, researchers showed that chemotherapy-induced apoptosis was enhanced by the presence of PDI inhibitors, particularly bacitracin, which inhibit the function of chaperone proteins that protect melanoma cells from ER stress. They used flow cytometry of propidium iodide-stained cells to estimate the level of apoptosis and used the MTS assay to measure cell viability of melanoma cells exposed to the following conditions: vehicle control (negative control), 500 μM bacitracin, 10 μM fenretinide, bacitracin + fenretinide, 30 nm velcade, bacitracin + velcade. The results of these experiments are shown in Figure 2B.
In summary, the bacitracin alone did not affect cell viability, but did enhance apoptosis of fenretinide (or velcade) when mixed with that chemotherapy drug. The researchers also used a western blot to show the presence of GADD153, a protein whose increased expression is widely accepted to be a marker of apoptosis due to ER stress. Figure 2C shows that the lanes with both bacitracin and one of the chemotherapy drugs had darker bands in GADD153 for all three melanoma cell lines. It is important to note that the researchers also found that bacitracin does not enhance the effect of chemotherapy drugs on healthy melanocyte cells. This differential effect has numerous implications in chemotherapy drug development.
Finally, to confirm that bacitracin was in fact enhancing apoptosis through the inhibition of PDI activity, the researchers designed a clever controlled experiment. By overexpressing chaperone proteins with PDI domains through transient transfection, the researchers limited the ability of bacitracin to enhance ER stress-induced apoptosis by having the transfected PDI-active proteins compete with endogenous PDI proteins – specifically P4HB – for the inhibition site of bacitracin. By transfecting both wild-type P4HB (with normal PDI activity) and mutant P4HB (with mutations in the PDI active site) and comparing their response to bacitracin, the researcher were able to check to see if bacitracin was in fact acting by inhibiting PDI activity. The results are summarized in Figure 4.
Figure 4B shows that the wild-type PDI cells had higher PDI activity than the mutant variety. This was measured as increased turbidity at 650 nm when reacted with bovine insulin. Figure 4C shows that bacitracin had a lesser effect on enhancing apoptosis in cells with overexpressed wild-type P4HB than cells with overexpressed mutant P4HB. This confirms that bacitracin acts by inhibiting the PDI domains.
Importance/Significance:
This study has invaluable implications for new chemotherapy drug development. Researchers found that PDI inhibiting chemicals, such as bacitracin, can enhance the effect of existing chemotherapy agents. Additionally, these PDI inhibiting chemicals do not increase healthy melanocyte apoptosis in response to chemotherapy drugs, allowing drug developers to enhance tumor cell death without increasing non-tumor cell apoptosis.
Critique:
The authors do a great job planning out their experiments with the appropriate controls and accounting for confounding factors by running additional tests. For example, for each experiment where they expose the melanoma cells to chemotherapy drugs, there is always a set of cells that act as a negative control and do not receive the drugs. Also, when they were unsure of whether bacitracin acted by inhibiting the PDI domains, researchers performed an additional controlled experiment to confirm their suspicions.
On the other hand, the authors did a poor job explaining how they determined the brightness of bands in their western blots. In some cases it was clear which band was darker, but in most cases it was unclear and the paper did not establish a method to quantify darkness of bands. They could have applied a simple ImageJ protocol to strengthen the assertions they make regarding their western blot results.
6 comments:
So the authors showed bacitracin and velcade synergistically promote cell death, but do they explain if this is clinically relevant? It seems logical that if you use a combination of drugs, more cells will die. However, the problem with chemotherapy is usually that the drugs are too cytotoxic for your non-cancerous cells. Do any of the results suggest that this combinatorial treatment has a higher therapeutic index than using Velcade alone? Otherwise, it just seems like this treatment might be more toxic for you overall and so you tolerate take even less of it.
According to Raj's summary, bacitracin does not enhance the effects of velcade and fenretinide on healthy, non-cancerous cells. It's probably worth noting that since this drug combination would be administered systemically in melanoma treatment, it would have to be tested on a wide range of non-cancerous cells rather than just melanocytes. That actually leads to something else I found interesting. Even considering just melanoma cell lines, we see variation in the relative apoptosis up to a factor of 2 (Figure 2B). It's pretty pronounced in the FenR-only and Bac+FenR treatments. Maybe finding out the molecular mechanism of resistance in some of these cell lines would tell us even more about the action of these drugs together.
Also, I presume the authors used the drugs in concentrations that are clinically achievable? If so, then this does seem very promising on paper.
Perhaps I missed something, but did they give or speculate a reason as to why bacitracin would not enhance the effects of velcade and fenretinide non-cancerous cells? Nothing about their mechanism of action would suggest this, except that cancerous cells would be using their ER more aggressively.
And I agree with Harry above that other cell types should probably be tested (though this would be future work type stuff) since melanoma becomes dangerous after it metastasizes-at which point it won't be near only other melanocytes. It would have to be intravenous.
Response to Tim's comment:
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Like Harry mentioned, the researchers did test the combination of bacitracin and velcade (as well as bacitracin and fenretinide) on melanocytes (non-cancerous cells) to see if there was a different effect. They found that bacitracin did NOT enhance the apoptotic effects of fenretinide and velcade in those cells, suggesting that the enhancement was specific to the cancerous cells. Therefore, bacitracin is a promising chemotherapeutic agent because of its differential effect on melanoma and melanocyte cell lines.
Response to Harry's comment:
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With regard to inducing ER stress, the paper explicitly says the levels of fenretinide and velcade were clinically achievable concentrations. However, it fails to place any other concentrations of drugs in a clinical context.
They do mention that bacitracin is clinically limited due to its neurotoxicity, but I think the purpose of the paper is to suggest that any PDI inhibitor could prove effective as a chemotherapeutic enhancer.
Also, I completely agree with your comment about testing other non-cancerous cells. It seems that to make a case for its differential effects on cancerous and non-cancerous cells, this study would have to be reproduced on many non-cancerous cell lines in addition to melanocytes.
Response to Charles' comments:
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They did not investigate mechanism-related reasons as to why bacitracin does not enhance the effects of fenretinide and velcade in non-cancerous cells. I believe that they just wanted to show that the effects were different, but I think you bring up a very good point. It doesn't make sense why PDI inhibition would be any different in melanomas and melanocytes. This is definitely a good area for future works.
I wonder what the specifics are as to why the drug does not target normal melanocytes. Synthetic lethality can be seen to only target cancer cells, but the ER seems an interesting place to target. I agree that since the drug would be used in combination with other toxic treatments, perhaps good cells are weakened enough to be susceptible to the drug.
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