The drug, a “prodrug” version of the glutamine antagonist DON, was designed so that the active form of the drug is functional within the tumor. In theory, this compound could be used across a wide spectrum of cancer types, says Jonathan Powell, M.D., Ph.D., associate director of the Bloomberg~Kimmel Institute for Cancer Immunotherapy at the Johns Hopkins Kimmel Cancer Center, and colleagues due to the critical role of glutamine in promoting the metabolism necessary for prodigious tumor growth.
Their study, published online Nov. 7 in Science, reveals surprising differences in the metabolic pathways fueling cancer cells and effector T cells, pathways that were thought previously to be very similar. These differences could be exploited as a “metabolic checkpoint” in treating cancer, Powell says.
“By targeting glutamine metabolism, we were not only able to inhibit tumor growth and change the tumor microenvironment, but also alter the T cells in a way that we markedly enhanced immunotherapy for cancer,” he says.
Although glutamine metabolism is a component of all cells of the body, the DON prodrug selectively targeted tumor cells because they are the “hungriest” for glutamine, said Powell. “What’s emerging in metabolic therapy — and to me this is why it’s incredibly exciting — is that a treatment like ours becomes selective because it preferentially affects the cells that have the greatest demand.”
Powell and colleagues tested the DON prodrug, dubbed JHU083, in mice models of colon cancer, lymphoma and melanoma.
“In the beginning, our thought was that if we could target tumor metabolism, we could achieve two goals: slow tumor growth and alter the tumor microenvironment,” says Powell. The tumor microenvironment — the cells, blood vessels and nutrients in the vicinity of tumors — is very hostile to the immune response because it is usually acidic, hypoxic and nutrient-depleted. “This immune shield that the tumor creates around itself is in a sense a direct result of tumor metabolism,” he says.
In mice, treatment with JHU083 led to a significant decrease in tumor growth and improved survival in many different cancer models, by derailing tumor cell metabolism and its effects on the tumor microenvironment, the research team found. In a number of the mice, treatment with JHU083 alone led to durable cures. These cures were facilitated because the metabolic therapy unleashed the natural anti-tumor immune response. When the researchers reinjected these cancer-free mice with new tumors, they found that almost all the mice rejected the new tumor, suggesting that the JHU083 treatment had produced a powerful immune memory to recognize and attack the new cancer.
They also treated the mice with JHU083 and an anti-PD-1 checkpoint inhibitor, a type of immunotherapy drug that removes restraints cancer cells place on immune cells. “Initially, we thought we would need to use the two therapies sequentially in order to avoid any potential impact of the metabolic therapy on the immunotherapy,” says Powell. “Remarkably, however, it turned out that the combined treatment worked best when we gave them simultaneously.” Concurrent treatment with the drugs produced improved anti-tumor effects compared with anti-PD-1 therapy alone.
“We found that JHU083 was having a very positive, very direct effect on the immune cells, and we had to investigate why,” Powell said.After analyzing and comparing gene expression in the treated tumor cells and a type of immune cell called effector T cells, Powell and colleagues noted differences in gene expression related to metabolism, which allowed them to guess at how the T cell was fueling itself compared with the tumor.
They found some similarities, but fundamentally the metabolic programming of tumor cells and the effector T immune cells was quite different, and it is those differences the researchers exploited by giving the glutamine-blocking drug.
The differences allowed the effector T cells to respond to the glutamine blockage by producing long-lasting, highly effective tumor-infiltrating T cells that seemed to be invigorated rather than exhausted in the tumor microenvironment. “By blocking glutamine metabolism, we were making these cells more persistent, more like an immune memory cell,” Powell noted.
The group also demonstrated that treating the tumors with JHU083 enhanced the efficacy of adoptive cellular therapy, a type of immunotherapy in which immune T cells are collected and grown in large numbers in the laboratory before being given to patients to boost the immune response against cancer. These findings suggest that this new approach may also be used to enhance a promising type of adoptive cell therapy called CAR-T. In future studies, Powell and colleagues want to examine how JHU083 combines with different types of immunotherapy to explore whether certain tumors can overcome the metabolic trap laid by JHU083.
Potentially, tumors that develop metabolic pathways to avoid the impacts of JHU083 could find themselves in a “blind alley,” said Powell. “By adding an additional metabolic antagonist, you could potentially get rid of the resistant tumors as well.”
Other Johns Hopkins researchers involved in the study were Robert D. Leone, Liang Zhao, Judson M. Englert, Im-Meng Sun, Min-Hee Oh, Im-Hong Sun, Matthew Arwood, Ian A. Bettencourt, Chirag H. Patel, Jiayu Wen, Ada Tam and Richard Blosser at the Bloomberg~Kimmel Institute for Cancer Immunotherapy, and Eva Prchalova, Jesse Alt, Rana Rais and Barbara Slusher at Johns Hopkins Drug Discovery.
The research was supported by the National Institutes of Health (R01CA226765, R01CA229451) and The Bloomberg∼Kimmel Institute for Cancer Immunotherapy.
Powell, Slusher and Rais are scientific founders, paid consultants (Powell and Slusher) and have equity in Dracen Pharmaceuticals. Technology arising in part from the studies described herein were patented by The Johns Hopkins University and subsequently licensed to Dracen Pharmaceuticals (JHU083 is currently labeled as DRP-083). Leone, Englert, Slusher, Rais, Alt and Powell are inventors for pending patent application no. PCT/US16/44829, submitted by The Johns Hopkins University, which covers the use of glutamine analogues, including ones such as JHU083 (DRP-083) for cancer immunotherapy.
Journal Reference:
RAPAMYCIN ---The mechanistic target of rapamycin (mTOR) pathway has a central role in cell activation...
METFORMIN -- The diabetes drug metformin used by some for anti-aging may diminish benefits of aerobic exercise...
QUERCETIN-- AND WITH DASATINIB--The senolytic cocktail, dasatinib plus quercetin, which causes selective elimination of senescent cells...
FISETIN--Of the 10 flavonoids tested, fisetin was the most potent senolytic...
EGCG- The most active component of green tea....
NAD BOOSTERS --'...The cells of the old mice were indistinguishable from the young mice, after just one week of treatment...
SULFORAPHANE-- An isothiocyanate present in cruciferous vegetables activates antioxidant and anti-inflammatory responses by ...
UROLITHIN --Metabolite of Pomegranate compound with anti-aging effects passes human trial...
MITO-Q -- A water soluble fomr of CoQ10 that has excellent absorption and high bioavailability...
HONOKIOL - A bioactive natural product derived from Magnolia Bark have demonstrated ...
CURCUMIN AND ANALOGS -Recent research is focused on the design and synthesis of curcumin analogs as antiproliferative and anti-inflammatory agents...
BERBERINE --berberine has recently been reported to expand life span in Drosophila melanogaster, and attenuate premature cellular senescence
N-ACETYL-CYSTINE (NAC)--"...pretreatment with NAC increased glutathione levels in the older cells and largely helped offset that level of cell death..."
PIPERLONGUMINE - A natural product from the Long pepper with high bioavailability...
RESVERATROL AND PTEROTSILBINE -- Pterostilben chemically similar to resveratrol bute differs from resveratrol by exhibiting increased bioavailability (80% compared to 20% in resveratrol)
SPERMIDINE--Spermidine delays aging in humans ...
ALLICIN -- Allicin is a compound produced when garlic is crushed or chopped. ...
VITAMIN D3 -- Production of the active forms of Vitamin D are reduced by 50% as a result of an age-related decline
VITAMIN K-- evidence suggests vitamin K has an anti-inflammatory action
TOCOTRIENOL(AND WITH QUERCETIN) --Tocotrieniols have been found to exert a synergistic antitumor effect on cancer cells when given in combination....
HSP-90 INHIBITORS --As a novel class of senolytics