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Mark Pegram, MD, discusses emerging treatments in HER2-positive breast cancer and his vision for the future of the field.
Mark Pegram, MD
Although tremendous advances have been made in HER2-positive breast cancer, Mark Pegram, MD, says researchers are just getting started.
“Everyone thinks that since we have good therapies for HER2-positive metastatic disease, that our work is done. We are far from finished. Too many patients die from this disease. It’s 20% of breast cancers globally. With metastatic disease, that is a lot of lives,” said Pegram, who spoke on the topic during the 16th Annual International Congress on the Future of Breast Cancer.
In an interview with OncLive at the meeting, Pegram, associate director for clinical research and director of the breast oncology program at Stanford Women’s Cancer Center, discussed emerging treatments in HER2-positive breast cancer and his vision for the future of the field.Pegram: Right now, based on level 1 evidence, we have good data to support the use of pertuzumab (Perjeta) in combination with trastuzumab (Herceptin) and chemotherapy in the first-line setting. That’s usually followed by T-DM1 (ado-trastuzumab emtansine; Kadcyla) in the second-line, based on the EMILIA pivotal trial, which was published in the New England Journal of Medicine just a few years ago. There was also a recent publication with the updated overall survival analysis, which remains significant.
Although EMILIA was not done in the pertuzumab metastatic breast cancer era, we still, by extrapolation, assume that T-DM1 will retain activity. Now there is some literature from retrospective reviews. There was a series recently published in the Journal of Clinical Oncology, suggesting that there is significant clinical benefit in T-DM1—treated patients, even after prior pertuzumab. That sets the stage for the standard of care currently in practice and guidelines. In the third-line, lapatinib (Tykerb)–based regimens are frequently used.
That begs the question what would be next in terms of excitement for HER2-positive disease, or is this current paradigm the end-all and the best we’re going to do for this disease. The answer is that we’re enjoying a renaissance, a tremendous resurgence and interest in HER2-positive disease with many exciting trials and new molecules that are being introduced. For example, there are FC-engineered antibodies, like margetuximab, that have an enhanced immune effector function, meaning greater immunologic responses with an anti-HER2 antibody. That is now in a phase III pivotal trial that is ongoing. It will be interesting if it can beat trastuzumab plus chemotherapy, which is the control arm in a salvage setting in that trial.
There are new, HER2-specific small molecule orally bioavailable tyrosine kinase inhibitors (TKIs). In the past, drugs like neratinib (Nerlynx) and lapatinib, while they hit HER2, they also hit the epidermal growth factor receptor (EFGR), which causes many EGFR toxicities, such as cutaneous toxicity, and GI toxicity that can be particularly problematic. Consequently, the new drug, tucatinib (ONT-380), has less GI and cutaneous toxicity compared to the other HER2 TKIs, which is a consequence of its specificity for HER2 and less overlap with EGFR. That is now in a pivotal phase III trial—an FDA registration trial—that’s going to be exciting if it gets approved. It also has CNS penetration, which is great news.
There are also new antibody-drug conjugates. It turns out, T-DM1 probably won’t be the last HER2 antibody-drug conjugate. It has some limitations, at least in theory, particularly in internalization rates. It turns out that the rate of internalization of the antibody-drug conjugate is very important for its activity in killing tumor targets. It seems that HER2 is a relatively internalization-resistant receptor.
One way to improve the internalization rate is to use a bispecific HER2 antibody that binds to both the pertuzumab epitope and the trastuzumab epitope in subdomains 2 and 4 of the HER2 extracellular domain. Instead of binding to both those epitopes on the same molecule with a bispecific antibody, it actually crosslinks adjacent molecules, setting up a lattice in the membrane, which is a potent stimulus for rapid internalization by receptor-mediated endocytosis.
These new antibody-drug conjugates are in the clinic already. There’s one from MedImmune that’s in phase I at our center and others. There is soon to be one from Zymeworks that has a similar bispecific construct targeting both subdomains 2 and 4 of the HER2 receptor. These are exciting developments and perhaps we’ll have new opportunities with antibody-drug conjugates. There are other ways of augmenting immunity with trastuzumab or with T-DM1. For example, there is some data showing synergism with checkpoint-inhibiting antibodies. That’s an exciting area of new research with ongoing trials with T-DM1.
There are also ways to activate antibody-dependent cellular cytotoxicity using agonist antibodies against CD137. At our center, we have an investigator-initiated trial looking at that combination. There are a lot of developments. This is truly a new renaissance of research in HER2-targeted therapy in the metastatic setting and hopefully, if we win success in metastatic disease, this can be translated into earlier-stage settings in the future. It’s likely that we could conceive of combining some of those strategies together. For example, there’s no reason why you couldn’t give a HER2-specific TKI, like tucatinib, along with a HER2 antibody or an FC engineered HER2 antibody. You could envision giving margetuximab, the FC engineered antibody, along with a CD137 agonist antibody. Perhaps they would synergistically enhance antibody-dependent cell-mediated cytotoxicity activity even more. As I mentioned, the checkpoint antibody combinations are obvious and will be explored thoroughly in the clinic. I suspect that we’ll see more and more combinations of HER2-targeted therapies, rather than just single-agent use for these new therapeutics. There are big challenges, mainly regarding safety signals. With HER2 TKIs, while they are active, they are difficult to give in some situations because of diarrhea. Even with new drugs like tucatinib, even though they have less diarrhea, it's still not zero. We'll still have to be mindful of off-target toxicities, even with the newer agents.
The antibody-drug conjugates, while a breakthrough in terms of tolerability and efficacy, still have some chemo-like side effects. We have to worry about liver function test abnormalities, in the case of T-DM1, we have to worry about thrombocytopenia and neuropathies. I think safety is going to be the biggest hurdle to overcome with any of the new emerging technologies. Certainly, with immunotherapies, we need to worry about off-target autoimmune phenomenon, for example, which is all very concerning. The phase I and phase Ib trials will have to be done very carefully to find the safe and efficacious doses.Biomarkers have been a tough battle in HER2-positive disease and in breast cancer in general, but not for lack of trying. There have been tens of thousands of publications on breast cancer biomarkers, and yet in the clinic we use a select few. I think that will change.
I think circulating tumor DNA will be useful to monitor metastatic disease. For example, you might be able to either decrease or perhaps eliminate the need for restaging imaging studies if you have a quantitation of circulating tumor DNA, which is reflective of total body tumor burden. Hopefully, that will be the case. That’s well positioned and can be tested. In earlier stage disease, I think the circulating tumor DNA isn’t quite sensitive enough for small, node-negative tumors. Maybe for locally advanced, there would be a signal there, but we’ll have to see. I expect the technology will continue to improve. Perhaps another order of magnitude or so in sensitivity would win interest for neoadjuvant or adjuvant therapy situations.
There is a huge list of interesting targets based on TCGA and METABRIC expression array data that’s been around for years. We’re certainly using the expression array subsets of triple-negative disease to inform future clinical trials in that type of breast cancer, and I think the same could be applied in the future of HER2-positive disease. Everyone thinks that since we have good therapies for HER2-positive metastatic disease, that our work is done. We are far from finished. Too many patients die from this disease. It’s 20% of breast cancers globally. With metastatic disease, that is a lot of lives.
There are some metastatic cases that are apparently cured with HER2-positive metastatic disease. We don’t see that often enough, but each of us that have busy practices have seen this more than once. We all have a handful of these subjects. We need to know what's happening in those people and whatever is working those cases. Maybe we can engineer other people to have those same types of responses if we could understand the biology better. I think that's promising. There could be a cure for HER2-positive metastatic disease, in theory, because of these anecdotes that are apparently cured. Something is going on, something very positive, and if we can figure that out, that would offer great hope for all of our patients.