Prostate cancer that spreads to the bone triggers the destruction of bone tissue that, in turn, thwarts the effectiveness of immune checkpoint inhibitors by blocking the development of T cells that are crucial to successful treatment, researchers report in Cell.
The discoveries explain why immunotherapy has been largely unsuccessful against prostate cancer bone metastases and point to a possible combination that could reverse the resistance. Their findings also highlight the need to look at metastatic cancer in a different light.
"We tend to think of stage 4 disease as being uniform, but it's not all the same," the senior author says. "We need to be more thoughtful about the immune microenvironment in different areas of metastasis to take into account different immune responses in those microenvironments when we develop treatments."
The team found that the bone destruction caused by tumors leads to massive production of transformational growth factor-beta (TGF-β), a protein that causes helper T cells to polarize into Th17 CD4 cells instead of the Th1 CD4 effector cells required to trigger an anti-tumor immune response.
Combining anti-TGF-β treatment with an inhibitor of the CTLA-4 checkpoint on T cells stifled growth of bone metastases in a mouse model. "We're working to develop a combination clinical trial of anti-CTLA-4 and anti- TGF-β for metastatic prostate cancer," the senior author says.
A majority of men with prostate cancer have their cancer progress to metastatic castration-resistant disease, which is almost uniformly lethal. About 70-80% of men with stage 4 prostate cancer develop bone metastases. While recent research by the authors showed that a combination of anti-CTLA-4 (ipilimumab) and anti-PD-1 (nivolumab) checkpoint inhibitors helps some men with stage 4 prostate cancer, it largely failed against bone metastasis.
To understand this issue, the team first examined pre- and post-treatment bone marrow from patients for clues about treatment resistance. They further explored their observations in mouse models of metastatic prostate cancer and tested combination therapies - "reverse translation" of their findings from people.
When it works, immune checkpoint blockade expands Th1 CD4 effector cells, which leads to activation of killer CD8 T cells and generation of long-term memory cells.
The team found plenty of Th1 effectors in the soft tissues of patients treated with ipilimumab, but these crucial cells were largely absent in the bones, where they instead found abundant Th17 cells.
"The important point here is the absence of the Th1 cells," the senior author notes. Cytokines polarize helper cells to different types, and in the bone microenvironment they produce an abundance of Th17 cells. The function of the Th17 cells there is not known.
The team developed two mouse models of metastatic disease - one that represented bone metastases and a subcutaneous model that represented primary prostate cancer or soft-tissue metastases.
As in humans, treatment with ipilimumab and nivolumab combination shrank tumors and extended survival of the mice with soft-tissue metastases but had minimal effects on the tumors and survival of those with bone metastases.
Treatment expanded tumor infiltrating CD4 and CD8 T cells in both soft tissue and bones, but failed to inhibit growth of bone tumors. Mass cytometry analysis of the T cells showed why. The CD4 T cells in the bone tumors were only of the Th17 and regulatory T cell (Treg) lineages. Tregs inhibit immune response. There were no Th1 effector cells.
In the subcutaneous model, Th1 effectors were detected before treatment and then greatly increased after treatment while Th17 and Tregs decreased.
Lack of Th1 cells in the bone marrow suggested a distinct cytokine profile in the bone microenvironment. The team analyzed levels of 13 cytokines in the tumor-bearing and tumor-free femurs of the mice.
They found significant elevation of TGF-β, known to restrain Th1 lineage and drive both Th17 and Treg development. Th17 also requires the presence of Interleukin-6, which was found abundantly, as expected, in the bone marrow.
Bone metastasis triggers abnormal bone remodeling, and bone components are known as a major reservoir of TGF-β. The team hypothesized that bone matrix remodeling causes the high TGF-β levels in prostate bone metastases. Their experiments confirmed that osteoclasts - cells that degrade bone - activated by tumors release excessive amounts of TGF-β while they erode bone surfaces.
To test the hypothesis in humans, they compared TGF-β levels in the bone marrow of healthy donors and prostate cancer patients with and without bone metastases. There was no difference in TGF-β levels between healthy controls and patients without bone metastases, while patients with bone tumors had aberrantly high levels of TGF-β in their bones. Treating mice with bone metastases with the ipilimumab and nivolumab combination failed to stop tumor growth. But adding anti- TGF-β to the immunotherapy combination halted tumor growth.
Anti- TGF-β and ipilimumab alone also stifled bone metastasis growth. This combination also increased the frequency of Th1 cells and decreased Tregs in the bone microenvironment.
Prostate cancer bone metastases thwart immunotherapy by producing TGF-beta
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