HIF-2 Complex Dissociation, Target Inhibition, and Acquired Resistance with PT2385, a First-in-Class HIF-2 Inhibitor, in Patients with Clear Cell Renal Cell Carcinoma

Courtney, Kevin D.; Ma, Yuanqing; Leon, Alberto Diaz de; Christie, Alana; Xie, Zhiqun; Woolford, Layton; Singla, Nirmish; Joyce, Allison; Hill, Haley; Madhuranthakam, Ananth J.; Yuan, Qing; Xi, Yin; Zhang, Yue; Chang, Jenny; Fatunde, Oluwatomilade; Arriaga, Yull; Frankel, Arthur E.; Kalva, Sanjeeva P.; Zhang, Song; McKenzie, Tiffani; Torras, Oscar Reig; Figlin, Robert A.; Rini, Brian I.; McKay, Renée M.; Kapur, Payal; Wang, Tao; Pedrosa, Iván; Brugarolas, James

doi:10.1158/1078-0432.ccr-19-1459

Cited by 136 publications

(114 citation statements)

References 54 publications

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“…GAGE analyses also identified a significant downregulation of the gene set HIF-2α Transcription Network, including Epo , Egln1 , Egln3 , Igfbp1, and Pfkfb3 . To further investigate potential overlap with recently defined HIF-2α-dependent genes in human ccRCC, we used a set of 277 genes that were identified as being inhibited specifically in tumour cells in ccRCC tumorgrafts in mice treated with the HIF-2α inhibitor PT2399 25 , 35 . Analyses of the expression levels of the mouse orthologues of this set of HIF-2α target genes revealed that many of these genes are highly upregulated in Vhl ∆/∆ Trp53 ∆/∆ Rb1 ∆/∆ tumours compared to WT cortex, but that the loss of either HIF-1α or HIF-2α did not broadly affect the upregulation of these genes (Supplementary Fig.…”

Section: Resultsmentioning

confidence: 99%

HIF-1α and HIF-2α differently regulate tumour development and inflammation of clear cell renal cell carcinoma in mice

et al. 2020

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Mutational inactivation of VHL is the earliest genetic event in the majority of clear cell renal cell carcinomas (ccRCC), leading to accumulation of the HIF-1α and HIF-2α transcription factors. While correlative studies of human ccRCC and functional studies using human ccRCC cell lines have implicated HIF-1α as an inhibitor and HIF-2α as a promoter of aggressive tumour behaviours, their roles in tumour onset have not been functionally addressed. Herein we show using an autochthonous ccRCC model that Hif1a is essential for tumour formation whereas Hif2a deletion has only minor effects on tumour initiation and growth. Both HIF-1α and HIF-2α are required for the clear cell phenotype. Transcriptomic and proteomic analyses reveal that HIF-1α regulates glycolysis while HIF-2α regulates genes associated with lipoprotein metabolism, ribosome biogenesis and E2F and MYC transcriptional activities. HIF-2α-deficient tumours are characterised by increased antigen presentation, interferon signalling and CD8 + T cell infiltration and activation. Single copy loss of HIF1A or high levels of HIF2A mRNA expression correlate with altered immune microenvironments in human ccRCC. These studies reveal an oncogenic role of HIF-1α in ccRCC initiation and suggest that alterations in the balance of HIF-1α and HIF-2α activities can affect different aspects of ccRCC biology and disease aggressiveness.

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Section: Resultsmentioning

confidence: 99%

HIF-1α and HIF-2α differently regulate tumour development and inflammation of clear cell renal cell carcinoma in mice

et al. 2020

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“…As in other targeted therapy, therapeutic resistance is of a concern. For example, a gatekeeper mutation G323E in HIF-2α was identified to be responsible for PT2385 resistance after prolonged treatment (Courtney et al, 2020). Thus, further insights into the understanding of the MYC-HIF interplay are warranted for developing novel targeted therapeutics.…”

Section: Discussionmentioning

confidence: 99%

“…PT2385 also inhibited HIF-2α-driven gene expression and induced ccRCC tumor regression (Wallace et al, 2016). Recent result from a phase I clinic trial showed response, partial response or stable disease in ∼66% of patients with favorable safety profile and well tolerance for PT2385 (Courtney et al, 2018(Courtney et al, , 2020. Phase II clinic trials for PT2385 are ongoing in ccRCC (NCT03108066) and recurrent glioblastoma (NCT03216499).…”

Section: Targeting Myc-hif Crosstalk For Cancer Therapymentioning

confidence: 99%

Molecular Crosstalk Between MYC and HIF in Cancer

Li¹,

Sun²,

Qian

et al. 2020

Front. Cell Dev. Biol.

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The transcription factor c-MYC (MYC thereafter) is a global regulator of gene expression. It is overexpressed or deregulated in human cancers of diverse origins and plays a key role in the development of cancers. Hypoxia-inducible factors (HIFs), a central regulator for cells to adapt to low cellular oxygen levels, is also often overexpressed and activated in many human cancers. HIF mediates the primary transcriptional response of a wide range of genes in response to hypoxia. Earlier studies focused on the inhibition of MYC by HIF during hypoxia, when MYC is expressed at physiological level, to help cells survive under low oxygen conditions. Emerging evidence suggests that MYC and HIF also cooperate to promote cancer cell growth and progression. This review will summarize the current understanding of the complex molecular interplay between MYC and HIF.

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“…Understanding the transcriptional regulation by HIFs has provided therapeutic targets currently under clinical evaluation 194,195 . Notably, HIF-2α inhibitors are being tested in renal cell carcinoma and pharmacologic inhibition of PHDs is being explored for the treatment of anaemia 196,197 . However, as conveyed in this article, cellular responses to hypoxia go much beyond the transcriptional networks governed by HIFs.…”

Section: Conclusion and Perspectivementioning

confidence: 99%

Cellular adaptation to hypoxia through hypoxia inducible factors and beyond

Lee

Chandel

Simon

2020

Nat Rev Mol Cell Biol

768

613

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Molecular oxygen (O 2) sustains intracellular bioenergetics and is consumed by numerous biochemical reactions, making it essential for most species on Earth. Accordingly, decreased O 2 concentrations (hypoxia) is a major stressor that generally subverts life of aerobic species and is a prominent feature of pathological states encountered in bacterial infection, inflammation, wounds, cardiovascular defects, and cancer. Therefore, key adaptive mechanisms to cope with hypoxia have evolved in mammals. Systemically, these adaptations include increased ventilation, cardiac output, blood vessel growth, and circulating red blood cell numbers. On a cellular level, ATP consuming reactions are suppressed and metabolism is altered until oxygen homeostasis is restored. A critical question is how mammalian cells sense O 2 levels to coordinate diverse biological outputs during hypoxia. The best studied mechanism of response to hypoxia involves hypoxia inducible factors (HIFs), which are stabilized by low oxygen availability and control the expression of a multitude of genes, including those involved in cell survival, angiogenesis, glycolysis, and invasion/ metastasis. Importantly, changes in O 2 can also be sensed via other stress pathways as well as changes in metabolite levels and the generation of reactive oxygen species (ROS) by mitochondria. Collectively, this leads to cellular adaptations of protein synthesis, energy metabolism, mitochondrial respiration, lipid and carbon metabolism as well as nutrient acquisition. These mechanisms are integral inputs into fine tuning the responses to hypoxic stress.

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HIF-2 Complex Dissociation, Target Inhibition, and Acquired Resistance with PT2385, a First-in-Class HIF-2 Inhibitor, in Patients with Clear Cell Renal Cell Carcinoma

Cited by 136 publications

References 54 publications

HIF-1α and HIF-2α differently regulate tumour development and inflammation of clear cell renal cell carcinoma in mice

HIF-1α and HIF-2α differently regulate tumour development and inflammation of clear cell renal cell carcinoma in mice

Molecular Crosstalk Between MYC and HIF in Cancer

Cellular adaptation to hypoxia through hypoxia inducible factors and beyond

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