Abstract
Simple SummaryProstate cancer is the principal cause of cancer-related mortality in men. While localized tumors can be successfully treated by orchiectomy or medical castration, most of the patients ultimately progress to the castration-resistant prostate cancer (CRPC) stage, which is incurable at present. Thus, uncovering the underlying mechanisms that cause CRPC could result in promising therapeutics. Our laboratory has identified LIMK2 kinase as an actionable target for CRPC. LIMK2 is vastly expressed in CRPC but minimally in normal prostates. LIMK2 knockout mice are healthy, indicating that LIMK2 inhibition should have minimal toxicity. LIMK2 is also expressed in other aggressive cancers; however, the molecular mechanisms leading to malignancy remain mostly unknown. This study identified that LIMK2 downregulates a prostate-specific tumor suppressor protein-NKX3.1 using two mechanisms. NKX3.1 loss is strongly associated with prostate cancer. Thus, LIMK2 inhibitor provides a powerful opportunity to rescue NKX3.1 loss, thereby preventing and/or delaying prostate cancer progression.NKX3.1’s downregulation is strongly associated with prostate cancer (PCa) initiation, progression, and CRPC development. Nevertheless, a clear disagreement exists between NKX3.1 protein and mRNA levels in PCa tissues, indicating that its regulation at a post-translational level plays a vital role. This study identified a strong negative relationship between NKX3.1 and LIMK2, which is critical in CRPC pathogenesis. We identified that NKX3.1 degradation by direct phosphorylation by LIMK2 is crucial for promoting oncogenicity in CRPC cells and in vivo. LIMK2 also downregulates NKX3.1 mRNA levels. In return, NKX3.1 promotes LIMK2’s ubiquitylation. Thus, the negative crosstalk between LIMK2-NKX3.1 regulates AR, ARv7, and AKT signaling, promoting aggressive phenotypes. We also provide a new link between NKX3.1 and PTEN, both of which are downregulated by LIMK2. PTEN loss is strongly linked with NKX3.1 downregulation. As NKX3.1 is a prostate-specific tumor suppressor, preserving its levels by LIMK2 inhibition provides a tremendous opportunity for developing targeted therapy in CRPC. Further, as NKX3.1 downregulates AR transcription and inhibits AKT signaling, restoring its levels by inhibiting LIMK2 is expected to be especially beneficial by co-targeting two driver pathways in tandem, a highly desirable requisite for developing effective PCa therapeutics.
Highlights
This study focuses on the tumor-suppressor NKX3.1, which was uncovered as a direct substrate of LIM kinase2 (LIMK2) using an inventive screen [11,12,13]
Analog-Sensitive LIMK2 (LIMK2-as7) Identifies NKX3.1 as a Direct Target
Our IF data showed that LIMK2 does not regulate the subcellular localization of NKX3.1, we investigated whether phosphorylation-resistant HA-tagged
Summary
Androgen deprivation therapy (ADT), which inhibits the androgen receptor (AR) signaling, is considered the gold standard treatment for PCa. ADT has a temporary effect and most of the patients develop castration-resistant prostate cancer (CRPC) [3]. LIMK2 is upregulated in multiple other cancers and promotes tumorigenesis and metastasis [5,6,7,8]. Despite these reports, the downstream mechanisms by which LIMK2 induces malignancy are largely unknown as only a few of its substrates are known to date. This study focuses on the tumor-suppressor NKX3.1, which was uncovered as a direct substrate of LIMK2 using an inventive screen [11,12,13]. We uncovered a key bidirectional relationship between LIMK2 and NKX3.1, which plays a critical role in CRPC progression
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