Project description:The RNA methyltransferase METTL3 is responsible for the generation of m6A, the most abundant modification mark on mRNA and long non-coding RNA. Accumulating evidence suggests numerous roles of METTL3 in cancer initiation and progression and highlights the potential for targeting this enzyme in oncology. STC-15 is a potent and selective METTL3 inhibitor and the first RNA modifying enzyme inhibitor to enter human clinical development. It is structurally related to the previously published tool inhibitors STM2457 and STM3675. We previously identified the induction of a cancer cell-intrinsic interferon response following pharmacological inhibition of METTL3, leading to activation of T-cell-mediated anti-tumour response. Here, we profiled m6A levels at nucleotide resolution using GLORI and characterised RNA changes following METTL3 inhibition with STC-15 or STM3675. Following loss of m6A, we uncovered aberrant mRNA transcripts arising from intron retention (IR) and transcriptional run-on (RO) events downstream of m6A-enriched exons in human cancer cells and in tumour samples in vivo. We found that these IR and RO events produce double-stranded RNA and are bound by the cytoplasmic dsRNA sensor MDA5.Using preclinical in vitro and in vivo models, we characterised in detail the anti-tumour immune responses induced by STC-15. Our study reveals how METTL3 inhibition leads to dsRNA accumulation, which triggers a type I interferon response and induces anti-tumour immunity. Together, these findings provide a mechanistic rationale for STC-15 as a novel anti-cancer drug both as monotherapy and in combination with anti-PD1 checkpoint inhibitors.

Project description:The RNA methyltransferase METTL3 is responsible for the generation of m6A, the most abundant modification mark on mRNA and long non-coding RNA. Accumulating evidence suggests numerous roles of METTL3 in cancer initiation and progression and highlights the potential for targeting this enzyme in oncology. STC-15 is a potent and selective METTL3 inhibitor and the first RNA modifying enzyme inhibitor to enter human clinical development. It is structurally related to the previously published tool inhibitors STM2457 and STM3675. We previously identified the induction of a cancer cell-intrinsic interferon response following pharmacological inhibition of METTL3, leading to activation of T-cell-mediated anti-tumour response. Here, we profiled m6A levels at nucleotide resolution using GLORI and characterised RNA changes following METTL3 inhibition with STC-15 or STM3675. Following loss of m6A, we uncovered aberrant mRNA transcripts arising from intron retention (IR) and transcriptional run-on (RO) events downstream of m6A-enriched exons in human cancer cells and in tumour samples in vivo. We found that these IR and RO events produce double-stranded RNA and are bound by the cytoplasmic dsRNA sensor MDA5.Using preclinical in vitro and in vivo models, we characterised in detail the anti-tumour immune responses induced by STC-15. Our study reveals how METTL3 inhibition leads to dsRNA accumulation, which triggers a type I interferon response and induces anti-tumour immunity. Together, these findings provide a mechanistic rationale for STC-15 as a novel anti-cancer drug both as monotherapy and in combination with anti-PD1 checkpoint inhibitors.

Project description:How cancer cells evade immune detection despite expressing immunostimulatory retroelement (RE) transcripts remains an open question in tumour immunology. In cancer cells, endogenous REs that escape histone and DNA silencing are transcribed into RNA and can form double-stranded RNA (dsRNA), triggering innate immune responses through a process known as viral mimicry. However, RNA-level checkpoints can limit this effect. Here, we identify the m6A RNA methyltransferase METTL3 as a key regulator of this suppression in colorectal cancer (CRC). Targeting METTL3 enhances the accumulation of dsRNA derived from both pre-existing and newly transcribed REs, thereby amplifying immunostimulatory signalling and activating cell-intrinsic anti-tumour immunity. Notably, CRCs exhibit differential sensitivity to METTL3 inhibition: tumours with high basal dsRNA levels and RNA methylation respond robustly to METTL3 blockade alone, whereas those with low endogenous dsRNA require combination therapy to achieve comparable immune activation. Co-treatment with DNA methyltransferase inhibitors (DNMTis) restores immune activation in these otherwise resistant tumours. Together, these findings uncover a novel mechanism by which METTL3 functions as an RNA-level immune checkpoint and suggest that combining METTL3 and DNMT inhibition may overcome resistance and serve as an effective therapeutic strategy in CRC.

Project description:How cancer cells evade immune detection despite expressing immunostimulatory retroelement (RE) transcripts remains an open question in tumour immunology. In cancer cells, endogenous REs that escape histone and DNA silencing are transcribed into RNA and can form double-stranded RNA (dsRNA), triggering innate immune responses through a process known as viral mimicry. However, RNA-level checkpoints can limit this effect. Here, we identify the m6A RNA methyltransferase METTL3 as a key regulator of this suppression in colorectal cancer (CRC). Targeting METTL3 enhances the accumulation of dsRNA derived from both pre-existing and newly transcribed REs, thereby amplifying immunostimulatory signalling and activating cell-intrinsic anti-tumour immunity. Notably, CRCs exhibit differential sensitivity to METTL3 inhibition: tumours with high basal dsRNA levels and RNA methylation respond robustly to METTL3 blockade alone, whereas those with low endogenous dsRNA require combination therapy to achieve comparable immune activation. Co-treatment with DNA methyltransferase inhibitors (DNMTis) restores immune activation in these otherwise resistant tumours. Together, these findings uncover a novel mechanism by which METTL3 functions as an RNA-level immune checkpoint and suggest that combining METTL3 and DNMT inhibition may overcome resistance and serve as an effective therapeutic strategy in CRC.

Project description:How cancer cells evade immune detection despite expressing immunostimulatory retroelement (RE) transcripts remains an open question in tumour immunology. In cancer cells, endogenous REs that escape histone and DNA silencing are transcribed into RNA and can form double-stranded RNA (dsRNA), triggering innate immune responses through a process known as viral mimicry. However, RNA-level checkpoints can limit this effect. Here, we identify the m6A RNA methyltransferase METTL3 as a key regulator of this suppression in colorectal cancer (CRC). Targeting METTL3 enhances the accumulation of dsRNA derived from both pre-existing and newly transcribed REs, thereby amplifying immunostimulatory signalling and activating cell-intrinsic anti-tumour immunity. Notably, CRCs exhibit differential sensitivity to METTL3 inhibition: tumours with high basal dsRNA levels and RNA methylation respond robustly to METTL3 blockade alone, whereas those with low endogenous dsRNA require combination therapy to achieve comparable immune activation. Co-treatment with DNA methyltransferase inhibitors (DNMTis) restores immune activation in these otherwise resistant tumours. Together, these findings uncover a novel mechanism by which METTL3 functions as an RNA-level immune checkpoint and suggest that combining METTL3 and DNMT inhibition may overcome resistance and serve as an effective therapeutic strategy in CRC.

Project description:How cancer cells evade immune detection despite expressing immunostimulatory retroelement (RE) transcripts remains an open question in tumour immunology. In cancer cells, endogenous REs that escape histone and DNA silencing are transcribed into RNA and can form double-stranded RNA (dsRNA), triggering innate immune responses through a process known as viral mimicry. However, RNA-level checkpoints can limit this effect. Here, we identify the m6A RNA methyltransferase METTL3 as a key regulator of this suppression in colorectal cancer (CRC). Targeting METTL3 enhances the accumulation of dsRNA derived from both pre-existing and newly transcribed REs, thereby amplifying immunostimulatory signalling and activating cell-intrinsic anti-tumour immunity. Notably, CRCs exhibit differential sensitivity to METTL3 inhibition: tumours with high basal dsRNA levels and RNA methylation respond robustly to METTL3 blockade alone, whereas those with low endogenous dsRNA require combination therapy to achieve comparable immune activation. Co-treatment with DNA methyltransferase inhibitors (DNMTis) restores immune activation in these otherwise resistant tumours. Together, these findings uncover a novel mechanism by which METTL3 functions as an RNA-level immune checkpoint and suggest that combining METTL3 and DNMT inhibition may overcome resistance and serve as an effective therapeutic strategy in CRC.

Project description:How cancer cells evade immune detection despite expressing immunostimulatory retroelement (RE) transcripts remains an open question in tumour immunology. In cancer cells, endogenous REs that escape histone and DNA silencing are transcribed into RNA and can form double-stranded RNA (dsRNA), triggering innate immune responses through a process known as viral mimicry. However, RNA-level checkpoints can limit this effect. Here, we identify the m6A RNA methyltransferase METTL3 as a key regulator of this suppression in colorectal cancer (CRC). Targeting METTL3 enhances the accumulation of dsRNA derived from both pre-existing and newly transcribed REs, thereby amplifying immunostimulatory signalling and activating cell-intrinsic anti-tumour immunity. Notably, CRCs exhibit differential sensitivity to METTL3 inhibition: tumours with high basal dsRNA levels and RNA methylation respond robustly to METTL3 blockade alone, whereas those with low endogenous dsRNA require combination therapy to achieve comparable immune activation. Co-treatment with DNA methyltransferase inhibitors (DNMTis) restores immune activation in these otherwise resistant tumours. Together, these findings uncover a novel mechanism by which METTL3 functions as an RNA-level immune checkpoint and suggest that combining METTL3 and DNMT inhibition may overcome resistance and serve as an effective therapeutic strategy in CRC.

Project description:Therapies that enhance anti-tumour immunity have dramatically changed the natural history of a range of cancers. Consequently, leveraging non-overlapping mechanisms to further increase the immunogenicity of cancer cells remains a major priority. Here, using a novel inhibitor of the RNA methyltransferase, METTL3, we demonstrate that enzymatic inhibition and a global decrease in N6-methyladenosine (m6A) results in double stranded RNA formation and a profound cell-intrinsic interferon response. By monitoring nascent mRNA, we show that the downstream induction of interferon stimulated genes (ISG) is coupled to a global increase in mRNA stability due to decreased m6A. One of the primary sequelae of this process is an increased expression and stability of genes associated with antigen presentation via MHC-I3. With unbiased global CRISPR screens we demonstrate that components of dsRNA sensing and interferon signalling are the primary mediators that potentiate T-cell killing of cancer cells following METTL3 inhibition. As PDL1, a key immune checkpoint, is also induced by interferon3, we show in a range of immunocompetent mouse models that whilst METTL3 inhibition alone is equally efficacious to anti-PD1 therapy, the combination has far greater pre-clinical activity. Importantly, using SPLINTR barcoding4, we demonstrate at single clone resolution that anti-PD1 and METTL3 inhibition target distinct malignant clones and the combination of these therapies augment anti-tumour immunity to overcome clones insensitive to the single agents. Together these data provide the molecular and pre-clinical rationale for employing METTL3 inhibitors to promote anti-tumour immunity in the clinical setting.

Project description:Therapies that enhance antitumor immunity have altered the natural history of many cancers. Consequently, leveraging nonoverlapping mechanisms to increase immunogenicity of cancer cells remains a priority. Using a novel enzymatic inhibitor of the RNA methyl­transferase METTL3, we demonstrate a global decrease in N6-methyladenosine (m6A) results in double-stranded RNA (dsRNA) formation and a profound cell-intrinsic interferon response. Through unbiased CRISPR screens, we establish dsRNA-sensing and interferon signaling are primary mediators that potentiate T-cell killing of cancer cells following METTL3 inhibition. We show in a range of immunocompetent mouse models that although METTL3 inhibition is equally efficacious to anti–PD-1 therapy, the combination has far greater preclinical activity. Using SPLINTR barcoding, we demonstrate that anti–PD-1 therapy and METTL3 inhibition target distinct malignant clones, and the combination of these therapies overcomes clones insensitive to the single agents. These data provide the mole­cular and preclinical rationale for employing METTL3 inhibitors to promote antitumor immunity in the clinic.

Project description:Therapies that enhance antitumor immunity have altered the natural history of many cancers. Consequently, leveraging nonoverlapping mechanisms to increase immunogenicity of cancer cells remains a priority. Using a novel enzymatic inhibitor of the RNA methyl­transferase METTL3, we demonstrate a global decrease in N6-methyladenosine (m6A) results in double-stranded RNA (dsRNA) formation and a profound cell-intrinsic interferon response. Through unbiased CRISPR screens, we establish dsRNA-sensing and interferon signaling are primary mediators that potentiate T-cell killing of cancer cells following METTL3 inhibition. We show in a range of immunocompetent mouse models that although METTL3 inhibition is equally efficacious to anti–PD-1 therapy, the combination has far greater preclinical activity. Using SPLINTR barcoding, we demonstrate that anti–PD-1 therapy and METTL3 inhibition target distinct malignant clones, and the combination of these therapies overcomes clones insensitive to the single agents. These data provide the mole­cular and preclinical rationale for employing METTL3 inhibitors to promote antitumor immunity in the clinic.