Yemin Wang

Prognostic values of molecular subtypes and SWI/SNF protein expression in de‐differentiated/undifferentiated endometrial carcinoma

AimsClassification and risk stratification of endometrial carcinoma (EC) has transitioned from histopathological features to molecular classification, e.g. the ProMisE classifier, identifying four prognostic subtypes: POLE mutant (POLEmut) with almost no recurrence or disease‐specific death events, mismatch repair deficient (MMRd) and no specific molecular profile (NSMP), with intermediate outcome and p53 abnormal (p53abn) with poor outcomes. However, the applicability of molecular classification is unclear in rare but aggressive histotypes of EC, e.g. de‐differentiated and undifferentiated endometrial cancers (DD/UDEC). Here, we aim to assembled a cohort of DD/UDEC from a single institution and analysed the prognostic significance of ProMisE molecular subtypes and the expression of SWItch/sucrose non‐fermentable (SWI/SNF) chromatin remodelling complex members, previously implicated in the pathogenesis of DD/UDEC.Methods and resultsWe accrued 88 DD/UDEC cases, assessed POLE status by Sanger sequencing and performed immunohistochemistry for p53, mismatch repair and SWI/SNF proteins on the tissue microarrays assembled. Assignment of molecular subtypes was possible in 80 tumours; POLE sequencing failed in the remaining eight cases. There were 12 (15%) POLEmut, 44 (55%) MMRd, 14 (17.5%) p53abn and 10 (12.5%) NSMP DD/UDEC. POLEmut DD/UDECs had excellent outcomes, but the other three molecular subtypes all had poor outcomes, with no significant differences among them. The loss of one or more SWI/SNF proteins [AT‐rich interactive domain‐containing protein 1A (ARID1A), ARID1B, SWI/SNF‐related, matrix‐associated, actin‐dependent regulator of chromatin, subfamily A, member 4 (SMARCA4), SMARCA2], observed in 66% (55 of 83) cases, was not of prognostic significance.ConclusionsThese results indicate that all molecular subtypes of DD/UDEC except POLEmut behave in an aggressive fashion. Further study is needed to determine whether these molecular alterations can be targeted with adjuvant therapy, in order to improve outcomes of patients with DD/UDEC.

Establishment and characterization of VOA1066 cells: An undifferentiated endometrial carcinoma cell line

Dedifferentiated endometrial carcinoma (DDEC) is a rare but highly aggressive type of endometrial cancer, in which an undifferentiated carcinoma arises from a low-grade endometrioid endometrial carcinoma. The low-grade component is often eclipsed, likely due to an outgrowth of the undifferentiated component, and the tumor may appear as a pure undifferentiated endometrial carcinoma (UEC). We and others have recently identified inactivating mutations of SMARCA4, SMARCB1 or ARID1B, subunits of the SWI/SNF chromatin-remodeling complex, that are unique to the undifferentiated component and are present in a large portion of DDEC and UEC. However, the understanding of whether and how these mutations drive cancer progression and histologic dedifferentiation is hindered by lack of cell line models of DDEC or UEC. Here, we established the first UEC cell line, VOA1066, which is highly tumorigenic in vivo. This cell line has a stable genome with very few somatic mutations, which do include inactivating mutations of ARID1A and ARID1B (2 mutations each), and a heterozygous hotspot DICER1 mutation in its RNase IIIb domain. Immunohistochemistry staining confirmed the loss of ARID1B, but ARID1A staining was retained due to the presence of a truncating non-functional ARID1A protein. The heterozygous DICER1 hotspot mutation has little effect on microRNA biogenesis. No additional DICER1 hotspot mutations have been identified in a cohort of 33 primary tumors. Therefore, we have established the first UEC cell line with dual inactivation of both ARID1A and ARID1B as the main genomic feature. This cell line will be useful for studying the roles of ARID1A and ARID1B mutations in the development of UEC.

Cystathionine gamma‐lyase‐mediated hypoxia inducible factor 1‐alpha expression drives clear cell ovarian cancer progression

AbstractClear cell ovarian cancer (CCOC) is the second most common ovarian cancer subtype, accounting for 5%–11% of ovarian cancers in North America. Late‐stage CCOC is associated with a worse prognosis compared to other ovarian cancer histotypes, a challenge that has seen limited progress in recent decades. CCOC typically originates within the toxic microenvironment of endometriotic ovarian cysts and is characterized by its intrinsic chemoresistance, a strong hypoxic signature, and abundant expression of cystathionine gamma‐lyase (CTH). CTH is a key enzyme in the transsulfuration pathway and serves as a marker of ciliated cells derived from the Müllerian tract. CTH plays a pivotal role in de novo cysteine synthesis, which is essential for glutathione (GSH) production and redox homeostasis. Using an array of molecular tools and cancer models, including in vivo studies, we demonstrated that CTH expression was induced under various stress conditions, such as exposure to endometriotic cyst content and hypoxia. This induction enables cell survival and creates a differentiation state manifested by CCOC that potentiates tumor progression and metastasis. In addition to regulating redox homeostasis, CTH enhances hypoxia inducible factor 1‐alpha (HIF1α) expression, independently of hydrogen sulfide (H2S) production. Re‐expression of HIF1α in CTH KO cells fully restored metastatic capacity in in vivo models. Co‐expression of CTH and HIF1α proteins was also observed in human CCOC samples. Importantly, targeting CTH in CCOC significantly reduced its metastatic potential in in vivo models and enhanced sensitivity to chemotherapy. These findings underscore that CTH is both a defining feature of CCOC and a promising therapeutic target, not only for CCOC patients but also for those with other CTH‐expressing cancers. © 2025 The Author(s). The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland.

Shifted assembly and function of mSWI/SNF family subcomplexes underlie targetable dependencies in dedifferentiated endometrial carcinomas

The mammalian (m)SWI/SNF family of chromatin remodelers govern cell type-specific chromatin accessibility and gene expression and assemble as three distinct complexes: canonical BRG1-associated or BRM-associated factor (cBAF), poly(bromo)-associated BAF (PBAF) and noncanonical BAF (ncBAF). ARID1A and ARID1B are paralog subunits that specifically nucleate the assembly of cBAF complexes and are frequently co-mutated in highly aggressive dedifferentiated or undifferentiated endometrial carcinomas (DDEC/UECs). Here in cellular models and primary human tumors, we find that ARID1A and/or ARID1B (ARID1A/B) deficiency-mediated cBAF loss results in increased ncBAF and PBAF biochemical abundance and chromatin-level functions to maintain the DDEC oncogenic state. Furthermore, treatment with clinical-grade SMARCA4 and/or SMARCA2 ATPase inhibitors markedly attenuates DDEC cell proliferation and tumor growth in vivo and synergizes with carboplatin-based chemotherapy to extend survival. These findings reveal the oncogenic contributions of shifted mSWI/SNF family complex stoichiometry and resulting gene-regulatory dysregulation and suggest therapeutic utility of mSWI/SNF small molecule inhibitors in DDEC/UECs and other cBAF-disrupted cancer types.

Loss of SMARCA4 Leads to Intron Retention and Generation of Tumor-Associated Antigens in Small Cell Carcinoma of the Ovary, Hypercalcemic Type

Abstract Small cell carcinoma of the ovary, hypercalcemic type (SCCOHT), is a rare, deadly form of ovarian cancer that uniformly harbors mutations in SMARCA4, a member of the SWI/SNF chromatin remodeling complex. SWI/SNF impacts RNA splicing, and dysregulation of splicing can generate immunogenic tumor antigens. In this study, we explored the relationship between SMARCA4 loss and RNA splicing dysregulation. SCCOHT primary tumors harbored tumor-associated outlier splicing events compared with normal tissues. Many of the tumor events were retained introns encoding novel peptides predicted to bind to MHC-I complexes. Immune cells were observed in primary SCCOHT tumors, suggesting a potentially immune-reactive tumor microenvironment. Mutations in several switch/sucrose nonfermenting (SWI/SNF) subunits were associated with higher rates of outlier retained introns across tumor types in The Cancer Genome Atlas data. Interestingly, RNA sequencing of isogenic SCCOHT cell lines demonstrated a role for SMARCA4 in intron retention (IR). Distinct protein–protein interactions between splicing factors identified in SCCOHT cell lines supported a role for SMARCA4 in splicing regulation. Furthermore, SWI/SNF localized to genes, which were differentially spliced. Mass spectrometry analyses confirmed expression of some of these novel peptides, and a subset of these are predicted to bind to MHC-I complexes. A pool of these novel peptides derived from retained introns in SCCOHT triggered proliferation and expression of TNFα and INFγ in primary human T cells. Together, these data suggest that SMARCA4 loss in SCCOHT leads to IR. Furthermore, T-cell activation by novel peptides encoded by these tumor-specific splicing events suggests IR could be a source of tumor-associated antigens in SCCOHT. Significance: SCCOHT, a rare ovarian cancer, features splicing dysregulation due to SMARCA4 loss that generates immunostimulatory peptides linked to potential immune responses and therapeutic avenues, challenging traditional views of the role of SMARCA4.

SMARCA4 Loss Increases RNA Polymerase II Pausing and Elevates R-Loops to Inhibit BRCA1-Mediated Repair in Ovarian Cancer

Abstract Small cell carcinoma of the ovary, hypercalcemic type (SCCOHT) is a rare, aggressive cancer affecting young women driven by inactivating mutations in SMARCA4, a key SWI/SNF chromatin remodeling gene. To uncover its druggable vulnerabilities, we performed a compound screen and found that SCCOHT cells and tumors were sensitive to PARP inhibitors. Paradoxically, SCCOHT displayed BRCA-deficient traits despite retaining wild-type BRCA1 expression. Elevated R-loop in SCCOHT sequestered BRCA1, limiting its availability for DNA damage repair. Proximity-dependent biotin identification revealed that wild-type SMARCA4, but not its pathogenic variants, promoted RNA polymerase II (Pol II) elongation by mediating the assembly of the polymerase-associated factor 1 complex. Thus, SMARCA4 loss increased Pol II pausing, resulting in elevated R-loops and BRCA1 redistribution. The suppression of BRCA1 activity sensitized SMARCA4-deficient SCCOHT cells and tumors to PARP inhibitors, which was further enhanced by the addition of a CDK9 inhibitor targeting Pol II elongation. Cotargeting PARP/CDK9 also elicited synergistic effects against other undifferentiated ovarian cancer cells with SMARCA4 loss. These findings link SMARCA4 loss to perturbed Pol II elongation and compromised DNA repair by BRCA1, providing a therapeutic opportunity to target SCCOHT and other SWI/SNF-deficient ovarian cancers. Significance: Pol II stalling induced by SMARCA4 loss leads to R-loop accumulation that sequesters BRCA1 to transcription complexes, underlying the sensitivity of SMARCA4-deficient ovarian cancers to inhibitors targeting PARPs and Pol II elongation.