Genetics
Loss of Tumor-Infiltrating Lymphocytes and Poor Response to Immunotherapy in IDH GOF Mutant Melanoma
Abstract
Recent innovations in melanoma treatment with immune checkpoint blockade (ICB) have improved overall outcomes for patients, however over 50% of patients still develop resistance to treatment. These patients either have intrinsic resistance, and never respond to therapy, or develop acquired resistance months or years into treatment. The mechanisms underlying ICB resistance remain poorly understood. Our data shows that isocitrate dehydrogenase gain of function (IDH GOF) mutant melanoma patients have a worse response to anti-PD1 immunotherapy. IDH mutations have been found to be oncogenic and associated with differential methylation in multiple cancers but are not yet characterized in human melanoma. Here, we investigate the clinical, immune, and transcriptional phenotypes of IDH GOF melanomas through analyses of clinical response, single-cell RNA sequencing, bulk RNA sequencing, and DNA methylation data. Single-cell data analysis shows decreased immune infiltrate and activity in the IDH GOF tumors. Bulk sequencing data demonstrates the association between IDH mutation, immune exclusion, and disruptions in global DNA methylation. The melanoma-derived genomic data presented supports previously described resistance mechanisms of IDH mutation in other cancer types and is the first demonstration of the role of IDH GOF in the human melanoma tumor microenvironment.
Authors
Emma Specht, Lakshmi Pakanati, Meng-Ju Wu, Russell W. Jenkins, Derek N. Effiom, Nabeel Bardeesy, Bradley E. Bernstein, Moshe Sade-Feldman, Christine G. Lian, Genevieve M. Boland, Elena Torlai Triglia, Sonia Cohen
Abstract
X-linked myotubular myopathy (XLMTM) is a rare genetic disorder that typically presents at birth with progressive muscle weakness and respiratory difficulties and is caused by myotubularin-1 (MTM1) gene mutations. Here we examine the role of phosphatidylinositol-4-phosphate 3-kinase catalytic subunit type 2 beta (PIK3C2B), a lipid kinase that interacts with MTM1, in XLMTM in various models. We examined the effect of BLU3797, a novel, highly potent, selective, orally bioavailable PIK3C2B inhibitor, on survival, muscle development, myofiber phenotypes, and gene expression in MTM1-/y mice. PIK3C2B-deficient XLMTM animals demonstrated increased survival, restored muscle function, fewer myofibers with centralized nuclei, and normalization of disease-associated molecular markers. BLU3797 alleviated the XLMTM phenotype in a dose-dependent and reversible manner. Loss of functional PIK3C2B in XLMTM mice promoted a more differentiated, adult-like myofiber profile, which was strongly associated with normalization of disease surrogates and a reduction in markers of early muscle development and regeneration. BLU3797 treatment appears to modulate the expression of microRNAs associated with satellite cell activation and myofiber fusion. These findings indicate that PIK3C2B inhibition with BLU3797 effectively reverses the XLMTM disease phenotype by enhancing muscle function and promoting development toward a more mature state.
Authors
Andrew Shearer, Melissa L. Brooks, Maxine M. Chen, Thiwanka Samarakoon, John Hsieh, Gramoz Kondakci, Emanuele Perola, Jason Brubaker, Kristina Fetalvero, Stefanie Schalm, Joana Caetano-Lopes
Abstract
VIC-1911 (formerly TAS-119) is a next-generation, ATP-competitive Aurora kinase A (AURKA) inhibitor with a favorable biosafety profile. However, it has not been evaluated in prostate cancer (PC), wherein AURKA is highly expressed in advanced stages and represents a critical therapeutic target. Here, we demonstrate that VIC-1911 potently inhibits AURKA activity with high selectivity over AURKB/C across diverse PC cell lines. Treatment with VIC-1911, even at nanomolar concentrations, substantially inhibits the growth of both androgen receptor (AR)-positive and AR-negative PC cells. VIC-1911 triggers mitotic failure, induces DNA double-strand breaks (DSBs), and activates the p53 pathway, halting cell division and inducing cell death. Notably, VIC-1911 showed synergistic effects in inhibiting PC cell growth in vitro and xenograft tumor growth in vivo with poly (ADP-ribose) polymerase inhibitors (PARPi), which have proven effective in PC with a deficiency in Homologous Recombination (HR) repair. Mechanistically, VIC-1911 disabled HR-mediated repair of DSBs in otherwise HR-proficient PC cells, leading to a “BRCAness” phenotype and pronounced accumulation of DNA damage and mitotic catastrophe. In summary, our study uncovers what we believe a novel mechanism to functional “BRCAness” by inducing mitotic arrest and highlights VIC-1911 as a promising therapeutic agent for advanced PC, either as a single agent or in combination, sensitizing HR-proficient tumors to PARP inhibitors.
Authors
Galina Gritsina, Sandip Kumar Rath, Hongshun Shi, Qi Chu, Wanqing Xie, Que Thanh Thanh Nguyen, Sambhavi Senthil, Thomas J. Myers, Mehmet A. Bilen, Sarah E. Fenton, Maha Hussain, David S. Yu, Jonathan C. Zhao, Jindan Yu
Abstract
Spinal muscular atrophy (SMA) is a devastating neuromuscular disorder caused by mutations in the survival motor neuron 1 (SMN1) gene leading to decreased SMN protein levels and motor neuron dysfunction. SMN-restoring therapies offer clinical benefit, but the downstream molecular consequences of SMN reduction remain incompletely understood. SMN deficiency resulted in downregulation of kinesin heavy chain isoform 5A (KIF5A) in human neurons and in a mouse model of SMA. SMN associated with KIF5A mRNA and contributed to its stability. Reduced SMN levels impaired axon regeneration, which was rescued by KIF5A overexpression. Because KIF5A has also been connected to ALS, these findings provide evidence of a molecular link between SMA and ALS pathophysiology, highlighting KIF5A as an SMN regulated factor. Our findings suggest SMN-independent interventions targeting KIF5A could represent a complementary therapeutic approach for SMA and other motor neuron diseases.
Authors
Tetsuya Akiyama, Yi Zeng, Caiwei Guo, Olivia Gautier, Lauren Koepke, Heankel Lyons, Elana Molotsky, Juliane S. Bombosch, Odilia Sianto, Jay P. Ross, Phuong Hoang, Luke Zhao, Cole Spencer, Charlotte J. Sumner, Michelle Monje, John W. Day, Aaron D. Gitler
Abstract
A large inter-individual variability in weight loss outcomes following bariatric surgery is reported. To ensure optimal patient management, it is crucial to accurately identify those most likely to benefit from the intervention. Since genetic variants largely contribute to surgery response, polygenic scores (PGS) derived from genome-wide association studies (GWAS) could constitute valuable tools for clinical decision making. We developed and evaluated PGS to predict the weight loss response in 540 patients with body mass index (BMI) ≥35kg/m2 who underwent biliopancreatic diversion with duodenal switch. Summary statistics derived from BMI-derived GWAS, together with summary statistics from previously published GWAS of BMI and adiposity features, were used to construct, evaluate, and benchmark weight-loss PGS. The full-adjusted BMI PGS model built in the entire cohort explained 39.6% of the mean-over-time excessive body weight loss (%EBWL), while the BMI-PGS built in the training dataset explained 38.9%. All benchmarked PGS based on BMI showed a significant relationship with mean-over-time %EBWL. These findings highlight the potential of BMI PGS in predicting weight loss after bariatric surgery and support their use as promising tools to improve the effectiveness of future anti-obesity treatments. Funding: Canadian Institutes of Health Research (PJT-168876).
Authors
Bastien Vallée Marcotte, Juan de Toro-Martín, André Tchernof, Louis Pérusse, Simon Marceau, Marie-Claude Vohl
Abstract
Cutaneous radiation injury is an unintended consequence of radiotherapy for many common cancers and can progress to debilitating radiation-induced skin fibrosis (RISF). Existing radiation injury models do not fully capture the skin toxicities observed in patients, contributing to the lack of efficacious therapies to mitigate RISF. To address this, we developed an ex vivo human skin model that recapitulates the temporal radiation injury and RISF response. Human skin explants (N=12) subjected to ionizing radiation demonstrated DNA double-strand breaks and robust p53-driven transcriptional programming of cell cycle arrest, apoptosis, and senescence compared to non-irradiated controls. Irradiated skin also exhibited induction of pro-inflammatory cytokines, epithelial-mesenchymal transition, pro-fibrotic TGF-beta1 (TGFB1)-mediated signaling, and thickened collagen over time. P53 regulators murine double minute 2 (MDM2) and microRNA (miR)-34a were induced post-irradiation and may be leveraged to modulate injury response. Notably, RNA-sequencing of breast skin from mastectomy patients post-radiotherapy showed similar p53, inflammatory, and TGFB1 signatures as the ex vivo model, supporting its translational relevance. Together, this model provides a platform for identifying biomarkers and testing therapies to prevent or mitigate cutaneous radiation toxicities. Targeting the dynamic p53-driven pro-fibrotic radiation response represents a new therapeutic avenue to improve post-radiotherapy quality of life for cancer survivors.
Authors
Caroline Dodson, Sophie M. Bilik, Gabrielle DiBartolomeo, Hannah Pachalis, Lindsey G. Siegfried, Jordan A. K. Johnson, Seth R. Thaller, Irena Pastar, Marjana Tomic-Canic, Anthony J. Griswold, Rivka C. Stone
Abstract
Myotonic Dystrophy Type 1 (DM1) is caused by an expanded CTG repeat in the DMPK gene, resulting in mutant transcripts that form expanded CUG (CUGexp) RNA foci and sequester muscleblind-like (MBNL) RNA-binding proteins. DM1 is multisystemic with progressive worsening of disease manifestations in affected tissues. Disease progression is attributed to somatic expansion of the CTG repeats with age, resulting in production of CUGexp RNA with enhanced intrinsic toxicity due to increased MBNL sequestration. To determine the degree to which cardiac disease progression can occur independently of repeat expansion, we used a transgenic DM1 mouse model with inducible heart-specific expression of a stable, interrupted 960-CUG repeat RNA. Sustained CUGexp RNA expression caused progressive cardiac enlargement, contractile dysfunction, conduction delay, myocardial fibrosis, and reduced survival, while MBNL-dependent splicing defects remained static, consistent with the stable repeat length. We also determined the degree of reversibility after different periods of CUGexp RNA expression by shutting off the repeat-containing transgene. Suppression of CUGexp RNA expression rescued cardiac abnormalities, but reversibility declined with longer exposure to the toxic RNA. These findings demonstrate that prolonged expression of stable CUGexp RNA drives progressive cardiac pathology, revealing a mechanism of disease progression in DM1 in addition to somatic expansion.
Authors
Rong-Chi Hu, Mohammadreza Tabary, Xander H.T. Wehrens, Thomas A. Cooper
Abstract
Sleep disturbance is a prevalent yet poorly understood comorbidity in autism spectrum disorders (ASD). Here, we uncover a bidirectional regulatory axis connecting the ASD risk gene POGZ to core circadian mechanisms. We demonstrate that Pogz is widely expressed in the suprachiasmatic nucleus (SCN), the central pacemaker of the circadian rhythms and exhibits circadian oscillations in both the hypothalamus and liver with its transcription directly regulated by the circadian molecule DBP through a D-box element in its proximal enhancer. Pogz-deficient mice exhibited prolonged circadian periodicity, impaired light-induced phase shift, delayed adaption to an 8-hour advance jet-lag, and reduced SCN c-Fos activation in response to light pulses. Mechanistically, POGZ interacts with and enhances the transcription activity of CREB, a key regulator of light-induced phase resetting. Notably, Pogz deletion leads to ASD-related deficits in social novelty and cognition, with cognitive impairments influenced by both photoperiod and behavioral paradigm. Our findings thus reveal a critical, previously unrecognized intersection between an ASD risk gene and circadian clock, offering new insights into the pathogenesis of core ASD symptoms and comorbid sleep disturbances.
Authors
Ting Wu, Jiao He, Chu-Jun Xu, Chi-Yu Li, Pingchuan Zhang, Yanfeng Wang, Shanshan Zhu, Lusi Zhang, Jingtan Zhu, Jing Zhang, Jia-Da Li, Huadie Liu
Abstract
BACKGROUND In chronic alcohol consumers, immune cells may drive the progression from mild liver injury to more severe alcohol-associated liver diseases (ALD), including alcohol-associated hepatitis (AAH) and cancer. Liver macrophages, both resident and infiltrating, express Allograft Inflammatory Factor 1 (AIF1), which is upregulated during inflammation and enhances immune activation. METHODS Using serum and urine samples from 868 individuals classified as having alcohol use disorder or not based on DSM-IV/V criteria, along with serum and liver biopsy tissue from a second cohort of 27 patients diagnosed with AAH, we evaluated the impact of the AIF1 promoter single nucleotide polymorphism (SNP) (rs3132451; C/C, C/G, G/G) on liver function markers and immune cell profiles. RESULTS AIF1 transcript levels were genotype-dependent: C/C homozygotes expressed 5.2% of the levels observed in G/G individuals, while C/G heterozygotes expressed 46%. Unlike most SNPs associated with harmful effects, the G/G genotype is highly prevalent, present in ~70% of patients. Among chronic alcohol users, G/G individuals exhibited elevated markers of liver injury and a more than threefold increase in hepatic immune cells, including infiltrating AIF1⁺ macrophages and neutrophils. Despite similar durations of alcohol misuse, G/G individuals had higher Model for End-Stage Liver Disease scores compared to C/G individuals, indicating a significantly greater 90-day mortality risk. Notably, some immune abnormalities, such as elevated neutrophils, persisted in G/G males even after alcohol abstinence. CONCLUSION These findings suggest that functional genetic variation in AIF1 may contribute to the severity and persistence of ALD. TRIAL REGISTRATION ClinicalTrials.gov NCT02231840. FUNDING Research support was provided from the National Institute on Alcohol Abuse and Alcoholism (NIAAA) of the National Institutes of Health (NIH) under grant 1ZIAAA000440-02 and R24AA025017.
Authors
Priscila C. Antonello, Colin A. Hodgkinson, Dechun Feng, Cheryl Marietta, Baskar Mohana Krishnan, Maria A. Parra, Zhaoli Sun, Bin Gao, David Goldman, Michelle W. Antoine
Abstract
Next-generation sequencing technologies are increasingly used to diagnose genetic disorders, particularly immunological diseases with broad and overlapping immune dysregulation. Cryopyrin-associated periodic syndromes (CAPS) are caused by gain-of-function mutations in NLRP3 and include 3 autoinflammatory diseases spanning a continuum of severity: familial cold autoinflammatory syndrome (FCAS), Muckle-Wells syndrome (MWS), and neonatal-onset multisystem inflammatory disease (NOMID). Linking NLRP3 variants to protein dysfunction and clinical phenotype remains challenging because of genetic modifiers and environmental factors. We report the generation and phenotyping of 5 mouse lines expressing either the common human NLRP3 allele or 1 of 4 CAPS mutations spanning the disease spectrum from FCAS to NOMID. In these lines, the murine Nlrp3 locus is replaced by syntenic integration of the human NLRP3 locus, yielding 1 line with the common allele and 4 lines each carrying a distinct CAPS mutation. Unlike models in which a human mutation is introduced into the mouse protein, these lines recapitulate the spectrum of disease severity observed in humans. These findings support a model in which evaluation of nonsynonymous mutations in mice is optimized when introduced in the context of the human gene. This suggests that species-specific regulation and/or intramolecular epistasis may impact modeling of disease-associated variants.
Authors
John N. Snouwaert, MyTrang Nguyen, Christopher A. Gabel, Ivona Aksentijevich, Jenny P.-Y. Ting, Beverly H. Koller
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