KRAS is one of the most frequently activated oncogenes in human cancers. While the role of KRAS mutation in tumorigenesis and tumor maintenance has been extensively studied, the relationship between KRAS and the tumor immune microenvironment is not fully understood. Herein, we identified a novel role of KRAS in driving tumor evasion from innate immune surveillance. In lung adenocarcinoma patient samples and Kras-driven genetic mouse models of lung cancer, mutant KRAS activated the expression of cluster of differentiation 47 (CD47), an antiphagocytic signal in cancer cells, leading to decreased phagocytosis of cancer cells by macrophages. Mechanistically, mutant KRAS activated PI3K-STAT3 signaling, which restrained miR-34a expression and relieved the post-transcriptional repression of miR-34a on CD47. In three independent lung cancer patient cohorts, KRAS mutation status positively correlated with CD47 expression. Therapeutically, disruption of the KRAS-CD47 signaling axis with KRAS siRNA, the KRASG12C inhibitor AMG 510 or miR-34a mimic suppressed CD47 expression, enhanced the phagocytic capacity of macrophages and restored innate immune surveillance. Our results revealed a direct mechanistic link between active KRAS and innate immune evasion and identified CD47 as a major effector underlying KRAS-mediated immunosuppressive tumor microenvironment.
Huanhuan Hu, Rongjie Cheng, Yanbo Wang, Xiaojun Wang, Jianzhuang Wu, Yan Kong, Shoubin Zhan, Zhen Zhou, Hongyu Zhu, Ranran Yu, Gaoli Liang, Qingyan Wang, Xiaoju Zhu, Chen-Yu Zhang, Rong Yin, Chao Yan, Xi Chen
BACKGROUND. Sanfilippo type B is a mucopolysaccharidosis (MPS) with a major neuronopathic component characterized by heparan sulfate (HS) accumulation due to mutations in the NAGLU gene encoding for alfa-N-acetyl-glucosaminidase. Enzyme replacement therapy for neuronopathic MPS requires efficient enzyme delivery throughout the brain in order to normalize HS, prevent brain atrophy and potentially delay cognitive decline. METHODS. In this phase 1/2, open-label study, subjects (n=22) affected with MPS IIIB were treated with tralesinidase alfa administered intracerebroventricularly (ICV). Subjects were monitored for drug exposure, total HS and HS non-reducing end (HS-NRE) levels in both cerebrospinal fluid (CSF) and plasma, anti-drug antibody response, brain, spleen and liver volumes as measured by magnetic resonance imaging and cognitive development as measured by age-equivalent (AEq) scores. RESULTS. In the Part 1 dose escalation (30, 100, and 300 mg) phase, tralesinidase alfa 300 mg was necessary to achieve normalization of HS and HS-NRE in CSF and plasma. In Part 2, tralesinidase alfa 300 mg sustained HS and HS-NRE normalization in the CSF and stabilized cortical grey matter volume (CGMV) over 48 weeks of treatment. Resolution of hepatomegaly and reduction in spleen volume were observed in most subjects. Significant correlations were also established between change in cognitive AEq and plasma drug exposure, plasma HS-NRE level and change in CGMV. CONCLUSION. ICV administration of tralesinidase alfa effectively normalized HS and HS-NRE as a prerequisite for clinical efficacy. Peripheral drug exposure data suggests a role for the glymphatic system in altering tralesinidase alfa efficacy. TRIAL REGISTRATION. Clinicaltrials.gov: NCT02754076.
Nicole Muschol, Anja Koehn, Katharina von Cossel, Ilyas Okur, Fatih Ezgu, Paul Harmatz, Maria Jose de Castro Lopez, Maria Luz Couce, Shuan-Pei Lin, Spyros Batzios, Maureen Cleary, Martha Solano, Igor Nestrasil, Brian D. Kaufman, Adam J. Shaywitz, Stephen M. Maricich, Bernice Kuca, Joseph Kovalchin, Eric H. Zanelli
BACKGROUND. Studies assessing the efficacy of therapies for neovascular age-related macular degeneration (nvAMD) have demonstrated that aflibercept may have a longer treatment interval than its lesser-expensive alternative, bevacizumab. However, whether this benefit justifies the additional cost of aflibercept remains under debate. We have recently reported that a “treat-and-extend-pause/monitor” (TEP/M) approach can be used to successfully wean 31% of nvAMD patients off anti-VEGF therapy. Here we examine whether the choice of therapy influences the outcomes of this approach. METHODS. In this retrospective analysis, 122 eyes of 106 patients with nvAMD underwent 3 consecutive monthly injections with either aflibercept (n=70) or bevacizumab (n=52) followed by a treat-and-extend protocol in which the decision to extend the interval between treatments was based on visual acuity, clinical exam, and the presence or absence of fluid on optical coherence tomography (OCT). Eyes that remained stable 12 weeks from their prior treatment were given a 6-week trial of holding further treatment, followed by quarterly monitoring. Treatment was resumed for worsening vision, clinical exam, or OCT findings. RESULTS. At the end of one year, eyes receiving bevacizumab had similar vision but required more injections (8.7 ±0.3 vs. 7.2 ±0.3) compared to aflibercept. However, eyes treated with aflibercept were almost 3-times more likely to be weaned off treatment (43% vs. 15%) compared to eyes treated with bevacizumab at the end of one year. CONCLUSIONS. These observations expose a previously unappreciated advantage of aflibercept over bevacizumab and have important clinical implications for the selection of therapy for patients with nvAMD.
Xuan Cao, Jaron Castillo Sanchez, Tapan P. Patel, Zhiyong Yang, Chuanyu Guo, Danyal Malik, Anuoluwapo Sopeyin, Silvia Montaner, Akrit Sodhi
BACKGROUND. The kynurenine pathway (KP) has been identified as a potential mediator linking acute illness to cognitive dysfunction by generating neuroactive metabolites in response to inflammation. Delirium (acute confusion) is a common complication of acute illness and is associated with increased risk of dementia and mortality. However, the molecular mechanism underlying delirium, particularly in relation to the KP, remain elusive. METHODS. We undertook a multi-center observational study with 586 hospitalized patients (248 with delirium) and investigated associations between delirium and KP metabolites measured in cerebrospinal fluid (CSF) and serum by targeted metabolomics. We also explored associations between KP metabolites and markers of neuronal damage and one-year mortality. RESULTS. In delirium, we found concentrations of the neurotoxic metabolite quinolinic acid in CSF (CSF-QA, OR 2.26 [1.78, 2.87], p<0.001) to be increased, as well as increases in several other KP metabolites in serum and CSF. In addition, CSF-QA was associated with the neuronal damage marker neurofilament light chain (NfL, β 0.43, p<0.001) and was a strong predictor of one-year mortality (HR 4.35 [2.93, 6.45] for CSF-QA ≥ 100 nmol/L, p<0.001). The associations between CSF-QA and delirium, neuronal damage, and mortality remained highly significant following adjustment for confounders and multiple comparisons. CONCLUSION. Our data identified how systemic inflammation, neurotoxicity, and delirium are strongly linked via the KP, and should inform future delirium prevention and treatment clinical trials that target enzymes of the KP. FUNDING. Norwegian Health Association and the South-Eastern Norway Regional Health Authorities
Leiv Otto Watne, Christian Thomas Pollmann, Bjorn Erik Neerland, Else Quist-Paulsen, Nathalie Bodd Halaas, Ane-Victoria Idland, Bjørnar Hassel, Kristi Henjum, Anne-Brita Knapskog, Frede Frihagen, Johan Raeder, Aasmund Godø, Per Magne Ueland, Adrian McCann, Wender Figved, Geir Selbæk, Henrik Zetterberg, Evandro Fei Fang, Marius Myrstad, Lasse M. Giil
Repeated or prolonged, but not short-term, general anesthesia during the early postnatal period causes long-lasting impairments in memory formation in various species. The mechanisms underlying long-lasting impairment in cognitive function are poorly understood. Here we showed that repeated general anesthesia in postnatal mice induces preferential apoptosis and subsequent loss of parvalbumin-positive inhibitory interneurons in the hippocampus. Each parvalbumin interneuron controls the activity of multiple pyramidal excitatory neurons, thereby regulating neuronal circuits and memory consolidation. Preventing the loss of parvalbumin neurons by deleting a pro-apoptotic protein MAPL (Mitochondrial Anchored Protein Ligase) selectively in parvalbumin neurons rescued anesthesia-induced deficits in pyramidal cell inhibition, and hippocampus-dependent long-term memory. Conversely, partial depletion of parvalbumin neurons in neonates was sufficient to engender long-lasting memory impairment. Thus, loss of parvalbumin interneurons in postnatal mice following repeated general anesthesia critically contributes to memory deficits in adulthood.
Patricia Soriano Roque, Carolina Thörn Perez, Mehdi Hooshmandi, Calvin Wong, Mohammad Javad Eslamizade, Shilan Heshmati, Nicole Brown, Vijendra Sharma, Kevin C. Lister, Vanessa Magalie Goyon, Laura E. Neagu-Lund, Cathy Shen, Nicolas Daccache, Hiroaki Sato, Tamaki Sato, Jeffrey S. Mogil, Karim Nader, Christos G. Gkogkas, Mihaela D. Iordanova, Masha Prager-Khoutorsky, Heidi M. McBride, Jean-Claude Lacaille, Linda Wykes, Thomas Schricker, Arkady Khoutorsky
Glioblastoma ranks among the most aggressive and lethal of all human cancers. Self-renewing, highly tumorigenic glioblastoma stem cells (GSCs) contribute to therapeutic resistance and maintain cellular heterogeneity. Here, we interrogated superenhancer landscapes of primary glioblastoma specimens and patient-derived GSCs, revealing a kelch domain-containing gene (KLHDC8A) with a previously unknown function as an epigenetically-driven oncogene. Targeting KLHDC8A decreased GSC proliferation and self-renewal, induced apoptosis, and impaired in vivo tumor growth. Transcription factor control circuitry analyses revealed that the master transcriptional regulator SOX2 stimulated KLHDC8A expression. Mechanistically, KLHDC8A bound Chaperonin-Containing TCP1 (CCT) to promote assembly of primary cilia to activate Hedgehog signaling. KLHDC8A expression correlated with Aurora B/C Kinase inhibitor activity, which induced primary cilia and Hedgehog signaling. Combinatorial targeting of Aurora B/C Kinase and Hedgehog displayed augmented benefit against GSC proliferation. Collectively, superenhancer-based discovery revealed KLHDC8A as a novel molecular target of cancer stem cells that promotes ciliogenesis to activate the Hedgehog pathway, offering insights into therapeutic vulnerabilities for glioblastoma treatment.
Derrick Lee, Ryan C. Gimple, Xujia Wu, Briana C. Prager, Zhixin Qiu, Qiulian Wu, Vikas Daggubati, Aruljothi Mariappan, Jay Gopalakrishnan, Matthew R. Sarkisian, David R. Raleigh, Jeremy N. Rich
WEE1 has emerged as an attractive target in epithelial ovarian cancer (EOC), but how EOC cells may alter sensitivity to WEE1 inhibition remains unclear. Here, through a cell cycle machinery-related gene RNAi screen, we found that targeting ODF2L is synthetic lethal with WEE1 kinase inhibition in EOC cells. Knockdown of ODF2L robustly sensitized cells to treatment of the WEE1 inhibitor AZD1775 in EOC cell lines in vitro, as well as xenografts in vivo. Mechanistically, the increased sensitivity to WEE1 inhibition upon ODF2L loss was accompanied by accumulated DNA damage. ODF2L licensed the recruitment of PKMYT1, a functionally redundant kinase of WEE1, to the CDK1/cyclin B complex and thus restricted the activity of CDK1 when WEE1 was inhibited. Clinically, upregulation of ODF2L correlated with CDK1 activity, DNA damage level, and sensitivity to WEE1 inhibition in patient-derived EOC cells. Moreover, the ODF2L level predicted the response to WEE1 inhibition in an EOC patient-derived xenograft model. Combination treatment with tumor-targeted lipid nanoparticles that package ODF2L siRNA and AZD1775 led to the synergistic attenuation of tumor growth in the ID8 ovarian cancer syngeneic mouse model. These data suggest that WEE1 inhibition is a promising precision therapeutic strategy for ODF2L-low-expressing EOC cells.
Jie Li, Jingyi Lu, Manman Xu, Shiyu Yang, Tiantian Yu, Cuimiao Zheng, Xi Huang, Yuwen Pan, Yangyang Chen, Junming Long, Chunyu Zhang, Hua Huang, Qingyuan Dai, Bo Li, Wei Wang, Shuzhong Yao, Chaoyun Pan
T cell exhaustion is a state of T cell dysfunction associated with expression of programmed death 1 (PD-1). Exhausted CD8 T cells are maintained by self-renewing stem-like T (TSL) cells that provide differentiated TIM3+ cells, a part of which possesses effector-like properties. PD-1-targeted therapies enhance T cell response by promoting differentiation of TSL cells toward TIM3+ cells, but the role of mTOR during T cell exhaustion remains elusive. Here, we show that mTOR inhibition has distinct outcomes during the beginning of and after the establishment of chronic viral infection. Blocking mTOR during the T cell expansion phase enhanced the T cell response by accumulating TSL cells, leading to improved efficacy of PD-1 immunotherapy. Whereas, after exhaustion progressed, mTOR inhibition caused immunosuppression characterized by decreased TIM3+ cells and increased viral load with minimal changes in TSL cells. Mechanistically, a cell-intrinsic mTOR signal was vital for differentiation of TSL cells into the TIM3+ state in the early and late phases of chronic infection as well as during PD-1 immunotherapy. Thus, PD-1 blockade worked after cessation of mTOR inhibition but simultaneous treatment failed to induce functional TIM3+ cells, reducing efficacy of PD-1 immunotherapy. Our data demonstrate that mTOR regulates T cell exhaustion and have important implications for combination cancer therapies with PD-1 blockade
Satomi Ando, Charles Perkins, Yamato Sajiki, Chase Chastain, Rajesh M. Valanparambil, Andreas Wieland, William H. Hudson, Masao Hashimoto, Suresh S. Ramalingam, Gordon J. Freeman, Rafi Ahmed, Koichi Araki
Peter Manza, Ehsan Shokri-Kojori, Sukru B. Demiral, Rui Zhang, Evan Dennis, Allison M. Johnson, Leah Vines, Diana Sotelo, Dardo Tomasi, Gene-Jack Wang, Nora D. Volkow
BACKGROUND. Acute febrile neutrophilic dermatosis (Sweet syndrome) is a potentially fatal multiorgan inflammatory disease characterized by fever, leukocytosis, and a rash with a neutrophilic infiltrate. Disease pathophysiology remains elusive, and current dogma suggests Sweet syndrome is a “reactive” process to an unknown antigen. Corticosteroids and steroid-sparing agents remain front-line therapies, but refractory cases pose a clinical challenge. METHODS. A 51-year-old woman with multiorgan Sweet syndrome developed serious corticosteroid-related side effects and was refractory to steroid-sparing agents. Blood counts, liver enzymes, and skin histopathology supported the diagnosis. Whole genome sequencing, transcriptomic profiling, and cellular assays of patient’s skin and neutrophils were performed. RESULTS. We identified elevated IL-1 signaling in lesional Sweet syndrome skin caused by a PIK3R1 gain-of-function mutation specifically found in neutrophils. This mutation increased neutrophil migration towards IL-1β and neutrophil respiratory burst. Targeted treatment with an IL-1R1 antagonist in the patient resulted in a dramatic therapeutic response and enabled tapering of corticosteroids. CONCLUSIONS. Dysregulated PI3K-AKT signaling is the first signaling pathway linked to Sweet syndrome and suggests Sweet syndrome may be caused by acquired mutations that modulate neutrophil function. Moreover, integration of molecular data across multiple levels identified a distinct subtype within a heterogenous disease that resulted in a rational and successful clinical intervention. Future cases will benefit from efforts to identify potential mutations. The ability to directly interrogate diseased skin allows this method to be generalizable to other inflammatory diseases and demonstrates a potential personalized medicine approach for challenging patients. FUNDING Berstein Foundation, NIH, VA, Moseley Foundation, and H.T. Leung Foundation.
Shreya Bhattacharya, Sayon Basu, Emily Sheng, Christina M. Murphy, Jenny Wei, Anna E. Kersh, Caroline A. Nelson, Joshua S. Bryer, Hovik A. Ashchyan, Katherine T. Steele, Amy K. Forrestel, John T. Seykora, Robert G. Micheletti, William D. James, Misha Rosenbach, Thomas H. Leung
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