Chimeric antigen receptor (CAR) T-cell therapies targeting single antigens perform poorly in clinical trials for solid tumors due to heterogenous expression of tumor-associated antigens (TAAs), limited T-cell persistence and exhaustion. Here we aimed to identify optimal CARs against Glypican-2 (GPC2) or CD276 (B7-H3), which were highly but heterogeneously expressed in neuroblastoma (NB), a lethal extracranial solid tumor of childhood. First, we examined CAR T-cell expansion in the presence of target by digital droplet PCR. Next, using Pooled Competitive Optimization of CAR by CITE-seq (P-COCC), we simultaneously analyzed protein and transcriptome expression of CAR T-cells to identify high activity CARs. Finally, we performed cytotoxicity assays to identify the most effective CAR against each target and combined them into a bicistronic “OR” CAR (BiCisCAR). BiCisCAR T-cells effectively eliminated tumor cells expressing GPC2 or CD276. Furthermore, the BiCisCAR demonstrated prolonged persistence and resistance to exhaustion comparing with single antigen targeting CARs. This study illustrated that targeting multiple TAAs with BiCisCARs may overcome heterogenous expression of target antigen in solid tumors, and identified a potent clinically relevant CAR against NB. Moreover, our multimodal approach integrating competitive expansion, P-COCC, and cytotoxicity assays is an effective strategy to identify potent CARs from a pool of candidates.
MEIJIE TIAN, Adam T. Cheuk, Jun S. Wei, Abdalla Abdelmaksoud, Hsien-Chao Chou, David Milewski, Michael C. Kelly, Young K. Song, Christopher M. Dower, Nan Li, Haiying Qin, Yong Yean Kim, Jerry T. Wu, Xinyu Wen, Mehdi Benzaoui, Katherine E. Masih, Xiaolin Wu, Zhongmei Zhang, Sherif Badr, Naomi Taylor, Brad St. Croix, Mitchell Ho, Javed Khan
Solid organ transplantation is the preferred treatment for end-stage organ failure. Although transplant recipients takelife-long immunosuppressive drugs, a substantial percentage of them still reject their allografts. Strikingly, barrier organs colonized with microbiota have significantly shorter half-lives than non-barrier transplanted organs, even in immunosuppressed hosts. We previously demonstrated that skin allografts mono-colonized with the common human commensal Staphylococcus epidermidis (S.epi) are rejected faster than germ-free (GF) allografts in mice because the presence of S.epi augments the effector alloimmune response locally in the graft. Here, we tested whether host immune responses against graft-resident commensal microbes, including S.epi, can damage colonized grafts independently from the alloresponse. Naïve hosts mounted an anti-commensalT cell response to colonized, but not GF, syngeneic skin grafts. Whereas naïve anti-graft-commensal T cells modestly damaged colonized syngeneic skin grafts, hosts with prior anti-commensal T cell memory mounted a post-transplant immune response against graft-resident commensals that significantly damaged colonized, syngeneic skin grafts. Importantly, allograft recipients harboring this host-versus-commensal immune response resisted immunosuppression. The dual effectsof host-versus-commensal and host-versus-allograft responses may partially explain why colonized organs have poorer outcomes than sterile organs in the clinic.
Isabella D. Pirozzolo, Martin Sepulveda, Luqiu Chen, Ying Wang, Yuk Man Lei, Zhipeng Li, Rena Li, Husain Sattar, Betty R. Theriault, Yasmine Belkaid, Anita S. Chong, Maria-Luisa Alegre
Human-β-defensin (hBD)-3 exhibits antimicrobial and immunomodulatory activities; however, its contribution to autophagy regulation remains unclear, and the role of autophagy in the regulation of the epidermal barrier in atopic dermatitis (AD) is poorly understood. Here, keratinocyte autophagy was restrained in the skin lesions of patients with AD and murine models of AD. Interestingly, hBD-3 alleviated the interleukin-4- and interleukin-13-mediated impairment of the tight junction (TJ) barrier through keratinocyte autophagy activation, which involved aryl hydrocarbon receptor (AhR) signaling. While autophagy deficiency impaired the epidermal barrier and exacerbated inflammation, hBD-3 attenuated skin inflammation and enhanced the TJ barrier in AD. Importantly, hBD-3-mediated improvement of the TJ barrier was abolished in autophagy-deficient AD mice and in AhR-suppressed AD mice, suggesting a role for hBD-3-mediated autophagy in the regulation of the epidermal barrier and inflammation in AD. Thus, autophagy contributes to the pathogenesis of AD, and hBD-3 could be used for therapeutic purposes.
Ge Peng, Saya Tsukamoto, Risa Ikutama, Hai Le Thanh Nguyen, Yoshie Umehara, Juan V. Trujillo-Paez, Hainan Yue, Miho Takahashi, Takasuke Ogawa, Ryoma Kishi, Mitsutoshi Tominaga, Kenji Takamori, Jiro Kitaura, Shun Kageyama, Masaaki Komatsu, Ko Okumura, Hideoki Ogawa, Shigaku Ikeda, François Niyonsaba
Respiratory viruses such as influenza do not typically cause viremia; however, SARS-CoV-2 has been detected in the blood of COVID-19 patients with mild and severe symptoms. Detection of SARS-CoV-2 in blood raises questions about its role in pathogenesis as well as transfusion safety concerns. Blood donor reports of symptoms or a diagnosis of COVID-19 after donation (post-donation information, PDI) preceded or coincided with increased general population COVID-19 mortality. Plasma samples from 2,250 blood donors who reported possible COVID-19 related PDI were tested for the presence of SARS-CoV-2 RNA. Detection of RNAemia peaked at 9-15% of PDI donors in late 2020 to early 2021 and fell to ~4% after implementation of widespread vaccination in the population. RNAemic donors were 1.2 to 1.4-fold more likely to report cough or shortness of breath and 1.8-fold more likely to report change in taste or smell compared to infected donors without detectable RNAemia. No infectious virus was detected in plasma from RNAemic donors; inoculation onto permissive cell lines showed <0.7-7 plaque forming units (PFU)/mL and into susceptible mice <100 PFU/mL in RNA positive plasma based on limits of detection in these models. These findings suggest that blood transfusions are highly unlikely to transmit SARS-CoV-2 infection.
Paula Saá, Rebecca V. Fink, Sonia Bakkour, Jing Jin, Graham Simmons, Marcus O. Muench, Hina Dawar, Clara Di Germanio, Alvin J. Hui, David J. Wright, David E. Krysztof, Steven H. Kleinman, Angela Cheung, Theresa Nester, Debra A. Kessler, Rebecca L. Townsend, Bryan R. Spencer, Hany Kamel, Jacquelyn M. Vannoy, Honey Dave, Michael P. Busch, Susan L. Stramer, Mars Stone, Rachael P. Jackman, Philip J. Norris
FcɣRIIB is an inhibitory receptor expressed throughout B cell development. Diminished expression or function is associated with lupus in mice and humans, in particular through an effect on autoantibody production and plasma cell differentiation. Here, we analysed the effect of B cell-intrinsic FcɣRIIB expression on B cell activation and plasma cell differentiation. Loss of FcɣRIIB on B cells (Fcgr2b cKO mice) led to a spontaneous increase in autoantibody titers. This increase was most striking for IgG3, suggestive of increased extrafollicular responses. Marginal zone (MZ) B cells had the highest expression of FcɣRIIB in both mouse and human. This high expression of FcɣRIIB was linked to increased MZ B cell activation, Erk phosphorylation, and calcium fluxin the absence of FcɣRIIB triggering. Marked increases in IgG3+ plasma cells and B cells were observed during extrafollicular plasma cell responses in Fcgr2b cKO mice. The increased IgG3 response following immunization of Fcgr2b cKO mice was lost in MZ-deficient Notch2/Fcgr2b cKO mice. Importantly, SLE patients exhibited decreased expression of FcɣRIIB, most strongly in MZ B cells. Thus, we present a model where high FcɣRIIB expression in MZ B cells prevents their hyperactivation and ensuing autoimmunity.
Ashley N. Barlev, Susan Malkiel, Izumi Kurata-Sato, Annemarie L. Dorjée, Jolien Suurmond, Betty Diamond
An extreme chronic wound tissue microenvironment causes epigenetic gene silencing. Unbiased whole-genome methylome was studied in the wound-edge (WE) tissue of chronic wound patients. A total of 4689 differentially methylated regions (DMRs) were identified in chronic WE compared to unwounded (UW) human skin. Hypermethylation was more frequently observed (3661 DMRs) in the chronic WE compared to hypomethylation (1028 DMRs). Twenty-six hypermethylated DMRs were involved in epithelial to mesenchymal transition (EMT). Bisulfite sequencing validated hypermethylation of a predicted specific upstream regulator TP53. RNA sequencing analysis was performed to qualify findings from methylome analysis. Analysis of the downregulated genes identified the TP53 signaling pathway as being significantly silenced. Direct comparison of hypermethylation and downregulated genes identified four genes, ADAM17, NOTCH, TWIST1 and SMURF1, that functionally represent the EMT pathway. Single-cell RNA sequencing studies identified that these effects on gene expression were limited to the keratinocyte cell compartment. Experimental murine studies established that tissue ischemia potently induces WE gene methylation and that 5’-azacytidine, inhibitor of methylation, improved wound closure. To specifically address the significance of TP53 methylation, keratinocyte-specific editing of TP53 methylation at the WE was achieved by a tissue nanotransfection (TNT) based CRISPR/dCas9 approach. This work identified that reversal of methylation-dependent keratinocyte gene-silencing represents a productive therapeutic strategy to improve wound closure.
Kanhaiya Singh, Yashika Rustagi, Ahmed S. Abouhashem, Saba Tabasum, Priyanka Verma, Edward Hernandez, Durba Pal, Dolly K. Khona, Sujit K. Mohanty, Manishekhar Kumar, Rajneesh Srivastava, Poornachander R Guda, Sumit S. Verma, Sanskruti Mahajan, Jackson A. Killian, Logan A. Walker, Subhadip Ghatak, Shomita S. Mathew-Steiner, Kristen Wanczyk, Sheng Liu, Jun Wan, Pearlly Yan, Ralf Bundschuh, Savita Khanna, Gayle M. Gordillo, Michael P. Murphy, Sashwati Roy, Chandan K. Sen
The switch from anchorage-dependent to anchorage-independent growth is essential for epithelial metastasis. The underlying mechanism, however, is not fully understood. Here in this study, we identified growth factor independent-1 (GFI1), a transcription factor that drives transition from adherent endothelial cells to suspended hematopoietic cells during hematopoiesis, as a critical regulator of anchorage-independence in lung cancer cells. GFI1 elevated the numbers of circulating and lung infiltrating tumor cells in xenograft models and predicted poor prognosis of lung cancer patients. Mechanistically, GFI1 inhibited the expression of multiple adhesion molecules and facilitated substrate detachment. Concomitantly, GFI1 reconfigured chromatin structure of the RASGRP2 gene and increased its expression, causing Rap1 activation and subsequent sustained ERK activation upon detachment, and this leaded to ERK signaling dependency in tumor cells. Our studies unveiled a mechanism by which carcinoma cells hijacked a hematopoietic factor to gain anchorage independence and suggested that the intervention of ERK signaling may suppress metastasis and improve the therapeutic outcome of GFI1-positive lung cancer patients.
Hao Wang, Zhenzhen Lin, Zhe Nian, Wei Zhang, Wenxu Liu, Fei Yan, Zengtuan Xiao, Xia Wang, Zhenfa Zhang, Zhenyi Ma, Zhe Liu
The focus of hepatitis B functional cure, defined as sustained loss of hepatitis B surface antigen (HBsAg) and HBV DNA from blood, is on eliminating or silencing the intranuclear template for HBV replication, covalently closed circular DNA (cccDNA). However, HBsAg also derives from HBV DNA integrated into the host genome (iDNA). Little is known about the contribution of iDNA to circulating HBsAg with current therapeutics. We applied a multiplex ddPCR assay to demonstrate that iDNA is responsible for maintaining HBsAg quantities in some individuals. Using paired bulk liver tissue from 16 HIV/HBV coinfected persons on nucleos(t)ide analogue (NUC) therapy, we demonstrate that people with larger HBsAg declines between biopsies derive HBsAg from cccDNA whereas people with stable HBsAg levels derive predominantly from iDNA. We applied our assay to individual hepatocytes in paired tissues from three people and demonstrated that the individual with significant HBsAg decline had a commensurate loss of infected cells with transcriptionally active cccDNA, while individuals without HBsAg decline had stable or increasing numbers of cells producing HBsAg from iDNA. We demonstrate that while NUC therapy may be effective at controlling cccDNA replication and transcription, innovative treatments are required to address iDNA transcription that sustains HBsAg production.
Tanner Grudda, Hyon S. Hwang, Maraake Taddese, Jeffrey Quinn, Mark S. Sulkowski, Richard K. Sterling, Ashwin Balagopal, Chloe L. Thio
Mitohormesis defines the increase in fitness mediated by adaptive responses to mild mitochondrial stress. Tetracyclines inhibit not only bacterial but also mitochondrial translation, thus imposing a low level of mitochondrial stress to eukaryotic cells. We demonstrate in cell and germ-free mouse models, that tetracyclines induce a mild adaptive mitochondrial stress response (MSR), involving both the ATF4-mediated integrative stress response and type I interferon (IFN) signaling. To overcome the interferences of tetracyclines with the host microbiome, we identify tetracycline derivatives that have minimal antimicrobial activity, yet retain full capacity to induce the MSR, such as the lead compound, 9-tert-butyldoxycycline (9-TB). The MSR induced by Doxycycline (Dox) and 9-TB improves survival and disease tolerance against lethal influenza virus (IFV) infection when given preventively. 9-TB, unlike Dox, did not affect the gut microbiome and showed also encouraging results against IFV when given in a therapeutic setting. Tolerance to IFV infection is associated with the induction of genes involved in lung epithelial cell and cilia function, and with down-regulation of inflammatory and immune gene sets in lungs, liver, and kidneys. Mitohormesis induced by non-antimicrobial tetracyclines and the ensuing IFN response may dampen excessive inflammation and tissue damage during viral infections, opening innovative therapeutic avenues.
Adrienne Mottis, Terytty Y. Li, Gaby El Alam, Alexis Rapin, Elena Katsyuba, David Liaskos, Davide D'Amico, Nicola L. Harris, Mark C. Grier, Laurent Mouchiroud, Mark L. Nelson, Johan Auwerx
Plasmacytoid dendritic cell (pDC) is a professional type I interferon producer, which plays critical roles in the pathogenesis of autoimmune diseases. However, both genetic regulation of pDC function and their relationships with autoimmunity are largely undetermined. Here, we investigated the causality of NCF1 missense variant, which is one of the most significant associated risk variants for lupus, and found that the substitution from arginine (R) to histidine (H) at position 90 in NCF1 protein (NCF1 p.R90H) led to excessive activation of pDCs. Mechanism study demonstrated that p.R90H reduced the affinity of NCF1 to phospholipid, thereby impaired endosomal localization of NCF1. As NCF1 is a subunit of NOX2 complex, this impairment led to acidified endosomal pH and facilitated downstream TLR signaling. Consistently, the homozygous knock-in mice manifested aggravated lupus progression in a pDC dependent lupus model. More importantly, pharmaceutical intervention revealed that hydroxychloroquine (HCQ) could antagonize the detrimental function of NCF1 p.R90H in lupus model and systemic lupus erythematosus (SLE) samples, supporting that NCF1 p.R90H could be identified as a genetic biomarker for HCQ application. Therefore, our study provides insights into the genetic control of pDC function and paradigm for applying genetic variants to improve targeted therapy for autoimmune diseases.
Yao Meng, Jianyang Ma, Chao Yao, Zhizhong Ye, Huihua Ding, Can Liu, Jun Li, Guanhua Li, Yuke He, Jia Li, Zhihua Yin, Li Wu, Haibo Zhou, Nan Shen
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