Research
Abstract
The RTS,S/AS01E vaccine targets the circumsporozoite protein (CSP) of the Plasmodium falciparum parasite. Using protein microarrays, levels of IgG to 1,000 P. falciparum antigens were measured in 2,138 infants (age 6-12 weeks) and children (age 5-17 months) from 6 African sites of the phase 3 trial, sampled before and at four longitudinal visits after vaccination. One month post-vaccination, IgG responses to 17% of all probed antigens showed differences between RTS,S/AS01E and comparator vaccination groups, whereas no prevaccination differences were found. A small subset of antigens presented IgG levels reaching 4- to 8 fold increases in the RTS,S/AS01E group, comparable in magnitude to anti-CSP IgG levels (~11-fold increase). They were strongly cross-correlated and correlated with anti CSP levels, waning similarly over time and re-increasing with the booster dose. Such an intriguing phenomenon may be due to cross-reactivity of anti-CSP antibodies with these antigens. RTS,S/AS01E vaccinees with strong off target IgG responses had an estimated lower clinical malaria incidence after adjusting for age group, site and post-vaccination anti-CSP levels. RTS,S/AS01E-induced IgG may bind strongly not only to CSP, but to unrelated malaria antigens, and this seems to either confer, or at least be a marker of, increased protection from clinical malaria.
Authors
Dídac Macià, Joseph J. Campo, Gemma Moncunill, Chenjerai Jairoce, Augusto J. Nhabomba, Maximilian Mpina, Hermann Sorgho, David Dosoo, Ousmane Traore, Kwadwo A. Kusi, Nana Aba Williams, Amit Oberai, Arlo Randall, Hector Sanz, Clarissa Valim, Kwaku P. Asante, Seth Owusu-Agyei, Halidou Tinto, Selidji T. Agnandji, Simon Kariuki, Ben Gyan, Claudia Daubenberger, Benjamin Mordmüller, Paula Petrone, Carlota Dobaño
Abstract
UMOD is a major risk gene for monogenic and complex forms of kidney disease. The encoded kidney-specific protein uromodulin is highly abundant in urine and related to chronic kidney disease, hypertension, and pathogen defense. To gain insights into potential systemic roles, we performed genome-wide screens of circulating uromodulin using complementary antibody-based (N=13,985) and aptamer-based (N=18,070) assays. We detected 3 and 10 distinct significant (p<5e-8) loci, respectively. Integration of antibody-based results at the UMOD locus with functional genomics data (RNA-seq, ATAC-seq, Hi-C) of primary human kidney tissue highlights an upstream variant with differential accessibility and transcription in uromodulin-synthesizing kidney cells as underlying the observed cis effect. Shared association patterns with complex traits, including chronic kidney disease and blood pressure, place the PRKAG2 locus in the same pathway as UMOD. Experimental validation of the third antibody-based locus, B4GALNT2, shows that the p.Cys466Arg variant of the encoded N-acetylgalactosaminyltransferase has a loss-of-function effect leading to higher serum uromodulin levels. Aptamer-based results point to enzymes writing glycan marks present on uromodulin and to their receptors in the circulation, suggesting that this assay permits investigating uromodulin’s complex glycosylation rather than its quantitative levels. Overall, our study provides new insights into circulating uromodulin and its emerging functions.
Authors
Yong Li, Yurong Cheng, Francesco Consolato, Guglielmo Schiano, Michael R. Chong, Maik Pietzner, Ngoc Quynh H. Nguyen, Nora Scherer, Mary L. Biggs, Marcus E. Kleber, Stefan Haug, Burulça Göçmen, Marie Pigeyre, Peggy Sekula, Inga Steinbrenner, Pascal Schlosser, Christina B. Joseph, Jennifer A. Brody, Morgan E. Grams, Caroline Hayward, Ulla T. Schultheiss, Bernhard K. Krämer, Florian Kronenberg, Annette Peters, Jochen Seissler, Dominik Steubl, Cornelia Then, Matthias Wuttke, Winfried März, Kai-Uwe Eckardt, Christian Gieger, Eric Boerwinkle, Bruce M. Psaty, Josef Coresh, Peter J. Oefner, Guillaume Pare, Claudia Langenberg, Jürgen E. Scherberich, Bing Yu, Shreeram Akilesh, Olivier Devuyst, Luca Rampoldi, Anna Köttgen
Abstract
Respiratory failure in COVID-19 is characterized by widespread disruption of the lung’s alveolar gas exchange interface. To elucidate determinants of alveolar lung damage, we performed epithelial and immune cell profiling in lungs from 24 COVID-19 autopsies and 43 uninfected organ donors ages 18-92 years. We found marked loss of type 2 alveolar epithelial (T2AE) cells and increased peri-alveolar lymphocyte cytotoxicity in all fatal COVID-19 cases, even at early stages before typical patterns of acute lung injury are histologically apparent. In lungs from uninfected organ donors, there is also progressive loss of T2AE with increasing age which may increase susceptibility to COVID-19 mediated lung damage in older individuals. In the fatal COVID-19 cases, macrophage infiltration differed according to the histopathological pattern of lung injury. In cases with acute lung injury, we found accumulation of CD4+ macrophages that express distinctly high levels of T-cell activation and co-stimulation genes and strongly correlate with increased extent of alveolar epithelial cell depletion and CD8 T-cell cytotoxicity. Together, our results show that T2AE deficiency may underlie age-related COVID-19 risk and initiate alveolar injury shortly after infection; and we define immune cell mediators that may contribute to alveolar injury in distinct pathological stages of lethal COVID-19.
Authors
Michael Chait, Mine M. Yilmaz, Shanila Shakil, Amy W. Ku, Pranay Dogra, Thomas J. Connors, Peter A. Szabo, Joshua I. Gray, Steven B. Wells, Masaru Kubota, Rei Matsumoto, Maya M.L. Poon, Mark E. Snyder, Matthew R. Baldwin, Peter A. Sims, Anjali Saqi, Donna L. Farber, Stuart P. Weisberg
Abstract
SARS-CoV-2 has resulted in over 450 million confirmed cases since 2019. Although several vaccines have been certified by World Health Organization and are being vaccinated on a global scale, it has been reported that multiple SARS-CoV-2 variants can escape neutralisation by antibodies, resulting in vaccine breakthrough infections. Bacillus Calmette-Guérin (BCG) is known to induce heterologous protection based on trained immune responses. Here, we investigated whether BCG-induced trained immunity protected against SARS-CoV-2 challenge in the K18-hACE2 mouse model. Our data demonstrates that intravenous BCG vaccination induces robust trained innate immune responses and provides protection against wild-type SARS-CoV-2 as well as the B.1.617.1 and B.1.617.2 variants. Further studies suggest that myeloid cell differentiation and activation of the glycolysis pathway are associated with BCG-induced training immunity in the K18-hACE2 mice. Overall, our study provides the experimental evidence that establishes a causal relationship between intravenous BCG vaccination and protection against SARS-CoV-2 challenge.
Authors
Bao-Zhong Zhang, Huiping Shuai, Hua-rui Gong, Jing-Chu Hu, Bingpeng Yan, Terrence Tsz-Tai Yuen, Ye-Fan Hu, Chaemin Yoon, Xiao-Lei Wang, Yuxin Hou, Xuansheng Lin, Xiner Huang, Renhao Li, Yee Man Au-Yeung, Wenjun Li, Bingjie Hu, Yue Chai, Ming Yue, Jian-Piao Cai, Guang Sheng Ling, Ivan Fan-Ngai Hung, Kwok-Yung Yuen, Jasper Fuk-Woo Chan, Jian-Dong Huang, Hin Chu
Abstract
Bacteria have evolved to cope with the detrimental effects of reactive oxygen species (ROS) using their essential molecular components. Catalase, a heme-containing tetramer protein expressed universally in most of the aerobic bacteria, plays an indispensable role in scavenging excess hydrogen peroxide (H2O2). Here, through utilization of wild-type and catalase-deficient mutants, we identified catalase as an endogenous therapeutic target of 400-420 nm blue light. Catalase residing inside bacteria could be effectively inactivated by blue light, subsequently rendering the pathogens extremely vulnerable to H2O2 and H2O2-producing agents. As a result, photoinactivation of catalase and H2O2 synergistically eliminate a wide range of catalase-positive planktonic bacteria and P. aeruginosa inside biofilms. In addition, photoinactivation of catalase is shown to facilitate macrophages to defend against intracellular pathogens. The antimicrobial efficacy of catalase photoinactivation is further validated using a Pseudomonas aeruginosa-induced mice abrasion model. Taken together, our findings offer a catalase-targeting phototherapy approach against multidrug-resistant bacterial infections.
Authors
Pu-Ting Dong, Sebastian Jusuf, Jie Hui, Yuewei Zhan, Yifan Zhu, George Y. Liu, Ji-Xin Cheng
Abstract
Greater than 25% of all men develop an inguinal hernia in their lifetime, and more than 20 million inguinal hernia repair surgeries are performed worldwide each year. The mechanisms causing abdominal muscle weakness, the formation of inguinal hernias, or their recurrence are largely unknown. We previously reported that excessively produced estrogen in the lower abdominal muscles (LAM) triggers extensive LAM fibrosis, leading to hernia formation in a transgenic male mouse model expressing the human aromatase gene (Aromhum). To understand the cellular basis of estrogen-driven muscle fibrosis, we performed single-cell RNA-sequencing on LAM tissue from Aromhum and wild-type littermates. We found a fibroblast-like cell group comprised of six clusters, two of which were validated for their enrichment in Aromhum LAM tissue. One of the novel hernia-associated fibroblast clusters in Aromhum was enriched for the estrogen receptor-α gene (Esr1Hi). Esr1Hi fibroblasts maximally expressed estrogen target genes and seemed to serve as the progenitors of another cluster expressing ECM-altering enzymes (Mmp3Hi) and upregulate expression of pro-inflammatory, pro-fibrotic genes. The discovery of these two novel and unique hernia-associated fibroblasts may lead to the development of novel treatments that can non-surgically prevent or reverse inguinal hernias.
Authors
Tanvi Potluri, Matthew J. Taylor, Jonah J. Stulberg, Richard L. Lieber, Hong Zhao, Serdar E. Bulun
Abstract
Molecular signaling in the tumor microenvironment (TME) is complex, and crosstalks among various cell compartments in supporting metastasis remain poorly understood. In particular, the role of vascular pericytes, a critical cellular component in the TME, in cancer invasion and metastasis warrants further investigation. Here we report an elevation of FGF-2 signaling in both nasopharyngeal carcinoma (NPC) patient samples and xenograft mouse models promotes NPC metastasis. Mechanistically, tumor cell-derived FGF-2 strongly promoted pericyte proliferation and pericyte-specific expression of an orphan chemokine (C-X-C motif) ligand 14 (CXCL14) via FGFR1- AHR signaling. Gain and loss-of-function experiments validated that pericyte-derived CXCL14 promoted macrophage recruitment and polarization towards an M2-like phenotype. Genetic knockdown of FGF2 or genetic depletion of tumoral pericytes blocked CXCL14 expression and tumor-associated macrophage (TAM) infiltration. Pharmacological inhibition of TAMs by clodronate liposomes treatment resulted in a reduction of FGF-2-induced pulmonary metastasis. Together, these findings shed light on the inflammatory role of tumoral pericytes in promoting TAM-mediated metastasis. We provide mechanistic insight into an FGF-2-FGFR1-pericyte-CXCL14-TAM stromal communication axis in NPC and propose an effective anti-metastasis therapy concept by targeting a pericyte-derived inflammation for NPC or FGF-2-high tumors.
Authors
Yujie Wang, Qi Sun, Ying Ye, Xiaoting Sun, Sisi Xie, Yuhang Zhan, Jian Song, Xiaoqin Fan, Bin Zhang, Ming Yang, Lei Lv, Kayoko Hosaka, Yunlong Yang, Guohui Nie
Abstract
Systemic therapies for pancreatic ductal adenocarcinoma (PDAC) remain unsatisfactory. Clinical prognosis is particularly poor for tumor subtypes with activating aberrations in the MYC pathway creating an urgent need for novel therapeutic targets. To unbiasedly find novel MYC-associated epigenetic dependencies, we conducted a drug screen in pancreatic cancer cell lines. Here, we found protein arginine N-methyltransferase 5 (PRMT5) inhibitors to trigger a MYC-associated dependency. In human and murine PDACs, a robust connection of MYC and PRMT5 was detected. By the use of gain- and loss-of-function models, we confirm the increased efficacy of PRMT5 inhibitors in MYC deregulated PDACs. Although inhibition of PRMT5 is inducing DNA-damage and arresting PDAC cells in the G2/M-phase of the cell cycle, apoptotic cell death was executed predominantly in cells with high MYC expression. Experiments in primary patient-derived PDAC models demonstrated the existence of a highly PRMT5 inhibitor sensitive subtype. Our work suggests developing PRMT5 inhibitor-based therapies for PDAC.
Authors
Felix Orben, Katharina Lankes, Christian Schneeweis, Zonera Hassan, Hannah Jakubowsky, Lukas Krauß, Fabio Boniolo, Carolin Schneider, Arlett P.G. Schäfer, Janine Murr, Christoph Schlag, Bo Kong, Rupert Öllinger, Chengdong Wang, Georg Beyer, Ujjwal Mukund Mahajan, Yonggan Xue, Julia Mayerle, Roland M. Schmid, Bernhard Kuster, Roland Rad, Christian J. Braun, Matthias Wirth, Maximilian Reichert, Dieter Saur, Günter Schneider
Abstract
Idiopathic pulmonary fibrosis (IPF) is a fatal disease with limited treatment options. The role of the developmental transcription factor Sine Oculis homeobox homolog 1 (SIX1) in the pathophysiology of lung fibrosis is not known. IPF lung tissue samples and IPF-derived alveolar type II cells (AT2) showed a significant increase in SIX1 mRNA and protein levels, and the SIX1 transcriptional co-activators EYA1 and EYA2 were elevated. Six1 was also upregulated in bleomycin (BLM)-treated mice and in a model of spontaneous lung fibrosis driven by deletion of Telomeric Repeat Binding Factor 1 (Trf1) in AT2 cells. Conditional deletion of Six1 in AT2 cells prevented or halted BLM-induced lung fibrosis as measured by a significant reduction in histological burden of fibrosis, reduced fibrotic mediator expression and improved lung function. These effects were associated with increased macrophage migration inhibitory factor (MIF) in lung epithelial cells in vivo following SIX1 overexpression in BLM-induced fibrosis. A MIF promoter-driven luciferase assay demonstrated direct binding of Six1 to the 5’-TCAGG-3’ consensus sequence of the MIF promoter, identifying a likely mechanism of SIX1-driven MIF expression in the pathogenesis of lung fibrosis, and providing a novel pathway for targeting in IPF therapy.
Authors
Cory Wilson, Tinne C.J. Mertens, Pooja Shivshankar, Weizen Bi, Scott D. Collum, Nancy Wareing, Junsuk Ko, Tingting Weng, Ram P. Naikawadi, Paul J. Wolters, Pascal Maire, Soma S.K. Jyothula, Rajarajan A. Thandavarayan, Dewei Ren, Nathan D. Elrod, Eric J. Wagner, Howard J. Huang, Burton F. Dickey, Heide L. Ford, Harry Karmouty-Quintana
Abstract
Pain emanating from the female reproductive tract is notoriously difficult to be treated and the prevalence of transient pelvic pain has been placed as high as 70-80% in women surveyed. Although sex hormones, especially estrogen, are thought to underlie enhanced pain perception in females, the underlying molecular and cellular mechanisms are not completely understood. Here we show that the pain-initiating TRPA1 channel is required for pain-related behaviors in a mouse model of estrogen-induced uterine pain in ovariectomized female mice. Surprisingly, 2- and 4-hydroxylated estrogen metabolites (HEMs) in the estrogen hydroxylation pathway, but not estrone, estradiol and 16-HEMs, directly increase nociceptor hyperactivity through TRPA1 and TRPV1 channels, and picomolar concentrations of 2- and 4-hydroxylation estrone (OHE1) can sensitize TRPA1 channel function. Moreover, both TRPA1 and TRPV1 are expressed in uterine-innervating primary nociceptors and their expressions are increased in the estrogen-induced uterine pain model. Importantly, pretreatment of 2- or 4-OHE1 recapitulates estrogen-induced uterine pain-like behaviors and intraplantar injections of 2- and 4-OHE1 directly produce a TRPA1-dependent mechanical hypersensitivity. Our findings demonstrate that TRPA1 is critically involved in estrogen-induced uterine pain-like behaviors, which may provide a potential drug target for treating female reproductive tract pain.
Authors
Zili Xie, Jing Feng, Tao Cai, Ronald McCarthy, Mark D. Eschbach II, Yuhui Wang, Yonghui Zhao, Zhihua Yi, Kaikai Zang, Yi Yuan, Xueming Hu, Fengxian Li, Qin Liu, Aditi Das, Sarah K. England, Hongzhen Hu
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