Top read articles in the last 30 days
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Abstract
Dry age-related macular degeneration (AMD) is a leading cause of untreatable vision loss. In advanced cases, retinal pigment epithelium (RPE) cell loss occurs alongside photoreceptor and choriocapillaris degeneration. We hypothesized that an RPE-patch would mitigate photoreceptor and choriocapillaris degeneration to restore vision. An induced pluripotent stem cell–derived RPE (iRPE) patch was developed using a clinically compatible manufacturing process by maturing iRPE cells on a biodegradable poly(lactic-co-glycolic acid) (PLGA) scaffold. To compare outcomes, we developed a surgical procedure for immediate sequential delivery of PLGA-iRPE and/or PLGA-only patches in the subretinal space of a pig model of laser-induced outer retinal degeneration. Deep learning algorithm-based optical coherence tomography (OCT) image segmentation verified preservation of the photoreceptors over the areas of PLGA-iRPE–transplanted retina and not in laser-injured or PLGA-only–transplanted retina. Adaptive optics imaging of individual cone photoreceptors further supported this finding. OCT-angiography revealed choriocapillaris regeneration in PLGA-iRPE– and not in PLGA-only–transplanted retinas. Our data, obtained using clinically relevant techniques, verified that PLGA-iRPE supports photoreceptor survival and regenerates choriocapillaris in a laser-injured pig retina. Sequential delivery of two 8 mm2 transplants allows for testing of surgical feasibility and safety of the double dose. This work allows one surgery to treat larger and noncontiguous retinal degeneration areas.
Authors
Rohan Gupta, Irina Bunea, Bruno Alvisio, Francesca Barone, Rishabh Gupta, Dara Baker, Haohua Qian, Elena Daniele, Casey G. Contreary, Jair Montford, Ruchi Sharma, Arvydas Maminishkis, Mandeep S. Singh, Maria Teresa Magone De Quadros Costa, Amir H. Kashani, Juan Amaral, Kapil Bharti
Total views: 2016
Abstract
The goal of this study was to determine if transplantation of enteric neural stem cells (ENSCs) can rescue the enteric nervous system, restore gut motility, reduce colonic inflammation, and improve survival in the Ednrb-KO mouse model of Hirschsprung disease (HSCR). ENSCs were isolated from mouse intestine, expanded to form neurospheres, and microinjected into the colons of recipient Ednrb-KO mice. Transplanted ENSCs were identified in recipient colons as cell clusters in “neo-ganglia.” Immunohistochemical evaluation demonstrated extensive cell migration away from the sites of cell delivery and across the muscle layers. Electrical field stimulation and optogenetics showed significantly enhanced contractile activity of aganglionic colonic smooth muscle following ENSC transplantation and confirmed functional neuromuscular integration of the transplanted ENSC-derived neurons. ENSC injection also partially restored the colonic migrating motor complex. Histological examination revealed a significant reduction in inflammation in ENSC-transplanted aganglionic recipient colon compared with that of sham-operated mice. Interestingly, mice that received cell transplant also had prolonged survival compared with controls. This study demonstrates that ENSC transplantation can improve outcomes in HSCR by restoring gut motility and reducing the severity of Hirschsprung-associated enterocolitis, the leading cause of death in human HSCR.
Authors
Ahmed A. Rahman, Takahiro Ohkura, Sukhada Bhave, Weikang Pan, Kensuke Ohishi, Leah Ott, Christopher Han, Abigail Leavitt, Rhian Stavely, Alan J. Burns, Allan M. Goldstein, Ryo Hotta
Total views: 1933
Abstract
Microvascular rarefaction substantially contributes to renal dysfunction following ischemia-reperfusion injury (IRI). We characterized the microRNA signature of extracellular vesicles (EVs) released during endothelial apoptosis to identify biomarkers and regulators of microvascular rarefaction and renal dysfunction. Using in vitro models and RNA-Seq, we found miR-423-5p, let-7b-5p, and let-7c-5p enriched in small EVs from apoptotic endothelial cells. In mouse models of renal IRI and a cohort of 51 patients who have undergone renal transplant with delayed graft function, serum miR-423-5p correlated with circulating EVs, while let-7b-5p and let-7c-5p were also present in free form. Early acute kidney injury saw increased serum miR-423-5p levels linked to small EVs with endothelial markers. Over time, higher serum miR-423-5p levels were associated with large EVs and correlated with greater renal microvascular density and reduced fibrosis. Microvascular density and fibrosis predicted renal function 3 years after transplantation. We explored miR-423-5p’s role in renal homeostasis, finding that its injection during renal IRI preserved microvascular density and inhibited fibrosis. Endothelial cells transfected with miR-423-5p showed enhanced resistance to apoptosis, increased migration, and angiogenesis. Localized miR-423-5p injection in hindlimb ischemia model accelerated revascularization. These findings position miR-423-5p as a predictor of renal microvascular rarefaction and fibrosis, highlighting potential strategies for preserving renal function.
Authors
Francis Migneault, Hyunyun Kim, Alice Doreille, Shanshan Lan, Alexis Gendron, Marie-Hélène Normand, Annie Karakeussian Rimbaud, Martin Dupont, Isabelle Bourdeau, Éric Bonneil, Julie Turgeon, Sylvie Dussault, Pierre Thibault, Mélanie Dieudé, Éric Boilard, Alain Rivard, Héloïse Cardinal, Marie-Josée Hébert
Total views: 1870
Abstract
Tumor-associated neutrophils (TANs) have been shown to promote immunosuppression and tumor progression, and a high TAN frequency predicts poor prognosis in triple-negative breast cancer (TNBC). Dysregulation of CREB-binding protein (CBP)/P300 function has been observed with multiple cancer types. The bromodomain (BRD) of CBP/P300 has been shown to regulate its activity. In this study, we found that IACS-70654, a selective CBP/P300 BRD inhibitor, reduced TANs and inhibited the growth of neutrophil-enriched TNBC models. In the bone marrow, CBP/P300 BRD inhibition reduced the tumor-driven abnormal differentiation and proliferation of neutrophil progenitors. Inhibition of CBP/P300 BRD also stimulated the immune response by inducing an IFN response and MHCI expression in tumor cells and increasing tumor-infiltrated cytotoxic T cells. Moreover, IACS-70654 improved the response of a neutrophil-enriched TNBC model to docetaxel and immune checkpoint blockade. This provides a rationale for combining a CBP/P300 BRD inhibitor with standard-of-care therapies in future clinical trials for neutrophil-enriched TNBC.
Authors
Xueying Yuan, Xiaoxin Hao, Hilda L. Chan, Na Zhao, Diego A. Pedroza, Fengshuo Liu, Kang Le, Alex J. Smith, Sebastian J. Calderon, Nadia Lieu, Michael J. Soth, Philip Jones, Xiang H.F. Zhang, Jeffrey M. Rosen
Total views: 1717
Abstract
Effective, reproducible, and safe delivery of therapeutics into the inner ear is required for the prevention and treatment of hearing loss. A commonly used delivery method is via the posterior semicircular canal (PSCC); however, its specific targeting within the cochlea remains unclear, impacting precision and reproducibility. To assess safety and target specificity, we conducted in vivo recordings of the pharmacological manipulations delivered through the PSCC. Measurements of auditory brainstem response (ABR), vibrometry, and vestibular behavioral and sensory-evoked potential (VsEP) revealed preserved hearing and vestibular functions after artificial perilymph injections. Injection of curare, a mechanoelectrical transducer (MET) channel blocker that affects hearing when in the endolymph, had no effect on ABR or VsEP thresholds. Conversely, injection of CNQX, an AMPA receptor blocker, or lidocaine, a Na+ channel blocker, which affects hearing when in the perilymph, significantly increased both thresholds, indicating that PSCC injections selectively target the perilymphatic space. In vivo tracking of gold nanoparticles confirmed their exclusive distribution in the perilymph during PSCC injection, supporting the pharmacological finding. Together, PSCC injection is a safe method for inner ear delivery, specifically targeting the perilymphatic space. Our findings will allow for precise delivery of therapeutics within the inner ear for therapeutic and research purposes.
Authors
Jinkyung Kim, Jesus Maldonado, Dorothy W. Pan, Patricia M. Quiñones, Samantha Zenteno, John S. Oghalai, Anthony J. Ricci
Total views: 1645
Abstract
Pregnancy is an immunological paradox where despite a competent maternal immune system, regulatory mechanisms at the fetoplacental interface and maternal secondary lymphoid tissues (SLTs) circumvent rejection of semi-allogeneic concepti. Small extracellular vesicles (sEVs) are a vehicle for intercellular communication; nevertheless, the role of fetoplacental sEVs in transport of antigens to maternal SLTs has not been conclusively demonstrated. Using mice in which the conceptus generates fluoroprobe-tagged sEVs shed by the plasma membrane or released from the endocytic compartment, we show that fetoplacental sEVs are delivered to immune cells in the maternal spleen. Injection of sEVs from placentas of females impregnated with Act-mOVA B6 males elicited suboptimal activation of OVA-specific CD8+ OT-I T cells in virgin females as occurs during pregnancy. Furthermore, when OVA+ concepti were deficient in Rab27a, a protein required for sEV secretion, OT-I cell proliferation in the maternal spleen was decreased. Proteomics analysis revealed that mouse trophoblast sEVs were enriched in antiinflammatory and immunosuppressive mediators. Translational relevance was tested in humanized mice injected using sEVs from cultures of human trophoblasts. Our findings show that sEVs deliver fetoplacental antigens to the mother’s SLTs that are recognized by maternal T cells. Alterations of such a mechanism may lead to pregnancy disorders.
Authors
Juliana S. Powell, Adriana T. Larregina, William J. Shufesky, Mara L.G. Sullivan, Donna Beer Stolz, Stephen J. Gould, Geoffrey Camirand, Sergio D. Catz, Simon C. Watkins, Yoel Sadovsky, Adrian E. Morelli
Total views: 1577
Abstract
Transcriptomic analyses have advanced the understanding of complex disease pathophysiology including chronic obstructive pulmonary disease (COPD). However, identifying relevant biologic causative factors has been limited by the integration of high dimensionality data. COPD is characterized by lung destruction and inflammation, with smoke exposure being a major risk factor. To define previously unknown biological mechanisms in COPD, we utilized unsupervised and supervised interpretable machine learning analyses of single-cell RNA-Seq data from the mouse smoke-exposure model to identify significant latent factors (context-specific coexpression modules) impacting pathophysiology. The machine learning transcriptomic signatures coupled to protein networks uncovered a reduction in network complexity and new biological alterations in actin-associated gelsolin (GSN), which was transcriptionally linked to disease state. GSN was altered in airway epithelial cells in the mouse model and in human COPD. GSN was increased in plasma from patients with COPD, and smoke exposure resulted in enhanced GSN release from airway cells from patients with COPD. This method provides insights into rewiring of transcriptional networks that are associated with COPD pathogenesis and provides a translational analytical platform for other diseases.
Authors
Justin Sui, Hanxi Xiao, Ugonna Mbaekwe, Nai-Chun Ting, Kaley Murday, Qianjiang Hu, Alyssa D. Gregory, Theodore S. Kapellos, Ali Öender Yildirim, Melanie Königshoff, Yingze Zhang, Frank Sciurba, Jishnu Das, Corrine R. Kliment
Total views: 1527
Abstract
Urinary obstruction causes injury to the renal medulla, impairing the ability to concentrate urine and increasing the risk of progressive kidney disease. However, the regenerative capacity of the renal medulla after reversal of obstruction is poorly understood. To investigate this, we developed a mouse model of reversible urinary obstruction. Despite robust regeneration and complete histological recovery of the renal medulla, these mice exhibited a permanent defect in urinary concentrating capacity. However, there were lasting changes in the composition, organization, and transcriptional profiles of epithelial, endothelial, and interstitial cells. Persistent inflammatory responses were also seen in patients with renal stone disease, but there were also adaptive responses to the increasingly hypoxic environment of the renal medulla that occurred only after reversal of obstruction. These findings indicate that while partial repair occurs after reversal of urinary obstruction, there are lasting structural and functional changes across all major cellular compartments of the renal medulla. These changes reflect shared and distinct responses to different renal medullary injuries in humans and mice.
Authors
Thitinee Vanichapol, Alex Gonzalez, Rachel Delgado, Maya Brewer, Kelly A. Clouthier, Anna A. Menshikh, William E. Snyder, Teebro Rahman, Veronika Sander, Haichun Yang, Alan J. Davidson, Mark P. de Caestecker
Total views: 1524
Abstract
The homeostasis of IgG is maintained by the neonatal Fc receptor, FcRn. Consequently, antagonism of FcRn to reduce endogenous IgG levels is an emerging strategy for treating antibody-mediated autoimmune disorders using either FcRn-specific antibodies or an engineered Fc fragment. For certain FcRn-specific antibodies, this approach has resulted in reductions in the levels of serum albumin, the other major ligand transported by FcRn. Cellular and molecular analyses of a panel of FcRn antagonists have been carried out to elucidate the mechanisms leading to their differential effects on albumin homeostasis. These analyses have identified 2 processes underlying decreases in albumin levels during FcRn blockade: increased degradation of FcRn and competition between antagonist and albumin for FcRn binding. These findings have potential implications for the design of drugs to modulate FcRn function.
Authors
Guanglong Ma, Andrew R. Crowley, Liesbeth Heyndrickx, Ilse Rogiers, Eef Parthoens, Jolien Van Santbergen, Raimund J. Ober, Vladimir Bobkov, Hans de Haard, Peter Ulrichts, Erik Hofman, Els Louagie, Bianca Balbino, E. Sally Ward
Total views: 1522
Abstract
Expanding the repertoire of CAR therapies to include intracellular antigens holds promise for treating a broad spectrum of malignancies. TCR-like T cells, capable of recognizing intracellular antigen–derived peptides in complex with HLA molecules (pHLA), represent a promising strategy in the field of engineered cellular therapy. This study introduced antibody-like TCR (abTCR) T cells that specifically targeted HLA-A*02:01–restricted LMP2426 peptides, a typical Epstein-Barr virus (EBV) latency II protein, for the treatment of EBV-associated lymphoproliferative diseases (EBV-LPDs). Compared with classic CAR T cells targeting the same epitope, abTCR T cells demonstrated superior efficiency, including increased CD107A expression, enhanced cytotoxicity, and elevated IFN-γ secretion, even when engaging with target cells that naturally present antigens. Moreover, a costimulatory signal–armed abTCR (Co-abTCR), which integrated a costimulatory structure with the abTCR, further enhanced the proliferation and in vivo tumoricidal efficacy of transfected T cells. Collectively, our study developed a potentially novel TCR-like T cell therapy that targets HLA-A*02/LMP2426 for the treatment of EBV-LPDs, providing a potential therapeutic solution for targeting of intracellular antigens in cancer immunotherapy.
Authors
Jiali Cheng, Xuelian Hu, Zhenyu Dai, Yuhao Zeng, Jin Jin, Wei Mu, Qiaoe Wei, Xiangyin Jia, Jianwei Liu, Meng Xie, Qian Luo, Guang Hu, Gaoxiang Wang, Xiaojian Zhu, Jianfeng Zhou, Min Xiao, Jue Wang, Taochao Tan, Liang Huang
Total views: 1415
