In vivo gene therapy to the liver using lentiviral vectors (LV) may represent a one-and-done therapeutic approach for monogenic diseases. Increasing LV gene therapy potency is crucial for reducing the effective doses, thus alleviating dose-dependent toxicities and facilitating manufacturing. LV-mediated liver transduction may be enhanced by positively selecting LV-transduced hepatocytes after treatment (a posteriori) or by augmenting the initial fraction of LV-targeted hepatocytes (a priori). We show here that the a posteriori enhancement increased transgene output without expansion of hepatocytes bearing LV genomic integrations near cancer genes, in mouse models of hemophilia, an inherited coagulation disorder. Furthermore, we enhanced hepatocyte transduction a priori in mice by transiently inhibiting antiviral pathways and/or through a fasting regimen. The most promising transduction-enhancer combination synergized with phagocytosis-shielded LV, resulting in a remarkable 40-fold increase in transgene output. Overall, our work highlights the potential of minimally invasive, cost-effective treatments capable of improving the potency of in vivo LV gene therapy to hepatocytes, in order to expand its applicability and ease clinical translation.
© 2025. The Author(s).

Liver fibrosis occurs in several genetic and acquired disease conditions, leading to alterations of the tissue and metabolism, which may adversely affect viral vector-mediated gene therapy. Here, we assessed the impact of liver fibrosis on in vivo gene transfer to hepatocytes mediated by lentiviral vectors or adeno-associated viral vectors. We exploited two chemically induced fibrosis mouse models characterized by tissue damage in different areas of the liver lobule. Moreover, we used Abcb11-/- and Agl-/- mice, recapitulating features of inherited cholestasis and glycogen storage disease, as representative models of genetic disorders characterized by liver fibrosis. We report a general negative influence of liver fibrosis on hepatocyte transduction and alteration of the vector distribution within the liver lobule, with different outcomes according to the viral vector used and the state of the liver at the time of vector administration. This study bears implications for future developments and applications of in vivo liver-directed gene therapy.
© 2025. The Author(s).

Injuries to skeletal muscle are among the most common injuries in civilian and military populations, accounting for nearly 60% of extremity injuries. The standard of care for severe extremity injury has been focused upon limb salvage procedures and the utilization of tissue grafts or orthotics in conjunction with rehabilitation to avoid amputation. Nonetheless, many patients have persistent strength and functional deficits that permanently impact their quality of life. Preclinical and clinical studies have shown that partial restoration of functional skeletal muscle tissue following injury can be achieved by the implantation of a biologic scaffold composed of extracellular matrix (ECM). These favorable outcomes are mediated, at least in part, through local immunomodulation. The mechanisms underlying this immunomodulatory effect, however, are poorly understood. The present study investigates a potential mechanistic driver of the immunomodulatory effects; specifically, the effect of selected ECM components upon inflammation resolution and repair. Results show that the host response to skeletal muscle injury is profoundly altered and functional recovery decreased in il33-/- mice compared to age- and sex-matched wildtype counterparts by 14 days post-injury. Results also show that IL-33, contained within matrix-bound nanovesicles (MBV), supports skeletal muscle regeneration by regulating local macrophage activation toward a pro-remodeling phenotype via canonical and non-canonical pathways to improve functional recovery from injury compared to untreated il33-/- counterparts. Taken together, these data suggest that MBV and their associated IL-33 cargo represent a novel homeostatic signaling mechanism that contributes to skeletal muscle repair.
© 2024. The Author(s).

The bone marrow in the skull is important for shaping immune responses in the brain and meninges, but its molecular makeup among bones and relevance in human diseases remain unclear. Here, we show that the mouse skull has the most distinct transcriptomic profile compared with other bones in states of health and injury, characterized by a late-stage neutrophil phenotype. In humans, proteome analysis reveals that the skull marrow is the most distinct, with differentially expressed neutrophil-related pathways and a unique synaptic protein signature. 3D imaging demonstrates the structural and cellular details of human skull-meninges connections (SMCs) compared with veins. Last, using translocator protein positron emission tomography (TSPO-PET) imaging, we show that the skull bone marrow reflects inflammatory brain responses with a disease-specific spatial distribution in patients with various neurological disorders. The unique molecular profile and anatomical and functional connections of the skull show its potential as a site for diagnosing, monitoring, and treating brain diseases.
Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.

The ATR kinase, which coordinates cellular responses to DNA replication stress, is also essential for the proliferation of normal unstressed cells. Although its role in the replication stress response is well defined, the mechanisms by which ATR supports normal cell proliferation remain elusive. Here, we show that ATR is dispensable for the viability of G0-arrested naïve B cells. However, upon cytokine-induced proliferation, Atr-deficient B cells initiate DNA replication efficiently, but by mid-S phase they display dNTP depletion, fork stalling, and replication failure. Nonetheless, productive DNA replication and dNTP levels can be restored in Atr-deficient cells by suppressing origin firing, such as partial inhibition of CDC7 and CDK1 kinase activities. Together, these findings indicate that ATR supports the proliferation of normal unstressed cells by tempering the pace of origin firing during the early S phase to avoid exhaustion of dNTPs and importantly also other replication factors.
© 2023. The Author(s).