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Chimeric antigen receptor (CAR) T cell expansion and persistence represent key factors to achieve complete responses and prevent relapses. These features are typical of early memory T cells, which can be highly enriched through optimized manufacturing protocols. Here, we investigated the efficacy and safety profiles of CAR T cell products generated from preselected naive/stem memory T cells (TN/SCM), as compared with unselected T cells (TBULK). Notwithstanding their reduced effector signature in vitro, limiting CAR TN/SCM doses showed superior antitumor activity and the unique ability to counteract leukemia rechallenge in hematopoietic stem/precursor cell-humanized mice, featuring increased expansion rates and persistence together with an ameliorated exhaustion and memory phenotype. Most relevantly, CAR TN/SCM proved to be intrinsically less prone to inducing severe cytokine release syndrome, independently of the costimulatory endodomain employed. This safer profile was associated with milder T cell activation, which translated into reduced monocyte activation and cytokine release. These data suggest that CAR TN/SCM are endowed with a wider therapeutic index compared with CAR TBULK.

gamma-Retroviral vectors (gammaRVs), which are commonly used in gene therapy, can trigger oncogenesis by insertional mutagenesis. Here, we have dissected the contribution of vector design and viral integration site selection (ISS) to oncogenesis using an in vivo genotoxicity assay based on transplantation of vector-transduced tumor-prone mouse hematopoietic stem/progenitor cells. By swapping genetic elements between gammaRV and lentiviral vectors (LVs), we have demonstrated that transcriptionally active long terminal repeats (LTRs) are major determinants of genotoxicity even when reconstituted in LVs and that self-inactivating (SIN) LTRs enhance the safety of gammaRVs. By comparing the genotoxicity of vectors with matched active LTRs, we were able to determine that substantially greater LV integration loads are required to approach the same oncogenic risk as gammaRVs. This difference in facilitating oncogenesis is likely to be explained by the observed preferential targeting of cancer genes by gammaRVs. This integration-site bias was intrinsic to gammaRVs, as it was also observed for SIN gammaRVs that lacked genotoxicity in our model. Our findings strongly support the use of SIN viral vector platforms and show that ISS can substantially modulate genotoxicity.

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. Lentiviral vectors are promising gene delivery vehicles to target hepatocytes in vivo, but restriction factors limit their efficiency. Here, the authors counteract many of these restrictions, amplifying lentiviral gene transfer into hepatocytes, strengthening its translational potential.

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. Simoni et al. show that liver fibrosis has a negative impact on in vivo viral vector-mediated gene transfer to hepatocytes in chemically induced and genetic mouse models varying on the type and severity of the pre-existing fibrosis and vector used.

Smoldering multiple myeloma (SMM), which is in principle curable, may develop into life-threatening MM. Intestinal microbiota and gut-born T helper-17 (Th17) lymphocytes may contribute to this development, but the mechanisms are unclear. Here we demonstrate that administering the human commensal Prevotella melaninogenica to transgenic Vk*MYC mice that exhibit SMM-like phenotypes delays the evolution to full-blown MM. Mechanistically, P. melaninogenica increases the production of short-chain fatty acids (SCFA), thereby preventing the skewing of dendritic cells towards a pro-Th17 phenotype and subsequently accumulation of Th17 cells in the bone marrow of treated mice. P. melaninogenica or butyrate synergizes with anti-PD-L1 or anti-TIGIT to suppress myeloma progression by restraining Th17 cell expansion while inducing effector CD8 + T cells. P. melaninogenica also attenuates IL-17-mediated skin lesions that mimic anti-PD-L1-induced adverse events. Our results thus suggest that gut microbiota modulation or SCFAs administration may represent treatment options for patients affected by plasma cell dyscrasias. Smoldering multiple myeloma (SMM) may develop into life- threatening MM, with gut microbiota and Th17 possibly contributing to this progression via unknown mechanisms. Here the authors use a mouse SMM model, VkMYC mice, to show that treatments with butyrate or the commensal, Prevotella melaninogenica , suppress Th17 and cancer progression.

Self-inactivating (SIN) lentiviral vectors (LV) have an excellent therapeutic potential as demonstrated in preclinical studies and clinical trials. However, weaker mechanisms of insertional mutagenesis could still pose a significant risk in clinical applications. Taking advantage of novel in vivo genotoxicity assays, we tested a battery of LV constructs, including some with clinically relevant designs, and found that oncogene activation by promoter insertion is the most powerful mechanism of early vector-induced oncogenesis. SIN LVs disabled in their capacity to activate oncogenes by promoter insertion were less genotoxic and induced tumors by enhancer-mediated activation of oncogenes with efficiency that was proportional to the strength of the promoter used. On the other hand, when enhancer activity was reduced by using moderate promoters, oncogenesis by inactivation of tumor suppressor gene was revealed. This mechanism becomes predominant when the enhancer activity of the internal promoter is shielded by the presence of a synthetic chromatin insulator cassette. Our data provide both mechanistic insights and quantitative readouts of vector-mediated genotoxicity, allowing a relative ranking of different vectors according to these features, and inform current and future choices of vector design with increasing biosafety.

Despite recent progress in cancer treatment, liver metastases persist as an unmet clinical need. Here, we show that arming liver and tumor-associated macrophages in vivo to co-express tumor antigens (TAs), IFNα, and IL-12 unleashes robust anti-tumor immune responses, leading to the regression of liver metastases. Mechanistically, in vivo armed macrophages expand tumor reactive CD8 + T cells, which acquire features of progenitor exhausted T cells and kill cancer cells independently of CD4 + T cell help. IFNα and IL-12 produced by armed macrophages reprogram antigen presenting cells and rewire cellular interactions, rescuing tumor reactive T cell functions. In vivo armed macrophages trigger anti-tumor immunity in distinct liver metastasis mouse models of colorectal cancer and melanoma, expressing either surrogate tumor antigens, naturally occurring neoantigens or tumor-associated antigens. Altogether, our findings support the translational potential of in vivo armed liver macrophages to expand and rejuvenate tumor reactive T cells for the treatment of liver metastases. Liver metastases are a clinical problem, with low responses to immunotherapy. Here, authors coordinate expression of tumor antigens IFNα and IL-12 in liver and tumor associated macrophages to rejuvenate tumor reactive T cells and eliminate liver metastases.

The immunosuppressive microenvironment surrounding tumor cells represents a key cause of treatment failure. Therefore, immunotherapies aimed at reprogramming the immune system have largely spread in the past years. We employed gene transfer into hematopoietic stem and progenitor cells to selectively express anti‐tumoral cytokines in tumor‐infiltrating monocytes/macrophages. We show that interferon‐γ (IFN‐γ) reduced tumor progression in mouse models of B‐cell acute lymphoblastic leukemia (B‐ALL) and colorectal carcinoma (MC38). Its activity depended on the immune system's capacity to respond to IFN‐γ and drove the counter‐selection of leukemia cells expressing surrogate antigens. Gene‐based IFN‐γ delivery induced antigen presentation in the myeloid compartment and on leukemia cells, leading to a wave of T cell recruitment and activation, with enhanced clonal expansion of cytotoxic CD8 + T lymphocytes. The activity of IFN‐γ was further enhanced by either co‐delivery of tumor necrosis factor‐α (TNF‐α) or by drugs blocking immunosuppressive escape pathways, with the potential to obtain durable responses. SYNOPSIS IFN‐γ gene therapy is safe and reduces tumor progression in mouse models of B‐cell acute lymphoblastic leukemia and colorectal carcinoma. Its effects are immune‐mediated through antigen‐presentation and reprogramming of the tumor microenvironment. IFN‐γ antitumor effects are driven by immune activation through antigen presentation, clonal T cell expansion, and TME reprogramming. Combining IFN‐γ gene therapy with other immunotherapies leads to enhanced and prolonged anti‐tumoral activity. Graphical Abstract IFN‐γ gene therapy is safe and reduces tumor progression in mouse models of B‐cell acute lymphoblastic leukemia and colorectal carcinoma. Its effects are immune‐mediated through antigen‐presentation and reprogramming of the tumor microenvironment.

Boosting antitumor immunity has emerged as a powerful strategy in cancer treatment. While releasing T‐cell brakes has received most attention, tumor recognition by T cells is a pre‐requisite. Radiotherapy and certain cytotoxic drugs induce the release of damage‐associated molecular patterns, which promote tumor antigen cross‐presentation and T‐cell priming. Antibodies against the “do not eat me” signal CD47 cause macrophage phagocytosis of live tumor cells and drive the emergence of antitumor T cells. Here we show that CXCR4 activation, so far associated only with tumor progression and metastasis, also flags tumor cells to immune recognition. Both CXCL12, the natural CXCR4 ligand, and BoxA, a fragment of HMGB1, promote the release of DAMPs and the internalization of CD47, leading to protective antitumor immunity. We designate as Immunogenic Surrender the process by which CXCR4 turns in tumor cells to macrophages, thereby subjecting a rapidly growing tissue to immunological scrutiny. Importantly, while CXCL12 promotes tumor cell proliferation, BoxA reduces it, and might be exploited for the treatment of malignant mesothelioma and a variety of other tumors. Synopsis Induction of antitumor immunity is a successful strategy in cancer treatment. This study reports that BoxA, a fragment of the alarmin HMGB1, induces tumor remission and antitumor immunity in mouse models of mesothelioma and colon carcinoma. Both BoxA and the chemokine CXCL12 bind the G‐Protein Coupled Receptor CXCR4. CXCR4 and CD47 are in contact on the surface of tumor cells and co‐internalize upon CXCR4 engagement by either BoxA or CXCL12. Both CXCL12 and BoxA induce the phagocytosis of tumor cells by macrophages. BoxA inhibits tumor cell growth and induces antitumor immunological memory in syngeneic mouse models of mesothelioma or colon carcinoma. CXCL12 is suggested to mediate a similar response (Immunogenic Surrender) in a fraction of untreated tumor‐bearing mice. Graphical Abstract Induction of antitumor immunity is a successful strategy in cancer treatment. This study reports that BoxA, a fragment of the alarmin HMGB1, induces tumor remission and antitumor immunity in mouse models of mesothelioma and colon carcinoma.

Pulmonary infections caused by Mycobacterium abscessus (MA) have increased over recent decades, affecting individuals with underlying pathologies such as chronic obstructive pulmonary disease, bronchiectasis and, especially, cystic fibrosis. The lack of a representative and standardized model of chronic infection in mice has limited steps forward in the field of MA pulmonary infection. To overcome this challenge, we refined the method of agar beads to establish MA chronic infection in immunocompetent mice. We evaluated bacterial count, lung pathology and markers of inflammation and we performed longitudinal studies with magnetic resonance imaging (MRI) up to three months after MA infection. In this model, MA was able to establish a persistent lung infection for up to two months and with minimal systemic spread. Lung histopathological analysis revealed granulomatous inflammation around bronchi characterized by the presence of lymphocytes, aggregates of vacuolated histiocytes and a few neutrophils, mimicking the damage observed in humans. Furthermore, MA lung lesions were successfully monitored for the first time by MRI. The availability of this murine model and the introduction of the successfully longitudinal monitoring of the murine lung lesions with MRI pave the way for further investigations on the impact of MA pathogenesis and the efficacy of novel treatments.