Lisa Woodworth scite author profile

Liver-directed gene therapy with adeno-associated virus (AAV) vectors effectively treats mouse models of lysosomal storage diseases (LSDs). We asked whether these results were likely to translate to patients. To understand to what extent preexisting anti-AAV8 antibodies could impede AAV8-mediated liver transduction in primates, commonly preexposed to AAV, we quantified the effects of preexisting antibodies on liver transduction and subsequent transgene expression in mouse and nonhuman primate (NHP) models. Using the highest viral dose previously reported in a clinical trial, passive transfer of NHP sera containing relatively low anti-AAV8 titers into mice blocked liver transduction, which could be partially overcome by increasing vector dose tenfold. Based on this and a survey of anti-AAV8 titers in 112 humans, we predict that high-dose systemic gene therapy would successfully transduce liver in >50% of human patients. However, although high-dose AAV8 administration to mice and monkeys with equivalent anti-AAV8 titers led to comparable liver vector copy numbers, the resulting transgene expression in primates was ~1.5-logs lower than mice. This suggests vector fate differs in these species and that strategies focused solely on overcoming preexisting vector-specific antibodies may be insufficient to achieve clinically meaningful expression levels of LSD genes using a liver-directed gene therapy approach in patients.

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CSF1R signaling is a regulator of pathogenesis in progressive MS

Hagan¹,

Kane²,

Grover³

et al. 2020

Cell Death Dis

108

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Microglia serve as the innate immune cells of the central nervous system (CNS) by providing continuous surveillance of the CNS microenvironment and initiating defense mechanisms to protect CNS tissue. Upon injury, microglia transition into an activated state altering their transcriptional profile, transforming their morphology, and producing pro-inflammatory cytokines. These activated microglia initially serve a beneficial role, but their continued activation drives neuroinflammation and neurodegeneration. Multiple sclerosis (MS) is a chronic, inflammatory, demyelinating disease of the CNS, and activated microglia and macrophages play a significant role in mediating disease pathophysiology and progression. Colony-stimulating factor-1 receptor (CSF1R) and its ligand CSF1 are elevated in CNS tissue derived from MS patients. We performed a large-scale RNA-sequencing experiment and identified CSF1R as a key node of disease progression in a mouse model of progressive MS. We hypothesized that modulating microglia and infiltrating macrophages through the inhibition of CSF1R will attenuate deleterious CNS inflammation and reduce subsequent demyelination and neurodegeneration. To test this hypothesis, we generated a novel potent and selective small-molecule CSF1R inhibitor (sCSF1Rinh) for preclinical testing. sCSF1Rinh blocked receptor phosphorylation and downstream signaling in both microglia and macrophages and altered cellular functions including proliferation, survival, and cytokine production. In vivo, CSF1R inhibition with sCSF1Rinh attenuated neuroinflammation and reduced microglial proliferation in a murine acute LPS model. Furthermore, the sCSF1Rinh attenuated a disease-associated microglial phenotype and blocked both axonal damage and neurological impairments in an experimental autoimmune encephalomyelitis (EAE) model of MS. While previous studies have focused on microglial depletion following CSF1R inhibition, our data clearly show that signaling downstream of this receptor can be beneficially modulated in the context of CNS injury. Together, these data suggest that CSF1R inhibition can reduce deleterious microglial proliferation and modulate microglial phenotypes during neuroinflammatory pathogenesis, particularly in progressive MS.

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RIPK1 activation mediates neuroinflammation and disease progression in multiple sclerosis

et al. 2021

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Allogeneic mesenchymal stem cells do not protect NZB × NZW F1 mice from developing lupus disease

Youd¹,

Blickarz²,

Woodworth³

et al. 2010

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SummaryMesenchymal stem cell (MSC) therapy has shown promise clinically in graft-versus-host disease and in preclinical animal models of T helper type 1 (Th1)-driven autoimmune diseases, but whether MSCs can be used to treat autoimmune disease in general is unclear. Here, the therapeutic potential of MSCs was tested in the New Zealand black (NZB) ¥ New Zealand white (NZW) F1 (NZB/W) lupus mouse model. The pathogenesis of systemic lupus erythematosus involves abnormal B and T cell activation leading to autoantibody formation. To test whether the immunomodulatory activity of MSCs would inhibit the development of autoimmune responses and provide a therapeutic benefit, NZB/W mice were treated with Balb/c-derived allogeneic MSCs starting before or after disease onset. Systemic MSC administration worsened disease and enhanced anti-double-stranded DNA (dsDNA) autoantibody production. The increase in autoantibody titres was accompanied by an increase in plasma cells in the bone marrow, an increase in glomerular immune complex deposition, more severe kidney pathology, and greater proteinuria. Co-culturing MSCs with plasma cells purified from NZB/W mice led to an increase in immunoglobulin G antibody production, suggesting that MSCs might be augmenting plasma cell survival and function in MSC-treated animals. Our results suggest that MSC therapy may not be beneficial in Th2-type T cell-and B cell-driven diseases such as lupus and highlight the need to understand further the appropriate application of MSC therapy.

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Potentiation of Gene Transfer to the Mouse Lung by Complexes of Adenovirus Vector and Polycations Improves Therapeutic Potential

Kaplan¹,

Pennington²,

George³

et al. 1998

Human Gene Therapy

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Recombinant adenovirus (Ad) vectors are being considered for in vivo delivery of various therapeutic genes. One limiting factor in the development of Ad-based gene therapy is the low efficiency of gene transfer to target tissues such as vascular endothelium, smooth muscle, and airway epithelium. Complexing Ad vector with various polycations has been shown to enhance transduction of cell lines otherwise resistant to Ad infection in vitro. On the basis of this observation, the activity of Ad/polycation complexes was tested in vivo in the mouse lung. The results indicated that several polycations were capable of enhancing transduction of mouse respiratory epithelium, leading to a 1-2 log increase in levels of transgene expression. Poly-L-lysine (PLL) and DEAE-dextran were examined further and were found to increase Ad-mediated gene transfer without any additional toxicity as assessed histologically or through the measurement of inflammatory cytokines in bronchoalveolar lavages. The two polycations also failed to affect the humoral response against Ad vector and were themselves nonimmunogenic under conditions leading to enhanced gene transfer. Moreover, the ability to use reduced doses of vector complexed with polycations resulted in lower levels of Ad-specific antibodies and, thereby, improved readministration of vector. These results suggest that complexing Ad vectors with polycations has the potential to improve the therapeutic index by increasing transgene expression while reducing unwanted responses associated with high doses of vector.

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Lisa Woodworth

Preexisting Immunity and Low Expression in Primates Highlight Translational Challenges for Liver-directed AAV8-mediated Gene Therapy

CSF1R signaling is a regulator of pathogenesis in progressive MS

RIPK1 activation mediates neuroinflammation and disease progression in multiple sclerosis

Allogeneic mesenchymal stem cells do not protect NZB × NZW F1 mice from developing lupus disease

Potentiation of Gene Transfer to the Mouse Lung by Complexes of Adenovirus Vector and Polycations Improves Therapeutic Potential

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