Project description:Dimethyl fumarate (DMF) is an immunomodulatory treatment for multiple sclerosis (MS) that can cross the blood-brain barrier, presenting neuroprotective potential. Its mechanism of action is not fully understood and there is a need to characterize if DMF or its bioactive metabolite monomethyl fumarate (MMF) exert neuroprotective properties. The combination of adjuvant agents such as cannabidiol (CBD) could be relevant to enhance neuroprotection. The aim of this study was to compare the effects of DMF, MMF and CBD on neuroprotective and immunomodulatory pathways in neurons and microglia in vitro. We found that DMF and CBD, but not MMF, activated the Nrf2 antioxidant pathway in neurons. Similarly, only DMF and CBD, but not MMF, prevented the LPS-induced activation of the inflammatory pathway NF-kB in microglia. However, the 3 drugs inhibited the production of nitric oxide in microglia and protected neurons against apoptosis. Transcriptomically, DMF, MMF and CBD exhibited differential effects on these pathways, with DMF achieving the most pronounced changes. Our results show that DMF and MMF, despite being structurally related, present differences in their mechanisms of action that could be relevant for the achievement of neuroprotection in MS patients and the potential of CBD as an adjuvant therapy in neuroprotection.

Project description:Primary human and mouse T cells were treated with the multiple sclerosis drug dimethyl fumarate (DMF) or its in vivo metabolite monomethyl fumarate (MMF). Cysteines sensitive to DMF or MMF were identified using iodoacetamide alkyne enrichment.

Project description:Dimethyl fumarate (DMF) has emerged as first-line therapy for relapsing-remitting multiple scle-rosis (RRMS). This treatment, however, has been limited by adverse effects, which has prompted development of novel derivatives with improved tolerability. We compared effects of fumarates on gene expression in astrocytes. Our analysis included diroximel fumarate (DRF) and its metabolite monomethyl fumarate (MMF), along with a novel compound isosorbide di-(methyl fumarate) (IDMF). Treatment with IDMF resulted in the largest number of differentially expressed genes. The effects of DRF and MMF were consistent with NRF2 activation and NF-kappaB inhibition, respectively. IDMF responses, however, were concordant with both NRF2 activation and NF-kappaB inhibition, and we confirmed IDMF-mediated NF-kappaB inhibition using a reporter assay. IDMF also down-regulated IRF1 expression and IDMF-decreased gene promoters were enriched with IRF1 recognition se-quences. Genes altered by each fumarate overlapped significantly with those near loci from MS genetic association studies, but IDMF had the strongest overall effect on MS-associated genes. These results show that next-generation fumarates such as DRF and IDMF have effects differing from those of the MMF metabolite. Our findings support a model in which IDMF attenuates oxidative stress via NRF2 activation, with suppression of NF-kappaB and IRF1 contributing to mitigation of in-flammation and pyroptosis.

Project description:The fumarate ester dimethyl fumarate (DMF) has been introduced recently for the treatment of relapsing remitting multiple sclerosis (RRMS), a chronic inflammatory condition resulting in neuronal demyelination and axonal loss. The complete mechanism of DMF action is unknown, but involves the depletion of intracellular glutathione and modification of thiols on Kelch-like ECH-associated protein 1 (Keap1), which in turn induces the expression of antioxidant response element genes. Previous work by our laboratory has shown that DMF reacts with a wide range of protein thiols in adipocytes, detected following ester hydrolysis by an antibody recognizing succinated proteins. We proposed that other intracellular thiol residues may also be irreversibly modified by DMF in neurons and astrocytes. DMF treatment of primary rodent neurons and astrocytes, as well as differentiated N1E-115 cells, resulted in the modification of 24 novel target proteins by mass spectrometry. Using this approach, we confirmed the identification and site of modification of the identified proteins, which include cofilin-1, tubulin and collapsin response mediator protein 2 (CRMP2). An in vitro functional assay that measures the ability of cofilin-1 to sever the actin cytoskeleton demonstrated that DMF-modified cofilin-1 loses activity and generates less monomeric actin, potentially inhibiting cofilin’s cytoskeletal remodeling activity; an effect that could be beneficial in the modulation of myelination during RRMS. DMF modification of tubulin did not significantly impact axonal lysosomal trafficking. The oxygen consumption rate of N1E-115 neurons and the levels of proteins related to mitochondrial energy production were only slightly affected by the highest doses of DMF, confirming that DMF treatment does not impair cellular respiratory function. In summary, we demonstrate that in addition to the stimulation of the antioxidant response, DMF resulted in electrophilic modification of novel protein targets that provide new insight on the mechanisms supporting the neuroprotective and re-myelination benefits associated with DMF treatment.

Project description:Delayed-release dimethyl fumarate (DMF) is approved in the United States, European Union, Canada, and Australia for the treatment of multiple sclerosis. DMF is also a component in a defined-mixture product with three salts of monoethyl fumarate (MEF) that is approved in Germany for the treatment of psoriasis. Characterizing common or distinct pharmacodynamic properties of DMF and MEF would provide insights into the mechanisms of action of delayed-release DMF versus fixed combination products containing DMF and MEF salts. In this study we evaluated the pharmacodynamic effects and pharmacokinetics of DMF and MEF in central nervous system and peripheral tissues of naïve mice following a single dose or 10 daily doses of DMF, MEF, or a combination of the two. DMF and MEF exhibited similar pharmacokinetic profiles, but differences were noted in biodistribution: monomethyl fumarate (MMF, the primary metabolite of DMF) exhibited a higher degree of brain penetration, whereas MEF was preferentially partitioned into kidney. Both common and distinct pharmacodynamic responses were observed in all assessed tissues for DMF and MEF alone or in combination. These findings indicate that all fumaric acid esters cannot be considered equivalent, and combinations of compounds may exert effects not observed when agents are used individually.

Project description:Delayed-release dimethyl fumarate (DMF) is approved in the United States, European Union, Canada, and Australia for the treatment of multiple sclerosis. DMF is also a component in a defined-mixture product with three salts of monoethyl fumarate (MEF) that is approved in Germany for the treatment of psoriasis. Characterizing common or distinct pharmacodynamic properties of DMF and MEF would provide insights into the mechanisms of action of delayed-release DMF versus fixed combination products containing DMF and MEF salts. In this study we evaluated the pharmacodynamic effects and pharmacokinetics of DMF and MEF in central nervous system and peripheral tissues of naïve mice following a single dose or 10 daily doses of DMF, MEF, or a combination of the two. DMF and MEF exhibited similar pharmacokinetic profiles, but differences were noted in biodistribution: monomethyl fumarate (MMF, the primary metabolite of DMF) exhibited a higher degree of brain penetration, whereas MEF was preferentially partitioned into kidney. Both common and distinct pharmacodynamic responses were observed in all assessed tissues for DMF and MEF alone or in combination. These findings indicate that all fumaric acid esters cannot be considered equivalent, and combinations of compounds may exert effects not observed when agents are used individually.

Project description:Dimethyl fumarate (DMF) is an effective oral treatment for psoriasis administered in Europe for nearly 60 years. Its potential, however, has been limited by contact dermatitis that prohibits topical application. This paper characterizes a DMF derivative, isosorbide di-(methyl fumarate) (IDMF), which was designed to have anti-psoriatic effects without skin-sensitizing properties. We show that IDMF exhibits neither genotoxicity nor radiation sensitivity in skin fibroblasts and is non-irritating and non-sensitizing in animal models (rat, rabbit, guinea pig). Microarray analysis of cytokine-stimulated keratinocytes showed that IDMF represses the expression of genes specifically up-regulated in psoriatic skin lesions but not those of other skin diseases. IDMF also down-regulated genes induced by IL-17A and TNF in keratinocytes, as well as predicted targets of NF-κB and the anti-differentiation ncRNA (ANCR). IDMF further stimulated transcription of oxidative stress response genes (NQO1, GPX2, GSR) with stronger Nrf2/ARE activation compared to DMF. Finally, IDMF reduced erythema and scaling while repressing expression of immune response genes in psoriasiform lesions elicited by topical application of imiquimod in mice. These data demonstrate that IDMF exbibits anti-psoriatic activity that is similar or improved compared to DMF, without the harsh skin-sensitizing effects that have prevented topical delivery of the parent molecule.

Project description:Dimethyl fumarate (DMF) is an effective oral treatment for psoriasis administered in Europe for nearly 60 years. Its potential, however, has been limited by contact dermatitis that prohibits topical application. This paper characterizes a DMF derivative, isosorbide di-(methyl fumarate) (IDMF), which was designed to have anti-psoriatic effects without skin-sensitizing properties. We show that IDMF exhibits neither genotoxicity nor radiation sensitivity in skin fibroblasts and is non-irritating and non-sensitizing in animal models (rat, rabbit, guinea pig). Microarray analysis of cytokine-stimulated keratinocytes showed that IDMF represses the expression of genes specifically up-regulated in psoriatic skin lesions but not those of other skin diseases. IDMF also down-regulated genes induced by IL-17A and TNF in keratinocytes, as well as predicted targets of NF-κB and the anti-differentiation ncRNA (ANCR). IDMF further stimulated transcription of oxidative stress response genes (NQO1, GPX2, GSR) with stronger Nrf2/ARE activation compared to DMF. Finally, IDMF reduced erythema and scaling while repressing expression of immune response genes in psoriasiform lesions elicited by topical application of imiquimod in mice. These data demonstrate that IDMF exbibits anti-psoriatic activity that is similar or improved compared to DMF, without the harsh skin-sensitizing effects that have prevented topical delivery of the parent molecule.

Project description:Dimethyl fumarate (DMF) is a first-line-treatment for relapsing-remitting multiple sclerosis (RRMS). The redox master regulator Nrf2, essential in redox balance, is a target of DMF, but the precise therapeutic mechanisms remain elusive. Here we show impact of DMF on circulating monocytes and T cells in a prospective longitudinal RRMS patient cohort. DMF increased the level of oxidized isoprostanes in peripheral blood. Other observed changes, including methylome and transcriptome profiles, occur in monocytes prior to T cells. Importantly, monocyte counts and monocytic ROS increase following DMF and distinguish patients with beneficial treatment-response from non-responders. A single nucleotide polymorphism in the ROS-generating NOX3 gene is associated with beneficial DMF treatment-response and suggestively associated with increased ROS generation. Our data implicate monocyte-derived oxidative processes in autoimmune diseases and their treatment, and identify NOX3 genetic variant, monocyte counts and redox state as parameters potentially useful to inform clinical decisions on DMF therapy of RRMS.

Project description:Dimethyl fumarate (DMF) is a first-line-treatment for relapsing-remitting multiple sclerosis (RRMS). The redox master regulator Nrf2, essential in redox balance, is a target of DMF, but the precise therapeutic mechanisms remain elusive. Here we show impact of DMF on circulating monocytes and T cells in a prospective longitudinal RRMS patient cohort. DMF increased the level of oxidized isoprostanes in peripheral blood. Other observed changes, including methylome and transcriptome profiles, occur in monocytes prior to T cells. Importantly, monocyte counts and monocytic ROS increase following DMF and distinguish patients with beneficial treatment-response from non-responders. A single nucleotide polymorphism in the ROS-generating NOX3 gene is associated with beneficial DMF treatment-response and suggestively associated with increased ROS generation. Our data implicate monocyte-derived oxidative processes in autoimmune diseases and their treatment, and identify NOX3 genetic variant, monocyte counts and redox state as parameters potentially useful to inform clinical decisions on DMF therapy of RRMS.