Nerve Growth Factor Compromise in Down Syndrome

The basal forebrain cholinergic system relies on trophic support by nerve growth factor (NGF) to maintain its phenotype and function. In Alzheimer’s disease (AD), basal forebrain cholinergic neurons (BFCNs) undergo progressive atrophy, suggesting a deficit in NGF trophic support. Within the central nervous system, NGF maturation and degradation are tightly regulated by an activity-dependent metabolic cascade. Here, we present a brief overview of the characteristics of Alzheimer’s pathology in Down syndrome (DS) with an emphasis on this NGF metabolic pathway’s disruption during the evolving Alzheimer’s pathology. Such NGF dysmetabolism is well-established in Alzheimer’s brains with advanced pathology and has been observed in mild cognitive impairment (MCI) and non-demented individuals with elevated brain amyloid levels. As individuals with DS inexorably develop AD, we then review findings that support the existence of a similar NGF dysmetabolism in DS coinciding with atrophy of the basal forebrain cholinergic system. Lastly, we discuss the potential of NGF-related biomarkers as indicators of an evolving Alzheimer’s pathology in DS.

Oligodendroglial Energy Metabolism and (re)Myelination

Central nervous system (CNS) myelin has a crucial role in accelerating the propagation of action potentials and providing trophic support to the axons. Defective myelination and lack of myelin regeneration following demyelination can both lead to axonal pathology and neurodegeneration. Energy deficit has been evoked as an important contributor to various CNS disorders, including multiple sclerosis (MS). Thus, dysregulation of energy homeostasis in oligodendroglia may be an important contributor to myelin dysfunction and lack of repair observed in the disease. This article will focus on energy metabolism pathways in oligodendroglial cells and highlight differences dependent on the maturation stage of the cell. In addition, it will emphasize that the use of alternative energy sources by oligodendroglia may be required to save glucose for functions that cannot be fulfilled by other metabolites, thus ensuring sufficient energy input for both myelin synthesis and trophic support to the axons. Finally, it will point out that neuropathological findings in a subtype of MS lesions likely reflect defective oligodendroglial energy homeostasis in the disease.

Oligodendroglial Energy Metabolism and (re) Myelination

Central nervous system (CNS) myelin has a crucial role in accelerating the propagation of action potentials and providing trophic support to the axons. Defective myelination and lack of myelin regeneration following demyelination can both lead to axonal pathology and neurodegeneration. Energy deficit has been evoked as an important contributor to various CNS disorders, including multiple sclerosis (MS). This suggests that dysregulation of energy homeostasis in oligodendroglia may be an important contributor to myelin dysfunction and lack of repair observed in the disease. This article will focus on energy metabolism pathways in oligodendroglial cells and highlight differences dependent on the maturation stage of the cell. In addition, it will emphasize that the use of alternative energy sources by oligodendroglia may be required to save glucose for functions that cannot be fulfilled by other metabolites, thus ensuring sufficient energy input for both myelin synthesis and trophic support to the axons. Finally, it will point out that neuropathological findings in a subtype of MS lesions likely reflect defective oligodendroglial energy homeostasis in the disease.

Manufacture and In Vivo Support of Gene-Edited, Regulatory-like, T-Cells (edTreg) Using a Synthetic IL2 Receptor

Regulatory T-cells (Treg) depend on signals from IL2 and their endogenous T-cell receptors to survive, proliferate, and maintain suppressive activity. We have developed a strategy for engineering effector CD4 T-cells into edited, regulatory-like T-cells (edTregs) for treatment of autoimmune disease. edTregs contain a rapamycin-activated synthetic IL2 receptor (designated a chemical-induced signaling complex or CISC) for use in selective cell manufacturing and in vivo trophic support. Our strategy uses gene editing to integrate an MND/ CISC expression cassette into the native FOXP3 locus, resulting in the CISC system cis-linked to expression of the native FOXP3 gene. The resulting high-level and stable expression of FOXP3 converts peripheral T-cells to edTregs with immunosuppressive activity. Cis-linked expression of the CISC system allows for selective cell expansion and in vivo support using rapamycin. Using an optimized protocol, we obtained efficient HDR rates across cells from multiple healthy donors. Edited cells were enriched to >90% purity and expanded 20-50-fold over a 10 day period of culture in rapamycin. Importantly, we demonstrated sustained in vivo suppressive activity of edTregs in a xeno-GvHD mouse model, and successful trophic support of these edTregs by rapamycin (via the CISC) in the absence of effector CD4 T-cells. Along with preliminary data showing successful editing of CD4-positive T-cells from auto-immune disease patients, our data provide pre-clinical proof-of-concept data supporting clinical use of CISC-edTreg in conjunction with rapamycin support for therapy of autoimmune disease. Disclosures Uenishi: Casebia Therapeutics: Employment. Mallari:Casebia Therapeutics: Employment. Gamboa:Casebia Therapeutics: Employment. Boucher:Casebia Therapeutics LLc: Employment. Chin:Casebia Therapeutics LLc: Employment. Aeran:Casebia Therapeutics: Employment. Wodziak:Casebia Therapeutics: Employment. Gebremeskel:Casebia Therapeutics: Employment. Vo:Casebia Therapeutics: Employment. Ito:Casebia Therapeutics: Employment. Patel:Casebia Therapeutics: Employment. Abe:Casebia Therapeutics: Employment. Stankovich:Casebia Therapeutics LLc: Employment. Torgerson:Shire: Consultancy; CSL Behring: Consultancy; ADMA Biosciences: Consultancy; UCB: Consultancy. Scharenberg:Generation Bio: Equity Ownership; Casebia Therapeutics LLc: Employment, Equity Ownership; Alpine Biosciences: Consultancy, Equity Ownership. Cost:Casebia Therapeutics: Employment.