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Purification and Uptake Studies of Recombinant Human N-α-D-Acetylglucosaminidase from Sf9 Insect CellsMorris, Geoffrey 27 August 2015 (has links)
Human α-N-acetylglucosaminidase (Naglu) is a lysosomal enzyme implicated in the rare metabolic storage disorder Mucopolysaccharidosis III type B (MPS IIIB). A deficiency in Naglu results in a buildup of heparan sulfate in lysosomes, which is most detrimental in the central nervous system, causing mental retardation and a shortened lifespan. Enzyme replacement therapy is currently ineffective in treating the neurological symptoms of MPS IIIB due to the inability of Naglu to cross the blood-brain barrier. This laboratory uses a Spodoptera frugiperda insect cell system to express recombinant Naglu conjugated to a synthetic protein transduction domain with the intent to allow Naglu to cross the blood-brain barrier and treat the neurological symptoms.
In the present study, we aimed to purify a recombinant Naglu-PTD4 fusion protein in order to assess its capacity to cross cellular membranes. A three-step method involving multi-modal, hydrophobic interaction, and gel filtration chromatography was optimized to achieve pure Naglu-PTD4, in good yield. Cellular uptake by human MPSIIIB fibroblasts of Naglu-PTD4 was not detectable. It is hypothesized that additional amino acids, including a hexahistidine domain, following the PTD4 domain limited the fusion protein’s membrane transduction capacity. Future studies will focus on removing the additional amino acids and adjusting the purification method as necessary. The ultimate goal of this research is to develop a large-scale recombinant Naglu production protocol for enzyme replacement therapy of MPS IIIB. / Graduate
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Molecular techniques for therapeutic and diagnostic applications in Mucopolysaccharidosis IIIB and Gaucher diseaseChristensen, Chloe L. 22 December 2020 (has links)
There is an unmet need to develop and test treatments for rare lysosomal disease (LD). Most LDs are present in childhood and do not currently have approved therapies. Rare diseases individually are uncommon but taken together account for a population prevalence of 3.5-5.9% worldwide. Due to their rarity, it often takes significant time and effort to diagnose rare diseases. New diagnostic tools, especially for early detection, will offer an advantage in avoiding this diagnostic odyssey. This dissertation is focused on investigating novel diagnostic and treatment methods in vitro for two neurodegenerative LDs: Gaucher disease (GD) and mucopolysaccharidosis IIIB (MPS IIIB). Mutations in NAGLU and GBA1, the genes that encode for lysosomal hydrolases required for degradation of heparan sulfate and glucocerebrosides, lead to the observed pathogenesis in MPS IIIB and GD, respectively. Since many LDs, including MPS IIIB and some forms of GD, are neurodegenerative, cell and gene-based therapeutic strategies are of significant interest. Therapeutics that offer some symptom mitigation in other LDs, such as enzyme replacement or substrate reduction therapies, do not offer appreciable disease mitigation in MPS IIIB or neurodegenerative GD.
Here, a novel compound heterozygous mutation, NAGLUY140C/R297X, that results in approximately 50% residual NAGLU protein and 0.6% NAGLU enzyme activity is reported in NAGLU. Furthermore, a RFLP and site-directed mutagenesis strategy was developed to identify the presence of the relatively common p.R297X mutation in patient cell samples, in addition to two other novel molecular assays for the detection of the p.E153K mutation in NAGLU and p.N370S mutation in GBA1. MPS IIIB and GD human skin fibroblasts were reprogrammed to iPSCs using non-integrating Sendai viral vectors with a reprogramming efficiency of 0.2% and 0.3%, respectively. Resulting iPS cell lines were confirmed as being pluripotent through a barrage of analyses for markers of pluripotency and differentiation. Intriguingly, early passage MPS IIIB iPSCs were found to exhibit increased cell death and spontaneous differentiation to embryoid body-like structures, which was hypothesized to be caused by fibroblast growth factor 2 (FGF2) sequestration or degradation due to inherent heparan sulfate dysregulation. Supplemental FGF2 (100 ng/mL) was found to significantly increase confluency of MPS IIIB iPSCs after 48 hours (n = 5, p ≤ 0.05) and persisting to 96 hrs (n = 5, p ≤ 0.05), thus providing evidence for an important role of FGF2-heparan sulfate interactions in the maintenance of stem cell pluripotency. These findings highlight the importance of considering inherent disease pathology when developing disease models.
Three genome editing strategies, CRISPR-Cas9, base and prime editing, are addressed throughout this dissertation. Genome editing outcomes in NAGLU and GBA1, as well as a control gene, HPRT1, are reported in HEK293 cells, human skin fibroblasts, and induced pluripotent stem cells (iPSCs). Although CRISPR-HDR failed to yield mutation correction, base editing of the common p.N370S (c.1226 A>G) in GD skin fibroblasts using with 42% efficiency is reported. Base editing of HPRT1 in HEK293 cells with an overall editing efficiency of 6 ± 0.5% (n = 3), but interestingly, when base editing at the centered nucleotide was analyzed, the editing efficiency increases to 27 ± 4.3% (n = 3). These findings align with other reports of a centered nucleotide preference for base editors and will help direct genome editing strategies in the future. This dissertation describes the first genome editing in NAGLU, and the first base editing in GBA1, and underscores the importance of optimizing genome editing strategies when targeting disease-causing mutations in patient-derived cells. The findings reported here will direct future genome editing strategies for developing cell and gene-based therapies for MPS IIIB and GD. / Graduate / 2021-12-15
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Purification of human recombinant Naglu from Sf9 cells and uptake studies with MPS IIIB fibroblastsAshmead, Rhea 15 July 2019 (has links)
Mucopolysaccharidosis IIIB (MPS IIIB) is a rare, metabolic disorder that results from a deficiency in the lysosomal hydrolase, α-N-acetylglucosaminidase (Naglu). Naglu is a housekeeping enzyme involved in the degradation pathway of heparan sulfate. A deficiency in active Naglu leads to an accumulation of heparan sulfate within the lysosome, initiating a pathological cascade within the cell. Patients with MPS IIIB experience progressive central nervous system degeneration and die within the first few decades of life. Presently, enzyme replacement therapy, which is a standard of care for other lysosomal storage disorders, is an ineffective treatment for MPS IIIB. This is due to impermeability of the blood-brain barrier (BBB) to exogenous recombinant enzymes. A promising approach to this therapeutic obstacle is protein transduction domains. Protein transduction domains have been shown to facilitate the delivery of active enzyme across the BBB in mice.
Previously, our laboratory used Spodoptera frugiperda (Sf9) insect cell system to express human recombinant Naglu fused to a synthetic protein transduction domain (PTD4). The purpose was to use PTD4 to the facilitate the delivery of Naglu across biological membranes, including the blood-brain barrier. However, a missing stop codon following PTD4 limited its transducibility. The stop codon was re-introduced and the improved fusion enzyme, Naglu-PTD4X, was stably expressed in Sf9 cells. The overarching goal of this project is to create a large-scale production of human recombinant Naglu that has the potential to be used to treat the neuropathology of patients with MPS IIIB.
This project used a three-step purification system to purify Naglu-PTD4X. Uptake of Naglu-PTD4X was assessed in MPS IIIB fibroblasts using a fluorogenic activity assay, immunoblotting, and immunocytochemistry. Our purification system was successful at purifying Naglu-PTD4X to homogeneity with a 26% yield and specific activity of 84,000 units/mg. An increase in Naglu activity was detected in MPS IIIB fibroblasts following incubation with Naglu-PTD4X. Future directions will focus on optimizing immunodetection and conducting BBB penetration studies in murine models. / Graduate / 2020-06-21
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Expression of human α-N-Acetylglucosaminidase in Sf9 insect cells: effect of cryptic splice site removal and native secretion-signaling peptide addition.Jantzen, Roni Rebecca 15 August 2011 (has links)
Human α-N-Acetylglucosaminidase (Naglu) is a lysosomal acid hydrolase
implicated in tthe rare metabolic storage disorder known as mucopolysaccharidosis type
IIIB (MPS IIIB; also Sanfilippo syndrome B). Absence of this enzyme results in
cytotoxic accumulation of heparan sulphate in the central nervous system, causing mental
retardation and a shortened lifespan. Enzyme replacement therapy is not currently
effective to treat neurological symptoms due to the inability of exogenous Naglu to
access the brain. This laboratory uses a Spodoptera frugiperda (Sf9) insect cell system to
express Naglu fused to a synthetic protein transduction domain with the intent to
facilitate delivery of Naglu across the blood-brain barrier.
The project described herein may be broken down into three main sections.
Firstly, the impact of two cryptic splice sites on Naglu expression levels was analyzed in
both transiently expressing Sf9 cultures and stably selected cell lines. Secondly, the
effectiveness of the native Naglu secretion-signaling peptide in the Sf9 system was
examined. Finally, purification of a Naglu fusion protein from suspension culture
medium was performed using hydrophobic interaction chromatographic techniques.
The ultimate goal of this research is to develop an efficient system for
economical, large-scale production of a human recombinant Naglu fusion protein that has
the potential to be successfully used for enzyme replacement therapy to treat MPS IIIB. / Graduate
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