An Intein-based Strategy for the Production of Tag-free Huntingtin Exon 1 Proteins Enables New Insights into the Polyglutamine Dependence of Httex1 Aggregation and Fibril Formation

Annalisa Ansaloni, Hilal Lashuel, Sophie Vieweg, John Blaine Warner IV
Amer Soc Biochemistry Molecular Biology Inc, 2016
Article

Résumé

The first exon of the Huntingtin protein (Httex1) is one of the most actively studied Htt fragments because its overexpression in R6/2 transgenic mice has been shown to recapitulate several key features of Huntington disease. However, the majority of biophysical studies of Httex1 are based on assessing the structure and aggregation of fusion constructs where Httex1 is fused to large proteins, such as glutathione S-transferase, maltosebinding protein, or thioredoxin, or released in solution upon in situ cleavage of these proteins. Herein, we report an inteinbased strategy that allows, for the first time, the rapid and efficient production of native tag-free Httex1 with polyQ repeats ranging from 7Q to 49Q. Aggregation studies on these proteins enabled us to identify interesting polyQ-length-dependent effects on Httex1 oligomer and fibril formation that were previously not observed using Httex1 fusion proteins or Httex1 proteins produced by in situ cleavage of fusion proteins. Our studies revealed the inability of Httex1-7Q/15Q to undergo amyloid fibril formation and an inverse correlation between fibril length and polyQ repeat length, suggesting possible polyQ length-dependent differences in the structural properties of the Httex1 aggregates. Altogether, our findings underscore the importance of working with tag-free Httex1 proteins and indicate that model systems based on non-native Httex1 sequences may not accurately reproduce the effect of polyQ repeat length and solution conditions on Httex1 aggregation kinetics and structural properties.

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https://infoscience.epfl.ch/record/219586?ln=fr

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Annalisa Ansaloni, Hilal Lashuel, Sophie Vieweg, John Blaine Warner IV
Amer Soc Biochemistry Molecular Biology Inc, 2016
Article

Résumé

Official source

https://infoscience.epfl.ch/record/219586?ln=fr

À propos de ce résultat

Concepts associés (11)

Concepts associés

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Publications associées (4)

Publications associées

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The growing demand of biopharmaceutical products is boosting the market for therapeutic recombinant proteins (r-proteins). More than half of the 140 r-proteins that have gained approval for human therapeutic use are manufactured in mammalian cells that make possible complex post-translational modifications, like glycosylation. In the industry, r-proteins are manufactured by stable gene expression (SGE) following Good Manufacturing Practice (GMP) standards. Transient gene expression (TGE) in mammalian cells is an alternative method for the expression of r-proteins whose main advantages are rapidity and flexibility. TGE involves the expression of the protein of interest from plasmids, which are transfected into the cells with a non-viral DNA transfecting agent, usually polyethylenimine (PEI). DNA is transcribed from the plasmids without the latter having been integrated into the host genome. Despite the recent improvements in r-protein titers by TGE and the scale up of this method to the 100-L scale, TGE remains so far a tool for protein production for research purposes. Therefore, to determine if TGE can be used for manufacturing therapeutic r-protein following GMP standards, different features related to reproducibility and product quality from TGE of a recombinant anti-rhesus D immunoglobulin G in HEK-293E cells using linear PEI were characterized. To test the effects of the size distribution and chemical structure of PEI on TGE, different commercially available PEIs were characterized and their impact on transfection and r-protein expression were assessed. The results showed that both the molecular weight distribution and the chemical structure of the PEI had an effect on TGE. However, the small variations in size distribution and structure between the batches of PEI from the same supplier did not affect significantly the transfection and r-protein production by TGE. Then, the fate of PEI and plasmid DNA in cell culture over time and their removal from the final r-protein during purification were determined and measured. Most of the PEI and pDNA remained in the cell culture medium after transfection. However, both PEI and plasmid DNA, which are additional components in TGE compared to processes based on recombinant cell lines, could be reduced to a concentration below the limit of detection of the assays after Protein A affinity purification of the antibody. To test the reproducibility of a TGE process, 10 batches of transfected cells were run in 500-mL orbitally shaken bottles. The cell specific productivity of the antibody was 20.2 ± 2.6 pg.cell-1.day-1 on average for the 10 batches. The purity and size consistency of the recombinant antibody produced in those 10 batches was demonstrated by gel electrophoresis and size exclusion chromatography. Then, the glycosylation profile of the antibody produced by TGE in HEK-293E cells was determined by mass spectrometry and was reproducible over the 10 batches. Moreover, it was similar to the glycosylation profile of the antibody produced by 3 stable HEK-293E cell lines. Finally, as a proof of concept, TGE was applied for the development of a vaccine against the respiratory syncytial virus. The fusion protein of the respiratory syncytial virus was produced by TGE and used as an antigen for the development of a recombinant vaccine. TGE enabled the rapid evaluation of the candidate vaccine in animal trials. Overall, the results of this study suggest that TGE is a reliable and reproducible method for manufacturing r-proteins of a consistent quality, provided that some particular features, such as reagents quality and process parameters, are well defined and controlled. Since TGE makes possible the rapid production of virtually any protein, even toxic, it could be used to provide GMP approved biopharmaceuticals for clinical trials in a short time, reducing development costs of biological therapeutic products.

EPFL2010

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The role of the polyglutamine and N-terminal domains in regulating the aggregation and structural properties of Huntingtin Exon 1

Sophie Vieweg

Huntington Disease (HD) is caused by a CAG repeat expansion in the huntingtin gene leading to the formation of mutant Huntingtin protein (Htt) with an expanded polyglutamine (polyQ) domain (>36Q). Generation of short N-terminal Htt fragments by proteolysis plays a key role in HD pathogenesis and Huntingtin exon1 (Httex1) is one of the most used models to study Htt aggregation in vitro. We developed a new expression and purification strategy to produce tag-free Httex1 and Httex1 fragments with different polyQ-lengths from E.coli for biophysical studies and for optimizing protein semisynthesis in our laboratory. Having these proteins in hand we sought to explore the effect of the polyQ and Nt17 domain on Httex1 aggregation and structure, given their essential role in mediating intra- and intermolecular interactions in Htt. We found that polyQ-length inversely correlates with fibril length and that expanded polyQ tracts increase the Î²-sheet content modulating the roughness and mechanical properties of Httex1 aggregates. This suggests that polyQ-dependent structural differences exist in aggregates formed by wildtype and mutant Httex1. Moreover, using infrared nanospectroscopy we were able to show that Httex1 aggregates are characterized by Î²-turn structures, whereas fibrils formed by Nt17-truncated Httex1 (âNt17-Httex1) contain antiparallel Î²-sheets, indicating that the NT17 domain influences secondary structure within the polyQ domain. The Nt17 effect on Httex1 structure translates into morphological differences between fibrils formed by Httex1 or âNt17-Httex1 as discerned by high-resolution imaging techniques. The presence of the Nt17 domain induces the formation of smooth and regular amyloid-like fibrils, while in absence of the Nt17 domain irregular and broad fibrils are formed due to strong lateral interaction between fibril filaments. Introduction of a helix-breaking proline into the Nt17 domain (M8P-Httex1) revealed that the Nt17 effect on the aggregate morphology is independent of its conformation. Interestingly, we were able to show that the Nt17 domain is not tightly bound within the fibril core of Httex1 fibrils and able to interact with membranes by performing trypsin digests of Httex1 fibrils and comparing the internalization of Httex1, âNt17-Httex1 and M8P-Httex1 fibrils into primary striatal neurons. The Nt17 domain harbors many post-translational modifications, e.g. phosphorylation, SUMOylation, ubiquitination and acetylation, which modulate Htt aggregation and toxicity. Therefore, we aimed at elucidating the effect of SUMOylation on the aggregation and structural properties of Httex1. After production of site-specifically SUMO1-modified Httex1 by semisynthesis, we observed that SUMO1-modification at K6 or K9 increased the compaction and stability of Httex1 inhibiting aggregation. The developed purification strategy enabled an efficient generation of the native Httex1 sequence. Using unmodified and modified (âNt17, M8P, SUMO1) Httex1 variants with varying polyQ lengths we were able to provide novel insights into how the polyQ and Nt17 domains regulate aggregate formation and influence the final aggregate structure. Our results contribute to a better understanding of the molecular determinants of Htt aggregate structure and could facilitate the development of inhibitors or biomarkers of Htt aggregation in vivo.

EPFL2017

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Polyglutamine expansion affects huntingtin conformation in multiple Huntington’s disease models

Sean Michael Deguire, Hilal Lashuel

Conformational changes in disease-associated or mutant proteins represent a key pathological aspect of Huntington's disease (HD) and other protein misfolding diseases. Using immunoassays and biophysical approaches, we and others have recently reported that polyglutamine expansion in purified or recombinantly expressed huntingtin (HTT) proteins affects their conformational properties in a manner dependent on both polyglutamine repeat length and temperature but independent of HTT protein fragment length. These findings are consistent with the HD mutation affecting structural aspects of the amino-terminal region of the protein, and support the concept that modulating mutant HTT conformation might provide novel therapeutic and diagnostic opportunities. We now report that the same conformational TR-FRET based immunoassay detects polyglutamine-and temperaturedependent changes on the endogenously expressed HTT protein in peripheral tissues and post-mortem HD brain tissue, as well as in tissues from HD animal models. We also find that these temperatureand polyglutamine-dependent conformational changes are sensitive to bona-fide phosphorylation on S13 and S16 within the N17 domain of HTT. These findings provide key clinical and preclinical relevance to the conformational immunoassay, and provide supportive evidence for its application in the development of therapeutics aimed at correcting the conformation of polyglutamine-expanded proteins as well as the pharmacodynamics readouts to monitor their efficacy in preclinical models and in HD patients.

Springer Nature2017

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The role of the polyglutamine and N-terminal domains in regulating the aggregation and structural properties of Huntingtin Exon 1

Sophie Vieweg

EPFL2017

EPFL2010