The amyloid- peptide (A) can generate cytotoxic oligomers, and their accumulation is thought to underlie the neuropathologic changes found in Alzheimer's disease. Known inhibitors of A polymerization bind to undefined structures and can work as nonspecific aggregators, and inhibitors that target conformations that also occur in larger A assemblies may even increase oligomerderived toxicity. Here we report on an alternative approach whereby ligands are designed to bind and stabilize the 13-26 region of A in an ␣-helical conformation, inspired by the postulated A native structure. This is achieved with 2 different classes of compounds that also reduce A toxicity to cells in culture and to hippocampal slice preparations, and that do not show any nonspecific aggregatory properties. In addition, when these inhibitors are administered to Drosophila melanogaster expressing human A 1-42 in the central nervous system, a prolonged lifespan, increased locomotor activity, and reduced neurodegeneration is observed. We conclude that stabilization of the central A ␣-helix counteracts polymerization into toxic assemblies and provides a strategy for development of specific inhibitors of A polymerization.amyloid fibrils ͉ neurodegenerative disease ͉ protein misfolding ͉ Alzheimer's disease A lzheimer's disease is a progressive neurodegenerative disorder that is characterized by cerebral extracellular amyloid plaques and intracellular neurofibrillary tangles (1). Classically, the amyloid cascade hypothesis (2) states that Alzheimer's disease is caused by fibril and plaque formation of amyloid- peptide (A) in the central nervous system. More recently, the hypothesis has been modified to include A assemblies of sizes intermediate to monomeric and fibrillar forms, which today are considered to be the main source of cytotoxicity (3). Such A assemblies include low-number oligomers and larger assemblies known as protofibrils, globulomers, Alzheimer's disease diffusible ligands, or A*56 (4-7). A is cleaved from an integral membrane protein, the amyloid  precursor protein (APP), predominantly as a 40-residue peptide (A 1-40 ). In addition, a C-terminally elongated 42-residue version can be excised (A 1-42 ); it is this longer variant that is the main constituent of parenchymal amyloid deposits (8).The link between A aggregation and Alzheimer's disease implies that inhibitors of this process should be able to slow down disease progression. A number of low-molecular-mass A aggregation inhibitors have been identified by use of screens of compound libraries as well as rational design strategies. The resulting inhibitors include such chemically diverse compounds as curcumin, inositol, and nicotine (9, 10). The screens have identified inhibitors of fibril formation that similarly to the rationally designed inhibitors are predicted to bind to A in an elongated, -strand-like conformation and prevent its polymerization. A potential problem with this strategy is that blocking the later stages of fibril formation will favor t...
Poly-N-methylated Amyloid β-Peptide (Aβ) C-Terminal Fragments Reduce Aβ Toxicity in Vitro and in Drosophila melanogaster
Alzheimer's disease (AD), an age related neurodegenerative disorder, threatens to become a major health-economic problem. Assembly of 40- or 42-residue amyloid beta-peptides (Abeta) into neurotoxic oligo-/polymeric beta-sheet structures is an important pathogenic feature in AD, thus, inhibition of this process has been explored to prevent or treat AD. The C-terminal part plays an important role in Abeta aggregation, but most Abeta aggregation inhibitors have targeted the central region around residues 16-23. Herein, we synthesized hexapeptides with varying extents of N-methylation based on residues 32-37 of Abeta, to target its C-terminal region. We measured the peptides' abilities to retard beta-sheet and fibril formation of Abeta and to reduce Abeta neurotoxicity. A penta-N-methylated peptide was more efficient than peptides with 0, 2, or 3 N-methyl groups. This penta-N-methylated peptide moreover increased life span and locomotor activity in Drosophila melanogaster flies overexpressing human Abeta(1-42).
Polymerisation of the amyloid beta-peptide (Abeta) gives rise to oligomers and amyloid fibrils, processes that generate cytotoxic assemblies and are associated with neuronal dystrophy and development of Alzheimer's disease. The relationship between Abeta aggregation and the development of Alzheimer's disease has resulted in immense efforts to find ways to prevent it. In spite of this, therapeutic approaches with proven clinical efficacy remain to be identified. The lack of success so far probably stem from a combination of factors. The details of the Abeta aggregation process (es) are not known, in particular several oligomeric forms have been identified but are not yet defined at a molecular level, Abeta is structurally polymorphic which complicate identification of compounds that bind selectively and strongly, and it is not settled which Abeta species is the main disease causing agent. Herein we review current knowledge about monomeric, oligomeric and polymeric Abeta, and discuss ongoing attempts to identify aggregation inhibitors and problems associated therewith.
Predictably regulating protein expression levels to improve recombinant protein production has become an important tool, but is still rarely applied to engineer mammalian cells. We therefore sought to set-up an easy-to-implement toolbox to facilitate fast and reliable regulation of protein expression in mammalian cells by introducing defined RNA hairpins, termed ‘regulation elements (RgE)’, in the 5′-untranslated region (UTR) to impact translation efficiency. RgEs varying in thermodynamic stability, GC-content and position were added to the 5′-UTR of a fluorescent reporter gene. Predictable translation dosage over two orders of magnitude in mammalian cell lines of hamster and human origin was confirmed by flow cytometry. Tuning heavy chain expression of an IgG with the RgEs to various levels eventually resulted in up to 3.5-fold increased titers and fewer IgG aggregates and fragments in CHO cells. Co-expression of a therapeutic Arylsulfatase-A with RgE-tuned levels of the required helper factor SUMF1 demonstrated that the maximum specific sulfatase activity was already attained at lower SUMF1 expression levels, while specific production rates steadily decreased with increasing helper expression. In summary, we show that defined 5′-UTR RNA-structures represent a valid tool to systematically tune protein expression levels in mammalian cells and eventually help to optimize recombinant protein expression.
Background Affibody molecules are synthetic peptides with a variety of therapeutic and diagnostic applications. To date, Affibody molecules have mainly been produced by the bacterial production host Escherichia coli. There is an interest in exploring alternative production hosts to identify potential improvements in terms of yield, ease of production and purification advantages. In this study, we evaluated the feasibility of Saccharomyces cerevisiae as a production chassis for this group of proteins. Results We examined the production of three different Affibody molecules in S. cerevisiae and found that these Affibody molecules were partially degraded. An albumin-binding domain, which may be attached to the Affibody molecules to increase their half-life, was identified to be a substrate for several S. cerevisiae proteases. We tested the removal of three vacuolar proteases, proteinase A, proteinase B and carboxypeptidase Y. Removal of one of these, proteinase A, resulted in intact secretion of one of the targeted Affibody molecules. Removal of either or both of the two additional proteases, carboxypeptidase Y and proteinase B, resulted in intact secretion of the two remaining Affibody molecules. The produced Affibody molecules were verified to bind their target, human HER3, as potently as the corresponding molecules produced in E. coli in an in vitro surface-plasmon resonance binding assay. Finally, we performed a fed-batch fermentation with one of the engineered protease-deficient S. cerevisiae strains and achieved a protein titer of 530 mg Affibody molecule/L. Conclusion This study shows that engineered S. cerevisiae has a great potential as a production host for recombinant Affibody molecules, reaching a high titer, and for proteins where endotoxin removal could be challenging, the use of S. cerevisiae obviates the need for endotoxin removal from protein produced in E. coli.
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