Enhanced amyloid fibril formation of insulin in contact with catalytic hydrophobic surfaces

Salagic, Belma

January 2007

<p>The important protein hormone insulin, responsible for different kind of functions in our body but mainly storage of nutrients, has for a long time been used for treatment of diabetic patients. This important protein is both physically and chemically unstable. Especially during production where the insulin protein is exposed to unnatural environmental conditions such as acidic pH has this been causing problems since huge volumes of the product go to waste.</p><p>In the human body the environment for the protein is tolerable with normal body temperature and the right pH, but when the protein is commercially synthesised the environmental conditions are not ultimate. What happens during these unfavourable conditions is that the insulin starts to fibrillate. Meaning that linear, biologically inactive aggregates are formed. If then under these kinds of conditions such as high temperature and acidic pH, the insulin comes in contact with hydrophobic surfaces then the fibrillation of the protein goes even faster.</p><p>In the following experiment I am going to investigate if the experiments and conclusions done before, where different kinds of additives to insulin solutions have been used to enhance the amyloid fibrillation of insulin, are as effective as it has been proposed and I am going to prove that the presence of hydrophobic surfaces, such as coated silicon surfaces or glass and addition of preformed fibrils, so called seeds, increase amyloid fibrillation of the insulin protein under certain conditions, in comparison with the normal fibrillation under the same conditions.</p>

amyloid fibril formation of insulin

enhanced fibril formation of insulin

Bioengineering

Bioteknik

Enhanced amyloid fibril formation of insulin in contact with catalytic hydrophobic surfaces

Salagic, Belma

January 2007

The important protein hormone insulin, responsible for different kind of functions in our body but mainly storage of nutrients, has for a long time been used for treatment of diabetic patients. This important protein is both physically and chemically unstable. Especially during production where the insulin protein is exposed to unnatural environmental conditions such as acidic pH has this been causing problems since huge volumes of the product go to waste. In the human body the environment for the protein is tolerable with normal body temperature and the right pH, but when the protein is commercially synthesised the environmental conditions are not ultimate. What happens during these unfavourable conditions is that the insulin starts to fibrillate. Meaning that linear, biologically inactive aggregates are formed. If then under these kinds of conditions such as high temperature and acidic pH, the insulin comes in contact with hydrophobic surfaces then the fibrillation of the protein goes even faster. In the following experiment I am going to investigate if the experiments and conclusions done before, where different kinds of additives to insulin solutions have been used to enhance the amyloid fibrillation of insulin, are as effective as it has been proposed and I am going to prove that the presence of hydrophobic surfaces, such as coated silicon surfaces or glass and addition of preformed fibrils, so called seeds, increase amyloid fibrillation of the insulin protein under certain conditions, in comparison with the normal fibrillation under the same conditions.

amyloid fibril formation of insulin

enhanced fibril formation of insulin

Bioengineering

Bioteknik

Bri2 BRICHOS domain : Eukaryotic expression and importance of strictly conserved cysteine residues

Hemmingsson, Lovisa

January 2017

Alzheimer’s disease (AD), the most common form of dementia is associated with fibril formation of amyloid-ß peptides (Aß). Aß, proteolytically derived from Aß precursor protein (AßPP), is the major component of amyloid plaques in AD brains. Familial British and Danish dementias (FBD and FDD) share pathological and clinical characteristics with AD, and the underlying mechanisms are associated with amyloid formation of mutant peptides released from the Bri2 protein. Bri2 interacts with AßPP and its BRICHOS domain has been shown to delay Aß40 and Aß42 fibril formation and toxicity in vitro and in vivo. This makes Bri2 BRICHOS a promising anti-amyloid chaperone and a potential treatment strategy for AD. Furthermore, Bri2 BRICHOS possesses a general chaperone activity as it suppresses non-fibrillar aggregation of destabilized citrate synthase (CS). Recent findings show that Bri2 BRICHOS produced in E.coli can form different molecular weight assemblies, ranging from monomers to dimers and poly-disperse oligomers. The oligomers inhibit CS aggregation, whereas the monomers and dimers are more efficient against Aß42 fibrillation and neurotoxicity, respectively. The work in this thesis shows that similar Bri2 BRICHOS quaternary structures are formed in eukaryotic cells as in E.coli. Larger BRICHOS oligomers were found in cell media, derived from proteolytically processed endogenous Bri2 in SH-SY5Y cells, as well as in human embryonic kidney (HEK293) cells transfected with a Bri2 BRICHOS construct. Recombinant human Bri2 BRICHOS mutants with one or none of the two strictly conserved cysteine residues were studied. All mutant monomers become proteolytically degraded during purification, but form stable oligomers. Single Cys to Ser mutants form stable disulfide-dependent dimers that differ in ability to prevent Aß42 fibrillation, the most stable mutant (C164S) being even more efficient than the wildtype Bri2 BRICHOS dimer. This result suggests that intra or intermolecular disulfide(s) and oligomerization affect Bri2 BRICHOS stability and activity towards Aß42 fibril formation.

Bri2 BRICHOS

Aß

Chaperone

Amyloid fibril formation

Alzheimer disease

Eukaryotic expression

Cysteine residues

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi