Selective protein unfolding: a universal mechanism of action for the development of irreversible inhibitors.

High-throughput differential scanning fluorimetry of GFP-tagged proteins (HT-DSF-GTP) was applied for the identification of novel enzyme inhibitors acting by a mechanism termed: selective protein unfolding (SPU). Four different protein targets were interrogated with the same library to identify target-selective hits. Several hits selectively destabilized bacterial biotin protein ligase. Structure-activity relationship data confirmed a structure-dependent mechanism of protein unfolding. Simvastatin and altenusin were confirmed to irreversibly inactivate biotin protein ligase. The principle of SPU combined with HT-DSF-GTP affords an invaluable and innovative workflow for the identification of new inhibitors with potential applications as antimicrobials and other biocides.

Direct and/or Indirect Roles for SUMO in Modulating Alpha-Synuclein Toxicity.

α-Synuclein inclusion bodies are a pathological hallmark of several neurodegenerative diseases, including Parkinson's disease, and contain aggregated α-synuclein and a variety of recruited factors, including protein chaperones, proteasome components, ubiquitin and the small ubiquitin-like modifier, SUMO-1. Cell culture and animal model studies suggest that misfolded, aggregated α-synuclein is actively translocated via the cytoskeletal system to a region of the cell where other factors that help to lessen the toxic effects can also be recruited. SUMO-1 covalently conjugates to various intracellular target proteins in a way analogous to ubiquitination to alter cellular distribution, function and metabolism and also plays an important role in a growing list of cellular pathways, including exosome secretion and apoptosis. Furthermore, SUMO-1 modified proteins have recently been linked to cell stress responses, such as oxidative stress response and heat shock response, with increased SUMOylation being neuroprotective in some cases. Several recent studies have linked SUMOylation to the ubiquitin-proteasome system, while other evidence implicates the lysosomal pathway. Other reports depict a direct mechanism whereby sumoylation reduced the aggregation tendency of α-synuclein, and reduced the toxicity. However, the precise role of SUMO-1 in neurodegeneration remains unclear. In this review, we explore the potential direct or indirect role(s) of SUMO-1 in the cellular response to misfolded α-synuclein in neurodegenerative disorders.

Significance of prion and prion-like proteins in cancer development, progression and multi-drug resistance.

Prions are renowned for their role in neurodegenerative diseases in humans and animals. These are manifested as transmissible spongiform encephalopathies (TSEs) that result from the conversion of the normal glycosylphosphatidylinositol (GPI) anchored cellular prion protein (PrP(c)) to a misfolded, aggregated and pathogenic form, prion protein scrapie (PrP(Sc)) via a post-translational process followed by the accumulation of PrP(Sc) within the central nervous system. New research in this area has demonstrated that PrP is over-expressed in a variety of cancers including gastric, pancreatic and breast cancers, affecting the growth and invasiveness of these cancers as well as playing an important role in the acquisition of multi-drug resistant (MDR) gastric cancer. Prion-like doppel protein (Dpl), sharing 25% amino acid sequence homology to PrP and whose function remains elusive, has also been shown to exhibit a high level of expression in a number of cancers including acute myeloid leukemia's, myelodysplastic syndromes, gastric adenocarcinoma, anaplastic meningioma and astrocytomas. Furthermore, the tumour suppressor protein, p53, already known for its involvement in cancer development, has recently been shown to display prion-like tendencies. This review provides an overview of prions and prion-like proteins in mammals discussing their structure, function and role in cell function and disease. Furthermore, current research progress on the role of prion/prion-like proteins in the development, progression, and drug resistance of various cancers will be summarized. Potential implications for future development of new therapeutic treatments targeting prion and prion-like proteins will be discussed.

A GFP-tagged nucleoprotein-based aggregation assay for anti-influenza drug discovery and antibody development.

Influenza is a viral pandemic that affects millions of people worldwide. Seasonal variations due to genetic shuffling and antigenic drifts in the influenza viruses have necessitated continual updating of therapeutics. The growing resistance to current influenza drugs has increased demand for new antivirals. The highly conserved nature of NP, a multi-functional viral protein that is serotypically distinct and abundantly expressed during infection, has led to its use in developing universal biotherapeutics and vaccines that could be effective against the virus, irrespective of its strain variations. Compounds causing aggregation of NP have recently been shown to be potent antivirals but require the development of new high-throughput assays capable of screening compounds with similar modes of action. Here, we describe the development of a new bioassay for the Influenza A nucleoprotein (NP). The assay was developed to quantify ligand-induced aggregation of a GFP-tagged NP and was validated with aggregation-inducing compounds such as nucleozin and a NP-specific antibody. The new NP-GFP aggregation assay can be performed with partially purified or mixtures of proteins and is amenable to a high-throughput format. Using this assay, we demonstrate the potential of a new anti-NP polyclonal antibody that we have obtained from chicken. This cost-effective high-yield source of anti-NP IgY has potential for large-scale production and development of therapeutic antibodies. The simplicity, speed and flexibility of this assay make it an invaluable tool for timely development of effective antivirals that can help to control future epidemics.

Alzheimer's Abeta fused to green fluorescent protein induces growth stress and a heat shock response.

The 42 amino acid Alzheimer's Abeta peptide is involved in the progression of Alzheimer's disease. Here we describe the effects of intracellular Abeta, produced through its attachment to either end of a green fluorescent protein, in yeast. Cells producing Abeta exhibited a lower growth yield and a heat shock response, showing that Abeta fusions promote stress in cells and supporting the notion that intracellular Abeta is a toxic molecule. These studies have relevance in understanding the role of Abeta in the death of neuronal cells, and indicate that yeast may be a new tractable model system for the screening for inhibitors of the stress caused by Abeta.