Functional Amyloids Are the Rule Rather Than the Exception in Cellular Biology.

Amyloids are a class of protein aggregates that have been historically characterized by their relationship with human disease. Indeed, amyloids can be the result of misfolded proteins that self-associate to form insoluble, extracellular plaques in diseased tissue. For the first 150 years of their study, the pathogen-first definition of amyloids was sufficient. However, new observations of amyloids foster an appreciation for non-pathological roles for amyloids in cellular systems. There is now evidence from all domains of life that amyloids can be non-pathogenic and functional, and that their formation can be the result of purposeful and controlled cellular processes. So-called functional amyloids fulfill an assortment of biological functions including acting as structural scaffolds, regulatory mechanisms, and storage mechanisms. The conceptual convergence of amyloids serving a functional role has been repeatedly confirmed by discoveries of additional functional amyloids. With dozens already known, and with the vigorous rate of discovery, the biology of amyloids is robustly represented by non-pathogenic amyloids.

Tuning Functional Amyloid Formation Through Disulfide Engineering.

Many organisms produce "functional" amyloid fibers, which are stable protein polymers that serve many roles in cellular biology. Certain Enterobacteriaceae assemble functional amyloid fibers called curli that are the main protein component of the biofilm extracellular matrix. CsgA is the major protein subunit of curli and will rapidly adopt the polymeric amyloid conformation in vitro. The rapid and irreversible nature of CsgA amyloid formation makes it challenging to study in vitro. Here, we engineered CsgA so that amyloid formation could be tuned to the redox state of the protein. A double cysteine variant of CsgA called CsgACC was created and characterized for its ability to form amyloid. When kept under oxidizing conditions, CsgACC did not adopt a ß-sheet rich structure or form detectable amyloid-like aggregates. Oxidized CsgACC remained in a soluble, non-amyloid state for at least 90 days. The addition of reducing agents to CsgACC resulted in amyloid formation within hours. The amyloid fibers formed by CsgACC were indistinguishable from the fibers made by CsgA WT. When measured by thioflavin T fluorescence the amyloid formation by CsgACC in the reduced form displayed the same lag, fast, and plateau phases as CsgA WT. Amyloid formation by CsgACC could be halted by the addition of oxidizing agents. Therefore, CsgACC serves as a proof-of-concept for capitalizing on the convertible nature of disulfide bonds to control the aggregation of amyloidogenic proteins.

C. elegans avoids toxin-producing Streptomyces using a seven transmembrane domain chemosensory receptor.

Predators and prey co-evolve, each maximizing their own fitness, but the effects of predator-prey interactions on cellular and molecular machinery are poorly understood. Here, we study this process using the predator Caenorhabditis elegans and the bacterial prey Streptomyces, which have evolved a powerful defense: the production of nematicides. We demonstrate that upon exposure to Streptomyces at their head or tail, nematodes display an escape response that is mediated by bacterially produced cues. Avoidance requires a predicted G-protein-coupled receptor, SRB-6, which is expressed in five types of amphid and phasmid chemosensory neurons. We establish that species of Streptomyces secrete dodecanoic acid, which is sensed by SRB-6. This behavioral adaptation represents an important strategy for the nematode, which utilizes specialized sensory organs and a chemoreceptor that is tuned to recognize the bacteria. These findings provide a window into the molecules and organs used in the coevolutionary arms race between predator and potential prey.

Prognostic value of post-Yttrium 90 radioembolization therapy 18F-fluorodeoxyglucose positron emission tomography in patients with liver tumors.

OBJECTIVE: This study assessed the benefit of post-therapy 18F-FDG PET/CT versus CT alone in identifying malignant liver tumor progression following radioembolization with Y-90 microspheres. METHODS: 24 patients with 44 liver tumors underwent CT imaging pre-radioembolization and PET/CT post-radioembolization. Predictive value of Response Evaluation Criteria in Solid Tumors (RECIST 1.1), The World Health Organization (WHO), mRECIST and European Association for the Study of the Liver (EASL) with PET/CT versus CT alone was assessed. RESULTS: Prediction of liver malignancy progression was improved (p<0.05) for tumors labeled as non-responding based on combined PET/CT with RECIST 1.1, WHO, mRECIST, and EASL criteria compared to assessment without PET. CONCLUSIONS: The addition of post-therapy PET to routine CT in patients with hepatic tumors undergoing radioembolization may improve identification of non-responding tumors.