MdfA is a novel ClpC adaptor protein that functions in the developing spore.

Bacterial protein degradation machinery consists of chaperone-protease complexes that play vital roles in bacterial growth and development and have sparked interest as novel antimicrobial targets. ClpC-ClpP (ClpCP) is one such chaperone-protease complex, recruited by adaptors to specific functions in the model bacterium and other Gram-positive bacteria, including the pathogens and Here we have identified a new ClpCP adaptor protein, MdfA (metabolic differentiation factor A; formerly YjbA), in a genetic screen for factors that help drive toward metabolic dormancy during spore formation. A knockout of stimulates gene expression in the developing spore, while aberrant expression of during vegetative growth is toxic.

Targeting bacterial degradation machinery as an antibacterial strategy.

The exploitation of a cell's natural degradation machinery for therapeutic purposes is an exciting research area in its infancy with respect to bacteria. Here, we review current strategies targeting the ClpCP system, which is a proteolytic degradation complex essential in the biology of many bacterial species of scientific interest. Strategies include using natural product antibiotics or acyldepsipeptides to initiate the up- or down-regulation of ClpCP activity.

Structural Analysis of Sigma Factors.

Bacteria use an array of sigma factors to regulate gene expression during different stages of their life cycles. Full-length, atomic-level structures of sigma factors have been challenging to obtain experimentally as a result of their many regions of intrinsic disorder. AlphaFold has now supplied plausible full-length models for most sigma factors.

Intrinsically disordered proteins: modes of binding with emphasis on disordered domains.

Our notions of protein function have long been determined by the protein structure-function paradigm. However, the idea that protein function is dictated by a prerequisite complementarity of shapes at the binding interface is becoming increasingly challenged. Interactions involving intrinsically disordered proteins (IDPs) have indicated a significant degree of disorder present in the bound state, ranging from static disorder to complete disorder, termed 'random fuzziness'.

Insights Into Peptide Inhibition of Alpha-Synuclein Aggregation.

α-Synuclein (aSyn) aggregation is an attractive target for therapeutic development for a range of neurodegenerative conditions, collectively termed synucleinopathies. Here, we probe the mechanism of action of a peptide 4554W, (KDGIVNGVKA), previously identified through intracellular library screening, to prevent aSyn aggregation and associated toxicity. We utilize NMR to probe association and identify that 4554W associates with a "partially aggregated" form of aSyn, with enhanced association occurring over time.

Cyclophilin D binds to the acidic C-terminus region of α-Synuclein and affects its aggregation characteristics.

Cyclophilin D (CypD) is a peptidyl-prolyl isomerase expressed in the nucleus and transported into the mitochondria where it is best associated with the regulation of the mitochondrial permeability transition pore (MPTP). There are, however, other possible roles of CypD in the mitochondria which may or may not be linked with the MPTP. Alpha synuclein (αSyn) is shown here to interact directly with CypD via its acidic proline-rich C-terminus region and binding at the putative ligand binding pocket of CypD.