Thermal characterization of the multimeric bacteriophage endolysin PlyC

Bacteriophage endolysins degrade the bacterial peptidoglycan and are considered enzymatic alternatives to small molecule antibiotics. In particular, the multimeric streptococcal endolysin PlyC has appealing antibacterial properties. However, a comprehensive thermal analysis of PlyC is lacking, which is necessary for evaluating long-term stability and downstream therapeutic potential. Biochemical and kinetic-based methods were used in combination with differential scanning calorimetry to investigate the structural, kinetic and thermodynamic stability of PlyC and its various subunits and domains. The PlyC holoenzyme structure is irreversibly compromised due to partial unfolding and aggregation at 46°C. Unfolding of the catalytic subunit, PlyCA, instigates this event, resulting in the kinetic inactivation of the endolysin. In contrast to PlyCA, the PlyCB octamer (the cell wall binding domain) is thermostable, denaturing at ~75°C. Isolation of PlyCA or PlyCB alone altered their thermal properties. Contrary to the holoenzyme, PlyCA alone unfolds uncooperatively and is thermodynamically destabilized whereas the PlyCB octamer reversibly dissociates into monomers and forms an intermediate state at 74°C in phosphate buffered saline, with each subunit subsequently denaturing at 927°C. Adding folded PlyCA to an intermediate state PlyCB, followed by cooling, allowed for in vitro reconstitution of the active holoenzyme.

Effect of Humid Air Exposed to IR Radiation on Enzyme Activity

Water vapor absorbs well in the infra-red region of the electromagnetic spectrum. Absorption of radiant energy by water or water droplets leads to formation of exclusion zone water that possesses peculiar physico-chemical properties. In the course of this study, normally functioning and damaged alkaline phosphatase, horseradish peroxidase and catalase were treated with humid air irradiated with infrared light with a wavelength in the range of 1270 nm and referred to as coherent humidity (CoHu). One-minute long treatment with CoHu helped to partially protect enzymes from heat inactivation, mixed function oxidation, and loss of activity due to partial unfolding. Authors suggest that a possible mechanism underlying the observed effects involves altering the physicochemical properties of aqueous media while treatment of the objects with CoHu where CoHu acts as an intermediary.

Computational and biochemical analyses reveal that cofilin-2 self assembles into amyloid-like structures and promotes the aggregation of other proteinaceous species: Pathogenic relevance to myopathies

Cofilin-2 is a member of the ADF/cofilin family, expressed extensively in adult muscle cells and involved in muscle maintenance and regeneration. Phosphorylated cofilin-2 is found in pre-fibrillar aggregates formed during idiopathic dilated cardiomyopathy. A recent study shows that phosphorylated cofilin-2, under oxidative distress, forms fibrillar aggregates. However, it remains unknown if cofilin-2 holds an innate propensity to form amyloid-like structures. In the present study, we employed various computational and biochemical techniques to explore the amyloid-forming potential of cofilin-2. We report that cofilin-2 possesses aggregation-prone regions (APRs), and these APRs get exposed to the surface, become solvent-accessible, and are involved in the intermolecular interactions during dimerization, an early stage of aggregation. Furthermore, the cofilin-2 amyloids, formed under physiological conditions, are capable of cross-seeding other monomeric globular proteins and amino acids, thus promoting their aggregation. We further show that Cys-39 and Cys-80 are critical in maintaining the thermodynamic stability of cofilin-2. The destabilizing effect of oxidation at Cys-39 but not that at Cys-80 is mitigated by Ser-3 phosphorylation. Cysteine oxidation leads to partial unfolding and loss of structure, suggesting that cysteine oxidation further induces early events of cofilin-2 aggregation. Overall, our results pose a possibility that cofilin-2 amyloidogenesis might be involved in the pathophysiology of diseases, such as myopathies. We propose that the exposure of APRs to the surface could provide mechanistic insight into the higher-order aggregation and amyloidogenesis of cofilin-2. Moreover, the cross-seeding activity of cofilin-2 amyloids hints towards its involvement in the hetero-aggregation in various amyloid-linked diseases.

Pathogenic D76N Variant of β2-Microglobulin: Synergy of Diverse Effects in Both the Native and Amyloid States

β2-microglobulin (β2m), the light chain of the MHC-I complex, is associated with dialysis-related amyloidosis (DRA). Recently, a hereditary systemic amyloidosis was discovered, caused by a naturally occurring D76N β2m variant, which showed a structure remarkably similar to the wild-type (WT) protein, albeit with decreased thermodynamic stability and increased amyloidogenicity. Here, we investigated the role of the D76N mutation in the amyloid formation of β2m by point mutations affecting the Asp76-Lys41 ion-pair of WT β2m and the charge cluster on Asp38. Using a variety of biophysical techniques, we investigated the conformational stability and partial unfolding of the native state of the variants, as well as their amyloidogenic propensity and the stability of amyloid fibrils under various conditions. Furthermore, we studied the intermolecular interactions of WT and mutant proteins with various binding partners that might have in vivo relevance. We found that, relative to WT β2m, the exceptional amyloidogenicity of the pathogenic D76N β2m variant is realized by the deleterious synergy of diverse effects of destabilized native structure, higher sensitivity to negatively charged amphiphilic molecules (e.g., lipids) and polyphosphate, more effective fibril nucleation, higher conformational stability of fibrils, and elevated affinity for extracellular components, including extracellular matrix proteins.

Cryo-EM structures of the translocational binary toxin complex CDTa-bound CDTb-pore from Clostridioides difficile

Besides two large cytotoxins (TcdA and TcdB), certain Clostridioides difficile strains also produce a binary toxin, called C. difficile toxin (CDT) composed of an enzymatic subunit involved in actin ADP-ribosylation (CDTa) and translocation pore (CDTb) that delivers CDTa into host cells through receptor-mediated endocytosis. CDTb is proposed to be a di-heptamer, but its physiological heptameric structure has not been reported to date. Here, we report the CDTa-bound CDTb-pore (heptamer) as a physiological complexes using cryo-EM. The high-resolution structure of the CDTa-bound CDTb-pore at 2.56-Å resolution revealed that CDTa binding to CDTb-pore induces partial unfolding and tilting of the first CDTa a-helix, and the translocation. In the CDTb-pore, the NSS-loop exists in “in” and “out” conformations, suggesting their involvement in substrate translocation through formation of weak, non-specific interactions. This structural information provides insights into drug design against hypervirulent C. difficile strains.

Comparative Assessment of NMR Probes for the Experimental Description of Protein Folding Pathways with High-Pressure NMR

Multidimensional NMR intrinsically provides multiple probes that can be used for deciphering the folding pathways of proteins: NH amide and CH groups are strategically located on the backbone of the protein, while CH3 groups, on the side-chain of methylated residues, are involved in important stabilizing interactions in the hydrophobic core. Combined with high hydrostatic pressure, these observables provide a powerful tool to explore the conformational landscapes of proteins. In the present study, we made a comparative assessment of the NH, CH, and CH3 groups for analyzing the unfolding pathway of ∆+PHS Staphylococcal Nuclease. These probes yield a similar description of the folding pathway, with virtually identical thermodynamic parameters for the unfolding reaction, despite some notable differences. Thus, if partial unfolding begins at identical pressure for these observables (especially in the case of backbone probes) and concerns similar regions of the molecule, the residues involved in contact losses are not necessarily the same. In addition, an unexpected slight shift toward higher pressure was observed in the sequence of the scenario of unfolding with CH when compared to amide groups.

E3 Ubiquitin Ligase SPL2 Is a Lanthanide-Binding Protein

The SPL2 protein is an E3 ubiquitin ligase of unknown function. It is one of only three types of E3 ligases found in the outer membrane of plant chloroplasts. In this study, we show that the cytosolic fragment of SPL2 binds lanthanide ions, as evidenced by fluorescence measurements and circular dichroism spectroscopy. We also report that SPL2 undergoes conformational changes upon binding of both Ca2+ and La3+, as evidenced by its partial unfolding. However, these structural rearrangements do not interfere with SPL2 enzymatic activity, as the protein retains its ability to auto-ubiquitinate in vitro. The possible applications of lanthanide-based probes to identify protein interactions in vivo are also discussed. Taken together, the results of this study reveal that the SPL2 protein contains a lanthanide-binding site, showing for the first time that at least some E3 ubiquitin ligases are also capable of binding lanthanide ions.

Leishmania major biotin protein ligase forms a unique cross-handshake dimer

Biotin protein ligase catalyses the post-translational modification of biotin carboxyl carrier protein (BCCP) domains, a modification that is crucial for the function of several carboxylases. It is a two-step process that results in the covalent attachment of biotin to the ɛ-amino group of a conserved lysine of the BCCP domain of a carboxylase in an ATP-dependent manner. In Leishmania, three mitochondrial enzymes, acetyl-CoA carboxylase, methylcrotonyl-CoA carboxylase and propionyl-CoA carboxylase, depend on biotinylation for activity. In view of the indispensable role of the biotinylating enzyme in the activation of these carboxylases, crystal structures of L. major biotin protein ligase complexed with biotin and with biotinyl-5′-AMP have been solved. L. major biotin protein ligase crystallizes as a unique dimer formed by cross-handshake interactions of the hinge region of the two monomers formed by partial unfolding of the C-terminal domain. Interestingly, the substrate (BCCP domain)-binding site of each monomer is occupied by its own C-terminal domain in the dimer structure. This was observed in all of the crystals that were obtained, suggesting a closed/inactive conformation of the enzyme. Size-exclusion chromatography studies carried out using high protein concentrations (0.5 mM) suggest the formation of a concentration-dependent dimer that exists in equilibrium with the monomer.

Evolutionary and Structural Constraints Influencing Apolipoprotein A-I Amyloid Behavior

Apolipoprotein A-I (apoA-I) has a key function in the reverse cholesterol transport mediated by the high-density lipoprotein (HDL) particles. However, aggregation of apoA-I single point mutants can lead to hereditary amyloid pathology. Although several studies have tackled the biophysical and structural impacts introduced by these mutations, there is little information addressing the relationship between the evolutionary and structural features that contribute to the amyloid behavior of apoA-I. We combined evolutionary studies, in silico saturation mutagenesis and molecular dynamics (MD) simulations to provide a comprehensive analysis of the conservation and pathogenic role of the aggregation-prone regions (APRs) present in apoA-I. Sequence analysis demonstrated the pervasive conservation of an APR, designated here APR1, within the N-terminal α-helix bundle. Moreover, stability analysis carried out with the FoldX engine showed that this motif contributes to the marginal stability of apoA-I. Structural properties of the full-length apoA-I model suggest that aggregation is avoided by placing APRs into highly packed and rigid portions of its structure. Compared to HDL-deficiency or natural silent variants extracted from the gnomAD database, the thermodynamic and pathogenic impact of apoA-I point mutations associated with amyloid pathologies were found to show a higher destabilizing effect. MD simulations of the amyloid variant G26R evidenced the partial unfolding of the α-helix bundle and the occurrence of β-strand secondary elements at the C-terminus of apoA-I. Our findings highlight APR1 as a relevant component for apoA-I structural integrity and emphasize a destabilizing effect of amyloid variants that leads to the exposure of APRs. This information contributes to our understanding of how apoA-I, with its high degree of structural flexibility, maintains a delicate equilibrium between its native structure and intrinsic tendency to form amyloid aggregates. In addition, our stability measurements could be used as a proxy to interpret the structural impact of new mutations affecting apoA-I.HighlightsAggregation-prone region 1 (APR1), comprising residues 14-19, is consistently conserved during the evolutionary history of Apolipoprotein A-I.APR1 contributes to thermal stability of the α-helix bundle in the full-length Apolipoprotein A-I model.Amyloid variants introduce a destabilizing effect on the monomer structure of Apolipoprotein A-I, in contrast to HDL-deficiency and naturally-occurring variants, which are nearly neutral.During molecular dynamics simulations, G26R amyloidogenic mutant lead to the partial unfolding of α-helix bundle and exposure of APR1.

Transient Unfolding and Long-Range Interactions in Viral BCL2 M11 Enable Binding to the BECN1 BH3 Domain

Viral BCL2 proteins (vBCL2s) help to sustain chronic infection of host proteins to inhibit apoptosis and autophagy. However, details of conformational changes in vBCL2s that enable binding to BH3Ds remain unknown. Using all-atom, multiple microsecond-long molecular dynamic simulations (totaling 17 μs) of the murine γ-herpesvirus 68 vBCL2 (M11), and statistical inference techniques, we show that regions of M11 transiently unfold and refold upon binding of the BH3D. Further, we show that this partial unfolding/refolding within M11 is mediated by a network of hydrophobic interactions, which includes residues that are 10 Å away from the BH3D binding cleft. We experimentally validate the role of these hydrophobic interactions by quantifying the impact of mutating these residues on binding to the Beclin1/BECN1 BH3D, demonstrating that these mutations adversely affect both protein stability and binding. To our knowledge, this is the first study detailing the binding-associated conformational changes and presence of long-range interactions within vBCL2s.