Quantum dot (Aun/Agn, n = 3-8) capped single lipids: interactions and physicochemical properties.

Realizing the potential of nano-hybrid biomaterials in various applications (nanoprobes to drug delivery), special attention has been devoted towards their synthesis and development. Nonetheless, several questions pertaining to the interface chemistry between the constituent entities (biomolecules and organic/inorganic part) of these hybrids, still remain unresolved. Keeping these unsolved issues in mind, the present theoretical investigation focuses on determining the electronic/physicochemical properties and interactions within gold and silver quantum dot-capped single lipid molecules. Quantum dots of varying sizes and shapes have been chosen and then coupled with lipid molecules (1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC), 1,2-dimyristoyl-sn-glycero-3-phosphoethanolamine (DMPE), 1,2-dimyristoyl-sn-glycero-3-phosphoglycerol, sodium salt (DMPG)), at the choline/glycerol, carboxylate and phosphate site. It has been identified that Au Qds interact strongly as compared to Ag clusters. In addition to the type, the shape and size of the Qd also influences their attachment with lipids. Among various sites, the phosphate site provides a considerably stronger platform for the coupling of Qds. On the other hand, attachment at the choline site leads to significantly lower interaction energies. The trend noted in interaction energies coincides with the structure-electronic property analysis (interatomic bond distances, charge transfer, PO2- stretching frequencies), which further helps in deducing the nature of interactions. The molecular dynamics simulations performed on selected Qd-lipid complexes established that the Qd interacting with lipids at the phosphate site remains fairly stable at room temperature without undergoing fragmentation into individual components. On the other hand, at the choline site, the Qd-to-lipid coupling is unstable and therefore they experience disintegration at 300 K temperature. Additionally, a unique glycerol-to-phosphate site crossover is evidenced, which reaffirms that the phosphate site is selectively preferred by Qds for binding with lipid molecules.

Differential copper binding to alpha-synuclein and its disease-associated mutants affect the aggregation and amyloid formation.

BACKGROUND: Copper is an essential trace element required for the proper functioning of various enzymes present in the central nervous system. An imbalance in the copper homeostasis results in the pathology of various neurodegenerative disorders including Parkinson's Disease. Hence, residue specific interaction of Cu2+ to α-Syn along with the familial mutants H50Q and G51D needs to be studied in detail. METHODS: We investigated the residue specific mapping of Cu2+ binding sites and binding strength using solution-state NMR and ITC respectively. The aggregation kinetics, secondary structural changes, and morphology of the formed fibrils in the presence and absence of Cu2+ were studied using fluorescence, CD, and AFM respectively. RESULTS: Copper binding to α-Syn takes place at three different sites with a higher affinity for the region 48-53. While one of the sites got abolished in the case of H50Q, the mutant G51D showed a binding pattern similar to WT. The aggregation kinetics of these proteins in the presence of Cu2+ showed an enhanced rate of fibril formation with a pronounced effect for G51D. CONCLUSION: Cu2+ binding results in the destabilization of long-range tertiary interactions in α-Syn leading to the exposure of highly amyloidogenic NAC region which results in the increased rate of fibril formation. Although the residues 48-53 have a stronger affinity for Cu2+ in case of WT and G51D, the binding is not responsible for enhancing the rate of fibril formation in case of H50Q. GENERAL SIGNIFICANCE: These findings will help in the better understanding of Cu2+ catalyzed aggregation of synucleins.

The Involvement of His50 during Protein Disulfide Isomerase Binding Is Essential for Inhibiting α-Syn Fibril Formation.

An increased level of protein disulfide isomerase (PDI) is a protective response to various neurodegenerative disorders, including Parkinson's disease. Interaction of PDI with α-synuclein (α-Syn) has been shown to inhibit its aggregation. Here, we report the residue-specific mapping of binding of PDI to α-Syn. We demonstrate that α-Syn N-terminal residues V3-S9 and L38-V40 bind more strongly to PDI than residues V49-V52 do, as do C-terminal residues E123-M127 and D135-E137. In addition, we show that residue H50 is key in preventing aggregation. These findings improve our understanding of PDI-protected aggregation of wild-type α-Syn and its H50Q familial mutant.

The newly discovered Parkinson's disease associated Finnish mutation (A53E) attenuates α-synuclein aggregation and membrane binding.

α-Synuclein (α-Syn) oligomerization and amyloid formation are associated with Parkinson's disease (PD) pathogenesis. Studying familial α-Syn mutants associated with early onset PD has therapeutic importance. Here we report the aggregation kinetics and other biophysical properties of a newly discovered PD associated Finnish mutation (A53E). Our in vitro study demonstrated that A53E attenuated α-Syn aggregation and amyloid formation without altering the major secondary structure and initial oligomerization tendency. Further, A53E showed reduced membrane binding affinity compared to A53T and WT. The present study would help to delineate the role of A53E mutation in early onset PD pathogenesis.

The Parkinson's disease-associated H50Q mutation accelerates α-Synuclein aggregation in vitro.

α-Synuclein (α-Syn) aggregation is directly linked with Parkinson's disease (PD) pathogenesis. Here, we analyzed the aggregation of newly discovered α-Syn missense mutant H50Q in vitro and found that this mutation significantly accelerates the aggregation and amyloid formation of α-Syn. This mutation, however, did not alter the overall secondary structure as suggested by two-dimensional nuclear magnetic resonance and circular dichroism spectroscopy. The initial oligomerization study by cross-linking and chromatographic techniques suggested that this mutant oligomerizes to an extent similar to that of the wild-type α-Syn protein. Understanding the aggregation mechanism of this H50Q mutant may help to establish the aggregation and phenotypic relationship of this novel mutant in PD.

An efficient combination of BEST and NUS methods in multidimensional NMR spectroscopy for high throughput analysis of proteins.

Application of Non Uniform Sampling (NUS) along with Band-selective Excitation Short-Transient (BEST) NMR experiments has been demonstrated for obtaining the important residue-specific atomic level backbone chemical shift values in short durations of time. This application has been demonstrated with both well-folded (ubiquitin) and unfolded (α-synuclein) proteins alike. With this strategy, the experiments required for determining backbone chemical shifts can be performed very rapidly, i.e., in ∼2 hours of spectrometer time, and this data can be used to calculate the backbone folds of proteins using well established algorithms. This will be of great value for structural proteomic investigations on one hand, where the speed of structure determination is a limiting factor and for application in the study of slow kinetic processes involving proteins, such as fibrillization, on the other hand.

Perturbation in Long-Range Contacts Modulates the Kinetics of Amyloid Formation in α-Synuclein Familial Mutants.

The characteristic cross-ß-sheet-rich amyloid fibril formation by intrinsically disordered α-synuclein proteins is one of the pathological hallmarks of Parkinson's disease. Although unstructured in solution, the presence of autoinhibitory long-range contacts in monomeric form prevents protein aggregation. Out of the various factors that affect the rate of amyloid formation, familial mutations play an important role in α-synuclein aggregation. Even though these mutations are believed to form an aggregation-prone intermediate by perturbing these contacts, the correlation between perturbation and rate of fibril formation is not very straightforward. A combination of solution and solid-state NMR in conjunction with other biophysical methods has been used to identify the underlying mechanism behind the anomaly in the rate of aggregation for the novel mutants H50Q (fast aggregating) and G51D (slow aggregating). Perturbation of long-range contacts at the mutation sites and C-termini in all of the six familial mutants of α-synuclein during the diseased condition (acidic pH) was observed. These contacts get rearranged at physiological pH resulting in the shielding of mutation sites. Additional contacts at the mutation site in a slow aggregating mutant could be the reason for slower aggregation. Indeed, these contacts provide more rigidity to the monomeric G51D. Nonetheless, these mutations did not alter the overall secondary structure. The differential pattern of the long-range contacts at the monomeric level resulted in the perturbation of the fibrillar-core region, which was evident in the solid-state NMR spectra. Our results provide valuable insights in understanding the effect of long-range contacts on the aggregation of α-synuclein and its mutants.

Dynamic association of PfEMP1 and KAHRP in knobs mediates cytoadherence during Plasmodium invasion.

Plasmodium falciparum infected erythrocytes display membrane knobs that are essential for their adherence to vascular endothelia and for prevention of clearance by the spleen. The knob associated histidine rich protein (KAHRP) is indispensable to knob formation and has been implicated in the recruitment and tethering of P. falciparum erythrocyte membrane protein-1 (PfEMP1) by binding to its cytoplasmic domain termed VARC. However, the precise mechanism of interaction between KAHRP and VARC is not very well understood. Here we report that both the proteins co-localize to membrane knobs of P. falciparum infected erythrocytes and have identified four positively charged linear sequence motifs of high intrinsic mobility on KAHRP that interact electrostatically with VARC in solution to form a fuzzy complex. The current study provides molecular insight into interaction between KAHRP and VARC in solution that takes place at membrane knobs.