Marina Ramirez-Alvarado

Formation and stability of β-hairpin structures in polypeptides

Abstract Experimental work on peptide models with β-hairpin structures has provided new insights into the formation and stability of this secondary structure element. Both the turn region and the antiparallel strand residues not only affect the overall stability of the hairpin, but also determine the type of hairpin formed. These results agree reasonably well with those from experimental and statistical analyses of β-sheet structures in proteins.

β-Hairpin and β-sheet formation in designed linear peptides

Abstract Recent knowledge about the determinants of β-sheet formation and stability has notably been improved by the structural analysis of model peptides with β-hairpin structure in aqueous solution. Several experimental studies have shown that the turn region residues can not only determine the stability, but also the conformation of the β-hairpin. Specific interstrand side-chain interactions, hydrophobic and polar, have been found to be important stabilizing interactions. The knowledge acquired in the recent years from peptide systems, together with the information gathered from mutants in proteins, and the analysis of known protein structures, has led to successful design of a folded three-stranded monomeric β-sheet structure.

Recruitment of Light Chains by Homologous and Heterologous Fibrils Shows Distinctive Kinetic and Conformational Specificity.

Light chain amyloidosis is a protein misfolding disease in which immunoglobulin light chains aggregate as insoluble fibrils that accumulate in extracellular deposits. Amyloid fibril formation in vitro has been described as a nucleation-polymerization, autocatalytic reaction in which nascent fibrils catalyze formation of new fibrils, recruiting soluble protein into the fibril. In this context, it is also established that preformed fibrils or seeds accelerate fibril formation. In some cases, seeds with a substantially different sequence are able to accelerate the reaction, albeit with a lower efficiency. In this work, we studied the recruitment and addition of monomers in the presence of seeds of five immunoglobulin light chain proteins, covering a broad range of protein stabilities and amyloidogenic properties. Our data reveal that in the presence of homologous or heterologous seeds, the fibril formation reactions become less stochastic than de novo reactions. The kinetics of the most amyloidogenic proteins (AL-T05 and AL-09) do not present significant changes in the presence of seeds. Amyloidogenic protein AL-103 presented fairly consistent acceleration with all seeds. In contrast, the less amyloidogenic proteins (AL-12 and κI) presented dramatic differential effects that are dependent on the kind of seed used. κI had a poor efficiency to elongate preformed fibrils. Together, these results indicate that fibril formation is kinetically determined by the conformation of the amyloidogenic precursor and modulated by the differential ability of each protein to either nucleate or elongate fibrils. We observe morphological and conformational properties of some seeds that do not favor elongation with some proteins, resulting in a delay in the reaction.

Differences in Protein Concentration Dependence for Nucleation and Elongation in Light Chain Amyloid Formation

Light chain (AL) amyloidosis is a lethal disease characterized by the deposition of the immunoglobulin light chain into amyloid fibrils, resulting in organ dysfunction and failure. Amyloid fibrils have the ability to self-propagate, recruiting soluble protein into the fibril by a nucleation-polymerization mechanism, characteristic of autocatalytic reactions. Experimental data suggest the existence of a critical concentration for initiation of fibril formation. As such, the initial concentration of soluble amyloidogenic protein is expected to have a profound effect on the rate of fibril formation. In this work, we present in vitro evidence that fibril formation rates for AL light chains are affected by the protein concentration in a differential manner. De novo reactions of the proteins with the fastest amyloid kinetics (AL-09, AL-T05, and AL-103) do not present protein concentration dependence. Seeded reactions, however, exhibited weak protein concentration dependence. For AL-12, seeded and protein concentration dependence data suggest a synergistic effect for recruitment and elongation at low protein concentrations, while reactions of κI exhibited poor efficiency in nucleating and elongating preformed fibrils. Additionally, co-aggregation and cross seeding of κI variable domain (VL) and the κI full length (FL) light chain indicate that the presence of the constant domain in κI FL modulates fibril formation, facilitating the recruitment of κI VL. Together, these results indicate that the dominant process in fibril formation varies among the AL proteins tested with a differential dependence of the protein concentration.

Assays for Light Chain Amyloidosis Formation and Cytotoxicity

Common biophysical techniques like absorption and fluorescence spectroscopy, microscopy, and light scattering studies have been in use to investigate fibril assembly for a long time. However, there is sometimes a lack of consensus from the findings of an individual technique when compared in parallel with the other techniques. In this chapter, we aim to provide a concise compilation of techniques that can effectively be used to obtain a comprehensive representation of the structural, aggregation, and toxicity determinants in immunoglobulin light chain amyloidosis. We start by giving a brief introduction on amyloid assembly and the advantages of using simple and readily available techniques to study aggregation. After an overview on preparation of protein to set up parallel experiments, we provide a systematic description of the in vitro techniques used to study aggregation in AL protein. Additionally, we thoroughly discuss the steps needed in our experience during the individual experiments for better reproducibility and data analysis.