GaMD simulations as an alternative in the TFE-water mixture description.

CONTEXT: 2,2,2-Trifluoroethanol has been widely used to study the structure and dynamic properties of intrinsically disordered proteins. Experimentally, it is known that TFE-water mixtures stabilize secondary structures of IDPs, and therefore, it allows the studying of conformational ensembles of these proteins. In the last decades, molecular dynamic simulations have helped study the IDPs' conformational ensemble. Unfortunately, conventional MD requires very long simulation times to describe the properties of IDPs. Therefore, a variety of accelerated sampling techniques have been developed and employed. The TFE-water mixture arrangement description through MD has faced substantial difficulties since emulating the TFE nanocrowding at certain TFE:H[Formula: see text]O ratios (around 15-40% of TFE). In this work, we determine the most suitable conditions that reproduce experimentally reported properties of TFE-water mixtures. We compared the employment of conventional MD and GaMD simulations and various water parameters. Our results show that the combination of parameters that better reproduce the experimental information is the combination of the TIP4PD water model and GaMD simulations. Therefore, these conditions help accurately describe the structural ensemble of IDPs in TFE-water mixtures. METHODS: Conventional MD and GaMD simulations were performed under AMBER 18 software. The TFE and water molecules were described using GAFF2 and a variety of water models, such as TIP3P, TIP4P2005, TIP4PD, and TIP5P, respectively. The systems were simulated a 100 ns at 298 K.

CARACTERIZACIÓN DE LA ESTRUCTURA SECUNDARIA DE SUBTIPOS DE LA HISTONA H1 POR DICROÍSMO CIRCULAR / CHARACTERIZATION OF THE SECONDARY STRUCTURE OF HISTONE H1 SUBTYPES BY CIRCULAR DICHROISM (CD)

Introducción: Las histonas H1 modulan la estructura y la función de la cromatina. Las células somáticas de mamífero contienen los subtipos H1º, H1a, H1b, H1c, H1d y H1e; en células germinales de testículo y en ovocito, se encuentran respectivamente H1t y H1oo. Su estructura está conformada por un dominio central globular flanqueado por los dominios N-Terminal (DNT) y C-Terminal (DCT). Objetivo: Caracterizar la estructura secundaria de subtipos de la histona H1 mediante dicroísmo circular (DC). Materiales y Métodos: La histona H1 total se extrajo de núcleos de cerebro de rata por cromatografía de intercambio catiónico; la H1º se purificó por filtración en gel y las H1a, H1b, H1c y H1e por cromatografía líquida de alta resolución de fase reversa (RF-HPLC). Los espectros de DC se realizaron en tampón fosfato 10 mM; tampón fosfato 10 mM, 20% TFE (trifluoroetanol); tampón fosfato 10 mM, 40% TFE; tampón fosfato 10 mM, 60% TFE; tampón fosfato 10 mM, 150 mM NaCl y tampón fosfato 10 mM, 1 M NaCl. El análisis de los espectros se realizó con el programa Standard Analysis. Resultados: El porcentaje de hélice-alfa se calculó por diferentes métodos matemáticos teniendo en cuenta elipticidad molar a 193 nm y a 222 nm; con programa de deconvolución K2D y con relaciones cualitativas R1 y R2. El TFE induce la estructura en hélice-alfa en cada uno de los subtipos, mientras que NaCl no induce ningún cambio importante. Conclusión: Los subtipos con mayor contenido de hélice-alfa son H1a y H1c. Las diferencias observadas en el porcentaje de hélice-alfa entre los diferentes subtipos puede ser importante para su diferenciación funcional.

H1 histones modulate the structure and function of chromatin. Mammalian somatic cells contain H1º, H1a, H1b, H1c, H1d and H1e subtypes; H1t and H1oo are found in testicular germ cells and oocyte, respectively. Its structure consists of a globular core domain flanked by N-terminal (DNT) and C-terminal (DCT) domains. Objective: To characterize the secondary structure of histone H1 subtypes through circular dichroism (CD). Materials and Methods: Total histone H1 was extracted for rat brain nuclei by cation exchange chromatography; histone H1º was purified by gel filtration and the histones H1a, H1b, H1c and H1e were purified by reversed phase high performance liquid chromatography (RP-HPLC). CD spectra were performed in 10 mM phosphate buffer; 10 mM, 20% TFE phosphate buffer (trifluoroethanol); 10 mM, 40% TFE; phosphate buffer 10 mM, 60% TFE; phosphate buffer 10 mM, 150 mM NaCl and phosphate buffer 10 mm, 1 M NaCl. The analysis of the spectra was performed with JASCO Standard Analysis. Results: The percentage of alpha-helix was calculated using different mathematical methods, taking into account the molar ellipticity at 193 nm, and 222 nm, with K2D deconvolution program and the R1 and R2 qualitative relationships. The results indicate that TFE induced the alpha-helix structure in each of the subtypes, whereas NaCl did not induce any significant change. Conclusion: H1a and H1c are subtypes with highest content of alpha-helix. The observed differences in the percentage of alpha-helix between different subtypes may be important for their functional differentiation.

Toward a common aggregation mechanism for a ß-barrel protein family: insights derived from a stable dimeric species.

Δ78Δ is a second generation functional all-ß sheet variant of IFABP (intestinal fatty acid binding protein) corresponding to the fragment 29-106 of the parent protein. This protein and its predecessor, Δ98Δ (segment 29-126 of IFABP), were initially uncovered by controlled proteolysis. Remarkably, although IFABP and Δ98Δ are monomers in solution, Δ78Δ adopts a stable dimeric structure. With the aim of identifying key structural features that modulate the aggregation of ß-proteins, we evaluate here the structure and aggregation propensity of Δ78Δ. The 2,2,2-trifluoroethanol (TFE) induced aggregation of this protein shows a primary nucleation-elongation mechanism, characterized by the stabilization of a dimeric nucleus. Its rate of production from the co-solvent induced aggregation prone state governs the kinetics of polymerization. In this context, the value of Δ78Δ lies in the fact that - being a stable dimeric species - it reduces an otherwise bimolecular reaction to a unimolecular one. Interestingly, even though Δ78Δ and IFABP display similar conformational stability, the abrogated form of IFABP shows an enhanced aggregation rate, revealing the ancillary role played on this process by the free energy of the native proteins. Δ78Δ share with IFABP and Δ98Δ a common putative aggregation-prone central peptide. Differences in the exposure/accessibility of this segment dictated by the environment around this region might underlie the observed variations in the speed of aggregation. Lessons learnt from this natural dimeric protein might shed light on the early conformational events leading to ß-conversion from barrels to amyloid aggregates.