Binding and thermodynamics of R<scp>EV</scp> peptide−ct<scp>DNA</scp> interaction

Upadhyay, Swati

doi:10.1002/bip.22902

Cited by 7 publications

(1 citation statement)

References 37 publications

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“…However, theoretical predictions through NN models [74] place the DNA duplex melting temperature at [NaCl] = 800 mM and [rDD] = 0.91 mM to be around 75-80 • C, although contributions from PLL binding to DNA were not accounted for. Previous studies have observed slight DNA melting temperature increases upon peptide binding [77,78] and that basic amino acids contribute to greater duplex stability [79]. This suggests that ISO coacervates are principally composed by still-duplexed DNA, in this case capable of weak linear aggregation due to a suppressed end-to-end interaction, and that DNA de-hybridization takes place at higher temperature when the system is in the uniform phase.…”

Section: Thermal Stability Of Lc-coacervatesmentioning

confidence: 96%

Liquid Crystal Peptide/DNA Coacervates in the Context of Prebiotic Molecular Evolution

Jia

Fraccia

2020

Crystals

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Liquid–liquid phase separation (LLPS) phenomena are ubiquitous in biological systems, as various cellular LLPS structures control important biological processes. Due to their ease of in vitro assembly into membraneless compartments and their presence within modern cells, LLPS systems have been postulated to be one potential form that the first cells on Earth took on. Recently, liquid crystal (LC)-coacervate droplets assembled from aqueous solutions of short double-stranded DNA (s-dsDNA) and poly-L-lysine (PLL) have been reported. Such LC-coacervates conjugate the advantages of an associative LLPS with the relevant long-range ordering and fluidity properties typical of LC, which reflect and propagate the physico-chemical properties of their molecular constituents. Here, we investigate the structure, assembly, and function of DNA LC-coacervates in the context of prebiotic molecular evolution and the emergence of functional protocells on early Earth. We observe through polarization microscopy that LC-coacervate systems can be dynamically assembled and disassembled based on prebiotically available environmental factors including temperature, salinity, and dehydration/rehydration cycles. Based on these observations, we discuss how LC-coacervates can in principle provide selective pressures effecting and sustaining chemical evolution within partially ordered compartments. Finally, we speculate about the potential for LC-coacervates to perform various biologically relevant properties, such as segregation and concentration of biomolecules, catalysis, and scaffolding, potentially providing additional structural complexity, such as linearization of nucleic acids and peptides within the LC ordered matrix, that could have promoted more efficient polymerization. While there are still a number of remaining open questions regarding coacervates, as protocell models, including how modern biologies acquired such membraneless organelles, further elucidation of the structure and function of different LLPS systems in the context of origins of life and prebiotic chemistry could provide new insights for understanding new pathways of molecular evolution possibly leading to the emergence of the first cells on Earth.

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Section: Thermal Stability Of Lc-coacervatesmentioning

confidence: 96%

Liquid Crystal Peptide/DNA Coacervates in the Context of Prebiotic Molecular Evolution

Jia

Fraccia

2020

Crystals

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Exploring the binding interaction of Maillard reaction by‐product 5‐hydroxymethyl‐2‐furaldehyde with calf thymus DNA

Zhou

Zhang

et al. 2019

J Sci Food Agric

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BACKGROUND 5‐Hydroxymethyl‐2‐furaldehyde (5‐HMF), a by‐product of the Maillard reaction, usually present in fried and baked food, may cause potential harm to the human body. Here, the interaction between 5‐HMF and calf thymus DNA (ctDNA) under physiological buffer (pH 7.4) was studied using multi‐spectroscopic methods combined with multivariate curve resolution–alternating least squares (MCR‐ALS) chemometrics and molecular simulation techniques. RESULTS The concentration profiles and pure spectra of the three components (5‐HMF, ctDNA and 5‐HMF–ctDNA complex) were extracted from highly overlapping spectra using MCR‐ALS analysis, which verified the formation of 5‐HMF–ctDNA complex. The binding constant being of the order of 103 L mol−1 at four temperatures (292, 298, 304 and 310 K) indicated a weak affinity in the binding of 5‐HMF to ctDNA. The binding interaction was mainly driven by hydrogen bonds and van der Waals forces. Viscosity analysis, melting assay, ionic strength effect and competitive fluorescence studies ascertained that 5‐HMF bound to ctDNA through groove binding, and it tended to bind to guanine–cytosine rich region of ctDNA which was characterized using Fourier transform infrared spectra and molecular docking. Circular dichroism spectral analysis and DNA cleavage assays indicated that the ctDNA conformation was altered from B to A form and 5‐HMF caused DNA damage at higher concentration. CONCLUSIONS The results suggested that 5‐HMF bound to ctDNA through groove binding and caused DNA damage. This research may contribute to understand the binding mechanism of 5‐HMF to ctDNA and to the assessment of the toxicological effect of 5‐HMF in biological processes. © 2018 Society of Chemical Industry

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Binding Properties of DNA and Antimicrobial Peptide Chensinin-1b Containing Lipophilic Alkyl Tails

et al. 2020

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Binding and thermodynamics of REV peptide−ctDNA interaction

Cited by 7 publications

References 37 publications

Liquid Crystal Peptide/DNA Coacervates in the Context of Prebiotic Molecular Evolution

Liquid Crystal Peptide/DNA Coacervates in the Context of Prebiotic Molecular Evolution

Exploring the binding interaction of Maillard reaction by‐product 5‐hydroxymethyl‐2‐furaldehyde with calf thymus DNA

Binding Properties of DNA and Antimicrobial Peptide Chensinin-1b Containing Lipophilic Alkyl Tails

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