Diego Ramírez scite author profile

Diego Ramírez

5Publications

67Citation Statements Received

109Citation Statements Given

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249

Affiliations

San Sebastián University, Universidad de Los Andes, University of Concepción

Publications

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Mechanical properties that influence antimicrobial peptide activity in lipid membranes

Marín-Medina

Ramírez

Trier

et al. 2016

Appl Microbiol Biotechnol

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Antimicrobial peptides are small amphiphilic proteins found in animals and plants as essential components of the innate immune system and whose function is to control bacterial infectious activity. In order to accomplish their function, antimicrobial peptides use different mechanisms of action which have been deeply studied in view of their potential exploitation to treat antibiotic-resistant bacterial infections. One of the main mechanisms of action of these peptides is the disruption of the bacterial membrane through pore formation, which, in some cases, takes place via a monomer to oligomer cooperative transition. Previous studies have shown that lipid composition, and the presence of exogenous components, such as cholesterol in model membranes or carotenoids in bacteria, can affect the potency of distinct antimicrobial peptides. At the same time, considering the membrane as a two-dimensional material, it has been shown that membrane composition defines its mechanical properties which might be relevant in many membrane-related processes. Nevertheless, the correlation between the mechanical properties of the membrane and antimicrobial peptide potency has not been considered according to the importance it deserves. The relevance of these mechanical properties in membrane deformation due to peptide insertion is reviewed here for different types of pores in order to elucidate if indeed membrane composition affects antimicrobial peptide activity by modulation of the mechanical properties of the membrane. This would also provide a better understanding of the mechanisms used by bacteria to overcome antimicrobial peptide activity.

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Chiral vortex dynamics on membranes is an intrinsic property of FtsZ, driven by GTP hydrolysis

Ramírez

García‐Soriano

Raso

et al. 2016

Preprint

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The primary protein of the bacterial Z ring guiding cell division, FtsZ, has recently been shown to engage in intriguing self-organization together with one of its natural membrane anchors, FtsA. When co-reconstituted on flat supported membranes, these proteins assemble into dynamic chiral vortices whose diameters resemble the cell circumference.These dynamics are due to treadmilling polar FtsZ filaments, supposedly destabilized by the co-polymerizing membrane adaptor FtsA, thus catalysing their turnover. Here we show that FtsA is in fact dispensable and that the phenomenon is an intrinsic property of FtsZ alone when supplemented with a membrane anchor. The emergence of these chiral dynamic patterns is critically dependent on GTP concentration and FtsZ surface densities, in agreement with theoretical predictions. The interplay of membrane tethering, GTP binding, and hydrolysis promotes both, the assembly and the destabilization of FtsZ polymers, leading to the observed treadmilling dynamics. Notably, the vortex chirality is defined by the position of the membrane targeting sequence (mts) and can be inverted when attaching it to the opposite end of FtsZ. This reveals a so far unknown vectorial character of these cytomotive filaments, comprising three orthogonal directions: Filament polarity, curvature, and membrane attachment.All rights reserved. No reuse allowed without permission.(which was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.

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Macroscopic domain formation during cooling in the platelet plasma membrane: An issue of low cholesterol content

Bali

Savino

Ramírez

et al. 2009

Biochimica et Biophysica Acta (BBA) - Biomembranes

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There has been ample debate on whether cell membranes can present macroscopic lipid domains as predicted by three-component phase diagrams obtained by fluorescence microscopy. Several groups have argued that membrane proteins and interactions with the cytoskeleton inhibit the formation of large domains. In contrast, some polarizable cells do show large regions with qualitative differences in lipid fluidity. It is important to ask more precisely, based on the current phase diagrams, under what conditions would large domains be expected to form in cells. In this work we study the thermotropic phase behavior of the platelet plasma membrane by FTIR, and compare it to a POPC/Sphingomyelin/Cholesterol model representing the outer leaflet composition. We find that this model closely reflects the platelet phase behavior. Previous work has shown that the platelet plasma membrane presents inhomogeneous distribution of DiI18:0 at 24°C, but not at 37°C, which suggests the formation of macroscopic lipid domains at low temperatures. We show by fluorescence microscopy, and by comparison with published phase diagrams, that the outer leaflet model system enters the macroscopic domain region only at the lower temperature. In addition, the low cholesterol content in platelets (~15 mol %), appears to be crucial for the formation of large domains during cooling.

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Long-term collaboration with strong friendship ties improves academic performance in remote and hybrid teaching modalities in high school physics

Pulgar

Ramírez²,

Abigail³

et al. 2022

Phys. Rev. Phys. Educ. Res.

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Antioxidant effect of resveratrol in single red blood cells measured by thermal fluctuation spectroscopy

Gallardo

Suwalsky

Ramírez

et al. 2019

Archives of Biochemistry and Biophysics

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Diego Ramírez

Mechanical properties that influence antimicrobial peptide activity in lipid membranes

Chiral vortex dynamics on membranes is an intrinsic property of FtsZ, driven by GTP hydrolysis

Macroscopic domain formation during cooling in the platelet plasma membrane: An issue of low cholesterol content

Long-term collaboration with strong friendship ties improves academic performance in remote and hybrid teaching modalities in high school physics

Antioxidant effect of resveratrol in single red blood cells measured by thermal fluctuation spectroscopy

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