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Is there a preferential interaction between cholesterol and tryptophan residues in membrane proteins?Gel domains in the plasma membrane of Saccharomyces cerevisiae: highly ordered, ergosterol-free, and sphingolipid-enriched lipid rafts.Sphingomyelin and sphingomyelin synthase (SMS) in the malignant transformation of glioma cells and in 2-hydroxyoleic acid therapy.Membrane lipid domains and rafts: current applications of fluorescence lifetime spectroscopy and imaging.Crystallization around solid-like nanosized docks can explain the specificity, diversity, and stability of membrane microdomains.Organization and dynamics of Fas transmembrane domain in raft membranes and modulation by ceramide.Copper(I) complexes with phosphine derived from sparfloxacin. Part II: a first insight into the cytotoxic action mode.Insights into the mechanisms underlying the antiproliferative potential of a Co(II) coordination compound bearing 1,10-phenanthroline-5,6-dione: DNA and protein interaction studies.The role of membrane fatty acid remodeling in the antitumor mechanism of action of 2-hydroxyoleic acid.[RuII(η⁵-C₅H₅)(bipy)(PPh₃)]⁺, a promising large spectrum antitumor agent: cytotoxic activity and interaction with human serum albumin.Development of lysosome-mimicking vesicles to study the effect of abnormal accumulation of sphingosine on membrane properties.The extracellular matrix modulates H2O2 degradation and redox signaling in endothelial cells.Lateral distribution of the transmembrane domain of influenza virus hemagglutinin revealed by time-resolved fluorescence imaging.Cholesterol-rich fluid membranes solubilize ceramide domains: implications for the structure and dynamics of mammalian intracellular and plasma membranes.Formation of ceramide/sphingomyelin gel domains in the presence of an unsaturated phospholipid: a quantitative multiprobe approach.Ceramide-domain formation and collapse in lipid rafts: membrane reorganization by an apoptotic lipid.Structural and dynamic characterization of the interaction of the putative fusion peptide of the S2 SARS-CoV virus protein with lipid membranes.Interaction of peptides with binary phospholipid membranes: application of fluorescence methodologies.Lipid rafts have different sizes depending on membrane composition: a time-resolved fluorescence resonance energy transfer study.Modulation of plasma membrane lipid profile and microdomains by H2O2 in Saccharomyces cerevisiae.VPAC1 and VPAC2 receptor activation on GABA release from hippocampal nerve terminals involve several different signalling pathways.Differential targeting of membrane lipid domains by caffeic acid and its ester derivatives.Biophysical properties of ergosterol-enriched lipid rafts in yeast and tools for their study: characterization of ergosterol/phosphatidylcholine membranes with three fluorescent membrane probes.Structure and dynamics of the gammaM4 transmembrane domain of the acetylcholine receptor in lipid bilayers: insights into receptor assembly and function.Exploiting the therapeutic potential of 8-β-d-glucopyranosylgenistein: synthesis, antidiabetic activity, and molecular interaction with islet amyloid polypeptide and amyloid β-peptide (1-42).Reorganization of plasma membrane lipid domains during conidial germination.The molecular mechanism of Nystatin action is dependent on the membrane biophysical properties and lipid composition.Changes in membrane organization upon spontaneous insertion of 2-hydroxylated unsaturated fatty acids in the lipid bilayer.Formation and Properties of Membrane-Ordered Domains by Phytoceramide: Role of Sphingoid Base Hydroxylation.Phospholipid/cholesterol/decanethiol mixtures for direct assembly of immunosensing interfaces.Ceramide-platform formation and -induced biophysical changes in a fluid phospholipid membraneChanges in the Biophysical Properties of the Cell Membrane Are Involved in the Response of to StaurosporineNew polydentate Ru(III)-Salan complexes: Synthesis, characterization, anti-tumour activity and interaction with human serum proteinsSugar-based bactericides targeting phosphatidylethanolamine-enriched membranesBiophysical Implications of Sphingosine Accumulation in Membrane Properties at Neutral and Acidic pHThe photophysics of a Rhodamine head labeled phospholipid in the identification and characterization of membrane lipid phasesEthanol effects on binary and ternary supported lipid bilayers with gel/fluid domains and lipid raftsA biomimetic platform to study the interactions of bioelectroactive molecules with lipid nanodomainsSphingolipid hydroxylation in mammals, yeast and plants - An integrated viewA route to understanding yeast cellular envelope - plasma membrane lipids interplaying in cell wall integrity
P50
Q31143576-9596D6B8-B88F-4863-903C-EAD48F5A06CDQ34568292-09615649-52DB-4477-9321-F105EB8BF2C3Q35621265-5360CA6A-9DF6-4425-B45E-99787D151560Q37250576-BAE0B20F-8799-42E9-8947-A99DD705033EQ37618993-4F80D5B2-3103-4BD4-B918-181538D0E71DQ38598080-A2E11012-EABC-44C7-9731-EE78FB5902F3Q38811344-FF71BBAE-9F2E-4267-9EFD-7F4C77DC7305Q39028760-81DA48F1-285B-438D-9CDB-58903B9B9A53Q39202521-16A0AFD8-06B4-44AA-8A23-05B6B4FEC89BQ39300142-03B8F912-935F-4317-84EB-97920D77DF80Q41073398-74AA4CF3-4950-4A4A-A0EA-B2349E1792C1Q41601792-7DF8660E-62E3-4A7F-9A63-415584466942Q42007038-8C31ED24-7D68-408E-8FC1-2DB6DE36C67FQ42087759-70EBC5F3-55A9-4043-9C2A-99179FDE31E1Q42271601-83C4038B-A465-45B9-B51B-50282DE8DB75Q43054697-2FB02B4D-D7F8-4C15-B960-5E5EF3735351Q43808921-CAE5B626-BD32-4CBC-A01E-2ACF29F1B551Q44322996-5454C140-5F0D-42EF-A215-00974592EA1FQ45258004-0AD0BC5A-D3F9-4A13-A4CE-0F46563DF48EQ46232254-BA9BE45E-FC47-4161-9B3E-EB17DF7FCA49Q47748308-9C6D1905-6312-4B8D-8B47-BAD4B2CEAB69Q49990567-05136212-4532-469A-80CD-73BF201D865FQ50245415-4EBC4AC8-15ED-4663-B3C8-FD0E3D4ADD51Q50724222-2262E8B3-FEF7-4D9F-8C0C-8191700F48F0Q51313643-A38784BC-8DA0-4A08-8F44-2A21BF0EDACDQ51343638-AA278BD4-AE89-4D06-A711-0B565FB12139Q52446250-79FFC316-14A6-4620-A4FF-FB1F9B519B0EQ52647457-24F28DAA-CA98-46B5-921B-B526CF824050Q52863330-139FDA0E-EC12-4B9F-8C52-8A8C45F15935Q53286503-39A36CFD-096D-4E76-B9CF-8B10573E46D6Q57373103-7A848831-F1FF-41A4-9C17-0DCE6AE08D1BQ58573401-152ABF7C-9FDD-4DD9-A9C6-80DB1ECDF9BDQ59082617-E5D0FF98-8FEB-448C-9E4E-31934B06EA53Q59134773-22D34C33-9A7F-4A72-BA68-C470E6C5FE30Q59153591-8DE27FBB-4E5F-4C16-8CC8-1EB72D87926EQ83617203-B083DA2B-2B1A-4CB4-A268-E2A407D15C62Q85213049-D4986319-B763-484F-98BC-4D6FF46CA542Q85651238-C1DDF525-FCF5-494A-BA74-143EC488C504Q88628723-A3A8AF30-084E-4629-886F-A594C5FA97E1Q89289428-7B0D0C15-2703-4518-8389-992BFD336172
P50
description
researcher, ORCID id # 0000-0002-9748-7083
@en
wetenschapper
@nl
name
Rodrigo F.M. de Almeida
@ast
Rodrigo F.M. de Almeida
@en
Rodrigo F.M. de Almeida
@es
Rodrigo F.M. de Almeida
@nl
type
label
Rodrigo F.M. de Almeida
@ast
Rodrigo F.M. de Almeida
@en
Rodrigo F.M. de Almeida
@es
Rodrigo F.M. de Almeida
@nl
prefLabel
Rodrigo F.M. de Almeida
@ast
Rodrigo F.M. de Almeida
@en
Rodrigo F.M. de Almeida
@es
Rodrigo F.M. de Almeida
@nl
P1053
D-8629-2012
P106
P1153
7005256125
P21
P31
P3829
P496
0000-0002-9748-7083