Literature DB >> 14733612

Interactions of histatin 5 and histatin 5-derived peptides with liposome membranes: surface effects, translocation and permeabilization.

Alice L Den Hertog1, Harro W Wong Fong Sang, Ruud Kraayenhof, Jan G M Bolscher, Wim Van't Hof, Enno C I Veerman, Arie V Nieuw Amerongen.   

Abstract

A number of cationic antimicrobial peptides, among which are histatin 5 and the derived peptides dhvar4 and dhvar5, enter their target cells and interact with internal organelles. There still are questions about the mechanisms by which antimicrobial peptides translocate across the membrane. We used a liposome model to study membrane binding, translocation and membrane-perturbing capacities of histatin 5, dhvar4 and dhvar5. Despite the differences in amphipathic characters of these peptides, they bound equally well to liposomes, whereas their membrane activities differed remarkably: dhvar4 translocated at the fastest rate, followed by dhvar5, whereas the histatin 5 translocation rate was much lower. The same pattern was seen for the extent of calcein release: highest with dhvar4, less with dhvar5 and almost none with histatin 5. The translocation and disruptive actions of dhvar5 did not seem to be coupled, because translocation occurred on a much longer timescale than calcein release, which ended within a few minutes. We conclude that peptide translocation can occur through peptide-phospholipid interactions, and that this is a possible mechanism by which antimicrobial peptides enter cells. However, the translocation rate was much lower in this model membrane system than that seen in yeast cells. Thus it is likely that, at least for some peptides, additional features promoting the translocation across biological membranes are involved as well.

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Year:  2004        PMID: 14733612      PMCID: PMC1224109          DOI: 10.1042/BJ20031785

Source DB:  PubMed          Journal:  Biochem J        ISSN: 0264-6021            Impact factor:   3.857


  49 in total

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Authors:  R E Hancock
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Review 2.  Arginine-rich peptides: potential for intracellular delivery of macromolecules and the mystery of the translocation mechanisms.

Authors:  Shiroh Futaki
Journal:  Int J Pharm       Date:  2002-10-01       Impact factor: 5.875

3.  Effects of histatin 5 and derived peptides on Candida albicans.

Authors:  A L Ruissen; J Groenink; E J Helmerhorst; E Walgreen-Weterings; W Van't Hof; E C Veerman; A V Nieuw Amerongen
Journal:  Biochem J       Date:  2001-06-01       Impact factor: 3.857

4.  Killing of Candida albicans by histatin 5: cellular uptake and energy requirement.

Authors:  C Gyurko; U Lendenmann; E J Helmerhorst; R F Troxler; F G Oppenheim
Journal:  Antonie Van Leeuwenhoek       Date:  2001-09       Impact factor: 2.271

5.  Interaction of hagfish cathelicidin antimicrobial peptides with model lipid membranes.

Authors:  Gorka Basañez; Ann E Shinnar; Joshua Zimmerberg
Journal:  FEBS Lett       Date:  2002-12-04       Impact factor: 4.124

6.  Internal thiols and reactive oxygen species in candidacidal activity exerted by an N-terminal peptide of human lactoferrin.

Authors:  Antonella Lupetti; Akke Paulusma-Annema; Sonia Senesi; Mario Campa; Jaap T Van Dissel; Peter H Nibbering
Journal:  Antimicrob Agents Chemother       Date:  2002-06       Impact factor: 5.191

7.  Temporin L: antimicrobial, haemolytic and cytotoxic activities, and effects on membrane permeabilization in lipid vesicles.

Authors:  Andrea C Rinaldi; Maria Luisa Mangoni; Anna Rufo; Carla Luzi; Donatella Barra; Hongxia Zhao; Paavo K J Kinnunen; Argante Bozzi; Antonio Di Giulio; Maurizio Simmaco
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8.  Antifungal mechanism of SMAP-29 (1-18) isolated from sheep myeloid mRNA against Trichosporon beigelii.

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Journal:  Biochem Biophys Res Commun       Date:  2002-07-19       Impact factor: 3.575

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Authors:  Floris J Bikker; Antoon J M Ligtenberg; Kamran Nazmi; Enno C I Veerman; Wim van't Hof; Jan G M Bolscher; Annemarie Poustka; Arie V Nieuw Amerongen; Jan Mollenhauer
Journal:  J Biol Chem       Date:  2002-06-05       Impact factor: 5.157

10.  Histatin 5 and derivatives. Their localization and effects on the ultra-structural level.

Authors:  A L A Ruissen; J Groenink; W Van't Hof; E Walgreen-Weterings; J van Marle; H A van Veen; W F Voorhout; E C I Veerman; A V Nieuw Amerongen
Journal:  Peptides       Date:  2002-08       Impact factor: 3.750
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  21 in total

1.  Candidacidal effects of two antimicrobial peptides: histatin 5 causes small membrane defects, but LL-37 causes massive disruption of the cell membrane.

Authors:  Alice L den Hertog; Jan van Marle; Henk A van Veen; Wim Van't Hof; Jan G M Bolscher; Enno C I Veerman; Arie V Nieuw Amerongen
Journal:  Biochem J       Date:  2005-06-01       Impact factor: 3.857

2.  A membrane-destabilizing peptide in capsid protein L2 is required for egress of papillomavirus genomes from endosomes.

Authors:  Nadine Kämper; Patricia M Day; Thorsten Nowak; Hans-Christoph Selinka; Luise Florin; Jan Bolscher; Lydia Hilbig; John T Schiller; Martin Sapp
Journal:  J Virol       Date:  2006-01       Impact factor: 5.103

3.  Distinct antifungal mechanisms: beta-defensins require Candida albicans Ssa1 protein, while Trk1p mediates activity of cysteine-free cationic peptides.

Authors:  Slavena Vylkova; Xuewei S Li; Jennifer C Berner; Mira Edgerton
Journal:  Antimicrob Agents Chemother       Date:  2006-01       Impact factor: 5.191

4.  Histatin 5 uptake by Candida albicans utilizes polyamine transporters Dur3 and Dur31 proteins.

Authors:  Rohitashw Kumar; Sonia Chadha; Darpan Saraswat; Jashanjot Singh Bajwa; Rui A Li; Heather R Conti; Mira Edgerton
Journal:  J Biol Chem       Date:  2011-10-27       Impact factor: 5.157

5.  Activity and characterization of a pH-sensitive antimicrobial peptide.

Authors:  Morgan A Hitchner; Luis E Santiago-Ortiz; Matthew R Necelis; David J Shirley; Thaddeus J Palmer; Katharine E Tarnawsky; Timothy D Vaden; Gregory A Caputo
Journal:  Biochim Biophys Acta Biomembr       Date:  2019-05-08       Impact factor: 3.747

6.  The P-113 fragment of histatin 5 requires a specific peptide sequence for intracellular translocation in Candida albicans, which is independent of cell wall binding.

Authors:  Woong Sik Jang; Xuewei Serene Li; Jianing N Sun; Mira Edgerton
Journal:  Antimicrob Agents Chemother       Date:  2007-11-12       Impact factor: 5.191

7.  Histatin 5 initiates osmotic stress response in Candida albicans via activation of the Hog1 mitogen-activated protein kinase pathway.

Authors:  Slavena Vylkova; Woong Sik Jang; Wansheng Li; Namrata Nayyar; Mira Edgerton
Journal:  Eukaryot Cell       Date:  2007-08-22

8.  The pH sensitivity of histidine-containing lytic peptides.

Authors:  Zhigang Tu; Albert Young; Christopher Murphy; Jun F Liang
Journal:  J Pept Sci       Date:  2009-11       Impact factor: 1.905

9.  Salivary histatin 5 internalization by translocation, but not endocytosis, is required for fungicidal activity in Candida albicans.

Authors:  Woong Sik Jang; Jashanjot Singh Bajwa; Jianing N Sun; Mira Edgerton
Journal:  Mol Microbiol       Date:  2010-05-12       Impact factor: 3.501

10.  Reactive oxygen species play no role in the candidacidal activity of the salivary antimicrobial peptide histatin 5.

Authors:  Enno C I Veerman; Kamran Nazmi; Wim Van't Hof; Jan G M Bolscher; Alice L Den Hertog; Arie V Nieuw Amerongen
Journal:  Biochem J       Date:  2004-07-15       Impact factor: 3.857
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