Advanced search
Publication Cover
Critical Reviews in Plant Sciences Volume 32, 2013 - Issue 5
Submit an article Journal homepage
1,319
Views
30
CrossRef citations to date
0
Altmetric
Original Articles

Anionic Antimicrobial and Anticancer Peptides from Plants

Saurabh Prabhu School of Pharmacy and Biomedical Sciences, University of Central Lancashire Preston, UK
,
Sarah R. Dennison School of Pharmacy and Biomedical Sciences, University of Central Lancashire Preston, UK
,
Bob Lea School of Pharmacy and Biomedical Sciences, University of Central Lancashire Preston, UK
,
Timothy J. Snape School of Pharmacy and Biomedical Sciences, University of Central Lancashire Preston, UK
,
Iain D. Nicholl School of Applied Sciences, University of Wolverhampton, Wolverhampton, UK
,
Iza Radecka School of Applied Sciences, University of Wolverhampton, Wolverhampton, UK
&
Frederick Harris School of Forensic and Investigative Science, University of Central Lancashire Preston, UK
 show all
Pages 303-320 | Published online: 29 Apr 2013

REFERENCES

  • Al-Benna , S. , Shai , Y. , Jacobsen , F. and Steinstraesser , L. 2011 . Oncolytic activities of host defense peptides . Int. J. Mol. Sci. , 12 : 8027 – 8051 .
  • Alexandre , D. , Linhares , R. T. , Queiroz , B. , Fontoura , L. , Uchôa , A. F. , Samuels , R. I. , Macedo , M. L. R. , Bezerra , C. S. , Oliveira , E. M. , Demartini , D. R. , Carlini , C. R. and Silva , C. P. 2011 . Vicilin-derived peptides are transferred from males to females as seminal nuptial gift in the seed-feeding beetle Callosobruchus maculatus . J. Insect Physiol. , 57 : 801 – 808 .
  • Almeida , H. O. , Mattos , E. C. , Barbosa , M. O. , Teixeira , F. R. , Magalhães , R. D. M. , Romeiro , R. S. , Fontes , E. P. B. and Baracat-Pereira , M. C. 2007 . Peptide fraction inhibiting plant pathogen growth predominated in cell wall extracts from young plants or in soluble cell fraction from expanded leaves from eggplants . J. Phytopathol. , 155 : 735 – 737 .
  • Amiche , M. and Galanth , C. 2011 . Dermaseptins as models for the elucidation of membrane-acting helical amphipathic antimicrobial peptides . Curr. Pharm. Biotechnol. , 12 : 1184 – 1193 .
  • Asensio , J. L. , Canada , F. J. , Bruix , M. , Gonzalez , C. , Khiar , N. , Rodriguez-Romero , A. and Jimenez-Barbero , J. 1998 . NMR investigations of protein-carbohydrate interactions: refined three-dimensional structure of the complex between hevein and methyl beta-chitobioside . Glycobiology , 8 : 569 – 577 .
  • Asensio , J. L. , Canada , F. J. , Bruix , M. , Rodriguezromero , A. and Jimenezbarbero , J. 1995 . The interaction of hevein with n-acetylglucosamine-containing oligosaccharides - solution structure of hevein complexed to chitobiose . Eur. J. Biochem. , 230 : 621 – 633 .
  • Baguley , B. C. 2010a . “ Multidrug resistance in cancer ” . In Multi-Drug Resistance in Cancer , Edited by: Zhou , J. 1 – 14 . Totowa , NJ : Humana Press .
  • Baguley , B. C. 2010b . Multiple drug resistance mechanisms in cancer . Mol. Biotechnol. , 46 : 308 – 316 .
  • Barbosa Pelegrini , P. , Del Sarto , R. P. , Silva , O. N. , Franco , O. L. and Grossi-de-Sa , M. F. 2011 . Antibacterial peptides from plants: what they are and how they probably work . Biochem. Res. , 2011 : 250349
  • Barlow , P. G. , Svoboda , P. , Mackellar , A. , Nash , A. A. , York , I. A. , Pohl , J. , Davidson , D. J. and Donis , R. O. 2011 . Antiviral activity and increased host defense against influenza infection elicited by the human cathelicidin LL-37 . PLoS One. , 6 : e25333
  • Beaglehole , R. , Bonita , R. and Magnusson , R. 2011 . Global cancer prevention: An important pathway to global health and development . Public Health. , 125 : 821 – 831 .
  • Bechinger , B. 2004 . Structure and function of membrane-lytic peptides . Crit. Rev. Plant Sci. , 23 : 271 – 292 .
  • Belarmino , L. C. and Benko-Iseppon , A. M. 2010 . Data bank based mining on the track of antimicrobial weapons in plant genomes . Curr. Protein Peptide Sci. , 11 : 195 – 198 .
  • Bell , A. 2011 . Antimalarial peptides: the long and the short of it . Curr. Pharm. Des. , 17 : 2719 – 2731 .
  • Benko-Iseppon , A. M. , Galdino , S. L. , Calsa , T. Jr. , Kido , E. A. , Tossi , A. , Belarmino , L. C. and Crovella , S. 2010 . Overview on plant antimicrobial peptides . Curr. Protein Peptide Sci. , 11 : 181 – 188 .
  • Bernard , J. J. and Gallo , R. L. 2011 . Protecting the boundary: the sentinel role of host defense peptides in the skin . Cell. Mol. Life Sci. , 68 : 2189 – 2199 .
  • Bevins , C. L. and Salzman , N. H. 2011 . Paneth cells, antimicrobial peptides and maintenance of intestinal homeostasis . Nat Rev Microbiol. , 9 : 356 – 368 .
  • Bokesch , H. R. , Pannell , L. K. , Cochran , P. K. , Sowder , R. C. , McKee , T. C. and Boyd , M. R. 2001 . A novel anti-HIV macrocyclic peptide from Palicourea condensata . J. Nat. Prod. , 64 : 249 – 250 .
  • Borad , V. and Sriram , S. 2008 . Pathogenesis-Related Proteins for the Plant Protection . Asian J. Exp. Sci. , 22 : 189 – 196 .
  • Bordi , C. and de Bentzmann , S. 2011 . Hacking into bacterial biofilms: a new therapeutic challenge . Ann. Intensive. Care. , 1 : 19
  • Bostanci , N. and Belibasakis , G. N. 2012 . Porphyromonas gingivalis: an invasive and evasive opportunistic oral pathogen . FEMS Microbiol. Lett. , 333 : 1 – 9 .
  • Broekaert , W. , Lee , H. I. , Kush , A. , Chua , N. H. and Raikhel , N. 1990 . Wound-induced accumulation of messenger-RNA containing a hevein sequence in laticifers of rubber tree (Hevea-Brasiliensis) . Proc. Natl. Acad. Sci. U. S. A. , 87 : 7633 – 7637 .
  • Broekaert , W. F. , Cammue , B. P. A. , DeBolle , M. F. C. , Thevissen , K. , DeSamblanx , G. W. and Osborn , R. W. 1997 . Antimicrobial peptides from plants . Crit. Rev. Plant Sci. , 16 : 297 – 323 .
  • Bruhn , O. , Grotzinger , J. , Cascorbi , I. and Jung , S. 2011 . Antimicrobial peptides and proteins of the horse—insights into a well-armed organism . Vet. Res. , 42
  • Burman , R. , Herrmann , A. , Tran , R. , Kivela , J. E. , Lomize , A. , Gullbo , J. and Goransson , U. 2011a . Cytotoxic potency of small macrocyclic knot proteins: Structure-activity and mechanistic studies of native and chemically modified cyclotides . Org. Biomol. Chem. , 9 : 4306 – 4314 .
  • Burman , R. , Stromstedt , A. A. , Malmsten , M. and Goransson , U. 2011b . Cyclotide-membrane interactions: Defining factors of membrane binding, depletion and disruption . Biochim. Biophys. Acta. , 1808 : 2665 – 2673 .
  • Calderon , L. D. , Silva , A. D. E. , Ciancaglini , P. and Stabeli , R. G. 2011 . Antimicrobial peptides from Phyllomedusa frogs: from biomolecular diversity to potential nanotechnologic medical applications . Amino Acids , 40 : 29 – 49 .
  • Camarero , J. A. 2011 . Legume cyclotides shed light on the genetic origin of knotted circular proteins . Proc. Natl. Acad. Sci. U. S. A. , 108 : 10025 – 10026 .
  • Candido , E. D. S. , Pinto , M. F. S. , Pelegrini , P. B. , Lima , T. B. , Silva , O. N. , Pogue , R. , Grossi-de-Sa , M. F. and Franco , O. L. 2011 . Plant storage proteins with antimicrobial activity: novel insights into plant defense mechanisms . FASEB J. , 25 : 3290 – 3305 .
  • Carvalho , A. D. O. and Gomes , V. M. 2011 . Plant defensins and defensin-like peptides - biological activities and biotechnological applications . Curr. Pharm. Des. , 17 : 4270 – 4293 .
  • Cazzaniga , E. , Bulbarelli , A. , Lonati , E. , Orlando , A. , Re , F. , Gregori , M. and Masserini , M. 2011 . Abeta peptide toxicity is reduced after treatments decreasing phosphatidylethanolamine content in differentiated neuroblastoma cells . Neurochem. Res. , 36 : 863 – 869 .
  • Cerenius , L. , Jiravanichpaisal , P. , Liu , H. P. and Soderhall , I. 2010 . “ Crustacean immunity ” . In Invertebrate Immunity , Edited by: Soderhall , K. 239 – 259 . Berlin : Springer-Verlag Berlin .
  • Chen , B. , Colgrave , M. L. , Daly , N. L. , Rosengren , K. J. , Gustafson , K. R. and Craik , D. J. 2005 . Isolation and characterization of novel cyclotides from Viola hederaceae - Solution structure and anti-HIV activity of vhl-1, a leaf-specific expressed cyclotide . J. Biol. Chem. , 280 : 22395 – 22405 .
  • Cho , J. H. , Sung , B. H. and Kim , S. C. 2009 . Buforins: Histone H2A-derived antimicrobial peptides from toad stomach . Biochim. Biophys. Acta. , 1788 : 1564 – 1569 .
  • Cheuk , R. F. , Chen , H. , Kim , C. J. , Shinn , P. and Ecker , J. R. 2004 . Arabidopsis ORF clones . Swiss-prot accession code: Q8VZK8
  • Colgrave , M. L. , Huang , Y. H. , Craik , D. J. and Kotze , A. C. 2010 . Cyclotide interactions with the nematode external surface . Antimicrob. Agents Chemother. , 54 : 2160 – 2166 .
  • Colgrave , M. L. , Kotze , A. C. , Huang , Y. H. , O’Grady , J. , Simonsen , S. M. and Craik , D. J. 2008 . Cyclotides: natural, circular plant peptides that possess significant activity against gastrointestinal nematode parasites of sheep . Biochemistry , 47 : 5581 – 5589 .
  • Collinge , D. B. , Jorgensen , H. J. L. , Lund , O. S. and Lyngkjaer , M. F. 2010 . “ Engineering pathogen resistance in crop plants: Current trends and future prospects ” . In Ann. Rev. Phytopathol. Edited by: VanAlfen , N. K. , Bruening , G. and Leach , J. E. Vol. 48 , 269 – 291 .
  • Collinge , D. B. , Lund , O. S. and Thordal-Christensen , H. 2008 . What are the prospects for genetically engineered, disease resistant plants? . Eur. J. Plant Pathol. , 121 : 217 – 231 .
  • Colombo , G. , Meli , M. , Canada , J. , Asensio , J. L. and Jimenez-Barbero , J. 2005 . A dynamic perspective on the molecular recognition of chitooligosaccharide ligands by hevein domains . Carbohydr. Res. , 340 : 1039 – 1049 .
  • Conlon , J. M. 2011 . Structural diversity and species distribution of host-defense peptides in frog skin secretions . Cell. Mol. Life Sci. , 68 : 2303 – 2315 .
  • Conlon , M. J. and Sonnevend , A. 2011 . Clinical applications of amphibian antimicrobial peptides . J. Med. Sci. , 4 : 62 – 72 .
  • Craik , D. J. 2010 . Discovery and applications of the plant cyclotides . Toxicon. , 56 : 1092 – 1102 .
  • Craik , D. J. 2012 . Host-defense activities of cyclotides . Toxins , 4 : 139 – 156 .
  • Craik , D. J. , Daly , N. L. , Bond , T. and Waine , C. 1999 . Plant cyclotides: A unique family of cyclic and knotted proteins that defines the cyclic cystine knot structural motif . J. Mol. Biol. , 294 : 1327 – 1336 .
  • Craik , D. J. , Swedberg , J. E. , Mylne , J. S. and Cemazar , M. 2012 . Cyclotides as a basis for drug design . Expert Opinion on Drug Discovery. , 7 : 179 – 194 .
  • Daly , N. L. , Chen , B. , Nguyencong , P. and Craik , D. J. 2010 . Structure and activity of the leaf-specific cyclotide vhl-2 . Aust. J. Chem. , 63 : 771 – 778 .
  • Daly , N. L. , Rosengren , K. J. and Craik , D. J. 2009 . Discovery, structure and biological activities of cyclotides . Adv. Drug Del. Rev. , 61 : 918 – 930 .
  • De Boer , S. H. and Boucher , A. 2011 . Prospect for functional eradication of the bacterial ring rot disease of potato . Canadian Journal of Plant Pathology-Revue Canadienne De Phytopathologie , 33 : 297 – 307 .
  • De Brucker , K. , Cammue , B. P. A. and Thevissen , K. 2011 . Apoptosis-inducing antifungal peptides and proteins . Biochem. Soc. Trans. , 39 : 1527 – 1532 .
  • De Lucca , A. J. , Cleveland , T. E. and Wedge , D. E. 2005 . Plant-derived antifungal proteins and peptides . Can. J. Microbiol. , 51 : 1001 – 1014 .
  • Dennison , S. R. , Harris , F. , Bhatt , T. , Singh , J. and Phoenix , D. A. 2009 . The effect of C-terminal amidation on the efficacy and selectivity of antimicrobial and anticancer peptides . Mol. Cell. Biochem. , 332 : 43 – 50 .
  • Dennison , S. R. , Harris , F. , Bhatt , T. , Singh , J. and Phoenix , D. A. 2010a . A theoretical analysis of secondary structural characteristics of anticancer peptides . Mol. Cell. Biochem. , 333 : 129 – 135 .
  • Dennison , S. R. , Harris , F. and Phoenix , D. A. 2005 . Are oblique orientated alpha-helices used by antimicrobial peptides for membrane invasion? . Protein Pept. Lett. , 12 : 27 – 29 .
  • Dennison , S. R. , Harris , F. and Phoenix , D. A. 2007 . The interactions of aurein 1.2 with cancer cell membranes . Biophys. Chem. , 127 : 78 – 83 .
  • Dennison , S. R. , Harris , F. and Phoenix , D. A. 2010b . A Langmuir approach using monolayer interactions to investigate surface active peptides . Protein Pept. Lett. , 17 : 1363 – 1375 .
  • Dennison , S. R. , Morton , L. H. G. and Phoenix , D. A. 2012a . Role of molecular architecture on the relative efficacy of aurein 2.5 and modelin 5 . Biochim. Biophys. Acta. , 1818 : 2094 – 2102 .
  • Dennison , S. R. , Harris , F. and Phoenix , D. A. 2012b . “ Models for the membrane interactions of antimicrobial peptides ” . In Antimicrobial Peptides , Edited by: Phoenix , D. A. , Dennison , S. R. and Harris , F. Wiley, Germany . pp. 145–180.
  • Dennison , S. R. , Akbar , Z. , Phoenix , D A. and Snape , T. J. 2012c . Interactions between suitably functionalised conformationally distinct benzanilides and phospholipid monolayers . Soft Matter. , 8 : 3258 – 3264 .
  • Dennison , S. R. , Snape , T. J. and Phoenix , D A. 2012d . Thermodynamic interactions of a cis and trans benzanilide with Escherichia coli bacterial membranes . Eur Biophys J. , 8 : 687 – 693 .
  • Dennison , S. R. and Phoenix , D. A. 2011a . Influence of C-terminal amidation on the efficacy of modelin-5 . Biochemistry , 50 : 1514 – 1523 .
  • Dennison , S. R. and Phoenix , D. A. 2011b . Effect of cholesterol on the membrane interaction of modelin-5 isoforms . Biochemistry. , 50 : 10898 – 10909 .
  • Dennison , S. R. , Phoenix , A. J. and Phoenix , D. A. 2011 . Effect of salt on the interaction of Hal18 with lipid membranes . Eur Biophys J. , 41 : 769 – 776 .
  • Dennison , S. R. , Whittaker , M. , Harris , F. and Phoenix , D. A. 2006 . Anticancer alpha-helical peptides and structure/function relationships underpinning their interactions with tumour cell membranes . Curr Protein Pept Sci. , 7 : 487 – 499 .
  • Dhekney , S. A. , Li , Z. T. and Gray , D. J. 2011 . Grapevines engineered to express cisgenic Vitis vinifera thaumatin-like protein exhibit fungal disease resistance . In Vitro Cellular & Developmental Biology-Plant , 47 : 458 – 466 .
  • Dodds , P. N. and Rathjen , J. P. 2010 . Plant immunity: towards an integrated view of plant-pathogen interactions . Nat Rev Genet. , 11 : 539 – 548 .
  • Doernenburg , H. 2008 . Plant cell culture technology-harnessing a biological approach for competitive cyclotides production . Biotechnol. Lett. , 30 : 1311 – 1321 .
  • Doernenburg , H. 2010 . Cyclotide synthesis and supply: From plant to bioprocess . Biopolymers , 94 : 602 – 610 .
  • Dunwell , J. M. 2005 . “ Vicilin and legumin seed storage proteins, structure, function, and evolution of ” . In Biopolymers Online , Wiley-VCH Verlag GmbH & Co. KGaA .
  • Edreva , A. 2005 . Pathogenesis-related proteins: Research progress in the last 15 years . General Applied Plant Physiology , 31 : 105 – 124 .
  • Egorov , T. A. and Odintsova , T. I. 2012 . Defense peptides of plant immunity . Russ. J. Bioorganic Chem. , 38 : 1 – 9 .
  • Ehrenstein , G. and Lecar , H. 1977 . Electrically gated ionic channels in lipid bilayers . Q. Rev. Biophys. , 10 : 1 – 34 .
  • Epand , R. M. and Epand , R. F. 2011 . Bacterial membrane lipids in the action of antimicrobial agents . J Pept Sci. , 17 : 298 – 305 .
  • Fernandez de Caleya , R. , Gonzalez-Pascual , B. , Garcia-Olmedo , F. and Carbonero , P. 1972 . Susceptibility of phytopathogenic bacteria to wheat purothionins in vitro . Appl. Microbiol. , 23 : 998 – 1000 .
  • Fernando , M.-S. , Ligia , B.-A. , Mayra , D.-B. and Ignacio , I.-F. 2011 . A review of a promising therapeutic and agronomical alternative: Antimicrobial peptides from Capsicum sp . Afr. J. Biotechnol. , 10 : 19918 – 19928 .
  • Fernebro , J. 2011 . Fighting bacterial infections—Future treatment options . Drug Resist. Updat. , 14 : 125 – 139 .
  • Firczuk , M. , Winiarska , M. , Szokalska , A. , Jodlowska , M. , Swiech , M. , Bojarczuk , K. , Salwa , P. and Nowis , D. 2011 . Approaches to improve photodynamic therapy of cancer . Frontiers in Bioscience-Landmark , 16 : 208 – 224 .
  • Fourie , G. , Steenkamp , E. T. , Ploetz , R. C. , Gordon , T. R. and Viljoen , A. 2011 . Current status of the taxonomic position of Fusarium oxysporum formae specialis cubense within the Fusarium oxysporum complex . Infect., Genet. Evol. , 11 : 533 – 542 .
  • Fusetani , N. 2010 . Antifungal peptides in marine invertebrates . Invertebr. Survival J. , 7 : 53 – 66 .
  • Genin , S. 2010 . Molecular traits controlling host range and adaptation to plants in Ralstonia solanacearum . New Phytol. , 187 : 920 – 928 .
  • Gerlach , S. L. and Mondal , D. 2012 . The bountiful biological activities of cyclotides . Chron. Young Sci. , 3 : 169 – 177 .
  • Ghosh , J. , Lun , C. M. , Majeske , A. J. , Sacchi , S. , Schrankel , C. S. and Smith , L. C. 2011 . Invertebrate immune diversity . Dev. Comp. Immunol. , 35 : 959 – 974 .
  • Giang , K. T. N. , Zhang , S. , Ngan , T. K. N. , Phuong , Q. T. N. , Chiu , M. S. , Hardjojo , A. and Tam , J. P. 2011 . Discovery and characterization of novel cyclotides originated from chimeric precursors consisting of albumin-1 chain a and cyclotide domains in the Fabaceae family . J. Biol. Chem. , 286 : 24275 – 24287 .
  • Giske , C. G. and Cornaglia Esgars , G. 2010 . Supranational surveillance of antimicrobial resistance: The legacy of the last decade and proposals for the future . Drug Resist. Update , 13 : 93 – 98 .
  • Gomes , A. , Giri , B. , Saha , A. , Mishra , R. , Dasgupta , S. C. , Debnath , A. and Gomes , A. 2007 . Bioactive molecules from amphibian skin: Their biological activities with reference to therapeutic potentials for possible drug development . Indian J. Exp. Biol. , 45 : 579 – 593 .
  • Goransson , U. , Herrmann , A. , Burman , R. , Haugaard-Jonsson , L. M. and Rosengren , K. J. 2009 . The conserved glu in the cyclotide cycloviolacin O2 has a key structural role . ChemBioChem , 10 : 2354 – 2360 .
  • Gotay , C. C. 2010 . Cancer prevention: major initiatives and looking into the future . Expert Rev. Pharmacoecon. Outcomes Res. , 10 : 143 – 154 .
  • Goumon , Y. , Lugardon , K. , Kieffer , B. , Lefevre , J. F. , Van Dorsselaer , A. , Aunis , D. and Metz-Boutigue , M. H. 1998 . Characterization of antibacterial COOH-terminal proenkephalin-A-derived peptides (PEAP) in infectious fluids—Importance of enkelytin, the antibacterial PEAP(209-237) secreted by stimulated chromaffin cells . J. Biol. Chem. , 273 : 29847 – 29856 .
  • Gran , L. 1973a . On the effect of a polypeptide isolated from “Kalata-Kalata” (Oldenlandia affinis DC) on the oestrogen dominated uterus . Acta Pharmacol. Toxicol. (Copenh.) , 33 : 400 – 408 .
  • Gran , L. 1973b . Oxytocic principles of oldenlandia-affinis . J. Nat. Prod. , 36 : 174 – 178 .
  • Gran , L. 1970 . An oxytocic principle found in Oldenlandia affinis DC . Medd Nor Farm Selsk , 32 : 173 – 180 .
  • Gran , L. , Sandberg , F. and Sletten , K. 2000 . Oldenlandia affinis (R&S) DC - A plant containing uteroactive peptides used in African traditional medicine . J. Ethnopharmacol. , 70 : 197 – 203 .
  • Gran , L. , Sletten , K. and Skjeldal , L. 2008 . Cyclic peptides from Oldenlandia affinis DC. Molecular and biological properties . Chem. Biodivers. , 5 : 2014 – 2022 .
  • Gray , D. J. , Jayasankar , S. and Li , Z. 2005 . “ Vitis spp ” . In Biotechnology of Fruit and Nut Crops , Edited by: Litz , R. E. 672 – 706 . Oxford , , UK : CAB Int. .
  • Gruber , C. W. , Cemazar , M. , Anderson , M. A. and Craik , D. J. 2007 . Insecticidal plant cyclotides and related cystine knot toxins . Toxicon. , 49 : 561 – 575 .
  • Gruber , C. W. , Elliott , A. G. , Ireland , D. C. , Delprete , P. G. , Dessein , S. , Goransson , U. , Trabi , M. , Wang , C. K. , Kinghorn , A. B. , Robbrecht , E. and Craik , D. J. 2008 . Distribution and Evolution of Circular Miniproteins in Flowering Plants . Plant Cell , 20 : 2471 – 2483 .
  • Gruber , C. W. and O’Brien , M. 2011 . Uterotonic plants and their bioactive constituents . Planta Med. , 77 : 207 – 220 .
  • Hammami , R. , Ben Hamida , J. , Vergoten , G. and Fliss , I. 2009 . PhytAMP: a database dedicated to antimicrobial plant peptides . Nucleic Acids Res. , 37 : D963 – D968 .
  • Hancock , R. E. W. , Brown , K. L. and Mookherjee , N. 2006 . Host defense peptides from invertebrates – emerging antimicrobial strategies . Immunobiol , 211 : 315 – 322 .
  • Hardner , C. M. , Peace , C. , Lowe , A. J. , Neal , J. , Pisanu , P. , Powell , M. , Schmidt , A. , Spain , C. and Williams , K. 2009 . Genetic resources and domestication of macadamia . Hort. Rev. , 35 : 1 – 125 .
  • Harrington , J. M. 2011 . Antimicrobial peptide killing of African trypanosomes . Parasite Immunol. , 33 : 461 – 469 .
  • Harris , F. , Dennison , S. and Phoenix , D. 2011 . Anionic antimicrobial peptides from eukaryotic organisms and their mechanisms of action . Curr. Chem. Biol. , 5 : 142 – 153 .
  • Harris , F. , Dennison , S. A. and Phoenix , D. A. 2012a . “ The selectivity and toxicity of oncolytic antimicrobial peptides ” . In Antimicrobial Peptides , Edited by: Phoenix , D. A. 181 – 221 . Germany : Wiley .
  • Harris , F. , Dennison , S. R. and Phoenix , D. A. 2009 . Anionic antimicrobial peptides from eukaryotic organisms . Curr. Protein Pept. Sci. , 10 : 585 – 606 .
  • Harris , F. , Dennison , S. R. and Phoenix , D. A. 2012b . Aberrant action of amyloidogenic host defense peptides: a new paradigm to investigate neurodegenerative disorders? . FASEB J. , 26 : 1776 – 1781 .
  • Harris , F. , Dennison , S. R. , Singh , J. and Phoenix , D. A. 2013 . On the selectivity and efficacy of defense peptides with respect to cancer cells . Med. Res. Rev. , 33 : 190 – 234 .
  • Harris , F. and Pierpoint , L. 2012 . Photodynamic therapy based on 5-aminolevulinic acid and its use as an antimicrobial agent . Med. Res. Rev. , 32 : 1292 – 1327 .
  • Hawkey , P. M. and Jones , A. M. 2009 . The changing epidemiology of resistance . J. Antimicrob. Chemother. , 64 : 3 – 10 .
  • Heller , W. T. , Waring , A. J. , Lehrer , R. I. and Huang , H. W. 1998 . Multiple states of beta-sheet peptide protegrin in lipid bilayers . Biochemistry , 37 : 17331 – 17338 .
  • Henriques , S. T. 2012 . Phosphatidylethanolamine-binding is a conserved feature of cyclotide-membrane interactions . J. Biol.Chem , 287 : 33629 – 33643 .
  • Henriques , S. T. and Craik , D. J. 2010 . Cyclotides as templates in drug design . Drug Discov. Today. , 15 : 57 – 64 .
  • Henriques , S. T. and Craik , D. J. 2012 . Importance of the Cell membrane on the mechanism of action of cyclotides . ACS Chem. Biol. , 7 : 626 – 636 .
  • Hernández-Gay , J. J. , Ardá , A. , Eller , S. , Mezzato , S. , Leeflang , B. R. , Unverzagt , C. , Cañada , F. J. and Jiménez-Barbero , J. 2010 . Insights into the dynamics and molecular recognition features of glycopeptides by protein receptors: The 3D solution structure of hevein bound to the trisaccharide core of N-glycoproteins . Chemistry , 16 : 10715 – 10726 .
  • Hogberg , L. D. , Heddini , A. and Cars , O. 2010 . The global need for effective antibiotics: challenges and recent advances . Trends Pharmacol. Sci. , 31 : 509 – 515 .
  • Hong , J. K. and Hwang , B. K. 2005 . Induction of enhanced disease resistance and oxidative stress tolerance by overexpression of pepper basic PR-1 gene in Arabidopsis . Physiol. Plant. , 124 : 267 – 277 .
  • Hoskin , D. W. and Ramamoorthy , A. 2008 . Studies on anticancer activities of antimicrobial peptides . Biochim Biophys Acta Biomembr , 1778 : 357 – 375 .
  • Huang , H. W. 2000 . Action of antimicrobial peptides: Two-state model . Biochemistry , 39 : 8347 – 8352 .
  • Huang , Y. , Huang , J. and Chen , Y. 2010 . Alpha-helical cationic antimicrobial peptides: relationships of structure and function . Protein Cell , 1 : 143 – 152 .
  • Huang , Y. H. , Colgrave , M. L. , Daly , N. L. , Keleshian , A. , Martinac , B. and Craik , D. J. 2009 . The biological activity of the prototypic cyclotide kalata B1 is modulated by the formation of multimeric pores . J. Biol. Chem. , 284 : 20699 – 20707 .
  • Hultmark , D. , Steiner , H. , Rasmuson , T. and Boman , H. G. 1980 . Insect immunity—purification and properties of 3 inducible bactericidal proteins from hemolymph of immunized pupae of hyalophora-cecropia . Eur. J. Biochem. , 106 : 7 – 16 .
  • Ireland , D. C. , Colgrave , M. L. and Craik , D. J. 2006 . A novel suite of cyclotides from Viola odorata: sequence variation and the implications for structure, function and stability . Biochem. J. , 400 : 1 – 12 .
  • Jagadish , K. and Camarero , J. A. 2010 . Cyclotides, A Promising Molecular Scaffold for Peptide-Based Therapeutics . Biopolymers. , 94 : 611 – 616 .
  • Jagadish , K. , Ji , Y. , Bi , T. , Berrade , L. and Camarero , J. A. 2011 . Cyclotides, a novel natural peptide scaffold for drug discovery . Biopolymers. , 96 ( 149 )
  • Jago , W. and Jago , W. 1926 . “ Toxic action of wheat flour to brewer's yeast ” . In Industrial Fermentations , Edited by: Allen , W. P. 128 – 167 . New York : The Chemical Catering Company .
  • Jang , S. A. , Kim , H. , Lee , J. Y. , Shin , J. R. , Kim , D. J. , Cho , J. H. and Kim , S. C. 2012 . Mechanism of action and specificity of antimicrobial peptides designed based on buforin IIb . Peptides , 34 : 283 – 289 .
  • Jayasankar , S. , Li , Z. J. and Gray , D. J. 2003 . Constitutive expression of Vitis vinifera thaumatin-like protein after in vitro selection and its role in anthracnose resistance . Funct. Plant Biol. , 30 : 1105 – 1115 .
  • Jennings , C. V. , Rosengren , K. J. , Daly , N. L. , Plan , M. , Stevens , J. , Scanlon , M. J. , Waine , C. , Norman , D. G. , Anderson , M. A. and Craik , D. J. 2005 . Isolation, solution structure, and insecticidal activity of kalata B2, a circular protein with a twist: do Mobius strips exist in nature? . Biochemistry. , 44 : 851 – 860 .
  • Jenssen , H. 2009 . Therapeutic approaches using host defense peptides to tackle herpes virus infections . Viruses-Basel , 1 : 939 – 964 .
  • Jenssen , H. and Hancock , R. E. W. 2010 . “ Therapeutic potential of HDPs as immunomodulatory agents ” . In Antimicrobial Peptides: Methods and Protocols , Edited by: Giuliani , A. and Rinaldi , A. C. 329 – 347 . Totowa , NJ : Humana Press .
  • Jones , J. D. G. and Dangl , J. L. 2006 . The plant immune system . Nature , 444 : 323 – 329 .
  • Kaas , Q. , Westermann , J.-C. , Troeira Henriques , S. and Craik , D. J. 2010 . “ Antimicrobial peptides in plants ” . In Antimicrobial Peptides: Discovery, Design, and Novel Therapeutic Strategies , Edited by: Wang , G. 40 – 71 . Oxford , , UK : CAB Int. .
  • Kanokwiroon , K. , Teanpaisan , R. , Wititsuwannakul , D. , Hooper , A. B. and Wititsuwannakul , R. 2008 . Antimicrobial activity of a protein purified from the latex of Hevea brasiliensis on oral microorganisms . Mycoses. , 51 : 301 – 307 .
  • Kiba , A. , Saitoh , H. , Nishihara , M. , Omiya , K. and Yamamura , S. 2003 . C-terminal domain of a hevein-like protein from Wasabia japonica has potent antimicrobial activity . Plant Cell Physiol. , 44 : 296 – 303 .
  • Kim , J. and Sudbery , P. 2011 . Candida albicans, a major human fungal pathogen . J. Microbiol. , 49 : 171 – 177 .
  • King , J. D. , Mechkarska , M. , Coquet , L. , Leprince , J. , Jouenne , T. , Vaudry , H. , Takada , K. and Conlon , J. M. 2012 . Host-defense peptides from skin secretions of the tetraploid frogs Xenopus petersii and Xenopus pygmaeus, and the octoploid frog Xenopus lenduensis (Pipidae) . Peptides. , 33 : 35 – 43 .
  • Klosterman , S. J. , Atallah , Z. K. , Vallad , G. E. and Subbarao , K. V. 2009 . Diversity, pathogenicity, and management of verticillium species . Annu. Rev. Phytopathol. , 47 : 39 – 62 .
  • Konno , K. 2011 . Plant latex and other exudates as plant defense systems: Roles of various defense chemicals and proteins contained therein . Phytochemistry , 72 : 1510 – 1530 .
  • LaForce , F. M. and Boose , D. S. 1981 . Sublethal damage of Escherichia coli by lung lavage . Am. Rev. Respir. Dis. , 124 : 733 – 737 .
  • LaForce , F. M. and Boose , D. S. 1984 . Effect of zinc and phosphate on an antibacterial peptide isolated from lung lavage . Infect. Immun. , 45 : 692 – 696 .
  • Lai , R. , Liu , H. , Hui Lee , W. and Zhang , Y. 2002 . An anionic antimicrobial peptide from toad Bombina maxima . Biochem. Biophys. Res. Commun. , 295 : 796 – 799 .
  • Laverty , G. , Gorman , S. P. and Gilmore , B. F. 2011 . The potential of antimicrobial peptides as biocides . Int. J. Mol. Sci. , 12 : 6566 – 6596 .
  • Lee , H. , Broekaert , W. F. and Raikhel , N. V. 1991 . Co-translational and posttranslational processing of the hevein preproprotein of latex of the rubber tree (hevea-brasiliensis) . J. Biol. Chem. , 266 : 15944 – 15948 .
  • Lee , H. I. and Raikhel , N. V. 1995 . Prohevein is poorly processed but shows enhanced resistance to a chitin-binding fungus in transgenic tomato plants . Braz. J. Med. Biol. Res. , 28 : 743 – 750 .
  • Lee , Y. K. , Lay , L. K. , Mahsufi , M. S. , Guan , T. S. , Elumalai , S. and Thong , O. M. 2012 . Anti-proliferation effect of Hevea brasiliensis latex B-serum on human breast epithelial cells . Pak. J. Pharm. Sci. , 25 : 645 – 650 .
  • Lehrer , R. I. and Lu , W. 2012 . alpha-Defensins in human innate immunity . Immunol. Rev. , 245 : 84 – 112 .
  • Leontiadou , H. , Mark , A. E. and Marrink , S. J. 2006 . Antimicrobial peptides in action . J. Am. Chem. Soc. , 128 : 12156 – 12161 .
  • Li , Z. T. , Dhekney , S. A. and Gray , D. J. 2011 . PR-1 gene family of grapevine: a uniquely duplicated PR-1 gene from a Vitis interspecific hybrid confers high level resistance to bacterial disease in transgenic tobacco . Plant Cell Rep. , 30 : 1 – 11 .
  • Linde , A. , Wachter , B. , Höner , O. , Dib , L. , Ross , C. , Tamayo , A. , Blecha , F. and Melgarejo , T. 2009 . Natural history of innate host defense peptides . Probiotics Antimicrob Proteins , 1 : 97 – 112 .
  • Lindholm , P. , Goransson , U. , Johansson , S. , Claeson , P. , Gullbo , J. , Larsson , R. , Bohlin , L. and Backlund , A. 2002 . Cyclotides: A novel type of cytotoxic agents . Mol. Cancer Ther. , 1 : 365 – 369 .
  • Liu , R. , Liu , H. , Ma , Y. , Wu , J. , Yang , H. , Ye , H. and Lai , R. 2011 . There are abundant antimicrobial peptides in brains of two kinds of bombina toads . J. Proteome Res. , 10 : 1806 – 1815 .
  • López-García , B. , Segundo , B. S. and Coca , M. “ Antimicrobial peptides as a promising alternative for plant disease protection ” . In Small Wonders: Peptides for Disease Control , Edited by: Rajasekaran , I K. , Cary , J. W. , Jaynes , J. M. and Montesinos , E. 263 – 294 . Washington : American Chemical Society .
  • Ludtke , S. J. , He , K. , Heller , W. T. , Harroun , T. A. , Yang , L. and Huang , H. W. 1996, 2012 . Membrane pores induced by magainin . Biochemistry. , 35 : 13723 – 13728 .
  • Mak , A. S. and Jones , B. L. 1976 . Amino-acid sequence of wheat beta-purothionin . Can. J. Biochem. , 54 : 835 – 842 .
  • Mandal , S. M. , Dey , S. , Mandal , M. , Sarkar , S. , Maria-Neto , S. and Franco , O. L. 2009 . Identification and structural insights of three novel antimicrobial peptides isolated from green coconut water . Peptides. , 30 : 633 – 637 .
  • Mandal , S. M. , Migliolo , L. , Das , S. , Mandal , M. , Franco , O. L. and Hazra , T. K. 2012 . Identification and characterization of a bactericidal and proapoptotic peptide from cycas revoluta seeds with DNA binding properties . J. Cell. Biochem. , 113 : 184 – 193 .
  • Manners , J. M. 2007 . Hidden weapons of microbial destruction in plant genomes . Genome Biol. , 8 ( 225 )
  • Manners , J. M. 2009 . Primitive defense: The MiAMP1 antimicrobial peptide family . Plant Mol. Biol. Rep. , 27 : 237 – 242 .
  • Marcotte , I. , Wegener , K. L. , Lam , Y. H. , Chia , B. C. S. , de Planque , M. R. R. , Bowie , J. H. , Auger , M. and Separovic , F. 2003 . Interaction of antimicrobial peptides from Australian amphibians with lipid membranes . Chem. Phys. Lipids. , 122 : 107 – 120 .
  • Marcus , J. P. , Goulter , K. C. , Green , J. L. , Harrison , S. J. and Manners , J. M. 1997 . Purification, characterisation and cDNA cloning of an antimicrobial peptide from Macadamia integrifolia . Eur. J. Biochem. , 244 : 743 – 749 .
  • Marcus , J. P. , Goulter , K. C. and Manners , J. M. 2008 . Peptide fragments from plant vicilins expressed in Escherichia coli exhibit antimicrobial activity in vitro . Plant Mol. Biol. Rep. , 26 : 75 – 87 .
  • Marcus , J. P. , Green , J. L. , Goulter , K. C. and Manners , J. M. 1999 . A family of antimicrobial peptides is produced by processing of a 7S globulin protein in macadamia integrifolia kernels . Plant J. , 19 : 699 – 710 .
  • Maróti , G. , Kereszt , A. , Kondorosi , É. and Mergaert , P. 2011 . Natural roles of antimicrobial peptides in microbes, plants and animals . Res. Microbiol. , 162 : 363 – 374 .
  • Marshall , S. H. and Arenas , G. 2003 . Antimicrobial peptides: A natural alternative to chemical antibiotics and a potential for applied biotechnology . Electron. J. Biotechnol. , 6 http://www.scielo.cl/pdf/ejb/v6n3/a02.pdf (accessed Jan, 2013)
  • Masuda , K. , Nakamura , K. , Yoshioka , S. , Fukaya , R. , Sakai , N. and Ayabe , T. 2011 . Regulation of microbiota by antimicrobial peptides in the gut . Adv. Otorhinolaryngol. , 72 : 97 – 99 .
  • Matejuk , A. , Leng , Q. , Begum , M. D. , Woodle , M. C. , Scaria , P. , Chou , S. T. and Mixson , A. J. 2010 . Peptide-based antifungal therapies against emerging infections . Drug Future , 35 : 197 – 217 .
  • Matsuzaki , K. , Murase , O. and Miyajima , K. 1995 . Kinetics of pore formation by an antimicrobial peptide, magainin-2, in phospholipid-bilayers . Biochemistry , 34 : 12553 – 12559 .
  • McManus , A. M. , Nielsen , K. J. , Marcus , J. P. , Harrison , S. J. , Green , J. L. , Manners , J. M. and Craik , D. J. 1999 . MiAMP1, a novel protein from macadamia integrifolia adopts a Greek key beta-barrel fold unique amongst plant antimicrobial proteins . J. Mol. Biol. , 293 : 629 – 638 .
  • Merzendorfer , H. 2011 . The cellular basis of chitin synthesis in fungi and insects: Common principles and differences . Eur. J. Cell Biol. , 90 : 759 – 769 .
  • Metz-Boutigue , M. H. , Goumon , Y. , Lugardon , K. , Strub , J. M. and Aunis , D. 1998 . Antibacterial peptides are present in chromaffin cell secretory granules . Cell. Mol. Neurobiol. , 18 : 249 – 266 .
  • Mourya , M. K. , Prakash, Swami , A. , Singh , G. K. and Mathur , A. 2011 . Leaves of cycas revoluta: Potent antimicrobial and antioxidant agent . World J. Sci. Tech. , 1 : 11 – 20 .
  • Mulvenna , J. P. , Wang , C. and Craik , D. J. 2006 . CyBase: a database of cyclic protein sequence and structure . Nucleic Acids Res. , 34 : D192 – D194 .
  • Mura , M. , Dennison , S. R. , Zvelindovsky , A. V. and Phoenix , D. A. 2013 . Aurein 2.3 functionality is supported by oblique orientated alpha-helical formation . Biochim. Biophys. Acta. , 1828 : 586 – 594 .
  • Mylne , J. S. , Wang , C. K. , Van der Weerden , N. L. and Craik , D. J. 2010 . Cyclotides are a component of the innate defense of Oldenlandia affinis . Biopolymers. , 94 : 635 – 646 .
  • Nair , S. S. , Romanuka , J. , Billeter , M. , Skjeldal , L. , Emmett , M. R. , Nilsson , C. L. and Marshall , A. G. 2006 . Structural characterization of an unusually stable cyclic peptide, kalata B2 from Oldenlandia affinis . Biochim. Biophys. Acta. , 1764 : 1568 – 1576 .
  • Nguyen , L. T. , Haney , E. F. and Vogel , H. J. 2011 . The expanding scope of antimicrobial peptide structures and their modes of action . Trends Biotechnol. , 29 : 464 – 472 .
  • Nicolas , P. 2009 . Multifunctional host defense peptides: intracellular-targeting antimicrobial peptides . FEBS J. , 276 : 6483 – 6496 .
  • Nourse , A. , Trabi , M. , Daly , N. L. and Craik , D. J. 2004 . A comparison of the self-association behavior of the plant cyclotides kalata B1 and kalata B2 via analytical ultracentrifugation . J. Biol. Chem. , 279 : 562 – 570 .
  • Octavio Luiz , F. 2011 . Peptide promiscuity: An evolutionary concept for plant defense . FEBS Lett. , 585 : 995 – 1000 .
  • Ohtani , S. , Okada , T. , Yoshizumi , H. and Kagamiyama , H. 1977 . Complete primary structures of 2 subunits of purothionin-a, a lethal protein for brewers-yeast from wheat-flour . J. Biochem. , 82 : 753 – 767 .
  • Ono , H. , Tesaki , S. , Tanabe , S. and Watanabe , M. 1998 . 6-methylsulfinylhexyl isothiocyanate and its homologues as food-originated compounds with antibacterial activity against Escherichia coli and Staphylococcus aureus . Biosci Biotechnol Biochem , 62 : 363 – 365 .
  • Otero-Gonzalez , A. J. , Magalhaes , B. S. , Garcia-Villarino , M. , Lopez-Abarrategui , C. , Sousa , D. A. , Dias , S. C. and Franco , O. L. 2010 . Antimicrobial peptides from marine invertebrates as a new frontier for microbial infection control . FASEB J. , 24 : 1320 – 1334 .
  • Padovan , L. , Scocchi , M. and Tossi , A. 2010 . Structural aspects of plant antimicrobial peptides . Curr. Protein Peptide Sci. , 11 : 210 – 219 .
  • Parijs , J. , Broekaert , W. F. , Goldstein , I. J. and Peumans , W. J. 1991 . Hevein: an antifungal protein from rubber-tree (Hevea brasiliensis) latex . Planta. , 183 : 258 – 264 .
  • Park , S. , Gunasekera , S. , Aboye , T. L. and Goransson , U. 2010 . An efficient approach for the total synthesis of cyclotides by microwave assisted Fmoc-SPPS . Int. J. Pept. Res. Ther. , 16 : 167 – 176 .
  • Park , S. C. , Park , Y. and Hahm , K. S. 2011 . The role of antimicrobial peptides in preventing multidrug-resistant bacterial infections and biofilm formation . Int. J. Mol. Sci. , 12 : 5971 – 5992 .
  • Pedras , M. S. C. , Sorensen , J. L. , Okanga , F. I. and Zaharia , I. L. 1999 . Wasalexins A and B, new phytoalexins from wasabi: Isolation, synthesis, and antifungal activity . Bioorg. Med. Chem. Lett. , 9 : 3015 – 3020 .
  • Peschel , A. and Sahl , H. G. 2006 . The co-evolution of host cationic antimicrobial peptides and microbial resistance . Nature Rev. Microbiol. , 4 : 529 – 536 .
  • Pestana-Calsa , M. C. and Tercilio , C. 2011 . “ In silico identification of plant-derived antimicrobial peptides ” . In Systems and Computational Biology - Molecular and Cellular Experimental Systems , Edited by: Yang , N.-S. 249 – 272 . Croatia : InTech, Rejka .
  • Phoenix , D. A. , Dennison , S. R. and Harris , F. 2012 . “ Antimicrobial peptides: their history, evolution and functional promiscuity. pp 1–81 ” . In Antimicrobial Peptides , Edited by: Phoenix , D. A. Germany : Wiley .
  • Phoenix , D. A. and Harris , F. 2002 . The hydrophobic moment and its use in the classification of amphiphilic structures (Review) . Mol. Membr. Biol. , 19 : 1 – 10 .
  • Phoenix , D. A. , Harris , F. , Daman , O. A. and Wallace , J. 2002 . The prediction of amphiphilic alpha-helices . Curr. Protein Peptide Sci. , 3 : 201 – 221 .
  • Pinto , M. F. S. , Fensterseifer , I. C. M. and Franco , O. L. “ Plant cyclotides: An unusual protein family with multiple functions ” . In Plant Defense: Biological Control , Edited by: Merillon , J. M. and Ramawat , K. G. Netherlands : Springer .
  • Plan , M. R. , Goransson , U. , Clark , R. J. , Daly , N. L. , Colgrave , M. L. and Craik , D. J. 2007, 2012 . The cyclotide fingerprint in oldenlandia affinis: elucidation of chemically modified, linear and novel macrocyclic peptides . ChemBioChem. , 8 : 1001 – 1011 .
  • Plan , M. R. , Saska , I. , Cagauan , A. G. and Craik , D. J. 2008 . Backbone cyclised peptides from plants show molluscicidal activity against the rice pest Pomacea canaliculata (golden apple snail) . J. Agric. Food Chem. , 56 : 5237 – 5241 .
  • Ponnuvel , K. M. , Subhasri , N. , Sirigineedi , S. , Murthy , G. N. and Vijayaprakash , N. B. 2010 . Molecular evolution of the cecropin multigene family in silkworm Bombyx mori . Bioinformation , 5 : 97 – 103 .
  • Poth , A. G. , Colgrave , M. L. , Lyons , R. E. , Daly , N. L. and Craik , D. J. 2011 . Discovery of an unusual biosynthetic origin for circular proteins in legumes . Proc. Natl. Acad. Sci. U. S. A. , 108 : 10127 – 10132 .
  • Poth , A. G. , Colgrave , M. L. , Philip , R. , Kerenga , B. , Daly , N. L. , Anderson , M. A. and Craik , D. J. 2010 . Discovery of cyclotides in the Fabaceae plant family provides new insights into the cyclization, evolution, and distribution of circular proteins . ACS Chem. Biol. , 6 : 345 – 355 .
  • Pouny , Y. and Shai , Y. 1992 . Interaction of D-amino-acid incorporated analogs of paradoxin with membranes . Biochemistry. , 31 : 9482 – 9490 .
  • Prabhu , S. Effects of novel compounds in an in vitro chemosensitivity system for glioma treatment. PhD thesis , UK : University of Central Lancashire .
  • Prabhu , S. , Harris , F. , Dennison , S. R. , Radek , I. , Lea , R. and Snape , T. 2011 . “ Joint Symposium on Antimicrobial peptides: Isolation, characterization, modification and applications ” . In Characterisation of an Anionic Anticancer Peptide Isolated from Green Coconut Water , UK-Netherlands : University of Durham, UK .
  • Prades , A. , Dornier , M. , Diop , N. and Pain , J. P. 2012 . Coconut water uses, composition and properties: a review . Fruits , 67 : 87 – 107 .
  • Pranting , M. , Loov , C. , Burman , R. , Goransson , U. and Andersson , D. I. 2010 . The cyclotide cycloviolacin O2 from Viola odorata has potent bactericidal activity against Gram-negative bacteria . J. Antimicrob. Chemother. , 65 : 1964 – 1971 .
  • Rajanbabu , V. and Chen , J. Y. 2011 . Applications of antimicrobial peptides from fish and perspectives for the future . Peptides , 32 : 415 – 420 .
  • Ramanathan , K. and Sethumadhavan , R. 2011 . Identifying therapeutic template by evaluating the structural stability of gram positive anti-bacterial peptides–a computational approach . Interdiscip Sci. , 3 : 182 – 188 .
  • Ribeiro , S. M. , Dias , S. C. and Franco , O. L. “ Plant antimicrobial peptides: From basic structures to applied research ” . In Peptide Drug Discovery and Development , Edited by: Ribeiro , S. M. , Dias , S. C. and Franco , O. L. 139 – 155 . Germany : Wiley .
  • Riedl , S. , Zweytick , D. and Lohner , K. 2011 . Membrane-active host defense peptides - Challenges and perspectives for the development of novel anticancer drugs . Chem. Phys. Lipids , 164 : 766 – 781 .
  • Rivas , L. , Luque-Ortega , J. R. and Andreu , D. 2009 . Amphibian antimicrobial peptides and Protozoa: Lessons from parasites . Biochim. Biophys. Acta. , 1788 : 1570 – 1581 .
  • Rivas , L. , Luque-Ortega , J. R. , Fernandez-Reyes , M. and Andreu , D. 2010 . Membrane-active peptides as anti-infectious agents . J. Appl. Biomed. , 8 : 159 – 167 .
  • Rollins-Smith , L. A. 2009 . The role of amphibian antimicrobial peptides in protection of amphibians from pathogens linked to global amphibian declines . Biochim. Biophys. Acta. , 1788 : 1593 – 1599 .
  • Rusconi , M. and Conti , A. 2010 . Theobroma cacao L., the Food of the Gods: A scientific approach beyond myths and claims . Pharmacol. Res. , 61 : 5 – 13 .
  • Salzet , M. 2005 . Neuropeptide-derived antimicrobial peptides from invertebrates for biomedical applications . Curr. Med. Chem. , 12 : 3055 – 3061 .
  • Sando , L. , Henriques , S. T. , Foley , F. , Simonsen , S. M. , Daly , N. L. , Hall , K. N. , Gustafson , K. R. , Aguilar , M.-I. and Craik , D. J. 2011 . A synthetic mirror image of Kalata B1 reveals that cyclotide activity is independent of a protein receptor . ChemBioChem. , 12 : 2456 – 2462 .
  • Sang , Y. and Blecha , F. 2009 . Porcine host defense peptides: expanding repertoire and functions . Dev. Comp. Immunol. , 33 : 334 – 343 .
  • Santaolalla , R. , Fukata , M. and Abreu , M. T. 2011 . Innate immunity in the small intestine . Curr. Opin. Gastroenterol. , 27 : 125 – 131 .
  • Sarika, Iquebal , M. A. and Rai , A. 2012 . Biotic stress resistance in agriculture through antimicrobial peptides . Peptides. , 36 : 322 – 330 .
  • Sels , J. , Mathys , J. , De Coninck , B. M. A. , Cammue , B. P. A. and De Bolle , M. F. C. 2008 . Plant pathogenesis-related (PR) proteins: A focus on PR peptides . Plant Physiol. Biochem. , 46 : 941 – 950 .
  • Selsted , M. E. , Brown , D. M. , Delange , R. J. , Harwig , S. S. L. and Lehrer , R. I. 1985 . Primary structures of 6 antimicrobial peptides of rabbit peritoneal neutrophils . J. Biol. Chem. , 260 : 4579 – 4584 .
  • Selsted , M. E. , Brown , D. M. , DeLange , R. J. and Lehrer , R. I. 1983 . Primary structures of MCP-1 and MCP-2, natural peptide antibiotics of rabbit lung macrophages . J. Biol. Chem. , 258 : 14485 – 14489 .
  • Sharma , M. 2011 . Plant defensins: Novel antimicrobial peptides . Vegetos. , 24 : 126 – 135 .
  • Shekhar , M. P. V. 2011 . Drug resistance: Challenges to effective therapy . Curr. Cancer Drug Targets , 11 : 613 – 623 .
  • Shenkarev , Z. O. , Nadezhdin , K. D. , Lyukmanova , E. N. , Sobol , V. A. , Skjeldal , L. and Arseniev , A. S. 2008 . Divalent cation coordination and mode of membrane interaction in cyclotides: NMR spatial structure of ternary complex Kalata B7/Mn2+/DPC micelle . J. Inorg. Biochem. , 102 : 1246 – 1256 .
  • Shenkarev , Z. O. , Nadezhdin , K. D. , Sobol , V. A. , Sobol , A. G. , Skjeldal , L. and Arseniev , A. S. 2006 . Conformation and mode of membrane interaction in cyclotides. Spatial structure of kalata B1 bound to a dodecylphosphocoline micelle . FEBS J. , 273 : 2658 – 2672 .
  • Shin , I. S. , Masuda , H. and Naohide , K. 2004 . Bactericidal activity of wasabi (Wasabia japonica) against Helicobacter pylori . Int. J. Food Microbiol. , 94 : 255 – 261 .
  • Shutov , A. D. and Kakhovskaya , I. A. 2011 . Evolution of seed storage globulins and cupin superfamily . Mol. Biol. , 45 : 529 – 535 .
  • Simons , K. and Ikonen , E. 2000 . Cell biology - How cells handle cholesterol . Science. , 290 : 1721 – 1726 .
  • Singh , P. , Singh , R. , Duveiller , E. , Mergoum , M. , Adhikari , T. and Elias , E. 2010 . Genetics of wheat–Pyrenophora tritici-repentis interactions . Euphytica. , 171 : 1 – 13 .
  • Skjeldal , L. , Gran , L. , Sletten , K. and Volkman , B. F. 2002 . Refined structure and metal binding site of the kalata b1 peptide . Arch. Biochem. Biophys. , 399 : 142 – 148 .
  • Slocinska , M. , Marciniak , P. and Rosinski , G. 2008 . Insects antiviral and anticancer peptides: new leads for the future? . Protein Pept. Lett. , 15 : 578 – 585 .
  • Soscia , S. J. , Kirby , J. E. , Washicosky , K. J. , Tucker , S. M. , Ingelsson , M. , Hyman , B. , Burton , M. A. , Goldstein , L. E. , Duong , S. , Tanzi , R. E. and Moir , R. D. 2010 . The Alzheimer's disease-associated amyloid beta-protein is an antimicrobial peptide . PLoS One. , 5
  • Souza , S. M. , Uchôa , A. F. , Silva , J. R. , Samuels , R. I. , Oliveira , A. E. A. , Oliveira , E. M. , Linhares , R. T. , Alexandre , D. and Silva , C. P. 2010 . The fate of vicilins, 7S storage globulins, in larvae and adult Callosobruchus maculatus (Coleoptera: Chrysomelidae: Bruchinae) . J. Insect Physiol. , 56 : 1130 – 1138 .
  • Sperstad , S. V. , Haug , T. , Blencke , H. M. , Styrvold , O. B. , Li , C. and Stensvag , K. 2011 . Antimicrobial peptides from marine invertebrates: Challenges and perspectives in marine antimicrobial peptide discovery . Biotechnol. Adv. , 29 : 519 – 530 .
  • Spoel , S. H. and Dong , X. 2012 . How do plants achieve immunity? Defense without specialized immune cells . Nature Rev. Immunol. , 12 : 89 – 100 .
  • Sprent , J. I. , Odee , D. W. and Dakora , F. D. 2010 . African legumes: a vital but under-utilized resource . J. Exp. Bot. , 61 : 1257 – 1265 .
  • Stec , B. 2006 . Plant thionins - the structural perspective . Cell. Mol. Life Sci. , 63 : 1370 – 1385 .
  • Stefano , G. B. , Salzet , B. and Fricchione , G. L. 1998 . Enkelytin and opioid peptide association in invertebrates and vertebrates: immune activation and pain . Immunol. Today , 19 : 265 – 268 .
  • Steiner , H. , Hultmark , D. , Engstrom , A. , Bennich , H. and Boman , H. G. 1981 . Sequence and specificity of 2 anti-bacterial proteins involved in insect immunity . Nature , 292 : 246 – 248 .
  • Steinstraesser , L. , Kraneburg , U. , Jacobsen , F. and Al-Benna , S. 2011 . Host defense peptides and their antimicrobial-immunomodulatory duality . Immunobiology , 216 : 322 – 333 .
  • Strömstedt , A. A. , Ringstad , L. , Schmidtchen , A. and Malmsten , M. 2010 . Interaction between amphiphilic peptides and phospholipid membranes . Curr. Opin. Colloid Interface Sci. , 15 : 467 – 478 .
  • Svetlana , O. , Jong Hyun , H. , Marc Alan , C. , Rajasekaran , I. K. and Cary , J. W. “ Thionins - nature's weapons of mass protection ” . In Small Wonders: Peptides for Disease Control , Edited by: Jaynes , J. M. and Montesinos , E. 415 – 443 . Washington : American Chemical Society .
  • Tacar , O. , Sriamornsak , P. and Dass , C. R. 2012 . Doxorubicin: an update on anticancer molecular action, toxicity and novel drug delivery systems . J. Pharm. Pharmacol. , 65 : 157 – 170 .
  • Tang , J. and Tan , N. H. 2010 . Progress of cyclotides in plants . Prog. Chemistry , 22 : 677 – 683 .
  • Tavares , L. S. , Santos Mde , O. , Viccini , L. F. , Moreira , J. S. , Miller , R. N. and Franco , O. L. 2008 . Biotechnological potential of antimicrobial peptides from flowers . Peptides , 29 : 1842 – 1851 .
  • Teixeira , F. R. , Lima , M. C. O. P. , Almeida , H. O. , Romeiro , R. S. , Silva , D. J. H. , Pereira , P. R. G. , Fontes , E. P. B. and Baracat-Pereira , M. C. 2006 . Bioprospection of cationic and anionic antimicrobial peptides from bell pepper leaves for inhibition of Ralstonia solanacearum and Clavibacter michiganensis ssp michiganensis growth . J. Phytopathol. , 154 : 418 – 421 .
  • Theis , T. and Stahl , U. 2004 . Antifungal proteins: targets, mechanisms and prospective applications . Cell. Mol. Life Sci. , 61 : 437 – 455 .
  • Uchoa , A. F. , Alcantara de Miranda , M. R. , de Souza , A. J. , Gomes , V. M. , Sales Fernandes , K. V. , Alves Lemos , F. J. , Amancio Oliveira , A. E. and Xavier-Filho , J. 2009 . Toxicity of hydrolyzed vicilins toward Callosobruchus maculatus and phytopathogenic fungi . J. Agric. Food Chem. , 57 : 8056 – 8061 .
  • Uvell , H. and Engstrom , Y. 2007 . A multilayered defense against infection: combinatorial control of insect immune genes . Trends Genet. , 23 : 342 – 349 .
  • Van Dijk , A. , Molhoek , E. M. , Bikker , F. J. , Yu , P. L. , Veldhuizen , E. J. A. and Haagsman , H. P. 2011 . Avian cathelicidins: Paradigms for the development of anti-infectives . Vet. Microbiol. , 153 : 27 – 36 .
  • Van Loon , L. C. , Rep , M. and Pieterse , C. M. J. 2006 . Significance of inducible defense-related proteins in infected plants . Annu. Rev. Phytopathol. , 44 : 135 – 162 .
  • Van Loon , L. C. and Van Strien , E. A. 1999 . The families of pathogenesis-related proteins, their activities, and comparative analysis of PR-1 type proteins . Physiol. Mol. Plant Pathol. , 55 : 85 – 97 .
  • Vazquez , J. A. 2010 . Management of oropharyngeal and esophageal candidiasis in patients with HIV infection . HIV Ther. , 4 : 325 – 341 .
  • Wang , C. K. , Colgrave , M. L. , Gustafson , K. R. , Ireland , D. C. , Goransson , U. and Craik , D. J. 2008a . Anti-HIV cyclotides from the Chinese medicinal herb Viola yedoensis . J. Nat. Prod. , 71 : 47 – 52 .
  • Wang , C. K. , Colgrave , M. L. , Ireland , D. C. , Kaas , Q. and Craik , D. J. 2009a . Despite a conserved cystine knot motif, different cyclotides have different membrane binding modes . Biophys. J. , 97 : 1471 – 1481 .
  • Wang , C. K. L. , Clark , R. J. , Harvey , P. J. , Johan Rosengren , K. , Cemazar , M. and Craik , D. J. 2011 . The role of conserved Glu residue on cyclotide stability and activity: A structural and functional study of Kalata B12, a naturally occurring Glu to Asp mutant . Biochemistry , 50 : 4077 – 4086 .
  • Wang , C. K. L. , Kaas , Q. , Chiche , L. and Craik , D. J. 2008b . CyBase: a database of cyclic protein sequences and structures, with applications in protein discovery and engineering . Nucleic Acids Res. , 36 : D206 – D210 .
  • Wang , G. , Li , X. and Wang , Z. 2009b . APD2: the updated antimicrobial peptide database and its application in peptide design . Nucleic Acids Res. , 37 : D933 – D937 .
  • Wang , G. , Li , X. and Zasloff , M. 2010 . “ A database view of naturally occurring antimicrobial peptides: Nomenclature, Classification and amino acid sequence analysis ” . In Antimicrobial Peptides: Discovery, Design and Novel Therapeutic Strategies , Edited by: Wang , G. Vol. 121 , Oxford , , UK : CAB Int. .
  • Williams , D. and Lewis , M. 2011 . Pathogenesis and treatment of oral candidosis . J. Oral Microbiol. , 3 doi: 10.3402/jom.v3:0.5771
  • Williamson , B. , Tudzynsk , B. , Tudzynski , P. and Van Kan , J. A. L. 2007 . Botrytis cinerea: the cause of grey mould disease . Mol. Plant Pathol. , 8 : 561 – 580 .
  • Wimley , W. C. 2010 . Describing the mechanism of antimicrobial peptide action with the interfacial activity model . ACS Chem. Biol. , 5 : 905 – 917 .
  • Wimley , W. C. and Hristova , K. 2011 . Antimicrobial peptides: Successes, challenges and unanswered questions . J. Membr. Biol. , 239 : 27 – 34 .
  • Yamada , K. , Lim , J. , Dale , J. M. , Chen , H. , Shinn , P. , Palm , C. J. , Southwick , A. M. , Wu , H. C. , Kim , C. , Nguyen , M. , Pham , P. , Cheuk , R. , Karlin-Newmann , G. , Liu , S. X. , Lam , B. , Sakano , H. , Wu , T. , Yu , G. , Miranda , M. , Quach , H. L. , Tripp , M. , Chang , C. H. , Lee , J. M. , Toriumi , M. , Chan , M. M. , Tang , C. C. , Onodera , C. S. , Deng , J. M. , Akiyama , K. , Ansari , Y. , Arakawa , T. , Banh , J. , Banno , F. , Bowser , L. , Brooks , S. , Carninci , P. , Chao , Q. , Choy , N. , Enju , A. , Goldsmith , A. D. , Gurjal , M. , Hansen , N. F. , Hayashizaki , Y. , Johnson-Hopson , C. , Hsuan , V. W. , Iida , K. , Karnes , M. , Khan , S. , Koesema , E. , Ishida , J. , Jiang , P. X. , Jones , T. , Kawai , J. , Kamiya , A. , Meyers , C. , Nakajima , M. , Narusaka , M. , Seki , M. , Sakurai , T. , Satou , M. , Tamse , R. , Vaysberg , M. , Wallender , E. K. , Wong , C. , Yamamura , Y. , Yuan , S. , Shinozaki , K. , Davis , R. W. , Theologis , A. and Ecker , J. R. 2003 . Empirical analysis of transcriptional activity in the Arabidopsis genome . Science , 302 : 842 – 846 .
  • Yeshak , M. Y. , Burman , R. , Asres , K. and Goransson , U. 2011 . Cyclotides from an extreme habitat: Characterization of cyclic peptides from Viola abyssinica of the Ethiopian Highlands . J. Nat. Prod. , 74 : 727 – 731 .
  • Yeung , A. T. Y. , Gellatly , S. L. and Hancock , R. E. W. 2011 . Multifunctional cationic host defense peptides and their clinical applications . Cell. Mol. Life Sci. , 68 : 2161 – 2176 .
  • Zasloff , M. 1987 . Magainins, a class of antimicrobial peptides from xenopus skin - isolation, characterization of 2 active forms, and partial cdna sequence of a precursor . Proc. Natl. Acad. Sci. USA. , 84 : 5449 – 5453 .
  • Zasloff , M. 2002 . Antimicrobial peptides of multicellular organisms . Nature , 415 : 389 – 395 .
  • Zhang , L. J. and Falla , T. J. 2010 . “ Potential therapeutic application of host defense peptides ” . In Antimicrobial Peptides: Methods and Protocols , Edited by: Giuliani , A. and Rinaldi , A. C. 303 – 327 . Totowa , NJ. : Humana Press .

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.