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Biotechnol., 101, pp. 2691-2711", "listPosition" : 18, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696519, "link" : "/api/reference/23696519", "label" : "19. Katsoulas, N., Current use of copper, mineral oils and sulphur for plant protection in organic horticultural crops across 10 European countries (2020) Org. Agric., 10, pp. 159-171", "listPosition" : 19, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696516, "link" : "/api/reference/23696516", "label" : "20. Taning, C.N.T., Does RNAi-based technology fit within EU sustainability goals? (2021) Trends Biotechnol., 39, pp. 644-647", "listPosition" : 20, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696512, "link" : "/api/reference/23696512", "label" : "21. Fones, H.N., Threats to global food security from emerging fungal and oomycete crop pathogens (2020) Nat. Food, 1, pp. 332-342", "listPosition" : 21, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696511, "link" : "/api/reference/23696511", "label" : "22. Steinberg, G., Gurr, S.J., Fungi, fungicide discovery and global food security (2020) Fungal Genet. Biol., 144", "listPosition" : 22, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696614, "link" : "/api/reference/23696614", "label" : "23. Klinter, S., Diversity and evolution of chitin synthases in oomycetes (Straminipila: Oomycota) (2019) Mol. Phylogenet. Evol., 139", "listPosition" : 23, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696582, "link" : "/api/reference/23696582", "label" : "24. Tavares, L.S., Antimicrobial activity of recombinant Pg-AMP1, a glycine-rich peptide from guava seeds (2012) Peptides, 37, pp. 294-300", "listPosition" : 24, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696622, "link" : "/api/reference/23696622", "label" : "25. Soulie, M.C., Botrytis cinerea virulence is drastically reduced after disruption of chitin synthase class III gene (Bcchs3a) (2006) Cell. Microbiol., 8, pp. 1310-1321", "listPosition" : 25, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696621, "link" : "/api/reference/23696621", "label" : "26. Kong, L.A., Different chitin synthase genes are required for various developmental and plant infection processes in the rice blast fungus Magnaporthe oryzae (2012) PLoS Pathog., 8", "listPosition" : 26, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696620, "link" : "/api/reference/23696620", "label" : "27. Grenville-Briggs, L.J., Cellulose synthesis in Phytophthora infestans is required for normal appressorium formation and successful infection of potato (2008) Plant Cell, 20, pp. 720-738", "listPosition" : 27, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696619, "link" : "/api/reference/23696619", "label" : "28. Denning, D.W., Echinocandin antifungal drugs (2003) Lancet, 362, pp. 1142-1151", "listPosition" : 28, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696618, "link" : "/api/reference/23696618", "label" : "29. Latgé, J.P., The cell wall: a carbohydrate armour for the fungal cell (2007) Mol. Microbiol., 66, pp. 279-290", "listPosition" : 29, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696617, "link" : "/api/reference/23696617", "label" : "30. Geoghegan, I., The role of the fungal cell wall in the infection of plants (2017) Trends Microbiol., 25, pp. 957-967", "listPosition" : 30, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696616, "link" : "/api/reference/23696616", "label" : "31. Samalova, M., The β-1,3-glucanosyltransferases (Gels) affect the structure of the rice blast fungal cell wall during appressorium-mediated plant infection (2017) Cell. Microbiol., 19", "listPosition" : 31, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696615, "link" : "/api/reference/23696615", "label" : "32. Guerriero, G., Chitin synthases from Saprolegnia are involved in tip growth and represent a potential target for anti-oomycete drugs (2010) PLoS Pathog., 6", "listPosition" : 32, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696613, "link" : "/api/reference/23696613", "label" : "33. Hinkel, L., Ospina-Giraldo, M.D., Structural characterization of a putative chitin synthase gene in Phytophthora spp. and analysis of its transcriptional activity during pathogenesis on potato and soybean plants (2017) Curr. Genet., 63, pp. 909-921", "listPosition" : 33, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696612, "link" : "/api/reference/23696612", "label" : "34. Mélida, H., Analyses of extracellular carbohydrates in oomycetes unveil the existence of three different cell wall types (2013) Eukaryot. Cell, 12, pp. 194-203", "listPosition" : 34, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696611, "link" : "/api/reference/23696611", "label" : "35. Free, S.J., Fungal cell wall organization and biosynthesis (2013) Adv. Genet., 81, pp. 33-82", "listPosition" : 35, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696610, "link" : "/api/reference/23696610", "label" : "36. Bowman, S.M., Free, S.J., The structure and synthesis of the fungal cell wall (2006) Bioessays, 28, pp. 799-808", "listPosition" : 36, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696609, "link" : "/api/reference/23696609", "label" : "37. Smith, G.P., Petrenko, V.A., Phage display (1997) Chem. Rev., 97, pp. 391-410", "listPosition" : 37, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696608, "link" : "/api/reference/23696608", "label" : "38. Joung, J.K., A bacterial two-hybrid selection system for studying protein–DNA and protein–protein interactions (2000) Proc. Natl. Acad. Sci., 97, pp. 7382-7387", "listPosition" : 38, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696607, "link" : "/api/reference/23696607", "label" : "39. Hoppe-Seyler, F., Peptide aptamers: specific inhibitors of protein function (2004) Curr. Mol. Med., 4, pp. 529-538", "listPosition" : 39, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696606, "link" : "/api/reference/23696606", "label" : "40. Mehla, J., A comparison of two-hybrid approaches for detecting protein–protein interactions (2017) Methods Enzymol., 586, pp. 333-358", "listPosition" : 40, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696605, "link" : "/api/reference/23696605", "label" : "41. Colombo, M., Peptide aptamers: the versatile role of specific protein function inhibitors in plant biotechnology (2015) J. Integr. Plant Biol., 57, pp. 892-901", "listPosition" : 41, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696604, "link" : "/api/reference/23696604", "label" : "42. Yin, C., Silencing Dicer-like genes reduces virulence and sRNA generation in Penicillium italicum, the cause of citrus blue mold (2020) Cells, 9, p. 363", "listPosition" : 42, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696603, "link" : "/api/reference/23696603", "label" : "43. Forster, H., Shuai, B., Exogenous siRNAs against chitin synthase gene suppress the growth of the pathogenic fungus Macrophomina phaseolina (2020) Mycologia, 112, pp. 699-710", "listPosition" : 43, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696602, "link" : "/api/reference/23696602", "label" : "44. Koch, A., An RNAi-based control of Fusarium graminearum infections through spraying of long dsRNAs involves a plant passage and is controlled by the fungal silencing machinery (2016) PLoS Pathog., 12", "listPosition" : 44, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696601, "link" : "/api/reference/23696601", "label" : "45. Sundaresha, S., Spraying of dsRNA molecules derived from Phytophthora infestans, as a plant protection strategies for the management of potato late blight (2021) Preprints, , Published online February 11, 2021", "listPosition" : 45, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696600, "link" : "/api/reference/23696600", "label" : "46. Brand, G.D., Dermaseptins from Phyllomedusa oreades and Phyllomedusa distincta: anti-Trypanosoma cruzi activity without cytotoxicity to mammalian cells (2002) J. Biol. Chem., 277, pp. 49332-49340", "listPosition" : 46, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696599, "link" : "/api/reference/23696599", "label" : "47. Tóth, L., Biofungicidal potential of Neosartorya (Aspergillus) fischeri antifungal protein NFAP and novel synthetic γ-core peptides (2020) Front. Microbiol., 11, p. 820", "listPosition" : 47, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696598, "link" : "/api/reference/23696598", "label" : "48. Sagehashi, Y., Partial peptides from rice defensin OsAFP1 exhibited antifungal activity against the rice blast pathogen Pyricularia oryzae (2017) J. Pestic. Sci., 42, pp. 172-175", "listPosition" : 48, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696597, "link" : "/api/reference/23696597", "label" : "49. Gourgues, M., The tetraspanin BcPls1 is required for appressorium-mediated penetration of Botrytis cinerea into host plant leaves (2003) Mol. Microbiol., 51, pp. 619-629", "listPosition" : 49, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696596, "link" : "/api/reference/23696596", "label" : "50. Feliziani, E., Romanazzi, G., Postharvest decay of strawberry fruit: Etiology, epidemiology, and disease management (2016) J. Berry Res., 6, pp. 47-63", "listPosition" : 50, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696595, "link" : "/api/reference/23696595", "label" : "51. Schumann, G.L., D'Arcy, C.J., Late blight of potato and tomato (2000) Plant Health Instr., , Published online January 1, 2020", "listPosition" : 51, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696594, "link" : "/api/reference/23696594", "label" : "52. Luciano-Rosario, D., Penicillium expansum: biology, omics, and management tools for a global postharvest pathogen causing blue mould of pome fruit (2020) Mol. Plant Pathol., 21, pp. 1391-1404", "listPosition" : 52, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696593, "link" : "/api/reference/23696593", "label" : "53. Nalley, L., Economic and environmental impact of rice blast pathogen (Magnaporthe oryzae) alleviation in the United States (2016) PLoS One, 11", "listPosition" : 53, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696592, "link" : "/api/reference/23696592", "label" : "54. Wilson, W.W., Economic impact of USWBSI's Scab initiative to reduce FHB (2017) Agribus. Appl. Econ., 774, pp. 1-149", "listPosition" : 54, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696591, "link" : "/api/reference/23696591", "label" : "55. Marburger, D.A., Impact of Fusarium graminearum on early-season soybean growth and seed yield under field conditions (2017) Can. J. Plant Pathol., 39, pp. 464-474", "listPosition" : 55, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696590, "link" : "/api/reference/23696590", "label" : "56. Buonassisi, D., Breeding for grapevine downy mildew resistance: a review of 'omics' approaches (2017) Euphytica, 213, p. 103", "listPosition" : 56, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696589, "link" : "/api/reference/23696589", "label" : "57. Bosland, P.W., Think global, breed local: specificity and complexity of Phytophthora capsici (2008) Proceedings of the 19th International Pepper Conference, , International Pepper Community Atlantic City, NJ", "listPosition" : 57, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696588, "link" : "/api/reference/23696588", "label" : "58. Dean, R., The Top 10 fungal pathogens in molecular plant pathology (2012) Mol. Plant Pathol., 13, pp. 414-430", "listPosition" : 58, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696587, "link" : "/api/reference/23696587", "label" : "59. 'late blight': the persistent disease (2020) Phytoparasitica, 48, pp. 87-94", "listPosition" : 59, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696586, "link" : "/api/reference/23696586", "label" : "60. Fry, W.E., Phytophthora infestans: the itinerant invader", "listPosition" : 60, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696585, "link" : "/api/reference/23696585", "label" : "61. Arpaia, S., Biosafety of GM crop plants expressing dsRNA: data requirements and EU regulatory considerations (2020) Front. Plant Sci., 11, p. 940", "listPosition" : 61, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696584, "link" : "/api/reference/23696584", "label" : "62. Gentilucci, L., Chemical modifications designed to improve peptide stability: incorporation of non-natural amino acids, pseudo-peptide bonds, and cyclization (2010) Curr. Pharm. Des., 16, pp. 3185-3203", "listPosition" : 62, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696583, "link" : "/api/reference/23696583", "label" : "63. Gaglione, R., Cost-effective production of recombinant peptides in Escherichia coli (2019) New Biotechnol., 51, pp. 39-48", "listPosition" : 63, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696581, "link" : "/api/reference/23696581", "label" : "64. Nieto-Taype, M.A., Continuous cultivation as a tool toward the rational bioprocess development with Pichia pastoris cell factory (2020) Front. Bioeng. Biotechnol., 8, p. 632", "listPosition" : 64, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696580, "link" : "/api/reference/23696580", "label" : "65. De, S., Established tools and emerging trends for the production of recombinant proteins and metabolites in Pichia pastoris (2021) Essays Biochem., 65, pp. 293-307", "listPosition" : 65, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696579, "link" : "/api/reference/23696579", "label" : "66. Duman-Scheel, M., Saccharomyces cerevisiae (baker's yeast) as an interfering RNA expression and delivery system (2019) Curr. Drug Targets, 20, pp. 942-952", "listPosition" : 66, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696578, "link" : "/api/reference/23696578", "label" : "67. Schwinges, P., A bifunctional dermaseptin-thanatin dipeptide functionalizes the crop surface for sustainable pest management (2019) Green Chem., 21, pp. 2316-2325", "listPosition" : 67, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696577, "link" : "/api/reference/23696577", "label" : "68. Terada, K., Artificial cell-penetrating peptide containing periodic α-aminoisobutyric acid with long-term internalization efficiency in human and plant cells (2020) ACS Biomater. Sci. Eng., 6, pp. 3287-3298", "listPosition" : 68, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696576, "link" : "/api/reference/23696576", "label" : "69. Gillet, F.X., Investigating engineered ribonucleoprotein particles to improve oral RNAi delivery in crop insect pests (2017) Front. Physiol., 8, p. 256", "listPosition" : 69, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696575, "link" : "/api/reference/23696575", "label" : "70. Yoshizumi, T., Selective gene delivery for integrating exogenous DNA into plastid and mitochondrial genomes using peptide–DNA complexes (2018) Biomacromolecules, 19, pp. 1582-1591", "listPosition" : 70, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696574, "link" : "/api/reference/23696574", "label" : "71. Thagun, C., Simultaneous introduction of multiple biomacromolecules into plant cells using a cell-penetrating peptide nanocarrier (2020) Nanoscale, 12, pp. 18844-18856", "listPosition" : 71, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696573, "link" : "/api/reference/23696573", "label" : "72. Mitter, N., Clay nanosheets for topical delivery of RNAi for sustained protection against plant viruses (2017) Nat. Plants, 3, p. 16207", "listPosition" : 72, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696572, "link" : "/api/reference/23696572", "label" : "73. Fischer, J., Targeted drug delivery in plants: enzyme-responsive lignin nanocarriers for the curative treatment of the worldwide grapevine trunk disease Esca (2019) Adv. Sci., 6", "listPosition" : 73, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696571, "link" : "/api/reference/23696571", "label" : "74. Gebremichael, D.E., RNA interference strategies for future management of plant pathogenic fungi: prospects and challenges (2021) Plants, 10, p. 650", "listPosition" : 74, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696570, "link" : "/api/reference/23696570", "label" : "75. Mezzetti, B., RNAi: what is its position in agriculture? (2020) J. Pest. Sci., 93, pp. 1125-1130", "listPosition" : 75, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696569, "link" : "/api/reference/23696569", "label" : "76. Wang, M., Jin, H., Spray-induced gene silencing: a powerful innovative strategy for crop protection (2017) Trends Microbiol., 25, pp. 4-6", "listPosition" : 76, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696568, "link" : "/api/reference/23696568", "label" : "77. Khajuria, C., Development and characterization of the first dsRNA-resistant insect population from western corn rootworm, Diabrotica virgifera virgifera LeConte (2018) PLoS One, 13", "listPosition" : 77, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696567, "link" : "/api/reference/23696567", "label" : "78. Koch, A., Kogel, K.H., New wind in the sails: improving the agronomic value of crop plants through RNAi-mediated gene silencing (2014) Plant Biotechnol. J., 12, pp. 821-831", "listPosition" : 78, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696566, "link" : "/api/reference/23696566", "label" : "79. Capriotti, L., Biotechnological approaches: gene overexpression, gene silencing, and genome editing to control fungal and oomycete diseases in grapevine (2020) Int. J. Mol. Sci., 21, p. 5701", "listPosition" : 79, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696565, "link" : "/api/reference/23696565", "label" : "80. Song, Y., Thomma, B.P.H.J., Host-induced gene silencing compromises Verticillium wilt in tomato and Arabidopsis (2018) Mol. Plant Pathol., 19, pp. 77-89", "listPosition" : 80, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696564, "link" : "/api/reference/23696564", "label" : "81. Cai, Q., Small RNAs and extracellular vesicles: New mechanisms of cross-species communication and innovative tools for disease control (2019) PLoS Pathog., 15", "listPosition" : 81, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696563, "link" : "/api/reference/23696563", "label" : "82. Niu, L., Enhanced tolerance to Phytophthora root and stem rot by over-expression of the plant antimicrobial peptide CaAMP1 gene in soybean (2020) BMC Genet., 21, pp. 1-10", "listPosition" : 82, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696562, "link" : "/api/reference/23696562", "label" : "83. Das, K., Expression of antimicrobial peptide snakin-1 confers effective protection in rice against sheath blight pathogen, Rhizoctonia solani (2021) Plant Biotechnol. Rep., 15, pp. 39-54", "listPosition" : 83, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696561, "link" : "/api/reference/23696561", "label" : "84. Uslu, V.V., High-pressure-sprayed double stranded RNA does not induce RNA interference of a reporter gene (2020) Front. Plant Sci., 11", "listPosition" : 84, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696560, "link" : "/api/reference/23696560", "label" : "85. Zeng, Cross-kingdom Small RNAs among animals, plants and microbes (2019) Cells, 8, p. 371", "listPosition" : 85, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696559, "link" : "/api/reference/23696559", "label" : "86. Weiberg, A., Fungal small RNAs suppress plant immunity by hijacking host RNA interference pathways (2013) Science, 342, pp. 118-123", "listPosition" : 86, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696558, "link" : "/api/reference/23696558", "label" : "87. Huang, C.Y., Small RNAs – big players in Plant–microbe interactions (2019) Cell Host Microbe, 26, pp. 173-182", "listPosition" : 87, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696557, "link" : "/api/reference/23696557", "label" : "88. Cai, Q., Cross-kingdom RNA trafficking and environmental RNAi – nature's blueprint for modern crop protection strategies (2018) Curr. Opin. Microbiol., 46, pp. 58-64", "listPosition" : 88, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696556, "link" : "/api/reference/23696556", "label" : "89. Zhao, P., Antimicrobial peptaibols, trichokonins, inhibit mycelial growth and sporulation and induce cell apoptosis in the pathogenic fungus Botrytis cinerea (2018) Appl. Biochem. Microbiol., 54, pp. 396-403", "listPosition" : 89, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696555, "link" : "/api/reference/23696555", "label" : "90. Shi, M., Antimicrobial peptaibols from Trichoderma pseudokoningii induce programmed cell death in plant fungal pathogens (2012) Microbiology, 158, pp. 166-175", "listPosition" : 90, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696554, "link" : "/api/reference/23696554", "label" : "91. Afanasyeva, E.F., Peptide antibiotic trichogin in model membranes: self-association and capture of fatty acids (2019) Biochimica et Biophysica Acta (BBA)-Biomembranes, 1861, pp. 524-531", "listPosition" : 91, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696553, "link" : "/api/reference/23696553", "label" : "92. Milov, A.D., Review conformation, self-aggregation, and membrane interaction of peptaibols as studied by pulsed electron double resonance spectroscopy (2016) Pept. Sci., 106, pp. 6-24", "listPosition" : 92, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696552, "link" : "/api/reference/23696552", "label" : "93. Stoppacher, N., The comprehensive peptaibiotics database (2013) Chem. Biodivers., 10, pp. 734-743", "listPosition" : 93, "published" : false, "snippet" : true }, { "otype" : "Reference", "mtid" : 23696549, "link" : "/api/reference/23696549", "label" : "94. 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