Summary
Functionalized polyhedral carboranes, including amino acid analogs, have unique physicochemical properties and are used as experimental anticancer agents. However, our current knowledge on their effect in nonmammalian biological systems is limited. We investigated the activity spectrumin vitro ofo-carboranylalanine (o-Cba), considered to be a highly lipophilic analog of phenylalanine, against representative plant pathogenic bacteria and fungi of various taxonomic position. The antibacterial effect ofo-Cba against some species was comparable to that of the widely used agricultural antibiotic, streptomycin. The sensitivity of individual bacterial species too-Cba within the same genus varied to a greater extent than the average sensitivity of various genera. In general, this carborane-containing amino acid was more toxic to Gram positive bacteria (Bacillus, Corynebacterium, Curtobacterium, Micrococcus, Rhodococcus, and Staphylococcus) than to Gram negative ones (Agrobacterium, Erwinia, Escherichia, Pseudomonas, Rhizobium, and Xanthomonas). Compared to the commercial fungicide, prochloraz,o-Cba was weakly toxic against various fungi (Zygo- and Ascomycota). It was also inferior to the commercial fungicide metalaxyl in inhibiting the vegetative growth of oomyceteous plant pathogens (Pythium irregulare, Phytophthora cryptogea and Plasmopara halstedii). Against the asexual spores of P. halstedii,o-Cba, however, was over a thousandfold more active than tridemorph, a selective zoospore inhibitor fungicide. For all taxonomic groups, the observed antimicrobial effect ofo-Cba could be diminished with histidine, but not with phenylalanine. In studies on healthy and mildew-infected sunflower and tobacco plantso-Cba showed neither fungicidal nor phytotoxic effects at 500ppm. This is the first report on the biological activity spectrum of a carborane-containing amino acid.
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References
Barth RF, Soloway AH, Fairchild RG (1990) Boron neutron therapy of cancer. Cancer Res 50: 1061–1070
Brattsev VA, Stanko VI (1969) ß-(o-Barenyl) alanine. Zh Obshch Khim 39:1175-1176 (in Russian)
Couture R, Drouin J-N, Leukart O, Regoli D (1979) Biological activity of kinins and substance P octapeptides (4–11) in which phenylalanine residues have been replaced with {spl-carboranylalanine}. Can J Physiol Pharmacol 57: 1437–1442
Denisenko PP, Lebedeva DP, Gridina VF, Zavgorodnyaya TI (1978) Toxicity of some metacarboranes used for the synthesis of some heat-resistant polymers. Gig Tr Prof Zabol 42–43 (in Russian)
Eberle A, Leukart O, Schiller P, Fauchere JL, Schwyzer R (1977) Hormone-receptor interactions: [4-carboranylalanine, 5-leucine]-enkephalin as a structural probe for the opiate receptor. FEBS Lett 82: 325–328
Escher E, Guillemette G, Leukart O, Regoli D (1980) Pharmacological properties of two analogues of angiotensin 11 containing carboranylalanine (Car). Eur J Pharmacol 66: 267–272
Fauchère JL, Do KQ, Jow PYC, Hansch C (1980) Unusually strong lipophilicity of ‘fat’ or ‘super’ amino acids, including a new reference value for glycine. Experientia 36: 1203–1204
Fischli W, Leukart O, Schwyzer R (1977) Hormone-receptor interactions. Carboranylalanine (Car) as a phenylalanine analogue: reactions with chymotrypsin. Helv Chim Acta 60: 959–963
Grimes RN (1970) Carboranes. Academic Press Inc., New York
Hawthorne MF (1993) The role of chemistry in the development of boron neutron capture therapy of cancer. Angew Chem Int Ed Engl 32: 950–984
Kahl SB, Radel PA (1994) Recent developments in tumor-selective targeting of boron for neutron capture therapy: carboranylalanine. In: Kabalka GW (ed) Current topics in the chemistry of boron. Royal Society of Chemistry, Cambridge UK, pp 155–160
Karnbrock W, Musiol H-J, Moroder L (1995) Enantioselective synthesis ofS-o-carboranylalanine via methylated bislactim ethers of 2,5-diketopiperazines. Tetrahedron 51: 1187–1196
Leukart O, Caviezel M, Eberle A, Escher E, Tun-Kyi A, Schwyzer R (1976) L-o-Carboranylalanine, a boron analogue of phenylalanine. Helv Chim Acta 59: 2184–2187
Malmquist J, Sjöberg S (1996) Asymmetric synthesis ofp-carboranylalanine (p-Car) and 2-methyl-o-carboranylalanine (Me-o-Car). Tetrahedron 52: 9207–9218
Nachman RJ, Teal PEA, Radel PA, Holman GM, Abernathy RL (1996) Potent pheromonotropic/myotropic activity of a carboranyl pseudotetrapeptide analogue of the insect pyrokinin/PBAN neuropteptide family administered via injection or topical application. Peptides 17: 747–752
O'Donnel MJ, Eckrich TM (1978) The synthesis of amino acid derivatives by catalytic phase-transfer alkylation.Tetrahedron Lett 4625–4628
Oros G, Érsek T, Virányi F (1988) Effect of tridemorph onPhytophthora infestans andPlasmopara halstedii. Acta Phytopathol Entomol Hung 23: 11–19
Oros G, Virányi F (1987) Glasshouse evaluation of fungicides for the control of sunflower downy mildew (Plasmopara halstedii). Ann Appl Biol 110: 53–63
Oros G, Kőmíves T (1991) Effects of phenylamide pesticides on the GSH-conjugation system of Phytophthora spp. fungi. Z Naturforsch 46c: 866–874
Oros G, Cserháti T, Szejtli J (1989) Cyclodextrins decrease the phytotoxicity of nonionic tensides. Acta Agron Hung 38: 211–217
Pillimor JB (1989) Amino acid biosynthesis: an Aladdin's cave of new pesticides? In: Copping LG, Dalziel J, Dodge AD (eds) Prospects for amino acid biosynthesis inhibitors in crop protection and pharmaceutical chemistry. BCPC Monographs No. 2. British Crop Protection Council, Farnham, UK, pp 23-31
Radel PA, Kahl SB (1996) Enantioselective synthesis of {spl- and {spd}-carboranylalanine}. J Org Chem 61: 4582–4588
Soloway AH, Tjarks W, Barnum BA, Rong F-G, Barth RF, Codogni IM, Wilson G (1998) The chemistry of neutron capture therapy. Chem Rev 98: 1515–1562
Sváb J (1981) Biometrics Mezőgazdasági Kiadó, Budapest
Totani T, Aono K, Yamamoto K, Tawara K (1981) Synthesis andin vitro antimicrobial property of o-carborane derivatives. J Med Chem 24: 1492–1499
Valerino DM, Soliman MRI, Aurori KC, Tripp SL, Wykes AA, Vesell ES (1974) Interaction of several boron hydrides with liver microsomal enzymes. Toxicol Appl Pharmacol 29: 358–366
Virányi F, Oros G (1991) Developmental stage response to fungicides ofPlasmopara halstedii (sunflower downy mildew). Mycol Res 98: 199–205
Wallsgrove RM (1989) The biosynthesis of amino acids in plants. In: Copping LG, Dalziel J and Dodge AD (eds) Prospects for amino acid biosynthesis inhibitors in crop protection and pharmaceutical chemistry. BCPC Monographs No. 2. British Crop Protection Council, Farnham, UK, pp 8–18
Wyzlic IM, Tjarks W, Soloway AH, Perkins DJ, Burgos M, O'Reilly KP (1996) Synthesis of carboranyl amino acids, hydantoins, and barbiturates. Inorg Chem 35: 4541–4547
Yong J-H, Barth RF, Rotaru JH, Wyzlic IM, Soloway AH (1995) Evaluation ofin vitro cytotoxicity of carboranyl amino acids, their chemical precursors andnido carboranyl amino acids for boron neutron capture therapy. Anticancer Res 15: 2039–2044
Zakharkin LI, Grebennikov AV, Lvov AI (1970) Synthesis of some nitrogen-containing carborane derivatives. Izv Akad Nauk SSSR, Ser Khim 106–112
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Oros, G., Ujváry, I. & Nachman, R.J. Antimicrobial activity ofo-carboranylalanine. Amino Acids 17, 357–368 (1999). https://doi.org/10.1007/BF01361661
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DOI: https://doi.org/10.1007/BF01361661