Abstract
Zeylasteral and demethylzeylasteral are 6-oxophenolic triterpenoids isolated from
the root of Maytenus blepharodes, which have antimicrobial activity against Gram-positive bacteria and the yeast Candida albicans. The time-kill curves for zeylasteral and demethylzeylasteral at concentrations twice
their MICs, against Bacillus subtilis showed that the colony forming units were reduced in 3-log10 and > 4-log10 respectively. This reduction was dependent on inoculum size and the growth phase
of cells, and was greater when the compounds were incorporated in the exponential
phase, indicating a bacteriolytic effect. Treatment with both agents, particularly
with zeylasteral (20 μg/mL) caused a reduction of optical density at 550 nm. With
regard to the synthesis of DNA, RNA, protein and cell wall, the compounds exhibited
the fastest inhibition against cell wall synthesis. Thus, the predisposition to lysis,
the morphological changes seen by microscopy, and the complete inhibition in the incorporation
the N-acetyl-D-[1 - 14
C]glucosamine, suggest that the phenolic compounds compromise the cell wall synthesis
and/or cytoplasmic membrane.
Key words
6-Oxophenolic triterpenoids -
Maytenus blepharodes
- Celastraceae - antibacterial activity -
Bacillus subtilis
- mode of action - macromolecular synthesis - cell wall
References
- 1 González A G, Bazzocchi I L, Moujir L M, Jiménez I A. Ethnobotanical uses of Celastraceae.
Bioactive Metabolites. In: Atta-Ur-Rahman, editor
Studies in natural products chemistry, bioactive natural products (Part D). Elsevier Science Publisher Amsterdam; 2000: pp 649-738
- 2 Muñoz O, Peñaloza A, González A G, Ravelo A G, Crespo A, Bazzocchi I L, Alvarenga N L.
Celastraceae, Bioactive Metabolites. In: Atta-Ur-Rahman, editor
Studies in natural products chemistry. Elsevier Science Publisher Amsterdam; 1996: pp 739-85
- 3
Alvarenga N L, Ravelo A G, Jiménez I A, Bazzocchi I L, Canela N J, Moujir L.
Antibiotic phenol nor-triterpenes from Maytenus canariensis
.
Phytochemistry.
1996;
43
129-32
- 4
Moujir L M, Gutiérrez-Navarro A M, González A G, Ravelo A G, Luis J G.
Netzahualcoyone mode of action.
Antimicrob Agents Chemother.
1991;
35
211-13
- 5
González A G, Alvarenga N L, Ravelo A G, Bazzocchi I L, Ferro E A, Navarro A G, Moujir L.
Scutione, a new bioactive norquinonemethide triterpene from Maytenus scutioides (Celastraceae).
Bioorgan Med Chem.
1996;
4
815-20
- 6
González A G, Alvarenga N L, Estévez-Braun A, Ravelo A G, Bazzocchi I L, Moujir L.
Structure and absolute configuration of triterpene dimers from Maytenus scutioides
.
Tetrahedron.
1996;
52
9597-608
- 7 Gupta M P. Panamanian flora: Source of bioactive molecules. In: Hostettmann K, Marston
A, Maillard M, Hamburger M, editors
Phytochemistry of plants used in traditional medicine. Oxford University Press New York; 1995: pp 359-98
- 8 Gamlath G RCB, Gunaherath G MKB, Gunatilaka A AL. Isolation and structures of some
novel phenolic triterpenoids of Sri Lankan Celastraceae. In: Atta-Ur-Rahman, LeQuesne
PW, editor
New trends in natural products chemistry. Elsevier Science Publisher Amsterdam; 1986: p 109
- 9
Bai J P, Shi Y L, Fang X, Shi Q X.
Effects of demethylzeylasteral and celastrol on spermatogenic cell Ca2+ channels and progesterone-induced sperm acrosome reaction.
Eur J Pharmacol.
2003;
464
9-15
- 10
Ushiro S, Ono M, Nakayama J, Fujiwara T, Komatsu Y, Sugimachi K, Kuwano M.
New nortriterpenoid isolated from anti-rheumatoid arthritic plant, Tripterigium wilfordii, modulated tumor growth and neovascularization.
Int J Cancer.
1997;
2
657-63
- 11
Tamaki T, Morota T, Kawamura H, Maruyama H, Kanekos A, Nunome S, Komatsu Y, Quin W Z,
Yang B H.
Immunosuppressive and anti-inflammatory effects of phenolic nortriterpenoids, demethylzeylasteral,
from Tripterygium wilfordii
.
Nat Med.
1997;
51
98-104
- 12
González A G, Alvarenga N L, Rodríguez F M, Ravelo A G, Jiménez I A, Bazzocchi I L,
Gupta M P.
New phenolics and quinine-methide triterpenes from Maytenus species (Celastraceae).
Natural Product Letters .
2000;
63
48-51
- 13
Chraïbi D S, Giron S, Michel G.
Evaluation of the activity of four antimicrobial agents using an in vitro rapid micromethod against oral streptococci and various bacterial strains implicated
in periodontitis.
J Periodontal Res.
1990;
25
201-6
- 14
Davis B D, Mingoli E S.
Mutants of Escherichia coli requiring methionine or vitamin B12
.
J Bacteriol.
1950;
60
17-28
- 15
Friederich C L, Rozek A, Patrykat A, Hancock E W.
Structure and mechanism of action of an indolicin peptide derivative with improved
activity against Gram-positive bacteria.
J Biol Chem.
2001;
276
24 015-24 022
- 16 Fitz-James P C. The Collection of Mesosomes Vesicles Extruded During Protoplasting. In:
Guze LB, editor
Microbial protoplast, spheroplast, and L-forms. Williams & Wilkins Baltimore, USA; 1967: pp 124-43
- 17
Tilby M J.
Helical shape and wall synthesis in bacteria.
Nature (London)..
1977;
266
450-52
- 18
Bhavsar A P, Beveridge T J, Brown E D.
Precise detection of tagD and controlled depletion of its products, glycerol 3-phosphate cytidylytransferase,
leads to irregular morphology and lysis of Bacillus subtilis grown at physiological temperature.
J Bacteriol.
2001;
183
6688-93
- 19
Robson R L, Baddiley J.
Role of teichuronic acid in Bacillus licheniformis: defective autolysis due to deficiency of teichuronic acid in a novobiocin-resistant
mutant.
J Bacteriol.
1977;
129
1051-58
- 20
Roger H J, Taylor C.
Autolysins and shape change in rodA mutants of Bacillus subtilis
.
J Bacteriol.
1978;
135
1032-42
- 21
Subbalakshmi C, Sitaram N.
Mechanism of antimicrobial action of indolicin.
FEMS Microbiol Lett.
1998;
160
91-6
Laila Moujir Moujir
Departamento de Microbiología y Biología Celular
Facultad de Farmacia
Universidad de La Laguna
38206 Tenerife
Canary Islands
Spain
Telefon: +34-922-318-513
Fax: +34-922-318-477
eMail: Imoujir@ull.es
