gefarnate and geranylfarnesol

A biosynthetic gene cluster from Streptomyces mobaraensis encoding the first cases of a bacterial geranylfarnesyl diphosphate synthase and a type I sesterterpene synthase was identified. The structures of seven sesterterpenes produced by these enzymes were elucidated, including their absolute configurations. The enzyme mechanism of the sesterterpene synthase was investigated by extensive isotope labeling experiments.

Topics: Gefarnate; Ligases; Multigene Family; Sesterterpenes; Stereoisomerism; Streptomyces

The enzymatic reactions of geranylfarnesol (8) and its acetate 9, classified as sesterterpenes (C25), using squalene-hopene cyclase (SHC) were investigated. The enzymatic reaction of 8 afforded 6/6-fused bicyclic 20, 6/6/6-fused tricyclic 21, and 6/6/6/6-fused tetracyclic compounds 22 and 23 as the main products (35% yield), whereas that of 9 afforded two 6/6/6-fused tricyclic compounds 24 and 25 in a high yield (76.3%) and a small amount (5.0%) of 26 (the acetate of 22). A significantly higher conversion of 9 indicates that the arrangement of the substrate in the reaction cavity changed. The lipophilic nature and/or the bulkiness of the acetyl group may have changed its binding with SHC, thus placing the terminal double bond of 9 in the vicinity of the DXDD motif of SHC, which is responsible for the proton attack on the double bond to initiate the polycyclization reaction. The results obtained for 8 are different to some extent than those reported by Shinozaki et al. The products obtained in this study were deprotonated compounds; however, the products reported by Shinozaki et al. were hydroxylated compounds.

Topics: Alicyclobacillus; Bacterial Proteins; Gefarnate; Gene Expression Regulation, Bacterial; Gene Expression Regulation, Enzymologic; Intramolecular Transferases; Molecular Structure

Cis-prenyltransferase from a hyperthermophilic archaeon Aeropyrum pernix was expressed in Escherichia coli and purified for characterization. Properties such as substrate specificity, product chain-length, thermal stability and cofactor requirement were investigated using the recombinant enzyme. In particular, the substrate specificity of the enzyme attracts interest because only dimethylallyl diphosphate and geranylfarnesyl diphosphate, both of which are unusual substrates for known cis-prenyltransferases, are likely available as an allylic primer substrate in A. pernix. From the enzymatic study, the archaeal enzyme was shown to be undecaprenyl diphosphate synthase that has anomalous substrate specificity, which results in a preference for geranylfarnesyl diphosphate. This means that the product of the enzyme, which is probably used as the precursor of the glycosyl carrier lipid, would have an undiscovered structure.

Topics: Aeropyrum; Alkyl and Aryl Transferases; Archaeal Proteins; Electrophoresis, Polyacrylamide Gel; Enzyme Stability; Escherichia coli; Gefarnate; Hot Temperature; Organophosphates; Recombinant Proteins; Substrate Specificity

Aleuritopteris ferns produce triterpenes and sesterterpenes with tricyclic cheilanthane and tetracyclic 18-episcalarane skeletons. The structural and mechanistic similarities between both classes of fern terpene suggest that their biosynthetic enzymes may be closely related. We investigate here whether a triterpene synthase is capable of recognizing geranylfarnesols as a substrate, and is able to convert them to cyclic sesterterpenes. We found that a bacterial triterpene synthase converted all-E-geranylfarnesol (1b) into three scalarane sesterterpenes with 18αH stereochemistry (5, 7 and 8), as well as mono- and tricyclic sesterterpenes (6 and 9). In addition, 2Z-geranylfarnesol (4) was converted into an 18-episcalarane derivative (10), whose skeleton can be found in sesterterpenes isolated from Aleuritopteris ferns. These results provide insight into sesterterpene biosynthesis in Aleuritopteris ferns.

Topics: Alicyclobacillus; Bacterial Proteins; Cyclization; Escherichia coli; Ferns; Gefarnate; Ligases; Molecular Structure; Recombinant Proteins; Sesterterpenes; Stereoisomerism; Substrate Specificity; Triterpenes

The triterpene alcohol constituents of the non-saponifiable lipids of two Theaceae seed oils, sasanqua and camellia oils, and two Gramineae seed oils, wheat germ and rice bran oils, were investigated. This led to the isolation and characterization of one acyclic and eight incompletely cyclized triterpene alcohols. They are camelliol A, camelliol B, camelliol C, achilleol A, helianol, isohelianol, sasanquol, graminol A [(13R, 14R)-3,4-seco-25(10->9)abeo-8alpha,9beta,10al phapodioda-4,17,21 -trien-3-ol], and (2Z,6Z,10Z,14E,18E)-farnesyl-farnesol. Two other compounds isolated were characterized as (2Z,6Z,10E,14E)-geranylfarnesol, a sesterterpene alcohol, and phytol, a diterpene alcohol. Graminol A and (2Z,6Z,10E,14E)-geranylfarnesol are considered to be new natural products.

Topics: Alcohols; Chromatography, High Pressure Liquid; Cyclization; Ericales; Gefarnate; Magnetic Resonance Spectroscopy; Mass Spectrometry; Molecular Conformation; Molecular Structure; Plant Oils; Poaceae; Seeds; Triterpenes

Geranylgeraniol, a polyprenylalcohol composing the side chain of vitamin K2 (VK2), was previously reported to be a potent inducer of apoptosis in tumor cell lines (Ohzumi H et al, J Biochem 1995; 117: 11-13). We examined the apoptosis-inducing ability of VK2 (menaquinone 3 (MK3), MK4 and MK5) and its derivatives such as phytonadione (VK1), as well as polyprenylalcohols with side chains of various lengths including farnesol (C15-OH; FO), geranylgeraniol (C20-OH; GGO), and geranylfarnesol (C25-OH; GFO) toward leukemia cells in vitro. MK3, MK4, MK5 and GFO (at 10 microM) showed a potent apoptosis-inducing activity for all freshly isolated leukemia cells tested and for leukemia cell lines such as NB4, an acute promyelocytic leukemia (APL)-derived cell line and MDS92, a cell line derived from a patient with myelodysplastic syndrome, although there were some differences depending on the cells tested. In contrast, VK1 showed no effect on any of the leukemia cells. The combination of MK5 plus all-trans retinoic acid (ATRA) resulted in enhanced induction of apoptosis in both freshly isolated APL cells and NB4 cells as compared to each reagent alone. These data suggest the possibility of using VK2 and its derivatives for the treatment of myelogenous leukemias, including APL.

Topics: Apoptosis; Bone Marrow; Diterpenes; Drug Synergism; Farnesol; Flow Cytometry; Gefarnate; Humans; Leukemia; Leukemia, Myelogenous, Chronic, BCR-ABL Positive; Leukemia, Myeloid; Leukemia, Promyelocytic, Acute; Molecular Structure; Myelodysplastic Syndromes; Structure-Activity Relationship; Tretinoin; Tumor Cells, Cultured; Vitamin K; Vitamin K 1; Vitamin K 2

We screened several synthetic polyprenoids about their capacity of cell differentiation using mouse myeloid leukemic M1 cells, and found that 3, 7, 11, 15, 19,-pentamethyleicosa-2, 6, 10, 14, 18-pentaenol (Geranyl Farnesol) could induce the differentiation of M1 cells into macrophage-like cells. The optimal concentration of this compound for its induction capacity was approximately 2 X 10(-5) M. The induced differentiation related markers were morphological change in M1 cells, Fc receptors for IgG (Fc gamma), and non-specific esterase activity. However, phagocytic activity was poorly induced. This suggests that most of Geranyl Farnesol treated cells may be retained functionally incomplete macrophages. The presence of cycloheximide at 1 X 10(-7)M or the incubation of M1 cells at 4 degrees C completely blocked the induction of Fc gamma, suggesting the induction of Fc gamma required protein synthesis. The treatment of M1 cells with Geranyl Farnesol resulted in suppression of DNA and RNA synthesis. Further analysis of RNA metabolism suggested that the suppression of RNA synthesis was mainly due to the decrease of rRNA. On the other hand the synthesis and turnover of polyA-containing RNA (mRNA) rather increased.

Topics: Animals; Cell Cycle; Cell Differentiation; Esterases; Gefarnate; Leukemia, Experimental; Mice; Nucleic Acids; Phagocytosis; Poly A; Receptors, Fc; RNA; RNA, Messenger; Terpenes