Psychoactive Plant Database - Neuroactive Phytochemical Collection

1. mBio. 2016 Jul 19;7(4):e01054-16. doi: 10.1128/mBio.01054-16.

Promiscuous Diffusible Signal Factor Production and Responsiveness of the 
Xylella fastidiosa Rpf System.

Ionescu M(1), Yokota K(2), Antonova E(1), Garcia A(1), Beaulieu E(3), Hayes 
T(3), Iavarone AT(4), Lindow SE(5).

Author information:
(1)Department of Plant and Microbial Biology, University of California, 
Berkeley, California, USA.
(2)Department of Applied Biology and Chemistry, Tokyo University of Agriculture, 
Tokyo, Japan.
(3)Biosciences Division, SRI International, Menlo Park, California, USA.
(4)California Institute for Quantitative Biosciences (QB3), University of 
California, Berkeley, California, USA.
(5)Department of Plant and Microbial Biology, University of California, 
Berkeley, California, USA icelab@berkeley.edu.

Cell density-dependent regulation of gene expression in Xylella fastidiosa that 
is crucial to its switching between plant hosts and insect vectors is dependent 
on RpfF and its production of 2-enoic acids known as diffusible signal factor 
(DSF). We show that X. fastidiosa produces a particularly large variety of 
similar, relatively long-chain-length 2-enoic acids that are active in 
modulating gene expression. Both X. fastidiosa itself and a Pantoea agglomerans 
surrogate host harboring X. fastidiosa RpfF (XfRpfF) is capable of producing a 
variety of both saturated and unsaturated free fatty acids. However, only 2-cis 
unsaturated acids were found to be biologically active in X. fastidiosa 
X. fastidiosa produces, and is particularly responsive to, a novel DSF species, 
2-cis-hexadecanoic acid that we term XfDSF2. It is also responsive to other, 
even longer 2-enoic acids to which other taxa such as Xanthomonas campestris are 
unresponsive. The 2-enoic acids that are produced by X. fastidiosa are strongly 
affected by the cellular growth environment, with XfDSF2 not detected in culture 
media in which 2-tetradecenoic acid (XfDSF1) had previously been found. 
X. fastidiosa is responsive to much lower concentrations of XfDSF2 than XfDSF1. 
Apparently competitive interactions can occur between various saturated and 
unsaturated fatty acids that block the function of those agonistic 2-enoic fatty 
acids. By altering the particular 2-enoic acids produced and the relative 
balance of free enoic and saturated fatty acids, X. fastidiosa might modulate 
the extent of DSF-mediated quorum sensing.
IMPORTANCE: X. fastidiosa, having a complicated lifestyle in which it moves and 
multiplies within plants but also must be vectored by insects, utilizes 
DSF-based quorum sensing to partition the expression of traits needed for these 
two processes within different cells in this population based on local cellular 
density. The finding that it can produce a variety of DSF species in a strongly 
environmentally context-dependent manner provides insight into how it 
coordinates the many genes under the control of DSF signaling to successfully 
associate with its two hosts. Since the new DSF variant XfDSF2 described here is 
much more active than the previously recognized DSF species, it should 
contribute to plant disease control, given that the susceptibility of plants can 
be greatly reduced by artificially elevating the levels of DSF in plants, 
creating "pathogen confusion," resulting in lower virulence.

Copyright © 2016 Ionescu et al.

DOI: 10.1128/mBio.01054-16
PMCID: PMC4958263
PMID: 27435463 [Indexed for MEDLINE]


2. Mol Plant Microbe Interact. 2014 Mar;27(3):244-54. doi: 
10.1094/MPMI-07-13-0197-FI.

Production of Xylella fastidiosa diffusible signal factor in transgenic grape 
causes pathogen confusion and reduction in severity of Pierce's disease.

Lindow S, Newman K, Chatterjee S, Baccari C, Lavarone AT, Ionescu M.

The rpfF gene from Xylella fastidiosa, encoding the synthase for diffusible 
signal factor (DSF), was expressed in 'Freedom' grape to reduce the pathogen's 
growth and mobility within the plant. Symptoms in such plants were restricted to 
near the point of inoculation and incidence of disease was two- to fivefold 
lower than in the parental line. Both the longitudinal and lateral movement of 
X. fastidiosa in the xylem was also much lower. DSF was detected in both leaves 
and xylem sap of RpfF-expressing plants using biological sensors, and both 
2-Z-tetradecenoic acid, previously identified as a component of X. fastidiosa 
DSF, and cis-11-methyl-2-dodecenoic acid were detected in xylem sap using 
electrospray ionization mass spectrometry. A higher proportion of X. fastidiosa 
cells adhered to xylem vessels of the RpfF-expressing line than parental 
'Freedom' plants, reflecting a higher adhesiveness of the pathogen in the 
presence of DSF. Disease incidence in RpfF-expressing plants in field trials in 
which plants were either mechanically inoculated with X. fastidiosa or subjected 
to natural inoculation by sharpshooter vectors was two- to fourfold lower in 
than that of the parental line. The number of symptomatic leaves on infected 
shoots was reduced proportionally more than the incidence of infection, 
reflecting a decreased ability of X. fastidiosa to move within DSF-producing 
plants.

DOI: 10.1094/MPMI-07-13-0197-FI
PMID: 24499029 [Indexed for MEDLINE]


3. mBio. 2013 Jan 8;4(1):e00539-12. doi: 10.1128/mBio.00539-12.

Characterization of a diffusible signaling factor from Xylella fastidiosa.

Beaulieu ED(1), Ionescu M, Chatterjee S, Yokota K, Trauner D, Lindow S.

Author information:
(1)Biosciences Division of SRI International, Menlo Park, California, USA.

Cell-cell signaling in Xylella fastidiosa has been implicated in the 
coordination of traits enabling colonization in plant hosts as well as insect 
vectors. This cell density-dependent signaling has been attributed to a 
diffusible signaling factor (DSF) produced by the DSF synthase RpfF. DSF 
produced by related bacterial species are unsaturated fatty acids, but that of 
X. fastidiosa was thought to be different from those of other taxa. We describe 
here the isolation and characterization of an X. fastidiosa DSF (XfDSF) as 
2(Z)-tetradecenoic acid. This compound was isolated both from recombinant 
Erwinia herbicola expressing X. fastidiosa rpfF and from an X. fastidiosa rpfC 
deletion mutant that overproduces DSF. Since an rpfF mutant is impaired in 
biofilm formation and underexpresses the hemagglutinin-like protein-encoding 
genes hxfA and hxfB, we demonstrate that these traits can be restored by ca. 0.5 
µM XfDSF but not by myristic acid, the fully saturated tetradecenoic acid. A 
phoA-based X. fastidiosa biosensor that assesses DSF-dependent expression of 
hxfA or hxfB revealed a high level of molecular specificity of DSF signaling.
IMPORTANCE: X. fastidiosa causes diseases in many important plants, including 
grape, where it incites Pierce's disease. Virulence of X. fastidiosa for grape 
is coordinated by cell-cell signaling molecules, designated DSF (Diffusible 
Signaling Factor). Mutants blocked in DSF production are hypervirulent for 
grape, suggesting that virulence is suppressed upon DSF accumulation and that 
disease could be controlled by artificial elevation of the DSF level in plants. 
In this work, we describe the isolation of the DSF produced by X. fastidiosa and 
the verification of its biological activity as an antivirulence factor. We also 
have developed X. fastidiosa DSF biosensors to evaluate the specificity of 
cell-cell signaling to be investigated.

DOI: 10.1128/mBio.00539-12
PMCID: PMC3546559
PMID: 23300249 [Indexed for MEDLINE]


4. Z Naturforsch C J Biosci. 1991 May-Jun;46(5-6):442-50. doi: 
10.1515/znc-1991-5-617.

Podoscyphic acid, a new inhibitor of avian myeloblastosis virus and Moloney 
murine leukemia virus reverse transcriptase from a Podoscypha species.

Erkel G(1), Anke T, Velten R, Steglich W.

Author information:
(1)LB-Biotechnologie der Universität, Kaiserslautern, Bundesrepublik 
Deutschland.

A novel enzyme inhibitor of RNA-directed DNA-polymerases of avian myeloblastosis 
and murine leukemia virus was isolated from fermentations of an tasmanian 
Podoscypha species. Its structure was elucidated by spectroscopic methods and 
oxidative degradation as (E)-4,5-dioxo-2-hexadecenoic acid (1). The enzyme 
inhibitor, which was named podoscyphic acid, did not inhibit DNA and RNA 
synthesis in permeabilized L 1210 cells nor did it affect RNA synthesis in 
isolated nuclei of L 1210 cells. 1 inhibits protein synthesis in whole L 1210 
cells and rabbit reticulocyte lysate and shows very weak antimicrobial and 
cytotoxic properties. The testing of ethyl (E)-4,5-dioxo-2-hexadecenoate (2) and 
(E)-4-oxo-2-tetradecenoic acid (11) revealed the importance of the free 
gamma-oxoacrylic acid unit for the biological activities of 1.

DOI: 10.1515/znc-1991-5-617
PMID: 1716894 [Indexed for MEDLINE]


5. Exp Parasitol. 1984 Oct;58(2):215-22. doi: 10.1016/0014-4894(84)90037-7.

Schistosoma mansoni: cercaricidal effect of 2-tetradecenoic acid, a penetration 
stimulant.

Haas W.

Schistosoma mansoni cercariae are stimulated by 2-tetradecenoic acid (TDA) to 
penetrate agar substrates. TDA simultaneously causes tegumental transformation 
similar to that seen when cercariae transform to schistosomula, reduces the 
Cercarienhüllen reaction in immune human serum, and reduces larval tolerance to 
water. TDA damages cercariae that fail to penetrate or have no opportunity to do 
so. This damage apparently stems from increased tegumental permeability to 
water. Preincubation in TDA for 60 min reduces the percutaneous infectivity of 
cercariae to mice by from 95% at 0.2 ppm to 100% at 0.7 ppm TDA, but does not 
reduce the infectivity of subcutaneously injected cercariae. The interference 
with percutaneous infection seems to be entirely due to osmotic damage. TDA does 
not induce premature secretion of the acetabular glands or block 
host-recognition chemoreceptors. TDA may be a promising cercaricide for 
schistosomiasis control. It is highly specific for schistosome cercariae and is 
effective at low concentrations (0.2 to 0.7 ppm). Both cercariae and TDA tend to 
collect in the upper few millimeters of standing water. It is unlikely that 
cercariae can evolve resistance to a chemical that triggers the host penetration 
mechanisms.

DOI: 10.1016/0014-4894(84)90037-7
PMID: 6479290 [Indexed for MEDLINE]