Page 17 - Volume 5, Issue 2, July 2012
Basic HTML Version
© Benaki Phytopathological Institute
Phytobacterial type III secretion systems in the era of biotechnology
45
Guo, M., Tian, F., Wamboldt, Y. and Alfano, J.R. 2009.
The majority of the type III effector inventory of
Pseudomonas syringae
pv.
tomato
DC3000 can
suppress plant immunity.
Mol Plant-Microbe In-
teract.,
9: 1069-80.
Hamilton, J.P., Neeno-Eckwall, E.C., Adhikari, B.N.,
Perna, N.T., Tisserat, N., Leach, J.E., Lévesque
C.A. and Buell, C.R. 2011. The Comprehensive
Phytopathogen Genomics Resource: a web-
based resource for data-mining plant pathogen
genomes.
Database
2011:bar053.
Hayes, C.S., Aoki, S. K. and Low, D.A. 2010. Bacteri-
al contact-dependent delivery systems. Annu.
Rev. Genet., 44: 71-90.
He, S.Y., Huang, H. and Collmer A. 1993.
Pseudomo-
nas syringae
pv.
syringae
harpin
Pss
: a protein
that is secreted via the Hrp pathway and elic-
its the hypersensitive response in plants.
Cell,
73: 1255–66.
He, S.Y., Nomura, K. and Whittam, T.S. 2004. Type
III protein secretion mechanism in mammali-
an and plant pathogens.
Biochim. Biophys. Acta,
1694: 181–206.
Hückelhoven, R. 2007. Cell wall-associated mecha-
nisms of disease resistance and susceptibility.
Annu. Rev. Phytopathol.,
45:101–127.
Hudson, D.L., Layton, A.N., Field, T.R., Bowen, A.J.,
Wolf-Watz, H., Elofsson, M., Stevens, M.P. and
Galyov, E.E. 2007. Inhibition of type III secre-
tion in
Salmonella enterica
serovar
Typhimurium
by small-molecule inhibitors.
Antimicrob Agents
Chemother.,
51: 2631-5.
Jones, J.D. and Dangl, J.L
.
2006
.
The plant immune
system
. Natur
e, 444: 323
–
329
.
Isberg, R.R. and, Falkow, S. 1985. A single genetic lo-
cus encoded by
Yersinia pseudotuberculosis
per-
mits invasion of cultured animal cell by
Escheri-
chia coli
K-12.
Nature,
317: 262-264.
Klement, Z. and Goodman R.N. 1967. The hypersen-
sitive reaction to infection by bacterial plant
pathogens.
Annu. Rev. Phytopathol
., 5: 17-44.
Kostic, T., Weilharter, A., Rubino, S., Delogu, G., Uzzau,
S., Rudi, K., Sessitsch, A. and Bodrossy, L. 2007. A
microbial diagnostic microarray technique for
the sensitive detection and identification of
pathogenic bacteria in a background of non-
pathogens.
Analytic. Biochem.,
360: 244–254.
Lee, J., Klusener, B., Tsiamis, G., Stevens, C., Neyt,
C., Tampakaki, A.P., Panopoulos, N.J., Nöller, J.,
Weiler, E.W., Cornelis, G.R., Mansfield, J.W. and
Nürnberger T. 2001. HrpZ(Psph) from the plant
pathogen
Pseudomonas syringae
pv.
phaseolico-
la
binds to lipid bilayers and forms an ion-con-
ducting pore in vitro.
Proc. Natl. Acad. Sci. USA,
98: 289-94.
Leite, R.P.Jr, Minsavage, G.V., Bonas, U. and Stall, R.E.
1994. Detection and identification and of phy-
topathogenic
Xanthomonas
strains by ampli-
fication of DNA sequences related to the hrp
genes of
Xanthomonas campestris
pv.
vesicato-
ria. Appl. Environ. Microbiol.,
60: 1068-77.
Li, T, Liu, B., Spalding, M.H., Weeks, D.P., and Yang,
B. 2012. High-efficiency TALEN-based gene ed-
iting produces disease-resistant rice.
Nature Bio-
technology,
30: 390–392 doi:10.1038/nbt.2199.
Lindeberg, M., Cunnac, S. and Collmer, A. 2012.
Pseudomonas syringae
type III effector reper-
toires: last words in endless arguments.
Trends
Microbiol.,
20: 199-208.
Lindgren, P.B., Peet, R.C., Willis, D.C. and Panopoulos,
N.J. 1986. Gene cluster of
Pseudomonas syringae
pv.
phaseolicola
controls pathogencity on bean
and hypersensitivity on non-host plants.
J. Bacte-
riol
., 168: 512-522.
Lorenz, C. and Büttner, D. 2009. Functional charac-
terization of the type III secretion ATPase HrcN
from the plant pathogen
Xanthomonas campes-
tris
pv.
vesicatoria
.
J. Bacteriol.,
191: 1414-28.
Madic J., de Garam ,C.P., Brugère, H., Loukiadis, E.,
Fach, P., Jamet, E. and Auvray F. 2011. Duplex
real-time PCR detection of typeIII effector
tccP
and
tccP2
genes in pathogenic
Escherichia coli
and prevalence in raw milk cheeses.
Lett. Appl.
Microbiol
., 52: 538-545.
Martin, G.B., Williams, J.G. and Tanksley, S.D. 1991.
Rapid identification of markers linked to a
Pseudomonas resistance
gene in tomato by us-
ing random primers and near-isogenic lines.
Proc. Natl. Acad. Sci. USA,
88: 2336-40.
McCabe, E.M., Burgess, C.M., Walsh, D., O’Regan, E.,
McGuinness, S., Barry, T., Fanning, S. and Duffy,
G. 2010. Validation of DNA and RNA real-time as-
says for food analysis using the hilA gene of
Sal-
monella enterica
serovars.
J. Microbiol. Methods.,
84: 19-26.
Miao, W., Wang, X., Li, M., Song, C., Wang, Y., Hu, D.
and Wang, J. 2010. Genetic transformation of
cotton with a harpin-encoding gene
hpa
Xoo
con-
fers an enhanced defense response against dif-
ferent pathogens through a priming mecha-
nism.
BMC Plant Biol.
10:67.
Minsavage, G.V., Dahlbeck, D., Whalen, M.C., Kear-
ney, B., Bonas, U., Staskawicz, B.J. and Stall, R.E.
1990. Gene-For-Gene relationships specifying
disease resistance in
Xanthomonas campestris
pv.
vesicatoria
– pepper interactions.
Mol. Plant-
Microbe Interact.
3: 41-47.
Morbitzer, R., Romer, P., Boch, J. and Lahaye, T. 2010.
Regulation of selected genome loci using de
novo-engineered transcription activator-like
effector (TALE)-type transcription factors
. Proc.
Natl. Acad. Sci. USA,
107: 21617–622.
Moscou, M.J. and Bogdanove, A.J. 2009. A simple ci-
pher governs DNA recognition by TAL effectors.
Science,
326:1501.
Muschiol, S., Normark, S., Henriques-Normark, B.
and Subtil, A. 2009. Small molecule inhibitors of
the Yersinia type III secretion system impair the
development of
Chlamydia
after entry into host
cells.
BMC Microbiol.,
9:75.
