This work is licensed under the Creative Commons Attribution 4.0 International License.
AbadP., GouzyJ., AuryJ. M., Castagnone-SerenoP., DanchinE. G. J., DeleuryE., Perfus-BarbeochL., AnthouardV., ArtiguenaveF., BlokV. C., CaillaudM., CoutinhoP. M., DasilvaC., LucaF. D., DeauF., EsquibetM., FlutreT., GoldstoneJ. V., HamamouchN., HeweziT., JaillonO., JubinC., LeonettiP., MaglianoM., MaierT. R., MarkovG. V., McVeighP., PesoleG., PoulainJ., Robinson-RechaviM., SalletE., SégurensB., SteinbachD., TytgatT., UgarteE., GhelderC. V., VeronicoP., BaumT. J., BlaxterM., Bleve-ZacheoT., DavisE. L., EwbankJ. J., FaveryB., GrenierE., HenrissatB., JonesJ. T., LaudetV., MauleA. G., QuesnevilleH., RossoM., SchiexT., SmantG., WeissenbachJ. and WinckerP.2008. Genome sequence of the metazoan plant-parasitic nematode Meloidogyne incognita. 26:908–15.10.1038/nbt.148218660804Search in Google Scholar
BackholmM., RyuW. S. and Dalnoki-VeressK.2013. Viscoelastic properties of the nematode Caenorhabditis elegans, a self-similar, shear-thinning worm. 110:4528–33.10.1073/pnas.1219965110360701823460699Search in Google Scholar
BergmannC. I.2006. Chemosensation in C. elegans. WormBook. doi: 10.1895/wormbook.1.123.1.10.1895/wormbook.1.123.1478156418050433Search in Google Scholar
BertinC., YangX. and WestonL. A.2003. The role of root exudates and allelochemicals in the rhizosphere. 256:67–83.10.1023/A:1026290508166Search in Google Scholar
CastroD. E., BelserN. O., McKinneyH. E. and ThomasonI. J.1989. Quantitative bioassay for chemotaxis with plant parasitic nematodes. Attractant and repellent fractions for Meloidogyne incognita from cucumber roots. 15:1297–1309.10.1007/BF0101483124272013Search in Google Scholar
ClarkeA. J. and HennessyJ.1984. Movement of Globodera rostochieusis (Woll.) juveniles stimulated by potato root exudate. 30:206–12.Search in Google Scholar
ClemensC. D., AumannL., SpiegelY. and WyssU.1994. Attractant-mediated behavior of mobile states of Heterodera schachtii. 17:569–74.Search in Google Scholar
CurtisR. H. C.2008. Plant-nematode interactions: environmental signals detected by the nematode’s chemosensory organs control changes in the surface cuticle and behavior. 15:310–16.10.1051/parasite/200815331018814700Search in Google Scholar
DavisE. L. and MacGuidwinA. E.2005. Lesion nematode disease. The Plant Health Instructor.Search in Google Scholar
DegenT., DillmannD., Marion-PollF. and TurlingsT. C.2004. High genetic variability of herbivore-induced volatile emission with a broad range of maize inbred lines. 135:1928–38.10.1104/pp.104.03989152076415299140Search in Google Scholar
DegenhardtJ., HiltpoldI., KöllnerT. G., FreyM., GieriA., GershenzonJ., HibbardB. E., EllersieckM. R. and TurlingsT. C.2009. Restoring a maize root signal that attracts insect-killing nematodes to control a major pest. 106:13218–13218.10.1073/pnas.0906365106272634419666594Search in Google Scholar
DevineK. J. and JonesP. W.2003. Investigations into the chemoattraction of the potato cyst nematodes Globodera rostochiensis and G. pallida towards fractionated potato root leachate. 5:65–75.Search in Google Scholar
DiezJ. A. and DusenberyD. B.1998. Repellence of root-knot nematodes from exudate of host roots. 15:2445–55.10.1007/BF0102037524271541Search in Google Scholar
DoaneJ. F. and KlinglerJ.1978. Location of CO2-receptive sensilla on larvae of wireworms Agriotes lineatus-obscurus and Limonius californicus. 71:357–63.10.1093/aesa/71.3.357Search in Google Scholar
DongL., LiX., HuangL., GaoY., ZhongL., ZhengY. and ZuoY.2014. Lauric acid in crown daisy root exudate potently regulates root-knot nematode chemotaxis and disrupts Mi-flp-18 expression to block infection. 65:131–41.10.1093/jxb/ert356388328524170741Search in Google Scholar
EilersE. J., TalaricoG., HanssonB. S., HilkerM. and ReineckeA.2012. Sensing the underground – ultrastructure and function of sensory organs in root-feeding Melolontha melolontha(Coleoptera: Scarabaeinae) larvae. 7 p. e41357.10.1371/journal.pone.0041357340514222848471Search in Google Scholar
FarnierK., BengtssonM., BecherP. G., WitzellJ., WitzgallP. and MandurícS.2012. Novel Bioassay demonstrates attraction of the shite potato cyst nematode Globodera pallida (Stone) to non-volatile and volatile host plant cues. 38:795–801.10.1007/s10886-012-0105-y22527050Search in Google Scholar
Fosu-NyarkoJ. and JonesM. G. K.2016. Advances in understanding the molecular mechanisms of root lesion nematode host interactions. 54:253–78.10.1146/annurev-phyto-080615-10025727296144Search in Google Scholar
HiltpoldI., JaffuelG. and TurlingsT. C. J.2015. The dual effects of root-cap exudates on nematodes: from quiescence in plant-parasitic nematodes to frenzy in entomopathogenic nematodes. 66:603–11.10.1093/jxb/eru345428640325165149Search in Google Scholar
HiltpoldI. and TurlingsT. C. J.2008. Belowground chemical signaling in maize: when simplicity rhymes with efficiency. 34:628–35.10.1007/s10886-008-9467-618443880Search in Google Scholar
HuY., YouJ., LiC., WilliamsonV. M. and WangC.2017. Ethylene response pathway modulates attractiveness of plant roots to soybean cyst nematode Heterodera glycines. 7:41282.10.1038/srep41282525637428112257Search in Google Scholar
HusseyR. S. and BarkerK. R.1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new techinique. 57:1025–8.Search in Google Scholar
JaffuelG., HiltpoldI. and TurlingsT. C. J.2015. Highly potent extracts from pea (Pisum sativum) and maize (Zea mays) roots can be used to induce quiescence in entomopathogenic nematodes. 41:793–800.10.1007/s10886-015-0623-526364294Search in Google Scholar
MaleitaC., EstevesI., ChimR., FonsecaL.,BragaM. E. M., AbrantesI. and de SousaH. C.2017. Naphthoquinones from Walnut Husk Residues Show Strong Nematicidal Activities against the Root-knot Nematode. 4:3390–98.10.1021/acssuschemeng.7b00039Search in Google Scholar
MargieO., PalmerC. and Chin-SangI.2013. C. elegans chemotaxis assay. 74:e50069.Search in Google Scholar
MaruyamaI. N.2017. Receptor guanylyl cyclases in sensory processing. 7:173.10.3389/fendo.2016.00173522510928123378Search in Google Scholar
MitchumM. G., HusseyR. S., BaumT. J., WangX., EllingA. A., WubbenM. and DavisE. L.2013. Nematode effector proteins: an emerging paradigm of parasitism. 199:879–84.10.1111/nph.1232323691972Search in Google Scholar
MooreS. R., LawrenceK. S., ArriagaF. J., BurmesterC. H. and van SantenE.2010. Natural Migration of Rotylenchulus reniformis in a no-till cotton system. 42:307–12.Search in Google Scholar
NicolJ. M., TurnerS. J., CoyneD. L., den NijsL., HocklandS. and Tahna MaafiZ.2011. Current nematode threats to world agriculture. in JonesJ., GheysenG. and FenollC. (ed.), Springer, Dordrecht, Netherlands: 21–43.Search in Google Scholar
OppermanC. H., BirdD. M., WilliamsonV. M., RokhsarD. S., BurkeM., CohnJ., CromerJ., DienerS., GajanJ., GrahamS., HoufekT. D., LiuQ., MitrosT., SchaffJ., SchafferR., SchollE., SosinskiB. R., ThomasV. P. and WindhamE.2008. Sequence and genetic map of Meloidogyne hapla: a compact nematode genome for plant parasitism. 105:14802–7.10.1073/pnas.0805946105254741818809916Search in Google Scholar
PapademetriousM. K. and BoneL. W.1983. Chemotaxis of larval soybean cyst nematode, Heterodera glycines Race 3, to root leachate and ions. 9:387–98.10.1007/BF0098845724407407Search in Google Scholar
PeacockF. C.1961. A note on the attractiveness of roots to plant parasitic nematodes. 6:85–6.10.1163/187529261X00315Search in Google Scholar
PerryR. N.1996. Chemoreception in plant-parasitic nematodes. 34:181–9.10.1146/annurev.phyto.34.1.18115012540Search in Google Scholar
PétriacqP., WilliamsA., CottonA., McFarianeA. E., RolfeS. A. and TonJ.2017. Metabolite profiling of non-sterile rhizosphere soil. 92:147–62.10.1111/tpj.13639563936128742258Search in Google Scholar
ProtJ. C.1980. Migration of plant-parasitic nematodes towards plant roots. 3:305–18.Search in Google Scholar
QiY., MengL., CaoS., LiM., ChenS. and YeD.2015. Chemotaxis of Meloidogyne incognita in response to different salts. 6:900–7.10.4236/as.2015.69086Search in Google Scholar
RankinC. H., BeckC. D. O. and ChibaC. M.1993. Caenorhabditis elegans: a new model system for the study of learning and memory. 37:89–92.Search in Google Scholar
RasmannS., KöllnerT. G., DegenhardtJ., HiltpoldI., ToepferS., KuhlmannU., GershenzonJ. and TurlingsT. C.2005. Recruitment of entomopathogenic nematodes by insect-damage maize roots. 434:732–7.10.1038/nature0345115815622Search in Google Scholar
ReineckeA., MüllerF. and HilkerM.2008. Attractiveness of CO2 released by root respiration fades on the background of root exudates. 9:568–76.10.1016/j.baae.2007.10.002Search in Google Scholar
ReynoldsA. M., DuttaT. K., CurtisR. H. C., PowersS. T., GaurH. S. and KerryB. R.2011. Chemotaxis can take plant-parasitic nematodes to the source of a chemo-attractant via the shortest possible routes. 8:568–77.10.1098/rsif.2010.0417306112320880854Search in Google Scholar
RobinsonA. F., BellA. A., DigheN. D., MenzM. A., NicholsR. L. and StellyD. M.2007. Introgression of resistance to nematode Rotylenchulus reniformis into upland cotton (Gossypium hisutum) from Gossypium longicalyx. 47:1865–77.10.2135/cropsci2006.12.0776Search in Google Scholar
RolfeR. N., BarrettJ. and PerryR. N.2000. Analysis of chemosensory responses of second stage juveniles of Globedera rostochiensis using electrophysiological techniques. 3:31–4.Search in Google Scholar
SchaffJ. E., MauchlineT. H., OppermanC. H. and DaviesK. G.2011. Exploiting genomics to understand the interactions between root-knot nematodes and Pasteuria penetrans, In DaviesK. and SpiegelY. (ed.), Springer, Dordrecht, Netherlands,91–113.Search in Google Scholar
SikkensR. B., WeaverD. B., LawrenceK. S., MooreS. R. and van SentenE.2011. LONREN upland cotton germplasm response to Rothyenchulus reniformis inoculum level. 6:68–74.Search in Google Scholar
SteeghsM., BaisH. P., de GouwJ., GoldanP., KusterW., NorthwayM., FallR. and VivancoJ. M.2004. Proton-transfer-reaction mass spectrometry as a new tool for real time analysis of root-secreted volatile organic compounds in Arabidopsis. 135:47–58.10.1104/pp.104.03870342933215141066Search in Google Scholar
SteinerG.1925. The problem of host selection and host specialization of certain plant-infesting nemas and its application in the study of nemic pests. 15:499–534.Search in Google Scholar
Van DamN. M. and BouwmeesterH. J.2016. Metabolomics in the rhizosphere: tapping into belowground chemical communication. 21:256–65.10.1016/j.tplants.2016.01.00826832948Search in Google Scholar
VenturiV. and KeelC.2016. Signaling in the rhizosphere. 21:187–98.10.1016/j.tplants.2016.01.00526832945Search in Google Scholar
WatersD. R., WalkerR. L. and WalkerK. C.2003. Lauric acid exhibits antifungal activity against plant pathogenic fungi. 151:228–30.10.1046/j.1439-0434.2003.00713.xSearch in Google Scholar
WicherD.2012. Functional and evolutionary aspects of chemoreceptors. 6:1–4.10.3389/fncel.2012.00048348111923112762Search in Google Scholar
WieserW.1956. The attractiveness of plants to larvae of root-knot nematodes. III. The effect of excised bean, eggplant and soybean roots on Meloidogyne hapla Chitwood. 23:59–64.Search in Google Scholar
XiangN. and LawrenceK. S.2016. Optimization of in vitro techniques for distinguishing between live and dead second stage juveniles of Heterodera gylcines and Meloidogyne incognita. 11:e0154818.10.1371/journal.pone.0154818485628127144277Search in Google Scholar
XiangN., LawrenceK. S., KloepperJ. W. and MicnroyJ. A.2014. In vitro screening of biological control agents on Meloidogyne incognita. 1:258–60.Search in Google Scholar
YanY. and DavisE. L.2002. Characterisation of guanylyl cyclease genes in the soybean cyst nematode, Heterodera glycines. 32:65–72.10.1016/S0020-7519(01)00315-011796123Search in Google Scholar