@article{barker_davis_2010, title={Anastasios (Tasso) Christos Triantaphyllou (1926-2009) obituary}, volume={12}, journal={Nematology}, author={Barker, K. R. and Davis, E. L.}, year={2010}, pages={311–312} }
 @article{barker_triantaphyllou_2006, title={In memoriam - Joseph Neal Sasser 1921-2005}, volume={38}, number={1}, journal={Journal of Nematology}, author={Barker, K. R. and Triantaphyllou, A. C.}, year={2006}, pages={1/2/2006} }
 @article{walters_wehner_daykin_barker_2006, title={Penetration rates of root-knot nematodes into Cucumis sativus and C-metuliferus roots and subsequent histological changes}, volume={36}, number={2}, journal={Nematropica}, author={Walters, S. A. and Wehner, T. C. and Daykin, M. E. and Barker, K. R.}, year={2006}, pages={231–242} }
 @article{dong_barker_opperman_2005, title={Virulence genes in Heterodera glycines: Allele frequencies and ror gene groups among field isolates and inbred lines}, volume={95}, ISSN={["1943-7684"]}, DOI={10.1094/PHYTO-95-0186}, abstractNote={ Genetic variation in field populations of Heterodera glycines is a key issue for both resistance gene deployment and basic understanding of virulence-gene flow in populations. In this study, we examined phenotypically defined genes for virulence under selection from host resistance. We separated the most common H. glycines genotypes in the United States into two virulence groups, based on their reproductive abilities on the resistant soybean plant introduction (PI) 88788. These groups correspond to previously identified virulence genes in the nematode, as follows: the dominant gene in H. glycines to PI88788, and the recessive genes to PI90763 and Pickett/Peking. Virulence allele frequencies and virulence genotype frequencies of selected field isolates were investigated by testing the host range of single-female-derived lines, which were developed through single-female inoculation on the standard susceptible soybean ‘Lee 68’. By comparing virulence genotype frequencies between the original field isolates and their single-female-derived lines, we were able to determine allele frequencies in the field populations. The results suggest that tremendous variation in H. glycines virulence genes exists among field populations. Potential mechanisms of selection which could cause virulence genotype frequency increases are discussed as related to population genetics equilibrium theory. }, number={2}, journal={PHYTOPATHOLOGY}, author={Dong, K and Barker, KR and Opperman, CH}, year={2005}, month={Feb}, pages={186–191} }
 @article{koenning_barker_2004, title={Influence of poultry litter applications on nematode communities in cotton agroecosystems}, volume={36}, number={4}, journal={Journal of Nematology}, author={Koenning, S. R. and Barker, K. R.}, year={2004}, pages={524–533} }
 @inbook{schmitt_koenning_barker_2004, title={Population density based management}, booktitle={Biology and management of the soybean cyst nematode  (2nd ed.)}, publisher={Weinheim: Wiley-VCH}, author={Schmitt, D. P. and Koenning, S. R. and Barker, K. R.}, editor={R. D. Riggs and Wrather, J. A.Editors}, year={2004}, pages={89–110} }
 @article{barker_sorenson_2003, title={Cropping systems and Integrated Pest Management: Examples from selected crops}, volume={8}, ISBN={1092-678X}, DOI={10.1300/j144v08n01_11}, abstractNote={SUMMARY Cropping systems have been central to managing associated pests for centuries. This treatment focuses on the history, concepts, and the integration of available Integrated Pest Management (IPM) tools/strategies into cropping systems. Pest assessments/diagnoses, IPM-decision-making aids, and examples of pest management in selected crops/cropping systems (wheat, soybean, corn, cotton, potato, and strawberry) as well as emerging opportunities and challenges are discussed. The evolving philosophy of IPM and the recently renewed emphasis on ecologically based pest management address the fact that significant levels of predation and/or parasitism are desirable insofar as they promote diversity and sustainability of agroecosystems. Thus, cropping systems are beginning to focus on soil and crop health as well as specific IPM and production goals. Although extensive efforts have been directed toward modeling the many interactions between crops, associated pests and the environment, the general implementati...}, number={1}, journal={Journal of Crop Production}, author={Barker, K. R. and Sorenson, C.}, year={2003}, pages={271} }
 @article{koenning_edmisten_barker_bowman_morrison_2003, title={Effects of rate and time of application of poultry litter on Hoplolaimus columbus on cotton}, volume={87}, ISSN={["0191-2917"]}, DOI={10.1094/PDIS.2003.87.10.1244}, abstractNote={ Field experiments were conducted to evaluate the effect of soil-incorporated poultry litter on the population dynamics of Hoplolaimus columbus and cotton lint yield. Rates of poultry litter applied varied from 0.0 to 27.0 t/ha and were applied in December, February, or March. Time of application did not influence population densities of this nematode or cotton yield. The rate of poultry litter applied was negatively related to the population density of H. columbus at midseason, but not at other sampling dates. The lower midseason levels of this nematode corresponded with increases in cotton lint yield in all experiments. Cotton yield increases generally were linear with respect to the rate of litter applied, although the highest rates of litter applied did not always result in the greatest cotton yield. Poultry litter can be used effectively to supply nutrients to the crop and suppress damaging levels of H. columbus. Optimal rates of litter application were from 6.0 to 13.4 t/ha. Application of poultry litter at these rates, however, may exceed nutrient levels required for best management practices. }, number={10}, journal={PLANT DISEASE}, author={Koenning, SR and Edmisten, KL and Barker, KR and Bowman, DT and Morrison, DE}, year={2003}, month={Oct}, pages={1244–1249} }
 @article{koenning_edmisten_barker_morrison_2003, title={Impact of cotton production systems on management of Hoplolaimus columbus}, volume={35}, number={1}, journal={Journal of Nematology}, author={Koenning, S. R. and Edmisten, K. L. and Barker, K. R. and Morrison, D. E.}, year={2003}, pages={73–77} }
 @misc{barker_2003, title={Perspectives on plant and soil nematology}, volume={41}, number={2003}, journal={Annual Review of Phytopathology}, author={Barker, K. R.}, year={2003}, pages={25-} }
 @article{bulluck_barker_ristaino_2002, title={Influences of organic and synthetic soil fertility amendments on nematode trophic groups and community dynamics under tomatoes}, volume={21}, ISSN={["1873-0272"]}, url={http://www.scopus.com/inward/record.url?eid=2-s2.0-0036784082&partnerID=MN8TOARS}, DOI={10.1016/S0929-1393(02)00089-6}, abstractNote={Research was conducted to examine the effects of organic and synthetic soil amendments and tillage on nematode communities in field soils planted to tomato (Lycopersicon esculentum) at two locations. The experimental design was a replicated split plot with chisel-plow tillage and bare-soil or chisel-plow tillage and surface mulch with wheat straw as main plots, and soil amendments of synthetic fertilizer, composted cotton-gin trash, swine manure, or a rye-vetch green manure as subplots. Tillage did not affect free-living or plant-parasitic nematode community dynamics, but soil amendments had a large impact on nematode community structure and diversity. Populations of bacterivorous nematodes mainly in the Rhabditidae and Cephalobidae, and fungivorous nematodes were greater after planting in soils amended with swine manure, composted cotton-gin trash, or rye-vetch, than in soils amended with synthetic fertilizer at both locations. Populations of nematodes in these trophic groups decreased through time in each year. Populations of Meloidogyne incognita in soil were not affected by soil amendments, but increased through time at each location. Root-gall indices were lower in plots containing swine manure or cotton-gin trash than in those with synthetic fertilizer or rye-vetch during the second season. The combined nematode maturity index values were greater at planting in soils amended with rye-vetch or fertilizer than in soils with swine manure and composted cotton-gin trash. Shannon’s diversity index decreased over time for both years at one location, regardless of soil amendment. At the second location, the Shannon’s diversity index decreased only in the second year. Use of descriptive indices, including the Enrichment index, structure index, and channel index provided useful information about the effects of organic amendments on the structure of nematode communities in tomato field soils.}, number={3}, journal={APPLIED SOIL ECOLOGY}, author={Bulluck, LR and Barker, KR and Ristaino, JB}, year={2002}, pages={233–250} }
 @article{stalker_beute_shew_barker_2002, title={Registration of two root-knot nematode-resistant peanut germplasm lines}, volume={42}, DOI={10.2135/cropsci2002.312a}, abstractNote={Crop ScienceVolume 42, Issue 1 p. 312-313 Registration of Germplasm Registration of Two Root-Knot Nematode-Resistant Peanut Germplasm Lines H.T. Stalker, Corresponding Author H.T. Stalker hts@unity.ncsu.edu Dep. of Crop Science, North Carolina State Univ., Raleigh, NC, 27695-7629Corresponding author (hts@unity.ncsu.edu)Search for more papers by this authorM.K. Beute, M.K. Beute Dep. of Plant Pathology, North Carolina State Univ., Raleigh, NC, 27695-7629Search for more papers by this authorB.B. Shew, B.B. Shew Dep. of Plant Pathology, North Carolina State Univ., Raleigh, NC, 27695-7629Search for more papers by this authorK.R. Barker, K.R. Barker Dep. of Plant Pathology, North Carolina State Univ., Raleigh, NC, 27695-7629Search for more papers by this author H.T. Stalker, Corresponding Author H.T. Stalker hts@unity.ncsu.edu Dep. of Crop Science, North Carolina State Univ., Raleigh, NC, 27695-7629Corresponding author (hts@unity.ncsu.edu)Search for more papers by this authorM.K. Beute, M.K. Beute Dep. of Plant Pathology, North Carolina State Univ., Raleigh, NC, 27695-7629Search for more papers by this authorB.B. Shew, B.B. Shew Dep. of Plant Pathology, North Carolina State Univ., Raleigh, NC, 27695-7629Search for more papers by this authorK.R. Barker, K.R. Barker Dep. of Plant Pathology, North Carolina State Univ., Raleigh, NC, 27695-7629Search for more papers by this author First published: 01 January 2002 https://doi.org/10.2135/cropsci2002.312aCitations: 19 Registration by CSSA. Read the full textAboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinked InRedditWechat Citing Literature Volume42, Issue1January–February 2002Pages 312-313 RelatedInformation}, number={1}, journal={Crop Science}, author={Stalker, H. T. and Beute, M. K. and Shew, B. B. and Barker, K. R.}, year={2002}, pages={312–313} }
 @article{koenning_barker_bowman_2001, title={Resistance as a tactic for management of Meloidogyne incognita on cotton in North Carolina}, volume={33}, number={2-3}, journal={Journal of Nematology}, author={Koenning, S. R. and Barker, K. R. and Bowman, D. T.}, year={2001}, pages={126–131} }
 @article{jonathan_barker_abdel-alim_vrain_dickson_2000, title={Biological control of Meloidogyne incognita on tomato and banana with rhizobacteria actinomycetes, and Pasteuria penetrans}, volume={30}, number={2}, journal={Nematropica}, author={Jonathan, E. I. and Barker, K. R. and Abdel-Alim, F. F. and Vrain, T. C. and Dickson, D. W.}, year={2000}, pages={231–240} }
 @article{shen_li_he_barker_li_hunt_2000, title={Conversion of compatible plant-pathogen interactions into incompatible interactions by expression of the Pseudomonas syringae pv. syringae 61 hrmA gene in transgenic tobacco plants}, volume={23}, ISSN={["0960-7412"]}, DOI={10.1046/j.1365-313x.2000.00772.x}, abstractNote={Summary}, number={2}, journal={PLANT JOURNAL}, author={Shen, SH and Li, QS and He, SY and Barker, KR and Li, DB and Hunt, AG}, year={2000}, month={Jul}, pages={205–213} }
 @article{marin_barker_kaplan_sutton_opperman_2000, title={Development and evaluation of a standard method for screening for resistance to Radopholus similis in bananas}, volume={84}, ISSN={["0191-2917"]}, DOI={10.1094/pdis.2000.84.6.689}, abstractNote={ The description and evaluation of a standard assay method for screening for resistance of bananas to the burrowing nematode (Radopholus similis) under greenhouse conditions is presented. Seven banana genotypes, ranging from susceptible to resistant, were used to evaluate the method. Banana plants from tissue culture, grown in 0.4-liter Styrofoam cups containing sterilized sand as substrate, were maintained in the greenhouse for 4 weeks before inoculation. Two hundred burrowing nematodes, reared in monoxenic carrot-disk culture, were used as inoculum for each container. Plants were kept in the greenhouse for an additional 8 weeks at about 27°C and 80% relative humidity after inoculation. Burrowing nematodes reproduced well in the susceptible cultivars False Horn, Grande Naine, Valery, and Lacatan, whereas the reproductive fitness was very low in the resistant cultivars Pisang Jari Buaya and Yangambi. An intermediate reaction between these two groups was observed with Pisang mas. A similar trend was obtained in a follow-up field test, which indicated that the method is accurate and reliable. Assessments of total-root necrosis associated with this pathogen were also comparable between greenhouse and field conditions. However, nematode effects on the roots were more severe in the greenhouse test than in the field. In spite of low nematode reproductive fitness, root necrosis was relatively high in the two resistant cultivars tested in the greenhouse trial. }, number={6}, journal={PLANT DISEASE}, author={Marin, DH and Barker, KR and Kaplan, DT and Sutton, TB and Opperman, CH}, year={2000}, month={Jun}, pages={689–693} }
 @article{marin_barker_sutton_2000, title={Efficacy of 'ABG-9008' against burrowing nematode (Radopholus similis) on bananas}, volume={30}, number={1}, journal={Nematropica}, author={Marin, D. H. and Barker, K. R. and Sutton, T. B.}, year={2000}, pages={1–8} }
 @article{mcbride_mikkelsen_barker_2000, title={The role of low molecular weight organic acids from decomposing rye in inhibiting root-knot nematode populations in soil}, volume={15}, ISSN={["1873-0272"]}, DOI={10.1016/S0929-1393(00)00062-7}, abstractNote={Organic soil amendments have been employed as an alternative to or in combination with, chemical nematicides and cultural practices to control plant-parasitic nematodes. Rye (Secale cereale L.) has been shown to be effective in minimizing the damage caused by root-knot nematodes (Meloidogyne incognita (Kofoid and White) Chitwood) when grown as a cover crop and then incorporated into the soil prior to planting. It has been suggested that the release of low molecular weight organic acids during the decomposition of rye is the cause of the nematicidal effects. This study was conducted to quantify the concentration and persistence of formic, acetic, propionic, butyric, and valeric acids in soil solution following the incorporation of fresh rye foliage. Formic and acetic acids were detected by means of ion exclusion chromatography, primarily in the first 24 h following addition of rye, and at concentrations <450 μmol/l. The effect of the rye treatment on the root-knot nematode population was determined by growing tomato plants (Lycopersicon esculentum Mill.) in the rye-amended soil and assessing the nematode damage to the root systems. Despite the low concentrations of organic acids detected, the rye treatment resulted in a significant suppression of root-knot nematode activity. To determine the fate of these acids in soil, an addition of each acid was made to a field soil resulting in a soil water concentration of 1500 μmol/l for each acid. Soil solution samples were collected every 2 h for 10 h and analyzed for the five added organic acids by means of ion exclusion chromatography. The concentration of all acids declined by 54–97% over the 10 h incubation. Although low molecular weight organic acids may be one of many factors that contribute to restriction in root-knot nematode damage, these acids do not appear to be solely responsible for the nematicidal effect of the rye.}, number={3}, journal={APPLIED SOIL ECOLOGY}, author={McBride, RG and Mikkelsen, RL and Barker, KR}, year={2000}, month={Nov}, pages={243–251} }
 @article{koenning_barker_bowman_2000, title={Tolerance of selected cotton lines to Rotylenchulus reniformis}, volume={32}, number={4}, journal={Journal of Nematology}, author={Koenning, S. R. and Barker, K. R. and Bowman, D. T.}, year={2000}, pages={519–523} }
 @article{mcbride_mikkelsen_barker_1999, title={A comparison of three methods for determining root-knot nematode infection of cotton roots}, volume={29}, number={2}, journal={Nematropica}, author={McBride, R. G. and Mikkelsen, R. L. and Barker, K. R.}, year={1999}, pages={147–151} }
 @article{marin_barker_kaplan_sutton_opperman_1999, title={Aggressiveness and damage potential of Central American and Caribbean populations of Radopholus spp. in banana}, volume={31}, number={4}, journal={Journal of Nematology}, author={Marin, D. H. and Barker, K. R. and Kaplan, D. T. and Sutton, T. B. and Opperman, C. H.}, year={1999}, pages={377–385} }
 @article{ng'ambi_rufty_barker_1999, title={Genetic analysis of Meloidogyne arenaria race 1 resistance in tobacco}, volume={83}, ISSN={["1943-7692"]}, DOI={10.1094/PDIS.1999.83.9.810}, abstractNote={ Inheritance of resistance to the peanut root-knot nematode (Meloidogyne arenaria (Neal) Chitwood race 1) was investigated in the flue-cured tobacco cv. Speight G 28 and the breeding lines 81-RL-2K and SA 1214. The genetic relationship of this resistance in Speight G 28 to the resistance of the same cultivar to races 1 and 3 of M. incognita was also studied. Crosses were made between the root-knot nematode-susceptible flue-cured tobacco cv. NC 2326 and the three resistant genotypes. Parental, F1, F2 and backcross generations (BC1P1, BC1P2) were grown for each cross in randomized complete block designs with five replications in the greenhouse. Data indicated that resistance to M. arenaria race 1 in the three resistance sources is conditioned by a single dominant gene, but this resistance is partial compared to that for M. incognita races 1 and 3. Further, resistance to races 1 and 3 of M. incognita and resistance to M. arenaria race 1 in cv. Speight G 28 appear to be controlled by the same gene. These results, combined with the absence of segregation in the F2 populations of the crosses between resistant parents 81-RL-2K × SA 1214, 81-RL-2K × Speight G 28, and SA 1214 × Speight G 28, suggest allelism of resistance among these genotypes. }, number={9}, journal={PLANT DISEASE}, author={Ng'ambi, TBS and Rufty, RC and Barker, KR}, year={1999}, month={Sep}, pages={810–813} }
 @article{walters_wehner_barker_1999, title={Greenhouse and field resistance in cucumber to root-knot nematodes}, volume={1}, ISSN={["1388-5545"]}, DOI={10.1163/156854199508270}, abstractNote={
					Abstract
					Ten cultigens were evaluated for resistance to Meloidogyne arenaria races 1
						and 2, and M. javanica under greenhouse and field conditions. Resistance to
						M. arenaria races 1 and 2, and M. javanica was verified in Cucumis sativus
						var. hardwickii line LJ 90430 and to M. arenaria race 2 in C. sativus var.
						sativus Southern Pickler and Mincu in a greenhouse test. Another cultigen of
						C. sativus var. hardwickii (PI 215589) was found to be resistant to M.
						arenaria race 2 but not to other root-knot nematode species tested. LJ 90430
						is the cultigen of choice to develop root-knot nematode resistant cucumbers,
						since it has multiple root-knot nematode resistance and is cross-compatible
						with cucumber. Greenhouse and field data were positively correlated (r =
						0.74) over both years. Experiment repeatabilities were calculated from the
						cultigens infected with root-knot nematodes under both greenhouse and field
						conditions. Four environments (greenhouse and field over 2 years) were used
						in the analysis. Repeatabilities were high in all instances (ranging from
						0.83-0.99) and indicated that the environment (field or greenhouse) was not
						an important factor in assessing root-knot nematode resistance for the
						cultigens evaluated. Resistenz von Gurkengegen Wurzelgallennematoden im
						Gewachshaus undim Freiland - Unter Gewachshausund Freilandbedingungen wurden
						zehn Cultigene auf ihre Resistenz gegen Meloidogyne arenaria Rassen 1 und 2
						und gegen M. javanica gepruft. Bei Cucumis sativus var. hardwickii Linie LJ
						90430 wurde im Gewachshausversuch Resistenz gegen M. arenaria Rassen 1 und 2
						sowie gegen M. javanica nachgewiesen, und in C. sativus var. sativus
						"Southern Pickler" und "Mincu" Resistenz gegen M. arenaria Rasse 2. Cultigen
						C. sativus var. hardwickii (PI 215589) war resistent gegen M. arenaria Rasse
						2 aber nicht gegen die anderen gepruften Arten von Wurzelgallennematoden. LJ
						90430 ist das Cultigen der Wahl bei der Entwicklung von Gurken, die gegen
						Wurzelgallennematoden resistent sind, da es multiple Resistenzen gegen
						Wurzelgallennematoden besitzt und kreuzungsvertraglich mit Gurke ist. Die
						Ergebnisse der Gewachshaus- und Feldversuche waren uber beide Versuchsjahre
						hin positiv korreliert (r = 0,74). Ausgehend von den Cultigenen, die im
						Gewachshaus und im Freiland mit Wurzelgallennematoden infiziert waren,
						wurden die Wiederholbarkeiten der Versuche berechnet. Dabei wurden vier
						verschiedene Umweltbedingungen (Gewachshaus und Freiland uber zwei Jahre)
						verwendet. Die Wiederholbarkeiten waren in allen Fallen hoch (0,83-0,99) und
						zeigten an, dass die Umwelt (Freiland oder Gewachshaus) kein wichtiger
						Faktor bei der Bestimmung der Resistenz gegen Wurzelgallennematoden bei den
						gepruften Cultigenen war.
				}, number={1999 June}, journal={NEMATOLOGY}, author={Walters, SA and Wehner, TC and Barker, KR}, year={1999}, month={Jun}, pages={279–284} }
 @article{ng'ambi_rufty_barker_melton_1999, title={Identification of sources of resistance to four species of root-knot nematodes in tobacco}, volume={31}, number={3}, journal={Journal of Nematology}, author={Ng'ambi, T. B. S. and Rufty, R. C. and Barker, K. R. and Melton, T. A.}, year={1999}, pages={272–282} }
 @article{mcbride_mikkelsen_barker_1999, title={Survival and infection of root-knot nematodes added to soil amended with rye at different stages of decomposition and cropped with cotton}, volume={13}, ISSN={["0929-1393"]}, DOI={10.1016/S0929-1393(99)00041-4}, abstractNote={Abstract The incorporation of a rye ( Secale cereale L.) cover crop into the soil prior to planting cotton ( Gossypium hirsutum L.) has been shown to restrict damage caused by root-knot nematodes ( Meloidogyne incognita (Kofoid and White) Chitwood). A greenhouse study was conducted to determine the duration of the effectiveness of rye decomposition in controlling root-knot nematode damage in relation to the time between rye incorporation and cotton planting. Fresh, chopped-rye foliage was mixed into pots of soil and root-knot nematode eggs were added to the rye + soil mixture or a non-amended soil at 0, 1, 3, 5, 7, 9, 11, 13, 15, 17, 19, and 21 days following rye incorporation. This resulted in a sequence of pots containing nematode eggs exposed to rye at different stages of decomposition. Cotton plants were transplanted into the pots after the addition of nematode eggs and assessed for damage after 28 days of exposure. Although the effectiveness of the rye treatment declined over the 21 days of the incubation, the root-knot nematode populations were significantly reduced by the rye treatment for all planting dates. This suggests that it is not necessary to plant cotton immediately after plowing in a rye cover crop, thereby providing some flexibility in the cotton planting date, minimizing any associated phytotoxicity to the young cotton plants.}, number={3}, journal={APPLIED SOIL ECOLOGY}, author={McBride, RG and Mikkelsen, RL and Barker, KR}, year={1999}, month={Dec}, pages={231–235} }
 @misc{barker_koenning_1998, title={Developing sustainable systems for nematode management}, volume={36}, ISSN={["1545-2107"]}, DOI={10.1146/annurev.phyto.36.1.165}, abstractNote={ ▪ Abstract  Early researchers identified key concepts and developed tactics for multiple-option management of nematodes. Although the emphasis on integrated pest management over the past three decades has promoted strategies and tactics for nematode management, comprehensive studies on the related soil biology–ecology are relatively recent. Traditional management tactics include host resistance (where available), cultural tactics such as rotation with nonhosts, sanitation and avoidance, and destruction of residual crop roots, and the judicious use of nematicides. There have been advances in biological control of nematodes, but field-scale exploitation of this tactic remains to be realized. New technologies and resources are currently becoming central to the development of sustainable systems for nematode-pest-crop management: molecular diagnostics for nematode identification, genetic engineering for host resistance, and the elucidation and application of soil biology for general integrated cropping systems. The latter strategy includes the use of nematode-pest antagonistic cover crops, animal wastes, and limited tillage practices that favor growth-promoting rhizobacteria, earthworms, predatory mites, and other beneficial organisms while suppressing parasitic nematodes and other plant pathogens. Certain rhizobacteria may induce systemic host resistance to nematodes and, in some instances, to foliage pathogens. The systems focusing on soil biology hold great promise for sustainable crop-nematode management, but only a few research programs are currently involved in this labor-intensive endeavor. }, journal={ANNUAL REVIEW OF PHYTOPATHOLOGY}, author={Barker, KR and Koenning, SR}, year={1998}, pages={165–205} }
 @article{marin_sutton_barker_1998, title={Dissemination of bananas in Latin America and the Caribbean and its relationship to the occurrence of Radopholus similis}, volume={82}, ISSN={["0191-2917"]}, DOI={10.1094/PDIS.1998.82.9.964}, abstractNote={HomePlant DiseaseVol. 82, No. 9Dissemination of Bananas in Latin America and the Caribbean and Its Relationship to the Occurrence of Radophouls similis PreviousNext OPENOpen Access licenseDissemination of Bananas in Latin America and the Caribbean and Its Relationship to the Occurrence of Radophouls similisDouglas H. Marin, Turner B. Sutton, and Kenneth R. BarkerDouglas H. MarinSearch for more papers by this author, Turner B. SuttonSearch for more papers by this author, and Kenneth R. BarkerSearch for more papers by this authorAffiliationsAuthors and Affiliations Douglas H. Marin Turner B. Sutton Kenneth R. Barker , North Carolina State University, Raleigh Published Online:22 Feb 2007https://doi.org/10.1094/PDIS.1998.82.9.964AboutSectionsPDF ToolsAdd to favoritesDownload CitationsTrack Citations ShareShare onFacebookTwitterLinked InRedditEmailWechat DetailsFiguresLiterature CitedRelated Vol. 82, No. 9 September 1998SubscribeISSN:0191-2917e-ISSN:1943-7692 Metrics Article History Issue Date: 25 Jan 2008Published: 22 Feb 2007 Pages: 964-974 Information© 1998 The American Phytopathological SocietyPDF downloadCited byThe Dispersal of Bananas (Musa spp.) to the Americas in the Sixteenth Century10 November 2022 | Economic Botany, Vol. 76, No. 4Modelling the Influence of Climatic Factors on the Population Dynamics of Radopholus Similis: Banana-Plantain Pest8 July 2022 | Acta Biotheoretica, Vol. 70, No. 3Plant Parasitic Nematodes: A Major Constraint in Fruit Production2 March 2022Optimal and sustainable management of a soilborne banana pestApplied Mathematics and Computation, Vol. 397Towards consensus on the transfer of Fusarium oxysporum V5w2-enhanced tissue culture banana technology to farmers through public-private partnerships in East AfricaScientific African, Vol. 10Genetic Diversity of Fusarium oxysporum f. sp. cubense, the Fusarium Wilt Pathogen of Banana, in Ecuador1 September 2020 | Plants, Vol. 9, No. 9Modelling and control of a banana soilborne pest in a multi-seasonal frameworkMathematical Biosciences, Vol. 322The genome of the migratory nematode, Radopholus similis, reveals signatures of close association to the sedentary cyst nematodes25 October 2019 | PLOS ONE, Vol. 14, No. 10Nematostatic activity of root extracts of banana ( Musa spp.) genotypes as pre-infectional resistance mechanism against the burrowing nematode, Radopholus similis6 March 2018 | The Journal of Horticultural Science and Biotechnology, Vol. 94, No. 1Status of Pratylenchus coffeae in banana-growing areas of TanzaniaPhysiological and Molecular Plant Pathology, Vol. 105Pest risk assessment of Radopholus similis for the EU territoryEFSA Journal, Vol. 15, No. 8Associations of soil type and previous crop with plant-feeding nematode communities in plantain agrosystemsApplied Soil Ecology, Vol. 113Frequencies and population densities of plant-parasitic nematodes on banana (Musa AAA) plantations in Ecuador from 2008 to 20141 January 2016 | Agronomía Colombiana, Vol. 34, No. 1Scientific Opinion on the pest categorisation of Radopholus similis (Cobb) Thorne and Radopholus citrophilus Huettel, Dickson and Kaplan16 October 2014 | EFSA Journal, Vol. 12, No. 10Plant-parasitic nematodes as invasive species: characteristics, uncertainty and biosecurity implications14 September 2013 | Annals of Applied Biology, Vol. 271A historical overview of the appearance and spread of Musa pests and pathogens on the African continent: highlighting the importance of clean Musa planting materials and quarantine measures22 November 2012 | Annals of Applied Biology, Vol. 162, No. 1Niche partitioning based on soil type and climate at the landscape scale in a community of plant-feeding nematodesSoil Biology and Biochemistry, Vol. 44, No. 1Support for the ‘out-of-Southeast Asia’ hypothesis for the origin of Australian populations of Radopholus similis (Cobb, 1893) (Nematoda: Pratylenchidae)20 October 2010 | Systematic Parasitology, Vol. 77, No. 3Emerging molecular knowledge on Radopholus similis , an important nematode pest of bananaMolecular Plant Pathology, Vol. 11, No. 3Contrastant banana accessions for resistance to the burrowing nematode, based on molecular markers RAPD18 July 2009 | Euphytica, Vol. 172, No. 1Host range as an axis of niche partitioning in the plant-feeding nematode community of banana agroecosystemsSoil Biology and Biochemistry, Vol. 41, No. 6Nematode dispersion by runoff water: Case study of Radopholus similis (Cobb) Thorne on nitisol under humid tropical conditionsApplied Soil Ecology, Vol. 41, No. 2Integrated Management Of Banana NematodesManaging Nematodes In Citrus OrchardsChallenges in Tropical Plant NematologyAnnual Review of Phytopathology, Vol. 45, No. 1Frequency of occurrence and abundance of root nematodes on banana ( Musa AAA) in BelizeInternational Journal of Pest Management, Vol. 52, No. 1Liste des nématodes phytoparasites (Tylenchida et Dorylaimida) des départements français d’Amérique (Guadeloupe, Martinique et Guyane) et dispositions réglementaires19 December 2005 | EPPO Bulletin, Vol. 35, No. 3PLANT DISEASES CAUSED BY NEMATODESNematode Problems: Most Prevalent27 February 2004Population differentiation in the banana leaf spot pathogen Mycosphaerella musicola, examined at a global scalePlant Pathology, Vol. 52, No. 6}, number={9}, journal={PLANT DISEASE}, author={Marin, DH and Sutton, TB and Barker, KR}, year={1998}, month={Sep}, pages={964–974} }
 @article{koenning_coble_bradley_barker_schmitt_1998, title={Effects of a low rate, of aldicarb on soybean and associated pest interactions in fields infested with Heterodera glycines}, volume={28}, number={2}, journal={Nematropica}, author={Koenning, S. R. and Coble, H. D. and Bradley, J. R. and Barker, K. R. and Schmitt, D. P.}, year={1998}, pages={205–211} }
 @inbook{barker_mcgawley_1998, title={Interrelations with other microorganisms and pests}, booktitle={The cyst nematodes}, publisher={Dordrecht ; Boston: Kluwer Academic Publishers}, author={Barker, K. R. and McGawley, E. C.}, year={1998}, pages={266–292} }
 @inbook{barker_1998, title={Introduction and synopsis of advancements in nematology}, booktitle={Plant and nematode interactions}, publisher={Madison, Wis.: American Society of Agronomy, Inc.: Crop Science Society of America, Inc.: Soil Science Society of  America, Inc.}, author={Barker, K. R.}, editor={K. R. Barker, G. A. Pederson and Windham, G. L.Editors}, year={1998}, pages={1–20} }
 @article{koenning_bailey_schmitt_barker_1998, title={Management of plant-parastic nematodes on peanut with selected nematicides in North Carolina}, volume={30}, number={4 suppl.}, journal={Journal of Nematology}, author={Koenning, S. R. and Bailey, J. E. and Schmitt, D. P. and Barker, K. R.}, year={1998}, pages={643–650} }
 @book{plant and nematode interactions_1998, publisher={Madison, Wis.: American Society of Agronomy, Inc.; Crop Science Society of America, Inc.; Soil Science Society of America, Inc.}, year={1998} }
 @article{koenning_barker_1998, title={Survey of Heterodera glycines races and other plant-parastic nematodes on soybean in North Carolina}, volume={30}, number={4, Suppl.}, journal={Journal of Nematology}, author={Koenning, S. R. and Barker, K. R.}, year={1998}, pages={569–576} }
 @article{dong_barker_opperman_1997, title={Genetics of soybean-Heterodera glycines interactions}, volume={29}, number={4}, journal={Journal of Nematology}, author={Dong, K. and Barker, K. R. and Opperman, C. H.}, year={1997}, pages={509–522} }
 @article{barker_1997, title={Opportunities for integrated management of plant-parasitic nematodes in the Near East}, number={144}, journal={FAO Plant Production and Protection Paper}, author={Barker, K. R.}, year={1997}, pages={93} }
 @article{barker_hussey_krusberg_bird_dunn_ferris_ferris_freckman_gabriel_grewal_et al._1994, title={Plant and soil nematodes: Societal impact and focus for the future}, volume={26}, number={2}, journal={Journal of Nematology}, author={Barker, K. R. and Hussey, R. S. and Krusberg, L. R. and Bird, G. W. and Dunn, R. A. and Ferris, H. and Ferris, V. R. and Freckman, D. W. and Gabriel, C. J. and Grewal, P. S. and et al.}, year={1994} }
 @article{barker_1993, title={Resistance/tolerance and related concepts/terminology in plant nematology}, volume={77}, number={2}, journal={Plant Disease}, author={Barker, K. R.}, year={1993}, pages={111} }
 @article{barker_1993, title={The future of nematology: Introduction}, volume={25}, number={3}, journal={Journal of Nematology}, author={Barker, K. R.}, year={1993}, pages={365} }
 @article{barker_weeks_1991, title={Relationships between soil and levels of Meloidogyne incognita and tobacco yield and quality}, volume={23}, number={1}, journal={Journal of Nematology}, author={Barker, K. R. and Weeks, W. W.}, year={1991}, pages={82} }
 @article{barker_1991, title={Rotation and cropping systems for nematode control: The North Carolina experience - Introduction}, volume={23}, number={3}, journal={Journal of Nematology}, author={Barker, K. R.}, year={1991}, pages={342} }
 @article{barker_1989, title={Yield relationships and population dynamics of Meloidogyne spp. on flue-cured tobacco}, volume={21}, number={4}, journal={Journal of Nematology}, author={Barker, K. R.}, year={1989}, pages={597} }
 @inbook{barker_noe_1988, title={Techniques in quantitative nematology}, ISBN={3540181288}, booktitle={Experimental techniques in plant disease epidemiology}, publisher={Berlin: Springer-Verlag}, author={Barker, K. R. and Noe, J. P.}, editor={J. Kranz and Rotem, J.Editors}, year={1988}, pages={223} }
 @article{barker_daughtry_corbett_1979, title={Equipment and techniques for establishing field microplots for the study of soilborne pathogens}, volume={11}, number={1}, journal={Journal of Nematology}, author={Barker, K. R. and Daughtry, B. I. and Corbett, D. W.}, year={1979}, pages={106} }
 @article{byrd_barker_ferris_nusbaum_griffin_small_stone_1976, title={2 semiautomatic elutriators for extracting nematodes and certain fungi from soil}, volume={8}, number={3}, journal={Journal of Nematology}, author={Byrd, D. W. and Barker, K. R. and Ferris, H. and Nusbaum, C. J. and Griffin, W. E. and Small, R. H. and Stone, C. A.}, year={1976}, pages={206–212} }
 @article{hussey_barker_1973, title={Comparison of methods of collecting inocula of meloidogyne-spp, including a new technique}, volume={57}, number={12}, journal={Plant Disease Reporter}, author={Hussey, R. S. and Barker, K. R.}, year={1973}, pages={1025–1028} }
 @article{barker_lehman_huisingh_1971, title={INFLUENCE OF NITROGEN AND RHIZOBIUM-JAPONICUM ON ACTIVITY OF HETERODERA-GLYCINES}, volume={17}, ISSN={["0028-2596"]}, DOI={10.1163/187529271X00602}, abstractNote={Greenhouse experiments were conducted to determine the effects of source and concentration of nitrogen (N) as well as inoculation of soybean with Rhizobium japonicum (R) on the activity of Heterodera glycines (SCN). The application of NaNO3 or NH4NO3 at 56 to 896 ppm N to soil or silica sand reduced nematode hatch, penetration and "cyst" development of SCN on soybean. Inhibitory effects were positively correlated with concentration of N. Concentrations of > 112 ppm N also reduced numbers of eggs per cyst. High concentrations of NaCl also resulted in slight inhibition of nematode penetration of host roots as compared to demineralized water. Since most N concentrations used (56-225 ppm) were below those necessary to give an osmotic inhibitory effect on nematode activity and since R also interfered with nematode development, it was concluded that N has a direct inhibitory effect on SCN. Simultaneous inoculations of nodulating (Nod) and nonnodulating (Nonnod) isogenic lines of soybean with R and SCN (minus N), as compared to SCN alone, reduced the number of cysts developing especially on the Nod line.}, number={3}, journal={NEMATOLOGICA}, author={BARKER, KR and LEHMAN, PS and HUISINGH, D}, year={1971}, pages={377-&} }