interactsWith

Recent claims (top 200)

• Oryza sativa interactsWith Solanum lycopersicum

  “Growing tomato after paddy rice reduces the incidence of diseases and nematodes”

  Sukprakarn S., Juntakool S., Huang R., Kalb T. (2006) #6496216

• Solanum lycopersicum interactsWith Solanum lycopersicum

  “Avoid fields where the previous crop was tomato”

  Sukprakarn S., Juntakool S., Huang R., Kalb T. (2006) #6496215

• Plantae (kingdom) interactsWith Insecta (class)

  “Nectar and pollen from the flowers help natural enemies survive and reproduce”

  Luther G.C., Srinivasan R. (2010) #6496213

• Capsicum annuum interactsWith Capsicum annuum

  “Ne jamais planter le piment après...le poivron”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496187

• Solanum aethiopicum interactsWith Capsicum annuum

  “Ne jamais planter le piment après...l'aubergine africaine”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496186

• Solanum nigrum interactsWith Capsicum annuum

  “Ne jamais planter le piment après...la morelle”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496185

• Solanum lycopersicum interactsWith Capsicum annuum

  “Ne jamais planter le piment après...la tomate”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496184

• Solanum tuberosum interactsWith Capsicum annuum

  “Ne jamais planter le piment après la pomme de terre”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496183

• Capsicum annuum interactsWith Solanum macrocarpon

  “éviter les parcelles ayant précédemment reçu une solanacée”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496177

• Solanum lycopersicum interactsWith Solanum macrocarpon

  “éviter les parcelles ayant précédemment reçu une solanacée”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496176

• Solanum nigrum interactsWith Solanum aethiopicum

  “éviter les parcelles ayant précédemment reçu une solanacée”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496170

• Capsicum annuum interactsWith Solanum aethiopicum

  “éviter les parcelles ayant précédemment reçu une solanacée (tomate, piment...)”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496169

• Solanum lycopersicum interactsWith Solanum aethiopicum

  “éviter les parcelles ayant précédemment reçu une solanacée”

  Kouamé C., Kamga R., Wanduku N., Chendjou R. #6496168

• Zea mays interactsWith Bemisia tabaci

  “Maize also can be grown as a barrier crop along the borders”

  Macharia J., Titley M., Aloyce A., Samali S. (2016) · p. 2 #6496138

• Malvaceae (family) interactsWith Abelmoschus esculentus

  “weeds (Malvaceae) that act as an alternative host to the Cercospora pathogen”

  World Vegetable Center West and Central Africa (2017) · p. 2 #6496124

• Beta vulgaris interactsWith Beta vulgaris

  “Beet and Swiss chard will cross-pollinate so isolate these”

  Kalb T., Sukprakarn S., Juntakool S., Huang R. (2006) #6496121

• Solanum melongena interactsWith Capsicum annuum

  “Do not grow sweet pepper in the same plot after tomato or eggplant.”

  Bosco J., Wame L., Joshi R.C., Palada M.C., Gniffke P., Luther G., Suimae D., Tutua J., Koito O., Amiki R. (2009) #6496101

• Solanum lycopersicum interactsWith Capsicum annuum

  “Do not grow sweet pepper in the same plot after tomato or eggplant.”

  Bosco J., Wame L., Joshi R.C., Palada M.C., Gniffke P., Luther G., Suimae D., Tutua J., Koito O., Amiki R. (2009) #6496100

• Abelmoschus esculentus interactsWith Abelmoschus manihot

  “Do not grow slippery cabbage in the same plot after okra or plantain.”

  Tutua J., Joshi R.C., Wang J.-F., Javier E., Luther G., Ladota'a J., Sala J., Maivin J., Amiki R., Ho'ota M., Sulifoa J.B., Wame L. (2009) #6496092

• Formicidae (family) interactsWith Lagenaria siceraria

  “Presence of ants due to honey dew”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496082

• Zea mays interactsWith Solanum lycopersicum

  “Rotate with non-host crops, such as rice and maize”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496071

• Oryza sativa interactsWith Solanum lycopersicum

  “Rotate with non-host crops, such as rice and maize”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496070

• Cicer arietinum interactsWith Solanum lycopersicum

  “alternate host plants such as cotton, pigeon pea, chickpea”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496069

• Cajanus cajan interactsWith Solanum lycopersicum

  “alternate host plants such as cotton, pigeon pea, chickpea”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496068

• Gossypium spp. interactsWith Solanum lycopersicum

  “Availability of alternate host plants such as cotton, pigeon pea, chickpea”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496067

• Pennisetum glaucum interactsWith Solanum lycopersicum

  “Sow 5-6 rows of barrier crops like maize, jowar or bajra”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496066

• Sorghum bicolor interactsWith Solanum lycopersicum

  “Sow 5-6 rows of barrier crops like maize, jowar or bajra”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496065

• Zea mays interactsWith Solanum lycopersicum

  “Sow 5-6 rows of barrier crops like maize, jowar or bajra around the tomato plot”

  AVRDC - The World Vegetable Center, SRTT Project · p. 2 #6496064

• Oryza sativa interactsWith Capsicum annuum

  “preceding paddy rice crop is often helpful in that the flooded soil is depleted of many soil-borne pathogens”

  Berke T., Black L.L., Talekar N.S., Wang J.F., Gniffke P., Green S.K., Wang T.C., Morris R. (2005) · p. 1 #6496061

• Solanum tuberosum interactsWith Capsicum annuum

  “another solanaceous crop such as tomato, eggplant, or potato”

  Berke T., Black L.L., Talekar N.S., Wang J.F., Gniffke P., Green S.K., Wang T.C., Morris R. (2005) · p. 1 #6496060

• Solanum melongena interactsWith Capsicum annuum

  “avoid sequences in which peppers are planted immediately following another solanaceous crop”

  Berke T., Black L.L., Talekar N.S., Wang J.F., Gniffke P., Green S.K., Wang T.C., Morris R. (2005) · p. 1 #6496059

• Solanum lycopersicum interactsWith Capsicum annuum

  “avoid sequences in which peppers are planted immediately following another solanaceous crop such as tomato”

  Berke T., Black L.L., Talekar N.S., Wang J.F., Gniffke P., Green S.K., Wang T.C., Morris R. (2005) · p. 1 #6496058

• Momordica charantia interactsWith Formicidae (family)

  “presence of honey dew, which is often attended by ants”

  Dhillon N.P.S., Lin L.-J., Srimat S., Laenoi S., Ramasamy S., Kenyon L., Sheu Z.-M., Mecozzi M. (2021) · p. 9 #6496057

• semi-natural habitat interactsWith Arthropoda (phylum)

  “landscapes with higher proportions of semi-natural areas exhibited lower pest abundance”

  Veres A., Petit S., Conord C., Lavigne C. (2013) · p. 1 #6496020

• Vicia (genus) interactsWith predatory and parasitoid insects

  “rye, crimson clover, cahaba vetch”

  Clark A. (editor) (2007) · p. 26 #6495994

• Secale cereale interactsWith predatory and parasitoid insects

  “their presence protects beneficials”

  Clark A. (editor) (2007) · p. 27 #6495993

• Trifolium incarnatum interactsWith predatory and parasitoid insects

  “habitat that beneficials need”

  Clark A. (editor) (2007) · p. 27 #6495992

• Secale cereale interactsWith predatory arthropods

  “habitat that beneficials need. Properly managed cover”

  Clark A. (editor) (2007) · p. 27 #6495991

• Brassica napus interactsWith Syrphidae (family)

  “contribution to visitation by non-bees differed markedly (5-80%)”

  Rader R., Bartomeus I., Garibaldi L.A., Garratt M.P.D., Howlett B.G., Winfree R., Cunningham S.A., Mayfield M.M., et al. (2015) · p. 3 #6495989

• Trifolium subterraneum interactsWith Geocoris spp.

  “Cool season cover crops (berseem clover & subterranean clover) and common knotweed”

  Baier A., Dufour R., Guerena M., Van Epen K. (2004) · p. 4 #6495988

• Muhlenbergia rigens interactsWith Coccinellidae (family)

  “Deergrass and other clumping grasses are excellent habitats for overwintering ladybugs”

  Baier A., Dufour R., Guerena M., Van Epen K. (2004) · p. 3 #6495987

• Helianthus annuus interactsWith Coccinellidae (family)

  “yarrow and sunflowers”

  Baier A., Dufour R., Guerena M., Van Epen K. (2004) · p. 3 #6495986

• Anethum graveolens interactsWith Syrphidae (family)

  “adults eat pollen & nectar ... carrot family”

  Baier A., Dufour R., Guerena M., Van Epen K. (2004) · p. 3 #6495985

• Foeniculum vulgare interactsWith Chrysoperla carnea

  “carrot family — fennel, dill, Queen Anne's lace”

  Baier A., Dufour R., Guerena M., Van Epen K. (2004) · p. 3 #6495984

• Coriandrum sativum interactsWith Syrphidae (family)

  “coriander (Coriander sativum)--reduced lacebug numbers because of the buildup of syrphids”

  Dufour R. (2000) · p. 33 #6495982

• Sorghum bicolor interactsWith Hippodamia convergens

  “general influx of generalist predators ... from sorghum to cotton”

  Dufour R. (2000) · p. 33 #6495981

• Brassica oleracea var. acephala interactsWith Plutella xylostella

  “more attractive to egglaying adult female diamond back moths”

  Dufour R. (2000) · p. 33 #6495980

• Vicia faba interactsWith Hymenoptera (order)

  “such as faba beans, cowpeas, vetch ... provide beneficials with easy access”

  Dufour R. (2000) · p. 5 #6495979

• Lobularia maritima interactsWith Diaeretiella rapae

  “provides a good food source for parasitic wasps”

  Dufour R. (2000) · p. 30 #6495978

• Phacelia tanacetifolia interactsWith Syrphidae (family)

  “Phacelia tanacetifolia ... a good source of pollen for syrphids”

  Dufour R. (2000) · p. 33 #6495977

• Acacia koa interactsWith Silvanidae

  “koa (Acacia koa) are potential host plants of flat bark beetles”

  Kawabata A., Follett P., Wright M., Brill E., Curtiss R.T. (2016) · p. 2 #6495976

• Samanea saman interactsWith Silvanidae

  “monkeypod (Samanea saman)... are potential host plants of flat bark beetles”

  Kawabata A., Follett P., Wright M., Brill E., Curtiss R.T. (2016) · p. 2 #6495975

• Leucaena leucocephala interactsWith Cathartus quadricollis

  “adults and larvae have been found in the seedpods of koa haole”

  Kawabata A., Follett P., Wright M., Brill E., Curtiss R.T. (2016) · p. 2 #6495974

• Sorghum bicolor interactsWith Insecta

  “cotton bollworms being controlled by predators in sorghum plots adjacent to cotton”

  Kuepper G., Dodson M., Duncan J. (2016) · p. 5 #6495973

• Trifolium incarnatum interactsWith Araneae (order)

  “increases the amount of spiders that patrol the broccoli plants”

  Kuepper G., Dodson M., Duncan J. (2016) · p. 6 #6495972

• Fagopyrum esculentum interactsWith Insecta

  “Buckwheat suppresses weeds and attracts beneficial insects”

  Kuepper G., Dodson M., Duncan J. (2016) · p. 1 #6495971

• Musa spp. interactsWith Cecidomyiidae (family)

  “fivefold increase in the density of banana/plantain clusters intercropped with cocoa”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology #6495970

• Lamiaceae (family) interactsWith predatory arthropods

  “intercropping with aromatic plants decreases herbivore abundance”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology #6495969

• Trifolium incarnatum interactsWith Solanum lycopersicum

  “strip-tilling crimson clover since 1985 to raise tomatoes”

  Clark A. (editor) (2007) · p. 27 #6495965

• Secale cereale interactsWith weeds

  “Rye provides control of disease, weed and nematode threats”

  Clark A. (editor) (2007) · p. 26 #6495964

• Sinapis alba interactsWith weeds

  “winter smother crop of yellow mustard minimizes weed”

  Clark A. (editor) (2007) #6495963

• Vicia villosa interactsWith Solanum tuberosum

  “80 to 100 percent of a subsequent potato crop's nitrogen requirement”

  Clark A. (editor) (2007) #6495962

• Vicia villosa interactsWith Zea mays

  “167 bu./A for hairy vetch, compared with a no legume/no N fertilizer yield of 134”

  Clark A. (editor) (2007) #6495961

• Trifolium pratense interactsWith Zea mays

  “Medium red clover companion seeded with oats... 163 bu./A for red clover”

  Clark A. (editor) (2007) #6495960

• Sorghum bicolor x sudanense interactsWith Solanum lycopersicum

  “Sorghum-sudangrass... powerfully fracture... nematodes”

  Clark A. (editor) (2007) #6495959

• Apis mellifera interactsWith Apoidea (superfamily)

  “managed honeybees can negatively impact wild bees through competition for floral resources”

  Garibaldi L.A., et al. (2024) · Impact of pesticide use on wild bee distributions across the United States · p. 1325 #6495808

• Faidherbia albida interactsWith Plantae (kingdom)

  “tree fixes nitrogen through its roots and has a positive effect on soil fertility”

  FAO (2011) · p. 5 #6495786

• Ipomoea batatas interactsWith Fabaceae (family)

  “Sweetpotato residues may prevent nodulation in nitrogen fixing crops”

  Valenzuela, Hector; Fukuda, Steven; Arakaki, Alton (1994) · p. 4 #6495732

• Ipomoea batatas interactsWith Sorghum bicolor

  “sweetpotato has been shown to reduce the growth of...sorghum”

  Valenzuela, Hector; Fukuda, Steven; Arakaki, Alton (1994) · p. 8 #6495731

• Ipomoea batatas interactsWith Cyperus esculentus

  “sweetpotato has been shown to reduce the growth of the yellow nutsedge”

  Valenzuela, Hector; Fukuda, Steven; Arakaki, Alton (1994) · p. 8 #6495730

• Phaseolus vulgaris interactsWith Zea mays

  “the crop was usually planted between the corn rows at the last cultivation”

  Krauss F.G. (1932) · p. 61 #6495630

• Mucuna pruriens interactsWith Asparagus officinalis

  “planting a row of cowpeas or velvet beans between the rows”

  Krauss F.G. (1932) · p. 59 #6495629

• Vigna unguiculata interactsWith Asparagus officinalis

  “asparagus patch may be green-manured, by planting a row of cowpeas”

  Krauss F.G. (1932) · p. 59 #6495628

• Juglans nigra interactsWith Lactuca sativa

  “juglone—suppress the growth of a wide range of other plants”

  Kuepper G., Dodson M., Duncan J. (2016) · p. 7 #6495597

• Secale cereale interactsWith Cucumis melo

  “melon yield is enhanced, weed pressures are lowered”

  Kuepper G., Dodson M., Duncan J. (2016) · p. 7 #6495596

• Trifolium incarnatum interactsWith Brassica oleracea var. italica

  “increases the amount of spiders that patrol the broccoli plants”

  Kuepper G., Dodson M., Duncan J. (2016) · p. 6 #6495595

• Vicia faba interactsWith Zea mays

  “Maize/Faba bean intercropping with Rhizobia inoculation enhances productivity”

  Kuepper G., Dodson M., Duncan J. (2016) · p. 5 #6495594

• Phaseolus vulgaris interactsWith Solanum tuberosum

  “beans did the opposite”

  Kuepper G., Dodson M., Duncan J. (2016) · p. 5 #6495593

• Desmodium spp. interactsWith Zea mays

  “Inclusion of a Desmodium companion crop triples corn yield”

  Kuepper G., Dodson M., Duncan J. (2016) #6495592

• Vicia faba interactsWith Triticum aestivum

  “secrete organic acids and phosphatases into the rhizosphere, thereby increasing soil P availability”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology #6495582

• Cucurbita spp. interactsWith Phaseolus vulgaris

  “the 'three sisters' polyculture of maize, beans and squash”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology #6495581

• Phaseolus vulgaris interactsWith Zea mays

  “legumes can contribute up to 15% of the N in an intercropped cereal”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology #6495580

• Cucurbita spp. interactsWith Zea mays

  “Squash acts as groundcover during the early season, reducing competition with early-season weeds”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology #6495579

• Fusarium oxysporum interactsWith Pseudomonas fluorescens CHA0

  “fusaric acid which downregulates the production of the antibiotic compound DAPG”

  Berendsen R.L., Pieterse C.M.J., Bakker P.A.H.M. (2012) · p. 482 #6495565

• Tithonia diversifolia interactsWith Elaeis guineensis

  “fertilizer species, including inga, gliricidia and Mexican sunflower”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 145 #6495545

• Arachis pintoi interactsWith Theobroma cacao

  “Pinto peanut, a forage legume, can also be planted as a ground-cover crop”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 143 #6495544

• Imperata cylindrica interactsWith tree seedlings (Dipterocarpaceae)

  “highly invasive grasses such as Imperata cylindrica”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 149 #6495543

• Pterocarpus indicus interactsWith Musa textilis

  “grown under nitrogen-fixing trees such as Erythrina fusca and narra”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 151 #6495542

• Erythrina fusca interactsWith Musa textilis

  “grown under nitrogen-fixing trees such as Erythrina fusca and narra”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 151 #6495541

• Leucaena leucocephala interactsWith Theobroma cacao

  “shade (Inga spp., gliricidia, leucaena)”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 141 #6495540

• Gliricidia sepium interactsWith Theobroma cacao

  “shade (Inga spp., gliricidia, leucaena)”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 141 #6495539

• Inga spp. interactsWith Theobroma cacao

  “shade (Inga spp., gliricidia, leucaena)”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 141 #6495538

• Acacia spp. interactsWith associated agroforestry components

  “eucalypts and acacias use a lot of water”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 120 #6495536

• Eucalyptus spp. interactsWith associated agroforestry components

  “fast-growing types of trees such as eucalypts and acacias use a lot of water”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 120 #6495535

• Calliandra calothyrsus interactsWith annual food crops

  “leguminous shrubs such as calliandra with the crops to support soil fertility”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 130 #6495534

• Cordia alliodora interactsWith Coffea arabica

  “coffee with erythrina pollards and laurel in Costa Rica”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 111 #6495533

• Erythrina spp. interactsWith Coffea arabica

  “coffee with erythrina pollards and laurel in Costa Rica”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 111 #6495532

• Chrysopogon zizanioides interactsWith agroforestry tree rows

  “Grasses like Napier and Vetiver can be planted between tree rows”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 57 #6495530

• Pennisetum purpureum interactsWith agroforestry tree rows

  “Grasses like Napier and Vetiver can be planted between tree rows”

  Gassner A., Dobie P. (eds.); Cornelius J.P., Coe R., Mercado A., Mukuralinda A., Okia C.A., Somarriba E., Thorne P., et al. (2022) · p. 57 #6495529

• cover crops interactsWith crop plants

  “increasing water quality by limiting nitrogen leaching loss”

  Tamburini G., Bommarco R., Wanger T.C., Kremen C., van der Heijden M.G.A., Liebman M., Hallin S. (2020) · Agricultural diversification promotes multiple ecosystem services without compromising yield · p. 4 #6495351

• intercropped plant species interactsWith crop plants

  “crop diversity improved (aboveground) biodiversity, pest control, nutrient cycling, and water regulation”

  Tamburini G., Bommarco R., Wanger T.C., Kremen C., van der Heijden M.G.A., Liebman M., Hallin S. (2020) · Agricultural diversification promotes multiple ecosystem services without compromising yield · p. 3 #6495350

• Triticum durum interactsWith Pisum sativum

  “Alternate-row intercropping of durum wheat and winter pea in France”

  Li C., Hoffland E., Kuyper T.W., Yu Y., Zhang C., Li H., Zhang F., van der Werf W. (2020) · Syndromes of production in intercropping impact yield gains · p. 2 #6495301

• Lens culinaris interactsWith Triticum aestivum

  “Mixed lentil/spring wheat intercropping at harvest”

  Li C., Hoffland E., Kuyper T.W., Yu Y., Zhang C., Li H., Zhang F., van der Werf W. (2020) · Syndromes of production in intercropping impact yield gains · p. 2 #6495300

• Pisum sativum interactsWith Triticum aestivum

  “Pea-wheat intercrops in low-input conditions combine high economic performances”

  Li C., Hoffland E., Kuyper T.W., Yu Y., Zhang C., Li H., Zhang F., van der Werf W. (2020) · Syndromes of production in intercropping impact yield gains · p. 6 #6495299

• Pisum sativum interactsWith Hordeum vulgare

  “Pea-barley intercropping for efficient symbiotic N2-fixation”

  Li C., Hoffland E., Kuyper T.W., Yu Y., Zhang C., Li H., Zhang F., van der Werf W. (2020) · Syndromes of production in intercropping impact yield gains · p. 5 #6495298

• Zea mays interactsWith Arachis hypogaea

  “pea... faba bean, soybean and peanut... most common companion species”

  Li C., Hoffland E., Kuyper T.W., Yu Y., Zhang C., Li H., Zhang F., van der Werf W. (2020) · Syndromes of production in intercropping impact yield gains · p. 3 #6495297

• Zea mays interactsWith Vicia faba

  “Legumes such as pea... faba bean... were the most common companion species”

  Li C., Hoffland E., Kuyper T.W., Yu Y., Zhang C., Li H., Zhang F., van der Werf W. (2020) · Syndromes of production in intercropping impact yield gains · p. 3 #6495296

• Zea mays interactsWith Pisum sativum

  “reduced N fertilizer input at the early cogrowth stage in maize/pea intercropping improves N2 fixation”

  Li C., Hoffland E., Kuyper T.W., Yu Y., Zhang C., Li H., Zhang F., van der Werf W. (2020) · Syndromes of production in intercropping impact yield gains · p. 5 #6495295

• Zea mays interactsWith Glycine max

  “intercrops with maize... yield gains... about four times as large”

  Li C., Hoffland E., Kuyper T.W., Yu Y., Zhang C., Li H., Zhang F., van der Werf W. (2020) · Syndromes of production in intercropping impact yield gains · p. 1 #6495294

• Poaceae (family) interactsWith Fabaceae (family)

  “cereals and grasses that release phytosiderophores can improve the acquisition of cationic micronutrients”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology · p. 110 #6495228

• Brassica spp. interactsWith Zea mays

  “brassica, maize, beet and squash, acidify their rhizosphere and secrete organic acids and phosphatases”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology · p. 110 #6495227

• Vigna unguiculata interactsWith Zea mays

  “peanut, cowpea, potato, sweet potato, maize, beans and brassica, secrete organic acids and phosphatases”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology · p. 110 #6495226

• Arachis hypogaea interactsWith Poaceae (family)

  “peanut, cowpea, potato, sweet potato, maize, beans and brassica, secrete organic acids and phosphatases into the rhizosphere”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology · p. 110 #6495225

• Cucurbita spp. interactsWith Phaseolus vulgaris

  “Squash acts as groundcover during the early season, reducing competition with early-season weeds and water losses by evaporation”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology · p. 109 #6495224

• Cucurbita spp. interactsWith Zea mays

  “Squash acts as groundcover during the early season, reducing competition with early-season weeds and water losses by evaporation”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology · p. 109 #6495223

• Phaseolus vulgaris interactsWith Zea mays

  “legumes can contribute up to 15% of the N in an intercropped cereal”

  Brooker R.W., Bennett A.E., Cong W.-F., Daniell T.J., George T.S., Hallett P.D., Hawes C., Iannetta P.P.M., Jones H.G., Karley A.J., Li L., McKenzie B.M., Pakeman R.J., Paterson E., Schob C., Shen J., Squire G., Watson C.A., Zhang C., Zhang F., Zhang J., White P.J. (2015) · Improving intercropping: a synthesis of research in agronomy, plant physiology and ecology · p. 110 #6495222

• Fabaceae (family) interactsWith Zea mays

  “legumes fix nitrogen benefiting companion crops in diversified systems”

  HLPE (High Level Panel of Experts on Food Security and Nutrition) (2019) · Agroecological and Other Innovative Approaches for Sustainable Agriculture and Food Systems that Enhance Food Security and Nutrition #6495211

• Phaseolus vulgaris interactsWith Zea mays

  “bean-maize milpa intercropping improved food security in Latin America”

  Bezner Kerr R., Madsen S., Stuber M., Liebert J., Enloe S., Borghino N., Parros P., Mutyambai D., Prudhon M., Wezel A. (2021) · Can agroecology improve food security and nutrition? A review #6495171

• Vigna unguiculata interactsWith Zea mays

  “cowpea-maize intercropping improved yields and dietary diversity”

  Bezner Kerr R., Madsen S., Stuber M., Liebert J., Enloe S., Borghino N., Parros P., Mutyambai D., Prudhon M., Wezel A. (2021) · Can agroecology improve food security and nutrition? A review #6495170

• Gliricidia sepium interactsWith Zea mays

  “Gliricidia green manure improved maize yields in Malawi”

  Bezner Kerr R., Madsen S., Stuber M., Liebert J., Enloe S., Borghino N., Parros P., Mutyambai D., Prudhon M., Wezel A. (2021) · Can agroecology improve food security and nutrition? A review #6495169

• Faidherbia albida interactsWith Sorghum bicolor

  “parkland trees improved sorghum yields in the Sahel”

  Bezner Kerr R., Madsen S., Stuber M., Liebert J., Enloe S., Borghino N., Parros P., Mutyambai D., Prudhon M., Wezel A. (2021) · Can agroecology improve food security and nutrition? A review #6495168

• Faidherbia albida interactsWith Zea mays

  “Faidherbia albida improved maize yields in Zambia and Malawi”

  Bezner Kerr R., Madsen S., Stuber M., Liebert J., Enloe S., Borghino N., Parros P., Mutyambai D., Prudhon M., Wezel A. (2021) · Can agroecology improve food security and nutrition? A review #6495167

• Leguminosae (family) interactsWith Zea mays

  “legume-maize intercropping improved yields through nitrogen fixation”

  Bezner Kerr R., Madsen S., Stuber M., Liebert J., Enloe S., Borghino N., Parros P., Mutyambai D., Prudhon M., Wezel A. (2021) · Can agroecology improve food security and nutrition? A review #6495166

• Desmodium spp. interactsWith Striga hermonthica

  “Desmodium suppresses Striga through allelopathic exudates”

  Bezner Kerr R., Madsen S., Stuber M., Liebert J., Enloe S., Borghino N., Parros P., Mutyambai D., Prudhon M., Wezel A. (2021) · Can agroecology improve food security and nutrition? A review #6495164

• Tithonia diversifolia interactsWith Zea mays

  “Tithonia green manure improved maize yields in sub-Saharan Africa”

  Bezner Kerr R., Madsen S., Stuber M., Liebert J., Enloe S., Borghino N., Parros P., Mutyambai D., Prudhon M., Wezel A. (2021) · Can agroecology improve food security and nutrition? A review #6495163

• Zea mays interactsWith Glycine max

  “rotating maize with soybean. Severe damage in maize caused by D. virgifera”

  Dent D. (2000) · Insect Pest Management, 2nd Edition · p. 335 #6494813

• Polygonum hydropiper interactsWith Aphididae (family)

  “polygodial, extracted from the water-pepper Polygonum hydropiper”

  Dent D. (2000) · Insect Pest Management, 2nd Edition #6494771

• Arbor (deep-rooted trees) interactsWith Plantae (shallow-rooted plants)

  “deep-rooted trees can transfer water from moist soil layers many meters deep to surface soil layers”

  Brady N.C., Weil R.R. (2017) · The Nature and Properties of Soils, Fifteenth Edition · p. 264 #6494222

• Formicidae (family) interactsWith Plantae (crops)

  “Ants and termites increase soil water supply and plant productivity in a semi-arid tropical”

  Brady N.C., Weil R.R. (2017) · The Nature and Properties of Soils, Fifteenth Edition · p. 260 #6494221

• Vicia villosa interactsWith Plantae (subsequent crops)

  “winter cover crop of hairy vetch; care may be needed to kill the cover crop before”

  Brady N.C., Weil R.R. (2017) · The Nature and Properties of Soils, Fifteenth Edition · p. 261 #6494220

• Cucurbita pepo interactsWith Zea mays

  “traditional corn-bean-squash intercrop brings together three different but complementary crops”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 189 #6494217

• Leguminosae (family) interactsWith Zea mays

  “nitrogen-fixing legumes and associated crop plants”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 189 #6494216

• Leguminosae (family) interactsWith Zea mays

  “cover crops particularly leguminous ones tilled into the soil, organic matter called green manure”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 175 #6494215

• Poaceae (family) interactsWith Zea mays

  “cover crops: reduced soil erosion, improved soil structure, enhanced soil fertility, suppression of weeds”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 175 #6494213

• Pseudomonas putida interactsWith Cucumis sativus

  “Cucumber seed treatment with Pseudomonas putida bacteria results in systemic production of phytoalexins.”

  Unknown (Unknown) · History of Plant Pathology and Early Significant Plant Diseases (Chapter 1 Introduction) · p. 414 #6494059

• cover crop (living mulch) interactsWith Poaceae (family)

  “Living mulches can provide and conserve nitrogen for grain crops, reduce soil erosion, reduce weed pressure”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 124 #6494056

• Medicago sativa interactsWith Zea mays

  “alternating it with a nitrogen-fixing leguminous crop like alfalfa can reduce the need for nitrogen-rich amendments”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 126 #6494055

• Fabaceae (family) interactsWith Poaceae (family)

  “When nitrogen-fixing legumes are used as cover crops, the quality of the biomass can be greatly improved.”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 123 #6494054

• Guiera senegalensis interactsWith Pennisetum glaucum

  “yield increases, especially during drought years, when intercropped with the hydraulic-redistributing native woody shrub”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 116 #6494049

• Medicago sativa interactsWith Lactuca sativa

  “chopped alfalfa added to soil stimulated the growth of tobacco, cucumber, and lettuce”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 105 #6494048

• Medicago sativa interactsWith Cucumis sativus

  “chopped alfalfa added to soil stimulated the growth of tobacco, cucumber, and lettuce”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 105 #6494047

• Medicago sativa interactsWith Nicotiana tabacum

  “chopped alfalfa added to soil stimulated the growth of tobacco, cucumber, and lettuce”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 105 #6494046

• Theobroma cacao interactsWith weeds

  “crushed pods leach tannic substances that can inhibit the germination”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 104 #6494045

• Mucuna pruriens interactsWith Zea mays

  “covering the soil with a nitrogen-rich mulch into which the next corn crop will be planted”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 103 #6494044

• Lemna spp. interactsWith crop (general)

  “duckweed (Lemna spp.)... applied as mulch”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition #6494039

• Eichhornia crassipes interactsWith crop (general)

  “water hyacinth (Eichornia crassipes)... can be pulled from the water and applied as mulch”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition #6494038

• Avena sativa interactsWith Vitis vinifera

  “mow the vetch/oat cover crop and mulch any vine or tree prunings”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition #6494037

• Vicia sativa interactsWith Vitis vinifera

  “mow the vetch/oat cover crop and mulch any vine or tree prunings”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition #6494036

• Isoptera (order) interactsWith Soil

  “Termites are especially important in the tropical agroecosystems of Africa and South America”

  Vandermeer J.H. (2009) · The Ecology of Agroecosystems · p. 196 #6494021

• Lumbricus terrestris interactsWith Soil

  “night crawler Lumbricus terrestris is an important... soil engineer”

  Vandermeer J.H. (2009) · The Ecology of Agroecosystems · p. 197 #6494020

• Avena sativa interactsWith Trifolium spp.

  “Clover seems to establish best around 50% of full sunlight”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 71 #6493994

• Erythrina poeppigiana interactsWith Coffea arabica

  “coffee is typically grown under the shade of trees, often species of the leguminous genus Erythrina”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition #6493993

• Cucurbita pepo interactsWith Weeds (functional group)

  “casting yet a deeper shade on the soil surface and aiding in weed control”

  Gliessman S.R. (2022) · Agroecology: The Ecology of Sustainable Food Systems, Fourth Edition · p. 70 #6493992

• Azolla spp. interactsWith Oryza sativa

  “let the Azolla grow on the surface, drain the paddy and incorporate the Azolla mulch”

  Vandermeer J.H. (2009) · The Ecology of Agroecosystems · p. 174 #6493991

• Zea mays interactsWith Solanum tuberosum

  “rotation with legumes, corn, or other unrelated crops reduces potato pathogens”

  Unknown (Unknown) · History of Plant Pathology and Early Significant Plant Diseases (Chapter 1 Introduction) · p. 350 #6493942

• Fabaceae (family) interactsWith Solanum tuberosum

  “rotation with legumes, corn, or other unrelated crops will reduce potato pathogens”

  Unknown (Unknown) · History of Plant Pathology and Early Significant Plant Diseases (Chapter 1 Introduction) · p. 350 #6493941

• Poa pratensis interactsWith Zea mays

  “the higher OM soil grew bluegrass sod during the same period”

  Brady N.C., Weil R.R. (2017) · The Nature and Properties of Soils, Fifteenth Edition · p. 172 #6493901

• Termitidae (family) interactsWith Plantae (kingdom)

  “Earthworms (and termites) move soil particles about, often ingesting them”

  Brady N.C., Weil R.R. (2017) · The Nature and Properties of Soils, Fifteenth Edition · p. 169 #6493900

• Capsicum annuum interactsWith Lumbricidae (family)

  “managed with cover crops and no-till techniques”

  Brady N.C., Weil R.R. (2017) · The Nature and Properties of Soils, Fifteenth Edition · p. 169 #6493899

• Lumbricidae (family) interactsWith Plantae (kingdom)

  “Earthworm burrows in the Bt horizon (60 cm depth)”

  Brady N.C., Weil R.R. (2017) · The Nature and Properties of Soils, Fifteenth Edition · p. 169 #6493898

• Vicia villosa interactsWith Zea mays

  “contribute nitrogen to the main crop”

  Andow D.A., Ragsdale D.W., Nyvall R.F. (1997) · Ecological Interactions and Biological Control · p. 178 #6493069

• Brassica rapa subsp. rapa interactsWith Bos taurus

  “fodder crop for livestock, the manure from which then raised the fertility”

  Fiebrig I.N. (ed.), Tornaghi C., McAllister G., Moeller N., Pedersen M., Sucholas J., Greinwald A., Ukhanova M., Luick R., Fiebrig I.N., van de Vijver M., van Kan C.J., Tilzey M., Stobart A., Prieto Garcia J., Vieweger A., Westaway S., Whistance L., Kümmritz S., Klocke B., Krähmer A., Johnson M., Sarabia L., Solorio F., Galindo F., González P., Sandoval Castro C.A., Torres F., Ku J., Păcurar F., Reif A., Ruşdea E., Nair M.N.B., Punniamurthy N., Venkatasubramanian P., Balasubramani S.P., Kukkupuni S.K., Weins C., Bombardi L., Peralta M.C.C., Bach A.E. (2023) · Medicinal Agroecology: Reviews, Case Studies, and Research Methodologies · p. 92 #6492926

• Mucuna pruriens interactsWith Zea mays

  “it has been shown to benefit main crop yield”

  Fiebrig I.N. (ed.), Tornaghi C., McAllister G., Moeller N., Pedersen M., Sucholas J., Greinwald A., Ukhanova M., Luick R., Fiebrig I.N., van de Vijver M., van Kan C.J., Tilzey M., Stobart A., Prieto Garcia J., Vieweger A., Westaway S., Whistance L., Kümmritz S., Klocke B., Krähmer A., Johnson M., Sarabia L., Solorio F., Galindo F., González P., Sandoval Castro C.A., Torres F., Ku J., Păcurar F., Reif A., Ruşdea E., Nair M.N.B., Punniamurthy N., Venkatasubramanian P., Balasubramani S.P., Kukkupuni S.K., Weins C., Bombardi L., Peralta M.C.C., Bach A.E. (2023) · Medicinal Agroecology: Reviews, Case Studies, and Research Methodologies · p. 70 #6492925

• Cucurbita spp. interactsWith Zea mays

  “intercropping agricultural system of corn, beans, and squash”

  Fiebrig I.N. (ed.), Tornaghi C., McAllister G., Moeller N., Pedersen M., Sucholas J., Greinwald A., Ukhanova M., Luick R., Fiebrig I.N., van de Vijver M., van Kan C.J., Tilzey M., Stobart A., Prieto Garcia J., Vieweger A., Westaway S., Whistance L., Kümmritz S., Klocke B., Krähmer A., Johnson M., Sarabia L., Solorio F., Galindo F., González P., Sandoval Castro C.A., Torres F., Ku J., Păcurar F., Reif A., Ruşdea E., Nair M.N.B., Punniamurthy N., Venkatasubramanian P., Balasubramani S.P., Kukkupuni S.K., Weins C., Bombardi L., Peralta M.C.C., Bach A.E. (2023) · Medicinal Agroecology: Reviews, Case Studies, and Research Methodologies #6492802

• Phaseolus spp. interactsWith Zea mays

  “intercropping agricultural system of corn, beans, and squash”

  Fiebrig I.N. (ed.), Tornaghi C., McAllister G., Moeller N., Pedersen M., Sucholas J., Greinwald A., Ukhanova M., Luick R., Fiebrig I.N., van de Vijver M., van Kan C.J., Tilzey M., Stobart A., Prieto Garcia J., Vieweger A., Westaway S., Whistance L., Kümmritz S., Klocke B., Krähmer A., Johnson M., Sarabia L., Solorio F., Galindo F., González P., Sandoval Castro C.A., Torres F., Ku J., Păcurar F., Reif A., Ruşdea E., Nair M.N.B., Punniamurthy N., Venkatasubramanian P., Balasubramani S.P., Kukkupuni S.K., Weins C., Bombardi L., Peralta M.C.C., Bach A.E. (2023) · Medicinal Agroecology: Reviews, Case Studies, and Research Methodologies #6492801

• Lumbricus terrestris interactsWith Plantae (kingdom)

  “facilitate aeration and water infiltration through their formation of burrows”

  Eldor A. Paul (editor); R.P. Voroney, R.J. Heck, Ken Killham, Jim Prosser, D. Lee Taylor, Robert L. Sinsabaugh, David C. Coleman, Diana H. Wall, Janice E. Thies, Ellen Kandeler, Serita D. Frey, Alain F. Plante, Maddie M. Stone, William B. McGill, Sherri J. Morris, Christopher B. Blackwood, R. Balestrini, E. Lumini, R. Borriello, V. Bianciotto, William Horwath, Claire Chenu, Cornelia Rumpel, Johannes Lehmann, G.P. Robertson, P.M. Groffman, Peter J. Bottomley, David D. Myrold, Michael A. Kertesz, Emmanuel Frossard, William J. Parton, Stephen J. Del Grosso, E. Carol Adair, Susan M. Lutz, Harold P. Collins, Alex R. Crump, Vanessa L. Bailey (2015) · Soil Microbiology, Ecology, and Biochemistry (Fourth Edition) #6492716

• Trifolium repens interactsWith Agrostis capillaris

  “many phylotypes did not occur in common, although others did”

  Smith S.E., Read D. (2008) · Mycorrhizal Symbiosis, Third Edition · p. 36 #6492713

• Microarthropoda (subclass) interactsWith Plantae (kingdom)

  “microarthropods fragment decomposing litter, improving availability to microbes”

  Eldor A. Paul (editor); R.P. Voroney, R.J. Heck, Ken Killham, Jim Prosser, D. Lee Taylor, Robert L. Sinsabaugh, David C. Coleman, Diana H. Wall, Janice E. Thies, Ellen Kandeler, Serita D. Frey, Alain F. Plante, Maddie M. Stone, William B. McGill, Sherri J. Morris, Christopher B. Blackwood, R. Balestrini, E. Lumini, R. Borriello, V. Bianciotto, William Horwath, Claire Chenu, Cornelia Rumpel, Johannes Lehmann, G.P. Robertson, P.M. Groffman, Peter J. Bottomley, David D. Myrold, Michael A. Kertesz, Emmanuel Frossard, William J. Parton, Stephen J. Del Grosso, E. Carol Adair, Susan M. Lutz, Harold P. Collins, Alex R. Crump, Vanessa L. Bailey (2015) · Soil Microbiology, Ecology, and Biochemistry (Fourth Edition) · p. 114 #6492704

• Termitidae (family) interactsWith Plantae (kingdom)

  “termites alter physical structure of soil, influencing nutrient flow”

  Eldor A. Paul (editor); R.P. Voroney, R.J. Heck, Ken Killham, Jim Prosser, D. Lee Taylor, Robert L. Sinsabaugh, David C. Coleman, Diana H. Wall, Janice E. Thies, Ellen Kandeler, Serita D. Frey, Alain F. Plante, Maddie M. Stone, William B. McGill, Sherri J. Morris, Christopher B. Blackwood, R. Balestrini, E. Lumini, R. Borriello, V. Bianciotto, William Horwath, Claire Chenu, Cornelia Rumpel, Johannes Lehmann, G.P. Robertson, P.M. Groffman, Peter J. Bottomley, David D. Myrold, Michael A. Kertesz, Emmanuel Frossard, William J. Parton, Stephen J. Del Grosso, E. Carol Adair, Susan M. Lutz, Harold P. Collins, Alex R. Crump, Vanessa L. Bailey (2015) · Soil Microbiology, Ecology, and Biochemistry (Fourth Edition) · p. 114 #6492703

• Formicidae (family) interactsWith Plantae (kingdom)

  “ants alter physical structure of the soil, influencing nutrient flow”

  Eldor A. Paul (editor); R.P. Voroney, R.J. Heck, Ken Killham, Jim Prosser, D. Lee Taylor, Robert L. Sinsabaugh, David C. Coleman, Diana H. Wall, Janice E. Thies, Ellen Kandeler, Serita D. Frey, Alain F. Plante, Maddie M. Stone, William B. McGill, Sherri J. Morris, Christopher B. Blackwood, R. Balestrini, E. Lumini, R. Borriello, V. Bianciotto, William Horwath, Claire Chenu, Cornelia Rumpel, Johannes Lehmann, G.P. Robertson, P.M. Groffman, Peter J. Bottomley, David D. Myrold, Michael A. Kertesz, Emmanuel Frossard, William J. Parton, Stephen J. Del Grosso, E. Carol Adair, Susan M. Lutz, Harold P. Collins, Alex R. Crump, Vanessa L. Bailey (2015) · Soil Microbiology, Ecology, and Biochemistry (Fourth Edition) · p. 114 #6492702

• Oligochaeta (class) interactsWith Plantae (kingdom)

  “earthworms alter physical structure of soil, influencing nutrient and energy flow”

  Eldor A. Paul (editor); R.P. Voroney, R.J. Heck, Ken Killham, Jim Prosser, D. Lee Taylor, Robert L. Sinsabaugh, David C. Coleman, Diana H. Wall, Janice E. Thies, Ellen Kandeler, Serita D. Frey, Alain F. Plante, Maddie M. Stone, William B. McGill, Sherri J. Morris, Christopher B. Blackwood, R. Balestrini, E. Lumini, R. Borriello, V. Bianciotto, William Horwath, Claire Chenu, Cornelia Rumpel, Johannes Lehmann, G.P. Robertson, P.M. Groffman, Peter J. Bottomley, David D. Myrold, Michael A. Kertesz, Emmanuel Frossard, William J. Parton, Stephen J. Del Grosso, E. Carol Adair, Susan M. Lutz, Harold P. Collins, Alex R. Crump, Vanessa L. Bailey (2015) · Soil Microbiology, Ecology, and Biochemistry (Fourth Edition) · p. 114 #6492701

• Fungi (kingdom) interactsWith Plantae (kingdom)

  “endophytes can confer resistance to thermal and drought stress”

  Eldor A. Paul (editor); R.P. Voroney, R.J. Heck, Ken Killham, Jim Prosser, D. Lee Taylor, Robert L. Sinsabaugh, David C. Coleman, Diana H. Wall, Janice E. Thies, Ellen Kandeler, Serita D. Frey, Alain F. Plante, Maddie M. Stone, William B. McGill, Sherri J. Morris, Christopher B. Blackwood, R. Balestrini, E. Lumini, R. Borriello, V. Bianciotto, William Horwath, Claire Chenu, Cornelia Rumpel, Johannes Lehmann, G.P. Robertson, P.M. Groffman, Peter J. Bottomley, David D. Myrold, Michael A. Kertesz, Emmanuel Frossard, William J. Parton, Stephen J. Del Grosso, E. Carol Adair, Susan M. Lutz, Harold P. Collins, Alex R. Crump, Vanessa L. Bailey (2015) · Soil Microbiology, Ecology, and Biochemistry (Fourth Edition) · p. 94 #6492699

• Eumycota (kingdom) interactsWith Embryophyta (kingdom)

  “influence the structure and function of plant communities”

  Eldor A. Paul (editor); R.P. Voroney, R.J. Heck, Ken Killham, Jim Prosser, D. Lee Taylor, Robert L. Sinsabaugh, David C. Coleman, Diana H. Wall, Janice E. Thies, Ellen Kandeler, Serita D. Frey, Alain F. Plante, Maddie M. Stone, William B. McGill, Sherri J. Morris, Christopher B. Blackwood, R. Balestrini, E. Lumini, R. Borriello, V. Bianciotto, William Horwath, Claire Chenu, Cornelia Rumpel, Johannes Lehmann, G.P. Robertson, P.M. Groffman, Peter J. Bottomley, David D. Myrold, Michael A. Kertesz, Emmanuel Frossard, William J. Parton, Stephen J. Del Grosso, E. Carol Adair, Susan M. Lutz, Harold P. Collins, Alex R. Crump, Vanessa L. Bailey (2015) · Soil Microbiology, Ecology, and Biochemistry (Fourth Edition) · p. 78 #6492649

• Desmodium uncinatum interactsWith Zea mays

  “silverleaf intercropped with maize repels stemborers”

  Gurr G.M., Wratten S.D., Altieri M.A. (2004) · Ecological Engineering for Pest Management: Advances in Habitat Manipulation for Arthropods · p. 46 #6492487

• Panicum trichoides interactsWith Coffea arabica

  “Panicum trichoides not hosts of the parasitic coffee nematode Meloidogyne incognita”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492343

• Canavalia ensiformis interactsWith Coffea arabica

  “wind break effect of taller-growing Canavalia and a possible nitrogen contribution from the prunings”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492342

• Desmodium ovalifolium interactsWith Coffea arabica

  “legumes provided excellent control of annual weeds in the interrow area”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492341

• Clusia rosea interactsWith Coffea arabica

  “most decomposition resistant species at double thickness”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492340

• Simarouba glauca interactsWith Coffea arabica

  “Simarouba glauca decomposed much more slowly with only a 15% loss”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492339

• Inga paterno interactsWith Coffea arabica

  “Inga paterno decomposed much more slowly with only a 15% loss”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492338

• Gliricidia sepium interactsWith Coffea arabica

  “managed under combination of temporary and permanent shade Gliricidia sepium”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492337

• Cajanus cajan interactsWith Lumbricidae (family)

  “mulching with leaves and branches of Cajanus cajan increased the number of roots, worms, and other soil invertebrates”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492278

• Leucaena leucocephala interactsWith Zea mays

  “equilibrium infiltration rates were greater in Leucaena leucocephala and Gliricidia sepium plots”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492275

• Cassia siamea interactsWith Vigna unguiculata

  “less than 1 mm from the mulched hedgerow-cowpea system”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492274

• Grevillea robusta interactsWith Zea mays

  “increased maize yields in rows on the windward side of Grevillea robusta hedgerows”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492273

• Leucaena leucocephala interactsWith Zea mays

  “Unmulched hedgerows were effective in reducing annual runoff by up to 55%”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492272

• Grevillea robusta interactsWith Zea mays

  “soil nitrate increased rather than decreased during the 11 months after establishment”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492247

• Calliandra calothyrsus interactsWith Zea mays

  “C. calothyrsus (312 kg N ha–1) … reduced soil nitrate throughout the 2-m-deep soil profile”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492245

• Gliricidia sepium interactsWith Zea mays

  “Gliricidia sepium alone or mixed with C. calothyrsus”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492244

• Cordia alliodora interactsWith Coffea arabica

  “higher total nutrient content was found in the C. alliodora associations”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492243

• Erythrina poeppigiana interactsWith Coffea arabica

  “transfer of N, P, K, Ca, and Mg to the soil was greater from E. poeppigiana”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492242

• Tephrosia vogelii interactsWith Phaseolus vulgaris

  “the second crop (bean) by 96%”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492241

• Tephrosia vogelii interactsWith Zea mays

  “a one-year fallow of this species increased yield of the first sequential crop (maize) by 72%”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492240

• Tephrosia candida interactsWith Zea mays

  “two-year fallow of Tephrosia candida increased yield of subsequent maize by 1.5 Mg ha–1 (or 157%)”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492239

• Cajanus cajan interactsWith Zea mays

  “maize yield following a three-year-old pigeonpea fallow was 55% higher”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492238

• Cajanus cajan interactsWith Zea mays

  “one-year monocrops of pigeonpea … increased subsequent maize yield by 57%”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492237

• Faidherbia albida interactsWith Arachis hypogaea

  “Groundnuts: +37%”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492235

• Faidherbia albida interactsWith Sorghum bicolor

  “sorghum yields were increased by 36% in Ethiopia and 125% in Burkina Faso”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492234

• Faidherbia albida interactsWith Zea mays

  “maize yields were increased by more than 100% in Malawi and 76% in Ethiopia”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492233

• Leucaena leucocephala interactsWith Zea mays

  “N contribution of roots, nodules … equivalent to 32 kg N ha–1 on maize”

  Buck L.E., Lassoie J.P., Fernandes E.C.M. (1999) · Agroforestry in Sustainable Agricultural Systems #6492232