Juan Francisco Zamora NATERA, Isidro Zapata HERNÁNDEZ, Carlos Ernesto Aguilar JİMÉNEZ, Franklin B. Martínez AGUİLAR, José Galdámez GALDÁMEZ

Assessing the biomass yield and nitrogen fixation of Lupinus angustifolius varieties as green manure in Jalisco, Mexico

Limited information is available in Mexico regarding the use of Lupinus angustifolius L. as a green manure. This study aimed to assess the effectiveness of six Lupinus angustifolius varieties as green manure in terms of above-ground biomass production, expressed as dry matter (DM), and total nitrogen (N) accumulation at successive harvest dates. Additionally, the study aimed to estimate N2 fixation 110 days after sowing (DAS). The varieties Haags Blaue, Boregine, Borlu, Probor, Sonate, and Boruta were sown during the winter season of 2018-2019 using a randomized block factorial design. The N difference method was employed to estimate N2 fixation, with wheat serving as the reference crop. Data on above-ground biomass production, N concentration, and total N accumulation were recorded at different harvest times: 80, 95, and 110 DAS. The biomass yield of all varieties significantly increased from the first to the last harvest, with the highest yield observed at the final harvest (ranging from 7,632 to 10,200 kg ha-1). The highest total N accumulation from biomass was recorded at the last harvest. On average, the Borlu, Boregine, Haags Blaue, and Boruta varieties accumulated 195.4 kg ha-1 of total N (ranging from 195.6 to 221.2 kg ha-1). The proportion of N derived from the atmosphere (%Ndfa) through N2 fixation averaged 80.09% (ranging from 72% to 93%), resulting in an average N fixation of 160 kg ha-1 (ranging from 106 to 185 kg ha-1) in above-ground biomass. All six varieties demonstrated potential as green manure, considering their above-ground biomass production, total N accumulation, and ability to fix N2.

Keywords:

Dry matter harvest date, legumes, lupins, N2 fixation, Rhizobia,

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Abiven, S., Heim, A., Schmidt, M.W., 2011. Lignin content and chemical characteristics in maize and wheat vary between plant organs and growth stages: consequences for assessing lignin dynamics in soil. Plant and Soil 343(1): 369–378.
Akter, Z., Pageni, B.B., Lupwayi, N.Z., Balasubramanian, P.M., 2018. Biological nitrogen fixation by irrigated dry bean (Phaseolus vulgaris L.) genotypes. Canadian Journal of Plant Science 98(5): 1159–1167.
Barrientos, L., Montenegro, A., Pino, I., 2002. Evaluación de la fijación simbiótica de nitrógeno de Lupinus albus y L. angustifolius en un Andisol Vilcun del sur de Chile. Terra Latinoamericana 20(1): 39–44.
Bender, A., Tamm, S., 2014. Fertilization value of early red clover, Washington lupin and crimson clover as green manure crops. In: Annual 20th International Scientific Conference Proceedings," Research for Rural Development". Jelgava, Latvia. Latvia University of Agriculture. pp. 84–88.
Bhardwaj, H.L., Starner, D.E., van Santen, E., 2010. Preliminary evaluation of white lupin (Lupinus albus L.) as a forage crop in the mid-atlantic region of the United States of America. Journal of Agricultural Science 2(4): 13–17.
Carranca, C., Madeira, M., Torres, M.O., 2013. N2 fixation by two lupine species under different soil management systems. Transfer of fixed N2 from legume to intercropped eucalyptus. Revista de Ciências Agrárias 36(1): 71–83.
Denton, M.D., Phillips, L.A., Peoples, M.B., Pearce, D.J., Swan, A.D., Mele, P.M. & Brockwell, J., 2017. Legume inoculant application methods: effects on nodulation patterns, nitrogen fixation, crop growth and yield in narrow-leaf lupin and faba bean. Plant and Soil 419(1): 25–39.
Dhamala, N.R., Eriksen, J., Carlsson, G., Søegaard, K., Rasmussen, J., 2017. Highly productive forage legume stands show no positive biodiversity effect on yield and N2-fixation. Plant and Soil 417(1): 169–182.
Diatta, A.A., Thomason, W.E., Abaye, O., Thompson, T.L., Battaglia, M.L., Vaughan, L.J., Lo, M., 2020. Assessment of nitrogen fixation by mungbean genotypes in different soil textures using 15N natural abundance method. Journal of Soil Science and Plant Nutrition 20(4): 2230–2240.
Drummond, C.S., Eastwood, R.J., Miotto, S.T., Hughes, C.E., 2012. Multiple continental radiations and correlates of diversification in Lupinus (Leguminosae): testing for key innovation with incomplete taxon sampling. Systematic Biology 61(3): 443–460.
Dubrovskis, V., Adamovics, A., Plume, I., Kotelenecs, V., Zabarovskis, E., 2011. Biogas production from greater burdock, largeleaf lupin and sosnovsky cow parsnip. In: Proceedings of the 10th International Scientific Conference, Engineering for Rural Development. Jelgava, Latvia. Latvia Academy of Agricultural and Forestry Sciences Division of Engineering. pp. 388–392.
Evans, J., Turner, G.L., O'Connor, G.E., Bergersen, F.J., 1987. Nitrogen fixation and accretion of soil nitrogen by field-grown lupins (Lupinus angustifolius). Field Crops Research 16(4): 309–322.
Fowler C.J.E., Condron, L.M., McLenaghen, R.D., 2004. Effects of green manures on nitrogen loss and availability in an organic cropping system. New Zealand Journal of Agricultural Research 47(1): 95–100.
Fowler, D., Coyle, M., Skiba, U., Sutton, M.A., Cape, J.N., Reis, S., Sheppard, L., Jenkins, A., Grizzetti, B., Galloway, J., Vitousek, P., Leach, A., Bouwman, A., Butterbach-Bahl, K., Dentener, F., Stevenson, D., Amann, M., Voss, M., 2013. The global nitrogen cycle in the twenty-first century. Philosophical Transactions of the Royal Society B: Biological Sciences 368(1621): 20130164.
Gladstones, J.S., 1974. Lupins of the Mediterranean region and Africa. Department of Primary Industries and Regional Development, Western Australia, Perth. Technical Bulletin 26. 48p.
Hanly, J.A., Gregg, P.E.H., 2004. Green‐manure impacts on nitrogen availability to organic sweetcorn (Zea mays). New Zealand Journal of Crop and Horticultural Science 32(3): 295–307.
Hardarson, G., Zapata, F., Danso, S.K.A., 1984. Effect of plant genotype and nitrogen fertilizer on symbiotic nitrogen fixation by soybean cultivars. Plant and Soil 82(3): 397–405.
Hernández, I.Z., Solís, H.V., Aguilar, F.B.M., Jimenez, C.E.A., Natera, J.F.Z., 2022. Biomass yield, soil cover and minerals accumulation by two green manures species grown in soils of Chiapas Mexico. Eurasian Journal of Soil Science 11(4): 329-336.
Hondelmann, W., 1984. The lupin—ancient and modern crop plant. Theoretical and Applied Genetics 68(1): 1–9.
Jordan, D.C., 1982. Transfer of Rhizobium Japonicum Buchanan 1980 to Bradyrhizobum gen. nov, a genus of slow-growing, root nodule from leguminous plant. International Journal of Systematic and Evolutionary Microbiology 32(1): 136–139.
Kelstrup, L., Rowarth, J.S., Williams, P.H., Ronson, C., 1996. Nitrogen fixation in peas (Pisum sativum L.), lupins (Lupinus angustifolius L.) and lentils (Lens culinaris Medik.). Proceedings Agronomy Society of N.Z 26: 71–74.
Kurlovich, B.S., 2002. The history of lupin domestication. Lupins, geography, classification, genetic resources and breeding. Intan, St. Petersburg. Russia. pp.147–164.
Lara-Rivera, A.H., García-Alamilla, P., Lagunes-Gálvez, L.M., Rodríguez-Macias, R., García-López, P.M., Zamora-Natera, J.F., 2017. Functional properties of Lupinus angustifolius seed protein isolates. Journal of Food Quality Article ID 8675814.
Markovi, J.P., Scaron, R.T., Terzi, D.V., Djoki, D.J., Vrvi, M.M., Sanja, P., 2012. Changes in lignin structure with maturation of alfalfa leaf and stem in relation to ruminants nutrition. African Journal of Agricultural Research 7(2): 257–264.
Matos, E.D.S., Mendonça, E.D.S., Lima, P.C.D., Coelho, M.S., Mateus, R.F., Cardoso, I.M., 2008. Green manure in coffee systems in the region of Zona da Mata, Minas Gerais: characteristics and kinetics of carbon and nitrogen mineralization. Revista Brasileira de Ciência do Solo 32: 2027–2035.
McSorley, R., 1999. Host suitability of potential cover crops for root-knot nematodes. Journal of Nematology 31(4S): 619–623.
Meena, R.S., Das, A., Yadav, G.S., Lal, R., 2018. Legumes for soil health and sustainable management. Springer Singapore. 541p.
Müller, M.M., Sundman, V., Soininvaara, O., Meriläinen, A., 1988. Effect of chemical composition on the release of nitrogen from agricultural plant materials decomposing in soil under field conditions. Biology and Fertility of Soils 6(1): 78–83.
Odhiambo, J.J., 2010. Decomposition and nitrogen release by green manure legume residues in different soil types. African Journal of Agricultural Research 5(1): 090–096.
Odhiambo, J.J., Bomke, A.A., 2001. Grass and legume cover crop effects on dry matter and nitrogen accumulation. Agronomy Journal 93(2): 299–307.
Pálmason, F., Danso, S.K.A., Hardarson, G., 1992. Nitrogen accumulation in sole and mixed stands of sweet-blue lupin (Lupinus angustifolius L.), ryegrass and oats. Plant and Soil 142(1): 135–142.
Pálmason, F., Gudmundsson, J., Sverrisson, H., 2004. Estimates of symbiotic nitrogen fixation in two lupin species in Iceland. In: Wild and cultivated lupins from the Tropics to the Poles. Proceedings of the 10th International Lupin Conference, in June in Laugarvatn, Iceland. International Lupin Association. pp. 118–120.
Perdigão, A., Coutinho, J., Moreira, N., 2012. Cover crops as nitrogen source for organic farming in southwest Europe. Acta Horticulturae 933: 355–361.
Pietrzykowski, M., Gruba, P., Sproull, G., 2017. The effectiveness of Yellow lupine (Lupinus luteus L.) green manure cropping in sand mine cast reclamation. Ecological Engineering 102: 72–79.
Prusiński, J., 2014. Dynamics and distribution of dry matter and total nitrogen in yellow lupine (Lupinus luteus L.) plants. Electronic Journal of Polish Agricultural Universities 17(2): 1–11.
Ridley, W.P., Shillito, R.D., Coats, I., Steiner, H.Y., Shawgo, M., Phillips, A., Dussold, P., Kurtyka, L., 2004. Development of the international life sciences institute crop composition database. Journal of Food Composition and Analysis 17(3-4): 423–438.
Ross, S.M., King, J.R., Izaurralde, R.C., O'Donovan, J.T., 2001. Weed suppression by seven clover species. Agronomy Journal 93(4): 820–827.
Solati, Z., Jørgensen, U., Eriksen, J., Søegaard, K., 2017. Dry matter yield, chemical composition and estimated extractable protein of legume and grass species during the spring growth. Journal of the Science of Food and Agriculture 97(12): 3958–3966.
Talgre, L., Lauringson, E., Roostalu, H., Astover, A., Makke, A., 2012. Green manure as a nutrient source for succeeding crops. Plant, Soil and Environment 58(6): 275–281.
Unkovich, M.J., Baldock, J., Peoples, M.B., 2010. Prospects and problems of simple linear models for estimating symbiotic N2 fixation by crop and pasture legumes. Plant and Soil 329(1): 75–89.
van Antwerpen R.S.A., Schumann Rhonda, A., Meyer Jan, H., 2002. Can non-legume crops be as successful as legumes when used as green manures?. 17th World Congress of Soil Science. Bangkok, Thailand. pp. 14–21.
Wivstad, M., 1999. Nitrogen mineralization and crop uptake of N from decomposing 15N labelled red clover and yellow sweetclover plant fractions of different age. Plant and Soil 208(1): 21–31.
Wivstad, M., Naetterlund, H., 2008. Learning in context–improved nutrient management in arable cropping systems through participatory research. 16th IFOAM Organic World Congress. Modena, Italy. pp. 16–20.
Zapata-Hernandez, I., Rodriguez-Macias, R., Garcia-Lopez, P.M., Salcedo-Perez, E., Lara-Rivera, A.H., Zamora-Natera, J.F., 2019. Dry matter yield and nitrogen content in Lupinus spp. (Leguminosae) with potential as a green manure. Legume Research 42(4): 523–527.
Zimmer, S., Messmer, M., Haase, T., Piepho, H.P., Mindermann, A., Schulz, H., Habekuß, A., Ordon, F., Wilbois, K.P., Heß, J., 2016. Effects of soybean variety and Bradyrhizobium strains on yield, protein content and biological nitrogen fixation under cool growing conditions in Germany. European Journal of Agronomy 72: 38–46.