Near-infrared leaf reflectance modeling of Annona emarginata seedlings for early detection of variations in nitrogen concentration

doi:10.1007/s11676-022-01557-3

Abstract

Abstract:

Nitrogen (N) monitoring is essential in nurseries to ensure the production of high-quality seedlings. Near-infrared spectroscopy (NIRS) is an instantaneous, nondestructive method to monitor N. Spectral data such as NIRS can also provide the basis for developing a new vegetation spectral index (VSI). Here, we evaluated whether NIRS combined with statistical modeling can accurately detect early variations in N concentration in leaves of young plants of Annona emarginata and developed a new VSI for this task. Plants were grown in a hydroponics system with 0, 2.75, 5.5 or 11 mM N for 45 days. Then we measured gas exchange, chlorophylla fluorescence, and pigments in leaves; analyzed complete leaf nutrients, and recorded spectral data for leaves at 966 to 1685 nm using NIRS. With a statistical learning approach, the dimensionality of the spectral data was reduced, then models were generated using two classes (N deficiency, N) or four classes (0, 2.75, 5.5, 11 mM N). The best combination of techniques for dimensionality reduction and classification, respectively, was stepwise regression (PROC STEPDISC) and linear discriminant function. It was possible to detect N deficiency in seedlings leaves with 100% precision, and the four N concentrations with 93.55% accuracy before photosynthetic damage to the plant occurred. Thereby, NIRS combined with statistical modeling of multidimensional data is effective for detecting N variations in seedlings leaves of A. emarginata.

Key words: Mineral nutrition of plants, Near-infrared spectroscopy, Spectral vegetation index, Digital signature, Statistical learning, Fluorescence of chlorophylla

Rafaela Lanças Gomes, Marília Caixeta Sousa, Felipe Girotto Campos, Carmen Sílvia Fernandes Boaro, José Raimundo de Souza Passos, Gisela Ferreira. Near-infrared leaf reflectance modeling of Annona emarginata seedlings for early detection of variations in nitrogen concentration[J]. JOURNAL OF FORESTRY RESEARCH, 2023, 34(1): 269-282.

Rafaela Lanças Gomes, Marília Caixeta Sousa, Felipe Girotto Campos, Carmen Sílvia Fernandes Boaro, José Raimundo de Souza Passos, Gisela Ferreira. [J]. 林业研究(英文版), 2023, 34(1): 269-282.

References 44

1	Baron D, Ferreira G, Rodrigues JD, Boaro CSF, Macedo AC. Gas exchange, physiological indexes and ionic accumulation in Annona emarginata (Schltdl.) H. Rainer seedlings in nutrients solution. Rev Bras Frutic, 2013, 36: 361-376, DOI
2	Birth SG, McVey RG. Measuring the color of growing turf with a reflectance spectrophotometer. Agron J, 1968, 60: 640-643, DOI
3	Blackburn GA. Quantifying chlorophylls and carotenoids at leaf and canopy scale: an evaluation of some hyperspectral approaches. Remote Sens Environ, 1998, 66: 273-285, DOI
4	Bloom AJ, Burger M, Rubio Asensio JS, Cousins AB. Carbon dioxide enrichment inhibits nitrate assimilation in wheat and Arabidopsis. Science, 2010, 328: 899-903, DOI
5	Campos FG, Vieira MAR, Amaro ACE, Dela Cruz-Chacón I, Marques MOM, Ferreira G, Boaro CSF. Nitrogen in the defense system of Annona emarginata (Schltdl.) H. Rainer. PLoS ONE, 2019, 14(6): e0217930, DOI
6	Carter GA, Knapp AK. Leaf optical properties in higher plants: linking spectral characteristics to stress and chlorophyll concentration. Am J Bot, 2011, 88: 677-684, DOI
7	Chen D, Wang S, Xiong B, Cao B, Deng X. Carbon/nitrogen imbalance associated with drought-induced leaf senescence in Sorghum bicolor. PLoS ONE, 2015, 10(8): e0137026, DOI
8	CONSEMA [Conselho Estadual do Meio Ambiente] Rio Grande do Sul (2002) Decreto estadual CONSEMA n. 42.099 de 31 de dezembro de 2002. Declara as espécies da flora nativa ameaçadas de extinção no estado do Rio Grande do Sul e da outras providências, Palácio Piratini, Porto Alegre, Rio Grande do Sul, 31 dez. 2002
9	Curran PJ. Remote sensing of foliar chemistry. Remote Sens Environ, 1989, 30: 271-278, DOI
10	Demmig-Adams B, Adams WW III, Barker DH, Logan BA, Bowling DR, Verhoeven AS. Using chlorophyll fluorescence to assess the fraction of absorbed light allocated to thermal dissipation of excess excitation. Physiol Plant, 1996, 98: 253-264, DOI
11	Efron B. Bootstrap methods: another look at the Jackknife. Ann Stat, 1979, 7(1): 1-26, DOI
12	Esteban R, Ariz I, Cruz C, Moran JF. Review: mechanisms of ammonium toxicity and the quest for tolerance. Plant Sci, 2016, 248: 92-101, DOI
13	Fernández-Martinez J, Joffre R, Zacchini M, Fernandez-Marin B, García-Plazaola JI, Fleck I. Near-infrared reflectance spectroscopy allows rapid and simultaneous evaluation of chloroplast pigments and antioxidants, carbon isotope discrimination and nitrogen content in Populus spp. leaves. For Ecol Manag, 2017, 399: 227-234, DOI
14	da Fonseca EL, Rosa LMG, Fontana DC. Caracterização espectral de Paspalum notatum em diferentes níveis de adubação nitrogenada. Pesq Agropec Bras, 2002, 37(3): 365-371, DOI
15	Galvez-Sola L, García-Sánchez F, Pérez-Pérez JG, Gimeno V, Navarro JM, Moral R, Martínez-Nicolás JJ, Nieves M. Rapid estimation of nutritional elements on citrus leaves by near infrared reflectance spectroscopy. Front Plant Sci, 2015, 6: 571, DOI
16	Gamon JA, Peñeulas J, Field CB. A narrow-waveband spectral index that tracks diurnal changes in photosynthetic efficiency. Remote Sens Environ, 1992, 41: 35-44, DOI
17	Hattey JA, Sabbe WE, Baten GD, Blakeney AB. Nitrogen and starch analysis of cotton leaves using near infrared reflectance spectroscopy (NIRS). Commun Soil Sci Plant Anal, 1994, 25: 1855-1863, DOI
18	Jensen JR. Remote sensing of the environment—an earth resource perspective, 2002 Upper Saddle River MIT Press 357-403
19	Johnson R, Wichern D. Applied multivariate statistical analysis, 2014 6 New Jersey Prentice Hall 628
20	Kalaji HM, Baba W, Gediga K, Goltsev V, Samborska IA, Cetner MD, Dimitrova S, Piszcz U, Bielecki K, Karmowska K, Dankov K, Kompała-Bąba A. Chlorophyll fluorescence as a tool for nutrient status identification in rapeseed plants. Photosynth Res, 2018, 136: 329-343, DOI
21	Lawlor DW, Kontturi M, Young AT. Photosynthesis by flag leaves of wheat in relation to protein, ribulose bis phosphate carboxylase activity and nitrogen supply. J Exp Bot, 1989, 40: 43-52, DOI
22	Lima RL, Ferreira GB, Weber OB, Cazetta JO. Diagnose foliar da gravioleira (Annona muricata L.): efeito da posição de ramos e folhas. Ciênc Agrotec, 2007, 31(5): 1320-1325, DOI
23	Maas P, Lobão A, Rainer H (2015) Annonaceae in Lista de Espécies da Flora do Brasil. Jardim Botânico do Rio de Janeiro. Disponível em: http://floradobrasil.jbrj.gov.br/jabot/FichaPublicaTaxonUC/FichaPublicaTaxonUC.do?id=FB110219. Acesso em: 14 Abr. 2019
24	Mantoan LPB, Ferreira G, Boaro CSF. Chlorophyll a fluorescence in Annona emarginata (Schltdl.) H. Rainer plants subjected to water stress and after rehydration. Sci Hortic (amsterdam), 2015, 184: 23-30, DOI
25	Miphokasap P, Honda K, Vaiphasa C, Souris M, Nagai M. Estimating canopy nitrogen concentration in sugarcane using field imaging spectroscopy. Remote Sens, 2012, 4: 1651-1670, DOI
26	Mur LAJ, Simpson C, Kumari A, Gupta AK, Gupta KJ. Moving nitrogen to the centre of plant defence against pathogens. Ann Bot, 2017, 119(5): 703-709, DOI
27	Nelder JA, Wedderburn RW. Generalized linear models. J R Stat Soc Ser A, 1972, 135(3): 370-384, DOI
28	Nunes-Nesi A, Fernie AR, Stitt M. Metabolic and signaling aspects underpinning the regulation of plant carbon nitrogen interactions. Mol Plant, 2010, 3(6): 973-996, DOI
29	Otto M. Chemometrics: statistics and computer application in analytical chemistry, 1999 Chinchester Wiley-VCH
30	Rennenberg H, Dannenmann M, Gessler A, Kreuzwieser J, Simon J, Papen H. Nitrogen balance in forest soils: nutritional limitation of plants under climate change stresses. Plant Biol, 2009, 11: 4-23, DOI
31	Rouse JW, Haas RH, Schell JA, Deering DW (1974) Monitoring vegetation systems in the great plains with ERTS. In: Proceeding of 3th earth resources technology satellite-1 symposium. Greenbelt, MD NASA, pp 301–317
32	Ryan MG. Effects of climate change on plant respiration. Ecol Appl, 1991, 1: 157-167, DOI
33	Siesler HW, Ozaki Y, Kawata S, Heise HM. Near-infrared spectroscopy: principles, instruments, applications, 2001 1 Chichester Wiley-VCH, DOI
34	Sims DA, Gamon JA. Relationships between leaf pigment content and spectral reflectance across a wide range of species, leaf structures and developmental stages. Remote Sens Environ, 2002, 81(2): 337-354, DOI
200	Souza SR, Fernandes MS, Nitrogênio (2006) In: FERNANDES, M. S. (Ed.) Nutrição Mineral de Plantas. Viçosa:Sociedade Brasileira de Ciência do Solo, pp. 215–252.
35	Tokunaga T (2005) A cultura da atemoia. 2.ed. Campinas: CATI, p 80 (Tecnical report)
36	Walsh KJE, McBride JL, Klotzbach PJ, Balachandran S, Camargo SJ, Holland G, Knutson TR, Kossin JP, Lee T, Sobel A, Sugi M. Tropical cyclones and climate change. Wires Clim Change, 2015, 7(1): 65-89, DOI
37	Wang Y, Hu X, Jin G, Hou Z, Ning J, Zhang Z. Rapid prediction of chlorophylls and carotenoids content in tea leaves under different levels of nitrogen application based on hyperspectral imaging. J Sci Food Agric, 2018, 99: 1997-2004, DOI
38	Westfall PH, Tobias RD, Rom D, Wolfinger RD, Hochberg Y. Multiple comparisons and multiple tests using the SAS system, 1999 Cary SAS Institute Inc
39	Xue J, Su B. Significant remote sensing vegetation indices: A review of developments and applications. J Sens, 2017, DOI
40	Yang J, Du L, Gong W, Shi S, Sun J, Chen B. Potential of vegetation indices combined with laser-induced fluorescence parameters for monitoring leaf nitrogen content in paddy rice. PLoS ONE, 2018, 13(1): e0191068, DOI
41	Yi QX, Huang JF, Wang FM, Wang X, Liu ZY. Monitoring rice nitrogen status using hyperspectral reflectance and artificial neural network. Environ Sci Technol, 2007, 41: 6770-6775, DOI
42	Zarco-Tejada PJ, Berjon A, Lopez-Lozana R, Miller JR, Martin P, Cachorro V, Gonzalez MR. Assessing vineyard conditions with hyperspectral indices: leaf canopy reflectance simulation in a row structured discontinuous canopy. Remote Sens Environ, 2005, 99: 271-287, DOI
43	Zhang S, Li Q, Ma K, Chen L. Temperature-dependent gas exchange and stomatal/non-stomatal limitation to CO₂ assimilation of Quercus Liaotungensis under midday high irradiance. Photosynthetica, 2001, 39(3): 383-388, DOI
44	Zhou QF, Liu ZY, Huang JF. Detection of nitrogen-overfertilized rice plants with leaf positional difference in hyperspectral vegetation index. J Zhejiang Univ Sci B, 2010, 11(6): 465-470, DOI