Is magnesium deficiency the major cause of needle chlorosis of Pinus taeda in Brazil?

doi:10.1007/s11676-023-01656-9

Abstract

Abstract:

Needle chlorosis (NC) in Pinus taeda L. systems in Brazil becomes more frequent after second and third harvest rotation cycles. In a study to identify factors contributing to yellowing needle chorosis (YNC), trees were grown in soils originating from contrasting parent materials, and soils and needles (whole, green and chlorotic portions) from 1- and 2-year-old branches and the first and second needle flush release at four sites with YNC on P. taeda were analyzed for various elements and properties. All soils had very low base levels (Ca²⁺, Mg²⁺ and K⁺) and P, suggesting a possible lack of multiple elements. YNC symptoms started at needle tips, then extended toward the needle base with time. First flush needles had longer portions with YNC than second flush needles did. Needles from the lower crown also had more symptoms along their length than those higher in the canopy. Symptoms were similar to those reported for Mg. In chlorotic portions, Mg and Ca concentrations were well below critical values; in particular, Mg levels were only one third of the critical value of 0.3 g kg⁻¹. Collectively, results suggest that Mg deficiency is the primary reason for NC of P. taeda in various parent soils in Brazil.

Key words: Nutritional deficiency, Forest management, Soil depletion, Pine foliar analysis, Needle chlorosis

Antônio Carlos Vargas Motta, Shizuo Maeda, Valdécio dos Santos dos Santos Rodrigues, Tamires Maiara Ercole, Stephen Arthur Prior, Ana Elisa Lyra Brumat, Amanda Pacheco Cardoso Moura, Julierme Zimmer Barbosa, João Bosco Vasconcellos Gomes. Is magnesium deficiency the major cause of needle chlorosis of Pinus taeda in Brazil?[J]. JOURNAL OF FORESTRY RESEARCH, 2024, 35(1): 24-.

References 47

1	Adam WM, Rodrigues VS, Magri E, Motta ACV, Prior SA, Zambon LM, Lima RLD. Mid-rotation fertilization and liming of Pinus taeda: growth, litter, fine root mass, and elemental composition. iForest, 2021, 14(1): 195-202, DOI
2	Albaugh JM, Blevins L, Allen HL, Albaugh TJ, Fox TR, Stape JL, Rubilar RA. Characterization of foliar macro- and micronutrient concentrations and ratios in loblolly pine plantations in the Southeastern United States. South J Appl for, 2010, 34(2): 53-64, DOI
3	Batista AH, Motta ACV, Reissmann CB, Schneider T, Martins IL, Hashimoto M. Liming and fertilisation in Pinus taeda plantations with severe nutrient deficiency in savanna soils. Acta Sci Agron, 2015, 37(1): 117-125, DOI
4	Beets PN, Jokela EJ. Upper mid-crown yellowing in Pinus radiata: some genetic and nutritional aspects associated with its occurrence. N Z J for Sci, 1994, 24(1): 35-50
5	Berthrong ST, Jobbágy EG, Jackson RB. A global meta-analysis of soil exchangeable cations, pH, carbon, and nitrogen with afforestation. Ecol Appl, 2009, 19(8): 2228-2241, DOI
6	Bonfatti BR (2012) Geotechnologies applied to soil survey and agricultural aptitude of the Lajeado dos Mineiros watershed, São José do Cerrito, SC. Dissertation, State University of Santa Catarina. (in Portuguese)
7	Cakmak I, Marschner H. Magnesium deficiency and high light intensity enhance activities of superoxide dismutase, ascorbate peroxidase, and glutathione reductase in bean leaves. Plant Physiol, 1992, 98(4): 1222-1227, DOI
8	Cakmak I, Yazici AM. Magnesium: a forgotten element in crop production. Better Crops, 2010, 94(2): 23-25
9	Chaudhry AH, Nayab S, Hussain SB, Ali M, Pan Z. Current understandings on magnesium deficiency and future outlooks for sustainable agriculture. Int J Mol Sci, 2021, 22(4): 2-18, DOI
10	Chaves RQ, Corrêa GF. Macronutrientes no sistema solo-Pinus caribaea Morelet em plantios apresentando amarelecimento das acículas e morte de plantas. Rev Árvore, 2005, 29(5): 691-700, DOI
11	Consalter R, Barbosa JZ, Prior SA, Vezzani FM, Bassaco MVM, Pedreira GQ, Motta ACV. Mid rotation fertilization and liming effects on nutrient dynamics of Pinus taeda L. in subtropical Brazil. Eur J for Res, 2021, 140: 19-35, DOI
12	Consalter R, Motta ACV, Barbosa JZ, Vezzani FM, Rubilar RA, Prior SA, Nisgoski S, Bassaco MVM. Fertilization of Pinus taeda L. on an acidic oxisol in southern Brazil: growth, litter accumulation, and root exploration. Eur J for Res, 2021, 140(5): 1095-1112, DOI
13	Embrapa (2018) Brazilian system of soil classification. Embrapa, Brasília, p. 355. (in Portuguese)
14	Ende HP, Evers FH (1997) Visual magnesium deficiency symptoms (coniferous, deciduous trees) and threshold values (foliar, soil). In: Hüttl RF, Schaaf W. Magnesium deficiency in forest ecosystems, Springer, Dordrecht. pp 3–22. https://doi.org/10.1007/978-94-011-5402-4_1
15	Ferreira CA, Silva HD, Reissmann CB, Bellote AFJ, Marques R (2001) Pinus nutrition in Southern Brazil: diagnosis and research priorities. Embrapa, Colombo, p 20. (in Portuguese)
16	Fink S. Structural changes in conifer needles due to Mg and K deficiency. Fert Res, 1991, 27(1): 23-27, DOI
17	Finke K, Jiménez-Esteve B, Taschetto AS, Ummenhofer CC, Bumke K, Domeisen DI. Revisiting remote drivers of the 2014 drought in South-Eastern Brazil. Clim Dyn, 2020, 55(1): 3197-3211, DOI
18	Forest Service NC (2012) Fertilizing guidelines for established loblolly pine forest stands. North Carolina forest service, Raleigh, p. 2.
19	Goor CL. The nutrition of some tropical pines. Silvicultura Em São Paulo, 1966, 4(4): 313-340 (in Portuguese)
20	Gustienė D, Varnagirytė-Kabašinskienė I, Stakėnas V. Ground vegetation, forest floor and mineral topsoil in a clear-cutting and reforested Scots pine stands of different ages: a case study. J Forestry Res, 2022, 33(4): 1247-1257, DOI
21	Hecht-Buchholz C, Jorns CA, Keil P. Effect of excess aluminum and manganese on Norway spruce seedlings as related to magnesium nutrition. J Plant Nutr, 1987, 10(9–16): 1103-1110, DOI
22	Huber C, Baier R, Göttlein A, Weis W. Changes in soil, seepage water and needle chemistry between 1984 and 2004 after liming an N-saturated Norway spruce stand at the Höglwald. Germany for Ecol Manage, 2006, 233(1): 11-20, DOI
23	Hunter IR, Prince JM, Graham JD, Nicholson GM. Growth and nutrition of Pinus radiata on rhyolitic tephra as affected by magnesium fertiliser. N Z J for Sci, 1986, 16(2): 152-165
24	IBGE (2021) Production of plant extraction and silviculture 2020. https://www.aen.pr.gov.br/sites/default/arquivos_restritos/files/migrados/0610pevs_2020_v35_informativo.pdf [accessed on 10.08.2022] (in Portuguese)
25	José JFBS, Cherubin MR, Vargas LK, Lisboa BB, Zanatta JA, Araújo EF, Bayer C. A soil quality index for subtropical sandy soils under different Eucalyptus harvest residue managements. J Forestry Res, 2023, 34(1): 243-255, DOI
26	Kampf N, Curi N (2012) Soil formation and evolution (pedogenesis). In: Ker JC, Curi N, Schaefer CEGR, Vidal-Torrado P (eds) Pedologia: fundamentos. Sociedade Brasileira de Ciência do Solo, Viçosa, pp 207–302. (in Portuguese)
27	Laing W, Greer D, Sun O, Beets P, Lowe A, Payn T. Physiological impacts of Mg deficiency in Pinus radiata: growth and photosynthesis. New Phytol, 2000, 146(1): 47-57, DOI
28	Marques R, Motta ACV. Lima MR, Sirtoli AE, Serrat BM, Wisniewski C, Almeida L, Machado MAM, Marques R, Motta ACV, Krieger KI, Oliveira AC, Ferreira FV. Soil chemical analysis for fertility purposes. Manual de diagnóstico da fertilidade e manejo dos solos agrícolas, 2003 Curitiba Universidade Federal do Paraná 81-102 (in Portuguese)
29	Martins APL, Reissmann CB. Plant material and laboratory routines in chemical-analytical procedures. Sci Agrar, 2007, 8(1): 1-17, DOI
30	Meiwes KJ. Application of lime and wood ash to decrease acidification of forest soils. Water Air Soil Pollut, 1995, 85(1): 143-152, DOI
31	Mitchell AD. Magnesium fertilizer effects on forest soils under Pinus radiata, 2000 Thesis Massey University, Palmerston North
32	Mitchell AD, Loganathan P, Payn TW, Olykan ST. Magnesium and potassium fertiliser effects on foliar magnesium and potassium concentrations and upper mid-crown yellowing in Pinus radiata. N Z J for Sci, 2003, 33(1): 25-243
33	Pauletti V, Motta ACV (eds) (2019) Fertilization and liming manual for the State of Paraná. SBCS, Curitiba, p. 289. (in Portuguese)
34	Pavlů L, Borůvka L, Drábek O, Nikodem A. Effect of natural and anthropogenic acidification on aluminium distribution in forest soils of two regions in the Czech Republic. J Forestry Res, 2021, 32(1): 363-370, DOI
35	Rabel DO, Maeda S, Araujo EM, Gomes JB, Bognolla IA, Prior AS, Magri E, Frigo C, Brasileiro BP, Santos MC, Pedreira GQ, Motta ACV. Recycled alkaline paper waste influenced growth and structure of Pinus taeda L. forest. New for, 2020, 52(1): 249-270, DOI
36	Reissmann CB. Nutrient supply and growth performance of pine stands in southern Brazil, 1981 Freiburg (Germany) Thesis, Albert-Ludwigs Universität (in German)
37	Reissmann CB, Zöttl HW. Problemas nutricionais em povoamentos de Pinus taeda em áreas do arenito da formação Rio Bonito-Grupo Guatá. Revista Ciência Agrária, 1987, 9(1): 75-80
38	Reissmann CB, Wisniewski C (2000) Aspectos nutricionais de plantios de Pinus. In: Gonçalves JLM, Benedetti V (eds) Nutrição e fertilização florestal. IPEF, Piracicaba, pp 135–166.
39	Sucoff EI (1961) Potassium, magnesium, and calcium deficiency symptoms of loblolly and Virginia pine seedlings. Upper Darby, U.S. Department of agriculture-forest service, Northeastern forest experiment station p 20.
40	Sun OJ, Payn TW. Magnesium nutrition and photosynthesis in Pinus radiata: clonal variation and influence of potassium. Tree Physiol, 1999, 19(8): 535-540, DOI
41	Sypert RH (2006) Diagnosis of loblolly pine (Pinus taeda L.) nutrient deficiencies by foliar methods. Dissertation, Virginia Polytechnic Institut, Blacksburg
42	Vidaurre GB, Silva JGM, Moulin JC, Carneiro ACO (2020) Quality of eucalyptus wood from plantations in Brazil. EDUFES, Vitória, p 221. (in Portuguese)
43	Viera M, Schumacher MV. Nutrient concentration and retranslocation in the Pinus taeda L. needles. Ciênc Florest, 2009, 19(4): 375-382, DOI
44	Will GM. Nutrient deficiencies in Pinus radiata in New Zealand. N Z J for Sci, 1978, 8(1): 4-14
45	Wit HA, Eldhuset TD, Mulder J. Dissolved Al reduces Mg uptake in Norway spruce forest: results from a long-term field manipulation experiment in Norway. For Ecol Manage, 2010, 259(10): 2072-2082, DOI
46	Xie KL, Cakmak I, Wang SY, Zhang FS, Guo SW. Synergistic and antagonistic interactions between potassium and magnesium in higher plants. Crop J, 2021, 9(2): 249-256, DOI
47	Zhu QC, de Vries W, Liu XJ, Zeng MF, Hao TX, Du EZ, Zhang FS, Shen JB. The contribution of atmospheric deposition and forest harvesting to forest soil acidification in China since 1980. Atmos Environ, 2016, 146(1): 215-222, DOI

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