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Plants Behavior Under Soil Acidity Stress: Insight into Morphophysiological, Biochemical, and Molecular Responses

  • M. H. M. Borhannuddin Bhuyan
  • Mirza HasanuzzamanEmail author
  • Kamrun Nahar
  • Jubayer Al Mahmud
  • Khursheda Parvin
  • Tasnim Farha Bhuiyan
  • Masayuki Fujita
Chapter

Abstract

Soil pH is a major, variable growth factor in natural and agricultural soils. Although many soils are naturally acidic, agricultural practices industrial processes and mining promote soil acidification. Proton (H+) rhizotoxicity arrested root growth in various plant and exerts its toxic effect by reducing the nutrient availability, disrupting the plasma membrane H+-ATPase activity, disturbing metabolic process, producing reactive oxygen species (ROS), and upsetting the antioxidant defense system. High activity of the H+ in the external growth medium exceeds the ability of the cell to maintain the cytoplasmic pH and stops the normal growth of the plants. Acidic condition in plant growing medium also disrupts the water uptake of plant. Another problem in the acidic soil is associated with phytotoxicity from Al, Mn, and Fe; those can exert detrimental effect on plant growth and development. Although some plant species evolved to survive in areas of low soil pH and can tolerate the acidity of soil, their number is very limited and productivity is very low. On the other hand, the diversity relationship between soil pH and plant is mostly negative, when its evolutionary center any plant species located on high pH soils, that species is more susceptible to acidic pH; hence, this phenomenon should be well considered. However, the mechanism by which the acidity (H+) exerts toxic effect on the plant species is still unclear, and only few researches addressed the effects of external pH change on plants. In addition, how some species can tolerate the low pH demands further researches. Hence, this chapter reviews the mechanism of damage under acidity (H+ rhizotoxicity) stress on plants, and also the recent approaches to improve growth and productivity under acidic condition, from the available literatures.

Keywords

Abiotic stress H+ rhizotoxicity Antioxidant defense Reactive oxygen species Oxidative damages Acidity stress tolerance 

References

  1. Adams F (1984) Crop response to lime in the southern United States. In: Adams F (ed) Soil acidity and liming, 2nd edn. American Society of Agronomy, Crop Science Society of America, and Soil Science Society of America, Madison, pp 211–265Google Scholar
  2. Anugoolprasert O, Kinoshita S, Naito H, Shimizu M, Ehara H (2012) Effect of low pH on the growth, physiological characteristics and nutrient absorption of sago palm in a hydroponic system. Plant Prod Sci 15:125–131CrossRefGoogle Scholar
  3. Arunakumara KKIU, Walpola BC, Yoon M (2013) Aluminum toxicity and tolerance mechanism in cereals and legumes—a review. J Korean Soc Appl Biol Chem 56:1–9CrossRefGoogle Scholar
  4. Arya SK, Roy BK (2011) Manganese induced changes in growth, chlorophyll content and antioxidants activity in seedlings of broad bean (Vicia faba L.). J Environ Biol 32:707–711PubMedGoogle Scholar
  5. Asrar Z, Khavari-nejad RA, Heidari H (2005) Excess manganese effects on pigments of Mentha spicata at flowering stage. Arch Agron Soil Sci 51:101–107CrossRefGoogle Scholar
  6. Audebert A, Fofana M (2009) Rice yield gap due to iron toxicity in West Africa. J Agron Crop Sci 195:66–76CrossRefGoogle Scholar
  7. Ayeni O, Kambizi L, Fatoki O, Olatunji O (2014) Risk assessment of wetland under aluminium and iron toxicities: a review. Aquat Ecosyst Health Manag 17:122–128CrossRefGoogle Scholar
  8. Bahrami H, Razmjoo J, Ostadi JA (2012) Effect of drought stress on germination and seedling growth of sesame cultivars (Sesamum indicum L.). Int J Agric Sci 2:423–428Google Scholar
  9. Bakos F, Darkó É, Ascough G, Gáspár L, Ambrus H, Barnabás B (2008) A cytological study on aluminium-treated wheat anther cultures resulting in plants with increased Al tolerance. Plant Breed 127:235–240CrossRefGoogle Scholar
  10. Bartoli G, Bottega S, Forino LMC, Ciccarelli D, Spano C (2014) Plant adaptation to extreme environments: the example of Cistus salviifolius of an active geothermal alteration field. C R Biol 337:101–110PubMedCrossRefPubMedCentralGoogle Scholar
  11. Batty LC, Younger PL (2003) Effects of external iron concentration upon seedling growth and uptake of Fe and phosphate by the common reed, Phragmites australis (Cav.) Trin ex. Steudel. Ann Bot 92:801–806PubMedPubMedCentralCrossRefGoogle Scholar
  12. Becker M, Asch F (2005) Iron toxicity in rice-conditions and management concepts. J Plant Nutr Soil Sci 168:558–573CrossRefGoogle Scholar
  13. Belachew KY, Stoddard FL (2017) Screening of faba bean (Vicia faba L.) accessions to acidity and aluminium stresses. PeerJ 5:e2963.  https://doi.org/10.7717/peerj.2963CrossRefPubMedPubMedCentralGoogle Scholar
  14. Bellani LM, Rinallo C, Muccifora S, Gori P (1997) Effects of simulated acid rain on pollen physiology and ultrastructure in the apple. Environ Pollut 95:357–362PubMedCrossRefPubMedCentralGoogle Scholar
  15. Bernel JH, Clark RB (1998) Growth traits among sorghum genotypes in response to Al3+. J Plant Nutr 21:297–305CrossRefGoogle Scholar
  16. Bian M, Zhou M, Sun D, Li C (2013) Molecular approaches unravel the mechanism of acid soil tolerance in plants. Crop J 1:91–104CrossRefGoogle Scholar
  17. Blossfeld S, Gansert D (2007) A novel non-invasive optical method for quantitative visualization of pH dynamics in the rhizosphere of plants. Plant Cell Environ 30:176–186PubMedCrossRefGoogle Scholar
  18. Bobbink R, Hicks K, Galloway J, Spranger T, Alkemade R, Ashmore M, Bustamante M, Cinderby S, Davidson E, Dentener F, Emmett B (2010) Global assessment of nitrogen deposition effects on terrestrial plant diversity: a synthesis. Ecol Appl 20:30–59PubMedCrossRefGoogle Scholar
  19. Bona L, Baligar VC, Wright RJ (1995) Soil acidity effects on agribotanical traits of durum and common wheat. In: Date RA, Grundon NJ, Rayment GE, Probert ME (eds) Plant-soil interactions at low pH: principles and management. Developments in plant and soil sciences, vol 64. Springer, Dordrecht, pp 425–428CrossRefGoogle Scholar
  20. Borlaug NE, Dowswell CR (1997) The acid lands: one of agriculture’s last frontiers. In: Moniz AC, Furlani AMC, Schaffert RE, Fageria NK, Rosolem CA, Cantarella H (eds) Plant-soil interactions at low pH: sustainable agriculture and forestry production. Sociedade Brasileira de CiEncia do Solo, Campinas, pp 5–15Google Scholar
  21. Bouma D, Dowling EJ, David DJ (1981) Relations between plant aluminium content and the growth of lucerne and subterranean clover: their usefulness in the detection of aluminium toxicities. Aust J Exp Agric 21:311–317CrossRefGoogle Scholar
  22. Bouman OT, Curtin D, Campbell CA, Biederbeck VO, Ukrainetz H (1995) Soil acidification from long-term use of anhydrous ammonia and urea. Soil Sci Soc Am J 59:1488–1494CrossRefGoogle Scholar
  23. Buerkert AKG, de la Piedra CR, Munns DN (1990) Soil acidity and liming effects on stand, nodulation, and yield of common bean. Agron J 82:749–754CrossRefGoogle Scholar
  24. Bush DS (1995) Calcium regulation in plant cells and its role in signaling. Annu Rev Plant Physiol Plant Mol Biol 46:95–122CrossRefGoogle Scholar
  25. Caires EF, Corrêa JCL, Churka S, Barth G, Garbuio FJ (2006) Surface application of lime ameliorates subsoil acidity and improves root growth and yield of wheat in an acid soil under no-till system. Sci Agric (Piracicaba Braz) 63:502–509CrossRefGoogle Scholar
  26. Caires EF, Garbuio FJ, Churka S, Barth G, Corrêa JCL (2008) Effects of soil acidity amelioration by surface liming on no-till corn, soybean, and wheat root growth and yield. Eur J Agron 28:57–64CrossRefGoogle Scholar
  27. Caires EF, Joris HAW, Churka S (2011) Long-term effects of lime and gypsum additions on no-till corn and soybean yield and soil chemical properties in southern Brazil. Soil Use Manag 27:45–53CrossRefGoogle Scholar
  28. Castro GSA, Crusciol CAC (2013) Effects of superficial liming and silicate application on soil fertility and crop yield under rotation. Geoderma 195 & 196:234–242CrossRefGoogle Scholar
  29. Cha-Um S, Supaibulwattana K, Kirdmanee C (2009) Comparative effects of salt stress and extreme pH stress combined on glycinebetaine accumulation, photosynthetic abilities and growth characters of two rice genotypes. Rice Sci 16:274–282CrossRefGoogle Scholar
  30. Chehregani A, Malayeri BE, Kavianpour F, Yazdi HL (2006) Effect of acid rain on the development, structure and viability of pollen grains in bean plants (Phaseolus vulgaris). Pak J Biol Sci 9:1033–1036CrossRefGoogle Scholar
  31. Chen D, Lan Z, Bai X, Grace JB, Bai Y (2013a) Evidence that acidification-induced declines in plant diversity and productivity are mediated by changes in below-ground communities and soil properties in a semi-arid steppe. J Ecol 101:1322–1334CrossRefGoogle Scholar
  32. Chen J, Wang WH, Liu TW, Wu FH, Zheng HL (2013b) Photosynthetic and antioxidant responses of Liquidambar formosana and Schima superba seedlings to sulfuric-rich and nitric-rich simulated acid rain. Plant Physiol Biochem 64:41–51PubMedCrossRefPubMedCentralGoogle Scholar
  33. Clark JS, Ji Y (1995) Fecundity and dispersal in plant populations: implications for structure and diversity. Am Nat 146:72–111CrossRefGoogle Scholar
  34. Cleavitt N (2001) Disentangling moss species limitations: the role of physiologically based substrate specificity for six species occurring on substrates with varying pH and percent organic matter. Bryologist 104:59–68CrossRefGoogle Scholar
  35. Cosgrove DJ (1999) Enzymes and other agents that enhance cell wall extensibility. Ann Rev Plant Physiol Plant Mol Biol 50:391–417CrossRefGoogle Scholar
  36. Cox RM (1983) Sensitivity of forest plant reproduction to long range transported air pollutants: in vitro sensitivity of pollen to simulated acid rain. New Phytol 95:269–276CrossRefGoogle Scholar
  37. Cox FR, Lins IDG (1984) A phosphorus soil test interpretation for corn grown on acid soils varying in crystalline clay content. Commun Soil Sci Plant Anal 15:1481–1491CrossRefGoogle Scholar
  38. Crawford NM, Forde BG (2002) Molecular and developmental biology of inorganic nitrogen nutrition. Arabidopsis Book 1:e0011.  https://doi.org/10.1199/tab.0011CrossRefPubMedPubMedCentralGoogle Scholar
  39. Cvikrová M, Gemperlová L, Martincová O, Vanková R (2013) Effect of drought and combined drought and heat stress on polyamine metabolism in proline-over-producing tobacco plants. Plant Physiol Biochem 73:7–15PubMedCrossRefPubMedCentralGoogle Scholar
  40. de Almeida NM, de Almeida AF, Mangabeira PAO, Ahnert D, Reis GSM, de Castro AV (2015) Molecular, biochemical, morphological and ultrastructural responses of cacao seedlings to aluminum (Al3+) toxicity. Acta Physiol Plant 37:1–17CrossRefGoogle Scholar
  41. de Vries W, Dobbertin M, Solberg S, Dobben H, Schaub M (2014) Impacts of acid deposition, ozone exposure and weather conditions on forest ecosystems in Europe: an overview. Plant Soil 380:1–45CrossRefGoogle Scholar
  42. Davies DD (1973) Control of and by pH. Symp Soc Exp Biol 27:513–529PubMedPubMedCentralGoogle Scholar
  43. Davies DD (1986) The fine control of cytosolic pH. Physiol Plant 67:702–706CrossRefGoogle Scholar
  44. Delhaize E, Ryan PR (1995) Aluminium toxicity and tolerance in plants. Plant Physiol 107:315–321PubMedPubMedCentralCrossRefGoogle Scholar
  45. Delhaize E, Taylor P, Hocking PJ, Simpson RJ, Ryan PR, Richardson AE (2009) Transgenic barley Hordeum vulgare L. expressing the wheat aluminium resistance gene (TaALMT1) shows enhanced phosphorus nutrition and grain production when grown on an acid soil. Plant Biotechnol J 7:391–400PubMedCrossRefPubMedCentralGoogle Scholar
  46. Demirevska-Kepova K, Simova-Stoilova L, Stoyanova Z, Holzer R, Feller U (2004) Biochemical changes in barley plants after excessive supply of copper and manganese. Environ Exp Bot 52:253–266CrossRefGoogle Scholar
  47. Deska J, Jankowski K, Bombik A, Jankowska J (2011) Effect of growing medium pH on germination and initial development of some grassland plants. Acta Sci Pol 10:45–56Google Scholar
  48. Dyhr-Jensen K, Brix H (1996) Effects of pH on ammonium uptake by Typha latifolia L. Plant Cell Environ 19:1431–1436CrossRefGoogle Scholar
  49. Edel KH, Marchadier E, Brownlee C, Kudla J, Hetherington AM (2017) The evolution of calcium-based signalling in plants. Curr Biol 27:R667–R679PubMedCrossRefGoogle Scholar
  50. Edge CP, Bell SA, Ashenden TW (1994) Contrasting growth responses of herbaceous species to acidic fogs. Agric Ecosyst Environ 51:293–299CrossRefGoogle Scholar
  51. Edmeades DC, Blarney FPC, Farina MPW (1995) Techniques for assessing plant responses on acid soils. In: Date RA, Grundon NJ, Rayment GE, Probert ME (eds) Plant-soil interactions at low pH: principles and management. Developments in plant and soil sciences, vol 64. Springer, Dordrecht, pp 221–233CrossRefGoogle Scholar
  52. Edmonds RL (2012) Patterns of China’s lost harmony: a survey of the country’s environmental degradation and protection. Routledge, NewyorkCrossRefGoogle Scholar
  53. Egerton-Warbuton LM, Griffin BJ, Lamont BB (1993) Pollen̵1pistil interactions in Eucalyptus calophylla provide no evidence of a selection mechanism for aluminium tolerance. Aust J Bot 41:541–552CrossRefGoogle Scholar
  54. Eswaran H, Almaraz R, van den Berg E, Reich P (1997) An assessment of the soil resources of Africa in relation to productivity. Geoderma 77:1–18CrossRefGoogle Scholar
  55. Evans LS, Lewin KF, Patti MJ, Cunningham EA (1983) Productivity of field-grown soybeans exposed to simulated acidic rain. New Phytol 93:377–388CrossRefGoogle Scholar
  56. Ewald J (2003) The calcareous riddle: why are there so many calciphilous species in the central European flora? Folia Geobot 38:357–366CrossRefGoogle Scholar
  57. Fageria NK, Baligar VC (2001) Improving nutrient use efficiency of annual crops in Brazilian acid soils for sustainable crop production. Commun Soil Sci Plant Anal 32:1303–1319CrossRefGoogle Scholar
  58. Fageria NK, Castro EM, Baliga VC (2004) Response of upland rice genotypes to soil acidity. In: Wilson MJ, He Z, Yang X (eds) The red soils of China: their nature, management and utilization. Springer, New York, pp 219–237CrossRefGoogle Scholar
  59. Fageria NK, Moreira A, Castro C, Moraes MF (2013) Optimal acidity indices for soybean production in Brazilian Oxisols. Commun Soil Sci Plant Anal 44:2941–2951CrossRefGoogle Scholar
  60. Farias TP, Trochmann A, Soares BL, Maringá FMS (2016) Rhizobia inoculation and liming increase cowpea productivity in Maranhão state. Acta Sci Agron 38:387–395CrossRefGoogle Scholar
  61. Felle HH (1988) Short term pH regulation in plants. Physiol Plant 74:583–591CrossRefGoogle Scholar
  62. Felle HH (1998) The apoplastic pH of the Zea mays root cortex as measured with pH-sensitive microelectrodes: aspects of regulation. J Exp Bot 49:987–995CrossRefGoogle Scholar
  63. Felle HH, Waller F, Molitor A, Kogel KH (2009) The mycorrhiza fungus Piriformospora indica induces fast root-surface pH signaling and primes systemic alkalinization of the leaf apoplast upon powdery mildew infection. Mol Plant-Microbe Interact 22:1179–1185PubMedCrossRefGoogle Scholar
  64. Fernando DR, Marshall AT, Lynch JP (2016) Foliar nutrient distribution patterns in sympatric maple species reflect contrasting sensitivity to excess manganese. PLoS ONE 11(7):e0157702. http://doi.org/10.1371/journal.pone.0157702
  65. Forster BP, Ellis RP, Thomas WTB, Newton AC, Tuberosa R, This D, El-Enein RA, Bahri MH, Ben Salem M (2000) The development and application of molecular markers for abiotic stress tolerance in barley. J Exp Bot 51:19–27PubMedCrossRefGoogle Scholar
  66. Foy CD (1984) Physiological effects of hydrogen, aluminum, and manganese toxicities in acid soil. In: Adams F (ed) Soil acidity and liming, 2nd edn. American Society of Agronomy, Crop Science Society of America, and Soil Science Society of America, Madison, pp 57–97Google Scholar
  67. Foy CD, Chaney RL, White MC (1978) The physiology of metal toxicity in plants. Annu Rev Plant Physiol 29:511–566CrossRefGoogle Scholar
  68. Gabara B, Sklodowska M, Wyrwicka A, Glinska S, Capinska M (2003) Changes in the ultra-structure of chloroplasts and mitochondria and antioxidant enzyme activity in Lycopersicum esculentum Mill. leaves sprayed with acid rain. Plant Sci 164:507–516CrossRefGoogle Scholar
  69. Gao D, Knight MR, Trewavas AJ, Sattelmacher B, Plieth C (2004) Self-reporting Arabidopsis expressing pH and [Ca2+] indicators unveil ion dynamics in the cytoplasm and in the apoplast under abiotic stress. Plant Physiol 134:898–908PubMedPubMedCentralCrossRefGoogle Scholar
  70. Garcia-Oliveira A, Benito C, Prieto P, Menezes RA, Rodrigues-Pousada C, Guedes-Pinto H, Martins-Lopes P (2013) Molecular characterization of TaSTOPI homoeologues and their response to aluminium and proton (H+) toxicity in bread wheat (Triticum aestivum L.). BMC Plant Biol 13:134.  https://doi.org/10.1186/1471-2229-13-134CrossRefPubMedPubMedCentralGoogle Scholar
  71. Garcia-Oliveira AL, Chander S, Barcelo J, Poschenrieder C. (2016) Aluminium Stress in Crop Plants. In: Yadav P, Kumar S, Jain V (eds) Recent Advances in Plant Stress Physiology, Daya Publishing House, New Delhi, pp 237–263Google Scholar
  72. Gill SS, Tuteja N (2010) Reactive oxygen species and antioxidant machinery in abiotic stress tolerance in crop plants. Plant Physiol Biochem 48:909–930PubMedCrossRefGoogle Scholar
  73. Ginocchio R, de la Fuente LM, Sanchez P, Bustamante E, Silva Y, Urrestarazu P, Rodriguez PH (2009) Soil acidification as a confounding factor on metal phytotoxicity in soils spiked with copper-rich mine wastes. Environ Toxicol Chem 28:2069–2081PubMedCrossRefGoogle Scholar
  74. Gordana B, Grljusic S, Rozman V, Lukic D, Lackovic R, Novoselovic D (2007) Seed age and pH of water solution effects on field pea (Pisum sativum L.) germination. Not Bot Hort Agrobot Cluj 35:20–26Google Scholar
  75. Goulding KWT (2016) Soil acidification and the importance of liming agricultural soils with particular reference to the United Kingdom. Soil Use Manag 32:390–399PubMedPubMedCentralCrossRefGoogle Scholar
  76. Gunsé B, Poschenrieder C, Barceló J (1997) Water transport properties of roots and root cortical cells in proton-and Al-stressed maize varieties. Plant Physiol 113:595–602PubMedPubMedCentralCrossRefGoogle Scholar
  77. Guo TR, Yao PC, Zhang ZD, Wang JJ, Wang M (2012) Devolvement of antioxidative defense system in rice growing seedlings exposed to aluminum toxicity and phosphorus deficiency. Rice Sci 19:179–185CrossRefGoogle Scholar
  78. Gupta N, Gaurav SJ, Kumar A (2013) Molecular basis of aluminium toxicity in plants: a review. Am J Plant Sci 4:21–37CrossRefGoogle Scholar
  79. Hai-yang H, Chun-qin C, Qiang-qiang D, Zhi-bing W (2013) Effect of pH value on seed germination and seedling growth of Betula luminifera. J Southwest Forest Univ 5:006Google Scholar
  80. Haling RE, Richardson AE, Culvenor RA, Lambers H, Simpson RJ (2010) Root morphology, root-hair development and rhizosheath formation on perennial grass seedlings is influenced by soil acidity. Plant Soil 335:457–468CrossRefGoogle Scholar
  81. Hasanuzzaman M, Hossain MA, Fujita M (2012) Exogenous selenium pretreatment protects rapeseed seedlings from cadmium-induced oxidative stress by upregulating antioxidant defense and methylglyoxal detoxification systems. Biol Trace Elem Res 149:248–261PubMedCrossRefGoogle Scholar
  82. Hasanuzzaman M, Nahar K, Hossain MS, Mahmud JA, Rahman A, Inafuku M, Oku H, Fujita M (2017) Coordinated actions of glyoxalase and antioxidant defense systems in conferring abiotic stress tolerance in plants. Int J Mol Sci 18:200.  https://doi.org/10.3390/ijms18010200CrossRefPubMedCentralPubMedGoogle Scholar
  83. Hasanuzzaman M, Nahar K, Alam MM, Bhuyan MHMB, Oku H, Fujita M (2018) Exogenous nitric oxide pretreatment protects Brassica napus L. seedlings from paraquat toxicity through the modulation of antioxidant defense and glyoxalase systems. Plant Physiol Biochem 126:173–186PubMedCrossRefGoogle Scholar
  84. Haug A, Foy CE (1984) Molecular aspects of aluminum toxicity. Crit Rev Plant Sci 1:345–373CrossRefGoogle Scholar
  85. Havlin JL, Beaton SL, Tisdale SL, Nelson WL (2005) In: Havlin J (ed) Soil fertility and fertilizers: an introduction to nutrient management, vol 515. Pearson Prentice Hall, Upper Saddle River, pp 97–141Google Scholar
  86. He G, Zhang J, Hu Z, Wu J (2011) Effect of aluminum toxicity and phosphorus deficiency on the growth and photosynthesis of oil tea (Camellia oleifera Abel.) seedlings in acidic red soils. Acta Physiol Plant 33:1285–1292CrossRefGoogle Scholar
  87. Helyar KR, Porter WM (1989) Soil acidification, its measurement and the processes involved. In: Robson AD (ed) Soil acidity and plant growth. Academic Press, New York, pp 61–102CrossRefGoogle Scholar
  88. Hernandez A, Francisco J, Corpas FJ, Gomez GM, del Rio LA, Sevilla F (1993) Salt induced oxidative stresses mediated by activated oxygen species in pea leaf mitochondria. Physiol Plant 89:103–110CrossRefGoogle Scholar
  89. Hinsinger P, Plassard C, Tang C, Jaillard B (2003) Origins of root-mediated pH changes in the rhizosphere and their responses to environmental constraints: a review. Plant Soil 248:43–59CrossRefGoogle Scholar
  90. Hiscox JD, Isrealstam GF (1979) A method for the extraction of chlorophyll from leaf tissue without maceration. Can J Bot 57:1332–1334CrossRefGoogle Scholar
  91. Hoekenga OA, Maron LG, Pineros MA, Cancado GMA, Shaff J, Kobayashi Y, Ryan PR, Dong B, Delhaize E, Sasaki T, Matsumoto H, Yamamoto Y, Koyama H, Kochian LV (2006) AtALMT1, which encodes a malate transporter, is identified as one of several genes critical for aluminum tolerance in Arabidopsis. Proc Natl Acad Sci U S A 103:9738–9743PubMedPubMedCentralCrossRefGoogle Scholar
  92. Hong E, Ketterings Q, Mcbride M (2010) Manganese. Agronomy fact sheet series–fact sheet 49. Nutrient Management Spear Program, Field Crop Extension, College of Agriculture and Life Sciences, Cornell University Cooperative Extension, Ithaca. http://nmsp.cals.cornell.edu. Accessed 30 Sept 2018
  93. Huang YL, Yang S, Long GX, Zhao ZK, Li XF, Gu MH (2016) Manganese toxicity in sugarcane plantlets grown on acidic soils of southern China. PLoS One 11(3):e0148956.  https://doi.org/10.1371/journal.pone.0148956CrossRefPubMedPubMedCentralGoogle Scholar
  94. Ikka T, Kobayashi Y, luchi S, Sakurai N, Shibata D, Kobayashi M, Koyama H (2007) Natural variation of Arabidopsis thaliana reveals that aluminum resistance and proton resistance are controlled by different genetic factors. Theor Appl Genet 115:709–719PubMedCrossRefGoogle Scholar
  95. Ingerpuu N (2002) Bryophyte diversity and vascular plants. Tartu University Press, TartuGoogle Scholar
  96. Iuchi S, Koyama H, luchi A, Kobayashi Y, Kitabayashi S, Kobayashi Y, Ikka T, Hirayama T, Shinozaki K, Kobayashi M (2007) Zinc finger protein STOP1 is critical for proton tolerance in Arabidopsis and coregulates a key gene in aluminum tolerance. Proc Natl Acad Sci U S A 104:9900–9905PubMedPubMedCentralCrossRefGoogle Scholar
  97. Ivanov Y, Savochkin Y, Kuznetsov V (2013) Effect of mineral composition and medium pH on scots pine tolerance to toxic effect of zinc ions. Russ J Plant Physiol 60:260–269CrossRefGoogle Scholar
  98. Iyer-Pascuzzi AS, Jackson T, Cui H, Petricka JJ, Busch W, Tsukagoshi H, Benfey PN (2011) Cell identity regulators link development and stress responses in the Arabidopsis root. Dev Cell 21:770–782PubMedPubMedCentralCrossRefGoogle Scholar
  99. Jin J, Jiang H, Zhang X, Wang Y, Song X (2013) Detecting the responses of Masson pine to acid stress using hyperspectral and multispectral remote sensing. Int J Remote Sens 34:7340–7355CrossRefGoogle Scholar
  100. Joris HAW, Caires EF, Bini AR, Scharr DA, Haliski A (2013) Effects of soil acidity and water stress on corn and soybean performance under a no-till system. Plant Soil 365:409–424CrossRefGoogle Scholar
  101. Jovanovic Z, Djalovic I, Komljenovic I, Kovacevic V, Cvijovic M (2006) Influences of liming on vertisol properties and yields of the field crops. Cereal Res Commun 34:517–520CrossRefGoogle Scholar
  102. Jovanovic Z, Djalovic I, Tolimir M, Cvijovic M (2007) Influence of growing sistem and NPK fertilization on maize yield on pseudogley of Central Serbia. Cereal Res Commun 35:1325–1329CrossRefGoogle Scholar
  103. Kalir A, Poljakoff-Mayber A (1981) Changes in activity of malate dehydrogenase, catalase, peroxidase and superoxide dimutase in the leaves of Halimione portulacoides (L.). Allen exposed to high sodium chloride concentrations. Ann Bot 47:75–85CrossRefGoogle Scholar
  104. Kamaluddin M, Zwiazek JJ (2004) Effects of root medium pH on water transport in paper birch (Betula papyrifera) seedlings in relation to root temperature and abscisic acid treatments. Tree Physiol 24:1173–1180.  https://doi.org/10.1093/treephys/24.10.1173CrossRefPubMedPubMedCentralGoogle Scholar
  105. Kang D, Seo Y, Futakuchi K, Vijarnsorn P, Ishii R (2011) Effect of aluminum toxicity on flowering time and grain yield on rice genotypes differing in al-tolerance. J Crop Sci Biotechnol 14:305–309CrossRefGoogle Scholar
  106. Kapczyńska A, Magdziarz K (2015) Influence of substrate pH on the growth and flowering of Mandevilla Lindl. Sundaville pretty red. Folia Hort 27:79–83CrossRefGoogle Scholar
  107. Kariuki SK, Zhang H, Schroder JL, Edwards J, Payton M, Carver BF, Raun WR, Krenzer EG (2007) Hard red winter wheat cultivar responses to a pH and aluminum concentration gradient. Agron J 99:88–98CrossRefGoogle Scholar
  108. Kasai M, Sasaki M, Yamamoto Y, Matsumoto H (1992) Aluminum stress increases K+ efflux and activities of ATP- and PPj-dependent H+ pumps of tonoplast-enriched membrane vesicles from barley roots. Plant Cell Physiol 33:1035–1039Google Scholar
  109. Khabaz-Saberi H, Barker SJ, Rengel Z (2012) Tolerance to ion toxicities enhances wheat (Triticum aestivum L.) grain yield in waterlogged acidic soils. Plant Soil 354:371–381CrossRefGoogle Scholar
  110. Kidd PS, Proctor J (2001) Why plants grow poorly on very acid soils: are ecologists missing the obvious? J Exp Bot 52:791–799PubMedCrossRefGoogle Scholar
  111. Kinraide TB (1993) Aluminum enhancement of plant-growth in acid rooting media: a case of reciprocal alleviation of toxicity by 2 toxic cations. Physiol Plant 88:619–625PubMedCrossRefGoogle Scholar
  112. Kinraide TB, Parker DR (1987) Non-phytotoxicity of the aluminum sulfate ion, AlSO4+. Physiol Plant 71:207–212CrossRefGoogle Scholar
  113. Kinraide TB, Ryan PR, Kochian LV (1994) Al3+-Ca2+ interactions in aluminium rhizotoxicity. II. Evaluating the Ca2+-displacement hypothesis. Planta 192:104–109Google Scholar
  114. Kisinyo PO, Othieno CO, Gudu SO, Okalebo JR, Opala PA, Maghanga JK, Ng’etich WK, Agalo JJ, Opile RW, Kisinyo JA, Ogola BO (2013) Phosphorus sorption and lime requirements of maize growing acids soil of Kenya. Sustain Agric Res 2:116–123CrossRefGoogle Scholar
  115. Kobayashi Y, Ohyama Y, Kobayashi Y, Ito H, Iuchi S, Fujita M, Zhao CR, Tanveer T, Ganesan M, Kobayashi M, Koyama H (2014) STOP2 activates transcription of several genes for Al-and low pH-tolerance that are regulated by STOP1 in Arabidopsis. Mol Plant 7:311–322PubMedCrossRefGoogle Scholar
  116. Kochian L, Hoekenga OA, Piňeros MA (2004) How do crop plants tolerate acid soils? Mechanisms of aluminum tolerance and phosphorous efficiency. Annu Rev Plant Biol 55:459–493PubMedCrossRefGoogle Scholar
  117. Kochian LV, Pineros MA, Liu J, Magalhaes JV (2015) Plant adaptation to acid soils: the molecular basis for crop aluminium resistance. Annu Rev Plant Physiol 66:571–598Google Scholar
  118. Kolodziejek J, Patykowski J (2015) Effect of environmental factors on germination and emergence of invasive Rumex confertus in Central Europe. Sci World J 2015:170176.  https://doi.org/10.1155/2015/170176CrossRefGoogle Scholar
  119. Konishi S, Miyamoto S (1983) Alleviation of aluminum stress and stimulation of tea pollen tube growth by fluorine. Plant Cell Physiol 24:857–862CrossRefGoogle Scholar
  120. Kooistra E (1967) Femaleness in breeding glasshouse cucumbers. Euphytica 16:1–17CrossRefGoogle Scholar
  121. Koyama H, Toda T, Yokota S, Zuraida D, Hara T (1995) Effects of aluminium and pH on root growth and cell viability in Arabidopsis thaliana strain Landsberg in hydroponic culture. Plant Cell Physiol 36:201–205Google Scholar
  122. Koyama H, Toda T, Hara T (2001) Brief exposure to low-pH stress causes irreversible damage to the growing root in Arabidopsis thaliana: pectin–Ca interaction may play an important role in proton rhizotoxicity. J Exp Bot 52:361–368PubMedGoogle Scholar
  123. Krstic D, Djalovic I, Nikezic D, Bjelic D (2012) Aluminium in acid soils: chemistry, toxicity and impact on maize plants. In: Aladjadjiyan A (ed) Food production—approaches, challenges and tasks. InTech, London.  https://doi.org/10.5772/33077CrossRefGoogle Scholar
  124. Krug EC, Frink CR (1983) Acid rain on acid soil: a new perspective. Science 221:520–525PubMedCrossRefGoogle Scholar
  125. Kumar S, Meena RS, Yadav GS, Pandey A (2017) Response of sesame (Sesamum indicum L.) to sulphur and lime application under soil acidity. Int J Plant Soil Sci 14:1–9CrossRefGoogle Scholar
  126. Lager I, Andreasson O, Dunbar TL, Andreasson E, Escobar MA, Rasmusson AG (2010) Changes in external pH rapidly alter plant gene expression and modulate auxin and elicitor responses. Plant Cell Environ 33:1513–1528PubMedPubMedCentralGoogle Scholar
  127. Laghmouchi Y, Belmehdi O, Bouyahya A, Senhaji NS, Abrini J (2017) Effect of temperature, salt stress and pH on seed germination of medicinal plant Origanum compactum. Biocatal Agric Biotechnol 10:156–160CrossRefGoogle Scholar
  128. Lavres J, Malavolta E, Nogueira NL, Moraes MF, Rodrigues A, Lanzoni M, Pereira C (2009) Changes in anatomy and root cell ultrastructure of soybean genotypes under manganese stress. R Bras Ci Solo 33:395–403CrossRefGoogle Scholar
  129. Lazof DB, Holland MJ (1999) Evaluation of the aluminium-induced root growth inhibition in isolation from low pH effects in Glycine max, Pisum sativum, and Phaseolus vulgaris. Aust J Plant Physiol 26:147–157Google Scholar
  130. Lee SS, Kim JH, Hong SB, Yun SH (1998) Effect of humidification and hardening treatment on seed germination of rice. Korean J Crop Sci 43:157–160Google Scholar
  131. Lefebvre V, Kiani SP, Durand-Tardif M (2009) A focus on natural variation for abiotic constraints response in the model species Arabidopsis thaliana. Int J Mol Sci 10:3547–3582PubMedPubMedCentralCrossRefGoogle Scholar
  132. Legesse H, Nigussie-Dechassa R, Gebeyehu S, Bultosa G, Mekbib F (2013) Response to soil acidity of common bean genotypes (Phaseolus vulgaris L.) under field conditions at Nedjo, Western Ethiopia. Sci Technol Arts Res J 2:3–15CrossRefGoogle Scholar
  133. Lidon FC, Teixeira MG (2000) Ricetolerance to excess Mn: implications in the chloroplast lamellae and synthesis of a novel Mnprotein. Plant Physiol Biochem 38:969–978CrossRefGoogle Scholar
  134. Lidon FC, Barreiro M, Ramalho J (2004) Manganese accumulation in rice: implications for photosynthetic functioning. J Plant Physiol 161:1235–1244PubMedCrossRefGoogle Scholar
  135. Long A, Zhang J, Yang L-T, Ye X, Lai N-W, Tan L-L, Lin D, Chen L-S (2017) Effects of low pH on photosynthesis, related physiological parameters, and nutrient profiles of citrus. Front Plant Sci 8:185.  https://doi.org/10.3389/fpls.2017.00185CrossRefPubMedPubMedCentralGoogle Scholar
  136. Longnecker DE (1974) The influence of high sodium upon fruiting and shedding boll characteristics, fiber properties and yields of two cotton species. Soil Sci 118:387–396CrossRefGoogle Scholar
  137. Magidow LC, Tommaso AD, Ketterings QM, Mohler CL, Milbrath LR (2013) Emergence and performance of two invasive swallowworts (Vincetoxicum spp.) in contrasting soil types and soil pH. Invasive Plant Sci Manag 6:281–291CrossRefGoogle Scholar
  138. Marciano DPRO, Ramos FT, Alvim MN, Magalhaes JR, França MGC (2010) Nitric oxide reduces the stress effects of aluminum on the process of germination and early root growth of rice. J Plant Nutr Soil Sci 173:885–891CrossRefGoogle Scholar
  139. Marschner H (1991) Mechanisms of adaptation of plants to acid soils. Plant Soil 134:1–20CrossRefGoogle Scholar
  140. Martins N, Gonçalves S, Palma T, Romano A (2011) The influence of low pH on in vitro growth and biochemical parameters of Plantago almogravensis and P. algarbiensis. Plant Cell Tissue Organ Cult 107:113–121CrossRefGoogle Scholar
  141. Martins N, Gonçalves S, Romano A (2013a) Metabolism and aluminum accumulation in Plantago almogravensis and P. algarbiensis in response to low pH and aluminum stress. Biol Plant 57:325–331CrossRefGoogle Scholar
  142. Martins N, Osório ML, Gonçalves S, Osório J, Palma T, Romano (2013b) A Physiological responses of Plantago algarbiensis and P. almogravensis shoots and plantlets to low pH and aluminum stress. Acta Physiol Plant 35:615–625CrossRefGoogle Scholar
  143. Meda AR, Furlani PR (2005) Tolerance to aluminum toxicity by tropical leguminous plants used as cover crops. Braz Arch Biol Technol 48:309–317CrossRefGoogle Scholar
  144. Menconi MCLM, Sgherri CLM, Pinzino C, Navari-Lzzo F (1995) Activated oxygen production and detoxification in wheat plants subjected to a water deficit programme. J Exp Bot 46:1123–1130CrossRefGoogle Scholar
  145. Michaels H (1910) Action of aqueous solutions of electrolytes on germination. Chem Abstr 4:1984–1985Google Scholar
  146. MiransarI M, Smith DL (2007) Overcoming the stressful effects of salinity and acidity on soybean nodulation and yields using signal molecule genistein under field conditions. J Plant Nutr 30:1967–1992CrossRefGoogle Scholar
  147. Misra A, Tyler G (1999) Influence of soil moisture on soil solution chemistry and concentrations of minerals in the calcicoles Phleum phleoides and Veronica spicata grown on a limestone soil. Ann Bot 84:401–410CrossRefGoogle Scholar
  148. Mohanty S, Das AB, Das P, Mohanty P (2004) Effect of a low dose of aluminum on mitotic and meiotic activity, 4C DNA content, and pollen sterility in rice, Oryza sativa L. cv. Lalat. Ecotoxicol Environ Saf 59:70–75PubMedCrossRefGoogle Scholar
  149. Mora M, Rosas A, Ribera A, Rengel R (2009) Differential tolerance to Mn toxicity in perennial ryegrass genotypes: involvement of antioxidative enzymes and root exudation of carboxylates. Plant Soil 320:79–89CrossRefGoogle Scholar
  150. Moroni J, Scott B, Wratten N (2003) Differential tolerance of high manganese among rapeseed genotypes. Plant Soil 253:507–519CrossRefGoogle Scholar
  151. Munzuroglu O, Obek E, Geckil H (2003) Effects of simulated acid rain on the pollen germination and pollen tube growth of apple (Malus sylvestris Miller cv. Golden). Acta Biol Hung 54:95–103PubMedCrossRefGoogle Scholar
  152. Murach D, Ulrich B (1988) Destabilization of forest ecosystems by acid deposition. GeoJournal 17:253–259CrossRefGoogle Scholar
  153. Nahar K, Hasanuzzaman M, Suzuki T, Fujita M (2017) Polyamines-induced aluminum tolerance in mung bean: a study on antioxidant defense and methylglyoxal detoxification systems. Ecotoxicology 26:58–73PubMedCrossRefGoogle Scholar
  154. Najeeb U, Xu L, Shafaqat A, Jilani G, Gong HJ, Shen WQ, Zhou WJ (2009) Citric acid enhances the phytoextraction of manganese and plant growth by alleviating the ultrastructural damages in Juncus effusus L. J Hazard Mater 170:1156–1163PubMedCrossRefGoogle Scholar
  155. Nazmi G, Esma AYY, Aykut T (2016) Acidity effect in pollen germination and tube length of Prunus amygdalus Batsch and Prunus domestica L. J Appl Biol Sci 10:41–45Google Scholar
  156. Neuvonen S, Nyyssönen T, Ranta H, Kiilunen S (1991) Simulated acid rain and the reproduction of mountain birch [Betula pubescens ssp. tortuosa (Ledeb.) Nyman]: a cautionary tale. New Phytol 118:111–117CrossRefGoogle Scholar
  157. Nian H, Yang C, Huang H, Hideaki M (2009) Effects on low pH and aluminum stresses on common beans (Phaseolus vulgaris) differing in low phosphorus and photoperiod responses. Front Biol 4:446–452CrossRefGoogle Scholar
  158. Nuruddin AA, Chang M (1999) Responses of herbaceous mimosa (Mimosa strigillosa), a new reclamation species to soil pH. Resour Conserv Recycl 27:287–298CrossRefGoogle Scholar
  159. Pal’ove-Balang P, Čiamporová M, Zelinová V, Pavlovkin J, Gurinová E, Mistrík I (2012) Cellular responses of two Latin-American cultivars of Lotus corniculatus to low pH and Al stress. Cent Eur J Biol 7:1046–1054Google Scholar
  160. Paoletti E (1991) Effects of acidity and detergent on in vitro pollen germination and tube growth in forest tree species. Tree Physiol 10:357–366CrossRefGoogle Scholar
  161. Pärtel M (2002) Local plant diversity patterns and evolutionary history at the regional scale. Ecology 83:2361–2366CrossRefGoogle Scholar
  162. Pärtel M, Zobel M, Zobel K, van der Maarel E (1996) The species pool and its relation to species richness: evidence from Estonian plant communities. Oikos 75:111–117CrossRefGoogle Scholar
  163. Pavlovkin J, Pal’ove-Balang P, Kolarovič L, Zelinová V (2009) Growth and functional responses of different cultivars of Lotus corniculatus to aluminum and low pH stress. J Plant Physiol 166:1479–1487PubMedCrossRefGoogle Scholar
  164. Pereira EG, Oliva MA, Rosado-Souza L, Mendes GC, Colares DS, Stopato CH, Almeida AM (2013) Iron excess affects rice photosynthesis through stomatal and non-stomatal limitations. Plant Sci 201 & 202:81–92CrossRefGoogle Scholar
  165. Plate F (1913) Inhibition in the seed of Avena sativa. Chem Abstr 8:360Google Scholar
  166. Popescu A (1998) Contributions and limitations to symbiotic nitrogen fixationin common bean (Phaseolus vulgaris L.) in Romania. Plant Soil 204:117–125CrossRefGoogle Scholar
  167. Poschenrieder C, Llugany M, Barcelo J (1995) Short-term effects of pH and aluminumon mineral-nutrition in maize varieties differing in proton and aluminum tolerance. J Plant Nutr 18:1495–1507CrossRefGoogle Scholar
  168. Promsy G (1911) Influence of acids on germination. Acad Sci 152:450–452Google Scholar
  169. Qiao F, Zhang XM, Liu X, Chen J, Hu WJ, Liu TW, Liu JY, Zhu CQ, Ghoto K, Zhu XY, Zheng HL (2018) Elevated nitrogen metabolism and nitric oxide production are involved in Arabidopsis resistance to acid rain. Plant Physiol Biochem 127:238–247PubMedCrossRefGoogle Scholar
  170. Ramlall C, Varghese B, Ramdhani S, Pammenter NW, Bhatt A, Berjak P, Sershen (2015) Effects of simulated acid rain on germination, seedling growth and oxidative metabolism of recalcitrant-seeded Trichilia dregeana grown in its natural seed bank. Physiol Plant 153:149–160PubMedCrossRefGoogle Scholar
  171. Rangel AF, Mubin M, Rao IM, Horst WJ (2005) Proton toxicity interferes with the screening of common bean Phaseolus vulgaris genotypes for aluminium resistance in nutrient solution. J Plant Nutr Soil Sci 168:607–616CrossRefGoogle Scholar
  172. Rao IM, Miles JW, Beede SE, Horst WJ (2016) Root adaptations to soils with low fertility and aluminium toxicity. Ann Bot 118:593–605PubMedCentralCrossRefPubMedGoogle Scholar
  173. Ring SM, Fisher RP, Poile GJ, Helyar KR, Conyers MK, Morris SG (1993) Screening species and cultivars for their tolerance to acidic soil conditions. Plant Soil 155:521–524CrossRefGoogle Scholar
  174. Rosas A, Rengel Z, Mora M (2007) Manganese supply and pH influence growth, carboxylate exudation and peroxidase activity of ryegrass and white clover. J Plant Nutr 30:253–270CrossRefGoogle Scholar
  175. Rouphael Y, Cardarelli M, Colla G (2015) Role of arbuscular mycorrhizal fungi in alleviating the adverse effects of acidity and aluminium toxicity in zucchini squash. Sci Hortic 188:97–105CrossRefGoogle Scholar
  176. Saenen E, Horemans N, Vanhoudt N, Vandenhove H, Biermans G, van Hees M, Wannijn J, Vangronsveld J, Cuypers A (2013) Effects of pH on uranium uptake and oxidative stress responses induced in Arabidopsis thaliana. Environ Toxicol Chem 32:2125–2133PubMedCrossRefGoogle Scholar
  177. Saenen E, Horemans N, Vanhoudt N, Vandenhove H, Biermans G, Hees MV, Wannijn J, Vangronsveld J, Cuypers A (2014) The pH strongly influences the uranium-induced effects on the photosynthetic apparatus of Arabidopsis thaliana plants. Plant Physiol Biochem 82:254–261Google Scholar
  178. Sairam RK (1994) Effect of moisture stress on physiological activities of two contrasting wheat genotypes. Indian J Exp Biol 32:584–593Google Scholar
  179. Sairam RK, Deshmukh PS, Saxena DC (1998) Role of antioxidant systems in wheat genotypes tolerance to water stress. Biol Plant 41:387–394CrossRefGoogle Scholar
  180. Sakano K (1998) Revision of biochemical pH-stat: involvement of alternative pathway metabolisms. Plant Cell Physiol 39:467–473CrossRefGoogle Scholar
  181. Samac DA, Tesfaye M (2003) Plant improvement for tolerance to aluminium in acid soils. Plant Cell Tissue Organ Cult 75:189–207CrossRefGoogle Scholar
  182. Sawaki Y, Iuchi S, Kobayashi Y, Kobayashi Y, Ikka T, Sakurai N, Fujita M, Shinozaki K, Shibata D, Kobayashi M, Koyama H (2009) STOP1 regulates multiple genes that protect Arabidopsis from proton and aluminum toxicities. Plant Physiol 150:281–294PubMedPubMedCentralCrossRefGoogle Scholar
  183. Searcy KB, Mulcahy DL (1990) Comparison of the response to aluminum toxicity in gametophyte and sporophyte of four tomato (Lycopersicon esculentum Mill). Theor Appl Genet 80:289–295PubMedCrossRefGoogle Scholar
  184. Shamsi IH, Wei K, Zhang GP, Jilani GH, Hassan MJ (2008) Interactive effects of cadmium and aluminum on growth and antioxidative enzymes in soybean. Biol Plant 52:165–169CrossRefGoogle Scholar
  185. Shavrukov Y, Hirai Y (2016) Good and bad protons: genetic aspects of acidity stress responses in plants. J Exp Bot 67:15–30PubMedCrossRefGoogle Scholar
  186. Shi QH, Zhu ZJ, Juan LI, Qian QQ (2006) Combined effects of excess Mn and low pH on oxidative stress and antioxidant enzymes in cucumber roots. Agric Sci China 5:767–772CrossRefGoogle Scholar
  187. Sidhu SS (1983) Effects of simulated acid rain on pollen germination and pollen tube growth of white spruce (Picea glauca). Can J Bot 61:3095–3099CrossRefGoogle Scholar
  188. Siecińska J, Nosalewicz A (2016) Aluminium toxicity to plants as influenced by the properties of the root growth environment affected by other co-stressors. Rev Environ Contam Toxicol 243:1–26Google Scholar
  189. Sierra J, Noël C, Dufour L, Ozier-Lafontaine H, Welcker C, Desfontaines L (2003) Mineral nutrition and growth of tropical maize as affected by soil acidity. Plant Soil 252:215–226CrossRefGoogle Scholar
  190. Sierra J, Ozier-Lafontaine H, Dufour L, Meunier A, Bonhomme R, Welcker C (2006) Nutrient and assimilate partitioning in two tropical maize cultivars in relation to their tolerance to soil acidity. Field Crops Res 95:234–249CrossRefGoogle Scholar
  191. Sikirou M, Saito K, Dramé KN, Saidou A, Dieng I, Ahanchédé A, Venuprasad R (2016) Soil-based screening for iron toxicity tolerance in rice using pots. Plant Prod Sci 19:489–496CrossRefGoogle Scholar
  192. Singh VP, Mall SL, Billore SK (1975) Effect of pH on germination of four common grass species of Ujjain (India). J Range Manag 6:497–498CrossRefGoogle Scholar
  193. Singh NB, Yadav K, Amist N (2011a) Phytotoxic effects of aluminum on growth and metabolism of Pisum sativum L. Int J Innov Biol Chem Sci 2:10–21Google Scholar
  194. Singh VP, Tripathi DK, Kumar D, Chauhan DK (2011b) Influence of exogenous silicon addition on aluminium tolerance in rice seedlings. Biol Trace Elem Res 144:1260–1274PubMedCrossRefGoogle Scholar
  195. Slootmaker LAJ (1974) Tolerance to high soil acidity in wheat related species, rye and triticale. Euphytica 23:505–513CrossRefGoogle Scholar
  196. Soil Survey Division Staff (2017) Examination and description of soil profiles. In: Soil Survey Division Staff (eds) Soil survey manual. US Department of Agriculture Handbook 18Washington, DC pp 83−230Google Scholar
  197. Song H, Xu X, Wang H, Tao Y (2011) Protein carbonylation in barley seedling roots caused by aluminum and proton toxicity is suppressed by salicylic acid. Russ J Plant Physiol 58:653–659CrossRefGoogle Scholar
  198. Srivastava S, Dubey RS (2011) Manganese-excess induces oxidative stress, lowers the pool of antioxidants and elevates activities of key antioxidative enzymes in rice seedlings. Plant Growth Regul 64:1–16CrossRefGoogle Scholar
  199. Steiner F, Zoz T, Junior ASP, Castagnara DD, Dranski JAL (2012) Effects of aluminium on plant growth and nutrient uptake in young physic nut plants. Semin Ciênc Agrar 33:1779–1788CrossRefGoogle Scholar
  200. Sullivan TJ, Lawrence GB, Bailey SW, McDonnell TC, Beier CM, Weathers KC, McPherson GT, Bishop DA (2013) Effects of acidic deposition and soil acidification on sugar maple trees in the adirondack mountains, New York. Environ Sci Technol 47:12687–12694PubMedCrossRefPubMedCentralGoogle Scholar
  201. Suthar AC, Naik VR, Mulani RM (2009) Seed and seed germination in Solanum nigrum Linn. Am Eurasian J Agric Environ Sci 5:179–183Google Scholar
  202. Tang C, Diatloff E, Rengel Z, McGann B (2001) Growth response to subsurface soil acidity of wheat genotypes differing in aluminium tolerance. Plant Soil 236:1–10CrossRefGoogle Scholar
  203. Tang C, Rengel Z, Abrecht D, Tennant D (2002) Aluminium-tolerant wheat uses more water and yields higher than aluminium-sensitive one on a sandy soil with subsurface acidity. Field Crop Res 78:93–103CrossRefGoogle Scholar
  204. Tang C, Asseng S, Diatloff E, Rengel Z (2003) Modelling yield losses of aluminium-resistant and aluminium-sensitive wheat due to subsurface soil acidity: effects of rainfall, liming and nitrogen application. Plant Soil 254:349–360CrossRefGoogle Scholar
  205. Taranishi Y, Tanaka A, Osumi N, Fukui S (1974) Catalase activity of hydrocarbon utilizing Candida yeast. Agric Biol Chem 38:1213–1216CrossRefGoogle Scholar
  206. The C, Calba H, Horst WJ, Zonkeng C (2001) Maize grain yield correlated responses to change in acid soil characteristics after 3 years of soil amendments. In: Seventh Eastern and Southern Africa regional maize conference, 11th to 15th February 2001, pp 222–227Google Scholar
  207. The C, Calba H, Zonkeng C, Ngonkeu ELM, Adetimirin VO, Mafouasson HA, Meka SS, Horst WJ (2006) Responses of maize grain yield to changes in acid soil characteristics after soil amendments. Plant Soil 284:45–57CrossRefGoogle Scholar
  208. The C, Meka SS, Ngonkeu ELM, Bell JM, Mafouasson HA, Menkir A, Calba H, Zonkeng C, Atemkeng M, Horst WJ (2012) Maize grain yield responses to changes in acid soil characteristics with yearly leguminous crop rotation, fallow, slash, burn and liming practices. Int J Plant Soil Sci 1:1–15CrossRefGoogle Scholar
  209. Troiano J, Colavito L, Heller L, HcCune DC, Jacobson JS (1983) Effects of acidity of simulated rain and its joint action with ambient ozone on measures of biomass and yield in soybean. Environ Exp Bot 23:113–119CrossRefGoogle Scholar
  210. Turner GD, Lau RR, Young DR (1998) Effect of acidity on germination and seedling growth of Paulownia tomentosa. J Appl Ecol 25:561–567CrossRefGoogle Scholar
  211. Uchida R, Hue NV (2000) Soil acidity and liming. In: Silva JA, Uchida R (eds) Plant nutrient management in Hawaii’s soils, approaches for tropical and subtropical agriculture. College of Tropical Agriculture and Human Resources, University of Hawaii, Manoa, pp 101–111Google Scholar
  212. Ulrich B, Mayer R, Khanna PK (1980) Chemical changes due to acid precipitation in a loess-derived soil in Central Europe. Soil Sci 130:193–199CrossRefGoogle Scholar
  213. Van Schaik CP, Mirmanto E (1985) Spatial variation in the structure and litter fall of a Sumatran rain forest. Biotropica 17:196–205CrossRefGoogle Scholar
  214. Van Wambeke A (1976) Formation, distribution and consequences of acid soils in agricultural development. In: Wright MJ, Ferrari SA (eds) Proceedings of workshop on plant adaptation to mineral stress in problem soils. Special Publications Cornell University, Agricultural Experiment Station, Ithaca, pp 15–24Google Scholar
  215. Vitorello VA, Capaldi FRC, Stefanuto VA (2005) Recent advances in aluminium toxicity and resistance in higher plants. Braz J Plant Physiol 17:129–143CrossRefGoogle Scholar
  216. Vleeshouwers LM, Bowmeester HJ, Karssen CM (1995) Redefining seed dormancy: an attempt to integrate physiology and ecology. J Ecol 83:1031–1037CrossRefGoogle Scholar
  217. Von Uexkȕll HR, Mutert E (1995) Global extent, development and economic impact of acid soils. Plant Soil 171:1–15CrossRefGoogle Scholar
  218. Wen XJ, Duan CQ, Zhang DC (2013) Effect of simulated acid rain on soil acidification and rare earth elements leaching loss in soils of rare earth mining area in southern Jiangxi Province of China. Environ Earth Sci 69:843–853CrossRefGoogle Scholar
  219. Wenzl P, Mancilla LI, Mayer JE, Albert R, Rao IM (2003) Simulating infertile acid soils with nutrient solutions. Soil Sci Soc Am J 67:1457–1469CrossRefGoogle Scholar
  220. Wikipedia (2018) Soil pH, from Wikipedia, the free encyclopedia. https://en.wikipedia.org/wiki/Soil_pH. Accessed 20 Sept 2018
  221. Wilkinson RE, Duncan RR (1989) Sorghum seedling growth as influenced by H+, Ca2+, and Mn2+ concentrations. J Plant Nutr 12:1379–1394CrossRefGoogle Scholar
  222. Wood S, Sebastian K, Scherr SJ (2000) Pilot analysis of global ecosystems: agroecosystems. WRI and IFPRI, WashingtonGoogle Scholar
  223. Yan F, Feuerle R, Schaffer S, Fortmeier H, Schubert S (1998) Adaptation of active proton pumping and plasmalemma ATPase activity of corn roots to low root medium pH. Plant Physiol 117:311–319PubMedPubMedCentralCrossRefGoogle Scholar
  224. Yang JL, Li YY, Zhang YJ, Zhang SS, Wu YR, Wu P, Zheng SJ (2008) Cell Wall polysaccharides are specifically involved in the exclusion of aluminium from the rice root apex. Plant Physiol 146:602–611PubMedPubMedCentralCrossRefGoogle Scholar
  225. Yang M, Huang SX, Fang SZ, Huang XL (2011) Response of seedling growth of four eucalyptus clones to acid and aluminum stress. Plant Nutr Fert Sci 17:195–201Google Scholar
  226. Yang ZB, Rao IM, Horst WJ (2013) Interaction of aluminium and drought stress on root growth and crop yield on acid soils. Plant Soil 372:3–25CrossRefGoogle Scholar
  227. Yang M, Tan L, Xu Y, Zhao Y, Cheng F, Ye S, Jiang W (2015) Effect of low pH and aluminum toxicity on the photosynthetic characteristics of different fast growing eucalyptus vegetatively propagated clones. PLoS One 10:e0130963.  https://doi.org/10.1371/journal.pone.0130963CrossRefPubMedPubMedCentralGoogle Scholar
  228. Yu H, He N, Wang Q, Zhu J, Gao Y, Zhang Y, Jia Y, Yu G (2017) Development of atmospheric acid deposition in China from the 1990s to the 2010s. Environ Pollut 231:182–190PubMedCrossRefGoogle Scholar
  229. Zabawi AGM, Esa SM, Leong CP (2008) Effects of simulated acid rain on germination and growth of rice plant. J Trop Agric Food Sci 36:1–6Google Scholar
  230. Zeigler RS, Pandey S, Miles J, Gourley LM, Sarkarung S (1995) Advances in the selection and breeding of acid-tolerant plants: rice, maize, sorghum and tropical forages. In: Date RA, Grundon NJ, Rayment GE, Probert ME (eds) Plant-soil interactions at low pH: principles and management. Developments in plant and soil sciences, vol 64. Springer, Dordrecht, pp 391–406CrossRefGoogle Scholar
  231. Zhang X, Liu P, Yang YS, Xu G (2007) Effect of Al in soil on photosynthesis and related morphological and physiological characteristics of two soybean genotypes. Bot Stud 48:435–444Google Scholar
  232. Zhang H, Tan Z, Hu L, Wang S, Luo J, Jones RL (2010) Hydrogen sulfide alleviates aluminum toxicity in germinating wheat seedlings. J Integr Plant Biol 52:556–567PubMedCrossRefGoogle Scholar
  233. Zhang CP, Meng P, Li JZ, Wan XC (2014) Interactive effects of soil acidification and phosphorus deficiency on photosynthetic characteristics and growth in Juglans regia seedlings. China J Plant Ecol 38:1345–1355CrossRefGoogle Scholar
  234. Zhang Y-K, Zhu D-F, Zhang Y-P, Chen H-Z, Xiang J, Lin X-Q (2015) Low pH-induced changes of antioxidant enzyme and atpase activities in the roots of rice (oryza sativa l.) seedlings. PLoS One 10:e0116971.  https://doi.org/10.1371/journal.pone.0116971CrossRefPubMedPubMedCentralGoogle Scholar
  235. Zhao MR, Li F, Fang Y, Gao Q, Wang W (2011) Expansin-regulated cell elongation is involved in the drought tolerance in wheat. Protoplasma 248:313–323PubMedCrossRefGoogle Scholar
  236. Zhao XQ, Guo SW, Shinmachi F, Sunairi M, Noguchi A, Hasegawa I, Shen RF (2013) Aluminum tolerance in rice is antagonistic with nitrate preference and synergistic with ammonium preference. Ann Bot 111:69–77PubMedCrossRefGoogle Scholar
  237. Zhu Y, Di T, Xu G, Chen X, Zeng H, Yan F, Shen Q (2009) Adaptation of plasma membrane H+-ATPase of rice roots to low pH as related to ammonium nutrition. Plant Cell Environ 32:1428–1440PubMedCrossRefGoogle Scholar

Copyright information

© Springer Nature Switzerland AG 2019

Authors and Affiliations

  • M. H. M. Borhannuddin Bhuyan
    • 1
    • 2
    • 3
  • Mirza Hasanuzzaman
    • 4
    Email author
  • Kamrun Nahar
    • 5
  • Jubayer Al Mahmud
    • 6
  • Khursheda Parvin
    • 1
    • 7
  • Tasnim Farha Bhuiyan
    • 5
  • Masayuki Fujita
    • 8
  1. 1.Laboratory of Plant Stress Responses, Department of Applied Biological, Sciences, Faculty of AgricultureKagawa UniversityTakamatsuJapan
  2. 2.Bangladesh Agricultural Research InstituteJoydebpur, GazipurBangladesh
  3. 3.Citrus Research Station, Bangladesh Agricultural Research Institute (BARI)JaintiapurBangladesh
  4. 4.Department of Agronomy, Faculty of AgricultureSher-e-Bangla Agricultural UniversityDhakaBangladesh
  5. 5.Department of Agricultural Botany, Faculty of AgricultureSher-e-Bangla Agricultural UniversityDhakaBangladesh
  6. 6.Department of Agroforestry and Environmental Science, Faculty of AgricultureSher-e-Bangla Agricultural UniversityDhakaBangladesh
  7. 7.Department of Horticulture, Faculty of AgricultureSher-e-Bangla Agricultural UniversityDhakaBangladesh
  8. 8.Laboratory of Plant Stress Responses, Department of Applied Biological Sciences, Faculty of AgricultureKagawa UniversityTakamatsuJapan

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