Abstract
The stress conditions of salt-alkalinized soil were simulated to investigate the features and acting factors of salt-alkaline mixed stress, using a natural salt-alkaline tolerant grass Aneurolepidium chinense (Trin.) Kitag. According to the features of salt-alkalinized soil in the northeast of China, various salt-alkali conditions with different salinities and pHs were established by mixing NaCl, NaHCO3, Na2SO4, and Na2CO3, in various proportions. The treatments included a salt concentration range of 50 to 350 mM and pH values from 7.14 to 10.81. Seedlings of A. chinense were stressed under these salt-alkali conditions. Several physiological indices of seedling stress were determined, including survival rate, tillering rate, number of rhizomes, relative growth rate (RGR), proline content, electrolyte leakage rate, and Na+ and K+ content, in order to analyze the characteristics of the stresses due to the salt-alkali mixes and their main stress factors.
The results showed that the survival rate, tillering rate, number of rhizomes, RGR, and K+ content of A. chinense decreased with increasing salinity and pH (or alkalinity). Proline and Na+ content and electrolyte leakage rate increased with increasing salinity and pH (or alkalinity). The deleterious effects of a high pH value or salinity alone were significantly less than those of high pH in combination with salinity. This result suggested that for a salt-alkaline mixed stress, a reciprocal enhancement between salt stress and alkali stress was a characteristic feature, and it was most evidently reflected in the survival rate. When salinity was below 125 mM or pH was below 8.8, survival rates were all 100%. However, when salinity was above 125 mM and pH was above 8.8, survival rates sharply declined with the increasing of either salinity or pH.
The buffer capacity of the treatment solution was taken as a stress factor in order to simplify the stress factor analysis. The results of the statistical analysis showed that for the stress factors of the salt-alkaline mixed stress, [CO 2−3 ] and [HCO −3 ] could be fully represented by the buffer capacity, and [Na+] could be fully represented by salinity, whereas [SO 2−4 ] was negligible. Therefore, four factors, salinity, buffer capacity, pH and [Cl−], could reflect all of the stress factors. Perfect linear correlations were observed between all physiological indices and four or three stress factors by a stepwise regression analysis. However, the effects of the four stress factors on the physiological indices were significantly different in magnitude. Buffer capacity and salinity were dominant factors for all physiological indices. Thus, it is reasonable to consider the sum of salinity plus buffer capacity as the strength value of salt-alkaline mixed stress. Furthermore, the relationships between different physiological indices and various stress factors were shown to be different.
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Abbreviations
- RGR:
-
relative growth rate
- DW:
-
dry weight
- FW:
-
fresh weight
References
JD Brand C. Tang AJ. Rathjen (2002) ArticleTitleScreening rough-seeded lupins (Lupinus pilosus Murr. and Lupinus atlanticus Glads.) for tolerance to calcareous soils Plant Soil 245 261–275 Occurrence Handle10.1023/A:1020490626513 Occurrence Handle1:CAS:528:DC%2BD38XnsVGltrw%3D
SA. Campbell JN. Nishio (2000) ArticleTitleIron deficiency studies of sugar beet using an improved sodium bicarbonate-buffered hydroponics growth system J. Plant Nutr 23 741–757 Occurrence Handle1:CAS:528:DC%2BD3cXjs1yqtb8%3D
JM. Cheeseman (1988) ArticleTitleMechanisms of salinity tolerance in plants Plant Physiol 87 547–550 Occurrence Handle1:CAS:528:DyaL1cXltVOlt70%3D
GR Cramer A. Lauchli E. Epstein (1986) ArticleTitleEffects of NaCl and CaCl2 on ion activities in complex nutrient solutions and root growth of cotton Plant Physiol 81 792–797 Occurrence Handle1:CAS:528:DyaL28Xkslyjurs%3D
B Degenhardt H Gimmler E. Hose W. Hartung (2000) ArticleTitleEffect of alkaline and saline substrates on ABA contents, distribution and transport in plant roots Plant Soil 225 83–94 Occurrence Handle10.1023/A:1026539311358 Occurrence Handle1:CAS:528:DC%2BD3MXotVGjug%3D%3D
CF Lacerda Particlede J Cambraia MA Oliva HA. Ruiz JT. Prisco (2003) ArticleTitleSolute accumulation and distribution during shoot and leaf development in two sorghum genotypes under salt stress Environ. Exp. Bot 49 107–120 Occurrence Handle10.1016/S0098-8472(02)00064-3
HMA. ElSamad MAK. Shaddad (1996) ArticleTitleComparative effect of sodium carbonate, sodium sulphate, and sodium chloride on the growth and related metabolic activities of pea plants J. Plant Nutr 19 717–728 Occurrence Handle1:CAS:528:DyaK28XislCitL4%3D
Y. Ge JD. Li (1990) ArticleTitleA preliminary study on the effects of halophytes on salt accumulation and desalination in the soil of Songnen Plain, Northeast China Acta Prataculturae Sin 1 70–76
C Ghoulam A. Foursy K Fares (2002) ArticleTitleEffects of salt stress on growth, inorganic ions and proline accumulation in relation to osmotic adjustment in five sugar beet cultivars Environ. Exp. Bot 47 39–50 Occurrence Handle10.1016/S0098-8472(01)00109-5 Occurrence Handle1:CAS:528:DC%2BD3MXos1WrsL0%3D
W Hartung L Leport RG Ratcliffe A Sauter R. Duda NC. Turner (2002) ArticleTitleAbscisic acid concentration, root pH and anatomy do not explain growth differences of chickpea (Cicer arietinum L.) and lupin (Lupinus angustifolius L.) on acid and alkaline soils Plant Soil 240 191–199 Occurrence Handle10.1023/A:1015831610452 Occurrence Handle1:CAS:528:DC%2BD38XkvVajsro%3D
L. Hong W. Lin (1996) ArticleTitleEffects of salt stress on root plasma membrane characteristics of salt-tolerant and salt-sensitive buffalograss clones Environ. Exp. Bot 36 239–247 Occurrence Handle10.1016/0098-8472(96)01025-8
SA James DT. Bell AD. Robson (2002) ArticleTitleGrowth response of highly tolerant Eucalyptus species to alkaline pH, bicarbonate and low iron supply Aust. J. Exp. Agric 42 65–70 Occurrence Handle10.1071/EA00154 Occurrence Handle1:CAS:528:DC%2BD38XitFGqsLk%3D
S. Kawanabe TC. Zhu (1991) ArticleTitleDegeneration and conservation of Aneurolepidium chinense grassland in Northern China J. Japan. Grassl. Sci 37 91–99
RW Kingsbury E. Epstein RW. Peary (1984) ArticleTitlePhysiological responses to salinity in selected lines of wheat Plant Physiol 74 417–423 Occurrence Handle1:CAS:528:DyaL2cXhtFyjsLk%3D
J. Liu JK. Zhu (1997) ArticleTitleProline accumulation and salt-stress-induced gene expression in a salt-hypersensitive mutant of Arabidopsis Plant Physiol 114 591–596 Occurrence Handle10.1104/pp.114.2.591 Occurrence Handle1:CAS:528:DyaK2sXktVSks78%3D Occurrence Handle9193091
S Lutts JM. Kiner J. Bouharmont (1996) ArticleTitleNaCl-induced senescence in leaves of rice (Oryza sativa L.) cultivars differing in salinity resistance Ann. Bot 78 389–398 Occurrence Handle10.1006/anbo.1996.0134 Occurrence Handle1:CAS:528:DyaK28XmtVSrsrc%3D
KB. Marcum (1999) ArticleTitleSalinity tolerance mechanisms of grasses in the subfamily chloridoideae Crop Sci 39 1153–1160
G Nuttall RD. Armstrong DJ. Connor (2003) ArticleTitleEvaluating physicochemical constraints of Calcarosols on wheat yield in the Victorian southern Mallee Aust. J. Agric. Res 54 487–497
PC Sharma B Mishra RK Singh YP. Singh NK. Tyagi (2001) ArticleTitleAdaptability of onion (Allium cepa) genotypes to alkali and salinity stresses Indian J. Agric. Sci 70 674–678
DC. Shi LJ. Yin (1993) ArticleTitleDifference between salt (NaCl) and alkaline (Na2CO3) stresses on Puccinellia tenuiflora (Griseb.) Scribn. et Merr. plants Acta Bot. Sin 35 144–149 Occurrence Handle1:CAS:528:DyaK2cXltVej
DC Shi YM. Sheng KF. Zhao (1998) ArticleTitleStress effects of mixed salts with various salinities on the seedlings of Aneurolepidium chinense Acta Bot. Sin 40 1136–1142 Occurrence Handle1:CAS:528:DyaK1MXhtFSqt7Y%3D
DC Shi SJ Yin GH. Yang KF. Zhao (2002) ArticleTitleCitric acid accumulation in an alkali-tolerant plant Puccinellia tenuiflora under alkaline stress Acta Bot. Sin 44 537–540 Occurrence Handle1:CAS:528:DC%2BD3sXlt1amtb4%3D
M Soussi A. Ocana C. Lluch (1998) ArticleTitleEffects of salt stress on growth, photosynthesis and nitrogen fixation in chick-pea (Cicer arietinum L.). J Exp. Bot 49 1329–1337 Occurrence Handle1:CAS:528:DyaK1cXlsVOktrg%3D
A. Surjus M. Durand (1996) ArticleTitleLipid changes in soybean root membranes in response to salt treatment J. Exp. Bot 47 17–23 Occurrence Handle1:CAS:528:DyaK28XhtlajtL8%3D
C. Tang NC. Turner (1999) ArticleTitleThe influence of alkalinity and water stress on the stomatal conductance, photosynthetic rate and growth of Lupinus angustifolius L. and Lupinus pilosus Murr Aust. J. Exp. Agric 39 457–464
Tanji KK. (1990). Agricultural salinity assessment and management. American Society of Civil Engineers, New York pp. 1–112
BS. Wang KF. Zhao (1995) ArticleTitleComparison of extractive methods of Na+ and K+ in wheat leaves Plant Physiol. Commun 3 50–52
H Yan DC Shi SJ. Yin W. Zhao (2000) ArticleTitleEffects of Ca2+, ABA and H3PO4 on relaxing stress of Na2CO3 and NaCl Chinese J. Appl. Ecol 11 889–892 Occurrence Handle1:CAS:528:DC%2BD3MXit1SlsL8%3D
GL Zhu XW. Deng WN. Zuo (1983) ArticleTitleDetermination of free proline in plants Plant Physiol. Commun 1 35–37
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Shi, D., Wang, D. Effects of various salt-alkaline mixed stresses on Aneurolepidium chinense (Trin.) Kitag.. Plant Soil 271, 15–26 (2005). https://doi.org/10.1007/s11104-004-1307-z
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DOI: https://doi.org/10.1007/s11104-004-1307-z