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Mitigation of Mineral Deficiency Stress
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By Dr.s Surya Kant
and Uzi Kafkafi
Department of Field crops, Faculty of Agriculture
The Hebrew
University
PO Box 12 Rehovot, 76100, Israel |
Mitigation by Crop Management
1.
Avoidance of Nutrient Stress
The efficiency of fertilizers might be lower than
fifty per cent either due to mismanagement or due to reactions of the
fertilizers with soil constituents. only a fraction of the fertilizer applied
to the soil is taken up by the crop, the rest is either remains in the soil or
lost through leaching, physical wash off, fixation by the soil, or release to
the atmosphere through chemical and microbiological processes (Hera, 1996).
Fertilizer losses especially of nitrogen could happen during the period of plant
growth and lead to low yields than expected. This
low
uptake and utilization of nutrients out of the added fertilizers results in lower
production and appearance of nutrient stress symptoms. The poor efficiency of
added fertilizers is mainly due to imbalance fertilization or improper
management practices. Critical information on the fertilization practices like:
method of fertilizer placement, time and rate of application and type of
fertilizers are essential for successful yields.
There
are three general main types of nitrogen fertilizers where the nitrogen in the
fertilizer is found in the chemical form of: ammonium, urea and nitrate. Nitrogen
in nitrate form fertilizer are soluble and highly
mobile in soil. They are prone to various kinds of losses: leaching beyond the
root zone in the light textured soils, denitrification in water logged
conditions or short time of over irrigation (Bar-Yosef
and Kafkafi, 1972). Ammonium type fertilizers usually transform in the soil
within a week or two to nitrate form and the further consideration is the same
as for nitrate fertilizers.
Phosphate fertilizers, which are highly
reactive, are fixed in soil and become immobile. Potassic fertilizers are less
mobile, since they are adsorbed on the clay complex. The entire quantity of phosphate and potassic fertilizers are,
therefore, applied in one dose at the time of sowing in annual crops. Whereas, split application of nitrogenous fertilizers increases
nitrate reductase activity, uptake of nitrogen (Abrol, 1990), use efficiency
(Destain et al., 1997) and grain yield (Sabbe and Batchelor, 1990).
Application
of fertilizers in narrow bands beneath and by the side of the crop rows i.e.
band placement is preferable when the crop needs initial good start; when the
soil fertility is low; when fertilizer materials react with soil constituents
leading to fixation (phosphorus) and where volatilization losses are high.
Addition
of organic matter to the soil at regular periods,
helps to maintain the buffer capacity of the soil to supply the essential
elements after its decomposition. Organic matter in soils can be regulated
through different agronomic practices such as application of compost, farmyard
manure, vermicompost, green manure etc’.
2.
Management of Nutrient Stress
When the soil is deficient in a particular nutrient
element and the crop grown on such soil show visible deficiency symptoms, there
is urgent need to correct it to improve the crop production. Methods of
correcting nutrient deficiencies vary according to agro-climatic regions, the
socioeconomic situations of the region, the magnitude of disorder, and nutrient
element involved. A generalized description of these methods is presented in
Table 2. Use of nutrient-efficient cultivars in combination with fertilizers or
amendments may be the best solution for correcting nutrient disorders in field
crops, but this will vary according to situation. Fertilizer recommendations
are usually based on the results of field trials in which crop response to
various rates of fertilizer application is determined. Such response curves
provide relationships between yield and the amount of fertilizer required for a
particular crop grown in a specific agro-climatic region.
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Table
2. Methods
of correcting nutrient deficiency (ased on Fageria et al., (1997b)
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Nutrient
element
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Corrective
Measures
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Nitrogen
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Addition of organic
matter to soil; application of N fertilizer, including legume in crop
rotation; use of foliar spray of 0.25-0.5% solution of urea
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Phosphorus
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Application of
amendments to maintain soil reaction to near neutral in acidic soils; application
of phosphorus fertilizer
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Potassium
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Application of potassium
fertilizers, incorporation of crop residues, manures
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Calcium
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Liming (addition of CaCO3)
of acid soils; addition of gypsum or other soluble calcium source where lime is
not required
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Magnesium
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Application of dolomite
limestone; foliar application of magnesium sulfate or magnesium nitrate
solutions
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Sulfur
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Use of fertilizers
containing sulfur such as ammonium sulfate; single super phosphate; gypsum or
elemental sulfur (in acidic soils only).
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Zinc
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Addition of zinc sulfate
to soil; foliar spray of 0.1-0.5% solution of zinc sulfate
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Iron
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Foliar spray of 2% iron
sulfate or 0.02-0.05% solution of iron chelate; use of efficient cultivars,
fertigation with chelated iron
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Copper
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Soil application of
copper source of fertilizer or foliar spray of 0.1-0.2% solution of copper
sulfate
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Boron
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Soil application of
boron source or foliar spray of 0.1-0.25% solution of borax, care not to exceed
0.5 ppm B in solution in irrigation
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Molybdenum
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Liming of acid soils;
soil application of sodium ammonium molybdate; foliar spray of 0.07-0.1%
solution of ammonium molybdate
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Manganese
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Foliar application of 0.1%
solution of manganese sulfate
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In
a standing crop if the nutrient deficiency is confirm, the foliar application
of selected nutrients by means of spray is a quick way to get rid of stress symptoms
and avoiding yield loss. Foliar fertilization of macro and micronutrients is
best practice whenever nutrient uptake through the roots is restricted due to
adverse growing conditions (El-Fouly and El-Sayed, 1997), when topsoil is dry
particularly in semiarid regions (Grundon, 1980), under saline soils (El-Fouly
and Salama, 1999), and when root activity decreases during reproductive stage
(Ikeda et al., 1991). In calcareous soils iron availability is generally
very low and chlorosis is quite common, foliar spraying under these conditions
is very beneficial (Horesh and Levy, 1981). For example, iron chlorosis was
corrected by foliar application of 0.1% aqueous solution of Fe applied at 2 Kg
Fe ha-1, either as iron citrate or as iron sulfate + 400 g ha-1
citric acid (0.02%), in four equal splits at 30, 45, 60 and 75 days after
emergence in groundnut (Singh and Joshi, 1997). Manganese deficiency in such
soils is also widespread and two or more sprays may be required within a
growing season (Gettier et al., 1985). Not all crops respond equally to
foliar nutrition and the nutrient elements differ in their rate of uptake
through foliage and the degree of mobility within the plant once absorbed
(Table 3).
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Table
3.
General absorption and mobility rankings for foliar applied nutrients (from C
F A, 1985).
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Absorption
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Mobility
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Rapid
Urea Nitrogen, Potassium, Zinc
Moderate
Calcium, Sulfate,
Manganese, Boron
Slow
Magnesium, Copper, Iron,
Molybdenum
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Mobile
Urea Nitrogen,
Potassium, Phosphorus, Sulfate
Partially Mobile
Zinc, Copper, Manganese,
Boron, Molybdenum
Immobile
Iron, Calcium, Magnesium
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Mitigation by Plant Resistance
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Fig.2. Possible
mechanisms in genotypic differences for nutrient efficiency (Marschener,
1977b)
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Nutrient concentration and uptake by different plant genotypes are
the most important criteria for identifying the existing genetic specificity of
plant nutrition (Saric, 1987). The tolerance in a given plant species or
genotype to nutrient stress is closely related to its nutrient use efficiency.
Genotypic differences in nutrient use efficiency are
linked with root nutrient acquisition capacity, or with utilization by the
plant, or both. Various plant species have developed morphological and/or
physiological mechanisms to improve acquisition and use efficiency of mineral
nutrients when grown on poor, infertile soils (Romeheld, 1998). By such mechanisms
plants achieve nutrient deficiency stress tolerance. However, sometimes the
ability to adapt to stress is limited, depending on the intensity and duration
of stress. For example, some nutrient stress factors, when operating for a long
period, can result in inhibited growth and root physiological processes
responsible for nutrient uptake with the consequence of an impaired capability
for adaptation and stress tolerance.
For
a given genotype, nutrient use efficiency is reflected by the ability to produce
a high yield in a soil that is limiting in one or more mineral nutrients for a
standard genotype (Graham, 1984). The efficiency should be compared under
stress and adequate nutrient supply to verify plant species or genotypic
differences in nutrient utilization under sub-optimal and optimal conditions.
The differential response of genotypes to nutrient stress is related to uptake,
transport and utilization pattern of nutrients within plants (Fig.2). Isolation
of intra-species differences in capacity for growth under specific nutritional
conditions, particularly under nutritional stress is a critical aspect in
nutritional plant genetics. A wide range of morphological, anatomical and
physiological plant traits can be responsible for variations in response to
nutrient stress within a plant species. Such traits can function either within
or outside the plant to affect nutrient availability, absorption, translocation
or utilization. Some physiological and morphological plant features controlling
plant resistance to nutritional stress are given in Table 4.
The acquisition of nutrients by plant roots plays the most
important role in tolerance to nutrient stress. Genotypes can differ widely in
both the affinity of uptake and the threshold concentration, for example, the
uptake of phosphorus in corn inbred lines (Schenk and Barber, 1979). The
differences in their ability to grow in soils of low phosphorus status might be
attributed to several factors including differential influx rates, root
length/shoot weight ratios (Fohse et al., 1988) or root system
morphology and root hair density (Randall, 1995). Among the more important
factors is the role of root exudates in making available soil P 'fixed' in
forms such as iron or aluminum phosphate. White lupin and pigeon pea are well
adapted to acidic P-deficient soils (Hocking et al., 1997). White lupin
forms develop proteoid roots (bottlebrush-like clusters of rootlets covered
with a dense mat of root hairs) which are considered to be a response to low P
availability (Marschner, 1986). Proteoid roots of white lupin secrete citric
acid which solubilizes 'fixed' P (Gardner et al., 1983; Gerke et al.,1994),
thus increasing P uptake by the plant. For pigeon pea, secretion of piscidic,
malonic and oxalic acids appears to be the mechanism by which this species is
able to release P from iron and aluminum phosphates (Otani et al.,
1996). Screening of tolerant Medicago sativa and Lablab purpureus
germplasm under phosphorus stress condition was carried out by Mugwira and
Haque (1993a and b) based on their root and shoot growth.
Genetic
differences in K uptake and utilization efficiency in field crop cultivars have
also been observed (Glass et al., 1981). Growth response of 20 wheat
genotypes were compared by Gill et al. (1997) under deficient (0.6 mM) and
adequate (3.0 mM) K levels in solution cultures. Substantial and significant
differences due to K-stress were obvious among genotypes for shoot dry weight,
relative reduction in shoot dry weight, root dry weight, and root/shoot ratio.
Rengel (1997) screened wheat genotypes tolerant to Zn and Mn stress. Wheat
genotypes tolerant to Zn deficiency released greater amounts of
phytosiderophore, 2-deoxymugineic acid, than the sensitive genotypes. In
addition, Zn deficiency increased the numbers of fluorescent pseudomonas in
rhizosphere of all wheat genotypes tested, but the effect was particularly
obvious for genotypes tolerant to Zn deficiency. Under Mn stress, wheat
genotypes tolerant of Mn deficiency had a greater ratio of Mn-reducers to Mn-oxidizers
in the rhizosphere compared to sensitive genotypes. Mn-efficient durum wheat
genotypes had greater Mn uptake from Mn deficient soil, produced higher grain
yield, relative grain yield and above ground biomass and generally maintained
higher seed Mn concentration (Khabaz-Saberi et al., 1997).
The
Fe efficient groundnut cultivar 'ICGV-86031' released more hydrogen ions and
reductants from its roots under iron deficiency stress treatment, maintained
higher leaf Fe and had less chlorosis than the Fe-inefficient cultivar
'TCGS-37' (Reddy et al., 1997). There are also large differences in
tolerance to Fe deficiency among field grown wheat genotypes (Hanson et al.,
1996).
Genetic
control of Cu efficiency has been located on the long arm of the rye chromosome
5 and has been applied to wheat breeding for CU efficiency (Podlesak et al.,
1990).
Similar,
increase in Cu efficiency was observed by Graham (1984) in spring form of rye (Secale
cereale L.) and genetically manipulated wheat. Wheat genotypes differ in
tolerance to Zn deficiency (Graham et al., 1992; Cakmak et al.,
1996a), with durum wheat being generally less tolerant than bread wheat (Rengel
and Graham, 1995; Cakmak et al., 1996). Tolerance of bread wheat genotypes
to Zn and Fe deficiency was expressed in shoot dry weight and relative shoot
growth as compared with to sensitive genotypes (Rengel and Romheld, 2000).
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Cereal
species, as well as genotypes of a given cereal greatly differ in adaptation to
Zn-deficient conditions. The susceptibility of cereals to Zn deficiency was
found to decline in the order: durum wheat > oat > bread wheat >
barley > triticale > rye. Among the cereals, rye showed an exceptionally
high Zn efficiency. Biomass production and grain yield of rye was not affected
under severe Zn-deficient conditions (Cakmak et al., 1997b). Several
mechanisms constitute the physiological bases of Zn efficiency. These are
enhancement of root growth (Dong et al., 1995), root uptake and
root-to-shoot translocation of Zn (Cakmak et al., 1996a; Rengel and
Graham, 1996), release of Zn-mobilizing phytosiderophores from roots (Cakmak et
al., 1996b; Erenoglu et al., 1996) and internal utilization of Zn
(Cakmak et al., 1996b; Rengel, 1995). Use of disomic wheat-rye addition
lines (Triticum aestivum L., cv. Holdfast-Secale cereale L., cv.
King-II) increases Zn efficiency (Table 5). The addition of rye chromosomes,
particularly 1R, 2R and 7R, into Holdfast reduced the severity of deficiency
symptoms (Cakmak et al., 1997a). Transgenic plants have improved
nutrient efficiency and resistant to nutrient stress. This was found for copper
in wheat (Graham et al., 1987); boron and phosphorus in tobacco (Brown et al.,
1999; Lopez-Bucio et al., 2000).
The
molecular approach to breeding of mineral deficiency resistance and mineral
efficiency is now receiving increasing attention. QTLs (quantitative trait
loci) controlling Phosphorus efficiency were identified in rice and maize.
Transgenic tobaccos overexpressing ferritin in the plastids or in the cytoplasm
resulted in higher leaf concentration of iron, manganese and zinc (see #4791 in
this site reference database). Tobacco transformation over expressing the
antioxidant superoxide dismutase had greater manganese deficiency resistance
(#4512).
Related Publications
·
Principles of Plant
Nutrition, by K. Mengel and E. A. Kirkby. (International Potash
Institute, Berne, Switzerland).
·
Diagnosis of Mineral
Disorders in Plants. Vol. 1, Principles, by C. Bould, E. H. Hewitt,
and P. Needham. (Chemical Publishing, New York, 1984).
·
Diagnosis of Mineral
Disorders in Plants. Vol. 2, Vegetables, by A. Scarfe and Mary
Turner. (Chemical Publishing, New York, 1984).
·
Plant Analysis
Handbook, by J. Benton Jones Jr., B. Wolf, and H. A. Mills.
(Micro-Macro Publishing, Athens, GA, 1991).
·
Nutritional
Disorders of Plants, Ed. by, Werner Bergmann. (Gustav Fischer Verlag, Gena, Germany, 1992).
·
Nutrient
Deficiencies and Toxicities in Crop Plants, Ed. by, William F.
Bennett. (The American Phytopathological Society, St. Paul Minnesota, 1993).
·
Mineral Nutrition of
Higher Plants 2nd Ed. by, H. Marschner
(Academic Press, London, 1997).
·
Growth and nutrition
of field crops 2nd Ed. by, N. K. Fageria; V.
C. Baligar, and C. A. Jones. (Marcel Dekker, Inc. New York, 1997).
Reviews
·
Raun W.R. Johnson
G.V. 1999. Improving nitrogen use
efficiency for cereal production Agron.
J. 91:357-363.
·
Liptay A. Arevalo A.E.
2000.
Plant mineral accumulation, use and transport during the life cycle of plants: A
review Can. J. Plant Sci. 80:29-38.
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