REVIEWARTICLE

Regulated deficit irrigation for crop production under drought
stress. A review

Qiang Chai1,3 & Yantai Gan2
& Cai Zhao1,3 & Hui-Lian Xu5

& Reagan M. Waskom4
&

Yining Niu1,2
& Kadambot H. M. Siddique6

Accepted: 6 November 2015 /Published online: 18 December 2015
# The Author(s) 2015. This article is published with open access at SpringerLink.com

Abstract Agriculture consumes more than two thirds of the
total freshwater of the planet. This issue causes substantial
conflict in freshwater allocation between agriculture and other
economic sectors. Regulated deficit irrigation (RDI) is key
technology because it helps to improve water use efficiency.
Nonetheless, there is a lack of understanding of the mecha-
nisms with which plants respond to RDI. In particular, little is
known about how RDI might increase crop production while
reducing the amount of irrigation water in real-world agricul-
ture. In this review, we found that RDI is largely implemented
through three approaches: (1) growth stage-based deficit irri-
gation, (2) partial root-zone irrigation, and (3) subsurface drip-
per irrigation. Among these, partial root-zone irrigation is the
most popular and effective because many field crops and some
woody crops can save irrigation water up to 20 to 30 %

without or with a minimal impact on crop yield. Improved
water use efficiency with RDI is mainly due to the following:
(1) enhanced guard cell signal transduction network that de-
creases transpiration water loss, (2) optimized stomatal control
that improves the photosynthesis to transpiration ratio, and (3)
decreased evaporative surface areas with partial root-zone ir-
rigation that reduces soil evaporation. The mechanisms in-
volved in the plant response to RDI-induced water stress in-
clude the morphological traits, e.g., increased root to shoot
ratio and improved nutrient uptake and recovery; physiologi-
cal traits, e.g., stomatal closure, decreased leaf respiration, and
maintained photosynthesis; and biochemical traits, e.g., in-
creased signaling molecules and enhanced antioxidation en-
zymatic activity.

Keywords Agricultural water . Drought stress . Irrigation
management . Leaf water potential . Partial root-zone drying .

Stomatal conductance . Stress-tolerant mechanism .Water
deficit

Contents
1. Introduction
2. Definition and main approaches

2.1. Stage-based deficit irrigation
2.2. Partial root-zone irrigation
2.3. Subsurface irrigation or infiltration movement

3. Physiological basis
3.1. Leaf water content
3.2. Stomatal morphology
3.3. Photosynthesis and respiration

4. Biochemical basis
4.1. Plant hormones
4.2. Antioxidation enzymes
4.3. Non-enzymatic substances

* Qiang Chai
Chaiq@gsau.edu.cn

* Yantai Gan
Gan@agr.gc.ca

1 Gansu Provincial Key Laboratory for Aridland Crop Sciences, Gansu
Agricultural University, Lanzhou 730070, Gansu, China

2 Agriculture and Agri-Food Canada, Swift Current Research and
Development Centre, Saskatchewan S9H 3X2, Canada

3 College of Agronomy, Gansu Agricultural University,
Lanzhou 730070, Gansu, China

4 Colorado Water Institute, Colorado State University, Fort
Collins, CO 80523, USA

5 International Nature Farming Research Center, 5632-1 Hata,
Matsumoto City, Nagano 390-1401, Japan

6 The UWA Institute of Agriculture, The University of Western
Australia, 35 Stirling Highway, Crawley, WA 6009, Australia

Agron. Sustain. Dev. (2016) 36: 3
DOI 10.1007/s13593-015-0338-6

http://crossmark.crossref.org/dialog/?doi=10.1007/s13593-015-0338-6&domain=pdf


5. Plant water status under regulated deficit irrigation
5.1. Determination of water use efficiency
5.2. Improvement of water use efficiency under regulat-

ed deficit irrigation
5.3. Mechanisms involved in improved water use

efficiency
6. Agronomic practices for improving crop productivity

under regulated deficit irrigation
6.1. Promoting plant growth and development
6.2. Stimulating root activity
6.3. Maintaining or increasing plant yield
6.4. Influencing product quality
6.5. Improving nutrient use efficiency
6.6. Enhancing plant acclimatization through biochem-

ical approaches
7. Opportunities and challenges

7.1. Opportunities
7.2. Challenges

8. Suggestions for future research
8.1. Signaling systems
8.2. Physiological and biochemical responses
8.3. Quantification of the magnitude of deficits
8.4. Potential impacts on soil quality attributes

9. Conclusion
References

1 Introduction

About 70 % of Earth’s surface is covered by water (Küppers
et al. 2014; Siddique and Bramley 2014), but only about
2.5 % is freshwater (Gleick and Palaniappan 2010). The
majority of water is trapped in glaciers, permanent snow,
or aquifers (Farihi et al. 2013; Sivakumar 2011). Water
shortages threaten many parts of the world, with nearly
800 million people lack access to safe drinking water and
2.5 billion have no proper sanitation (Schiermeier 2014).
The situation may get worse in coming decades, as world’s
population is expected to increase by 30 % by 2050
(Godfray et al. 2010) coupled with forecasted climate
change (de Wit and Stankiewicz 2006). It is estimated that
up to one fifth of the global population could suffer severe
shortages of freshwater (Schiermeier 2014) or quality water
in the foreseeable future (Girones et al. 2010).

Agriculture is the largest freshwater user on the planet,
consuming more than two thirds of total withdrawals (Gan
et al. 2013). In many parts of the world, irrigation water has
been over-exploited and over-used (Chai et al. 2014a), and
freshwater shortage is becoming critical in the arid and semi-
arid areas of the world (Forouzani and Karami 2011). For
example, China has water resource that is about one quarter
of the world’s average per capita (Liu 2006). The country’s
availability of water resources has declined in recent years,

fast approaching the internationally accepted threshold for
water shortage of 1700 m3 per capita per year. China needs
to produce various commodities to meet the needs of the fast-
growing economy and the 1.3 billion people’s needs for food,
feed, fiber, and fuel (Nie et al. 2012). Yet, the availability of
freshwater for the country’s economy is approaching zero to
negative growth in the foreseeable future (Liu 2006). Also,
rapid urbanization has caused conflict between the need for
freshwater in agriculture and other sectors. Consequently,
freshwater resources available to agriculture will need to be
re-rationalized to satisfy the developmental needs of other
sectors. In a recent review, regulated deficit irrigation (RDI)
has been identified as one of the key water-saving technolo-
gies in agriculture (Chai et al. 2014a). However, there is a lack
of detailed information on the definition, scientific principles,
or specific practices of RDI. Little is known about how this
technology may be practiced effectively in real-world
agriculture.

In the present review, we focus on three aspects: (1) the
definition of RDI and its main application in agriculture; (2)
morphological, physiological, and biochemical basis of plant
responses to RDI; and (3) potential and challenges of applying
RDI in large-scale agriculture. The overall goal is to under-
stand the science behind RDI, provide science-based recom-
mendations on the implementation of this practice in agricul-
ture, and improve water use efficiency (WUE) in crop
production.

2 Definition and main approaches

RDI is generally defined as an irrigation practice whereby a
crop is irrigated with an amount of water below the full re-
quirement for optimal plant growth; this is to reduce the
amount of water used for irrigating crops, improve the re-
sponse of plants to the certain degree of water deficit in a
positive manner, and reduce irrigation amounts or increase
the crop’s WUE. In the scientific literature, there are substan-
tial variations in terms of the definition of “water deficit” for
agricultural crops. To facilitate the analysis and summariza-
tion of the published research findings, we define water deficit
at the following five levels:

1. Severe water deficit—soil water is less than 50 % of the
field capacity;

2. Moderate water deficit—soil water is remained between
50 to 60 % of the field capacity;

3. Mild water deficit—soil water is remained between 60 to
70 % of the field capacity;

4. No deficit or full irrigation—soil water is generally great-
er than 70 % of the field capacity during the key plant
growth period; and

3 Page 2 of 21 Agron. Sustain. Dev. (2016) 36: 3



5. Over-irrigation—the amount of water irrigated may be
greater than what plants would require for optimal
growth.

These definitions provide a “standardized” approach with
which water deficit treatments and the responses reported in
various published studies can be assessed using a similar
scale. There are three main RDI approaches in the production
of agricultural crops, as follows.

2.1 Stage-based deficit irrigation

Stage-based deficit irrigation is defined as RDI applied at dif-
ferent stages of plant development, with water applied to meet
full plant evapotranspiration (ET) at the critical growth stages
and less applied at the non-critical growth stages. The princi-
ple behind this approach is that the response of plants to RDI-
induced water stress varies with growth stages and that less
irrigation applied to plants at non-critical stages may not cause
significant negative impact on plant productivity even though
it may reduce normal plant growth. To apply this approach
effectively, one must predetermine the critical growth stages
for a specific crop species and cultivar and evaluate the rela-
tive sensitivity of crop plants to water deficit at various stages
in their life cycle.

The sensitivity of plant growth stage to water deficit can be
affected by many factors, including climatic conditions, crop
species and cultivars, and agronomic management practices,
among others. For example, under a Mediterranean climate,
the most sensitive growth stage of wheat (Triticum aestivum)
is at stem elongation and booting, followed by anthesis and
grain filling (García Del Moral et al. 2003). In North China
Plains, wheat plants respond to water deficit more sensitively
post-tillering than in the early stage (Kang et al. 2002). With a
plant species, genotypes differ in photosynthesis rate, stomatal
conductance, and transpiration rate, thus, expressing different
degrees of responses to water stress (Hongbo et al. 2005).

Sensitivity to water deficit also depends on crop species.
Rice (Oryza sativa) plants watered at a level equal to full field
capacity during the active tillering stage significantly reduced
the numbers of tillers, panicles, and spikelets and ultimately
decreased grain yield (Ashraf et al. 2012). Cotton (Gossypium
hirsutum L.) receiving mild deficit irrigation at the flowering
and budding stages improved WUE compared to fully irrigat-
ed controls (Du et al. 2006). A short duration of water deficit
during tasselling stages in maize (Zea mays) reduced biomass
production by 30 % and grain yield by up to 40 % (Çakir
2004). In the southern High Plains of the USA, water stress
reduced soybean (Glycine max) yield by 9 to 13 % when
imposed during early flowering to full bloom stage, by 46 %
when imposed during early pod development, and by 45 %
when imposed during later podding (Eck et al. 1987).
Furthermore, the sensitivity to water deficit is also influenced

by agronomic management practices. For example, in a
wheat–maize relay planting study, straw covering on the soil
surface at the vegetative growth stage significantly reduced
stress-induced plant damage and enhanced WUE than any
other treatments in arid irrigation areas (Yin et al. 2015).

2.2 Partial root-zone irrigation

Partial root-zone irrigation (also called partial root-zone dry-
ing in some literatures) is the secondmost popular approach of
RDI. Essentially, half of the root system is irrigated with a full
amount, while the remaining half is exposed to drying soil
(Fig. 1). Typically, this approach includes two types as
follows:

1.Alternate partial root-zone irrigation (Fig. 1a). The watering
and drying of root zone are alternated in a pre-set frequency
that allows the previously well-watered side of the root zone to
dry down while fully irrigating the previously dried root
zones. The drying–wetting frequency is typically decided ac-
cording to water requirements of the crop species, growth
stages, and soil water holding capacity at the time irrigation
is applied. The irrigated and partially dried sides of the root
zone are interchanged in subsequent irrigations.
2. Fixed partial root-zone irrigation (Fig. 1b). During the entire
growth period, approximately half of the root system is irri-
gated in a normal amount each timewhen irrigation is applied,
and the remaining half is always exposed to drying soil.

In both approaches, it is assumed that (i) the fraction of the
root system under the drying soil may respond to drying by
sending a root-sourced signal to the shoot where stomata may
close to reduce water loss through transpiration (Liu et al.
2006b; Sobeih et al. 2004), and (ii) by reducing the amount
of water applied to plants, a small narrowing of the stomatal
opening may occur which helps reduce water loss with little or
no impact on plant photosynthesis (De Souza et al. 2005; Liu
et al. 2004).

The concept of partial root-zone irrigation was originally
derived from some split-root studies conducted in 1980s
(Caradus and Snaydon 1986; Kirkham 1983), and later, alter-
nate drying of part of the root zone with subsequent wetting
was used as an acclimatization process in stress-related studies
(Kang and Zhang 2004). Of the two types, approach (a) is
more common than approach (b). In both approaches, the
roots in the drying zone obtain substantially less irrigation
water than the roots in the wet zone, even though no direct
irrigation is applied to the dry zone. Under field conditions,
the width of the root zone may vary with plant species and
planting configurations.

Positive effects of partial root-zone irrigation have been
shown in many crop species. The possible mechanism respon-
sible for the positive effects may include the following: (i)

Agron. Sustain. Dev. (2016) 36: 3 Page 3 of 21 3



inducing a compensatory effect of water uptake (Jarvis 2011)
where the roots that have access to soil water (wet part of the
zone) increase water uptake and to compensate for the roots
that have little access to water (dry part of the zone), therefore
upholding the full transpiration rate of the plant; (ii) reducing
the surface areas for soil water evaporation; (iii) stimulating
the growth of secondary roots and increasing root activity; and
(iv) improving uptake of mineral nutrients and enhancing nu-
trient recovery in plants. More details on the physiological and

biochemical aspects of the mechanisms are provided in
Sect. 3).

2.3 Subsurface irrigation or infiltration movement

Subsurface irrigation is the third most popular RDI
practice. Irrigation water is supplied to plants by capil-
lary movement from the bottom (Fig. 1c). The root-zone
air space is not immediately filled by water, in contrast
with traditional irrigation where water is supplied direct-
ly overhead and water first fills the air space in the soil.
Infiltration movement induces plant hardening or inter-
nal physiological regulations caused by mild water
stress. A false signal of water deficit is transduced to
the internals of the cell, where it induces apparent
xerophytophysiological regulation with internal adjust-
ment from the gene level to physiological levels (Xu
et al. 2009a, 2011a, 2012). The plants under subsurface
irrigation have been shown to maintain a high leaf tur-
gor potential and a retention of a high symplastic water
fraction that help plants to improve morphological
strengthening, such as a thicker epidermis and more
wax deposits on leaves and cuticle.

Subsurface irrigation is used mostly in nursery sys-
tems and, to a lesser extent, in the production of large-
scale field crops (Xu et al. 2009a). In nursing systems,
potted soil or medium absorbs water through capillary
absorption from the bottom of the pot, and then, water
is transported into root zones. Under field conditions,
irrigation water is usually supplied through a subsoil
dripper system. Research shows that subsurface irriga-
tion increases crop productivity and product quality. For
example, tomato (Solanum lycopersicum L.) seedlings
watered through subsurface irrigation dripper system in-
creased both fruit yield and quality compared to the
control where water was directly dripped to near the
base of the plants (Xu et al. 2011b). Subsurface irriga-
tion usually induces osmotic adjustment, increases leaf
turgor potential, and consequently enhances photosyn-
thetic activities (Xu et al. 2011b).

In some regions, supplementary irrigation is applied to
crops in combination with soil surface covering. At the critical
growth stages, dripper systems are used to provide supple-
mental water under the cover of plastic film (Fig. 2a). In other
cases, some of the plant rows are irrigated and the other plant
rows are left unirrigated but mulched with plastic films (Hu
et al. 2015) (Fig. 2b). In areas with crop straw readily avail-
able, the straw is used to cover the soil surface of plant rows
with alternate rows irrigated (Fig. 2c). All these techniques
add benefits such as reduced soil evaporation and soil erosion,
increased topsoil temperature with plastic cover in the early
spring when soil temperatures are low, and improved soil nu-
trient availability to crops (Gan et al. 2013).

Fig. 1 Sketch of the main “regulated deficit irrigation” approaches,
including a alternate partial root-zone irrigation where the two
neighboring plant rows in every four rows are irrigated and they are
shifted in consecutive irrigations, b fixed partial root-zone irrigation
where the two neighboring plant rows in every four rows are irrigated
every time and the remaining two rows of plants kept in drying soil, and c
subsurface irrigation where irrigation is applied in the lower part of the
root zone

3 Page 4 of 21 Agron. Sustain. Dev. (2016) 36: 3



3 Physiological basis

RDI has been used as a means of saving water in agriculture
since the early 1960s (Bouyoucos 1962; Grimes et al. 1969), but
the physiological basis has not been well documented. During
the past two decades, many researchers have focused on the
determination of the mechanisms involved in the RDI approach
which typically decreases water consumption and increases
WUE with little or no yield penalty. Two basic theoretical as-
sumptions have been made in this regard: (a) a small narrowing
of stomatal opening under RDI-induced water deficit conditions
may enhance leaf water retention and reducewater losswith little

or no effect on photosynthesis, and (b) part of the root system in
drying soil under partial root-zone irrigation sends an enzyme-
based signal to the shoots to stimulate stomatal closure and gen-
erate certain drought-tolerant mechanisms to act against water
stress. There are a number of reports in the scientific literature
that show how plants respond to RDI physiologically. The most
common observations and expressions are as follows.

3.1 Leaf water content

Plant leaves are the key organ for transpiration and photosyn-
thesis, and the complex anatomy of a leaf plays a crucial role

Fig. 2 Sketch of the other
“regulated deficit irrigation”
approaches, including the
following :a dripper systems are
used to provide supplemental
water under plastic film cover at
critical growth stages; b some of
the plant rows are irrigated, and
the other plant rows left
unirrigated are mulched with
plastic films; and c alternate plant
rows are irrigated, and the other
plant rows left unirrigated are
mulched with crop straw (photo
taken from fields in northwest
China in 2014)

Agron. Sustain. Dev. (2016) 36: 3 Page 5 of 21 3



in plant growth and development (Barbour and Farquhar
2004). A short period of mild water deficit under RDI may
promote plants to reduce leaf water content or leaf water po-
tential substantially (Liu et al. 2006a; Pérez-Pastor et al.
2014). Decreased leaf water potential acts as a hydraulic sig-
nal (along with chemical signals discussed in Sect. 4.1) trig-
gering the reduced leaf area expansion and partial closure of
stomata (Shahnazari et al. 2007).

Many factors influence the maintenance of leaf water po-
tential under RDI; this depends on the intensity of water def-
icit applied (Liu et al. 2006a), crop growth stage (Li et al.
2010b), and duration of deficit (Xu et al. 2011a). In potato
(Solanum tuberosum L), partial root-zone irrigation applied
during the early growth period improved the fractional ratio
of water in the cell symplasm to water in apoplasm and
lowered the osmotic potential and relative water content at
the point of incipient plasmolysis (Xu et al. 2011a). The
early-season partial root-zone irrigation resulted in better use
of soil water reserves through improved root to shoot ratio (Li
et al. 2013), increased root biomass (Wang et al. 2012b), and
enhanced root activity (Yang et al. 2012a). As a result, the
early-season partial root-zone irrigation increased photosyn-
thetic activity compared to that applied during the other
growth stages.

Accurate measurement of leaf water potential is essential
when assessing the response of plants to deficit irrigation.
Many methodologies are available for this task, some being
more preferable than others, depending on research prefer-
ences. Leaf water potential associated with RDI can be deter-
mined using the method, such as pressure chamber method
(Sperry et al. 1996), hyperspectral indices (Yi et al. 2013),
normalized spectral indices and ratio spectral indices (Cheng
et al. 2011; Zhang et al. 2012),Mid-wave Infrared Normalized
Difference Water Index (Ullah et al. 2013), near-infrared
hyperspectral imaging (Higa et al. 2013), and microfabricated
thermal sensor (Atherton et al. 2012), among others. We sug-
gest that detailed experiments need to be conducted to com-
pare which method would provide most accurate assessment
of leaf water potential in response to RDI.

3.2 Stomatal morphology

An important physiological response to drought stress associ-
ated with RDI is stomatal characteristics, including stomatal
opening and closing rhythms, the size of guard cells, and
stomatal density. Guard cells regulate both the influx of CO2

as a rawmaterial for photosynthesis and water loss from plants
through transpiration to the atmosphere; thus, guard cells play
a critical role in plant transpiration. In response to RDI-
induced water stress, researchers have shown that guard cells
trigger the process of stomatal closure (Schroeder et al. 2001),
thus reducing water loss. Stomatal behavior of plants under
RDI is regulated by chemical signals that provide the shoot

with some indication of water availability. The central com-
ponent of the signaling process involves the plant hormone
abscisic acid that is produced in roots and shoot and moved to
leaves where it triggers stomatal closure (Fig. 3). This process
may be reversed once normal irrigation is applied (Schroeder
et al. 2001). Also, stomatal density (Sun et al. 2013a), and
changes in xylem sap pH are also involved in the response
of plants to RDI-induced water stress. The redistribution of
inorganic ions between different compartments in the leaf may
provide sensitive control of stomata and water loss in response
to water stress (Sobeih et al. 2004). More details on the in-
volvement of the hormone in stomatal function are provided
in Sect. 4.1.

In potato, partial root-zone irrigation significantly im-
proved stomatal morphological characteristics compared with
fully irrigated controls (Yan et al. 2012). Potato leaves under
partial root-zone irrigation had smaller guard cells with lower
stomatal density than the leaves under conventional irrigation,
providing the benefits of reducing water loss from leaf sur-
faces (Cui et al. 2009a) and increasing net photosynthesis (Liu
and Dickmann 1996).

3.3 Photosynthesis and respiration

Plants under mild deficit associated with RDI often express
different levels of response in photosynthesis and respiration
because RDI is implemented with different degrees of severity
and at different growth stages (Sects. 2.1, 2.2). A number of
studies show that it is common that plants under partial root-
zone irrigation can improve leaf transpiration (Du et al. 2006)
and enhance photosynthesis rate (Romero et al. 2012) com-
pared to the normal irrigation control. In the cotton study (Du
et al. 2006), for example (Fig. 4), irrigation methods and the
amounts of water applied had little or no effect on photosyn-
thesis rate but had highly significant impacts on leaf respira-
tion, seed yield, and WUE. It was consistent across the three
water regimes (22.5- vs 30.0- vs 45.0-cm irrigation each time)
that alternate partial root zone irrigation decreased transpira-
tion, increased seed yield, and enhanced WUE significantly
compared to the other irrigation methods. A low leaf transpi-
ration rate with partial root-zone irrigation allows plants to use
more photosynthates to form sinks (Shahnazari et al. 2007),
increase carboxylation efficiency, or decrease carbon isotope
discrimination and bundle–sheath cell leakiness to CO2

(Wang et al. 2012a). Increased leaf vapor pressure due to
water deficit decreases the ratio of photosynthesis rate to tran-
spiration rate, thus increasing transpiration efficiency
(Shabani et al. 2013).

However, in other studies, plants grown under severe water
stress reduce photosynthesis rate substantially (Romero et al.
2013). The magnitude of the photosynthetic response to RDI
may vary with crop species. Under the same level of water
deficit, mung bean (Vigna radiata) maintained a higher

3 Page 6 of 21 Agron. Sustain. Dev. (2016) 36: 3



Fig. 3 Under drought stress with
regulated deficit irrigation, plant
hormone abscisic acid is
produced in roots and shoot and
acting as a signaling chemical to
the leaves where it triggers
stomatal closure

Fig. 4 Photosynthesis rate, transpiration rate, seed yield, and water use
efficiency of cotton irrigated with conventional furrow irrigation (CFI, all
furrows were irrigated), alternate furrow irrigation (AFI, neighboring two
furrows alternately irrigated), fixed furrow irrigation (FFI, fixed one of

every two furrows irrigated), and a conventional irrigation method (CK).
Vertical line bars are standard errors of the means (data source: Du et al.
2006)

Agron. Sustain. Dev. (2016) 36: 3 Page 7 of 21 3



photosynthesis rate than common bean (Phaseolus vulgaris)
with the same levels of transpiration (Bourgault et al. 2010).

4 Biochemical basis

4.1 Plant hormones

A number of studies have shown that in response to RDI,
plants typically produce phytohormones (also known as plant
growth regulators). These molecules, albeit in low concentra-
tion, regulate cellular processes in targeted cells, control the
formation of flowers, stems, and leaves, and adjust the shed-
ding of leaves and abscission of fruits. More importantly, these
phytohormones act as signaling molecules, regulating a num-
ber of biochemical processes in plants and helping minimize
the potential damage caused by RDI-induced water stress.
Among the phytohormones is abscisic acid, a well-known
plant growth regulator in plants. Since 1960s when abscisic
acid was first discovered, this hormone has been studied ex-
tensively in many crop species. Under the RDI-induced water
stress, biosynthesis occurs indirectly through the production
of the organic pigment carotenoids in the chloroplasts and
chromoplasts. Depending on the level of the stress, abscisic
acid may follow different catabolic pathways (Balint and
Reynolds 2013). At a low level of water stress, abscisic acid
may be catabolized by conjugation to form abscisic acid glu-
cose ester, whereas at a high level of water stress, the oxidation
pathway is preferred, which is leading to the production of
catabolites (phaseic acid or dihydrophaseic acid).

4.2 Antioxidation enzymes

Plants under RDI can alter their cellular metabolism and in-
voke various defense mechanisms. A major defense mecha-
nism is the increased activity of antioxidation enzymes, such
as superoxide dismutase, catalase, ascorbate peroxidase,
guaiacol peroxidase, phenylpropanoid, lipoxygenase, and
malondialdehyde contents in roots and leaves (Guidi et al.
2008; Hu et al. 2010; Sajedi et al. 2011; Sofo et al. 2004).
With partial root-zone irrigation at mild water deficit level,
some plant species maintain or increase the activity of those
enzymes in leaves and roots (Hu et al. 2010). Usually, a higher
degree of enzyme activity is required to improve the protec-
tion against pronounced oxidative stress.

Plant growth stages play an important role in the expression
of enzymatic activities in leaves and roots under water deficit.
For example, partial root-zone irrigation from jointing to
tasselling did not cause damage to maize plants, as the accu-
mulation of these substances prevents plant cell damage from
water stress (Hu et al. 2010). However, water stress during the
silking stage significantly reduced membrane permeability in
maize leaves, as the expression of plasma membrane

aquaporins (an intrinsic protein) in the leaf largely depends
on the developmental stage of the leaf tissue (Hachez et al.
2008). Tomato plants under RDI increased peroxidase activity
in cell walls rapidly during the initial phase of fruit setting,
with enzymatic activity reaching the peak at the end of fruit
ripening (Savić et al. 2008).

The activities of antioxidant enzymes under water stress
vary among plant species or cultivars (Chaitanya et al.
2009). The sensitivity of the enzymatic response depends on
intrinsic genetic traits in plants. In maize, drought-tolerant
cultivars often express a higher concentration of superoxide
anion radicals, malondialdehyde, and proline, along with
higher activities of antioxidant enzymes compared to
drought-sensitive cultivars (Sun et al. 2013a). The increased
biochemical activity in stressed tissues can offset some of the
reduced chlorophyll concentration and chlorophyll fluores-
cence under water stress. However, in some of the woody
plant species, the opposite can be true. For example, olive tree
(Olea europaea) is found to decrease enzymatic activities in
leaves and roots under RDI-induced water stress (Sofo et al.
2004).

4.3 Non-enzymatic substances

Another important defense mechanism with RDI is the
production of non-enzymatic substances, which consist
of low-molecular-weight substances such as soluble
sugars, proline (Mansouri-Far et al. 2010), and
malondialdehyde in leaves (Sofo et al. 2004) and in
roots (Hu et al. 2010). These substances regulate osmot-
ic potential in plants by the law of mass action to re-
duce osmotic stress and enhance plant water holding
capacity. Also, water stress can promote plants to pro-
duce other non-enzymatic substances such as caroten-
oids, nonprotein thiol (Mishra et al. 2013), polyphenols,
and anthocyanins (Tahkokorpi et al. 2007). These sub-
stances may serve to decrease leaf osmotic potential,
allowing leaves to tolerate suboptimal water levels.
Leaf turgor maintenance caused by osmotic adjustment
through solute accumulation is found in plants under
subsurface irrigation (Xu et al. 2009a, 2011a, b).

5 Plant water status under regulated deficit
irrigation

5.1 Determination of water use efficiency

Water use efficiency (WUE) serves as a key variable in the
assessment of plant responses to RDI-induced water stress,
because the outcome of using RDI in crop production is to
assess the amount of irrigation that can be saved or the crop
yield produced per unit of water supplied. Physiologically,

3 Page 8 of 21 Agron. Sustain. Dev. (2016) 36: 3



WUE describes the intrinsic trade-off between carbon fixation
and water loss, because water evaporates from the interstitial
tissues of leaves whenever stomata open for CO2 acquisition
for photosynthesis (Bramley et al. 2013). In plant research,
WUE is defined as crop yield per unit of water used and
calculated using the following formula:

WUEy ¼ Y
�
ET ð1Þ

where Y can be (a) economic yield in kilogram per hectare
(e.g., grain yield in cereals, seed yield in legume and oilseed
crops, tuber yield in potatoes and root crops, and leaf yield in
vegetables), (b) biomass yield in kilogram per hectare, or (c)
energy yield (MJ ha–1) (Chai et al. 2014b), depending on the
nature of the study. In all cases, the denominator ET (mm) is
the total actual evapotranspiration. Thus, the unit of WUE is
typically expressed in kilogram per hectare per millimeter. In
some cases, the term precipitation use efficiency (PUE) (Gan
et al. 2013) or irrigation water use efficiency (Sun et al. 2010)
is used to describe the efficiency of precipitation during the
growing season or the amount of irrigation applied to the crop,
respectively.

In the cases of RDI in crop production, the total and/or
irrigation WUE is most popularly used, which is defined as
follows:

WUEi ¼ Y i−Ydð Þ
Ir

ð2Þ

where Yi is the crop yield with irrigation and Yd is the crop
yield without irrigation or an equivalent rainfed field and Ir is
the amount of irrigation water applied. The unit of WUEi is
kilogram per hectare per millimeter.

In some cases, WUEj is also expressed as the ratio of pho-
tosynthesis rate to transpiration rate or the ratio of photosyn-
thesis rate to stomatal conductance of CO2 (Bramley et al.
2013; Cui et al. 2009a), as follows:

WUE j ¼ Photosynthesis rate

Transpiration rate
or

Photosynthesis rate

Stomatal conductance of CO2

ð3Þ

Additionally, crop water productivity (CWP), an alterna-
tive term, has been used for the expression of WUE by some
irrigation managers and is defined as follows:

CWP ¼ Y

10ET
ð4; Þ

where CWP has a unit of kilogram per cubic meter, Y is the
crop yield (kg ha–1) and ET is total ETover the entire growing
season (mm). Because 1 ha is 10,000 m2, 1 mm (0.001 m) of
ET from 1 ha of cropped land equates to 10 m3. Thus, the ET
denominator is multiplied by 10 to obtain the CWP in kilo-
gram per cubic meter.

5.2 Improvement of water use efficiency under regulated
deficit irrigation

Most of the studies that we have reviewed show that the fore-
most benefit of using RDI is to reduce the amount of irrigation
and increase WUE, but crop yield can be increased, main-
tained, or decreased (Table 1); this has been demonstrated in
many crop species such as green gram (Vigna radiata L.)
(Webber et al. 2006), maize (Li et al. 2013), potato (Xie
et al. 2012), and tomato (Wang et al. 2010a), as well as some
woody plant species, such as pear–jujube tree (Zizyphus
jujube Mill.) (Cui et al. 2009a), almond (Prunus dulcis
Mill.) (Egea et al. 2011), apple (Van Hooijdonk et al. 2004),
and peach (Prunus persica L) (Geiiy et al. 2004).

The following are some typical WUE examples. In a
controlled-environment study with maize, partial root-zone
irrigation applied at the jointing stage reduced water consump-
tion by 12 % and enhanced WUE by 12 % (Li et al. 2010a);
partial root-zone irrigation applied from jointing to tasselling
reduced water consumption by 32 % and enhanced WUE by
41 %. In sunflower (Helianthus annuus) grown in a semiarid
area of Italy, small (150 mm) to moderate (270 mm) amounts
of water ensured an average seed yield but with water saving
by 74 and 53 %, respectively, compared to the fully irrigated
control treatment (Garofalo and Rinaldi 2015). In a study with
potato, partial root-zone irrigation reduced water use by nearly
50 % without reducing potato tuber yield, thus increasing
potato WUE by more than 50 % (Xie et al. 2012). In tomato,
the application of full irrigation until the beginning of the fruit
ripening stage and the cessation of irrigation thereafter saved
irrigation water by 33 % and increased WUE by 42 % with a
5 % yield loss (Kuşçu et al. 2014). Such a water saving phe-
nomenon is also reported in woody plant species. In apple, use
of partial root-zone irrigation helped save irrigation water by
780,000 L per hectare (or 49.8 %) compared to the fully irri-
gated control treatment without affecting apple yield (Van
Hooijdonk et al. 2004). In a 6-year study with ‘Clementina
de Nules’ citrus trees, use of RDI ensured a water saving of
15 % annually without impacting fruit yield (Ballester et al.
2014). In a 5-year study with Japanese plum (Prunus
thibetica), RDI applied post-harvest at 60 and 30 % of the
control (which had 639-mm irrigation annually) helped save
irrigation by 39 and 70 %, respectively, compared to the con-
trol, without causing reduction in fruit yield or quality
(Samperio et al. 2015).

5.3Mechanisms involved in improved water use efficiency

A number of mechanisms are responsible for the reduced wa-
ter use or increased WUE for the plants under RDI-induced
water stress. Those plants under mild water deficit may be
able to perform one or more of the following:

Agron. Sustain. Dev. (2016) 36: 3 Page 9 of 21 3



1. Enhance guard cell signal transduction network that con-
trols water loss from leaves through transpiration to the
atmosphere (Schroeder et al. 2001);

2. Promote higher osmotic adjustment particularly when
mild water stress is applied in early growth stages
(Yactayo et al. 2013);

3. Allow the development of drought hardiness by partial
drought stimulations (Xu et al. 2011a), where multiple

cellular tolerance pathways operate in a coordinated man-
ner in drought-tolerant plants (Parvathi et al. 2013);

4. Optimize stomatal control over gas exchange (Wang et al.
2010a), improving the ratio of photosynthesis to transpira-
tion or to stomatal conductance of CO2 (Cui et al. 2009a);

5. Reduce “luxury” transpiration loss without or with a min-
imal impact on photosynthesis (Yang et al. 2012a); and
finally

Table 1 Examples of the effects of partial root-zone deficit irrigation, compared to full irrigation on water use efficiency and crop yields in some
selected arid and semiarid areas

Study site Study year Crop Partial root-zone deficit irrigation over
full irrigation

Reference

Water use efficiency

Minqin, Gansu 38° 05′ N, 103° 03′ E 2004–2005 Cotton Saved 31–33 % of irrigation water,
increased WUE by 5–21 % over
full irrigation

Du et al. (2008a)

Shenyang, Liaoning 41° 31′ N, 123° 24′ E 2007 Tomato Increased WUE on fresh yield by
52 %, mainly due to reduced
transpiration rate

Yang et al. (2012a)

Lima, Peru 12° 05′ W, 76° 55′ S 2010 Potato Saved water consumption by
32–54 % over full irrigation
with early deficit application
without yield penalty

Yactayo et al. (2013)

Yangling, China 34° 18′ N, 108° 24′ E 2008 Maize Saved water by 11–32 %;
increased canopy WUE by
10–42 %

Li et al. (2010a)

Shiraz, Iran (29° 36′ N, 52° 32′ E 2012 Potato Saved water by 28 %, but decreased
water productivity (kg per m–3

of water) by 35 % due to
decreased yield

Ahmadi et al. (2014)

Tarsus, Turkey 37° 01′ N, 35° 01′ E 2006−2007 Sunflower Saved water by 36 %, increased
irrigation water use efficiency
by 33 % but decreased seed yield

Sezen et al. (2011)

Portici, Italy 40° 31′ N, 14° 58′ E 2 years Tomato WUE (in terms of marketable
yield per unit of actual
evapotranspiration) did not differ

Casa and Rouphael
(2014)

Crop yield

Minqin, Gansu 38° 05′ N, 103° 03′ E 2004–2005 Cotton Increased seed–cotton yield
by 5–21 % over full irrigation,
due to improved harvest index

Du et al. (2008a)

South Jutland, Denmark 54° 54′ N, 9° 07′ W 2004–2005 Potato Improved the marketable class of
potato tubers by as high as 20 %;
no yield penalty, with
30 % water reduction

Shahnazari et al.
(2007)

Gangu, China 36° 2′ N, 103° 40′ E 2011 Wheat Decreased grain yield by 43 % due to
water stress imposed during
reproductive growth stage

Ma et al. (2014)

Shiraz, Iran (29° 36′ N, 52° 32′ E 2012 Potato Decreased tuber yield by an average
of 54 %

Ahmadi et al. (2014)

Jumilla, SE Spain 38° 23′ N, 1° 25′ W 1999–2001 Grape Increased berry yield by 0–43 %,
due to promotion of shoot length,
pruning weight, berry number
per cluster, and cluster weight

De la Hera et al. (2007)

Tarsus, Turkey 37° 01′ N, 35° 01′ E 2006−2007 Sunflower Decreased seed yield by 15 % due to
lowered seeds per heat and weight
per seed

Sezen et al. (2011)

Portici, Italy 40° 31′ N, 14° 58′ E 2 years Tomato Decreased fruit yield by 52 % due
to lowered fresh weight

Casa and Rouphael
(2014)

3 Page 10 of 21 Agron. Sustain. Dev. (2016) 36: 3



6. Improve moisture distribution across the soil profile and
reduce potential evaporation due to decreased evaporative
surface areas exposed by the partial root-zone irrigation
approach (Xie et al. 2012).

6 Agronomic practices for improving crop
productivity under regulated deficit irrigation

RDI has been used for many field crops such as wheat
(Hongbo et al. 2005), maize (Liang et al. 2013; Wang et al.
2012b), cotton (Du et al. 2008b; Li and Lascano 2011; Ünlü
et al. 2011), rapeseed (Brassica napus) (Hamzei and Soltani
2012), soybean (Mishra et al. 2013), common bean (Simsek
et al. 2011), mung bean (Bourgault et al. 2010), sunflower
(Garofalo and Rinaldi 2015), potato (Ahmadi et al. 2014),
and tomato (Wang et al. 2013). And, this technology has been
used in somewoody plant species, such as grapevine (Romero
et al. 2012), apple (Yang et al. 2012b), olive trees (Ghrab et al.
2013), nectarine (Prunus persica L.) (De la Rosa et al. 2015),
and wine grape (Vitis vinifera L.) (De la Hera et al. 2007).
Here, we summarize the key agronomic traits of plants in
response to RDI-induced water stress and discuss some of
the key agronomic strategies and practices to improve the
growth and development and plant yield and product quality
under RDI-induced water stress.

6.1 Promoting plant growth and development

The majority of the studies that we have reviewed show that
RDI places plants in a mild water stress condition for a short
period of time, and once full irrigation is applied, normal plant
growth and development resumes, and plants are rapidly re-
covered to a level similar to the fully irrigated controls. A short
period of mild water deficit promotes plant development with
a positive effect on plant growth. For example, in maize, the
growth and development of water-stressed plants rapidly re-
covered to the control level only 3 days after being re-watered
(Kang et al. 2000).

Timing and the extent to which RDI is applied plays a
critical role in plant recovery from deficit-induced stress. In
maize, deficit irrigation applied during the vegetative stage
increased grain yield by 10 to 20 % compared to the stress
retained during the whole growth cycle (Domínguez et al.
2012). Maize plants treated with mild water deficit (defined
in Sect. 2 above) at the seedling and stem elongation stages
showed a positive “transferring effect” from early to later
growth stages (Kang et al. 2000). Compared to the fully irri-
gated control, the maize plants that recovered from the
seedling-stage water stress were better adapted to soil water
deficit occurring later in the life cycle. However, long-term
severe water deficits can have a significant, negative impact

on plant growth (Siddique and Bramley 2014). These studies
clearly show that a mild water stress can be applied at the early
growth stage through RDI; this will improve the adaptability
of plants to the stress through a stress-induced acclimatization
process.

6.2 Stimulating root activity

There are a limited number of reports in the scientific literature
that assessed the effect of RDI on plant roots. Some recent
publications show that RDI generally increases root to shoot
ratio (Vandoorne et al. 2012; Wang et al. 2012b). In a climate-
controlled environmental study, maize plants under alternate
partial root-zone deficit irrigation produced 49 % more root
biomass and increased root to shoot ratio by 54 %, compared
to the fully irrigated control (Wang et al. 2012b). This is a
typical example where mild water stress associated with RDI
has little or no effect on shoot biomass, but it promotes root
growth significantly (Fig. 5). Consequently, the increased root
to shoot ratio provides benefits for water and nutrient uptake
once full irrigation resumes. Similarly, in cotton, alternate par-
tial root-zone irrigation stimulated the growth of secondary
roots (Du et al. 2008a). The increased secondary roots, along
with increased root to shoot ratio, are beneficial for improving
water absorption (Li et al. 2013) and enhancing soil nutrient
uptake (Hu et al. 2009;Wang et al. 2012b). This phenomenon,
commonly observed under alternate partial root zone strategy,
has been validated using simulation models (Li et al. 2013).

In plant research, “root activity” has been used to eval-
uate the metabolic capacity of a root system. Root activity
is usually measured using triphenyl tetrazolium chloride
(Upadhyaya and Cladwell 1993). Roots are washed with
deionized water and excised at a certain length from the
root tips, and root tips are allowed to react with triphenyl
tetrazolium chloride in phosphate buffer solution. After a
certain time, sulfuric acid is added to stop the reaction. The
extraction of root tips is then measured with dehydroge-
nases. Dehydrogenase activity is regarded as an indicator
of root activity which has a direct effect on the ability of
the roots to absorb water and minerals from soils. Alternate
partial root-zone irrigation has been shown to increase root
activity in tomato plants by 48 to 59 % compared to the
conventional irrigation control (Yang et al. 2012a).
Watering alternation between drying and wetting root zones
with partial root-zone irrigation allows roots to experience
mild water stress first, and then, re-watering provides a
compensatory effect in enhancing root activity.

These studies indicate that partial root-zone deficit irriga-
tion has a compensatory effect to stimulate root growth and
increase the root shoot ratio, helping stress-treated plants to
recover rapidly once normal irrigation is resumed later in their
life cycle. Plant growth-promoting rhizobacteria have been
found to colonize plant roots and increase root growth under

Agron. Sustain. Dev. (2016) 36: 3 Page 11 of 21 3



water stress (Prudent et al. 2015). Also, the use of thuricin-17
under water stress can modify rooting systems and increase
root and nodule biomass in soybean.

However, the effect of RDI on root activity may not occur
in some plant species. For example, partial root-zone irriga-
tion has no effect on root growth in oilseed rape (Wang et al.
2009). The tap and lateral rooting nature of oilseed allows the
plants to root vertically and horizontally in response to water
availability in the soil. The strong plasticity allows oilseed
plants to maintain the root system that facilitates the use of
rainfall and irrigation when water is available in the top soil
layers and root deeper in the soil layers to absorb available
water particularly under water deficit (Gan et al. 2009). In this
case, water deficit treatments have little to no signaling effect.

6.3 Maintaining or increasing plant yield

Deficit irrigation applied at the early growth stage or partial
root-zone deficit irrigation has been shown to maintain or
even increase yields in many field crops. In a ridge–furrow
planting of cotton in arid northwest China, irrigation to alter-
nate furrows (i.e., half the furrows were irrigated with a full
amount of water while the other half were exposed to drying)
increased cotton yield by 13 to 24 % (Du et al. 2006). Mild
water deficit applied in the early stage is shown to enhance the
level of drought resistance later in the life cycle and conse-
quently maintain (Liu et al. 2006a) or even increase plant
yields (Cui et al. 2009b; Xue et al. 2006).Mechanisms respon-
sible for the increased plant productivity under RDI are not
well understood. However, we find the following three key
factors that may have contributed to the increased plant
productivity:

1. Mild deficit at the seedling stage stimulates root develop-
ment and increases root to shoot ratio, so that the plants
are better equipped for soil water deficit at the later stages,

2. Plants with deficit irrigation at the vegetative stage in-
crease the remobilization of pre-anthesis carbon reserved

in the vegetative tissues to the grains (Xue et al. 2006),
and

3. Water deficit reduces the growth redundancy of stem and
leaves and promotes the translocation of photosynthetic
assimilates to the final products (Du et al. 2008a).

However, water deficit applied during reproductive
stages typically decreases crop yield. Usually, a yield re-
duction is unavoidable even though water stress during
grain filling can promote the remobilization of the pre-
and post-anthesis carbon reserves to the developing grains
(Fig. 6). In this particular example (Ma et al. 2014), wheat
plants under stress contributed 37 % more dry matter re-
served in the vegetative tissues to the grain compared to
wheat plants that were grown under no stress condition,
but this compensatory effect from the increased percent
dry matter remobilization was not sufficient enough to
offset lost yield due to water deficit applied in the repro-
ductive stage. Similarly, in root chicory (Cichorium
intybus var. sativum), a cash crop cultivated for inulin
production in western Europe, plants exposed to water
stress during the last half of their life cycle drastically
decreased fresh and dry weight in shoot and roots, leading
to a significant decrease in inulin yield even though the
plants expressed high levels of drought tolerance
(Vandoorne et al. 2012). Similar observations are reported
in some woody plant species. RDI applied to apricot trees
(Prunus armeniaca L.) at the amount of 50 % of the
seasonal ET significantly reduced trunk growth and prun-
ing and decreased the number of fruits per tree and overall
fruit yields (Pérez-Pastor et al. 2014). These studies sug-
gest that farm managers could apply a mild to moderate
degree of water deficit at the early growth stage, which
can restrain growth redundancy, optimize the relationship
between vegetative growth and reproductive growth, and
maintain or increase plant yield, but RDI applied at the
reproductive growth stage can decrease crop yields
substantially.

Fig. 5 Maize plants under
alternate partial root-zone deficit
irrigation (PRD) produced a
greater (49 % more) amount of
root biomass with increased (by
54 %) root to shoot ratio,
compared to maize plants under
full irrigation (FI, the control) or
the conventional deficit irrigation
(DI). Different letters in a
subpanel indicate significant
differences (P< 0.05) between the
treatments (data source: Wang
et al. 2012b)

3 Page 12 of 21 Agron. Sustain. Dev. (2016) 36: 3



6.4 Influencing product quality

In the scientific literature, the effects of RDI on end-use qual-
ity of products are inconsistent, varying with crop species or
the quality traits evaluated. Processing tomato crops grown
under partial root-zone deficit irrigation increased solid con-
tent and improved taste and sensory quality (Zegbe-
Domínguez et al. 2003); potato grown under RDI during late
tuber filling to maturing stages at a level near 60 % of the
control increased the proportion of marketable tuber class
(by 20 %) compared to the fully irrigated control with no
change in tuber yield (Shahnazari et al. 2007); tomato under
RDI reduced the incidence and severity of blossom end rot (a
troublesome disease affecting fruit quality), thus improving
end-use quality (Sun et al. 2013b). However, oilseed rape
under RDI decreased seed oil content substantially (Ghobadi
et al. 2006); tomato under RDI decreased the size of the fruits
(Kirda et al. 2007). In some of the woody plant species, in-
consistent effects of RDI on product quality are obtained. In
navel orange trees (Citrus sinensis L.), both fruit size and juice
percentage were decreased whereas total soluble solid per-
centage and juice acid percentage increased (Hutton and
Loveys 2011); in peach (Prunus persica L), RDI applied dur-
ing the late part of fruit growth increased the ratio of soluble
solid content to titratable acidity with a more reddish colora-
tion on the fruit skin, representing a large improvement in fruit
quality (Geiiy et al. 2004); in berry, water stress imposed
through RDI substantially decreased color intensity, lowered
sugar content, and reduced anthocyanin concentration
(Romero et al. 2013). These examples show that RDI can help
improve end-use quality attributes in some cases, but in other
cases, deficit irrigation practice can have adverse effects on
the end-use quality in some products. Farm managers will
need to evaluate the effect of RDI on quality attributes for

each particular product to minimize the trade-off between sav-
ing certain amounts of irrigation and decreasing the end-use
quality of the product.

6.5 Improving nutrient use efficiency

A number of studies have shown that crops with RDI can
increase nutrient use efficiency through the promotion of nu-
trient recovery after a short period of water stress. For exam-
ple, alternate partial root-zone irrigation to maize enhanced
the ratio of N uptake in plants to the N supplied by 16 %
compared to fully irrigated control (Li et al. 2007); similarly,
in a maize–wheat rotation study where full irrigation and par-
tial root-zone deficit irrigation were compared in maize, par-
tial root-zone irrigation increased N recovery by 17 % com-
pared to full irrigation (Kirda et al. 2005). Also, partial root-
zone irrigation has been shown to improve agronomic N use
efficiency, apparent N recovery efficiency, and N yield (Wang
et al. 2013).

In this review, we find that the improved nutrient use with
RDI is reflected in the following aspects:

1. Plants under mild deficit increase root surface area, root
length density (Liu et al. 2011), and horizontal distance
(Li et al. 2013) that facilitate nutrient uptake;

2. Drying and wetting cycles of root zones with partial root-
zone irrigation improve the ability of plants to acquire
nutrients from the soil, as drying and wetting cycles of
soils stimulate the mineralization of soil organic N, there-
by increasing mineral N available to plants;

3. Water deficit improves N distribution in the canopy with
more N made available to the upper and middle portion of
the leaf canopy (Wang et al. 2010a);

Fig. 6 Percent dry matter remobilized from the vegetative tissues to the
grains during the pre-anthesis and post-anthesis periods (left) and
aboveground biomass and grain yield (right) of spring wheat grown
under non-stress control and moderate and severe water stress imposed

during grain filling. Vertical bars represent standard errors of the mean
differences. The percentages on the bars represent the decreases of
biomass and grain yield under the moderate and severe water stress
compared to the control (data source: Ma et al. 2014)

Agron. Sustain. Dev. (2016) 36: 3 Page 13 of 21 3



4. Deficit irrigation decreases soil bulk density and percent
water holding pores in the soil, facilitating N uptake by
plants (El Baroudy et al. 2014);

5. Drying/wetting cycles with partial root zone irrigation en-
hance microbial activity with high microbial substrate
availability which is partly responsible for the enhance-
ment of net N mineralization in plants (Wang et al.
2010b); and

6. In some cases, drying and wetting cycles stimulate the
colonization of arbuscular mycorrhizal fungi, stimulating
the plants for nutrient uptake (Schreiner et al. 2007).

6.6 Enhancing plant acclimatization through biochemical
approaches

Many agronomic strategies and practices can be used to
stimulate plant growth and development and improve crop
yields in association with the use of RDI for saving irri-
gation water. An innovative approach is to promote
plants’ photochemical efficiency through the use of bio-
informatics (Kurz et al. 2010), genetic variations (Zhuang
et al. 2007), and pharmacological means (Xu et al. 2009b)
in improving water stress tolerance in plants. For exam-
ple, the bacterium Pseudomonas syringae pv. syringae
produces the compatible solutes betaine, ectoine, N-
acetylglutaminylglutamine amide, and trehalose (Kurz
et al. 2010). These osmolytes can interact at the transcrip-
tion level to yield a hierarchy of expression, contributing
to water stress tolerance. Protein phosphorylation is
shown to play an important role in regulating hydrogen
peroxide accumulation in maize under water stress (Xu
et al. 2009b). Some cross talk between protein phosphor-
ylation and hydrogen peroxide accumulation may help
enhance water stress defense systems. Also, transcription-
al responses of identifiable genes can be regulated by
water stress, and these stress-regulated transcripts are in-
volved in cellular and biochemical activities, such as the
function of carbohydrate metabolism and cell wall meta-
bolism (Zhuang et al. 2007).

Furthermore, many practical crop management strategies
can be employed to increase stress tolerance of plants
under RDI (Romero et al. 2004). For example, the appli-
cation of nitrogen to progressively drying soil can induce
stomatal closure and minimize water loss (Liu and
Dickmann 1996); the application of microelements can
increase superoxide dismutase enzyme activity in the
leaves of stressed plants and thus reduce the stress damage
caused by water deficit (Sajedi et al. 2011); the application
of bacterial endophytes to stressed plants can increase
plant photochemical efficiency, reducing the leaf damage
of relative membrane permeability caused by water deficit
(Naveed et al. 2014).

7 Opportunities and challenges

7.1 Opportunities

Available water resources for agriculture have been rapidly
decreasing in recent years due to increased competition for
freshwater between agriculture and other sectors (Gan et al.
2013). RDI is considered a key water-saving practice for effi-
cient use of the limited water resources (Chai et al. 2014a). In
this review, we have identified that RDI can save irrigation
water up to 20 to 30 % and increase WUE up to 30 % in the
favorable situations. In some extreme cases, the RDI approach
can savewater up to 50%with a minimal impact on crop yield
(Li et al. 2010a, b; Xie et al. 2012). However, the conventional
irrigation that was used to compare with RDI in those extreme
cases was usually schemed as “border irrigation” or “flood
irrigation” in which plants may be overly irrigated which is
not efficient in any standard. Among the RDI approaches,
alternate partial root-zone irrigation has been found to be most
effective and efficient in saving water and improving WUE
while maintaining crop productivity (Hutton and Loveys
2011; Yactayo et al. 2013; Yang et al. 2012b).

Also, there are tremendous opportunities to combine the
RDI practice with other advanced agronomic practices to en-
hance WUE in crop production. This may include (a) no-till
management with cover crops (DeLaune et al. 2012), (b) sub-
surface tillage practices (Salar et al. 2013), (c) rotating tillage
with no-till practices on farmland (Hou et al. 2012), (d) use of
crop straw and plastic mulching (Yuan et al. 2014; Yin et al.
2015), (e) adoption of relay planting configuration (Yin et al.
2015), and (f) adoption of ridge–furrow planting configura-
tions (Gan et al. 2013). Moreover, RDI can be combined with
some modern irrigation techniques such as sprinkler irrigation
(Bielorai 1982), surface drip irrigation (Du et al. 2008a; Faci
et al. 2014), subsurface infiltration (DeLaune et al. 2012), and
in combination with root-zone nutrient management through
fertigation (Chen et al. 2011), to increase both water and nu-
trient use efficiencies. Additionally, the reallocation of water
resources and modification of irrigation systems may have a
role to play for the improvement of water use in agriculture
(Homayounfar et al. 2014).

7.2 Challenges

The central novelty of RDI is that it allows plants to grow
under mild water stress to induce root-sourced chemical sig-
nals from drying roots to reach the shoot where physiological
and biochemical processes can be regulated. However, the
physiological and biochemical responses are difficult to quan-
tify, given that partial root-zone irrigation is usually applied to
plants in accordance with both temporal and spatial droughts.
In practice, adoption of water-saving technique requires sci-
entific understanding of the mechanisms involved in the

3 Page 14 of 21 Agron. Sustain. Dev. (2016) 36: 3



physiological and biochemical processes. Also, the outcome
of the water stress-induced responses is influenced by many
factors, such as the stages of crop growth when the deficit is
applied, the intensity and severity of deficit imposed, the
method with which deficit irrigation is applied, crop species
and cultivars, and their respective non-critical growth stages
when the stage-based deficit irrigation may be applied. These
factors need to be investigated at a system level under specific
growing conditions.

RDI and, particularly, alternate partial root-zone irrigation
are still relatively new to manage farm managers. This tech-
nique is not easy to implement in crop species with dense plant
population such as cereal and oilseed crops. Some standard-
ized irrigation design may be required in order to ensure high
irrigation efficiency. This may require (a) enacting rules or
regulations to ensure that irrigation water is applied using a
standard method, (b) educating end-users to realize the poten-
tial benefits and risks of yield penalty involved in the use of
the deficit irrigation technique, (c) increasing sophisticated
irrigation management tools coupled with cost-efficient irriga-
tion equipment to facilitate implementation of this technique,
and (d) analysis of cost–benefit ratio of using this technique in
large-scale farming, especially for cash crops. Finally, it is
extremely important that more experimental tests are needed
to evaluate the response of specific crop species to RDI before
the technique may be used extensively.

8 Suggestions for future research

In this review, we focus primarily on water stress-induced
responses of plants, mainly morphological, physiological,
and biochemical responses as well as their influence on crop
productivity. We believe that more in-depth research is re-
quired to better understand the science beyond RDI. In addi-
tion, more applied techniques are required to facilitate appli-
cation of this technique in large-scale agricultural systems.
The real challenge is to establish RDI on the basis of deliver-
ing sustained or increased crop productivity, while saving ir-
rigation water and enhancing WUE. Many topics or subject
areas are needed to be studied in the near future; we suggest
the following areas to be the top priorities.

8.1 Signaling systems

Abscisic acid, a naturally occurring compound in plants, has
been considered the domain hormone in regulating stomatal
opening and closure in plants under RDI-induced water stress.
However, the current understanding of the pathway is narrow
in some crop species. It is unclear how biosynthesis occurs in
leaves and what catabolic pathways would be used under mild
versus severe water stress. It is clear that with water stress,
abscisic acid stimulates stomatal closure, inhibits shoot

growth, and induces production of storage proteins relative
to seed dormancy at maturity. However, it is unclear how the
hormone functions to provide additional benefits to plants
under stress, such as the potential role in defending pathogen
attack or stimulating the development of root systems. Also,
little has been documented in regard to other signaling sys-
tems, such as silicon which has been found to regulate the
levels of endogenous plant hormones under stress conditions
(Zhu and Gong 2014). However, silicon involvement in sig-
naling and regulation of gene expression related to increasing
stress tolerance remains to be explored.

8.2 Physiological and biochemical responses

There is a need to redefine major indicators of the effect of
RDI on plant growth, photosynthesis and respiration, and bio-
chemical responses in an effective manner. In the literature, it
is unclear how to predict water consumption using the stoma-
tal opening and closing mechanism, as stomatal control only
constitutes part of the total transpirational resistance.
Boundary resistance from the leaf surface to the outside of
the canopy may be substantial such that any reduction in sto-
matal conductance may be partially compensated for by an
increase in leaf temperature. Stomatal control over transpira-
tion may differ between densely populated field crops, such as
wheat, and fruit trees which are more sparsely planted. Little is
known about how long stomata remain partially closed with
prolonged soil drying and what role rewatering may play in
stimulating root growth under drying soils. In this review, we
find that the research on the plant-soil interactions, a way
toward better crop water supply (Bodner et al. 2015), is still
at infancy. One of the major areas in mitigating water stress
may be focusing on the management of complex plant-soil
interactions under site-specific conditions.

8.3 Quantification of the magnitude of deficits

There are inconsistent findings in the scientific literature with
regard to the magnitude of water stress-induced responses to
RDI. We believe that those inconsistencies are, to a large ex-
tent, caused by poorly designed experiments, inadequately
defined treatment structures, and inconsistently managed test-
ing conditions. A key component is that the irrigation water
applied to plants should be based on the percentage of total
crop ET, leaf water potential, or crop coefficients for a partic-
ular crop species of interest. Crops under deficit irrigation
treatments must be really under water stress conditions with
a quantitativemeasure. A fully irrigated control treatment may
be, in fact, over-irrigated if the experimental treatments were
not well designed or implemented. Investigation on small-
grain crops, such as wheat, maize, and rice, can be better
controlled in terms of root water uptake and crop water con-
sumption (for example, using lysimeters to determine kc

Agron. Sustain. Dev. (2016) 36: 3 Page 15 of 21 3



factors) than deep rooting trees where it cannot be ruled out
that reducing irrigation water is not compensated by water
uptake through deep roots. The latter aspect needs to be quan-
tified in future studies. Furthermore, it is important to develop
and adapt a model-based approach to quantify the amounts of
irrigation that can be applied to crops through deficit irriga-
tion. Some of the models are quite promising such as
AquaCrop model (Iqbal et al. 2014) and ORDI model
(Domínguez et al. 2012), among others, and yet, their accura-
cy, efficiency, and effectiveness should be validated using
multiple years of data.

8.4 Potential impacts on soil quality attributes

Deficit irrigation is an important strategy to manage water, but
the relationship with soils is not well documented. For exam-
ple, irrigation to the partial root zone may depend on soil type,
as it is known that sandy soil may have a lot of water to flow
downward whereas, for heavy clay soil, it will flow more hor-
izontally. Also, the potential effects of deficit irrigation on soil
physical and chemical properties have not been documented.
We expect that drying and wetting cycles of soils with deficit
irrigation may stimulate the mineralization of soil organic car-
bon and soil N, leading to increased N bioavailability to plants,
which may potentially increase C and N losses in the soil
(Trost et al. 2013). Rarely, such information is found in the
scientific literature. Similarly, there is a lack of information
on soil physical properties such as aggregate stability, bulk
density, particle size distribution, soil structural development,
and inorganic carbon dynamics, as well as soil microorganism
communities, structures, and their functionalities, in relation to
water deficit. In some regions, soil salinity management goals
may conflict with deficit irrigation goals. Determination of
those soil quality-related parameters is needed to develop sus-
tainable systems with water-saving approaches.

9 Conclusion

Water deficit is an inevitable consequence of life for terrestrial
plants. A variety of mechanisms have evolved to control plant
water status, regulate water loss, maintain turgor pressure, and
reduce water transport out of plant systems. Many water-
saving practices have been adapted to tackle the critical issue
of water shortage worldwide. RDI, in the form of partial root-
zone irrigation, stage-based deficit irrigation, infiltration water
movement, and subsurface irrigation and supplemental irriga-
tion, has been regarded as a key water-saving approach for the
production of horticultural crops, field crops, and some woody
plant species. In this review, we focus on the understanding of
the physiological and biochemical mechanisms involved in the
plant response to RDI-induced water stress. A mild water def-
icit applied at the early growth stages can provide large benefits

to plant growth and development under certain conditions. In
particular, a slowly increased water stress can induce internal
physiological adjustments and regulations to protect plants
from damage. Some of the key agronomic management strat-
egies and practices can be employed to the adaptation of this
technology in agriculture. No doubt, RDI practices can be
adopted in real-world agricultural systems, but many theoreti-
cal and technical issues need to be solved. There is a need to
define specific conditions under which RDI can be implement-
ed effectively and efficiently and appropriate methodologies
which can be successfully applied in large-scale fields. Some
deficit irrigation methods, such as subsoil irrigation and hori-
zontal infiltration movement, are still in the early stage of re-
search and development. Whether or not these approaches can
be profitably used on a large scale remains to be determined.

Open Access This article is distributed under the terms of the Creative
Commons At t r ibut ion 4 .0 In te rna t ional License (h t tp : / /
creativecommons.org/licenses/by/4.0/), which permits unrestricted use,
distribution, and reproduction in any medium, provided you give appro-
priate credit to the original author(s) and the source, provide a link to the
Creative Commons license, and indicate if changes were made.

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