MARSCHNER REVIEW

Opportunities for mobilizing recalcitrant phosphorus
from agricultural soils: a review

Daniel Menezes-Blackburn & Courtney Giles & Tegan Darch & Timothy S. George &

Martin Blackwell & Marc Stutter & Charles Shand & David Lumsdon & Patricia Cooper &

Renate Wendler & Lawrie Brown & Danilo S. Almeida & Catherine Wearing & Hao Zhang &

Philip M. Haygarth

Received: 31 March 2017 /Accepted: 20 July 2017 /Published online: 1 August 2017
# The Author(s) 2017. This article is an open access publication

Abstract
Background Phosphorus (P) fertilizer is usually applied
in excess of plant requirement and accumulates in soils
due to its strong adsorption, rapid precipitation and
immobilisation into unavailable forms including organic
moieties. As soils are complex and diverse chemical,
biochemical and biological systems, strategies to access
recalcitrant soil P are often inefficient, case specific and
inconsistently applicable in different soils. Finding a
near-universal or at least widely applicable solution to
the inefficiency in agricultural P use by plants is an

important unsolved problem that has been under inves-
tigation for more than half a century.
Scope In this paper we critically review the strategies
proposed for the remobilization of recalcitrant soil phos-
phorus for crops and pastures worldwide. We have
additionally performed a meta-analysis of available soil
31P–NMR data to establish the potential agronomic
value of different stored P forms in agricultural soils.
Conclusions Soil inorganic P stocks accounted on av-
erage for 1006 ± 115 kg ha−1 (57 ± 7%), while the
monoester P pool accounted for 587 ± 32 kg ha−1

(33 ± 2%), indicating the huge potential for the future
agronomic use of the soil legacy P. New impact driven
research is needed in order to create solutions for the
sustainable management of soil P stocks.

Keywords Phosphorus . Organic phosphorus . Soil .

Crops . Fertilizer . Plant nutrition

Introduction

Historically, agricultural strategies to cope with the large
phosphorus (P) fixing capacity of many soils have relied
on saturating the system with P in the form of fertilizer,
derived from non-renewable rock phosphates, to main-
tain plant-optimum P concentrations in soil solution
(Fox and Kamprath 1970). In some countries, long term
fertilizer applications to meet plant needs have led to a
build-up of a legacy soil P ‘bank’, which is largely
unavailable to plants (Kamprath 1967). Recent scientific
efforts have been directed toward increasing the plant

Plant Soil (2018) 427:5–16
DOI 10.1007/s11104-017-3362-2

Responsible Editor: Philippe Hinsinger.

Electronic supplementary material The online version of this
article (doi:10.1007/s11104-017-3362-2) contains supplementary
material, which is available to authorized users.

D. Menezes-Blackburn (*) : C. Wearing :H. Zhang :
P. M. Haygarth
Lancaster Environment Centre, Lancaster University,
Lancaster LA1 4YQ, UK
e-mail: d.blackburn@lancaster.ac.uk

C. Giles : T. S. George :M. Stutter :C. Shand :
D. Lumsdon : P. Cooper : R. Wendler : L. Brown
The James Hutton Institute, Dundee and Aberdeen, Scotland DD2
5DA and AB15 8QH, UK

T. Darch :M. Blackwell
Rothamsted Research, North Wyke, Okehampton, Devon EX20
2SB, UK

D. S. Almeida
College of Agricultural Sciences, Department of Crop Science,
São Paulo State University, Botucatu 18610-307, Brazil

http://crossmark.crossref.org/dialog/?doi=10.1007/s11104-017-3362-2&domain=pdf
http://dx.doi.org/10.1007/s11104-017-3362-2


availability of this legacy soil P and enabling an efficient
agronomic use of this important P reserve. But, how
likely is legacy soil P to be a key source of P to sustain
agricultural production? For how many growing sea-
sons would legacy soil P be able to sustain crop produc-
tion, and what yields may be expected? What are our
most promising and sustainable agroecological innova-
tions to accomplish this?

Modern agricultural dependence on non-renewable
natural resources, namely P fertilizers and fossil fuels, is
problematic. However, while renewable alternatives to
fossil fuels are available, there are still no renewable
alternative sources of fertilizer P to rock phosphate
mining (Cordell et al. 2009). As rock phosphate mineral
resources decline, phosphate fertilizers will inevitably
become a scarce, and consequently a costly input, with
severe effects on agricultural production and food secu-
rity (Abelson 1999; Cordell et al. 2009). Additionally,
there is the issue of volatility in rock phosphate supply
and the related price oscillations, like the recent sharp
increase in price which occurred in 2008 with direct
impact on the market value of P fertilizers and in the
FAO food price index (Cordell and White 2014). Most
of the known reserves of rock phosphate are present in
Morocco (74%) while Europe has virtually no rock
phosphate remaining, and therefore geopolitical issues
will be increasingly influential in future P production.
Improving P cycling in soils and using recycled P fer-
tilizer sources are not likely to be complete solutions to a
future P crisis, but are key contributors to delaying and
reducing the impact of a P scarcity scenario (Stutter et al.
2012). Model simulations show that the residual soil P
pool may play a role in reducing global P fertilizer use
by up to 50% by 2050, in relation to other estimates that
do not consider the plant use of soil fixed P (Sattari et al.
2012). Here we argue that an even larger reduction in P
fertilizer input could be accomplished if appropriate
technologies were applied in mobilizing recalcitrant
forms of soil P currently not considered in P use models,
and that represent a legacy from historic fertilizer inputs.

Phosphorus fixation and bioavailability in soils

Phosphorus is perhaps, amongst all the plant nutrients,
the one with the most limited bioavailability in soils
(Vance et al. 2003). Typically, approximately 6% (range
1.5 to 11%) of total soil P is readily available (Olsen P)
while the majority of it is locked in primary minerals,

precipitated, adsorbed or in organically-complexed
forms (Condron et al. 2005a; Pierzynski et al. 2005;
Stutter et al. 2012). To ensure optimal plant growth,
phosphate fertilizers are applied to agricultural soils in
excess of plant requirements to overcome soil P fixation
processes and maintain soil solution P at optimal levels
for plant growth (Syers et al. 2008). Long term P fertil-
izer or P rich manure application is directly proportional
to the soil accumulation of up to two thirds of the
applied P dose, leading to the progressive saturation of
soils with P and the concomitant reduction in P-
retention capacity of the soil matrix (Hooda et al.
2001). For example, in Western Europe more than 1.1
tons of P ha−1 were applied on average to cropland soils
between 1965 and 2007 while less than 0.3 tons ha−1 are
estimated to have been removed from these systems
during the same period (Sattari et al. 2012). Many
European soils are excessively fertilized, accumulating
soil P pools at levels that are environmentally unaccept-
able due to the risk of P transfer to watercourses, and the
potential for eutrophication (Barberis et al. 1995; Dodd
and Sharpley 2015; Haygarth et al. 2014). It is likely this
applies to most soils worldwide with a long P fertilizer
application history.

Soluble P from freshly applied fertilizer interacts
with soil surfaces, displacing other anions with less
affinity, to become adsorbed (Pierzynski et al. 2005;
Syers et al. 2008). Processes of P sorption and desorp-
tion are hysteretic, and desorption rates are much slower
than sorption rates at common soil solution P concen-
trations (Menezes-Blackburn et al. 2016c). Precipitation
and surface co-adsorption with metals also play an
important role in short term soil P fixation (Hedley and
McLaughlin 2005; Li and Stanforth 2000). After fertil-
izer application, soluble P levels increase to a transient
soil solution P concentration, and net P adsorption and
precipitation takes place until equilibrium is reached
(Fox and Kamprath 1970; Hedley and McLaughlin
2005; Pierzynski et al. 2005). The fixation rates of
soluble inorganic P (Pi) in agricultural soils are usually
large and agronomic optimum levels of soil solution P
may not be sustained even through one agricultural
cycle (Kovar and Claassen 2005; Syers et al. 2008). If
fertilizer application is stopped or reduced, solution P is
depleted and the equilibrium turns into a slow net
solubilisation and desorption of stabilized soil P. The P
desorption rate is markedly different between soils of
different pH (Smet et al. 1998), and of different miner-
alogy and organic matter content, and therefore these

6 Plant Soil (2018) 427:5–16



factors are likely to be key regulators of plant P uptake
(Barros and Comerford 2005; Koopmans et al. 2004).

Although plants can only uptake inorganic ortho-
phosphate anions (a component of the inorganic P, Pi),
a considerable fraction (30% to 65%) of soil P is present
as organic P forms (Po) (Condron et al. 2005b; Turner
et al. 2003b). These soil Po forms are produced when
plants and microbes take up orthophosphate,
immobilising them into organic molecules essential for
life (DNA, phospholipids, inositol phosphates, ATP),
and which are deposited in soils upon the death of these
organisms (Richardson et al. 2005). Similar to Pi, ad-
sorption and precipitation processes are responsible for
stabilizing soil Po that in some soils can build up to 80%
of total soil P (Turner et al. 2002). Since plants can only
take up inorganic orthophosphate (Raghothama 2005),
mobilizing Po forms requires undertaking two steps: first
the release of Po from precipitates and adsorption sites;
secondly the mineralization of these into plant available
Pi through the action of phosphatase enzymes (Clarholm
et al. 2015; Richardson et al. 2005). The adsorption and
release of Po is controlled by similar geochemical con-
straints to the ones for Pi, but in some cases such as for
phytate, the strength of reactions can be even greater due
to the presence of multiple orthophosphate groups and a
higher anionic charge density (Yan et al. 2014). Many
different enzyme types are involved in soil Po mineral-
ization and these enzymes show considerable differ-
ences in catalytic properties, behaviour and efficiency
in soils (Menezes-Blackburn et al. 2013). Some plants
naturally exude phosphomonoesterases into the rhizo-
sphere in response to P starvation, however these en-
zymes have, in general, limited or no activity towards
recalcitrant forms of P such as phytate (Jakobsen et al.
2005; Menezes-Blackburn et al. 2013). On the other
hand, soil microbes express a diverse range of extracel-
lular phosphatase enzymes capable of hydrolysing dif-
ferent soil Po forms (Dick 1994; Konietzny and Greiner
2004; Menezes-Blackburn et al. 2016a; Tapia-Torres
et al. 2016). The extracellular microbial phosphatases
usually have a short half-life in soil environments, due
to inactivation by metal inhibitors, adsorption, proteol-
ysis, pH and ionic strength shifts (George et al. 2006b).
When this microbially-mediated dephosphorylation is
insufficient to overcome fixation rates, fresh Po forms
are stabilized and accumulate in soils as previously
discussed. These processes are all regulated by the sol-
ubility of Po forms and presence, abundance and func-
tion of phosphatases in soil environments (Giles et al.

2016; Menezes-Blackburn et al. 2013). Understanding
the complex interrelation of the factors affecting Po
mobilization and those affecting enzyme performance
in soil environments still represents a huge challenge.
Recent projects have been designed to unveil the dy-
namics of soil rhizosphere microbiome impacts and
functions related to soil carbon mineralization (Nuccio
et al. 2014; Shi et al. 2014), but so far nothing at a
similar level is being performed with regard to soil
organic P .

How much soil phosphorus can potentially be
mobilized?

The amount of P that can be mobilized by different
strategies is dependent on the abundance and lability
of the targeted chemical P species in each soil environ-
ment. We have studied soil 31P–NMR data from scien-
tific literature (258 different soils from 41 publications)
reporting quantitative speciation of orthophosphate,
phosphate monoesters and phosphate diesters groups
(Table S1). The NMRmethod is usually performed with
soil NaOH-EDTA extracts and examines the chemical
structure of alkali soluble P species, which corresponds
on average to 55% of the total soil P (mined literature).
This is a strong extraction process that does not reflect
bioavailable P in soils. To choice of using 31P–NMR
data in this analysis, in detriment of other methods was
to evaluate stocks of different P chemical species, and
their potential future sustainable use. To estimate the
agronomic value of the soil P, these concentrations were
scaled up into total P stocks (kg P ha−1) in the first 15 cm
depth of soil. Across all samples, the orthophosphate
pool accounted for approximately 57% of the NaOH-
EDTA extractable total P, while the monoester P pool
accounted for approximately 33% (Table 1). By using
an approximate P offtake for arable soils and grasslands
from Sattari et al. (2016), on average the total P stocks
represent 352 ± 26 years’ worth of P for agronomic use;
the orthophosphate pool would account for
201 ± 23 years and the monoester pool would account
for 117 ± 6 years’ worth of production. This indicates
that our strategies for mobilizing soil P for plant nutri-
tion should be focused mainly on the adsorbed and
precipitated forms of orthophosphate and on the miner-
alization of monoester organic P forms like inositol
phosphates. The potential of the use of monoester P is
slightly greater for grasslands than for arable soils. Large

Plant Soil (2018) 427:5–16 7



differences in P stocks were also associated with conti-
nental distributions (Table 1), with a greater potential
use of monoester P in North America, followed by
Europe and Oceania; South America, Africa and Asia
showed much smaller values, but were excluded from
this analysis due to the smaller sample size bringing a
stronger bias to this interpretation. There are confound-
ing issues with the analysis of the data in Table 1,
including: a) the directed sampling strategy of each
individual study; b) insufficient geographical represen-
tation; c) differences in the soil extraction efficiency and
NMR spectra interpretation; d) samples taken at differ-
ent times during the last decades and no trends can be
found with regard to the dynamics of P accumulation.
Although no major analytical inconsistencies are ex-
pected when considering 31P–NMR data from different
sources due to a fairly well standardized approach being
adopted, there are potentially minor issues regarding the
NaOH-EDTA extraction efficiency, the peak integration
method used to interpret the spectra and the choice of
equipment setup (delay time, pulse angle, probe size and
field strength). Some of these problems were partially
overcome by bootstrapping the data with a resample size
of 1000, thus decreasing the sample/study specific bias
and achieving a better estimation of the population
dispersion parameters (Table S2). However, this

analysis is only sufficient to demonstrate that there is
huge potential to mobilise soil P for future agronomic
use.

Approaches and technologies for sustainably
increasing recalcitrant soil phosphorus
bioavailability

A sustainable agricultural approach for facing a future
rock phosphate shortage should include the unlocking
of legacy soil P, in parallel to reducing P fertiliser load,
and increasing the use of recycled P sources. The most
relevant question is which technologies will ultimately
be the most suitable for increasing recalcitrant soil P
bioavailability?

The first obvious strategy to increase the use of the
soil residual P ‘bank’, involves reducing P fertilizer
application rates and allowing adsorbed and precipitated
P to restore to equilibrium after P depletion (Menezes-
Blackburn et al. 2016c). Nevertheless, this strategy
would at some point sacrifice agricultural productivity
and it is only suitable for the initial depletion of ex-
tremely P rich soils. For most agricultural soils under a
depletion scenario, soil solution P levels would decrease
below optimal levels for plant growth, and therefore

Table 1 Soil phosphorus stocks analysis of global literature on
31P–NMR data for agricultural soils. The analysis performed was
based on the typical NMR speciation between orthophosphate,
monoester P, diester P and other forms of P (phosphonates,

pyrophosphate and unidentified P forms) transformed into kg
ha−1 basis. Values represent the average ± the standard error from
Bootstrap analysis (B = 1000; R statistics), and ‘n’ corresponds to
the number of soil samples

Total P Inorganic Orthophosphate Monoester Diester Other

kg ha−1 kg ha−1 (%) kg ha−1 (%) kg ha−1 (%) kg ha−1 (%) n

All samples 1762 ± 132 1006 ± 115 (57 ± 7) 587 ± 32 (33 ± 2) 64 ± 7 (4 ± 0) 96 ± 13 (5 ± 1) 258

Arable soils 1666 ± 133 964 ± 72 (58 ± 4) 519 ± 62 (31 ± 4) 64 ± 15 (4 ± 1) 123 ± 28 (7 ± 2) 115

Pastures 1830 ± 220 1037 ± 190 (57 ± 10) 644 ± 28 (35 ± 2) 64 ± 6 (3 ± 0) 74 ± 6 (4 ± 0) 143

Europe 1699 ± 94 927 ± 82 (55 ± 5) 646 ± 28 (38 ± 2) 55 ± 7 (3 ± 0) 68 ± 7 (4 ± 0) 143

North America 2170 ± 327 965 ± 94 (44 ± 4) 842 ± 177 (39 ± 8) 129 ± 42 (6 ± 2) 250 ± 81 (12 ± 4) 35

Oceania 1947 ± 412 1350 ± 363 (69 ± 19) 472 ± 36 (24 ± 2) 44 ± 8 (2 ± 0) 92 ± 14 (5 ± 1) 75

Soil bulk density was used to transform original data frommg kg−1 into kg ha−1 in the first 15 cm depth. Data was collected from 258 soils
and a total of 41 publications (Abdi et al. 2014; Ahlgren et al. 2013; Annaheim et al. 2015; Bourke et al. 2008; Bunemann et al. 2008a,
2008b; Cade-Menun and Preston 1996; Cade-Menun et al. 2010; Chapuis-Lardy et al. 2001; Cheesman et al. 2010; Condron et al. 1990;
Doolette et al. 2009, 2010; Doolette et al. 2011; Dougherty et al. 2007; Ebuele et al. 2016; Gatiboni et al. 2007; George et al. 2006a; Giles
et al. 2015; Guggenberger et al. 1996a, 1996b; Hill and Cade-Menun 2009; Jin et al. 2016; Koopmans et al. 2003; Lehmann et al. 2005;
Leinweber et al. 1997; Liu et al. 2014; McDowell et al. 2005; McDowell and Koopmans 2006; McDowell and Stewart 2006; McLaren et al.
2014, 2015; Moller et al. 2000; Murphy et al. 2009; Soinne et al. 2011; Solomon and Lehman 2000; Solomon et al. 2002; Stutter et al. 2015;
Turner 2006; Turner et al. 2003a, 2003b), see Table S1 for detailed information about the data collected and Table S2 for the bootstrapped
populations

8 Plant Soil (2018) 427:5–16



coupled strategies are needed to replenish soil solution P
by actively promoting P desorption, solubilisation and
mineralization. Sacrificing productivity is unacceptable
and incompatible with the need of feeding an ever
growing world population. However, in many devel-
oped western temperate agriculture systems, due to the
increasing prices of P fertilizer the decline in production
as a consequence of reducing P inputs may actually
improve net returns for producers, where the focus is
on profitability rather than maximizing food production.
In fact many countries are progressively reducing P
fertilizer application rates in response to P sufficiency
in soils (Sattari et al. 2012), but not at rates sufficient to
undo P fixation, only enough to maintain P fertility and
accumulated fixed P at levels capable of sustaining crop
productivity.

On the other hand, in many developing countries,
mainly in the tropics, P fertilizer inputs have been his-
torically restricted. Conversely, large areas of tropical
soils that are increasingly being used for food and ani-
mal feed production, now require large P fertilizer in-
puts. Additionally, the nature of many of these soils will
constrain P bioavailability to crops due to their naturally
high P fixing characteristics (Richter and Babbar 1991).
In these cases, there is often no accumulated P ‘bank’ to
exploit. The focus for low P soils such as these is on
increasing P fertilizer use efficiency and preventing the
accumulation of recalcitrant soil P. Crop rotation using
plant species with the ability to scavenge soil recalcitrant
P, adapted to low soil P availability and high P fixing
capacity conditions, have been suggested as a means of

enhancing the solubility of less labile P forms and
increasing P cycling (Almeida and Rosolem 2016), with
the intention of improving P availability for subsequent
cash crops. Furthermore, the use of cover crops in no-till
farming system has been shown as a good strategy to
reduce the soil P adsorption capacity, when compared to
conventional system.

Several different approaches are available to im-
prove Po and Pi availability and improve Po turnover
(Fig. 1). Enhancing the solubility of soil Po by using
amendments that alter surface properties of soil par-
ticles (Guppy et al. 2005), adding oxidizing agents,
increased root exudation of organic acids, managing
crop rotation and tillage, and increasing aeration and
microbial respiration in soils may improve the avail-
ability of P, but may also have undesirable impacts on
the carbon cycle. These include increasing organic
matter loss and CO2 emission into the atmosphere.
Little is known about whether carbon loss would be
greater or less than the equivalent impact of P fertil-
izer application. As climate change represents another
global threat for future agriculture sustainability, then
innovations to improve soil P availability ideally
should not induce increases in greenhouse gas emis-
sions. Acting independently of the soils C:P stoichi-
ometry, enzyme related technologies can release Pi
from soil Po without affecting stabilized organic car-
bon and therefore appear to be a favourable approach
to mobilizing a significant fraction of the residual Po
without causing loss of carbon to the atmosphere
(Trouillefou et al. 2015).

Technologies to
improve soil P

use by crops and
pastures

Biofer�lizers
Enzyme amendments (eg.
immobilised phytases)

Microbial PGPR inoculants (eg. Rhizosphere
phosphobacteria and mycorrhiza)

Bios�mula�on of na�ve microbes for
increased P solubiliza�on and mineraliza�on

Pre treatment of phytate
rich manures before their

use in soils

Engineered
Plants for

efficient use
of soil P

Root exuda�on of organic acids

Exuda�on of
phosphatase
enzymes

Op�mised P uptake
and resistance to

limited P availability

Management
prac�ces

Fer�lizer
applica�on
strategies

Amendments that increase P solubility
(eg. Manures and compost)

Prac�ces to
induce organic

ma�er
mineraliza�on

Reducing input of recalcitrant P
forms (Fe stabilized sludge, and

phytate rich manures)

Fig. 1 Innovations and
technologies to improve soil
phosphorus use by crops and
pastures via: biofertilizers,
engineered plants and agricultural
management practices

Plant Soil (2018) 427:5–16 9



If an amendment is applied to increase soil P
solubilisation, desorption rates and bioavailability
(Chasse and Ohno 2016; Edwards et al. 2016; Guppy
et al. 2005) it would arguably also increase P losses
(Nest et al. 2014) through leaching and runoff, and
therefore would possibly aggravate the diffuse nutrient
pollution of receiving waters and reduce the sustainabil-
ity of agriculture. Considering both fresh water and
oceans, current planetary conditions exceed all bound-
aries for P discharges (Carpenter and Bennett 2011).
Due to these environmental pressures, soil P mobiliza-
tion solutions should be targeted in the rhizosphere to
guarantee that most of the mobilized P is taken-up by
plants (Giles et al. 2017, 2016; Stutter et al. 2012).Many
plant-evolved mechanisms to cope with P deficiency
have been described, including modified root architec-
ture, abundance of root hairs, root depth distribution,
and P mobilisation by root exudation of enzymes, or-
ganic acids, siderophores, surfactants and microbial
growth stimulants (Brown et al. 2013; Hinsinger 2001;
Richardson et al. 2009; Vance et al. 2003). There is a
general assumption in the scientific literature that after
continuous selection of crop lineages under P sufficient
conditions, modern cultivars have become ‘lazy’ in
scavenging recalcitrant soil P, meaning that Pmobilizing
traits have become either lost or are not sufficiently
expressed in most commercial plant varieties
(Menezes-Blackburn et al. 2016b). Some of these plant
mechanisms can still be widely enhanced in crops either
by selective breeding or by genetic modification
(Richardson et al. 2009) in order to develop genotypes
which can cope with reduced P inputs. Similar, and
sometimes more specialized, soil P scavenging traits
can be found in microbes. The genetic modification of
plants to express microbial traits, such as root exudation
of appropriate enzymes and organic acids, is in theory a
good approach for mobilizing soil fixed P (Richardson
et al. 2009). Nevertheless, in most countries genetically
modified (GM) food products still encounter strong
public resistance and prohibitive legislative environ-
ments, regardless of the source and benefits of the genes
being modified (Frewer et al. 2004). While countries
with greater acceptance of GM products can (but not
necessarily will) use plants expressing more efficient
microbial traits, currently most countries will have to
rely only on traits evolved within the same plant species.

From a technical point of view, the genetic modifi-
cation of plants to express root exudation traits
favouring greater P mobilization and uptake efficiency

is also not a simple challenge, and many problems may
render them ineffective. These include: a) insufficient
expression of the trait to translate into increased P
mobilisation (Menezes-Blackburn et al. 2016b); b) un-
even distribution of the trait expression in roots causing
insufficient spatial coverage; c) co-expression of com-
plementary or synergistic traits may be needed for the
application to successfully work in soil environments,
such as the co-expression of organic acids and phytases
(Giles et al. 2017); d) the expressed trait may cause a
down regulation of the rhizosphere microbial expression
of the same trait (unpublished); c) unforeseen interac-
tions of exuded biomolecules in different soil environ-
ments, such as unfavourable changes in soil pH (Giles
et al. 2017), enzyme inactivation after adsorption into
solid soil phase (George et al. 2006b) or immediate
microbial degradation of the exuded biomolecule
(Menezes-Blackburn et al. 2016b); d) unforeseen nega-
tive effects related to the function of the rhizosphere
microbes, such as increased immobilization of P in the
microbial biomass (Menezes-Blackburn et al. 2016b); e)
the genetic modification may represent ‘too big’ an
energetic/ biochemical burden to the plant, overcoming
its benefits (Hu and Du 2006); f) unintended plant
physiological changes are observed even in vector con-
trols, lacking the heterologous expression of the targeted
functional gene, which can cause them to underperform
compared to the wild type controls in terms of P uptake
(Giles et al. 2016).

In consideration of these complicated issues, the
optimum approach may not be to directly mobilize soil
P at all, but to reduce plant requirements for high P
availability in soils. A promising biotechnological ap-
proach derives from genetic studies to develop crops
with reduced phosphate accumulation in the form of
phytate in grains (Raboy 2001, 2002). On the other
hand, reducing phytate levels in seeds may have unin-
tended consequences for germination and seedling vig-
our. However, a reduction in plant requirements for high
P availability in soils would allow productivity to be
maintained at a reduced P fertilizer input, depleting
available P and reversing the equilibrium towards a
natural and gradual mobilization of fixed soil P by
crops.

Inoculating the soil with microbes screened for traits
that favour the efficient mobilization of recalcitrant P
has been widely proposed, and some phosphobacteria
and mycorrhizal inoculants are already commercially
available (Owen et al. 2015). Nevertheless, these

10 Plant Soil (2018) 427:5–16



inoculants have to compete with native soil microbes
and a few important issues still keep this technology
from being the decisive solution for accessing soil fixed
P (Jakobsen et al. 2005), including: a) limited impact on
plant growth and therefore limited commercial value; b)
plant-inoculant specificity; c) inefficient colonization of
rhizospheres and small inoculum survival (Martinez-
Viveros et al. 2010). Even when enough P is released
by the microbe inoculants, parallel P fixation in the
microbial biomass can negate plant growth and P uptake
(Menezes-Blackburn et al. 2014). Recent developments
have demonstrated that using phosphobacteria inocu-
lants along with their grazers (nematodes) could signif-
icantly increase available P and plant P uptake (Irshad
et al. 2012). This work underlines the importance of
trophic cascades to avoid/diminish competition of plant
and microbial inoculants and increase the cycling of
released P.

Fertilizer application technologies such as rate, fre-
quency, depth and fertilizer placement relative to seed
position have an important effect on P uptake efficiency,
and are dependent on both plant and soil type. The
fertilizer should be applied where and when the plants
need it; applying P fertilizer to the whole topsoil is not
an efficient approach and the rhizosphere should ideally
be targeted. At the field scale, one way to manage the
heterogeneity of P in agricultural soils is through preci-
sion farming, whereby the distribution of bioavailable P
in the topsoil is accurately assessed by soil testing, and
fertiliser spread at appropriate rates accordingly (Carr
et al. 1991; Wollenhaupt et al. 1994).

The need for a new understanding
of the bioavailability of phosphorus pools

Not only effective biotechnologies for soil phosphorus
mobilization are needed but also better management
practices. In order to intervene in the fixation and soil
recalcitrance of different P species there is a need for
better management of P fertilizer application in arable
and grassland soils. Fertilizer recommendations can
vary greatly (up to 3-fold) for the same P status (Often
derived by Olsen extraction) (Jordan-Meille et al. 2012),
and better ways of assessing P bioavailability, linked to
clear criteria for P fertilizer application rates, still do not
exist after decades of related research (Beegle 2005; Six
et al. 2013). The main reason is that most soil agronomic
P tests tend to poorly represent the plant P uptake across

different soils and only work well for limited soil and
plant combinations under increasing P fertilizer doses
because they are derived from limited classical critical P
experiments. In the same sense, there is still not a well
validated, universal soil test that represents soil P satu-
ration and potential for P loss to receiving waters
(Maguire et al. 2005). Our conceptual understanding
of P cycling and bioavailability based on static pools
(that can be represented by single soil test) needs to be
revised and updated in order to better inform our man-
agement strategies for sustainable management of our
natural resources.

Plant roots can deplete rhizosphere solution P in a
matter of minutes (Oehl et al. 2001), and therefore soil P
fertility is actually not only a function of a Bpool size^
but of the rate at which P can move to the rhizosphere by
diffusion and desorption following depletion (Kovar
and Claassen 2005). Understanding the nature of P
availability as an integration of kinetic rhizosphere pro-
cesses (Fig. 2; rate of diffusion, desorption and
mineralization) is a critical change of mind-set for the
current P research community (Menezes-Blackburn
et al. 2016c). Soil P pools are traditionally viewed as a
range of static, largely isolated groups of P species,
separated by their chemical lability. Chemical lability
is defined as how likely these P forms are to undergo a
change of state, such as adsorbed-to-desorbed or precip-
itated-to-soluble, and is normally poorly assessed by
quantifying equilibrium solution P after shaking these
soils with different extractants. From their chemical
lability, plant bioavailability is estimated, and may be
arbitrarily classified on a gradient of increasing lability
and plant (crop) bioavailability pools, such as the ones
described by Johnston et al. (2014): a) immediately

Fig. 2 Rhizosphere processes involved in soil phosphorus bio-
availability and plant uptake: diffusion through soil solution; sorp-
tion desorption balance; organic phosphorus (Po) mineralization;
and fixation in microbial biomass

Plant Soil (2018) 427:5–16 11



accessible – soil solution P or water extractable P; b)
large accessibility - readily available and extractable by
agronomic P tests such as Olsen P; c) limited accessi-
bility - less readily available, strongly bonded and
adsorbed P; d) very limited accessibility – mostly un-
available, very strongly bound to soil solid phase, min-
eral P or insoluble P precipitates (Johnston et al. 2014).

This mechanistic approach of using 2 to 4 lability
compartments (pools) to define plant bioavailability has
been proven to be compatible with the different methods
of extracting P (such as Olsen and Morgan tests), and
has also proven useful to some extent in managing the
fertilizer dose needed to sustain adequate crop produc-
tivity (Johnston et al. 2014; Syers et al. 2008). Never-
theless, when it comes to understanding the system
dynamics and the accumulation / mobilisation of soil P
over years, this approach is simplistic and limits the
current understanding in several ways: a) it mostly ig-
nores the role of organic phosphorus and P forms locked
in the soil microbial biomass; b) the chemical speciation
of Pi and Po and their different behaviour is only dealt in
a very superficial way (e.g. acid vs alkali solubility and
different extractant strength); c) when dealing with read-
ily bioavailable pools, this model ignores the abundance
of the different chemical P species and their kinetics of
diffusion, desorption and solubilisation; d) information
about the effect of size of chemical P complexes and
their aggregates on P lability is overlooked; e) this type
of model only deals with complexity by increasing the
number of lability compartments, which does not direct-
ly represent soil processes or their integration
(solubilisation, diffusion, desorption, mineralization,
uptake, etc.); f) it ignores plant mechanisms to actively
mobilize P through root conditioning of the rhizosphere
environment such as pH change, exudation of organic
acids and enzymes (Darch et al. 2016).

An improved conceptual model of P cycling in soils
is needed in order to improve our understanding of soil
P accumulation and to address the limited knowledge on
soil P bioavailability by improving fertilizer P use effi-
ciency. In this new conceptual model of P cycling, a
temporal (kinetic) component of soil P transformations
must be considered. Zheng and Zhang (2011) made an
attempt to associate the Hedley sequential fractionation
with chemical lability pools, categorized in slow and
rapid cycling depending on the strength of the extractant
(Hedley et al. 1982; Zheng and Zhang 2011). This type
of pool fractionation analysis is misleading, does not
capture the real processes occurring in soils and often

leads to speculative discussions about their bioavailabil-
ity and chemical lability (Turner et al. 2005). On the
other hand, giving a kinetic component to this analysis is
an improvement on the static lability pools, and there is
still much to be uncovered about the behaviour of indi-
vidual chemical P species. For an accurate and correct
interpretation of the system, coupled with better assess-
ment of bioavailability, a complete speciation of soil P
must be made with the characterization of the temporal
dynamics of individual soil P species and their rates of
cycling. This will allow the assessment of possible
interventions on the soil P cycle to alter input/output
balances of rapid cycling species (quasi instant and
daily) and or intervene on accumulation/depletion of
slower cycling pools (seasonal and inter-annual).

Future perspectives for the biotechnological
mobilization of soil phosphorus

Soil P research up to the 1970s was driven by the
question of how much fertilizer P was needed in order
to securemaximum crop productivity. A secondwave of
research was driven by environmental concerns about
the high P status of many fertilized soils and the
resulting nutrient pollution of receiving watercourses.
Both are still valid scientific questions: there is a strong
need to reduce total P in soils to environmentally ac-
ceptable levels, whilst maintaining optimal crop growth
conditions (Barberis et al. 1995). Nevertheless, the time
has come to move on from simply understanding the
behaviour, movement and transport of P in soil systems
to taking action by developing technologies to enhance
the efficiency of P fertilizer application and the use of
our natural rock phosphate resources. In many ways, the
scientific community is starting to address this demand.
Nonetheless, satisfactory solutions/technologies have
not yet been developed and breakthroughs are still
needed. Many meetings and symposia have been held
recently on the subject of soil P resulting in an increase
in international cooperation on this topic. However
much of the ongoing research is still fragmented and
disconnected. Independently of the approach taken, re-
searchers have a natural tendency to process information
at increasingly finer scales, focusing on their individual
sub-disciplines (e.g. microbial ecology, enzymology,
chemical speciation, method development, etc.). Addi-
tionally, it is our appreciation that researchers in general
are moved by their curiosity rather than by their

12 Plant Soil (2018) 427:5–16



willingness to generate impact. The final application or
purpose of the knowledge generated tends therefore to
become more often an Bintroduction material^ rather
than the actual focus of the research. In other words,
new ‘big picture’ driven and impact focused research is
needed if we are to create solutions for the sustainable
use of the legacy soil P.

Although there is clear evidence that long term fer-
tilizer application leads to soil P accumulation, the size
and potential uses of residual soil P pools worldwide are
still unknown. The analysis presented in Table 1 indi-
cates the huge potential for using soil residual P, but the
limitations inherent in this analysis mean it is insuffi-
cient for making an accurate assessment of the actual
size and distribution of the legacy P pool. There is a
need for building a world soil P inventory considering
plant P availability indices, speciation of P forms and
more importantly the size of the residual P pool that can
potentially be mobilized by different technologies. Op-
timistically, we expect that wider multidisciplinary ini-
tiatives will soon be funded and important steps can be
taken in the direction of a positive outcome on soil P
mobilization technologies.

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Acknowledgements This work was performed as part of the
Organic Phosphorus Utilisation in Soils (OPUS) project, funded
by Biotechnology and Biological Sciences Research Council
(BBSRC) responsive mode grant (BB/K018167/1) in the UK to
explore cropping strategies to target the use of recalcitrant soil Po.

Open Access This article is distributed under the terms of the
Creative Commons Attribution 4.0 International License (http://
creativecommons.org/licenses/by/4.0/), which permits unrestrict-
ed use, distribution, and reproduction in any medium, provided
you give appropriate 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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16 Plant Soil (2018) 427:5–16

http://dx.doi.org/10.1016/S0146-6380(03)00061-5
http://dx.doi.org/10.5772/1401

	Opportunities for mobilizing recalcitrant phosphorus from agricultural soils: a review
	Abstract
	Abstract
	Abstract
	Abstract
	Introduction
	Phosphorus fixation and bioavailability in soils
	How much soil phosphorus can potentially be mobilized?
	Approaches and technologies for sustainably increasing recalcitrant soil phosphorus bioavailability
	The need for a new understanding of the bioavailability of phosphorus pools
	Future perspectives for the biotechnological mobilization of soil phosphorus
	References