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Synthesis, structure and biological evaluation of ruthenium(III) complexes of triazolopyrimidines with anticancer properties.
Eur J Plant Pathol (2019) 154:91–107
https://doi.org/10.1007/s10658-019-01743-w
Pseudomonas chlororaphis and organic amendments
controlling Pythium infection in tomato
Joeke Postma & Els H. Nijhuis
Accepted: 4 April 2019 / Published online: 16 April 2019
# The Author(s) 2019
Abstract To create more resilient growing systems for
greenhouse crops, the efficacy of different organic
amendments alone and in combination with the biocontrol strain Pseudomonas chlororaphis 4.4.1 was tested
to suppress Pythium disease in tomato plants. Four
independent greenhouse experiments were performed
with young tomato plants in potting soil. Inoculating
the pathogen Pythium aphanidermatum to the potting
soil prior to sowing resulted in significant losses of
tomato plants; i.e. 94–98% healthy plants in pathogenfree control compared to 43–68% healthy plants when
the pathogen was added. P. chlororaphis 4.4.1 inoculations increased the number of healthy plants in the
potting soil up to 80% on average; soil and seed treatment were both effective. Numbers of P. chlororaphis in
the rhizosphere had increased 4 to 100 fold 3 weeks after
its inoculation (qPCR detection). All compost types
reduced Pythium disease in potting soil resulting in
80–95% healthy plants. Animal bone char was not
effective against P. aphanidermatum, whereas with
plant-based biochar there was an effect, although not
significantly different from the control treatment. Phosphorous and potassium uptake by the plants were elevated by the different organic amendments. These
Electronic supplementary material The online version of this
article (https://doi.org/10.1007/s10658-019-01743-w) contains
supplementary material, which is available to authorized users.
J. Postma (*) : E. H. Nijhuis
Business Unit Biointeractions and Plant Health, Wageningen Plant
Research, PO Box 16, 6700 AA Wageningen, The Netherlands
e-mail: joeke.postma@wur.nl
results demonstrate the potential of the organic amendments to enhance sustainability of growing media such
as potting soil by increasing its disease suppressiveness,
the re-use of nutrients and replacement of peat by using
organic amendments. In addition, inoculating the growing medium or tomato seeds with the biocontrol strain
P. chlororaphis 4.4.1 enhanced Pythium control in the
susceptible growing media.
Keywords Compost . Biochar . Animal-bone char .
Biological control . Disease suppression . rpoD qPCR
Introduction
With an increasing world population (predicted 9.7 × 109
in 2050 (United Nations 2017)) and a growing need for
food, agricultural systems must become more productive
and more sustainable. Especially intensive cropping systems consume significant amounts of non-renewable inputs such as fertilizers, fuel and growing media containing
peat. Chemical pesticides, applied to protect crops from
biotic stresses and yield losses, cause environmental contamination. Meanwhile, organic materials are treated as
waste, but have the potential to be re-used as fertilizer, as
soil improver or as part of growing media. In this context,
the paradigmatic shift in waste management initiated by
the European Waste Framework Directive (Council
Directive 2008/98/EC) enhances the possibility of continuing the life cycle of materials in the perspective of a circular
economy, i.e. organic rich waste can be applied for agricultural beneficial use allowing organic matter and nutrient
�92
cycling, as alternatives to their landfilling or incineration
(Alvarenga et al. 2017; Estrada De Luis and Gómez
Palacios 2013; Manfredi and Pant 2013). Nowadays, a
wide range of resources and products with the potential
to overcome soil constraints, improve nutrient use efficiency or support plant health, is available for application in
agriculture (Abbott et al. 2018).
Also micro-organisms have the potential to enhance
plant growth and protect them against biotic and abiotic
stresses (Reid and Greene 2012; Parnell et al. 2016; Kim
and Anderson 2018). The presence of beneficial organisms in soil can be stimulated by organic amendments as
well as biostimulants, or by inoculating microbial strains
(Calvo et al. 2014; Abbott et al. 2018). Efficacy of all
these products, separate or in combination, is often unclear and very much dependent on the environmental
condition, soil type as well as the crop type. More experimental data on efficacy of these products to support all
the different claims are needed (Abbott et al. 2018).
Long term experience is available with compost applications in agriculture and horticulture to improve soil
quality and fertility (Martinez et al. 2006). Compost can
also substitute peat in potting soil (Vandecasteele et al.
2018; Avilés et al. 2011). Moreover, compost is often
mentioned for its disease suppressive effects against
several foliar and soil-borne diseases (Termorshuizen
et al. 2006; Noble and Coventry 2005; Bonanomi et al.
2010), but results can be variable and the effects are
case-specific (Martinez et al. 2006).
More recently, positive effects of biochar as a soil
amendment are appointed on plant growth and soil
quality (Bonanomi et al. 2015; Glaser et al. 2002;
Jeffery et al. 2011). Biochar is a relatively recalcitrant
product generated through pyrolysis, i.e. a reductive
thermal process carried out at temperatures from 300
to 850 °C, whereas input material as well as temperature
and residence time are crucial for the quality of the
resulting carbonized product (Someus and Pugliese
2018). A meta-analysis of 16 studies on biochar application to soil indicated that improved water holding
capacity, liming effect and improved crop nutrient availability are the main causes for increased crop productivity (Jeffery et al. 2011). Biochar is also indicated as
sustainable alternative for the use of peat in potting soil
reducing the peat derived CO2 emissions (Blok et al.
2017; Kern et al. 2017). Some studies indicate the
potential of biochar to reduce foliar diseases and pests
(Kumar et al. 2018; Meller Harel et al. 2012; De Tender
et al. 2016) as well as soil-borne plant pathogens
Eur J Plant Pathol (2019) 154:91–107
(Jaiswal et al. 2017; Huang et al. 2015; Jaiswal et al.
2014). However, compared to compost, very few experimental studies on biochar controlling plant diseases are
available (Bonanomi et al. 2015).
To create more sustainable growing systems for greenhouse crops, both compost and biochar can be added to
potting soil to recycle nutrients and to substitute part of the
peat. In addition, the impact of these amendments on
disease suppressiveness is relevant, but the variability in
disease control among different crops and/or systems will
complicate the application. Addition of microbial inoculants, alone or in combination with the organic amendments, might provide more robust disease suppressive
effects (Pugliese et al. 2011; Bonanomi et al. 2018). Especially artificial growing media (i.e. rockwool, perlite) and
potting soil can benefit from introducing micro-organisms
not yet present, since such media start with a low microbial
biodiversity and lack plant associated microbes. Some
studies demonstrated an increased disease suppression by
the addition of biocontrol micro-organisms to compost
(Postma et al. 2003; Trillas et al. 2006; Pugliese et al.
2011). Other studies tested the potential of biochar to be
used as carrier for beneficial micro-organisms (Hale et al.
2015; Postma et al. 2013).
In the current research, disease suppressive effects of
several composts and two biochar types were evaluated
in four independent greenhouse experiments performed
with young tomato plants in potting soil. All potting soil
mixtures were tested without (i.e. healthy controls) and
with the pathogen Pythium aphanidermatum inoculated
to the potting soil prior to sowing. Pseudomonas
chlororaphis strain 4.4.1, which previously successfully
controlled P. aphanidermatum (Postma et al. 2010), was
inoculated to potting soil, biochar or tomato seeds, alone
and in combination with the different organic amendments. Seed germination, number of healthy plants,
plant growth and nutrient uptake were evaluated. Root
colonization by the inoculated P. chlororaphis 4.4.1
strain was assessed by making use of a novel designed
quantitative PCR system targeting the rpoD gene of
P. chlororaphis 4.4.1.
Materials and methods
Growing medium and organic amendments
Potting soil was used as growing medium for all greenhouse experiments. This potting soil (product nr.
�ammonium lactate extraction (plant available nutrients)
a
BGU, Spain
BGU, Spain
1.5
7.1
21.8
8.4
1.7
6.6
16.1
26.0
37.0
40.0
24.8
14.2
7.5
8.3
2014
2015
10
COES3
Compost
Green waste + manure 10
COSPBD
Compost
Green waste
BGU, Spain
BGU, Spain
4.8
7.9
21.7
20.9
6.9
8.7
14.2
9.5
19.1
31.3
22.0
22.6
8.5
8.7
2014
2014
10
COSPBS
Compost
Green waste + manure 10
COSPGD
Compost
Green waste
Proficomp, Hungary
BGU, Spain
4.2
19.2
6.9
9.4
22.2
23.6
8.4
2014
10
COSPGS
Compost
Green waste
5.6 a
COHU214 Green waste
Compost
10
2014, 2015
8.1
13.5
20.0
15.2
1.3 a
0.2 a
Van Iersel, Netherlands
Proficomp, Hungary
0.2 a
5.5 a
1.2 a
12.4
18.0
14.3
8.0
2014, 2015
COHU114 Green waste
Compost
10
Van Iersel, Netherlands
2.0
2.1
7.0
7.0
0.9
–
8.3
5.4
6.3
11.3
13.6
11.7
7.8
7.3
2013
2014, 2015
10
10
Green waste
CONL
CONL
Compost
Compost
Green waste
Pyreg, Germany
Van Iersel, Netherlands
–
3.6
1.1
4.7
–
–
7.4
2012
10
Green waste
CONL
Compost
Terra Humana, Hungary
7.0
1.1
10.5
2.0
133
5.8
8.4
18.0
9.2
49.0
5.1
58.7
9.7
2014, 2015
2012, 2013, 2014, 2015 7.6
1
1
Plant biomass
Pigg bones
ABC
Animal-bone char
Plant-based biochar PBC
pH C/N ratio TOC (%) Ntotal (g/kg) P (g/kg) K (g/kg) Na (g/kg) Company
Dosage (%) Year of experiment
Ingredients
The pathogen Pythium aphanidermatum 89 is causing
pre- and post-emergence damping off in different plant
species, including tomato seedlings. The strain was
stored in liquid nitrogen. The pathogen was grown in
100 ml Erlenmeyer flasks with 25 ml liquid V8 medium,
containing 5 ml V8 vegetable juice (Campbell Foods,
Puurs, Belgium), 75 mg CaCO 3 , and 20 ml
demineralized water (Postma et al. 2010). Flasks were
incubated in the dark without shaking at 25 °C for 8–
10 days. After incubation, the mycelium was washed
three times with 50 ml sterilised tap-water to remove the
medium, and blended in a Warring blender. Inoculum
from one flask was used to infest 2.5 l growing medium,
resulting in an inoculum density per experimental unit
Code
Pathogen inoculum
Product
80,917, Lentse Potgrond BV, the Netherlands) consisted
of 26% German/Irish fraction 0, 14% Baltic peat medium, 40% Swedish fine peat moss, 20% perlite,
0.5 kg m−3 PG-mix 12–14-24, 0.025 kg m−3 Superspoor
MMS, and had a pH of 5.2.
Organic amendments (see overview in Table 1) were
mixed through this potting soil. Two different types of
biochar, animal-bone char (ABC) produced by Terra
Humana ltd. (Biofarm Agri Research Station, Hungary)
and plant-based biochar (PBC) (PYREG®) produced by
Pyreg GmbH (Dörth, Germany), were applied in a dosage
of 1% (weight/volume). ABC is made from food-grade
animal bones at high carbonization temperature 850 °C
and consists mainly of calcium phosphate. PBC is made
from plant materials at a lower carbonization temperature,
usually 450 °C, having a high carbon content.
A Dutch green waste compost (0–15 mm fraction)
produced by Van Iersel Biezenmortel BV (the Netherlands) coded CONL was used in all experiments in a
10% dosage (volume/volume). Sterilized CONL compost was used for assessment of microbial effects on
P. aphanidermatum disease suppression in the 2015
experiment (sterilization by gamma-radiation at 60
kGray; Synergy Health Ede, the Netherlands). Seven
composts from other origins were included in the experiments in 2014 and 2015 (dosage 10% volume/volume).
Detailed chemical analysis of the organic amendments, including organic pollutants such as PAHs (polycyclic aromatic hydrocarbons) and heavy metals, were
performed by Wessling (Hungary Kft., Budapest). A
selection of the characteristics, focussing on the plant
nutritional value, is summarized in Table 1.
93
Table 1 Characteristics of the organic amendments applied in different experiments. Analyses are performed by Wessling Hungary Kft. (Budapest, Hungary)
Eur J Plant Pathol (2019) 154:91–107
�94
(pot) of approximately 105 colony-forming units (CFU)
consisting of viable mycelium fragments and spores.
Inoculum concentration was checked by plating serial
dilutions on ¼ potato dextrose agar (PDA; 9.6 g PDA
(Oxoid), 11.2 g agar per litre; 100 mg l−1 streptomycin
and 10 mg l − 1 tetracycline were added after
autoclaving).
Bacterial antagonist P. chlororaphis 4.4.1
The bacterial strain inoculated to the different growing
media in the experiments 2012, 2013, 2014 and 2015
was selected for its capacity to mobilize phosphorous
(Postma et al. 2010) and its potential to control diseases
in tomato plants (Postma et al. 2013). Strain 4.4.1 was
originally isolated from an arable soil (Postma et al.
2008) and later identified as Pseudomonas chlororaphis
subsp. aureofaciens based on sequencing of a 1500 bp
fragment of the 16S rRNA gene (EMBL accession
FR682804). The strain was maintained in freeze stock
culture (−80 °C in 20% glycerol) and freshly cultured
from frozen stocks prior to each experiment.
Inoculum was produced on R2A (Difco) plates at
25 °C. Bacterial cells were scraped from the plates
and diluted in R2B (broth) to obtain the proper
inoculum concentration. Ingredients of R2B per litre
were 0.5 g proteose peptone, 0.5 g casamino acids,
0.5 g soluble starch (Difco), 0.5 g dextrose, 0.3 g
sodium-pyruvate, 0.3 g K2HPO4 and 0.05 g MgSO4
(Sigma). The inoculum density was checked during
preparation by measuring the optical density of the
suspension. Final concentration was assessed by plating serial dilutions of the inoculum on R2A plates in
duplicate and counting colony-forming units (CFU)
after 2–4 days incubation at 25 °C.
P. chlororaphis was also applied to the tomato
seeds in the 2015 experiment following a procedure
which has been used for other non-spore forming
gram-negative bacteria (Abuamsha et al. 2011). The
method was adapted slightly for treatment of tomato
seeds. Seeds were gently stirred during 30 min in
5 ml suspension P. chlororaphis with 1 ×
107 CFU ml−1 in MgSO4 (0.1 M l−1). Thereafter the
excess of water was removed on filter paper. Colonization of the seeds with P. chlororaphis was determined in duplicate by plate counting. Ten seeds per
replicate were homogenized in 1 ml Ringers solution
in BIOREBA extraction bags. A dilution series was
plated on R2A medium as described above.
Eur J Plant Pathol (2019) 154:91–107
Effect of potting soil treatments on Pythium suppression
The ability of P. chlororaphis and two organic amendments to control P. aphanidermatum in tomato seedlings
was first tested in two independent greenhouse experiments (2012 and 2013) as described by Postma et al.
(2013). Four growing media were tested: potting soil
alone (Control), and potting soil mixtures with 1%
animal-bone char (ABC), 10% compost (CONL), or
10% compost +1% ABC (CONL+ABC). The assay
was performed in plastic pots (11 × 11 × 12 cm) with
500 cm3 growing medium (equivalent to 91 g moist
product). P. chlororaphis was added as liquid formulation directly to the growing media or to the animal-bone
char (ABC) particles prior to their addition to the growing media. All inoculations of P. chlororaphis in the
growing media were designed to have a final concentration of 106 cells g−1 potting soil. The microbial
enriched ABC, used as a solid formulation, was directly
applied to the potting soil without drying and contained
108 cells P. chlororaphis g−1 ABC. All growing media
were also tested without P. chlororaphis and all treatments were assessed with and without pathogen inoculum. P. chlororaphis and pathogen inoculum were
mixed gently through the potting soil mixtures, pots
were filled with these mixtures and placed in the greenhouse at 25/20 °C d/n with 16 h light. Pots were covered
with a plastic sheet to avoid evaporation. After 2 days
incubation, 10 tomato seeds cultivar Pronto (De Ruiter
Seeds, Bergschenhoek, The Netherlands) were sown per
pot. Germination of seeds and post-emergence
damping-off symptoms were monitored for a period of
21 days.
Two additional greenhouse experiments were performed in 2014 and 2015 to repeat the effect of ABC
and the CONL compost on disease suppression and to
evaluate an additional type of biochar, as well as seven
other compost types. The bacterial antagonist
P. chlororaphis was added directly to the growing media
and in 2015 also as seed treatment. The assay was
performed similar as described above, with few changes. All amendments were mixed with the potting soil
mixtures 7 days before sowing and incubated in bags at
25/20 °C (day/night). Three (2014) or two (2015) days
before sowing the pathogen and antagonist, or equal
amounts of water in case of the control, were added
and mixed through the soil. The concentration of
P. chlororaphis when added as liquid to the growing
media was adjusted to a 10 times higher final density
�Eur J Plant Pathol (2019) 154:91–107
then in the previous experiments, i.e. 107 cells g−1 soil.
In 2015, the antagonist was also applied as a seed
treatment (method is described above) at the day of
sowing. On average 2.4 × 103 CFU seed−1 were present
after seed treatment. In the presence of the pathogen 10
tomato seeds were sown per pot and germination of
seeds and post-emergence damping-off symptoms were
monitored for a period of 21 days. In the treatments
without the pathogen, five seeds per pot were sown to
determine plant biomass and nutrient uptake 25 days
after sowing; seed germination and number of healthy
plants were monitored as well.
All experiments were carried out with four replicates
in a randomized block design with one pot of each
treatment per block.
Nutrient analysis
Above ground parts of healthy plants were harvested
after 25 days of growth and dried at 70 °C to determine
fresh and dry weight (2014 and 2015). Thereafter the
dried plant material was grinded, and after extraction
total N, P and K concentrations were analysed at CBLB
(ISO-17025 accredited lab, Wageningen, the
Netherlands).
Rhizosphere sampling and DNA extraction
Presence and localization of P. chlororaphis 4.4.1 on the
tomato roots was visualized at the end of the experiment in
2013. Roots of healthy plants were taken out of the soil,
washed with tap water, excess of water was removed with
filter paper and roots were pressed on square Petri dishes
with agar medium (R2A). Roots were removed with forceps and the plates with imprints were incubated for 3 days
at 25 °C. P. chlororaphis was recognized by its yellowishorange colony pigmentation.
For quantitative detection of P. chlororaphis 4.4.1,
tomato rhizosphere samples were harvested from treatments without Pythium inoculation in 2012, 2013 and
2015, respectively 21, 26 and 25 days after sowing.
Roots with adhering potting soil were cut into pieces
and stored at −80 °C. For each sample 0.4 g of root
pieces with adhering potting soil was used for DNA
extraction with a PowerMag® Soil DNA Extraction kit,
optimized for KingFisher (Mo Bio Laboratories Inc.,
Carlsbad, USA). The manufacturer’s protocol was
adapted to the combination of roots and potting soil.
Lysis was done in 5 ml tubes to accommodate 2.5 times
95
more lysis buffer per sample and all following steps were
subsequently adapted resulting in 200 μl eluted DNA for
each sample after KingFisher wash-steps. DNA of all
samples was quantified with a PicoGreen assay (QuantiT PicoGreen dsDNA Assay kit, Invitrogen) on Infinite
M200pro (Tecan Group Ltd) according to the manufacturers’ instructions. All samples were diluted to 5 ng μl−1
DNA, prior to quantitative PCR.
Primer design of P. chlororaphis 4.4.1
and quantification of microbial populations
in rhizosphere soil
A strain specific primer system was designed for
P. chlororaphis strain 4.4.1. For that purpose, type
strains of P. chlororaphis subsp. aureofaciens, subsp.
aurantiaca, subsp. chlororaphis and P. corrugata were
used, as well as a selection of strains available from our
collection that were expected to be P. chlororaphis
based on partial 16S sequences and their production of
green to orange exo-pigments during growth (Table 2).
Also three other Pseudomonas spp. strains and two less
related bacterial strains were included. P. chlororaphis
strain 4.4.1, type strain P. chlororaphis subsp.
aureofaciens DSM 6698, and strains 10.2.5 and 11.4.2
appeared to be identical in REP-PCR (repetitive
extragenic palindromic-PCR) (Rademaker et al. 1998)
fingerprint analysis. Consequently, no suitable specific
band allowing the design of primers and probes based
on a strain specific sequence as described by Nijhuis
et al. (2010) was available.
The strategy for designing specific primers for
P. chlororaphis 4.4.1 detection was to target the rpoD
(RNA polymerase sigma factor) gene, which is most discriminating out of four protein-coding genes studied in the
genus Pseudomonas (Mulet et al. 2010). The rpoD fragments of P. chlororaphis 4.4.1 and the three closely related
strains were amplified with a nested approach (Yamamoto
et al. 2000). For the first PCR the 70F/70R primer set was
used, followed by a second PCR on the 70F/70R
amplicons with 70Fs/70Rs (Yamamoto et al. 2000) and
PsEG30F/PsEG790R (Mulet et al. 2009). Sequences were
aligned using CLC Main Workbench (www.clcbio.com)
with 146 rpoD sequences for the Pseudomonas genus
retrieved from NCBI database to visualize possible
interesting areas in the sequence for primer and probe
design targeting subspecies level. The NCBI PrimerBlast tool (Ye et al. 2012) was used to find suitable primers
in these areas. The thus designed rpoD primer set, as well
�type strain
collection
P. chlororaphis subsp. chlororaphis
P. corrugata
DSM 50083
DSM 7228
type strain
collection
collection
Pseudomonas sp. (P. chlororaphis subsp. chlororaphis*) #
Pseudomonas sp. (P. thivervalensis*)
Pseudomonas sp. (P. lini*)
P. fluorescens
Lysobacter antibioticus
Burkholderia phenazinium
10.2.6
1110-103A
CE17
1110–027
5
3.2.10
N1–3
* Best blast scores NCBI database based on partial 16S sequences,
# selected as potential P. chlororaphis due to its green/orange exo-pigmentation
++ = strong positive, + = positive, ± = weak, − = no reaction
a
b
c
11.4.2
collection
collection
collection
collection
±
collection
–
–
–
–
–
–
–
+
–
++
–
–
±
–
±
++
++
++
±
++
++
++
Quantitative PCR
rpoD1F/rpoD1R c (this study)
–
++
++
++
±
++
++
++
PCR rpoD1F/rpoD1R c
(this study)
++
++
±
±
++
++
++
++
++
++
++
PCR rpoD 30–84 c
(Wang et al. 2012)
collection
collection
P. chlororaphis subsp. aureofaciens
Pseudomonas sp. (P. chlororaphis subsp.
aureofaciens*) #
Pseudomonas sp. (P. chlororaphis subsp.
aureofaciens*) #
Pseudomonas sp. (P. chlororaphis*) #
4.4.1
10.2.5
type strain
type strain
P. chlororaphis subsp. aureofaciens
P. chlororaphis subsp. aurantiaca
DSM 6698
Origin
Species a b
DSM 19603
Code
Table 2 Reaction of bacterial strains with the selected primers for detection of Pseudomonas chlororaphis 4.4.1
96
Eur J Plant Pathol (2019) 154:91–107
�(Cai et al. 2009)
TaqMan
60
ND
5.8P1: 5′-CATCGATGAAGAAC
GCAGCGAAATGC
(Fierer et al. 2005)
SybrGreen
53
200
(Bergmark et al. 2012)
TaqMan
60
251
Pse449: Fam-ACAGAATA
AGCACCGGCTAAC-BHQ
NA
This study
SybrGreen
60
166
NA
rpoD1r: 5′-TTCT
GCTGGCAACGGATGAT
Pse686R: ACACAGGA
AATTCCACCACCC
Eub518r: 5’-ATTACCGC
GGCTGCTGG
5.8R1: 5′-GCGTTCAAAGACTC
GATGATTCAC
rpoD
16S V3-V4
16S V3
5.8S
P. chlororaphis 4.4.1
Pseudomonas spp.
Bacteria
Fungi
rpoD1f: 5′-TGCA
GCTCTGTGTTCGTGAT
Pse435F: ACTTTAAG
TTGGGAGGAAGGG
Eub338f: 5′-ACTC
CTACGGGAGGCAGCAG
5.8F1: 5’-AACTTTCA
ACAACGGATCTCTTGG
PCR-assay
Annealing
temp (°C)
Amplicon
length (bp)
Probe
Reverse primer
Forward primer
Target
gene
Target organism
Table 3 Primers and probes for quantitative DNA detection of Pseudomonas chlororaphis 4.4.1, Pseudomonas spp., total bacterial and fungal populations
as another rpoD primer set developed for P. chlororaphis
strain 30–84 (Wang et al. 2012), were evaluated for their
specificity with all strains listed in Table 2, i.e. band
intensity, size, and presence of by-products were taken into
account. Then, the performance of the selected rpoD primer set was tested in qPCR (SybrGreen assay, described
below) on dilution series of P. chlororaphis 4.4.1 (2–
0.0002 ng μl−1 DNA) compared to the strains listed in
Table 2 (0.2 ng μl−1 DNA) with two primer concentrations
(300 and 600 nM).
P. chlororaphis 4.4.1 populations were quantified in
the rhizosphere samples with qPCR using the newly
designed rpoD primer set. In addition, more general
primer sets to quantify Pseudomonas spp., total bacteria
and fungi were included for the same samples. Used
primer sets and references are listed in Table 3. qPCR
was performed as a SybrGreen assay with Sybr® Premix
Ex Taq (Takara Bio Inc., Otsu, Japan) to quantify
P. chlororaphis 4.4.1 and total bacteria. For the
SybrGreen assays each 25 μl reaction contained 2 μl
(= 10 ng DNA) of sample, 12.5 μl Sybr Premix Ex Taq
(2x), 0.5 μl of ROX reference Dye and either 300 nM
for the rpoD primers or 600 nM for the total Bacteria
primers. Premix Ex Taq (Takara Bio Inc., Otsu, Japan)
was used for the Pseudomonas and fungi TaqMan assays. For each TaqMan PCR reaction of 25 μl, 2 μl
sample was mixed with 23 μl of reaction mix containing
12.5 μl of Premix Ex Taq 2x, 0.5 μl of ROX reference
Dye, 100 nM FAM-labelled hydrolysis probe, and
600 nM for the Pseudomonas primers or 300 nM for
fungal primers.
In every 96-well plate, negative controls (water) and
a standard curve were included at least twice. In the
qPCRs for P. chlororaphis 4.4.1, Pseudomonas spp. and
total bacteria, the standard curves consisted of a freshly
prepared 10-fold serial dilution series of P. chlororaphis
4.4.1 DNA, prepared from a suspension with optical
density of 0.1 (≈8.0 log CFU ml−1). CFU number in
the original cell suspension was assessed by enumeration on R2A plates in duplicate. This calibration series
was used to transform resulting Cq (quantification cycle)
values to log CFU g−1 rhizosphere. For the total fungi
TaqMan assay, a freshly prepared 10-fold serial dilution
series with known amount of fungal DNA was included,
ranging from 5 to 0.00005 ng μl−1 of Fusarium nivale
DNA. This calibration series was used to transform
resulting Cq values to log fg DNA g−1 rhizosphere.
Since fungi consist of different propagules (spores and
mycelia) DNA concentrations cannot be transformed
97
Reference
Eur J Plant Pathol (2019) 154:91–107
�98
into CFU values. Standard curves for all qPCRs were
calculated with linear regression by plotting the Cq value
against the log CFU g−1 rhizosphere or log fg DNA g−1
rhizosphere for fungi.
All qPCRs were carried out in an Applied
Biosystems 7500 Real-Time PCR system (Applied
Biosystems) using the standard program, except for
PCRs with primer set for total bacteria where a lower
annealing temperature of 53 °C was used. For all
SybrGreen assays dissociation curves were included.
Statistical analysis
Analyses of variance (ANOVA) and regression analysis
were carried out with the statistical program GenStat
release 18.1 (Rothamsted Experimental Station,
Harpenden, UK). All plant experiments were carried
out in a randomized block design with four replications
(independent pots) per treatment. Microbial numbers
were analysed after logarithmic (10log(x)) transformation. Multi-factor analyses were performed with type of
amendment, P. chlororaphis inoculation and year as
factors. After ANOVA, least significant differences
(LSD) were calculated at a significance level of P =
0.05. The percentage of healthy plants in the Pythium
infected treatments was correlated with the qPCR detected P. chlororaphis populations in the rhizosphere
(log scale) by regression analysis for the different organic amendments.
Results
Seed germination
In the absence of P. aphanidermatum, on average 96,
98, 97 and 98% of the tomato seeds germinated and
remained healthy in the four independent experiments in
respectively 2012, 2013, 2014 and 2015. The bacterial
antagonist P. chlororaphis 4.4.1 did not significantly
improve or reduce germination in the absence of the
pathogen P. aphanidermatum. Also the applied dosages
of the organic amendments did not significantly influence germination of the seeds; except for two compost
batches in the 2014 experiment COSPBS and COSPBD
that seriously reduced seed germination, i.e. germination rates were 68 and 73% respectively. These composts were prepared from green waste with manure for
fertilizer purpose and appeared to be phytotoxic when
Eur J Plant Pathol (2019) 154:91–107
added in a 10% dosage to potting soil. Therefore, these
composts were not used in further experiments to evaluate the effect of amendments on Pythium control.
Pythium control by organic amendments
Inoculation with the pathogen P. aphanidermatum
resulted in significant losses of tomato plants during and after seed germination, due to respectively
pre- and post-emergence damping off. Only 43 to
68% of the tomato plants remained healthy in the
control treatments with unamended potting soil
when the pathogen was added in the experiments
of the different years, whereas the pathogen-free
treatments had 96 to 98% healthy plants.
The experiments in 2012 and 2013 did not show any
significant interaction between treatments and years,
allowing the presentation of average values of both
experiments (Fig. 1a). Potting soil amended with compost (CONL) resulted in a significantly greater number
of healthy plants (85%) compared to the non-amended
control potting soil (50%). Amendment with ABC
(without microbial inoculant) did not significantly increase the number of healthy plants as compared to the
control, or when added to the treatment with compost.
Results were based on one single dosage applied to the
potting soil, i.e. 10% compost and 1% ABC.
In the experiments 2014 and 2015, amendments
with compost (CONL), as well as animal-bone
char (ABC) and plant-based biochar (PBC) were
tested in the same dosage as before. Since there
was no significant interaction between these treatments and years, the average values of the two
experiments are presented (Fig. 1b). Again, CONL
significantly increased the number of healthy
plants, whereas ABC had no effect. The effect of
PBC was intermediate and not significantly different from the control.
Also several other types of compost were evaluated in 2014 and 2015, which all demonstrated
higher numbers of healthy plants compared to the
unamended potting soil, and equally or more
healthy plants than the CONL compost that was
used in all experiments (Fig. 2; for results of 2014
see SUPPLEMENTARY Fig. 1). Surprisingly, also
the sterilized CONL compost (CONL-st) enhanced
the number of healthy plants compared to the
control (Fig. 2).
�Eur J Plant Pathol (2019) 154:91–107
100
90
A
b
b
Healthy plants (%)
80
99
No
b
b
Pc
b
b
70
60
a
a
50
40
30
20
10
0
Control
ABC
CONL
CONL+ABC
Amendment
100
90
B
No
c
bc
Healthy plants (%)
80
70
ab
a
Control
ABC
60
abc abc
Pc
c
c
50
40
30
20
10
0
PBC
CONL
Amendment
Fig. 1 Healthy tomato plants in potting soil (Control) and potting
soil amended with animal-bone char (ABC), plant-based biochar
(PBC), compost (CONL) or a combination of compost with ABC
(CONL+ABC), 21 days after inoculation with Pythium
aphanidermatum. All treatments were without (No) or with (Pc)
Pseudomonas chlororaphis 4.4.1 inoculation. Upper fig. (a): average of experiments in 2012 and 2013 with a least significant
difference (LSD) of 16.5 at P = 0.05. Lower fig. (b): average of
experiments in 2014 and 2015 with LSD of 18.6 at P = 0.05. Bars
with different letters are significantly different. (N = 8)
Pythium control by bacterial antagonist P. chlororaphis
4.4.1
The antagonist P. chlororaphis was added in all experiments to each of the growing media. Different inoculation
strategies were tested. Comparison of P. chlororaphis
added as liquid formulation to potting soil or as solid
formulation within the ABC particles in the experiments
of 2012 and 2013 demonstrated that there was no difference in the effect due to the formulation (Fig. 1a); in both
treatments (Control and ABC) P. chlororaphis inoculation
resulted in approximately 80% healthy plants, compared to
50 and 56% healthy plants in the treatments without
P. chlororaphis. In the treatments with compost, where
the growing medium was already reducing the Pythium
symptoms, P. chlororaphis did not further elevate the
number of healthy plants; i.e. there was no additive effect
of the antagonist combined with compost amendment
(Fig. 1a).
Inoculation of P. chlororaphis as liquid formulation in
experiments 2014 and 2015 had similar results (Fig. 1b) as
the 2012 and 2013 experiments (Fig. 1a). Inoculation of
P. chlororaphis significantly increased the number of
healthy plants in de control potting soil as well as in the
potting soil amended with ABC. Number of healthy plants
were not further increased by inoculating P. chlororaphis
in the treatments with PBC or compost that were already
(partly) controlling the Pythium symptoms (Fig. 1b). Inoculation of P. chlororaphis to all other compost amendments had similar effects as the compost amendment itself
(Fig. 2 and SUPPLEMENTARY Fig. 1); i.e. there was no
additive effect of the antagonist combined with any type of
compost amendment.
In 2015, P. chlororaphis was also introduced through
seed treatment (Pc-seed). Although the antagonist inoculum dosage was very low (2.35 × 103 CFU seed−1),
significantly more healthy plants were present after seed
treatment with P. chlororaphis in the ABC and PBC
amended potting soil compared to the same growing
media without P. chlororaphis inoculation (Fig. 2).
The numbers of healthy plants in the control potting soil
were higher at a significance level of P = 0.10. In general, the seed treatment with P. chlororaphis was as
effective in controlling Pythium as the addition of the
antagonist to the growing media (Fig. 2).
Plant growth and nutrient uptake
The effect of the different organic amendments and
P. chlororaphis on plant biomass and nutrient uptake
by the tomato plants was measured in the experiments
2014 and 2015 using healthy plants in the absence of the
pathogen. There was no significant effect due to inoculation with P. chlororaphis compared to the noninoculated treatments, therefore average values of treatments with and without P. chlororaphis are presented in
Fig. 3. Dry weight of the plants (Fig. 3a) and total
nitrogen (N-total) (Fig. 3b) were similar for most of
the treatments. Only the compost treatment in 2014
had a higher level of N-total than the control potting
soil (Fig. 3b). However, there were important differences in P and K content of the plants. P levels in the
�100
Eur J Plant Pathol (2019) 154:91–107
110
100
No
Pc
Pc-seed
Healthy plants (%)
90
80
70
60
50
40
30
20
10
0
Control
ABC
PBC
CONL
CONL-st
COHU114 COHU214
COES3
Amendment
Fig. 2 Healthy tomato plants in potting soil (Control) and potting
soil amended with animal-bone char (ABC), plant-based biochar
(PBC), four different compost types (CO), and sterilized compost
(CONL-st) in 2015, 21 days after inoculation with Pythium
aphanidermatum. All treatments were without the antagonist
(No) or with the bacterial antagonist Pseudomonas chlororaphis
4.4.1 inoculated to soil (Pc) or seed (Pc-seed). Least significant
difference (LSD) is 17.8 at P = 0.05. Bars present mean values ±
standard deviation. (N = 4)
plants were twice as high in the treatments with ABC
and compost compared to the control (Fig. 3c). PBC
was intermediate, but results differed in both years. K
levels in the plants were increasing in the order: control,
ABC, PBC and compost (Fig. 3d).
other P. chlororaphis type strains DSM 19603, DSM
50083 and strain 1110–027, but not with the other
Pseudomonas species or the Burkholderia and
Lysobacter strains. The simultaneously tested rpoD
primer set for P. chlororaphis strain 30–84 (Wang
et al. 2012) reacted with the same strains as our rpoD
primer set, but also with P. corrugata type strain DSM
7228 and P. fluorescens strain 5 (Table 2).
In the qPCR tests, Cq values and estimated melting
temperatures (Tm) in dissociation curves were similar
for our target strain 4.4.1, DSM 6698, 10.2.5 and 11.4.2.
Similar Cq values and Tm slightly lower but within
−0.5 °C range were found for DSM 19603 and DSM
50083. For strain 1110–027, Cq values shifted up with
2 cycles and Tm was 1 °C lower. All other strains
showed negative reactions: Cq values increased 8 to
15 cycles and Tm dropped with −1.5 to −13 °C. As a
comparison, in negative water controls Cq values increased 16 to 17 cycles and Tm dropped with −13 °C.
For all performed qPCR assays, the slopes of standard curves were between of −3.1 and − 3.6, E values
were above 99% and all R2 values were above 0.99,
which is in the same range as recommended by Smith
and Osborn (2009) and Bustin et al. (2009). For our
rpoD primer set, qPCR standard curves with 300 nM
matched the above mentioned criteria, whereas standard
curves with 600 nM did not. Therefore, primer concentration of 300 nM was used in the rpoD qPCRs.
Although the developed qPCR system was quite
specific, a strictly strain specific detection of
Detection method for P. chlororaphis 4.4.1
The rpoD sequences of P. chlororaphis 4.4.1 were
found to be identical to the sequences of 10.2.5, 11.4.2
and the type strain DSM 6698 (NCBI accession numbers of rpoD sequences of the four strains are
MK574038, MK574039, MK574040 and MK574041,
respectively). The fragment size of 728 bp, representing
these four strains, was used for primer design with the
NCBI Primer-Blast tool (Ye et al. 2012). The designed
primers matched 100% to P. chlororaphis subsp.
aureofaciens strains LMG1245T and NCIMB 9030 entries in NCBI database (FN554453 and AB039554,
respectively) which are other collection numbers for
the type strain P. chlororaphis subsp. aureofaciens
DSM 6698. In the forward primer sequence, one mismatch was found with P. chlororaphis subsp.
aureofaciens 30–84 and LMG5832 and in both primers
for P. chlororaphis subsp. aureofaciens NCIMB 9265
(NCBI entries HE586461 and JN397563, AB039555,
respectively). PCR tests with this rpoD primer set resulted in strong single bands of the expected size with
the target strain 4.4.1, as well as the strains with identical
rpoD sequences DSM 6698, 10.2.5, 11.4.2, and the two
�Eur J Plant Pathol (2019) 154:91–107
101
0.6
4.0
A
b
b
b
a
2015
ab b
ab
C
b
0.4
0.3
2014
3.5
P (mg/plant)
Dry weight (g/plant)
0.5
2014
3.0
c
2.5
c
c
2.0
a
a
a
1.0
0.1
0.5
0.0
0.0
Control
ABC
PBC
CONL
Control
ABC
Amendment
6
CONL
25
B
2014
ab b
bc
ab
2015
D
c
b
a
a
5
4
3
2
2014
2015
e
e
20
K (mg/plant)
7
PBC
Amendment
8
N-total (mg/plant)
c
b
1.5
0.2
2015
d
15
c
b
b
10
a
a
5
1
0
0
Control
ABC
PBC
CONL
Amendment
Control
ABC
PBC
CONL
Amendment
Fig. 3 Plant biomass (dry weight) and nitrogen (N-total), phosphorous (P) and potassium (K) uptake by 25-day old tomato plants
in 2014 and 2015. Average data for treatments with and without
Pseudomonas chlororaphis 4.4.1 inoculation. Least significant
differences (LSD) at P = 0.05 are 0.69, 0.22, and 1.59 for respectively N-total, P, and K uptake, whereas dry weight did not
significantly differ between the treatments. Bars with different
letters are significantly different. (N = 8)
P. chlororaphis 4.4.1 based on rpoD sequences was not
feasible. The rpoD based qPCR targeted a subgroup of
P. chlororaphis, and results on presence of the inoculated strain should therefore be compared with noninoculated treatments to take background levels of naturally present P. chlororaphis strains into account.
that bacterial colonies (recognized by its yellowish-orange
colony pigmentation) were all along the roots (data not
shown). Quantitative detection of P. chlororaphis populations with qPCR demonstrated that P. chlororaphis could
establish in the rhizosphere up to 3 weeks after inoculation: all inoculated treatments had higher P. chlororaphis
values compared to the non-inoculated (No) treatments
(Pc-subgroup in Table 4). Average values of
P. chlororaphis after inoculation were above 104 cells
g−1 rhizosphere, and were 4 to 100 times higher than
without inoculation of the antagonist in the different years.
The final concentration of P. chlororaphis on the tomato
roots was similar in the different experiments, although the
inoculum density was 10 times higher in 2015 as compared to 2012 and 2013. The different organic amendments appeared to have no clear effect on the root
Rhizosphere colonization by P. chlororaphis and other
microbial populations
Healthy plants without Pythium inoculation of the greenhouse experiments in 2012, 2013 and 2015 were used to
evaluate the rhizosphere colonization in different amended
growing media, with and without P. chlororaphis inoculation. Qualitative tests in 2013, by making an imprint of
washed root system on nutrient medium, demonstrated
�102
Eur J Plant Pathol (2019) 154:91–107
Table 4 Microbial populations per g fresh root in the tomato rhizosphere, without (No), or with Pseudomonas chlororaphis 4.4.1 inoculated
to the growing medium (Pc) or to the seeds (Pc-seed); average values of the four growing media tested in the different years
Year
Pc-subgroup
Pseudomonas spp.
Bacteria
Fungi
Log cell g−1 root
Log cell g−1 root
Log cell g−1 root
Log fg DNA g−1 root
No
Pc a
Pc-seed b
No
Pc a
Pc-seed b
2012
3.43
4.95
ND
4.34
4.91
ND
LSD c
0.26
2013
3.72
LSD c
0.21
2015
2.76
LSD c
0.43
0.21
4.25
ND
4.45
3.56
3.90
Pc a
Pc-seed b
No
7.44
7.34
ND
3.63
(0.20) NS
4.52
ND
(0.19) NS
4.78
No
7.38
4.92
4.19
7.71
Pc-seed b
3.67
ND
(0.27) NS
7.44
ND
4.39
(0.11) NS
0.38
Pc a
4.76
ND
(0.16) NS
7.69
7.67
(0.07) NS
4.34
4.53
4.37
0.13
qPCR detection of P. chlororaphis subgroup (Pc-subgroup), Pseudomonas spp., total bacteria, and total fungi, expressed as 10 log cell
numbers or 10 log DNA weight
a
P. chlororaphis inoculum density was 106 cells g−1 growing medium (2012 and 2013) or 107 cells g−1 growing medium (2015)
b
Seed inoculation with P. chlororaphis 2.4 × 103 CFU seed−1 (2015); ND means not determined
c
Least significant difference (LSD) at P = 0.05 according to analysis of variance, NS means that there are no significant differences detected
with ANOVA. (N = 16)
colonization by P. chlororaphis (see SUPPLEMENTARY
Table 1 and 2 for the results of the individual treatments).
Inoculation of P. chlororaphis through seed treatment
resulted in an average of 4 × 103 cells g−1 rhizosphere,
which was 7 times higher than without inoculation
(Table 4). These lower population levels are probably
due to the rather low inoculum dosage used for seed
inoculation resulting in 2.4 × 103 cells seed−1 at the start
of the experiment.
Increase of the Pseudomonas spp. counts after inoculation with the biocontrol strain can be attributed to the
inoculation with P. chlororaphis 4.4.1. In general the Pseudomonas numbers surpassed the numbers of the Pc-subgroup, and in the treatments where P. chlororaphis 4.4.1
was inoculated, the share of Pc-subgroup in the Pseudomonas spp. numbers was higher (Table 4). Pseudomonas
populations in the rhizosphere of the non-inoculated treatments were in general lowest in the control potting soil
without organic amendment, but this was not a consistent
and significant difference (SUPPLEMENTARY Table 1
and 2 show the results of the individual treatments).
Total bacterial and total fungal numbers were not influenced by the inoculation with P. chlororaphis (Table 4).
Moreover, bacterial and fungal populations were not systematically influenced by the organic amendments. Only
in part of the compost treatments elevated numbers of
bacteria or fungi were present, but this was not consistent
(SUPPLEMENTARY Table 1 and 2).
Correlation between plant health and P. chlororaphis
populations
Taking all P. chlororaphis population measurements
and plant health results of the 2012, 2013 and 2015
experiments into account, there was no significant
correlation (correlation coefficient of 0.23). Therefore,
regression analysis was performed per type of growing
medium. In the unamended potting soil, addition of
P. chlororaphis resulted in higher populations of the
inoculated antagonist (qPCR detection of Pc-subgroup)
as well as in more healthy plants; a significant linear
correlation could be fitted with regression analysis.
The % of healthy plants corresponded with 29.2 +
10.2 x log value of the Pc-subgroup (variance
accounted for was 22.7%; standard error of observations was estimated to be 17.9). In the compost
amended potting soil, addition of P. chlororaphis also
resulted in higher populations of the inoculated antagonist (qPCR detection of Pc-subgroup), but there was
no increase of healthy plants. Consequently, there was
no significant linear correlation. Potting soil amended
with ABC followed the same trend as the unamended
potting soil. From the other growing media the number
of data were too few for proper regression analysis.
For visualization of the correlation between plant
health and P. chlororaphis populations see SUPPLEMENTARY Fig. 2.
�Eur J Plant Pathol (2019) 154:91–107
Discussion
Several types of compost and two biochars were mixed
with potting soil in four independent greenhouse experiments. Their efficacy on plant growth and plant health
was tested alone or in combination with a biocontrol
strain. Several of the organic amendments as well as the
biocontrol strain P. chlororaphis 4.4.1 repeatedly
protected young tomato plants against infection with
the plant pathogen P. aphanidermatum. The focus of
this research was on disease suppression, but in addition
the potential of the organic products for nutrient cycling
was assessed by measuring growth and nutrient uptake
by the young tomato plants.
Compost amended in a 10% dosage to the potting soil,
significantly reduced the number of infected tomato plants
in the presence of the pathogen P. aphanidermatum compared to unamended potting soil in all four experiments.
Surprisingly, all green-waste composts tested reduced
Pythium infection. Generally, the effect of compost on
suppression of plant pathogens is indicated to be dependent on their physical, chemical and biological characteristics (Termorshuizen et al. 2006; Avilés et al. 2011).
Several mechanisms of disease suppression by compost
are described. Microbial enrichment due to the compost is
generally mentioned to be involved (Avilés et al. 2011). In
our study, this mechanism is unlikely, since sterilized
compost was also effective in reducing the infection.
Moreover, the total number of bacteria and fungi as well
as the pseudomonas populations in the rhizosphere of
suppressive and non-suppressive treatments did not clearly
differ (qPCR detection). The fact that eight different types
of green-waste compost were all reducing disease incidence indicates that specific micro-organisms do not play
a role. Pythium spp. are described as highly sensitive to
nutrient competition and antibiosis, and most likely the
green-waste composts have induced an elevated microbial
activity contributing to general disease suppression (Avilés
et al. 2011). Also some other studies demonstrated such a
general suppressive effect of compost against Pythium spp.
when amended to peat-like growing media (Pane et al.
2011; Alfano et al. 2011; Vestberg et al. 2014).
Application of biochar in agricultural soils to improve soil quality and to enhance plant growth is a
relatively new development, and an increasing number of publications is available only from the last 15
to 20 years (Bonanomi et al. 2015; Glaser et al. 2002;
Jeffery et al. 2011). In our experiments we applied
two very distinct types of biochar in a 1% dosage to
103
potting soil, i.e. a plant-based biochar and a biochar
produced from animal by-products. These products
are very different in composition and are generally
applied for different purposes. Plant-based biochar
(PBC) is carbon-rich and aimed for soil improvement,
whereas animal bone char (ABC) is rich in calcium
phosphate and useful as P fertilizer. In the current
research we focussed on disease suppressive potential
of these products alone or in combination with a
biocontrol strain. The effect of PBC on disease suppression was intermediate to compost and the control
potting soil. ABC did not show any increase of
Pythium disease suppression in all four experiments.
Previous experiments showed little effect of ABC on
disease suppression of the soil-borne pathogens
Pythium and Fusarium when the material was used
without microbial additions (Postma et al. 2013).
Some studies demonstrated the potential of plantderived biochar types to reduce foliar diseases and
pests (Kumar et al. 2018; Meller Harel et al. 2012;
De Tender et al. 2016), as well as few soil-borne
plant pathogens (Jaiswal et al. 2017; Huang et al.
2015; Jaiswal et al. 2014). Often the mechanism
claimed is induced resistance (Bonanomi et al.
2015). However, disease suppressiveness is in general
crop- and pathogen-specific and studies with positive
effects of biochar on suppressiveness of Pythium spp.
have not been found (Dorais et al. 2016; Gravel et al.
2013). Also the applied concentration of biochar is
relevant. Higher dosages of biochar might be more
effective, but some studies demonstrate negative effects on disease suppression when e.g. 3% or more
biochar was applied (Frenkel et al. 2017).
A complementary strategy to enhance disease suppression is to add biocontrol organisms. Here we applied
the strain P. chlororaphis 4.4.1 that controlled Pythium
as well as Fusarium in a previous study when it was
applied with ABC as a carrier (Postma et al. 2013). The
biocontrol strain was inoculated with different procedures into the different potting soil mixtures. The strain
consequently protected young tomato plants against
P. aphanidermatum infection in the control potting soil.
It also significantly enhanced suppressiveness of the
potting soil that was amended with 1% ABC. However,
when the compost amendment increased suppressiveness of the potting soil mixture, the biocontrol strain did
not result in elevated numbers of healthy plants; i.e.
there was no additive effect when combining the biocontrol strain P. chlororaphis with compost.
�104
Efficacy of the biocontrol strain was independent from
the inoculation procedure. Adding P. chlororaphis as
liquid formulation to the growing medium, as well as
seed inoculation were effective. Interestingly,
P. chlororaphis could also be applied as a solid formulation with ABC as a carrier.
Seed inoculation is a good strategy to overcome the
limitations of short shelf-life of non-spore forming bacteria. The applied seed inoculation procedure resulted in
rather low numbers of P. chlororaphis, i.e. 2.4 × 103 cells
seed−1. Nevertheless, protection of tomato plants against
Pythium symptoms was significant. Studies on inoculating
oil seed rape seeds with P. chlororaphis MA 342 demonstrated that time and inoculum concentration both influenced the bacterial concentration on the seeds (Abuamsha
et al. 2011). Since treatment time of tomato seeds had to be
shorter for proper seed germination than for oil seed rape
(30 min instead of 4 h), higher cell densities in the inoculum suspension are advised to further optimize the inoculation procedure for tomato seeds.
Survival and root colonization of biocontrol organisms is a key factor for efficacy (Lugtenberg and
Kamilova 2009). The imprint of the washed root
system on nutrient medium demonstrated that colonies of the inoculated strain were along the entire root
system. This confirms the root colonizing capacity of
P. chlororaphis 4.4.1 which was demonstrated previously by plate counts using an antibiotic resistant
mutant (Postma et al. 2013). However, a molecular
detection method is more appropriate for quantitative
detection of the wild type strain in the rhizosphere of
different growing media. Therefore, a primer set was
developed based on the rpoD protein-coding gene,
which shows proper discrimination in the Pseudomonas genus (Mulet et al. 2010) and is present as single
copy allowing quantitative detection (Mulet et al.
2009). P. chlororaphis was detected at low levels as
a background in the treatments that were not inoculated with our strain, since the designed primer set
targets a subgroup of P. chlororaphis. However, when
P. chlororaphis 4.4.1 was inoculated numbers were
significantly higher, indicating the usefulness of the
rpoD primer set for the quantitative detection of
P. chlororaphis 4.4.1. The root colonizing capacity
of P. chlororaphis 4.4.1 was confirmed once more
with this novel qPCR method, i.e. P. chlororaphis
populations in the rhizosphere were 4 to 100 fold
higher 3 weeks after the biocontrol strain was inoculated to soil or seeds as compared to non-inoculated
Eur J Plant Pathol (2019) 154:91–107
treatments. The strain colonized the roots even when
it was inoculated locally (on seeds) at a low dosage
(2.4 × 103 cells seed−1).
Compost and biochar are generally applied for their
fertilizer effect (Abbott et al. 2018). In our study we
used fertilized potting soil to avoid interactions with
disease infection while testing the disease suppressive
effects, thus nutrients were not a limiting factor during
tomato growth up to 3 weeks. As a result, plant growth
(expressed as dry weight) of the healthy plants without
Pythium inoculation was similar for all treatments. Nevertheless, nutrient uptake by the tomato plants was influenced by the organic amendments. Potassium (K)
levels in the plant increased most distinct by the compost amendment, followed by PBC and ABC amendments. Phosphorous (P) levels increased by compost
and ABC, and to a lesser extent by PBC. Here we should
remark that the compost dosage was 10 times higher
than the applied dosage of ABC and PBC. Since the
global reserves of economically recoverable P will be
depleted when increasing amounts of mineral P are used
(Cordell et al. 2009), combined with the fact that mineral P is containing cadmium and uranium (Schnug and
Lottermoser 2013), recycling P-rich organic materials is
of great importance. ABC can be considered as a safe P
fertilizer due to its purity and practically absence of
contaminants (Someus and Pugliese 2018). The uptake
of P was not improved by inoculating P. chlororaphis,
although this strain was selected for its P-solubilising
capacity (Postma et al. 2010). P availability of ABC
depends on soil acidity (Warren et al. 2009) and the
product formulation (Someus and Pugliese 2018). Since
potting soil has a pH 5.2 and tomato roots exudate
organic acids (Kamilova et al. 2006), the inoculated
P. chlororaphis probably had no additional effect on P
solubilisation under these conditions. To evaluate the
fertilizer effect of the different organic amendments,
nutrient poor soils or growing media in combination
with longer growing periods of the crops must be tested,
preferably under realistic growing conditions.
Our results demonstrate the potential of the assessed
organic amendments to enhance sustainability of growing media by (i) increasing disease suppressiveness of
the growing medium, (ii) re-use of nutrients present in
the applied organic products, as well as (iii) to replace
part of the peat by other organic materials. In addition,
inoculating seed or growing medium with the biocontrol
strain P. chlororaphis enhanced Pythium control in the
susceptible growing media.
�Eur J Plant Pathol (2019) 154:91–107
The evaluated products have very different characteristics, and are targeted for different purposes. The
challenge in designing more sustainable systems is the
proper application and combination of these products.
A l t h o u g h i n o c u l a t i n g t h e b i o c o nt r o l s t r a i n
P. chlororaphis into growing medium that became suppressive by compost amendment did not further enhance
Pythium suppressiveness, such a combination can improve the robustness of the system, when the biocontrol
strain is effective against other diseases as well. ABC
with its high P content is a suitable organic fertilizer,
meanwhile due to its porous structure it is an interesting
carrier for micro-organisms. Enrichment with the biocontrol bacterium demonstrated that the product will
become suppressive to plant diseases. PBC being a
carbon rich product, is a soil improver with water and
nutrient retention capacity. Due to its slow degradability,
it can also be used in growing media to replace peat. In
all cases, the recycled organic products should be
targeted for agricultural purposes and meet all safety
criteria.
Acknowledgements The research was financially supported by
the 7th Framework of the European Commission, grant agreement
no. 289785 (REFERTIL, http://www.refertil.info). We thank
Edward Someus and Massimo Pugliese for coordinating and
organising the organic products. Compost and biochar products
were kindly supplied by Van Iersel, Proficomp, BGU, Pyreg and
Terra Humana. We gratefully acknowledge the chemical analyses
performed by Wessling Hungary Kft. and technical support at the
experiments by Mirjam T. Schilders and Hanneke A.G. Elema.
Funding This study was funded by 7th Framework of the European Commission (grant agreement no. 289785).
Compliance with ethical standards This article does not contain any study with human participants or animals performed by
the authors.
Conflict of interest The authors declare that they have no conflict of interest.
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 unrestricted 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.
105
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