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Author(s): Leena Hamberg, Timo Saksa & Jarkko Hantula 

Title: Role and function of Chondrostereum purpureum in biocontrol of trees 

Year: 2020 

Version: Published version 

Copyright:  The Author(s) 2020 

Rights: CC BY 4.0 

Rights url: http://creativecommons.org/licenses/by/4.0/ 

Please cite the original version: 

Hamberg, L., Saksa, T. & Hantula, J. Role and function of Chondrostereum purpureum in 
biocontrol of trees. Appl Microbiol Biotechnol 105, 431–440 (2021). https://doi.org/10.1007/
s00253-020-11053-5



MINI-REVIEW

Role and function of Chondrostereum purpureum
in biocontrol of trees

Leena Hamberg1
& Timo Saksa2 & Jarkko Hantula1

Received: 6 November 2020 /Revised: 6 November 2020 /Accepted: 9 December 2020
# The Author(s) 2020

Abstract
A decay fungus,Chondrostereum purpureum (Pers. Ex Fr.) Pouzar, has been investigated in Europe, Northern America and New
Zealand for its ability to decay hardwood stumps and thus prevent sprouting. The aim of these investigations has been to find an
alternative to mechanical (cutting only) and chemical sprout control (cutting and applying chemicals to stumps in order to prevent
sprouting). Mechanical sprout control is not an efficient option due to hardwood tree species’ ability to re-sprout efficiently after
cutting, and therefore management costs are high. Chemicals would be efficient but due to their harmful effects on the environ-
ment, alternatives are needed. The fungal treatment, i.e., cutting accompanied withC. purpureum inoculum is an environmentally
friendly and efficient option for sprout control. This mini-review comprises the role and function of C. purpureum in biocontrol
of trees: the ecology of C. purpureum, its sprout control efficacy, factors affecting sprout control efficacy, devices in biological
sprout control, potential risks, and the future perspectives of biological sprout control.

Key points
• A fungus Chondrostereum purpureum is efficient in preventing sprouting of hardwoods
• C. purpureum is not sensitive to environmental conditions
• Devices should be developed for cost-efficient biological sprout control

Keywords Forestry . Sprout control . Decay fungus . Stumpmortality

Introduction

Microorganisms such as fungi and bacteria, or the compounds
that they produce, have potential as biological control agents
in preventing the growth of harmful pests and diseases as
described in many mini-reviews (Keswani et al. 2019;
Memariani and Memariani 2020; Mukherjee et al. 2020;
Tong and Feng 2020; Torracchi et al. 2020). Furthermore, this
approach could also be utilized in restricting the growth of
unwanted hardwood tree species (de Jong 2000; Wall 1990),
for example in forest management, under electric power lines,

above gas pipelines and next to roads and railways (de la
Bastide et al. 2002; Hamberg et al. 2015).

In forestry, specific tree species are cultivated to produce
timber and biomass for industry. Usually, the desired tree
saplings must compete with naturally grown tree species for
growing space, solar radiation, water and nutrients, and there-
fore, unwanted saplings are removed to promote the growth of
more valuable cultivated trees (Huuskonen and Hynynen
2006; Huuskonen et al. 2020; Wagner et al. 2006).
However, unwanted trees are often hardwoods that can sprout
efficiently from stumps (Becker et al. 2005; Hamberg et al.
2020; Jobidon 1998; Lygis et al. 2012; Mallik et al. 2002;
Wall 1990), and therefore additional pre-commercial thinning
(PCT) operations are usually needed (Äijälä et al. 2019;
Thiffault and Roy 2011).

Since hardwood thickets often need to be removed repeat-
edly, the cost of sprout control increases considerably (de la
Bastide et al. 2002). An efficient option to control excessive
growth of hardwood thickets would be chemicals (Bellgard
et al. 2014; Harper et al. 1999; Lygis et al. 2012; Pitt et al.

* Leena Hamberg
leena.hamberg@luke.fi

1 Natural Resources Institute Finland, P.O. Box 2, (Latokartanonkaari
9), FI-00790 Helsinki, Finland

2 Natural Resources Institute Finland, Juntintie 154,
FI-77600 Suonenjoki, Finland

https://doi.org/10.1007/s00253-020-11053-5

/ Published online: 19 December 2020

Applied Microbiology and Biotechnology (2021) 105:431–440

http://crossmark.crossref.org/dialog/?doi=10.1007/s00253-020-11053-5&domain=pdf
https://orcid.org/0000-0002-0009-7768
mailto:leena.hamberg@luke.fi


1999) but public concern and the harmful effects of chemicals
on the environment have restricted their use (de la Bastide
et al. 2002; Bellgard et al. 2014; Benachour and Séralini
2009; Mallik et al. 2002; Dumas et al. 1997; Graymore et al.
2001; Lygis et al. 2012; Thiffault and Roy 2011;
Vandenbroucke et al. 2005; Wagner 1993; Wagner et al.
2006; Wall 1990).

An environmentally friendly option to prevent hardwood
sprouting is a decay fungus, Chondrostereum purpureum
(Pers. Ex Fr.) Pouzar, that can be utilized as a biological con-
trol agent due to its efficient ability at preventing sprouting,
potentially even as efficiently as chemicals (Becker et al.
2005; Bellgard et al. 2014; Harper et al. 1999; Jobidon
1998; Lygis et al. 2012). Consequently, the use of this fungal
species as a biocontrol agent against weed hardwoods has
been investigated in the Netherlands, Belgium, Lithuania,
Finland, Canada, and New Zealand (Becker et al. 2005;
Bellgard et al. 2014; de Jong 2000; Dumas et al. 1997;
Hamberg et al. 2015, 2018, 2020; Lygis et al. 2012; Roy
et al. 2010; Spiers and Hopcroft 1988; van den Meersschaut
and Lust 1997; Vartiamäki et al. 2008a). In this mini-review,
the role and function of C. purpureum in biocontrol of trees is
described.

Ecology of a decay fungus Chondrostereum
purpureum

C. purpureum is a saprophytic or a weakly pathogenic pioneer
species invading mainly stumps, branches, and trunks of de-
ciduous tree species, but it is sometimes detected also in co-
nifers as a saprophyte (Etheridge and Morin 1963; Gosselin
et al. 1995; Ramsfield et al. 1996). The basidiocarps of this

fungus are purple and often found on stumps and dead wood
remains of broadleaved trees (Fig. 1). The fungus can also
cause silver leaf disease in fruit trees (Percival 1902).

As a typical basidiomycete, the spore release of
C. purpureum depends on high humidity (Spiers and
Hopcroft 1988). It is capable of infecting trees only through
open vessels in fresh wounds in branches, stems, or roots
(Becker et al. 2005; Brooks and Moore 1923; Butler and
Jones 1949; de Jong 2000; Erikson and Ryvarden 1973;
Gosselin et al. 1999; Hamberg et al. 2017). The fungus grows
through xylem tissues of the host plant and blocks vessels,
causes cambial necrosis, decay, sapwood staining, and often
death of the host (Rayner 1977; Wall 1986, 1991). The mech-
anism of its action is not fully understood, but it is associated
with toxic polygalacturonases and laccases, as well as lignin-
and manganese peroxidase activities (Miyairi et al. 1977; ten
Have and Teunissen 2001; Vartiamäki et al. 2008a).

C. purpureum occurs commonly in boreal and temperate
vegetation zones and is also present in New Zealand as an
introduced species (Ramsfield et al. 1996). The populations
between Europe and North America belong to the same bio-
logical species, but molecular markers show certain levels of
differentiation between the continents, while intracontinental
population differences are small (Becker et al. 2004, 2005;
Gosselin et al. 1996, 1999; Hamberg et al. 2018; Ramsfield
et al. 1996, 1999; Vartiamäki et al. 2008b).

Sprout control efficacy

The sprout control efficacy of C. purpureum is based on its
efficiency in disrupting the physiology of a treated tree and
finally killing it. In biological sprout control, hardwood trees

Fig. 1 a Fruiting bodies of a
decay fungus Chondrostereum
purpureum in birch (Betula
pendula Roth and B. pubescens
Ehrh.), and stump sprouts killed
by the fungus. b The basidiocarps
of this fungus are purple.
Photographs: Leena Hamberg

432 Appl Microbiol Biotechnol (2021) 105:431–440



are cut and an inoculum medium—containing the hyphae of
C. purpureum diluted with water or formulated as a gel-based
paste—is spread or laid immediately on freshly cut stump
surfaces (Bellgard et al. 2014; de Jong 2000; Hamberg et al.
2015).When inoculummedium is spread on freshly cut stump
surfaces, C. purpureum gains an advantage over other natu-
rally occurring decay fungi (Brooks and Moore 1926), pene-
trates the stumps, starts to decay wood, and finally kills the

host when living tissues have been killed and decayed suffi-
ciently (Hamberg et al. 2017). Decaying wood is a biological
process and therefore treated stumps are not killed immediate-
ly. Depending on the ability of a fungal strain to decay wood
and the resistance of a host tree, stump mortality begins ca.
2 months later and continues for up to at least 4 years after the
treatment (Hamberg et al. 2014, 2015, 2017; Lygis et al. 2012,
Table 1).

Table 1 Stump mortalities after the Chondrostereum purpureum
treatments and control (cutting only or cutting only with inoculum
medium without fungal hyphae) in different hardwood species. Values

for the best fungal strain or for optimal application time are provided in
case several strains or application times were investigated. Stump mean
diameter and/or diameter range has been provided when available

Tree species Scientific name Stump diameter
(cm)

Stump mortality (%) Reference

Fungal
treatment

Control

Box elder Acer negundo 3.5 (1–12) 95b 33 Lygis et al. 2012

Gray alder Alnus incana 3.5 (1–12) 65b 41 Lygis et al. 2012

8.3 (0.6–24.3) 91b 43 Hamberg and Hantula 2018

Red alder Alnus rubra 5–10 100b 86 Becker et al. 2005

Sitka alder Alnus viridis ssp. sinuata 2.2 90c! 11 Harper et al. 1999

Paper birch Betula papyrifera 5.4 99c 56 Jobidon 1998

Silver birch Betula pendula 3.5 (1–12) 100b 20 Lygis et al. 2012

Silver and downy birch Betula pendula and B. pubescens 3.5 92b 57 Vartiamäki et al. 2008a

3.0 (2.1–4.4) 96c 60 Vartiamäki et al. 2009a

1.1 78c 9 Hamberg et al. 2015

1.4 86c 17 Hamberg et al. 2020

11.2 (1.0–30.8) 97b 56 Hamberg and Hantula 2018

Largetooth and trembling
aspen

Populus grandidentata and
P. tremuloides

5–60 37a-b 12 Dumas et al. 1997

Poplar Populus euramericana 40–60 100b 15 de Jong 2000

European aspen Populus tremula 1.9 77d 52 Hamberg et al. 2014

1.2 78c 47 Hamberg and Hantula 2016

3.5 (1–12) 100b 75 Lygis et al. 2012

Trembling aspen Populus tremuloides – 84c 31 Harper et al. 1999

Black cherry Prunus serotina – 95b – de Jong 2000

2–6 99b 53 Scheepens and Hoogerbrugge
1989

– 91b 44 van den Meersschaut and Lust
1997

Pin cherry Prunus pensylvanica 4.6 86c 35 Jobidon 1998

Black locust Robinia pseudoacacia 3.5 (1–12) 7b 2 Lygis et al. 2012

Goat willow Salix caprea 3.5 (1–12) 57b 23 Lygis et al. 2012

Rowan Sorbus aucuparia 1.8 50d 14 Hamberg et al. 2014

Gorse Ulex europaeus 1.1 (0.6–1.8) 66!! 50!! Bourdôt et al. 2006

a Sprout control efficacy measured one growing season after the treatments
b Sprout control efficacy measured two growing seasons after the treatments
c Sprout control efficacy measured three growing seasons after the treatments
d Sprout control efficacy measured four growing seasons after the treatments
! Clump mortality
!!Mean values provided for different application times

433Appl Microbiol Biotechnol (2021) 105:431–440



The efficacy of different fungal strains of C. purpureum to
kill treated stumps varies, with some strains more efficiently
preventing sprouting than others (Bellgard et al. 2014;
Hamberg and Hantula 2016; Hamberg et al. 2015; Harper
et al. 1999; Jobidon 1998; Lygis et al. 2012; Pitt et al. 1999;
Scheepens and Hoogerbrugge 1989; Vartiamäki et al. 2008a;
Wall et al. 1996). The efficacy of different strains has been
tested in laboratory conditions using different approaches.
C. purpureum hyphae have been laid on Petri plates including
wood tissue cultures or on tree cuttings, and the effect of a strain
on tissue or cutting mortality then investigated (Bellgard et al.
2014; Eckramoddoulah et al. 1993; Spiers et al. 1998, 2000;
Wall et al. 1996). In the laboratory, the laccase and manganese
peroxidase enzyme production of a C. purpureum strain has
been shown to correlate with its sprout control efficacy in the
field, and therefore enzyme tests have been used in screening
potential fungal strains (Hamberg et al. 2015; Vartiamäki et al.
2008a). Also, a short-term breeding process has been utilized to
crossbreed efficient fungal strains (Hamberg et al. 2015).
Pairing of mycelia for breeding is easy to perform in the labo-
ratory. Two homokaryotic hyphae—both originating from a
single spore of C. purpureum—are laid on the same growth
substrate on a Petri plate, and when hypha meet on a plate they
can form a new heterokaryoticC. purpureum strain, similarly as
it happens on wood in nature (Butler and Jones 1949; Hamberg
et al. 2015; Spiers et al. 2000; Wall et al. 1996). Thereafter, the
best strain for biological control can be selected based on the
efficacy of new strains in decaying stumps and killing host trees
in field investigations or, e.g., efficacy-associated enzymatic
activities (Hamberg et al. 2015).

Since the 1980s, the efficacy of different C. purpureum
strains as biological control agents has been tested in several
different hardwood trees (Hamberg and Hantula 2018;
Hamberg et al. 2015; Lygis et al. 2012; Scheepens and
Hoogerbrugge 1989; Vartiamäki et al. 2008a; Wall 1990,
Table 1). C. purpureum has been especially efficient in con-
trolling sprouting of birch (Betula papyrifera Marsh.,
B. pendula, B. pubescens), alder (Alnus incana (L.) Moench,
A. rubra Bong.), box elder (Acer negundo L., 1753), and
cherry species (Prunus serotina Ehrh., P. pensylvanica L.
fil.) with stump mortalities of 80–100% after the treatment
(Becker et al. 2005; Hamberg and Hantula 2018; Hamberg
et al. 2015, 2020; Jobidon 1998; Lygis et al. 2012;
Scheepens and Hoogerbrugge 1989), but promising results
have been achieved also for aspen (Populus tremula L.,
P. tremuloides Michx.) (Hamberg and Hantula 2016;
Hamberg et al. 2014; Harper et al. 1999; Lygis et al. 2012).
Efficacy has been lower in rowan (Sorbus aucuparia L.), goat
willow (Salix caprea L.), and black locust (Robinia
pseudoacacia L.) with stump mortalities less than 60%
(Hamberg et al. 2014; Lygis et al. 2012).

Although C. purpureum does not always kill its host, it
may affect the number and height of living sprouts.

Reduction in the number of stump sprouts or delay in the
development of stump sprouts after the C. purpureum treat-
ment, compared to control (cutting only), has been observed
in birch (Betula pendula and B. pubescens) (Hamberg et al.
2015; Vartiamäki et al. 2009a). The height of living sprouts
has been considerably lower after the C. purpureum treatment
than cutting only, e.g., in birch (Betula pendula and
B. pubescens), rowan (Sorbus aucuparia), and European as-
pen (Populus tremula) but also in other hardwoods (Hamberg
n.d.; Hamberg et al. 2014; Vandenbroucke et al. 2005;
Vartiamäki et al. 2008a). Height reduction is promising in
terms of forest management, as desired tree species can more
easily gain an advantage over unwanted hardwoods.

Some hardwood species, such as rowan (Sorbus
aucuparia), aspen (Populus tremula, P. tremuloides),
and gray alder (Alnus incana), also produce root suckers
that increase the number of competing saplings around
cultivated trees (Hamberg and Hantula 2018; Harper
et al. 1999; Worrell 1995; Zerbe 2001). Rowan, aspen
and gray alder are capable of allocating resources to root
sucker production especially if stump sprouting is restrict-
ed due to fungal treatment with C. purpureum (Hamberg
and Hantula 2018; Hamberg et al. 2011, 2014), and there-
fore with these tree species, sprout control is more diffi-
cult at the stand level (see e.g., Harper et al. 1999; Lygis
et al. 2012). Currently, no long-term investigations have
been performed to show how far the fungus can penetrate
along underground stems and roots and for how long the
treated stumps can produce root suckers after stumps have
been decayed. However, living, aboveground stems be-
longing to the same clone as a treated stump can support
suffering parts within the clone (Hamberg and Hantula
2016; Hamberg et al. 2014). Thus, cutting and applying
C. purpureum inoculum for all unwanted saplings poten-
tially belonging to the same clone is recommended in
order to increase biocontrol success.

Factors affecting sprout control efficacy

Host tree

The ability of C. purpureum to infect different tree species and
saplings varies greatly due to the ability of a tree to resist fungal
infection (see above), and the physiological state of a tree
(Hamberg n.d.; Heide 2011; Stanislawek et al. 1987;
Vartiamäki et al. 2009a; Wall 1990). Some evidence has been
found that themost severe effects of the fungus take place when
the amount of soluble carbohydrates is highest in wood, i.e.,
when a tree is growing intensively (Brooks and Moore 1926;
Butler and Jones 1949; Lygis et al. 2012; Stanislawek et al.
1987). Thus, an important component in terms of sprout control
efficacy is timing, i.e., applying fungal inoculum when the re-
sistance of trees against C. purpureum is lowest.

434 Appl Microbiol Biotechnol (2021) 105:431–440



Seasonal effects on the sprout control efficacy of
C. purpureum have been found in several tree species. In birch
(Betula pendula and B. pubescens), the sprout control efficacy
of C. purpureum is good when the treatment is performed in
spring or summer but it seems to decrease towards the end of
the growing season (Hamberg et al. 2015, 2017; Laine et al.
2020a; Vartiamäki et al. 2009a). The reason for decreasing
efficacy towards the end of a growing season is not fully
understood. In several tree species, summer treatments have
resulted in higher stump mortalities than those of autumn
treatments (pooled data from Betula pendula, Alnus incana,
Populus tremula, Salix caprea and Acer negundo in Lygis
et al. 2012). In Prunus and Salix, susceptibility to
C. purpureum is greatest in spring and early summer, and least
in winter (Spiers et al. 1998). In Prunus serotina Ehrh., both
spring and autumn were equally suitable for C. purpureum
infection (Scheepens and Hoogerbrugge 1989). In rowan
(Sorbus aucuparia), sprout control efficacy is highest in sum-
mer while in spring and autumn, it is clearly lower (Hamberg
n.d.; Hamberg et al. 2017), probably because at that time most
of the resources are in underground stems and roots (Heide
2011; Millard 1996; Millard et al. 2001), and thus available
after cutting for regrowth and defending against fungal infec-
tion. This effect is largely regulated by temperature (Heide
2011). In aspen (Populus tremula), the fungal treatment has
been successful early in spring (Hamberg and Hantula 2016),
possibly because at that time carbohydrates are transported
from underground parts to shoots (Johansson 1993).
However, the amounts of defensive compounds in wood
may also regulate the success of C. purpureum treatment dur-
ing a growing season (Palo 1984).

Increasing stump diameter has been associated with in-
creasing stump mortality after C. purpureum treatment
(Salmi 2017). In a large stump, there is more space for a higher
number of fungal fragments to colonize it and cause stump
decay, leading to mortality sooner than in smaller stumps.
When birch (Betula pendula and B. pubescens) saplings
0.5–6.0 cm in stump diameter were cut and treated with
C. purpureum inoculum, larger stumps died faster than small-
er stumps (Hamberg and Hantula 2020; Hamberg et al. 2020).
However, when the diameter of experimentally treated stumps
ranged from 0.6 to 30.0 cm, the results showed that the
smallest and largest stumps were most susceptible to the fun-
gal treatment, with trees ca. 13 cm in stump diameter being the
most resistant, whereas in gray alder (Alnus incana), all
stumps irrespective of stump diameter were prone to the treat-
ment (Hamberg and Hantula 2018). After the second growing
season, almost all treated stumps had died and no effect of
basal diameter could be observed.

Wound susceptibility to C. purpureum infection decreases
clearly with time (Brooks and Moore 1926; Spiers and
Hopcroft 1988), and therefore fungal inoculum should be
spread to stump surfaces immediately after a sapling has been

cut. Even a 15–30min delay between cutting and spreading of
fungal inoculum decreases the sprout control efficacy of
C. purpureum (Hamberg and Hantula 2020). Delay in spread-
ing especially affects the treatment efficacy on stumps with
small diameters. Observations in the field have shown that
immediately after cutting, the fungal inoculum will be sucked
into a stump but after a delay, it stays as a drop on the stump
surface, probably due to the closing of the vessels.

Site-specific factors

After C. purpureum treatment, some site-specific effects on
tree mortality have been observed (Hamberg et al. 2017; Pitt
et al. 1999). Increasing soil moisture levels have been associ-
ated with an increase in stump mortality rates of birch (Betula
pendula and B. pubescens), but this effect disappeared during
the second growing season following stump treatment
(Hamberg and Hantula 2020). Growing space affects the abil-
ity ofC. purpureum to kill inoculated stumps. Both increasing
volume of standing trees (> 5 cm in diameter at breast height)
and the number of other saplings around a treated stump in-
crease stump mortality (Hamberg et al. 2014, 2015).
However, in clonal species, such as European aspen
(Populus tremula), conspecific mature trees around an inves-
tigated stump—possibly belonging to the same clone—can
provide support for stumps treated with C. purpureum
(Hamberg and Hantula 2016).

Weather

Weather conditions affect Chondrostereum purpureum, al-
though these effects are often temporal and milder than those
of a host tree. In laboratory investigations, the optimum
growth temperature for C. purpureum is 24–25 °C but the
growth is severely inhibited at near zero and in temperatures
over 35 °C (Eckramoddoulah et al. 1993; Hamberg and
Hantula 2020; Spiers and Hopcroft 1988; Spiers et al. 2000;
Stanislawek et al. 1987;Wall 1986). However, in the field, the
mycelium can survive during winter, although its growth is
limited due to low temperatures and low soluble carbohydrate
concentration in the wood (Butler and Jones 1949; Scheepens
and Hoogerbrugge 1989), and C. purpureum is able to with-
stand high temperatures (even 30–40 °C) in the field (Dumas
et al. 1997; Hamberg and Hantula 2020). High temperatures
may initially delay the sprout control efficacy of
C. purpureum (i.e., the growth of mycelia within a stump)
but two growing seasons after the fungal treatment, this effect
on stump mortality is no longer observed (Hamberg and
Hantula 2020).

Wood moisture content is an important factor determining
decay (Boddy and Rayner 1983), and therefore C. purpureum
benefits from optimal moisture conditions (Hamberg and
Hantula 2020). If moisture content is high in living wood, it

435Appl Microbiol Biotechnol (2021) 105:431–440



can limit fungal infection, but water shortage as a stress factor
may make trees prone to infection (Boddy and Rayner 1983;
Hamberg and Hantula 2020; Pitt et al. 1999). Thus, low pre-
cipitation before the C. purpureum treatment helps the fungus
to penetrate the wood of a host suffering from water stress,
while an increase in precipitation after the treatment provides
suitable moisture conditions for the fungus to invade deeper
into the wood (Hamberg and Hantula 2020). C. purpureum is
not sensitive to heavy rains during stump treatments, although
fungal inoculum may be easily washed from stump surfaces
(Hamberg et al. 2020). In birch (Betula pendula and
B. pubescens), rain showers may initially delay the sprout
control efficacy of C. purpureum but three growing seasons
after the fungal treatment, stump mortality is as high for
stumps treated in a rainstorm as in sunny weather (Hamberg
et al. 2020).

Devices in biological sprout control

Most biological sprout control experiments have been per-
formed by spraying or spreading C. purpureum inoculum on
freshly cut stumps manually after a cutting operation (e.g.,
Hamberg et al. 2014; Roy et al. 2010). In practical forestry,
pre-commercial thinning (PCT) is done with clearing saws or,
in a small proportion, with fully mechanized devices fitted on
forest machines. In these practical solutions, the spreading of
the biocontrol agent should be done simultaneously with the
cutting operation. Additionally, in mechanized PCT-work, the
weight of inoculummediumwhich must be carried in the field
is less of an obstacle as in motor-manual work.

In recent years, some practical scale experiments for
spreading inoculum with clearing saws and devices installed
on forest machines have been conducted (Laine et al. 2019,
2020a, b). In motor-manual work, different kinds of nozzle
solutions connected to clearing saw blades have been tested
(Laine et al. 2020b), and in mechanized PCT-work, a UW40-
cleaning head installed on a Tehojätkä mini-harvester
(Usewood Forest Tec LTD) and Mense cutting head installed
on a normal harvester have been tested (Laine et al. 2019,
2020a). According to these studies, the efficacy of the biolog-
ical control was not as high as in manual application experi-
ments. In these practical scale experiments, ca. 20–40% of
birch stumps died after the fungal treatment. The lack of reli-
ability and accuracy of spreading mechanisms in both motor-
manual and mechanized devices were the main reasons for
low success rates (Laine et al. 2019, 2020b). In some cases,
the stumps were also too tall after mechanized PCT-work, and
therefore they continued to grow from branches.

The consumption of inoculum has been high with all stud-
ied devices (Laine et al. 2020b). In future, the accuracy of
spreading mechanisms should be improved in order to get
the consumption of inoculum on an economically sound level.
The advantage of the motor-manual and mechanized methods

over the manual application methods is the immediate treat-
ment after cutting, which improves the ability of the fungus to
infect a stump. In practice, motor-manual and mechanized
methods are the only economically feasible solutions.
Biological sprout control provides good possibilities for in-
creasing the cost-efficiency of PCT-work by decreasing the
number of cases when two-phase PCT-work is needed.

Potential risks

Intentional spreading of pathogenic organisms is always dan-
gerous, and therefore risk analyses should be conducted care-
fully prior to such actions on a wide scale (e.g., Hantula et al.
2012). Considering the biocontrol use of C. purpureum, the
first problem might be the infection of nontarget trees due to
the increased production of basidiospores. This possibility
was studied in North America by Wall (1991) and in Europe
by de Jong et al. (1990a, b) and Vartiamäki et al. (2009b). All
these studies suggested that the risk is small, and even the
assumption of considerably increased spore load compared
to natural levels may be incorrect (de Jong et al. 1996).
However, it may be possible that in favorable environmental
conditions, control agents could infect freshly wounded non-
target trees, although a long distance spread of spores has been
shown to be unlikely (de Jong et al. 1990a, b).

The second obvious risk is a possible major change in the
genetic composition of C. purpureum populations due to bio-
control actions. Therefore, the population genetics of the con-
trol fungus should be understood before widespread control
actions are conducted. As pointed out above, the populations
of C. purpureum have been studied in northern Europe and
North America, and in both continents the degree of genetic
variation is high, but differentiation between populations is
small (Becker et al. 2004, 2005; Gosselin et al. 1996, 1999;
Hamberg et al. 2018; Ramsfield et al. 1996, 1999; Vartiamäki
et al. 2008b). Therefore, either a gene flow occurs naturally
over large geographic distances, or the population size of the
fungus is so large in both continents that the frequencies of
selectively neutral genes change extremely slowly. In terms of
biocontrol risks, this can be interpreted so that the use of local
genotypes of C. purpureum will not lead to introduction of
novel genes or genotypes to the natural environment.

However, the case is completely different if C. purpureum
strains would be transmitted between the continents. Although
the strains in Europe and North America belong to the same
biological species, they differ considerably in genetic markers
(Hamberg et al. 2018). Therefore, introducing these strains
between North America and Europe could lead to unexpected
consequences as demonstrated by the high degree of damage
by the introduction of North American Heterobasidion
irregulare Garbel. & Otrosina (2010) and its hybridization
with the European H. annosum (Fr.) Bref. (1888) in Italy
(D’Amico et al. 2011; Gonthier and Garbelotto 2011).

436 Appl Microbiol Biotechnol (2021) 105:431–440



Population analyses (Gosselin et al. 1996, 1999; Ramsfield
et al. 1999; Vartiamäki et al. 2008b) have also suggested that
C. purpureum has no asexual (i.e., clonal) reproduction.
Therefore, the genes of the biocontrol strain will mix freely
with those of the natural population of C. purpureum as soon
as basidiospores are produced. In this process, the combina-
tion of alleles in the obviously efficient isolate to be used will
break down by genetic recombination, and the original geno-
type will not spread outside the treated areas. Therefore, the
risk of widespread dispersal of a highly virulentC. purpureum
clone does not exist.

The unwinding of allele combination is true also, as in the
case of the Finnish biocontrol strain R5, which was created by
a short breeding program (Hamberg et al. 2015). In that case,
however, another question arises: whether the spread of this
strain with obviously a high number of virulence alleles in-
creases overall pathogenicity of the naturally spreading
C. purpureum population. There is no study available regard-
ing this risk, but according to population genetics theory, the
extremely large size of C. purpureum populations (and thus
the vastness of the gene pool) in nature will slow down such a
change, if it even occurs. Regardless, the development of ge-
netic diversity of this fungus should be followed over time
where its use in the biocontrol of hardwood sprouting be-
comes a common practice.

Sprout control in the future

As far as we know, commercially available biocontrol prod-
ucts based on C. purpureum do not exist currently, although
some products have been registered (see de Jong 2000).
Difficulties in getting to market are probably not in the pro-
duction lines nor in the efficacy of the treatment agent, as the
fungus grows well on artificial media and is excellent in con-
trolling the sprouting of the target tree species (see above).
Instead, the major dilemma is the lack of cost-efficient treat-
ment protocols for large-scale usage (Laine et al. 2020b).

In Finland, this has led to a self-defeating circle: as there is
no cost-efficient mechanized devices available, the possible
producer(s) are not willing to register the product in the EU,
and as there is no registration, the possible developers of such
machinery are not interested in investing in such develop-
ments. The need for an efficient sprout control is, however,
increasing as the workforce for manual treatments is declin-
ing, and therefore the self-defeating circle will probably be
broken sooner or later. If so, the final solution could be a
lightweight mini-harvester due to the need for carrying large
amounts of liquids.

The economic l imit— i .e . , the chal lenge to be
overcome—of using biological control in forest regenera-
tion sites can be set to the price of the second round of a
man-made treatment with a clearing saw, as today two-
phase PCT-work is typically conducted in northern

Europe. The main issue to be solved will be how to target
the biocontrol agent exactly on the stumps of cut hardwoods
which are small in diameter, instead of spreading most of it
off the target. In order to solve this, both purely mechanical
solutions where collecting aligns the stump surfaces with
the face of the treatment nozzle and more advanced technol-
ogy using, e.g., artificial vision and intelligence to recog-
nize and individually treat each stump surface can be imag-
ined. In both cases, the additional time consumption of the
treatment should be minimized (Laine et al. 2020b).

As genetic differences between C. purpureum on differ-
ent continents are obvious despite their biological
conspecificity (Hamberg et al. 2018), none of the control
agents will probably be used globally. However, the low
level of population differentiation (Becker et al. 2004,
2005; Gosselin et al. 1996, 1999; Ramsfield et al. 1996,
1999; Vartiamäki et al. 2008b) within continents allows
the use of a single strain over large areas in Europe or
North America. Also, development of resistance in hard-
woods against any of these strains is unlikely due to the high
frequency of natural infection. However, if there will be a
need or willingness for new control strains, a breeding pro-
gram is probably more efficient than simple testing of nat-
ural strains in order to find high efficacy (Hamberg et al.
2015). It might be even more efficient to develop more vir-
ulent strains via genetic modification or gene editing, but we
consider it highly unlikely that such strains of already high-
ly efficient plant pathogens would ever be developed.

Conclusion

A decay fungus, Chondrostereum purpureum, is efficient in
decaying wood and as a fungal inoculum is a potential option
in controlling excessive regrowth of hardwoods from stumps.
Sprout control efficacy of C. purpureum varies in different
tree species, and the growth of fungal hyphae within a stump
is also affected by the physiological state of a host tree.
Biological sprout control is not sensitive to environmental
conditions, and therefore it can be used also during hot and
rainy periods and in different soil moisture conditions.
However, fungal inoculum should be spread on fresh stump
surfaces immediately after cutting. From this point of view,
fully mechanized devices capable of carrying the weight of
fungal inoculum are optimal options in biological sprout con-
trol in the future.

Acknowledgments We thank Heikki Kiheri for checking language.

Authors’ contributions LH designed and lead the writing process. LH,
TS, and JH jointly performed the literature search and wrote the manu-
script. All authors have critically reviewed and approved the final
manuscript.

437Appl Microbiol Biotechnol (2021) 105:431–440



Funding Open Access funding provided by Natural Resources Institute
Finland (LUKE). Funding was received from the Natural Resources
Institute Finland (project number 41007-00140900 for LH, 41007-
00096400 for TS and 41008-80000601 for JH).

Data availability Not applicable.

Compliance with ethical standards

Conflict of interest The authors declare that they have no conflict of
interest.

Ethical approval This article does not contain any studies with human
participants or animals performed by any of the authors.

Consent to participate Not applicable.

Consent for publication All authors have read and approved the final
version.

Code availability Not applicable.

Open Access This article is licensed under a Creative Commons
Attribution 4.0 International License, which permits use, sharing, adap-
tation, distribution and reproduction in any medium or format, as long as
you give appropriate credit to the original author(s) and the source, pro-
vide a link to the Creative Commons licence, and indicate if changes were
made. The images or other third party material in this article are included
in the article's Creative Commons licence, unless indicated otherwise in a
credit line to the material. If material is not included in the article's
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statutory regulation or exceeds the permitted use, you will need to obtain
permission directly from the copyright holder. To view a copy of this
licence, visit http://creativecommons.org/licenses/by/4.0/.

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	Hamberg_L_et_al_2020.pdf
	Hamberg et al 2020.pdf
	Hamberg2020_Article_RoleAndFunctionOfChondrostereu
	Role and function of Chondrostereum purpureum in biocontrol of trees
	Abstract
	Abstract
	Abstract
	Introduction

	This link is 10.1016/S0269-(00)80005-,",
	Outline placeholder
	Ecology of a decay fungus Chondrostereum purpureum
	Sprout control efficacy
	Factors affecting sprout control efficacy
	Host tree
	Site-specific factors
	Weather

	Devices in biological sprout control
	Potential risks
	Sprout control in the future

	Conclusion
	References



	Hamberg et al. 2021 (Appl Microbiol Biotec).pdf
	Role and function of Chondrostereum purpureum in biocontrol of trees
	Abstract
	Abstract
	Abstract
	Introduction

	This link is 10.1016/S0269-(00)80005-,",
	Outline placeholder
	Ecology of a decay fungus Chondrostereum purpureum
	Sprout control efficacy
	Factors affecting sprout control efficacy
	Host tree
	Site-specific factors
	Weather

	Devices in biological sprout control
	Potential risks
	Sprout control in the future

	Conclusion
	References