Article type: Short Communication
Title: Emergence of a bufonid herpesvirus in a population of the common
toad (Bufo bufo ) in Germany
Running Title: Bufonid herpesvirus in Germany
Authors:
Tobias Eisenberg1,2,3*, Hans-Peter
Hamann1, Carina Reuscher2, Axel
Kwet3, Katja Klier-Heil3,4, Benjamin
Lamp2
1 Hessian State Laboratory (LHL), Giessen, Germany
2 Justus-Liebig-University, Giessen, Germany
3 German Herpetological Society (DGHT), Fellbach,
Germany
4 Nature and Biodiversity Conservation Union (NABU),
Ortenberg, Germany
*corresponding author, mailing address: Hessian State Laboratory (LHL),
Department of Veterinary Medicine, Schubertstr. 60/ Haus 13, 35392
Giessen, Germany. Phone: 49-641-4800 5219. Fax: 49-641-4800 5268.
E-mail: tobias.eisenberg@lhl.hessen.de.
Keywords: bufonid herpesvirus 1, common toad, Bufo bufo, emerging
disease, amphibian decline
Abstract
Bufonid herpesvirus 1 (BfHV1) was initially described in 2018
from cases of severe dermatitis in Swiss populations of the common toad
(Bufo bufo ). We identified a closely related herpes virus strain
in a German toad population affected by an epidemic of multifocal
proliferative to ulcerative dermatitis.
Amphibians are believed to be the most endangered class of vertebrates,
with an unprecedented decline of almost one third of the populations in
the recent decades. At global level, the crisis has been attributed to
environmental pollution (Slaby, Marin, Marchand, & Lemiere, 2019),
climate change (Rollins-Smith, 2017), and the spread of infectious
diseases (Eisenberg et al., 2012; Gray, Miller, & Hoverman, 2009;
Martinho & Heatley, 2012). Among the pathogens, chytridiomycosis is the
best-studied example with major effects on the populations of many
frogs, toads and salamanders (Fisher & Garner, 2020; Latney &
Klaphake, 2020). The toad herpesvirus Bufonid herpesvirus 1(BfHV1), classified within the genus Batrachoviru s in the family
Alloherpesviridae, has recently been described as a cause of morbidities
and mortalities in toads in Switzerland, where BfHV1 was detected in
skin lesions and in the central nervous system (Origgi et al., 2018).
Here, we document an epidemic of severe dermatitis in a free-living
population of the common toad (Bufo bufo ) in Germany starting in
2018 caused by a closely related bufonid herpesvirus strain.
The dermatitis epidemic occurred in a toad population located in central
Hesse, Germany. The habitat of these toads covers a wide range of
biotopes, including hardwood forests and semi-open landscapes of
meadows, pastures and hedges. The central part of their habitat is a
pond area of approx. 8.000 m2, which is seasonally
used by many different amphibian species in order to mate and to raise
their tadpoles (Table 1). The toad population has been systematically
monitored in the last three years by animal conservationists, who have
initiated protective measures to reduce road kills among amphibians.
Migrating amphibians were collected on a 250 m long transect beneath the
neighbouring main road almost every night in March and April using
common bucket traps. The animals were collected, classified, weighed,
photographed, and finally released at the designated breeding site. The
availability of monitoring data of the recent years allows a rough
comparison of basic measures for the population, including number,
weight and health status of captured toads. In 2018, when the first
cases of an unknown skin disease were observed, a number of 837 toads
could be caught within the buckets. In contrast, only 245 and 431 toads
were registered for 2019 and 2020, respectively. However, only a few of
the captured animals showed signs of skin lesions in 2018. These animals
suffered from multifocal dermatitis spots located on the dorsal and
ventral side of the body (Fig. 1B, C). Affected toads usually showed
multiple lesions in different manifestation stages. Typical early
lesions were greyish-dark, circumscribed, round to irregularly shaped
and up to 10 mm in diameter. In these early stages, mild proliferative
superficial alterations appeared that ended up at later stages in
ulcerative lesions with a crusty, cauliflower-like appearance, slightly
elevated above the normal skin level (Fig. 1B). After molting of the
affected skin regions of lighter areas remained, which were more
yellowish pigmented (Fig. 1C). All captured toads appeared to be healthy
except for the skin lesions described. Even the toads affected by severe
dermatitis spots were in good nutritional condition and no neurological
abnormalities were observed. No acute deaths due to the unknown
dermatitis have been documented or reported from other parties for the
toad population. It was therefore suspected that these skin lesions were
harmless to the animals and represented skin burns possibly caused by
natural tannins from the ecosystem. Due to the official protection
status of toads, no biopsy was performed. No further diagnostic measures
were taken as no other amphibian species in this habitat showed
comparable skin lesions (Table 1).
The decision to take samples and carry out an in-depth microbiological
examination was made in March 2020, when characteristic lesions were
found in more than one third of all captured toads (Table 1). Skin swabs
were taken from the affected toads and spontaneously molted fresh skin
material was collected from two male and two female toads (permit no.
4.1.2/19.1-0183-15660/20). After extraction of the nucleic acids, all
samples were examined by PCR assays for the presence of genetic material
of the major amphibian pathogens Batrachochytrium (B .)dendrobatidis, B. salamandrivorans and ranaviruses. Furthermore,
the fresh skin samples of the molted epidermis were processed and
analyzed by transmission electron microscopy (TEM). While no pathogens
could be detected by PCR, characteristic virus-like structures were
apparent in the negatively stained TEM samples. Multiple fried egg
shaped, electron dense particles could be seen. Central in these
particles an icosahedral nucleocapsid with a diameter of about 120 nm
build of capsomeres was situated. The structure was typical for members
of the order Herpesvirales (Fig. 2A). Based on the nucleotide
sequence of the recently described herpesvirus of toads we designed
oligonucleotides to amplify a large fragment of the putative DNA
polymerase gene covering most of the open reading frame (BHpf
5’-cagagcagcggtctgccgcgac-3’ and BHpr 5’-ctggcaacaccataatggctg-3’). A
DNA fragment of 1,552 bp was amplified from swab samples of the affected
toads (GenBank MT975973). After sub-cloning, Sanger sequencing of the
plasmids, and phylogenetic analysis, we termed the strain
BfHV1_G/H/20_1, because it showed a very close phylogenetic
relationship (Fig. 2B) to the type-strain from Switzerland (BfHV1,
FO1_2015, NC_040681.1). In direct comparison only four nucleic acid
exchanges were found between the two herpesvirus strains in the 1,552 bp
fragment, of which only one caused an amino acid exchange (A412V) after
translation (YP_009552918.1).
Conclusions
A negative population trend for common toads was observed in
representative long-term studies in Great Britain and Switzerland. While
exact reasons for this population trend are currently unknown, an
involvement of infectious diseases is very likely (Petrovan & Schmidt,
2016). A literature search revealed that epidemic dermatitis cases in
toads have already been reported in the past as ”black fungus disease”
(David, 2013) and that there have been previous reports from Belgium on
the identification of a toad herpes virus (Garner, 2013). In addition, a
virus termed Ranid herpesvirus 3 has recently been described in
European common frogs as the cause behind a similar skin disease with
clinically relevant lesions (Bennati, Bonetti, Lavazza, & Gelmetti,
1994; Franklinos et al., 2018; Origgi et al., 2017). These data are
suggesting that besides other microorganisms, especially chytrid fungi
and ranaviruses, also herpesviruses have to be considered as an
underlying agent behind a population decline among amphibians. Different
consensus PCR protocols have been established as a strong diagnostic
tool for the detection of all the known Ranid herpesviruses (15).
The incidence of BfHV1 cases in Germany is currently unknown and data on
diseased toads exist mainly from the reproductive habitat, as the shy
animals are otherwise rarely noticed. In line with previous reports on
the benignity of herpesvirus infections in amphibians, no toads were
found or reported that died acutely of BfHV1. The skin lesions of the
toads captured during this study did not significantly affect the
general condition of the animals. However, the study toad population is
facing a decline since the first occurrence of apparent BfHV1 disease
and the proportion of BfHV1 affected animals is constantly rising since
2018 reaching over 30% in 2020. Furthermore, it seems likely that
BfHV1-associated morbidities and mortalities could have been overlooked,
even in this study as only healthy animals can make the strenuous
journey to the site of reproduction. Dead toads are quickly disposed by
scavengers in their habitat and therefore, they will rarely be noticed
by humans. Even a slight loss of fitness often means that small animals
fall victim to a larger predator in the wild. It remains to be
determined, whether this virus is involved in the population decline
documented in this study. The presence of BfHV1 disease in common toads
in another region of Europe implies a greater importance of the pathogen
for the European toad population. Hence, the prevalence of BfHV1 and its
impact on the European toad population should be studied in more detail
in future investigations.
Contributors
TE and BL conceived the study. KKH and AK found affected and control
toads, respectively and submitted material. HPH conducted electron
microscopy. HPH, CR and BL performed molecular experiments. TE and BL
wrote the report and all authors approved the final manuscript.
Acknowledgments
The Hessian State Laboratory is supported by the Hessian Ministry for
the Environment, Climate Change, Agriculture and Consumer Protection.
Statement
All authors do not declare any conflict of interest. No funding was
received for this study.
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Captions (2 Figures and 1 table)
Figure 1. Clinical picture of BfHV1 skin lesions in toads. A) Healthy
toad skin; B) toad with prominent skin lesions on the body surface; C)
appearance of proliferative and ulcerative skin changes in close-up.
Figure 2. Identification of BfHV1. A) Electron micrograph of virions
from the lesions with two concentric layers indicative for a
herpesvirus. B) Phylogenetic analyses of BfHV1 strain G/H/20_1 and
related viruses was done by Neighbor Joining based on a 517 AA fragment
of the putative DNA polymerase. Labels at end nodes indicate the species
and strains of the respective herpesviruses. The protein IDs to the
fragments of BfHV1 strain FO1_2015 (YP_009552918.1), BfHV1 strain
G/H/20_1 (MT975973.1), ranid herpesvirus 1 strain McKinnell (RaHV1,
YP_656727.1), ranid herpesvirus 2 strain ATCC VR-568 (RaHV2,
YP_656618.1) are provided in parentheses. The ranid herpesvirus 3
strain FO1_2015 (RaHV3, YP_009362398.1) showed only a distant relation
and served as an outgroup. The scale bar indicates substitutions per
site. Bootstrapping values from 1,000 replicates are indicated.
Table 1: Captured toads of the study population as well as other
amphibian species at the study location and occurrence of BfHV lesions