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African swine fever virus (ASFV) is one of the most threatening animal viruses which has dramatically expanded its distribution range within the last years. ASFV was first described and is endemic in sub-Saharan Africa where it is transmitted in a sylvatic cycle between indigenous suids and Ornithodoros soft ticks. Therefore, ASFV is the only known DNA-arbovirus and, in addition to that, the only member of the genus Asfivirus within the family Asfarviridae. Being highly infectious to domestic pigs and wild boar, the virus was introduced into Georgia in 2007 and has subsequently spread throughout eastern Europe reaching the European Union in 2014. Despite almost 100 years of intensive research and the occurrence of African swine fever (ASF) on four continents including Europe, many aspects of its epidemiology, vector dynamics and virus evolution are unknown. In our study, first evidence is presented on endogenous ASFV-like (EASFL)- elements which are integrated into the genome of ASFV natural vectors, O. moubata soft ticks. Through a series of experiments including next-generation sequencing, infection experiments, phylogenetic and BEAST analyses as well as PCR-screening, evidence is provided that these elements belong to an ancestral ASFV strain that might have existed 50,000 to 30,000 years BCE. Further results suggest that the EASFL-elements are involved in protecting ticks against ASFV infection and might belong to a generalised tick defence mechanism. In order to evaluate factors influencing ASFV epidemiology in eastern Europe, experiments were conducted on possible indigenous vector species and circulating virus isolates. In the absence of the natural tick vector, blow fly larvae were considered as possible mechanical vectors involved in ASFV transmission and persistence. Results are presented that even after feeding on highly infectious wild boar tissue, fly larvae and pupae showed no contamination with infectious virus. On the contrary, the maggots appeared to have inactivated the virus in the organ tissue through their salivary secretions. Further experiments conducted on an ASFV-strain isolated from northeastern Estonia resulted in the first report of an ASFV-strain with attenuated phenotype isolated in Eastern Europe. Results from NGS-analyses provided evidence for a major genome reorganisation in that strain that included a large deletion and a duplication of multiple ASFV genes.
Taken together, this study provides novel insights into the epidemiology of ASF and evolution of ASFV one of the major threats to animal health worldwide and therefore does not only contribute significantly to basic research but possibly also to specific knowledge necessary for future disease management.
Culicidae, auch bekannt als Stechmücken, sind medizinisch bedeutsame Zweiflügler, die als Vektoren eine Vielzahl von Krankheitserregern auf Menschen und Tiere übertragen können. Die vorliegende Arbeit beschäftigt sich einerseits mit der Verbreitung von zwei seltenen Stechmückenarten, welche im Rahmen eines Monitoringprojekts gefangen wurden, und andererseits mit der Ökologie der Asiatischen Tigermücke. Bei allen Arten handelt es sich um thermophile Arten, bei denen angenommen wird, dass der Klimawandel ihre Verbreitung Richtung Norden begünstigt. Dies konnte vor allem für die Art Uranotaenia unguiculata gezeigt werden, da sie an zwei Orten gefunden wurde, die ausgesprochen weit entfernt waren von der einzigen jemals zuvor beschriebenen Nachweisstelle in Deutschland. Obwohl an beiden Fundorten jeweils nur ein einziges adultes Individuum gefangen werden konnte, ergab eine Beprobung von potenziellen Bruthabitaten im darauffolgenden Jahr, dass lokale Reproduktion stattfand. Somit konnte eine ausschließliche Verschleppung von adulten Einzelindividuen weitgehend ausgeschlossen werden. Eine weitere seltene Stechmückenart, die im Zuge des Monitorings nachgewiesen werden konnte, ist Anopheles algeriensis. Diese Art wurde an drei Standorten gefangen, an zwei von ihnen mit einer viel höheren Abundanz als Ur. unguiculata.
Den ökologischen Teil dieser Arbeit machen Feld- und Laborexperimente mit Aedes albopictus aus. Sie dienten der Ermittlung der Kältetoleranz der Eier dieser Spezies, die als Vektor für eine Vielzahl von Viren und andere Pathogene gilt. Drei verschiedene Stämme, die aus tropischen, subtropischen und gemäßigten Breiten stammen, wurden niedrigen Temperaturen, welche typischerweise im Winter herrschen, unter Feld- und Laborbedingungen ausgesetzt. Die Experimente belegen, dass alle untersuchten Stämme prinzipiell einen Winter mit einem Temperaturminimum von –8 °C im Feld überleben konnten. Die Laborexperimente konnten hingegen zeigen, dass alle Stämme in der Lage waren, Temperaturen von –10 °C für eine gewisse Zeit zu ertragen. Die Überlebensfähigkeit schwankte je nach Stamm zwischen 2 und 20 Tagen. Dabei hatte der Stamm aus den gemäßigten Breiten eine Kältetoleranz, die nur wenig höher lag als die des subtropischen Stammes. Der tropische Stamm hingegen besaß die geringste Toleranz gegenüber niedrigen Temperaturen, sowohl in den Freiland- als auch in den Laborexperimenten. Diapausierende Eier zeigen nur eine höhere Kältetoleranz nahe den physiologischen Grenzen der jeweiligen Stämme. Weiterhin konnte festgestellt werden, dass Eier unter fluktuierenden Temperaturen eine bestimmte Minimaltemperatur länger aushalten konnten als unter konstanten Temperaturen. Somit zeigen beide Experimente, dass gewisse Stämme von Ae. albopictus eine sehr hohe Toleranz gegenüber niedrigen Temperaturen haben. Das macht es sehr wahrscheinlich, dass diese invasive Art Winter in Deutschland oder anderen mitteleuropäischen Ländern überleben und ihre Ausbreitung weiter fortschreiten werden. Diese Entwicklung wird epidemiologische Auswirkungen auf die Human- und Veterinärmedizin haben.
The present study deals with the spread and population genetics of the invasive Asian bush
mosquito Ae. japonicus in Europe and Germany. Since the first detection of Ae. japonicus
in Europe in 2000, the species spread rapidly through Europe, either actively by flying or
passively by human activities. In 2017, four confirmed populations of Ae. japonicus existed
in Europe. The largest population covered western Germany, parts of France, Switzerland,
Liechtenstein, Austria and Italy. The most northern population around Hanover, Germany,
did not spread since 2013. A very small population existed in Belgium and the second largest
population covered parts of Austria, Italy, Slovenia, Croatia and Hungary. By 2019, Ae.
japonicus had established in 15 European countries.
Most of the monitoring programmes in Europe dealing with the distribution and spread of
Ae. japoncus investigate cemeteries for juvenile stages. However, activities are not
harmonised, e.g. regarding numbers of investigated collection sites and declaration of
negative sites, making data comparison between different studies difficult. Therefore,
suggestions for a standardised Ae. japonicus monitoring method have been developed and
provided.
In the present study, 445 individuals of Ae. japonicus originating from five different
European countries were investigated for population genetic analyses by sequencing parts
of the nad4 gene and genotyping seven polymorphic microsatellite loci. In total, 16 different
nad4 haplotypes were identified with haplotype H1 being the most common and widespread
one through all populations.
Within Germany, Ae. japonicus has been spreading immensely over the last decade. Even
though the present results (2017) demonstrate incipient genetic admixture of populations as
compared to previous studies (2012-2015), no complete genetic mixture has taken place yet.
The populations of Ae. japonicus still fall into two genetic clusters, but the genetic diversity
on individual level had increased considerably (from three nad4 haplotypes in 2012 to 12
according to the present thesis). Both additional introductions and mutation are possible
reasons, but determining the origin of the German populations is not possible anymore.
In the years following the invasion of Germany, Ae. japonicus spread to southeastern
Europe. In 2013, it established in Croatia, in 2017 in Bosnia and Herzegovina and in 2018
in Serbia. In the current study, immature stages of Ae. japonicus were found at 19 sites in
Croatia, two sites in Bosnia and Herzegovina and one site in Serbia. The population genetic
analyses indicate at least two independent introductions in that area. Aedes japonicus collected west of Orahovica (Croatia) seemed to be genetically similar to samples previously
investigated from Southeast Germany/Austria and Austria/Slovenia. By contrast, samples
from east of Orahovica, together with those from Serbia and Bosnia and Herzegovina, were
characterised by another genetic make-up, but their origin could not be determined.
In 2021, individuals of Ae. japonicus were detected at two collection sites in the Czech
Republic for the first time: Prachatice close to the Czech-German border and Mikulov on
the Czech-Austrian border. Population genetics and comparison of genetic data showed a
close relationship of the Prachatice samples to a German population, while for Ae. japonicus
from Mikulov close relatives could not be identified.
In the future, the global spread and establishment of invasive mosquitoes through
international trade and travel will increase. Potential vectors, like the Asian bush mosquito
Ae. japonicus, can become a problem in Europe and Germany, especially in the course of
global warming which supports pathogen transmission. Monitoring the known populations
and identifying introduction and migration routes are therefore essential for vector
managing.
In Germany, basic data on the biology, ecology and distribution of rare mosquito species are insufficiently recorded leading to knowledge gaps, for example regarding their vector potential. The introduction of new mosquito species and of the pathogens they transmit has increased the risk of diseases previously uncommon in Germany. These circumstances have led to increased efforts within the past 10 years to better understand the spatio-temporal occurrence and underlying habitat binding of mosquito species and to predict their future distribution, particularly with regard to the changing climatic conditions and changing landscape. A reliable morphological and genetic identification was lacking for several native mosquito species, which forms the basis for any robust monitoring within mosquito surveillance programs or insect conservation projects.
The aim of this thesis was to gain detailed knowledge on the current spatial and temporal occurrence, the habitat binding, and morphological and genetic features with regard to species identification for the non-native species Aedes albopictus (Skuse, 1895), the native species of the Aedes Annulipes Group, and the native and rare species Aedes refiki Medschid, 1928, Culex martinii Medschid, 1930 and Culiseta ochroptera (Peus, 1935).
The thesis compares the suitability of the local climate for the persistence of the species Aedes albopictus sporadically observed in Jena (Thuringia) from 2015 to 2018 with two populations in southern Germany. The focus was on the analysis of extreme winter temperatures and the duration below selected temperature thresholds. In addition to critical temperature conditions, aquatic habitat conditions were of importance. The results of this study suggest that the population could become established in the long term.
Through the monitoring conducted for this thesis, the very rare mosquito species Aedes refiki, Culex martinii in Thuringia and Culiseta ochroptera were rediscovered at several sites in northern and eastern Germany. It was possible to add new information on habitat binding, distribution and abundance for the considered mosquito species. The survival of these rare native mosquito species depends on the preservation of a few remaining habitats. In addition, it can be assumed that these species will become even rarer with future climate change in Germany and, therefore, should be considered endangered. In contrast, other mosquito species could benefit from an increase in average temperatures or precipitation in individual cases.
Due to the contribution to species identification, difficulties in the morphological and genetic identification of selected mosquito species native to Germany could be dispelled. Three forms each were assigned to the known morphological variants of Aedes refiki and Culiseta ochroptera and their peculiarities were described, as well as a new character for species identification was highlighted in the case of Culiseta ochroptera. Generated CO1 mtDNA sequences provide the first DNA-barcodes of Aedes refiki and Culex martinii for Germany.
In five native mosquito species of the Aedes Annulipes Group, twenty types of aberrant tarsal claws were illustrated and described in their morphology. Morphological peculiarities and an asymmetrical occurrence of the aberrant claw types were observed and possible causes for their development were discussed. Together with the development of a basic blueprint of mosquito tarsal claws, the results opened another field of research for the taxonomy, developmental biology and aquatic ecology of arthropods.
The present work focusses on the mosquito populations of two zoological gardens in Germany with the aim to better understand mosquito biology of native species and to contribute to a greater awareness of mosquito and mosquito-borne disease agent surveillance in zoos. For this purpose, data on species composition, blood meal patterns and mosquito-borne pathogens were analysed. The investigated zoological gardens differed not only in their sizes and animal stocks, but also in their surrounding environments. The 160 ha Tierpark Berlin is located in a densely populated urban area, while the 15 ha Zoological Garden Eberswalde is surrounded by forest.
To gain an overview about the mosquito fauna of both zoos, adult specimens were caught by aspirating and EVS-trapping during the 2016 season. In addition, larval stages were collected from their breeding sites located in the zoo areas. In total, 2,257 mosquitoes were sampled, belonging to 20 taxa. Seasonal differences between the zoos were documented, both in terms of species composition and the relative abundance of mosquito species collected. As the studied zoos were located in the same climatic region and both locations provided similar breeding sites, differences in species composition were attributed to the entry of mosquitoes from surrounding landscapes. Influencing factors could have been the different sizes of the zoos and variations in the potential host animal populations.
According to the vector potential of most frequently collected taxa in the Zoological Garden Eberswalde (Annulipes Group, Culiseta annulata), TAHV, USUV, WNV, filariae and avian malaria parasites appear to have the highest risk of being transmitted at this location. In the Tierpark Berlin, Aedes vexans was the most frequently collected mosquito species, suggesting a theoretical risk for the transmission of a broader spectrum of pathogens due to covered vector competences. Pathogens such as BATV, SINV, TAHV, USUV and filarial worms could be of major importance regarding transmission risk to zoo animals, as they had previously been found to circulate Germany. In addition, avian malaria parasites represent a considerable risk for susceptible exotic bird species in Berlin.
Since the blood-feeding behaviour of vector-competent mosquito species has a major influence on the transmission of a mosquito-associated pathogen, the analysis of blood meal patterns is crucial to better understand vector-pathogen cycles. Therefore, blood meals of blood-fed mosquitoes caught in 2016 and 2017 by aspirating and EVS-trapping in the Tierpark Berlin and the Zoological Garden Eberswalde were analysed. The aim was to investigate to what extent native mosquito species accept exotic zoo animals, wild native animals and humans as blood hosts. In addition, it was examined whether the collected species are generalists or specialists when selecting vertebrates for blood feeding.
A total of 405 blood-fed mosquitoes from 16 taxa were collected. The genetic analysis of blood meals identified 56 host species, which – in addition to humans – mainly originated from mammals of the zoo animal populations. In agreement with the previous study on the mosquito fauna of the Tierpark Berlin and the Zoological Garden Eberswalde, the analysis of blood meals also showed differences between the two zoos. In the smaller Zoological Garden Eberswalde, a higher number of blood-fed mosquitoes was collected than in the Tierpark Berlin, probably caused by a higher host density in Eberswalde, which may have led to an overall higher mosquito density. However, no differences between both zoos were observed with respect to the blood feeding behaviour of the analysed mosquito species: Mosquitoes of both locations were rather generalistic, although species could be grouped according their blood meals into 'amphibian', 'non-human mammal' and, ‘non-human mammal and human' feeding species. The more random selection of hosts could indicate a low probability of effective pathogen transmission by applying the 'dilution effect'. Notwithstanding, since wild animals have also been accepted as hosts, pathogen transmission by bridge vectors from one vertebrate group to another could be relevant in the sampled zoos.
Adult mosquito specimens collected in 2016 and 2017 were screened for filarial nematodes, avian Haemosporidia and mosquito-borne viruses. Dirofilaria repens was detected in a mosquito from the Zoological Garden Eberswalde. Mosquitoes from Berlin and Eberswalde were tested positive for the nematode species S. tundra. Sindbis virus was found in a mosquito pool collected in the Tierpark Berlin, while no mosquito-associated viruses were detected in specimens collected in the Zoological Garden Eberswalde. Mosquitoes from both zoos were positive for the haemosporidian parasites Haemoproteus sp. and Leucocytozoon sp., and one documentation was made for avian Plasmodium sp. in the Tierpark Berlin.
The identified pathogens have the potential to cause disease in captive and wild animals, and some of them also in humans. Most of the mosquitoes tested positive had been collected in July, suggesting a high infection risk during this month. Since most pathogen detections were made from species belonging to the Cx. pipiens complex, species of this complex seem to be most relevant in the studied zoos when it comes to mosquito-borne pathogen transmission. Although mosquitoes are no proven vectors of most of the avian malaria parasite genera found, evidence for Haemoproteus sp. and Leucozytozoon sp. demonstrated a high prevalence of avian malaria parasites in the zoos.
In summary, the results of the three studies indicate regional differences both in the mosquito species composition and in the occurrence of mosquito-borne pathogens. However, no differences were found between the mosquito communities of both zoos concerning their blood feeding behaviour, suggesting that the general behaviour of the insects is location-independent.
Several potential disease agents were found in the collected mosquitoes, although not at high abundances. Whether these pathogens were found by chance in the two zoos or whether the particular zoo environment is a hot spot of arthropod-borne pathogens cannot be determined with the studies conducted. Nonetheless, it seems clear that zoological gardens are attractive to mosquito females not only in their search for breeding sites, but also when looking for blood hosts and places for mating or resting. These advantageous conditions also attract mosquito species that have their larval habitats outside the zoological gardens, which is why elimination of breeding sites on the zoo premises alone will not necessarily keep away all mosquitoes.
A closer collaboration between zoological gardens and entomologists could be beneficial for both. Zoo officials could benefit from being able to identify potential arthropod vectors on the zoo grounds and receiving information on circulating arthropod-borne disease agents, as well as on the animal species susceptible to those. For entomologists, zoological gardens are ideal research locations, as they provide an environment with a high diversity of habitats and potential blood hosts for haematophagous arthropods in a confined space.
Studying mosquito biology will become even more significant in the future, since in a world that is getting smaller, both potential vectors and pathogens are regularly introduced into areas where they did not occur before. Therefore, it would be desirable if more studies targeting ecological as well as infectiological aspects of vector species in zoological gardens in Germany were carried out.