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Institute
Technological advances in light microscopy have always gone hand in hand with unprecedented biological insight. For microbiology, light microscopy even played a founding role in the conception of the entire discipline. The ability to observe pathogens that would otherwise evade human observation makes it a critical necessity and an indispensable tool to infectious disease research. Thus, the aim of this thesis was to optimize, extend, and functionally apply advanced light microscopy techniques to elucidate spatio-temporal and spatio-morphological components of bacterial and viral infection in vitro and in vivo.
Pathogens are in a constant arms race with the host’s immune system. By finding ways to circumvent host-mediated immune responses, they try to evade elimination and facilitate their own propagation. The first study (publication I) demonstrated that the obligate intracellular pathogen Coxiella burnetii is not just able to infect natural killer (NK) cells, but is actually capable of surviving the harsh degradative conditions in the cytotoxic lymphocyte’s granules. Using live-cell imaging of reporter-expressing Coxiella burnetii, the transient NK cell passage was closely monitored to provide detailed spatio-temporal information on this dynamic process in support of a range of static analyses. Bacterial release from NK cells was pinpointed to a time frame between 24 to 48 hours post-infection and the duration of release to about 15 minutes.
The second approach (publications II-V) aimed at shedding light on the greater spatio-morphological context of virus infection. Thus far, most studies investigating the distribution or tropism of viruses in vivo have used conventional immunohistochemistry in thin sections. Omitting the native spatial context of the infection site in vivo inherently bears the risk of incomplete description. While the microscopic tools and sample preparation protocols needed for volumetric 3D immunofluorescence imaging have recently been made available, they had not gained a foothold in virus research yet. An integral part of this thesis was concerned with the assessment and optimization of available tissue optical clearing protocols to develop an immunofluorescence-compatible 3D imaging pipeline for the investigation of virus infection inside its intact spatio-morphological environment (publication II). This formed the basis for all subsequent volumetric analyses of virus infection in vivo presented here. Consequently, this thesis provided a valuable proof of concept and blueprints for future virus research on the mesoscopic scale of host-pathogen interactions in vivo (publications II-V), using rabies virus (RABV; publications II-IV) and the newly-emerged severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2; publication V) as infection models for the nervous system and the respiratory tract, respectively.
Applying and further improving this volumetric 3D imaging workflow enabled unprecedented insights into the comprehensive in vivo cell tropism of RABV in the central (CNS) (publication III) and peripheral nervous system (PNS) (publication IV). Accordingly, differential infection of CNS-resident astrocytes by pathogenic and lab-attenuated RABV was demonstrated (publication III). While either virus variant showed equal capacity to infect neurons, as demonstrated by quantitative image analysis, only pathogenic field RABVs were able to establish non-abortive infection of astrocytes via the natural intramuscular inoculation route. A combined 3D LSFM-CLSM workflow further identified peripheral Schwann cells as a relevant target cell population of pathogenic RABV in the PNS (publication IV). This suggested that non-abortive infection of central and peripheral neuroglia by pathogenic RABV impairs their immunomodulatory function and thus represents a key step in RABV pathogenesis, which may contribute significantly to the establishment of lethal rabies disease.
Finally, utilizing the full volumetric acquisition power of LSFM, a further refined version of the established 3D imaging pipeline facilitated a detailed mesoscopic investigation of the distribution of SARS-CoV-2 in the respiratory tract of the ferret animal model (publication V). Particularly for this newly-emerged pathogen of global concern, in-depth knowledge of host-pathogen interactions is critical. By preserving the complete spatio-morphological context of virus infection in the ferret respiratory tract, this thesis provided the first specific 3D reconstruction of SARS-CoV-2 infection and the first report of 3D visualization of respiratory virus infection in nasal turbinates altogether. 3D object segmentation of SARS-CoV-2 infection in large tissue volumes identified and emphasized a distinct oligofocal infection pattern in the upper respiratory tract (URT) of ferrets. Furthermore, it corroborated a preferential replication of SARS-CoV-2 in the ferret URT, as only debris-associated virus antigen was detected in the lower respiratory tract of ferrets, thus providing crucial information on the spatial distribution of SARS-CoV-2.
Bisherige Analysen von RABV-Pathogenitätsdeterminanten wurden mit laboradaptierten, teils attenuierten Viren durchgeführt. Es ist unklar, ob bisher untersuchte Faktoren auch für hoch virulente RABV-Feldviren relevant sind. Der hier durchgeführte systematische Vergleich von Feldviren und Laborstämmen im infizierten Tier konnte Unterschiede hinsichtlich der Fähigkeit immunkompetente Neuroglia des ZNS zu infizieren als mögliche Pathogenitätsdeterminante aufzeigen. Darüber hinaus wurden erstmals SZ-Neuroglia peripherer Nerven als Zielzellen für die RABV-Infektion identifiziert.
Für die Analyse von RABV-infizierten Geweben wurde ein modernes 3D Imaging-Verfahren angewandt. Gehirne aus experimentell infizierten Mäusen und Frettchen wurden wie in Veröffentlichung 1 beschrieben immunfluoreszenz-gefärbt, optisch geklärt und hochauflösend mit einem konfokalen Laserscan Mikroskop untersucht. RABV N und P Protein konnten dreidimensional in räumlicher Umgebung zu zellulären Strukturen des Wirtes visualisiert werden. Diese Untersuchung bewies die besondere Eignung des Verfahrens zur Identifizierung vereinzelter Zielstrukturen und wurde für nachfolgende systematische Analysen im ZNS und PNS verwendet.
Der RABV-Zelltropismus wurde als vermutlich wichtige Pathogenitätsdeterminante in Veröffentlichung 2 untersucht. RABV Feldviren vom Hund (rRABV Dog), Fuchs (rRABV Fox) und Waschbär (rRABV Rac) konnten im Vergleich zu den laboradaptierten Viren (rCVS-11, SAD L16 und ERA) nicht-neuronale Zellen im ZNS wie Astroglia produktiv infizieren. Der Anteil infizierter Astrozyten ist mit 7-17 % nach i.m. Inokulation vergleichbar mit dem der Neuronen (7-19 %). Interessanterweise wurde eine Inokulationsroutenabhängige Infektion von Astrozyten mit dem moderat virulenten Laborstamm rCVS-11 beobachtet. Diese systematische und quantitative Analyse des RABV-Astrozyten- und Neuronentropismus zeigt, dass mit abnehmender Virulenz die Fähigkeit der Viren produktiv in Astroglia im ZNS zu replizieren abnimmt. Die Fähigkeit eine produktive Infektion in Astrozyten auszubilden, scheint demnach ein grundlegender Unterschied zwischen Feldviren und weniger virulenten Laborstämmen zu sein.
Weiterführend wurde in Veröffentlichung 3 die Virusausbreitung vom ZNS in periphere Nerven untersucht. Hinterbeine, Wirbelsäule inklusive Rückenmark, Gehirn und weitere Kopfbereiche experimentell infizierter Mäuse wurden mittels Lichtblatt- und konfokaler Laserscanmikroskopie analysiert. Zum Ersten Mal konnte eine RABV-Infektion peripherer Neuroglia dargestellt werden. Eine produktive Infektion immunkompetenter SZ im PNS ist also möglicherweise, genauso wie die Infektion von Astrozyten im ZNS, entscheidend für die RABV-Neuropathogenese. Die Detektion von RABV-Antigen im Hinterbein nach i.c. Inokulation beweist eine anterograde axonale Virusausbreitung vom ZNS in periphere Nerven. Interessanterweise konnte das Virus auch in Bereichen des Nasopharynx und des Zungenepithels nachgewiesen werden, worüber möglicherweise zusätzlich zur Speicheldrüse Virus in den Nasenrachenraum ausgeschieden wird. Zusammenfassend konnten mit dieser Arbeit neue Einblicke hinsichtlich des Zelltropismus und der Ausbreitung von RABV in vivo im Modellorganismus Maus gewonnen werden. Die Fähigkeit der untersuchten hoch virulenten Feldviren nicht-neuronale, immunkompetente Neuroglia des ZNS und PNS zu infizieren unterscheidet diese von den weniger virulenten bzw. apathogenen Virusstämmen und könnte ein entscheidender Faktor bei der Ausbildung einer Tollwut-Enzephalitis darstellen.
Lyssaviruses, the causative agents of rabies, are a long-known threat for animals and humans. To date, terrestrial rabies still accounts for tens of thousands of human deaths annually, notwithstanding ambitious vaccination campaigns targeting susceptible dog and wildlife populations that act as reservoirs for the prototypic rabies virus. Moreover, the continuing discovery of newly emerging virus species in hitherto unconcerned chiropteran hosts and geographic regions drive the expansion of the Lyssavirus genus by unveiling its actual variety, host range and distribution.In this work, the genetic diversity of three distinct lyssaviruses, namely EBLV-1, KBLV and RABV, was elucidated by in-depth genomic analyses to provide further insight into lyssavirus evolution. The generation of full-genome sequences from primarily bat-associated Danish EBLV-1 samples significantly increased the number of available Danish EBLV-1 genome sequences while phylogenetic and phylogeographic analysis revealed a stronger phylogeographic structure for the cluster A1 of the sublineage EBLV-1a than it was postulated in previous studies. In addition, the acquisition of a nearly complete genome sequence for the Kotalahti bat lyssavirus provided the basis for the classification of this putative new lyssavirus species as a recognized member of the genus. Furthermore, phylogenetic analysis revealed the affiliation of KBLV to a group of Myotis-associated lyssaviruses giving a deeper insight into the shared evolutionary history of lyssaviruses co-evolving with particular bat species. Moreover, a deep-sequencing approach was utilized to assess the high genetic diversity of vaccine virus populations, uncovering three independent patterns of single nucleotide variants (SNVs) that became selected in ERA-related vaccine-induced cases. However, no apparent influence of the genetic diversity of vaccine viruses on microevolutionary processes like a potential reversion to virulence or a species-specific adaptation of the vaccine virus strains could be detected, leaving the question for the cause of rabies induction in the affected animals unanswered. Lastly, the successful implementation of a hybridization capturing system for the generation of full-genome sequences and deep-sequencing variant analyses of RABV and KBLV samples was demonstrated for a diagnostic bait set, highlighting the versatility and consistency of this approach to assess the genetic spectrum of known and novel lyssavirus species while setting the basis for its application and optimization in upcoming projects.In conclusion, as shown by the studies in this work, the investigation of lyssavirus genomes at the sub-consensus, full-genome and population level remains crucial to assess the complexity of lyssavirus evolution, as it provides an indispensable source of information to cover the diversity of the genus and understand evolutionary dynamics on a long-term and microevolutionary scale.