Interferon receptor-deficient mice are susceptible to eschar-associated rickettsiosis

  1. Thomas P Burke
  2. Patrik Engström
  3. Cuong J Tran
  4. Ingeborg M Langohr
  5. Dustin R Glasner
  6. Diego A Espinosa
  7. Eva Harris
  8. Matthew D Welch

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Abstract

Arthropod-borne rickettsial pathogens cause mild and severe human disease worldwide. The tick-borne pathogen Rickettsia parkeri elicits skin lesions (eschars) and disseminated disease in humans; however, inbred mice are generally resistant to infection. We report that intradermal infection of mice lacking both interferon receptors ( Ifnar1 -/- ;Ifngr1 -/- ) with as few as 10 R . parkeri elicits eschar formation and disseminated, lethal disease. Similar to human infection, eschars exhibited necrosis and inflammation, with bacteria primarily found in leukocytes. Using this model, we find that the actin-based motility factor Sca2 is required for dissemination from the skin to internal organs, and the outer membrane protein OmpB contributes to eschar formation. Immunizing Ifnar1 -/- ;Ifngr1 -/- mice with sca2 and ompB mutant R. parkeri protects against rechallenge, revealing live-attenuated vaccine candidates. Thus, Ifnar1 -/- ;Ifngr1 -/- mice are a tractable model to investigate rickettsiosis, virulence factors, and immunity. Our results further suggest that discrepancies between mouse and human susceptibility may be due to differences in interferon signaling.

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  1. Version published to 10.7554/elife.67029 on eLife
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    Reply to the reviewers

    Overall:

    We thank the reviewers for their thoughtful comments and suggestions on how to improve the manuscript. We also thank the reviewers for describing the study as “highly significant,” “rigorous and reliable as described and can be reproduced by others,” and as “relevant to investigators working in the field of rickettsial diseases and to a broader audience studying mechanisms of intracellular parasitism and host responses.”

    In this revised manuscript we have addressed all the minor points raised by the reviewers. In regard to additional experiments, all three reviewers suggested that we perform histology of skin lesions, and in a revised manuscript we propose to thoroughly address this by performing histology at multiple time points in infected wild type and in interferon receptor-deficient mice. We will also attempt to use immunohistochemistry to identify the infected cell types in the skin and in internal organs. We will compare these findings to histology of human eschars. We feel that the reviewer comments support our contention that a manuscript containing these proposed additional experiments will be of strong significance in the field.

    __Reviewer #1 (Evidence, reproducibility and clarity (Required)): __

    “Rickettsial eschars are hallmarks of less severe spotted fever diseases. The underlying mechanisms involved in the formation of the eschar caused by pathogenic rickettsiae remains unknown. The authors of this manuscript studied this interesting research question by using Ifnar-/-Ifngr-/- mice and Sca2 or OmpB mutant of R. parkeri. R. parkeri probably is the best rickettsial species to study rickettsial eschar due to the clinical features of R. parkeri rickettsioses and the biosafety level required to work with it. The data presented in the manuscript are very promising. The conclusions are supported by the presented results. For the first time, this study recapitulated human eschar-like skin lesion observed in patients with R. parkeri rickettsioses in the mouse models. More interestingly, mice inoculated with Sca2 mutant of R. parkeri i.d. had less disseminated rickettsiae in tissues, which helps us to understand the mechanisms by which pathogenic rickettsiae cause systemic infection after the arthropod bite.”

    **Minor comments: **

    “1) Figure 2D, it looks likely the lethality of mice i.d. infection with R. parkeri is not dose dependent. For example, mice inoculated with 10^4 showed greater lethality compared to 10^7. The authors might want to explain it in the Discussion.”

    The reviewer is correct in observing that the lethality between different doses of R. parkeri in Ifnar-/-Ifngr-/-mice after intradermal infection is not dose dependent with the current number of mice used per group. We do not understand the reason for this, and more broadly we don’t understand the mechanism of lethality. We speculate that there could be a bottleneck; however, answering this question will require future investigations into the mechanisms of lethality that are beyond the scope of this study. To address the reviewer’s point, we now include this statement: “Degrees of lethality between different doses in Ifnar-/-Ifngr-/- mice were not significantly different from one another, and the cause of lethality in this model remains unclear.”

    “2) Line 202, innate immunity in vitro might need to be revised.”

    We agree that the previous description was vague. We changed the description to be more specific and it now reads: “…Sca2 does not significantly enhance the ability of *R. parkeri *to evade interferon-stimulated genes or inflammasomes in vitro.

    “3) It is unclear what is the unit of the inoculum in animal experiments, PFU?”

    Yes, it is PFU. We have now indicated this in the figure legends.

    “4) Line 36, in the study of "Reference 16", C3H/HeN mice, not B6 mice, were used.”

    We thank the reviewer for noticing this error and we have changed the text to C3H/HeN.

    “5) The conclusion on eschar will be greatly strengthened if histological analysis is included, particularly whether dermis necrosis is present or not.”

    In the revised manuscript we will perform histology on eschars in wild type and Ifnar-/-Ifngr-/- mice over time. We will also use immunohistochemistry to analyze the infected cell types and will compare this to data on human eschars. We agree that this will greatly strengthen our conclusions regarding the similarities between the mouse and human eschars.

    “6) Line 357, it is not clear what "spinfection" means.”

    We have changed this to “infection” for clarity.

    “Reviewer #1 (Significance (Required)):* Several approaches employed in the study are new to the field of animal models of the rickettsioses. For example, fluorescent dextran was used to investigating the vascular damage in skin at the inoculation site; body temperature for mice infected with R. parkeri. Overall, the study is highly significant since it has answered the important questions in the research area of spotted fever rickettsioses and employed appropriate approaches. No major concerns were noticed.” *

    We thank the reviewer for appreciating the significance of this work.

    __**Referees cross commenting** __* I agree with other reviewers' comments. Thanks for the invite.”*

    Reviewer #2 (Evidence, reproducibility and clarity (Required)):

    “The manuscript utilizes a new model of spotted fever rickettsiosis. Using this model, the authors have determined that knockout of the sca2 or ompB gene attenuates Rickettsia parkeri, and vaccination with the attenuated rickettsiae provides protection against virulent challenge. However, the model is far less than ideal as it has eliminated important effectors of immunity.”

    We thank the reviewer for their comments and we hope to thoroughly address their concerns. In regard to the effects of interferons on long-lasting immunity to *R. parkeri, *we note to the reviewer that we observed that immunized Ifnar-/-Ifngr-/- mice were completely and robustly protected from rechallenge. No lethality and no loss of body weight or temperature was observed after a rechallenge dose of 10x the LD-50. These data reveal that interferons are dispensable for long-lasting immunity to *R. parkeri *in inbred mice and are not important effectors of adaptive immunity to R. parkeri. This is thus the first model that can be used to investigate the factors required for adaptive immunity to R. parkeri in mice.

    If the reviewer’s comment is not referring to long-lasting adaptive immunity to *R. parkeri *but is instead referring to the general concept of using immunocompromised mice as models, we note that immunocompromised mice are used as models for a variety of pathogens, including many *Rickettsia *species (reviewed in Osterloh, Med Microbiol Immunol 2017), and Ifnar-/-Ifngr-/- mice specifically are used as models for Zika and Dengue virus infections. Unlike many other immunocompromised mice, *Ifnar-/-Ifngr-/- *mice do not require maintenance on antibiotics and they have no noticeable differences to wild type mice in regard to breeding or growth.

    “Manuscript also fails to recognize that there is a Amblyomma maculatum tick transmitted model of Rickettsia parkeri infection that causes an eschar and disseminated pathology”

    In the previous version of the manuscript in lines 266-269 we cited and acknowledged the reported tick transmission model in non-human primates (Banajee et al., 2015). As also noted by Reviewer 3, our model with needle inoculation is significantly less time consuming and expensive than a tick transmission model. Moreover, needle inoculation makes it feasible to precisely measure the number of bacteria that are administered, which is not true with ticks. Lastly, the tick model was described in non-human primates, which are significantly more expensive than inbred mice and are not amenable to genetic manipulation. Thus, our model provides many significant advantages over the tick model in non-human primates, including cost, time, availability of genetic mutants, and reproducibility.

    *“The model that they have used is inadequately characterized. The cutaneous lesion was not evaluated histologically to determine if it features the actual characteristics of an eschar.” *

    We thank the reviewer for the suggestion and as a part of our revision plan, we propose to thoroughly analyze the lesion histologically.

    “Although bacteria were found in the liver and spleen, in which macrophages are significant target, there was no evaluation of the vital organs including lung and brain nor demonstration of the target cells or pathologic lesions.”

    In previous work from our lab (Engström et al., 2019), we found that lungs of wild type mice contained similar number of infectious *R. parkeri *as the spleen and liver after intravenous infection. Thus, in order to be able to process more samples quickly, we did not include lungs in the experiments described here. In unreported data, we also found that organs including the brain, kidneys, and heart had no/little recoverable PFUs. As a part of our revision plan, we propose to perform immunohistochemistry in the spleen, liver, lung, and skin to identify the infected cell types. Identifying the infected cell types will reveal if the same cell types are infected in our mouse model as in humans.

    “Unfortunately, the assay of vascular permeability was applied only to the inoculation site and not to the disseminated visceral organs such as lung and brain.”

    We have performed the vascular permeability assay using internal organs alongside the skin; however, little/no fluorescence was observed in any sample. We were unable to distinguish differences between control groups or between control and experimental groups in organs from mice that were treated and untreated with the fluorescent dextran. Thus, we were unfortunately not able to apply the described vascular damage assay to organs other than the skin. We now indicate this in the revised text.

    Reviewer #2 (Significance (Required)):

    “The authors all have misrepresented the eschar as a critically important lesion whereas the patients usually do not even know i's presence until they began to develop systemic symptoms and it is a detected by a physician examining the patient.”

    We did not intend to suggest that the eschar is either more or less critically important than other features of rickettsial disease. We simply described the eschar as a “hallmark feature” of eschar-associated rickettsiosis. Additionally, as the reviewer notes, patients report systemic symptoms, and our model elicits systemic disease by *R. parkeri *in mice. Thus, the model we describe recapitulates both an eschar and disseminated disease and is the first mouse model for *R. parkeri *that exhibits both of the disease manifestations mentioned by the reviewer.

    “On line 30 the authors state that mice are the natural reservoir of Rickettsia parkeri. The references cited describe the failure of acquisition by feeding ticks, meaning that it is not a true reservoir. The reference describing animals with antibodies merely indicates exposure to a spotted fever group Rickettsia not sufficient evidence of a role as a reservoir.”

    We thank the reviewer for making this important distinction and we have altered the text to read: “…small rodents including mice have been found as seropositive for *R. parkeri *in the wild.”

    “In response to the request for my expertise, I have contributed a large amount of data to understanding mechanisms of immunity to rickettsiae and have developed several useful animal models of Rickettsial diseases. I also have expertise on clinical aspects of spotted fever group rickettsioses, including the eschar.”

    **Referees cross commenting**

    “This is not the first Mouse model of rickettsiosis to contain an eschar. There is a model of Rickettsia parkeri transmitted by Amblyomma maculatum ticks in which eschars occur.”

    As noted above by us and also by Reviewer 3, we cited and discussed the tick transmission model in non-human primates (Banajee et al., 2015) in the Discussion. We also note to the reviewer the many advantages of our i.d. infection model, including how it will make these experiments more widely accessible, more reproducible, less expensive, faster, and enable the infection of mice with various genetic modifications.

    __Reviewer #3 (Evidence, reproducibility and clarity (Required)): __

    “This manuscript reports novel observations pertinent to development in inbred mice of an eschar lesion and generalized lethal infection following intradermal infection with Rickettsia parkeri, the mice are deficient in two types of interferon receptors. This is a new observation for the murine system and expands the existing repertoire of model infections for tick-borne rickettsiae. This study also reports that Sca2-mediated actin-based motility is required for R. parkeri dissemination and provides indirect evidence that OmpB protein is involved in eschar formation, thus corroborating previous knowledge about these major surface exposed antigens of rickettsiae and host cell interactions and host responses to these organisms.”

    “The study is rigorous and reliable as described and can be reproduced by others given availability of adequate funding, access to similar facilities, strains of mice and rickettsial mutants, and technical personnel with similar skills and training. There are no ethical or technical concerns.”

    We thank the reviewer for their thoughtful comments and for appreciating the advantages of this model.

    “The main limitation of the manuscript is due to the fact that histological and immunohistochemical analysis of the eschar was not performed; therefore, it is not clear if pathological processes and features of this lesion formation are the same or related to the human pathology.”

    We thank the reviewer for this suggestion. As a part of the revision plan, we propose to perform histological and immunohistochemical analysis of the eschar and will compare these findings to reported data from humans. We will also identify the cell types infected in the skin and internal organs in wild type and *Ifnar-/-Ifngr-/- *mice.

    “Similarly, in an attempt to generalize (as the authors try very hard), it is not clear how these observations will be relevant to rickettsial pathogens which are responsible for more severe forms of rickettsioses (such as R. rickettsii and R. prowazekii) but are not known to cause eschar formation as a part of their clinical manifestations.”

    Our findings with Sca2 are in agreement with findings on *R. rickettsii *Sca2 in guinea pigs (Kleba et al., 2010), which showed that Sca2 was required for eliciting fever and an antibody response. Our work also expands on these findings by showing that *sca2 *mutants immunize against rechallenge and by finding reduced bacterial burdens in internal organs after intradermal infection with *sca2 *mutant bacteria. Thus, we believe that studying *R. parkeri *genes in Ifnar-/-Ifngr-/- mice can serve as a model to better understand conserved virulence genes in diverse rickettsial pathogens.

    Beyond virulence genes, we note that our model also recapitulates systemic disease including dissemination to internal organs. Thus, it provides a platform to study disease manifestations beyond the eschar that may be relevant to other rickettsial pathogens including *R. rickettsii *and R. prowazekii.

    Some other virulent rickettsial pathogens cause limited/no disease in WT C57Bl/6 mice, including *R. akari, R. conorii, R. typhi, *and O. tsutsugamushi (reviewed in Osterloh, Med Microbiol Immunol 2017). Thus, *Ifnar-/-Ifngr-/- *mice may potentially serve as models for these pathogens. We now include this point in the Discussion.

    “The other deficiency is due to a limited description of the Sca2 and OmpB mutants used in this study. It was necessary to locate and review previous publications by this group in order to understand the experiments conducted here and their interpretation. It would be useful to the readers if this information (a better more complete description of the mutants and their properties) is summarized in this manuscript.”

    We have now provided a more complete description of the mutants in the Introduction and Results.

    __Reviewer #3 (Significance (Required)): __

    *“The study is relevant to investigators working in the field of rickettsial diseases and to a broader audience studying mechanisms of intracellular parasitism and host responses.

    The study argues that difference(s) in dermal IFN signaling mechanism(s) distinguish human and murine susceptibility to R. parkeri infection. This is a very useful speculation; however, a better and deeper discussion would be helpful to demonstrate the relevance of these observations and their connection(s) to events occurring during the course of human infections. Regrettably, there are almost no citations of classic or current literature addressing these aspects of rickettsial pathogenesis and the role of IFN-dependent mechanisms beyond self-citations. Overall, the discussion includes four relatively short paragraphs, each addressing different directions of possible research, which indicates ample possible utility of this murine model; however, a more coherent and convincing discussion is desirable.”*

    We thank the reviewer for the suggestion, and we have now expanded the Discussion to address the role for IFN-dependent mechanisms in humans and mice during rickettsial infections, including classic and current literature citations.

    **Referees cross commenting**

    “I agree with the Reviewer #2 that per se this is not the first murine model reproducing eschar upon A. maculatum transmission; however, this is the first model that allows to monitor eschar formation using needle inoculation. This model can be widely used; while many labs maybe limited by their facility setup and can't afford/conduct tick transmission experiments. The authors acknowledged existing of the tick transmission model and discuss inclusion of this option in their future experiments.”

    We thank the reviewer for recognizing the many advantages of this model.

  3. Review Commons

    Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

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    Referee #3

    Evidence, reproducibility and clarity

    This manuscript reports novel observations pertinent to development in inbred mice of an eschar lesion and generalized lethal infection following intradermal infection with Rickettsia parkeri, the mice are deficient in two types of interferon receptors. This is a new observation for the murine system and expands the existing repertoire of model infections for tick-borne rickettsiae. This study also reports that Sca2-mediated actin-based motility is required for R. parkeri dissemination, and provides indirect evidence that OmpB protein is involved in eschar formation, thus corroborating previous knowledge about these major surface exposed antigens of rickettsiae and host cell interactions and host responses to these organisms.

    The study is rigorous and reliable as described, and can be reproduced by others given availability of adequate funding, access to similar facilities, strains of mice and rickettsial mutants, and technical personnel with similar skills and training. There are no ethical or technical concerns.

    The main limitation of the manuscript is due to the fact that histological and immunohistochemical analysis of the eschar was not performed; therefore, it is not clear if pathological processes and features of this lesion formation are the same or related to the human pathology. Similarly, in an attempt to generalize (as the authors try very hard), it is not clear how these observations will be relevant to rickettsial pathogens which are responsible for more severe forms of rickettsioses (such as R. rickettsii and R. prowazekii) but are not known to cause eschar formation as a part of their clinical manifestations.

    The other deficiency is due to a limited description of the Sca2 and OmpB mutants used in this study. It was necessary to locate and review previous publications by this group in order to understand the experiments conducted here and their interpretation. It would be useful to the readers if this information (a better more complete description of the mutants and their properties) is summarized in this manuscript.

    Significance

    The study is relevant to investigators working in the field of rickettsial diseases, and to a broader audience studying mechanisms of intracellular parasitism and host responses.

    The study argues that difference(s) in dermal IFN signaling mechanism(s) distinguish human and murine susceptibility to R. parkeri infection. This is a very useful speculation; however, a better and deeper discussion would be helpful to demonstrate the relevance of these observations and their connection(s) to events occurring during the course of human infections. Regrettably, there are almost no citations of classic or current literature addressing these aspects of rickettsial pathogenesis and the role of IFN-dependent mechanisms beyond self-citations. Overall the discussion includes four relatively short paragraphs, each addressing different directions of possible research, which indicates ample possible utility of this murine model; however, a more coherent and convincing discussion is desirable.

    Referees cross commenting

    I agree with the Reviewer #2 that per se this is not the first murine model reproducing eschar upon A. maculatum transmission; however, this is the first model that allows to monitor eschar formation using needle inoculation. This model can be widely used; while many labs maybe limited by their facility setup and can't afford/conduct tick transmission experiments. The authors acknowledged existing of the tick transmission model and discuss inclusion of this option in their future experiments.

  4. Review Commons

    Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

    Learn more at Review Commons

    Referee #2

    Evidence, reproducibility and clarity

    The manuscript utilizes a new model of spotted fever rickettsiosis. Using this model, the authors have determined that knockout of the sca2 or ompB gene attenuates Rickettsia parkeri, and vaccination with the attenuated rickettsiae provides protection against virulent challenge. However, the model is far less than ideal as it has eliminated important effectors of immunity. Manuscript also fails to recognize that there is a Amblyomma maculatum tick transmitted model of Rickettsia parkeri infection that causes an eschar and disseminated pathology. The model that they have used is inadequately characterized. The cutaneous lesion was not evaluated histologically to determine if it features the actual characteristics of an eschar. Although bacteria were found in the liver and spleen, in which macrophages are significant target, there was no evaluation of the vital organs including lung and brain nor demonstration of the target cells or pathologic lesions. Unfortunately the assay of vascular permeability was applied only to the inoculation site and not to the disseminated visceral organs such as lung and brain.

    Significance

    The authors all have misrepresented the eschar as a critically important lesion whereas the patients usually do not even know i's presence until they began to develop systemic symptoms and it is a detected by a physician examining the patient.

    On line 30 the authors state that mice are the natural reservoir of Rickettsia parkeri. The references cited describe the failure of acquisition by feeding ticks, meaning that it is not a true reservoir. The reference describing animals with antibodies merely indicates exposure to a spotted fever group Rickettsia not sufficient evidence of a role as a reservoir.

    In response to the request for my expertise, I have contributed a large amount of data to understanding mechanisms of immunity to rickettsiae and have developed several useful animal models of Rickettsial diseases. I also have expertise on clinical aspects of spotted fever group rickettsioses, including the eschar.

    Referees cross commenting

    This is not the first Mouse model of rickettsiosis to contain an eschar.There is a model of Rickettsia parkeri transmitted by Amblyomma maculatum ticks in which eschars occur.

  5. Review Commons

    Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

    Learn more at Review Commons

    Referee #1

    Evidence, reproducibility and clarity

    Rickettsial eschars are hallmarks of less severe spotted fever diseases. The underlying mechanisms involved in the formation of the eschar caused by pathogenic rickettsiae remains unknown. The authors of this manuscript studied this interesting research question by using Ifnar-/-Ifngr-/- mice and Sca 2 or OmpB mutant of R. parkeri. R. parkeri probably is the best rickettsial species to study rickettsial eschar due to the clinical features of R. parkeri rickettsioses and the biosafety level required to work with it. The data presented in the manuscript are very promising. The conclusions are supported by the presented results. For the first time, this study recapitulated human eschar-like skin lesion observed in patients with R. parkeri rickettsioses in the mouse models. More interestingly, mice inoculated with Sca2 mutant of R. parkeri i.d. had less disseminated rickettsiae in tissues, which helps us to understand the mechanisms by which pathogenic rickettsiae cause systemic infection after the arthropod bite.

    Minor comments:

    1)Figure 2D, it looks likely the lethality of mice i.d. infection with R. parkeri is not dose-dependent. For example, mice inoculated with 10^4 showed greater lethality compared to 10^7. The authors might want to explain it in the "Discussion".

    2)Line 202, innate immunity in vitro might need to be revised.

    3)It is unclear what is the unit of the inoculum in animal experiments, PFU?

    4)Line 36, in the study of "Reference 16", C3H/HeN mice, not B6 mice, were used.

    5)The conclusion on eschar will be greatly strengthened if histological analysis is included, particularly whether dermis necrosis is present or not.

    6)Line 357, it is not clear what "spinfection" means.

    Significance

    Several approaches employed in the study are new to the field of animal models of the rickettsioses. For example, fluorescent dextran was used to investigating the vascular damage in skin at the inoculation site; body temperature for mice infected with R. parkeri. Overall, the study is highly significant since it has answered the important questions in the research area of spotted fever rickettsioses and employed appropriate approaches. No major concerns was noticed.

    Referees cross commenting

    I agree with other reviewers' comments. Thanks for the invite.

  6. Version published to 10.1101/2020.09.23.310409v2 on bioRxiv
  7. Version published to 10.1101/2020.09.23.310409v1 on bioRxiv