Resilience and virus ecol...

Title: Resilience and virus ecology of paleotropical bats

Type Dataset Seltmann, Anne, Corman, Victor M, Rasche, Andrea, Drosten, Christian, Courtiol, Alexandre, Czirjak, Gabor A, Bernard, Henry, Struebig, Matthew, Voigt, Christian (2020): Resilience and virus ecology of paleotropical bats. Zenodo. Dataset. https://zenodo.org/record/3948443

Authors: Seltmann, Anne (Leibniz Institute for Zoo and Wildlife Research) ; Corman, Victor M ; Rasche, Andrea ; Drosten, Christian ; Courtiol, Alexandre ; Czirjak, Gabor A ; Bernard, Henry ; Struebig, Matthew ; Voigt, Christian ; The SAFE Project (Imperial College London) ;

Summary

Description:

Emerging infectious diseases (EIDs) are a threat to human and animal health. Bats are known reservoir hosts for various highly fatal viruses associated with EIDs. Previously, outbreaks of some EIDs were directly associated with environmental conditions, namely an increased contact zone between reservoir hosts and humans resulting from bush-meat consumption and increasing anthropogenic land-use. However, anthropogenic land-use, especially habitat logging and fragmentation, may also take effect via consequences upon wildlife communities, including population declines. Before effects manifest in decreased population sizes, individuals may show changes in physiological parameters. In this project, I investigated if habitat logging and fragmentation are associated with changes in body mass, levels of chronic stress, immunity and occurrence of viruses in bats. I sampled individuals of eight bat species of the genus Rhinolophus, Hipposideros and Kerivoula at the SASFE project in Sabah, Malaysia. I found that individuals of foliage-roosting bat species weighed less in currently logged and recently fragmented habitats and had lower white blood cell counts than their conspecifics from undisturbed forests. In a cave-roosting species (Rhinolophus borneensis) individuals from fragmented forests showed higher levels of chronic stress (indicated by the neutrophil to lymphocyte ratio) than conspecifics from actively logged forests. Overall, I conclude that foliage-roosting bat species may be particularly vulnerable to habitat fragmentation, affecting their overall health including cell-mediated immunity.Further, I investigated if the detrimental effects of habitat logging andfragmentation on the overall health of bats are reflected in increased detection rates of corona- and astroviruses in fecal samples of bats in the same study site. An increase in detection rates may increase the risk for pathogen spill-overs from bats to humans. Unexpectedly, the detection rates were not associated with habitat logging and fragmentation in any species. However, I identified the rainy season as a risk factor for increased astrovirus shedding. Further, individuals in poor body condition tended to have a higher risk for astrovirus shedding.In conclusion, foliage-roosting bat species may turn into a source for future viral spillover events if they are sufficiently resistant to remain in logged and fragmented habitats. Ongoing landscape fragmentation in Southeast Asia and worldwide will reduce the connectivity of remaining habitats, resulting in lower mobility and genetic diversity of bats within a species in future generations. These bat populations may have a higher susceptibility to contract and shed viruses especially during the rainy season. If humans or their livestock live nearby, these viruses or other pathogens may spill over in new hosts.

Project: This dataset was collected as part of the following SAFE research project: Resilience and virus ecology of paleotropical bats

Funding: These data were collected as part of research funded by:

German Research Council (Research grant, DFG Priority Programm 1596; Vo890/23, DR772/10-1 and 2)UK NERC Natural Environment Research Council (Research grant, HTMF Human-Modified Tropical Forests program under the LOMBoK Land-Use Options for Maintaining Biodiversity and Ecosystem Function consortium)

This dataset is released under the CC-BY 4.0 licence, requiring that you cite the dataset in any outputs, but has the additional condition that you acknowledge the contribution of these funders in any outputs.

Permits: These data were collected under permit from the following authorities:

Sabah Biodiversity Council (Research licence JKM/MBS.1000-2/2 JLD.3 (153))Sabah Biodiversity Council (Research licence JKM/MBS.1000-2/2 JLD.3 (317))Sabah Biodiversity Council (Research licence JKM/MBS.1000-2/3 JLD.2 (16))

XML metadata: GEMINI compliant metadata for this dataset is available here

Files: This dataset consists of 2 files: Seltmann_bat_data_V2.xlsx, Traps2014.2015.gpx

Seltmann_bat_data_V2.xlsx

This file contains dataset metadata and 9 data tables:

ACTH_challenge (described in worksheet ACTH_challenge)

Description: ACTH challenge

Number of fields: 17

Number of data rows: 15

Fields:

Viral_fecal_samples (described in worksheet Viral_fecal_samples)

Description: Viral prevalences 03-04 2015

Number of fields: 31

Number of data rows: 790

Fields:

Overview_3 (described in worksheet Overview_3)

Description: Viral prevalences 03-04 2015

Number of fields: 4

Number of data rows: 7

Fields:

Species: Species of bat (Field type: taxa)Scientific_name: Scientific name of bat (Field type: comments)Total_urine_samples: Total number of urine samples (Field type: numeric trait)Total_fecal_samples: Total number of fecal samples (Field type: numeric trait)

Sequences (described in worksheet Sequences)

Description: Coronavirsu sequences

Number of fields: 3

Number of data rows: 5

Fields:

ID: Bat ID. Start with year, e.g. 140001 is the first bat caught in 2014. Numbers starting with Q follow Dave Bennett's and Victoria Kemp's consecutive capture numbers, numbers starting without a lettter or with "L" only appear in my dataset. (Field type: id)Species: Species of bat sampled (Field type: taxa)Gene_seq: Gene sequence code (Field type: comments)

IgG_BKA (described in worksheet IgG_BKA)

Description: IgGs and BKA

Number of fields: 28

Number of data rows: 44

Fields:

Location: Location within the SAFE landscape (Field type: location)Capture: Bat ID. Start with year, e.g. 140001 is the first bat caught in 2014. Numbers starting with Q follow Dave Bennett's and Victoria Kemp's consecutive capture numbers, numbers starting without a lettter or with "L" only appear in my dataset. (Field type: id)Band: Ring-Number (Field type: id)Date: Date of sampling (Field type: date)Trap: Trap ID (Field type: id)Species: Species of bat sampled (Field type: taxa)R: Recapture (Field type: categorical trait)Sex: Sex of bat (Field type: categorical trait)Age: Age of bat (A - adult) (Field type: categorical trait)Rep: Reproductive status (L - lactating, PL - postlacting, RPL - recently postlactating, Pr - Pregnant, NR - non reproductive) (Field type: categorical trait)Forearm length: Forearm length (Field type: numeric trait)Weight: Biomass of bat (Field type: numeric trait)BC: Body condition (mass divided by forearm) (Field type: numeric trait)Fed: Feeding status (Field type: categorical trait)O: Oral swab (Field type: numeric trait)U: Urine swab (Field type: numeric trait)F: fecal sample (Field type: numeric trait)FS: fecal swab (Field type: numeric trait)BS: blood smear (Field type: numeric trait)B1: blood sample before ACTH injection (Field type: numeric trait)T1: temperature before ACTH injection (Field type: numeric trait)B2: blood sample after ACTH injection (Field type: numeric trait)T2: temperature after ACTH injection (Field type: numeric trait)W: Wing punch (Field type: numeric trait)Iggs1: IgGs (optical density) measured before blood injected with hormone ACTH intraperitoneal (Field type: numeric trait)Iggs2: IgGs (optical density) measured 2.5 hours after blood injected with hormone ACTH intraperitoneal (Field type: numeric trait)BKA1: "The BKA is a constitutive innate marker of the immune system and measures humoral and cellular components in function of the sample used. While using whole blood is possible to quantify the overall constitutive innate immunity of an individual44, with serum or plasma samples only the humoral part is measured45,46. We assessed the bacterial killing activity (BKA) of the plasma against E. coli in vitro following the method of Schneeberger et al.47. The BKA of plasma is a functional marker of the humoral part of the constitutive innate immunity45,46. Plasma samples were diluted 1:50 in sterile PBS and we added 10 µl of a suspension of living E. coli (ATCC #8739) to each diluted sample (140 µl). The bacterial suspension was adjusted to a concentration of ~200 colonies per 50 µl plasma-bacteria mixture. The mixtures were then incubated for 30 min at 37°C. After incubation, 50 µl aliquot of the vortexed mixture was spread onto Tryptic Soy Agar plates in duplicate, followed by overnight incubation at 37°C. To obtain the initial number of bacteria that we had before starting to interact with the plasma, we diluted 140 µl PBS with bacterial suspension and plated in similar ways. On the following day, the colony-forming units were counted and the bacterial killing activity was defined as percent of the killed bacteria, which was calculated as 1-(average of viable bacteria after incubation / the initial number of bacteria47). 45 Heinrich, S. K. et al. Feliform carnivores have a distinguished constitutive innate immune response. Biol. Open 5, 550-555 (2016). 46 Heinrich, S. K. et al. Cheetahs have a stronger constitutive innate immunity than leopards. Sci. Rep. 7, 44837 (2017). 47 Schneeberger, K., Czirják, G. Á. & Voigt, C. C. Measures of the constitutive immune system are linked to diet and roosting habits of Neotropical bats. PLoS One 8, e54023 (2013). (Field type: numeric trait)BKA2: "The BKA is a constitutive innate marker of the immune system and measures humoral and cellular components in function of the sample used. While using whole blood is possible to quantify the overall constitutive innate immunity of an individual44, with serum or plasma samples only the humoral part is measured45,46. We assessed the bacterial killing activity (BKA) of the plasma against E. coli in vitro following the method of Schneeberger et al.47. The BKA of plasma is a functional marker of the humoral part of the constitutive innate immunity45,46. Plasma samples were diluted 1:50 in sterile PBS and we added 10 µl of a suspension of living E. coli (ATCC #8739) to each diluted sample (140 µl). The bacterial suspension was adjusted to a concentration of ~200 colonies per 50 µl plasma-bacteria mixture. The mixtures were then incubated for 30 min at 37°C. After incubation, 50 µl aliquot of the vortexed mixture was spread onto Tryptic Soy Agar plates in duplicate, followed by overnight incubation at 37°C. To obtain the initial number of bacteria that we had before starting to interact with the plasma, we diluted 140 µl PBS with bacterial suspension and plated in similar ways. On the following day, the colony-forming units were counted and the bacterial killing activity was defined as percent of the killed bacteria, which was calculated as 1-(average of viable bacteria after incubation / the initial number of bacteria47). 45 Heinrich, S. K. et al. Feliform carnivores have a distinguished constitutive innate immune response. Biol. Open 5, 550-555 (2016). 46 Heinrich, S. K. et al. Cheetahs have a stronger constitutive innate immunity than leopards. Sci. Rep. 7, 44837 (2017). 47 Schneeberger, K., Czirják, G. Á. & Voigt, C. C. Measures of the constitutive immune system are linked to diet and roosting habits of Neotropical bats. PLoS One 8, e54023 (2013). (Field type: numeric trait)

Leukocytes (described in worksheet Leukocytes)

Description: Leukocyte counts

Number of fields: 37

Number of data rows: 57

Fields:

Site: Location within the SAFE landscape (Field type: location)Transect: Transect within SAFE block (Field type: replicate)Trap: Trap ID (Field type: id)Capture: Bat ID. Start with year, e.g. 140001 is the first bat caught in 2014. Numbers starting with Q follow Dave Bennett's and Victoria Kemp's consecutive capture numbers, numbers starting without a lettter or with "L" only appear in my dataset. (Field type: id)Band: Ring-Number (Field type: id)Date: Date of sampling (Field type: date)Time: Time of sampling (Field type: time)Species: Species of bat sampled (Field type: taxa)Recapture: Recapture (uk - unknown) (Field type: categorical trait)Age: Age of bat sampled (Field type: categorical trait)Rep: Reproductive status (L - lactating, PL - postlacting, RPL - recently postlactating, Pr - Pregnant, NR - non reproductive) (Field type: categorical trait)Sex: Sex of bat sampled (Field type: categorical trait)Forearm: Forearm length (Field type: numeric trait)Body mass: Biomass of bat (Field type: numeric trait)Fed: Feeding status (Field type: categorical trait)O: Oral swab (Field type: numeric trait)U: Urine swab (Field type: numeric trait)F: fecal sample (Field type: numeric trait)FS: fecal swab (Field type: numeric trait)BS: blood smear (Field type: numeric trait)B1: blood sample before ACTH injection (Field type: numeric trait)T1: temperature before ACTH injection (Field type: numeric trait)B2: blood sample after ACTH injection (Field type: numeric trait)T2: temperature after ACTH injection (Field type: numeric trait)Parasites: Parasites on bat (Field type: comments)W: Wing punch (Field type: numeric trait)CommentsEnglish: Blood sample comments (Field type: comments)Eosinophiles: Eosinophiles (Field type: numeric trait)Basophiles: Basophiles (Field type: numeric trait)Neutrophiles: Neutrophiles (Field type: numeric trait)Monocytes: Monocytes (Field type: numeric trait)Lymphocytes: Lymphocytes (Field type: numeric trait)CommentsGerman: Comments in german (Field type: comments)NL-ratio: NL-ratio (Field type: numeric trait)Monolayers: Monolayers (Field type: numeric trait)Leukocytes: Leukocytes (Field type: numeric trait)Mean_leukocytes_monolayer: Proportion of monolayers with leukocytes (Field type: numeric trait)

PCR (described in worksheet PCR)

Description: PCR analysis

Number of fields: 10

Number of data rows: 78

Fields:

ID: Bat ID (Field type: id)Species: Species of bat sampled (Field type: taxa)Location: Location within the SAFE landscape (Field type: location)Ct_bIL-6: ? (Field type: numeric trait)Ct_bSTAT1: ? (Field type: numeric trait)Ct_bMAPK: ? (Field typ

More information

DOI: 10.5281/zenodo.3948443

Subjects

Bats, Harp trapping, Anthropogenic disturbance, body mass, chronic stress, fragmentation, white blood cell count, coronaviruses, astroviruses, coinfection, habitat fragmentation, human-modified landscapes

Dates

Publication date: 2020
Issued: July 16, 2020

Rights

https://creativecommons.org/licenses/by/4.0/legalcode Creative Commons Attribution 4.0 International
info:eu-repo/semantics/openAccess Open Access

Format

electronic resource

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		IsVersionOf	https://doi.org/10.5281/zenodo.3948442
		IsPartOf	https://zenodo.org/communities/safe
		IsPartOf	https://zenodo.org/communities/zenodo

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Title: Resilience and virus ecology of paleotropical bats

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