Sage Journals: Discover world-class research

Abstract

Background:

Throughout Armenia, a range of climate conditions exist, from dry subtropical to cold alpine, with a topographic diversity from 400 to 4,100 meters above sea level. Climate analysis has suggested what the territory of Armenia may experience in response to climate change. The persistence of tularemia in Armenia, in conjunction with observed ecological trends, indicates that host reservoir distributions are likely to shift, consequently altering the geographic regions at risk of transmission. This study endeavors to evaluate the potential effects of climate change on the habitat suitability and population dynamics of the common vole, the principal reservoir of Francisella tularensis in Armenia. The objectives aim to elucidate prospective changes in disease-endemic areas, thereby informing targeted control strategies to mitigate pathogen dissemination and reduce public health risks associated with tularemia.

Methods:

Field and laboratory data from 2000 to 2023 on the common vole and presence of tularemia were compiled from the National Center for Disease Control and Prevention archived records. For spatial and geostatistical analyses, data were compiled from monthly historical temperature and precipitation records from 2000 to 2021 and forecasted data from the WorldClim database. Data were analyzed using a geographic information system.

Results:

The comparison of current climate data with predictive models indicates a likely shift in regions with favorable habitats for the common vole. By 2100, areas below 2,000 meters are projected to partially lose suitability, the conditions there could be less suitable for particular animal species. Currently, the common vole’s habitat area is above an altitude of 1,400 meters above sea level but by 2100, changes in climate suggest the habitat will shift above an altitude of 2,000 meters above sea level.

Conclusion:

The vole distribution shrinks because of the change in habitats attributed to climate change. This dynamic underscores the critical need for more targeted surveillance and integrated collaboration between human and animal health agencies to effectively monitor alterations in the ecology of zoonotic diseases. Such proactive measures are essential to anticipate and prevent future cases of human tularemia, ensuring a coordinated response to emerging public health threats.

Keywords

climate change tularemia common vole Armenia geographic information system

Get full access to this article

View all access options for this article.

References

ANIMALIA. Animalia: Common vole. 2021. Available from: https://www.animalia.bio/common-vole [Last accessed: June 12, 2024].

Bartlow

, Manore

, Xu

, et al. Forecasting zoonotic infectious disease response to climate change: Mosquito vectors and a changing environment. Vet Sci, 2019; 6(2):40.

Basilova

, Nekrasov

, Velidzhanashvili

, et al. Results of studying cultures of the tularemia microbe isolated in various natural foci. Particularly dangerous information in the Caucasus. Stavropol, 1987:190–192. (in Russian)

Basilova

, Nekrasov

, Pilipenko

. Culture properties of the causative agent of tularemia isolated in natural foci in Stavropol Territory, the Kalmyk ASSR and the Armenian SSR. Zh Mikrobiol Epidemiol Immunobiol, 1983(1):40–42. (in Russian)

Carlson

, Albery

, Merow

, et al. Climate change increases cross-species viral transmission risk. Nature, 2022; 607(7919):555–562.

Dobrokhotov

, Mnatsakanian

, Meshcheriakova

, Rudnev

. Exploration of natural foci of tularemia and plague in Armenia using the serological examination of bird droppings and excrements of predatory mammals. Zh Mikrobiol Epidemiol Immunobiol, 1978(2):111–115. (in Russian)

EU4CLIMATE. Better Climate Policies for Eastern Partner Countries—Armenia. 2024. Available from: https://eu4climate.eu/armenia [Last accessed: June 12, 2024].

European Centre for Disease Control. Factsheet on tularemia. 2024. Available: Available from: https://www.ecdc.europa.eu/en/tularaemia/facts [Last accessed: June 12, 2024].

Government of the Republic of Armenia. The Strategic Program for the Prevention of Communicative Diseases in the Republic of Armenia and the Entry of the Strategic Program. arlis.am; 2012.

10.

Grigoryan

. Fourth National Communication on Climate Change. Ministry of Environment Republic of Armenia; 2020.

11.

International Union for Conservation of Nature and Natural Resources. IUCN Red List—Common Vole. 2023. Available from: https://www.iucnredlist.org/species/13488/22351133 [Last accessed: June 12, 2024].

12.

Kosoy

, Imnadze

, Malania

, et al. Atlas of Zoonotic Diseases in the South Caucasus. LEPL National Centre for Disease Cotrol and Public Health (NCDC): Georgia; 2024.

13.

Leal Filho

, Ternova

, Parasnis

, et al. Climate Change and Zoonoses: A Review of Concepts, Definitions, and Bibliometrics. Int J Environ Res Public Health, 2022; 19(2):893.

14.

Manucharyan

. Epizootological, characteristics of the natural focus of tularemia in the Southeast part of the Republic of Armenia. Doctoral PhD, National Academy of Sciences; 2023. Available from: https://sczhe.sci.am/wp-content/uploads/2024/12/Arsen_manucharyan.pdf

15.

Manucharyan

, Achenbach

, Paronyan

, et al. Gamasid Ticks as Vectors of Tularemia in the Southeast of Armenia. Vector-Borne and Zoonotic Diseases, 2023a;23(5):284–290.

16.

Manucharyan

, Danielyan

, Melik-Andreasyan

. Characteristics of the Epizootic activity of the focus of tularemia in the Southeastern region of the republic of Armenia 1970–2018. Climate Changes: Adaptation: Yerevan, Armenia, 2023b. Available from: http://elib.sci.am/2023_1/06_1_2023.pdf

17.

Manucharyan

, Danielyan

, Melik-Andreasyan

, et al. Results of Field and Laboratory Studies of Carriers and Vectors of Natural-Focal Infections on the Territory of the Republic of Armenia. Problems of Especially Dangerous Infections, 2022; 4:90–95. (in Russian)

18.

Meeussen

SEJ

, Hof

. Predicted Future Benefits for an Endemic Rodent in the Irano-Turanian Region. Climate, 2021; 9(1):16.

19.

Melikjanyan

, Palayan

, Vanyan

, et al. Human Cases of Tularemia in Armenia, 1996–2012. Am J Trop Med Hyg, 2017; 97(3):819–825.

20.

Ministry of Economy Republic of Armenia. Hydrometerology and Monitoring Center. 2018. Available from: https://www.meteomonitoring.am/#home [Last accessed: June 12, 2024].

21.

Ministry of Justice of the Republic of Armenia. Concerning approval of Climate Change adaptability agenda list of measures in the agricultural sector. 2016. Available from: https://www.e-draft.am/en/projects/4888/justification [Last accessed: June 12, 2024].

22.

Nakazawa

, Williams

, Peterson

, et al. Climate Change Effects on Plague and Tularemia in the United States. Vector-Borne and Zoonotic Diseases, 2007; 7(4):529–540.

23.

National Center for Disease Control and Prevention. Epidemic situation, Armenia. ncdc.am. 2025. Available from: https://ncdc.am/activity/newsletters/epidemic-situation/ [Last accessed: January 15, 2025].

24.

Ouagrham-Gormley

, Melikishvili

, Zilinskas

. 2008. The Anti-plague System in the Newly Independent States, 1992 and Onwards: Assessing Proliferation Risks and Potential for Enhanced Public Health in Central Asia and the Caucasus. In: Chapter I: The Anti-plague System of Armenia. James Martin Center for Nonproliferation Studies Monterey Institute of International Studies Monterey, California. https://nonproliferation.org/wp-content/uploads/cns-archive/antiplague/080103_part2_ch01.pdf

25.

Parmesan

, Yohe

. A globally coherent fingerprint of climate change impacts across natural systems. Nature, 2003; 421(6918):37–42.

26.

Parmesan

. Ecological and Evolutionary Responses to Recent Climate Change. Annual Review of Ecology, Evolution, and Systematics, 2006; 37(1):637–669.

27.

Pollitzer

. A Review of Selected Problems of Tularemia in the Soviet Union. The Institute of Contemporary Russian Studies; 1963.

28.

Revich

, Tokarevich

, Parkinson

. Climate change and zoonotic infections in the Russian Arctic. Int J Circumpolar Health, 2012; 71:18792.

29.

Rowe

, Rowe

KMC

, Tingley

, et al. Spatially heterogeneous impact of climate change on small mammals of montane California. Proc R Soc B, 2015; 282(1799):20141857.

30.

Rydén

, Sjöstedt

, Johansson

. Effects of climate change on tularaemia disease activity in Sweden. Glob Health Action, 2009; 2:2063.

31.

Statistical Committee Republic of Armenia. Statistical Data. 2017. Available from: https://www.armstat.am/en/ [Last accessed: June 12, 2024].

32.

The Lancet Infectious Diseases. Twin threats: Climate change and zoonoses. The Lancet Infectious Diseases, 2023; 23(1):1.,

33.

U.S. Fish and Wildlife Service. Amargosa vole (Microtus californicus scirpensis). 5-Year Review: Summary and Evaluation. 2022. Available from: https://ecosphere-documents-production-public.s3.amazonaws.com/sams/public_docs/species_nonpublish/3936.pdf

34.

USGS. Science Data Catalog (SDS). 2025. Available from: https://data.usgs.gov/datacatalog/data/USGS:77ae0551-c61e-4979-aedd-d797abdcde0e [Last accessed: January 1, 2025].

35.

WORLDCLIM. Global climate and weather data. 2022. Available from: https://www.worldclim.org/ [Last accessed: June 12, 2024].

Assessing the Impact of Climate Change on the Habitat of the Common Vole,an Important Host of Tularemia in Armenia

Abstract

Background:

Methods:

Results:

Conclusion:

Keywords

Get full access to this article

References