Top

Published in:

17-04-2018

Humans and urban development mediate the sympatry of competing carnivores

Authors: Remington J. Moll, Jonathon D. Cepek, Patrick D. Lorch, Patricia M. Dennis, Terry Robison, Joshua J. Millspaugh, Robert A. Montgomery

Published in: Urban Ecosystems | Issue 4/2018

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Humans can profoundly shape animal community dynamics, but such effects have rarely been evaluated for terrestrial carnivores. Humans affect carnivores in both spatial and temporal dimensions via the chance of human encounter and alteration of the landscape through urban development. We investigated three hypotheses regarding how humans mediate the sympatry of larger, dominant carnivores with their smaller, subordinate counterparts. We tested these hypotheses by examining the spatio-temporal dynamics of a dominant carnivore (coyote Canis latrans) and its subordinate competitor (red fox Vulpes vulpes) across an extensive urban park system. We found that dominant and subordinate carnivores exhibited strong and often opposing spatio-temporal responses to the probability of human encounter and urban development. Spatially, coyotes visited more highly developed sites less frequently while red foxes exhibited an opposing response. Temporally, both species avoided humans via nocturnal activity. Spatio-temporally, red foxes avoided coyotes at all sites and avoided humans at highly developed sites, whereas coyotes showed a positive association with humans at such sites. Our analysis indicates that areas with higher urban development might act as spatial refugia for some subordinate carnivores against interference from larger, dominant carnivores (a “human shield” effect). Our findings also reveal that broad-scale spatial avoidance is likely a crucial component of coexistence between larger, dominant carnivores and humans, whereas finer-scale spatio-temporal avoidance is likely a key feature of coexistence between humans and smaller, subordinate carnivores. Overall, our study underscores the complex and pervasive nature of human influence over the sympatry of competing carnivores inhabiting urban systems.

previous article Spatial and genetic distribution of a north American termite, Reticulitermes flavipes, across the landscape of Paris

next article Birds biodiversity in urban and periurban forests: environmental determinants at local and landscape scales

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Available only for authorised users

Adkins CA, Stott P (1998) Home ranges, movements and habitat associations of red foxes Vulpes vulpes in suburban Toronto, Ontario, Canada. J Zool 244:335–346CrossRef

Barbieri MM, Berger JO (2004) Optimal predictive model selection. Ann Stat 32:870–897CrossRef

Bejder L, Samuels A, Whitehead H, Gales N (2006) Interpreting short-term behavioral responses to disturbance within a longitudinal perspective. Anim Behav 72:1149–1158CrossRef

Berger J (2007) Fear, human shields and the redistribution of prey and predators in protected areas. Biol Lett 3:620–623CrossRefPubMedPubMedCentral

Burton AC, Neilson E, Moreira D, Ladle A, Steenweg R, Fisher JT, Bayne E, Boutin S (2015) Wildlife camera trapping: a review and recommendations for linking surveys to ecological processes. J Appl Ecol 52:675–685CrossRef

Cleveland Metroparks. (2017) Cleveland Metroparks by the numbers. In: Clevel. Metroparks.com. https://www.clevelandmetroparks.com/about/cleveland-metroparks-organization/by-the-numbers. Accessed 6 Dec 2017

Crooks KR, Riley SPD, Gehrt SD et al (2010) Community ecology of urban carnivores. In: Gehrt SD, Riley SPD, Cypher BL (eds) Urban carnivores: ecology, conflict, and conservation. The Johns Hopkins University Press, Baltimore, Maryland, USA, pp 185–200

Crooks KR, Soulé ME (1999) Mesopredator release and avifaunal extinctions in a fragmented system. Nature 400:563–566CrossRef

Darimont CT, Carlson SM, Kinnison MT et al (2009) Human predators outpace other agents of trait change in the wild. Proc Natl Acad Sci 106:8–10CrossRef

Darimont CT, Fox CH, Bryan HM, Reimchen TE (2015) The unique ecology of human predators. Science 80(349):858–861CrossRef

Dirzo R, Young HS, Galetti M et al (2014) Defaunation in the Anthropocene. Science 80(345):401–406CrossRef

Dorresteijn I, Schultner J, Nimmo DG, Fischer J, Hanspach J, Kuemmerle T, Kehoe L, Ritchie EG (2015) Incorporating anthropogenic effects into trophic ecology: predator–prey interactions in a human-dominated landscape. Proc R Soc B Biol Sci 282:20151602CrossRef

Dröge E, Creel S, Becker MS, M’soka J (2017) Risky times and risky places interact to affect prey behaviour. Nat Ecol Evol 1:1123–1128CrossRefPubMed

Ellis EC (2011) Anthropogenic transformation of the terrestrial biosphere. Philos Trans R Soc A Math Phys Eng Sci 369:1010–1035CrossRef

Fischer JD, Cleeton SH, Lyons TP, Miller JR (2012) Urbanization and the predation paradox: the role of trophic dynamics in structuring vertebrate communities. Bioscience 62:809–818CrossRef

Forman RTT (2016) Urban ecology principles: are urban ecology and natural area ecology really different? Landsc Ecol 31:1653–1662CrossRef

Frey S, Fisher JT, Burton AC, Volpe JP (2017) Investigating animal activity patterns and temporal niche partitioning using camera-trap data: challenges and opportunities. Remote Sens. Ecol Conserv:1–10

Frid A, Dill L (2002) Human-caused disturbance stimuli as a form of predation risk. Ecol Soc 6:11

Gallo T, Fidino M, Lehrer EW, Magle SB (2017) Mammal diversity and metacommunity dynamics in urban green spaces: implications for urban wildlife conservation. Ecol Appl 0:1–12

Gehr B, Hofer EJ, Muff S et al (2017) A landscape of coexistence for a large predator in a human dominated landscape. Oikos:1–11

Gehrt SD, Anchor C, White LA (2009) Home range and landscape use of coyotes in a metropolitan landscape: conflict or coexistence? J Mammal 90:1045–1057CrossRef

Gehrt SD, Brown JL, Anchor C (2011) Is the urban coyote a misantrhopic synanthrope? The case from Chicago. Cities Environ 4:3CrossRef

Gehrt SD, Riley SPD (2010) Coyotes (Canis latrans). In: Gehrt SD, Riley SPD, Cypher BL (eds) Urban carnivores: ecology, conflict, and conservation. The Johns Hopkins University Press, Baltimore, Maryland, USA, pp 79–96

Gelman A, Hill J (2007) Data analysis using regression and multilevel/hierarchical models. Cambridge University Press, New York, New York

Goad EH, Pejchar L, Reed SE, Knight RL (2014) Habitat use by mammals varies along an exurban development gradient in northern Colorado. Biol Conserv 176:172–182CrossRef

Gompper ME (2002) Top carnivores in the suburbs? Ecological and conservation issues raised by colonization of northeastern North America by coyotes. Bioscience 52:185CrossRef

Gosselink TE, Van DTR, Warner RE, Joselyn MG (2003) Temporal habitat partitioning and spatial use of coyotes and red foxes in east-Central Illinois. J Wildl Manag 67:90–103CrossRef

Gosselink TE, Van Deelen TR, Warner RE et al (2007) Survival and cause-specific mortality of red foxes in agricultural and urban areas of Illinois. J Wildl Manag 71:1862–1873CrossRef

Greene W (2008) Functional forms for the negative binomial model for count data. Econ Lett 99:585–590CrossRef

Harrison DJ, Bissonette JA, Sherburne JA (1989) Spatial relationships between coyotes and red foxes in eastern Maine. J Wildl Manag 53:181–185CrossRef

Hartigan JA, Wong MA (1979) Algorithm AS 136: a K-means clustering algorithm. J R Stat Soc C 28:100–108

Hooten MB, Hobbs ANT (2015) A guide to Bayesian model selection for ecologists. Ecol Monogr 85:3–28CrossRef

Karanth KU, Srivathsa A, Vasudev D, Puri M, Parameshwaran R, Kumar NS (2017) Spatio-temporal interactions facilitate large carnivore sympatry across a resource gradient. Proc R Soc B Biol Sci 284:20161860CrossRef

Kays R, Parsons AW, Baker MC et al (2016) Does hunting or hiking affect wildlife communities in protected areas? J Appl Ecol 54:242–252CrossRef

Kays RW, Gompper ME, Ray JC (2008) Landscape ecology of eastern coyotes based on large-scale estimates of abundance. Ecol Appl 18:1014–1027CrossRefPubMed

Kéry M, Royle JA (2015) Applied hierarchical modeling in ecology: analysis of distribution, abundance and species richness in R and BUGS / volume 1. Prelude and static models, Elsevier, San Diego, California

Kuijper DPJ, Bubnicki JW, Churski M, Mols B, van Hooft P (2015) Context dependence of risk effects: wolves and tree logs create patches of fear in an old-growth forest. Behav Ecol 26:1558–1568CrossRef

Kuijper DPJ, Sahlén E, Elmhagen B, Chamaillé-Jammes S, Sand H, Lone K, Cromsigt JPGM (2016) Paws without claws? Ecological effects of large carnivores in anthropogenic landscapes. Proc R Soc B Biol Sci 283:20161625CrossRef

Lashley MA, Cove MV, Chitwood MC et al (2018) Estimating wildlife activity curves: comparison of methods and sample size. Sci Rep:1–11

Lesmeister DB, Nielsen CK, Schauber EM, Hellgren EC (2015) Spatial and temporal structure of a mesocarnivore guild in Midwestern North America. Wildl Monogr 191:1–61CrossRef

Levi T, Wilmers C (2012) Wolves – coyotes – foxes : a cascade among carnivores. Ecology 93:921–929CrossRefPubMed

Loveridge AJ, Valeix M, Elliot NB, Macdonald DW (2017) The landscape of anthropogenic mortality: how African lions respond to spatial variation in risk. J Appl Ecol 54:815–825CrossRef

MacKenzie DI, Nichols JD, Lachman GB et al (2002) Estimating site occupancy rates when detection probabilities are less than one. Ecology 83:2248–2255CrossRef

Magle SB, Hunt VM, Vernon M, Crooks KR (2012) Urban wildlife research: past, present, and future. Biol Conserv 155:23–32CrossRef

Mao JS, Boyce MS, Smith DW et al (2005) Habitat selection by elk before and after wolf reintroduction in Yellowstone National Park. J Wildl Manag 69:1691–1707CrossRef

Marks CA, Bloomfield TE (2006) Home-range size and selection of natal den and diurnal shelter sites by urban red foxes (Vulpes vulpes) in Melbourne. Wildl Res 33:339–347CrossRef

McKinney ML (2006) Urbanization as a major cause of biotic homogenization. Biol Conserv 127:247–260CrossRef

Meredith M, Ridout M (2014) Overlap: Estimates of coefficient of overlapping for animal activity patterns

Mielke PW, Berry KJ, Johnson ES (1976) Multi-response permutation procedures for a priori classifications. Commun Stat - Theory Methods 5:1409–1424CrossRef

Mitchell N, Strohbach MW, Pratt R, Finn WC, Strauss EG (2015) Space use by resident and transient coyotes in an urban-rural landscape mosaic. Wildl Res 42:461–469CrossRef

Moll RJ, Kilshaw K, Montgomery RA, Abade L, Campbell RD, Harrington LA, Millspaugh JJ, Birks JDS, Macdonald DW (2016) Clarifying habitat niche width using broad-scale, hierarchical occupancy models: a case study with a recovering mesocarnivore. J Zool 300:177–185CrossRef

Moll RJ, Redilla KM, Mudumba T, Muneza AB, Gray SM, Abade L, Hayward MW, Millspaugh JJ, Montgomery RA (2017) The many faces of fear: a synthesis of methodological variation in characterizing predation risk. J Anim Ecol 86:749–765CrossRefPubMed

Monterroso P, Alves PC, Ferreras P (2013) Catch me if you can: diel activity patterns of mammalian prey and predators. Ethology 119:1044–1056CrossRef

Morey PS, Gense EM, Gehrt SD (2007) Spatial and temporal variation in the diet of coyotes in the Chicago metropolitan area. Am Midl Nat 158:147–161CrossRef

Mueller MA, Drake D, Allen ML (2018) Coexistence of coyotes (Canis latrans) and red foxes (Vulpes vulpes) in an urban landscape. 1–19

Newey S, Davidson P, Nazir S, Fairhurst G, Verdicchio F, Irvine RJ, van der Wal R (2015) Limitations of recreational camera traps for wildlife management and conservation research: a practitioner’s perspective. Ambio 44:624–635CrossRefPubMedPubMedCentral

Niedballa J, Sollmann R, Courtiol A, Wilting A (2016) camtrapR: an R package for efficient camera trap data management. Methods Ecol Evol 7:1457–1462CrossRef

Nouvellet P, Rasmussen GSA, MacDonald DW, Courchamp F (2012) Noisy clocks and silent sunrises: measurement methods of daily activity pattern. J Zool 286:179–184CrossRef

Ordeñana MA, Crooks KR, Boydston EE, Fisher RN, Lyren LM, Siudyla S, Haas CD, Harris S, Hathaway SA, Turschak GM, Miles AK, van Vuren DH (2010) Effects of urbanization on carnivore species distribution and richness. J Mammal 91:1322–1331CrossRef

Oriol-Cotterill A, Valeix M, Frank LG, Riginos C, Macdonald DW (2015) Landscapes of coexistence for terrestrial carnivores: the ecological consequences of being downgraded from ultimate to penultimate predator by humans. Oikos 124:1263–1273CrossRef

Plummer M (2003) JAGS: A program for analysis of Bayesian graphical models using Gibbs sampling. Proceedings of the 3rd International Workshop on Distributed Statistical Computing. p 124:1–8

Poessel SA, Breck S, Teel TL et al (2012) Patterns of human – coyote conflicts in the Denver metropolitan area. J Wildl Manag 77:297–305CrossRef

Polis GA, Holt RD (1992) Intraguild predation: the dynamics of complex trophic interactions. Trends Ecol. Evol 7:151–154CrossRefPubMed

Randa LA, Yunger JA (2006) Carnivore occurrence along an urban-rural gradient: a landscape-level analysis. J Mammal 87:1154–1164CrossRef

Ridout MS, Linkie M (2009) Estimating overlap of daily activity patterns from camera trap data. J Agric Biol Environ Stat 14:322–337CrossRef

Royle JA, Dorazio RM (2008) Hierarchical modeling and inference in ecology: the analysis of data from populations, metapopulations and communities. Elsevier Academic Press, Oxford, UK

RStudio Team (2015) RStudio: integrated development for R. RStudio, Inc., Boston

Šálek M, Drahníková L, Tkadlec E (2015) Changes in home range sizes and population densities of carnivore species along the natural to urban habitat gradient. Mamm Rev 45:1–15

Sargeant AB, Allen SH (1989) Observed interactions between coyotes and red foxes. J Mammal 70:631–633CrossRef

Sargeant AB, Allen SH, Hastings JO (1987) Spatial relations between sympatric coyotes and red foxes in North Dakota. J Wildl Manag 51:285–293CrossRef

Schmitz OJ, Miller JRB, Trainor AM, Abrahms B (2017) Toward a community ecology of landscapes: predicting multiple predator-prey interactions across geographic space. Ecology 98:2281–2292CrossRefPubMed

Schoener TW (1974) Resource partitioning in ecological communities. Science 80(185):27–39CrossRef

Smith JA, Suraci JP, Clinchy M, Crawford A, Roberts D, Zanette LY, Wilmers CC (2017) Fear of the human “super predator” reduces feeding time in large carnivores. Proc R Soc B Biol Sci 284:20170433CrossRef

Stevens DL, Olsen AR (2003) Variance estimation for spatially balanced samples of environmental resources. Environmetrics 14:593–610CrossRef

Su YS, Yajima M (2012) R2jags: a package for running jags from R

Theberge JB, Wedeles CHR (1989) Prey selection and habitat partitioning in sympatric coyote and red fox populations, Southwest Yukon. Can J Zool 67:1285–1290CrossRef

Treves A, Karanth KU (2003) Human-carnivore conflict and perspectives on carnivore management worldwide. Conserv Biol 17:1491–1499CrossRef

Vanak AT, Fortin D, Thaker M, Ogden M, Owen C, Greatwood S, Slotow R (2013) Moving to stay in place: behavioral mechanisms for coexistence of African large carnivores. Ecology 94:2619–2631CrossRefPubMed

Wang Y, Allen ML, Wilmers CC (2015) Mesopredator spatial and temporal responses to large predators and human development in the Santa Cruz Mountains of California. Biol Conserv 190:23–33CrossRef

Wapenaar W, de Bie F, Johnston D, et al (2012) Population structure of harvested red foxes (Vulpes vulpes) and coyotes (Canis latrans) on Prince Edward Island, Canada. Can Field-Naturalist 126:288–294

Werner EE, Peacor SD (2003) A review of trait-mediated indirect interactions in ecological communities. Ecology 84:1083–1100CrossRef

Wilmers CC, Wang Y, Nickel B, Houghtaling P, Shakeri Y, Allen ML, Kermish-Wells J, Yovovich V, Williams T (2013) Scale dependent behavioral responses to human development by a large predator, the puma. PLoS One 8:e60590CrossRefPubMedPubMedCentral

Zuur AF, Ieno EN, Elphick CS (2010) A protocol for data exploration to avoid common statistical problems. Methods Ecol Evol 1:3–14CrossRef

Title: Humans and urban development mediate the sympatry of competing carnivores
Authors: Remington J. Moll
Jonathon D. Cepek
Patrick D. Lorch
Patricia M. Dennis
Terry Robison
Joshua J. Millspaugh
Robert A. Montgomery
Publication date: 17-04-2018
Publisher: Springer US
Published in: Urban Ecosystems / Issue 4/2018
Print ISSN: 1083-8155
Electronic ISSN: 1573-1642
DOI: https://doi.org/10.1007/s11252-018-0758-6

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 4/2018

Spatial and genetic distribution of a north American termite, Reticulitermes flavipes, across the landscape of Paris

Birds biodiversity in urban and periurban forests: environmental determinants at local and landscape scales

Ichthyofauna diet changes in response to urbanization: the case of upper Paranapanema River basin (Brazil)

City parks vs. natural areas - is it possible to preserve a natural level of bee richness and abundance in a city park?

Landscape urbanization threatens plant phylogenetic diversity in the Brazilian Atlantic Forest

Floral morphology as the main driver of flower-feeding insect occurrences in the Paris region