Comparison of Neotoma (packrat) feces to associated sediments from Paisley Caves, Oregon, U.S.A

References

• Adam DP, Mehringer PJ. 1975. Modern pollen surface samples – an analysis of subsamples. US Geological Survey. Journal of Research. 3:733–736.
   Google Scholar
• Atchinson JA. 2005. Concise Guide to Compositional Data Analysis. In2do Compositional Data Analysis Workshop CoDaWork Oct. 5:17–21.
   Google Scholar
• Baker RG. 2000. Holocene environments reconstructed from plant macrofossils in stream deposits from Southeastern Nebraska, USA. The Holocene. 10(3):357–365.
   Web of Science ®Google Scholar
• Beck CW. 2019. Developing new techniques in coprolite analysis: packrat feces from Paisley Caves and human coprolites from Hinds Cave [dissertation]. College Station (TX): Texas A&M University.
   Google Scholar
• Beck CW, Bryant VM, Jenkins DL. 2018. Analysis of Younger Dryas–Early Holocene pollen in sediments of Paisley Cave 2, South-central Oregon. Palynology. 42(2):168–179.
   Web of Science ®Google Scholar
• Bennet KD. 1999. Data-handling methods for Quaternary microfossils. The 14Chrono Centre. 12:2017.
   Google Scholar
• Bern C, Kjos S, Yabsley MJ, Montgomery SP. 2011. Trypanosoma cruzi and Chagas' disease in the United States. Clinical Microbiology Reviews. 24(4):655–681.
   PubMed Web of Science ®Google Scholar
• Betancourt JL, Van Devender TR, Martin PS, eds. 1990. Packrat middens: the last 40,000 years of biotic change. Tucson (AZ): University of Arizona Press.
   Google Scholar
• Callen EO, Cameron T. 1960. A prehistoric diet revealed in coprolites. The New Science. 8:35–40.
   Google Scholar
• Cole KL. 1990. Reconstruction of past desert vegetation along the Colorado River using packrat middens. Palaeogeography, Palaeoclimatology, Palaeoecology. 76(3-4):349–366.
   Web of Science ®Google Scholar
• Dearing MD, Mangione AM, Karasov WH, Morzunov S, Otteson E, St. Jeor S. 1998. Prevalence of hantavirus in four species of Neotoma from Arizona and Utah. Journal of Mammalogy. 79(4):1254–1259.
   Web of Science ®Google Scholar
• Dial KP, Czaplewski NJ. 1990. Do woodrat middens accurately represent the animals' environments and diets? The Woodhouse Mesa study. Packrat middens: the last 40,000 years of biotic change. Tucson (AZ): The University of Arizona Press; p. 43–58.
   Google Scholar
• Erdtman G. 1960. The acetolysis method. A revised description. Svensk Botanisk Tidskrift. 54:561–564.
   Google Scholar
• Finley RBJ. 1990. Woodrat ecology and behavior and the interpretation of paleomiddens. Packrat middens: the last 40,000 years of biotic change. Tucson (AZ): The University of Arizona Press; p. 28–42.
   Google Scholar
• Fulhorst CF, Charrel RN, Weaver SC, Ksiazek TG, Bradley RD, Milazzo ML, Tesh RB, Bowen MD. 2001. Geographic distribution and genetic diversity of Whitewater Arroyo virus in the southwestern United States. Emerging Infectious Diseases. 7(3):403.
   PubMed Web of Science ®Google Scholar
• Gander FF. 1929. Experiences with wood rats, Neotoma fuscipes macrotis. Journal of Mammalogy. 10(1):52–58.
   Google Scholar
• González C, Wang O, Strutz SE, González-Salazar C, Sánchez-Cordero V, Sarkar S. 2010. Climate change and risk of leishmaniasis in North America: predictions from ecological niche models of vector and reservoir species. PLoS Neglected Tropical Diseases. 4(1):e585.
   PubMed Web of Science ®Google Scholar
• Grimm EC. 1987. CONISS: a Fortran 77 program for stratigraphically constrained cluster analysis by the method of incremental sum of squares. Computers & Geosciences . 13:13–35.
   Google Scholar
• Hall SA. 1992. Packrat middens: the last 40,000 years of biotic change. [Review of the book Packrat middens: the last 40,000 years of biotic change by Julio L. Betancourt, Thomas R. Van Devender, and Paul S. Martin (editors)]. Geoarchaeology: An International Journal. 5(7):485–497.
   Google Scholar
• Hall SA. 1997. Pollen analysis and woodrat middens: re-evaluation of Quaternary vegetational history in the. American Southwestern Geography. 1:25–43.
   Google Scholar
• Hall SA, Riskind DA. 2010. Palynology, radiocarbon dating, and woodrat middens: new applications at Hueco Tanks, Trans-Pecos Texas, USA. Journal of Arid Environments. 74(7):725–730.
   Web of Science ®Google Scholar
• Hall WE, Van Devender TR, Olson CA. 1988. Late Quaternary arthropod remains from Sonoran Desert packrat middens, southwestern Arizona and northwestern Sonora. Quaternary Research. 29(3):277–293.
   Web of Science ®Google Scholar
• Hemmes RB, Alvarado A, Hart BL. 2002. Use of California bay foliage by wood rats for possible fumigation of nest-borne ectoparasites. Behavioral Ecology. 13(3):381–385.
   Web of Science ®Google Scholar
• Horowitz A. 1992. Palynology of arid lands. Amsterdam, Netherlands: Elsevier.
   Google Scholar
• Hubálek Z, Rudolf I. 2010. Microbial zoonoses and sapronoses. Springer Science & Business Media.
   Google Scholar
• Hunt CO, Gilbertson DD, Hill EA, Simpson D. 2015. Sedimentation, re-sedimentation and chronologies in archaeologically important caves: problems and prospects. Journal of Archaeological Science. 56:109–116.
   Web of Science ®Google Scholar
• Jackson ST, Betancourt JL, Lyford ME, Gray ST, Rylander KA. 2005. A 40,000‐year woodrat‐midden record of vegetational and biogeographical dynamics in North‐eastern Utah, USA. Journal of Biogeography. 32(6):1085–1106.
   Web of Science ®Google Scholar
• Jackson ST, Lyford ME. 1999. Pollen dispersal models in Quaternary plant ecology: assumptions, parameters, and prescriptions. The Botanical Review. 65(1):39–75.
   Web of Science ®Google Scholar
• Jankovská V, Komárek J. 2000. Indicative value of Pediastrum and other coccal green algae in palaeoecology. Folia Geobotanica. 35(1):59–82.
   Web of Science ®Google Scholar
• Jenkins DL. 2007. Distribution and dating of cultural and paleontological remains at the Paisley 5 Mile Point Caves (35LK3400) in the northern Great Basin: an early assessment. Paleoindian or Paleoarchaic?: Great Basin Human Ecology at the Pleistocene/Holocene Transition. Salt Lake City (UT): University of Utah Press; p. 57–81.
   Google Scholar
• Jenkins DL, Davis LG, Stafford TW, Campos PF, Hockett B, Jones GT, Cummings LS, Yost C, Connolly TJ, Yohe RM, et al. 2012. Clovis age western stemmed projectile points and human coprolites at the Paisley Caves. Science. 337(6091):223–228.,
   PubMed Web of Science ®Google Scholar
• Jenkins DL, Davis LG, Stafford TW, Campos PF, Connolly TJ, Cummings LS, Hofreiter M, Hockett B, McDonough K, Luthe I, et al. 2013. Geochronology, archaeological context, and DNA at the Paisley Caves. Paleoamerican Odyssey, College Station (TX): Texas A&M University; p. 485–510.
   Google Scholar
• Jenkins DL, Davis LG, Stafford TW, Connolly TJ, Jones GT, Rondeau MS, Cummings L, Hockett B, McDonough K, O’Grady PW, et al. 2016. Younger Dryas archaeology and human experience at the Paisley Caves in the northern Great Basin. In Marcel Kronfeld and Bruce B. Huckell (Eds.), Stones, Bones and Profiles: Exploring Archaeological Context, Early American Hunter-Gatherers, and Bison. Louisville (CO): University Press of Colorado; p. 127–204.
   Google Scholar
• Johnson MK, Hansen RM. 1979. Foods of cottontail and woodrats in south-central Idaho. Journal of Mammalogy. 60(1):213–215.
   Web of Science ®Google Scholar
• Lee AK. 1963. The adaptations to arid environments in wood rats of the genus Neotoma. Berkeley and Los Angeles (CA): University of California Press.
   Google Scholar
• Linsdale JM. Tevis LP 1951. The dusky-footed wood rat: a record of observations made on the Hastings Natural History Reservation. Berkeley (CA): University of California Press.
   Google Scholar
• Lyford ME, Jackson ST, Gray ST, Eddy RG. 2004. Validating the use of woodrat (Neotoma) middens for documenting natural invasions. Journal of Biogeography. 31(2):333–342.
   Web of Science ®Google Scholar
• Mack RN, Bryant VM. 1974. Modern pollen spectra from the Columbia Basin, Washington. NW Science. 48:181–194.
   Google Scholar
• Martín-Fernández JA, Barceló-Vidal C, Pawlowsky-Glahn V. 1998. Measures of difference for compositional data and hierarchical clustering methods. Proceedings of IAMG. 98:526–531.
   Google Scholar
• Maupin GO, Gage KL, Piesman J, Montenieri J, Sviat SL, VanderZanden L, Happ CM, Dolan M, Johnson BJ. 1994. Discovery of an enzootic cycle of Borrelia burgdorferi in Neotoma mexicana and Ixodes spinipalpis from northern Colorado, an area where Lyme disease is nonendemic. Journal of Infectious Diseases. 170(3):636–643.
   PubMed Web of Science ®Google Scholar
• McClure PA, Randolph JC. 1980. Relative allocation of energy to growth and development of homeothermy in the eastern wood rat (Neotoma floridana) and hispid cotton rat (Sigmodon hispidus). Ecological Monographs. 50(2):199–219.
   Web of Science ®Google Scholar
• Mehringer PJ, Wigand PE. 1990. Comparison of Late Holocene environments from woodrat middens and pollen: Diamond Craters, Oregon. Packrat middens: the last 40,000 years of biotic change. Tucson (AZ): The University of Arizona Press; p. 294–325.
   Google Scholar
• Minckley TA, Bartlein PJ, Whitlock C, Shuman BN, Williams JW, Davis OK. 2008. Associations among modern pollen, vegetation, and climate in western North America. Quaternary Science Reviews. 27(21-22):1962–1991.
   Web of Science ®Google Scholar
• Minckley TA, Whitlock C, Bartlein PJ. 2007. Vegetation, fire, and climate history of the northwestern Great Basin during the last 14,000 years. Quaternary Science Reviews. 26(17-18):2167–2184.
   Web of Science ®Google Scholar
• Reinhard KJ, Araujo A. 2015. Prehistoric earth oven facilities and the pathoecology of Chagas disease in the Lower Pecos Canyonlands. Journal of Archaeological Science. Dave Egan and Evellyn A. Howell (Eds.) chapter 10, Fire Island Press, Washington, DC. 53:227–234.
   Web of Science ®Google Scholar
• Rhode D. 2001. Packrat middens as a tool for reconstructing historic ecosystems. Historical ecology handbook: A restorationist’s guide to reference ecosystems. p. 257–293.
   Google Scholar
• Poinar H, Fiedel S, King CE, Devault AM, Bos K, Kuch M, Debruyne R. 2009. Comment on “DNA from pre-Clovis human coprolites in Oregon, North America”. Science. 325(5937):148.
   PubMed Web of Science ®Google Scholar
• Schmitt DN, Lupo KD. 2012. The Bonneville Estates rockshelter rodent fauna and changes in Late Pleistocene–Middle Holocene climates and biogeography in the Northern Bonneville Basin, USA. Quaternary Research. 78(1):95–102.
   Web of Science ®Google Scholar
• Shillito L, Blong JC, Jenkins DL, Stafford TW, Jr Whelton H, McDonough K, Bull ID. 2018. New research at Paisley Caves: applying new integrated analytical approaches to understanding stratigraphy, taphonomy and site formation processes. PaleoAmerica. 4(1):82–86.
   Google Scholar
• Smith FA, Betancourt JL, Brown JH. 1995. Evolution of body size in the woodrat over the past 25,000 years of climate change. Science. 270(5244):2012–2014.
   Web of Science ®Google Scholar
• Smith FA. 1997. Neotoma cinerea. Mammalian Species. 564:1–8.
   Google Scholar
• Smith FA, Betancourt JL. 1998. Response of bushy-tailed Woodrats (Neotoma cinerea) to Late Quaternary climatic change in the Colorado Plateau. Quaternary Research. 50(1):1–11.
   Web of Science ®Google Scholar
• Smith FA, Betancourt JL. 2006. Predicting woodrat (Neotoma) responses to anthropogenic warming from studies of the palaeomidden record. Journal of Biogeography. 33(12):2061–2076.
   Web of Science ®Google Scholar
• Spaulding GW, Betancourt JL, Croft LK, Cole KL. 1990. Packrat middens: their composition and methods of analysis. Packrat middens: the last 40,000 years of biotic change. Tucson (AZ): The University of Arizona Press; p. 59–84.
   Google Scholar
• Thompson RS. 1985. Palynology and Neotoma middens. American Association of Stratigraphic Palynologists Contribution Series. 16:89–112.
   Google Scholar
• Thompson SD. 1982. Spatial utilization and foraging behavior of the desert woodrat, Neotoma lepida lepida. Journal of Mammalogy. 63(4):570–581.
   Web of Science ®Google Scholar
• Van Devender TR, King JE. 1971. Late Pleistocene vegetational records in western Arizona. Journal of the Arizona Academy of Science. 6(4):240–4.
   Google Scholar
• Van Devender TR, Bradley G. 1990. Late Quaternary mammals from the Chihuahuan Desert: paleoecology and latitudinal gradients. Packrat middens: the last 40,000 years of biotic change. Tucson (AZ): The University of Arizona Press; p. 104–133.
   Google Scholar
• Van Devender TR, Hall WE. 1994. Holocene arthropods from The Sierra Bacha, Sonora, Mexico, with emphasis on beetles (Coleoptera). Quaternary Research. 48:30–50.
   Google Scholar
• Vaughan TA. 1990. Ecology of living packrats. Packrat middens: the last 40,000 years of biotic change. Tucson (AZ): The University of Arizona Press; p. 14–27.
   Google Scholar
• Verts B. J, Carraway L N. 2002. Neotoma lepida. Mammalian Species. 699:1–12.
   Google Scholar
• Wells PV, Jorgensen CD. 1964. Pleistocene wood rat middens and climatic change in Mohave Desert: a record of juniper woodlands. Science. 143(3611):1171–1173.
   PubMed Web of Science ®Google Scholar
• Zeidner NS, Burkot TR, Massung R, Nicholson WL, Dolan MC, Rutherford JS, Biggerstaff BJ, Maupin GO. 2000. Transmission of the agent of human granulocytic ehrlichiosis by Ixodes spinipalpis ticks: evidence of an enzootic cycle of dual infection with Borrelia burgdorferi in Northern Colorado. The Journal of Infectious Diseases. 182(2):616–619.
   PubMed Web of Science ®Google Scholar