Hostname: page-component-cd9895bd7-hc48f Total loading time: 0 Render date: 2024-12-28T05:26:58.687Z Has data issue: false hasContentIssue false

Water requirements for emergence of buffelgrass (Pennisetum ciliare)

Published online by Cambridge University Press:  20 January 2017

Steven E. Smith
Affiliation:
School of Natural Resources, 325 Biological Sciences East, University of Arizona, Tucson, AZ 85721
Mitchel P. McClaran
Affiliation:
School of Natural Resources, 325 Biological Sciences East, University of Arizona, Tucson, AZ 85721

Abstract

The ability of an invasive species to acquire and use a limiting resource during critical life history stages governs its ability to establish and persist within an environment. Arid environments are generally considered more resistant to invasion and are defined by low and sporadic precipitation. Warm-season grasses are most susceptible to mortality during seedling emergence, but water requirements for emergence are rarely known. We examined the ability of the often invasive warm-season grass, buffelgrass, to emerge given a range of simulated precipitation delivered on 2, 3, and 4 consecutive days with the use of a line-source irrigation system in a glasshouse. The minimum amount of water required for buffelgrass emergence was observed to be 6.3 mm (3.14 mm on 2 consecutive days). With the use of probit analysis, the median emergence response (0.5 emergence probability) was predicted to require 17.4–19.9 mm of water. Emergence was concentrated within the first 5 days following initial simulated precipitation with the probability of new emergence highest on Days 3 and 4. Over the period from 1949–2001 in Tucson, Arizona within the Sonoran Desert, the total number of consecutive rainy-day sequences meeting the minimum per-day precipitation levels for a median and minimum emergence response was 27 and 92, respectively. Precipitation sufficient to result in emergence of 50% of viable buffelgrass caryopses has occurred in Tucson in about 1 of 2 years over this period. We compare the soil water requirements for emergence of buffelgrass to other perennial species in the Sonoran Desert and suggest that the invasion success of buffelgrass is due in part to its ability to emerge following relatively low precipitation levels.

Type
Research Article
Copyright
Copyright © Weed Science Society of America 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Literature Cited

Allison, P. D. 1995. Survival Analysis Using the SAS® System: A Practical Guide. Cary, NC: Statistical Analysis Systems Institute. 292 p.Google Scholar
Anderson, E. R. 1974. Presoaking treatment of Cenchrus ciliaris seed. Queensl. J. Agric. Anim. Sci 31:125128.Google Scholar
Arriaga, L., Castellanos, A. E., Moreno, E., and Alarcón, J. 2003. Potential ecological distribution of alien invasive species and risk assessment: a case study of buffel grass in arid regions of Mexico. Conserv. Biol 18:15041514.CrossRefGoogle Scholar
Bashaw, E. C. 1985. Buffelgrass origins. Pages 68 in Runge, E.C.A. and Schuster, J. L., editors. Buffelgrass: Adaptation, management and forage quality symposium. College Station, TX: Texas Agricultural Experiment Station MP-1575.Google Scholar
Bowers, J. E., Turner, R. M., and Burgess, T. L. 2004. Temporal and spatial patterns in emergence and early survival of perennial plants in the Sonoran Desert. Plant Ecol 172:107119.CrossRefGoogle Scholar
Breckenfeld, D. J. and Robinett, D. 2003. Soil and Ecological Sites of the Santa Rita Experimental Range. U.S. Dep. Agric. For. Ser. Proc RMRS-P-30:157165.Google Scholar
Burgess, T. L., Bowers, J. E., and Turner, R. M. 1991. Exotic plants at the desert laboratory, Tucson, Arizona. Madroño 38:96114.Google Scholar
Búrquez-Montijo, A., Miller, M. E., and Martínez-Yrízar, A. 2002. Mexican grasslands, thornscrub, and the transformation of the Sonoran Desert by invasive exotic buffelgrass (Pennisetum ciliare). Pages 126146 in Tellman, B., editor. Invasive Exotic Species in the Sonoran Region. Tucson, AZ: The University of Arizona Press and the Arizona-Sonora Desert Museum.Google Scholar
Call, C. A. and Roundy, B. A. 1991. Perspectives and processes in revegetation of arid and semiarid rangelands. J. Range Manage 44:543549.CrossRefGoogle Scholar
Case, T. J. 1990. Invasion resistance arises in strongly interacting species-rich model competition communities. Proc. Natl. Acad. Sci 87:96109614.CrossRefGoogle ScholarPubMed
Cox, J. R., Martin, M. H., Ibarra, F. A., Fourie, J. H., Rethman, N. F. G., and Wilcox, D. G. 1988. The influence of climate and soils on the distribution of four African grasses. J. Range Manage 41:127139.Google Scholar
Crawley, M. J. 1987. What makes a community invasible?. Pages 429453 in Crawley, M. J., Edwards, P. J., and Gray, A. J., editors. Colonization, Succession, and Stability. London: Blackwell Scientific.Google Scholar
D'Antonio, C. M. and Vitousek, P. M. 1992. Biological invasions by exotic grasses, the grass/fire cycle and global change. Annu. Rev. Ecol. Syst 23:6387.CrossRefGoogle Scholar
Davis, M. A., Grime, J. P., and Thompson, K. 2000. Fluctuating resources in plant communities: a general theory of invasibility. J. Ecol 88:528534.CrossRefGoogle Scholar
Esque, T. C. and Schwalbe, C. 2000. Non-Native Grasses and Fire Create Double Jeopardy. People, Land, and Water. http://www.usgs.gov/invasive_species/plw/grassfire.html.Google Scholar
Felger, R. S. 1990. Non-native plants of Organ Pipe Cactus National Monument, Arizona. Technical Report No. 31. Washington, D.C.: U.S. Geological Survey, Cooperative Park Studies Unit, The University of Arizona and National Park Service, Organ Pipe Cactus National Monument.Google Scholar
Frasier, G. W., Woolhiser, D. A., and Cox, J. R. 1984. Emergence and seedling survival of two warm-season grasses as influenced by the timing of precipitation: a greenhouse study. J. Range Manage 37:711.Google Scholar
Gerlach, J. D. Jr. and Rice, K. J. 2003. Testing life history correlates of invasiveness using congeneric plant species. Ecol. Appl 13:167179.Google Scholar
Goodwin, B. J., McAllister, A. J., and Fahrig, L. 1999. Predicting invasiveness of plant species based on biological information. Conserv. Biol 13:422426.Google Scholar
Higgins, S. I., Richardson, D. M., Cowling, R. M., and Trinder-Smith, T. H. 1999. Predicting the landscape-scale distribution of alien plants and their threat to plant diversity. Conserv. Biol 13:303313.CrossRefGoogle Scholar
Holt, E. C. 1985. Buffelgrass—A brief history. Pages 15 in Runge, E.C.A. and Schuster, J. L., editors. Buffelgrass: Adaptation, Management and Forage Quality Symposium. College Station, TX: Texas Agricultural Experiment Station MP-1575.Google Scholar
Humphreys, L. R. 1958. Studies in the Germination, Early Growth, Drought Survival, and Field Establishment of Buffelgrass (Cenchrus ciliaris L.) and of Birdwood Grass (C. setigerus Vahl), with Particular Reference to the Yalleroi District of Queensland. . University of Sydney, Sydney, Australia.Google Scholar
Johnson, D. A., Rumbaugh, M. D., Willardson, L. S., Asay, K. H., Rinehart, D. N., and Aurasteh, M. R. 1982. A greenhouse line-source sprinkler system for evaluating plant response to a water application gradient. Crop Sci 22:441442.Google Scholar
Jordan, G. L. and Haferkamp, M. R. 1989. Temperature responses and calculated heat units for germination of several range grasses and shrubs. J. Range Manage 42:4145.Google Scholar
Lazarides, M., Cowley, K., and Hohnen, P. 1997. CSIRO Handbook of Australian Weeds. Canberra, Australia: CSIRO.Google Scholar
Lonsdale, W. M. 1994. Inviting trouble: introduced pasture species in northern Australia. Aust. J. Ecol 19:345354.Google Scholar
Mack, R. N., Simberloff, D., Lonsdale, W. M., Evans, H., Clout, M., and Bazzaz, F. A. 2000. Biotic invasions: Causes, epidemiology, global consequences, and control. Ecol. Appl 10:689701.Google Scholar
National Oceanic and Atmospheric Administration, National Climate Data Center (NOAA, NCDC). 2003. Station Data from Cooperative Network. http://www7.ncdc.noaa.gov/IPS/LCDPubs.Google Scholar
Noy-Meir, I. 1973. Desert ecosystems: environment and producers. Annu. Rev. Ecol. Syst 4:2551.Google Scholar
Payton, M. E., Greenstone, M. H., and Schenker, N. 2003. Overlapping confidence intervals or standard error intervals: What do they mean in terms of statistical significance? J. Insect Sci 3:16.Google Scholar
Peterson, A. T. 2003. Predicting the geography of species' invasions via ecological niche modeling. Quart. Rev. Biol 78:419433.CrossRefGoogle ScholarPubMed
Pyšek, P. 1998. Is there a taxonomic pattern to plant invasions? Oikos 82:282294.Google Scholar
Rejmánek, M. 1989. Invasibility of plant communities. Pages 369388 in Drake, J. A., Mooney, H. A., di Castri, F., Groves, R. H., Kruger, F. J., Rejmánek, M., and Williamson, M., editors. Biological Invasions. A Global Perspective. Chichester, United Kingdom.Google Scholar
Reynolds, J. F., Kemp, P. R., Ogle, K., and Fernandez, R. J. 2004. Modifying the ‘pulse-reserve’ paradigm for deserts of North America: precipitation pulses, soil water, and plant responses. Oecologia 141:194210.Google Scholar
Rutman, S. and Dickson, L. 2002. Management of buffelgrass on Organ Pipe Cactus National Monument, Arizona. Pages 311318 in Tellman, B., editor. Invasive Exotic Species in the Sonoran Region. Tucson, AZ: The University of Arizona Press and the Arizona-Sonora Desert Museum.Google Scholar
[SAS] Statistical Analysis Systems. 1999. SAS/STAT® Software and User's Guide, Version 8. Cary, NC: Statistical Analysis Systems Institute.Google Scholar
Schmid, M. K. and Rogers, G. F. 1988. Trends in fire occurrence in the Arizona Upland subdivision to the Sonoran Desert, 1955 to 1982. Southwest. Nat 33:437444.Google Scholar
Scott, S. J., Jones, R. A., and Williams, W. A. 1984. Review of data analysis methods for seed germination. Crop Sci 24:11921199.Google Scholar
Smith, N. M. 1995. Weeds of Natural Ecosystems: A Field Guide to Environmental Weeds of the Northern Territory, Australia. Darwin, Australia: Environment Centre NT Inc.Google Scholar
Smith, S. E., Fendenheim, D., and Halbrook, K. 2006. Epidermal conductance as a component of dehydration avoidance in Digitaria californica and Eragrostis lehmanniana, two perennial desert grasses. J. Arid Environ 64:238250.Google Scholar
Smith, S. E., Riley, E., Tiss, J. L., and Fendenheim, D. M. 2000. Geographical variation in predictive seedling emergence in a perennial desert grass. J. Ecol 88:139149.CrossRefGoogle Scholar
United States Department of Agricultural, Soil Conservation Service. 1943– 1983. Unpublished establishment trial records. Tucson, AZ: Tucson Plant Materials Center.Google Scholar
Usher, M. B. 1988. Biological invasions of nature reserves: a search for generalisations. Conserv. Biol 44:119135.Google Scholar
Van Devender, T. R., Felger, R. S., and Burquez, A., M. 1997. Exotic Plants in the Sonoran Desert region, Arizona and Sonora. 1997 Symposium Proceedings, California Exotic Pest Plant Council. http://endangered.fws.gov/r/fr94547.html.Google Scholar
Wade, M. 1997. Predicting plant invasions: making a start. Pages 118 in Brock, J. H., Wade, M., Pyšek, P., and Green, D., editors. Plant Invasions—Studies from North America and Europe. Leiden, The Netherlands: Backhuys.Google Scholar
Ward, J. P. 2003. Estimating the Potential Distribution of buffelgrass in Saguaro National Park, Arizona: Illustration of a Conservation Planning Tool in the Age of Biotic Homogenization. . University of Arizona, Tucson, AZ.Google Scholar
Williams, D. G. and Baruch, Z. 2000. African grass invasion in the Americas: ecosystem consequences and the role of ecophysiology. Biol. Invasions 2:123140.Google Scholar
Winkworth, R. E. 1971. Longevity of buffelgrass seed sown in an arid Australian range. J. Range Manage 24:141145.Google Scholar