TITLE PAGE - acumen - The University of Alabama

17.11.2013 Views
parameters, mortality rates, and recruitment of Astacus leptodactylus (Eschscholtz, 1823) (Decapoda, Astacidae) in unexploited inland waters of the northern Marmara region, European Turkey. Crustaceana, 80, 655-665. Dickson G.W., Briese L.A. & Giesy J.P. (1979) Tissue metal concentrations in two crayfish species cohabiting a Tennessee cave stream. Oecologia, 44, 8-12. Elliott W.R. (2001) Conservation of the North American cave and karst biota. In: Ecosystems of the World; Subterranean Ecosystems Vol. 30 (Eds H. Wilkens, D.C. Culver, & W.F. Humphreys), pp. 665-689. New York, New York, USA. Engel A.S., Porter M.L., Stern L.A., Quinlan S. & Bennett P.C. (2004) Bacterial diversity and ecosystem function of filamentous microbial mats from aphotic (cave) sulfidic springs dominated by chemolithoautotrophic “Epsilonproteobacteria”. FEMS Microbiology Ecology, 51, 31-53. Fidalgo M.L., Carvalho A.P. & Santos P. (2001) Population dynamics of the red swamp crayfish, Procambarus clarkii (Girard, 1852) from the Aveiro region, Portugal (Decapoda, Cambaridae). Crustaceana, 74, 369-375. Finch C.E. (2009) Update on slow aging and negligible senescence—a mini-review. Gerontology, 55, 307-313. Flint R.W. (1975) The natural history, ecology and production of the crayfish, Pacifastacus leniusculus, in a subalpine lacustrine environment. Ph.D. dissertation, University of California, Davis. Hamr P. & Richardson A. (1994) Life history of Parastacoides tasmanicus tasmanicus Clark, a burrowing freshwater crayfish from south-western Tasmania. Journal of Marine and Freshwater Research, 45, 455-470. Hobbs III H.H. (1978) Studies of the cave crayfish, Orconectes inermis inermis Cope (Decapoda, Cambaridae). Part IV: Mark-recapture procedures for estimating population size and movements of individuals. International Journal of Speleology, 10, 303-322. Hobbs Jr. H.H., Hobbs III H.H. & Daniel M.A. (1977) A review of the troglobitic decapod crustaceans of the Americas. Smithsonian Institution Press, Washington, D.C., USA. Hobbs H.H. & Lodge D.M. (2010) Decapoda. In: Ecology and Classification of North American Freshwater Invertebrates 3 rd edition. (Eds J.H. Thorp & A.P. Covich), pp. 901-967. San Diego, California, USA. Hüppop K. (2001) How do cave animals cope with the food scarcity in caves? In: Ecosystems of the World; Subterranean Ecosystems Vol. 30 (Eds H. Wilkens, D.C. Culver, & W.F. Humphreys), pp. 159-188. New York, New York, USA. 89

Huryn A.D. & Wallace J.B. (1987) Production and litter processing by crayfish in an Appalachian mountain stream. Freshwater Biology, 18, 277-286. Huryn A.D., Venarsky M.P. & Kuhjada B.J. (2008) Assessment of population size, age structure and growth rates for cave inhabiting crayfish in Alabama. Alabama State Wildlife Grant T- 03-02, Final Report. Alabama Department of Conservation and Natural Resources, Montgomery, Alabama. Johnston C.E. & Figiel C. (1997) Microhabitat parameters and life-history characteristics of Fallicambarus gordoni Fitzpatrick, a crayfish associated with pitcher-plant bogs in southern Mississippi. Journal of Crustacean Biology, 17, 687-691. Jones D.R. & Eversole A.G. (2011) Life History Characteristics of the Elk River Crayfish. Journal of Crustacean Biology, 31, 647-652. Jones J.P.G., Andriahajaina F.B., Hockley N.J., Crandall K.A. & Ravoahangimalala O.R. (2007) The ecology and conservation status of Madagascar's endemic freshwater crayfish (Parastacidae; Astacoides). Freshwater Biology, 52, 1820-1833. Jones J.P.G. & Coulson T. (2006) Population regulation and demography in a harvested freshwater crayfish from Madagascar. Oikos, 112, 602-611. Kawai T., Hamano T. & Matsuura S. (1997) Survival and growth of the Japanese crayfish Cambaroides japonicus in a small stream in Hokkaido. Bulletin of marine science, 61, 147- 157. Koslow J., Boehlert G., Gordon J., Haedrich R., Lorance P. & Parin N. (2000) Continental slope and deep-sea fisheries: implications for a fragile ecosystem. ICES Journal of Marine Science: Journal du Conseil, 57, 548-557. Krajick K. (2001) Cave biologists unearth buried treasure. Science, 293, 2378-2381. Krajick K. (2007) Discoveries in the dark. National Geographic, 212, 134-137. Larson E.R. & Magoulick D.D. (2011) Life-History Notes on Cambarus hubbsi Creaser (Hubbs Crayfish) from the South Fork Spring River, Arkansas. Southeastern Naturalist, 9, 121-132. Loughman Z.J. (2010) Ecology of Cambarus dubius (upland burrowing crayfish) in north-central West Virginia. Southeastern Naturalist, 9, 217-230. Momot W.T. (1984) Crayfish production: a reflection of community energetics. Journal of Crustacean Biology, 4, 35-54. Muck J.A., Rabeni C.F. & Distefano R.J. (2002) Reproductive biology of the crayfish Orconectes luteus (Creaser) in a Missouri stream. The American Midland Naturalist, 147, 338-351. 90

Page 1 and 2: THE INFLUENCE OF ENERGY AVAILABILIT

Page 3 and 4: ABSTRACT Detritus from surface envi

Page 5 and 6: LIST OF ABBREVIATIONS AND SYMBOLS m

Page 7 and 8: NC IL ON U.K. VIAT VIE Fig. North C

Page 9 and 10: AIC K-S Akaike information criterio

Page 11 and 12: laboratory work and was an excellen

Page 13 and 14: LIST OF TABLES TABLE 2.1 TABLE 2.2

Page 15 and 16: LIST OF FIGURES FIGURE 2.1 (a) Box

Page 17 and 18: FIGURE 4.3 Growth models for Orcone

Page 19 and 20: chemolithoautotrophy-based systems;

Page 21 and 22: ecology, 51, 31-53. Gibert J. & Cul

Page 23 and 24: CHAPTER 2 EFFECTS OF ORGANIC MATTER

Page 25 and 26: community structure in cave “pits

Page 27 and 28: communities and how variation in co

Page 29 and 30: the different source locations was

Page 31 and 32: of natural-log transformed data (%

Page 33 and 34: peak in organic matter in Big Mouth

Page 35 and 36: Figs. 5a, b). The breakdown rate of

Page 37 and 38: per litter bag. Similarly, Huntsman

Page 39 and 40: ags was the greater retention of li

Page 41 and 42: Historically, limited resource inpu

Page 43 and 44: Culver, D.C. & Pipan, T. (2009) The

Page 45 and 46: Merritt, R.W., Cummins, K.W. & Berg

Page 47 and 48: Table 1. Mean (1 S.D.) macroinverte

Page 49 and 50: Table 2. Mean (±1 S.D.) daily temp

Page 51 and 52: Figure 1. (a) Box and whisker plot

Page 53 and 54: Figure 3. Non-metric multidimension

Page 55 and 56: Figure 5. Box and whisker plot of l

Page 57 and 58: streams, while the obligate-cave sp

Page 59 and 60: More recent observational and exper

Page 61 and 62: of netting (mesh size 2.5×1.5-cm)

Page 63 and 64: the two end-members. This conservat

Page 65 and 66: crop organic matter significantly i

Page 67 and 68: macroinvertebrate biomass to levels

Page 69 and 70: and surface streams (20-35,000 g m

Page 71 and 72: these factors, the stable isotope a

Page 73 and 74: surface streams. Thus, it is likely

Page 75 and 76: subsides to ecosystem dynamics have

Page 77 and 78: populations. Journal of Applied Eco

Page 79 and 80: Poulson T.L. & Lavoie K.H. (2001) T

Page 81 and 82: Wood P., Gunn J. & Perkins J. (2002

Page 83 and 84: Table 2. Mean (±1 standard deviati

Page 85 and 86: Table 2. Continued Chironomini Para

Page 87 and 88: Figure 1. Mean (bars are standard e

Page 89 and 90: Figure 3. Non-metric multidimension

Page 91 and 92: CHAPTER 4 REXAMINING EXTREME LONGEI

Page 93 and 94: individuals, he predicted that it w

Page 95 and 96: A phylogeographic study by Buhay &

Page 97 and 98: differences in size structure among

Page 99 and 100: and females in Tony Sinks Cave were

Page 101 and 102: Estimates of life span for O. austr

Page 103 and 104: available size-classes were well re

Page 105: References Anonymous (1999) Cave Sc

Page 109 and 110: Whitmore N. & Huryn A.D. (1999) Lif

Page 111 and 112: Table 2. Estimated life span (years

Page 113 and 114: Figure 1. Annual growth increment (

Page 115 and 116: Figure 3. Growth models for Orconec

Page 117 and 118: CHAPTER 5 CONSUMER-RESOURCE DYNAMIC

Page 119 and 120: following incidental inputs of orga

Page 121 and 122: Temperature data were not available

Page 123 and 124: minimum (Venarsky et al., 2012b). A

Page 125 and 126: 100% organic matter (i.e., maximum

Page 127 and 128: Macroinvertebrate biomass varied si

Page 129 and 130: Discussion The energy-limitation hy

Page 131 and 132: crayfish captured in most months we

Page 133 and 134: systems is likely high, especially

Page 135 and 136: function of microbial films in grou

Page 137 and 138: Crustacean Biology, 4, 35-54. Momot

Page 139 and 140: Whitmore N. & Huryn A. (1999) Life

Page 141 and 142: Table 2. Assimilation efficiencies

Page 143 and 144: Table 3. Continued Tanypodinae 0.03

Page 145 and 146: Table 5. Estimates of mean wood and

Page 147 and 148: Figure 1. (A) Box and whisker plot

Page 149 and 150: CHAPTER 6 OVERALL CONCLUSIONS Due t

Page 151 and 152: characteristics (e.g., higher growt

Page 153 and 154: characteristics, highly efficient p

organic

litter

biomass

crayfish

rates

species

macroinvertebrate

streams

sinks

australis

acumen

alabama

acumen.lib.ua.edu

TITLE PAGE - acumen - The University of Alabama

TITLE PAGE - acumen - The University of Alabama ... View more TITLE PAGE - acumen - The University of Alabama

Delete template?

Save as template ?

TITLE PAGE - acumen - The University of Alabama TITLE PAGE - acumen - The University of Alabama