期刊论文详细信息
Movement Ecology
Daily activity budgets reveal a quasi-flightless stage during non-breeding in Hawaiian albatrosses
Scott A Shaffer3  Marc D Romano4  Maura B Naughton4  Marty L Leonard5  Ian D Jonsen1  Lee FG Gutowsky2  Sarah E Gutowsky5 
[1] Department of Biological Sciences, Macquarie University, Sydney, NSW, Australia;Fish Ecology & Conservation Physiology Lab, Carleton University, Ottawa, ON, Canada;Institute of Marine Sciences, University of California, Santa Cruz, CA, USA;USFWS, Pacific Region, Migratory Birds and Habitat Programs, Portland, OR, USA;Biology Department, Dalhousie University, Halifax, NS, Canada
关键词: Non-breeding, Overwinter;    North Pacific;    Seabirds;    Moult;    Migration;    Flight;    Biologging;    Behaviour;    Activity budget;   
Others  :  1132169
DOI  :  10.1186/s40462-014-0023-4
 received in 2014-07-21, accepted in 2014-10-09,  发布年份 2014
PDF
【 摘 要 】

Background

Animals adjust activity budgets as competing demands for limited time and energy shift across life history phases. For far-ranging migrants and especially pelagic seabirds, activity during breeding and migration are generally well studied but the “overwinter” phase of non-breeding has received less attention. Yet this is a critical time for recovery from breeding, plumage replacement and gaining energy stores for return migration and the next breeding attempt. We aimed to identify patterns in daily activity budgets (i.e. time in flight, floating on the water’s surface and active foraging) and associated spatial distributions during overwinter for the laysan Phoebastria immutabilis and black-footed P. nigripes albatrosses using state-space models and generalized additive mixed-effects models (GAMMs). We applied these models to time-series of positional and immersion-state data from small light- and conductivity-based data loggers.

Results

During overwinter, both species exhibited a consistent ‘quasi-flightless’ stage beginning c. 30 days after initiating migration and lasting c. 40 days, characterized by frequent long bouts of floating, very little sustained flight, and infrequent active foraging. Minimal daily movements were made within localized areas during this time; individual laysan albatross concentrated into the northwest corner of the Pacific while black-footed albatross spread widely across the North Pacific Ocean basin. Activity gradually shifted toward increased time in flight and active foraging, less time floating, and greater daily travel distances until colony return c. 155 days after initial departure.

Conclusions

Our results demonstrate that these species make parallel adjustments to activity budgets at a daily time-scale within the overwinter phase of non-breeding despite different at-sea distributions and phenologies. The ‘quasi-flightless’ stage likely reflects compromised flight from active wing moult while the subsequent increase in activity may occur as priorities shift toward mass gain for breeding. The novel application of a GAMM-based approach used in this study offers the possibility of identifying population-level patterns in shifting activity budgets over extended periods while allowing for individual-level variation in the timing of events. The information gained can also help to elucidate the whereabouts of areas important at different times across life history phases for far-ranging migrants.

【 授权许可】

   
2014 Gutowsky et al.; licensee BioMed Central Ltd.

【 预 览 】
附件列表
Files Size Format View
20150303145524708.pdf 1912KB PDF download
Figure 5. 73KB Image download
Figure 4. 80KB Image download
Figure 3. 72KB Image download
Figure 2. 113KB Image download
Figure 2. 50KB Image download
【 图 表 】

Figure 2.

Figure 2.

Figure 3.

Figure 4.

Figure 5.

【 参考文献 】
  • [1]Stearns SC: The Evolution of Life Histories. Oxford University Press, Oxford; 1992.
  • [2]Dingle H: Migration. Oxford University Press, Oxford; 1996.
  • [3][http://www.ace-eco.org/vol4/iss2/art5/] webcite Calvert AM, Walde SJ, Taylor PD: Nonbreeding-Season Drivers of Population Dynamics in Seasonal Migrants: Conservation Parallels Across Taxa.Avian Conserv Ecol 2009, 4:E5. .
  • [4]Lack D: Bird Migration and Natural Selection. Oikos 1968, 19:1-9.
  • [5]Alerstam T, Hedenström A, Åkesson S: Long-distance migration: evolution and determinants. Oikos 2003, 2:247-260.
  • [6]Egevang C, Stenhouse IJ, Phillips RA, Petersen A, Fox JW, Silk JRD: Tracking of Arctic terns Sterna paradisaea reveals longest animal migration. Proc Natl Acad Sci U S A 2010, 107:2078-2081.
  • [7]Shaffer SA, Tremblay Y, Weimerskirch H, Scott D, Thompson DR, Sagar PM, Moller H, Taylor GA, Foley DG, Block BA, Costa DP: Migratory shearwaters integrate oceanic resources across the Pacific Ocean in an endless summer. Proc Nat Acad Sci 2006, 103:12799-12802.
  • [8]Wilson RP, Weimerskirch H, Lys P: A device for measuring seabird activity at sea. J Av Biol 1995, 26:172-176.
  • [9]Weimerskirch H, Wilson RP, Lys P: Activity pattern of foraging in the wandering albatross: a marine predator with two modes of prey searching. Mar Ecol Prog Ser 1997, 151:245-251.
  • [10]Fernández P, Anderson DJ: Nocturnal and Diurnal Foraging Activity of Hawaiian Albatrosses Detected With a New Immersion Monitor. Condor 2000, 102:577-584.
  • [11]Catry P, Phillips RA, Phalan B, Silk JRD, Croxall JP: Foraging strategies of grey-headed albatrosses Thalassarche chrysostoma: integration of movements, activity and feeding events. Mar Ecol Prog Ser 2004, 280:261-273.
  • [12]Phalan B, Phillips RA, Silk JRD, Afanasyev V, Fukuda A, Fox J, Catry P, Higuchi H, Croxall JP: Foraging behaviour of four albatross species by night and day. Mar Ecol Prog Ser 2007, 340:271-286.
  • [13]Guilford T, Meade J, Willis J, Phillips RA, Boyle D, Roberts S, Collett M, Freeman R, Perrins CM: Migration and stopover in a small pelagic seabird, the Manx Shearwater Puffinus puffinus: insights from machine learning. Pro Roy Soc B 2009, 276:1215-1223.
  • [14]Mackley E, Phillips R, Silk J, Wakefield E, Afanasyev V, Fox J, Furness R: Free as a bird? Activity patterns of albatrosses during the nonbreeding period. Mar Ecol Prog Ser 2010, 406:291-303.
  • [15]Catry P, Dias MP, Phillips RA, Granadeiro JP: Different means to the same end: long-distance migrant seabirds from two colonies differ in behaviour, despite common wintering grounds. PLoS One 2011, 6:E26079. doi:10.1371/journal.pone.0026079
  • [16]Dean B, Freeman R, Kirk H, Leonard K, Phillips RA, Perrins CM, Guilford T: Behavioural mapping of a pelagic seabird: combining multiple sensors and hidden Markov models reveals at-sea behaviour and key foraging areas.J R Soc Interface 2012, 10(78) doi:10.1098/rsif.2012.0570.
  • [17]Dias MP, Granadeiro JP, Catry P: Do seabirds differ from other migrants in their travel arrangements? On route strategies of Cory’s shearwater during its trans-equatorial journey. PLoS One 2012, 7:E49376. doi:10.1371/journal.pone.0049376
  • [18]Hedd A, Montevecchi W, Otley H, Phillips R, Fifield D: Trans-equatorial migration and habitat use by sooty shearwaters Puffinus griseus from the South Atlantic during the nonbreeding season. Mar Ecol Prog Ser 2012, 449:277-290.
  • [19]Freeman R, Dean B, Kirk H, Leonard K, Phillips RA, Perrins CM, Guilford T: Predictive ethoinformatics reveals the complex migratory behaviour of a pelagic seabird.J Roy Soc Interface 2012, 10(84) doi: 10.1098/rsif.2013.0279.
  • [20]Orians GH, Pearson NE: On the theory of central-place foraging. In Analysis of Ecological Systems. Edited by Horn DJ, Mitchell RD, Stairs GR. Ohio University Press, Columbus, Ohio; 1979:154-177.
  • [21]Croxall JP, Silk JRD, Phillips RA, Afanasyev V, Briggs DR: Global circumnavigations: tracking year-round ranges of nonbreeding albatrosses. Science 2005, 307:249-250.
  • [22]Arata JA, Sievert PR, Naughton MB: Status Assessment of Laysan and Black-footed Albatrosses, North Pacific Ocean, 1923–2005: A USGS Scientific Investigations Report 2009–5131. USGS, U.S. Geological Survey, Reston, Virginia; 2009.
  • [23]Tickell WLN: Albatrosses. Yale University Press, London; 2000.
  • [24][http://www.iucnredlist.org] webcite International Union for the Conservation of Nature: Red List of Threatened Species. 2014. .
  • [25]Fernández P, Anderson DJ, Sievert PR, Huyvaert KP: Foraging destinations of three low-latitude albatross (Phoebastria) species. J Zool 2001, 254:391-404.
  • [26]Hyrenbach KD, Fernández P, Anderson DJ: Oceanographic habitats of two sympatric North Pacific albatrosses during the breeding season. Mar Eco Pro Ser 2002, 233:283-301.
  • [27]Hyrenbach KD, Keiper C, Allen SG, Ainley DG, Anderson DJ: Use of marine sanctuaries by far-ranging predators: commuting flights to the California Current System by breeding Hawaiian albatrosses. Fish Oceanogr 2006, 15:95-103.
  • [28]Kappes MA, Shaffer SA, Tremblay Y, Foley DG, Palacios DM, Robinson PW, Bograd SJ, Costa DP: Hawaiian albatrosses track interannual variability of marine habitats in the North Pacific. Prog Oceanogr 2010, 86:246-260.
  • [29]Young LC, Vanderlip C, Duffy DC, Afanasyev V, Shaffer SA: Bringing home the trash: do colony-based differences in foraging distribution lead to increased plastic ingestion in Laysan albatrosses? PLoS One 2010, 4:e7623. doi:10.1371/journal.pone.0007623
  • [30]Hyrenbach KD, Dotson RC: Post-breeding movements of a male Black-footed albatross Phoebastria nigripes. Mar Ornithol 2001, 29:7-10.
  • [31]Fischer KN, Suryan RM, Roby DD, Balogh GR: Post-breeding season distribution of Black-footed and Laysan albatrosses satellite-tagged in Alaska: Inter-specific differences in spatial overlap with North Pacific fisheries. Biol Conserv 2009, 142:751-760.
  • [32]Hyrenbach D, Hester M, Adams J, Michael P, Vanderlip C, Keiper C, Carver M: Synthesis of Habitat Use by Black-footed Albatross tracked from Cordell Bank National Marine Sanctuary (2004–2008) and Kure Atoll Seabird Sanctuary 2008: A Special Report to NOAA. NOAA; 2010.
  • [33]Block BA, Jonsen ID, Jorgensen SJ, Winship AJ, Shaffer SA, Bograd SJ, Hazen EL, Foley DG, Breed GA, Harrison A-L, Ganong JE, Swithenbank A, Castleton M, Dewar H, Mate BR, Shillinger GL, Schaefer KM, Benson SR, Weise MJ, Henry RW, Costa DP: Tracking apex marine predator movements in a dynamic ocean. Nature 2011, 6:1-5.
  • [34]Gutowsky SE, Tremblay Y, Kappes MA, Flint EN, Klavitter J, Laniawe L, Costa DP, Naughton MB, Romano MD, Shaffer SA: Divergent post-breeding distribution and habitat associations of fledgling and adult Black-footed Albatrosses Phoebastria nigripes in the North Pacific. Ibis 2014, 156:60-72.
  • [35]Jonsen ID, Myers RA, Flemming JM: Meta-analysis of animal movement using state-space models. Ecology 2003, 84:3055-3063.
  • [36]Jonsen ID, Flemming JM, Myers RA: Robust state-space modelling of animal movement data. Ecology 2005, 86:2874-2880.
  • [37]Wood SN: Generalized Additive Models: An Introduction with R. Chapman and Hall⁄CRC press, Boca Raton, Florida; 2006.
  • [38]Phillips RA, Xavier JC, Croxall JP: Effects of satellite transmitters on albatrosses and petrels. Auk 2003, 120:1082-1090.
  • [39]Ekstrom PA: An advance in geolocation by light. Mem Nat Inst Polar Res Spec Issue 2004, 58:210-226.
  • [40]Shaffer SA, Tremblay Y, Awkerman JA, Henry RW, Teo SLH, Anderson DJ, Croll DA, Block BA, Costa DP: Comparison of light- and SST-based geolocation with satellite telemetry in free-ranging albatrosses. Mar Biol 2005, 147:833-843.
  • [41]Thiebot J, Pinaud D: Quantitative method to estimate species habitat use from light-based geolocation data. Endanger Species Res 2010, 10:341-353.
  • [42]Worton BJ: Kernel methods for estimating the utilization distribution in home-range studies. Ecology 1989, 70:164-168.
  • [43]Wood AG, Naef-Daenzer NB, Prince PA, Croxall JP: Quantifying habitat use in satellite-tracked seabirds: application of kernel estimation to albatross locations. J Avian Biol 2000, 31:278-286.
  • [44]Shaffer SA, Weimerskirch H, Scott D, Pinaud D, Thompson DR, Sagar PM, Moller H, Taylor GA, Foley DG, Tremblay Y, Costa DP: Spatiotemporal habitat use by breeding sooty shearwaters Puffinus griseus. Mar Ecol Prog Ser 2009, 391:209-220.
  • [45]McKnight A, Irons DB, Allyn AJ, Sullivan KM, Suryan RM: Winter dispersal and activity patterns of post-breeding black-legged kittiwakes Rissa tridactyla from Prince William Sound, Alaska. Mar Ecol Prog Ser 2011, 442:241-253.
  • [46]Weimerskirch H, Guionnet T, Martin J, Shaffer SA, Costa DP: Fast and fuel-efficient? Optimal use of wind by flying albatrosses. Proc Roy Soc Lon B 2000, 267:1869-1874.
  • [47]Shaffer SA, Costa DP, Weimerskirch H: Behavioural factors affecting foraging effort in breeding wandering albatrosses. J Anim Eco 2001, 70:864-874.
  • [48]Luque SP, Guinet C: A maximum likelihood approach for identifying dive bouts improves accuracy, precision and objectivity. Behaviour 2007, 144:1315-1332.
  • [49]Luque SP, Arnould JPY, Guinet C: Temporal structure of diving behaviour in sympatric Antarctic and subantarctic fur seals. Mar Ecol Prog Ser 2008, 372:277-287.
  • [50]Regular PM, Hedd A, Montevecchi W: Fishing in the dark: a pursuit-diving seabird modifies foraging behaviour in response to nocturnal light levels. PLoS One 2011, 6:E26763. doi:10.1371/journal.pone.0026763
  • [51]Leung E, Chilvers B, Moore A, Robertson B: Mass and bathymetry influences on the foraging behaviour of dependent yearling New Zealand sea lions (Phocarctos hookeri). New Zeal J Mar Freshw Res 2013, 47:38-50.
  • [52]Luque SP: Diving behavior analysis in R. R News 2007, 7:8-14.
  • [53]Zuur AF, Ieno EN, Walker N, Saveliev AA, Smith GM: Mixed Effects Models and Extensions in Ecology with R. Springer, New York; 2009.
  • [54]Pineiro JC, Bates DM: Mixed Effects Models in S and S-Plus. Springer-Verlag, New York; 2000.
  • [55]Shuntov VP: Seabirds and the biological structure of the ocean: National Technical Information Service TT-74-55032. Washington, DC, US Department of Commerce; 1972.
  • [56]Strandberg R, Alerstam T: The strategy of fly-and-forage migration, illustrated for the osprey (Pandion haliaetus). Behav Ecol Sociobiol 2007, 61:1865-1875.
  • [57]Edwards AE: Large-scale variation in flight feather molt as a mechanism enabling biennial breeding in albatrosses. J Avian Biol 2008, 39:144-151.
  • [58]Edwards AE, Rohwer S: Large-Scale Patterns of Molt Activation in the Flight Feathers of Two Albatross Species. Condor 2005, 107:835-848.
  • [59]Rohwer S, Viggiano A, Marzluff JM: Reciprocal Tradeoffs Between Molt and Breeding in Albatrosses. Condor 2011, 113:61-71.
  • [60]Meyers RA, Stakebake EF: Anatomy and histochemistry of spread-wing posture in birds. 3. Immunohistochemistry of flight muscles and the “shoulder lock” in albatrosses. J Morphol 2005, 263:12-29.
  • [61]Hedenstrom A, Sunada S: On the aerodynamics of moult gaps in birds. J Exp Biol 1999, 202:67-76.
  • [62]Bridge E: Influences of morphology and behavior on wing-molt strategies in seabirds. Mar Ornithol 2006, 19:7-19.
  • [63]Suryan RM, Anderson DJ, Shaffer SA, Roby DD, Tremblay Y, Costa DP, Sato F, Ozaki K: Wind, waves, and wing loading: Their relative importance to the at-sea distribution and movements of North and Central Pacific albatrosses. PLoS One 2008, 3(12):E4016. doi:10.1371/journal.pone.0004016
  • [64]Langston NE, Rohwer S: Molt-breeding tradeoffs in albatrosses: Life history implications for big birds. Oikos 1996, 76:498-510.
  • [65]Astheimer LB, Prince PA, Grau CR: Egg formation and the pre-laying period of Black-browed and Grey-headed Albatrosses Diomedea melanophris and D. chrysostoma at Bird Island, South Georgia. Ibis 1985, 127:523-529.
  • [66]Frings BH, Frings M: Some biometric studies on the albatrosses of midway atoll. Condor 1961, 63:304-312.
  • [67]Suryan RM, Dietrich KS, Melvin EF, Balogh GR, Sato F, Ozaki K: Migratory routes of short-tailed albatrosses: Use of exclusive economic zones of North Pacific Rim countries and spatial overlap with commercial fisheries in Alaska. Biol Conserv 2007, 137:450-460.
  • [68]Rayner MJ, Taylor GA, Thompson DR, Torres L, Sagar PM, Shaffer SA: Migration and diving activity in three non-breeding Flesh-footed shearwaters Puffinus carneipes. J Avi Biol 2011, 42:266-270.
  • [69]Carey MJ, Phillips RA, Silk JRD, Shaffer SA: Trans-equatorial migration of Short-tailed Shearwaters – testing old theories with new technology.Emu in press.
  • [70]Anderson O, Small C, Croxall J, Dunn E, Sullivan B, Yates O, Black A: Global seabird bycatch in longline fisheries. Endanger Species Res 2011, 14:91-106.
  文献评价指标  
  下载次数:67次 浏览次数:20次