DOCSLIB.ORG

Or POLYMYODI): Oscines (Songbirds

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Or POLYMYODI): Oscines (Songbirds Text extracted from Gill B.J.; Bell, B.D.; Chambers, G.K.; Medway, D.G.; Palma, R.L.; Scofield, R.P.; Tennyson, A.J.D.; Worthy, T.H. 2010. Checklist of the birds of New Zealand, Norfolk and Macquarie Islands, and the Ross Dependency, Antarctica. 4th edition. Wellington, Te Papa Press and Ornithological Society of New Zealand. Pages 275, 279, 301-302 & 305-306. Order PASSERIFORMES: Passerine (Perching) Birds See Christidis & Boles (2008) for a review of recent studies relevant to the higher-level systematics of the passerine birds. Suborder PASSERES (or POLYMYODI): Oscines (Songbirds) The arrangement of songbirds in the 1970 Checklist (Checklist Committee 1970) was based on the premise that the species endemic to the Australasian region were derived directly from Eurasian groups and belonged in Old World families (e.g. Gerygone and Petroica in Muscicapidae). The 1990 Checklist (Checklist Committee 1990) followed the Australian lead in allocating various native songbirds to their own Australasian families (e.g. Gerygone to Acanthizidae, and Petroica to Eopsaltriidae), but the sequence was still based largely on the old Peters-Mayr arrangement. Since the late 1980s, when the 1990 Checklist was finalised, evidence from molecular biology, especially DNA studies, has shown that most of the Australian and New Zealand endemic songbirds are the product of a major Australasian radiation parallel to the radiation of songbirds in Eurasia and elsewhere. Many superficial morphological and ecological similarities between Australasian and Eurasian songbirds are the result of convergent evolution. Sibley & Ahlquist (1985, 1990) and Sibley et al. (1988) recognised a division of the songbirds into two groups which were called Corvida and Passerida (Sibley & Ahlquist 1990). The Parvorder Corvida contained songbirds with Australasian affinities—nearly all the endemic New Zealand songbirds plus the introduced Australian magpie. The Parvorder Passerida contained songbirds with Old World affinities— nearly all the songbirds introduced to New Zealand, plus one endemic genus (Bowdleria) and a few native songbirds (e.g Hirundo, Zosterops). Recent studies (e.g. Barker et al. 2004, Cracraft et al. 2004) partly supported the distinction between Corvida and Passerida, but questioned the monophyly of the Corvida. Passerida is now thought not to be the sister group to Corvida but to be embedded within it (see detailed discussion by Christidis & Boles 2008) with Petroica added to the list of native Australasian passeridans. The following arrangement of New Zealand songbirds is based largely (and where relevant) on the sequence justified by Christidis & Boles (2008). It is an interim scheme which is likely to change in future checklists with further research on songbird phylogeny. Recent improvements in techniques to eliminate or control mammalian predators on islands, or in defined mainland areas, mean that some of the New Zealand endemic songbirds are being translocated (re- introduced) to growing lists of localities at which predators are controlled. This is extending the ranges of the species concerned —ranges that were shrinking. Many of the more recent transfers are not mentioned in the species accounts because several years must pass before the viability of a given transfer can be assured. “PASSERIDA”: Eurasian and New World Songbirds The families recognised within Passerida, and their sequence, follow Christidis & Boles (2008) except for the Prunellidae, which they did not cover. Petroica is now seen as a passeridan genus rather than a corvidan one, for the reasons discussed by Christidis & Boles (2008). Niethammer (1971) attempted to assign subspecific attributions to all the populations of European songbirds established in New Zealand. However, in some cases this is problematical for a list of reasons discussed by Checklist Committee (1990: xii), and until more work is done on these taxa some are best named at just the binomial level. Family PETROICIDAE Mathews: Australasian Robins Petroicinae Mathews, 1920: Birds Australia. 8: 80 – Type genus Petroica Swainson, 1830. Genus Petroica Swainson The order of New Zealand taxa follows Checklist Committee (1990), which recognised three New Zealand species following Fleming (1950a,b). Miller & Lambert (2006) analysed mtDNA sequences of New Zealand populations of Petroica. Their study supported the specific status of the black robin, and supported the separation of North and South Island robins at the specific level. The North Island robin is considerably smaller than its South Island congener, with marked plumage differences, as detailed in the major study by Fleming (1950a,b). We have given them specific rank, but the Stewart Island / Rakiura population is poorly distinguished, both genetically (Miller & Lambert 2006) and morphologically, and is retained here as a subspecies of the South Island robin. Miller & Lambert (2006) recommended retaining the tomtit populations as subspecies; the greatest genetic distinction, in the sequences they studied, was for the Chatham Island tomtit rather than the melanistic Snares Island tomtit. Given this, we have retained the status quo (Checklist Committee 1990) with the tomtit taxa kept as subspecies, pending further data. Fleming’s hypothesis (1950a,b) that the black robin is an insular derivative of the mainland robins, was not supported by Miller & Lambert (2006), who found that it grouped strongly with the tomtit instead. If upheld by further data (such as sequences from other genes) this could mean the removal of P. traversi from the subgenus Miro to the subgenus Petroica. Hamilton (1909: 15) listed “Petroeca vittata, Quoy et Gaim. (Dusky Robin.)”, as a species present in New Zealand. That species, currently known as Melanodryas (Amaurodryas) vittata (Quoy & Gaimard, 1830), is endemic to Tasmania (Green 1989: 58) and has not been recorded in New Zealand. Hamilton’s “Petroeca vittata” is almost certainly a misidentification. Subgenus Miro Lesson Miro Lesson, 1831: Traité d’Ornith. 5(1): 389 – Type species (by monotypy) Muscicapa longipes Garnot = Petroica (Miro) longipes (Lesson). Myioscopus Reichenbach, 1850: Avium Syst. Nat.: pl. 67 – Type species (by monotypy) Muscicapa longipes Garnot = Petroica (Miro) longipes (Garnot). Nesomiro Mathews & Iredale, 1913: Ibis 1 (10th ser.): 440 – Type species (by original designation) Miro traversi Buller = Petroica (Miro) traversi (Buller). Petroica (Miro) australis (Sparrman) South Island Robin South Island plus Stewart Island / Rakiura and its outliers. Petroica (Miro) australis australis (Sparrman) South Island Robin Turdus australis Sparrman, 1788: Mus. Carlsonianum 3: no LXIX, pl. 69 – Dusky Sound, Fiordland. Turdus albifrons Gmelin, 1789: Syst. Nat., 13th edition 1(2): 882. Based on the “White-fronted Thrush” of Latham 1783, Gen. Synop. Birds 2(1): 71 – Dusky Sound, Fiordland. Miro albifrons (Gmelin); G.R. Gray 1843, in E. Dieffenbach, Travels in N.Z. 2: 190. Aplonis australis (Sparrman); G.R. Gray 1843, in E. Dieffenbach, Travels in N.Z. 2: 192. Petroica albifrons (Gmelin); G.R. Gray 1844, in Richardson & J.E. Gray (eds), Zool. Voy. ‘Erebus’ & ‘Terror’, Birds 1(3): 7, pl. 6, fig. 2. Turdus ochrotarsus J.R. Forster, 1844: in M.H.C. Lichtenstein, Descrip. Animalium: 82 – Dusky Sound, Fiordland. Muscicapa saxicolina Bonaparte, 1851: Consp. Gen. Avium 1: 300 – New Zealand. Muscicapa albifrons (Gmelin); Ellman 1861, Zoologist 19: 7465. Myioscopus albifrons (Gmelin); Finsch 1872, Journ. für Ornith. 20: 112. Miro ochrotarsus (J.R. Forster); Buller 1896, Trans. Proc. N.Z. Inst. 28: 337. Miro albifrons (Gmelin); Buller 1905, Suppl. Birds N.Z. 2: 120. Miro bulleri Sharpe, 1905: in Buller, Suppl. Birds N.Z. 2: 123 – Karamea Saddle, north West Coast. Miro australis bulleri Buller [sic]; Mathews & Iredale 1913, Ibis 1 (10th ser.): 439. Miro australis australis (Sparrman); Mathews & Iredale 1913, Ibis 1 (10th ser.): 439. Miro australis (Sparrman); Oliver 1930, New Zealand Birds, 1st edition: 466. Petroica (Miro) australis australis (Sparrman); Checklist Committee 1990, Checklist Birds N.Z.: 210. Petroica australis (Sparrman); Holdaway et al. 2001, New Zealand Journ. Zool. 28(2): 138, 180. South Island: native and older exotic forests especially in the northern third of the island and the south- west (Fiordland); otherwise of restricted and local distribution. Widely distributed Holocene fossil and midden records, several outside the present range. Petroica (Miro) australis rakiura C.A. Fleming Stewart Island Robin Petroica (Miro) australis rakiura C.A. Fleming, 1950: Trans. Roy. Soc. N.Z. 78(1): 141 – Jacques Lees [= Jacky Lee] Island, off east coast of Stewart Island. Miro australis rakiura (C.A. Fleming); Oliver 1955, New Zealand Birds, 2nd edition: 489. Stewart Island / Rakiura and outliers (e.g. Jacky Lee Island (Pukeokaoka) and Green Island). .
Load more

Recommended publications
  • Disaggregation of Bird Families Listed on Cms Appendix Ii
    Convention on the Conservation of Migratory Species of Wild Animals 2nd Meeting of the Sessional Committee of the CMS Scientific Council (ScC-SC2) Bonn, Germany, 10 – 14 July 2017 UNEP/CMS/ScC-SC2/Inf.3 DISAGGREGATION OF BIRD FAMILIES LISTED ON CMS APPENDIX II (Prepared by the Appointed Councillors for Birds) Summary: The first meeting of the Sessional Committee of the Scientific Council identified the adoption of a new standard reference for avian taxonomy as an opportunity to disaggregate the higher-level taxa listed on Appendix II and to identify those that are considered to be migratory species and that have an unfavourable conservation status. The current paper presents an initial analysis of the higher-level disaggregation using the Handbook of the Birds of the World/BirdLife International Illustrated Checklist of the Birds of the World Volumes 1 and 2 taxonomy, and identifies the challenges in completing the analysis to identify all of the migratory species and the corresponding Range States. The document has been prepared by the COP Appointed Scientific Councilors for Birds. This is a supplementary paper to COP document UNEP/CMS/COP12/Doc.25.3 on Taxonomy and Nomenclature UNEP/CMS/ScC-Sc2/Inf.3 DISAGGREGATION OF BIRD FAMILIES LISTED ON CMS APPENDIX II 1. Through Resolution 11.19, the Conference of Parties adopted as the standard reference for bird taxonomy and nomenclature for Non-Passerine species the Handbook of the Birds of the World/BirdLife International Illustrated Checklist of the Birds of the World, Volume 1: Non-Passerines, by Josep del Hoyo and Nigel J. Collar (2014); 2.
    [Show full text]
  • Birds Oforegon
    ttttCuittJtkL COILE1 JUN 1,'1924 Ii.1MRY 6000. Bulletin No. 68. January, 1902. OREGON AGRiCULTURAL EXPERIMENT STATION, CORVALLIS. OREGON. ANNOTATED LIST OF THE BIRDS OFOREGON A. R. WOODCOCK. The Bulletins of this Station are sent Free to all Residents of Oregon who request them. - Oregon Agricultural College Printing OSce. Gico. B. KEAO-V, Printer. 1902. Board of Regents of the Oregon Agricultural Gollege and Exjierifflent Station Hon. J. K. Weatherford, President Albany, Oregon. Hon. John D. Daly, Secretary Corvallis, Oregon. Hon. B. F. Irvine, Treasurer Corvallis, Oregon. Hon. T. T. Geer, Governor Salem, Oregon. Hon. F. I. Dunbar, Secretary of Stale Salem, Oregon. Hon. J. H. Ackerman, State Sut. of Pub. Instruction, Salem, Oregon. Hon. B. G. Leedy, iWaster of Stale Grange Tigardville, Oregon. Hon. Benton Kuhn Portland, Oregon. Hon. Jonas M. Church La Grande, Oregon. Hon. William E. Yates Corvallis, Oregon. Hon. J. T. Olwell Central Point, Oregon. Hon. J. T. Apperson, Park Place, Oregon. Hon. W. P. Keady Portland, Oregon. OFFICERS OF THE STATION. STATION COUNCIL. Thos. M. Gatch, A. M,, Ph. D President and .D-zreclor, James Withycombe, M. Agr Vice-Director and AgrculEurist. A. L. Tuisely, M. S. Chemist. B. Cordley, M. 5 Entomologist. R. Lake, M. S Horticultnrist and Botanist. B. P. Pernot Bacteriology. Other Members of Staff'. George Coote Florist. F. L. Kent, B. S Dairying. C. M. McKeUips, Ph. C., M. S... Chemistry. .. F. B. Edwards, B. M. B. -. CJzemstiy. I THE DENNY PHEASANT. Introduced from China by Judge 0. N. Denny in 1880-81.See page4. I N TROD U CT! ON.
    [Show full text]
  • Birds Suborder PASSERES (Or POLYMYODI): Oscines
    Text extracted from Gill B.J.; Bell, B.D.; Chambers, G.K.; Medway, D.G.; Palma, R.L.; Scofield, R.P.; Tennyson, A.J.D.; Worthy, T.H. 2010. Checklist of the birds of New Zealand, Norfolk and Macquarie Islands, and the Ross Dependency, Antarctica. 4th edition. Wellington, Te Papa Press and Ornithological Society of New Zealand. Pages 275, 279 & 301-305. Order PASSERIFORMES: Passerine (Perching) Birds See Christidis & Boles (2008) for a review of recent studies relevant to the higher-level systematics of the passerine birds. Suborder PASSERES (or POLYMYODI): Oscines (Songbirds) The arrangement of songbirds in the 1970 Checklist (Checklist Committee 1970) was based on the premise that the species endemic to the Australasian region were derived directly from Eurasian groups and belonged in Old World families (e.g. Gerygone and Petroica in Muscicapidae). The 1990 Checklist (Checklist Committee 1990) followed the Australian lead in allocating various native songbirds to their own Australasian families (e.g. Gerygone to Acanthizidae, and Petroica to Eopsaltriidae), but the sequence was still based largely on the old Peters-Mayr arrangement. Since the late 1980s, when the 1990 Checklist was finalised, evidence from molecular biology, especially DNA studies, has shown that most of the Australian and New Zealand endemic songbirds are the product of a major Australasian radiation parallel to the radiation of songbirds in Eurasia and elsewhere. Many superficial morphological and ecological similarities between Australasian and Eurasian songbirds are the result of convergent evolution. Sibley & Ahlquist (1985, 1990) and Sibley et al. (1988) recognised a division of the songbirds into two groups which were called Corvida and Passerida (Sibley & Ahlquist 1990).
    [Show full text]
  • Printable PDF Format
    Field Guides Tour Report Australia Part 2 2019 Oct 22, 2019 to Nov 11, 2019 John Coons & Doug Gochfeld For our tour description, itinerary, past triplists, dates, fees, and more, please VISIT OUR TOUR PAGE. Water is a precious resource in the Australian deserts, so watering holes like this one near Georgetown are incredible places for concentrating wildlife. Two of our most bird diverse excursions were on our mornings in this region. Photo by guide Doug Gochfeld. Australia. A voyage to the land of Oz is guaranteed to be filled with novelty and wonder, regardless of whether we’ve been to the country previously. This was true for our group this year, with everyone coming away awed and excited by any number of a litany of great experiences, whether they had already been in the country for three weeks or were beginning their Aussie journey in Darwin. Given the far-flung locales we visit, this itinerary often provides the full spectrum of weather, and this year that was true to the extreme. The drought which had gripped much of Australia for months on end was still in full effect upon our arrival at Darwin in the steamy Top End, and Georgetown was equally hot, though about as dry as Darwin was humid. The warmth persisted along the Queensland coast in Cairns, while weather on the Atherton Tablelands and at Lamington National Park was mild and quite pleasant, a prelude to the pendulum swinging the other way. During our final hours below O’Reilly’s, a system came through bringing with it strong winds (and a brush fire warning that unfortunately turned out all too prescient).
    [Show full text]
  • 9SS Bioone Complete
    9SS BioOne complete Phylogeny, Biodiversity, and Species Limits of Passerine Birds in the Sino-Himalayan Region—A Critical Review* Authors: Martens, Jochen, Institut für Zoologie, Johannes Gutenberg-Universität Mainz, 55099 Mainz, Germany, Tietze, Dieter Thomas, Senckenberg Naturhistorische Sammlungen Dresden, Museum für Tierkunde, Königsbrücker Landstraße 159, D-01109 Dresden, Germany, and Päckert, Martin, Senckenberg Naturhistorische Sammlungen Dresden, Museum für Tierkunde, Königsbrücker Landstraße 159, D-01109 Dresden, Germany Source: Ornithological Monographs No. 70 Published By: American Ornithological Society URL: https://doi.org/10.1525/om.2011.70.1.64 BioOne Complete (complete.BioOne.org) is a full-text database of 200 subscribed and open-access titles in the biological, ecological, and environmental sciences published by nonprofit societies, associations, museums, institutions, and presses. Your use of this PDF, the BioOne Complete website, and all posted and associated content indicates your acceptance of BioOne’s Terms of Use, available at www.bioone.org/terms-of-use. Usage of BioOne Complete content is strictly limited to personal, educational, and non-commercial use. Commercial inquiries or rights and permissions requests should be directed to the individual publisher as copyright holder. BioOne sees sustainable scholarly publishing as an inherently collaborative enterprise connecting authors, nonprofit publishers, academic institutions, research libraries, and research funders in the common goal of maximizing access to
    [Show full text]
  • Discovery of a Relict Lineage and Monotypic Family of Passerine Birds
    Discovery of a relict lineage and monotypic family of passerine birds Based on a comprehensive molecular dataset of passerines birds we identified a branch with a single species, the Spotted Wren-babbler Spelaeornis formosus. We suggest that this represents a relict lineage, which we propose should be placed in its own family, Elachuridae. The scientific name Elachura formosa should be used. We analysed of one of the most comprehensive datasets to date of the largest passerine bird clade, Passerida, which comprises c. 36% of the World’s c. 10,500 bird species. We identified 10 primary branches in the tree. One of these primary branches was made up of a single species, the Spotted Wren-Babbler Spelaeornis formosus, which is a small Wren-like bird that occurs in mountains from the eastern Himalayas to southeast China. This species apparently represents an old branch in the large passerine tree, without any close living relatives. There have surely been other relatives on this branch, which have gone extinct. The fact that it resembles wren-babblers and wrens in appearance is either due to pure chance or to convergent evolution, which may result in similar appearances in unrelated species that live in similar environments. We proposed the new family name Elachuridae for this single species. We also suggested that the scientific name Elachura formosa should be used, and the English name be changed to Elachura, to highlight its distinctness. Timaliidae (56) Pellorneidae (69) Leiothrichidae (133) Zosteropidae (128) Sylviidae (70) Pnoepygidae
    [Show full text]
  • Based on Nuclear and Mitochondrial Sequence Data
    MOLECULAR PHYLOGENETICS AND EVOLUTION Molecular Phylogenetics and Evolution 29 (2003) 126–138 www.elsevier.com/locate/ympev Phylogeny of Passerida (Aves: Passeriformes) based on nuclear and mitochondrial sequence data Per G.P. Ericsona,* and Ulf S. Johanssona,b a Department of Vertebrate Zoology and Molecular Systematics Laboratory, Swedish Museum of Natural History, Frescativagen 44, P.O. Box 50007, SE-10405 Stockholm, Sweden b Department of Zoology, University of Stockholm, SE-106 91 Stockholm, Sweden Received 18 September 2002; revised 23 January 2003 Abstract Passerida is a monophyletic group of oscine passerines that includes almost 3500 species (about 36%) of all bird species in the world. The current understanding of higher-level relationships within Passerida is based on DNA–DNA hybridizations [C.G. Sibley, J.E. Ahlquist, Phylogeny and Classification of Birds, 1990, Yale University Press, New Haven, CT]. Our results are based on analyses of 3130 aligned nucleotide sequence data obtained from 48 ingroup and 13 outgroup genera. Three nuclear genes were sequenced: c-myc (498–510 bp), RAG-1 (930 bp), and myoglobin (693–722 bp), as well one mitochondrial gene; cytochrome b (879 bp). The data were analysed by parsimony, maximum-likelihood, and Bayesian inference. The African rockfowl and rock- jumper are found to constitute the deepest branch within Passerida, but relationships among the other taxa are poorly resolved— only four major clades receive statistical support. One clade corresponds to Passeroidea of [C.G. Sibley, B.L. Monroe, Distribution and Taxonomy of Birds of the World, 1990, Yale University Press, New Haven, CT] and includes, e.g., flowerpeckers, sunbirds, accentors, weavers, estrilds, wagtails, finches, and sparrows.
    [Show full text]
  • New Zealand Passerines Help Clarify the Diversification of Major Songbird Lineages During the Oligocene
    GBE New Zealand Passerines Help Clarify the Diversification of Major Songbird Lineages during the Oligocene Gillian C. Gibb1,*,y, Ryan England2,4,y, Gerrit Hartig2,5, Patricia A. (Trish) McLenachan2, Briar L. Taylor Smith1, Bennet J. McComish2,6, Alan Cooper3, and David Penny2 1Ecology Group, Institute of Agriculture and Environment, Massey University, Palmerston North, New Zealand 2Institute of Fundamental Sciences, Massey University, Palmerston North, New Zealand 3Australian Centre for Ancient DNA, School of Earth and Environmental Sciences, University of Adelaide, South Australia, Australia 4Present address: Forensic Business Group, Institute of Environmental Science and Research (ESR Ltd.), Mt Albert Science Centre, Auckland, New Zealand 5Present address: Starlims Germany GmbH An Abbott Company, Witten, Germany 6Present address: School of Physical Sciences, University of Tasmania, Hobart, Australia *Corresponding author: E-mail: [email protected]. yThese authors contributed equally to this work. Accepted: October 7, 2015 Data deposition: This project has been deposited at GenBank under the accession numbers KC545397-KC545409, KT894672. Abstract Passerines are the largest avian order, and the 6,000 species comprise more than half of all extant bird species. This successful radiation probably had its origin in the Australasian region, but dating this origin has been difficult due to a scarce fossil record and poor biogeographic assumptions. Many of New Zealand’s endemic passerines fall within the deeper branches of the passerine radiation, and a well resolved phylogeny for the modern New Zealand element in the deeper branches of the oscine lineage will help us understand both oscine and passerine biogeography. To this end we present complete mitochondrial genomes representing all families of New Zealand passerines in a phylogenetic framework of over 100 passerine species.
    [Show full text]
  • The Division of the Major Songbird Radiation Into Passerida and 'Core
    TheBlackwell Publishing Ltd division of the major songbird radiation into Passerida and ‘core Corvoidea’ (Aves: Passeriformes) — the species tree vs. gene trees MARTIN IRESTEDT & JAN I. OHLSON Submitted: 19 July 2007 Irestedt, M. & Ohlson, J. I. (2008). The division of the major songbird radiation into Passerida Accepted: 26 November 2007 and ‘core Corvoidea’ (Aves: Passeriformes) — the species tree vs. gene trees. — Zoologica doi:10.1111/j.1463-6409.2007.00321.x Scripta, 37, 305–313. The knowledge of evolutionary relationships among oscine songbirds has been largely improved in recent years by molecular phylogenetic studies. However, current knowledge is still largely based on sequence data from a limited number of loci. In this study, we re-evaluate relationships among basal lineages within the ‘core Corvoidea’ and Passerida radiations, by adding additional loci to previously published data. The trees obtained from the individual genes suggest incongruent topologies. Especially the positions of Callaeatidae (wattlebirds), Cnemophilidae (satinbirds) and Melanocharitidae (longbills and berrypeckers) vary among the trees, but RAG-1 is the only gene that unambiguously suggested a ‘core Corvoidea’ affinity for these taxa. Analyses of various combined data sets show that the phylogenetic positions for Callaeatidae, Cnemophilidae and Melanocharitidae largely depend on which genes that have been combined. As the RAG-1 gene has contributed to a majority of the phylogenetic information in previous studies, it has deeply influenced previous molecular affinities of these taxa. Based on the current data, we found a reasonable support for a Passerida affinity of Callaeatidae and Cnemophilidae, contrary to previous molecular studies. The position of Melanocharitidae is more unstable but a basal position among Passerida is congruent with a deletion observed in the glyceraldehyde-3-phosphodehydrogenase (GAPDH) loci.
    [Show full text]
  • Distribution, Ecology, and Life History of the Pearly-Eyed Thrasher (Margarops Fuscatus)
    Adaptations of An Avian Supertramp: Distribution, Ecology, and Life History of the Pearly-Eyed Thrasher (Margarops fuscatus) Chapter 6: Survival and Dispersal The pearly-eyed thrasher has a wide geographical distribution, obtains regional and local abundance, and undergoes morphological plasticity on islands, especially at different elevations. It readily adapts to diverse habitats in noncompetitive situations. Its status as an avian supertramp becomes even more evident when one considers its proficiency in dispersing to and colonizing small, often sparsely The pearly-eye is a inhabited islands and disturbed habitats. long-lived species, Although rare in nature, an additional attribute of a supertramp would be a even for a tropical protracted lifetime once colonists become established. The pearly-eye possesses passerine. such an attribute. It is a long-lived species, even for a tropical passerine. This chapter treats adult thrasher survival, longevity, short- and long-range natal dispersal of the young, including the intrinsic and extrinsic characteristics of natal dispersers, and a comparison of the field techniques used in monitoring the spatiotemporal aspects of dispersal, e.g., observations, biotelemetry, and banding. Rounding out the chapter are some of the inherent and ecological factors influencing immature thrashers’ survival and dispersal, e.g., preferred habitat, diet, season, ectoparasites, and the effects of two major hurricanes, which resulted in food shortages following both disturbances. Annual Survival Rates (Rain-Forest Population) In the early 1990s, the tenet that tropical birds survive much longer than their north temperate counterparts, many of which are migratory, came into question (Karr et al. 1990). Whether or not the dogma can survive, however, awaits further empirical evidence from additional studies.
    [Show full text]
  • Margarops Fuscatus)In Puerto Rico
    624 THE WILSON JOURNAL OF ORNITHOLOGY N Vol. 123, No. 3, September 2011 The Wilson Journal of Ornithology 123(3):624–628, 2011 Hourly Laying Patterns of the Pearly-eyed Thrasher (Margarops fuscatus)in Puerto Rico Wayne J. Arendt1 ABSTRACT.—Temporal aspects of egg deposition hatching patterns and synchrony, size, fitness, and are important factors governing avian reproductive viability of nestlings (Williams 1994, Maddox and success. I report hourly egg-laying patterns of the Weatherhead 2008). Egg size, usually expressed in Pearly-eyed Thrasher (Margarops fuscatus)inthe Luquillo Experimental Forest in northeastern Puerto volumetric or longitudinal measures (Barta and Rico during 1979–2000. Initiatory eggs were laid by Szekely 1997), is often correlated to hatchling size, early morning (median 5 0642 hrs, AST) and almost fitness, and subsequent nestling development half of the eggs were laid by 0723 hrs. Many (Slagsvold et al. 1984, Deeming and Birchard penultimate and eggs completing a clutch, however, 2007). However, Ricklefs (1984) cautioned using were laid later in the morning and some not until mid egg size or mass as a measure of egg quality as afternoon (1429 hrs), thus extending egg deposition to actual composition, e.g., the amount and quality of 8 hrs. Delayed laying of the last eggs in a clutch may be an adaptive strategy triggering brood reduction to yolk, is usually independent of linear or volumetric ensure survival of older and more robust siblings during measures. Even variation in embryonic metabolic periods of physiological stress and food shortages. rates influences time of hatching and hatchling Received 20 March 2007.
    [Show full text]
  • Eastern Australia: October-November 2016
    Tropical Birding Trip Report Eastern Australia: October-November 2016 A Tropical Birding SET DEPARTURE tour EASTERN AUSTRALIA: From Top to Bottom 23rd October – 11th November 2016 The bird of the trip, the very impressive POWERFUL OWL Tour Leader: Laurie Ross All photos in this report were taken by Laurie Ross/Tropical Birding. 1 www.tropicalbirding.com +1-409-515-9110 [email protected] Page Tropical Birding Trip Report Eastern Australia: October-November 2016 INTRODUCTION The Eastern Australia Set Departure Tour introduces a huge amount of new birds and families to the majority of the group. We started the tour in Cairns in Far North Queensland, where we found ourselves surrounded by multiple habitats from the tidal mudflats of the Cairns Esplanade, the Great Barrier Reef and its sandy cays, lush lowland and highland rainforests of the Atherton Tablelands, and we even made it to the edge of the Outback near Mount Carbine; the next leg of the tour took us south to Southeast Queensland where we spent time in temperate rainforests and wet sclerophyll forests within Lamington National Park. The third, and my favorite leg, of the tour took us down to New South Wales, where we birded a huge variety of new habitats from coastal heathland to rocky shorelines and temperate rainforests in Royal National Park, to the mallee and brigalow of Inland New South Wales. The fourth and final leg of the tour saw us on the beautiful island state of Tasmania, where we found all 13 “Tassie” endemics. We had a huge list of highlights, from finding a roosting Lesser Sooty Owl in Malanda; to finding two roosting Powerful Owls near Brisbane; to having an Albert’s Lyrebird walk out in front of us at O Reilly’s; to seeing the rare and endangered Regent Honeyeaters in the Capertee Valley, and finding the endangered Swift Parrot on Bruny Island, in Tasmania.
    [Show full text]