160 research outputs found

    Not so rare snakes: a revision of theGeophis sieboldigroup (Colubridae: Dipsadinae) in lower Central America and Colombia

    No full text
    Figure 9. Comparison of variation in total segmental counts in four population samples of the Geophis brachycephalus complex.Published as part of Savage, Jay M. & Watling, James I., 2008, Not so rare snakes: a revision of the Geophis sieboldi group (Colubridae: Dipsadinae) in lower Central America and Colombia, pp. 561-599 in Zoological Journal of the Linnean Society 153 (3) on page 576, DOI: 10.1111/j.1096-3642.2008.00400.x, http://zenodo.org/record/544614

    Science Support for Climate Change Adaptation in South Florida

    No full text
    WEC286, a 5-page illustrated fact sheet by Laura M. Early, Rebecca G. Harvey, Laura A. Brandt, James I. Watling, and Frank J. Mazzotti, discusses how climate change will affect sea level and the ecosystem in South Florida and outlines the Department of Interior’s approach to manage public lands and natural resources impacted by climate change. Includes references. Published by the UF Department of Wildlife Ecology and Conservation, July 2010. WEC286/UW331: Science Support for Climate Change Adaptation in South Florida (ufl.edu

    Science Support for Climate Change Adaptation in South Florida

    No full text
    WEC286, a 5-page illustrated fact sheet by Laura M. Early, Rebecca G. Harvey, Laura A. Brandt, James I. Watling, and Frank J. Mazzotti, discusses how climate change will affect sea level and the ecosystem in South Florida and outlines the Department of Interior’s approach to manage public lands and natural resources impacted by climate change. Includes references. Published by the UF Department of Wildlife Ecology and Conservation, July 2010. WEC286/UW331: Science Support for Climate Change Adaptation in South Florida (ufl.edu

    Science Support for Climate Change Adaptation in South Florida

    No full text
    WEC286, a 5-page illustrated fact sheet by Laura M. Early, Rebecca G. Harvey, Laura A. Brandt, James I. Watling, and Frank J. Mazzotti, discusses how climate change will affect sea level and the ecosystem in South Florida and outlines the Department of Interior’s approach to manage public lands and natural resources impacted by climate change. Includes references. Published by the UF Department of Wildlife Ecology and Conservation, July 2010. WEC286/UW331: Science Support for Climate Change Adaptation in South Florida (ufl.edu

    Cladarisis nouvianae Watling, 2015, new species

    No full text
    Cladarisis nouvianae new species Figures 1–7 Material examined. Holotype: Collected off Rum Cay, Bahama Islands, 23 ° 38.0756 'N, 74 ° 57.2196 'W, depth 1117 m, 24 March 2009, specimen RUM 107 - 2, YPM IZ 0 70870. Other material: Off Cat Island, Bahama Islands, 24 °08.9927'N, 75 ° 12.0680 'W, depth 1243 m, 21 March 2009, specimen CAT 207 - 1 (most of the specimen deteriorated during storage, after sclerite examination and genetic analysis; small fragments exist in the lab of S.C. France at the University of Louisiana at Lafayette, USA). Diagnosis. With the characters of the genus. Description of Holotype. The colony is long and slender, sparsely branched, with branches emanating from nodes. The holdfast is very small, not much larger than the diameter of the axis (Fig. 1 A). From the holdfast to the first branch point is about 10 cm, subsequent branches are spaced about 9 to 14 cm apart, with one interbranch distance of 4.5 cm. The two main branches carry two or three subsequent branches, one of which is branched twice more, resulting in two third-order branches that are approximately 18 cm long. Total colony length is about 75 cm (as determined by measurements made on the in situ image in Fig. 1 A). Axial internodes are solid, except for those newly forming at the ends of the branches. The internode hollow center appears to be secondarily calcified (Fig. 2 C). Internodes (Fig. 2 A, B) range in length from 3.5 to 14.9 mm (mean= 9.76 mm, std. dev.= 2.36, n= 49), and in width from 0.33 to 0.93 mm (mean= 0.67 mm, std. dev.= 0.21, n= 12). Nodes are very short, about 1 mm in length and do not seem to be very heavily calcified resulting in a very flexible colony whose branch tips are often curved (e.g., Fig. 1 B, 2 B). Polyps are small, less than 3 mm tall when contracted, and are arranged in two irregular rows along the branches, often in alternate fashion (Fig. 2 A,B). Interpolyp distances in each row range from 5 to 18 mm, but are most frequently about 10 mm. No polyps are present on the distal-most 3 cm of the branches and polyps and tissue appears to be absent along part of the axis from the holdfast to the first branch-point. Because of the relative shortness of the internodes, each internode supports only one or two polyps; occasionally a polyp is located on a node. Polyps are short cylinders, being as wide as tall (Fig. 3 A-D). When contracted the tentacles are not visible and the top of the polyp is covered with a logjam of rod-shaped sclerites (Fig. 3 D). The outside of the polyp is festooned with curved rods that are loosely organized. The longer sclerites originate at the base of the polyp, often extending the width of the skeletal axis, and are oriented diagonally. The shorter sclerites are mostly located higher on the polyp and can be oriented either horizontally or longitudinally. None of the sclerites appear to be aligned directly with the mesenterial insertions on the polyp body wall (Fig. 3 B). All sclerites on the polyp body are robust rods with blunt or rounded tips (Fig. 4). Each is ornamented with small regularly spaced tubercles (Fig. 2 D, E). Most of the rods are curved or have irregular outlines. Only those at the base of the tentacles are more or less straight (Fig. 5 D). Rods are oriented longitudinally along the aboral side of the tentacles, becoming progressively smaller toward the tentacle tip. Flat rods (Fig. 5 C) are common in the pinnules and along the oral surface of the tentacles. Polyp body sclerites range in length from 1.0 to 2.5 mm, the rods along the aboral side of the tentacles are 0.4 to 0.9 mm long, and tentacle flat rods are 0.06 to 0.15 mm (Fig. 6). The pharyngeal sclerites are 0.07 to 0.14 mm in length. The tentacles contract completely into the oral cavity of the polyp (Fig. 3 D, 7 A). The “mouth” is funnelshaped, demarcated from the pharynx by a flat ring (R, Fig 7 A). The pharynx (as determined by the presence of pharyngeal sclerites) continues the structure ventrally, terminating in a hypopharynx (H, Fig 7 A, 7 C) uniting the eight septa. The sclerites of the pharynx region consist of two distinct types, those that are flat rods with tooth-like protuberances (Fig. 5 B) being found at the junction with the oral funnel, while the more typical short and wide toothed rods (Fig. 5 A, 7 D) occupy the lower part of the pharynx. Variation. The only other specimen collected, CAT 207 - 1, was about 30 cm in length and branched twice. The polyps of the latter specimen were examined in detail and differed from those of the holotype only in having slightly smaller sclerites on the polyp body. The largest sclerites were 2.4 mm in length whereas on the larger holotype the largest body sclerites are about 2.5 mm in length (Fig. 6). But the smaller CAT 207 - 1 had a much larger array of smaller rods on the polyp body and the rods in the tentacles were much smaller than on the holotype. Etymology. This species is named in honor of Claire Nouvian, founder of the organization Bloom Association, in recognition of her tireless efforts working to reduce the destruction of deep-sea habitats by bottom trawls. Remarks. Within the Keratoisidinae, the genera Lepidisis, Jasonisis, Acanella, and Isidella were known to branch at the nodes if they branched at all (France 2007, Alderslade and McFadden 2012). Cladarisis branches at the nodes once the colony reaches sufficient size to begin branching. Among this group, the pattern of branching of Cladarisis is most similar to that seen in Isidella (sparse and lateral, not in whorls), and in fact, the specimens collected were provisionally assigned to that genus as samples were sorted on board the ship. The genus Isidella currently comprises the species I. elongata Esper, 1788 (type species), I. lofotensis Sars, 1868, I. trichotoma Bayer, 1990, I. longiflora (Verrill, 1883), and I. tentaculum Etnoyer, 2008. Only the first three are likely to remain in the genus. Isidella longiflora was originally described and placed in the genus Lepidisis by Verrill, but since that genus came to be thought of as unbranched, Grasshoff (1986; Grasshoff and Zibrowius 1983) moved longiflora to Isidella on the basis of dichotomous branching from the nodes. The exact placement of this species remains to be determined since the existing museum material is not in very good condition. Further, Verrill (1883) noted that branches arising at the nodes could arise singly, or two at a time. In a manuscript that was unfortunately not published before his death, Verrill suggested that L. longiflora should be moved to a new genus “ Acanellides ” (this manuscript is in the collection of the Yale Peabody Museum and photocopies of the pages can be obtained from this author). Isidella tentaculum differs from all the others in having sclerites in the form of rods, the mesenterially placed sclerites are rods rather than needles, and the branches, while originating at the nodes form more of a candelabra shape. In addition, the axis internodes are thick and heavy, rather than thin and moderately delicate. Unpublished genetic sequence data suggests that I. tentaculum belongs to a clade different from that in which the other three Isidella species (including the type) reside (Scott C. France, personal communication). Thus, for this discussion, the genus Isidella will be considered to consist only of the first three species noted above. The species Isidella elongata, I. lofotensis, and I. trichotoma have moderately long to very long, thin hollow internodes, polyps armed with sclerites predominantly in the form of needles, with larger needles in groups of 2-3 placed at the mesenterial insertions on the body wall (Bayer 1990) and usually projecting between the tentacle bases. Branching at the nodes has been termed dichotomous (Bayer 1990), but should be lateral according to Alderslade (1998), and sparse. The tentacles, when contracted, fold over the mouth but remain exposed. Isidella lofotensis needs redescription (in preparation); however, colonies recently studied in the collection of the Tromsø Museum are bushy, branching at the nodes in all planes, and the sclerites arranged along the mesenterial insertions are large pointed rods rather than thin needles. A very small colony collected in 1872 at the type locality by G.O. Sars, from the collection of the Copenhagen Museum, has a similar arrangement of polyp body sclerites, but all are needles rather than rods (inviting the supposition that as the colony grows and ages the needles either become thicker or are replaced). Both colonies have solid internodes. The tentacles contract but stay exposed. The genus Cladarisis resembles these three species of Isidella in the form of the colony, the long and thin branches, branching sparse and lateral, and with branches originating at the nodes. Cladarisis differs, however, in several ways. The internodes are generally shorter (mean length, 9 mm). Measurements made on photos of specimens of I. elongata and pieces of a specimen of I. lofotensis, show that internode length in those two species range from 13 to 17 mm and 9 to 15 mm, respectively. Internode lengths in I. trichotoma reach 85 mm (Bayer 1990). The polyp body of Cladarisis possesses sclerites that are exclusively rods, and the sclerites are organized haphazardly such that none are aligned with the mesenteries. Indeed, the rods are arranged almost randomly along the outside of the polyp, with some on the distal part of the polyp oblique to horizontal, and with longitudinally oriented smaller rods only along the aboral surface of the tentacles. The pharyngeal sclerites of Cladarisis also differ significantly from those of I. trichotoma (details for the other two species are missing). In the latter, the sclerites are elongate, slightly toothed rods, verging on being flat rods, whereas in Cladarisis one group of pharyngeal sclerites are short, wide, and thick, with protuberances on all sides.Published as part of Watling, Les, 2015, A new genus of bamboo coral (Octocorallia: Isididae) from the Bahamas, pp. 239-249 in Zootaxa 3918 (2) on pages 240-244, DOI: 10.11646/zootaxa.3918.2.5, http://zenodo.org/record/23807

    Geophis nigroalbus Boulenger 1908

    No full text
    GEOPHIS NIGROALBUS BOULENGER, 1908 Geophis nigroalbus Boulenger, 1908: 552 (Type locality: Colombia: Valle del Cauca: Pavas, 3°41′N, 76°35′W, 1350 m; Holotype BMNH 1946.1.6.50, a juvenile male); Restrepo & Wright, 1987: 195; Myers, 2003: 33, figs 15–17. Diagnostics: Distinguished from other species in the Geophis brachycephalus complex by the following combination of characters: (1) ventrals 134–143.5 ± 3.8–149 in males, 141–148.0 ± 5.2–157 in females; subcaudals 42–46.3 ± 2.1–51 in males, 37–41.3 ± 2.8–46 in females; total segmentals 180–190.0 ± 3.6– 197 in males, 181–189.3 ± 7.5–203 in females; (2) upper surfaces of body and tail uniform black; (3) hemipenis slightly bilobed with a long, slender capitulum about 3 times length of truncus (Myers, 2003). Distribution: Tropical premontane wet forest sites in the Cordillera Occidental of Colombia, 1350–1680 m (Fig. 16).Published as part of Savage, Jay M. & Watling, James I., 2008, Not so rare snakes: a revision of the Geophis sieboldi group (Colubridae: Dipsadinae) in lower Central America and Colombia, pp. 561-599 in Zoological Journal of the Linnean Society 153 (3) on page 584, DOI: 10.1111/j.1096-3642.2008.00400.x, http://zenodo.org/record/544614

    Climate Changes, Shifting Ranges: Climate change effects on wildlife in the Florida Everglades and Keys

    No full text
    Where do the animals go when the sea rises? Learn the probable futures of Florida panthers and other south Florida wildlife in this 5-page fact sheet. Written by Larry Perez, James I. Watling, David Bucklin, Mathieu Basille, Frank J. Mazzotti, Stephanie Romañach, and Laura Brandt and published by the UF Department of Wildlife Ecology and Conservation, it explains how a changing climate could impact wild animals.­edis.ifas.ufl.edu/uw42

    Council cottages and community in inter-war Britain: a study of class, culture,politics and place.

    No full text
    PhDThis thesis makes a contribution to the debates surrounding the idea of community on the cottage council estates of inter-war Britain. It questions the conventional wisdom that community was lacking upon these estates. Recognising the problematic nature of the notion of community, this thesis overcomes the confusion inherent in the term when it is used to describe social structures by viewing community instead as a structure of meaning, as a discursive rather than material reality. This guides my examination of community on the estates. Rather than there being no community, it is argued that there were at least three different discourses of community, and what is important is the relationships between them. Chapter One discusses the contexts in which these estates were built, and then sets out the ways in which community is understood in this thesis. Chapter Two explains the methodology that was used, a combination of archival and oral histoiy. In Chapter Three Roehampton and Watling - the two estates this research focuses upon - are described in order to provide the contextual setting for my interpretation of the discourses of community that were present there. Chapter Four is concerned with community from the viewpoint of the residents who lived on the estates. Chapter Five considers discourses of community from the point of view of the tenants' and residents' associations that developed upon Roehampton and Watling. Chapter Six explores the discourse of community that was promoted on the estates by the Community Association movement. Overall the thesis argues that the discourses of community on inter-war housing estates have to be understood in terms of the occupational structures, cultures and politics of these estates

    Geophis talamancae Lips & Savage 1994

    No full text
    <i>GEOPHIS TALAMANCAE</i> LIPS & SAVAGE, 1994 <p> <i>Geophis brachycephalus</i>, Slevin, 1942: 474 (in part); Dunn, 1942: 4 (in part); Downs, 1967: 146 (in part); Savage, 2002: 604 (in part); Myers, 2003: 38 (in part); Solórzano, 2004: 276 (in part).</p> <p> <i>Geophis talamancae</i> Lips & Savage, 1994: 410, fig. 1 (Type locality: Costa Rica: Puntarenas: Coto Brus, Sitio Las Tablas: Finca Jaguar, 1800 m; Holotype: LACM 147196, a subadult female); Savage, 2002: 602; Solórzano, 2004: 290, fig. 82.</p> <p> <i>Diagnostics:</i> Unique within the <i>Geophis brachycephalus</i> complex in having the following combination of characters: (1) 118–124.9 ± 3.7–132 ventrals in male, 121–128.8 ± 4.4–139 in females; 35–38.1 ± 1.4–41 subcaudals in males, 23–33.4 ± 2.3–38 in females; 154–163.2 ± 4.0–171 total segmentals in males, 155– 161.7 ± 3.9–171 in females; (2) upper surfaces of body and tail uniform black or anterior body uniform black and rest of body black with pairs of red spots that are usually offset and sometimes fused to form elongate blotches; tail black above; (3) hemipenis slightly bilobed with short, robust capitulum that is about twice length of truncus on asulcate side (Myers, 2003).</p> <p> <i>Distribution:</i> Tropical premontane wet forest and rainforest and lower montane rainforest on the Pacific slope of the Cordillera Talamanca-Barú in extreme south-western Costa Rica and adjacent western Panama, 1200–1800 m (Figs 14, 15).</p>Published as part of <i>Savage, Jay M. & Watling, James I., 2008, Not so rare snakes: a revision of the Geophis sieboldi group (Colubridae: Dipsadinae) in lower Central America and Colombia, pp. 561-599 in Zoological Journal of the Linnean Society 153 (3)</i> on pages 584-585, DOI: 10.1111/j.1096-3642.2008.00400.x, <a href="http://zenodo.org/record/5446145">http://zenodo.org/record/5446145</a&gt

    Support for the habitat amount hypothesis from a global synthesis of species density studies

    No full text
    Decades of research suggest that species richness depends on spatial characteristics of habitat patches, especially their size and isolation. In contrast, the habitat amount hypothesis predicts that (1) species richness in plots of fixed size (species density) is more strongly and positively related to the amount of habitat around the plot than to patch size or isolation; (2) habitat amount better predicts species density than patch size and isolation combined, (3) there is no effect of habitat fragmentation per se on species density and (4) patch size and isolation effects do not become stronger with declining habitat amount. Data on eight taxonomic groups from 35 studies around the world support these predictions. Conserving species density requires minimising habitat loss, irrespective of the configuration of the patches in which that habitat is contained
    corecore