[PDF] Patterns In The Distribution And Abundance Of Terrestrial Arthropods On Sub Antartic Marion Island eBook

Author : Jaco Barendse
Publisher :
Page : 77 pages
File Size : 45,56 MB
Release : 1999
Category : Arthopoda
ISBN :

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Quantitative studies of complete soil arthropod communities are considered essential if a thorough understanding of the structure and dynamics of soil faunas, and their likely response to anthropogenic environmental change, is to be gained. In practice, however, high species richness and poor taxonomic knowledge for most systems often hampers the acquisition of such information. In consequence, many studies resort to the use of higher taxa or more qualitative data. Sub-Antarctic terrestrial systems which are moderately diverse with well-known faunas allow us to bridge some of these problems. Two major terrestrial habitat types (or biotopes) are distinguished on sub-Antarctic islands, namely the epilithic and vegetated biotopes. These two habitat types differ in terms of current extent of vegetational cover and age relative to previous glacial events. The epilithic biotope includes the older habitats such as rocky shores and fellfields that have escaped glaciation, have little vascular plant cover, and is cryptogam dominated. Quantitative data on the soil fauna of a fellfield habitat on sub-Antarctic Marion Island is used to illustrate the pitfalls associated with the qualitative approach. Fellfield is an important vegetation complex in the broad Antarctic region, and on Marion Island consists of both bare rocky areas and cushion plants. Soil arthropod communities in these two distinct habitat components were quantified over one year. Species richness was relatively high (42 spp.) and consisted almost exclusively of indigenous species, although abundances were lower compared with less extreme vegetation types in the sub-Antarctic. In general, arthropods either showed no pronounced seasonal peak in abundance, or a summer peak, although these patterns differed between habitat components within species, and between species. Quantitative analyses highlighted prominent differences between the two habitat components in arthropod community structure, despite the fact that most species were common to both of them. Qualitative analyses, in contrast, obscured these differences, while the use of higher taxa for analyses of seasonality resulted in abundant species generally masking the phenologies of less abundant ones. It is concluded that quantitative analyses of soil arthropod communities are essential if natural and anthropogenic changes in their structure are to be detected, monitored and understood. Studies on sub-Antarctic insects have suggested that species inhabiting the epilithic habitats exhibit higher habitat preference or specificity and also a higher incidence of biotic interactions, such as competition, than those in vegetated habitats. The Acari, a more speciose but less well studied group than the insects, is used to independently test the aspect of habitat specificity. Seventeen different habitats or zones belonging to both the epilithic and vegetated biotopes were quantitatively sampled for mites over a one year period. These included a rocky shore, mire and non-mire lowland vegetation, and a mid-altitude fellfield. Species richness across all habitats was 39 spp., while rocky shore habitats showed higher abundances, but lower species richness, and a distinct fauna, to strictly terrestrial habitats. Multivariate analyses indicated that mite assemblage structure differed significantly between all different habitat types. However, most species in the terrestrial habitats (both epilithic and vegetated) were shared, suggesting that the epilithic fellfield, and especially its vegetated component (Azorella selago cushion plants) would have been suitable refugia during glaciation. The shoreline, due to its distinct fauna, seems a less likely refuge from which recolonisation of vegetated habitats could have taken place. Most species could be considered habitat generalists, although the epilithic habitats (shore and fellfield) had more habitat specific species than the lowland vegetated habitats. Bothrometopus elongatus is one of four Ectemnorhinus-group species restricted to the epilithic biotope on the Prince Edward Islands. The biology of this species was examined over a full year at Kerguelen Rise, a mid-altitude fellfield site on Marion Island. B. elongatus adults eclose from April onwards, reaching maximum densities (c. 17 individuals.m-2) in September. Females mature approximately three eggs at a time and these commence hatching in July. Larval eclosion reaches a peak in November, during which time larval densities are also highest (c. 153 individuals.m-2). The larvae develop through six instars, which is within the range found for other Ectemnorhinus-group species. The high densities of B. elongatus in fellfield habitats, and its single, virtually discrete annual generation, make this species unusual among insects indigenous to the sub-Antarctic. The latter generally have low densities compared to other micro-arthropods, prolonged life cycles, and flexible life histories. It is suggested that the diversity of life histories found amongst the indigenous insects at Marion Island presents considerable potential for testing environmental effects on insect life histories. An overview of sub-Antarctic insect life history data suggests that the indigenous species, with generally prolonged life cycles, are at a disadvantage relative to introduced ones that have more rapid cycles and often complete several generations per year. This is reason for concern given rapid climate change at these islands.

Author : Richard Dennis Mercer
Publisher :
Page : pages
File Size : 12,16 MB
Release : 2013
Category :
ISBN :

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This study provides the first quantitative analysis of the littoral and supralittoral arthropod assemblages of sub-Antarctic Marion Island. Seventeen mite species (126 203 individuals) from 11 families were found on the shore at Macaroni Bay. Three families dominated the assemblages in both abundance and diversity: the Hyadesiidae, Ameronothridae and Halacaridae. Six insect species from three orders were found on the shore. Species richness increased from one in the littoral, to four and two species in the Mastodia and Caloplaca zones, respectively. The littoral, chironomid midge, Telmatogeton amphibius was the most abundant insect species, constituting 80% of all insects counted. Arthropod assemblages corresponded closely to the cryptogram dominated zonation patterns previously identified for the Marion Island shore. This clear association between arthropod and cryptogam zonation patterns provided a clear indication of habitat specificity in many of the species, and a quantitative analysis of habitat specificity on a species by species basis supported this tenet. The specificity of most species to the shore, which forms part of the epilithic biotope, is most likely a consequence of the considerable age of this biotope compared to the younger, post-glacial vascular vegetation. Tourist species, i.e. species transient to an assemblage, inflated species richness in zones and the distribution ranges of species across zones. It is suggested that previous, qualitative analyses of shoreline arthropod communities may have overestimated species ranges and richnesses because of the inclusion of tourist species. It is suggested that if a sound understanding of patterns in and processes underlying Antarctic arthropod assemblages is to be achieved, quantitative analyses must be expanded in the region. In this study the spatial patterns of littoral and supralittoral arthropods from sub-Antarctic Marion Island are examined. Primary consumers were by far the most diverse group on the shore, with nine algivore and ten fungivore species from a total of 23 species. Positive species associations were found in the Mastodia and Caloplaca zones and positive abundance covariation in the Verrucaria, Mastodia and Caloplaca zones. There were no negative associations between any taxa, indicating that interspecific interactions on the shore are either minimal or absent. Significant interactions were related to the diversity of the respective habitats, with higher diversity resulting in higher levels of positive associations and abundance covariation. High levels of aggregation clearly demonstrated that species were not randomly distributed within habitats. Intraspecific aggregation was generally higher than interspecific aggregation in the five habitats and if competition was to occur it would most likely be among conspecifics. The absence of suitable biological information for species precluded further analyses of competition. However, if competitive interactions were found to occur between heterospecifics then coexistence would best be explained using the aggregated nature of superior competitors, allowing weaker competitors to coexist in zones. Positive associations between species were attributed to favourable environmental conditions, the availability of limiting resources (e.g. shelter) and the structure of the dominant cryptogram species. Body sizes, spanning five orders of magnitude (0.5 J.1g - 26 mg), were measured for 59 of the approximately 120 invertebrate species on Marion Island. Mass-length and fresh-dry mass relationships were calculated for orders, families and species (for those with sufficient data). A comparison of their slopes indicates that for prediction of body mass it may be useful to use regressions from the lowest taxonomic rank possible. Differences between the mass-length relationship for Marion Island insects (log mass = -4.294 + 3.151 log length) and other relationships on continental assemblages raises the questions as to the applicability of these results. This study should prove useful for estimating body sizes for other, similar taxa in the Antarctic and provide baseline information on an important species trait that seems to be changing with local and global environmental changes.

Author : Alex D. Rogers
Publisher : John Wiley & Sons
Page : 585 pages
File Size : 36,36 MB
Release : 2012-02-28
Category : Science
ISBN : 1444347225

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Since its discovery Antarctica has held a deep fascination for biologists. Extreme environmental conditions, seasonality and isolation have lead to some of the most striking examples of natural selection and adaptation on Earth. Paradoxically, some of these adaptations may pose constraints on the ability of the Antarctic biota to respond to climate change. Parts of Antarctica are showing some of the largest changes in temperature and other environmental conditions in the world. In this volume, published in association with the Royal Society, leading polar scientists present a synthesis of the latest research on the biological systems in Antarctica, covering organisms from microbes to vertebrate higher predators. This book comes at a time when new technologies and approaches allow the implications of climate change and other direct human impacts on Antarctica to be viewed at a range of scales; across entire regions, whole ecosystems and down to the level of species and variation within their genomes. Chapters address both Antarctic terrestrial and marine ecosystems, and the scientific and management challenges of the future are explored.

Author : Steven Chown
Publisher : AFRICAN SUN MeDIA
Page : 481 pages
File Size : 15,72 MB
Release : 2008-06-01
Category : Science
ISBN : 1920109854

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This book provides a modern, synthetic overview of what is known about the structure, functioning and interactions of marine and terrestrial systems at the Prince Edward Islands. Building on more than 50 years of biological, geological, meteorological, and oceanographic research, it demonstrates not only how inextricably linked marine and terrestrial systems at the islands are, but also how global environmental challenges, such as climate change, biological invasions, and over exploitation, are playing out at the regional and local levels in the Southern Ocean.