Conservation Biology (conservation + biology)

Distribution by Scientific Domains
Distribution within Life Sciences


Selected Abstracts


Conservation Biology in Asia: the Major Policy Challenges

CONSERVATION BIOLOGY, Issue 4 2009
JEFFREY A. McNEELY
Asia; bosques; comercio de vida silvestres; conflicto humano-animal; economía Abstract:,With about half the world's human population and booming economies, Asia faces numerous challenges to its biodiversity. The Asia Section of the Society for Conservation Biology has identified some key policy issues in which significant progress can be made. These include developing new sources of funding for forest conservation; identifying potential impacts of energy alternatives on the conservation of biodiversity; curbing the trade in endangered species of plants and animals; a special focus on the conservation of mountain biodiversity; enhancing relevant research; ensuring that conservation biology contributes to major international conventions and funding mechanisms; using conservation biology to build a better understanding of zoonotic diseases; more effectively addressing human,animal conflicts; enhancing community-based conservation; and using conservation biology to help address the pervasive water-deficit problems in much of Asia. These challenges can be met through improved regional cooperation among the relevant stakeholders. Resumen:,Con aproximadamente la mitad de la población humana y economías prósperas, Asia enfrenta numerosos retos para su biodiversidad. La sección Asia de la Sociedad para la Biología de la Conservación ha identificado algunos temas políticos claves en los que se puede hacer un progreso significativo. Estos incluyen el desarrollo de nuevas fuentes de financiamiento para la conservación de bosques; la identificación de impactos potenciales de las energías alternativas sobre la conservación de la biodiversidad; reducción del comercio de especies de animales y plantas en peligro; un enfoque especial en la conservación de la biodiversidad montana; promoción de investigación relevante; garantía de que la biología de la conservación contribuye a convenios internacionales y mecanismos de financiamiento; utilización de la biología de la conservación para lograr un mejor entendimiento de enfermedades zoonóticas; mejor atención a los conflictos humanos-animales; reforzamiento de la conservación basada en comunidades y utilización de la biología de la conservación para atender los problemas de déficit de agua en gran parte de Asia. Estos retos se pueden atender mediante una mejor cooperación regional entre los principales actores. [source]


Conservation Challenges for the Austral and Neotropical America Section

CONSERVATION BIOLOGY, Issue 4 2009
GERARDO CEBALLOS
América Austral y Neotropical; América Latina; desarrollo de capacidades Abstract:,The Austral and Neotropical America (ANA) section of the Society for Conservation Biology includes a vast territory with some of the largest relatively pristine ecosystems in the world. With more than 573 million people, the economic growth of the region still depends strongly on natural resource exploitation and still has high rates of environmental degradation and biodiversity loss. A survey among the ANA section membership, with more than 700 members, including most of the section's prominent ecologists and conservationists, indicates that lack of capacity building for conservation, corruption, and threats such as deforestation and illegal trade of species, are among the most urgent problems that need to be addressed to improve conservation in the region. There are, however, strong universities and ecology groups taking the lead in environmental research and conservation, a most important issue to enhance the ability of the region to solve conservation and development conflicts. Resumen:,La sección América Austral y Neotropical (AAN) de la Sociedad para la Biología de la Conservación incluye un vasto territorio con unos de los ecosistemas relativamente prístinos más extensos del mundo. Con más de 573 millones de habitantes, el crecimiento económico de la región aun depende fuertemente de la explotación de recursos naturales y aún tiene altas tasas de degradación ambiental y pérdida de biodiversidad. Un sondeo de la membresía de la sección AAN, con más de 700 miembros, incluyendo la mayoría de los ecólogos y conservacionistas más prominentes de la sección, indica que la carencia de desarrollo de capacidades para la conservación, la corrupción y amenazas como la deforestación y el comercio ilegal de especies, son algunos de los problemas que requieren ser atendidos más urgentemente para mejorar la conservación en la región. Sin embargo, hay universidades y grupos ecológicos que están tomando el liderazgo en investigación ambiental y conservación, un tema importante para mejorar la habilidad de la región para resolver conflictos de conservación y desarrollo. [source]


Leadership: a New Frontier in Conservation Science

CONSERVATION BIOLOGY, Issue 4 2009
JIM C. MANOLIS
estrategia; influencia; liderazgo; manejo; política Abstract:,Leadership is a critical tool for expanding the influence of conservation science, but recent advances in leadership concepts and practice remain underutilized by conservation scientists. Furthermore, an explicit conceptual foundation and definition of leadership in conservation science are not available in the literature. Here we drew on our diverse leadership experiences, our reading of leadership literature, and discussions with selected conservation science leaders to define conservation-science leadership, summarize an exploratory set of leadership principles that are applicable to conservation science, and recommend actions to expand leadership capacity among conservation scientists and practitioners. We define 2 types of conservation-science leadership: shaping conservation science through path-breaking research, and advancing the integration of conservation science into policy, management, and society at large. We focused on the second, integrative type of leadership because we believe it presents the greatest opportunity for improving conservation effectiveness. We identified 8 leadership principles derived mainly from the "adaptive leadership" literature: recognize the social dimension of the problem; cycle frequently through action and reflection; get and maintain attention; combine strengths of multiple leaders; extend your reach through networks of relationships; strategically time your effort; nurture productive conflict; and cultivate diversity. Conservation scientists and practitioners should strive to develop themselves as leaders, and the Society for Conservation Biology, conservation organizations, and academia should support this effort through professional development, mentoring, teaching, and research. Resumen:,El liderazgo es una herramienta crítica para la expansión de la influencia de la ciencia de la conservación, pero los avances recientes en los conceptos y práctica del liderazgo son subutilizados por los científicos de la conservación. Más aun, en la literatura no hay una fundamentación conceptual ni definición de liderazgo en la ciencia de la conservación. Aquí nos basamos en nuestras experiencias de liderazgo, nuestra lectura de literatura sobre liderazgo y discusiones con líderes selectos de la ciencia de conservación para definir liderazgo para la ciencia de la conservación, resumir un conjunto exploratorio de principios de liderazgo aplicables a la ciencia de la conservación y recomendar acciones para expandir la capacidad de liderazgo entre los científicos y los practicantes de la conservación. Definimos dos tipos de liderazgo de la ciencia de la conservación: configuración de la ciencia de la conservación mediante investigación original, y avance hacia la integración del liderazgo en la ciencia de la conservación en la política, el manejo y la sociedad en general. Nos centramos en el segundo tipo de liderazgo porque consideramos que presenta la mejor oportunidad para mejorar la efectividad de la conservación. Identificamos ocho principios de liderazgo derivados principalmente de la literatura sobre "liderazgo adaptativo": reconocer la dimensión social del problema; alternar entre acción y reflexión frecuentemente; obtener y mantener atención; combinar fortalezas de múltiples líderes; extender el alcance mediante redes de relaciones; organizar el esfuerzo estratégicamente; evitar conflictos productivos y desarrollar la biodiversidad. Los científicos y los practicantes de la conservación deberían esforzarse para desarrollarse como líderes y la Sociedad para la Biología de la Conservación, las organizaciones de conservación y la academia deberían respaldar este esfuerzo mediante el desarrollo profesional, la tutoría, la enseñanza y la investigación. [source]


The Role of Religion in the HIV/AIDS Intervention in Africa: a Possible Model for Conservation Biology

CONSERVATION BIOLOGY, Issue 4 2008
Stephen Mufutau Awoyemi
No abstract is available for this article. [source]


Value and Advocacy in Conservation Biology: Crisis Discipline or Discipline in Crisis?

CONSERVATION BIOLOGY, Issue 1 2008
Kai M. A. Chan
No abstract is available for this article. [source]


Availability of Formal Academic Programs in Conservation Biology in Latin America

CONSERVATION BIOLOGY, Issue 6 2007
Martín Mendez
First page of article [source]


Editorial: The Success,and Challenges,of Conservation Biology

CONSERVATION BIOLOGY, Issue 4 2006
Gary K. Meffe Editor
No abstract is available for this article. [source]


Conservation Biology at Twenty

CONSERVATION BIOLOGY, Issue 3 2006
Gary K. Meffe Editor
No abstract is available for this article. [source]


Conservation Biology: Views from the Ecological Sciences

CONSERVATION BIOLOGY, Issue 3 2006
JOSÉ SARUKHÁN
No abstract is available for this article. [source]


Landscape Planning and Conservation Biology: Systems Thinking Revisited

CONSERVATION BIOLOGY, Issue 3 2006
JOAN IVERSON NASSAUER
No abstract is available for this article. [source]


Glimpses of Conservation Biology, Act II

CONSERVATION BIOLOGY, Issue 3 2006
THOMAS E. LOVEJOY
No abstract is available for this article. [source]


Conservation Biology in the Pacific

CONSERVATION BIOLOGY, Issue 6 2004
Harry F. Recher Editor, Pacific Conservation Biology
No abstract is available for this article. [source]


Everything You Wanted to Know About Conservation Biology

CONSERVATION BIOLOGY, Issue 1 2004
Andrew T. Smith
No abstract is available for this article. [source]


The Speke's Gazelle Breeding Program as an Illustration of the Importance of Multilocus Genetic Diversity in Conservation Biology: Response to Kalinowski et al.

CONSERVATION BIOLOGY, Issue 4 2002
Alan R. Templeton
First page of article [source]


Conservation Biology for the Biodiversity Crisis

CONSERVATION BIOLOGY, Issue 1 2002
David M. Olson
No abstract is available for this article. [source]


The Context of Conservation Biology

CONSERVATION BIOLOGY, Issue 4 2001
Gary K. Meffe
No abstract is available for this article. [source]


Conservation Biology and Private Land: Shifting the Focus

CONSERVATION BIOLOGY, Issue 5 2000
David A. Norton
No abstract is available for this article. [source]


Making the Monkey: How the Togean Macaque Went from "New Form" to "Endemic Species" in Indonesians' Conservation Biology

CULTURAL ANTHROPOLOGY, Issue 4 2004
Celia Lowe
Indonesian scientists inhabit a postcolonial world where they are both elite (within the nation) and subaltern (within transnational science) at precisely the same moments. A study of science that is neither "ethno" nor "Euro" requires a postcolonial refiguration not only of how science's matter is made but of where and by whom. In the 1990s, the Togean macaque (Macaca togeanus) was proposed as a new species endemic to the Togean Islands, the proposed site of a new conservation area in Central Sulawesi, Indonesia. In the scientific production of biodiverse nature, Indonesian primatologists identified the monkey first as a "new form," then as a "dubious name," and subsequently, as an "endemic species." Throughout these acts of making, unmaking, and remaking the monkey, its unique and endemic status was important for developing Indonesian conservation biology, attracting foreign donors, and enlisting government and public interest in Togean Island nature, even as forms of nature important to Togean peoples were overwritten in this process. [source]


Recommendations for Integrating Restoration Ecology and Conservation Biology in Ponderosa Pine Forests of the Southwestern United States

RESTORATION ECOLOGY, Issue 1 2006
Reed F. Noss
Abstract Over the past century, ponderosa pine,dominated landscapes of the southwestern United States have been altered by human activities such as grazing, timber harvest, road building, and fire exclusion. Most forested areas within these landscapes now show increased susceptibility to stand-replacing fires, insect outbreaks, and drought-related mortality. Recent large wildfires in the region have spurred public interest in large-scale fuel reduction and restoration programs, which create perceived and real conflicts with the conservation of biodiversity. Conservation concerns include the potential for larger road networks, soil and understory disturbance, exotic plant invasion, and the removal of large trees in treated areas. Pursuing prescribed burning, thinning, or other treatments on the broad scale that many scientists and managers envision requires the reconciliation of ecological restoration with biodiversity conservation. This study presents recommendations from a workshop for integrating the principles and practices of restoration ecology and conservation biology, toward the objective of restoring the composition, structure, and function of dry ponderosa pine forests. Planning on the scale of hundreds of thousands of hectares offers opportunities to achieve multiple objectives (e.g., rare species protection and restoration of ecological structures and processes) that cannot easily be addressed on a site-by-site basis. However, restoration must be coordinated with conservation planning to achieve mutual objectives and should include strict guidelines for protection of rare, declining, and sensitive habitats and species. [source]


Key Topics in Conservation Biology

AUSTRAL ECOLOGY, Issue 3 2007
ROBERT DAVIS
No abstract is available for this article. [source]


The Geographical and Institutional Distribution of Ecological Research in the Tropics

BIOTROPICA, Issue 4 2008
Gabriela Stocks
ABSTRACT We reviewed 1333 papers published in Biotropica and the Journal of Tropical Ecology from 1995 to 2004. Only 62 percent of tropical countries were represented in our survey, with 62 percent of the publications based on research conducted in only ten countries. Sixty-two percent of papers had lead authors that were based at institutions outside the country where the research was conducted. Cross-national collaboration was limited, accounting for only 28 percent of papers with multiple authors. To evaluate if our choice of focal journals could have biased our results, we also reviewed 652 papers published in Ecology, Oecologia, Conservation Biology, and Biological Conservation for five randomly selected years from the same time period. While some differences in authorship and the geographic distribution of research existed, the results from these journals generally mirrored patterns observed in the two focal ones,almost 54 percent of publications were based on research conducted in only ten countries, and most studies had lead authors from a developed country. The results of our review suggest that the geographical distribution of research in the tropics is unequal, and that some important regions remain understudied. The results also suggest a need for a greater focus on establishing collaborative relationships with scientists from tropical countries. RESUMEN Revisamos 1333 artículos publicados en Biotropica y el Journal of Tropical Ecology entre 1995 y 2004. Solo el 62 por ciento de los países tropicales estuvieron presentes en nuestro sondeo, y un 62 por ciento de las publicaciones se basaron en investigaciónes llevadas a cabo sólo en diez países. En el 62 por ciento de los artículos, la institución base del autor principal estaba fuera del país donde se realizó la investigación. La colaboración entre países fue limitada, solo ocurrió en el 28 por ciento de los artículos con múltiples autores. Para evaluar si nuestra selección de revistas científicas habría distorsionado los resultados revisamos también 652 artículos publicados en Ecology, Oecologia,Conservation Biology, y Biological Conservation de cinco años seleccionados al azahar durante la misma decada del estudio. Aunque se evidenciaron algunas diferencias en autoría y distribución geográfica, los resultados de este nuevo grupo de revistas científicas reflejaron los mismos patrones de las dos revistas iniciales , casi un 54 por ciento de las publicaciones se basaron en investigación realizada en solo 10 países, y la mayoría de los autores principales provenían de países desarrollados. Nuestros resultados sugieren que la distribución geográfica de la investigación en los trópicos es desigual y aún algunas regiones importantes permanecen sub-estudiadas. El estudio también sugiere la necesidad establecer una mayor colaboración con científicos de países tropicales. [source]


Academic Research Training for a Nonacademic Workplace: a Case Study of Graduate Student Alumni Who Work in Conservation

CONSERVATION BIOLOGY, Issue 6 2009
MATTHEW J. MUIR
educación en conservación; formación de graduados; habilidades para el trabajo; programas universitarios Abstract:,Graduate education in conservation biology has been assailed as ineffective and inadequate to train the professionals needed to solve conservation problems. To identify how graduate education might better fit the needs of the conservation workplace, we surveyed practitioners and academics about the importance of particular skills on the job and the perceived importance of teaching those same skills in graduate school. All survey participants (n = 189) were alumni from the University of California Davis Graduate Group in Ecology and received thesis-based degrees from 1973 to 2008. Academic and practitioner respondents clearly differed in workplace skills, although there was considerably more agreement in training recommendations. On the basis of participant responses, skill sets particularly at risk of underemphasis in graduate programs are decision making and implementation of policy, whereas research skills may be overemphasized. Practitioners in different job positions, however, require a variety of skill sets, and we suggest that ever-increasing calls to broaden training to fit this multitude of jobs will lead to a trade-off in the teaching of other skills. Some skills, such as program management, may be best developed in on-the-job training or collaborative projects. We argue that the problem of graduate education in conservation will not be solved by restructuring academia alone. Conservation employers need to communicate their specific needs to educators, universities need to be more flexible with their opportunities, and students need to be better consumers of the skills offered by universities and other institutions. Resumen:,La educación en biología de la conservación a nivel licenciatura ha sido calificada como ineficaz e inadecuada para formar a los profesionales que se requieren para resolver problemas de conservación. Para identificar cómo la educación a nivel licenciatura puede satisfacer las necesidades del ámbito laboral en conservación, sondeamos a profesionales y académicos sobre la importancia de habilidades particulares del trabajo y la percepción de la importancia de esas mismas habilidades en la universidad. Todos los participantes en el sondeo (n = 189) fueron alumnos del Grupo de Graduados en Ecología de la Universidad de California en Davis y obtuvieron el grado basado en tesis entre 1973 y 2008. Los académicos y profesionales encuestados difirieron claramente en sus habilidades, aunque hubo considerablemente mayor acuerdo en las recomendaciones de capacitación. Con base en las respuestas de los participantes, los conjuntos de habilidades en riesgo de no ser consideradas en los programas educativos son la toma de decisiones y la implementación de políticas, mientras que las habilidades de investigación tienden a ser sobre enfatizadas. Sin embargo, los profesionales en diferentes puestos de trabajo requieren una variedad de conjuntos de habilidades, y sugerimos que los constantes llamados a ampliar la capacitación para responder a esta multitud de labores conducirán a un desbalance en la enseñanza de otras habilidades. Algunas habilidades, como el manejo de programas, pueden desarrollarse en proyectos colaborativos o de capacitación en el trabajo. Argumentamos que el problema de la educación en biología de la conservación a nivel licenciatura no se resolverá solo con la reestructuración de la academia. Los empleadores deben comunicar sus requerimientos específicos a los educadores, las universidades deben ser más flexibles con sus oportunidades y los estudiantes necesitan ser mejores consumidores de las habilidades ofrecidas por las universidades y otras instituciones. [source]


Conservation Biology in Asia: the Major Policy Challenges

CONSERVATION BIOLOGY, Issue 4 2009
JEFFREY A. McNEELY
Asia; bosques; comercio de vida silvestres; conflicto humano-animal; economía Abstract:,With about half the world's human population and booming economies, Asia faces numerous challenges to its biodiversity. The Asia Section of the Society for Conservation Biology has identified some key policy issues in which significant progress can be made. These include developing new sources of funding for forest conservation; identifying potential impacts of energy alternatives on the conservation of biodiversity; curbing the trade in endangered species of plants and animals; a special focus on the conservation of mountain biodiversity; enhancing relevant research; ensuring that conservation biology contributes to major international conventions and funding mechanisms; using conservation biology to build a better understanding of zoonotic diseases; more effectively addressing human,animal conflicts; enhancing community-based conservation; and using conservation biology to help address the pervasive water-deficit problems in much of Asia. These challenges can be met through improved regional cooperation among the relevant stakeholders. Resumen:,Con aproximadamente la mitad de la población humana y economías prósperas, Asia enfrenta numerosos retos para su biodiversidad. La sección Asia de la Sociedad para la Biología de la Conservación ha identificado algunos temas políticos claves en los que se puede hacer un progreso significativo. Estos incluyen el desarrollo de nuevas fuentes de financiamiento para la conservación de bosques; la identificación de impactos potenciales de las energías alternativas sobre la conservación de la biodiversidad; reducción del comercio de especies de animales y plantas en peligro; un enfoque especial en la conservación de la biodiversidad montana; promoción de investigación relevante; garantía de que la biología de la conservación contribuye a convenios internacionales y mecanismos de financiamiento; utilización de la biología de la conservación para lograr un mejor entendimiento de enfermedades zoonóticas; mejor atención a los conflictos humanos-animales; reforzamiento de la conservación basada en comunidades y utilización de la biología de la conservación para atender los problemas de déficit de agua en gran parte de Asia. Estos retos se pueden atender mediante una mejor cooperación regional entre los principales actores. [source]


A Transdisciplinary Approach to Conservation Land Acquisition

CONSERVATION BIOLOGY, Issue 6 2002
Brian Czech
I integrated principles of conservation biology, ecological economics, and political science to outline an approach to conservation land acquisition in the United States. American political economy, especially, has profound implications for conservation land acquisition, yet these implications have been largely neglected by public land conservation agencies. I derived three general recommendations for the conservation of biodiversity via land acquisition: (1) relatively inexpensive lands in relatively intact ecosystems should be prioritized for acquisition, (2) fee-title acquisition should be favored over easement acquisition, and (3) low-lying coastal properties should receive lower priority. These recommendations contribute to an ecologically macroeconomic approach to conservation land acquisition, and each will become more appropriate as the sizes of the U.S. and global economies increase. Ultimately, however, the conservation of biodiversity will require a new political economy predicated on sustainability rather than growth. Resumen: La adquisición de tierras es uno de los aspectos claves para la conservación de la biodiversidad y es una empresa transdisciplinaria que requiere de la consideración de fenómenos sociales y naturales. Integré los principios de la biología de la conservación, la economía ecológica y las ciencias políticas para desarrollar una metodología de adquisición de tierras para la conservación en los Estados Unidos. La economía política norteamericana, especialmente tiene implicancias profundas sobre la adquisición de tierras para la conservación, sin embargo, estas aplicaciones han sido negadas ampliamente por las agencias de conservación de tierras públicas. Derivé tres recomendaciones generales para la conservación de la biodiversidad mediante la adquisición de tierras: 1) tierras relativamente baratas en ecosistemas relativamente intactos deben ser priorizadas para la adquisición, 2) los títulos de adquisición honoraria deben ser favorecidos sobre las adquisiciones forzadas y 3) las propiedades costeras bajas deberán recibir la prioridad más baja. Estas recomendaciones contribuyen a una aproximación ecológicamente macroeconómica para la adquisición de tierras para la conservación y cada una de ellas será más apropiada en tanto que los bienes de los Estados Unidos y la economía global incremente. Sin embargo, a fin de cuentas, la conservación de la biodiversidad requerirá de una nueva economía política predicada en la sustentabilidad más que en el crecimiento. [source]


Making the Monkey: How the Togean Macaque Went from "New Form" to "Endemic Species" in Indonesians' Conservation Biology

CULTURAL ANTHROPOLOGY, Issue 4 2004
Celia Lowe
Indonesian scientists inhabit a postcolonial world where they are both elite (within the nation) and subaltern (within transnational science) at precisely the same moments. A study of science that is neither "ethno" nor "Euro" requires a postcolonial refiguration not only of how science's matter is made but of where and by whom. In the 1990s, the Togean macaque (Macaca togeanus) was proposed as a new species endemic to the Togean Islands, the proposed site of a new conservation area in Central Sulawesi, Indonesia. In the scientific production of biodiverse nature, Indonesian primatologists identified the monkey first as a "new form," then as a "dubious name," and subsequently, as an "endemic species." Throughout these acts of making, unmaking, and remaking the monkey, its unique and endemic status was important for developing Indonesian conservation biology, attracting foreign donors, and enlisting government and public interest in Togean Island nature, even as forms of nature important to Togean peoples were overwritten in this process. [source]


A Semantic View of Ecological Theories,

DIALECTICA, Issue 1 2001
David G.A. CastleArticle first published online: 23 JUN 200
Philosophical analysis of ecological theories has lagged behind the study of evolutionary theory. The semantic conception of scientific theories, which has been employed successfully in the analysis of evolutionary theory, is adopted here to analyse ecological theory. Two general problems in ecology are discussed. One arises from the continued use of covering law models in ecology, and the other concerns the applicability of ecological theory in conservation biology. The semantic conception of ecological theories is used to resolve these problems. [source]


Climate, climate change and range boundaries

DIVERSITY AND DISTRIBUTIONS, Issue 3 2010
Chris D. Thomas
Abstract Aim, A major issue in ecology, biogeography, conservation biology and invasion biology is the extent to which climate, and hence climate change, contributes to the positions of species' range boundaries. Thirty years of rapid climate warming provides an excellent opportunity to test the hypothesis that climate acts as a major constraint on range boundaries, treating anthropogenic climate change as a large-scale experiment. Location, UK and global data, and literature. Methods, This article analyses the frequencies with which species have responded to climate change by shifting their range boundaries. It does not consider abundance or other changes. Results, For the majority of species, boundaries shifted in a direction that is concordant with being a response to climate change; 84% of all species have expanded in a polewards direction as the climate has warmed (for the best data available), which represents an excess of 68% of species after taking account of the fact that some species may shift in this direction for non-climatic reasons. Other data sets also show an excess of animal range boundaries expanding in the expected direction. Main conclusions, Climate is likely to contribute to the majority of terrestrial and freshwater range boundaries. This generalization excludes species that are endemic to specific islands, lakes, rivers and geological outcrops, although these local endemics are not immune from the effects of climate change. The observed shifts associated with recent climate change are likely to have been brought about through both direct and indirect (changes to species' interactions) effects of climate; indirect effects are discussed in relation to laboratory experiments and invasive species. Recent observations of range boundary shifts are consistent with the hypothesis that climate contributes to, but is not the sole determinant of, the position of the range boundaries of the majority of terrestrial animal species. [source]


Life history and population size variability in a relict plant.

DIVERSITY AND DISTRIBUTIONS, Issue 1 2008
Different routes towards long-term persistence
ABSTRACT A central tenet of conservation biology is that population size affects the persistence of populations. However, many narrow endemic species combine small population ranges and sizes with long persistence, thereby challenging this tenet. I examined the performance of three different-sized populations of Petrocoptis pseudoviscosa (Caryophyllaceae), a palaeoendemic rupicolous herb distributed along a small valley in the Spanish Pyrenees. Reproductive and demographic parameters were recorded over 6 years, and deterministic and stochastic matrix models were constructed to explore population dynamics and extinction risk. Populations differed greatly in structure, fecundity, recruitment, survival rate, and life span. Strong differentiation in life-history parameters and their temporal variability resulted in differential population vulnerability under current conditions and simulated global changes such as habitat fragmentation or higher climatic fluctuations. This study provides insights into the capacity of narrow endemics to survive both at extreme environmental conditions and at small population sizes. When dealing with species conservation, the population size,extinction risk relationship may be too simplistic for ancient, ecologically restricted organisms, and some knowledge of life history may be most important to assess their future. [source]


Determinants for the successful establishment of exotic ants in New Zealand

DIVERSITY AND DISTRIBUTIONS, Issue 4 2005
Philip J. Lester
ABSTRACT Biological invasions can dramatically alter ecosystems. An ability to predict the establishment success for exotic species is important for biosecurity and conservation purposes. I examine the exotic New Zealand ant fauna for characteristics that predict or determine an exotic species' ability to establish. Quarantine records show interceptions of 66 ant species: 17 of which have established, 43 have failed to establish, whereas nests of another six are periodically observed but have failed to establish permanently (called ,ephemeral' establishment). Mean temperature at the highest latitude and interception variables were the only factors significantly different between established, failed or ephemeral groups. Aspects of life history, such as competitive behaviour and morphology, were not different between groups. However, in a stepwise discriminant analysis, small size was a key factor influencing establishment success. Interception rate and climate were also secondarily important. The resulting classification table predicted establishment success with 71% accuracy. Because not all exotic species are represented in quarantine records, a further discriminant model is described without interception data. Though with less accuracy (65%) than the full model, it still correctly predicted the success or failure of four species not used in the previous analysis. Techniques for improving the prediction accuracy are discussed. Predicting which species will establish in a new area appears an achievable goal, which will be a valuable tool for conservation biology. [source]


Conservation Biogeography: assessment and prospect

DIVERSITY AND DISTRIBUTIONS, Issue 1 2005
Robert J. Whittaker
ABSTRACT There is general agreement among scientists that biodiversity is under assault on a global basis and that species are being lost at a greatly enhanced rate. This article examines the role played by biogeographical science in the emergence of conservation guidance and makes the case for the recognition of Conservation Biogeography as a key subfield of conservation biology delimited as: the application of biogeographical principles, theories, and analyses, being those concerned with the distributional dynamics of taxa individually and collectively, to problems concerning the conservation of biodiversity. Conservation biogeography thus encompasses both a substantial body of theory and analysis, and some of the most prominent planning frameworks used in conservation. Considerable advances in conservation guidelines have been made over the last few decades by applying biogeographical methods and principles. Herein we provide a critical review focussed on the sensitivity to assumptions inherent in the applications we examine. In particular, we focus on four inter-related factors: (i) scale dependency (both spatial and temporal); (ii) inadequacies in taxonomic and distributional data (the so-called Linnean and Wallacean shortfalls); (iii) effects of model structure and parameterisation; and (iv) inadequacies of theory. These generic problems are illustrated by reference to studies ranging from the application of historical biogeography, through island biogeography, and complementarity analyses to bioclimatic envelope modelling. There is a great deal of uncertainty inherent in predictive analyses in conservation biogeography and this area in particular presents considerable challenges. Protected area planning frameworks and their resulting map outputs are amongst the most powerful and influential applications within conservation biogeography, and at the global scale are characterised by the production, by a small number of prominent NGOs, of bespoke schemes, which serve both to mobilise funds and channel efforts in a highly targeted fashion. We provide a simple typology of protected area planning frameworks, with particular reference to the global scale, and provide a brief critique of some of their strengths and weaknesses. Finally, we discuss the importance, especially at regional scales, of developing more responsive analyses and models that integrate pattern (the compositionalist approach) and processes (the functionalist approach) such as range collapse and climate change, again noting the sensitivity of outcomes to starting assumptions. We make the case for the greater engagement of the biogeographical community in a programme of evaluation and refinement of all such schemes to test their robustness and their sensitivity to alternative conservation priorities and goals. [source]