5,880 research outputs found
Evolutionary comparison between viral lysis rate and latent period
Marine viruses shape the structure of the microbial community. They are,
thus, a key determinant of the most important biogeochemical cycles in the
planet. Therefore, a correct description of the ecological and evolutionary
behavior of these viruses is essential to make reliable predictions about their
role in marine ecosystems. The infection cycle, for example, is indistinctly
modeled in two very different ways. In one representation, the process is
described including explicitly a fixed delay between infection and offspring
release. In the other, the offspring are released at exponentially distributed
times according to a fixed release rate. By considering obvious quantitative
differences pointed out in the past, the latter description is widely used as a
simplification of the former. However, it is still unclear how the dichotomy
"delay versus rate description" affects long-term predictions of host-virus
interaction models. Here, we study the ecological and evolutionary implications
of using one or the other approaches, applied to marine microbes. To this end,
we use mathematical and eco-evolutionary computational analysis. We show that
the rate model exhibits improved competitive abilities from both ecological and
evolutionary perspectives in steady environments. However, rate-based
descriptions can fail to describe properly long-term microbe-virus
interactions. Moreover, additional information about trade-offs between
life-history traits is needed in order to choose the most reliable
representation for oceanic bacteriophage dynamics. This result affects deeply
most of the marine ecosystem models that include viruses, especially when used
to answer evolutionary questions.Comment: to appear in J. Theor. Bio
Evolution at the ecosystem level: On the evolution of ecosystem patterns
A mesura que problemes ambientals com la superpoblació,
la sobrepesca, la contaminació i la pluja àcida han
rebut més atenció pública, l'interès s'ha centrat més en vincles
biogeoquímics i en estudis integrals d'ecosistemes sencers.
Ramon Margalef va reconèixer fermament la notable influència
intel·lectual que es podria obtenir mitjançant la transferència,
d'un camp a un altre, de les perspectives i avenços de cadascun
d'ells. En aquest article voldria tractar la naixent unificació
de la biologia de poblacions i la ciència dels ecosistemes. La
gestió sostenible requereix que es relacionin les característiques
macroscòpiques de les comunitats i els ecosistemes
amb els detalls microscòpics dels individus i les poblacions.
Sostindré que les diferències que han impedit aquesta síntesi
són artificials i que les hem de superar per a poder construir
una ciència que ens permeti afrontar la pèrdua dels beneficis
que es deriven dels ecosistemes.As environmental problems like overpopulation,
overfishing, pollution and acid rain commanded greater public
attention, much focus shifted to biogeochemical linkages, and
to holistic studies of whole ecosystems. Ramon Margalef recognized
as forcefully as anyone the remarkable intellectual leverage
one could gain by transferring the unique perspectives
and advances from one field to another. In this article I discuss
the nascent unification of population biology and ecosystems
science. Sustainable management requires that we relate the
macroscopic features of communities and ecosystems to the
microscopic details of individuals and populations. I argue that
the distinctions that have prevented this synthesis are artificial,
and that we need to overcome them to build a science that allows
us to deal with the loss of the benefits we derive from ecosystems
Fundamental Questions in Biology
The pace of our understanding of biology has engendered increasing specialization but there are still common fundamental challenges that unify biology and should form the core of future research
The Effects of Disturbance Architecture on Landscape-Level Population Dynamics
Phenomena such as disturbance play a major role in structuring ecological systems by producing a spatiotemporal mosaic of patches at different successional states. The distribution of species within the resulting mosaic depends upon an interaction between species\u27 life history traits and the spatial and temporal structure of the ecological processes controlling species\u27 distributions. We have used a spatially explicit simulation model (Jasper) of a serpentine grassland to examine the importance of some of these relationships, focusing primarily on the role of disturbance. The model Jasper is hierarchical in design and was developed to simulate the population dynamics of three interacting plant species: Bromus mollis, Calycadenia multiglandulosa, and Plantago erecta. Population dynamics were modeled as occurring within local sites, which were then arranged in a square array to form a landscape. Connections among sites within a landscape were made primarily through seed dispersal. Several components of disturbance architecture were varied systematically among model runs to determine their impact on population dynamics at the scale of the landscape. We considered three levels of organization in modeling disturbance: (1) overall rate of disturbance, (2) size of individual disturbances, and (3) temporal and spatial autocorrelation among individual disturbances. The results demonstrate that the impact of disturbance depends upon a complex interaction between the life history characteristics of the species making up the community and the spatial and temporal structure of the disturbance regime. For example, we found that the biggest impact on species abundance occurred in response to a shift in the temporal autocorrelation structure of the disturbance regime. Also, species diversity was found to increase at intermediate levels of disturbance (as has been shown in several other studies). However, what can be considered an intermediate level of disturbance depends as much upon the temporal autocorrelation structure of the disturbance regime as it does upon the absolute rate of disturbance. These results suggest that predicting the impact of disturbance on ecological communities will require an explicit understanding of at least some aspects of the spatial and temporal architecture of the disturbance regime
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Toward a Science of Sustainability
This report presents an overview of research horizons in sustainability science. Its motivation is to help harness science and technology to foster a transition toward sustainability – toward patterns of development that promote human well-being while conserving the life-support systems of the planet. It builds on but does not explicitly address the vast range of relevant sector-specific and cross-sectoral problem-solving work now underway in fields ranging from green technologies in energy and manufacturing to urban design to agriculture and natural resources. It focuses on the narrower but essential task of characterizing the needs for fundamental work on the core concepts, methods, models, and measurements that, if successful, would support work across all of those sectoral applications by advancing fundamental understanding of the science of sustainability. The report sets forth the workshop’s findings and recommendations on six fundamental questions now facing scholars seeking to harness science and technology to foster sustainability: 1. What are the principal tradeoffs between human well-being and the natural environment, and how are those tradeoffs mediated by the ways in which people use nature? 2. What determines the adaptability of coupled human-environment systems and, more broadly, their vulnerability and robustness/resilience in the face of external shocks and internal dynamics? 3. What shapes the long term trends and transitions that set the stage on which humanenvironment interactions are played out? 4. How can theory and models be formulated that better account for the variation in types or trends of human-environment interactions? 5. How can society most effectively guide or manage human-environment systems toward a sustainability transition? 6. How can the “sustainability” of alternative trajectories of human-environment interactions be usefully and rigorously evaluated
Opinion: A new approach to financial regulation
It has been five years since the US Congress enacted the landmark Dodd–Frank Wall Street Reform and Consumer Protection Act; and despite the fact that about 20% of the Act has yet to be implemented (1), several legislative initiatives are now attempting to soften or roll back key provisions. This pattern of regulatory action and reaction is not new. The financial excesses of one period often lead to asset bubbles that burst, ushering in a new period of much greater regulation. This, in turn, is systematically weakened over time as markets recover and we forget the reasons why we imposed such stringent regulations in the first place. Even before Dodd–Frank, the financial industry was among the most highly regulated of industries in the world. However, the many layers of regulation and multiple regulatory agencies were insufficient to prevent financial crisis. Why
Cooperation among Microorganisms
Understanding cooperation among microorganisms presents conceptual and mathematical challenges at the interface of evolutionary biology and the theory of emergent properties of independent agents, two of the most exciting areas in modern mathematical biology
From single steps to mass migration: the problem of scale in the movement ecology of the Serengeti wildebeest
A central question in ecology is how to link processes that occur over
different scales. The daily interactions of individual organisms ultimately
determine community dynamics, population fluctuations and the functioning
of entire ecosystems. Observations of these multiscale ecological
processes are constrained by various technological, biological or logistical
issues, and there are often vast discrepancies between the scale at which
observation is possible and the scale of the question of interest. Animal
movement is characterized by processes that act over multiple spatial and
temporal scales. Second-by-second decisions accumulate to produce
annual movement patterns. Individuals influence, and are influenced by,
collective movement decisions, which then govern the spatial distribution
of populations and the connectivity of meta-populations. While the
field of movement ecology is experiencing unprecedented growth in the
availability of movement data, there remain challenges in integrating
observations with questions of ecological interest. In this article, we present
the major challenges of addressing these issues within the context of the
Serengeti wildebeest migration, a keystone ecological phenomena that
crosses multiple scales of space, time and biological complexity.
This article is part of the theme issue ’Collective movement ecology’
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