Your search keyword '"Richard Karban"' showing total 5 results

1. Altered precipitation dynamics lead to a shift in herbivore dynamical regime

Author

Adam Pepi, Richard Karban, and Marcel Holyoak

Subjects

0106 biological sciences, Periodicity, Herbivore, education.field_of_study, Ecology, Climate Change, 010604 marine biology & hydrobiology, Population Dynamics, Dynamics (mechanics), Population, Climate change, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Lead (geology), Delayed density dependence, Environmental science, Regime shift, Herbivory, sense organs, Precipitation, education, Ecology, Evolution, Behavior and Systematics

Abstract

The interaction between endogenous dynamics and exogenous environmental variation is central to population dynamics. Although investigations into the effects of changing mean climate are widespread, changing patterns of variation in environmental forcing also affect dynamics in complex ways. Using wavelet and time series analyses, we identify a regime shift in the dynamics of a moth species in California from shorter to longer period oscillations over a 34-year census, and contemporaneous changes in regional precipitation dynamics. Simulations support the hypothesis that shifting precipitation dynamics drove changes in moth dynamics, possibly due to stochastic resonance with delayed density-dependence. The observed shift in climate dynamics and the interaction with endogenous dynamics mean that predicting future population dynamics will require information on both climatic shifts and their interaction with endogenous density-dependence, a combination that is rarely available. Consequently, models based on historical data may be unable to predict future population dynamics.

Published

2021

2. Self-recognition affects plant communication and defense

Author

Kaori Shiojiri and Richard Karban

Subjects

Kin recognition, Ecology, fungi, Immunity, food and beverages, Autoimmunity, Cell Communication, Grasshoppers, Kin selection, Self recognition, Biology, Article Addendum, Artemisia, Animals, Ecology, Evolution, Behavior and Systematics

Abstract

Animals have the ability to distinguish self from non-self, which has allowed them to evolve immune systems and, in some instances, to act preferentially towards individuals that are genetically identical or related. Self-recognition is less well known for plants, although recent work indicates that physically connected roots recognize self and reduce competitive interactions. Sagebrush uses volatile cues emitted by clipped branches of self or different neighbours to increase resistance to herbivory. Here, we show that plants that received volatile cues from genetically identical cuttings accumulated less natural damage than plants that received cues from non-self cuttings. Volatile communication is required to coordinate systemic processes such as induced resistance and plants respond more effectively to self than non-self cues. This self/non-self discrimination did not require physical contact and is a necessary first step towards possible kin recognition and kin selection.

Published

2009

3. How 17-year cicadas keep track of time

Author

C.A. Black, S.A. Weinbaum, and Richard Karban

Subjects

Biological clock, Ecology, media_common.quotation_subject, Periodical cicadas, Metamorphosis, Biology, Nymph, biology.organism_classification, Ecology, Evolution, Behavior and Systematics, media_common

Abstract

Seventeen-year periodical cicadas (Magicicada spp.) require 17 years to develop underground and all individuals at any location emerge synchronously within several days. The mechanisms that animals use to keep track of time are poorly understood and nothing is known about how cicada nymphs emerge after precisely 17 years. We altered the seasonal cycles of trees supporting cicada nymphs and thereby induced premature metamorphosis of the associated cicadas. This indicates that cicadas accomplish a consistently accurate 17-year preadult development time by counting host seasonal cycles and not either by the passage of real time or by the accumulation of degree days.

Published

2000

4. Plant behaviour and communication

Author

Richard Karban

Subjects

Herbivore, Phenotypic plasticity, Ecology, Reproduction, fungi, Foraging, food and beverages, Germination, Biology, Modular construction, Plant Physiological Phenomena, Adaptation, Physiological, Physiological responses, Adaptation, Sensory cue, Ecology, Evolution, Behavior and Systematics, Ecosystem

Abstract

Plant behaviours are defined as rapid morphological or physiological responses to events, relative to the lifetime of an individual. Since Darwin, biologists have been aware that plants behave but it has been an underappreciated phenomenon. The best studied plant behaviours involve foraging for light, nutrients, and water by placing organs where they can most efficiently harvest these resources. Plants also adjust many reproductive and defensive traits in response to environmental heterogeneity in space and time. Many plant behaviours rely on iterative active meristems that allow plants to rapidly transform into many different forms. Because of this modular construction, many plant responses are localized although the degree of integration within whole plants is not well understood. Plant behaviours have been characterized as simpler than those of animals. Recent findings challenge this notion by revealing high levels of sophistication previously thought to be within the sole domain of animal behaviour. Plants anticipate future conditions by accurately perceiving and responding to reliable environmental cues. Plants exhibit memory, altering their behaviours depending upon their previous experiences or the experiences of their parents. Plants communicate with other plants, herbivores and mutualists. They emit cues that cause predictable reactions in other organisms and respond to such cues themselves. Plants exhibit many of the same behaviours as animals even though they lack central nervous systems. Both plants and animals have faced spatially and temporally heterogeneous environments and both have evolved plastic response systems.

Published

2008

5. Experimental clipping of sagebrush inhibits seed germination of neighbours

Author

Richard Karban

Subjects

Herbivore, Eriogonum, Ecology, media_common.quotation_subject, food and beverages, Plant community, Germination, Plant litter, Biology, biology.organism_classification, Poaceae, Competition (biology), Pheromones, Soil, Artemisia, Seedling, Seeds, Litter, Volatilization, Ecology, Evolution, Behavior and Systematics, Allelopathy, Ecosystem, Plant Shoots, media_common

Abstract

Current views of plant communities emphasize the importance of competition for resources and colonization ability in determining seedling establishment and plant distributions. Many desert shrubs are surrounded by bare zones that lack other plants or have different suites of species beneath them compared with the open desert surrounding them. Releases of biochemicals as volatiles from leaves, leachates from litter, or exudates from roots have been proposed as mechanisms for this pattern, but such phytotoxicity has been controversial. I tested the hypothesis that experimental clipping of sagebrush foliage enhances its effect as a germination inhibitor. Germination of native forbs and grasses was reduced in association with clipped, compared with unclipped, sagebrush foliage in lath house and field experiments. Sagebrush seeds were not significantly affected. Air contact was required for this inhibition of germination. Soil contact and leaf litter were not required and added little inhibition of germination. These results suggest a potentially large, indirect, and previously overlooked role for interactions between herbivory and germination that could affect plant community structure.

Published

2007