Your search keyword '"Sharon M. Ferrier"' showing total 7 results

1. Landscape genetic connectivity in a riparian foundation tree is jointly driven by climatic gradients and river networks

Author

Nashelly Meneses, Sharon M. Ferrier, Thomas G. Whitham, Gerard J. Allan, Barbara M. Honchak, Luke M. Evans, Samuel A. Cushman, and Tamara L. Max

Subjects

Gene Flow, Genetic diversity, geography, geography.geographical_feature_category, Ecology, Resistance (ecology), Biology, biology.organism_classification, Trees, Rivers, Habitat, Populus fremontii, Threatened species, Southwestern United States, Foundation species, Ecosystem, Riparian zone, Landscape connectivity

Abstract

Fremont cottonwood (Populus fremonti) is a foundation riparian tree species that drives community structure and ecosystem processes in southwestern U.S. ecosystems. Despite its ecological importance, little is known about the ecological and environmental processes that shape its genetic diversity, structure, and landscape connectivity. Here, we combined molecular analyses of 82 populations including 1312 individual trees dispersed over the species' geographical distribution. We reduced the data set to 40 populations and 743 individuals to eliminate admixture with a sibling species, and used multivariate restricted optimization and reciprocal causal modeling to evaluate the effects of river network connectivity and climatic gradients on gene flow. Our results confirmed the following: First, gene flow of Fremont cottonwood is jointly controlled by the connectivity of the river network and gradients of seasonal precipitation. Second, gene flow is facilitated by mid-sized to large rivers, and is resisted by small streams and terrestrial uplands, with resistance to gene flow decreasing with river size. Third, genetic differentiation increases with cumulative differences in winter and spring precipitation. Our results suggest that ongoing fragmentation of riparian habitats will lead to a loss of landscape-level genetic connectivity, leading to increased inbreeding and the concomitant loss of genetic diversity in a foundation species. These genetic effects will cascade to a much larger community of organisms, some of which are threatened and endangered.

Published

2014

2. Conservative leaf economic traits correlate with fast growth of genotypes of a foundation riparian species near the thermal maximum extent of its geographic range

Author

Thomas G. Whitham, Thomas Kolb, Stephen C. Hart, Kevin C. Grady, Gerard J. Allan, Daniel C. Laughlin, and Sharon M. Ferrier

Subjects

Stomatal conductance, biology, Specific leaf area, Ecology, Range (biology), fungi, food and beverages, Interspecific competition, biology.organism_classification, Intraspecific competition, Populus fremontii, Growth rate, Adaptation, Ecology, Evolution, Behavior and Systematics

Abstract

Summary 1. Plant functional traits involved in carbon and water acquisition are likely to be adaptive across the range of a species if the availability of these resources varies across this range and are limiting to growth or fitness. At the interspecific level, leaf economic traits associated with rapid resource capture are correlated with fast growth rates. However, relationships between leaf traits and growth are poorly understood at the intraspecific level. 2. We examined two hypotheses: (i) leaf traits vary genotypically among Populus fremontii populations from different thermal environments; and (ii) leaf traits are related to growth rate of these P. fremontii populations. We used a common garden at the warm edge of P. fremontii distribution that included individuals transplanted from 11 provenances. Provenances varied in mean annual maximum temperature by 5� 9 °C, reflecting a range of expected increases in temperature over the next 80 years. 3. Conservative leaf traits (e.g. low specific leaf area, N content, stomatal conductance, net photosynthetic rate and high leaf water-use efficiency) were positively related to growth rates of genotypes and populations, a pattern opposite of that widely reported among species in other studies. 4. Provenance temperature explained 75% of the variation in multivariate leaf traits with the warmest provenances having the most conservative traits and highest growth rates. Clinal genetic variation suggests that P. fremontii may be adapted to thermal environments. 5. Leaf area-to-sapwood area ratio was positively associated with growth rate, while leaf areabased net photosynthetic rate was negatively associated with growth rate; these results suggest that hydraulic architecture was more important than leaf-level photosynthetic rate in determining growth rate. 6. Synthesis. Our results suggest that conservative leaf traits promote rapid growth of P. fremontii genotypes in extremely hot environments. Thus, relationships between leaf economic traits among species do not necessarily apply to the range of variation among genotypes within species. The generality of this pattern should be examined for other species that will be exposed to climate warming. Moreover, our research shows that common garden provenance trials are useful for identifying genotypes best suited to a predicted warmer climate and for improving understanding of the physiological basis for adaptation to warm environments.

Published

2013

3. The Proportion of Three Foundation Plant Species and Their Genotypes Influence an Arthropod Community: Restoration Implications for the Endangered Southwestern Willow Flycatcher

Author

Sharon M. Ferrier, Thomas G. Whitham, Randy K. Bangert, Karla Kennedy, Kevin C. Grady, Erika I. Hersch-Green, Luke M. Evans, and Gerard J. Allan

Subjects

Willow, Ecology, biology, fungi, Endangered species, food and beverages, Salix gooddingii, biology.organism_classification, Salix exigua, Species of concern, Populus fremontii, Species richness, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, Woody plant

Abstract

As part of a restoration project, multiple genotypes of two tree species, Fremont cottonwood (Populus fremontii) and Goodding's willow (Salix gooddingii), and one shrub species, Coyote willow (S. exigua), were experimentally planted in different proportions at the Palo Verde Ecological Reserve near Blythe, California, U.S.A. These common woody plant species are important to the endangered southwestern willow flycatcher, providing perch, nesting, and foraging habitat. We conducted this study to evaluate plant species proportion and plant genotype effects on the arthropod community, the prey base for the endangered southwestern willow flycatcher. Three patterns emerged. First, plant species proportions were important; the arthropod community had the greatest richness and diversity (H′) when Goodding's willow proportion was high and Fremont cottonwood proportion was lower; that is, fewer Fremont cottonwoods are required to positively affect overall arthropod diversity. Second, we found significant genotypic effects, for all three plant species, on arthropod species accumulation. Third, while both planting proportion and genotype effects were significant, we found that the effect of planting proportion on arthropod richness was about twice as large as the effect of plant genotype. This shows that both plant species proportions and genotype should be utilized in restoration projects to maximize habitat heterogeneity and arthropod richness. Similar studies can determine which planting proportion and specific genotypes may result in a more favorable arthropod prey base for the southwestern willow flycatcher and other species of concern. Greater attention to planting design and genotype can result in significant gains in diversity at little or no additional project cost.

Published

2012

4. Unique arthropod communities on different host-plant genotypes results in greater arthropod diversity

Author

Thomas G. Whitham, Sharon M. Ferrier, G. J. Allan, Randy K. Bangert, Erika I. Hersch-Green, and Joseph K. Bailey

Subjects

Canopy, Entomology, Ecology, biology, fungi, food and beverages, Community genetics, biology.organism_classification, stomatognathic system, Genetic distance, Populus fremontii, Insect Science, Genotype, Arthropod, human activities, Agronomy and Crop Science, Ecology, Evolution, Behavior and Systematics, Invertebrate

Abstract

Studies on the effect of plant-species diversity on various ecological processes has led to the study of the effects of plant-genetic diversity in the context of community genetics. Arthropod diversity can increase with plant-species or plant-genetic diversity (Wimp et al. in Ecol Lett 7:776–780, 2004). Plant diversity effects can be difficult to separate from other ecological processes, for example, complementarity. We asked three basic questions: (1) Are arthropod communities unique on different host-plant genotypes? (2) Is arthropod diversity greater when associated with greater plant-genetic diversity? (3) Are arthropod communities more closely associated with host-plant genetics than the plant neighborhood? We studied canopy arthropods on Populus fremontii trees randomly planted in a common garden. All trees were planted in a homogeneous matrix, which helped to reduce P. fremontii neighborhood effects. One sample was comprised of few P. fremontii genotypes with many clones. A second sample was comprised of many P. fremontii genotypes with few clones. A second data set was used to examine the relationships between the arthropod community with P. fremontii genetic composition and the neighborhood composition of the focal host plant. Unique arthropod communities were associated with different P. fremontii genotypes, and arthropod community diversity was greater in the sample with greater P. fremontii genotypic diversity. Arthropod community similarity was negatively correlated with P. fremontii genetic distance, but arthropod community similarity was not related to the neighborhood of the P. fremontii host plant.

Published

2012

5. Genetic variation in productivity of foundation riparian species at the edge of their distribution: implications for restoration and assisted migration in a warming climate

Author

Thomas Kolb, Thomas G. Whitham, Gerard J. Allan, Stephen C. Hart, Sharon M. Ferrier, and Kevin C. Grady

Subjects

Global and Planetary Change, geography, education.field_of_study, geography.geographical_feature_category, Ecology, biology, ved/biology, Population, ved/biology.organism_classification_rank.species, Endangered species, Salix gooddingii, biology.organism_classification, Shrub, Salix exigua, Populus fremontii, Environmental Chemistry, education, Restoration ecology, General Environmental Science, Riparian zone

Abstract

We examined the hypothesis that genotypic variation among populations of commonly co-occurring phreatophytic trees (Populus fremontii, Salix gooddingii) and the shrub (Salix exigua) regulates aboveground net primary productivity (ANPP) at a hot site at the edge of the species’ distribution. We used a provenance trial in which replicated genotypes from populations varying in mean annual temperature were transplanted to a common garden adjacent to the Lower Colorado River in southeastern California. The garden environment represented an extreme maximum temperature for the study species. Four major findings emerged: (1) Genotypic variation in ANPP was significant for all species with broad-sense heritability (H 2 ) across populations of 0.11, 0.13, and 0.10 for P. fremontii, S. gooddingii, and S. exigua, respectively, and within-population H 2 ranging from 0.00 to 0.25, 0.00 to 0.44, and 0.02 to 0.21, respectively. (2) Population ANPP decreased linearly as mean annual maximum temperature (MAMT) transfer distance increased for both P. fremontii (r 2 = 0.64) and S. gooddingii (r 2 = 0.37), whereas it did not change for S. exigua; (3) Populations with similar MAMT to that of the common garden were 1.5 and 1.2 times more productive than populations with 5.0 °C MAMT transfer distances for P. fremontii and S. gooddingii, respectively; and (4) Variation in regression slopes among species for the relationship between ANPP and MAMT indicate species-specific responses to temperature. As these plant species characterize a threatened habitat type and support a diverse community that includes endangered species, ecosystem restoration programs should consider using both local genotypes and productive genotypes from warmer environments to maximize productivity of riparian ecosystems in the face of global climate change.

Published

2011

6. Release of phylogenetic constraints through low resource heterogeneity: the case of gall-inducing sawflies

Author

Heikki Roininen, Sharon M. Ferrier, Timothy P. Craig, Peter W. Price, Takayuki Ohgushi, Michihiro Ishihara, and Jorma Tahvanainen

Subjects

education.field_of_study, Ecology, biology, Population, Hymenoptera, biology.organism_classification, Sawfly, Abscission, Salicaceae, Insect Science, Botany, Shoot, Gall, education, Tenthredinidae

Abstract

A group of six unusual sawfly species, which do not conform to the phylogenetic constraints hypothesis as it has been applied to sawflies, was exam- ined in natural populations. All species were in the genus Pontania (Hymenoptera: Tenthredinidae), which induce galls on leaves of willow species (Salicaceae). An understanding of these non-conformist species was important as a test of the validity of the general hypothesis. 2. The six species of sawfly, Pontania mandshurica, P. cf. arcticornis, P. aestiva, P. arcticornis, P. pacifica, and P. nr. pacifica, showed no oviposition preference for long, vigorous shoots, in contrast to 37 documented tenthredinid species that have demonstrated such a preference. Rather, the non-conformist species attacked the shortest shoot length classes more frequently and larval establishment in galls was successful. 3. The evident escape from the phylogenetic constraint, which commonly limits sawfly attack to the most vigorous shoots in a willow population, resulted from low apparent heterogeneity of the resources exploited by these Pontania species. At the time of female oviposition, shoots and leaves were too uniform to allow discrimination by females among shoot length classes, resulting in random, or near random attack of shoots. 4. The unusual relative uniformity of resources to which sawflies were exposed resulted from several characteristics. (1) Females emerged early relative to shoot growth phenology, making discrimination among shoot length and vigour difficult or impossible. (2) Low heterogeneity in leaf length resulted in resource similarity independent of shoot length. (3) Abscission of leaves occurred after emergence of larvae from leaf galls so that differential abscission of leaves in relation to shoot length became irrelevant. (4) In some cases, low variance in shoot lengths was evident in old ramets lacking long, vigorous shoots. Probably as a result of low resource heterogeneity, larvae survived well across all shoot length classes, revealing no ovipositional preference and larval performance linkage related to the exploita- tion of the longest shoot length classes in a population of willows, as in the conformist species. Therefore, larval survival did not provide positive feedback on female preferential behaviour for long shoots, as in the conformist species studied.

Published

2004

7. Oviposition Preference and Larval Performance of a Rare Bud-Galling Sawfly (Hymenoptera: Tenthredinidae) on Willow in Northern Arizona

Author

Peter W. Price and Sharon M. Ferrier

Subjects

Larva, Willow, Ecology, Hymenoptera, Biology, biology.organism_classification, Horticulture, Sawfly, Nutrient, Insect Science, Shoot, Botany, Salix scouleriana, Tenthredinidae, Ecology, Evolution, Behavior and Systematics

Abstract

Oviposition preference was examined in relation to offspring performance in a bud gall-forming sawfly, Euura sp., which attacks the Scouler or fire willow, Salix scouleriana (Barratt). The only known locality for this sawfly in Arizona is in the inner basin of the San Francisco Peaks, at 3,100–3,450 m above sea level. A random sample of shoots was taken in October of 1995, 1996, 1997, and 1998 to record shoot length, number of buds per shoot, number of galls per shoot, percent mortality, and overall percent survival for each generation. Oviposition preference was quantified for the first 3 yr, and larval performance was measured over all 4 yr. We found a strong oviposition preference for longer shoots. The longest shoot-length classes contained the smallest proportion of buds, and yet they were attacked more frequently than the short shoot-length classes. Therefore, the rarest shoot-length classes were the most preferred. Larval establishment and survival in galls were used to evaluate offspring performance. No significant correlation existed between larval establishment and shoot length, thus negating the prediction of a preference-performance linkage. Overall survivorship was high in 1995 (77%), 1997 (80%), and 1998 (82%), but drastically dropped in 1996 (16%), possibly because of a severe drought during that year. We discuss two alternative hypotheses to possibly explain these results: (1) all modules (long and short shoots) could provide sufficient nutrients for larvae to survive; and (2) selective pressures acting on female oviposition behavior are independent of larval performance.

Published

2004