TY - CHAP T1 - IN PRESS: Using the Southwest Experimental Garden Array to enhance riparian restoration in response to global change: Identifying and deploying genotypes and populations for current and future environments. T2 - In Riparian research and management: Past, present, future. Y1 - 2017 A1 - Whitham, T.G. A1 - C.A. Gehring A1 - H.M. Bothwell A1 - H.F. Cooper A1 - J.B. Hull A1 - G.J. Allan A1 - K.C. Grady A1 - L. Markovchick A1 - S.M. Shuster A1 - J. Parker A1 - A.E. Cadmus A1 - D.H. Ikeda A1 - R.K. Bangert JF - In Riparian research and management: Past, present, future. PB - Gen. Tech. Rep. RMRS-GTR-inpress Fort Collins U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station. CY - Fort Collins, CO, USA VL - 2 ER - TY - JOUR T1 - Local biotic adaptation of trees and shrubs to plant neighbors. JF - Okios Y1 - 2017 A1 - Grady, K.C. A1 - Wood, T. E. A1 - Kolb, T. E. A1 - Hersch-Green, E. A1 - Shuster, S.M. A1 - Gehring, C. A. A1 - Hart, S.C. A1 - Allan, G.J. A1 - T. G. Whitham AB -

Natural selection as a result of plant–plant interactions can lead to local biotic adaptation. This may occur where species frequently interact and compete intensely for resources limiting growth, survival, and reproduction. Selection is demonstrated by comparing a genotype interacting with con‐ or hetero‐specific sympatric neighbor genotypes with a shared site‐level history (derived from the same source location), to the same genotype interacting with foreign neighbor genotypes (from different sources). Better genotype performance in sympatric than allopatric neighborhoods provides evidence of local biotic adaptation. This pattern might be explained by selection to avoid competition by shifting resource niches (differentiation) or by interactions benefitting one or more members (facilitation). We tested for local biotic adaptation among two riparian trees, Populus fremontii and Salix gooddingii, and the shrub Salix exigua by transplanting replicated genotypes from multiple source locations to a 17 000 tree common garden with sympatric and allopatric treatments along the Colorado River in California. Three major patterns were observed: 1) across species, 62 of 88 genotypes grew faster with sympatric neighbors than allopatric neighbors; 2) these growth rates, on an individual tree basis, were 44, 15 and 33% higher in sympatric than allopatric treatments for P. fremontii, S. exigua and S. gooddingii, respectively, and; 3) survivorship was higher in sympatric treatments for P. fremontii and S. exigua. These results support the view that fitness of foundation species supporting diverse communities and dominating ecosystem processes is determined by adaptive interactions among multiple plant species with the outcome that performance depends on the genetic identity of plant neighbors. The occurrence of evolution in a plant‐community context for trees and shrubs builds on ecological evolutionary research that has demonstrated co‐evolution among herbaceous taxa, and evolution of native species during exotic plants invasion, and taken together, refutes the concept that plant communities are always random associations.

VL - 126 UR - https://onlinelibrary.wiley.com/doi/full/10.1111/oik.03240 IS - 4 ER - TY - JOUR T1 - Climate change perils for dioecious plant species. JF - Nature Plant 16109 Y1 - 2016 A1 - KR Hultine A1 - Grady,KC A1 - Wood,TE A1 - SM Shuster A1 - Stella,JC A1 - TG Whitham VL - 109 IS - 2 N1 - [Original String]:Hultine, K. R., Grady, K. C., Wood, T. E., Shuster, S. M., Stella, J. C. and Whitham, T.G. (2016). Climate change perils for dioecious plant species. Nature Plant, 109 (2): 16109. ER - TY - JOUR T1 - Genetically informed ecological niche models improve climate change predictions JF - Global Change Biology Y1 - 2016 A1 - DH Ikeda A1 - Max,TL A1 - GJ Allan A1 - Lau,MK A1 - SM Shuster A1 - TG Whitham ER - TY - JOUR T1 - Genotypic variation in foundation species generates network structure that may drive community dynamics and evolution. JF - Ecology Y1 - 2016 A1 - Lau,Matthew K A1 - Keith,Arthur R A1 - Borrett,Stuart R A1 - Shuster,Stephen M A1 - Whitham,Thomas G KW - Animals KW - Biological Evolution KW - Computer Simulation KW - Food Chain KW - Genetic Variation KW - Genotype KW - Insecta KW - Models, Biological KW - Populus AB -

Although genetics in a single species is known to impact whole communities, little is known about how genetic variation influences species interaction networks in complex ecosystems. Here, we examine the interactions in a community of arthropod species on replicated genotypes (clones) of a foundation tree species, Populus angustifolia James (narrowleaf cottonwood), in a long-term, common garden experiment using a bipartite "genotype-species" network perspective. We combine this empirical work with a simulation experiment designed to further investigate how variation among individual tree genotypes can impact network structure. Three findings emerged: (1) the empirical "genotype-species network" exhibited significant network structure with modularity being greater than the highly conservative null model; (2) as would be expected given a modular network structure, the empirical network displayed significant positive arthropod co-occurrence patterns; and (3) furthermore, the simulations of "genotype-species" networks displayed variation in network structure, with modularity in particular clearly increasing, as genotypic variation increased. These results support the conclusion that genetic variation in a single species contributes to the structure of ecological interaction networks, which could influence eco-ogical dynamics (e.g., assembly and stability) and evolution in a community context.

VL - 97 SN - 0012-9658 UR - http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&DbFrom=pubmed&Cmd=Link&LinkName=pubmed_pubmed&LinkReadableName=Related%20Articles&IdsFromResult=27197399&ordinalpos=3&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSumhttp://www.ncbi. IS - 3 ER - TY - JOUR T1 - Soil-mediated local adaptation alters seedling survival and performance . JF - Plant and Soil Y1 - 2012 A1 - Smith,DS A1 - Schweitzer,JA A1 - Turk,P A1 - JK Bailey A1 - Hart,SC A1 - SM Shuster A1 - TG Whitham VL - 352 N1 - [Original String]:Smith DS, Schweitzer JA, Turk P, Bailey JK, Hart SC, Shuster SM, Whitham TG. 2012. Soil-mediated local adaptation alters seedling survival and performance . Plant and Soil 352: 243-251. ER - TY - JOUR T1 - A geographic mosaic of trophic interactions and selection: trees, aphids and birds JF - Journal of Evolutionary Biology Y1 - 2011 A1 - Smith,DS A1 - JK Bailey A1 - SM Shuster A1 - TG Whitham KW - Administration, Inhalation KW - Administration, Intranasal KW - Aerosols KW - Animals KW - Female KW - Influenza A Virus, H3N2 Subtype KW - Lung KW - Lung Diseases KW - Mice KW - Mice, Inbred BALB C KW - Orthomyxoviridae Infections VL - 24 SN - 1010-061X UR - http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&DbFrom=pubmed&Cmd=Link&LinkName=pubmed_pubmed&LinkReadableName=Related%20Articles&IdsFromResult=21449723&ordinalpos=3&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSumhttp://www.ncbi. IS - 2 ER - TY - JOUR T1 - Extending genomics to natural communities and ecosystems. JF - Science Y1 - 2008 A1 - Whitham,Thomas G A1 - DiFazio,Stephen P A1 - Jennifer A Schweitzer A1 - Shuster,Stephen M A1 - Allan,Gery J A1 - JK Bailey A1 - Woolbright,Scott A KW - Animals KW - Biological Evolution KW - Ecosystem KW - Epigenesis, Genetic KW - Genome, Plant KW - Genomics KW - Plant Physiological Phenomena KW - Plants KW - Selection, Genetic KW - Symbiosis AB -

An important step in the integration of ecology and genomics is the progression from molecular studies of relatively simple model systems to complex field systems. The recent availability of sequenced genomes from key plants is leading to a new understanding of the molecular drivers of community composition and ecosystem processes. As genome sequences accumulate for species that form intimate associations in nature, a detailed view may emerge as to how these associations cause changes among species at the nucleotide level. This advance could dramatically alter views about the structure and evolution of communities and ecosystems.

VL - 320 SN - 0036-8075 UR - http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&DbFrom=pubmed&Cmd=Link&LinkName=pubmed_pubmed&LinkReadableName=Related%20Articles&IdsFromResult=18436780&ordinalpos=3&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSumhttp://www.ncbi. IS - 5875 ER - TY - JOUR T1 - Genetic structure of a foundation species: scaling community phenotypes from the individual to the region. JF - Heredity Y1 - 2008 A1 - RK Bangert A1 - E V Lonsdorf A1 - Wimp,G M A1 - Shuster,S M A1 - Fischer,D A1 - Schweitzer,J A A1 - Allan,G J A1 - JK Bailey A1 - Whitham,T G KW - Animals KW - biodiversity KW - Ecosystem KW - Environment KW - Populus KW - Trees AB -

Understanding the local and regional patterns of species distributions has been a major goal of ecological and evolutionary research. The notion that these patterns can be understood through simple quantitative rules is attractive, but while numerous scaling laws exist (e.g., metabolic, fractals), we are aware of no studies that have placed individual traits and community structure together within a genetics based scaling framework. We document the potential for a genetic basis to the scaling of ecological communities, largely based upon our long-term studies of poplars (Populus spp.). The genetic structure and diversity of these foundation species affects riparian ecosystems and determines a much larger community of dependent organisms. Three examples illustrate these ideas. First, there is a strong genetic basis to phytochemistry and tree architecture (both above- and belowground), which can affect diverse organisms and ecosystem processes. Second, empirical studies in the wild show that the local patterns of genetics based community structure scale up to western North America. At multiple spatial scales the arthropod community phenotype is related to the genetic distance among plants that these arthropods depend upon for survival. Third, we suggest that the familiar species-area curve, in which species richness is a function of area, is also a function of genetic diversity. We find that arthropod species richness is closely correlated with the genetic marker diversity and trait variance suggesting a genetic component to these curves. Finally, we discuss how genetic variation can interact with environmental variation to affect community attributes across geographic scales along with conservation implications.

VL - 100 SN - 0018-067X UR - http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&DbFrom=pubmed&Cmd=Link&LinkName=pubmed_pubmed&LinkReadableName=Related%20Articles&IdsFromResult=17047690&ordinalpos=3&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSumhttp://www.ncbi. IS - 2 ER - TY - JOUR T1 - Tree hybridization and genotypic variation drive cryptic speciation of a specialist mite herbivore. JF - Evolution; international journal of organic evolution Y1 - 2008 A1 - Evans,Luke M A1 - Allan,Gerard J A1 - Shuster,Stephen M A1 - Woolbright,Scott A A1 - Whitham,Thomas G KW - Analysis of Variance KW - Animals KW - Base Sequence KW - Cluster Analysis KW - Crosses, Genetic KW - DNA Primers KW - Genetic Variation KW - Genetics, Population KW - Geography KW - Host-Parasite Interactions KW - Hybridization, Genetic KW - Mites KW - Molecular Sequence Data KW - Phylogeny KW - Populus KW - Sequence Analysis, DNA KW - Utah AB -

Few studies have investigated the roles that plant hybridization and individual plant genotype play in promoting population divergence within arthropod species. Using nrDNA sequence information and reciprocal transfer experiments, we examined how tree cross type (i.e., pure Populus angustifolia and P. angustifolia x P. fremontii F(1) type hybrids) and individual tree genotype influence host race formation in the bud-galling mite Aceria parapopuli. Three main findings emerged: (1) Strong genetic differentiation of mite populations found on pure P. angustifolia and F(1) type hybrids indicates that these mites represent morphologically cryptic species. (2) Within the F(1) type hybrids, population genetic analyses indicate migration among individual trees; however, (3) transfer experiments show that the mites found on heavily infested F(1) type trees perform best on their natal host genotype, suggesting that genetic interactions between mites and their host trees drive population structure, local adaptation, and host race formation. These findings argue that hybridization and genotypic differences in foundation tree species may drive herbivore population structure, and have evolutionary consequences for dependent arthropod species.

VL - 62 SN - 0014-3820 UR - http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&DbFrom=pubmed&Cmd=Link&LinkName=pubmed_pubmed&LinkReadableName=Related%20Articles&IdsFromResult=18752612&ordinalpos=3&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSumhttp://www.ncbi. IS - 12 ER - TY - JOUR T1 - Community heritability measures the evolutionary consequences of indirect genetic effects on community structure. JF - Evolution; international journal of organic evolution Y1 - 2006 A1 - Shuster,S M A1 - E V Lonsdorf A1 - Wimp,G M A1 - JK Bailey A1 - Whitham,T G KW - Animals KW - Arthropods KW - Computer Simulation KW - Environment KW - Evolution, Molecular KW - Genetic Variation KW - North America KW - Phenotype KW - Populus KW - Selection, Genetic KW - Trees AB -

The evolutionary analysis of community organization is considered a major frontier in biology. Nevertheless, current explanations for community structure exclude the effects of genes and selection at levels above the individual. Here, we demonstrate a genetic basis for community structure, arising from the fitness consequences of genetic interactions among species (i.e., interspecific indirect genetic effects or IIGEs). Using simulated and natural communities of arthropods inhabiting North American cottonwoods (Populus), we show that when species comprising ecological communities are summarized using a multivariate statistical method, nonmetric multidimensional scaling (NMDS), the resulting univariate scores can be analyzed using standard techniques for estimating the heritability of quantitative traits. Our estimates of the broad-sense heritability of arthropod communities on known genotypes of cottonwood trees in common gardens explained 56-63% of the total variation in community phenotype. To justify and help interpret our empirical approach, we modeled synthetic communities in which the number, intensity, and fitness consequences of the genetic interactions among species comprising the community were explicitly known. Results from the model suggest that our empirical estimates of broad-sense community heritability arise from heritable variation in a host tree trait and the fitness consequences of IGEs that extend from tree trait to arthropods. When arthropod traits are heritable, interspecific IGEs cause species interactions to change, and community evolution occurs. Our results have implications for establishing the genetic foundations of communities and ecosystems.

VL - 60 SN - 0014-3820 UR - http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&DbFrom=pubmed&Cmd=Link&LinkName=pubmed_pubmed&LinkReadableName=Related%20Articles&IdsFromResult=16817539&ordinalpos=3&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSumhttp://www.ncbi. IS - 5 ER - TY - JOUR T1 - A framework for community and ecosystem genetics: from genes to ecosystems. JF - Nature reviews. Genetics Y1 - 2006 A1 - Whitham,Thomas G A1 - JK Bailey A1 - Jennifer A Schweitzer A1 - Shuster,Stephen M A1 - RK Bangert A1 - LeRoy,Carri J A1 - Lonsdorf,Eric V A1 - Allan,Gery J A1 - DiFazio,Stephen P A1 - Potts,Brad M A1 - Fischer,Dylan G A1 - Gehring,Catherine A A1 - Lindroth,Richard L A1 - Jane C Marks A1 - Stephen C Hart A1 - Wimp,Gina M A1 - Wooley,Stuart C KW - Animals KW - Ecosystem KW - Genetics, Population KW - Humans KW - Plants AB -

Can heritable traits in a single species affect an entire ecosystem? Recent studies show that such traits in a common tree have predictable effects on community structure and ecosystem processes. Because these 'community and ecosystem phenotypes' have a genetic basis and are heritable, we can begin to apply the principles of population and quantitative genetics to place the study of complex communities and ecosystems within an evolutionary framework. This framework could allow us to understand, for the first time, the genetic basis of ecosystem processes, and the effect of such phenomena as climate change and introduced transgenic organisms on entire communities.

VL - 7 SN - 1471-0056 UR - http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&DbFrom=pubmed&Cmd=Link&LinkName=pubmed_pubmed&LinkReadableName=Related%20Articles&IdsFromResult=16778835&ordinalpos=3&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSumhttp://www.ncbi. IS - 7 ER -