Morphological Differences in Across Latitudinal and Elevational Gradients

Overview

Journal Front Plant Sci

Date 2020 Nov 16

PMID 33193485

Citations 6

Authors

Alejandro Leal-Saenz

Kristen M Waring

Mitra Menon

Samuel A Cushman

Andrew Eckert

Lluvia Flores-Renteria

Jose Ciro Hernandez-Diaz

Carlos Antonio Lopez-Sanchez

Jose Hugo Martinez-Guerrero

Christian Wehenkel

Affiliations

Soon will be listed here.

Abstract

The phenotype of trees is determined by the relationships and interactions among genetic and environmental influences. Understanding the patterns and processes that are responsible for phenotypic variation is facilitated by studying the relationships between phenotype and the environment among many individuals across broad ecological and climatic gradients. We used , which has a wide latitudinal distribution, as a model species to: (a) estimate the relative importance of different environmental factors in predicting these morphological traits and (b) characterize the spatial patterns of standing phenotypic variation of cone and seed traits across the species' range. A large portion of the total variation in morphological characteristics was explained by ecological, climatic and geographical variables (54.7% collectively). The three climate, vegetation and geographical variable groups, each had similar total ability to explain morphological variation (43.4%, 43.8%, 51.5%, respectively), while the topographical variable group had somewhat lower total explanatory power (36.9%). The largest component of explained variance (33.6%) was the four-way interaction of all variable sets, suggesting that there is strong covariation in environmental, climate and geographical variables in their relationship to morphological traits of southwest white pine across its range. The regression results showed that populations in more humid and warmer climates expressed greater cone length and seed size. This may in part facilitate populations of in warmer and wetter portions of its range growing in dense, shady forest stands, because larger seeds provide greater resources to germinants at the time of germination. Our models provide accurate predictions of morphological traits and important insights regarding the factors that contribute to their expression. Our results indicate that managers should be conservative during reforestation efforts to ensure match between ecotypic variation in seed source populations. However, we also note that given projected large range shift due to climate change, managers will have to balance the match between current ecotypic variation and expected range shift and changes in local adaptive optima under future climate conditions.

Citing Articles

Evolutionary trends of reproductive phenotype in Cycadales: an analysis of morphological evolution in Ceratozamia.

Martinez-Dominguez L, Nicolalde-Morejon F, Vergara-Silva F, Gernandt D, Huesca-Dominguez I, Stevenson D Ann Bot. 2024; 134(4):631-650.

PMID: 38676472 PMC: 11523635. DOI: 10.1093/aob/mcae058.

Effects of geo-climate factors on phenotypic variation in cone and seed traits of .

Gao C, Liu F, Miao Y, Li J, Liu Z, Cui K Ecol Evol. 2023; 13(10):e10568.

PMID: 37780092 PMC: 10534196. DOI: 10.1002/ece3.10568.

Color and morphological differentiation in the Sinaloa Wren (Thryophilus sinaloa) in the tropical dry forests of Mexico: The role of environment and geographic isolation.

Malpica A, Mendoza-Cuenca L, Gonzalez C PLoS One. 2022; 17(6):e0269860.

PMID: 35737646 PMC: 9223310. DOI: 10.1371/journal.pone.0269860.

Phenotypic Trait Subdivision Provides New Sight Into the Directional Improvement of Oliver.

Deng P, Wang Y, Hu F, Yu H, Liang Y, Zhang H Front Plant Sci. 2022; 13:832821.

PMID: 35463430 PMC: 9026163. DOI: 10.3389/fpls.2022.832821.

Assessment and Models of Insect Damage to Cones and Seeds of in the Sierra Madre Occidental, Mexico.

Leal-Saenz A, Waring K, Alvarez-Zagoya R, Hernandez-Diaz J, Lopez-Sanchez C, Martinez-Guerrero J Front Plant Sci. 2021; 12:628795.

PMID: 33995433 PMC: 8116514. DOI: 10.3389/fpls.2021.628795.

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