Is Floral Diversification Associated with Pollinator Divergence? Flower Shape, Flower Colour and Pollinator Preference in Chilean Mimulus

Overview

Journal Ann Bot

Publisher Oxford University Press

Specialty Biology

Date 2008 Feb 15

PMID 18272528

Citations 19

Authors

A M Cooley

G Carvallo

J H Willis

Affiliations

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Abstract

Background And Aims: Adaptation to different pollinators is thought to drive divergence in flower colour and morphology, and may lead to interspecific reproductive isolation. Floral diversity was tested for association with divergent pollinator preferences in a group of four closely related wildflower species: the yellow-flowered Mimulus luteus var. luteus and the red-pigmented M. l. variegatus, M. naiandinus and M. cupreus.

Methods: Patterns of pollinator visitation were evaluated in natural plant populations in central Chile, including both single-species and mixed-species sites. Floral anthocyanin pigments were identified, and floral morphology and nectar variation were quantified in a common garden experiment using seeds collected from the study sites.

Key Results: Mimulus l. luteus, M. l. variegatus and M. naiandinus are morphologically similar and share a single generalist bumblebee pollinator, Bombus dahlbomii. Mimulus cupreus differs significantly from the first three taxa in corolla shape as well as nectar characteristics, and had far fewer pollinator visits.

Conclusions: This system shows limited potential for pollinator-mediated restriction of gene flow as a function of flower colour, and no evidence of transition to a novel pollinator. Mimulus cupreus may experience reduced interspecific gene flow due to a lack of bumblebee visitation, but not because of its red pigmentation: rare yellow morphs are equally undervisited by pollinators. Overall, the results suggest that factors other than pollinator shifts may contribute to the maintenance of floral diversity in these Chilean Mimulus species.

Citing Articles

Coding-Sequence Evolution Does Not Explain Divergence in Petal Anthocyanin Pigmentation Between Mimulus luteus Var luteus and M. l. variegatus.

Orr W, Kim J, Marquez I, Ryan C, Raj T, Hom E Evol Dev. 2024; 27(1):e12493.

PMID: 39599977 PMC: 11599639. DOI: 10.1111/ede.12493.

Phylogenetic Analysis and Flower Color Evolution of the Subfamily Linoideae (Linaceae).

Villalvazo-Hernandez A, Burgos-Hernandez M, Gonzalez D Plants (Basel). 2022; 11(12).

PMID: 35736730 PMC: 9231132. DOI: 10.3390/plants11121579.

Abiotic Environment Predicts Micro- but Not Macroevolutionary Patterns of Flower Color in Monkeyflowers (Phrymaceae).

Grossenbacher D, Makler L, McCarthy M, Fraga N Front Plant Sci. 2021; 12:636133.

PMID: 33841464 PMC: 8030662. DOI: 10.3389/fpls.2021.636133.

The regulatory network for petal anthocyanin pigmentation is shaped by the MYB5a/NEGAN transcription factor in Mimulus.

Zheng X, Om K, Stanton K, Thomas D, Cheng P, Eggert A Genetics. 2021; 217(2).

PMID: 33724417 PMC: 8045675. DOI: 10.1093/genetics/iyaa036.

Geographic Mosaics of Fly Pollinators With Divergent Color Preferences Drive Landscape-Scale Structuring of Flower Color in Daisy Communities.

Ellis A, Anderson B, Kemp J Front Plant Sci. 2021; 12:617761.

PMID: 33597961 PMC: 7882612. DOI: 10.3389/fpls.2021.617761.

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