Increased solar radiation and soil moisture determine flower colour frequency in a mountain endemic plant population

Flower colour is a fascinating trait that has been of interest to biologists for its utility in understanding variation in natural populations and its role in floral evolution. Here, we investigated whether the co-occurring white and pink flowers of individual plants of the Drakensberg near-endemic...

Full description

Saved in:
Bibliographic Details
Published in:Plant ecology 2024-03, Vol.225 (3), p.201-211
Main Authors: Mtileni, M. P., Le Maitre, N. C., Steenhuisen, S., Glennon, K. L.
Format: Article
Language:English
Subjects:
Anthocyanins
Applied Ecology
Biodiversity
Biomedical and Life Sciences
Color
Community & Population Ecology
Damage prevention
Ecology
Endemic plants
Environmental changes
Environmental conditions
Environmental factors
Environmental stress
Flowering
Flowers
Flowers & plants
Gene polymorphism
Growth chambers
Life Sciences
Natural populations
Phenotypic plasticity
Plant Ecology
Plant populations
Plants (botany)
Polymorphism
Radiation
Seasons
Soil moisture
Soil temperature
Solar radiation
Terrestial Ecology
Ultraviolet radiation
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Flower colour is a fascinating trait that has been of interest to biologists for its utility in understanding variation in natural populations and its role in floral evolution. Here, we investigated whether the co-occurring white and pink flowers of individual plants of the Drakensberg near-endemic taxon, Rhodohypoxis baurii (Baker) Nel. var. confecta Hilliard & Burtt (Hypoxidaceae) are an example of phenotypic plasticity or of flower colour polymorphism and what environmental factors may drive observed changes. We used both field and growth chamber studies to test the relationship between environmental variables and the shift in the proportion of the two flower colours over the flowering season. We found that single flowers do not change colour over time, but some individual plants are potentially responding to changes in environmental conditions by producing pigmented flowers later in the flowering season, which suggests that the trait could be plastic rather than a true polymorphism. The field data showed that soil moisture along with an interaction between ultraviolet (UV) radiation and temperature best explained the change in the number of pigmented flowers over the flowering season but none of our treatments in the growth chambers had a significant effect on the change in the number of pigmented flowers. Given the relationship between anthocyanin production and environmental stress, our field findings suggest that soil moisture plays an important role in facilitating stress tolerance and that R. baurii var. confecta may produce anthocyanins to prevent tissue damage from increased temperature and UV later in the flowering season.
ISSN:1385-0237
1573-5052
DOI:10.1007/s11258-023-01388-0