# Retrospective phenology in western Mediterranean plants: revealing climate change patterns through herbarium specimens

**Authors:** Andros Solakis-Tena, Federico Casimiro-Soriguer Solanas, Noelia Hidalgo-Triana

PMC · DOI: 10.1093/aobpla/plaf064 · AoB Plants · 2025-11-03

## TL;DR

Herbarium specimens show Mediterranean plants are flowering and growing earlier due to climate change, which could disrupt ecosystems.

## Contribution

The study uses herbarium data to reveal consistent phenological shifts across thermotypes in Mediterranean plants.

## Key findings

- Flowering advanced by ~3.6 days per decade and vegetative growth by ~5.6 days per decade.
- 97% of plant species showed significant phenological shifts linked to rising temperatures and reduced precipitation.
- Phenological homogenization is emerging across different elevational thermotypes.

## Abstract

Herbarium specimens have proven useful for assessing phenological responses to climate change. Using preserved specimens, we analysed the changes in day of year (DOY) for four phenophases: three reproductive (preflowering, flowering, fruiting) and one vegetative (growth). We conducted phenological analysis across bioclimatic belts (thermotypes) from the Rivas–Martinez classification and across 77 taxa present in the Baetic Ranges of the southern Iberian Peninsula. Taxa were characteristic, common, or endemic species from Habitats of Community Interest (HCI) under the European Directive 92/43/EEC. Phenological shifts were assessed using two approaches: long-term trends in DOY with time and relationships with historical climate variables related to temperature and precipitation. At the thermotypes level, flowering advanced consistently over time and with increasing temperatures, showing homogeneous responses and suggesting a weakening of altitudinal differentiation. In contrast, growth exhibited thermotype-specific trends, with stronger advances at high elevations, while preflowering and fruiting showed little or no sensitivity to time or climate variables. At the species level, 31% of taxa showed phenological changes over time in the Baetic Ranges (−3.6 days/decade for reproductive and −5.6 days/decade for vegetative phenophases). However, 97% of taxa showed significant relationships with increasing temperatures and decreasing precipitation, particularly with mean annual temperature (−12.7 days for reproductive and −14.3 days for vegetative phenophases per increased °C). These phenological changes could hinder reproductive and vegetative success by causing mismatches with other ecosystem role-players. As the Mediterranean is expected to become warmer and drier, our findings indicate a potential threat to HCI in the southern Mediterranean.

Herbarium records reveal widespread earlier timing of Mediterranean plant life cycles under warming. Flowering shifted earlier by ~3.6 days per decade (~12.7 days per °C), and vegetative growth by ~5.6 days per decade (~14.3 days per °C). Responses were largely consistent across elevational thermotypes, suggesting emerging phenological homogenization. Such advances threaten the timing with pollinators and seed dispersers, and highlight the power of herbaria to track climate impacts.

## Full-text entities

- **Diseases:** FS (MESH:D052159), MS (MESH:D009103), CL (MESH:D002971)
- **Chemicals:** F (MESH:D005461), P (MESH:D010758), T (MESH:D014316), carbon (MESH:D002244), Cistus ladanifer (-)
- **Species:** Klasea boetica (species) [taxon 305365], Juniperus sabina (species) [taxon 224740], Abies pinsapo var. pinsapo (varietas) [taxon 928732], Quercus faginea (species) [taxon 501392], Odontarrhena serpyllifolia (species) [taxon 226043], Helichrysum stoechas (species) [taxon 261805], Macrochloa tenacissima (species) [taxon 666013], Hormathophylla spinosa (species) [taxon 283749], Prunus prostrata (species) [taxon 195662], Ceratonia siliqua (carob, species) [taxon 20340], Teline rosmarinifolia (species) [taxon 175406], Phillyrea angustifolia (species) [taxon 96521], C. albidus [taxon 99750], Quercus rotundifolia (species) [taxon 501391], Acer granatense (species) [taxon 2499985], Halimium atriplicifolium (species) [taxon 566273], Rhamnus alaternus (species) [taxon 280017], Crepis oporinoides (species) [taxon 509679], Fumana thymifolia (species) [taxon 335157], Oenomaus lea (species) [taxon 1256052], Chaenorhinum glareosum (species) [taxon 1732068], Cistus albidus (species) [taxon 335163], Cistus ladanifer (species) [taxon 335173], Cotoneaster granatensis (species) [taxon 2720241], Phlomis purpurea (species) [taxon 316258], Thymus mastichina (mastic thyme, species) [taxon 157259], Quercus suber (cork oak, species) [taxon 58331], Abies pinsapo (hedgehog fir, species) [taxon 56046], Homo sapiens (human, species) [taxon 9606], Cistus populifolius (species) [taxon 335177], Leontodon boryi (species) [taxon 379111], Lonicera etrusca (species) [taxon 245821], Sempervivum minutum (species) [taxon 92855], Chamaesiphon minutus (species) [taxon 1173032]

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12611260/full.md

## References

129 references — full list in the complete paper: https://tomesphere.com/paper/PMC12611260/full.md

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Source: https://tomesphere.com/paper/PMC12611260