# Cold tolerance of native plants in the Lancang River dry–hot valley: an integrative physiological–biochemical assessment with implications for cold-resistance breeding

**Authors:** Yunchen Zhang, Jianying Yang, Xu Yuan, Yandong Yang, Xiaodong Ji, Jinnan Ji, Yan Zhang, Jiao Huang

PMC · DOI: 10.3389/fpls.2025.1724940 · Frontiers in Plant Science · 2026-01-27

## TL;DR

This study evaluates cold tolerance in native plants from a dry-hot valley to guide ecological restoration and breeding for cold resistance.

## Contribution

The study introduces a multi-trait physiological-biochemical framework to assess cold tolerance more accurately than single metrics like LT50.

## Key findings

- Species like Sophora davidii showed high membrane stability and osmolyte accumulation under freezing conditions.
- An integrated cold-tolerance index ranked species differently than rankings based solely on LT50.
- Photosystem II efficiency and electrolyte leakage were the most informative cold-response traits.

## Abstract

Extreme winter cold in the Lancang River dry–hot valley limits vegetation establishment. Selecting cold-tolerant native species is therefore critical for ecological restoration and for maintaining stable agro-vegetation. This study aimed to assess cold tolerance in representative native shrubs and herbs using an integrated physiological and biochemical approach.

Seedlings of three shrubs (Sophora davidii, Vitex negundo var. microphylla, Rumex hastatus) and two herbs (Arthraxon lanceolatus, Artemisia vestita) were exposed to temperatures from 25°C down to –35°C in growth chambers. We quantified membrane injury (relative electrolyte leakage and semilethal temperature, LT50), gas exchange, chlorophyll fluorescence, osmolyte levels (proline, soluble sugars), and antioxidant enzyme activities (e.g., superoxide dismutase). Multivariate analyses (principal component analysis and membership functions) were used to develop an integrated cold-tolerance index.

Semilethal temperature (LT50) differed markedly among species (approximately –27°C in S. davidii vs –5°C in A. lanceolatus), indicating a wide range of freezing tolerance. Across the freezing gradient, S. davidii maintained the lowest electrolyte leakage and partial Photosystem II efficiency, while accumulating high proline and soluble sugar levels and sharply increasing superoxide dismutase activity. In contrast, A. lanceolatus showed rapid membrane leakage and fluorescence declines. The most informative cold-response traits were Photosystem II efficiency and electrolyte leakage. An integrated cold-tolerance index based on multiple physiological metrics ranked species from highest to lowest tolerance as A. vestita > A. lanceolatus > V. negundo > R. hastatus > S. davidii. This ranking differed notably from the ranking based on LT50 alone.

The discrepancy between the multi-trait index and single-trait (LT50) ranking highlights the risk of inferring cold tolerance from one metric. Acute stress responses (membrane stability, photosynthesis) and long-term freezing thresholds capture complementary aspects of cold tolerance. The derived physiological thresholds and the multi-indicator framework provide practical guidance for selecting and breeding native species for ecological restoration and cold-resilient agriculture in dry–hot valleys.

Experimental workflow of controlled low-temperature treatments and multi-indicator assessment of cold tolerance in five native species from the Lancang River dry–hot valley.Illustration explaining the physiological and biochemical mechanisms of cold tolerance in native plants from the Lancang River dry-hot valley. It details extreme cold conditions, plant species tolerance levels, and cellular stress responses. Modules include membrane stability, osmotic regulation, antioxidative capacity, photosynthetic function, and proline biosynthesis. A logistic model shows semi-lethal temperature (LT50), and PCA analyzes data across 24 indicators. Diagrams represent environmental temperatures, cellular structures, and statistical models highlighting plant resilience and stress responses.

Experimental workflow of controlled low-temperature treatments and multi-indicator assessment of cold tolerance in five native species from the Lancang River dry–hot valley.

## Linked entities

- **Species:** Sophora davidii (taxon 49839), Rumex hastatus (taxon 174650), Arthraxon lanceolatus (taxon 435775), Artemisia vestita (taxon 1811969)

## Full-text entities

- **Diseases:** membrane injury (MESH:D015433)
- **Chemicals:** sugar (MESH:D000073893), proline (MESH:D011392), chlorophyll (MESH:D002734)
- **Species:** Sophora davidii (species) [taxon 49839], Arthraxon lanceolatus (species) [taxon 435775], Artemisia vestita (species) [taxon 1811969], Rumex hastatus (species) [taxon 174650], Vitex negundo (Chinese chaste tree, species) [taxon 361442]
- **Mutations:** -5 C in A, -27 C in S

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12887594/full.md

## References

70 references — full list in the complete paper: https://tomesphere.com/paper/PMC12887594/full.md

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Source: https://tomesphere.com/paper/PMC12887594