# Heat stress in dairy buffalo: biometeorological, molecular, and adaptive strategies for climate change resilience in subtropical regions

**Authors:** Eman M. Ismail, Aly M. Aly, Heba S. Farag, Shaimaa Kamel, Karima M. Fahim

PMC · DOI: 10.1007/s11259-025-11009-y · 2026-01-16

## TL;DR

This study explores how heat stress affects dairy buffalo in Egypt and shows that adaptive strategies can improve milk yield and reduce stress.

## Contribution

The study introduces a biometeorological approach and presents the first transcriptional analysis of stress-responsive genes in buffalo under heat stress.

## Key findings

- Adaptive interventions reduced heat stress exposure and increased milk yield by 53%.
- Heat stress caused higher expression of AMPK, HRH1, and mTOR genes, indicating metabolic strain.
- Each unit increase in THI above 69 reduced milk yield by 0.17–0.23 kg/day.

## Abstract

Buffalo milk production in Egypt has steadily declined since 2014, mainly due to climate-driven heat stress (HS) and rising temperature–humidity index (THI). This quasi-field study randomly evaluated twelve lactating buffalo during peak summer, introducing a biometeorological approach to define and predict HS impacts precisely. Heat stress in buffalo was classified according to THI ranges as follows: non-HS zone (NHSZ, 56.7–73.2), moderate HS zone (MHSZ, 73.2–75.4), severe HS zone (SHSZ, 75.4–80.3), and critical HS zone (CHSZ, ≥ 80.3). Two models were compared: Model I (natural, group A) and Model II (adaptive, group B), which received targeted environmental and management interventions. Continuous monitoring of THI alongside daily milk yield (DMY), physiological responses, oxidative stress biomarkers, and the expression of key energy homeostasis genes was assessed in both groups. Adaptive interventions effectively reduced THI exposure, shifted animals from critical HS to non-HS zones, improved physiological parameters, increased milk yield by 53%, lowered oxidative stress, and enhanced milk quality (p < 0.05). The study presents the first transcriptional analysis of stress-responsive energy-regulating genes in buffalo, revealing higher AMPK, HRH1, and mTOR expression in HS-Model I buffalo, which reflects the metabolic strain associated with unmanaged thermal stress. Regression analysis showed that for every one-unit increase in THI above 69, milk yield decreased by 0.17–0.23 kg/day. These findings underscore the value of integrated biostatistical modeling and targeted adaptation strategies for sustaining buffalo productivity under the pressures of subtropical climates. Adaptive housing, nutritional support, and management interventions effectively mitigate the impacts of HS. At the molecular level, evidence of oxidative stress and altered energy regulation highlights the physiological toll of thermal load, emphasizing the need for holistic approaches to protect productivity and herd resilience in heat-stressed regions.

The online version contains supplementary material available at 10.1007/s11259-025-11009-y.

## Linked entities

- **Genes:** PRKAA1 (protein kinase AMP-activated catalytic subunit alpha 1) [NCBI Gene 5562], HRH1 (histamine receptor H1) [NCBI Gene 3269], MTOR (mechanistic target of rapamycin kinase) [NCBI Gene 2475]

## Full-text entities

- **Genes:** HRH1 [NCBI Gene 102404937], mTOR [NCBI Gene 102407977], MTOR (mechanistic target of rapamycin kinase) [NCBI Gene 2475] {aka FRAP, FRAP1, FRAP2, RAFT1, RAPT1, SKS}, Beta-actin [NCBI Gene 102413719], Catalase [NCBI Gene 102409858], PRKAB1 (protein kinase AMP-activated non-catalytic subunit beta 1) [NCBI Gene 5564] {aka AMPK, HAMPKb}, HRH1 (histamine receptor H1) [NCBI Gene 3269] {aka H1-R, H1R, HH1R, hisH1}
- **Diseases:** impaired reproductive performance (MESH:D060737), HS (MESH:D018882), inflammatory (MESH:D007249), SCC (MESH:D013001)
- **Chemicals:** lysine (MESH:D008239), Mg (MESH:D008274), Mn (MESH:D008345), Ca (MESH:D002118), ROS (MESH:D017382), SYBR Green (MESH:C098022), GSH (MESH:D005978), lipid (MESH:D008055), ABT (MESH:C002502), amino acids (MESH:D000596), MDA (MESH:D008315), ABT 2x SYBR Green (-), hydrogen peroxide (MESH:D006861), K (MESH:D011188), Na (MESH:D012964), 5,5'-dithiobis-2-nitrobenzoic acid (MESH:D004228), vitamin C (MESH:D001205), nitric oxide (MESH:D009569), ethyl alcohol (MESH:D000431), water (MESH:D014867), thiobarbituric acid (MESH:C029684), lactose (MESH:D007785), agar (MESH:D000362), lipid peroxides (MESH:D008054), methionine (MESH:D008715), salt (MESH:D012492), P (MESH:D010758), oxygen (MESH:D010100), Zn (MESH:D015032)
- **Species:** Bos taurus (bovine, species) [taxon 9913], Homo sapiens (human, species) [taxon 9606], Bifidobacterium (genus) [taxon 1678], Streptococcus (genus) [taxon 1301], Enterococcus (genus) [taxon 1350], Bubalus bubalis (domestic water buffalo, species) [taxon 89462], Lactobacillus (genus) [taxon 1578], Glycine max (soybean, species) [taxon 3847]

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12811276/full.md

---
Source: https://tomesphere.com/paper/PMC12811276