Research Article

Cold Stress Modulates the Phenotype of Lymphocyte Subsets and the Function of Blood Phagocytes in Goats

Mohammed Ali Al-Sukruwah, Mohammed Ali Al Hejji, Baraa Falemban, Jamal Hussen*

Department of Microbiology, College of Veterinary Medicine, King Faisal University, Al-Ahsa, Saudi Arabia.

Received | February 07, 2025; Accepted | March 24, 2025; Published | April 19, 2025

*Correspondence | Jamal Hussen, Department of Microbiology, College of Veterinary Medicine, King Faisal University, Al-Ahsa, Saudi Arabia; Email: [email protected]

Citation | Al-Sukruwah MA, Al Hejji MA, Falemban B, Hussen J (2025). Cold stress modulates the phenotype of lymphocyte subsets and the function of blood phagocytes in goats. Adv. Anim. Vet. Sci. 13(5): 1104-1112.

DOI | https://dx.doi.org/10.17582/journal.aavs/2025/13.5.1104.1112

ISSN (Online) | 2307-8316; ISSN (Print) | 2309-3331

Copyright: 2025 by the authors. Licensee ResearchersLinks Ltd, England, UK.

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

INTRODUCTION

The impact of thermal stress on the immune system has been extensively investigated in several veterinary species (Alhussien et al., 2024; Morgado et al., 2023). Most studies, however, focused on the adaptation of the immune system to heat stress conditions (Hoter et al., 2019; Worku et al., 2023). Although climate change-induced colder winter is currently observed in several desert areas, only few studies investigated the impact of cold stress on the immune system of livestock animals in these area (Becker et al., 2019; Kang et al., 2016; Hu et al., 2021; Xu et al., 2017; Kim et al., 2023; Vialard and Olivier, 2020; Hu et al., 2016; Hangalapura et al., 2006). In pigs, cold stress was associated with increased basal levels of the pro-inflammatory cytokines IL-1β, and IL-6 with enhanced upregulation of tissue cytokines in response to LPS stimulation (Frank et al., 2003). Studies in rodents showed that housing at sub-optimal temperatures is associated with reduced energy availability for driving the immune responses resulting in significant changes in the functionality of the immune system (Vialard and Olivier, 2020). In rats, short-term cold stress resulted in decreased plasma levels of the T cell cytokines IFN-γ, IL-2, IL-4, and the percentage of regulatory CD4+CD25+Foxp3+ T cells (Hu et al., 2016).

CD4+ helper T cells and CD8+ cytotoxic T cells are two lymphocyte subsets with key roles in the adaptive immune response to intracellular and extracellular pathogens, respectively (Ron et al., 2023). On the other hand, neutrophils and monocytes are innate immune cells of the first line of defense with the capacity to phagocytose and kill pathogens (Soehnlein and Lindbom, 2010).

Limited data are available on the impact of low ambient temperatures on the immune system of goat kids. The current study aimed, therefore, to investigate the impact of ambient temperature drop on some phenotypic and functional parameters related to innate and adaptive immune response in goat kids.

MATERIALS AND METHODS

Study Design

The study was conducted between October and December 2024 in the eastern province of Saudi Arabia. For this arid region (Al-Ahsa region; N 25°17′8.0844″, E 49°29′11.3316″), the climate is characterized by a long hot and dry summer from April to November (day temperatures range between 40°C and 50°C) and a short moderate winter from December (day temperatures range between 15°C and 29°C). Environmental temperatures (Table 1) were measured using a digital thermometer (ThermoPro TP50 Digital Hygrometer) with the measurement range from -40 to + 80ºC. Blood samples were collected at 07: 00 am on the following dates: 01.10.2024, 07.10.2024, 14.10.2024, 28.10.2024, 04.11.2024, 20.11.2024, and 03.12.2024.

 

Table 1: Time-related changes in ambient temperature (ºC) and humidity level.

Date	Temp. Max.	Temp.min.	Temp. Average	Humidity level
01.10.2024	41.3	33.6	37.5	60.8
07.10.2024	40.2	31.6	35.9	61.2
14.10.2024	39.3	28.5	33.9	68.2
28.10.2024	37.7	25.3	31.5	42.7
04.11.2024	35.2	24.8	30.0	59.3
20.11.2024	33.6	14.6	24.1	53.5
03.12.2024	17.3	9.4	13.4	50.8

 

Animals and Sampling

Blood samples were collected from five goat kids aged between 4 and 6 months including two males and 3 females of the Jabali goat breed. The goats were kept on the farm of the Scientific Research Station at King Faisal University in Al-Ahsa region (Saudi Arabia). Blood samples (5 mL) were collected from the jugular vein into vacutainer heparin tubes (Guangzhou Improve Medical Instruments Co., Ltd; Guangzhou, China) and transported to the laboratory for further processing.

Cell Separation

Separation of white blood cells (WBC) by hypotonic lysis of red blood cells was performed according to a previously published protocol for camel leukocytes (Hussen, 2021). For this, 6 mL of distilled water was added to 2 mL blood for 20 seconds in a 15 mL sterile falcon tube followed by the addition of 6 mL 2x PBS to restore tonicity. After centrifugation at 1000 xg for 15 min at 4ºC, the lysis step was repeated twice (two rounds of centrifugation at 500 and 250 xg for 10 min each round) for complete removal of erythrocytes. Finally, the pellet was resuspended in cold PBS (2 x 106 cell / mL).

Flow Cytometric Analysis of Leukocyte Subsets

Staining of separated cells with monoclonal antibodies (mAbs) was performed as previously described for bovine leukocytes (Hussen et al., 2013). Briefly, isolated WBCs (1 x 105 cell/well) were incubated in a 96-well plate for 15 min at 4°C with monoclonal antibodies to the lymphocyte markers CD4, CD8, CD335 (NKp46), BAQ44A (B cell), WC1 (Ƴδ T cell), and CD44. After washing in PBS-containing bovine serum albumin (BSA; 0.5%), the cells were subsequently incubated with secondary antibodies to mouse immunoglobulin isotypes (Table 2) for 15 min at 4°C. Labeled cells were finally washed two times and analyzed by flow cytometry (Becton Dickinson Accuri C6 flow cytometer; Becton Dickinson Biosciences, San Jose, California, USA).

 

Table 2: Monoclonal antibodies.

Antigen	Antibody clone	Labeling	Source	Isotype
CD4	GC50A1	-	Kingfisher	Mouse IgM
CD8	CC63	-	Biorad	Mouse IgG2a
WC1	CC15	FITC	Biorad	Mouse IgG2a
CD335	EC1.1	-	Kingfisher	Mouse IgG1
CD44	BAT31A	-	Kingfisher	Mouse IgG1
Mouse IgM	poly	APC	Thermofisher	Goat IgG
Mouse IgG1	poly	FITC	Thermofisher	Goat IgG
Mouse IgG2a	poly	PE	Thermofisher	Goat IgG

 

Phagocytosis

The phagocytosis activity of neutrophils and monocytes was analysed according to a protocol previously described for bovine phagocytes (Hussen et al., 2016). Briefly, separated WBC (1 x 105 cell/well) were incubated in vitro in a 96-well plate with 50 µL of FITC-conjugated inactivated Staphylococcus aureus (S. aureus) bacteria (2 × 108 cells/mL in RPMI medium; Institute of Immunology, Hannover University of Veterinary Medicine, Germany). After incubation for 45 min at 37°C, flow cytometric analysis of phagocytosis was performed on the Accuri C6 flow cytometer.

 

Statistical Analyses

Statistical analysis was performed using Prism software (GraphPad). The comparison between means at different timepoints of the study was performed using the repeated measure One way analysis of variance (ANOVA) test in combination with Bonferroni test for normally distributed data and the Friedman test with Kruskal-Wallis test for not normally distributed data. P values less than 0.05 indicate significant effects. The Common Language Effect Size (CLES) and the confidence intervals were calculated based on Cohen’s d using an online calculation tool (https://www.psychometrica.de/effect_size.html) and presented it alongside the p-values.

RESULTS

Relative Composition of Blood Lymphocytes

The relative frequency of lymphocyte subsets was analyzed using flow cytometry (Figure 1A, 1B, 1C,1D, 1E, 1F, 1G and 1H). The fraction of CD4+ T cells showed a gradual decrease with decreased ambient temperatures. The percentage of CD4+ T cells reached the lowest value on time point 7. The difference was, however, only significant (p < 0.05) in comparison to values of time points 2 (CLES = 0.96; CI = 0.82 - 4.1) and 3 (CLES = 0.97; CI = 0.90 - 4.25) (Figure 2). In contrast to this, the percentage of CD8+ T cells was significantly (p < 0.05) higher on time point 7 than at time point 1 (CLES = 0.97; CI = -4.35 - -0.95), 3 (CLES = 0.893; CI = -3.2 - -0.29), and 6 (CLES = 0.725; CI = -0.45 - 2.1). This change in the percentages of CD4+ and CD8+ T cells resulted in significantly lower CD4 to CD8 ratio (CD4/CD8) on time point 7 than time points 1 (CLES = 1; CI = 2.5 - 7.6) and 3 (CLES = 0.99; CI = 1.92 – 6.3) (p < 0.05). The lowest percentage of B cells was found on time point 7, which was significantly lower than time points 1 (CLES = 0.66; CI = -1.86 – 0.67) and 4 (CLES = 0.65; CI = -1.80 – 0.73). No significant changes were observed in the percentages of WC1+ T cells or natural killer (NK) cells at any time point (p > 0.05) (Figure 2). No data was available for WC1+ T cells on time point 3 due to low cell staining quality. Descriptive statistics of the analyzed parameters are presented in Table 3. In addition, the raw data for each time point and each animal and each analyzed parameter is shown in supplementary Table S1.

Count of Blood Lymphocyte Subsets in Goat Blood

The absolute number of total lymphocytes was calculated by counting leukocytes under microscope after the addition of Turk solution, to lyse the red blood cells, followed by multiplication of lymphocyte percentage with total white blood cell count (Table 3). The total lymphocyte count did not show any significant changes at any time point (p > 0.05) (Figure 3). Only CD4+ T cells were significantly reduced on point 7 compared to time point 5 (CLES = 0.98; CI = 1.3 - 5.0; p < 0.05) (Figure 3). Although some tendential differences were observed over the study period, the numbers of CD8+ T cells, B cells, Ƴδ T cells (WC1), or NK cells did not show significant changes on any time point (p > 0.05) (Figure 3).

 

Changes in the Expression Level of the Activation Marker CD44 on Goat Lymphocytes

The expression density of CD44 was analysed by flow cytometry (Figure 4A, 4B, 4C and 4D). The abundance of the activation marker CD44 showed significant time-related changes only for CD8+ T cells (Table 3). The mean fluorescence intensity (MFI) of CD44 on CD8+ T cells was lowest on time point 7. The difference was significant between time point 7 (effect sizes f and d = 0.85 and 2.55; calculated based on group means from ANOVA) and all other time points (p < 0.05) (Figure 4E and 4F).

 

Impact of Ambient Temperature Change on Phagocytic Activity of Goat Neutrophils and Monocytes

The phagocytosis function of neutrophils and monocytes were analyzed by using flow cytometry after incubating the cells with FITC-labeled and inactivated staphylococcus aureus bacteria (Figure 5A). For both neutrophils and monocytes, the percentage of phagocytosis-positive cells was significantly lower on time point 7 (effect sizes f and d = 1.9 and 5.9; calculated based on group means from ANOVA) than on all other time points (p < 0.05) (Figure 5B).

 

DISCUSSION

The evaluation of changes in the distribution of lymphocyte subsets in blood is one of the most popular methodologies for evaluating the status of the immune system. The present study investigated the impact of changes in ambient temperature on the distribution of lymphocyte cell subsets in goat blood and the phagocytic function of blood neutrophils and monocytes.

 

Although the total number of lymphocytes did not show significant changes during the study period, lymphocyte composition was significantly affected by the change in ambient temperature. The drop in ambient temperature was associated with a decrease in the percentage and absolute count of CD4+ T cells (T helper cells) with increased frequency of CD8+ T cells (cytotoxic T cells). Due to their essential role in all immune cell activities including the activation of B cells for antibody production and cytotoxic T cells for killing virus-infected cells, reduced numbers of T helper cells usually reflect compromised adaptive immune responses

 

Table 3: Lymphocyte populations, marker expression, and phagocytosis activity.

	Time 1	Time 2	Time 3	Time 4	Time 5	Time 6	Time 7
	Mean± SEM	Mean± SEM	Mean± SEM	Mean± SEM	Mean± SEM	Mean± SEM	Mean±SEM
Total lymphocyte count1	3146 ± 397	2747 ± 82	3030 ± 445	3123 ± 380	3651 ± 435	-	3324 ± 525
CD4+ T cells %2	21 ± 4 ab	24 ± 4 a	22 ± 4 a	19 ± 3 ab	22 ± 2 ab	18 ± 2 ab	14 ± 1 b
CD8+ T cells %2	12 ± 2 a	18 ± 4 ab	15 ± 3 a	16 ± 3 ab	16 ± 3 ab	14 ± 3 a	21 ± 4 b
B cells %2	20 ± 5 a	16 ± 4 ab	18 ± 4 ab	19 ± 4 a	18 ± 4 ab	16 ± 3 ab	14 ± 4 b
Ƴδ T cells %2	18 ± 3 a	16 ± 3 a	-	17 ± 3 a	23 ± 4 a	24 ± 3 a	22 ± 4 a
NK cells %2	3 ± 0.9 a	4 ± 0.7 a	2 ± 0.4 a	2 ± 0.4 a	5 ± 2 a	4 ± 1 a	3 ± 0.5 a
CD4/CD8 ratio	2 ± 0.4 a	1 ± 0.4 ab	2 ± 0.2 a	1 ± 0.1 ab	1 ± 0.1 ab	1 ± 0.2 ab	0.7 ± 0.06 b
CD4+ T cells count1	625 ± 91 ab	632 ± 108 ab	645 ± 105 ab	558 ± 29 ab	802 ± 147 a	-	455 ± 53 b
CD8+ T cells count1	393 ± 71 a	495 ± 114 a	465 ± 105 a	481 ± 50 a	622 ± 155 a	-	643 ± 70 a
B cells count1	685 ± 235 a	439 ± 107 a	574 ± 162 a	615 ± 161 a	675 ± 190 a	-	554 ± 211 a
Ƴδ T cells count1	582 ± 133 a	433 ± 83 a	-	551 ± 152 a	799 ± 141 a	-	699 ± 119 a
NK cells count1	122 ± 52 a	97 ± 19 a	61 ± 13 a	72 ± 12 a	173 ± 53 a	-	95 ± 29 a
CD44 MFI on CD4 T cells	-	36566± 2449a	32024± 1818a	30207± 1881a	30409± 1509a	32853± 1809a	31535± 1145a
CD44 MFI on CD8 T cells	-	16946± 2191a	16152± 1176a	13214± 929 a	16693± 667 a	15926± 1186 a	10801± 313 b
Phagocytic neutrophils (%)3	-	64 ± 1 a	62 ± 2 a	65 ± 1 a	69 ± 0.9 a	70 ± 2 a	48 ± 2 b
Phagocytic monocytes (%)4	-	54 ± 1 a	50 ± 2 a	53 ± 1 a	57 ± 1 a	55 ± 1 a	39 ± 1 b

 

1: cell/µl blood; 2:percent of total lymphocytes; MFI: mean fluorescence intensity; 3: percent of total neutrophils; 4: percent of total monocytes. Different small letters indicate significant differences between the means (p < 0.05).

 

(Luckheeram et al., 2012). This indicates that cold stress negatively affects T helper-cell-mediated immunity in goats. The cold-stress-induced decrease in the CD4/CD8 ratio, which represents a marker of immune competence (Ron et al., 2023), is in support of this. The frequency of immune cells in blood is regulated by the balance between their production in the bone marrow and cell migration and mobilization to tissues. For the identification of the mechanisms responsible for the observed change in the frequency of lymphocyte subsets one may discuss the role of altered thymic output (Thapa and Farber, 2019), changes in peripheral survival of lymphocytes, or changed migration patterns of these cells under cold stress. As the exposure of broiler chicken to cold stress was associated with improved development and function of the thymic gland reflected in an altered expression of several TLRs and cytokines (Fu et al., 2022), a role of altered thymic output in the observed changes in CD4 and CD8 frequencies seems unlikely. Although short-term cold exposure in humans was associated with decreased numbers of CD4+ cells without changing the abundance of CD8+ cells (Hennig et al., 1993), the study did not identify the exact mechanism behind this effect. Furthermore, cold-stress induced cell apoptosis has been reported in the published literature (Kizaki et al., 2001; Cong et al., 2018). Identified mechanisms include the inhibition of the Nrf2-Keap1 signaling pathway and modulation of the AMPK/PI3K/AKT/mTOR pathways. However, it is still unknown whether exposure of goats to cold stress may differently impact cell apoptosis in T cell subsets leading to selective decrease in CD4+ T cells. As the mobilization of T cell subsets between their compartments in the bone marrow, blood, and lymphatic tissues is regulated by several cytokines and chemokines as well as the expression of homing receptors, gene expression analysis of distinct T cell chemokines, colony stimulating factors, and homing receptors would support a better understanding of the mechanisms behind the observed alterations in the distribution of T cell subsets. In addition, the analysis of lymphocyte functions such as proliferation and cytotoxicity would uncover the impact of cold stress on immune cell function in goats. Furthermore, cytokine production measurement or gene expression analysis of T helper type 1 and type 2 cytokines after in vitro stimulation may provide insights into T helper cell polarization in goats under cold stress.

In the present study, no temperature-induced changes were observed in the abundance of NK cells in goat blood. NK cells represent only a minor fraction of lymphocytes in blood. Therefore, the observed minimal changes in their frequency under cold stress could be due to small sample size. In addition, the reported enhancement of NK cell function in humans after exposure to cold temperatures suggests possible positive effect of cold stress on NK cell function (Brenner et al., 1999). Therefore, future studies with larger animal size are important to answer the question whether goat NK cells are affected by or might possess higher resistance to cold stress.

Caprine Ƴδ T cells can be divided into different subsets (Yirsaw and Baldwin, 2021; Yirsaw et al., 2021). Therefore, although the total number of or Ƴδ T cells was not affected by cold stress, the detailed enumeration of all subsets in goat blood may uncover possible changes in distinct Ƴδ T cell subsets.

The hyaluronan receptor CD44 is a glycoprotein with wide range cellular expression and involvement in several cellular activities, including cell adhesion, migration, and activation (Ponta et al., 2003; Guan et al., 2009). Although not proven through in-vitro analysis in this study, the observed decrease in CD44 expression on CD8+ T cells suggests reduced activation status of these cytotoxic cells under cold conditions. Given their role in the immune response to viruses (Brooks et al., 2021), these results suggest impaired immune response to viral infection in goats under cold stress. The identification of exact mechanisms through which cold stress impairs T cell functions and the involvement of CD44 in these effects represent interesting areas for future in vitro or in vivo studies. It is especially important to see whether cold stress directly modulates distinct pathways such as mTOR (Xu et al., 2023) leading to modulated expression of CD44 on CD8+ T cells or whether the effect is indirectly mediated by changed cytokines expression such as the proinflammatory cytokine IL-1beta (Foster et al., 1998).

Neutrophils and monocytes represent cells of the first defense barrier contributing to effective innate immunity against microbes through their ability to engulf and kill pathogens (Dale et al., 2008). In the present study, the reduced phagocytosis percentages of both phagocytic cells in goats after ambient temperature drop indicate reduced antimicrobial functionality of these innate immune cells. However, additional functional analysis on phagocytes by analyzing oxidative burst, bacterial killing, Netosis, and degranulation is required to confirm the observed cold stress-induced reduction in antimicrobial activity. Bacterial phagocytosis by neutrophils and monocytes is mediated by opsonin receptors, IgG receptors FcγRII and FcγRIII and the C3b receptors CR1 and CR3, and phagocytosis priming receptors. As the bacteria used for the phagocytosis assay in the present study was non-opsonized bacteria, the role of altered expression of FC and complement receptors in the observed changes in phagocytosis function can be excluded. It is most likely that cold stress affects the expression of other receptors involved in the direct priming of phagocytosis. Such receptors include scavenger receptors, TLRs, the complement receptors C3aR and C5aR, IL-8R, and TNFR (van Kessel et al., 2014). Additionally, it is also possible that cold stress-induced changes in the cytoskeletal dynamics in neutrophils and monocytes are responsible for the observed decrease in their phagocytosis function (Mylvaganam et al., 2021). Furthermore, the impact of energy availability and nutrient status on the immune system has been intensively investigated in the literature (Iddir et al., 2020; Pikula et al., 2020). Whether the observed decrease in phagocytic activity could be linked to changes in metabolic pathways or energy availability in immune cells under cold stress, is still to be investigated.

The results of the current study were generated based on samples collected from only five goat kids, which is a limitation of the present study. Therefore, future studies should consider increasing the number of animals and including animals of different age groups and breeds in order to provide conclusions that are more robust.

CONCLUSIONS AND RECOMMENDATIONS

The present study evaluated the impact of cold stress on the immunophenotype of blood lymphocytes and the antimicrobial function of neutrophils and monocytes. The results indicate a compromising effect of ambient temperature drop on adaptive and innate immune cells in goats. Whether these effects are related to the young age of the goat kids used in this study and whether older goats may show higher resistance to cold stress is still to be investigated in future studies. Additionally, as the current study only focused on the short-time effects of temperature change on selected parameters of goat immune cells, it would be interesting to see how chronic cold stress for a longer period or how the exposure to extremely colder temperatures would modulate the goat immune system. Especially longitudinal studies would help in answering the question whether chronic and or extreme cold stress will more profoundly impact the goat immune system or whether the animals will adapt to the chronic cold stress after a specify time of exposure.

ACKNOWLEDGEMENTS

The authors thank the Scientific Research Station at King Faisal University for providing the experimental animals.

NOVELTY STATEMENTS

The present study employed membrane immunofluorescence and flow cytometry to investigate the impact of cold stress on the immune system of goat kids. Specifically, the study performed a time course analysis of cold-stress-induced changes in the distribution of lymphocyte cell subsets in goat blood and the phagocytic function of blood neutrophils and monocytes.

AUTHOR’S CONTRIBUTIONS

Jamal Hussen designed the study, Mohammed Ali Al Hejji, Mohammed Ali Al-Sukruwah, and Baraa Falemban collected the samples. Jamal Hussen did the flow cytometry and wrote the first draft of the manuscript. All authors revised and approved the manuscript.

Funding

This work was supported by the Deanship of Scientific Research, Vice Presidency for Graduate Studies and Scientific Research, King Faisal University, Saudi Arabia [KFU250139].

Data Availability

The datasets generated during the current study are available from the corresponding author on reasonable request

Ethics Approval

This study was performed in line with the principles of the Declaration of Helsinki. Approval was granted by the Ethics Committee of King Faisal University, Saudi Arabia (KFU-REC-2024-JUN-ETHICS1843). All measures were taken to minimize stress and discomfort to the animals during blood sampling.

Supplementary Material

There is supplementary material associated with this article. Access the material online at; https://dx.doi.org/10.17582/journal.aavs/2025/13.5.1104.1112

Conflict of Interest

The authors have no relevant financial or non-financial interests to disclose.

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