Transgenerational skin adaptations to late-gestation heat stress in great-granddaughters

IF 2.2

JDS communications Pub Date : 2025-07-16 DOI:10.3168/jdsc.2025-0786

B.D. Davidson, K. Hardy, J. Laporta

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Abstract

Homeostasis and thermoregulation depend on the interplay of the hair and skin. Maternal heat stress in late gestation triggers postnatal hair and skin adaptations in daughters and granddaughters. Herein, we investigated the transgenerational effects of late-gestation heat stress on the hair and skin of the great-granddaughters. Pregnant dams (F₀) were heat stressed (shade) or cooled (shade, fans, water soakers) during the last ~56 d of gestation in a subtropical summer. The first generation of heifers (F₁) that experienced in utero heat stress (HT_F1) or cooling (CL_F1) were managed as a cohort until they gave birth to the second generation of heifers (F₂) that experienced heat stress (HT_F2) or cooling (CL_F2) as a germ cell within the F₁ fetal ovaries. All F₂ heifers were managed as a cohort and gave birth to the third generation of heifers (F₃; great-granddaughters) that were unexposed to the F₀ treatments (HT_F3 and CL_F3). At 70 d of age, a hair sample and skin biopsy were collected from the neck on a subset of F₃ heifers (n = 6/group). Hair length and diameter; skin epidermis thickness and area; dermis thickness; sweat gland (SWTG) number, area, and depth; and sebaceous gland (SEBG) number, area, and depth were evaluated using hematoxylin and eosin staining and analyzed in ImageJ. Data were analyzed using PROC MIXED in SAS. No differences were captured in hair length or diameter, epidermis thickness or area, depth of the shallowest SWTG, depth of the SEBG, dermis thickness, and the number or size of SWTG. The HT_F3 had fewer (13.3 vs. 17.8 ± 1.1 glands) and smaller SEBG (61,641 vs. 89,963 ± 6,768 µm²), relative to CL_F3. Although SWTG number or size did not differ, distance from the skin surface to the deepest SWTG tended to be shorter in the HT_F3 (1.1 vs. 1.3 ± 0.04 mm). Late-gestation heat stress alters SEBG size and number and SWTG localization of F₃ heifers, suggesting a transgenerational programming of postnatal thermal adaptivity.

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曾孙女对妊娠后期热应激的跨代皮肤适应

体内平衡和体温调节依赖于头发和皮肤的相互作用。妊娠后期母亲的热应激会触发女儿和孙女出生后的头发和皮肤适应。在此，我们研究了妊娠后期热应激对曾孙女头发和皮肤的跨代影响。在亚热带夏季，孕坝（F0）在妊娠最后~56 d进行热应激（遮荫）或冷却（遮荫，风扇，浸水）。经历过子宫热应激（HTF1）或冷却（CLF1）的第一代小母牛（F1）作为一个队列进行管理，直到它们生下第二代经历过热应激（HTF2）或冷却（CLF2）的小母牛（F2）作为生殖细胞在F1胚胎卵巢内。所有F2小母牛作为一个队列进行管理，并生下未暴露于F0处理（HTF3和CLF3）的第三代小母牛（F3；曾孙女）。在70日龄时，从F3小母牛的颈部采集毛发样本和皮肤活检（n = 6/组）。头发长度和直径；皮肤表皮厚度和面积；真皮厚度;汗腺（SWTG）数量、面积和深度；并用苏木精和伊红染色评估皮脂腺（SEBG）的数量、面积和深度，并在ImageJ中进行分析。采用SAS软件中的PROC mix对数据进行分析。毛发长度或直径、表皮厚度或面积、最浅SWTG深度、SEBG深度、真皮层厚度、SWTG数量或大小均无差异。与CLF3相比，HTF3有更少的腺体（13.3比17.8±1.1）和更小的SEBG（61,641比89,963±6,768µm2）。虽然SWTG数量或大小没有差异，但HTF3中皮肤表面到最深SWTG的距离往往更短（1.1 vs. 1.3±0.04 mm）。妊娠后期热应激改变了F3小母牛SEBG的大小、数量和SWTG的定位，提示了出生后热适应性的跨代编程。

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来源期刊

JDS communications Animal Science and Zoology

CiteScore

2.00

自引率

0.00%

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