Group of Research in Ruminants (G2R), Department of Animal and Food Sciences, Universitat Autònoma de Barcelona, Bellaterra 08193, Spain.
Grupo de Investigación Biogénesis, Facultad de Ciencias Agrarias, Universidad de Antioquia, Carrera 75 # 65-87, Medellín, Colombia.
J Dairy Sci. 2019 Mar;102(3):2469-2480. doi: 10.3168/jds.2018-15219. Epub 2019 Jan 11.
Heat stress (HS) causes reductions in milk production, but it is unclear whether this effect is due to reduced number or functional capacity (or both) of mammary cells. Methionine supplementation improves milk protein, whereas Arg is taken up in excess by mammary cells to produce energy and nonessential AA that can be incorporated into milk protein. To evaluate molecular mechanisms by which mammary functional capacity is affected by HS and Met or Arg, mammary alveolar (MAC-T) cells were incubated at thermal-neutral (37°C) or HS (42°C) temperatures. Treatments were optimal AA profiles (control; Lys:Met = 2.9:1.0; Lys:Arg = 2.1:1.0), control plus Met (Lys:Met = 2.5:1.0), or control plus Arg (Lys:Arg = 1.0:1.0). After incubation for 6 h, cells were harvested and RNA and protein were extracted for quantitative real-time PCR and Western blotting. Protein abundance of mechanistic target of rapamycin (MTOR), eukaryotic initiation factor 2a, serine-threonine protein kinase (AKT), 4E binding protein 1 (EIF4EBP1), and phosphorylated EIF4EBP1 was lower during HS. The lower phosphorylated EIF4EBP1 with HS would diminish translation initiation and reduce protein synthesis. Both Met and Arg had no effect on MTOR proteins, but the phosphorylated EIF4EBP1 decreased by AA, especially Arg. Additionally, Met but not Arg decreased the abundance of phosphorylated eukaryotic elongation factor 2, which could be positive for protein synthesis. Although HS upregulated the heat shock protein HSPA1A, the apoptotic gene BAX, and the translation inhibitor EIF4EBP1, the mRNA abundance of PPARG, FASN, ACACA (lipogenesis), and BCL2L1 (antiapoptotic) decreased. Greater supply of Met or Arg reversed most of the effects of HS occurring at the mRNA level and upregulated the abundance of HSPA1A. In addition, compared with the control, supply of Met or Arg upregulated genes related to transcription and translation (MAPK1, MTOR, SREBF1, RPS6KB1, JAK2), insulin signaling (AKT2, IRS1), AA transport (SLC1A5, SLC7A1), and cell proliferation (MKI67). Upregulation of microRNA related to cell growth arrest and apoptosis (miR-34a, miR-92a, miR-99, and miR-184) and oxidative stress (miR-141 and miR-200a) coupled with downregulation of fat synthesis-related microRNA (miR-27ab and miR-221) were detected with HS. Results suggest that HS has a direct negative effect on synthesis of protein and fat, mediated in part by coordinated changes in mRNA, microRNA, and protein abundance of key networks. The positive responses with Met and Arg raise the possibility that supplementation with these AA during HS might have a positive effect on mammary metabolism.
热应激(HS)会导致产奶量减少,但尚不清楚这种影响是由于乳腺细胞数量减少还是功能能力(或两者兼而有之)降低所致。蛋氨酸补充可以改善乳蛋白,而精氨酸被乳腺细胞过量摄取以产生能量和非必需氨基酸(AA),这些 AA 可以掺入乳蛋白中。为了评估 HS 和 Met 或 Arg 对乳腺功能能力的分子机制,将乳腺腺泡(MAC-T)细胞在热中性(37°C)或 HS(42°C)温度下孵育。处理为最佳 AA 谱(对照;Lys:Met=2.9:1.0;Lys:Arg=2.1:1.0)、对照加 Met(Lys:Met=2.5:1.0)或对照加 Arg(Lys:Arg=1.0:1.0)。孵育 6 小时后,收获细胞并提取 RNA 和蛋白质,用于实时定量 PCR 和 Western blot 分析。HS 时,雷帕霉素(mTOR)、真核起始因子 2a、丝氨酸-苏氨酸蛋白激酶(AKT)、4E 结合蛋白 1(EIF4EBP1)和磷酸化 EIF4EBP1 的蛋白丰度降低。HS 时磷酸化 EIF4EBP1 减少会减少翻译起始并降低蛋白质合成。Met 和 Arg 对 mTOR 蛋白均无影响,但 AA 特别是 Arg 降低了磷酸化 EIF4EBP1。此外,Met 但不是 Arg 降低了磷酸化真核延伸因子 2 的丰度,这可能对蛋白质合成有利。尽管 HS 上调了热休克蛋白 HSPA1A、凋亡基因 BAX 和翻译抑制剂 EIF4EBP1,但 PPARG、FASN、ACACA(脂肪生成)和 BCL2L1(抗凋亡)的 mRNA 丰度降低。Met 或 Arg 的大量供应逆转了 HS 在 mRNA 水平上发生的大多数影响,并上调了 HSPA1A 的丰度。此外,与对照相比,Met 或 Arg 的供应上调了与转录和翻译相关的基因(MAPK1、MTOR、SREBF1、RPS6KB1、JAK2)、胰岛素信号(AKT2、IRS1)、AA 转运(SLC1A5、SLC7A1)和细胞增殖(MKI67)。HS 时检测到与细胞生长停滞和凋亡相关的 microRNA(miR-34a、miR-92a、miR-99 和 miR-184)和氧化应激(miR-141 和 miR-200a)上调,以及与脂肪合成相关的 microRNA(miR-27ab 和 miR-221)下调。结果表明,HS 对蛋白质和脂肪的合成具有直接的负作用,部分是通过关键网络的 mRNA、microRNA 和蛋白质丰度的协调变化介导的。Met 和 Arg 的积极反应表明,在 HS 期间补充这些 AA 可能对乳腺代谢产生积极影响。
