兽类学报 ›› 2023, Vol. 43 ›› Issue (3): 293-303.DOI: 10.16829/j.slxb.150743
张璐1,2, 吴学琴1,2, 陈慧青1,2, 董昕1,2, 尚国珍1,3(), 吴雁4, 边疆晖1,3
收稿日期:
2022-10-25
接受日期:
2023-02-06
出版日期:
2023-05-31
发布日期:
2023-05-18
通讯作者:
尚国珍
作者简介:
张璐 (1998- ),女,硕士研究生,主要从事动物生理生态学研究;基金资助:
Lu ZHANG1,2, Xueqin WU1,2, Huiqing CHEN1,2, Xin DONG1,2, Guozhen SHANG1,3(), Yan WU4, Jianghui BIAN1,3
Received:
2022-10-25
Accepted:
2023-02-06
Online:
2023-05-31
Published:
2023-05-18
Contact:
Guozhen SHANG
摘要:
高原鼠兔 (Ochotona curzoniae) 不仅是青藏高原特有的小型植食性哺乳动物,也是高寒草地生态系统的关键物种,其种群数量随着过度放牧引起的草地退化而急剧增加。我们近期的研究发现,随着高寒草地退化,高原鼠兔的免疫力明显增强,推测可能与退化的高寒草地中丰富的高蛋白质食物资源有关。为了进一步验证上述推测,本研究在青海海北高寒草地生态系统国家野外科学观测研究站地区的重度退化草地中,选取6块70 m × 70 m的实验样地,通过添加蛋白质含量为20%和5%的兔颗粒饲料及不添加饲料处理,测定了高原鼠兔的粪便皮质醇 (Fecal cortisol metabolite, FCM) 含量、植物血凝素反应 (Phytohemagglutinin, PHA)、血清抗匙孔血蓝蛋白 (Keyhole limpet haemoeyanin, KLH) 的 IgG 水平含量和肠道寄生物感染状况,以验证丰富的高蛋白质食物资源可增加高原鼠兔的免疫力的假设。结果表明,添加20%蛋白质含量的饲料显著降低了高原鼠兔的FCM含量,显著增加了PHA反应和抗KLH的IgG含量,显著降低了球虫的感染率和绦虫的感染强度。该结果验证了上述假设,并认为在退化的高寒草地中,高蛋白质食物通过缓解高原鼠兔的应激―免疫―寄生物感染状况之间的恶性循环,从而促进高原鼠兔种群增长。
中图分类号:
张璐, 吴学琴, 陈慧青, 董昕, 尚国珍, 吴雁, 边疆晖. 食物蛋白质含量对高原鼠兔免疫功能的影响[J]. 兽类学报, 2023, 43(3): 293-303.
Lu ZHANG, Xueqin WU, Huiqing CHEN, Xin DONG, Guozhen SHANG, Yan WU, Jianghui BIAN. Effects of dietary protein contents on the immune function of plateau pika (Ochotona curzoniae)[J]. ACTA THERIOLOGICA SINICA, 2023, 43(3): 293-303.
图 1 添加不同蛋白质含量饲料处理下高原鼠兔粪便皮质醇含量. 不同小写字母表示同一诱捕期不同处理间差异显著 (P < 0.05),“*”表示不同诱捕期之间存在差异显著 (P < 0.05). 3月,对照组、5%低蛋白质组和20%高蛋白质组皮质醇含量样本数分别为11、36、48;7月,样本数分别为23、84、110;数据表示为平均值 ± 标准误
Fig. 1 Cortisol content of plateau pika under the treatment of adding feeds with different protein content. Different lowercase letters indicate significant differences (P < 0.05) between treatments in the consent trapping period, “*” indicates significant differences between trapping periods (P < 0.05), and in March, the sample sizes n = 11, 36, 48 for the control, 5% low protein groups, and 20% high protein groups, respectively; Correspondingly, n = 23, 84, 110 in July. Data were expressed as the mean ± SE
图 2 添加不同蛋白质含量饲料处理下高原鼠兔的PHA反应.不同小写字母表示同一诱捕期不同处理间差异显著 (P < 0.05),“ns”表示不同诱捕期之间差异不显著 (P > 0.05). 3月,对照组、5%低蛋白质组和20%高蛋白质组PHA反应样本数分别为14、38、56;7月,样本数分别为31、80、78;数据表示为平均值 ± 标准误
Fig. 2 PHA responses of plateau pikas under the treatment with different protein content feeds. Different lowercase letters indicate significant differences between treatments in the same trapping period (P < 0.05), and “ns”indicates non-significant differences between trapping periods (P > 0.05). In March, the sample sizes n = 14, 38, 56 for the control, 5% low protein groups, and 20% high protein groups, respectively; Correspondingly, n = 31, 80, 78 in July. Data were expressed as the mean ± SE
图 3 添加不同蛋白质含量饲料处理下高原鼠兔抗KLH 的IgG含量.不同大写字母表示不同处理间差异显著 (P < 0.05). 3月,对照组、5%低蛋白质组和20%高蛋白质组抗KLH 的IgG含量样本数分别为10、23、39;7月,样本数分别为13、52、59;数据表示为平均值 ± 标准误
Fig. 3 Anti-KLH IgG level of plateau pika under supplement different diets of protein content treatments. Different capital letters indicate significant differences between treatments (P < 0.05).In March, the sample sizes n = 10, 23, 39 for the control, 5% low protein groups, and 20% high protein groups, respectively; Correspondingly, n = 13, 52, 59 in July. Data were expressed as the mean ± SE
图4 高原鼠兔肠道球虫感染率 (A) 和感染强度 (D)、绦虫感染率 (B) 及感染强度 (E) 和线虫感染率 (C) 及感染强度 (F). 不同大写字母表示不同处理间差异显著 (P < 0.05),不同小写字母表示处理和时间的交互作用差异显著 (P < 0.05). 3月对照组、5%低蛋白质组和20%高蛋白质组寄生物感染强度样本数分别为8、36、63;5月样本数分别为13、59、78;7月样本数分别为26、98、124;9月样本数分别为25、83、102;数据表示为平均值 ± 标准误
Fig. 4 Prevalence (A) and intensity (D) of intestinal coccidia infection, prevalence (B) and intensity (E) of cestode infection, and prevalence (C) and intensity (F) of nematode infection in plateau pika. Different capital letters indicate significant differences between treatments (P < 0.05), and different lowercase letters indicate significant differences in the interaction of treatment and time (P < 0.05). In March, the sample sizes n = 8, 36, 63 for the control group, 5% low protein group, and 20% high protein group, respectively; Correspondingly, n = 13, 59, 78 in May, n = 26, 98, 124 in July, and n = 25, 83, 102 in September. Data were expressed as the mean ± SE
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