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研究生: 林維星
Lin, Wei-Hsing
論文名稱: 探討綑綁處理對於青少年期與成年期條件化恐懼與焦慮行為之影響
Comparison of juvenile and adult immobilization treatment on the conditioned fear and anxiety-like behavior
指導教授: 呂國棟
Lu, Kwok-Tung
學位類別: 碩士
Master
系所名稱: 生命科學系
Department of Life Science
論文出版年: 2019
畢業學年度: 107
語文別: 英文
論文頁數: 115
中文關鍵詞: 青少年不良對待綑綁處理條件化恐懼開放空間測試舉臂式十字迷宮削減作用電生理的長期增益效應
英文關鍵詞: juvenile, maltreatment, immobilization, conditioned fear, open field testing, elevated plus maze, extinction effects, long-term potentiation
DOI URL: http://doi.org/10.6345/THE.NTNU.SLS.006.2019.D01
論文種類: 學術論文
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  • 在青少年或成年期遭受壓力(stress)或創傷經驗(traumatic experience),例如心理或生理的虐待(physiological or psychological abuse),均會造成長期的不良影響(long-term adverse impact),包括引發創傷後壓力症候群(post-traumatic stress disorder, PTSD),及提高罹患焦慮症(anxiety)之風險,但是目前對於探討青少年壓力或創傷長期影響的動物模式十分稀少。而在青少年期時,下視丘-腦垂體-腎上腺軸(hypothalamic-pituitary-adrenal axis, HPA axis)仍處於發育及調整期,因此遭受創傷時,會較成年期有更嚴重的不良影響。本研究之主要目的為探討青少年的壓力及創傷經驗,造成長期不良影響之機轉。
    實驗結果顯示,於小鼠青少年期(五週齡)給予每天兩小時連續兩天綑綁處理(immobilization treatment, IMO),會在隔週的條件化恐懼實驗中,造成恐懼記憶無法削減(extinction)的現象。而只進行單一次的IMO處理,則不會對削減作用有明顯影響,表示可能有累加效應(accumulation effect)的存在。之後在開放空間測試(open field test),IMO 組亦出現類焦慮行為(anxiety-like syndrome)增加的現象。另外在即時定量聚合酶連鎖反應(real-time polymerase chain reaction, qPCR)中,發現經兩次IMO處理的動物,其海馬迴(hippocampus)中Fkbp5的表現量顯著增加。爾後透過離體胞外電生理記錄法(in vitro extracellular recording)測試海馬迴的長期增益效應(long-term potentiation,LTP),結果顯示青少年經IMO處理兩次的動物,在其海馬迴的LTP出現增強的現象。此外,我們發現青少年IMO 處理組(五週齡,IMO_2 (J))與成年IMO處理組(十一週齡,IMO_2 (A))皆在十二週齡的條件化恐懼實驗中呈現無法削減恐懼記憶的異常反應,牠們也在高架十字迷宮(elevated plus-maze)中出現類焦慮的行為特徵。透過qPCR發現Fkbp5的表現量,只在IMO_2 (A) 的海馬迴與杏仁核(amygdala)中都明顯增加;另外在Bdnf 的表現量,只在IMO_2 (A) 組動物的杏仁核中明顯增加,而在IMO_2 (J)組皆沒有顯著增加,顯示青少年IMO處理對Fkbp5與Bdnf的表現量只有短期影響,效果不會持續到成年期。
    本實驗採用青少年或成年期綑綁方式,模擬創傷經驗對於不同時期條件化恐懼及類焦慮反應之影響,發現青少年的IMO 處理可能有累加效應(accumulation effect)與急性影響(acute effect),而本研究提供往後可供研究青少年期壓力或創傷經驗的動物模式。研究成果具有臨床應用之價值,將有助於未來新一代治療策略及藥物之開發。

    Previous studies have demonstrated that some adverse experiences in juveniles or adults, such as sexual molest and psychological or physiological abuse, would elicit long-term deleterious effects which might increase the susceptibility of exhibiting the post-traumatic disorder (PTSD) and anxiety disorder in adulthood. Up to now, however, the animal model for the study of these adverse experiences still appears to be rather limited on exploring the long-term effect on juveniles. To juvenile, the hypothalamic–pituitary–adrenal (HPA) axis is still under development and fine-tuning, making it vulnerable to the trauma experience and stress. The present study was aimed to study the possible long-term adverse effect of juvenile immobilization treatment and the underlined mechanism.
    In this study, we attempted to investigate the mechanism of early life immobilization treatment effects on the behaviors of the consolidation and extinction of conditioned fear. The juvenile mice (5 weeks old) were subjected to immobilization (IMO) treatment and then tested for conditioned fear and anxiety response at the age of 6 weeks (juvenile) and 12 weeks (adult) old. Several behavioral experiments, including conditioned fear, open field test (OFT) and elevated plus-maze (EPM) were applied to investigate the effect of juvenile IMO on the conditioned fear. Also, we also used real-time polymerase chain reaction (qPCR), to elucidate the molecular mechanism underlying the long-term effect of juvenile immobilization treatment. Brain tissues, including the amygdala and dorsal hippocampus, were collected and subjected to biochemical analysis.
    Our results showed that mice with two times of immobilization treatment (two hours per day, for two consecutive days, IMO_2) at the age of 5 weeks old (juvenile) displayed interference on the extinction of conditioned fear. And, such the impairment was not significant in the single IMO treated animals. These results indicated that an accumulation effect was observed for the juvenile immobilization treatment. Besides, an anxiety-like behavior phenotype was also found from the OFT of IMO treated animals. The results of the qPCR revealed a significant increase in the hippocampal Fkbp5 expression in the IMO_2 animals. Furthermore, high-frequency stimulation (HFS) could induce long-term potentiation (LTP) elevation in the IMO_2 animals, suggesting a long-term effect of IMO on the function of the hippocampus.
    Based on this study, both juvenile (5 weeks old, IMO_2(J)) and adult (11 weeks old, IMO_2(A)) with twice IMO treatment showed impairment on the extinction of conditioned fear on adulthood (12 weeks old), meaning that the impact of juvenile IMO treatment will be sustained into adulthood. According to qPCR, the expression of Fkbp5 was increased significantly in both hippocampus and amygdala of IMO_2 (A). Similarly, the expression of BDNF revealed the same trend in the amygdala of the IMO_2(A). Above results clearly indicated that the impact of juvenile IMO treatment in the expression of Fkbp5 and Bdnf is just an acute effect, and it could not be sustained into adulthood.
    In summary, the present study has adopted juvenile or adulthood IMO to simulate the traumatic experience and study its long-term impact on the conditioned fear response and anxiety-like response. Results showed that IMO treatment might reveal some accumulative and acute effects. We demonstrated the current animal model could be applied in studying the influences of juvenile stress and traumatic experience. Results of this study should as well have contributed to the development of novel therapeutic strategies and pharmacological interventions.

    Acknowledgments 1 Table of contents 2 Abstract 5 Abstract in Chinese 5 Abstract in English 7 Abbreviations 10 Introduction 12 Earlier maltreatment reveals a long-term adverse impact on adulthood. 12 HPA axis functional abnormalities and psychological illness induced by stress. 13 Stress-related gene FK506-binding protein 51 (FKBP5) 16 Brain-derived neurotrophic factor (BDNF) and mental illness. 19 The importance of studying mechanisms of the long-term adverse effect of juvenile maltreatment using animal models 20 Research aim and significance 24 Experimental Design & Animal Grouping 25 Materials and Methods 26 Animals 26 Immobilization stress treatment 26 Acoustic fear conditioning model 27 The open field test, OFT 29 The elevated plus-maze, EPM 30 Real-time PCR, qPCR: 31 Brain slice preparation 31 Extracellular recording 33 Results 34 Stage 1. Juvenile immobilization treatment 34 Experiment 1-1: The effect of immobilization treatment on the conditioned fear in the juvenile. 34 Experiment 1-2: Determine the juvenile IMO induced anxiety-like behavior by using an open field test and elevated plus maze. 36 Experiment 1-3: Examine the expression of anxiety related genes of the juvenile IMO animals by using real-time polymerase chain reaction. 38 Experiment 1-4: Determine the hippocampal function of the IMO animals by using brain slice extracellular recording. 41 Stage 2. Adult immobilization treatment 43 Experiment 2-1 The effect of immobilization treatment on the conditioned fear in the adult. 43 Experiment 2-2 Analyze the IMO induced anxiety-like behavior in the adult by using an open field test and elevated plus maze. 45 Experiment 2-3 Examine the expression of anxiety related genes of the IMO animals in the adult by using real-time polymerase chain reaction. 47 Discussion 50 Research aim and a summary of the results 50 The significance of studying the long-term impact of the juvenile adverse experience 52 Optimal conditions for preparing the juvenile IMO animals 53 Juvenile IMO treatment induced behavioral abnormalities 54 The possible genes involved in the acute or long-term effect of juvenile IMO treatment 56 The change of hippocampal HFS-LTP in the juvenile IMO treated animals. 60 The inadequacies of the present study 63 References 67 Figure and appendix 87 Figure 1. The summary of the hypothalamic-pituitary-adrenal axis 88 Figure 2 This diagram illustrates the FKBP5 related stress reactions induced by glucocorticoids in cells. 90 Figure 3. Immobilization stress treatment for mice. 91 Figure 4. Arduino controller for sound and foot shock in the top and horizontal view. 92 Figure 6. The behavioral instrument of elevated plus-maze 94 Figure 7. The timeline and summary of the experimental procedures in juvenile and adult models. 96 Figure 8: Juvenile immobilization treatment and its effect on conditioned fear. 98 Figure 9. Juvenile immobilization treatment induced anxiety-like behavior evaluated by open field test and elevated plus maze. 100 Figure 10. Real-time polymerase chain reaction quantification of some reported fear-associated gene expression in juvenile. 103 Figure 11. Electrophysiology in two-time immobilization in juvenile 105 Figure 12. The long-term and short-term effects of IMO on the conditioned fear. 107 Figure 13. Adult immobilization treatment induced anxiety-like behavior evaluated by open field test and elevated plus maze. 109 Figure 14 Real-time polymerase chain reaction quantification of some reported fear-associated gene expression in the adult. 112 Appendix 1. Arduino code for Behavioral apparatus controlled 113 Appendix 2. The primer sequences in real-time PCR 115

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