The fight and flight responses of crickets depleted of biogenic amines.

Journal of neurobiology Pub Date : 2000-05-01
P A Stevenson, H A Hofmann, K Schoch, K Schildberger
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Abstract

Aggressive and escape behaviors were analysed in crickets (Orthoptera) treated with either reserpine, a nonspecific depleter of biogenic amines, or the synthesis inhibitors alpha-methyltryptophan (AMTP) and alpha-methyl-p-tyrosine (AMT) to specifically deplete serotonin, respectively dopamine and octopamine. Standard immunocytochemical techniques were used to verify depletion from central nervous tissue, and determine the effective dosages. Reserpinized crickets became exceedingly lethargic and had severely depressed escape responses. However, they were still able to express all the major elements of the escalating sequences of stereotype motor performances that typifies normal aggressive behavior in the cricket. AMT and AMTP treatment had opposing influences on escape behavior, being enhanced by serotonin depletion, but depressed by dopamine/octopamine depletion. AMTP-induced serotonin depletion had no influence on aggressive or submissive behaviors. AMT-treated crickets could normally only be brought to fight by coaxing. Though capable of expressing aggressive behavior per se, agonistic encounters between AMT-treated crickets were shorter, and rarely involved actual physical interactions. Hence, although amines seem to have similar actions on escape behavior in insects and crustaceans, the aminergic control of aggression seems to be fundamentally different in these arthropods groups. We conclude that amines are not in principle required for the initiation and operation of the motor circuits underlying aggression in the cricket. However, octopamine and/or dopamine seem necessary for establishing a level of excitability sufficient for aggressive behavior to become overt in response to appropriate natural releasing stimuli.

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耗尽生物胺的蟋蟀的战斗和逃跑反应。
用利血平(一种非特异性生物胺消耗剂)或α -甲基色氨酸(AMTP)和α -甲基-对酪氨酸(AMT)合成抑制剂特异性消耗血清素,分别是多巴胺和章鱼胺,对蟋蟀(直翅目)的攻击和逃跑行为进行了分析。标准免疫细胞化学技术用于验证中枢神经组织的耗竭,并确定有效剂量。利血平化的蟋蟀变得非常嗜睡,并且有严重的逃避反应。然而,他们仍然能够表达所有主要元素的升级序列的刻板印象运动表现,典型的正常攻击行为在板球。AMT和AMTP治疗对逃避行为有相反的影响,血清素减少会增强逃避行为,但多巴胺/章鱼胺减少会抑制逃避行为。amtp诱导的血清素耗竭对攻击或服从行为没有影响。经过amt治疗的蟋蟀通常只能通过哄骗才能打架。虽然能够表达攻击行为本身,但amt治疗的蟋蟀之间的激动性接触时间较短,很少涉及实际的身体相互作用。因此,尽管胺类在昆虫和甲壳类动物的逃避行为中似乎有相似的作用,但在这些节肢动物群体中,胺类对攻击的控制似乎有着根本的不同。我们得出的结论是,胺在原则上不需要启动和操作的运动电路潜在的侵略在蟋蟀。然而,章鱼胺和/或多巴胺似乎是建立足以使攻击行为在适当的自然释放刺激下变得明显的兴奋性水平所必需的。
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