Kitazono Tomohiro, Hara-Kuge Sayuri, Matsuda Osamu, Inoue Akitoshi, Fujiwara Manabi, Ishihara Takeshi
Graduate School of Systems Life Sciences.
Department of Biology, Faculty of Science.
J Neurosci. 2017 Oct 18;37(42):10240-10251. doi: 10.1523/JNEUROSCI.0031-17.2017. Epub 2017 Sep 18.
Forgetting memories is important for animals to properly respond to continuously changing environments. To elucidate the mechanisms of forgetting, we used one of the behavioral plasticities of hermaphrodite, olfactory adaptation to an attractive odorant, diacetyl, as a simple model of learning. In the TIR-1/JNK-1 pathway accelerates forgetting of olfactory adaptation by facilitating neural secretion from AWC sensory neurons. In this study, to identify the downstream effectors of the TIR-1/JNK-1 pathway, we conducted a genetic screen for suppressors of the gain-of-function mutant of (), which shows excessive forgetting. Our screening showed that three proteins-a membrane protein, MACO-1; a receptor tyrosine kinase, SCD-2; and its putative ligand, HEN-1-regulated forgetting downstream of the TIR-1/JNK-1 pathway. We further demonstrated that MACO-1 and SCD-2/HEN-1 functioned in parallel genetic pathways, and only MACO-1 regulated forgetting of olfactory adaptation to isoamyl alcohol, which is an attractive odorant sensed by different types of sensory neurons. In olfactory adaptation, odor-evoked Ca responses in olfactory neurons are attenuated by conditioning and recovered thereafter. A Ca imaging study revealed that this attenuation is sustained longer in and mutant animals than in wild-type animals like the TIR-1/JNK-1 pathway mutants. Furthermore, temporal silencing by histamine-gated chloride channels revealed that the neuronal activity of AWC neurons after conditioning is important for proper forgetting. We propose that distinct signaling pathways, each of which has a specific function, may coordinately and temporally regulate forgetting by controlling sensory responses. Active forgetting is an important process to understand the whole mechanisms of memories. Recent papers have reported that the noncell autonomous regulations are required for proper forgetting in invertebrates. We found that in hermaphrodite, the noncell autonomous regulations of forgetting of olfactory adaptation is regulated by three conserved proteins: a membrane protein, MACO-1; a receptor tyrosine kinase, SCD-2: and its ligand, HEN-1. MACO-1 and SCD-2/HEN-1, working in coordination, accelerate forgetting by controlling sensory responses in parallel. Furthermore, temporal regulation of neuronal activity is important for proper forgetting. We suggest that multiple pathways may coordinately and temporally regulate forgetting through control of sensory responses. This study should lead to a better understanding of forgetting in higher organisms.
遗忘记忆对于动物正确应对不断变化的环境至关重要。为了阐明遗忘的机制,我们利用雌雄同体动物的一种行为可塑性——对有吸引力的气味剂二乙酰的嗅觉适应,作为学习的一个简单模型。在秀丽隐杆线虫中,TIR-1/JNK-1通路通过促进AWC感觉神经元的神经分泌来加速嗅觉适应的遗忘。在本研究中,为了鉴定TIR-1/JNK-1通路的下游效应器,我们对秀丽隐杆线虫功能获得型突变体(该突变体表现出过度遗忘)的抑制因子进行了遗传筛选。我们的筛选表明,三种蛋白质——一种膜蛋白MACO-1、一种受体酪氨酸激酶SCD-2及其假定配体HEN-1在TIR-1/JNK-1通路的下游调节遗忘。我们进一步证明,MACO-1和SCD-2/HEN-1在平行的遗传通路中发挥作用,并且只有MACO-1调节对异戊醇的嗅觉适应的遗忘,异戊醇是一种由不同类型感觉神经元感知的有吸引力的气味剂。在嗅觉适应中,嗅觉神经元中气味诱发的钙反应通过条件作用而减弱,随后恢复。一项钙成像研究表明,在秀丽隐杆线虫和TIR-1/JNK-1通路突变体的突变动物中,这种减弱比在野生型动物中持续的时间更长。此外,组胺门控氯离子通道的时间沉默表明,条件作用后AWC神经元的神经元活动对于正确的遗忘很重要。我们提出,不同的信号通路,每个都有特定的功能,可能通过控制感觉反应在时间上协调调节遗忘。主动遗忘是理解记忆整体机制的一个重要过程。最近的论文报道,非细胞自主调节对于无脊椎动物的正确遗忘是必需的。我们发现,在秀丽隐杆线虫雌雄同体中,嗅觉适应遗忘的非细胞自主调节由三种保守蛋白质调节:一种膜蛋白MACO-1、一种受体酪氨酸激酶SCD-2及其配体HEN-1。MACO-1和SCD-2/HEN-1协同工作,通过并行控制感觉反应来加速遗忘。此外,神经元活动的时间调节对于正确的遗忘很重要。我们认为,多种通路可能通过控制感觉反应在时间上协调调节遗忘。这项研究应该有助于更好地理解高等生物中的遗忘。
