Fluoxetine Can Cause Epileptogenesis and Aberrant Neurogenesis in Male Wild-Type Mice.

IF 2.3 4区 医学 Q2 DEVELOPMENTAL BIOLOGY
Developmental Neuroscience Pub Date : 2024-01-01 Epub Date: 2023-06-09 DOI:10.1159/000531478
Ksenia Musaelyan, Mark A Horowitz, Stephen McHugh, Francis G Szele
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Abstract

Antidepressants in general, and fluoxetine in particular, increase adult hippocampal neurogenesis (AHN) in mice. Here we asked how the antidepressant fluoxetine affects behavior and AHN in a corticosterone model of depression. In three groups of adult male C57BL/6j mice, we administered either vehicle (VEH), corticosterone (CORT) treatment to induce a depression-like state, or corticosterone plus a standard dose of fluoxetine (CORT+FLX). Following treatment, mice performed the open field test, the novelty suppressed feeding (NSF) test, and the splash test. Neurogenesis was assessed by means of immunohistochemistry using BrdU and neuronal maturation markers. Unexpectedly, 42% of the CORT+FLX-treated mice exhibited severe weight loss, seizures, and sudden death. As expected, the CORT-treated group had altered behaviors compared to the VEH group, but the CORT+FLX mice that survived did not show any behavioral improvement compared to the CORT group. Antidepressants generally increase neurogenesis and here we also found that compared to CORT mice, CORT+FLX mice that survived had a significantly greater density of BrdU+, BrdU+DCX+, and BrdU+NeuN+ cells, suggesting increased neurogenesis. Moreover, the density of BrdU+NeuN+ cells was increased in an aberrant location, the hilus, of CORT+FLX mice, similar to previous studies describing aberrant neurogenesis following seizures. In conclusion, fluoxetine could induce considerable adverse effects in wild-type mice, including seizure-like activity. Fluoxetine-induced neurogenesis increases could be related to this activity; therefore, proneurogenic effects of fluoxetine and other antidepressants, especially in the absence of any behavioral therapeutic effects, should be interpreted with caution.

氟西汀会导致雄性野生型小鼠癫痫发生和神经发生异常
抗抑郁药尤其是氟西汀能增加小鼠成年海马神经发生(AHN)。在此,我们探讨了抗抑郁药氟西汀如何在皮质酮抑郁模型中影响行为和AHN。在三组成年雄性 C57BL/6j 小鼠中,我们分别给予药物(VEH)、皮质酮(CORT)治疗以诱导抑郁样状态,或皮质酮加标准剂量的氟西汀(CORT+FLX)。治疗后,小鼠进行了开阔地试验、新奇抑制摄食(NSF)试验和飞溅试验。通过使用 BrdU 和神经元成熟标记物的免疫组化方法对神经发生进行了评估。出乎意料的是,42% 经 CORT+FLX 处理的小鼠表现出严重的体重减轻、癫痫发作和猝死。不出所料,与 VEH 组相比,CORT 治疗组小鼠的行为发生了改变,但与 CORT 组相比,存活下来的 CORT+FLX 小鼠没有表现出任何行为改善。抗抑郁药通常会增加神经发生,在这里我们还发现,与 CORT 小鼠相比,存活下来的 CORT+FLX 小鼠的 BrdU+、BrdU+DCX+ 和 BrdU+NeuN+ 细胞密度显著增加,表明神经发生增加。此外,BrdU+NeuN+细胞的密度在CORT+FLX小鼠的一个异常位置(脊髓)有所增加,这与之前描述癫痫发作后异常神经发生的研究相似。总之,氟西汀会对野生型小鼠产生相当大的不良影响,包括癫痫发作样活动。氟西汀诱导的神经发生增加可能与这种活动有关;因此,应谨慎解释氟西汀和其他抗抑郁药的神经发生效应,尤其是在没有任何行为治疗效应的情况下。
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来源期刊
Developmental Neuroscience
Developmental Neuroscience 医学-发育生物学
CiteScore
4.00
自引率
3.40%
发文量
49
审稿时长
>12 weeks
期刊介绍: ''Developmental Neuroscience'' is a multidisciplinary journal publishing papers covering all stages of invertebrate, vertebrate and human brain development. Emphasis is placed on publishing fundamental as well as translational studies that contribute to our understanding of mechanisms of normal development as well as genetic and environmental causes of abnormal brain development. The journal thus provides valuable information for both physicians and biologists. To meet the rapidly expanding information needs of its readers, the journal combines original papers that report on progress and advances in developmental neuroscience with concise mini-reviews that provide a timely overview of key topics, new insights and ongoing controversies. The editorial standards of ''Developmental Neuroscience'' are high. We are committed to publishing only high quality, complete papers that make significant contributions to the field.
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