The pathophysiology of bipolar disorder is still unclear, although family, twin and linkage studies implicate genetic factors. Here we identified XBP1, a pivotal gene in the endoplasmic reticulum (ER) stress response, as contributing to the genetic risk factor for bipolar disorder. Using DNA microarray analysis of lymphoblastoid cells derived from two pairs of twins discordant with respect to the illness, we found downregulated expression of genes related to ER stress response in both affected twins. A polymorphism (-116C-->G) in the promoter region of XBP1, affecting the putative binding site of XBP1, was significantly more common in Japanese patients (odds ratio = 4.6) and overtransmitted to affected offspring in trio samples of the NIMH Bipolar Disorder Genetics Initiative. XBP1-dependent transcription activity of the -116G allele was lower than that of the -116C allele, and in the cells with the G allele, induction of XBP1 expression after ER stress was markedly reduced. Valproate, one of three mood stabilizers, rescued the impaired response by inducing ATF6, the gene upstream of XBP1. These results indicate that the -116C-->G polymorphism in XBP1 causes an impairment of its positive feedback system and increases the risk of bipolar disorder.
Melatonin is a pineal hormone produced at night; however, many strains of laboratory mice are deficient in melatonin. Strangely enough, the gene encoding HIOMT enzyme (also known as ASMT) that catalyzes the last step of melatonin synthesis is still unidentified in the house mouse (Mus musculus) despite the completion of the genome sequence. Here we report the identification of the mouse Hiomt gene, which was mapped to the pseudoautosomal region (PAR) of sex chromosomes. The gene was highly polymorphic, and nonsynonymous SNPs were found in melatonin-deficient strains. In C57BL/6 strain, there are two mutations, both of which markedly reduce protein expression. Mutability of the Hiomt likely due to a high recombination rate in the PAR could be the genomic basis for the high prevalence of melatonin deficiency. To understand the physiologic basis, we examined a wild-derived strain, MSM/Ms, which produced melatonin more under a short-day condition than a long-day condition, accompanied by increased Hiomt expression. We generated F2 intercrosses between MSM/ Ms and C57BL/6 strains and N2 backcrosses to investigate the role of melatonin productivity on the physiology of mice. Although there was no apparent effect of melatonin productivity on the circadian behaviors, testis development was significantly promoted in melatonin-deficient mice. Exogenous melatonin also had the antigonadal action in mice of a melatonin-deficient strain. These findings suggest a favorable impact of melatonin deficiency due to Hiomt mutations on domestic mice in breeding colonies.
There is no established genetic model of bipolar disorder or major depression, which hampers research of these mood disorders. Although mood disorders are multifactorial diseases, they are sometimes manifested by one of pleiotropic effects of a single major gene defect. We focused on chronic progressive external ophthalmoplegia (CPEO), patients with which sometimes have comorbid mood disorders. Chronic progressive external ophthalmoplegia is a mitochondrial disease, which is accompanied by accumulation of mitochondrial DNA (mtDNA) deletions caused by mutations in nuclear-encoded genes such as POLG (mtDNA polymerase). We generated transgenic mice, in which mutant POLG was expressed in a neuron-specific manner. The mice showed forebrain-specific defects of mtDNA and had altered monoaminergic functions in the brain. The mutant mice exhibited characteristic behavioral phenotypes, a distorted day-night rhythm and a robust periodic activity pattern associated with estrous cycle. These abnormal behaviors resembling mood disorder were worsened by tricyclic antidepressant treatment and improved by lithium, a mood stabilizer. We also observed antidepressant-induced mania-like behavior and long-lasting irregularity of activity in some mutant animals. Our data suggest that accumulation of mtDNA defects in brain caused mood disorder-like mental symptoms with similar treatment responses to bipolar disorder. These findings are compatible with mitochondrial dysfunction hypothesis of bipolar disorder.
Accumulation of unfolded proteins in the endoplasmic reticulum initiates intracellular signaling termed the unfolded protein response (UPR). Although Xbp1 serves as a pivotal transcription factor for the UPR, the physiological role of UPR signaling and Xbp1 in the central nervous system remains to be elucidated. Here, we show that Xbp1 mRNA was highly expressed during neurodevelopment and activated Xbp1 protein was distributed throughout developing neurons, including neurites. The isolated neurite culture system and time-lapse imaging demonstrated that Xbp1 was activated in neurites in response to brain-derived neurotrophic factor (BDNF), followed by subsequent translocation of the active Xbp1 into the nucleus. BDNF-dependent neurite outgrowth was significantly attenuated in Xbp1 ؊/؊ neurons. These findings suggest that BDNF initiates UPR signaling in neurites and that Xbp1, which is activated as part of the UPR, conveys the local information from neurites to the nucleus, contributing the neurite outgrowth. Endoplasmic reticulum (ER)2 is a site of synthesis, folding, and modification of secretory and cell surface proteins, and this organelle is widely distributed throughout neurons, including axons, dendrites, and growth cones (1). Various biological phenomena, such as increased protein synthesis, nutrient deprivation, and alteration in Ca 2ϩ homeostasis, hamper protein folding in the ER, causing unfolded proteins to accumulate in the ER lumen. This condition is designated as ER stress, which triggers an adaptive reaction known as the unfolded protein response (UPR) (2, 3). The protective signaling of the UPR acts transiently to maintain homeostasis within the ER, but sustained ER stress ultimately leads to apoptosis. Most of the previous studies on ER stress focused on its pathological aspect, as the pathogenesis of ischemic and neurodegenerative disorders is characterized by the accumulation of protein aggregates. Nevertheless, recent studies suggested that the UPR is required for normal development for certain cell lineages and that Xbp1, a pivotal transcription factor of the UPR, is essential for liver development (4) and plasma cell differentiation (5).Xbp1 is a basic leucine zipper type transcription factor; it is activated by spliceosome-independent mRNA splicing initiated by Ire1␣ on the cytosolic surface of the ER membrane (6). The endoribonuclease Ire1␣ cleaves a 26-nt fragment from an unspliced form of Xbp1 mRNA, inducing a frameshift of the open reading frame (ORF) of the message. Xbp1 protein translated from the unspliced mRNA (Xbp1u protein) has no transcriptional activity, whereas Xbp1 protein from the spliced mRNA (Xbp1s protein) is a potent transcription factor inducing expression of UPR-related genes. This type of transcription factor activation (the unconventional splicing of its mRNA in the cytoplasm not in the nucleus) is unique to Xbp1 in animals, and the mechanistic basis of Xbp1 splicing and its function has been studied intensively in non-neuronal cells (5-9). Although the mRNA of Xbp1 i...
Depression is a common debilitating human disease whose etiology has defied decades of research. A critical bottleneck is the difficulty in modeling depressive episodes in animals. Here, we show that a transgenic mouse with chronic forebrain expression of a dominant negative mutant of Polg1, a mitochondrial DNA (mtDNA) polymerase, exhibits lethargic behavioral changes, which are associated with emotional, vegetative and psychomotor disturbances, and response to antidepression drug treatment. The results suggested a symptomatic similarity between the lethargic behavioral change that was recurrently and spontaneously experienced by the mutant mice and major depressive episode as defined by DSM-5. A comprehensive screen of mutant brain revealed a hotspot for mtDNA deletions and mitochondrial dysfunction in the paraventricular thalamic nucleus (PVT) with similar defects observed in postmortem brains of patients with mitochondrial disease with mood symptoms. Remarkably, the genetic inhibition of PVT synaptic output by Cre-loxP-dependent expression of tetanus toxin triggered de novo depression-like episodes. These findings identify a novel preclinical mouse model and brain area for major depressive episodes with mitochondrial dysfunction as its cellular mechanism.
The present findings coincide with our hypothesis that circulating mtDNA contributes to the inflammation in MDD. Further studies are needed to conclude whether plasma mtDNA would be a biomarker of mood disorders.
Background: In a transcription/translation-based autoregulatory feedback loop of vertebrate circadian clock systems, a BMAL1-CLOCK heterodimer is a positive regulator for the transcription of the negative element gene Per. The chicken pineal gland represents a photosensitive clock tissue, but the pineal clock genes constituting the oscillator loop have been less well characterized.
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