Transcription factor Nurr1 maintains fiber integrity and nuclear-encoded mitochondrial gene expression in dopamine neurons

Kadkhodaei, Banafsheh; Alvarsson, Alexandra; Schintu, Nicoletta; Ramsköld, Daniel; Volakakis, Nikolaos; Joodmardi, Eliza; Yoshitake, Takashi; Kehr, Ján; Decressac, Mickaël; Björklund, Anders; Sandberg, Rickard; Svenningsson, Per; Perlmann, Thomas

doi:10.1073/pnas.1221077110

Cited by 149 publications

(190 citation statements)

References 33 publications

(45 reference statements)

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“…Because other genetic mouse models with a moderate reduction in DA content similar to that of adult Foxa1/2 cKO mice do not lead to an aphagic phenotype (22,77), we therefore speculate that our model represents a scenario whereby a 50% reduction in DA content in combination with a reduction of burst firing together impair both the quantity and the temporal control of DA release in the striatum. This dysregulation primarily contributes to aphagia due to lack of motivation to feed/drink (37), whereas overall activity/motor function remains unaffected.…”

Section: Discussionmentioning

confidence: 89%

“…4A). In addition, we quantified the expression levels of Pitx3 and Nr4a2, two transcription factors also expressed in adult mDA neurons (22,35). We found that neither Pitx3 nor Nr4a2 expression A B C Fig.…”

Section: Da Transmission Shows Deficits Restricted To Dorsal Striatum Ofmentioning

confidence: 91%

“…For example, OTX2 expression is restricted to the VTA in adult mDA neurons and is necessary to control VTA identity and to protect these neurons from 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-mediated toxic insults (21). In addition, NURR1 has recently been found to sustain nuclear-encoded mitochondrial gene expression and to preserve neurite integrity of adult mDA neurons (22). A recent study from our laboratory demonstrated that late developmental inactivation of FOXA1/2 in mDA neurons leads to a phenotypic change, and mDA neurons lose their DAergic markers without incurring cell loss (23).…”

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confidence: 99%

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Transcription factors FOXA1 and FOXA2 maintain dopaminergic neuronal properties and control feeding behavior in adult mice

Pristerà

Lin

Kaufmann

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Midbrain dopaminergic (mDA) neurons are implicated in cognitive functions, neuropsychiatric disorders, and pathological conditions; hence understanding genes regulating their homeostasis has medical relevance. Transcription factors FOXA1 and FOXA2 (FOXA1/2) are key determinants of mDA neuronal identity during development, but their roles in adult mDA neurons are unknown. We used a conditional knockout strategy to specifically ablate FOXA1/2 in mDA neurons of adult mice. We show that deletion of Foxa1/2 results in down-regulation of tyrosine hydroxylase, the rate-limiting enzyme of dopamine (DA) biosynthesis, specifically in dopaminergic neurons of the substantia nigra pars compacta (SNc). In addition, DA synthesis and striatal DA transmission were reduced after Foxa1/2 deletion. Furthermore, the burst-firing activity characteristic of SNc mDA neurons was drastically reduced in the absence of FOXA1/2. These molecular and functional alterations lead to a severe feeding deficit in adult Foxa1/2 mutant mice, independently of motor control, which could be rescued by L-DOPA treatment. FOXA1/2 therefore control the maintenance of molecular and physiological properties of SNc mDA neurons and impact on feeding behavior in adult mice.FOXA1 | FOXA2 | dopamine | burst firing | feeding M ost dopaminergic (DAergic) neurons in the adult midbrain are grouped in the ventral tegmental area (VTA) and substantia nigra pars compacta (SNc). VTA and SNc neurons have been classically linked to diverse functions and different projection targets (1). VTA neurons project to the ventral striatum, cortical areas, and limbic structures. Midbrain dopaminergic (mDA) neurons in this group are implicated in emotional behavior, motivational functions, and reward mechanisms (2-4). On the other hand, SNc neurons mainly project to the dorsal striatum and regulate motor function (5). mDA neurons are of major interest in biomedical research because degeneration of SNc mDA neurons is the hallmark of Parkinson's disease (6). In addition, mDA neuron dysfunction is associated with cognitive impairment, motivational deficits, addiction, and drug abuse (7-10). The identification of factors that maintain dopamine (DA) function in developed adult neurons may contribute to the understanding of the mechanisms supporting the homeostasis of mDA neurons and therefore help in identifying therapeutic targets to treat disorders arising from dysfunctional mDA neurons.FOXA1 and FOXA2 (FOXA1/2) are members of the wingedhelix/forkhead transcription factors, which share over 95% homology between mice and humans (11). FOXA1/2 are so-called "pioneer proteins" that, by binding to tightly condensed chromatin in promoters and enhancer regions, facilitate access of other transcription factors (12, 13). FOXA1/2 regulate the development of diverse organs, including the lung, liver, pancreas, prostate, and kidneys (14). We have also found that FOXA1/2 play a crucial role in the generation of mDA neurons during early and late development, regulating both their specification and dif...

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Section: Discussionmentioning

confidence: 89%

Section: Da Transmission Shows Deficits Restricted To Dorsal Striatum Ofmentioning

confidence: 91%

mentioning

confidence: 99%

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Transcription factors FOXA1 and FOXA2 maintain dopaminergic neuronal properties and control feeding behavior in adult mice

Pristerà

Lin

Kaufmann

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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“…This research was elegantly summarized by Dr. Robert Burke in his talk and recent review [9]. The models that were discussed include: AAV/2 human a-syn-A53T in rat [10], AAV/6 human a-syn-WT in rat [11], hBAC-LRRK2 in mouse [12,13], mBAC-Nurr1(fl/fl)XmBACDAT-CreT2 in mouse [14] and Engrailed1 +/-mouse [15,16], and it is likely that there are other models where such changes are yet to be reported. All of them present some form of axonal abnormalities in TH-positive nigrostriatal fibers before the degenerative processes are detected in the cell bodies.…”

Section: Main Textmentioning

confidence: 99%

“…Similar axonal spheroids were described in the post-mortem brains of PD [18] and Diffuse Lewy Body Disease patients [19], and they are also seen in other neurodegenerative diseases such as multiple sclerosis (MS). In aforementioned rodent models, the axo-degenerative processes are accompanied by other axonal abnormalities that mimic findings made in PD, such as loss of dopaminergic phenotype [11,14,15], changes in levels of axonal transport proteins [10], and autophagy markers [15]. 'It is important to emphasize that although this evidence suggests that axons are the first site of degenerative change, this does not necessarily mean that the primary disturbance at the molecular level first occurs in the axons.…”

Section: Main Textmentioning

confidence: 99%

Is Axonal Degeneration a Key Early Event in Parkinson’s Disease?

Kurowska

Kordower

Stoessl

et al. 2016

JPD

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Recent research suggests that in Parkinson's disease the long, thin and unmyelinated axons of dopaminergic neurons degenerate early in the disease process. We organized a workshop entitled 'Axonal Pathology in Parkinson's disease', on March 23 rd , 2016, in Cleveland, Ohio with the goals of summarizing the state-of-the-art and defining key gaps in knowledge. A group of eight research leaders discussed new developments in clinical pathology, functional imaging, animal models, and mechanisms of degeneration including neuroinflammation, autophagy and axonal transport deficits. While the workshop focused on PD, comparisons were made to other neurological conditions where axonal degeneration is well recognized. Main textAround 7 -10 million people worldwide suffer from Parkinson's disease (PD). PD is usually diagnosed based on motor symptoms (e.g. tremor, slowness of movements, bradykinesia) which are attributed to loss of dopamine in the striatum, as a consequence to degeneration of nigrostriatal dopamine neurons. Devising methods to protect the cell bodies of nigral dopamine neurons has long been a research priority, but emerging knowledge suggests that the research community should shift its focus from the soma to the axonal compartment of dopaminergic neurons.'I had been sitting on these data for two years before I submitted the paper' -said Dr. Jeffrey Kordower in the first talk of the Workshop, referring to his initial skepticism about the finding published in 2013 that in brains of PD patients, only 3-7 years after the diagnosis the putamen is almost completely depleted of TH-positive axons, while numerous cell bodies in the SNpc remain because the death of these neurons occurs at much slower pace [1]. It is not known if the axons had already degenerated at 3-7 years after diagnosis, or they are still there, just not expressing TH and other molecules involved in production and maintenance of functional dopaminergic synapses. Unfortunately, it has not been possible to address those questions in post-mortem human brains, as a structural marker specific for dopaminergic axons is not available, and striatum is innervated by axons from multiple nuclei including the cortex, amygdala, and raphe.Dr. Kordower also highlighted that studies with the growth factors GDNF/neurturin in monkeys and PD patients have suggested that nigrostriatal pathway axons need to be preserved for functional recovery to occur [2,3]. Moreover, the restoration of the nigrostriatal pathway alone is not necessarily translated to functional benefits as formation of synapses with the right target is also required.Degenerative changes that eventually lead to PD diagnosis start several years before the disease is discovered, and it is possible that loss of synaptic function in dopaminergic neurons is one of the first changes. Dr. Jon Stoessl presented the functional imaging data from PD patients showing evidence for early changes in striatal dopaminergic terminals [4]. The changes in effective dopamine turnover in the caudate and the putamen...

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Nuclear receptor Nur77 and Yin‐Yang 1 synergistically increase mitochondrial abundance and activity in macrophages

Koenis,

Evers‐van Gogh,

van Loenen

et al. 2024

FEBS Letters

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Mitochondrial biogenesis requires precise regulation of both mitochondrial‐encoded and nuclear‐encoded genes. Nuclear receptor Nur77 is known to regulate mitochondrial metabolism in macrophages and skeletal muscle. Here, we compared genome‐wide Nur77 binding site and target gene expression in these two cell types, which revealed conserved regulation of mitochondrial genes and enrichment of motifs for the transcription factor Yin‐Yang 1 (YY1). We show that Nur77 and YY1 interact, that YY1 increases Nur77 activity, and that their binding sites are co‐enriched at mitochondrial ribosomal protein gene loci in macrophages. Nur77 and YY1 co‐expression synergistically increases Mrpl1 expression as well as mitochondrial abundance and activity in macrophages but not skeletal muscle. As such, we identify a macrophage‐specific Nur77‐YY1 interaction that enhances mitochondrial metabolism.

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Transcription factor Nurr1 maintains fiber integrity and nuclear-encoded mitochondrial gene expression in dopamine neurons

Cited by 149 publications

References 33 publications

Transcription factors FOXA1 and FOXA2 maintain dopaminergic neuronal properties and control feeding behavior in adult mice

Transcription factors FOXA1 and FOXA2 maintain dopaminergic neuronal properties and control feeding behavior in adult mice

Is Axonal Degeneration a Key Early Event in Parkinson’s Disease?

Nuclear receptor Nur77 and Yin‐Yang 1 synergistically increase mitochondrial abundance and activity in macrophages

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