Parkinson’s Disease-Like Neuropathology and Phenotype Following Induction of Oxidative Stress and Inflammation in the Brain

Parkinson’s Disease (PD) is a neurodegenerative disorder characterized by motor deficits caused by the loss of dopaminergic neurons in the Substantia Nigra (SN) and Ventral Tegmental Area (VTA). However, clinical data revealed that not only the dopaminergic system is affected in PD. Pharmacological models support the concept that modification of noradrenergic transmission can influence the PD-like phenotype induced by neurotoxins. Exposure to ambient pollutants such as air pollutants also can be adversely impacted the Central Nervous System (CNS) by the activation of proinflammatory pathways and reactive oxygen species. Thus, targeting neuroinflammation and oxidative stress can be a useful strategy to eliminate the obvious symptoms of neurodegeneration. Overall, in the current mini-review, we examined the neuroprotective role of noradrenaline in the model of oxidative stress and neuroinflammation.

Air pollution and other ambient pollutants exposure can be adversely impacted the Central Nervous System (CNS) by the activation of proinflammatory pathways and reactive oxygen species. It is estimated that 20-70 % of urban air pollutants are resulting from traffic combustion [1-3] and 85% of Particulate Matter (PM) in urban areas is related to traffic [4]. New evidence suggests that air pollution exposure has been known as one of the main sources of neuroinflammation and oxidative stress, causing CNS and neuropathology disease [5-7]. Activation of ROS and pro-inflammatory pathways by PM is thought to elicit maladaptive responses that can in turn adversely impact organ function and the CNS also isn’t immune to air pollution impact [5,8,9]. There are several pathways via which can be transmitted inflammatory signals from environment to brain [6], so in people exposed to urban air pollutants, activation of the peripheral immune system may lead to neuroinflammation [10]. Neuroinflammatory reactions are triggered by oxidative stress, cytokines, and chemokines and can lead to impaired neurotransmitter and neurotrophin signaling disorders, abnormal protein accumulation, neurodegeneration, and neuronal remodeling [11]. Prolonged exposure to these pollutants may lead to an increase in the inflammatory markers upregulation and exacerbate previous neurodegenerative disorders [12-15]. In addition, new findings support the involvement of neuroinflammation in the pathogenesis of emotional and cognitive disorders [16,17]. Neurodegenerative Diseases (NDs) pose a greater risk to humans, more precisely to the elderly population [18], and according to the WHO, it will overtake cancer in the next 20 years [19]. These diseases include a number of neurological disorders characterized by a diverse array of pathophysiology and are associated with cognitive impairment and/or mobility impairment [20]. It includes a wide range of disorders, the two most common of which are Parkinson's Disease (PD) and Alzheimer's Sisease (AD) [21,22]. Neurodegenerative diseases are common to many of the major processes associated with dysfunction and neuronal death, including oxidative stress and the formation of free radicals, neuroinflammation, protein folding and malformation, bioenergy disorders, and mitochondrial dysfunction [23]. PD, the second most common neurodegenerative disorder, is characterized by increased production of oxygen free radicals leading to alterations of the cellular constituents and subsequent loss of dopamine and dopaminergic neurons, which are directly responsible for the disease symptomatology (bradykinesia, tremor, rigidity, impaired posture and balance) [24]. Most cases (up to 90%) have a sporadic occurrence, and even for cases in which genetic factors have been identified, distinct molecular pathways leading to eventual and inevitable cell death are unclear. As a result, existing therapies are currently based on the symptoms of the disease, and although they do reduce the usual symptoms to some extent, they do not restore neuronal function or prevent neuronal loss. An important factor that significantly reduces therapeutic efforts is that dopaminergic neuron degradation begins long before the first clinical signs appear, and even rapid diagnosis at this stage does not allow effective treatment, because most cells have already disappeared [25]. Although historically the hallmarks of PD have been related to the degeneration of the Substantia Nigra (SN) and Ventral Tegmental Area (VTA), it has recently become widely accepted that damage to other brain areas precedes the cell loss of SN/VTA neurons, making PD-related neurodegeneration a multi-stage process [26,27]. The extranigral structures involved in PD also include the noradrenergic system [28].

Noradrenaline role in parkinson’s disease

Noradrenaline is one of the most important neurotransmitters in the central nervous system, and predictions of noradrenergic neurons originating from the Locus Coeruleus (LC) permeate almost all brain structures. In addition, degeneration of noradrenergic neurons in the LC region is more pronounced in patients with PD and exacerbates the loss of dopaminergic neurons in the SN [29,30]. These findings were underscored in a recent study, which suggested that PD could not be considered a mere dopaminergic neuronal disease [31]. In addition, LC integration is a useful indicator in PD clinical trials to classify patients for clinical trials due to their noradrenergic dysfunction [32]. In fact, PD patients are characterized by the following: reduction of LC MRI contrast limited to the middle and caudal region of this structure, downregulation of Norepinephrine Transporter (NET) density, and loss of the noradrenergic terminal [33]. Studies on animal models are scarce, but support the statement that modification of noradrenergic transmission could affect the basic PD-like phenotype observed in models of pharmacological PD rodents. For example, loss of noradrenaline can worsen the degradation of nigrostriatal dopamine induced by 6-Hydroxy Dopamine (6-OHDA). Conversely, an enhanced level of noradrenaline may have a neuroprotective effect in mice subjected to 1- Methyl-4-Phenyl-1,2,3,6-Tetrahydropyridine (MPTP) [34,35]. These results prompt the hypothesis that noradrenergic degradation may be thought of as a prodromal phase of PD that progresses in six neuropathological stages and eventually reaches a threshold responsible for symptoms directly related to profound loss of SN / VTA dopaminergic cells [26]. Recently, it has also been suggested in non-human primates that severe degeneration of ascending noradrenergic protrusions may contribute to dysfunction of the dopaminergic cell groups of the ventral midbrain and subthalamic nuclei neurons observed in PD [36]. Although there is widespread evidence for the effects of noradrenaline on different populations of dopamine neurons in the midbrain, these interactions have not been fully elucidated and this topic has not been studied in PD-related research that focuses primarily on dopamine and dopaminergic systems. As our previous results demonstrated the beneficial effects of noradrenergic system stimulation in a conditional model of progressive Parkinsonism [37], we investigated whether decreased noradrenaline levels lead to early signs of dopaminergic neuron degeneration in SN / VTA. Following that hypothesis, we suggest that an approach focused on studying the long-term effects of noradrenergic degeneration may help elucidate the pathophysiological changes that occur in the pre-symptomatic phase of PD.

Noradrenergic and dopaminergic systems

Although the noradrenergic and dopaminergic systems of the CNS have different characteristics, they are physiologically and functionally having close relationships that can overlap and complement each other. Therefore, abnormalities in these systems can also be closely related to the pathogenesis of many neurodegenerative diseases. Noradrenaline was suggested as a compensatory mechanism in dopaminergic neuronal degradation of PD [28]. Accordingly, a genetic model of PD mice showed that noradrenaline levels were directly related to the loss of dopaminergic cells [38]. Similarly, in a pharmacological PD model, the interrelationships between the two systems were confirmed in a recent study that described the degeneration of LC neurons mediated through NLPR3 inflammation-dependent microglial activation [39]. Understanding the noradrenergic/dopaminergic interaction, especially the modulatory effects of LC-controlled noradrenergic neurotransmission on dopaminergic neurons, may benefit the early diagnosis of the prodromal phase of PD and potential preventive treatment. Neuroinflammation associated with microglial activation and increased reactive gliosis is typical of neurodegenerative disorders including PD [40]. Human tissues after death from patients suffering from PD but also Huntington's Disease (HD), Alzheimer's Disease (AD), and amyotrophic lateral sclerosis showed reactive astrocytes accompanied by reactive microglia in vulnerable areas [41]. The imbalance between the noradrenergic and dopaminergic systems can directly trigger neuroinflammation and early signs of neurodegeneration. Noradrenergic neurons may affect the wellbeing of dopaminergic neurons, by the induction of inflammatory processes.

Glial activation and neuroinflammation

Glial activation, the release of proinflammatory cytokines, and astrocytic dysfunction have been suggested at the source of the neuroinflammatory process [42,43]. Although inflammation may be the result of persistent neuronal cell death in PD, α-Synuclein may misfold cause glial activation [44]. One of the potential physiological roles of noradrenaline is to protect neurons by inhibiting glial activation and subsequent release of pro-inflammatory factors [45]. This is partly due to the nature of about half of the LC axon terminals that do not form the classical synapses: noradrenaline escapes to the synaptic cleft and reaches adrenergic receptors on glial cells [46], which express all functional adrenergic receptors (α1-, α2-, β1- and β2-ARs) [47]. In addition, laboratory studies have shown that noradrenaline protection measures, at least in part, are due to their ability to weaken the activation of microglia [48] and astrocytes [49]. Noradrenaline deficiency and its modulatory functions may exacerbate glial functions loss. Inflammation was also observed in previous models based on the induction of nuclear stress in other neural populations [50]. Failure to induction of inflammatory cytokines (such as IL-6, IL-1β, or TNFα) may indicate that degeneration of noradrenergic neurons results in a weak inflammatory state, which activates also neuroprotective events such as increased IL-10 expression, probably leads to reduce IL-6 levels. IL-10 is a highly potent anti-inflammatory cytokine that plays an important role in the prevention of inflammatory and autoimmune pathologies [51], and a recent study noted its specific role in PD [52]. That is, heterozygous M83^+/– transgenic mice expressing the mutant human A53T α-synuclein under the control of the mouse prion protein promoter, primed with IL-10 and next seeded with preformed α-synuclein fibrils had shorter lifespan or presented exaggerated αSyn pathology [52]. The opposite results were obtained by preconditioning IL-6, which improved the outcome of induced synucleinopathy in mice [53]. Both metalloproteinases have been reported to be neuroprotective in AD or multiple sclerosis [54]. The MMP-3, MMP1 or MMP-9 metalloproteinases, which are prone to inhibition by TIMP1/2, appear to be involved in the pathogenesis of PD as shown in vitro studies on neurotoxic animal models of PD or postmortem tissue of PD patients [55,56]. Also, increasing IL-13 levels can contribute to the death of dopaminergic neurons because activation of the IL-13Rα1 receptor increases their vulnerability to oxidative damage [57,58]. The role of obvious apoptosis-related transcripts like Casp9 (caspase 9) in neurodegeneration is well documented [59]. Enhanced transcription of Sgk1 (Serum/Glucocorticoid Related Kinase 1) is upregulated in the brains of PD patients [60]. Another upregulated transcript is Sparc (Secreted Protein Acidic and Cysteine-Rich) which has been reported to be expressed differently in Parkinson's LRRK2-derived astrocytes from iPSC [61]. An interesting example is the Eukaryotic Initiation Factor 3 (Eif3), one of the most complex factors in translation initiation, which is crucial in ribosomal turnover in translational processes [62]. In addition to reboxetine [37], mirtazapine, a noradrenergic and serotonergic antidepressant drug, was shown to have therapeutic potency in classic pharmacological models of PD: MPTP-treated mice [63] and 6-OHDA- injected mice [64]. Atomoxetine, a noradrenaline transporter blocker, reduces dopaminergic neuronal damage, reduces microglial activation in SN / VTA, and promotes functional improvement of motor defects in the PD model of inflammatory lipopolysaccharide mice [65]. In addition to β2-AR mediating mechanisms, noradrenaline can affect inflammation by suppressing superoxide produced by NADPH oxidase [45]. In contrast, reduction of noradrenaline through pharmacological lesions degenerates dopaminergic neurons in the midbrain by promoting inflammation, reducing neurotrophic factor release, and promoting oxidation in the SN [66,67]. On the other hand, it has also been confirmed that combined noradrenergic and dopaminergic pharmacological lesions lead to more severe motor and non-motor behavioral impairments by increasing neuroinflammation and promoting neuronal death [68].

Disruption of the nucleolar structure and function impair ribosome biogenesis and triggers the so-called nucleolar stress response [69,70], which induces cell death [71]. Nucleolar stress is common in neurodegenerative diseases [72,73]. Dopaminergic neurons in PD patients show impaired nuclear integrity [74]. The notion that nuclear stress may monitor the early stages of the disease is supported by the similar redistribution of B23 (NPM1) found in the progressive HD model of mice and in skeletal muscle sampling of early HD patients [75].

Neuronal damage following genetic disorders as well as exposure to chemicals and drugs or environmental contaminants activates proinflammatory cytokines, mainly associated with oxidative stress, and can affect the Central Nervous System (CNS) by activating pro-inflammatory and reactive oxygen species pathways are negatively affected. Glial activation and the effects of oxidative stress on SN / VTA neurons stem directly from the state of gradually dying noradrenergic cells and their loss of function, including the secretory function of noradrenaline. Mechanisms observed before degeneration of the dopamine system may have the potential for early detection of PD. Limiting mutations to central noradrenergic neurons allows focusing on the description of long-term functional changes in the dopaminergic system, which should be considered. In addition, such a model should allow the testing of potential neuroprotective drugs, which reverse the onset of dopaminergic neuronal degradation. Extensive results may provide an opportunity to anticipate new strategies for drug development. Overall, new evidence that the noradrenergic system controls the function of dopaminergic neurons and homeostasis may open up new avenues for research into the causes of early PD onset.

1. Geller MD, Sardar SB, Phuleria H, Fine PM, Sioutas C. Measurements of particle number and mass concentrations and size distributions in a tunnel environment. Environ Sci Technol. 2005 Nov 15;39(22):8653-8663. doi: 10.1021/es050360s. PMID: 16323759.
2. Lanki T. Can we identify sources of fine particles responsible for exercise-induced ischemia on days with elevated air pollution? The ULTRA study. Environmental Health Perspectives. 2006;114(5):655. https://tinyurl.com/mwutyfwd
3. Al Kury LT, Zeb A, Abidin ZU, Irshad N, Malik I, Alvi AM, Khalil AAK, Ahmad S, Faheem M, Khan AU, Shah FA, Li S. Neuroprotective effects of melatonin and celecoxib against ethanol-induced neurodegeneration: a computational and pharmacological approach. Drug Des Devel Ther. 2019 Aug 2;13:2715-2727. doi: 10.2147/DDDT.S207310. PMID: 31447548; PMCID: PMC6683968.
4. Jafari A, Ehsanifar. The share of different vehicles in air pollutant emission in tehran, using 2013 traffic information. Caspian Journal of Health Research. 2016;2(2):28-36. https://tinyurl.com/5n6tyk6y
5. Ehsanifar M, Banihashemian, Farokhmanesh. Exposure to urban air pollution nanoparticles and cns disease. On J Neur & Br Disord. 2021;5(5):520-526. https://tinyurl.com/yckpyvyv
6. Ehsanifar M, Tameh AA, Farzadkia M, Kalantari RR, Zavareh MS, Nikzaad H, Jafari AJ. Exposure to nanoscale diesel exhaust particles: Oxidative stress, neuroinflammation, anxiety and depression on adult male mice. Ecotoxicol Environ Saf. 2019 Jan 30;168:338-347. doi: 10.1016/j.ecoenv.2018.10.090. Epub 2018 Nov 2. PMID: 30391838.
7. Ehsanifar M, Jafari AJ, Nikzad H, Zavareh MS, Atlasi MA, Mohammadi H, Tameh AA. Prenatal exposure to diesel exhaust particles causes anxiety, spatial memory disorders with alters expression of hippocampal pro-inflammatory cytokines and NMDA receptor subunits in adult male mice offspring. Ecotoxicol Environ Saf. 2019 Jul 30;176:34-41. doi: 10.1016/j.ecoenv.2019.03.090. Epub 2019 Mar 25. PMID: 30921694.
8. Ehsanifar M, Banihashemian, Ehsanifar. Exposure to air pollution nanoparticles: Oxidative stress and neuroinfl ammation. J Biomed Res Environ Sci. 2021;2(10):964-976. https://tinyurl.com/ykdbc6a7
9. Ehsanifar M, Banihashemian, Farokhmanesh. Exposure to ambient ultra-fine particles and stroke. J Biomed Res Environ Sci. 2021;2(10):954-958. https://tinyurl.com/2p9ebxxe
10. Brook RD, Rajagopalan S, Pope CA 3rd, Brook JR, Bhatnagar A, Diez-Roux AV, Holguin F, Hong Y, Luepker RV, Mittleman MA, Peters A, Siscovick D, Smith SC Jr, Whitsel L, Kaufman JD; American Heart Association Council on Epidemiology and Prevention, Council on the Kidney in Cardiovascular Disease, and Council on Nutrition, Physical Activity and Metabolism. Particulate matter air pollution and cardiovascular disease: An update to the scientific statement from the American Heart Association. Circulation. 2010 Jun 1;121(21):2331-2378. doi: 10.1161/CIR.0b013e3181dbece1. Epub 2010 May 10. PMID: 20458016.
11. Teeling JL, Perry VH. Systemic infection and inflammation in acute CNS injury and chronic neurodegeneration: underlying mechanisms. Neuroscience. 2009 Feb 6;158(3):1062-1073. doi: 10.1016/j.neuroscience.2008.07.031. Epub 2008 Jul 25. PMID: 18706982.
12. Godbout JP, Chen J, Abraham J, Richwine AF, Berg BM, Kelley KW, Johnson RW. Exaggerated neuroinflammation and sickness behavior in aged mice following activation of the peripheral innate immune system. FASEB J. 2005 Aug;19(10):1329-1331. doi: 10.1096/fj.05-3776fje. Epub 2005 May 26. PMID: 15919760.
13. Cunningham C, Campion S, Lunnon K, Murray CL, Woods JF, Deacon RM, Rawlins JN, Perry VH. Systemic inflammation induces acute behavioral and cognitive changes and accelerates neurodegenerative disease. Biol Psychiatry. 2009 Feb 15;65(4):304-312. doi: 10.1016/j.biopsych.2008.07.024. Epub 2008 Sep 18. PMID: 18801476; PMCID: PMC2633437.
14. Ehsanifar M, Montazeri Z, Taheri MA, Rafati M, Behjati M, Karimian M. Hippocampal inflammation and oxidative stress following exposure to diesel exhaust nanoparticles in male and female mice. Neurochem Int. 2021 May;145:104989. doi: 10.1016/j.neuint.2021.104989. Epub 2021 Feb 12. PMID: 33582162.
15. Ehsanifar M. Airborne aerosols particles and COVID-19 transition. Environ Res. 2021 Sep;200:111752. doi: 10.1016/j.envres.2021.111752. Epub 2021 Jul 22. PMID: 34302822; PMCID: PMC8295061.
16. Clark IA, Alleva LM, Vissel B. The roles of TNF in brain dysfunction and disease. Pharmacol Ther. 2010 Dec;128(3):519-548. doi: 10.1016/j.pharmthera.2010.08.007. Epub 2010 Sep 8. PMID: 20813131.
17. Ehsanifar M, Jafari AJ, Montazeri Z, Kalantari RR, Gholami M, Ashtarinezhad A. Learning and memory disorders related to hippocampal inflammation following exposure to air pollution. J Environ Health Sci Eng. 2021 Jan 22;19(1):261-272. doi: 10.1007/s40201-020-00600-x. PMID: 34150234; PMCID: PMC8172730.
18. Heemels MT. Neurodegenerative diseases. Nature. 2016 Nov 10;539(7628):179. doi: 10.1038/539179a. PMID: 27830810.
19. Durães F, Pinto M, Sousa E. Old drugs as new treatments for neurodegenerative diseases. Pharmaceuticals (Basel). 2018 May 11;11(2):44. doi: 10.3390/ph11020044. PMID: 29751602; PMCID: PMC6027455.
20. Jiang B, Zhao Y, Cao J, Yang Y, Kuang T, Zhang Q, Liu X, Chen X, Liu X, Liao X, Zhou X, Xu Z. Synthesis and preliminary biological evaluation of naproxen-probenecid conjugate for Central Nervous System (CNS) delivery. Pak J Pharm Sci. 2021 Nov;34(6):2197-2203. PMID: 35034881.
21. Brettschneider J, Del Tredici K, Lee VM, Trojanowski JQ. Spreading of pathology in neurodegenerative diseases: a focus on human studies. Nat Rev Neurosci. 2015 Feb;16(2):109-120. doi: 10.1038/nrn3887. Epub 2015 Jan 15. PMID: 25588378; PMCID: PMC4312418.
22. Ehsanifar M, Montazeri Z, Rafati M. Alzheimer’s disease-like neuropathology following exposure to ambient noise. J Biomed Res Environ Sci. 2021;2(11):1159-1162. https://tinyurl.com/yevheu6b
23. Gitler AD, Dhillon, Shorter. Neurodegenerative disease: Models, mechanisms, and a new hope. The Company of Biologists Ltd. 2017;499-502. https://tinyurl.com/mtpf2k97
24. Rafa-Zabłocka K, Kreiner G, Bagińska M, Kuśmierczyk J, Parlato R, Nalepa I. Transgenic mice lacking CREB and CREM in noradrenergic and serotonergic neurons respond differently to common antidepressants on tail suspension test. Sci Rep. 2017 Oct 18;7(1):13515. doi: 10.1038/s41598-017-14069-6. PMID: 29044198; PMCID: PMC5647346.
25. Marino BLB, de Souza LR, Sousa KPA, Ferreira JV, Padilha EC, da Silva CHTP, Taft CA, Hage-Melim LIS. Parkinson's Disease: A Review from pathophysiology to treatment. Mini Rev Med Chem. 2020;20(9):754-767. doi: 10.2174/1389557519666191104110908. PMID: 31686637.
26. Braak H, Ghebremedhin E, Rüb U, Bratzke H, Del Tredici K. Stages in the development of Parkinson's disease-related pathology. Cell Tissue Res. 2004 Oct;318(1):121-134. doi: 10.1007/s00441-004-0956-9. Epub 2004 Aug 24. PMID: 15338272.
27. Braak H, Del Tredici K, Rüb U, de Vos RA, Jansen Steur EN, Braak E. Staging of brain pathology related to sporadic Parkinson's disease. Neurobiol Aging. 2003 Mar-Apr;24(2):197-211. doi: 10.1016/s0197-4580(02)00065-9. PMID: 12498954.
28. Rommelfanger KS, Weinshenker D. Norepinephrine: The redheaded stepchild of Parkinson's disease. Biochem Pharmacol. 2007 Jul 15;74(2):177-190. doi: 10.1016/j.bcp.2007.01.036. Epub 2007 Feb 3. PMID: 17416354.
29. Espay AJ, LeWitt PA, Kaufmann H. Norepinephrine deficiency in Parkinson's disease: the case for noradrenergic enhancement. Mov Disord. 2014 Dec;29(14):1710-1779. doi: 10.1002/mds.26048. Epub 2014 Oct 9. PMID: 25297066.
30. Sotiriou E, Vassilatis DK, Vila M, Stefanis L. Selective noradrenergic vulnerability in α-synuclein transgenic mice. Neurobiol Aging. 2010 Dec;31(12):2103-2114. doi: 10.1016/j.neurobiolaging.2008.11.010. Epub 2009 Jan 18. PMID: 19152986.
31. Giguère N, Burke Nanni S, Trudeau LE. On cell loss and selective vulnerability of neuronal populations in parkinson's disease. Front Neurol. 2018 Jun 19;9:455. doi: 10.3389/fneur.2018.00455. PMID: 29971039; PMCID: PMC6018545.
32. Betts MJ, Kirilina E, Otaduy MCG, Ivanov D, Acosta-Cabronero J, Callaghan MF, Lambert C, Cardenas-Blanco A, Pine K, Passamonti L, Loane C, Keuken MC, Trujillo P, Lüsebrink F, Mattern H, Liu KY, Priovoulos N, Fliessbach K, Dahl MJ, Maaß A, Madelung CF, Meder D, Ehrenberg AJ, Speck O, Weiskopf N, Dolan R, Inglis B, Tosun D, Morawski M, Zucca FA, Siebner HR, Mather M, Uludag K, Heinsen H, Poser BA, Howard R, Zecca L, Rowe JB, Grinberg LT, Jacobs HIL, Düzel E, Hämmerer D. Locus coeruleus imaging as a biomarker for noradrenergic dysfunction in neurodegenerative diseases. Brain. 2019 Sep 1;142(9):2558-2571. doi: 10.1093/brain/awz193. PMID: 31327002; PMCID: PMC6736046.
33. Giguère N, Burke Nanni S, Trudeau LE. On cell loss and selective vulnerability of neuronal populations in parkinson's disease. Front Neurol. 2018 Jun 19;9:455. doi: 10.3389/fneur.2018.00455. PMID: 29971039; PMCID: PMC6018545.
34. Doppler CEJ, Kinnerup MB, Brune C, Farrher E, Betts M, Fedorova TD, Schaldemose JL, Knudsen K, Ismail R, Seger AD, Hansen AK, Stær K, Fink GR, Brooks DJ, Nahimi A, Borghammer P, Sommerauer M. Regional locus coeruleus degeneration is uncoupled from noradrenergic terminal loss in Parkinson's disease. Brain. 2021 Oct 22;144(9):2732-2744. doi: 10.1093/brain/awab236. PMID: 34196700.
35. Srinivasan J, Schmidt WJ. Potentiation of parkinsonian symptoms by depletion of locus coeruleus noradrenaline in 6-hydroxydopamine-induced partial degeneration of substantia nigra in rats. Eur J Neurosci. 2003 Jun;17(12):2586-2592. doi: 10.1046/j.1460-9568.2003.02684.x. PMID: 12823465.
36. Masilamoni GJ, Groover O, Smith Y. Reduced noradrenergic innervation of ventral midbrain dopaminergic cell groups and the subthalamic nucleus in MPTP-treated parkinsonian monkeys. Neurobiol Dis. 2017 Apr;100:9-18. doi: 10.1016/j.nbd.2016.12.025. Epub 2016 Dec 30. PMID: 28042095; PMCID: PMC5511687.
37. Kreiner G. Stimulation of noradrenergic transmission by reboxetine is beneficial for a mouse model of progressive parkinsonism. Scientific reports. 2019;9(1):1-9. https://tinyurl.com/2mxck4w9
38. Pickrell AM, Pinto M, Moraes CT. Mouse models of parkinson's disease associated with mitochondrial dysfunction. Mol Cell Neurosci. 2013 Jul;55:87-94. doi: 10.1016/j.mcn.2012.08.002. Epub 2012 Aug 11. PMID: 22954895; PMCID: PMC3997253.
39. Hu L, Zhang S, Ooi K, Wu X, Wu J, Cai J, Sun Y, Wang J, Zhu D, Chen F, Xia C. Microglia-derived NLRP3 activation mediates the pressor effect of prorenin in the rostral ventrolateral medulla of stress-induced hypertensive rats. Neurosci Bull. 2020 May;36(5):475-492. doi: 10.1007/s12264-020-00484-9. Epub 2020 Apr 3. PMID: 32242284; PMCID: PMC7186257.
40. Wang Q, Liu, Zhou. Neuroinflammation in Parkinson’s disease and its potential as therapeutic target. Translational neurodegeneration. 2015;4(1):1-9.
41. Liddelow SA. Neurotoxic reactive astrocytes are induced by activated microglia. Nature. 2017;541(7638):481-487. https://tinyurl.com/6mt565ep
42. Liu B, Teschemacher AG, Kasparov S. Neuroprotective potential of astroglia. J Neurosci Res. 2017 Nov;95(11):2126-2139. doi: 10.1002/jnr.24140. Epub 2017 Aug 24. PMID: 28836687.
43. Tsutsumi R, Hori Y, Seki T, Kurauchi Y, Sato M, Oshima M, Hisatsune A, Katsuki H. Involvement of exosomes in dopaminergic neurodegeneration by microglial activation in midbrain slice cultures. Biochem Biophys Res Commun. 2019 Apr 2;511(2):427-433. doi: 10.1016/j.bbrc.2019.02.076. Epub 2019 Feb 23. PMID: 30803759.
44. Butkovich LM, Houser MC, Tansey MG. α-Synuclein and Noradrenergic Modulation of Immune Cells in Parkinson's Disease Pathogenesis. Front Neurosci. 2018 Sep 11;12:626. doi: 10.3389/fnins.2018.00626. PMID: 30258347; PMCID: PMC6143806.
45. Jiang L, Chen SH, Chu CH, Wang SJ, Oyarzabal E, Wilson B, Sanders V, Xie K, Wang Q, Hong JS. A novel role of microglial NADPH oxidase in mediating extra-synaptic function of norepinephrine in regulating brain immune homeostasis. Glia. 2015 Jun;63(6):1057-1072. doi: 10.1002/glia.22801. Epub 2015 Mar 4. PMID: 25740080; PMCID: PMC4405498.
46. Feinstein DL, Kalinin S, Braun D. Causes, consequences, and cures for neuroinflammation mediated via the locus coeruleus: noradrenergic signaling system. J Neurochem. 2016 Oct;139 Suppl 2:154-178. doi: 10.1111/jnc.13447. Epub 2016 Mar 10. PMID: 26968403.
47. Zhang Y, Chen K, Sloan SA, Bennett ML, Scholze AR, O'Keeffe S, Phatnani HP, Guarnieri P, Caneda C, Ruderisch N, Deng S, Liddelow SA, Zhang C, Daneman R, Maniatis T, Barres BA, Wu JQ. An RNA-sequencing transcriptome and splicing database of glia, neurons, and vascular cells of the cerebral cortex. J Neurosci. 2014 Sep 3;34(36):11929-47. doi: 10.1523/JNEUROSCI.1860-14.2014. Erratum in: J Neurosci. 2015 Jan 14;35(2):846-866. PMID: 25186741; PMCID: PMC4152602.
48. Dello Russo C, Boullerne AI, Gavrilyuk V, Feinstein DL. Inhibition of microglial inflammatory responses by norepinephrine: effects on nitric oxide and interleukin-1beta production. J Neuroinflammation. 2004 Jun 30;1(1):9. doi: 10.1186/1742-2094-1-9. PMID: 15285793; PMCID: PMC500870.
49. Braun SM, Jessberger S. Adult neurogenesis: mechanisms and functional significance. Development. 2014 May;141(10):1983-1986. doi: 10.1242/dev.104596. PMID: 24803647.
50. Kreiner G, Bierhoff H, Armentano M, Rodriguez-Parkitna J, Sowodniok K, Naranjo JR, Bonfanti L, Liss B, Schütz G, Grummt I, Parlato R. A neuroprotective phase precedes striatal degeneration upon nucleolar stress. Cell Death Differ. 2013 Nov;20(11):1455-1464. doi: 10.1038/cdd.2013.66. Epub 2013 Jun 14. PMID: 23764776; PMCID: PMC3792439.
51. Iyer SS, Cheng G. Role of interleukin 10 transcriptional regulation in inflammation and autoimmune disease. Crit Rev Immunol. 2012;32(1):23-63. doi: 10.1615/critrevimmunol.v32.i1.30. PMID: 22428854; PMCID: PMC3410706.
52. Cockey SG, McFarland KN, Koller EJ, Brooks MMT, Gonzalez De La Cruz E, Cruz PE, Ceballos-Diaz C, Rosario AM, Levites YR, Borchelt DR, Golde TE, Giasson BI, Chakrabarty P. Il-10 signaling reduces survival in mouse models of synucleinopathy. NPJ Parkinsons Dis. 2021 Mar 19;7(1):30. doi: 10.1038/s41531-021-00169-8. PMID: 33741985; PMCID: PMC7979923.
53. Koller EJ, Brooks MM, Golde TE, Giasson BI, Chakrabarty P. Inflammatory pre-conditioning restricts the seeded induction of α-synuclein pathology in wild type mice. Mol Neurodegener. 2017 Jan 3;12(1):1. doi: 10.1186/s13024-016-0142-z. PMID: 28049533; PMCID: PMC5210310.
54. Rivera S, García-González L, Khrestchatisky M, Baranger K. Metalloproteinases and their tissue inhibitors in Alzheimer's disease and other neurodegenerative disorders. Cell Mol Life Sci. 2019 Aug;76(16):3167-3191. doi: 10.1007/s00018-019-03178-2. Epub 2019 Jun 13. PMID: 31197405.
55. Choi DH, Kim YJ, Kim YG, Joh TH, Beal MF, Kim YS. Role of matrix metalloproteinase 3-mediated alpha-synuclein cleavage in dopaminergic cell death. J Biol Chem. 2011 Apr 22;286(16):14168-77. doi: 10.1074/jbc.M111.222430. Epub 2011 Feb 17. PMID: 21330369; PMCID: PMC3077618.
56. Kim YS, Choi DH, Block ML, Lorenzl S, Yang L, Kim YJ, Sugama S, Cho BP, Hwang O, Browne SE, Kim SY, Hong JS, Beal MF, Joh TH. A pivotal role of matrix metalloproteinase-3 activity in dopaminergic neuronal degeneration via microglial activation. FASEB J. 2007 Jan;21(1):179-187. doi: 10.1096/fj.06-5865com. Epub 2006 Nov 20. PMID: 17116747.
57. Mori S, Sugama S, Nguyen W, Michel T, Sanna MG, Sanchez-Alavez M, Cintron-Colon R, Moroncini G, Kakinuma Y, Maher P, Conti B. Lack of interleukin-13 receptor α1 delays the loss of dopaminergic neurons during chronic stress. J Neuroinflammation. 2017 Apr 21;14(1):88. doi: 10.1186/s12974-017-0862-1. PMID: 28427412; PMCID: PMC5399344.
58. Morrison BE, Marcondes MC, Nomura DK, Sanchez-Alavez M, Sanchez-Gonzalez A, Saar I, Kim KS, Bartfai T, Maher P, Sugama S, Conti B. Cutting edge: IL-13Rα1 expression in dopaminergic neurons contributes to their oxidative stress-mediated loss following chronic peripheral treatment with lipopolysaccharide. J Immunol. 2012 Dec 15;189(12):5498-5502. doi: 10.4049/jimmunol.1102150. Epub 2012 Nov 19. PMID: 23169588; PMCID: PMC3545403.
59. Tatton WG, Chalmers-Redman R, Brown D, Tatton N. Apoptosis in Parkinson's disease: signals for neuronal degradation. Ann Neurol. 2003;53 Suppl 3:S61-70; discussion S70-72. doi: 10.1002/ana.10489. PMID: 12666099.
60. Kwon OC, Song JJ, Yang Y, Kim SH, Kim JY, Seok MJ, Hwang I, Yu JW, Karmacharya J, Maeng HJ, Kim J, Jho EH, Ko SY, Son H, Chang MY, Lee SH. SGK1 inhibition in glia ameliorates pathologies and symptoms in Parkinson disease animal models. EMBO Mol Med. 2021 Apr 9;13(4):e13076. doi: 10.15252/emmm.202013076. Epub 2021 Mar 1. PMID: 33646633; PMCID: PMC8033538.
61. Booth HDE, Wessely F, Connor-Robson N, Rinaldi F, Vowles J, Browne C, Evetts SG, Hu MT, Cowley SA, Webber C, Wade-Martins R. RNA sequencing reveals MMP2 and TGFB1 downregulation in LRRK2 G2019S Parkinson's iPSC-derived astrocytes. Neurobiol Dis. 2019 Sep;129:56-66. doi: 10.1016/j.nbd.2019.05.006. Epub 2019 May 11. PMID: 31085228.
62. Gomes-Duarte A, Lacerda R, Menezes J, Romão L. eIF3: a factor for human health and disease. RNA Biol. 2018 Jan 2;15(1):26-34. doi: 10.1080/15476286.2017.1391437. Epub 2017 Nov 13. PMID: 29099306; PMCID: PMC5785978.
63. Kadoguchi N, Okabe S, Yamamura Y, Shono M, Fukano T, Tanabe A, Yokoyama H, Kasahara J. Mirtazapine has a therapeutic potency in 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-induced mice model of Parkinson's disease. BMC Neurosci. 2014 Jun 25;15:79. doi: 10.1186/1471-2202-15-79. PMID: 24965042; PMCID: PMC4076436.
64. Kikuoka R, Miyazaki I, Kubota N, Maeda M, Kagawa D, Moriyama M, Sato A, Murakami S, Kitamura Y, Sendo T, Asanuma M. Mirtazapine exerts astrocyte-mediated dopaminergic neuroprotection. Sci Rep. 2020 Nov 26;10(1):20698. doi: 10.1038/s41598-020-77652-4. PMID: 33244123; PMCID: PMC7693322.
65. Yssel JD. Treatment with the noradrenaline re-uptake inhibitor atomoxetine alone and in combination with the α2-adrenoceptor antagonist idazoxan attenuates loss of dopamine and associated motor deficits in the LPS inflammatory rat model of Parkinson’s disease. Brain, behavior, and immunity. 2018;69:456-469. https://tinyurl.com/4mmjeb7h
66. Af Bjerkén S, Stenmark Persson R, Barkander A, Karalija N, Pelegrina-Hidalgo N, Gerhardt GA, Virel A, Strömberg I. Noradrenaline is crucial for the substantia nigra dopaminergic cell maintenance. Neurochem Int. 2019 Dec;131:104551. doi: 10.1016/j.neuint.2019.104551. Epub 2019 Sep 19. PMID: 31542295.
67. Yao N, Wu Y, Zhou Y, Ju L, Liu Y, Ju R, Duan D, Xu Q. Lesion of the locus coeruleus aggravates dopaminergic neuron degeneration by modulating microglial function in mouse models of Parkinson׳s disease. Brain Res. 2015 Nov 2;1625:255-274. doi: 10.1016/j.brainres.2015.08.032. Epub 2015 Sep 3. PMID: 26342895.
68. Song S, Wang Q, Jiang L, Oyarzabal E, Riddick NV, Wilson B, Moy SS, Shih YI, Hong JS. Noradrenergic dysfunction accelerates LPS-elicited inflammation-related ascending sequential neurodegeneration and deficits in non-motor/motor functions. Brain Behav Immun. 2019 Oct;81:374-387. doi: 10.1016/j.bbi.2019.06.034. Epub 2019 Jun 24. PMID: 31247288; PMCID: PMC6754798.
69. Parlato R, Kreiner G. Nucleolar activity in neurodegenerative diseases: A missing piece of the puzzle? J Mol Med (Berl). 2013 May;91(5):541-547. doi: 10.1007/s00109-012-0981-1. Epub 2012 Nov 20. PMID: 23179684; PMCID: PMC3644402.
70. Boulon S, Westman BJ, Hutten S, Boisvert FM, Lamond AI. The nucleolus under stress. Mol Cell. 2010 Oct 22;40(2):216-227. doi: 10.1016/j.molcel.2010.09.024. PMID: 20965417; PMCID: PMC2987465.
71. Lindström MS, Jurada D, Bursac S, Orsolic I, Bartek J, Volarevic S. Nucleolus as an emerging hub in maintenance of genome stability and cancer pathogenesis. Oncogene. 2018 May;37(18):2351-2366. doi: 10.1038/s41388-017-0121-z. Epub 2018 Feb 12. PMID: 29429989; PMCID: PMC5931986.
72. Pfister AS. Emerging role of the nucleolar stress response in autophagy. Frontiers in cellular neuroscience. 2019;13:156. https://tinyurl.com/2p8rkvhn
73. Yang K, Yang J, Yi J. Nucleolar Stress: hallmarks, sensing mechanism and diseases. Cell Stress. 2018 May 10;2(6):125-140. doi: 10.15698/cst2018.06.139. PMID: 31225478; PMCID: PMC6551681.
74. Rieker C, Engblom D, Kreiner G, Domanskyi A, Schober A, Stotz S, Neumann M, Yuan X, Grummt I, Schütz G, Parlato R. Nucleolar disruption in dopaminergic neurons leads to oxidative damage and parkinsonism through repression of mammalian target of rapamycin signaling. J Neurosci. 2011 Jan 12;31(2):453-460. doi: 10.1523/JNEUROSCI.0590-10.2011. PMID: 21228155; PMCID: PMC6623444.
75. Sönmez A, Mustafa R, Ryll ST, Tuorto F, Wacheul L, Ponti D, Litke C, Hering T, Kojer K, Koch J, Pitzer C, Kirsch J, Neueder A, Kreiner G, Lafontaine DLJ, Orth M, Liss B, Parlato R. Nucleolar stress controls mutant Huntington toxicity and monitors Huntington's disease progression. Cell Death Dis. 2021 Dec 8;12(12):1139. doi: 10.1038/s41419-021-04432-x. PMID: 34880223; PMCID: PMC8655027.