The role of the brain renin-angiotensin system in Parkinson´s disease

Several major processes such as oxidative stress, neuroinflammation, and accumulation of α-synuclein aggregates are involved in the dopaminergic neurodegeneration in PD. However, their order of appearance is not clear and it remains unknown which of them acts first. It is frequently suggested that α-synuclein aggregation and Lewy body pathology are the initial processes triggering neurodegeneration. However, molecular and cellular changes originating from different genetic and/or environmental triggers may occur before α-synuclein aggregation, particularly affecting the most vulnerable neurons [177, 178]. An initial impairment in dopamine metabolism [179], a decrease in tyrosine hydroxylase [180], oxidative damage [181], and early neuroinflammation [182] have been suggested as initial triggers of the disease. Dysregulation of the brain RAS, and particularly, over-activation of the AngII/AT1 receptor axis are involved in all these potential triggering processes, and may be an early mechanism mediating the progression of dopaminergic neuron degeneration. However, the next question could be what the cause for the RAS dysregulation is (Table 1).

First, an initial decrease in dopamine levels (Fig. 2), due to dopamine homeostasis dysregulation, may lead to a compensatory increase in AngII/AT1 receptor activity to normalize dopamine levels. This may occur in the very initial stages of PD, aging, and other situations that have been associated with an increased risk of developing PD (see below). AngII/AT1 receptor overactivity may lead to a transitory upregulation of dopamine levels [67, 99, 100, 102, 134]. However, the AngII/AT1 receptor axis upregulation may simultaneously promote oxidative stress, neuroinflammation, and α-synuclein aggregation through increased NADPH-oxidase activity and alteration of intracellular calcium homeostasis. Furthermore, it is well known that dopamine is an immunomodulatory molecule, that dopamine receptors are present in immune effector cells [135, 136], and that dopamine inhibits NLRP3 inflammasome via dopamine receptors in several cell types [137, 138]. Therefore, an initial decrease in dopamine or dopaminergic function may enhance the inflammatory response, and upregulation of the pro-inflammatory RAS axis appears to be involved in this process (Fig. 2). Consistent with this, we have recently shown that dopamine regulates RAS activity in glial cells, modulating AngII release by astrocytes and the expression of angiotensin receptors in microglia [102]. Dopaminergic neurotoxins such as MPP⁺ can increase the release of angiotensinogen and AngII from astrocytes. However, dopamine, via type-2 (D2) receptors, down-regulates the production of angiotensinogen and the expression of AT1 receptors while increasing the expression of AT2 receptors in astrocytes. In microglia, dopamine administration induces downregulation of the AT1/AT2 ratio and inhibits the inflammatory response [102]. Furthermore, recent studies showed that AT1 receptors mediate microglial inflammasome complex activation in dopamine-depleted models [140].

Consistent with the role of RAS dysregulation in PD progression, overactivity of the pro-oxidative/pro-inflammatory AngII/AT1 receptor axis has been observed in several processes described below, which are known to increase the risk of PD.

Different studies have shown that aging increases the vulnerability of dopaminergic neurons to degeneration. Advanced age is the first risk factor for PD and other neurodegenerative diseases. It has been shown that the pro-inflammatory and pro-oxidative state associated with aging (inflammaging) [183, 184] may favor the development of degenerative diseases [185, 186]. As RAS is involved in the neuroinflammatory response, the AngII/AT1 receptor upregulation in the nigrostriatal system may be a factor for increased dopaminergic vulnerability with aging. In aged male rats (see below for aged females), we observed higher levels of neuroinflammatory and oxidative markers in the SN and striatum, and an increase in the dopaminergic neuron death triggered by dopaminergic neurotoxins, which are downregulated by the AT1 receptor antagonist candesartan [99, 141]. AT1 receptor inhibition also ameliorates the upregulation of the NLRP3 inflammasome observed in aged rats [140, 187]. Aging-related upregulation of the pro-inflammatory axis components such as AT1 receptors and prorenin receptors has also been observed [89, 99, 142]. In dopaminergic neurons, this may be mediated by an age-related decrease in dopaminergic activity and the already mentioned RAS compensatory changes. Consistent with this, several studies have shown a loss of striatal D2 and D1 receptors in aged animals and humans [143, 144], and that the dopaminergic system is altered during normal aging [145, 146]. However, other non-dopaminergic factors appear also involved, as the age-related upregulation of the pro-oxidative/pro-inflammatory RAS has also been observed in other tissues apparently unrelated with the dopaminergic systems [147‐149]. Interestingly, aged animals also show a decrease in the expression of components of the RAS anti-inflammatory axis, such as AT2 or Mas receptor expression, not only at the level of the cell membrane but also in the intracellular RAS system detailed below [35, 56, 57], revealing a decrease in the compensatory response of the RAS anti-inflammatory axis that contributes to the aging-related RAS imbalance.

Menopause is also a risk factor for PD, as the incidence and the prevalence of the disease are higher in men and postmenopausal women than in premenopausal women of similar age [188, 189]. Over the last few decades, different experimental studies have reported the beneficial effects of estrogen against dopaminergic neurodegeneration [190, 191], and shown that the anti-inflammatory effects of estrogen are responsible for the neuroprotective effects [192, 193]. The beneficial effects of estrogen replacement therapies are more controversial [194, 195], with age and the period without estrogen before receiving the replacement treatment as underlying factors for the discrepancies. As estrogen-induced regulation of the RAS has been suggested to mediate the beneficial effects of estrogen in several peripheral tissues [150, 151], we studied the effects of the lack of estrogen on the nigrostriatal RAS in female rats with early surgical menopause (young ovariectomized rats) and natural menopause (aged rats) [152‐155]. The activity of the RAS pro-oxidative/pro-inflammatory arm was increased in both groups of menopausal rats. Interestingly, treatment with the AT1 receptor blocker candesartan reduced the loss of neurons induced by low doses of dopaminergic neurotoxins in both groups of menopausal rats; however, the neuroprotection of the replacement therapy was effective only in the young rat groups [154]. We observed that there is a critical period for the neuroprotection with estrogen against dopaminergic neurodegeneration and that the local RAS plays a major role, as treatment with the AT1 receptor antagonist candesartan provided significant neuroprotection beyond the critical period for estrogen, [152]. The brain RAS system may be an efficient therapeutic target for the treatment or prevention of PD in estrogen-deficient women, together with or substituting estrogen replacement therapies [152].

Interestingly, recent studies have shown that levels of estrogen are not the only factor responsible for the reduced activity of the RAS pro-inflammatory axis in the nigrostriatal system of females relative to males and that the expression of the anti-inflammatory AT2 receptors is higher in females, independently of circulating levels of estrogen and probably related with the sex chromosome complement effects, which contribute to attenuate the inflammatory response [30].

Chronic brain hypoperfusion has also been related to an increased risk of neurodegeneration and PD [157, 158, 196]. This is consistent with previous studies in animal models showing that brain hypoperfusion enhances the neuronal loss induced by dopaminergic neurotoxins, together with the nigrostriatal expression of inflammatory markers such as IL-1β and increased oxidative stress such as increased NADPH-oxidase activity [159]. Interestingly, the hypoperfusion-induced changes are accompanied by upregulation of the AngII/AT1 receptor activity in the SN, and these changes are downregulated by chronic treatment with the AT1 receptor blocker candesartan [159].

Autoimmune processes have also been involved in the triggering and progression of degenerative diseases, including PD [197‐199]. We have recently observed an increase in the serum levels of autoantibodies for AT1 receptors (AT1 receptor agonistic autoantibodies, AT1-AA) and ACE2 autoantibodies (ACE2 antagonists) in PD patients compared to non-PD controls. We also found both autoantibodies in the CSF samples from some PD patients [80]. Furthermore, there was a significant correlation between serum levels of AT1-AA and serum inflammatory cytokines in PD patients but not in controls. In parallel experiments, using in vivo and in vitro PD models, we confirmed that these autoantibodies are associated with the neurodegenerative process and the accompanying neuroinflammatory changes, and led to further progression of neurodegeneration by increasing the activity of AT1 receptors and decreasing the activity of ACE2-related anti-inflammatory RAS axis, respectively. Consistent with the findings in PD patients, we observed a significant increase of these RAS-related autoantibodies in both serum and CSF of rats lesioned with the dopaminergic neurotoxin 6-OHDA. Furthermore, we confirmed in cultures that administration of AT1-AA increased the loss of dopaminergic neurons, which was inhibited by treatment with the AT1 receptor blocker candesartan [80]. Altogether, these findings suggest that the generation of RAS autoantibodies during early degenerative stages contributes to RAS dysregulation towards the proinflammatory axis and to the increased progression of dopaminergic degeneration and PD. ARBs or treatments that inhibit the generation of these autoantibodies may inhibit these effects.

In addition to the already mentioned risk factors, several peripheral diseases related to chronic inflammation, appear to increase the risk of neurodegenerative diseases including PD [200, 201]. MetS has been associated with chronic peripheral inflammation and increased risk of PD [202, 203]. As in the case of neurodegenerative diseases, MetS can be currently considered a silent epidemic disease. The definition of MetS consists of the presence of obesity and at least 2 of the following conditions: hypertension, hypertriglyceridemia, low HDL cholesterolemia, and type-2 diabetes/hyperglycemia [204]. In a rat model, we showed that MetS leads to the upregulation of the pro-oxidative/pro-inflammatory RAS axis in the SN, together with increases in oxidative stress, neuroinflammatory markers, and dopaminergic neurodegeneration, and all these changes were decreased by treatment with ARBs [81]. In rats, MetS also increases the circulating levels of major pro-inflammatory cytokines and 27-hydroxycholesterol. Interestingly, serum levels of pro-inflammatory AT1 and ACE2 autoantibodies are increased and correlated with several MetS parameters. AT1 and ACE2 autoantibodies are also present in the CSF of these rats. Osmotic minipump infusions of AT1 receptor autoantibodies disrupt BBB and affect the brain, leading to upregulation of the pro-inflammatory RAS activity in the SN and a significant increase in dopaminergic neurodegeneration in two different rat PD models [81]. Activation of AT1 endothelial receptors by the circulating agonistic AT1 receptor autoantibodies appears as a major mechanism of BBB disruption. This is consistent with several previous studies showing that stimulation of AT1 receptors in endothelial cells and perivascular macrophages by circulating AngII, but not hypertension itself, is a major mechanism of the BBB disruption observed in hypertension. Consistently, the disruption can be blocked by AT1 receptor blockers (ARBs) and not by other anti-hypertensive drugs [205‐209]. In MetS patients, previous studies have also observed increases in the levels of pro-inflammatory cytokines [210, 211] and BBB permeability [212, 213], which were attributed to the increase in circulating cytokines. However, the increase in circulating agonistic AT1 receptor autoantibodies may also play a major role in BBB disruption, as patients with MetS show significantly higher levels of AT1 receptor autoantibodies, which lead to dysregulation of the SN RAS as observed in the MetS rat model [81]. In addition, circulating levels of AT1 receptor autoantibodies are significantly higher in non-Parkinsonian patients with MetS than in non-Parkinsonian patients without MetS. However, no significant difference has been observed between Parkinsonian patients with and without MetS, both showing higher levels of AT1 receptor autoantibodies than normal controls. This may be because dopaminergic degeneration and neuroinflammation in PD patients (without MetS) also lead to an increase in circulating autoantibodies [80], as detailed above. In MetS patients, both processes may trigger a vicious cycle that accelerates PD progression, which may be blocked by strategies against generation of these autoantibodies or by AT1 receptor blockers.

Additional mechanisms may be involved in the association between MetS and PD. Recent results from rat models of MetS suggest involvement of circulating extracellular vesicles (EVs) and their RAS cargo in the link between MetS and PD [81]. EV cargo shows the molecular state of their cells of origin [214], including the cellular level of RAS components [215]. Circulating EVs can cross the BBB and serve as inflammatory mediators [216, 217] and carriers of oxidative stress signals [218]. In the adipose tissues from obese animals, increases of angiotensinogen [219, 220], AT1 receptors [221],and prorenin receptors [222] have been reported. Consistent with this, we have recently observed that in rat models of MetS, EVs are highly increased in the serum and show increased pro-oxidative/pro-inflammatory and decreased anti-oxidative/anti-inflammatory RAS components, as well as increased inflammatory and oxidative stress markers. Interestingly, the increase of serum EVs, the RAS dysregulation and the increases of inflammatory and oxidative stress markers in the EV cargo are inhibited by chronical treatment with theAT1 blocker candesartan in MetS rats [165]. In vitro, administration of EVs isolated from the serum of MetS rats increases dopaminergic cell death and regulates the astrocytic function, leading to the upregulation of neuroinflammation and oxidative stress markers. The effects of treatment with EVs are inhibited by pre-treatment of cultures with the AT1 blocker candesartan [165]. Altogether, in MetS, circulating EVs may contribute, via RAS dysregulation, to the progression of neuroinflammation and dopaminergic cell death. This mechanism can be inhibited by treatment with ARBs such as candesartan.

Many recent studies have suggested the association of gastrointestinal diseases with a higher risk of PD, and revealed the presence of a gut-brain axis. Gut dysmotility is a PD component, although the mechanisms are still unclear. Conversely, the role of gut diseases in PD remains to be clarified. Braak´s hypothesis suggested that PD may be caused by pathogens that act on the gastrointestinal tract, which induce gastrointestinal inflammation and oxidative stress, leading to α-synuclein deposition that is retrogradely transported to the brain [223, 224]. However, the gut-brain axis also regulates the nigrostriatal dopamine homeostasis, via the vagus nerve, as a caloric intake regulatory system [225, 226]. Consistent with this, a decrease in nigrostriatal dopamine level leads to changes in colonic expression of dopamine receptors as well as dopamine and acetylcholine levels in rodents, and experimental gut inflammation leads to changes in the nigrostriatal dopaminergic homeostasis [92]. Those results suggest that the nigrostriatal dopaminergic system and the gastrointestinal system interact bidirectionally and that both brain dopaminergic lesions and gastrointestinal lesions can lead to dysregulation of the functional interaction. This may explain the gastrointestinal alterations observed in PD patients, and the higher vulnerability of central dopaminergic neurons after gastrointestinal inflammation [92]. Several recent studies in rodents and humans support this proposition [227‐229], and brain-first and body-first subtypes of PD have been proposed [228].

Interestingly, the gastrointestinal tract has a local RAS that is involved in major functional processes such as motility, absorption, and gastrointestinal inflammation [166‐168]. The gastrointestinal RAS also plays a role in gut diseases such as inflammatory bowel disease and gastrointestinal motility disorders [167, 168]. As in the case of the nigrostriatal dopaminergic system, mutual regulation between the gastrointestinal dopaminergic and the angiotensin systems has been observed, which may be dysregulated with aging and by different processes, leading to increased vulnerability to gastrointestinal inflammatory diseases [91, 93]. Furthermore, nigrostriatal dopaminergic depletion also leads to upregulation of the pro-inflammatory axis of the gastrointestinal RAS, together with increased gut levels of oxidative stress and pro-inflammatory markers [92]. Conversely, experimental gastrointestinal inflammation leads to changes in dopaminergic homeostasis and upregulation of the pro-inflammatory RAS in the SN, which may contribute to increases in neuroinflammation, dopaminergic neuron vulnerability, and progression towards PD [92, 169].

Recent studies suggest a connection of gut microbiota with neuroinflammatory and neurodegenerative disorders such as Alzheimer's disease and PD, and that intervention on microbiota may provide a novel strategy for treating and preventing neurodegeneration [230]. Although the exact mechanism remains to be clarified, gut microbiota and its metabolites may contribute to PD pathophysiology through modulation of gut inflammation (see above). However, additional mechanisms including the release of short-chain fatty acids or compounds affecting the BBB may also be involved [230].

Interestingly, the RAS, including systemic and gastrointestinal RAS, has emerged as a major mediator of microbiota-derived effects [170, 171]. The microbiota and its metabolites may modulate gastrointestinal and systemic RAS, and RAS alterations may modify microbiota composition and metabolism. In animal models, treatment with microbiota metabolites such as trimethylamine-oxide results in altered expression of RAS receptors in the heart and kidney [170, 172], ACE inhibitory peptides are produced during the bacterial fermentation processes [173], and chronic losartan treatment reduces gut dysbiosis [174]. Consistent with this, the microbiome, acting via RAS regulation, has been related to diabetic-induced kidney injury, hypertension, and organ damage related to hypertension [171, 175]. Interestingly, gut microbiota, via RAS, has been involved in obesity and the development of MetS [176]. As described in a previous section, MetS is related to a higher risk of PD [202, 203], and we have recently shown several potential mechanisms connecting MetS and PD [81, 165].

Given the above-mentioned major role of RAS dysfunction in the inflammatory changes involved in COVID-19, a role of the microbiota/RAS interaction in the pathogenesis and progression of COVID-19 has been suggested [231, 232]. The RAS is suggested to play a pivotal role in inflammatory processes that affect microbiome dysregulation, COVID-19 and the development of PD [233]. As a consequence, prebiotics and probiotics have been suggested for the treatment of RAS-related diseases. Recent studies have shown that probiotics can activate the ACE2/MAS receptor axis [234], and that oral delivery of Ang(1–7)-expressing Lactobacillus paracasei led to significant modification of microbiota and decreased expression of neuroinflammatory genes in the cortex [235]. However, the microbiome-related effects require further clarification in future studies.