Role of Phytoconstituents as PPAR Agonists: Implications for Neurodegenerative Disorders

Abstract

1. Introduction

Nuclear receptors (NRs) are a class of ligand-dependent transcription factors that govern a variety of biological processes, such as cell proliferation, growth, reproduction, metabolism, and inflammation when activated by a specific ligand [1,2]. This superfamily of NRs includes peroxisome proliferator-activated receptors (PPARs), steroid hormone receptors, thyroid hormone receptors, vitamin D3 receptors, and retinoic acid receptors [3]. However, ligands of some NRs are yet to be discovered, earning them the moniker “orphan receptors” [4]. Recent research on NRs has revealed that when these receptors bind to specific ligands, they undergo conformational changes, bind to specific DNA sequences throughout the genome, and activate or inhibit target gene expression [4,5,6,7]. Moreover, NRs are known to regulate hundreds of cellular pathways and hence their activity could influence the pathophysiology of a range of diseases [8,9,10]. Their role in disease regulation has piqued the interest of researchers, prompting them to investigate these receptors in relation to various diseases and discover novel natural or synthetic compounds that could either act as agonists or antagonists of these receptors, thereby regulating their altered function in various diseases. Among the various NRs investigated thus far, PPARs have been shown to play an important role in various diseases such as neurodegenerative, inflammatory, and cardiovascular disorders, as well as diabetes and cancers. Several reviews have been published in recent years describing the therapeutic potential of natural and/or synthetic PPAR agonists in a variety of disorders, including neurodegenerative, cardiovascular, diabetes, and cancer. However, a detailed report outlining the role of naturally produced phytoconstituents as PPAR agonists for neurodegenerative disorders has yet to be published. Thus, the aim of this review is to provide a comprehensive discussion of phytoconstituents as PPAR agonists and their importance in neurodegenerative disorders.

2. PPARs Isoforms and Their Distribution across the Nervous System

PPAR gamma (PPARγ), PPAR alpha (PPARα), and PPAR beta/delta (PPAR β/δ, also known as PPARδ) [11], are three isoforms of PPARs that are expressed throughout the brain during development, although PPARα and PPARγ expression levels decline over time and become limited to specific brain locations [12].

PPARα (52 kDa) is primarily found in the basal ganglia, reticulum formation, certain mesencephalic, thalamic, and cranial motor nuclei, and the spinal cord [13]. Additionally, it has also been found in dopaminergic and spiny neurons in the substantia nigra and dorsal striatum, and is vital for controlling behavioral responses [14,15,16]. PPARα has also been discovered in oligodendrocytes, microglia, and astrocytes [17,18,19]. Previous studies have suggested that PPAR activation contributes to neuroprotection by delivering antioxidative and anti-inflammatory actions [20,21].

PPARγ (58 kDa) is found in various parts of the brain, including the ventral target area, nucleus accumbens, amygdala, and hippocampus, which are primarily involved in the modulation of reward mechanisms, mood, and learning [13]. PPARγ activation has also been reported to exert neuroprotective and anti-inflammatory effects by inhibiting the nuclear factor kappa-light-chain-enhancer of activated B-cell signaling (NF-κB signaling), activator protein 1 (AP-1), signal transducer and activator of transcription (STATs), and inducible nitric oxide synthase (iNOS) [22]. PPARγ is the most extensively researched PPAR isoform [23].

PPARβ/δ (50 kDa) is widely expressed, and its bioactivity is coordinated with that of PPARα and PPARγ. PPARβ/δ is expressed in neurons, astrocytes, oligodendrocytes, and microglial cells, according to recent studies [22,24]. Similar to the other two isoforms of PPARs, PPARβ/δ have been reported to have anti-inflammatory, antioxidant, and anti-cancer properties. They also play an important role in the regulation of cell cycle and cell death inhibition. However, when compared to the other two PPAR isoforms, PPARβ/δ have received lesser attention [25,26].

3. PPARs-Structure and Mechanism of Action

PPARs have a three-dimensional structure that comprises four different domains: (1) A/B contains the ligand-independent activation function 1 (AF1) and is involved in transcription activation; (2) C is a DNA-binding domain that binds to peroxisome proliferator response elements (PPRE); (3) D controls the receptor’s ability to bind to DNA and co-repressor binding; and 4) the carboxy-terminal E/F domain is a ligand-binding domain (LBD) containing a ligand-binding pocket (LBP), a ligand-dependent activation function (AF-2), and a region for heteromerization with retinoid-X-receptor (RXR) (Figure 1a) [27,28].

PPARs can regulate transcriptional activity directly through two mechanisms. In the first mechanism, PPARs, as a ligand-dependent transcription factor, bind to DNA in the promoter region of genes with sequences known as PPREs. PPAR needs to form a heterodimer with RXR to bind to specific DNA sequences (PPRE) in the promoter region of target genes. This heterodimer exists in a repressor form until the presence of its ligand and can be activated either way, through RXR agonist and PPAR agonist, and the presence of both ligands shows a synergistic effect [29]. Second, transcription factors influence gene expression by interacting with activator proteins, independent of PPREs [30] (Figure 1b). Thus, PPARs can regulate the expression of various genes involved in metabolic pathways. Additionally, PPAR activity can also be controlled by various post-translational modifications such as phosphorylation, small ubiquitin-like modifier (SUMO) phosphorylation, ubiquitination, acetylation, and O-linked-N-acetylglucosaminylation (Figure 1b) [31]. Although they are co-expressed in several different tissues or organs, each possesses its own ligand specificity and functional characteristics. They can sense a variety of endogenous lipids such as unsaturated, mono, and polyunsaturated fatty acids, as well as natural exogenous compounds [32].

4. Neurodegenerative Disorders (NDDs) and Role of PPARs

Neurodegenerative disorders are a serious threat to human health. These age-related diseases have become more common owing to an increase in the senior population in recent years [33]. Neurodegenerative disorders, characterized by slow and cumulative neuron loss and neuronal function decrease, frequently result in cognitive and behavioral dysfunction, as well as a significant reduction in the quality of life of the patient. Examples include neuroinflammation, cerebral ischemia, Alzheimer’s disease (AD), multiple sclerosis (MS), Parkinson’s disease (PD), Huntington’s disease (HD), and autoimmune encephalitis (AE) [34]. Drugs for the treatment of neurodegenerative disorders have limited efficacy because of their complicated origins and pathophysiology. Multiple risk factors, including environmental and genetic factors, contribute to vulnerability, in addition to aging.

Neuroinflammation is a term used to describe the complex immune system defense mechanism used in response to several stimuli in the central nervous system. It is marked by the activation of astrocytes and microglia and local immune cell invasion by the release of cytokines and pro-inflammatory molecules, which reverts to normal with the aid of endogenous anti-inflammatory cytokines [35,36]. Under normal circumstances, neurons and astrocytes regulate microglial activation [37]. However, under pathological conditions, including neuronal damage or cell death, repressive action is rendered ineffective. Neuroinflammation mediated by microglia is a key feature of neurodegenerative diseases [38,39], and substantial evidence suggests that inflammation pathways play an important role in the etiology of neurodegenerative disorders [12]. Neuroinflammation also impairs the ability of the brain to generate new neurons [40]. Thus, neuroinflammation could be a potential target for treating neuroinflammatory/neurodegenerative diseases, and several therapeutic approaches may be targeted to mitigate these deleterious effects.

Several research and review articles published in recent years have provided information on different naturally isolated and identified PPAR agonists that have been investigated and studied for their specific receptors targeting different disorders [41]. The existence, location, and neuroprotective function of PPARs in the CNS were thoroughly addressed by Zolezzi et al. [42]. All three PPARs were found to have distinct effects on the CNS. For example, PPARα, has been related to neuroinflammation and ischemia/reperfusion in certain studies and has been shown to be expressed in diverse regions of the CNS [43,44]. Several in vitro and in vivo studies involving PPAR agonist/antagonist and knockout mice have revealed the significant role of PPARα in anti-inflammation and neuroprotection [45]. PPARγ has been associated with anti-inflammatory activity and brain metabolite balance [46,47,48]. It is believed to induce neuronal differentiation and neutrite outgrowth [49,50]. Because of their diverse roles discovered in various studies, they have been suggested as therapeutic agents in the treatment of CNS disorders such as AD, PD, HD, ischemia/reperfusion injury, and depression [43,51,52,53]. However, only a few studies have focused on the role of PPARβ/δ, which represents their antioxidative and anti-inflammatory functions [54]. As PPAR agonists have gained significant attention in clinical trials and research, the focus of this review will be on phytoconstituents that exhibit direct or indirect PPAR activity [55]. It is crucial to remember that both antagonists and inverse agonists are potentially helpful novel medications with clinical potential.

5. Literature Search Strategy

A literature search was carried out using Google Scholar, PubMed, and Science direct repositories for related findings between January 2004 and May 2021. The following keywords were used to find the relevant information regarding the role of natural compounds as PPAR agonist in neurological disorder: “Natural compounds as PPAR agonist” or “PPAR Agonist” or “PPAR agonists and Neurodegenerative disorders“ or “Role of natural compounds as PPAR agonist in neurodegenerative disorders” or “PPARs in neurological diseases” or Natural ligands for PPARs” or Effects of natural compounds in neurological disorders” or “Neuroinflammation and PPARs” or “ Anti-inflammatory role of natural compounds in neurological disorders”. There are 282 publications in total in this review paper, comprising 156 research articles and 126 review papers.

6. Natural Compounds as PPAR Agonists

PPARα, PPARγ, and PPARβ/δ synthetic agonists have been shown to have protective effects in a variety of neurological illness models. Currently, there are 18 clinically approved synthetic PPAR agonists for illnesses such as diabetes, hyperlipidemia, and heart disease [95]. For NDDs, rosiglitazone, pioglitazone, indomethacin, DSP-8658, thiazolidinedione, ibuprofen, fenofibrate, bezafibrate, GW0742, l-165041, and other synthetic agonists that inhibit disease progression have been reviewed before for PD, AD, HD, and amyotrophic lateral sclerosis (ALS) [96]. To the best of our knowledge, no thorough evaluation of phytoconstituents as natural PPAR agonists and their prospective implications has been published thus far. Therefore, this study is the first to summarize the pharmacological effects of various phytoconstituents on neurodegenerative disease prevention. The neuroprotective properties of these natural agonists might be related to their anti-inflammatory properties and the capacity to regulate cell signaling pathways.

7. Phytoconstituents’ Other Modes of Action in NDDs

Although this review concentrated on phytoconstituents’ PPAR-mediated bioactivities, there are lot of alternative methods by which these phytoconstituents exert their positive effects in various NDDs. Below is a quick description of the other modes of action of these phytoconstituents, including new findings:

Biochanin A has also been found to provide neuroprotection in glutamate-induced cytotoxicity in PC12 cells by inhibiting apoptosis by decreasing LDH and caspase-3 activity [241], protecting dopaminergic neurons against LPS-induced damage by inhibiting microglia activation and proinflammatory factor generation [242], triggers LPS-induced production of nitric oxide, NF-κB p65, TNF-α, IL-1β, IL-6, PGE2, and ROS in BV-2 cells [243], and alleviating rotenone-induced neurotoxicity in mice by enhancing PI3K/Akt/mTOR signaling and Bcl-1 production [244]. Icariin was found to target Nrf2 signaling to inhibit microglia-mediated neuroinflammation [245], regulating Aβ-enhanced phosphatase and tensin homologue deleted on chromosome 10 protein levels, leading to an improvement in Aβ-induced insulin resistance [246], enhancing neuronal autophagy through the AMPK/mTOR/ autophagy initiating factor uncoordinated-51 like kinase 1 (ULK1) pathway and preventing brain function decline in aging rats [247].

Luteolin-7-O-glucoside was found to protect neurons through activation of the estrogen-receptor-mediated signaling pathway in 1-methyl-4-phenyl-1, 2, 3, 6-tetrahydropyridine-induced mice [248]. Naringenin was shown to target mitochondrial membrane potential, and higher ATP levels and paraquat-induced mRNA expressions of dopamine receptor, dopamine transporter, leucine-rich repeat kinase 2, alpha-synuclein, β-catenin, caspase-3, and BDNF genes [249], and upregulated AMPK-mediated autophagy to prevent neuronal cells from β-Amyloid (1–42) evoked neurotoxicity [250].

Chrysin was found to be involved in alleviating PD pathology as an anti-inflammatory and anti-oxidant agent, together with modifying S100B, BDNF, nerve growth factor (NGF) and glial cell line-derived neurotrophic factor levels [251], Nrf2, which reduces NO, activates myocyte enhancer factor 2D, a critical transcription factor involved in dopaminergic survival. It inhibits MPP-induced upregulation of cleaved-caspase and Bax as well as downregulation of the anti-apoptotic protein Bcl-2 [252], normalizes acetylcholinesterase and butyrylcholinesterase activities, and oxidative damage such as lipid peroxidation, protein carbonylation, catalase, and superoxide dismutase impairment [253]. Cy-3-G was found to regulate Nrf2 mediated oxidative stress [254], and galangin has been shown to suppress protein kinase dependent AP-1, activate forkhead box protein O1, and inhibit LPS-induced MMP-9 expression in rat brain astrocytes [255].

PUFAs were discovered to be involved in cytochrome P450 metabolism in NDDs [256], lysophosphatidylcholine-DHA/EPA-enriched diets were discovered to modulate brain DHA and behavior in mice expressing APOE4 [257], ALA was discovered to suppress GFAP, NF-κB, and IL-1 and modulate Bax, Bcl-2, and caspase-3 activities [258] and induced insulin and insulin-like growth factor I secretion from astrocytes in Aβ-induced SH-SY5Y cells [259]. In addition to these, there are number of studies reported during the recent years, which highlighted the role of natural cannabinoids as well as synthetic cannabinoid receptor agonists in NDDs [260,261].

Other compounds such as curcumin have also been found to modulate lipid peroxidation, HO-1 levels, suppression of malondialdehyde (MDA) levels, increasing glutathione and CAT and Nrf2 activities to produce neuroprotective or anti-ageing effects in different models of NDDs [262], capsaicin decreased brain MDA whereas increased GSH and paraoxonase-1 activity in pentylene-tetrazole-induced Seizures [263], piperamide was found to inhibit NF-κB translocation [264] and activated the Nrf2/HO-1 pathway to induce anti-inflammation in different neuroinflammatory disease models [265]

8. In Vitro Studies from Patient’s Sample and Clinical Data

In addition to in vitro and in vivo research based on phytoconstituents as PPAR agonists, a few studies have evaluated samples from patients with neurodegenerative illnesses to report their effects. Nasl-Khameneh et al. [266] published a study that found that DHA and all-trans retinoic acid (ATRA) had synergistic effects in treating MS. Peripheral blood mononuclear cells (PBMCs) were treated with DHA (15 μM) and ATRA (1 μM) alone and in combination, except for the control (DMSO). Both IL-17 (p = 0.02) and RORγt (p = 0.01) (transcription factor) were shown to be inhibited by combined treatment with ATRA and DHA, which could be considered as a beneficial outcome, as IL-17 and RORγt were found to be upregulated in MS patients, particularly during clinical exacerbations [267]. Despite the lack of direct evidence for PPARγ participation, the authors postulated that DHA could act as a PPARγ and RXR agonist in their investigation, which was consistent with previous findings [268,269]. These data suggest that PUFAs and vitamin A may be suitable targets for future research and therapeutic intervention efforts. Because this in vitro study was conducted on PBMCs from patients with relapsing-remitting MS (RRMS), more extensive trials will be required to expand these findings.

Fu et al. [270] reported that DHA and Asp have neuroprotective synergistic effects on PD by inhibiting miR-21 and activating RXRα and PPARα. SH-SY5Y cells and PBMCs were collected from blood samples of 15 PD patients. It has been established that miR-21 plays a significant role in human tumor progression and in managing peripheral nerve injury by stimulating axon production [271,272]. The authors’ initial aim was to determine the function of miR-21 in the nervous system. The results showed that the expression of PPARα was substantially lower in PD patients than in the general population, and no significant difference was found with RXRα, and miR-21 was negatively correlated with PPARα. In SH-SY5Y cells, DHA supplementation downregulated miR-21, which upregulated PPARα expression, a transcription factor that stimulates the production of neuroprotective factors such as BDNF and glial derived neurotrophic factor and inhibits NF-κB. According to these findings, decreasing miR-21 levels decreases inflammation and improves neuroprotection.

In addition to in vitro research using patient samples, the review includes a few clinical investigations of the selected compounds). In a study of 402 patients with mild to moderate AD treated with 2 g of dose/placebo for 18 months, no differences were observed in the cognitive decline in patients with AD [273]. In a 24-wk randomized, double blind, placebo-controlled trial, curcumin C3 complex^® 2 gm/day, or 4 gm/day placebo vs. curcumin in patients with mild-to-moderate AD. In this preliminary study, no significant outcomes were reported [274]. Another study evaluated the effect of a commercial product Sativex^®, a mixture of cannabidiol and Δ⁹-THC on 24 patients with HD for 12 weeks, Sativex^® vs. placebo, 12 oral sprays/day. No significant findings were observed [275]. All these studies have been completed.

9. Drosophila in Translational Medicine

The genomes of Drosophila melanogaster (commonly known as fruit fly) and mammals have a high degree of homology, allowing Drosophila to be used in translational medicine. Drosophila has been regarded as an excellent model for research in a variety of domains, including medicine, developmental biology, and neurology. The dopaminergic system in Drosophila is quite similar to the human system, and dopaminergic cells make up a small percentage of neurons in both the brains of flies and mammals [276]. Two studies have evaluated the importance of Drosophila as a model organism for investigating AD [277] and PD [278]. There have also been studies linking the effects of various drugs in a Drosophila neurodegenerative model to the activation of PPARs.

In a Drosophila model of amyotrophic lateral sclerosis (ALS) based on TDP-43 (TAR DNA-binding protein 43), activation of PPARγ was found to generate neuroprotective benefits [279]. The PPARγ agonist pioglitazone was found to protect Drosophila motor neurons and glia against TDP-43-dependent locomotor impairment. It was also found to be neuroprotective in ALS models of Drosophila when FUS, rather than SOD1, is expressed in motor neurons. E75 and E78 were identified as in vivo targets of pioglitazone using pharmacogenetic methods. In the context of TDP-43 expression in motor neurons, metabolic methods allowed the identification of several metabolites that pioglitazone can restore. Although PPARγ activation did not prolong longevity in Drosophila, it did reveal molecular targets for avoiding locomotor impairment in TDP-43 and FUS models of ALS [279].

Overall, the findings from testing PPARs’ natural agonists (such as FAs, flavonoids, curcumin, and others) in various neurological disorders support PPAR-γ, PPAR-α, and PPAR-β (few studies) as potential novel targets for the therapeutic management of common and debilitating conditions such as AD and PD. Few clinical studies have been reported; hence, more clinical trials are needed to prove the efficacy and safety of these natural PPAR agonists. Given the risks associated with synthetic agonist treatment, it is important to investigate alternative administration routes, as well as altering drug doses and delivery. A better understanding of the molecular mechanism of PPAR’s participation in neuroinflammation, which is emerging as a common process in neurodegenerative illnesses, as well as their activation by endogenous ligands, which can also be introduced by food sources, is also required.

10. Conclusions and Future Implications

In summary, phytoconstituents as PPAR agonists could be valuable potential therapeutic targets for a variety of neurodegenerative disorders, because data based on in vivo and in vitro models of neurodegenerative disorders support the beneficial effects of PPAR agonists. In addition, it is easy to introduce natural products containing active compounds into the diet because they are common, so they can be used prophylactically throughout life. However, additional research is required to completely understand the potency of PPAR agonists for clinical tests, as well as the processes through which PPAR confers its preventive effects. Nonetheless, as PPAR-based curative treatment cannot entirely slow disease development, blends of other active ingredients with PPAR agonists may provide a superior therapeutic alternative for neuroprotection. Additionally, efforts will need to focus on other phytoconstituents whose pharmacology is currently being investigated. Future research could focus on combining PPAR agonists with a synbiotic and probiotic mixture [280,281], and using the fruit fly (Drosophila melanogaster) as a model organism to explore the effects of PPAR agonists [282]. In addition to experimental approaches, multiple methodologies, such as system biology, machine learning, and other bioinformatics tools, can be used to identify and characterize phytoconstituents as new PPAR agonists.

Author Contributions

Conceptualization, H.-J.L., A.S. and Sanjay; writing—original draft preparation, Sanjay, A.S. and H.-J.L.; writing—review and editing, H.-J.L., A.S., Sanjay; Supervision, H.-J.L.; funding acquisition, H.-J.L. All authors have read and agreed to the published version of the manuscript.

Funding

This study was supported by the Cooperative Research Program of the Center for Companion Animal Research (Project No. PJ01476703), funded by the Rural Development Administration, Republic of Korea.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

Footnotes

References