Thymosin Beta 4 Protects Hippocampal Neuronal Cells against PrP (106–126) via Neurotrophic Factor Signaling
1
Department of Laboratory Animal Medicine, College of Veterinary Medicine, Jeonbuk National University, Gobong-ro 79, Iksan 54596, Jeollabuk-do, Republic of Korea
2
Knotus Co., Ltd., Incheon 22014, Republic of Korea
*
Author to whom correspondence should be addressed.
†
These authors contributed equally to this work.
Molecules 2023, 28(9), 3920; https://doi.org/10.3390/molecules28093920
Submission received: 15 March 2023
/
Revised: 2 May 2023
/
Accepted: 4 May 2023
/
Published: 6 May 2023
(This article belongs to the Special Issue Developing Drug Strategies for the Neuroprotective Treatment)
Abstract
:Prion protein peptide (PrP) has demonstrated neurotoxicity in brain cells, resulting in the progression of prion diseases with spongiform degenerative, amyloidogenic, and aggregative properties. Thymosin beta 4 (Tβ4) plays a role in the nervous system and may be related to motility, axonal enlargement, differentiation, neurite outgrowth, and proliferation. However, no studies about the effects of Tβ4 on prion disease have been performed yet. In the present study, we investigated the protective effect of Tβ4 against synthetic PrP (106–126) and considered possible mechanisms. Hippocampal neuronal HT22 cells were treated with Tβ4 and PrP (106–126) for 24 h. Tβ4 significantly reversed cell viability and reactive oxidative species (ROS) affected by PrP (106–126). Apoptotic proteins induced by PrP (106–126) were reduced by Tβ4. Interestingly, a balance of neurotrophic factors (nerve growth factor and brain-derived neurotrophic factor) and receptors (nerve growth factor receptor p75, tropomyosin related kinase A and B) were competitively maintained by Tβ4 through receptors reacting to PrP (106–126). Our results demonstrate that Tβ4 protects neuronal cells against PrP (106–126) neurotoxicity via the interaction of neurotrophic factors/receptors.
1. Introduction
Prion disease is the common name for transmissible spongiform encephalopathies (TSE), neurodegenerative diseases of animals and humans [1]. These diseases are sporadic of inherited in origin and are characterized by histopathology involving spongiform degeneration with neuronal loss and gliosis [2]. Although the etiology of prion disease has not been well elucidated, major evidence suggests that modification of prion protein (PrP) from a normal cellular protein (PrPc) to a disease-specific species called the pathological scrapie isoform (PrPsc) causes insolubility and protease resistance, resulting in the disruption of neuronal homeostasis. The PrP fragment (106–126) has a similar function as PrPSC and easily aggregates in brain cells, causing resistance to proteolytic enzymes [3]. To study the prions involved in neurodegenerative diseases, model agents such as synthetic peptides homologous to PrP have been used (106–126) [4]. Prion peptide PrP (106–126) has been demonstrated to be neurotoxic in brain cells due to its spongiform degenerative, amlyoidogenic, and aggregative propertied both in vivo and in vitro [5]. Prion-related encephalopathies are rare and deadly diseases caused by the abnormal transition of normal cellular prion protein into a pathogenic protease-resistant form. Synthetic peptides similar to this pathogenic protein, such as PrP (106–126), have been used to study the mechnisms of neurodegeneration. Both full-length PrPSC and PrP (106–126) have been shown to be toxic to neurons, and various mechanisms have been proposed to explain neuronal death in prion diseases [3,5].
Neurotrophic factors called neurotrophins are related to neurogenesis and are important for neuronal survival in the brain [6]. A previous study has suggested that neurotrophic factors can be used as therapeutic agents in neuronal disorders [7]. Neurotrophic factors are a family of proteins with similar structure and function to nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), and glial cell line-derived neurotrophic factor (GDNF) [8]. The actions of neurotrophic factors are mediated by two membrane receptor signaling systems, nerve growth factor receptor p75 (NGFRp75) and the tropomyosin related kinase (Trk) family including TrkA and TrkB [9]. Each neurotrophic factor reveals a different binding specificity for specific receptors. NGF preferentially binds to TrkA, a high-affinity nerve growth factor receptor, and NGFRp75, a low-affinity nerve growth factor receptor [10]. BDNF preferentially binds to TrkB. A previous study demonstrated that the relationship between neurotrophic factors and their receptor is involved in the pathogenesis of neurodegenerative diseases [11]. With prion diseases, PrP (106–126)-induced apoptosis of mouse neuronal cells reacted to the NGFRp75 signaling pathway [12], suggesting that NGFRp75 might be particularly related to the pathogenesis of prion diseases.
Thymosin beta 4 (Tβ4) is a peptide identified as an actin monomer binding molecule present in all mammalian species [13]. Tβ4 plays a role in many cellular processes, including motility, axonal enlargement, differentiation, neurite outgrowth, and proliferation [14]. Based on the above roles of Tβ4, the physiological and pathological nervous system processes mediated by Tβ4 have been established [15]. The underlying mechanism of Tβ4 in the nervous system may be related to its neuronal growth effects [16]. The previous study, we found Tβ4 prevent neurodegenerative diseases caused by PrP (106–126)-induced blood–brain barrier (BBB) dysfunction [17]. In addition, Tβ4 can regulate autophagy activation not only in PrP (106–126)-induced HT22 cells [18], but also in LPS and ATP-induced RAW264.7 and LX-2 cells [19]. Tβ4 has also demonstrated neuroprotective and neurorestorative potential within various neurological injury models [20]. In particular, the neuroprotective effects of Tβ4 have been observed in a mouse model of neuroinflammatory BBB dysfunction induced by systemic infection with LPS [21,22]. However, since Tβ4 cannot directly pass through the BBB [20], it is believed that these effects are mediated outside of the central nervous system, affecting the body as a whole. However, no direct evidence of neurotrophic factors or neurotrophic receptor involved with Tβ4 has been suggested yet. The present study examined direct interaction among Tβ4, neurotrophic factors, and neurotrophic receptors in the presence or absence of PrP (106–126). Accordingly, neuronal cell protection by Tβ4 against PrP (106–126) neurotoxicity via neurotrophic signaling pathways was assessed. The results of the present study suggest the first evidence of an interaction between Tβ4 and PrP (106–126) via possible underlying mechanisms involved in neurotrophic factors/receptors. These results may lead to a novel therapeutic strategy for treating prion diseases.
2. Results
2.1. Tβ4 Protects HT22 Cells against PrP (106–126)
To evaluate the effect of Tβ4 on PrP (106–126)-treated HT22 cells, cell viability and ROS activity were confirmed. As shown in Figure 1A, Tβ4 increased cell viability in a dose-dependent manner. Figure 1B shows that synthetic PrP (106–126) decreased cell viability in a dose-dependent manner compared to scrambled PrP (106–126), which was used as a positive control for synthetic peptide toxicity. A significant reduction was shown over 100 μM PrP (106–126) treatment. Accordingly, the effect of Tβ4 on 100 μM PrP (106–126) treated HT22 cells was assessed. As shown in Figure 1C, over 400 ng/mL of Tβ4 on 100 μM PrP (106–126)-treated cells resulted in cell viability similar to non-treated control. ROS activity was significantly reduced by Tβ4 treatment in dose-dependent manner on HT22 cells treated with 100 μM PrP (106–126) (Figure 1D). Based on these results, adequate doses of Tβ4 (400 ng/mL) and PrP (106–126) (100 μM) were used for subsequent experiments.
2.2. Tβ4 Inhibited Apoptosis Induced by PrP (106–126)
The cellular toxicity of PrP (106–126) directly induced apoptosis such as Bcl-family, Bax, cleaved caspase-3. Furthermore, the anti-apoptosis effect of Tβ4 on PrP (106–126) treated HT22 cell was confirmed. As shown in Figure 2, the anti-apoptosis protein Bcl-xL was increased by Tβ4 while it was decreased by PrP (106–126). Apoptosis proteins such as Bax and cleaved caspase-3 were decreased by Tβ4 while they were increased by PrP (106–126). These results suggest that Tβ4 inhibited apoptosis induced by PrP (106–126) in HT22 cells.
2.3. Tβ4 Induced Neruotrophic Factors Such as NGF and BDNF
The above results suggest that Tβ4 improved neuronal cell survival. To dissect the possible mechanisms of Tβ4, neurotrophic factor was confirmed to affect the cell physiology of neurons (Figure 3). As expected, Tβ4 revealed significant results on both RNA and protein levels of neurotrophic factors. PrP (106–126) decreased the levels of NGF and BDNF in both RNA and protein. Only Tβ4 treated cells showed significant increase in both NGF and BDNF in RNA and protein levels. Tβ4 increased both NGF and BDNF compared to reduction by PrP (106–126) in HT22 cells. Thus, Tβ4 induced NGF and BDNF to improve neuronal cell survival.
2.4. Intrinsic Tβ4 Induced Neurotrophic Factors and Its Own Receptors
As shown in Figure 3, the effect of intrinsic Tβ4 on neurotrophic factors and its own receptors was confirmed through Tβ4 siRNA. As shown in Figure 4A, RNA levels were changed by Tβ4 siRNA. Tβ4, NGF, and BDNF expression showed similar tendencies as each other. Tβ4 siRNA significantly inhibited Tβ4 levels as well as NGF and BDNF levels. Co-treatment with Tβ4 on Tβ4-siRNA-treated cells revealed the reverse effect of Tβ4 siRNA. The protein levels of Tβ4, NGF and BDNF showed similar results as RNA levels of Tβ4, NGF, and BDNF (Figure 4B). Additionally, altered receptors were confirmed as a reaction to neurotrophic factors. As shown in Figure 4C, Tβ4 reduced NGFRp75, possibility due to reaction with PrP, while it induced both TrkA and TrkB due to reaction with NGF and BDNF. PrP (106–126) significantly increased NGFRp75, which was boosted with Tβ4 siRNA. The deletion of Tβ4 by Tβ4 siRNA revealed a similar tendency as RNA levels of PrP (106–126)-treated cells. Tβ4 treated with PrP (106–126) and Tβ4 siRNA resulted in reversed RNA levels of Tβ4, NGFRp75, TrkA, and TrkB compared to cells co-treated with PrP (106–126) and Tβ4 siRNA. The protein levels of Tβ4, NGFRp75, TrkA, and TrkB were confirmed to belong to the same groups as RNA results. As shown in Figure 4D, protein levels of Tβ4, NGFRp75, TrkA, and TrkB revealed similar tendencies as RNA levels. These results suggested that both intrinsic and extrinsic Tβ4 affected NGF. In addition, BDNF has its own receptors, such as NGFRp75, TrkA, and TrkB.
Moreover, both TrkA inhibitor and TrkB inhibitor were used to artificially delete each receptor in Tβ4 treated cells (Figure 5). Each inhibitor significantly reduced the phosphorylated form of each protein level. Tβ4 increased the total form of TrkA and TrkB expression as well as the phosphorylated form of TrkA and TrkB. TrkA inhibitor and TrkB inhibitor significantly reduced the phosphorylated form induced by Tβ4.
2.5. Tβ4 Protects HT22 Cells from PrP (106–126) via Induced Neurotrophic Factors
Finally, repeated experiments were performed to confirm results regarding apoptosis, cell viability, and ROS. As shown in Figure 6A, Tβ4 inhibited cleaved caspase-3, which was reversed by Tβ4 siRNA, PrP (106–126), TrkA inhibitor, and TrkB inhibitor. Accordingly, Tβ4 increased the cell viability that was reversed by Tβ4 siRNA, PrP (106–126), TrkA inhibitor, and TrkB inhibitor (Figure 6B). ROS activity also had the same tendency as cleaved caspase-3 results (Figure 6C). These results suggested that Tβ4 protects hippocampal neuronal cells against PrP (106–126) via an induced neurotrophic factor and reaction with its receptors.
3. Discussion
The present study demonstrated that Tβ4 protects hippocampal neuronal cells against PrP (106–126) via upregulation of neurotrophic factors and their receptors. The mammalian nervous system naturally produces Tβ4 during postnatal development [15]. Moreover, early-stage embryogenesis involves abundant expression of Tβ4 in neural tissue [23]. Tβ4 is distributed in the adult forebrain including the cerebral cortex, hippocampal entorhinal region, cerebellum, infundibular region, substantia nigra pars compacta, supraoptic, medial amygdaloid, and dorsal premammillary nuclei [24,25]. In a previous study, neuron and glial cells induced Tβ4 with focal brain ischemia and kainic acid treatment [26]. The previous study demonstrated that Tβ4 has a crucial role in physiological and pathological process in the nervous system. Extrinsic Tβ4 treatment is also involved in motility, axon growth, and synapse generation in neurons after brain damage [27]. A reasonable proposed mechanism for this is neurotrophic effects [16]. However, any direct evidence for the relationship between Tβ4 and neurotrophic factors has not yet been elucidated, although NGF has been shown to induced Tβ4 in PC12 cells [28]. Thus, we studied how Tβ4 involved with both neurotrophic factors and their receptors to protect against PrP toxicity.
Prion disease, also known as transmissible spongiform encephalopathy, is the only natural occurring infectious protein misfolding disease. It is caused by the PrPC into PrPSC, resulting in the accumulation of misfolded protein particels [29,30]. Numerous studies have been conducted to identify effective agents for drug development in prion diseases [30]. This study used PrP (106–126) as a derivative to simulate the pathological signaling observed in prion diseases. PrP (106–126), a synthetic peptide homologous to PrP (106–126), was widely used as an extrinsic treatment to study prion disease [4]. PrP (106–126) induced neurotoxicity in neuronal cells due to its amyloidogenic properties both in vivo and in vitro [5]. In particular, in our previous study, we demonstrated the effectiveness of Tβ4 on neurotoxicity and on autophagy activity in PrP (106–126)-induced HT22 cells [18]. Results in Figure 1 showed that Tβ4 protects hippocampal neuronal HT22 cells against PrP (106–126), demonstrated by increased cell viability and reduced ROS activity. Moreover, the PrP (106–126)-induced proteins associated with apoptosis were reversed by Tβ4 (Figure 2). To dissect reasonable mechanisms for this, neurotrophic factors such as NGF and BDNF were examined (Figure 3). Both the RNA and protein levels of NGF and BDNF were increased by Tβ4 compared to reduced NGF and BDNF with PrP (106–126).
Neurotrophic factors and their receptor have a known role in neurogenesis and protection in mammalian nervous systems. Neurotrophic factor mechanisms are related to throsin kinase receptors such as TrkA, TrkB, TrkC and NGFRp75, a subfamily of the tumor necrosis factor receptor [9]. Different neurotrophic factors have binding specificities for precise receptors. However, these interactions can be altered with regulation by receptor dimerization, structural modifications, or association with NGFRp75. The interaction between neurotrophic factors and their receptors is related to neurodegenerative diseases [11]. In prion diseases, PrP (106–126)-induced apoptosis in neuroblastoma cells involves up-regulated NGFRp75 and the nuclear factor kappa B (NF-κB) signaling pathway [12]. Based on previous studies, neurotrophic factors binding to their receptors affect the pathogenesis of prion diseases. Thus, the interaction between Tβ4 and neurotrophic factor/receptors was examined (Figure 4). Deletion of Tβ4 inhibited expression of NGF and BDNF, as well as their high affinity receptors TrkA and TrkB (Figure 4B,D). NGFRp75, which reacts to PrP (106–126), was incrased by Tβ4 siRNA. PrP (106–126) accelerated the effect of Tβ4 siRNA on NGFPp75 and reduction in TrkA and TrkB (Figure 4C,D). Thus, NGF and BDNF and their receptors have important roles in the protective effect of intrinsic Tβ4 against PrP (106–126).
Nerve growth factor (NGF) binds to TrkA, and BDNF and neurotrophin 4 bind to TrkB. However, the low affinity of binding of NGF to TrkA and binding of BDNF to TrkB can be transformed by dimerization of receptors, structural deformation, and association with p75NTR receptors, which can also increase ligand selectivity [31]. To confirm the interaction between Tβ4 and neurotrophic receptors, TrkA inhibitor and TrkB inhibitor were used. As shown in Figure 5, each particular inhibitor inhibited the phosphorylated form of TrkA and TrkB. Tβ4 significantly reversed the expression of phosphorylated TrkA and TrkB caused by each inhibitor. This result indicated that Tβ4 induced neurotrophic receptors for neuron survival. All corresponding treatments with Tβ4 in HT22 cells revealed coincident results that Tβ4 significantly reduced the neurotoxicity induced by PrP (106–126) via interaction of neurotrophic factors/receptors (Figure 6). In addition, the accumulation of misfolded prions leads to vesicle stress and disturbances in calcium signaling regulation, which can cause mitochondrial dysfunction, compounding the stress produced by misfolded proteins [32]. ROS production due to intracellular oxidative stress affects the prion infection process, contributing to apoptosis and damage [33]. Tβ4 decreased apoptosis (Figure 6A) and ROS activity (Figure 6C).
The present results show for the first time that Tβ4 reduces neuronal cell toxicity induced by PrP (106–126), regarded as a cause of prion disease. Tβ4 also plays a crucial role as a key recovery factor that induces NGF and BDNF, signals transmitted to TrkA and TrkB in the neuronal survival signaling pathway (Figure 7). Based on these findings, we suggest that Tβ4 could serve as a novel therapeutic strategy for treating prion disease via the neurotrophic factor/receptor signaling pathway. This interaction warrants further investigation regarding its role in neurotrophic factor balance.
4. Materials and Methods
4.1. Chemicals
Tβ4 was purchased from Tocris Bioscience (Bristol, UK). TrkA inhibitor was purchased from Santa Cruz Biotechnology (Dallas, TX, USA). TrkB inhibitor was purchased from Sigma-Aldrich (St. Louis, MO, USA). Primary antibodies for NGF, BDNF, Bcl-xL, Bax, Cleaved caspase-3, Caspase-3, Thymosin beta 4 (Tβ4), NGFRp75, phosphorylated (p)-TrkA, TrkA, p-TrkB, TrkB, and β-actin were purchased from Abcam (Cambridge, UK). Secondary antibodies (i.e., anti-rabbit, anti-goat, or anti-mouse IgG antibody conjugated with horseradish peroxidase) was obtained from Thermo (Temecula, CA, USA). Synthetic PrP (106–126) (KTNMKHMAGAAAAGAVVGGLG) and scrambled PrP (106–126) (NGAKALMGGHGAYKVMVGAAA) were synthesized by Peptron (Seoul, Korea). PrP peptides were dissolved in sterile dimethyl sulfoxide at a concentration of 10 mM and stored at −72 °C. All other chemicals and reagents were of analytic grade.
4.2. Cell Culture
The hippocampal neuronal cell line (HT22; ATCC, Rockville, MD, USA) originated from mouse was maintained in Dulbecco’s modified Eagle’s medium (DMEM; HyClone, Logan, UT, USA) containing 10% fetal bovine serum (FBS; Hyclone, Canada) and 1% penicillin–streptomycin (Sigma-Aldrich, St. Louis, MO, USA) in a 37 °C humidified incubator with 5% CO2. The medium was changed every 2~3 days. Cells were treated with PrP (106–126) at 100 μM and Tβ4 at 400 ng/mL. TrkA inhibitor at 3 μM and TrkB inhibitor at 5 μM were used.
4.3. Small Interfering RNA (siRNA) Rransfection
HT22 cells were plated in 6 cm2 dishes (4 × 105 cells/dish) until confluence and then starved for 24 h. The DharmaFECT 1 small interfering RNA (siRNA) Transfection Reagent (Dharmacon, Denver, CO, USA) was used to transfect cells with 50 nM Tβ4 siRNA or scrambled siRNA oligonucleotides (Dharmacon, Danver, CO, USA) according to the manufacturer’s instructions, as reported previously.
4.4. Cell Viability
Cell viability was determined using a 3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay kit from Sigma-Aldrich (St. Louis, MO, USA) according to the manufacturer’s instructions. HT22 cells were grown on 96-well plates (SPL, Pochon, Korea) at a density of 2 × 104 cells/well. After the corresponding treatment, cell viability was evaluated by assaying the ability of functional mitochondria to catalyze reduction in MTT to a formazan salt by mitochondrial dehydrogenases. The index of cell viability was determined with multiplate reader spectrophotometry (PowerWave 2, Bio-Tek Instruments, Winooski, VT, USA) based on an absorbance of 570 nm.
4.5. Intracellular Reactive Oxygen Species Assay
The level of intracellular reactive oxygen species (ROS) was quantified by fluorescence using 2′,7′-dichlorodihydrofluorescein diacetate (DCF-DA; Invitrogen, Carlsbad, CA, USA). Cells were grown on 48-well plates and incubated in corresponding treatment conditions for 6 h. After the incubation period, cells were washed with phosphate-buffered saline (PBS) and stained with DCF-DA in PBS for 30 min in the dark. Cells were then washed twice with PBS and extracted with 0.1% Tween-20 in PBS for 10 min at 37 °C. Fluorescence was recorded using an excitation wavelength of 490 nm and emission wavelength of 525 nm.
4.6. RNA Preparation and Real-Time (RT)-PCR
Total RNA was isolated from cells and precipitated with Ribo EX (Geneall, Daejeon, South Korea) according to the manufacturer’s instructions. mRNA was reverse transcribed to cDNA using a Maxime RT PreMix kit (Intron, Seongnam, South Korea) according to the manufacturer’s instructions. For real-time RT-PCR, cDNA was amplified using a Mastercycler Gradient 5331 Thermal Cycler (Eppendorf, Germany). An ABI Step One Plus Sequence Detection System (Applied Biosystems, Middlesex County, MA, USA) was used to monitor real-time PCR runs by measuring fluorescence signals after each cycle. Specific primers for each gene were designed using Primer Express software (Applied Biosystems). The following forward and reverse primers were used for real-time RT-PCR quantification (forward and reverse): 5′-AAACCCGATATGGCTGAGATTG -3′ and 5′-GCCTGCTTGCTTCTCCTGTT-3′ for Tβ4, 5′-TGGGCTTCAGGGACAGAGTC-3′ and 5′-CAGCTTTCTATACTGGCCGCAG-3′ for NGF, 5′-AACCATAAGGACGCGGACTT-3′ and 5′-TGCAGTCTTTTTATCTGCCG-3′ for BDNF, 5′-ACCATCTCAGGCCTTTCCTT-3′ and 5′-TGTTGGGTG GCCTAGGTTAG-3′ for NGFRp75, 5′-GAGGAGCAAATTTGGGATCA-3′ and 5′-GGTGCAGACTCCAAAGAAGC-3′ for TrkA, 5′-AAGGACTTTCATCGGGAAGCTG-3′ and 5′- TCGCCCTCCACACAGACAC-3′ for TrkB, and 5′-TGTGTCCGTCGTGGATCTGA-3′ and 5′-CAACACCTCAACAGGAGTGGACA-3′ for glyceraldehyde-3-phosphate dehydrogenase (GAPDH), the housekeeping gene used as an internal control. All experiments were performed at least three times. Data were normalized to the reference gene, GAPDH.
4.7. Immunoblotting Analysis
Total proteins were extracted with a RIPA lysis buffer with EDTA containing a protease inhibitor cocktail and a phosphatase inhibitor cocktail. Proteins in cells were subjected to sodium dodecyl sulfate–polyacrylamide gel electrophoresis using 8%, 10%, and 14% gels, and then were electrophoretically transferred to polyvinylidene fluoride (PVDF) membranes (#162177, Bio-Rad, Contra Costa, CA, USA). The membranes were blocked with 5% skim milk in PBS and then individually incubated with each primary antibody diluted to 1:1000 in 1% skim milk in PBS overnight at 4 °C. Blots were further incubated with each secondary antibody diluted to 1:10,000 at room temperature for 1 h. The immunoreactions were visualized using SuperSignal West Dura Extended Duration Substrate (Thermo Fischer Scientific, San Jose, CA, USA) and analyzed using a ChemiImager system (Alpha Innotech, San Leandro, CA, USA).
4.8. Statistical Analysis
The data were analyzed using Student’s t-test (for two groups), one-way ANOVA, and Tukey’s test (for more than two groups). Data are presented as mean and SEM values. The cutoff for statistical significance was set at p < 0.05. All analyses were performed using the Statistical Package for Social Sciences (version 13.0 for Windows, SPSS, Chicago, IL, USA).
5. Conclusions
In conclusion, our study provides evidence that thymosin beta 4 (Tβ4) has a protective effect against neurotoxicity induced by synthetic prion protein peptide (PrP) (106–126) in hippocampal neuronal cells. Tβ4 treatment significantly improved cell viability, reduced ROS levels, and decreased apoptotic protein expression induced by PrP (106–126). Additionally, Tβ4 appears to play a role in maintaining a balance of neurotrophic factors and receptors, which are essential for proper signaling in the nervous system. Although there is promising in vitro evidence supporting the effectiveness of Tβ4, it is important to note that there is a lack of in vivo experiments to confirm these findings. Therefore, further research, particularly in vivo studies, is needed to fully evaluate the potential of Tβ4 as a therapeutic agent. Our findings suggest that Tβ4 may have therapeutic potential in the treatment of prion diseases and other neurodegenerative disorders.
Author Contributions
Conceptualization, J.K.; methodology, S.K.; writing—original draft preparation, S.K. and J.C.; writing—review and editing, J.K.; project administration, J.K. All authors have read and agreed to the published version of the manuscript.
Funding
This work was supported by a grant from the National Research Foundation of Korea, funded by the Korean government (NRF-2015R1D1A1A01057696).
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.
Sample Availability
Samples of the compounds are not available from the authors.
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Figure 1.
Cell viability and ROS activity in Tβ4 and PrP (106–126)-treated cells. Cell vability was assessed by MTT assay. (A) Tβ4 was treated dose-dependently (100~1000 ng/mL) for 24 h. (B) PrP (106–126) and scrambled PrP (106–126) were treated dose dependently (25–200 μM) for 24 h. (C) Tβ4 was treated dose-dependently (100–1000 ng/mL) with PrP (106–126) at 100 μM for 24 h. ROS activity was assessed by DCF-DA staining. (D) Tβ4 was treated dose dependently (100–1000 ng/mL) with PrP (106–126) at 100 μM for 24 h. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with only PrP (106–126)-treated group. ## p < 0.01, compared with only PrP (106–126)-treated group. ### p < 0.001, compared with only PrP (106–126)-treated group.
Figure 1.
Cell viability and ROS activity in Tβ4 and PrP (106–126)-treated cells. Cell vability was assessed by MTT assay. (A) Tβ4 was treated dose-dependently (100~1000 ng/mL) for 24 h. (B) PrP (106–126) and scrambled PrP (106–126) were treated dose dependently (25–200 μM) for 24 h. (C) Tβ4 was treated dose-dependently (100–1000 ng/mL) with PrP (106–126) at 100 μM for 24 h. ROS activity was assessed by DCF-DA staining. (D) Tβ4 was treated dose dependently (100–1000 ng/mL) with PrP (106–126) at 100 μM for 24 h. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with only PrP (106–126)-treated group. ## p < 0.01, compared with only PrP (106–126)-treated group. ### p < 0.001, compared with only PrP (106–126)-treated group.
Figure 2.
Apoptosis in Tβ4 and PrP (106–126)-treated cells. Tβ4 at 400 ng/mL treated with or without PrP (106–126) at 100 μM for 24 h. Bcl-xL, Bax, cleaved caspase-3, caspase-3, and β-actin were confirmed by immunoblotting. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. # p < 0.05, compared with PrP (106–126)-treated group. ## p < 0.01, compared with only PrP (106–126)-treated group.
Figure 2.
Apoptosis in Tβ4 and PrP (106–126)-treated cells. Tβ4 at 400 ng/mL treated with or without PrP (106–126) at 100 μM for 24 h. Bcl-xL, Bax, cleaved caspase-3, caspase-3, and β-actin were confirmed by immunoblotting. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. # p < 0.05, compared with PrP (106–126)-treated group. ## p < 0.01, compared with only PrP (106–126)-treated group.
Figure 3.
NGF and BDNF expression in Tβ4- and PrP (106–126)-treated cells. Tβ4 at 400 ng/mL treated with or without PrP (106–126) at 100 μM for 24 h. (A) RNA levels of NGF and BDNF. (B) Protein levels of NGF and BDNF. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. # p < 0.05, compared with only PrP-treated group. ### p < 0.001, compared with only PrP-treated group.
Figure 3.
NGF and BDNF expression in Tβ4- and PrP (106–126)-treated cells. Tβ4 at 400 ng/mL treated with or without PrP (106–126) at 100 μM for 24 h. (A) RNA levels of NGF and BDNF. (B) Protein levels of NGF and BDNF. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. # p < 0.05, compared with only PrP-treated group. ### p < 0.001, compared with only PrP-treated group.
Figure 4.
Neurotrophic factors and their receptors affected by Tβ4. (A) RNA levels and (B) protein levels of Tβ4, NGF, and BDNF in 400 ng/mL Tβ4 treated with or without scrambled siRNA and Tβ4 siRNA for 24 h. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with Tβ4 siRNA group. ## p < 0.01, compared with Tβ4 siRNA group. ### p < 0.001, compared with Tβ4 siRNA group. (C) RNA levels and (D) protein levels in 400 ng/mL Tβ4 with or without scrambled siRNA, Tβ4 siRNA, and PrP (106–126) at 100 μM for 24 h. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with only PrP-treated group. ## p < 0.01, compared with only PrP-treated group. ### p < 0.001, compared with only PrP-treated group. + p < 0.05, compared with Tβ4 + PrP-treated group. ++ p < 0.01, compared with Tβ4 + PrP-treated group. +++ p < 0.001, compared with Tβ4 + PrP-treated group.
Figure 4.
Neurotrophic factors and their receptors affected by Tβ4. (A) RNA levels and (B) protein levels of Tβ4, NGF, and BDNF in 400 ng/mL Tβ4 treated with or without scrambled siRNA and Tβ4 siRNA for 24 h. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with Tβ4 siRNA group. ## p < 0.01, compared with Tβ4 siRNA group. ### p < 0.001, compared with Tβ4 siRNA group. (C) RNA levels and (D) protein levels in 400 ng/mL Tβ4 with or without scrambled siRNA, Tβ4 siRNA, and PrP (106–126) at 100 μM for 24 h. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with only PrP-treated group. ## p < 0.01, compared with only PrP-treated group. ### p < 0.001, compared with only PrP-treated group. + p < 0.05, compared with Tβ4 + PrP-treated group. ++ p < 0.01, compared with Tβ4 + PrP-treated group. +++ p < 0.001, compared with Tβ4 + PrP-treated group.
Figure 5.
Relationship between Tβ4 and neurotrophic factor receptors. Protein levels of Tβ4, p-TrkA, TrkA, p-TrkB, TrkB, and β-actin in 400 ng/mL Tβ4 treated with or without 5 μM TrkA inhibitor and 20 μM TrkB inhibitor for 24 h. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with only Tβ4-treated group. ## p < 0.01, compared with the Tβ4-treated only group.
Figure 5.
Relationship between Tβ4 and neurotrophic factor receptors. Protein levels of Tβ4, p-TrkA, TrkA, p-TrkB, TrkB, and β-actin in 400 ng/mL Tβ4 treated with or without 5 μM TrkA inhibitor and 20 μM TrkB inhibitor for 24 h. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with only Tβ4-treated group. ## p < 0.01, compared with the Tβ4-treated only group.
Figure 6.
Protective effect of Tβ4 via neurotrophic factors and their receptors. Tβ4 at 400 ng/mL treated with or without scrambled siRNA, Tβ4 siRNA, 5 μM TrkA inhibitor, 20 μM TrkB inhibitor, and PrP (106–126) at 100 μM for 24 h. (A) Protein levels of cleaved caspase-3, caspase-3, and β-actin were confirmed. (B) Cell viability and (C) ROS activity were also confirmed. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with only prp-treated group. ## p < 0.01, compared with only PrP-treated group. + p < 0.05, compared with Tβ4 + PrP-treated group. ++ p < 0.01, compared with Tβ4 + PrP-treated group. $ p < 0.05, compared with PrP + TrkA IH-treated group. @ p < 0.05, compared with PrP + TrkB IH-treated group.
Figure 6.
Protective effect of Tβ4 via neurotrophic factors and their receptors. Tβ4 at 400 ng/mL treated with or without scrambled siRNA, Tβ4 siRNA, 5 μM TrkA inhibitor, 20 μM TrkB inhibitor, and PrP (106–126) at 100 μM for 24 h. (A) Protein levels of cleaved caspase-3, caspase-3, and β-actin were confirmed. (B) Cell viability and (C) ROS activity were also confirmed. Data are represented as mean ± SEM (n = 3). * p < 0.05, compared with control. ** p < 0.01, compared with control. *** p < 0.001, compared with control. # p < 0.05, compared with only prp-treated group. ## p < 0.01, compared with only PrP-treated group. + p < 0.05, compared with Tβ4 + PrP-treated group. ++ p < 0.01, compared with Tβ4 + PrP-treated group. $ p < 0.05, compared with PrP + TrkA IH-treated group. @ p < 0.05, compared with PrP + TrkB IH-treated group.
Figure 7.
Scheme of Tβ4 signaling pathway on PrP (106–126)-treated cells.
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Kim, S.; Choi, J.; Kwon, J. Thymosin Beta 4 Protects Hippocampal Neuronal Cells against PrP (106–126) via Neurotrophic Factor Signaling. Molecules 2023, 28, 3920. https://doi.org/10.3390/molecules28093920
AMA Style
Kim S, Choi J, Kwon J. Thymosin Beta 4 Protects Hippocampal Neuronal Cells against PrP (106–126) via Neurotrophic Factor Signaling. Molecules. 2023; 28(9):3920. https://doi.org/10.3390/molecules28093920
Chicago/Turabian StyleKim, Sokho, Jihye Choi, and Jungkee Kwon. 2023. "Thymosin Beta 4 Protects Hippocampal Neuronal Cells against PrP (106–126) via Neurotrophic Factor Signaling" Molecules 28, no. 9: 3920. https://doi.org/10.3390/molecules28093920
