Abstract
Aims
The involvement of cyclin D1 in the proliferation of microglia, and the generation and maintenance of bone cancer pain (BCP), have not yet been clarified. We investigated the expression of microglia and cyclin D1, and the influences of cyclin D1 on pain threshold.
Methods
Female Sprague Dawley (SD) rats were used to establish a rat model of BCP, and the messenger RNA (mRNA) and protein expression of ionized calcium binding adaptor molecule 1 (IBA1) and cyclin D1 were detected by reverse transcription-polymerase chain reaction (RT-PCR) and western blot, respectively. The proliferation of spinal microglia was detected by immunohistochemistry. The pain behaviour test was assessed by quantification of spontaneous flinches, limb use, and guarding during forced ambulation, mechanical paw withdrawal threshold, and thermal paw withdrawal latency.
Results
IBA1 and cyclin D1 in the ipsilateral spinal horn increased in a time-dependent fashion. Spinal microglia proliferated in BCP rats. The microglia inhibitor minocycline attenuated the pain behaviour in BCP rats. The cyclin-dependent kinase inhibitor flavopiridol inhibited the proliferation of spinal microglia, and was associated with an improvement in pain behaviour in BCP rats.
Conclusion
Our results revealed that the inhibition of spinal microglial proliferation was associated with a decrease in pain behaviour in a rat model of BCP. Cyclin D1 acts as a key regulator of the proliferation of spinal microglia in a rat model of BCP. Disruption of cyclin D1, the restriction-point control of cell cycle, inhibited the proliferation of microglia and attenuated the pain behaviours in BCP rats. Cyclin D1 and the proliferation of spinal microglia may be potential targets for the clinical treatment of BCP.
Cite this article: Bone Joint Res 2022;11(11):803–813.
Article focus
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The purpose of this study was to examine whether cyclin D1 acts as a key regulator of the proliferation of spinal microglia in bone cancer pain (BCP) rats, and whether the disruption of cyclin D1 would inhibit the proliferation of microglia and attenuate the pain behaviours in BCP rats.
Key messages
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Inhibition of spinal microglial proliferation was associated with a decrease in pain behaviour in BCP rats.
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Cyclin D1 acts as a key regulator of the proliferation of spinal microglia in BCP rats.
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Disruption of cyclin D1 was associated with attenuation of pain behaviour in BCP rats.
Strengths and limitations
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This is the first study to confirm that cyclin D1 acts as a key regulator of the proliferation of spinal microglia in BCP rats, and disruption of cyclin D1 was associated with attenuation of pain behaviour in BCP rats.
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One limitation of our study was that we did not investigate the role of cyclin D1 and proliferation of microglia in BCP rats at supraspinal level.
Introduction
Bone cancer pain (BCP) is a common complication in patients with cancer bone metastasis or primary bone cancer.1-6 BCP may be severe and difficult to adequately control by current drugs and therapeutic approaches, which illustrates that this clinical problem has not been solved.7 Thus, it is necessary to elucidate the molecular and cellular mechanisms of BCP.
A paradigm shift in understanding chronic pain has been the realization that neurones are not the only cells involved in the aetiology. Immune cells, such as glial cells, contribute to sensitization in pain pathway both in the central nervous system (CNS) and the peripheral nervous system (PNS). Microglia, the tissue-resident macrophages of the CNS, infiltrate and take up residence in the developing brain, actively engulf synaptic material, and play a major role in synaptic maturation during postnatal development.8 Recent research emphasizes the role of neuron-microglia interaction in neuropathic pain. The proliferation of spinal glia has been shown to regulate neuropathic pain.9,10 A correlation between pain behaviours and microglial activation has been reported,11 although there are contradictory findings.12 We have reported the correlation between BCP and microglia,13-15 but little is known about the mechanisms.7,13-16
Disruption of restriction-point control may be a common biological feature in cancer treatment. Cyclins and their kinase partners regulate cell-cycle progression. For example, cyclin D1 regulated the proliferation of spinal astrocytes in a rat model of neuropathic pain.9 However, whether cyclin D1 participates in the generation and maintenance of BCP has not yet been clarified.
In the present study, we firstly established a rat model of BCP by injecting Walker 256 rat mammary gland carcinoma cells into the medullary canal of the tibia.13-15,17-19 Then we investigated the role of cyclin D1 in regulating the proliferation of spinal microglia and their role in pain behaviour in BCP rats. Our findings may elucidate the mechanisms of neuron-microglia interaction in BCP, and thereby provide novel targets for the clinical treatment of BCP.
Methods
Materials
A total of 300 female Sprague Dawley (SD) rats were purchased from the Experimental Animal Research Centre of Guangxi Medical University. Walker 256 rat mammary gland carcinoma cells (LLC-WRC 256) and polyethylene (PE)-10 catheters (PE-0503) were obtained from the Institute of Cancer Research of Chinese Academy of Medical Science and Peking Union Medical College, and Anilab (China), respectively. Minocycline (S4226) and flavopiridol (L86-8275) were obtained from Selleck chem (USA). D-Hank’s solution (H1045) and Triton X-100 (T8200) were provided by Solarbio Life Sciences (China). RIPA (P0013B) and bicinchoninic acid (BCA) assay (P0012) were supplied by Beyond (China). Polyvinylidene fluoride membrane was purchased from Merck Millipore (Germany). Horseradish peroxidase (HRP)-conjugated donkey anti goat immunoglobulin G (IgG) (bs-0294D) was obtained from Bioss (China). Rabbit anti-glyceraldehyde 3-phosphate dehydrogenase (GAPDH) (ab181602), rabbit anti-Ki67 (ab15580), rabbit anti-cyclin D1 (ab156448), rabbit anti p-HisH3 (ab5176), polyclonal anti-IBA1 (ab5076), CY3-conjugated donkey anti-goat IgG (ab6949), Alexa Fluor 488-conjugated donkey anti-rabbit IgG (ab150073), and HRP-conjugated goat anti-rabbit IgG (ab136817) were acquired from Abcam (UK). TRIzol reagent (#15596026) and 4′6-diamidino-2-phenylindole (DAPI, Cat# D1306) were provided by Thermo Fisher Scientific (USA). The specific primer sequences of IBA1 and GAPDH were designed and synthesized by Takara (Japan).
Ethical statement and experimental design
All experimental protocols were approved by the Animal Care and Use Committee of our hospital and were in accordance with the Declaration of the National Institutes of Health Guide for Care. We have included an ARRIVE checklist to show that we have conformed to the ARRIVE guidelines. Adult female SD rats (weighing 180 to 220 g; Supplementary Figure a) were housed under a 12 hr/12 hr light-dark cycle regime at a constant temperature of 22°C ± 1°C with ad libitum access to food and water. Animals were randomly allocated to the following groups: 1) Sham, 2) BCP, 3) BCP-Vehicle, 4) BCP-MC, and 5) BCP-Flavo. Ten rats were assigned to each group for behavioural testing, and four rats were assigned to each group at various timepoints for different molecular experiments.
Preparation of carcinoma cells and BCP model
The preparation of Walker 256 rat mammary gland carcinoma cells and the BCP procedure were carried out as previously described.13,15,19 Briefly, carcinoma cells were inoculated into the abdominal cavity of female rats and extracted from the ascites after seven days, rinsed in D-Hank’s solution, and centrifuged at 500 g for five minutes at 4°C (four cycles). Then, the pellet was calibrated at a concentration of 4 × 105 cells/ml and maintained on ice until inoculation. Under anaesthesia with pentobarbital sodium (50 mg/kg, intraperitoneal), rats were laid in the supine position. The right leg was shaved and disinfected with 7% iodine. The plateau of the tibia was exposed with a small incision. A 23-gauge needle was inserted into the medullary canal of the tibia. Then, the needle was replaced with a thin blunt needle attached to a 10 μl Hamilton syringe. A 10 μl volume containing approximately 4 × 104 live cells (BCP model) or heat-killed cells (denatured at 95°C for five minutes, Sham model) was slowly injected into the bone cavity. The injected site was sealed with bone wax after the syringe was retracted. The skin was sutured with 3/0 silk thread and dusted with penicillin antibiotic powder. All rats were placed on a heated pad until recovery from anaesthesia, and then transferred into their cages.
Intrathecal catheterization and drug administration
Intrathecal catheterization was performed as described previously.15,20 Under pentobarbital sodium (50 mg/kg, i.p.) anaesthesia, a PE-10 catheter (outer diameter 0.6 mm, inner diameter 0.3 mm) was implanted through a gap in the vertebrae between L5 and L6, extending to the subarachnoid space. The catheter position was determined by intrathecal injection of 1% lidocaine (5 μl). If there is no hind limb paralysis within five minutes after intrathecal injection of lidocaine, the animal is considered as failure of catheterization. Animals with neurological deficits (eight rats) or failed catheterization (eight rats) were excluded from further experimentation. Minocycline (4, 20, or 100 μg/ 10 μl, once a day, from postoperative day 3 to 15), flavopiridol (0.04, 0.2, or 1 μg/10 μl, once a day, from postoperative day 3 to 15), or vehicle (10 μl) was intrathecally injected (i.t.) via the implanted catheter in a 10 μl volume followed by 10 μl sterile saline for flushing, lasting at least three minutes. The dosage was based on our preliminary experiments.
Behavioural testing
All behavioural tests and data analysis were performed under double-blind condition by two experimenters (ZYJ and HYC) who did not know the group allocation and the treatments. Rats were acclimated for 30 minutes in a quiet room before behavioural tests. The behavioural tests were performed before drug administration at days 0 (before the operation), 5, 10, 15, and 20 after carcinoma cell injection. Quantification of spontaneous flinches over a two-minute period was used to measure ongoing pain.14,21 Limb use during normal ambulation in an open field and guarding during forced ambulation were used to evaluate movement-evoked pain.14,21 Briefly, forced ambulatory guarding was measured using a rotarod and was scored on a scale of 5 to 0:14,21 5, complete lack of use of limb; 4, partial non-use of limb; 3, substantial limping and prolonged guarding of limb; 2, substantial limping; 1, some limping, but not substantial; and 0, normal use of limb. Limb use was rated on a scale of 4 to 0: 4, normal use; 3, substantial limping; 2, limping and guarding behaviour; 1, partial non-use of the limb in locomotor activity; and 0, complete lack of limb use.
Mechanical paw withdrawal threshold (PWT) was measured by using von Frey filaments (1, 1.4, 2, 4, 6, 8, 10, and 15 g bending force; Stoelting, USA), starting with 1 g and ending with 15 g in ascending order.14,22 Each monofilament was applied five times, for a duration of one second and at ten-second intervals. Paw-flinching or quick withdrawal was considered as a positive response. The paw withdrawal frequency (PWF) to each monofilament was calculated from five applications. PWT was determined by the force at which PWF ≥ 60%; 15 g was recorded as the PWT if PWF < 60% to all filaments.
Paw withdrawal latency (PWL) from a radiant heat machine was used to measure the thermal hyperalgesia according to the method described by Hargreaves et al.14,23-25 In brief, rats were acclimated to the test chamber for one hour on a glass platform at 25°C. Radiant heat was focused on the area of the ipsilateral paw from underneath the glass. The time required to cause an abrupt withdrawal of the ipsilateral paw was regarded as the PWL.
Western blot
Rats were deeply anaesthetized by intraperitoneal injection of sodium pentobarbital (60 mg/kg). The ipsilateral and contralateral spinal cord at L3-5 segments was homogenized in radio immunoprecipitation assay (RIPA) lysis buffer (250 μl). The homogenized samples were centrifuged at 12,000 g for 30 minutes at 4°C. The concentration of the supernatant was determined by BCA assay. Samples were dissolved in 5× sample buffer (125 mM Tris, 10% sodium dodecyl sulphate (SDS), 0.25% bromophenol blue, 10% 2-Mercaptoethanol, 50% Glycerol) and denatured at 95°C for five minutes. Samples containing 30 μg protein were separated by SDS-PAGE gel (10% to 15%) and transferred onto polyvinylidene fluoride membranes. Membranes were blocked in 5% bovine serum albumin (BSA) in tris-buffered saline with Tween-20 (TBST) for two hours at room temperature, incubated overnight at 4°C with the following primary antibodies: goat anti-IBA1 (1:1,000), rabbit anti cyclin D1 (1:1,000), rabbit anti-GAPDH (1:5,000) made in the blocking solution, and then further incubated with HRP-conjugated secondary antibodies for two hours at room temperature. Target protein bands were visualized using chemiluminescence and measured by an Odyssey Fc Image System (LI-COR Biosciences; Imaging software: Image Studio Ver 5.2, USA).
Real-time quantitative PCR
Total RNA was extracted from ipsilateral and contralateral spinal cords (L3-5) using TRIzol reagent. The synthesis and real-time PCR were performed as previously described.19 GAPDH was used as an internal control. The expression level of target mRNA was quantified relative to GAPDH by using the comparative quantification 2-∆∆CT method. The specific primer sequences were designed and synthesized by Takara: IBA1-TGGCTCCGAGGAGACGTTCAG (forward), ACTCTGGCTCACAACTGCTTCTTC (reverse); GAPDH-GGCACAGTCAAGGCTGAGAATG (forward), and ATGGTGGTGAAGACGCCACTA (reverse).
Immunohistochemistry
Rats were deeply anaesthetized by intraperitoneal injection of sodium pentobarbital (60 mg/kg), and perfused transcardially with 200 ml saline, followed by 200 ml of ice-cold paraformaldehyde (4%) in phosphate-buffered saline (PBS). The L3-5 segments of the spinal cord were dissected and post-fixed in 4% paraformaldehyde for 24 hours, and subsequently allowed to equilibrate in 30% sucrose in PBS overnight at 4°C. A total of 20 μm transverse sections were cut on a cryostat (Leica, Germany) and every fifth section was mounted on gelatine-coated slides. After washing with PBS, the sections were penetrated with 0.3% Triton X-100 at room temperature (RT) for 15 minutes. Non-specific binding was blocked by incubation in 5% normal donkey serum in PBS at RT for 60 minutes. Sections were incubated in the following primary antibodies: rabbit anti-Ki67 (1:200), rabbit anti-cyclin D1 (1:300), rabbit anti p-HisH3 (1:200), and polyclonal goat anti-IBA1 (IBA1; microglia marker, 1:300). All sections were incubated at 4°C overnight. After washing with PBS (3 × 5 minutes), the sections were incubated with a mixture of CY3-conjugated donkey anti-goat IgG (1:300) and Alexa Fluor 488-conjugated donkey anti-rabbit IgG (1:300) secondary antibodies at 37°C for two hours. For nuclear staining, 4′6-diamidino-2-phenylindole (DAPI; 500 ng/ml) was used in the last ten minutes before a final PBS wash (3 × 5 minutes). Non-specific labelling was determined running the same protocol without incubating with the primary antibodies. Sections were then mounted and cover-slipped with 75% glycerol in the dark. Images were taken using a fluorescence microscope (BX51, Olympus; Imaging software: cell Sens Standard 1.5, Japan).
To analyze alterations of positive cells, every fifth section was selected from a series of consecutive sections for each rat, and the total number of positive cells in the ipsilateral lamina (I-IV) were counted. The mean number (standard error of the mean (SEM)) in each section represented the change of positive cells.
Statistical analysis
The number of rats used in each experiment was based on the experience of Guan et al14 and Xu et al24-28 with this design. No a priori statistical power calculation was used to estimate the sample size. Differences were analyzed by GraphPad Prism 5.01 software (USA). Two-way analysis of variance (ANOVA) or one-way ANOVA with Bonferroni post hoc tests were used where appropriate. ‘Time’ was treated as ‘within subjects’ factor, and ‘Drug’ was treated as a ‘between’ subject factor. F values are expressed with degrees of freedom (DF) of treatment, time, interaction/residual. The criterion for statistical significance was p < 0.05.
Results
Spinal microglia were activated in BCP rats
To determine whether microglia were activated in BCP rats, we assessed mRNA and protein of IBA1 (biomarker of microglia) in the ipsilateral side of the spinal cord dorsal horn by real-time PCR, western blot, and immunofluorescence. Compared with the sham controls, the mRNA and protein of IBA1 increased starting at five days after carcinoma cell injection (Figures 1a to 1c). Expression of IBA1 on the contralateral side of the dorsal horn did not change significantly between BCP and sham controls (data are not shown).
Fig. 1
Minocycline attenuated the pain behaviour in BCP rats
Although microglia were activated, their role in BCP is still unclear. Minocycline, one member of the tetracycline class of antibiotics, has been found to be a potent analgesic by selectively inhibiting microglia, besides its antimicrobial activity. In order to define the involvement of spinal microglia in BCP, we examined the capacity of intrathecal delivery of minocycline to attenuate pain behaviour in BCP rats. Minocycline (4, 20, and 100 μg in 10 μl of 5% dimethyl sulfoxide (DMSO)) was administered intrathecally from days 3 to 15 after carcinoma cell injection. The treatment of minocycline showed a dose-dependent recovery in the decreased paw withdrawal threshold (Figure 1d), paw withdrawal latency (Figure 1e), limb use scores (Figure 1h), or in the increased number of spontaneous flinches (Figure 1f) and activity-related guarding scores (Figure 1g). After the last administration of minocycline on day 15, the significant attenuation of pain behaviours remained on day 20 (analyzed using two-way ANOVA: paw withdrawal threshold (Figure 1d, p < 0.001), paw withdrawal latency (Figure 1e, p < 0.001), number of spontaneous flinches (Figure 1f, p < 0.001), activity-related guarding scores (Figure 1g, p < 0.01), and limb use scores (Figure 1h, p < 0.01)).
Microglia proliferated in BCP rats
To visualize the proliferating cells in the lumbar dorsal horn, we performed immunohistochemical experiments by using Ki67-biomarker protein expressed in all phases of the cell cycle, excluding the resting phase. The number of Ki67+/DAPI+ cells in the ipsilateral dorsal horn increased significantly in a time-dependent manner, starting at day 10 after carcinoma cell injection (p < 0.001; Figures 2a to 2f), whereas the numbers in the contralateral side and sham rats were just slightly increased (data not shown). To identify the cell type of Ki67+/DAPI+ cells, we performed triple immunolabelling for cell type-specific markers. Most Ki67+/DAPI+ cells were labelled with IBA1 (a microglia marker, Figures 2a to 2f), but not with NeuN (a neuronal marker, data not shown) or glial fibrillary acidic protein (GFAP) (an astrocyte marker, data not shown).
Fig. 2
To determine the mitotic phase of cycling microglia, we performed immunohistochemical experiments by using p-HisH3, a biomarker for the G2/M phase of the cell cycle. As shown in Figures 2g to 2l, the number of p-HisH3+/DAPI+ cells in the ipsilateral dorsal horn increased significantly in a time-dependent manner, starting at day 5 after BCP, peaking at day 20 (p < 0.001, one-way ANOVA), whereas the numbers in the contralateral side and sham rats were just slightly increased (data not shown). Most p-HisH3+/DAPI+ cells were colocalized with microglia (Figures 2g to 2l), but not with neurones or astrocytes (data not shown).
Cyclin D1 is the biomarker protein expressed in the G1 or G2/M transition. Compared with the sham controls, the mRNA (Figure 3a) and protein (Figures 3b and 3c) of cyclin D1 increase started at five days after carcinoma cell injection. Expression of cyclin D1 in the contralateral side of the dorsal horn did not change significantly between BCP and sham controls (data not shown). The number of IBA+/DAPI+ cells and cyclin D1+/DAPI+ cells in the ipsilateral dorsal horn increased significantly in a time-dependent manner, starting at day 10 after BCP, peaking at day 20 (p < 0.001, one-way ANOVA; Figures 3d to 3i), whereas the numbers in the contralateral side and sham rats were just slightly increased (data not shown). Most cyclin D1+/DAPI+ cells were colocalized with microglia (Figure 3i), but not with neurones or astrocytes (data not shown).
Fig. 3
Effects of the cyclin-dependent kinase inhibitor flavopiridol on microglia proliferation and pain behaviours in BCP rats
If the proliferation of spinal microglia contributed to pain behaviour in BCP rats, interfering with microglia cycling should alleviate the pain behaviours. To test this hypothesis, we conducted a test by using flavopiridol, a cell cycle inhibitor that inhibited glia proliferation in vivo and in vitro.9 Flavopiridol reduces cyclin D1 mRNA transcription, and arrests cells in G1 or G2/M transition.29 Flavopiridol (1 μg, in 10 μl of 5% DMSO, once a day, i.t.) was administered intrathecally from days 3 to 15 after carcinoma cell injection. On day 15 after the last administration of flavopiridol, a series of molecular tests were conducted. Compared with BCP-vehicle, flavopiridol attenuated the increase of the mRNA (Figure 4a) and protein (Figures 4b and 4c) of cyclin D1, decreased the number of IBA1+/DAPI+ cells, cyclin D1+/DAPI+ cells, and cyclin D1+/IBA1+/DAPI+ cells in the ipsilateral dorsal horn significantly (Figures 4d to 4f). Also, the number of Ki67+/DAPI+ cells, Ki67+/IBA1+/DAPI+ cells, p-HisH3+/DAPI+ cells, and p-HisH3+/IBA1+/DAPI+ cells in the ipsilateral dorsal horn on day 15 were significantly lower in BCP-flavopiridol rats than in BCP-vehicle rats (p < 0.01, one-way ANOVA; Figures 4g to 4l).
Fig. 4
Behaviourally, rats with BCP treated with flavopiridol from days 3 to 15 showed a significant recovery in the decreased paw withdrawal threshold (Figure 5a), paw withdrawal latency (Figure 5b), limb use scores (Figure 5e), or in the increased number of spontaneous flinches (Figure 5c) and activity-related guarding scores (Figure 5d). After the last administration of flavopiridol on day 15, the significant attenuation of pain behaviours remained on day 20 (paw withdrawal threshold (p < 0.01, two-way ANOVA; Figure 5a), paw withdrawal latency (p < 0.01; Figure 5b), number of spontaneous flinches (p < 0.01; Figure 5c), and activity-related guarding scores (p < 0.01; Figure 5d)).
Fig. 5
Discussion
Microglia are regarded as the immune cells in the CNS and the PNS, and are activated quickly in response to outside stimuli, surveying the environments with their ramified processes and monitoring synaptic activity and microenvironments. Studies of inflammation pain and neuropathic pain have focused on the early phase of the pathology; little is known about the dynamics of the microglia response for BCP, a chronic pain.16,30 In our experiments, IBA1 mRNA in the ipsilateral spinal horn increased in a time-dependent fashion, and IBA1 protein (a microglia marker) increased from day 5 to day 20 (Figures 1a to 1c, Figures 3d to 3i). Also, most Ki67+/DAPI+ cells (in all phases of the cell cycle, excluding the resting phase, Figures 2a to 2f) and p-HisH3+/DAPI+ cells (in G2/M phase of the cell cycle, Figures 2g to 2l) were labelled with IBA1, which means that resident microglia proliferate under the BCP condition. Activated microglia produce and release a series of diffusible factors, including interleukin (IL)-1β, IL-6, tumour necrosis factor alpha (TNF-α), protease, and nitric oxide in response to outside stimuli via cognate receptors.12 These factors influence spinal neuronal function via direct or indirect actions. Microglia contract presynaptic terminals and dendritic spines, extending neuronal excitation and contributing to neuronal plasticity.31,32
Minocycline inhibited microglia activity selectively. Behaviourally, rats with BCP treated with minocycline (i.t.) showed a dose-dependent recovery in the decreased paw withdrawal threshold (Figure 1d), paw withdrawal latency (Figure 1e), limb use scores (Figure 1h), or in the increased number of spontaneous flinches (Figure 1f), and activity-related guarding scores (Figure 1g). After the last administration of minocycline on day 15, the significant attenuation of pain behaviours remained on day 20 (Figures 1d to 1h). Therefore, these results suggest that microglia proliferation contributes to pain behaviour in BCP rats. It is possible that inhibition of proliferated microglia may relieve pain behaviour in BCP.
Cyclins and their kinase partners regulate cell cycle progression. Disruption of restriction-point control may be a common biological feature in clinical treatment. There are two families of cyclins, the cyclin D family (D1, D2, and D3) and the cyclin E family (E1 and E2). Importantly, cyclin D1 regulated the proliferation of spinal astrocytes in a rat model of neuropathic pain.9 The failure of tumours in the cyclin D1-deficient animals to progress to higher grades was correlated with a failure to fully activate microglia in the tumour microenvironment.33 Cyclin D1 is the biomarker protein expressed in G1 or G2/M transition. Compared with the sham controls, the mRNA (Figure 3a) and protein (Figures 3b and 3c) of cyclin D1 increase started at five days after carcinoma cell injection. The number of cyclin D1+/DAPI+ cells in the ipsilateral dorsal horn increased significantly in a time-dependent manner, starting at day 10 after BCP, and peaking at day 20 (p < 0.001, one-way ANOVA; Figures 3d to 3i). Most cyclin D1+/DAPI+ cells were colocalized with microglia (Figures 3d to 3i). The pool of microglia (IBA1+ cells) was already diminished at postnatal day 3 in the absence of cyclin D1, while the number of astrocytes remained unchanged in the cerebral cortex.34 Based on these results, we concluded that cyclin D1 regulates the proliferation of microglia in a rat model of BCP, and the proliferation of astrocytes in a rat model of neuropathic pain.9,35 This discrepancy might be explained by different animal models (BCP versus chronic constrictive injury), treatment regimen (female SD rats versus male Wistar rats), and different timepoints (day 20 vs day 10).
Flavopiridol is a cell cycle inhibitor that inhibits glia proliferation in vivo and in vitro.9 Flavopiridol reduces cyclin D1 mRNA transcription, and arrests cells in G1 or G2/M transition.29 In our experiment, flavopiridol attenuated the increase of the mRNA (Figure 4a) and protein (Figures 4b and 4c) of cyclin D1, and decreased the number of IBA1+/DAPI+ cells, cyclin D1+/DAPI+ cells, and cyclin D1+/IBA1+/DAPI+ cells in the ipsilateral dorsal horn significantly (Figures 4d to 4f). Also, flavopiridol decreased the number of Ki67+/DAPI+ cells, Ki67+/IBA1+/DAPI+ cells, p-HisH3+/DAPI+ cells, and p-HisH3+/IBA1+/DAPI+ cells in the ipsilateral dorsal horn (Figures 4g to 4l). We concluded that flavopiridol inhibited the microglia proliferation by reducing cyclin D1 in BCP rats.
Cell cycle modulation may provide an effective therapeutic strategy to reduce hyperpathia after spinal cord injury.36 Cyclin D1 is the marker protein of G1 or G2/M transition. The number of cyclin D1+/DAPI+ cells in the ipsilateral dorsal horn increased significantly and most cyclin D1+/DAPI+ cells were colocalized with microglia (Figure 3). If cyclin D1 regulates pain behaviour, disruption of this cell cycle should recover the pain threshold. In our study, flavopiridol, a cell cycle inhibitor, prevented the decrease of paw withdrawal threshold, paw withdrawal latency, limb use scores, orthe increase of spontaneous flinches, activity-related guarding scores (Figure 5). After the last administration of flavopiridol on day 15, the significant attenuation of pain behaviours remained on day 20, excluding limb use scores (Figure 5). Therefore, these results suggest that cyclin D1 contributes to pain behaviour in BCP rats, and disruption of this cell cycle recovers the pain threshold.
In conclusion, our results revealed that the inhibition of spinal microglial proliferation was associated with a decrease in pain behaviour in a rat model of BCP. Cyclin D1 acts as a key regulator of the proliferation of spinal microglia in BCP rats. Disruption of cyclin D1, the restriction-point control of cell cycle, could inhibit the proliferation of microglia and attenuate the pain behaviour in BCP rats. Our findings suggest that cyclin D1 and the proliferation of spinal microglia may be potential targets for the clinical treatment of BCP.
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Author contributions
X. H. Guan: Writing – review & editing, Funding acquisition, Conceptualization.
X. F. Gong: Project administration, Resources.
Z. Y. Jiao: Methodology, Investigation.
H. Y. Cao: Methodology, Project administration.
S. S. Liu: Investigation, Formal analysis.
C. X. Lin: Writing – original draft, Validation.
X. F. Huang: Software.
H. M. Lan: Data curation.
L. Ma: Supervision, Validation.
B. Xu: Data curation, Visualization, Conceptualization.
Funding statement
The authors disclose receipt of the following financial or material support for the research, authorship, and/or publication of this article: this work was supported by the Natural Science Foundation of Guangxi Zhuang Autonomous Region (No. 2022GXNSFAA035628) and the National Natural Science Foundation of China (No. 81660200).
ICMJE COI statement
The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. The authors declare no conflict of interest.
Data sharing
The data generated during the current study are available from the corresponding author on reasonable request.
Acknowledgements
We are grateful to Jin Wei and the Medical Sciences Research Center of the People’s Hospital of Guangxi Zhuang Autonomous Region for their kind assistance.
Ethical review statement
All experimental protocols were approved by the Animal Care and Use Committee of The First Affiliated Hospital of Guangxi Medical University and were in accordance with the Declaration of the National Institutes of Health Guide for Care. We have included an ARRIVE checklist to show that we have conformed to the ARRIVE guidelines.
Open access funding
The authors confirm that the open access fee for this study was self-funded.
Supplementary material
ARRIVE checklist and additional experiment details.
© 2022 Author(s) et al. This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivatives (CC BY-NC-ND 4.0) licence, which permits the copying and redistribution of the work only, and provided the original author and source are credited. See https://creativecommons.org/licenses/by-nc-nd/4.0/