Pingping Qiao1, Jun Zhu2, Xiaoheng Lu3, Yifei Jin3, Yifan Wang3, Qianqian Shan4, Yaxian Wang1. 1. Nantong University, Key Laboratory of Neuroregeneration of Jiangsu and Ministry of Education, Co-innovation Center of Neuroregeneration, NMPA Key Laboratory for Research and Evaluation of Tissue Engineering Technology Products, Nantong, Jiangsu, China. 2. The Affiliated Hospital of Nantong University, Department of Thoracic Surgery, Nantong, Jiangsu, China. 3. Medical School of Nantong University, Nantong, Jiangsu, China. 4. The Affiliated Hospital of Nantong University, Department of Radiotherapy and Oncology, Nantong, Jiangsu, China.
Abstract
Macrophages benefit myelin debris removal, blood vessel formation, and Schwann cell activation following peripheral nerve injury. Identifying factors that modulate macrophage phenotype may advantage the repair and regeneration of injured peripheral nerves. microRNAs (miRNAs) are important regulators of many physiological and pathological processes, including peripheral nerve regeneration. Herein, we investigated the regulatory roles of miR-140-3p, a miRNA that was differentially expressed in injured rat sciatic nerves, in macrophage RAW264.7 cells. Observations from EdU proliferation assay demonstrated that elevated miR-140-3p decreased the proliferation rates of RAW264.7 cells while suppressed miR-140-3p increased the proliferation rates of RAW264.7 cells. Transwell-based migration assay showed that up-regulated and down-regulated miR-140-3p led to elevated and reduced migration abilities, respectively. However, the abundances of numerous phenotypic markers of M1 and M2 macrophages were not significantly altered by miR-140-3p mimic or inhibitor transfection. Bioinformatic analysis and miR-140-3p-induced gene suppression examination suggested that Smad3 might be the target gene of miR-140-3p. These findings illuminate the inhibitory effects of miR-140-3p on the proliferation and migration of macrophages and contribute to the cognition of the essential roles of miRNAs during peripheral nerve regeneration.
Macrophages benefit myelin debris removal, blood vessel formation, and Schwann cell activation following peripheral nerve injury. Identifying factors that modulate macrophage phenotype may advantage the repair and regeneration of injured peripheral nerves. microRNAs (miRNAs) are important regulators of many physiological and pathological processes, including peripheral nerve regeneration. Herein, we investigated the regulatory roles of miR-140-3p, a miRNA that was differentially expressed in injured rat sciatic nerves, in macrophage RAW264.7 cells. Observations from EdU proliferation assay demonstrated that elevated miR-140-3p decreased the proliferation rates of RAW264.7 cells while suppressed miR-140-3p increased the proliferation rates of RAW264.7 cells. Transwell-based migration assay showed that up-regulated and down-regulated miR-140-3p led to elevated and reduced migration abilities, respectively. However, the abundances of numerous phenotypic markers of M1 and M2 macrophages were not significantly altered by miR-140-3p mimic or inhibitor transfection. Bioinformatic analysis and miR-140-3p-induced gene suppression examination suggested that Smad3 might be the target gene of miR-140-3p. These findings illuminate the inhibitory effects of miR-140-3p on the proliferation and migration of macrophages and contribute to the cognition of the essential roles of miRNAs during peripheral nerve regeneration.
Peripheral nerves, unlike central nerves, exhibit a remarkable spontaneous
regeneration capacity after nerve injury. The successful regeneration of injured
peripheral nerves largely depends on the reprogramming of Schwann cells, the
attraction and recruitment of macrophages, and the activation of the intrinsic
growth capacity of affected neurons (Chen Z-L
; Jessen
and Mirsky, 2016). Following peripheral nerve injury, infiltrated
macrophages clear redundant myelin debris and eliminate inhibiting factors for
subsequent axon growth (Chen P ). Besides their phagocytosis function, macrophages
sense hypoxia, encourage angiogenesis, and promote the proliferation and directional
migration of Schwann cells (Cattin ; Liu ). Therefore, regulating the biological activities
of macrophages may facilitate the regeneration of injured peripheral nerves.Emerging studies have demonstrated that non-coding RNAs, especially microRNAs
(miRNAs), play essential roles following peripheral nerve injury (Yu ). miRNAs are
evolutionarily conserved single-stranded non-coding RNAs containing ~22 nucleotides
(Bartel, 2018). miRNAs pair with
complementary sequences within their target mRNAs and thus silence their target
mRNAs post-transcriptionally (Bartel, 2009). A
large number of miRNAs have been found to be dysregulated in peripheral nerves after
nerve injury, implying the involvement of miRNAs in the peripheral nerve repair and
regeneration process (Li ; Yu ). Further functional studies have demonstrated that many
differentially expressed miRNAs participate in the modulation of various types of
cells in peripheral nerves, such as Schwann cells, neurons, and endothelial cells
(Yi ; 2017; Ji
; Wang X
). Therefore, it is likely that
differentially expressed miRNAs following peripheral nerve injury may also regulate
the cellular behaviors of macrophages.Sequencing data of injured rat sciatic nerves showed that miR-140-3p, a miRNA
previously annotated as miR-140* according to miRbase database (Ambros ), was one
of the most highly expressed and significantly dysregulated miRNAs in the injured
peripheral nerves (Yu ). However, whether differentially expressed miR-140-3p modulates the
phenotype of macrophages remains largely unrevealed. Therefore, in the current
study, we cultured macrophage RAW264.7 cells, transfected macrophages with
miR-140-3p mimic or inhibitor to increase or decrease miR-140-3p abundance,
respectively, and examined the functional roles of miR-140-3p in the proliferation,
migration, and polarization of macrophages. Potential targets of miR-140-3p were
also investigated using bioinformatic tools and expression correlation analysis.
Material and Methods
Cell culture and transfection
The murine macrophage cell line RAW264.7 was purchased from the Typical Culture
Preservation Commission (Chinese Academy of Sciences, Shanghai Institutes for
Biological Sciences Cell Resource Center, Shanghai, China). RAW264.7 cells were
cultured in DMEM (Corning, Coring, NY, USA) supplemented with 10%
heat-inactivated FBS (Gibco, Grand Island, NY, USA) in a 5% CO2
incubator at 37°C. Cultured RAW264.7 cells were transfected with miR-140-3p
mimic, miR-140-3p inhibitor, or corresponding non-targeting controls (RiboBio,
Guangzhou, Guangdong, China) using Lipofectamine RNAiMAX transfection reagent
(Invitrogen, Carlsbad, CA, USA).
Quantificational real time PCR (qRT-PCR)
RNA samples were isolated from cultured RAW264.7 cells using RNA-Quick
Purification Kit (Yishan Biotechnology Co., LTD, Shanghai, China) and reversely
transcribed using Bulge-LoopTM miRNA qRT-PCR Starter Kit (RiboBio) or
HiScript III RT SuperMix for qPCR (+gDNA wiper) (Vazyme, Nanjing, Jiangsu,
China). A StepOne Real-time PCR System (Applied Biosystems, Foster City, CA,
USA) was used to determine the Ct values of miR-140-3p, miRNA internal control
U6, Cd86, Tnf,
Gpr18, Egr2, Myc,
Il-10, Smad3, and mRNA internal control
Gapdh. The comparative 2-ΔΔCt method was applied
to calculate relative gene expressions. Bulge-loopTM miRNA qRT-PCR
Primer Sets specific for miR-140-3p was designed and synthesized by RiboBio and
primer sets for coding RNAs were synthesized by Sangon Biotech (Shanghai,
China). Primer sequences (Table 1) were
designed using Primer Express® software (v3.0.1; Thermo Fisher Scientific,
Inc.). The amplification efficiency of primer pairs was determined by producing
serial dilutions of the DNA sample. Primers with amplification efficiencies
between 90% and 110% were selected (Seol
).
Table 1.
Nucleotide sequences of the primers used in qRT-PCR.
Cell counting kit-8 (CCK-8) proliferation assay kit (Beyotime Biotechnology,
Shanghai, China) was used to determine the effect of miR-140-3p on the viability
of cells according to the manufacturer’s instructions. Briefly, RAW264.7 cells
were transfected with miR-140-3p mimic, mimic control, miR-140-3p inhibitor, or
inhibitor control for 36 hours, respectively. Then cells were seeded onto a
96-well cell culture plate and treated with 10 μl CCK-8 solution for 2 hours
(Shen ).
A microplate reader (Bio-Rad Laboratories, Inc., Hercules, CA, USA) was applied
to measure the optical density (O.D.) readings at 450 nm and to calculate the
relative number of viable RAW264.7 cells in the medium.
Cell proliferation assay
Cell-LightTM EdU DNA Cell Proliferation Kit (RiboBio) was applied to
examine the effect of miR-140-3p on the proliferation rate of cells as
previously reported (Bei ). Briefly, after transfection with miR-140-3p mimic, miR-140-3p
inhibitor, or corresponding non-targeting controls for 36 hours, RAW264.7 cells
were exposed to 50 μM EdU (RiboBio) for 2 hours and fixed with 4% formaldehyde
(Xilong Scientific, Guangzhou, China) in PBS for 30 minutes. Cells were labeled
with Hoechst 33342 staining in blue color while proliferative cells were labeled
with EdU staining in red color. Images were taken under a DMR fluorescence
microscope (Leica Microsystems, Bensheim, Germany) and the relative
proliferation rate of RAW264.7 cells was calculated by dividing the number of
proliferative RAW264.7 cells to the number of total cells in randomly selected
fields.
Cell migration assay
A transwell-based cell migration assay was conducted to evaluate the effect of
miR-140-3p on the migration ability of RAW264.7 cells. RAW264.7 cells
transfected with miR-140-3p mimic, miR-140-3p inhibitor, or corresponding
non-targeting controls were resuspended in DMEM. Cell suspension was added to
the upper chamber of a 6.5 mm transwell chamber with 8 μm pores (Costar,
Cambridge, MA, USA) while FBS containing complete cell culture medium was added
to the lower chamber. After 36 hours of culture, RAW264.7 cells left on upper
surface of the upper chamber were scraped away with a cotton swab while invaded
cells on the bottom surface were fixed in 4% paraformaldehyde, stained with 0.1%
crystal violet, and observed under a DMR inverted microscope (Leica
Microsystems). The relative migration ability of RAW264.7 cells was calculated
by measuring crystal violet-stained areas in randomly selected fields. In
addition, cell migration was confirmed with a second assay using
fibronectin-coated transwells. The procedure was the same as above except that
the surface of the transwell chamber was pre-coated with a layer fibronectin
(EMD Millipore Corporation, Temecula, CA, USA) before cells plantation, as
previously reported (Cougoule ; Börschel
).
Bioinformatic analysis of potential target genes of miR-140
The prediction of potential target genes of mmu-miR-140 and the involvement of
Gene Ontology (GO) terms and Kyoto Enrichment of Genes and Genomes (KEGG)
pathways were analyzed using the ClueGo plug-in in the Cytoscape software (Shannon ).
Enriched GO terms and KEGG pathways of potential target genes
Smad3, Cxcl12, and Hdac4
with a p-value cutoff of 0.05 were selected. An interaction network of
mmu-miR-140, potential target genes Smad3,
Cxcl12, and Hdac4, and potential target
gene-involved GO terms and KEGG pathways were constructed using the Cytoscape
software.
Statistical analysis
Statistical analysis was conducted by the Student's t-test or
one-way analysis of variance (ANOVA) test using GraphPad Prism 5.0 (GraphPad
Software, Inc., San Diego, CA, USA). Differences with a p-value less than 0.05
were considered statistically significant.
Results
miR-140-3p affects cell viability of macrophages
Cultured macrophage RAW264.7 cells were transfected with miR-140-3p mimic, mimic
control, miR-140-3p inhibitor, or inhibitor control to determine the functional
effects of miR-140-3p on macrophages. Compared with RAW264.7 cells or cells
transfected with mimic control, RAW264.7 cells transfected with miR-140-3p mimic
exhibited robust elevation of miR-140-3p expression (Figure 1A-C). In contrast, RAW264.7 cells transfected with
miR-140-3p inhibitor showed a vigorous reduction of the abundance of miR-140-3p
(Figure 1A, B, D), indicating the high
efficiency of cellular transfection. We then examined the effect of miR-140-3p
on macrophage viability. The results showed that compared with mimic control,
miR-140-3p mimic significantly decreased the cell viability (Figure 1E). While miR-140-3p inhibitor
significantly increased cell viability compared with the control group (Figure 1F).
Figure 1 -
Effect of miR-140-3p on macrophage viability. (A)
The amplification plot of miR-140-3p in RAW264.7 cells.
(B) The amplification plot of miR-140-3p in
RAW264.7 cells transfected with miR-140-3p mimic (Mimic), mimic
control (MC), inhibitor (Inhibit), or inhibitor control (IC),
respectively. (C) The relative abundances of miR-140-3p
in RAW264.7 cells after transfection with mimic control (MC) or
miR-140-3p mimic (Mimic). (D) The relative abundances
of miR-140-3p in RAW264.7 cells after transfection with inhibitor
control (IC) or miR-140-3p inhibitor (Inhibit). (E) The
cell viability of RAW264.7 cells transfected with mimic control (MC)
or miR-140-3p mimic (Mimic). (F) The cell viability of
RAW264.7 cells transfected with inhibitor control (IC) or miR-140-3p
inhibitor (Inhibit). All data were summarized from 3 paired
experiments (n=3). Numerical data were presented as means ± SEM.
Asterisk represents statistically different from control (***
indicates p-value < 0.001, * indicates p-value <
0.05).
miR-140-3p inhibits the proliferation of macrophages
The effect of miR-140-3p on macrophage proliferation was then investigated.
Considerable cells were observed to be existed in a proliferating state in
RAW264.7 cells transfected with mimic control or inhibitor control. Compared
with cells transfected with mimic control, less amount of RAW264.7 cells were
labeled as EdU-positive cells. Rather, the number of EdU-positive RAW264.7 cells
was obviously higher in cells transfected with miR-140-3p inhibitor as compared
with cells transfected with inhibitor control (Figure 2). The inhibiting role of miR-140-3p mimic and the promoting
role of miR-140-3p inhibitor in RAW264.7 cell proliferation suggest that
miR-140-3p suppresses the proliferation of macrophages.
Figure 2-
Effect of miR-140-3p on macrophage proliferation. Representative
EdU staining images of RAW264.7 cells transfected with mimic control
(MC), miR-140-3p mimic (Mimic), inhibitor control (IC), or
miR-140-3p inhibitor (Inhibit). The proliferation rates of RAW264.7
cells were determined as the relative ratio of EdU-positive cells to
total cells in the experiment group as compared with the
corresponding control group and the cell proliferation assay was
repeated four times using triplicate wells (n=12). Numerical data
were presented as means ± SD. Red color represents EdU staining and
blue color represents Hoechst 33342 staining. Scale bars represents
100 μm. Asterisk represents statistically different from control
(*** indicates p-value < 0.001).
miR-140-3p inhibits the migration of macrophages
Transwell migration assay was applied to observe the effect of miR-140-3p on
macrophage migration. Crystal violet staining of the bottom surface of the upper
chamber of transwell showed that RAW264.7 cells obtain certain ability to
migrate across transwell. However, following the transfection of miR-140-3p
mimic, crystal violet-stained areas of migrated cells reduced to about 60% as
compared with stained areas in the control group. In contrast, RAW264.7 cells
transfected with miR-140-3p inhibitor had enlarged crystal violet-stained areas
(Figure 3). Additionally, we obtained
similar results in the second fibronectin-coated transwells assay (Figure 4). These observations indicate that
besides the proliferation of macrophages, miR-140-3p also exhibit inhibitory
effect on the migration of macrophages.
Figure 3-
Effect of miR-140-3p on macrophage migration. Representative
transwell migration images of RAW264.7 cells transfected with mimic
control (MC), miR-140-3p mimic (Mimic), inhibitor control (IC), or
miR-140-3p inhibitor (Inhibit). The migration abilities of RAW264.7
cells were determined as the relative crystal violet-stained areas
in the experiment group as compared with the corresponding control
group. All data were summarized from 3 paired experiments (n=3).
Numerical data were presented as means ± SD. Scale bars represents
50 μm. Asterisks represent statistical differences from control (***
indicates p-value < 0.001).
Figure 4 -
Effect of miR-140-3p on macrophage migration through
fibronectin-coated transwells. Representative transwell migration
images of RAW264.7 cells transfected with mimic control (MC),
miR-140-3p mimic (Mimic), inhibitor control (IC), or miR-140-3p
inhibitor (Inhibit). All data were summarized from 3 paired
experiments (n=3). Numerical data were presented as means ± SD.
Scale bars represents 50 μm. Asterisks represent statistical
differences from control (*** indicates p-value < 0.001).
miR-140-3p mimic reverses the effect of the inhibitor
Quantificational results showed that miR-140-3p mimic significantly increased the
expression level of miR-140-3p (over 300 fold). So, we wondered if miR-140-3p
mimic could reverse the effect of the inhibitor when RAW264.7 cells were
transfected with both. PCR results showed that miR-140-3p inhibitor
significantly reduced the expression level of miR-140-3p which was consistent
with the above results. However, miR-140-3p mimic reversed the effect of
inhibitor and elevated the abundance of miR-140-3p when RAW264.7 cells were
simultaneously transfected with miR-140-3p inhibitor and mimic (Figure 5A, B). Cellular behavior evaluation
showed that miR-140-3p mimic reversed the ability of miR-140-3p inhibitor to
promote cell proliferation and migration (Figure
5C, D).
Figure 5-
miR-140-3p mimic reverses the effect of the inhibitor.
(A) The amplification plot of miR-140-3p in
RAW264.7 cells transfected with miR-140-3p inhibitor (Inhibit),
inhibitor control (IC) or miR-140-3p inhibitor+mimic
(Inhibit+Mimic), respectively. (B) The relative
abundances of miR-140-3p in RAW264.7 cells after transfection with
inhibitor control (IC), miR-140-3p inhibitor (Inhibit) or miR-140-3p
inhibitor+mimic (Inhibit+Mimic). (C) Representative EdU
staining images of RAW264.7 cells transfected with inhibitor control
(IC), miR-140-3p inhibitor (Inhibit) or miR-140-3p inhibitor+mimic
(Inhibit+Mimic), Scale bars represents 100 μm. (D)
Representative transwell migration images of RAW264.7 cells
transfected with inhibitor control (IC), miR-140-3p inhibitor
(Inhibit) or miR-140-3p inhibitor+mimic (Inhibit+Mimic), Scale bars
represents 50 μm. All data were summarized from 3 paired experiments
(n=3). Numerical data were presented as means ± SD. Asterisks
represent statistical differences between groups (*** indicates
p-value < 0.001, * indicates p-value < 0.05).
miR-140-3p does not affect the polarization of macrophages
Pro-inflammatory (M1) and anti-inflammatory (M2) macrophages execute unique
functions in diverse biological activities. The switch of M1 and M2 phenotypes
of macrophages is also involved in the regeneration of injured peripheral
nerves. Therefore, the expression levels of M1 and M2 macrophage markers in
miR-140-3p-transfected RAW264.7 cells were evaluated to identify whether
miR-140-3p would affect the M1/M2 polarization of macrophages. RT-PCR results
showed that neither miR-140-3p mimic nor miR-140-3p inhibitor significantly
altered the abundances of mRNAs coding for M1/M2 markers Cd86
and Tnf or M2 macrophage markers Egr2,
Myc, and Il10. For M1 macrophage marker
Gpr18, although the mRNA expression of
Gpr18 seemed to be decreased after miR-140-3p inhibitor
transfection, the expression of Gpr18 was not increased after
miR-140-3p mimic transfection (Figure 6).
These outcomes imply that miR-140-3p may not induce changes of M1 and M2
phenotypes of macrophages.
Figure 6-
Effect of miR-140-3p on macrophage polarization. The relative
abundances of Cd86, Tnf,
Gpr18, Egr2,
Myc, and Il10 in RAW264.7
cells after transfection with mimic control (MC), miR-140-3p mimic
(Mimic), inhibitor control (IC), or miR-140-3p inhibitor (Inhibit).
Gene abundances were determined as the relative expressions in the
experiment group as compared with the corresponding control group
and summarized from 3 paired experiments (n=3). Numerical data were
presented as means ± SEM. Asterisks represent statistical
differences from control (* indicates p-value < 0.05) and ns
represents non-statistically relevant to the control group.
Identification of potential targets of miR-140
Potential target genes of miR-140 in macrophage RAW264.7 cells were discovered
using Cytoscape bioinformatic analysis software in view of the fact that miRNAs
regulate biological activities via binding to and suppressing their target
genes. A total of four coding genes, i.e., Asp1,
Smad3, Cxcl12, and Hdac4,
were identified to be potential target genes of mmu-miR-140 (Figure 7A). Downstream GO terms and KEGG
pathways of these candidate target genes were identified and an interaction
network between mmu-miR-140, candidate target genes of mmu-miR-140, as well as
involved GO terms and KEGG pathways was generated (Figure 7B). Asp1 was not found to be significantly
related with GO terms or KEGG pathways and thus was not displayed in the
interaction network. The constructed network showed that Smad3
was associated with activities enriched in functional groups of mineralcorticoid
receptor binding, osteoblasts development, and positive regulation of positive
chemotaxis, Hdac4 was associated with osteoblasts development,
positive regulation of positive chemotaxis, and regulation of myotube
differentiation, while Cxcl12 was associated with regulation of
myotube differentiation, response to ultrasound, and positive regulation of
positive chemotaxis. Considering that Smad3 was linked to a
large number of essential biological processes, the regulating effect of
miR-140-3p on Smad3 mRNA expression was further examined.
RT-PCR results demonstrated that the mRNA expression of Smad3
was reduced after miR-140-3p mimic transfection but was increased after
miR-140-3p inhibitor transfection, suggesting that miR-140-3p negatively
regulates the abundance of Smad3 mRNA (Figure 7C).
Figure 7 -
Candidate target genes of miR-140. (A) Predicted
potential target genes of mmu-miR-140. (B) The
miRNA-potential target gene-biological activity network of
mmu-miR-140. Dotted lines represent interactions between mmu-miR-140
and Smad3, Cxcl12, and
Hdac4 while solid lines represent interactions
between Smad3, Cxcl12, and
Hdac4 and GO terms or KEGG pathways. Diverse
groups of biological functions are indicated by different colors.
Node sizes reflect the enrichment of biological functions.
(C) The relative abundances of
Smad3 in RAW264.7 cells after transfection with
mimic control (MC), miR-140-3p mimic (Mimic), inhibitor control
(IC), or miR-140-3p inhibitor (Inhibit). The abundances of
Smad3 were determined as the relative
expressions in the experiment group as compared with the
corresponding control group and summarized from 3 paired experiments
(n=3). Numerical data were presented as means ± SEM. Asterisks
represent statistical differences from control (* indicates p-value
< 0.05).
Discussion
Functional recovery of injured peripheral nerves requires the joint work of neurons,
Schwann cells, endothelial cells, macrophages, fibroblasts, and other types of
cells. miRNAs extensively regulate the biological functions of various types of
cells and execute considerable functions during peripheral nerve regeneration. By
performing deep sequencing, the expression patterns of miRNAs in the proximal nerve
stumps after rat sciatic nerve injury were explored and many dysregulated miRNAs
were screened, including miR-140-3p (Yu ).Although the regulatory roles of miR-140-3p in Schwann cells have not been reported,
a previous study examined the effect of miR-140-5p, a miRNA that originates from the
opposite arm of the pre-miR-140, on Schwann cells and showed that miR-140-5p
inhibits the differentiation and myelination of Schwann cells (Viader ). The biological functions
of miR-140 on endothelial cells have also been discovered. For example, Sun ) found that
miR-140-5p inhibits the viability, migration, and tube formation of human umbilical
vein endothelial cells Zhang H ) demonstrated that miR-140-3p impairs the
viability and colony formation ability of human coronary endothelial cells. Liang )
demonstrated that miR-140-3p impairs the proliferation, wound healing, and tube
formation of human umbilical vein endothelial cells. Here, we examined the
regulatory effects of miR-140 on macrophages and found that miR-140-3p decreases the
cell viability, and inhibits the proliferation and migration of macrophages.
Therefore, it is possible that elevated miR-140-3p after peripheral nerve injury may
play inhibitory roles in the cellular behaviors of Schwann cells, endothelial cells,
and macrophages and impair the nerve regeneration process. Therefore, therapies
targeting at suppressing the expression of miR-140-3p may benefit peripheral nerve
regeneration.Besides cellular proliferation and migration, the polarization of macrophages and
changes of M1 and M2 macrophages are highly associated with the regeneration process
(Liu ; Zhang F ). At
present, a number of miRNAs have been confirmed to be involved in the regulation of
macrophage polarization. For example, miR-9, miR-127, miR-155, and miR-125b have
been shown to promote M1 polarization while miR-124, miR-223, miR-34a, let-7c,
miR-132, miR-146a, and miR-125a-5p induce M2 polarization in macrophages (Essandoh ). To
evaluate the potential effect of miR-140-3p on the polarization of M1/M2
macrophages, the mRNA expression patterns of canonical macrophage markers as well as
novel murine M1 macrophage marker Gpr18 and novel murine M2
macrophage markers Egr2 and Myc were determined
(Jablonski ). Quantificational outcomes did not reveal significant alternations of
the abundances of universal macrophage markers and M1/M2-exclusive macrophage
markers, suggesting that miR-140-3p may fail to induce M1/M2 phenotype switch in
macrophages.The potential downstream target genes and biological implications of miR-140-3p were
further analyzed. Notably, Smad3, a well-known intracellular signal
transducer of TGF-β signaling pathway, was identified as a candidate target gene of
miR-140-3p. Mojsilovic ) reported that estramustine phosphate (EP) inhibited RAW264.7 cell
migration by decreasing the ability of TGF-β to trigger the
activation of its downstream Smad3 effector. Therefore,
Smad3 is an important factor affecting cell migration.
Cytoscape analyses-identified Smad3-associated GO terms and KEGG
pathways are also closely connected with tissue development and regeneration. For
instance, mineralcorticoid receptor activation adjust the pro-inflammatory signaling
and regulate the injury response of cardiac tissue (Ong ). Macrophage chemotaxis, i.e.,
external stimulus-induced movement of macrophages, is important for the initiation
of the repair and regeneration of injured tissues, including the nervous system
(Calcutt ;
Bosurgi ;
Yano ; Wang P ). These
findings, together with the inhibitory effect of miR-140-3p on
Smad3 mRNA expression, indicate that miR-140-3p may participate
in macrophage phenotype modulation and peripheral nerve regeneration via negatively
regulating Smad3, which remains to be confirmed by our further
study.Collectively, our results reveal functional effects of miR-140-3p on macrophages and
suggest that overexpression and silencing of miR-140-3p inhibits and promotes the
proliferation rate and migration ability of macrophages, respectively. These
findings contribute to a better understanding of the essential regulatory roles of
miR-140-3p in multiple cell types and emphasize the functional involvement of miRNAs
in peripheral nerve repair and regeneration.
Authors: N A Calcutt; H F McMurray; D F Moorhouse; M Bache; S Parthasarathy; H C Powell; A P Mizisin Journal: Exp Neurol Date: 1994-08 Impact factor: 5.330
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