Peripheral nerve injury (PNI) is a relatively frequent type of trauma that results in the suffering of many patients worldwide every year. Schwann cells (SCs) are expected to be applied in cell therapy because of their ability to promote peripheral nerve regeneration. However, the lack of clinically renewable sources of SCs hinders the application of SC-based therapies. Adipose-derived stem cells (ADSCs) have generated great interest in recent years because of their multipotency and ease of harvest, and they have already been verified to differentiate into Schwann-like cells (SLCs) in vitro. However, the efficiency of differentiation and the functions of SLCs remain unsatisfactory. We newly generated three-dimensional (3D) SLC spheroids from ADSCs using a modified protocol with human recombinant peptide (RCP) petaloid μ-piece. Morphological analysis, gene expression analysis by qRT-PCR, ELISA measurement of the secretion capabilities of neurotrophic factors, and neurite formation assay were performed to evaluate the functions of these 3D SLCs in vitro. Motor function recovery was measured in a sciatic nerve injury mouse model to analyze the nerve regeneration-promoting effect of 3D SLCs in vivo. The differentiation efficiency and the secretion of neurotrophic factors were enhanced in 3D SLCs compared with conventional SLCs. 3D SLCs could more effectively promote neurite growth and longer neurite extension in a neuron-like SH-SY5Y model. Additionally, 3D SLCs had a better therapeutic effect on nerve regeneration after transplantation into the sciatic nerve injury mouse model. These findings demonstrated that the potential of ADSC-derived SLCs to promote nerve regeneration could be significantly increased using our modified differentiation protocol and by assembling cells into a 3D sphere conformation. Therefore, these cells have great potential and can be used in the clinical treatment of PNI.
Peripheral nerve injury (PNI) is a relatively frequent type of trauma that results in the suffering of many patients worldwide every year. Schwann cells (SCs) are expected to be applied in cell therapy because of their ability to promote peripheral nerve regeneration. However, the lack of clinically renewable sources of SCs hinders the application of SC-based therapies. Adipose-derived stem cells (ADSCs) have generated great interest in recent years because of their multipotency and ease of harvest, and they have already been verified to differentiate into Schwann-like cells (SLCs) in vitro. However, the efficiency of differentiation and the functions of SLCs remain unsatisfactory. We newly generated three-dimensional (3D) SLC spheroids from ADSCs using a modified protocol with human recombinant peptide (RCP) petaloid μ-piece. Morphological analysis, gene expression analysis by qRT-PCR, ELISA measurement of the secretion capabilities of neurotrophic factors, and neurite formation assay were performed to evaluate the functions of these 3D SLCs in vitro. Motor function recovery was measured in a sciatic nerve injury mouse model to analyze the nerve regeneration-promoting effect of 3D SLCs in vivo. The differentiation efficiency and the secretion of neurotrophic factors were enhanced in 3D SLCs compared with conventional SLCs. 3D SLCs could more effectively promote neurite growth and longer neurite extension in a neuron-like SH-SY5Y model. Additionally, 3D SLCs had a better therapeutic effect on nerve regeneration after transplantation into the sciatic nerve injury mouse model. These findings demonstrated that the potential of ADSC-derived SLCs to promote nerve regeneration could be significantly increased using our modified differentiation protocol and by assembling cells into a 3D sphere conformation. Therefore, these cells have great potential and can be used in the clinical treatment of PNI.
Entities:
Keywords:
Schwann-like cells; adipose-derived stem cells; nerve regeneration; three-dimensional model
Peripheral nerve injury (PNI) is a relatively frequent type of trauma that
affects more than 1 million people worldwide every year and is a global
clinical problem that exhibits a significant socioeconomic burden
. Autologous nerve anastomosis is considered the gold standard for PNI treatment
. However, because of the need to sacrifice naive nerve tissues, the
risk of neuroma formation, and other complications associated with this
second surgery, its application is limited[3,4]. In addition, PNI
caused by pelvic surgery must be addressed to improve patients’ quality of life
. Cell therapy based on Schwann cells (SCs) may be a good option
because the mechanism is ideal. Previous reports demonstrated that SCs could
accelerate peripheral nerve repair through a variety of mechanisms,
including establishment of a regeneration guide, secretion of neurotrophic
factors, and remyelination of damaged axons[6-9]. However, because
of limitations regarding the isolation, purification, and proliferation
technology of primary SCs, there is an urgent need to develop a method to
generate large numbers of replacement cells with low immunogenicity
. Our previous studies have successfully demonstrated a modified
protocol to effectively induce Schwann-like cells (SLCs) from
adipose-derived stem cells (ADSCs) into an SC phenotype with typical repair
characteristics and increased secretion of nerve growth factor (NGF)
.However, other important issues still need to be addressed, such as improving
cell viability and differentiation efficiency and increasing the retention
and survival of cells after transplantation[10,12]. In the
traditional two-dimensional cell culture method, cells are in a single-layer
structure, and the interactions between the cells do not reflect those in
physiological tissues. In addition, adherent cells need to be treated with
trypsin before transplantation to produce a single cell suspension, which
inevitably disrupts the cell–cell interactions and the extracellular matrix
(ECM) of the cells. This process causes cell destruction before
transplantation, thus greatly reducing the cell function and their
subsequent therapeutic potential[13,14]. Culturing cells
in a three-dimensional (3D) sphere configuration can promote the
differentiation efficiency of stem cells and improve the final therapeutic
efficacy of cell transplantation and cell therapy and is widely used in
tissue engineering[15-17]. We previously established and reported the
generation of effective insulin-producing cells from ADSCs and examined
their advantages in vitro and in vivo, and these cells will soon be used in
the first in-human clinical trials[18-22]. These cells were
generated using a human recombinant peptide (RCP) petaloid μ-piece provided
by Fuji Film (Tokyo, Japan). The RCP μ-piece acts as a scaffold for ADSCs
and can support the formation of a large cell cluster. The features of this
RCP include xeno-antigen-free characteristics, high cell adhesiveness,
biodegradation absorption, clinical-grade quality, and stable manufacturing quality
. Therefore, it can achieve a cell aggregate-like technology. The
generated large cell cluster is named as “CellSaic” because the cells and
RCP petaloid μ-piece are combined like a mosaic. This CellSaic is able to
form a 3D sphere and maintain the viability of transplanted cells
. Therefore, we adapted this technique for SLC differentiation.Here, we report our establishment of 3D SLC spheroids from ADSCs using our
modified protocol with an RCP μ-piece. We also demonstrate their enhanced
therapeutic potential for peripheral nerve regeneration both in vitro and in
vivo.
Materials and Methods
Cell Culture and Preparation of ADSC-Derived SLCs
Human ADSCs were purchased from Invitrogen (Grand Island, NY, USA) and
maintained in ADSC basal medium with added growth supplement (Gibco,
Carlsbad, CA, USA) and GlutaMAX-I (Gibco). Primary human SCs were
procured from ScienCell Research Laboratories (Carlsbad, CA, USA) and
cultured in complete SC medium (ScienCell Research Laboratories)
according to the manufacturer’s instructions. The SH-SY5Y cell line
was obtained from ATCC (CRL-2266, Manassas, VA, USA) and maintained in
DMEM/F12 (Thermo Fisher Scientific, Inc. Waltham, MA, USA)
supplemented with 15% fetal bovine serum (FBS) (Thermo Fisher
Scientific, Inc.) and a 1% penicillin-streptomycin solution (Thermo
Fisher Scientific, Inc.). To induce differentiation of ADSCs into
SLCs, ADSCs were cultured for three to five passages, and then 1 ×
105 ADSCs/well were seeded onto collagen I-coated
six-well plates (4810-010; IWAKI, Tokyo, Japan) for the conventional
SLC group, or 2 × 104 ADSCs/well mixed with 0.2 mg/ml
μ-piece (16629004; Fuji Film) were seeded onto ultra-low attachment
96-well plates (174925; Thermo Fisher Scientific) for the 3D SLC
group. After cells in the 3D group had formed a spheroid in each well
(approximately 24 h after seeding), our modified protocol with folic acid
was used to induce differentiation in both the conventional SLC
and 3D SLC groups. All cells were incubated at 37 °C with 5%
CO2 in a humidified incubator. When the medium was
changed, 2 ml/well medium was added to the conventional SLC group and
100 μl/well was added to the 3D SLC group.
Morphological Analysis of 3D Spheroids
During differentiation, the morphology of 3D spheroids was directly
observed, and images were captured by a light microscope
(magnification, ×100; DP22-CU; Olympus, Tokyo, Japan). For microtomy,
spheres were solidified using iPGell (PG20-1; Genostaff, Osaka, Japan)
and fixed in 4% paraformaldehyde, as previously described
. After embedding in paraffin and slicing at a thickness of 5
µm, hematoxylin and eosin staining was performed according to a
standard protocol.
An RNeasy Mini Kit (Qiagen, Hilden, Germany) was used to extract the
total RNA in each sample according to the manufacturer’s instructions.
After measurement of the RNA concentration using a spectrophotometer
(NanoDrop 2000; Thermo Fisher Scientific), 2.5 μg RNA was
reverse-transcribed into cDNA using a reverse transcription kit
(Applied Biosystems, Thermo Fisher Scientific) in a total of 50 μl of
the reaction system, in accordance with the manufacturer’s
instructions. The StepOnePlus Real-Time PCR System (Applied
Biosystems, Thermo Fisher Scientific, Inc.) was used to perform
TaqMan-qRT-PCR analyses under the following thermocycling conditions:
initial denaturation at 95 °C for 3 min; 40 cycles of denaturation at
95 °C for 30 s, annealing at 58 °C for 30 s, and extension at 72 °C
for 45 s; and final extension at 72 °C for 10 min. The primers (TaqMan
gene expression assays; Thermo Fisher Scientific) were
S100B (Hs00902901_m1) and NGFR
(Hs00609976_m1). Glyceraldehyde 3-phosphate dehydrogenase
(GAPDH; 4326317E) was used as the internal
control, and the results were expressed as the relative mRNA
expression change in the experimental group compared with the control
group.
Enzyme-Linked Immunosorbent Assay (ELISA)
After washing twice with phosphate-buffered saline (PBS), serum-free DMEM
was added to the indicated cells. The supernatant was collected after
48 h of incubation, centrifuged (500 × g; 20 min) at room temperature,
and filtered using a 0.2 μm filter to remove the cell debris. The
cells were digested with trypsin and re-counted. Next, Human NGF ELISA
kit (BEK-2212-1P; Biosensis, Thebarton, Australia) and Human Glial
Cell-Derived Neurotrophic Factor (GDNF) ELISA kit (BEK-2222-1P;
Biosensis) were used to assess NGF and GDNF secretion in supernatants
according to the manufacturer’s instructions. The absorbance was
measured at 450 nm (540 nm as the reference wavelength) using a
microplate reader (SpectraMax i3; Molecular Devices, CA, USA). The
relative secretion capacity was normalized to the cell number.
Immunofluorescence Staining
Cells were mounted on slides, washed twice with PBS, and fixed with 4%
paraformaldehyde (163-20145; FUJIFILM) at 4 °C for 30 min. For frozen
sections, slides were reheated and dried at room temperature for 30
min and then washed in PBS for 5 min to remove the residual O.C.T.
Compound (4583; Sakura Finetek Japan Co., Ltd., Tokyo, Japan). After
permeabilization with 0.1% Triton X-100 (HFH10; Thermo Fisher
Scientific) for 5 min at room temperature, all slides were incubated
with 3% bovine serum albumin (BSA) diluted from MACS BSA Stock
Solution (130-091-376; Miltenyibiotec, Bergisch Gladbach, Germany) in
PBS for 60 min at room temperature. Then, the slides were incubated
with an anti-βIII tubulin antibody (ab18207, 1:500; Abcam, Cambridge,
UK) at 4 °C overnight. The next day, the slides were washed three
times with PBS and incubated with Alexa Fluor 488-conjugated secondary
antibodies (A-11008, 1:1000; Thermo Fisher Scientific, Inc.) for 1 h
at 37 °C in the dark. After three washes with PBS in the dark, ProLong
Gold Antifade Mountant with DAPI (P36931; Thermo Fisher Scientific)
was used to stain the nuclei for 10 min in the dark. The slides were
observed and photographed under a fluorescence microscope (BZ-X700;
KEYENCE, Tokyo, Japan). For negative controls, the primary antibody
was replaced with BSA.
In Vitro Effects of SLCs on Neurite Formation in Neural Cells
To induce a neuronal-like phenotype, SH-SY5Y cells were stimulated in
DMEM/F12 supplemented with 1% FBS and 10 μM retinoic acid
(Sigma–Aldrich, St Louis, MO, USA) for 5 days according to previous
reports[16,26,27], and then
seeded on the Nunc Lab-Tek II Chamber Slide system (Cat. No. 154526PK;
Thermo Fisher Scientific). ADSCs, conventional SLCs, and 3D SLCs were
seeded (6 × 105 cells/well) in an insert (Falcon Permeable
Support for a 24-well Plate with a 0.4 µm Transparent PET Membrane,
353095; Corning, NY, USA) and co-cultured with SH-SY5Y cells for 48 h
in an indirect contact manner, which involved sharing the same medium
with SH-SY5Y cells. For the control group, SH-SY5Y cells were cultured
alone. After co-cultivation, the slides were washed three times with
PBS, and then immunofluorescence staining was performed as described
above. ImageJ v1.46r software (National Institute of Mental Health,
Bethesda, MD, USA) with the NeurphologyJ plugin was used to analyze
the immunofluorescence staining images, and the number of branching
neurites and neurite length of each neuron were calculated. According
to previous reports[16,28], this software is capable of automatically
quantifying neuronal morphologies such as the number of branching
neurites, neurite length, and neurite branching complexity, and it has
been verified and applied in previous experiments in SCs. The results
are expressed as the relative length in the experimental group
compared with the control group.
In Vivo Sciatic Nerve Injury Model and Cell Transplantation
Male BALB/c nu-nu nude mice at 8 weeks of age were supplied by CIEA, JAC
Inc. (Tokyo, Japan) and bred at the animal facility of Tokushima
University for all experiments. After mice were anesthetized with
isoflurane and the local skin was disinfected, a 1 cm incision was
made in the right hind limb, and the biceps femoris muscle was bluntly
separated to expose the right sciatic nerve. The nerve was injured by
cutting the central region as previously described
, and cell transplantation was performed immediately. ADSCs and
conventional SLCs were digested with trypsin and suspended in PBS. For
3D SLCs, spheroids (2 × 104 cells/spheroid) were collected
by pipette tip and gently washed twice with PBS. Then, a total of 1 ×
106 cells in 100 µl PBS or PBS alone (control group)
were directly administered to the site of the nerve defect of one
mouse in each group. The wound was sutured, and footprint analysis was
performed weekly until the animals were killed. The experiments and
procedures were approved by the Animal Care and Use Committee of the
University of Tokushima.
Sciatic Function Index (SFI) Analysis
Quantitative in vivo functional recovery was evaluated postoperatively
using footprint analysis and the SFI
. Briefly, the hind paws of mice were painted with red ink, and
the mice were allowed to walk down a white paper-covered track (length
50 cm, width 6 cm) at 1, 2, 3, and 4 weeks after the surgery. Three
mice in each group were assessed, and each mouse walked along the
track three times. The hind paw prints were scanned, and the print
length (PL, distance between the heel and the third toe), toe spread
(TS, distance between the first and the fifth toe), and intermediary
toe spread (IT, distance between the second and the fourth toe) were
measured to calculate the SFI using the following formula: SFI = −38.3
× (EPL−NPL)/NPL + 109.5 × (ETS−NTS)/NTS + 13.3 × (EIT−NIT)/NIT−8.8 (E,
experimental foot; N normal foot)
.
Euthanasia and Harvesting of Tissue Specimens From Mice
After each mouse was killed, the gastrocnemius muscle of the injured limb
was separated carefully and weighed immediately. The relative wet
weights of gastrocnemius muscles were obtained by dividing by the
corresponding bodyweight of the mouse. The sciatic nerve containing
the regenerated portion was carefully isolated, embedded in O.C.T.
compound, and immediately frozen in liquid nitrogen. Cryostat sections
(5 μm) were mounted on glass slides and stored at −80 °C until
immunofluorescence staining was performed.
Statistical Analysis
Data are expressed as the mean ± standard deviation. Statistical analysis
and graph plotting were performed with GraphPad Prism 7.0 software
(GraphPad Software, Inc. San Diego, CA, USA) and ImageJ v1.46r
software. One-way analysis of variance (ANOVA) or two-way ANOVA with
Tukey’s test was used to compare differences among multiple groups.
All experiments were repeated at least three times. A p-value of 0.05
was considered to indicate statistical significance.
Results
Characteristics of SLCs Generated Using the 3D Culture System
Human ADSCs were differentiated into SLCs using our protocol according to
our previous report
. Representative images show the morphological changes in the 3D
SLC group during the differentiation process (Fig. 1A). After 18 days of
differentiation, the cells aggregated into a tight spheroid with a
slightly reduced volume. Adequate cell formation was maintained using
the RCP μ-piece as a scaffold, as shown in Fig. 1B. Moreover, the
expression of SC markers such as S100 calcium-binding protein B
(S100B) and nerve growth factor receptor
(NGFR) was significantly upregulated in 3D SLCs
compared with conventional SLCs, which demonstrated that the
differentiation efficiency was improved using the 3D culture system
(Fig.
1C).
Figure 1.
Three-dimensional (3D) SLC spheroids generated from ADSCs.
(A) Representative image of cell morphology under light
microscopy during the differentiation process. (B) The
morphology of 3D SLC spheroids is shown after hematoxylin
and eosin staining. (C) Gene expression levels of the
Schwann cell markers S100B and
NGFR were detected in ADSCs,
conventional SLCs, 3D SLCs, and primary Schwann cells
using RT-qPCR analysis (n = 4). Data are expressed as
means ± SD. **P < 0.01, one-way ANOVA
with Tukey’s post-test. Scale bar in A, 400 μm; B (left),
500 μm; B (right), 50 μm. ADSCs: Adipose-derived stem
cells; NGFR: nerve growth factor
receptor; SLC: Schwann-like cell; S100B:
S100 calcium-binding protein B.
Three-dimensional (3D) SLC spheroids generated from ADSCs.
(A) Representative image of cell morphology under light
microscopy during the differentiation process. (B) The
morphology of 3D SLC spheroids is shown after hematoxylin
and eosin staining. (C) Gene expression levels of the
Schwann cell markers S100B and
NGFR were detected in ADSCs,
conventional SLCs, 3D SLCs, and primary Schwann cells
using RT-qPCR analysis (n = 4). Data are expressed as
means ± SD. **P < 0.01, one-way ANOVA
with Tukey’s post-test. Scale bar in A, 400 μm; B (left),
500 μm; B (right), 50 μm. ADSCs: Adipose-derived stem
cells; NGFR: nerve growth factor
receptor; SLC: Schwann-like cell; S100B:
S100 calcium-binding protein B.
3D SLCs Exhibited Enhanced Therapeutic Potential In vitro
In the in vitro functional evaluation, we examined the ability of SLCs to
secrete neurotrophic factors and whether they could promote neurite
outgrowth in neurons. NGF and GDNF secretion were significantly
upregulated in both conventional SLCs and 3D SLCs compared with ADSCs.
However, the 3D SLC group had a greater secretion capacity (Fig. 2A,
B).
Immunofluorescence staining of βIII tubulin was used to estimate the
number and length of neurites. After direct co-culture with SLCs, the
neurite outgrowth of SH-SY5Y cells was significantly enhanced (Fig. 2C). The
statistical results revealed significantly more neurite branching.
Moreover, longer neurite extensions in SH-SY5Y cells were observed in
the 3D SLC group after calculation via the NeurphologyJ plugin. All
these observations confirmed the superiority of 3D SLCs over
conventional SLCs and undifferentiated ADSCs (Fig. 2D, E).
Figure 2.
Three-dimensional (3D) SLCs exhibit enhanced therapeutic
potential in vitro. The relative secretion of NGF (A) and
GDNF (B) in the supernatant was analyzed by an
enzyme-linked immunosorbent assay in the ADSC,
conventional SLC, and 3D SLC groups (n = 4). Data are
expressed as means ± SD. *P < 0.05;
**P < 0.01, one-way ANOVA with
Tukey’s post-test. (C) Representative images of SH-SY5Y
cells after direct co-culture with ADSCs, conventional
SLCs, and 3D SLCs. The neurites were visualized by
immunofluorescent labeling of βIII tubulin (green). (D)
Statistical analyses of the number of neurites per cell (n
= 4). Data are expressed as means ± SD.
*P < 0.05; **P
< 0.01, one-way ANOVA with Tukey’s post-test. (E)
Statistical analyses of the relative length of each
neurite (n = 4). Data are expressed as means ± SD.
*P < 0.05; **P
< 0.01, one-way ANOVA with Tukey’s post-test. Scale bar
in C, 50 μm. SLCs: Schwann-like cells; NGF: nerve growth
factor; GDNF: glial cell-derived neurotrophic factor;
ADSC: Adipose-derived stem cell; DAPI,
4,’6-diamidino-2-phenylindole, dihydrochloride.
Three-dimensional (3D) SLCs exhibit enhanced therapeutic
potential in vitro. The relative secretion of NGF (A) and
GDNF (B) in the supernatant was analyzed by an
enzyme-linked immunosorbent assay in the ADSC,
conventional SLC, and 3D SLC groups (n = 4). Data are
expressed as means ± SD. *P < 0.05;
**P < 0.01, one-way ANOVA with
Tukey’s post-test. (C) Representative images of SH-SY5Y
cells after direct co-culture with ADSCs, conventional
SLCs, and 3D SLCs. The neurites were visualized by
immunofluorescent labeling of βIII tubulin (green). (D)
Statistical analyses of the number of neurites per cell (n
= 4). Data are expressed as means ± SD.
*P < 0.05; **P
< 0.01, one-way ANOVA with Tukey’s post-test. (E)
Statistical analyses of the relative length of each
neurite (n = 4). Data are expressed as means ± SD.
*P < 0.05; **P
< 0.01, one-way ANOVA with Tukey’s post-test. Scale bar
in C, 50 μm. SLCs: Schwann-like cells; NGF: nerve growth
factor; GDNF: glial cell-derived neurotrophic factor;
ADSC: Adipose-derived stem cell; DAPI,
4,’6-diamidino-2-phenylindole, dihydrochloride.
3D SLCs Promoted Motor Function and Structural Recovery in a Sciatic
Nerve Injury Model
Next, we investigated the in vivo effect of 3D SLCs in a sciatic nerve
injury nude mouse model. Immediately after injury, ADSCs, conventional
SLCs, and 3D SLCs were transplanted into the injured area according to
a previous report
, and motor functional recovery of the injured sciatic nerve was
evaluated by footprint analysis. Representative walking footprints of
mice from each group at 4 weeks after cell engraftment are shown in
Fig.
3A. At day 7, footprint analysis showed that there were no
statistically significant differences in the SFI among all groups. At
28 days after transplantation, the 3D SLC group demonstrated better
motor function than both the conventional group and the ADSC group, as
revealed by the highest SFI value and the greatest SFI improvement in
the 3D SLC group (Fig. 3B, C). Moreover, we analyzed
the gastrocnemius muscle weight in the injured limbs of each group
because denervation could induce muscle atrophy. The relative weights
of gastrocnemius muscles were highest in the 3D SLC group, which
confirmed the ability of 3D SLCs to promote nerve regeneration after
injury (Fig.
3D, E). Finally, the injured nerve was observed, which
showed some fibrous tissue connections in damaged nerves (Fig. 3F).
Furthermore, βIII tubulin immunofluorescence staining showed
incomplete nerve regeneration (Fig. 3G).
Figure 3.
Three-dimensional (3D) SLCs promote motor function and
structural recovery in vivo. (A) Representative images of
the right hind paw prints of the control, ADSC,
conventional SLC, and 3D SLC groups before injury and 1,
2, 3, and 4 weeks after injury. (B) Change in the SFI from
1 week to 4 weeks after injury (n = 3). Data are expressed
as means ± SD. *P < 0.05 vs. control;
**P < 0.01 vs. control; ##p <
0.01 vs. conventional SLCs, two-way ANOVA with Tukey’s
post-test. (C) Statistical analyses of the differences
between 1 week and 4 weeks post-surgery (n = 3). Data are
expressed as means ± SD. **P < 0.01,
one-way ANOVA with Tukey’s post-test. (D) Representative
images of the gastrocnemius muscle of the injured limb in
the control, ADSC, conventional SLC, and 3D SLC groups at
4 weeks post-surgery. (E) The relative weights of
gastrocnemius muscles in the control, ADSC, conventional
SLC, and 3D SLC groups at 4 weeks post-surgery (n = 3).
Data are expressed as means ± SD. *P <
0.05; **P < 0.01, one-way ANOVA with
Tukey’s post-test. (F) Representative image of sciatic
nerve regeneration after 3D SLC transplantation into the
injured nerve region for 4 weeks. (G) βIII tubulin (green)
expression was determined by immunofluorescence staining
in the regenerated sciatic nerve. The dotted lines
indicate the borders of injury sites. Scale bar in G, 200
μm. SLCs: Schwann-like cells; ADSC: Adipose-derived stem
cell; SFI: Sciatic Function Index; DAPI,
4,’6-diamidino-2-phenylindole, dihydrochloride.
Three-dimensional (3D) SLCs promote motor function and
structural recovery in vivo. (A) Representative images of
the right hind paw prints of the control, ADSC,
conventional SLC, and 3D SLC groups before injury and 1,
2, 3, and 4 weeks after injury. (B) Change in the SFI from
1 week to 4 weeks after injury (n = 3). Data are expressed
as means ± SD. *P < 0.05 vs. control;
**P < 0.01 vs. control; ##p <
0.01 vs. conventional SLCs, two-way ANOVA with Tukey’s
post-test. (C) Statistical analyses of the differences
between 1 week and 4 weeks post-surgery (n = 3). Data are
expressed as means ± SD. **P < 0.01,
one-way ANOVA with Tukey’s post-test. (D) Representative
images of the gastrocnemius muscle of the injured limb in
the control, ADSC, conventional SLC, and 3D SLC groups at
4 weeks post-surgery. (E) The relative weights of
gastrocnemius muscles in the control, ADSC, conventional
SLC, and 3D SLC groups at 4 weeks post-surgery (n = 3).
Data are expressed as means ± SD. *P <
0.05; **P < 0.01, one-way ANOVA with
Tukey’s post-test. (F) Representative image of sciatic
nerve regeneration after 3D SLC transplantation into the
injured nerve region for 4 weeks. (G) βIII tubulin (green)
expression was determined by immunofluorescence staining
in the regenerated sciatic nerve. The dotted lines
indicate the borders of injury sites. Scale bar in G, 200
μm. SLCs: Schwann-like cells; ADSC: Adipose-derived stem
cell; SFI: Sciatic Function Index; DAPI,
4,’6-diamidino-2-phenylindole, dihydrochloride.
Discussion
We differentiated ADSCs into 3D SLC spheroids using a modified protocol with an
RCP μ-piece for PNI treatment. The enhanced protocol uses non-gene editing
methods, and its advantages include its ability to induce ADSCs to an SC
phenotype with typical repair characteristics and increase NGF secretion
. In addition, 3D SLC spheroids exhibited enhanced therapeutic
potential both in vitro and after transplantation into a murine sciatic
nerve injury model.Morphological observations showed that SLCs and the μ-piece formed a “CellSaic”
in the 3D spheroids. This structure has been reported to effectively promote
cell survival after transplantation
. The mRNA expression levels of the most commonly used mature SC
markers, S100 and NGFR[27,32], were
significantly higher in 3D SLCs than in conventional SLCs, indicating their
greater differentiation efficiency. This advantage is produced by the 3D
culture system, which more accurately reflects physiological conditions
.Paracrine secretion of neurotrophic factors by SLCs is an important mechanism
for promoting nerve regeneration, and NGF and GDNF are the two most
important factors[8,33]. We assessed the secretion of these factors
using an ELISA, and our results showed that 3D SLCs exhibited greater
secretion ability. To further determine whether 3D SLCs can functionally
support neurite formation, we used a neuron-like human cell line, SH-SY5Y,
which was induced by retinoic acid as a model to evaluate the potential of
SLCs to promote axon growth[16,26,27]. By labeling βIII
tubulin, which is a neuron-specific protein, immunofluorescence staining was
used to visualize the neurites
. In the co-cultivation experiment, both conventional SLCs and 3D SLCs
showed high therapeutic potential for promoting neurite growth. Upon
interaction with SH-SY5Y cells, the 3D SLC group promoted increases in the
number and length of neurites, which indicated that 3D SLCs were beneficial
for neuron growth.To further verify the function of 3D SLCs, a widely used sciatic nerve injury
model was used to explore their effect on PNI repair in vivo[29,34].
The results showed that ADSC, conventional SLC, and 3D SLC transplantation
could improve the SFI and prevent denervation-induced gastrocnemius muscle
atrophy. Consistent with the in vitro experiments, the 3D SLC group
exhibited an enhanced ability to promote nerve repair after transplantation.
In addition to the greater differentiation efficiency and secretion capacity
of 3D SLCs confirmed by the above in vitro experiments, the multicellular 3D
spheroids retained their cell–cell and cell–ECM interactions, whereas
conventional SLCs require trypsin digestion when preparing cell suspensions
for transplantation. The ECM has been shown to effectively store growth
factors secreted from cells
and enhance cell adhesion and survival after
transplantation[18,36]. Moreover, human
pluripotent stem cells (i.e., ES cells and iPS cells) have potential risks
of tumorigenicity
in clinical applications compared with our SLCs. Considering other
cell types, we have already demonstrated that matured cells differentiated
from ADSCs have low risks of tumorigeneicity
. Therefore, consistent with previous studies[16,36,38,39],
the therapeutic cells delivered by the 3D spheroids in our study showed
better therapeutic potential.Although we successfully generated 3D SLC spheroids with enhanced therapeutic
ability, this study still has some limitations. The current differentiation
period is 18 days, which is relatively long. Because attempts to shorten the
differentiation time have not been successful
, additional studies should be conducted to develop a shorter and more
economical differentiation protocol. Moreover, even though we demonstrated
that the regenerative ability of our 3D SLCs was significantly superior to
that of ADSC administration alone, the efficiency of nerve regeneration is
still not sufficient because only an incomplete connection of the injured
nerve was observed. Especially in large nerve defects, guidance for nerve
stump growth is lacking, which prompted us to further combine the cells with
more structurally supportive biomaterials such as a conduit
. Furthermore, the fate of transplanted SLCs remains unknown. Many
transplanted animals are required for this cell tracking system because in
vivo closed circumstances might be desirable for nerve regeneration. Thus,
cell tracking experiments will be conducted in the future to reveal the
mechanism of the acceleration of peripheral nerve regeneration using our 3D
SLCs.
Conclusion
The results of this study demonstrate the feasibility of 3D SLC spheroids
generated through a modified differentiation protocol combined with an RCP
μ-piece as an alternative cell source to promote peripheral nerve
regeneration. In vitro and in vivo experiments showed that the cells
exhibited significantly improved therapeutic potential. This method may have
great potential for clinical application in PNI treatment.
Authors: Matthew Anderson; Namdev B Shelke; Ohan S Manoukian; Xiaojun Yu; Louise D McCullough; Sangamesh G Kumbar Journal: Crit Rev Biomed Eng Date: 2015
Figure 1.
Figure 2.
Figure 3.