During development of the peripheral nervous system (PNS), Schwann cells (SCs) wrap individual axons to form myelin sheaths, which act as surrounding insulators and markedly enhance the propagation of the action potential. In peripheral neuropathies such as Guillain-Barré syndrome (GBS) and inherited demyelinating Charcot-Marie-Tooth (CMT) disease and diabetic neuropathies, chronic demyelination and defective remyelination are repeated, causing more severe neuropathies. It is thus thought that development of a drug that promotes proper myelination with minimal side effects could provide an effective therapy for these diseases. As yet, however, little is known about therapeutic target molecules and genetically-modified mice for testing such approaches. We previously cloned the dock7 gene and characterized Dock7 as the regulator controlling SC myelination; however, an important issue, whether knockdown of Dock7 specifically affects myelination by SCs but not leaves neurons unaffected, has remained unclear. Here, we generate newly-produced transgenic mice harboring short-hairpin RNA (shRNA) targeting Dock7. We also describe that Dock7 shRNA transgenic mice exhibit enhanced myelin thickness without affecting axon thickness in sciatic nerves of the PNS, as reduced thickness of the axon diameter is the primary indicator of denatured neurons. Similarly, purified in vitro SC-neuronal cocultures established from transgenic mice exhibit enhanced formation of myelin segments, suggesting that knockdown of Dock7 promotes myelination by SCs. Collectively, Dock7 knockdown specifically affects SC myelination in sciatic nerves, providing evidence that Dock7 may be a promising drug-target-specific molecules for developing a therapy for peripheral neuropathies that aims to enhance myeliantion.
The myelin sheath is a unique multiple-layer structure that acts as an insulator between surrounding axons, and markedly enhances the propagation of the action potential [1,2]. The myelin sheath is derived from myelinforming glial cells, Schwann cells (SCs) in the peripheral nervous system (PNS) and oligodendrocytes (OLs) in the central nervous system (CNS). Over time, myelin sheaths grow to more than 100 times larger than the collective surface area of premyelinating SC or OL plasma membranes [1,2]. On the other hand, inherited neuropathies such as Charcot-Marie-Tooth (CMT) disease, GuillainBarré syndrome (GBS), and certain diabetic neuropathies cause chronic demyelination, resulting in repeated cycles of demyelination and defective remyelination that cause more severe neuropathies [3-5]. These major demyelinating diseases are primarily peripheral neuropathies. At present, it is thus thought that promotion of proper myelination, with few accompanying side effects as possible, is a potentially important therapeutic approach [3-5].
All stages of myelination by SCs are primarily accomplished by interactions of two different types of cells, namely, SCs and peripheral neurons [1,2]. While evidence illustrates that growth factors such as neuregulin-1 and insulin-like growth factor 1 (IGF1), as well as adhesion molecules, which are presented by peripheral neurons such as dorsal root ganglion (DRG) neurons, promote myelination [4-6]. It is unlikely that these growth factors and general signaling molecules that belong to downstream pathways provide suitable target molecules, since in most cases they are indispensable factors that support life. Here, we describe that in vivo knockdown of Dock7 in mice that have a specific short-hairpin RNA (shRNA) yields a specific phenotype with enhanced myelin thickness in SCs without observable reduced axon thickness in PNS sciatic nerves. We previously cloned the dock7 gene and characterized Dock7 as a guanine-nucleotide exchange factor (GEF) that activates small GTPases of the Rho family, Rac1 and Cdc42 [7,8]. Rho GTPases are critical regulators that control cell morphological changes in many types of cells including SCs [9-13]. However, it remained unclear whether inhibition of Dock7 in vivo as well as in vitro affects myelination by SCs, or axon thickness in neurons, or both [
The following antibodies were purchased: anti-Dock7 from Immuo-Biological Laboratories, Co., Ltd. (Fujioka, Gunma, Japan); anti-myelin basic protein (MBP) from Covance (Berkeley, CA, USA); and anti-actin from BD Biosciences Pharmingen (Franklin Lake, NJ, USA).
Genetically modified/unmodified mice were cared for in accordance with a protocol approved by the Japanese National Research Institute for Child Health and Development Animal Care Committee and were monitored by the Laboratory Animal Facility of the Japanese National Research Institute for Child Health and Development. First, the tandem units, namely, simian virus SV40 enhancer; artificial ferritin composite promoter, which combines human ferritin heavy chain FerH promoter with mouse elongation factor EF1 promoter, EGFP, and mouse EF1 polyadenylation signal, were amplified using the mouse in vivo expression vector pVIVO2-GFP/LacZ (4982-9620 bases; InvivoGen, San Diego, CA, USA), as the template, and then digested with EcoRI and BamHI restriction enzymes. Second, the mouse shRNA transcription vector pSINsimU6 (1294-3944 bases; Takara Bio, Kyoto, Japan), which was inserted with ShDock7 oligonucleotide (sense oligonucleotide: 5’-GATCCGAC GTTCGATGTCAATAGATAGTGCTCCTGGTTGTCT ATTGACATCGAACGTCTTTTTTAT-3’; antisense oligonucleotide: 5’-CGATAAAAAAGACGTTCGATGTC AATAGACAACCAGGAGCACTATCTATTGACATC GAACGTAG-3’), was digested with EcoRI. They were successively ligated into the EcoRI and BamHI sites of a pCMV5 backbone as the subcloning vector. The DNA fragment (approximately 6.2 kb) containing EGFP and ShDock7 was digested from the vector backbone with NcoI, purified, and injected into fertilized BDF1 mouse oocytes [8,14]. Transgenic founders were mated to wild type C57BL/6JJmc and the transgene was stably maintained for at least 10 generations. Male mice were used for experiments when gender discrimination was possible. The transgenic mice and their nontransgenic littermates were fertile under standard breeding conditions. Identification of transgenic founder mice and transgenic mice was determined by PCR on genomic DNA prepared from tail biopsies (EGFP primer pair: 5’-CAATCATGA GCAAGGGAGAAGAACTCTTTACTGGTGTTGTC-3’ and 5-TTTACTTGTACAGCTCATCCATTCCCAGAG TAATTCCTGC-3’; and U6 primer pair: 5’-CGCACAG ACTTGTGGGAGAAGCTCGGCTACTC-3’ and 5’- GC TTTGCATACTTCTGCCTGCTGGGGAGCCTG-3’). The primer pair for Oct3/4 as the positive control was 5’- CCGGGATCCAAGCTTTGTGAACTTGGCGGCTTCC AAGTCG-3’and 5’-CCGGGATCCCATTACTGGCCT GGTGCTTAGTTATCTTTG-3’. PCR was performed for 30 cycles, each consisting of denaturation at 94˚C for 1 min, annealing at 65˚C for 1 min, and extension at 72˚C for 1 min. For Southern blotting, genomic DNAs were digested with EcoRI and BamHI and hybridized to a genomic probe for EGFP. The transgenic allele resulted in a hybridized band of ~4.5 kb.
Primary neurons were dissociated from dorsal root ganglia (DRGs) of C57BL/6JJms mouse embryos on embryonic day 13 (Sankyo Laboratories, Tokyo, Japan) and purified through culturing on collagen-coated dishes or glass coverslips in DMEM-GlutaMAX I (Life Technologies, Carlsbad, CA, USA) containing 10% FBS, 100 ng/ml NGF (AbD Serotec, Kidlington, UK), 8 μM fluorodeoxyuridine, and 4 μM uridine [15-17]. After 3 cycles of antimitotic reagent administration over 2 - 3 weeks, purified DRG neurons were cultured in DMEMGlutaMAX I containing 10% FBS and 100 ng/ml NGF. Primary Schwann cell precursors (SCPs) were also prepared from mouse DRGs on embryonic day 13 by the method of Ratner et al. [
Cells on glass coverslips were fixed in PBS containing 4% paraformaldehyde and permeabilized with PBS containing 0.1% Tween-20. Permeabilized cells were blocked, and incubated first with a primary antibody and then with a fluorescence-labeled secondary antibody. The glass coverslips were mounted with Vectashield reagent (Vector Laboratories, Burlingame, CA, USA) onto slides for microscopic observation. The fluorescent images were captured using an Eclipse TE-300 microscope system (Nikon, Kawasaki, Japan) and analyzed with AxioVision software (Carl Zeiss, Oberkochen, Germany) or captured using a DMI4000 microscope system (Leica, Heerbrugg, Switzerland) and analyzed with AF6000 software (Leica).
Sciatic nerves were fixed with 2% paraformaldehyde and 2% glutaraldehyde in 0.1% cacodylate buffer, contrasted with 2% osmium tetroxide, dehydrated with an ethanol gradient, and treated with propylene oxide. Finally, samples were infiltrated and embedded in pure epoxy. Ultrathin sections were stained with uranyl acetate and lead staining solution. Images were taken with a JEM-1200EX electron microscope system (JOEL, Tokyo, Japan).
Cells were lysed in lysis buffer A (50 mM HEPESNaOH, pH 7.5, 20 mM MgCl2, 150 mM NaCl, 1 mM dithiothreitol, 1 mM phenylmethane sulfonylfluoride, 1 μg/ml leupeptin, 1 mM EDTA, 1 mM Na3VO4, 10 mM NaF, and 0.5% NP-40) or lysis buffer A containing 1% CHAPS and 0.3% SDS. Unless otherwise indicated, all steps were performed at 4˚C. Proteins in the cell supernatants were denatured and then subjected to SDS-PAGE. The electrophoretically separated proteins were transferred to a PVDF membrane, blocked, and immunoblotted with a primary antibody and then with a peroxidaseconjugated secondary antibody. The bound antibodies were detected by chemiluminescence (Nacalai Tesque, Kyoto, Japan).
Briefly, transgenic mouse splenocytes on glass slides were synchronized in the presence of thymidine for 16 hours and treated with 5-bromo-2’-deoxyuridine for an additional 5.5 hours. The cells were further treated with colcemid and harvested. Transgene-containing plasmid DNAs were labeled with Cy3-dUTP for use as probes. After hybridization, the glass slides were washed first in 50% formamide/2 × SSC and then in 1 × SSC, and counterstained with DAPI. FISH images were captured using a DMRA2 microscope system (Leica) and analyzed with CW4000 FISH software (Leica).
Values shown represent the mean ± SD from separate experiments. A one-way analysis of variance (ANOVA) was followed by a Fisher’s protected least significant difference (PLSD) test as a post hoc comparison.
The aim of this study was to determine whether Dock7 has a specific effect on myelin sheaths formed by SCs but does not affect neuronal axon thickness in PNS sciatic nerves. To clarify this, we injected the transgene with Dock7 shRNA transcription sequence controlled under the U6 promoter and DNA sequence encoding EGFP as the genomic PCR marker into fertilized mouse oocytes (
one year and bred normally under standard breeding conditions.
To clarify whether knockdown of Dock7 has a specific effect on myelin formation in vivo, we analyzed sciatic nerve cross sections using electron microscopy. Dock7 shRNA transgenic mice exhibited enhanced myelin thickness compared with littermate controls (nontransgenic mice) and axon thickness in neurons was unaffected in both populations (Figures 3(a) and (b)). In fact, the average axon diameter in transgenic mice was 2.8 μm ± 0.78 μm (n = 52 of the total number in two independent nerves) and that in the littermate controls was 2.7 μm ± 0.73 μm (n = 53 of the total number in two independent nerves). The presence of myelinated axons with reduced diameters is the primary indicator of denatured neurons [3-5]. Rather, the average axon diameter in transgenic mice appeared to be slightly thicker than that in the controls. Additionally, 52% of Dock7 shRNA transgenic mice had myelinated axons with a sheath thickness greater than 1 μm whereas only 32% of litter
mate controls had myelin sheath thickness greater than 1 μm (n = 50 for both). Taken together, these results suggest that knockdown of Dock7 in vivo has a specific effect on myelin thickness but not on reduction of axon thickness in sciatic nerves.
To confirm whether knockdown of Dock7 promotes myelination, we established SC-DRG neuronal cocultures. We isolated primary SCs from Dock7 shRNA transgenic mice and their littermate controls, and primary DRG neurons from wild type mice. SCs were cultured for proliferation in association with DRG axons, treated with ascorbic acid to initiate myelination, and allowed to wrap individual axons. Cultures were stained with an anti-MBP antibody to enable visualization of myelin segments. The representative images for myelin segments are depicted in Figures 4(a) and (b), showing that knockdown of Dock7 promotes myelination compared with cocultures established from the SCs of littermate controls. In 200 μm microscopic square fields, Dock7 shRNA SC-neuronal cocultures showed 37 ± 3.0 of MBP-positive myelin segments whereas control SC-neuronal cocultures did only 7.3 ± 1.9 of segments (n = 4, p < 0.01). These results suggest that knockdown of Dock7 promotes myelination.
In this study, we succeeded in generating Dock7 shRNA transgenic mice that exhibit enhanced myelin thickness in sciatic nerves without reduced axon diameters. We previously reported that Dock7 shRNA transgenic mice exhibit not only enhanced myelin thickness but also reduced axon diameter in neurons [
serted region are expressed may allow us to develop better mouse models for testing therapeutic target genes, as well as to generate mouse models using the knockout technique.
Most demyelinating diseases and related pathologies, especially in the PNS, show repeated demyelination and defective remyelination that exacerbates neuropathies. Therefore, finding therapeutic target molecules that promote proper myelination with minimal accompanying side effects may provide useful therapeutic methods for these diseases [3-5]. This study presents two important findings: 1) knockdown of Dock7 promotes myelination by SCs, and 2) this knockdown appears to have no reduced effect on axon thickness in neurons. Also, the transgenic mice in this study appeared to be healthy and bred normally. As far as we could ascertain, this is the first report of a target molecule that can specifically promote myelination without reduced axon thickness. Further studies on the role of Dock7 knockdown in pathological conditions may shed light on the development of novel therapeutic drug-target-specific medicines.
We thank Drs. W. Furmanski and K. Spicer for reading this manuscript. This work was supported by Grants-in-Aid for Scientific Research from the Japanese Ministry of Education, Culture, Sports, Science, and Technology (MEXT) and the Japanese Ministry of Health, Labor, and Welfare (MHLW) and partially supported by research grants from the Astellas Foundation, the Takeda Foundation, and the Uehara Foundation.