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Integrin-mediated axoglial interactions initiate myelination in the central nervous system
Correspondence to Charles ffrench-Constant: cffc{at}ed.ac.uk
All but the smallest-diameter axons in the central nervous system are myelinated, but the signals that initiate myelination are unknown. Our prior work has shown that integrin signaling forms part of the cell–cell interactions that ensure only those oligodendrocytes contacting axons survive. Here, therefore, we have asked whether integrins regulate the interactions that lead to myelination. Using homologous recombination to insert a single-copy transgene into the hypoxanthine phosphoribosyl transferase (hprt) locus, we find that mice expressing a dominant-negative β1 integrin in myelinating oligodendrocytes require a larger axon diameter to initiate timely myelination. Mice with a conditional deletion of focal adhesion kinase (a signaling molecule activated by integrins) exhibit a similar phenotype. Conversely, transgenic mice expressing dominant-negative β3 integrin in oligodendrocytes display no myelination abnormalities. We conclude that β1 integrin plays a key role in the axoglial interactions that sense axon size and initiate myelination, such that loss of integrin signaling leads to a delay in myelination of small-diameter axons.
© 2009 Câmara et al.
This article is distributed under the terms of an Attribution–Noncommercial–Share Alike–No Mirror Sites license for the first six months after the publication date (see http://www.jcb.org/misc/terms.shtml). After six months it is available under a Creative Commons License (Attribution–Noncommercial–Share Alike 3.0 Unported license, as described at http://creativecommons.org/licenses/by-nc-sa/3.0/).
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Cell adhesion molecules represent excellent candidates for these additional signals regulating myelination (Laursen and ffrench-Constant, 2007). One of these is 
6β1 integrin, a receptor expressed on oligodendrocytes for laminins expressed in axon tracts at the time of myelination that promotes oligodendrocyte survival by amplification of growth factor signaling (Colognato et al., 2002). This provides a mechanism for the target-dependent survival of oligodendrocytes, with those that fail to establish normal contact with axons during development undergoing programmed cell death. The importance of integrins in oligodendrocyte biology is further underscored by the finding that integrin-mediated signaling pathways are strongly represented in a genome-wide analysis of expression in differentiating oligodendrocytes (Cahoy et al., 2008). Here, therefore, we have asked whether integrins play a role in the regulation of myelination, either by contributing to the signals that initiate myelination or by regulating the thickness of the resulting myelin sheath.
Prior studies on the role of β1 integrin in CNS myelination in vivo have been contradictory. Constitutive disruption of the β1 integrin gene resulted in early lethality (Fassler and Meyer, 1995; Stephens et al., 1995), requiring the use of conditional ablation or dominant-negative strategies to examine function. Lee et al. (2006) reported that mice expressing a β1 integrin lacking the C-terminal cytoplasmic tail (β1
C) in oligodendrocytes displayed region-specific hypomyelination in optic nerve and spinal cord and no myelination abnormalities in the corpus callosum. In contrast, conditional inactivation of the β1 integrin gene in premyelinating oligodendrocytes showed that β1 integrin is not required for CNS axon ensheathment, myelination, or remyelination (Benninger et al., 2006). Nonetheless, the contribution made by integrin signaling to oligodendrocyte survival, evidenced by our earlier studies on the 6 knockout CNS, was confirmed by a transient reduction in oligodendrocyte numbers in the developing cerebellum (Benninger et al., 2006). However, it is possible that both these studies fail to reveal the specific function of β1 integrin in myelinating oligodendrocytes. In the knockout study, gene deletion occurs early, at the premyelinating stage of oligodendrocyte development, thus potentially enabling compensation by other integrins to occur by the stage of myelination. The ability of different integrin β subunits to compensate for one another has been previously shown in Drosophila embryogenesis (Martin-Bermudo et al., 1999). In the dominant-negative study, the construct used by Lee et al. (2006) contained a normal integrin extracellular domain that will bind laminin and compete with any other laminin receptors for available ligand in the myelinating tract. Here, therefore, we have used the reverse strategy—expression in oligodendrocytes of a well-characterized dominant-negative β1 integrin subunit containing only the intracellular domain that will not bind ligand and would thus be predicted to be more specific in targeting β1 integrin signaling (LaFlamme et al., 1994; Relvas et al., 2001). Furthermore, we have minimized the time available for compensatory mechanisms to develop by expressing the dominant-negative subunit only at the myelinating stage in oligodendrocytes using the myelin basic protein (MBP) promoter (Farhadi et al., 2003).
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-subunit of the human interleukin-2 receptor (IL2R). This chimeric integrin has been shown to function in a dominant-negative manner in vitro (LaFlamme et al., 1994) and when expressed in oligodendrocyte precursors transplanted into demyelinated lesions (Relvas et al., 2001). To overcome the usual limitations of random and multiple-copy insertion in standard transgenesis, we used the hypoxanthine phosphoribosyl transferase (hprt) targeting system (Farhadi et al., 2003) for the generation of the genetically modified embryonic stem (ES) cells expressing the dnβ1 integrin (Fig. 1 a). This technology uses homologous recombination to target a single copy of the desired transgene (in this case the dnβ1 integrin) driven by a specific promoter (in this case the MBP promoter) into the hprt locus on the X-chromosome. The ES cell line used lacks a complete hprt gene and the targeting vector "rescues" the hprt gene by replacing the lost sequences in addition to inserting the desired transgene and its promoter. As a result, ES cells with the correct insertion can easily be selected by virtue of their expression of hprt and the subsequent ability to grow in HAT medium. This process was extremely efficient, with 12 out of 12 clones selected having the correct insertion, as evidenced by PCR analysis performed as described in the Materials and methods (Fig. 1 b). We then generated transgenic mice from one of these ES cell lines to establish a dnβ1 transgenic line. These mice had no overt phenotype, and in particular showed no evidence of locomotor defects.
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Dnβ1 mice express the dominant-negative β1 integrin in white matter tracts
Expression of the dnβ1 integrin in the mutant was initially confirmed by RT-PCR. Primers hybridizing to the human IL2R gene, only present in the inserted dominant-negative construct, showed specific amplification in mutant mice (Fig. 2 a). To visualize the expression of the dnβ1 integrin protein in the myelinating tracts, we used immunofluorescence labeling with an anti–human IL2R antibody on transverse sections of optic nerve, sagittal sections of cerebellum, and coronal sections of corpus callosum in wild-type and mutant mice (Fig. 2 b). The dnβ1 integrin was expressed in white matter tracts within these regions in mutant mice, whereas no expression was detected in the wild-type animals. These results confirm that the dnβ1 integrin is expressed in transgenic mice at the RNA and protein level in the predicted pattern within myelinating tracts.
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Integrin signaling is inhibited in the dnβ1 mice
To confirm the efficacy of our strategy, we asked to what extent the dnβ1 construct expressed in the transgenic mice inhibited the endogenous β1 integrin. First, we compared the expression levels of the endogenous and the transgenic β1 integrin. In vitro studies have demonstrated that approximately equal expression levels of the IL2R-integrin chimera to the endogenous integrin are sufficient to inhibit integrin-mediated cell spreading and migration, confirming that this level of transgene expression exerts a dominant-negative effect (LaFlamme et al., 1994). We therefore designed a semi-quantitative RT-PCR analysis using two distinct sets of primers, one specific for the endogenous β1 integrin and another for the dnβ1 integrin, taking advantage of the differences in their extracellular domains (Fig. 3 a). To examine whether the levels of β1 integrin inhibition might vary in the different areas of the nervous system, we performed this RT-PCR analysis on several areas of the nervous system. We showed that in all CNS white matter tracts the dnβ1 integrin expression levels were equal to or greater than the levels of the mRNA for the endogenous integrin, with significantly higher levels seen in optic nerve (Fig. 3 b). The same expression pattern was observed in four pairs of mice analyzed, with the mean levels of the dnβ1 mRNA relative to the wild-type β1 mRNA being 2.22 ± 0.37 in optic nerve (P = 0.033), 1.6 ± 0.37 in spinal cord, and 1.22 ± 0.17 in cerebellum, as compared with 0.92 ± 0.10 in cortex.
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The relationship between axon diameter and myelin thickness is normal in dnβ1 mice
To examine myelination in the dnβ1 mice, we first compared white matter tracts in several CNS regions of wild-type and dnβ1 mice by immunohistochemistry using an anti-MBP antibody. We observed no differences in these studies, with the white matter tracts visualized in sections of corpus callosum and optic nerve showing identical thickness and labeling intensity (Fig. S2).
To assess myelination in more detail, we performed an ultrastructural electron microscopy (EM) analysis on optic nerve, spinal cord, and cerebellum at P28, an age when myelination is largely complete (Fig. 4). We found that the relationship between axon diameter and myelin thickness (g-ratio) was not significantly different between dnβ1 mutants and their wild-type counterparts in P28 optic nerve, cerebellum, and spinal cord, with average g-ratios for control and mutant optic nerves of 0.79 ± 0.013 and 0.77 ± 0.020 (P = 0.57); for control and mutant cerebella of 0.80 ± 0.014 and 0.82 ± 0.019 (P = 0.43); for control and mutant spinal cords of 0.80 ± 0.001 and 0.79 ± 0.004 (P = 0.36), respectively. Additionally, no evidence of a higher frequency of dysmyelinated axons in mutant optic nerve, corpus callosum, or spinal cord was observed. We conclude that, for myelinated axons, the myelin morphology and the ratio of myelin thickness/axon diameter in the dnβ1 mutants are the same as in wild-type mice at P28.
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0.6 µm diameter (P = 0.0085), whereas a similar percentage of myelination was seen in larger axons of >0.6 µm of diameter. In particular, mutant axons of a diameter within the 0.3–0.4-µm range showed the most significant reduction in myelination as compared with wild-type controls (P = 0.023). These results therefore show that the threshold diameter required to initiate myelination is increased in the dnβ1 optic nerve.
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As an alternative method to demonstrate the increased threshold diameter required to initiate myelination in the dnβ1 mice, we compared the frequency distribution of the diameters of all myelinated and total axons (irrespective of myelination status) between wild-type and dnβ1 mutants in P17 optic nerve (Fig. 5 e). As predicted from the observations above, both the mean myelinated and unmyelinated axon diameters were significantly larger (P < 0.0001) in mutant optic nerves (0.86 ± 0.015 µm for myelinated axons, 0.38 ± 0.004 µm for unmyelinated axons) than in their wild-type littermate controls (0.75 ± 0.012 µm and 0.35 ± 0.004 µm, respectively). By contrast, the mean diameter of all axons was not significantly different, with an average axon diameter of 0.47 ± 0.006 µm and 0.48 ± 0.007 µm for wild-type and mutant, respectively (P = 0.21). This excludes the possibility that changes in the distribution of axon diameters might contribute to the effects on myelination we observe.
A greater threshold for myelination is also seen in FAK-deficient mice
If the increased threshold for myelination we observed in the dnβ1 mice reflects an inhibition of integrin signaling, then we would predict that other transgenic mice having perturbations of downstream signaling molecules should show a similar phenotype. To test this we examined P16–P21 optic nerves from mice in which FAK had been deleted in myelinating glial cells by crossing mice homozygous for a floxed FAK allele with a Cnp-Cre line (Grove et al., 2007). As discussed above, FAK is a key part of the integrin signaling pathway, binding to the integrin cytoplasmic domain and being activated by phosphorylation after integrin ligand binding, and loss of FAK activity in oligodendrocytes has very recently been shown to result in hypomyelination in the developing mouse optic nerve (Forrest et al., 2009). Similarly to the dnβ1 mice, we found that an increased threshold diameter was required for myelination at this age, as evidenced by a reduced percentage of myelinated axons in knockout (57.37 ± 10.38%, n = 2,186 from 4 animals) compared with wild-type (64.93 ± 10.70%, n = 2,560 from 4 animals) optic nerves of P16–P21 animals (P = 0.0087; Fig. 6), whereas there was no difference in the percentage of myelinated axons in adult (P60) nerves (Fig. S3).
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To discern which mechanism is responsible for our observations, we performed co-culture experiments in which oligodendrocytes are provided in considerable excess (thus eliminating any extrinsic effects of cell number variation) and examined myelination by oligodendrocytes derived from wild-type or dnβ1 mice. These oligodendrocytes were cultured in the presence of wild-type dorsal root ganglion (DRG) neurons and their myelination efficiency was evaluated as described elsewhere (Wang et al., 2007) by determining the percentage of oligodendrocytes forming myelin. Although not the normal target of CNS oligodendrocytes, axons formed by DRG neurones grown in culture have a range of diameters of less than 2 µm (Fig. S4 a), similar to those in the optic nerve studied here, and are myelinated by oligodendrocytes added to these cultures. They therefore provide an appropriate test of the intrinsic myelinogenic capacity of the oligodendrocyte. We found that dnβ1 oligodendrocytes myelinated DRG axons significantly less efficiently (P < 0.01) than wild-type oligodendrocytes (Fig. 7). To show any intrinsic defect more clearly, we then asked whether each dnβ1 oligodendrocyte myelinated a reduced number of internodes and/or internodes with reduced length. We therefore quantified for each individual cell the number and average length of internodes in a total of 50 wild-type and dnβ1 oligodendrocytes in co-culture. Dnβ1 oligodendrocytes showed a reduced number of internodes (37 ± 2) when compared with wild-type (50 ± 5) oligodendrocytes (P < 0.05, n = 5). This difference was not due either to a reduced neurite density or perturbed oligodendrocyte differentiation in the dnβ1 cultures, as these were similar in the cultures of all three genotypes (Fig. S4 b). By contrast, no difference was found between the average internodal length per oligodendrocyte from the two genotypes (Fig. S4 c, wild-type: 45.8 ± 0.9 µm; dnβ1: 44.2 ± 0.8 µm, n = 5) or in the number of primary processes generated by each oligodendrocyte (wild-type: 4.12 ± 0.10, n = 74 from 4 experiments; dnβ1: 4.25 ± 0.12, n = 79 from 4 experiments). We conclude, therefore, that the increased axon diameter required for myelination reflects an intrinsic abnormality of axoglial signaling within the dnβ1 oligodendrocytes.
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The conclusion that oligodendrocyte integrins form part of the recognition complex for axonal signals that determine whether or not myelination occurs is important, as the identity of such axonal signals in the CNS is unknown. In the PNS, the level of axonal type III Nrg1 has been shown to play a crucial role in determining both whether an axon is myelinated and in the regulation of myelin thickness (Michailov et al., 2004; Taveggia et al., 2005). We have shown that laminin-binding integrins amplify neuregulin signaling as part of the mechanisms that regulate target-dependent survival of newly formed oligodendrocytes in the CNS (Colognato et al., 2002). Our results here would therefore be consistent with a model in which axonal neuregulins in the CNS, recognized by oligodendrocyte ErbB receptors, generate a signal to initiate myelination that is further amplified by integrins. In the case of small-diameter axons, this amplification is essential for triggering myelination, whereas large-diameter axons generate sufficient signal without integrin amplification. However, the role of neuregulins in CNS myelination has not been resolved. Exogenous addition of Nrg1 promotes myelination in co-cultures of oligodendrocytes and DRG neurons (Wang et al., 2007) and myelination of type III Nrg1-deficient DRG neurons is significantly reduced in co-culture (Taveggia et al., 2008). Hypomyelination is seen in transgenic mice expressing a dominant-negative ErbB receptor in oligodendrocytes, and in mice haploinsufficient for type III Nrg1 (Roy et al., 2007; Taveggia et al., 2008). However, in contrast to the PNS, increased expression of this axonal signal does not promote myelination of very small, and normally unmyelinated, axons in co-cultures of superior cervical ganglion neurons and oligodendrocytes (Taveggia et al., 2008). Moreover, conditional mutants with ablation of Nrg1, ErbB3, or ErbB4 exhibit no cortical myelination abnormalities (Brinkmann et al., 2008), a result that rather compellingly argues against a necessary role for Nrg1 signaling in CNS myelination. Additional neuregulin isoforms may be important in the CNS but equally, and in contrast to the PNS, other axonal signals may be required for regulating myelination. These may also be amplified by integrins, as seen for a number of different growth factors in other cell types. The hypothesis that such multi-component signaling complexes initiate and regulate myelination by oligodendrocytes provides a mechanism to explain the "catch-up" by the mutant oligodendrocytes in the older animals, as compensatory interactions within the complex will facilitate restoration of normal axoglial interactions.
Interestingly, both in monkeys and humans the area of the CNS most prone to remyelination failure is the optic nerve (Lachapelle et al., 2005). A model in which amplification of a myelination signal is required for small- but not large-diameter axon myelination could explain both the vulnerability of the optic nerve and the regional selectivity of the phenotype seen in the dnβ1 mouse, as the optic nerve contains entirely small-diameter axons. Similar regional differences in myelination are observed in other mutants that perturb integrin signaling, such as the Fyn knockout and the laminin-2–deficient (dy/dy) mouse. In these mice myelination defects are seen in optic nerve but not in spinal cord, where the density of larger axons is higher. Another possibility to explain regional heterogeneity, intrinsic differences in the oligodendrocytes arising from different regions of the developing CNS, seems less likely given that ablation of one such population is followed by replacement from a different region (Kessaris et al., 2006). In addition, transplantation of oligodendrocytes from optic nerve into spinal cord reveals that the transplanted cells can myelinate the full range of axon diameters in their new environment, even though these diameters are much greater than those present in their original location (Fanarraga et al., 1998).
Although the two previous studies examining the role of β1 integrins in regulating CNS myelination appear contradictory (Benninger et al., 2006; Lee et al., 2006), the current study allows their reconciliation. Here we have concluded that inhibition of integrins perturbs axoglial signaling and delays myelination of small-diameter axons, but has no effect on the subsequent formation of the myelin sheath. This conclusion is consistent with our previous report on the absence of g-ratio disturbances in the oligodendrocyte-specific conditional β1 knockout (Benninger et al., 2006), where the analysis focused on myelin sheath thickness in older animals. Hypomyelination after expression of β1C (Lee et al., 2006) can be explained by a requirement for dystroglycan in sheath formation. As noted in the introduction, the β1C integrin extracellular domain will form heterodimers with integrin- subunits and thus compete for ligand with other oligodendroglial laminin receptors. One of these is dystroglycan (Colognato et al., 2007), for which the main binding site on laminin overlaps with that of integrins at the laminin G domains LG1-3 (Talts et al., 1999; Wizemann et al., 2003). We have shown that dystroglycan is a significant laminin receptor for CNS myelination in vitro, and transgenic studies reveal an essential role in PNS myelination (Saito et al., 2003; Occhi et al., 2005; Colognato et al., 2007). We propose, therefore, that the study of Lee et al. (2006) expressing β1C reveals a requirement for dystroglycan in later stages of myelin sheath formation in addition to the role of integrins in the earlier stages of initiation. Our present and previous studies, by contrast, specifically target integrin signaling and would thus not reveal any later role of other laminin receptors.
The identification of the signals regulating the initiation of myelination may lead to the development of strategies to promote effective remyelination by oligodendrocytes within MS lesions arrested at the premyelinating stage and therefore unable to contribute to repair (Chang et al., 2002). Further studies examining the partners and ligands of the integrins expressed on oligodendrocytes represent promising new approaches toward understanding this goal.
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The dominant-negative sequences were initially cloned into a Gateway entry vector containing the 9.5-Kb MBP promoter (pENTR1A9.5). The IL2Rβ1 integrin sequence was available (Relvas et al., 2001) cloned as an XhoI fragment into XhoI of pLXIN vector (Clontech Laboratories, Inc.). We subsequently subcloned IL2Rβ1 as an XhoIK-PstI + PstI-BamHI fragment into EcoRV-BamHI of pBluescript. The IL2Rβ1 was then excised as an XhoI-ClaI fragment from pBluescript and cloned into pENTR1A9.5 linearized with SalI-ClaI. The IL2Rβ3 integrin sequence was also available cloned as an XhoI fragment into XhoI of pLXIN vector (Clontech Laboratories, Inc.). We subsequently subcloned IL2Rβ3 as an XhoIK-HindIII + HindIII-BamHI fragment into EcoRV-BamHI of pBluescript. The IL2Rβ3 was then excised as an XhoI-ClaI fragment from pBluescript and cloned into pENTR1A9.5 linearized with SalI-ClaI. The clones were all confirmed by an extensive series of restriction digests and the final clones in pENTR1A9.5 were also confirmed by automatic sequencing using the primers pE9.5bS 5'-aaagcaggctttaaaggaacc-3', pE9.5aC 5'-ggctgcaggaattcgatatca-3', and pE9.5mbpF 5'-ttcccggggcatctcgggaaaag-3', pE9.5mbpR 5'-aggccatcgccctctggagtggt-3'. Transgenes cloned into pENTR1A9.5 vector were subsequently transferred to the hprt targeting destination vector, in vitro, using the Gateway technology (Invitrogen). Both transgenes were docked, in single copy and fixed orientation, in the 5' flanking sequence of the hprt locus on the X chromosome. BPES5 ES cells (Denarier et al., 2005), bearing the same hprt deletion as the original BK4 ES cells (Bronson et al., 1996), were electroporated with 40 µg of linearized DNA and selected on HAT-supplemented medium as described previously (Farhadi et al., 2003). The HAT+ ES cell clones were screened by PCR using the primers ESIL2Rb1II 5'-cagagcttgtgcattgacattg-3' and pE9.5aC.
Generation of dominant-negative β1/β3 integrin transgenic mice
The genetically altered agouti ES cells were subsequently injected into C57BL/6-derived blastocysts that were then transplanted into the uteri of recipient females. Resulting chimeric males were bred with C57BL/6 females, and the F1 female agouti offspring were backcrossed with C57BL/6 males. Genotyping was performed by PCR with a set of primers for the wild-type (PfHprt mus 5'-gagggagaaaaatgcggagtg-3' and PrHprt mus 5'-ctccggaaagcagtgaggtaag-3') and a set of primers for the transgenic (ESIL2Rb1II and pE9.5aC) alleles. When further confirmation of sex determination was required, especially at young ages, PCR for the sex-determining region Y (SRY) gene was additionally performed. Mutant homozygous females and hemizygous males of the two dominant-negative lines were viable and showed no obvious behavioral abnormalities.
FAK knockout mice
The conditional inactivation of FAK in myelinating cells by crossing transgenic mice with lox sites inserted into the FAK gene (McLean et al., 2004; Charlesworth et al., 2006) with transgenic mice expressing cre recombinase under the regulation of the CNP promoter (a gift of Dr Klaus Nave, Gottingen, Germany) has been described elsewhere (Grove et al., 2007).
Myelinating co-cultures
Dorsal root ganglia (DRGs) were dissected from E14–E16 rats and digested for 45 min at 37°C with 1.2 U/ml papain (Worthington), 0.24 mg/ml L-cysteine (Sigma-Aldrich), and 40 µg/ml Dnase I (Sigma-Aldrich). The dissociated cells were plated onto 22-mm coverslips precoated with poly-D-lysine (10 µg/ml; Sigma-Aldrich) followed by matrigel (1:20 dilution; BD Biosciences) at a density of 5 x 105 cells/ml. The DRGs were grown for two weeks in DMEM supplemented with 10% fetal bovine serum (Invitrogen) and nerve growth factor (NGF, 100 
g/ml; AbD Serotec). The cultures were pulsed three times, for 2 d each time, with fluorodeoxyuridine (10 µM; Sigma-Aldrich) to remove contaminating fibroblasts and glial cells. Neurospheres from wild-type or mutant litters were added to each coverslip with purified DRGs. The medium used for the co-cultures was 50:50 DMEM/Neurobasal medium (Invitrogen) supplemented with Sato and B27 (Invitrogen), NGF (100 g/ml), N-acetyl cysteine (5 µg/ml, Sigma-Aldrich), and D-biotin (10 g/ml). Co-cultures were maintained for 3 wk with medium and supplements changed every 3–4 d. After 3 wk, the extent of myelination was quantified by determining the slope of the best-fit line defining the relationship between the percentage of oligodendrocytes (defined by the expression of MBP as detected by immunohistochemistry) with myelin sheaths and the density of the underlying neurite network (Wang et al., 2007). The number and length of internodes was traced and measured using ImageJ software. The average number of primary processes (defined as those originated directly from the cell body) was quantified in MBP+ oligodendrocytes at the initial stages of myelination, before internode formation, using OpenLab image analysis software (Improvision).
RT-PCR
Total RNA was extracted from mouse tissues using the RNeasy mini kit (QIAGEN), according to the manufacturer's instructions, and subjected to one-step RT-PCR (QIAGEN). The following primers were used for the extracellular β1 integrin domain: B1ecF 5'-tggacaatgtcacctggaaa-3', B1ecR 5'-tgtgcccactgctgacttag-3'; and for the IL2R extracellular domain: IL2RaF5'-atcagtgcgtccagggatac-3', IL2RaR 5'-gacgaggcaggaagtctcac-3'. Data were normalized to β-actin levels (5'-agccatgtacgtatccatcc-3' and 5'-ctctcagctgtggtggtgaa-3'). ImageJ software was used to quantify mRNA expression levels.
Western blot
Dissected tissues from dnβ1 and wild-type mice were homogenized in 1% SDS and subjected to SDS-PAGE using appropriate percentage of acrylamide minigels. They were then transferred onto 0.45-µm nitrocellulose membranes (HybondC; GE Healthcare) and blocked with 5% nonfat dry milk and 0.1% Tween 20 Tris-buffered saline (TBS) for 1 h at room temperature (RT). The primary antibody diluted in blocking solution was incubated for 2 h at RT or overnight (ON) at 4°C. The blots were then washed three times in TBS 0.1% Tween (TBS-T) and incubated for 1 h at RT with a horseradish peroxidase–labeled secondary antibody (GE Healthcare). After washing again in TBS-T the immunoreactive proteins were revealed by chemiluminescence (ECL; GE Healthcare) according to the manufacturer's instructions. Digitalized images were obtained and bands quantified using ImageJ software.
Immunofluorescence and image acquisition
When staining for MBP on tissue sections, a post-fixation step prior staining was performed with 95% ethanol and 5% acetic acid for 30 min at –20°C, followed by three rinses in PBS. Sections were then blocked for 1 h in PBS containing 10% normal goat serum (NGS) and 0.1% Triton X-100 at RT, after which the primary antibody incubation was performed either ON at 4°C or for 2 h at RT. The following primary antibodies were used for immunofluorescence or Western blot: rat anti-MBP (AbD Serotec), mouse anti-neurofilament 200 (Sigma-Aldrich), rabbit polyclonal anti-pFAK (Y397; Invitrogen), rabbit polyclonal anti-FAK (Invitrogen), and monoclonal mouse anti–human CD25/interleukin-2 receptor (Dako). After washing in PBS, the sections were incubated for 1 h with the secondary antibody (FITC or Alexa 588 and TRITC or Alexa 488 labeled) and Hoechst. After further washes in PBS, slides were mounted in fluoromount (SouthernBiotech). All fluorescence images were acquired at RT with a fluorescence microscope (Axioplan; Carl Zeiss, Inc.), fitted with 10x eyepiece magnification, 20x (0.5 NA) and 40x (0.75 NA) objectives, and a digital camera (model C4742-95; Hamamatsu) using OpenLab image analysis software (Improvision).
Electron microscopy
Hemizygous and wild-type males were used as mutant and control mice, respectively. Anaesthetized mice were perfused intracardially with freshly prepared 4% glutaraldehyde containing 2 mmol/l CaCl2 in 0.1 M phosphate buffer (PB) at RT. Dissected tissues were incubated in the same solution ON. After rinsing in 0.1 M PB, samples were post-fixed in 1% osmium tetroxide ON and dehydrated in a grade series of ethanol. The tissues were embedded in TAAB resin, and sections for light and electron microscopy were prepared using a microtome (Ultracut UCT; Leica). Semi-thin sections were stained with methylene blue. Ultra-thin sections were stained with saturated uranyl acetate in 50% ethanol and lead citrate and examined in a transmission electron microscope (model CM100; Philips).
Morphometry
Digitalized images were obtained from corresponding levels of the various mouse tissues. The g-ratio was calculated by the ratio between the area of the axon and the area of the same axon including myelin using OpenLab image analysis software (Improvision). A minimum of 100 randomly chosen axons, from at least 5 nonoverlapping images per animal, were analyzed for calculating the g-ratio. A minimum of 400 axons from at least 3 nonoverlapping images per animal were analyzed to calculate the percentage of myelination per axon diameter.
Statistical analysis
The data show the mean ± SEM, unless otherwise indicated. Statistical significance for the expression of the dnβ1 integrin by RT-PCR and changes in pFAK by Western blot was determined by using paired t test; for g-ratio analysis by Student's t test; for percentage of myelination per axon diameter analysis by two-way ANOVA; for average axon diameter determination by Student's t test; for evaluation of myelination efficiency in co-culture by repeated measures ANOVA with Tukey's multiple comparison post-test; and for internodal number, internodal length, and number of processes analyses by one-way ANOVA with Tukey's multiple comparison post-test. n represents the number of axons examined for each control and mutant littermate, with at least three independent litters of transgenic mice analyzed unless otherwise indicated or, in the case of the co-cultures, the number of independent experiments performed. Statistical analysis was performed using GraphPad Prism software.
Online supplemental material
Figure S1 shows the expression pattern in the brain and optic nerve of the 9.5-Kb MBP promoter used for the dominant-negative integrins. This promoter is expressed only at the time of myelination in different white matter tracts. Figure S2 shows that the morphology of corpus callosum and optic nerve in the dnβ1 mice is normal, as assessed by immunohistochemistry. Figure S3 shows that the threshold axon diameter for myelination is normal in adult dnβ1 and FAK KO mice. Figure S4 provides further quantification of the myelinating co-cultures, showing the distribution of axon diameters and that oligodendrocyte differentiation and internodal length are similar in cultures using cells from wt, dnβ1, and dnβ3 mice. Figure S5 illustrates the steps taken to generate and characterize the dnβ3 transgenic line used as a control in our study. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200807010/DC1.
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Acknowledgments |
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This work was funded by the Wellcome Trust and the National Multiple Sclerosis Society (C. ffrench-Constant) and the Gulbenkian PhD Program in Biomedicine and Fundação para a Ciência e a Tecnologia, Portugal (J. Câmara).
Submitted: 2 July 2008
Accepted: 23 April 2009
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References |
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