Abstract
Axonal myelination of neocortical pyramidal neurons is modulated dynamically by neuronal activity. Recent studies have shown that a substantial proportion of neocortical myelin content is contributed by fast-spiking, parvalbumin (PV)-positive interneurons. However, it remains unknown whether the myelination of PV+ interneurons is also modulated by intrinsic activity. Here, we used cell-type-specific Designer Receptors Exclusively Activated by Designer Drugs (DREADDs) in adult mice to activate a sparse population of medial prefrontal cortex (mPFC) PV+ interneurons. Using single-cell axonal reconstructions, we found that DREADD-stimulated PV+ interneurons exhibited a nearly two-fold increase in total length of myelination, predominantly mediated by a parallel increase of axonal arborization and number of internodes. In contrast, the distribution of axonal interbranch segment distance and myelin internode length were not altered significantly. Topographical analysis revealed that myelination of DREADD-stimulated cells extended to higher axonal branch orders while retaining a similar interbranch distance threshold for myelination. Together, our results demonstrate that chemogenetically induced neuronal activity increases the myelination of neocortical PV+ interneurons mediated at least in part by an elaboration of their axonal morphology.
SIGNIFICANCE STATEMENT Myelination is the wrapping of an axon to optimize conduction velocity in an energy-efficient manner. Previous studies have shown that myelination of neocortical pyramidal neurons is experience and activity dependent. We now show that activity-dependent myelin plasticity in the adult neocortex extends to parvalbumin (PV)-expressing fast-spiking interneurons. Chemogenetic stimulation of PV interneurons in the medial prefrontal cortex (mPFC) significantly enhanced axonal myelination, which was paralleled by an increase in axonal arborization. This suggests that activity-dependent axonal plasticity may involve changes in both structural morphology and myelination. Such multicomponent plasticity reveals an unexpected repertoire of anatomical parameters available for optimizing and adapting neuronal networks in response to experience.
Introduction
Myelin functions critically to enable complex neuronal function, including learning and cognition. Recent studies have shown that a substantial fraction of myelin in the cerebral cortex is localized to fast-spiking, parvalbumin-positive (PV+) interneurons (Micheva et al., 2016; Stedehouder et al., 2017). PV+ interneuron myelination is topographically biased toward the proximal axon and constrained by local axonal morphology, including branch points and en passant boutons (Stedehouder et al., 2017).
In addition, recent studies have shown that myelination is activity dependent (Fields, 2015; Chang et al., 2016). Optogenetic neuronal stimulation increases oligodendrogenesis and myelination selectively in mice (Gibson et al., 2014) and neuronal activity biases axonal selection and myelin topography in zebrafish (Hines et al., 2015; Mensch et al., 2015). Complex motor skill learning requires the production of new oligodendrocytes (McKenzie et al., 2014), monocular deprivation leads to both oligodendrogenesis and reduced internode length (Etxeberria et al., 2016), and social isolation negatively influences oligodendrocyte morphological complexity with a concomitant reduction of internode density and g-ratio (Makinodan et al., 2012).
An important outstanding question is whether PV+ interneuron myelination is similarly dependent upon neuronal activity. In the present study, we use cell-specific Designer Receptor Exclusively Activated by Designer Drug (DREADD) technology to confirm that activity-dependent myelination extends to PV+ interneurons in the adult brain. Electrophysiological recordings with single-cell labeling of manipulated cells permitted the coordinated examination of axonal morphology and myelin topography, revealing an activity-dependent enhancement of PV+ interneuron myelination that could be largely explained by an elaboration of axonal arborization with a parallel increase of internode number.
Materials and Methods
Mice.
All experiments were approved by the Dutch Ethical Committee and in accordance with the Institutional Animal Care and Use Committee guidelines. Mouse lines were obtained from The Jackson Laboratory [Pvalbtm1(cre)Arbr/J mice (PV::cre) (Hippenmeyer et al., 2005), strain #008069; C57BL/6J (WT), strain #000664]. All lines were backcrossed for >10 generations in C57BL/6J. Adult mice of both genders were used from 8–12 weeks of age. Mice were group-housed and maintained on a 12 h light/dark cycle with ad libitum access to food and water. After surgery, mice were single-housed until further experiments.
Viral labeling and CNO injections.
Heterozygous PV::cre mice were used for viral-mediated cell-type-specific labeling performed using adeno-associated virus (AAV) expression with cre-dependent AAV5/hSyn-DIO-hM3Dq-mCherry and AAV5/hSyn-DIO-GFP (University of Pennsylvania Viral Vector Core). Virus was diluted to ∼5 × 1011 GC/ml in PBS to achieve sparse labeling. hM3Dq-mCherry and GFP control injections were counterbalanced between the left and right hemisphere. All mice showed successful bilateral virus expression with no contralateral contamination.
Anesthesia was induced using 5% isoflurane (O2 flow of 0.5 L/min), and subsequently maintained with 1–2% isoflurane during surgery. Body temperature was maintained at 37°C. Mice were placed into a custom-made stereotaxic frame using a mouth bar (Stoelting) for head fixation. Analgesia was provided systemically by subcutaneous Temgesic injection (buprenorphine 0.5 mg/kg) and locally by xylocaine spray (100 mg/ml; AstraZeneca) applied directly on the skull. To access the brain, a longitudinal scalp incision of ∼1 cm length was made to reveal the skull and a small craniotomy (<1 mm) was performed overlying the injection sites at the following coordinates (in mm): mPFC: +1.75 bregma, ±0.35 lateral, −1.9 dorsoventral
Mice used for electrophysiological recordings received 1 μl in a ½ dilution. Virus was aspirated in a borosilicate glass micropipette, which was slowly lowered to the target site. Virus injection was controlled by an automated syringe pump (infusion speed 0.1 μl/min). At the conclusion of the injection, the micropipette was maintained in place for another 5 min and then slowly withdrawn. The surgical wound was closed with skin glue (Derma+flex). Mice were left to recover for 28 d to allow expression of hM3Dq-mCherry and GFP protein. To optimize the bilateral virus injection symmetry necessary for consequent bilateral electrophysiology, we took particular care at a few key points: (1) mouse skulls were always carefully vertically leveled based on bregma and lambda, (2) glass micropipettes were always checked to run properly before injections and were carefully cleaned to remove excess virus particles, (3) drill holes were kept as small as possible (<1 mm), and (4) mice were left to recover for exactly 28 d before starting clozapine N-oxide (CNO) injections to minimize expression variations between mice.
After 28 d of recovery, mice were injected intraperitoneally with CNO (Sigma-Aldrich) 1 mg/kg twice daily (at ∼9:00 h and ∼18:00 h) for 14 consecutive days. Mice displayed no weight loss over the injection period (day 1: 26.2 ± 1.5 g; day 14: 24.8 ± 1.1 g; p = 0.458; paired two-tailed t test) or overt behavioral abnormalities under CNO administration.
Electrophysiology.
The next morning after the last CNO injection, mice were anesthetized using 5% isoflurane and decapitated in ice-cold, N-methyl-d-glucamine (NMDG)-based cutting solution containing the following (in mm): 93 NMDG, 93 HCl, 30 NaHCO3, 25 d-glucose, 20 HEPES, 5 Na-ascorbate, 2 thiourea, 10 MgCl2, 3 Na-pyruvate, 2.5 KCl, 1.25 NaH2PO4, and 0.5 CaCl2, 300 mOsm, pH 7.4, oxygenated with 95% O2/5% CO2. Coronal slices (300 μm) were cut with a vibrating slicer (Microm HM 650 V; Thermo Scientific) and incubated in cutting solution at 37°C for 8 min, followed by oxygenated (95% O2/5% CO2) artificial CSF (aCSF) at 37°C for another 10 min. ACSF contained the following (in mm): 127 NaCl, 25 NaHCO3, 25 d-glucose, 2.5 KCl, 1.25 NaH2PO4, 1.5 MgSO4, and 1.6 CaCl2. Slices were then allowed to recover at room temperature for at least 1 h before recordings.
PV+ interneurons from the prelimbic region layer V of the mPFC were visualized by mCherry or GFP fluorescence using a TXRED or GFP filter (Semrock), respectively. Importantly, GFP+ control cells were recorded from contralateral hemispheres of the same coronal slices as recorded hM3Dq-mCherry+ cells and cells were recorded from equal distances from the midline (see Fig. 4d). To minimize variation in proportion of missing axon due to slicing, cells were consistently patched at a depth of 20–50 μm from the slice surface. Whole-cell recordings were made using borosilicate glass pipettes (3.5–5.5 MΩ resistance) with intracellular solution containing the following (in mm): 120 K-gluconate, 10 KCl, 10 HEPES, 10 K-phosphocreatine, 4 ATP-Mg, 0.4 GTP, and 5 mg/ml biocytin, pH adjusted to 7.4 using KOH and osmolarity 285–290 mOsm. All recorded mCherry+ and GFP+ cells had a fast-spiking phenotype, with subthreshold membrane potential oscillations, suprathreshold high-frequency, nonadapting firing patterns, and large-amplitude fast afterhyperpolarizations. Cells were filled for at least 25 min for proper biocytin spreading.
Recordings were performed in aCSF at near-physiological temperatures (33 ± 1°C) using HEKA EPC10 Quattro amplifiers and Patchmaster software (40 kHz). Series resistance was typically <20 MΩ and fully compensated for bridge balance and capacitance. No correction was made for liquid junction potential. Data analysis was performed offline using Igor Pro version 6 (Wavemetrics).
Basic physiological characteristics were determined from voltage responses to square-wave current pulses of 500 ms duration ranging from −100 pA to +300 pA and delivered in 20 pA intervals. Input resistance was determined by the slope of the linear regression through the voltage-current curve. Single action potential (AP) characteristics were obtained from the first elicited AP. AP threshold was defined as the inflection point at the foot of the regenerative upstroke. AP amplitude was defined as the voltage difference between the threshold and peak voltage. AP half-width was measured at half of the peak amplitude. AP rise time was quantified as duration from 10% to 90% of the peak amplitude. The fast afterhyperpolarizing potential (fAHP) amplitude was measured as the hyperpolarizing deflection from AP threshold after AP initiation.
Local application of CNO was performed at a concentration of 10 μm (in 0.9% NaCl) through a borosilicate glass pipette (3.5–5.5 MΩ resistance). The pipette was backfilled with CNO and positioned at a distance of ∼20 μm from the recorded soma within the same focal plane. A total of 50 μl of CNO (10 μm) was applied over 250 ms at a fixed rate of 200 μl/s.
Immunofluorescence.
For recovery of biocytin-labeled cells after electrophysiological recordings, 300 μm slices were incubated overnight at 4°C in fresh 4% paraformaldehyde (PFA). Slices were extensively rinsed at room temperature in PBS and stained in PBS buffer containing 0.4% Triton X-100, 2% normal horse serum (NHS; Invitrogen) and streptavidin-conjugated secondary antibody 488 (1:300, Jackson Laboratories; for hM3Dq-mCherry+ cells) or streptavidin-Cy3 (1:300; Invitrogen; for GFP+ cells) for 5 h at room temperature. Slices were washed with PBS and PB 0.1 m and mounted on slides, coverslipped with 200 μl of Mowiol (Sigma-Aldrich), sealed, and immediately imaged for full axonal morphology (see “Confocal microscopy” section). To avoid excessive thinning or drying of 300 μm sections, cells were mounted, imaged, and returned to PB 0.1 m directly after imaging.
After full cell imaging, 300 μm slices were extensively washed in PB 0.1 m and PBS, and subsequently incubated overnight at 4°C in 30% sucrose (0.1 m PB). Sections were then carefully recut at 40 μm using a freezing microtome (Leica; SM 2000R) and stored serially in 0.1 m PB at 4°C. Forty-micrometer sections were washed with PBS and preincubated with a blocking PBS buffer containing 0.5% Triton X-100 and 10% NHS for 1 h at room temperature. Sections were incubated in PBS buffer containing 0.4% Triton X-100 and 2% NHS for 72 h at 4°C and goat anti-MBP (1:300, Santa Cruz Biotechnology, C-16, sc-13914). Then, sections were washed with PBS and incubated with corresponding Alexa Fluor-conjugated secondary antibodies (1:300, Invitrogen) and cyanine dyes (1:300, Sanbio) in PBS buffer containing 0.4% Triton X-100, 2% NHS for 5 h at room temperature. For biocytin, streptavidin-A488 (1:300; Jackson Laboratories) and streptavidin-Cy3 (1:300; Invitrogen) were again used. Nuclear staining was performed using DAPI (1:10,000; Invitrogen). Sections were washed with PB 0.1 m and mounted on slides, coverslipped with Vectashield H1000 fluorescent mounting medium (Vector Laboratories), sealed, and imaged (see “Confocal microscopy” section).
An independent group of mice received CNO injections for 14 d before transcardial perfusion using 4% PFA. Brains were resected, placed in 4% PFA for postfixation (2 h) at room temperature and subsequently stored in 10% sucrose solution (0.1 m PB) overnight at 4°C. The next day, brains were embedded in gelatin (12% gelatin (SigmaAldrich)/10% sucrose), postfixed (10% PFA/30% sucrose) for 2 h at room temperature, and then stored in 30% sucrose solution overnight at 4°C. Coronal sections were made on a freezing microtome in 40 μm and collected in 0.1 m PB. Subsequently, slices were similarly stained as described above for recut electrophysiology slices.
The following primary antibodies were used: rabbit anti-mCherry (1:500, Abcam, ab167453), chicken anti-GFP (1:2000, Aves Laboratories), mouse anti-PV (1:1000, Swant, 235), goat anti-MBP (1:300, Santa Cruz Biotechnology, C-16, sc-13914), and mouse anti-CC1 (1:100, Merck, ab-7).
Confocal imaging and analysis.
Confocal imaging was performed using a Zeiss LSM 700 microscope equipped with Plan-Apochromat 10×/0.45, 20×/0.8 and 63×/1.4 (oil-immersion) objectives. DAPI, Alexa Fluor 488, Cy3, and Alexa Fluor 647 were imaged using excitation wavelengths of 405, 488, 555, and 639 nm, respectively. Reconstructions of biocytin-filled cells were obtained from 300 μm slices at 63× magnification with 1× digital zoom and a z-step size of 0.5 μm. For axonal myelin reconstructions, recut and restained 40 μm slices were imaged at 63× magnification with 1× digital zoom and a z-step size of 0.5 μm.
All images were transferred to Neurolucida 360 software (version 2.8; MBF Bioscience) and reconstructed using interactive tracing with the directional kernels method. Reconstructed soma, axon, and myelin segments were analyzed with Neurolucida Explorer (MBF Bioscience). Axons were easily identified as the thinnest, smoothest, and most highly branched processes originating from either the soma or primary dendrite. In addition, axons seemed to branch at more obtuse ≥90° angles from one another, often turning back toward the soma, whereas dendrites branched at smaller angles (<90°), continuing a trajectory away from the soma. All reconstructed cells showed a classical basket cell morphology (DeFelipe et al., 2013), which is consistent with a recent study showing absence of chandelier cells beyond mPFC layer II (Miyamae et al., 2017).
Myelinated axonal segments were defined as the circumferential bordering of a streptavidin-labeled axon by an MBP+ myelin signal. Myelin segments that exited a slice were removed from subsequent analysis. No spatial corrections were made for tissue shrinkage.
Transduction efficiency and specificity, as well as oligodendrocyte number, were measured in transduced regions in the prelimbic area of the mPFC (bregma: +2.30 till +1.70 mm) of brain slices from transcardially perfused mice. Stacked confocal images were obtained at 20× with 1× digital zoom and a z-step size of 3 μm. A 467 μm × 467 μm × 12 μm counting frame was established for manual counting using the multipoint tool in Fiji image analysis software (version 2.0.0). Colocalization with PV was defined as a mCherry- or GFP-labeled soma overlapping with PV+ soma signal.
Statistical analysis.
Statistical analysis was performed using IBM SPSS software version 23. All datasets were examined using Shapiro–Wilk test for normality. Datasets with normal distributions were analyzed for significance using unpaired or paired Student's two-tailed t test or repeated-measures ANOVA measures followed by Tukey's post hoc test. Datasets with non-normal distributions were analyzed using Mann–Whitney U test. Significance threshold was set at p < 0.05 and, herein, exact p-values values are provided except when p < 0.001. All data are expressed as mean ± SE. On the basis of previously published datasets (Stedehouder et al., 2017), we chose similar sample sizes for all experiments performed. Results are the combination of three animal cohorts that showed similar results.
Results
Chemogenetic activation increases parvalbumin interneuron myelination
We used in vivo cell-specific expression of activating DREADD (Armbruster et al., 2007), followed by ex vivo whole-cell electrophysiology and single-cell axonal reconstructions (Fig. 1a). Adult PV::cre mice (Hippenmeyer et al., 2005) received bilateral stereotactic injections in the mPFC using adeno-associated viruses (AAV) with cre-dependent expression of unilateral hM3Dq-mCherry and contralateral GFP (Fig. 1b,c). Four weeks after transduction, mice were given intraperitoneal administrations of CNO (1 mg/kg, twice daily) for 14 consecutive days. Viral transduction was highly specific for PV+ cells with a similarly high cell-type specificity of hM3Dq-mCherry and GFP vectors (Fig. 1d,e). Sixteen hours after the last intraperitoneal CNO injection, ex vivo whole-cell recordings with post hoc biocytin labeling were performed in hM3Dq-mCherry+ cells and contralateral GFP+ cells from mPFC layer V (Fig. 2a,b). hM3Dq-mCherry+ and GFP+ cells exhibited subthreshold membrane potential oscillations, a suprathreshold high-frequency nonadapting pattern of AP firing, and a large-amplitude fAHP, consistent with a fast-spiking, PV+ interneuron identity. No differences were observed between hM3Dq-mCherry+ and GFP+ cells in baseline membrane properties or single AP characteristics (Fig. 2c–j).
To determine the influence of DREADD receptor activation on PV+ interneurons, we performed ex vivo electrophysiological recordings of hM3Dq-mCherry+ and GFP+ cells in the presence of CNO (Fig. 3a). Local application of CNO resulted in membrane depolarization, followed by a robust increase in firing frequency of hM3Dq-mCherry+ cells (Fig. 3b). Similarly, bath application of CNO (5 μm) induced an ∼5 mV membrane depolarization in hM3Dq-mCherry+ cells (Fig. 3c), whereas no changes were observed in GFP+ cells (Fig. 3d). Therefore, CNO administration selectively increased activity in hM3Dq-mCherry+ cells.
We next sought to determine whether DREADD-mediated activation of PV+ interneurons modulates their myelination. Therefore, we performed Neurolucida reconstructions of proximal axons of biocytin-labeled hM3Dq-mCherry+ (Fig. 4a,c,f) and GFP+ (Fig. 4b,c,g) cells, including myelination (Fig. 4e). hM3Dq-mCherry+ and GFP+ cells were located at a similar depth within the mPFC (Fig. 4d). Consistent with previous findings in PV+ interneurons (Stedehouder et al., 2017), all reconstructed hM3Dq-mCherry+ and GFP+ cells exhibited axonal myelination (hM3Dq-mCherry: 14/14 cells, 100%; GFP: 12/12 cells, 100%) (Fig. 4h). However, hM3Dq-mCherry+ cells exhibited an increase of total length of axonal myelination per neuron (Fig. 4i) driven primarily by an increase in the number of internodes (Fig. 4j). Internode length showed a trend toward longer internodes in hM3Dq-mCherry+ cells but was statistically unchanged (Fig. 4k). Topographical analysis of axonal reconstructions revealed that the enhanced myelination of hM3Dq-mCherry+ cells occurred along fourth to ninth axonal branch order segments (Fig. 4l), for which hM3Dq-mCherry+ cells exhibited a significantly higher axonal branch order of distal myelination compared with GFP+ cells (Fig. 4n); the initial onset of myelination was unchanged (Fig. 4m). Together, these data show that chemogenetic activation of PV+ interneurons enhances their myelination through an increased number and more distally extended distribution of axonal internodes.
Cell-specific activation results in axon morphology changes
We next sought to determine whether changes in axonal morphology might underlie the observed increase in total myelination on DREADD-stimulated PV+ interneurons. Therefore, we reconstructed the axon of each cell, beginning from the axon initial segment until the occurrence of a string of en passant boutons (≥3 consecutive boutons on a single axonal branch located within 15 μm) on each terminal branch. Consistently, DREADD-stimulated PV+ interneurons had a significantly more elaborated axonal morphology compared with GFP+ controls (Figs. 5a,b, 6a,b). Using Sholl analysis, hM3Dq-mCherry+ cells exhibited a greater number of intersections and longer axonal length compared with GFP+ cells (Fig. 5c,d). Moreover, branch structure analysis (Fig. 6a–d) also confirmed that hM3Dq-mCherry+ cells had a longer axonal length (Fig. 6e) and an increased number of branch points (Fig. 6f), beginning from the fifth branch order distally (Fig. 6g). The average interbranch point distance also remained unchanged (Fig. 6h). Together, these data indicate that PV+ interneurons exhibit a robust and highly specific activity-dependent elaboration of their axonal morphology after in vivo stimulation in the adult neocortex.
Activity-driven myelin increases are proportional to axonal morphology changes
Given that DREADD-stimulated PV+ interneurons exhibit increased myelination and altered axonal morphology, we investigated whether the increase in myelination was proportional to the change in axonal complexity. For each cell, we examined the proportion of axonal segments per branch order that contained internodes (myelination fraction). Both hM3Dq-mCherry+ and GFP+ cells showed a progressively decreasing myelination fraction with increasing branch order (Fig. 7a–c). Moreover, hM3Dq-mCherry+ cells exhibit a similar myelination fraction extending to the distal limit of GFP+ cells (Fig. 7c), beyond which hM3Dq-mCherry+ cells exhibit additional myelinated segments along their extended axonal length (Fig. 7d). Together, these data suggest that the activity-dependent increase in myelination of PV+ interneurons is predominantly mediated by the elaboration of axon morphology.
Myelination is restricted by axonal distance between branch points
Previous studies have reported that proximal axon myelination most commonly occurs on uninterrupted axonal segments of at least 15 μm (Stedehouder et al., 2017). Therefore, we investigated whether activity-induced myelination changed these requirements. We quantified interbranch point distances from the soma up to fifth-order axonal segments, including whether these segments contained an internode. Unmyelinated interbranch point segments were consistently shorter than corresponding myelinated segments in both GFP+ cells and hM3Dq-mCherry+ cells (Fig. 8a). Overall, interbranch segments >40 μm were frequently myelinated (91.6%), whereas interbranch segments <15 μm tended to be unmyelinated (96.2%). An analogous dichotomy was also evident in the location of the first axonal branch point, which was positioned closer to the soma when it arose before, compared with after, the first internode of both hM3Dq-mCherry+ and GFP cells+ (Fig. 8b). These findings suggest that the activity-driven increase of PV+ interneuron myelination is proportional to the increase of total axonal length while maintaining a similar topography of axonal morphology and myelination.
No alterations in total myelin content or oligodendrocyte number
Prior studies using optogenetic and chemogenetic pyramidal cell activation have demonstrated substantial increases in total myelin content and oligodendrocyte lineage cell density (Gibson et al., 2014; Mitew et al., 2018). Therefore, we investigated the cell-type specificity of the activity-dependent changes in PV+ axonal myelination by quantifying both total myelin content and oligodendrocyte density in the surrounding volume. We performed immunofluorescent stainings for myelin (MBP) and mature oligodendrocytes (CC1) in hM3Dq-mCherry+ and GFP+ transduced areas (Fig. 9a). In contrast to previous studies involving pyramidal cell stimulation, we did not find evidence for changes of total myelin content (Fig. 9b–e) or oligodendrocyte density (Fig. 9f–h) following stimulation of PV+ interneurons. Accordingly, the observed activity-dependent changes in PV+ axonal morphology and myelination appear likely to be cell autonomous.
Discussion
Here, we investigated whether in vivo activity-dependent myelination occurs in neocortical fast-spiking, PV+ interneurons. Using cell-specific chemogenetic activation followed by single-cell reconstructions of PV+ interneurons in the adult mouse mPFC, we found that in vivo stimulation of PV+ interneuron activity induced an ∼50% increase in proximal axonal length with a proportional increase in myelination. These findings add to the understanding of dynamic myelination, but our results suggest that, at least for PV+ interneurons, this is mediated to a significant extent by activity-dependent plasticity of axonal morphology.
Using single-cell reconstructions allowed us to document comprehensively the position of each myelinated segment along the axon, in contrast to previous studies using larger-scale analyses (Gibson et al., 2014). We found that stimulated cells exhibited increased myelination of more distal axon segments (branch order ≥4), whereas myelination did not differ on more proximal branch orders. Furthermore, due to bilateral transfection with either DREADDs or GFP, we could reconstruct cells from both hemispheres under similar conditions, thereby minimizing possible experience-dependent variation. Finally, our studies were performed in adult mice, thereby reducing the likelihood of neurodevelopmental interactions. As a corollary, whether activity-dependent PV+ myelination is regulated similarly during neurodevelopment is an important question that remains to be answered.
A limitation of the current study is that we could not follow axonal and myelination changes longitudinally over time. Therefore, the time course of the observed changes of axonal morphology and myelination remain unknown, as well as a definitive confirmation that the changes in axonal morphology precede the increase in myelination. Moreover, it remains unknown which specific axonal parameters govern the increase of PV+ interneuron myelination. Our findings suggest that a substantial proportion of the increase in myelination is mediated by an activity-induced elaboration of PV+ interneuron axonal arborization (Yamada et al., 2010) that is subsequently myelinated. Another candidate is axon diameter, which has been shown to change rapidly upon neuronal activity in CA3 pyramidal cells (Chéreau et al., 2017) and has been demonstrated to function as a critical biophysical threshold permissive for myelination (Lee et al., 2012; Bechler et al., 2015). Moreover, an activity-dependent modulation of vesicular release probability could also be an important determinant because axonal vesicular release has been shown to regulate the differentiation to myelinating oligodendrocytes of oligodendrocyte progenitor cells in close proximity to unmyelinated axonal segments (Mensch et al., 2015; Wake et al., 2015).
The increase of axonal myelination appears to result from the addition of internodes because the distribution of internode length is largely preserved (Fig. 4k). Consistent with previous findings (Stedehouder et al., 2017), we also found that the pattern of myelination along axons of stimulated PV+ interneurons is constrained by a similar interbranch segment length threshold (Fig. 8). This suggests that, although neuronal activity can modulate axonal morphology dynamically, there is as yet no evidence for activity-dependent plasticity of the fundamental biophysical parameters dictating the eligibility of myelination at a given axonal segment.
Previous reports demonstrated that cell-type-specific stimulation of cortical pyramidal neurons lead to observable changes of total myelin content and oligodendrocyte density. We similarly assessed cell-type specificity after chemogenetic activation of PV+ interneurons. However, we did not find changes in oligodendrocyte density or overall myelin labeling. We suggest two possibilities for the absence of an observable difference of these metrics. First, given that PV+ interneurons contribute only a small minority of the total myelin content in the mPFC (Stedehouder et al., 2017) and that virally labeled cells constitute only a subset of PV+ interneurons within the transduced areas, the possibility exists that changes in the number of oligodendrocytes due to PV+ activation might have been too small to be observed using volumetric quantification. Moreover, with regard to total myelin content, the limitation of a volumetric quantification might therefore also be considered likely on the basis of the demonstrated increase of myelination per chemogenetically activated PV+ interneuron (Fig. 4). The second non-mutually exclusive possibility is predicated upon the established function of PV+ interneurons as strong modulators of local network activity (Hu et al., 2014). In this scenario, PV+ interneuron-mediated inhibition of principal cell firing might lead to reductions in myelination of an equivalent magnitude as the increase in myelination of PV+ interneurons.
Here, we identified a novel form of activity-dependent myelination mediated by axonal morphological plasticity of PV+ interneurons. These findings contribute to the increasing evidence demonstrating the dynamic plasticity of adult neocortical myelination and axonal morphology.
Footnotes
- Correspondence should be addressed to Steven A. Kushner, Department of Psychiatry, Erasmus MC, Rotterdam 3015 CE, The Netherlands. s.kushner{at}erasmusmc.nl