ABSTRACT
Frontotemporal dementia and parkinsonism (FTDP-17) caused by the 10+16 splice-site mutation in the gene encoding microtubule-associated protein tau (MAPT) provides an established platform to model tau-related dementia in vitro. Neurons derived from human induced pluripotent stem cells (iPSCs) have been shown to recapitulate the neurodevelopmental profile of tau pathology during in vitro corticogenesis, as in the adult human brain. However, the neurophysiological phenotype of these cells has remained unknown, leaving unanswered questions regarding the functional relevance and the gnostic power of this disease model. In this study, we used electrophysiology to explore the membrane properties and intrinsic excitability of the generated neurons and found that human cells mature by ∼150 days of neurogenesis to become compatible with matured cortical neurons. In earlier FTDP-17, however, neurons exhibited a depolarized resting membrane potential associated with increased resistance and reduced voltage-gated Na+- and K+-channel-mediated conductance. Expression of the Nav1.6 protein was reduced in FTDP-17. These effects led to reduced cell capability of induced firing and changed the action potential waveform in FTDP-17. The revealed neuropathology might thus contribute to the clinicopathological profile of the disease. This sheds new light on the significance of human in vitro models of dementia.
KEY WORDS: Tau pathology, Human cells, Maturation of iPSC-derived neurons, Neuronal excitability, Neuropathological phenotype, Frontotemporal dementia and parkinsonism
Summary: Pathophysiological excitability was revealed for human cells in dementia. This provides a major advance in understanding of tau-induced brain neuropathology and sheds new light on human models of dementia.
INTRODUCTION
A recurrent problem in dementia research is that the generated animal models do not show neuropathological profiles that match pathological changes found in the human brain (Van Dam and De Deyn, 2006; Irwin et al., 2018; Rohrer et al., 2011; Götz and Ittner, 2008). Although the wide use of animal models (∼180 models of Alzheimer's disease are currently available) remains under scrutiny, the latest advances in generating patient-specific nerve cells from induced pluripotent stem cells (iPSCs) have enabled studies in live human cells (Livesey, 2014; Shi et al., 2012b). Because such model systems are ideally suited for exploring the mechanistic basis of cellular pathogenesis in live cells, they could provide an essential tool for exploring the cell and molecular biology of dementia (Iovino et al., 2015; Ortiz-Virumbrales et al., 2017; Sposito et al., 2015).
Various types of dementia share common functional impairments that occur in nerve cells as the disease progresses. This suggests that different dementia forms have a similar cellular basis. As an example, a class of tauopathies that includes, among others, Alzheimer's disease, Pick's disease and inherited frontotemporal dementia and parkinsonism linked to chromosome 17 (FTDP-17) features the abnormal tau protein, which appears to underlie the pathology at the neuronal level. The primary molecular mechanism involves self-aggregation of hyperphosphorylated tau, toxicity of the tau deposits and, eventually, neuronal death in Alzheimer's disease (Goedert et al., 1989; Matsuo et al., 1994) and FTDP-17 (Hutton et al., 1998; Pickering-Brown et al., 2002; Poorkaj et al., 1998). However, exactly how tau pathology affects human nerve cell function leading to cell death remains unknown for the whole class of tauopathies.
We therefore sought to understand the changes, if any, in the neurophysiological properties of human cells in tau-related dementia, in particular, in a human iPSC model of FTDP-17 caused by the 10+16 intronic mutation in the gene coding the microtubule-associated protein tau (MAPT). This experimental model recapitulates the developmental changes in tau-splicing pathology (increased splicing of 4R tau isoforms) as found in the adult human brain (Sposito et al., 2015; Verheyen et al., 2018; Paonessa et al., 2019). Because very little is known about the neurophysiology of human cells with tau pathology at any stage of earlier or overt symptoms, we sought first to establish the timeline of functional neuronal maturation in vitro. Having established the timing of well-developed neurophysiological properties of human iPSC-derived neurons in controls (healthy donor iPSC lines), we next examined the biophysical properties of neurons with the 10+16 MAPT mutation to document the pathophysiological phenotype of intrinsic excitability for human cells in FTDP-17.
RESULTS
Time-dependent maturation of intrinsic excitability of human iPSC-derived cortical neurons
Human iPSC-derived cells were positively stained with neuronal markers for several cortical layers, detectable following 80 days of in vitro neurogenesis in control lines (healthy donors) and those obtained from patients with FTDP-17 caused by the 10+16 intronic mutation in MAPT (Sposito et al., 2015). Consistently, cells displayed a clear neuronal morphology at 100 days of corticogenesis in these cell lines (Fig. 1A). Hence, patch-clamp recordings were performed on iPSC-derived neurons at 100 and 150 days in vitro (DIV) to trace the maturation of their biophysical properties over an extended period of neurogenesis for the anticipated neurophysiological maturation of the differentiated neurons. At this developmental stage, iPSC-derived neurons with the mutation express both 3R and 4R tau isoforms, whereas control cells express only the 3R tau isoform (Sposito et al., 2015).
Intrinsic membrane properties determine key aspects of neuronal function and behaviour. We, therefore, started by comparing the passive membrane properties of the generated cells at different time points in control lines. First, there was a substantial increase (almost twofold) in the membrane capacitance (Cm) between 100 and 150 DIV (from 29.6±2.6 pF, n=17 to 61.0±6.9 pF; n=37, P<0.001; Fig. 1B). Second, we measured the resting membrane potential (Vrest, immediately after membrane breakthrough). At 100 DIV, Vrest was relatively depolarized, as observed in all tested cells (a range from −17 mV to −32 mV, an average of −25.3±1.8 mV, n=10; Fig. 1C). This suggests that the generated neurons at this developmental age remain underdeveloped. Indeed, only a proportion of iPSC-derived neurons at the age of 100 DIV (6 out of 18) enabled generation of a single action potential (AP) in response to current injection (Vrest held at −60 mV to −70 mV; Fig. 1D). We never observed a cell capable of generating a train of induced APs at 100 DIV. The Vrest markedly developed by ∼150 DIV (a range from −43 mV to −70 mV, average −54.7±2.5 mV, n=23; Fig. 1C). Consistent with the ‘maturation’ of Vrest, neurons developed their capability for a high-frequency discharge (Fig. 1D).
Other passive properties of the membrane, such as the input resistance (Rin, indicating membrane conductance, i.e. a pool of readily available functional ion channels) and the time constant (τm, the time for the neuron membrane potential to reach 63% of its resting value) were also markedly improved by ∼150 DIV (see next section).
Next, we assessed the voltage-dependent membrane properties underlying the intrinsic excitability of differentiated cells. Because the hyperpolarization-activated cation current (Ih), a mixed current carried by both K+ and Na+, makes an important contribution to setting of the Vrest (Biel et al., 2009; Ludwig et al., 1998) and hence reflects a maturation level, we measured cell responses to hyperpolarizing current steps. For quantitative comparisons, we calculated the drop in resting potential (Vdrop) and the sag response (ratio of the peak to steady-state) for a hyperpolarizing current pulse of −150 pA (Fig. 2A). The iPSC-derived neurons showed a more prominent Vdrop at 150 DIV than at 100 DIV (120.9±14.0 mV, n=18 versus 46.3±12.6 mV, n=17; P<0.001; Fig. 2B). In line with this, neurons at the age of 150 DIV exhibited a larger voltage sag, which was followed in some cells by a rebound spike on termination of the hyperpolarization step (Fig. 2A); cells at 100 DIV had a minor sag response or none (0.31±0.05 versus 0.10±0.04, P<0.01; Fig. 2B). Because hyperpolarization-activated and cyclic nucleotide-gated (HCN) channels largely mediate Ih (Bennett et al., 2000; Biel et al., 2009), the increased Ih (threefold increase in the sag ratio) indicates increased HCN channel density by ∼150 DIV (i.e. improved neuronal maturation).
To assess the functional expression of fast-activating Na+ channels underlying cell firing activity, we next examined the AP upstroke in the generated neurons (Fig. 2C). In line with a cell's capability of generating a train of induced APs at 150 DIV (as compared with a generated single AP spike by iPSC-derived neurons at 100 DIV; Fig. 1D and Fig. 2C, left traces), the AP spike was of a larger amplitude at 150 DIV (Fig. 2C, right). Importantly, the AP threshold had further developed, as revealed by analysis of the first AP in a train induced by a slow-injecting ramp current (−20.9±6.4 mV at 100 DIV versus −42.9±2.0 mV at 150 DIV; n=9, P<0.05; Fig. 2D). The threshold thus became comparable to that of primary brain neurons (Kopach et al., 2018b; Kopach et al., 2018a). The slow after-hyperpolarization (sAHP) mediated by K+ channels, which largely contribute to AP repolarization and spike shaping (Wilson and Goldberg, 2006), was also developed. The sAHP measured at the end of a square depolarizing pulse train (Fig. 2C) markedly increased by ∼150 DIV, with a clear difference between ∼100 and ∼150 DIV detectable for all depolarizing currents tested, including relatively small currents (0-450 pA; Fig. 2E). This reflects a time-dependent increase in the K+ channel density, especially Ca2+-activated K+ channel subtypes, as an ionic basis of the sAHP component in pyramidal neurons (Andrade et al., 2012; King et al., 2015).
Together, the results show that human iPSC-derived cortical neurons require ∼150 DIV to mature intrinsic excitability up to a common neurophysiological level.
Human iPSC-derived neurons with the MAPT mutation display normal development but changed intrinsic excitability
Having established the time of maturation of neurophysiological excitability for control human cells (non-demented group) as ∼150 DIV, we next investigated the intrinsic excitability of cells with the 10+16 intronic mutation in MAPT (FTDP-17 group).
First, we assessed iPSC-derived neurons with the mutation for their morphological development at ∼100 DIV, an earlier stage of corticogenesis. For analysis of neuronal morphology, cells were immunostained for β-tubulin III and GFAP, together with nuclear staining, and two parameters of the area and the diameter of neuronal somata were quantified in both control and FTDP-17 lines (Fig. 3A). We analysed a total of 367 neurons derived from the two control lines and 431 neurons derived from iPSC lines obtained from two FTDP-17 patients with the 10+16 MAPT mutation (at least six independent preparations per group tested). Quantitative analysis of the neuronal somata area revealed a similar distribution in the density (number of cells) of pooled control and FTDP-17 groups (Fig. 3B). Similarly, the soma diameter did not differ between the groups (median, ∼8.8 µm in control and ∼8.3 µm in FTDP-17; P=0.359 Mood's median test; Fig. 3C). These results demonstrate that human cells with the mutation develop neuronal morphology to a similar extent as control cells at the age of ∼100 DIV.
Second, we made patch-clamp recordings from iPSC-derived neurons with the mutation. In full agreement with morphological assessment, electrophysiological studies showed no significant difference in the Cm of iPSC-derived neurons in FTDP-17 compared with age-matched controls at 100 DIV, but a trend to increase in FTDP-17 (29.6±2.6 pF, n=17 in control versus 44.6±9.6 pF, n=7 in FTDP-17; P=0.175; Fig. 4A). Neither was a difference observed over an extended period of neurogenesis (at 150 DIV), regardless of comparison between pooled groups (61.0±6.9 pF, n=37 in control versus 60.3±5.1 pF, n=66 in FTDP-17; P=0.935; Fig. 4A, left) or between individual cases (median, ∼43.3 pF, n=37 in control neurons versus ∼45.6 pF, n=31 in neurons from patient 1, P=0.667 versus ∼52.73, n=34 in neurons from patient 2, P=0.797, Mann–Whitney test; Fig. 4A, right).
Third, one of the other passive properties of membranes, τm, was not different in neurons from FTDP-17 lines and age-matched controls at any time point tested. The τm was 5.6±1.0 ms (n=17) in control versus 13.9±4.5 ms (n=7, P=0.120) in FTDP-17 at 100 DIV and 43.4±5.5 ms (n=37) versus 46.2±3.7 ms (n=66, P=0.665) at 150 DIV (Fig. 4B). This suggests ‘normal’ development of iPSC-derived neurons with the 10+16 mutation in MAPT (i.e. similar to that in age-matched controls) over the examined period of neurogenesis.
However, neurons with the mutation exhibited changed membrane excitability by ∼150 DIV. In comparison with the control group, neurons with the mutation had an increased Rin (690.2±90.9 MΩ, n=37 in control versus 1000.6±112.7 MΩ, n=66 in FTDP-17; P<0.05; Fig. 4C), although no difference was found at the age of 100 DIV (196.5±33.4 MΩ, n=17 in control versus 270.7±42.3 MΩ, n=7 in FTDP-17; P=0.190; Fig. 4C). Furthermore, neurons with the mutation displayed a depolarized Vrest at 150 DIV compared with the age-matched control (Fig. 4D), which was significant for each individual case (median value, −53 mV, n=23 in control versus −39.0 mV, n=22 in patient 1, P<0.001 and versus −41.5 mV, n=24 in patient 2, P<0.001; Mann–Whitney test; Fig. 4D). Again, such a depolarized Vrest could not be a result of slower Vrest maturation in neurons with the mutation because at 100 DIV the Vrest developed by these cells was even more hyperpolarized than for control cells (−25.3±1.8 mV, n=10 in control versus −45.9±7.0 mV, n=5 in FTDP-17; P<0.05; Fig. 4D, left).
To assess whether such an increase in membrane excitability of human cells in FTDP-17 could be a result of impairments in the voltage-dependent conductance mediated by HCN channels, we recorded the Ih. Surprisingly, there was no significant difference in the Ih between control and FTDP-17 neurons at 150 DIV (Vdrop, n=17 in control and n=32 in FTDP-17, P=0.190; sag ratio, n=16 and 32, respectively, P=0.798, Mann–Whitney test; Fig. 5A), nor at 100 DIV (Vdrop, n=17 in control and n=6 in FTDP-17, P=0.403; sag ratio, n=17 in control and n=6 in FTDP-17, P=0.806; Fig. 5A). Western blot analysis further confirmed a similar level of HCN1 protein expression at ∼150 DIV in control neurons and neurons with the MAPT mutation (Fig. 5B). This suggests that other voltage-gated conductance, instead of HCN channels, is involved in the increased membrane excitability of neurons with the MAPT mutation by the age of ∼150 DIV.
Functional downregulation of voltage-gated Na+ and K+ channels in human cells with tau pathology: implication of the neuronal Nav1.6 channel in FTDP-17
We next looked at whether the voltage-gated membrane conductance mediated by Na+ and K+ channels could be affected in human cells by the mutation in MAPT. To assess this, we recorded Na+ (INa) and K+ (IK) currents in differentiated neurons at 150 DIV at different membrane potentials and plotted the current–voltage (I–V) relationships for both channels to compare control and FTDP-17 cells. Most recorded cells displayed robust voltage-activated INa and IK (Fig. 6A). The I–V relationship showed that INa activation occurs at a range of membrane potentials more positive than approximately −50 mV, with no bias in the I–V curve shape, but a clear reduction in the INa density in neurons with the mutation (n=12 in control and n=36 in FTDP-17; Fig. 6B). The peak INa density was dramatically decreased in cells with the mutation (median, ∼7.39 pA/pF in control versus ∼1.9 pA/pF in FTDP-17; P<0.05 Mann–Whitney test; Fig. 6B). Also, there was a decrease in the density of IK (consisting of fast and slow non-inactivating components) in FTDP-17; this reduction appeared at membrane potentials more positive than −30 mV (n=7 in control and n=30 in FTDP-17; Fig. 6C). The results indicate the functional downregulation of Na+ and K+ channels in FTDP-17.
To evaluate the mechanism for tau-related functional downregulation of Na+ channels, we examined the protein expression in iPSC-derived neurons in control and FTDP-17 cell lines at 130-165 DIV. Western blot experiments demonstrated reduced expression of the Nav1.6 channel in neurons with the mutation (n=6 samples in control and n=8 in FTDP-17, 4 independent experiments performed; P<0.05, Mann–Whitney test; Fig. 6D). This indicates loss of neuronal Nav1.6 channel as a mechanism contributing to changed intrinsic excitability of human cells in FTDP-17.
Because voltage-gated Na+ and K+ channels are largely responsible for neuronal firing, functional downregulation of these channels would lead to impaired cell function (i.e. changes in firing activity). Therefore, we examined changes in AP discharge at 150 DIV by neurons with the mutation, using two different experimental protocols for eliciting firing: injecting a slow ramp current (200 pA/s; Fig. 7A) or injecting a series of short, square depolarizing pulses (Fig. 7C). First, we found that neurons with the mutation exhibited a depolarized AP threshold (measured for the first AP spike in a train elicited by a ramp protocol) compared with that in age-matched control neurons (−42.4±2.3 mV, n=4 in control versus −31.1±2.6 mV, n=9 in FTDP-17; P<0.05; Fig. 7A). Thus, there was a shift in the threshold of ∼11 mV (depolarizing shift). Second, there was a reduction in amplitude of the induced AP spike (from 46.9±2.9 mV, n=14 in control to 35.5±2.5 mV, n=36 in FTDP-17; P<0.05; Fig. 7B). Third, neurons with the mutation exhibited an increased rheobase, which is the magnitude of depolarizing current required to shift membrane potential to the spike threshold to drive firing (Fig. 7C). A twofold stronger current was needed to bring neurons with tau pathology to firing compared with control neurons (48.2±8.2 pA, n=11 in control versus 96.1±11.5 pA, n=41 in FTDP; P<0.05; Fig. 7C). The latter indicates that neurons with tau pathology need a stimulus almost twice as strong to drive firing. In addition, neurons with the mutation exhibited decreased sAHP, as observed at different depolarizing current pulses (50-250 pA; Fig. 7D), consistent with a reduced K+ channel density in these neurons. Overall, these changes characterize the phenotypic spectrum of pathological neuronal excitability of human cells in FTDP-17.
DISCUSSION
Development of human stem cell models that employ patient-specific cell types was a milestone in dementia research. However, physiological studies of iPSC-derived neurons are challenging and sparse. Here, we show that human iPSC-derived cortical neurons require ∼150 days of neurogenesis to match the physiological traits of mature cortical neurons. For the first time, we reveal the phenotypic pathophysiological intrinsic excitability of human cells in frontotemporal dementia and parkinsonism related to tau protein pathology.
Maturation of neurophysiological properties of human cells in vitro
Despite the fact that dementia is a disorder that gradually progresses over a considerably prolonged time, at present, there is no precise treatment to cease or modify the disease. The major challenge in developing therapies has been the lack of a clear understanding of the mechanistic basis underlying the neuropathology. Because animal models appear to not fully replicate neuronal loss as it occurs in the human brain, being associated with a clear clinicopathological profile of memory loss and cognitive decline (somewhat debatable for animal species), human stem cell models have been used for modelling genetic forms of Alzheimer and non-Alzheimer types of dementia for the direct study of patient-specific cells. This study demonstrates the electrophysiological expertise of human iPSC-derived cortical neurons to establish, in the first instance, neuronal maturation of human cells in control and FTDP-17 with tau pathology.
Determining the time when iPSC-derived neurons mature and set neurophysiological activity has always been a challenge that most studies overcome via routine use of various antigens and markers. Although immunocyto(histo)chemistry can document firm expression of receptors and proteins in generated nerve cells, it cannot prove the cell function, with regard to a constitutive level of neurophysiological activity (Kopach, 2019). From the neurophysiological point of view, the biophysical properties of human iPSC-derived cortical neurons at 150 days of neurogenesis in control (non-demented) cell lines confirm that these cells are physiologically credible. The matured intrinsic excitability of generated neurons was confirmed cumulatively by their Vrest and AP threshold – both comparable to that of primary brain neurons (Kopach et al., 2018b) – and a cell capability of high-frequency firing by the age of ∼150 DIV. In comparison with control neurons, neurons with the mutation in MAPT (demented group) did not appear to have underdeveloped biophysical properties at the age of 100 DIV, nor at 150 DIV. For instance, the Ih (reflecting the functional HCN channel expression responsible for recovery from hyperpolarization) was comparable to that in control neurons, consistently with a similar level of HCN1 protein expression (Fig. 5). Likewise, some of the passive membrane properties, such as the capacitance and the time constant were also similar between the groups (Fig. 4). Quantification of neuronal morphology (the somata size) further confirmed similar neuronal development between groups, using an approach other than electrophysiology (Fig. 3).
Overall, varied tests (quantitative comparison of morphological and electrophysiological parameters) indicate that human iPSC-derived neurons mature intrinsic excitability to a constitutive neurophysiological level by ∼150 days of corticogenesis, in both control and FTDP-17 cell lines.
Pathophysiological neuronal excitability of human cells in FTDP-17
The established biophysical properties of the generated neurons suggest that the model is reliable for use in functional studies of genetic forms of tauopathy. In this stem cell model, the developmental changes in tau splicing pathology have been already confirmed (Paonessa et al., 2019; Sposito et al., 2015; Iovino et al., 2015), detecting both 3R and 4R adult brain tau isoforms after a few months of in vitro corticogenesis in FTDP-17 but only 3R in control (non-demented) cell lines. This study documents the tau-related neuropathological phenotype of human cell function through detecting the pathophysiological intrinsic excitability of neurons with the mutation at the development stage between ∼100 and 150 DIV. The phenotype can be described by (i) a depolarized Vrest, (ii) an increased Rin, (iii) a downregulated Na+- and K+-channel-mediated conductance, leading to (iv) functional impairments in firing activity and (v) the changed waveform of APs in FTDP-17. At this earlier stage of the pathology, cells exhibited a depolarized AP threshold (depolarizing shift in ∼11 mV), generated APs of a smaller amplitude and altered shape, and displayed a reduced capability of induced firing (a stimulus nearly twice as strong was needed to drive firing).
Numerous experimental studies have shown the tau-related neuronal dysfunction using animal models, at either earlier or advanced stages of the pathology. Results include (but are not limited to) reduced firing of neocortical neurons in a transgenic model of tauopathy in vivo (Menkes-Caspi et al., 2015), frontotemporal dementia and amyotrophic lateral sclerosis (Radzicki et al., 2016), Alzheimer models (Busche et al., 2019) and parkinsonism (Fieblinger et al., 2014) that opposes neuronal hyperexcitability in aged animals (Crimins et al., 2012). The emerged discrepancy could relate to severe morphological impairment (regression of the brain structure) at later stages, namely loss of synapses and cell death (Crimins et al., 2011). Given the important physiological role of tau in neuronal excitability (DeVos et al., 2013) and synaptic plasticity (Kimura et al., 2014), careful interpolation of obtained phenotypes in transgenic models is needed, because tau overexpression would rapidly shift neurons to hyperexcitability.
The revealed phenotype of pathological neuronal excitability of human cells in FTDP-17 has emerged, at least partially, due to the loss of function of voltage-gated Na+ channels, in particular the neuronal Nav1.6 channel as one of the predominant candidates. The role of the Nav1.6 channel in AP initiation and propagation in cortical excitatory pyramidal neurons (Hu et al., 2009) implies impaired AP parameters and firing discharge by neurons with the MAPT mutation. Dysfunction of Nav1.6-mediated currents is associated with altered learning and memory, being linked to a number of neurological and psychiatric brain disorders, such as epilepsy, intellectual disability and sudden unexpected death in epilepsy (Estacion et al., 2014; Lopez-Santiago et al., 2017; Wagnon et al., 2017). Thus far, we have only revealed a reduced Nav1.6 channel expression in FTDP-17, although other voltage-gated channels could also be involved in this neuropathology. For example, our data indicate that K+ channels are very likely to contribute to the phenotypic pattern of human cell excitability in FTDP-17. Because the slow component of AHP, lasting hundreds of milliseconds to seconds, is Ca2+ dependent (Azouz et al., 1996; Power et al., 2002), the reduced sAHP in FTDP-17 suggests functional downregulation of Ca2+-dependent K+ channels (Andrade et al., 2012; King et al., 2015), which mediate AP repolarization (Azouz et al., 1996; King et al., 2015) and are essential for the generation of rhythmic bursts (Wilson and Goldberg, 2006). Taking into account that slowly inactivating, voltage-gated K+ conductance could be mediated by several channel types, not limited to the Kv1, Kv2, Kv3 and Kv7 subfamilies, numerous candidates could be considered as potential contributors to the pathophysiological excitability of human cells with the MAPT mutation. The most promising candidates apparently refer to the Kv1 subfamily (containing Kv1.1, Kv1.2 and Kv1.6), whose expression contributes to changes in rheobase, AP threshold and the spike waveform (Wykes et al., 2012; Brew et al., 2003).
The tau-induced impairments in intrinsic neuronal excitability can be accompanied by changes in synaptic excitability. The abnormal synaptic function was observed in transgenic animal models before tau aggregates appeared (Van der Jeugd et al., 2012) and prior to neurodegeneration (Menkes-Caspi et al., 2015). Whether this phenotype of intrinsic neuronal excitability of human cells in FTDP-17 is associated with altered synaptic excitation (transmission) remains to be determined. Further studies are needed to decipher in detail the tau-related changes in human cell function at the neuronal network level.
This study provides evidence for the time-dependent maturation of the neurophysiological properties of human iPSC-derived cortical neurons during in vitro neurogenesis, an essential factor for reliable model use in studies of tau-related dementia in vitro. The pathophysiological phenotype of intrinsic neuronal excitability of human cells with the 10+16 splice-site mutation in MAPT has been revealed at 150 DIV, providing a major advance in our understanding of human brain cell dysfunctions at earlier stages of tau-induced dementia. These findings shed new light on human stem cell models of dementia.
MATERIALS AND METHODS
Human stem cell model of FTDP-17
This study included four human cell lines: two control iPSC lines (non-demented group) and two obtained from patients bearing the 10+16 MAPT mutation (FTDP-17 group). Human iPSC lines were as reported previously in detail (Esteras et al., 2017; Sposito et al., 2015). In particular, two 10+16 MAPT iPSC lines were generated by retroviral-transduction reprogramming of fibroblasts obtained from the National Hospital for Neurology and Neurosurgery (London, UK). One control iPSC line, also generated using retroviral transduction from fibroblasts, was obtained from the laboratory of Dr Kunath (Edinburgh University, UK). Another control was purchased from ThermoFisher Scientific. Human iPSC-derived neurons were generated and characterized as previously described (Shi et al., 2012a; Sposito et al., 2015; Esteras et al., 2017). Briefly, differentiation of the pluripotent stem cells into cortical neurons was performed via dual SMAD inhibition for 10 days followed by in vitro neurogenesis. At 46 days after induction, cells were plated on polyornithine/laminin-coated glass coverslips and maintained until use in neural maintenance medium composed of a mixture of N2 and B27 media, as described elsewhere (Shi et al., 2012a), with changes of medium twice a week.
For each group, at least six different preparations were examined. Patch-clamp experiments were performed by the experimenter in a blind to experimental group manner.
Immunocytochemistry
Immunocytochemistry was performed using a common immunostaining protocol by fixing neuronal cultures with 4% paraformaldehyde (15 min at room temperature), followed by permeabilization/blocking with 0.2% Triton X-100 and 10% bovine albumin serum (BSA) for 1 h. Cells were then incubated with Alexa-Fluor-conjugated primary antibodies (anti-β-tubulin III and anti-GFAP, 1:200; Abcam, UK) overnight at 4°C. Hoechst 33342 (10 μM) was used to stain nuclei. Confocal imaging was carried out using a Zeiss 710 VIS CLMS confocal microscope.
Western blot analysis
Cells were washed with PBS and lysed in an ice-cold RIPA lysis buffer supplemented with protease and phosphatase inhibitors (ThermoFisher, Paisley, UK). Samples were snap frozen, sonicated and centrifuged at 14,000 rpm; the protein content was determined using the Pierce BCA protein assay (ThermoFisher). Protein (20 μg) was fractionated on SDS polyacrylamide gel (4-12%) (ThermoFisher), transferred to a PVDF membrane (Bio-Rad, Richmond, CA) and blocked with 5% non-fat milk. Membranes were incubated overnight with primary antibodies (HCN1 and Nav1.6, 1:500, Alomone Labs, Jerusalem, Israel; β-actin, 1:5000, Cell Signaling Technologies, Danvers, MA) diluted in 5% BSA and then with horseradish peroxidase (HRP)-conjugated secondary antibodies. The luminol-based Pierce ECL Western Blotting Substrate (ThermoFisher) was used to detect HRP activity. Protein band densities were quantified using ImageJ software (NIH, Bethesda, MD) after scanning of the X-ray films, and normalized to the control.
Whole-cell electrophysiology
Whole-cell recordings were made from iPSC-derived neurons (Fig. 1A) using a Multipatch 700B amplifier controlled by pClamp 10.2 software package (Molecular Devices, San Jose, CA). For the recordings, a neuronal culture was placed in a recording chamber mounted on the stage of Olympus BX51WI upright microscope (Olympus, Japan) equipped with a LUMPlanFI/IR 40×0.8 objective coupled to an infrared DIC imaging system. Recordings were performed in a bicarbonate-buffered solution containing 126 mM NaCl, 3 mM KCl, 2 mM MgSO4, 2 mM CaCl2, 26 mM NaHCO3, 1.25 mM NaH2PO4 and 10 mM D-glucose (95% O2 and 5% CO2; pH 7.4; osmolarity 300–310 mOsmol) at 31–33°C. Recording electrodes had a resistance of 2.5-5 MΩ when filled with a potassium gluconate-based intracellular solution containing 126 mM potassium gluconate, 10 mM HEPES, 4 mM KCl, 4 mM MgCl2, 2 mM BAPTA, 4 mM Mg-ATP and 0.4 mM GTP-Na, adjusted to pH 7.2 with KOH (osmolarity ∼290 mOsmol). Once in the whole-cell, iPSC-derived neurons were recorded for passive membrane properties, including the resting membrane potential (Vrest), which was detected immediately after membrane breakthrough, membrane capacitance (Cm), input resistance (Rin) and the membrane time constant (τm), measured from the hyperpolarizing square current pulse steps in current mode. The constant, measured as a function of two membrane properties, Rm and Cm, was calculated using the equation τm=Rm×Cm.
Experimental protocols and data analysis
For the assessment of intrinsic excitability, iPSC-derived neurons were tested in the first instance for their capability to generate induced AP. Neuronal firing was elicited using either of two experimental protocols. The first consisted of a series of sub- and supra-threshold rectangular current pulses of 500 ms duration applied with stepwise increased stimulus intensity (an increment of 30–150 pA). The second protocol was a slow-ramp current injection, ramped up with a slope of 100–200 pA/s. For the recordings, Vrest was set at −60 mV to −70 mV by injecting a hyperpolarizing bias current, if needed. Analysis of the parameters of individual AP spikes was performed for the first AP only, in any experimental protocol applied. For the I–V relationship for Na+- and K+-channel-mediated conductance, voltage-clamp recordings consisted of voltage steps of 250 ms duration applied from −100 mV with an increment of 5-10 mV (Kopach et al., 2018a). The voltage drop (Vdrop) during hyperpolarization was measured as the difference between the peak for a hyperpolarizing current (Vmin) and Vrest (Fig. 2A). The hyperpolarization-activated cationic current (Ih) was calculated as the sag ratio by measuring the ratio between the Vmin and its steady-state (Vst) in cell responses to −150 pA or −100 pA pulse injection as (Vmin–Vst)/Vst. Quantitative comparisons of the slow after-hyperpolarization (sAHP) were performed at the end of a spike train in response to a square depolarizing pulse of 500 ms duration (Fig. 2B). Clampfit 10.3 software (Molecular Devices) and Origin Pro (OriginLab, Northampton, MA) were used for analysis.
Statistical analysis
Data are presented as mean±s.e.m., with n referring to the number of cells analysed. The data sets not normally distributed are presented as median values. The Shapiro–Wilk test was used for testing whether experimental data sets were distributed normally. For determining the statistical differences between experimental groups, one-way analysis of variance (ANOVA) with Bonferroni or Tukey multiple comparisons post-hoc test was used as appropriate. The nonparametric Mann–Whitney test or Moods median test was used to compare the medians from two or more populations. P<0.05 was considered as a statistically significant difference between the groups for either test used.
Supplementary Material
Footnotes
Competing interests
The authors declare no competing or financial interests.
Author contributions
Conceptualization: O.K., A.Y.A.; Methodology: O.K., N.E., S.W.; Validation: O.K., N.E.; Formal analysis: O.K., N.E.; Investigation: O.K., N.E.; Resources: D.A.R., A.Y.A.; Data curation: D.A.R., A.Y.A.; Writing - original draft: O.K.; Writing - review & editing: O.K., N.E., D.A.R., A.Y.A.; Visualization: O.K., N.E.; Supervision: D.A.R., A.Y.A.; Project administration: A.Y.A.; Funding acquisition: D.A.R., A.Y.A.
Funding
This work was supported by an Engineering and Physical Sciences Research Council grant (EP/R024898/1) to A.Y.A. and a Wellcome Trust Principal Fellowship (212251_Z_18_Z) and European Commission NEUROTWIN grant (857562) to D.A.R. Deposited in PMC for release after 6 months.
Peer review history
The peer review history is available online at https://jcs.biologists.org/lookup/doi/10.1242/jcs.241687.reviewer-comments.pdf
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