Abstract
Tissue plasminogen activator (tPA) is an immediate-early gene important for regulating physiological processes like synaptic plasticity and neurovascular coupling. It has also been implicated in several pathological processes including blood-brain barrier (BBB) permeability, seizure progression, and stroke. These varied reports suggest that tPA is a pleiotropic mediator whose actions are highly compartmentalized in space and time. The specific localization of tPA, therefore, can provide useful information about its function. Accordingly, the goal of this study was to provide a detailed characterization of tPA’s regional, cellular, and subcellular localization in the brain. To achieve this, two new transgenic mouse lines were utilized: (1) a PlatβGAL reporter mouse, which houses the β-galactosidase gene in the tPA locus and (2) a tPABAC-Cerulean mouse, which has a cerulean-fluorescent protein fused in-frame to the tPA C-terminus. Using these two transgenic reporters, we show that while tPA is expressed throughout most regions of the adult murine brain, it appears to be preferentially targeted to fiber tracts in the limbic system. In the hippocampus, confocal microscopy revealed tPA-Cerulean (tPA-Cer) puncta localized to giant mossy fiber boutons (MFBs) and astrocytes in stratum lucidum. With amplification of the tPA-Cer signal, somatically localized tPA was also observed in the stratum oriens (SO)/alveus layer of both CA1 and CA3 subfields. Coimmunostaining of tPA-Cer and interneuronal markers indicates that these tPA-positive cell bodies belong to a subclass of somatostatin (SST)/oriens-lacunosum moleculare (O-LM) interneurons. Together, these data imply that tPA’s localization is differentially regulated, suggesting that its neuromodulatory effects may be compartmentalized and specialized to cell type.
Significance Statement
The serine protease tissue plasminogen activator (tPA) has been shown to modulate numerous neurologic processes including synaptic plasticity and neurodegeneration. Many of the functional conclusions drawn about tPA activity, however, have not been affirmed by high-resolution, imaging analysis of tPA localization. To address these shortcomings, we used two new transgenic reporter mice to provide a detailed characterization of tPA expression in the adult murine brain. A comparison of these reporter mice demonstrates a differential expression pattern between the sites of tPA synthesis and its targeted localization in the hippocampus, amygdala, and basal ganglia. Moreover, colocalization and coexpression analysis reveals that tPA is primarily trafficked to presynaptic structures and that it’s predominant somatic and/or axonal localization is cell-type specific.
Introduction
Tissue plasminogen activator (tPA) is a serine protease expressed in vascular endothelial cells with a well-established role in fibrinolysis. Biomechanistic understanding of tPA’s fibrinolytic function led to the development of recombinant tPA (rtPA) as a thrombolytic agent, and the current standard of care for moderate to severe ischemic stroke is thrombolytic therapy with rtPA (Prabhakaran et al., 2015). However, beyond 3–4.5 h following stroke onset, thrombolytic efficacy is diminished, and there is an increased risk of hemorrhagic conversion, limiting the therapeutic window for rtPA administration (Ahmed et al., 2010; Sandercock et al., 2012). The molecular mechanisms responsible for the increased risk of hemorrhage are thought, in part, to occur from exogenously administered rtPA crossing the ischemic, compromised blood-brain barrier (BBB) and acting through endogenous tPA-mediated signaling pathways on the abluminal side of the vasculature in the CNS to induce BBB opening (Su et al., 2008).
In addition to BBB regulation (Fredriksson et al., 2015) parenchymal brain tPA has been reported to be involved in other processes in the CNS, including neurite outgrowth (Krystosek and Seeds, 1981), regeneration (Akassoglou et al., 2000; Zou et al., 2006), synaptic transmission and synaptic plasticity (Wu et al., 2015; Frey et al., 1996; Huang et al., 1996), excitotoxic injury (Tsirka et al., 1995; Nicole et al., 2001; Siao et al., 2003), and neurovascular coupling (Park et al., 2008). One of the earliest studies implicating tPA in a non-fibrinolytic function found the serine protease to be an immediate-early gene that is upregulated in the hippocampus following seizures, kindling, and long-term potentiation (LTP; Qian et al., 1993), suggesting a proteolytic mechanism for activity-dependent structural changes at the synapse. Subsequent in situ hybridization studies showed tPA mRNA expression predominantly in hippocampal pyramidal and granule cell layers, and the granule cell layer of the cerebellum (Sappino et al., 1993).
While gross anatomic localization studies of tPA protein and protease activity have consistently shown tPA in the hilus and stratum lucidum layer of the hippocampus (Sappino et al., 1993; Salles and Strickland, 2002), more detailed cellular localization studies of tPA protein expression have been inconsistent (Fredriksson et al., 2015; Louessard et al., 2016). tPA-immunoreactivity, following colchicine treatment to block axo-dendritic transport, has been reported in glutamatergic cortical neurons and in the pyramidal and granule cell layers of the hippocampus (Louessard et al., 2016). In contrast, Fredriksson et al. (2015) primarily detected tPA-immunoreactivity in endothelial cells and a subset of perivascular interneurons. At the subcellular level, tPA appears to have a polarized distribution, as it has been localized to dense core vesicles in both presynaptic (Silverman et al., 2005; Scalettar et al., 2012) and postsynaptic (Lochner et al., 1998; Shin et al., 2004; Lochner et al., 2006) compartments; although these studies were done in vitro using clonal neuroendocrine cell lines or primary hippocampal neurons.
These disparate findings on localization of tPA have complicated and contributed to the multivariate hypotheses that exist regarding tPA’s function in the CNS. To address some of these discrepancies, we have used two transgenic mouse strategies: (1) a PlatβGAL reporter mouse, which has the β-galactosidase gene knocked-in to the tPA gene, Plat, and (2) a tPABAC-Cerulean (tPABAC-Cer) fusion mouse, which has a cerulean-fluorescent protein fused to tPA. The tPABAC-Cer mice were generated using bacterial artificial chromosome (BAC) technology. Critically, large transgene vectors, like BACs, are more likely than smaller plasmids to produce copy-number dependent transgene expression, and thereby, recapitulate endogenous gene expression patterns (Van Keuren et al., 2009). In parallel analysis of coronal sections from PlatβGAL and tPABAC-Cer mice, our results demonstrate that tPA’s protein localization is uncoupled from its site of synthesis. This differential expression pattern is most prominent in the hippocampus, but it is also pronounced in the amygdala and basal ganglia. Moreover, using high-resolution confocal microscopy, in the hippocampus we found tPA to be localized to giant mossy fiber boutons (MFBs) and astrocytes in stratum lucidum and somatically localized to interneurons in stratum oriens (SO)/alveus. Coexpression analysis indicates that these tPA-positive cell bodies in the hippocampus belong to a subset of somatostatin (SST)/oriens-lacunosum moleculare (O-LM) inhibitory interneurons. These results suggest that tPA is differently trafficked and positioned to have diverse modulatory effects on synaptic efficacy based on cell type and subcellular localization.
Materials and Methods
Transgenic mice
tPABAC-Cerulean transgenic mice
Founder lines (863 and 876) for tPABAC-Cer transgenic mice were generated using BAC technology. To generate tPABAC-Cer transgenic mice, exon 14 of the tPA gene, Plat, on a 162.524 kb BAC acquired from chori.org (RP23-259A10), was replaced with a cerulean fluorescent gene (Rizzo et al., 2004) fused to the C-terminus of exon 14 of the murine tPA gene (NM_008872.2) followed by a bovine growth hormone polyadenylation signal sequence. The tPA-Cerulean (tPA-Cer) fusion gene is under control of the endogenous regulatory elements contained in the Plat locus. BAC DNA integrity was verified by restriction enzyme analysis via pulse field gel electrophoresis and exon sequencing before pronuclear microinjection of supraovulated eggs from (C57BL/6 x SJL)F1/TAC female mice. Transgenic mice were genotyped by PCR using primers that were specific to a remnant of the sub-cloning PGKneo vector and the tPA-Cer fusion gene (FWD 5’–CAT GAA GCA AGG ATC CAT GG–3’, and REV 5’–GGA ACT TCG CGG CCG CAG C–3’); and tPA protein expression was confirmed by analysis of brain homogenates from the founder lines. After PCR analysis of the cerulean fusion gene confirmed stable, germline transmission in F1 pups two founder lines, lines 863 and 876, were propagated; these mice were then backcrossed at least eight generations onto a C57BL/6J genetic background. Transgenic mice displayed normal gross anatomy and a Mendelian inheritance pattern.
PlatβGAL reporter mice
The PlatβGAL mice were acquired from the UC Davis Knockout Mouse Project (KOMP) Repository (Project ID: VG15085) on a C57BL/6NTac background. PlatβGAL mice were then backcrossed onto a C57BL/6J background for at least 10 generations. Per the KOMP Repository, PlatβGAL mice were generated by inserting a LacZ-containing targeting vector between exon 2 and 14 to produce a null allele. The insertion sites of the PlatβGAL mice were sequenced to confirm the appropriate insertion of the LacZ gene in the Plat locus.
All animals were housed in a controlled environment and were provided with food and water ad libitum. All animal experiments were approved by a local committee at the University of Michigan, and the studies were conducted in accordance with the United States Public Health Services Policy on Humane Care and Use of Laboratory Animals.
Protein expression analysis
Sample preparation
Total tPA protein and enzymatic activity were analyzed using whole-brain homogenates from tPABAC-Cer mice. The total and active tPA values from tPABAC-Cer transgene-positive mice were normalized to transgene negative littermate controls for each experimental run. Two independent experiments were conducted for a combined total of six to seven mice per transgenic line. Briefly, brains were harvested into ice-cold extraction buffer [0.4 M HEPES, 0.1 M NaCl (pH 7.4), and 1% Triton X-100], homogenized for 1 min. (2 × 30 s) and centrifuged at 10,000 × g for 10 min. The supernatant was removed to a new, chilled 1.5-ml microcentrifuge tube and centrifuged again at 10,000 × g for 10 min. The supernatant was again removed to a new, chilled 1.5-ml microcentrifuge tube and used for ELISA, Luminex, and SDS-PAGE zymography assays.
ELISA
An ELISA was performed to measure tPA activity from brain tissue extracts. Briefly, avidin-coated microtiter plates (Molecular Innovations, AVI-PLATE) were incubated with a biotin-conjugated PAI-1 capture (1 μg/ml; Molecular Innovations, NTBIOCPAI) for 30 min at room temperature. After which, 100 μl of brain extract samples were loaded onto the plate and incubated for 1 h at room temperature. A rabbit anti-human tPA (3 μg/ml; Molecular Innovations, ASHTPA-GF) was used as the primary antibody and a donkey anti-rabbit HRP (1:5000; Jackson ImmunoResearch, 711-036-152) was used as the secondary. All sample and antibody incubations were followed by three washes of PBS-0.05% Tween 20. After the final wash, 3,3’,5,5’-tetramethylbenzidine (TMB) substrate (Molecular Innovations, TMB) was added to each sample for 3 min at room temperature. H2SO4 (1 N) was then added and the plate read on a spectrophotometer at 450 nm.
Luminex
To measure total murine tPA protein from tPABAC-Cer brain extracts, 50 μg of Rabbit anti-murine tPA (mtPA; Molecular Innovations, ASMTPA-GF-HT) was coupled to Luminex carboxylated beads for mtPA capture. Standards of known concentration of murine tPA (Molecular Innovations, MTPA) and brain extract samples [diluted in 0.4 M HEPES, 0.1 M NaCl (pH7.4), and 1.0% Triton X-100] were loaded onto a 96 well filter plate (Millipore) and incubated with 5000 beads [PBS-1.0% bovine serum albumin (BSA)] for 2 h at room temperature in the dark. The solution from was removed from each well and washed twice with PBS-0.05% Tween 20. The beads were then mixed with continuous shaking in the dark at room temperature for 1 h with 2 μg/ml biotin-labeled rabbit anti-mouse tPA-high titer (Molecular Innovations, ASHTPA-HT), after which 10 μg/ml of Streptavidin, R-Phycoerythrin (ThermoFisher Scientific, S866) was added to each well for 1 h. The solution was removed from each well, and the beads were washed three times with PBS-0.05% Tween 20, and, lastly, sheath fluid was added for 5–10 min. The beads were then read with the Luminex 100 (medium setting; 10-μl sample size; 100 events/bead).
SDS-PAGE zymographies
Gel electrophoresis and zymography were performed as previously described (Huarte et al., 1985). Briefly, 1 μg of protein from homogenized whole-brain tissue extracts from transgene-positive and transgene-negative tPABAC-Cer mice were loaded onto an in-house prepared 10% polyacrylamide gel with plasminogen ([10.0 μg/ml]FINAL) and casein ([1.0 mg/ml]FINAL). Samples were run for 30 min at 100 V through the stacking gel and 200 V for 40 min through the running gel. Gel was washed 4 × 30 min in 2.5% Tx-100 (dH2O) and then briefly washed for 5 min in 0.1 M Tris buffer (pH 8.1) before developing in 0.1 M Tris buffer at 37°C for 4 h. Gels were stained with Bio-Safe Coomasie (Bio-Rad, 1610786); bands devoid of stain indicate areas of proteolytic activity.
Immunofluorescence and histochemical analysis
Immunofluorescence analysis
Mice were anesthetized with isoflurane and sacrificed by transcardiac perfusion for 3 min with PBS followed by perfusion for 5 min with 4% paraformaldehyde (PFA). Brains were harvested and postfixed in 4% PFA for 1 h at 4°C, then overnight in PBS. The brains were then moved to a 30% sucrose solution and kept at 4°C till submerged. Subsequently, dorsal hippocampal sections (14 and 50 μm) and serial sections (14 μm, bregma +1.0 to bregma -8.0) were cut coronally for immunofluorescence analysis of tPA expression. When using the Rabbit anti-mtPA antibody, sections underwent antigen retrieval (DAKO, S1700); the additional antigen retrieval step was not necessary for other antibodies. Sections were permeabilized with 0.50% Triton X-100 (PBS) for 20 min at room temperature and blocked in 3% BSA (PBS) for 1 h at room temperature. The sections were then incubated with primary antibodies in 2% BSA (PBS) overnight at 4°C, followed by incubation with secondary antibodies in 2% BSA (PBS) for 1 h at room temperature. When using biotin-conjugated primary antibodies and their respective streptavidin-conjugated secondary was used, a biotin-blocking kit was used to reduce background (ThermoFisher Scientific, E21390). For amplification using the Tyramide SuperBoost kit (ThermoFisher Scientific, B40932) detection protocols were followed according to the manufacturer’s instructions.
The primary antibodies used were as follows: calbindin D28K (rabbit anti-calbindin, 1:500; Synaptic Systems, 214002; lot #214002/3), microtubule-associated protein 2 (rabbit anti-MAP2, 1:1000; Millipore, AB5622; lot #2624211), zinc transporter 3 (guinea pig anti-ZnT3, 1:500; Synaptic Systems, 197004; lot #197004/4), excitatory amino acid transporter 2 (rabbit anti-EAAT2, 1:500; Synaptic Systems, 250203; lot #250203/3), GFP (chicken anti-GFP, 1:1000; abcam, ab13970; lot #GR236651-7 and GR236651-14), NeuN (guinea pig anti-NeuN, 1:400; Synaptic Systems 266004; lot #266004/2-14 and 266004/7), GAD65 (guinea pig anti-GAD65, 1:500; Synaptic Systems 198104; lot #198104/7), murine tPA (rabbit anti-mtPA, 12 μg/ml; Molecular Innovations, ASMTPA-GF-HT; lot #804 and 914), metabotropic glutamate receptor type 1a (rabbit anti-mGluR1a, 1:200; Sigma, G9665; lot #SLBL4165V), SST (rat anti-SST, 1:100; Millipore, MAB354; lot #2885355, 3005269), CD31 (rat anti-mCD31, 1:100; BD Biosciences, 550274; lot #21055). The secondary antibodies used were as follows: biotin-conjugated goat anti-chicken IgY H&L (1:100; abcam, ab6876), goat anti-guinea pig IgG (H + L) 568 (1:500; ThermoFisher Scientific, A-11075), donkey anti-rabbit IgG (H + L) 568 (1:500; ThermoFisher Scientific, A-10042), donkey anti-guinea Pig IgG (H + L) 594 (1:500; Jackson ImmunoResearch, 706-585-148), donkey anti-rat IgG (H + L) 594 (1:500; ThermoFisher Scientific, A-21209), donkey anti-rabbit IgG (H + L) 594 (1:500; ThermoFisher Scientific, A-21207), tyramide-conjugated Alexa Fluor 488 (ThermoFisher Scientific, B40953). The sections were mounted using VectaShield anti-fade mounting medium (Vector Laboratories, H-1000).
5-Bromo-4-chloro-3-indolyl-β-D-galactoside analysis
Heterozygous, homozygous, and wild-type PlatβGAL mice (mice, n = 3–5 per genotype) were used to examine the regional somatic expression of tPA. Homozygous PlatβGAL mice, which are null for tPA with two copies of the β-Gal gene, served as control mice for immunohistochemical stains that used an antibody directed against mtPA. PlatβGAL mice were anesthetized with isoflurane and sacrificed by transcardiac perfusion for 3 min with PBS and 1 min with 2% PFA, and postfixed in 2% PFA for 1 h at 4°C. Brains were then cryopreserved and sectioned by microtome. Dorsal hippocampal sections and serial sections (50 μm, bregma +1.0 to bregma -8.0) were stained and analyzed for LacZ reporter gene expression using the β-Galactosidase Reporter Gene Staining kit (Sigma, GALS).
Image acquisition, processing, and analysis
Widefield and confocal microscopy
For PlatβGAL and tPABAC-Cer transgenic mice, low-resolution images were acquired on an inverted Nikon Te2000 widefield microscope equipped with a MicroPublisher 5.0 RTV color camera and a CoolSNAP HQ2 CCD camera or an inverted Ti Nikon widefield microscope with an ANDOR Zyla sCMOS camera. High-resolution fluorescent images of the dorsal hippocampus in tPABAC-Cer transgenic mice were taken using an upright confocal laser scanning microscope (Leica SP5X). The SP5X is equipped with an acousto-optical beam splitter (AOBS) and a tunable white-light laser; accordingly, the following Ex/Em combinations were used: Cerulean (458/468-558) and Alexa Fluor 568 (568/578-720); and Alexa Fluor 488 (488/498-584) and Alexa Fluor 594 (594/604-750). Images were acquired with a 20× multi-immersion objective or a 63× oil objective [Plan-Apo, 1.4 numerical aperture (NA)] at a scanning rate of 200 Hz with 4× line averaging at 2× or 4× optical zoom. Each frame consists of 512 × 512 pixels or 1024 × 1024 pixels. Z-stacks were collected at 0.5- or 1-μm increments, ranging in total thickness from 5.0 to 35 μm, respectively, with the pinhole set to 1 Airy unit.
Image processing and colocalization analysis
Widefield images (4×, 10×, 20×, or 40× objectives) of hippocampal and serial sections from PlatβGAL mice and tPABAC-Cer transgene-positive and transgene-negative mice were stitched using MetaMorph Image Analysis software or Nikon’s NIS-Elements Advanced Research software package, respectively. Further processing was done using the open source image processing package FIJI (Schindelin et al., 2012). Confocal images are presented as either maximum intensity projections, orthongonal slices, or 3D maximum projections using FIJI’s 3D viewer (Schmid et al., 2010).
Subcellular colocalization analysis of tPA-Cer puncta in stratum lucidum was performed using the JACoP (Just Another Colocalization Plugin) analysis software in FIJI (Bolte and Cordelières, 2006). Images were concatenated from 5-μm z-stacks (Δz = 0.5 μm) that were independently acquired two to four times (ZnT3: mice n = 10, lines 863 and 876; EAAT2: mice n = 6–8, lines 863 and 876, respectively; MAP2: mice n = 4, lines 863 and 876). Manders coefficient and Costes randomization control were used to quantify tPA-Cer colocalization (Costes et al., 2004; Bolte and Cordelières, 2006; Dunn et al., 2011). The Manders coefficient was chosen because it is a more sensitive measure of colocalization for partial colocalization events and when there are large differences in fluorescent intensity between fluorophores (Bolte and Cordelières, 2006; Dunn et al., 2011). The Manders coefficient, which does not mathematically take into account average fluorophore intensity values, ranges from 0 to 1, with 0 corresponding to no overlap and 1 to complete overlap. Two coefficients are given: M1 and M2, where M1 is the summed intensities of fluorophore 1 that are coincident with fluorophore 2, divided by the total intensity of fluorophore 1; M2 is calculated the same but for fluorophore 2. Costes randomization control provides a statistical assessment of whether or not observed colocalization events could be expected to occur by chance. It is calculated by comparing the coincidence of colocalization in an original image against the coincidence of colocalization in a randomized imaged of shuffled pixels (200 times). Costes approach is expressed as a percentage; a probability p value of ≥95% suggests that colocalization is significant and not random (Costes et al., 2004).
Cell count of tPA-Cer and SST-positive cell bodies was performed in the dorsal hippocampus of tPABAC-Cer transgenic mice over an approximate 500-μm range from -2.0 to -2.5 bregma. tPA-Cer and SST-positive cells were counted manually using the ROI Manager in FIJI. Cells were deemed positive if their mean pixel intensity was 1 SD above the mean pixel intensity for the image (Liao et al., 2016). Cell count data were gathered from two to four hippocampal sections per mouse (mice, n = 8) for each of tPABAC-Cer transgenic lines and their transgene negative littermate controls. Cell count data were averaged per mouse and statistics were generated using GraphPad Prism, version 7.0. Data are presented as the mean ± 95% confidence interval [CI(0.95)] of tPA-Cer-expressing cells from SO/alveus (CA1 and CA3, respectively) and stratum radiatum (SR)/stratum pyramidale (SP; CA1 and CA3). The percentage mean ± CI(0.95) of tPA-Cer cells that coexpress SST and the percentage mean ± CI(0.95) of SST-positive cells that coexpress tPA-Cer is also given. Immunohistochemical analysis of tPA-Cer cell bodies that coexpress markers of O-LM interneurons was gathered from stainings from four to eight mice per coexpression marker.
Experimental design and statistical analysis
Experimental design, including all critical variables for independent replication, is described in detail in the Materials and Methods for each experiment. Briefly, for all analysis using PlatβGAL and tPABAC-Cer transgenic mice, a mixture of adult male and female mice was used (age, 12–45 weeks). Wild-type PlatβGAL littermates were used as controls for β-Gal stains, while homozygous PlatβGAL littermates were used as controls for immunoreactivity against tPA. When evaluating global protein expression or using antibodies directed against GFP, tPABAC-Cer transgene negative littermates were used as controls. Brightness and contrast were adjusted over the entire image and applied equally to control images from transgene negative samples for figure display. All image processing and statistical analysis of colocalization was preformed using the JACoP software in FIJI and described in detail in Materials and Methods. Statistical t tests were performed in GraphPad Prism, version 7.0, and a significance criterion of p < 0.05 was adopted. All other graphs and statistics [including mean, SEM, and CI(0.95)] were also generated using GraphPad Prism.
Results
Global and regional expression pattern of tPA in the adult murine brain
PlatβGAL reporter mice were used to characterize the global expression pattern of tPA in the adult murine brain. Serial coronal sections (50 μm) from heterozygous PlatβGAL mice were stained for β-Gal to assess regional patterning of somatic tPA expression. Prominent staining is present in layers 2-6 of the cortex (Fig. 1A–F), with an especially strong β-Gal signal highlighting the compact granule cell layer of the dentate gyrus and the pyramidal cell layer of the dorsal hippocampal CA3 subfield (Fig. 1D). Although less concentrated, the pyramidal cell layer of the CA1 and CA2 subfields in the dorsal hippocampus also demonstrates tPA/β-Gal expression (Fig. 2A). In addition, β-Gal staining is apparent in blood vessels throughout the adult murine brain, as illustrated in the hippocampal formation (Fig. 2A, filled arrows). More diffuse reporter gene expression is present in subcortical regions, like the medial (Fig. 1B) and lateral (Fig. 1C) septal nuclei, the bed nucleus of the stria terminalis (Fig. 1C), the thalamus and hypothalamus (Fig. 1D,E), caudate/putamen (Fig. 1D), and the basolateral and centromedial nuclei of the amygdala (Fig. 1D), while intense β-Gal staining populates the molecular and granular layers of the cerebellum (Fig. 1G,H). There is also noticeable β-Gal staining in the midbrain, pons, and medulla (Fig. 1E–H); specifically, there is a cluster of reporter gene expression in the interpeduncular nucleus (Fig. 1F). The interpeduncular nucleus is an integral group of cells involved in limbic midbrain circuitry and has been implicated in active avoidance behavior (Hammer and Klingberg, 1990). Interestingly, multiple groups have demonstrated a role for tPA in avoidance behavioral tasks (Huang et al., 1996; Calabresi et al., 2000; Pawlak et al., 2002), although interpeduncular tPA has never been explicitly examined. Also, in the pontine central gray (Fig. 1G), there is a small area devoid of β-Gal staining that appears to correspond to the locus coeruleus, which is known for its high concentration of neuroserpin, the neuronal inhibitor of tPA (Krueger et al., 1997). The regional patterning of tPA in the PlatβGAL mice is largely consistent with previous reports examining tPA expression using [P32]-labeled tPA cRNA probes (Sappino et al., 1993) and transgenic mice with tPA promoter-directed expression of β-Gal (Carroll et al., 1994; Yu et al., 2001). However, some differences were observed, such as strong tPA expression in the CA3 subfield and blood vessels (Fig. 2A), suggesting that the earlier studies lacked either the resolution or specific regulatory elements important for regional and cell specific expression.
Differential expression pattern between where tPA is synthesized and where it is trafficked in the dorsal hippocampus
Immunohistochemical analysis of heterozygous PlatβGAL mice, which have one functional copy of the tPA gene and one copy of the LacZ gene, reveals tPA to have a differential expression pattern. Using an antibody directed against tPA, there is a distinct uncoupling between the sites of tPA synthesis and sites of tPA trafficking. This is most apparent in the dorsal hippocampus where the granule cell layer of the dentate gyrus is brightly positive for β-Gal, but devoid of tPA-immunoreactivity (Fig. 2A,B,B’). Conversely, the mossy fiber axonal tracts of the granule cells that project into the hilus (Fig. 2B’) and traverse along stratum lucidum (Fig. 2B’’) are strongly immunoreactive against anti-tPA antibodies. Although strongly expressing β-Gal, no tPA-immunoreactivity is detectable in the granule cell layer or CA3 pyramidal layer (Fig. 2B–B’’).
Given the disparate expression profiles of where tPA is synthesized and where it is trafficked, a more targeted strategy for visualizing tPA is needed. To achieve this, BAC technology was used to generate transgenic fusion reporter mice that have a fluorescent cerulean protein tagged to the C-terminus of tPA (Fig. 3A). Compared to a reporter gene approach, the tPA-Cer fusion reporter approach facilitates a more precise analysis of the regional, cellular, and subcellular expression pattern of tPA in the adult murine brain. And, it can lead to greater functional insights about the dynamic nature of tPA in the brain, including cellular packaging and transport, cellular communication, and regional connectivity.
Global tPA protein expression profile in tPABAC-Cerulean transgenic mice
Before a detailed characterization of tPA localization in tPABAC-Cer mice, global tPA protein expression levels were measured. Brains from transgene-positive and transgene-negative adult tPABAC-Cer mice (mice, n = 6–7) were harvested and homogenized for total and active protein levels using a bead-based Luminex assay (Fig. 3B) and ELISA (Fig. 3C). tPABAC-Cer mice were found to have an approximate 5–6 fold change in total tPA levels from transgene negative mice (Fig. 3B), and an approximate 6 fold change in active tPA levels from transgene negative mice (Fig. 3C). No statistical difference in total or active tPA was noted between the two transgenic lines. To more specifically discriminate between endogenous tPA protein and that which is from the BAC, whole-brain homogenates from transgenic tPABAC-Cer mice (lines 863 and 876) and their respective transgene negative littermate controls were run on a zymography gel (Fig. 3D). Transgene-positive tPABAC-Cer mice showed enzymatic activity from both endogenous tPA (∼60 kDa) and the tPA-Cer protein (∼75 kDa). Samples from transgene negative mice did not display the higher molecular weight band that is indicative of tPA protein with the added cerulean fluorescent protein.
tPA-Cer fusion protein is prominently expressed in limbic structures and blood vessels in the adult murine brain
In a global survey of tPA-Cer fluorescence in tPABAC-Cer transgenic mice, tPA-Cer puncta appear to be primarily restricted to two pools: nerve fibers (Fig. 4A–G,I–M) and vascular endothelial cells (Fig. 4N). No observable cerulean fluorescence was detected in transgene negative littermate controls (Fig. 5A–F,H). In the brain parenchyma, faint tPA-Cer cell bodies are noticeable in the piriform and entorhinal cortex (Fig. 4A–E), while more predominant and intense tPA-Cer fluorescence is seen in nerve fibers in hippocampal and subcortical regions of the brain. Juxtaposed to the somatic neuronal marker NeuN, tPA-Cer fluorescence is clearly not localized to the cell body; rather, it appears to be expressed in nerve fibers emanating or innervating brain structures associated with the limbic system, including the medial and lateral septal nuclei (Fig. 4B), the bed nucleus of the stria terminalis (Fig. 4C,I), the paraventricular nucleus of the thalamus (Fig. 4C), hypothalamus (Fig. 4C,D), the mossy fiber pathway of the hippocampus (Figs. 4D–F, 5G ), the centromedial nucleus of the amygdala (Fig. 4D,J), the external globus pallidus (GPe) and internal globus pallidus (GPi) nuclei of the basal ganglia (Fig. 4D,M), the substantia nigra pars reticulata (SNr; Fig. 4E), the periaqueductal gray (Fig. 4F,K), and the parabrachical nucleus (Fig. 4G,L).
In situ zymography previously demonstrated tPA activity in the mossy fiber pathway and hypothalamus (Sappino et al., 1993), the bed nucleus stria terminalis (Matys et al., 2004), and the centromedial, but not basolateral, nucleus of the amygdala (Pawlak et al., 2003). To our knowledge, however, we are the first to report on tPA expression in the paraventricular nucleus of the thalamus, the periaqueductal gray, and the parabrachial nucleus. These regions, in addition to the bed nucleus stria terminalis and the hypothalamus, are connected via afferent and/or efferent projections to the centromedial amygdalar nucleus (Janak and Tye, 2015; Penzo et al., 2015; Tasan et al., 2016; Babaev et al., 2018). Neurons in the basolateral nucleus also send projections to the centromedial nucleus. And, while β-Gal expression was detected in both the basolateral and centromedial nuclei, given the complex circuitry of the amygdala, it is unclear if the tPA-Cer fluorescence in the centromedial nucleus is trafficked tPA from basolateral nerve projections or trafficked tPA in afferent/efferent nerve fibers to/from other brain regions.
We also report, for the first time, on tPA expression in the GPe and GPi nuclei of the basal ganglia. Indeed, the differential expression of somatic tPA/β-Gal and trafficked tPA-Cer is appreciable when comparing tPA expression in the PlatβGAL (Fig. 1D) and tPABAC-Cer (Fig. 4D) transgenic mice. While β-Gal staining is present in the caudate/putamen nucleus, it is devoid in both the GPe and GPi nuclei in the PlatβGAL reporter mice (Fig. 1D). In contrast, tPA-Cer fluorescence is absent in the caudate/putamen, but present in the GPe, GPi, and SNr (Fig. 4D,E). The GPi and SNr are equivalent anatomic structures, both embryologically and functionally (Purves et al., 2001), as they are the output nuclei of the basal ganglia. Given that tPA-Cer, but not β-Gal, is present in the GPe, it is likely that the observed tPA-Cer is part of the direct loop through the basal ganglia. The circuitry of the direct loop involves GABAergic neurons that project from caudate/putamen through the GPe to the GPi or GABAergic neurons from caudate/putamen that travel through the strionigral fibers to SNr (Purves et al., 2001; Gilman and Newman, 2002). In turn, both the GPi and SNr send GABAergic projections to the thalamus. The direct loop is known to increase thalamocortical excitation, and it is important for the selection of desired behaviors (Purves et al., 2001; Gilman and Newman, 2002). Together, the high expression of tPA-Cer fluorescence in cell bodies and nerve fibers in limbic structures, especially amygdalar-associated brain regions, strongly support a role for tPA in affective, motivational, and anxiety-like behavior (Pawlak et al., 2002, 2003; Matys et al., 2004). And, while tPA has yet to be studied in the basal ganglia, more recent evidence has suggested that, functionally, the basal ganglia are more than an “organ of habit” in the brain, as it plays a role in perception, cognition, and emotional behaviors (Jahanshahi et al., 2015).
tPA-Cer puncta are localized to large MFBs in the stratum lucidum CA3 subregion of the hippocampus
Our previous results established that tPA-Cer fluorescence is highly enriched in the mossy fiber pathway (Figs. 4D, 5G ). These findings are consistent with immunohistochemical analysis and in situ zymography which also report high levels of tPA localization and proteolytic activity in the mossy fiber pathway (Sappino et al., 1993; Salles and Strickland, 2002; Louessard et al., 2016). As mossy fiber axons are known to have morphologically and functionally distinct presynaptic terminals we leveraged the use of the tPABAC-Cer mice, combined with high-resolution confocal imaging, to establish tPA’s subcellular distribution in the hippocampus. Confocal z-stacks were captured of both tPA-Cer and putative colocalization markers. Dorsal hippocampal sections from tPABAC-Cer mice were first probed for zinc transporter-3 (ZnT3), which is the protein correlate underlying the Timm’s histochemical stain to visualize the mossy fiber pathway (Frotscher et al., 1994). ZnT3 was used based on previous electron microscopy immunocytochemistry of ZnT3 in the murine brain which revealed the exclusive localization of ZnT3 to large MFBs (Wenzel et al., 1997). An analysis of orthogonal YZ and XZ sections from a 5-μm z-stack (Δz = 0.5 μm) suggests that tPA-Cer puncta colocalize with ZnT3 (Fig. 6A). Further, 3D projection confirms that tPA-Cer puncta reside in ZnT3-positive MFBs (Fig. 6A’ ). As shown in Figure 6D,E, quantification of colocalization between tPA and ZnT3 from 5-μm concatenated image stacks (mice, n = 10), shows that tPA-Cer has a high degree of overlap with ZnT3 (M1 coefficient: 0.704 and 0.649 for lines 863 and 876, respectively; Costes probability p value ≥ 95%). There was no observable detection of cerulean fluorescence in transgene negative littermate controls (Fig. 5H). Conversely, ZnT3 shows only partial overlap with tPA-Cer (M2 coefficient: 0.426 and 0.352 for lines 863 and 876, respectively). The lack of a one-to-one relationship between the M1 and M2 coefficients is possibly due to the zinc transporter being a synaptic, not dense core, vesicle marker. Although dense core vesicles are sporadically found in MFBs (Wenzel et al., 1997; Rollenhagen et al., 2007), synaptic vesicles are much more abundant. ZnT3 staining, therefore, likely illuminates a larger area of the MFB, while the tPA-Cer signal, presumably in dense core vesicles, appears more punctate (Silverman et al., 2005; Lochner et al., 2008; Scalettar, et al., 2012). Lastly, these data indicate that while the vast majority of tPA is localized to giant MFBs there is also a population that occupies another locale.
As astrocytes are known to wrap fine processes around MFBs (Rollenhagen and Lubke, 2010) and as tPA has been shown to be taken-up by astrocytes (Cassé et al., 2012), tPABAC-Cer hippocampal sections were stained for the astrocytic glutamate transporter EAAT2 (excitatory amino acid transporter 2). While a strong visual colocalization was difficult to ascertain from orthogonal YZ and XZ slices (Fig. 6B) and 3D projections (Fig. 6B’), image quantification (Fig. 6D,E) did demonstrate lower levels of colocalization (M1 coefficient: 0.183 and 0.198 for lines 863 and 876, respectively; Costes probability p value ≥ 95%). To further validate our results, tPABAC-Cer sections were stained for the dendritic marker MAP2 (microtubule associated protein 2) as a negative control. In stratum lucidum, MAP2 detects the dendritic thorny excrescences of CA3 pyramidal neurons which are the postsynaptic partner to the MFBs. As predicated, orthogonal YZ and XZ slices of tPA-Cer and MAP2 showed no visual overlap (Fig. 6C) and a 3D projection (Fig. 6C’) showed that tPA-Cer puncta encapsulate the MAP2-positive dendritic thorny excrescences. Moreover, when quantified (Fig. 6D,E), no colocalization was found (M1 coefficient: 0.032 and 0.060 for lines 863 and 876, respectively; Costes probability p value = 0%).
tPA is expressed in a subset of SST-positive inhibitory interneurons in SO/alveus of CA1 and CA3 hippocampal subfields
The presence of sporadic β-Gal puncta in SO, SR, and the hilus (Fig. 2A) of the hippocampus in PlatβGAL reporter mice suggested that other cell types, in addition to the granule and pyramidal cells, express tPA. In an effort to visualize and identify these cells in the tPABAC-Cer transgenic mice, the cerulean signal was magnified using a GFP antibody in conjunction with tyramide signal amplification. With amplification, tPA-Cer-positive cell bodies were revealed in the CA1 and CA3 hippocampal subfields of transgene positive mice (Fig. 7A,E). CA3 pyramidal cells became visible, but more strikingly were the sparsely-populated tPA-Cer-expressing cell somas in SO, SP, and SR, although most were strongly localized to the SO/alveus lamina of the CA1 and CA3 subfields (Table 1). To quantify strata localization of tPA-Cer cell bodies, two to four hippocampal sections per mouse (mice, n = 8) for each of the transgenic lines were analyzed. Our results show that for a hippocampal section there were, on average, 11.68 ± 1.53 (n = 301 cells) and 10.90 ± 2.06 (n = 238 cells) tPA-Cer cells bodies in the CA1 SO/alveus region and 5.58 ± 1.14 (n = 141 cells) and 5.34 ± 1.98 (n = 115 cells) tPA-Cer cell bodies in the CA3 SO/alveus region for lines 863 and 876, respectively. Less frequently, on average, 3.32 ± 1.15 (n = 78 cells) and 2.28 ± 1.06 (n = 52 cells) tPA-Cer cells bodies were found in SR and SP for lines 863 and 876, respectively. No statistical difference was noted between lines 863 and 876.
The sporadic nature of tPA-Cer-positive cell bodies is consistent with that of GABAergic interneurons (Oliva et al., 2000). To test if tPA-Cer-positive cells are indeed GABAergic interneurons, various immuno-markers for SO/alveus-interneurons were used to neurochemically identify the subpopulation of tPA-Cer-positive cells in the hippocampus (Somogyi and Klausberger, 2005). tPA-Cer-positive cells were found to strongly coexpress the interneuronal marker SST in the SO/alveus lamina of hippocampal regions CA1 and CA3 (Table 1; Fig. 7). Widefield images of the hippocampus show prominent tPA expression in stratum luciudum (Fig. 7E), but also in SST-positive interneurons scattered throughout SO/alveus (Fig. 7A). Immunostaining for SST and GFP with tyramide signal amplification in transgene negative controls only revealed SST-positive interneurons (Fig. 7I,J). Confocal images from CA1 (Fig. 7B–D) and CA3 (Fig. 7F–H) show tPA-Cer cells (green) that clearly overlap with SST-positive (magenta) interneurons. When quantified, for a given hippocampal section, on average ∼54.35 ± 6.32% (n = 520 cells) and 58.90 ± 6.74% (n = 405 cells) of tPA-Cer cells were found to coexpress SST, while 53.89 ± 8.82% (n = 520 cells) and 44.66 ± 9.45% (n = 540 cells) of SST-positive cells were found to coexpress tPA-Cer, for lines 863 and 876, respectively. No statistical difference was noted between lines 863 and 876.
Since O-LM interneurons, whose cell bodies reside in SO and send axonal projections to stratum lacunosum-moleculare, are known to express SST (Fig. 8A), other neurochemical markers of O-LM interneurons were probed for to see whether tPA-Cer cells can be immunocytochemically classified as O-LM interneurons. tPA-Cer cells were found to coexpress the calcium-binding protein calbindin (Fig. 8C), which has previously been reported to comprise roughly 32% of SST/O-LM interneurons (Oliva et al., 2000); they were also found to coexpress the metabotropic glutamate receptor 1 (mGlur1a; Fig. 8B), which is highly expressed in SST/O-LM interneurons (Klausberger, et al., 2003; Somogyi and Klausberger, 2005; Sylwestrak and Ghosh, 2012). Interestingly, tPA mRNA polyadenylation and translation has previously been shown to be dependent on mGluR1 activation (Shin et al., 2004). To confirm the inhibitory nature of these cells, immunohistochemistry against GAD65 (glutamic acid decarboxylase 65) in tPABAC-Cer mice was performed (Fig. 8D). In agreement with the localization and cytochemical profile of SST/O-LM interneurons, tPA-Cer puncta were observed in structures reminiscent of axonal processes in SR (Fig. 8E). These data strongly suggest that at least a portion of tPA-Cer cells can be categorized as O-LM interneurons.
Discussion
In the present study, we have confirmed and extended our understanding of the expression of tPA in the adult murine brain. Using both a PlatβGAL reporter mouse and a BAC transgenic mouse expressing a tPA-Cer fusion protein, we have provided a detailed characterization of the regional, cellular, and sub-cellular localization of tPA. While largely complimenting the expression pattern observed in transgenic mice that harbored a 9.5-kb segment of the human tPA promoter to drive expression of LacZ (Yu et al., 2001), PlatβGAL reporter mice displayed differences that provide insight into the transcriptional regulation of tPA. In contrast to the PlatβGal reporter mice, in the human 9.5-kb tPALacZ reporter mouse, β-Gal staining was only weakly observed in the CA3 subfield, and there was no detection of β-Gal in blood vessels, a well-established site of tPA expression (Fredriksson et al., 2015; Louessard et al., 2016). In addition, Yu et al. (2001) observed high tPA/LacZ expression in the medial habenula, which was not the case for the PlatβGAL reporter mice. These discrepancies suggest that regulatory elements important for the regional and cellular expression patterning of tPA are not encompassed in the 9.5-kb human promoter segment or that there are differences between the human and murine promoter sequences that do not completely recapitulate species specific expression of tPA.
When comparing the PlatβGAL reporter mice and the tPABAC-Cer transgenic mice, there is a clear uncoupling between where tPA is synthesized and where it is trafficked, which is in agreement with previous in situ expression studies examining tPA mRNA and tPA-catalyzed proteolysis (Sappino et al., 1993). And, while the laminar, tri-synaptic circuitry of the hippocampus illustrates this uncoupling most distinctly, tPA’s differential expression pattern is also apparent in the amygdala and the basal ganglia. In addition, there is a stark dichotomy between β-Gal expression and tPA-Cer fluorescence in the cortex and cerebellum. Although β-Gal is abundant throughout the cortex and cerebellum in PlatβGAL reporter mice, other than faintly positive cell bodies in the piriform and entorhinal cortex, there is no detectable tPA-Cer fluorescence in the cortex and cerebellum of tPABAC-Cer transgenic mice. Tracing experiments of cortical and cerebellar projections, which are beyond the scope of this article, would help address this discrepancy. For, if tPA is primarily trafficked as our data suggests, then it is possible that tPA-Cer is localized along cortical descending pathways or in efferent targets in the cerebellum, the basal ganglia, the brainstem, and spinal cord. Similarly, more detailed tracing studies would be required to assess if tPA-Cer is localized to cerebellar efferents, like the vestibulocerebellum, spinocerebellum, and cerebrocerebellum pathways, and their target nuclei. Given that tPA’s site of action is removed from its site of synthesis, the tPABAC-Cer transgenic mice, when analyzed in conjunction with the PlatβGAL reporter mice, provide a more informative expression profile of tPA in the adult murine brain.
Taking advantage of the tPA-Cer fusion construct, therefore, we report for the first time tPA’s subcellular localization to giant MFBs in stratum lucidum of CA3. Previous studies have only generally described tPA expression in the mossy fiber pathway, without examining its specific compartmentalization. The specific structural localization can potentially provide meaningful insight into tPA’s function. This is especially true since mossy fiber axons of DGCs display two other morphologically distinct presynaptic terminals, small en passant boutons and filipodial extensions that emanate from the MFBs (Acsády et al., 1998; Rollenhagen and Lübke, 2010). Moreover, these structurally distinct terminals have divergent postsynaptic targets; MFBs synapse with hilar mossy cells and the apical dendritic spines or “thorny excrescences” of CA3 pyramidal cells, while en passant boutons and filipodial extensions preferentially target GABAergic interneurons in the hilus and stratum lucidum (Frotscher et al., 1994; Acsády et al., 1998). The mossy fiber-to-CA3 pyramidal cell synapse also has a different synaptic physiology; compared to the mossy fiber-to-interneuron synapse, the mossy fiber-to-CA3 pyramidal cell synapses shows marked paired-pulse facilitation and LTP (Salin et al., 1996; Henze et al., 2000; Toth et al., 2000; Nicoll and Schmitz, 2005).
Thus, the specific localization of tPA-Cer puncta to giant MFBs suggests that it may have a role in regulating synaptic efficacy at the mossy fiber-to-CA3 pyramidal cell synapse. Consistent with this model, functional studies demonstrate tPA-/- mice to have deficits in LTP in the mossy fiber pathway (Huang et al., 1996). Further interrogations into the mechanism underlying deficits in LTP have focused on a postsynaptic locus of expression. Mice deficient in tPA, which carries a cAMP response element in its promoter, exhibit reduced potentiation by cAMP analogs (Huang et al., 1996); blocking tPA’s non-proteolytic interaction with the postsynaptically expressed low-density lipoprotein receptor-related protein (LRP) causes deficits in synaptic potentiation (Bu et al., 1992; Zhuo et al., 2000); and tPA-mediated cleavage of proBDNF was found to be essential for the full expression of LTP (Korte et al., 1995, 1998; Pang et al., 2004). These mechanistic studies, however, presumed postsynaptic tPA expression and were performed in the hippocampal CA1 region, not at the mossy fiber-to-CA3 pyramidal cell synapse, where we have shown tPA to be most highly expressed in the giant MFBs. Additionally, while amplification of the tPA-Cer signal was able to reveal tPA expression in the soma of CA3 pyramidal cells, high-resolution colocalization analysis did not uncover tPA in the postsynaptic thorny excrescences of CA3 pyramidal cells. In fact, no colocalization was observed between tPA-Cer puncta and the dendritic marker MAP2. Although in vitro studies have shown activity-dependent release of tPA from both pre- and postsynaptic compartments (Gualandris et al., 1996; Lochner et al., 1998, 2006; Scalettar et al., 2012), our in situ expression data demonstrates that tPA’s localization is largely presynaptic and suggests that potential presynaptic neuromodulatory effects at the mossy fiber-to-CA3 synapse may have been overlooked.
Interestingly, tPA-Cer puncta were also observed to partially colocalize with astrocytes. It is unclear, however, if the tPA present is endogenous to astrocytes, as transcriptome analysis has shown astrocytes to express tPA mRNA in vitro (Zhang et al., 2014), or if tPA is endocytosed by astrocytes in an LRP-dependent fashion (Cassé et al., 2012). The mossy fiber-to-CA3 pyramidal cell synapse appears unique with respect to its trisynaptic cytoarchitecture. Previous studies indicate that astrocytes completely insulate the synapse, cordoning off the active zone and synaptic cleft from the surrounding parenchyma, but not physically encroaching into the cleft (Rollenhagen et al., 2007). And, while there is no in vivo functional evidence demonstrating the effects of tPA release from astrocytes on synaptic function, in vitro evidence has pointed to tPA acting as a gliotransmitter that is released and recycled by astrocytes (Cassé et al., 2012). The lack of perisynaptic astrocytic processes making contact with axon-spine interfaces (Rollenhagen et al., 2007), however, possibly indicates that, at least at the mossy fiber-to-CA3 pyramidal cell synapse, diffusion-limited gliotransmitter tPA may have reduced effects on synaptic function. Moreover, if tPA is released in an activity-dependent manner (Gualandris et al., 1996; Parmer et al., 1997) from giant MFBs, the configuration of the mossy fiber-to-CA3 pyramidal cell synapse suggests that it is not geared toward immediate clearance and uptake, but rather, toward potentiating the effects of tPA and presumably enhancing synaptic efficacy.
In this study, we also identify tPA expression in a subset of SST-positive interneurons in the hippocampal SO/alveus lamina. We provide a detailed distribution of tPA-Cer-positive cell bodies in both the CA1 and CA3 subfields and their quantified coexpression with SST-positive interneurons. While enhancement of the tPA-Cer protein, with anti-GFP tyramide amplification, was necessary to distinctly visualize these cell bodies, we believe this somatic expression of tPA is physiologic as (1) no signal was observed in littermate transgene negative controls, (2) the recapitulation of tPA expression in the mossy fiber pathway indicates that tPA-Cer is appropriately targeted to its cellular and subcellular locale, and (3) β-GAL puncta in the PlatβGAL reporter mice are noticeable in SO/alveus and SR (Fig. 2). Presumably, the increase in tPA expression, due to extra copy number from the BAC transgene, allowed for the detection of a previously unrecognized and specific population of tPA-expressing cells. It is unclear, however, why tPA is differentially localized to the soma or axonal projection and if such differential trafficking is functionally significant. For, tPA appears to be largely localized to the soma of inhibitory interneurons (Fredriksson et al., 2015) and to the axons of excitatory neurons (Louessard et al., 2015). While knowledge about dense core vesicle trafficking is still nascent compared to synaptic vesicle trafficking, there is evidence which demonstrates regionally-specific, differential trafficking of the neuropeptide NPY to dendrites and axons (Ramamoorthy et al., 2011) and that excitatory and inhibitory neurons in the hippocampus exhibit different dense core vesicle molecular machinery (Ramírez-Franco et al., 2016).
In the CA1 hippocampal region alone, more than a dozen different types of interneurons have been classified based on their morphologic, neurochemical and physiologic properties (Freund and Buzsáki, 1996; Somogyi and Klausberger, 2005). And, while no one single marker is indicative of a specific type of interneuron, tPA-Cer-positive cells appear to share a very similar somatic distribution (Oliva et al., 2000) and immunocytochemical profile with O-LM interneurons (Somogyi and Klausberger, 2005; Minneci et al., 2007; Sylwestrak and Ghosh, 2012). As tPA-expressing neurons have never been described in SST/O-LM interneurons before, it is unclear how tPA may be exerting its effects. Morphologically, the axonal projections of O-LM interneurons ramify at the distal apical dendrites of CA1 pyramidal cells, where perforant path fibers from the entorhinal cortex terminate. Functionally, O-LM interneurons are known to fire rhythmically at the trough of theta (4-8 Hz) oscillations in the hippocampus (Klausberger et al., 2003), and they have been shown to facilitate LTP in the Schaffer collateral-to-CA1 pathway. Although deficiency in tPA has been previously implicated in defects in the late-phase of LTP in the hippocampal CA1 region (Huang et al., 1996; Calabresi et al., 2000), the contribution of tPA from O-LM interneurons has not been specifically tested in this paradigm. Plasticity of glutamatergic CA1 synapses onto O-LM interneurons has also been investigated, as changes in synaptic efficacy may have an important role in modulating network excitability (Nicholson and Kullmann, 2014). To date, however, it is unknown if tPA is involved in these events.
Taken together, the regional, cellular, and subcellular characterization of tPA expression presented here provides a primer on tPA’s role in the CNS. Many of the foundational experiments on tPA’s function in the brain were performed before a detailed description of its protein localization, this is especially confounding in the case of tPA as its site of synthesis is uncoupled from it targeted site of action. With the generation of the tPABAC-Cer transgenic mice and its appropriately targeted tPA-Cer fusion protein, however, future mechanistic studies to elucidate tPA’s function are now possible.
Acknowledgments
Acknowledgments: We thank Kris Mann and Mark Warnock for excellent technical assistance and the University of Michigan Transgenic Core for their expertise in the generation of BAC transgenic animals. We also thank Geoffrey Murphy, Edward Stuenkel, Shannon Moore, Kasia Glanowska, and Victor Cazares for their critical reading of this manuscript.
Footnotes
The authors declare no competing financial interests.
This work was supported by National Institutes of Health Grants HL055374 and NS079639 (to D.A.L.) and T32-HL125242 and T32-GM008322 (T.K.S.).
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