Introduction
The accumulation and deposition of hyperphosphorylated tau aggregates in the brain is a hallmark of Alzheimer’s disease (AD) and neurodegenerative tauopathies, including corticobasal degeneration (CBD), progressive supranuclear palsy (PSP), and Pick’s disease (PiD). Tau pathology in AD brain is found sequentially in the trans-entorhinal–entorhinal areas, hippocampus, limbic areas, and finally in the associative and then primary neocortical areas, according to the Braak stages [
4,
5]. It associates strongly with the progression of cognitive impairment [
5], suggesting that regional propagation of tau pathology underlies the progression of AD. Recently, tau tracer retention measured by positron emission tomography (PET) showed similar stages [
36,
51,
52].
The ability of misfolded tau seeds, that is, proteopathic tau, to recruit and template monomeric tau misfolding and propagate across brain regions has been widely studied and demonstrated in vitro and in vivo
. In vitro, cytosolic and hyperphosphorylated tau isolated from AD brain (AD P-tau) sequesters normal tau to form filaments in a non-saturable manner [
1,
2]. Pre-formed aggregates/filaments either generated in vitro or isolated from AD brain accelerate the aggregation of recombinant tau into paired helical filaments [
16,
58]. In cultured cells, tau aggregates are internalized and induce aggregation of intracellular monomeric tau [
17,
27,
38]. In tau transgenic mice, the inoculation of tau aggregates induces tau aggregation and the spread of tau pathology to distant brain regions [
9,
10,
32,
34]. The seeding ability of tau from AD brains correlates positively with Braak stages and negatively with MMSE scores and precedes overt tau pathology [
18]. In tau transgenic mice, tau seeds predict the spread of disease by appearing in brain regions prior to the appearance of any other pathological change [
31]. Assessment of seeding activity of proteopathic tau in human samples may be relevant and may correlate with clinical data. In addition, tau seeding activity assays also provide a tool for drug screening that targets propagation of tau pathology.
Down syndrome (DS), caused by partial or complete trisomy of chromosome 21, is the most common chromosomal disorder and one of the leading causes of intellectual disability (ID). Today, as many as 6 million people worldwide are living with DS [
54]. Individuals with DS develop AD pathology by the age of 40 years [
62]. Imaging studies suggest a similar pattern of pathology between DS-AD and sporadic AD, but beginning at an earlier age in DS-AD. Tau burden assessed by PET in DS is similar to that in AD in binding pattern and progression [
48]. Tau accumulation correlates with progressive neurodegeneration and cognitive decline, as do AD-specific hypometabolism and atrophy [
48]. However, the seeding activity of proteopathic tau in the brain of individuals with DS has not been determined.
The seeding activity of proteopathic tau has been evaluated by seed amplification assay in vitro, cell-based assay, and in vivo seed amplification assay [
40]. Tau in AD and most tauopathies is not mutated [
22,
55]. Most tau seeding activity assays use tau with FTDP-17–associated mutations [
40]. Here, by using truncated tau
151-391, we report two new assays, an in vitro tau capture assay and a seeded-tau aggregation assay in cultured cells, for the assessment of tau seeding activity. We validated these two methods with brain extracts from AD, related tauopathies, and control cases and measured tau seeding activity in various regions of DS brain. The brain extracts from AD and related tauopathies captured tau in vitro and seeded-tau aggregation, but not from control brains or from the diseased brain tissues in which tau was not hyperphosphorylated. In DS brain, higher tau seeding activity in the temporal (TC), frontal (FC), and occipital cortex (OC) was found than in the corresponding regions of control brains. Extract of DS corpus callosum (CC) showed low tau seeding activity, but no detectable tau seeding activity, in DS cerebellar cortex (CBC). Tau seeding activity was positively correlated with the levels of hyperphosphorylated tau which displayed SDS- and β-mercaptoethanol-resistant high molecular weight (HMW) species. Of special note, these two methods can be performed using routine biochemical techniques. They can provide a platform for determining the role of post-translational modifications of tau in the captured tau and in the seeded-tau aggregates and for drug screening.
Materials and methods
Human brain tissue
Frozen tissue samples from the TC, FC, OC, CBC, and CC of DS and normal control brains (Table
1) were obtained from the Brain Bank for Developmental Disabilities and Aging of our institute. Diagnosis of DS trisomy 21 was extracted from subjects' medical records. Selection of control subjects was based on the diagnostic criteria developed at a consensus conference of the National Institute of Aging and the Reagan Institute. Cases with diagnosis of dementia, including AD and Parkinson disease were excluded. Cases with brain tumors, metastases, hemorrhages, multiple small infarcts, and brains with gross traumatic injury were also excluded. Exclusion of cases with Parkinson disease pathology was based on results of immunostaining for α-synuclein in Lewy bodies and neurites. Frozen autopsied tissues from FCs of five AD and five control brains (Table
2) were obtained from the Sun City Health Research Institute Brain Donation Program (Sun City, AZ, USA). The subjects were selected based on the criterion of diagnosis prior to death as being clinical AD. Control cases were cognitively normal, without any significant neuropathological findings that could contribute to cognitive symptoms. Frozen frontal cortical tissues from three CBD, three PiD, and two PSP brains (Table
3) were obtained from the Alzheimer’s Disease Research Center at New York University Grossman School of Medicine. The diagnosis of these cases was confirmed histopathologically by TW (a board-certified neuropathologist), using standard neuropathological criteria [
3,
6,
30,
33,
39,
45,
57]. The use of autopsied frozen human brain tissue was in accordance with the National Institutes of Health guidelines and was exempted by the Institutional Review Board (IRB) of the New York State Institute for Basic Research in Developmental Disabilities because ‘‘the research does not involve intervention or interaction with the individuals’’ nor ‘‘is the information individually identifiable.’’ The brain tissue samples were stored at − 80 °C until used. Brain tissue was homogenized in cold buffer consisting of 20 mM Tris–HCl, pH 8.0, 0.32 M sucrose, 10 mM β-mercaptoethanol (β-ME), 5 mM MgSO
4, 1 mM EDTA, 10 mM glycerophosphate, 1 mM Na
3VO
4, 50 mM NaF, 1 mM 4-(2-aminoethyl) benzenesulfonyl fluoride hydrochloride (AEBSF), and 10 μg/ml each of aprotinin, leupeptin, and pepstatin. After centrifugation of the homogenates at 10,000×
g at 4°C for 10 min, the supernatants were used for analyses of seeding activity and phosphorylation of tau.
Table 1
Human brain tissues of Down syndrome and normal control used in this study
DS | 1342 | 61 | M | 3 | VI | + | | + | + | + |
DS | 1170 | 28 | M | N/A | I | | + | | | + |
DS | 375 | 43 | F | N/A | V | | + | + | + | |
DS | 1151 | 43 | F | N/A | V | + | + | + | + | |
DS | 1335 | 47 | F | N/A | VI | + | | + | + | + |
DS | 1330 | 48 | M | N/A | VI | + | + | + | + | |
DS | 1280 | 54 | M | < 24 | VI | + | + | + | + | + |
DS | 1238 | 55 | M | 6 | VI | + | + | + | + | + |
DS | 1162 | 55 | F | 5 | VI | + | + | | + | + |
DS | 1308 | 57 | F | < 24 | VI | + | + | + | + | |
DS | 1139 | 58 | F | 5 | VI | + | + | + | + | + |
DS | 1283 | 59 | F | 6 | VI | + | + | + | + | + |
DS | 1322 | 59 | M | < 24 | VI | + | + | + | + | |
DS | 367 | 62 | F | 12 | VI | + | + | + | + | + |
DS | 311 | 63 | M | N/A | VI | + | + | + | + | |
DS | 709 | 63 | M | NA | VI | + | + | + | + | + |
DS | 712 | 63 | M | 24 | VI | + | + | + | + | + |
DS | 69 | 65 | M | 4.5 | VI | | | + | + | + |
DS | 1153 | 65 | M | N/A | VI | + | | + | + | |
DS | 482 | 74 | M | 26 | VI | + | + | + | | + |
Con | 1169 | 32 | M | 14 | N/A | + | + | + | | |
Con | 247 | 31 | M | 3 | N/A | + | + | + | + | + |
Con | 254 | 55 | M | 16.5 | N/A | + | + | + | + | + |
Con | 256 | 59 | M | 6 | N/A | + | + | + | + | + |
Con | 248 | 61 | F | 7 | N/A | + | + | + | + | + |
Con | 255 | 67 | F | 4 | N/A | + | + | + | + | + |
Con | 252 | 68 | F | 3 | N/A | + | + | | + | + |
Con | 241 | 68 | F | 2.5 | N/A | | | + | + | |
Con | 596 | 71 | M | 7 | N/A | + | + | + | + | + |
Con | 580 | 78 | M | N/A | N/A | + | | | + | |
Con | 239 | 85 | F | N/A | N/A | + | + | + | + | + |
Con | 244 | 86 | M | 1.5 | N/A | + | + | + | + | + |
Con | 246 | 90 | F | N/A | N/A | + | + | + | + | + |
Table 2
Human brain tissues of Alzheimer’s disease and control cases used in this study
AD | 00–18 | 89 | F | 2.33 | V | 8.66 | 2 | Stroke |
AD | 00–33 | 73 | F | 2 | V | 15 | 11 | Dementia, Failure to thrive |
AD | 00–22 | 60 | M | 3.33 | VI | 15 | 8 | Presenile dementia |
AD | 00–13 | 87 | M | 2.4 | V | 14.5 | 12 | AD |
AD | 00–29 | 60 | F | 3.5 | VI | 15 | 9 | Cardiac and/or respiratory |
Con | 00–34 | 85 | M | 3.16 | II | 4.25 | | Congestive heart failure |
Con | 03–28 | 80 | M | 2.16 | I | 1 | | Unknown |
Con | 03–50 | 91 | M | 3.33 | III | 3.5 | | Congestive heart failure |
Con | 03–63 | 83 | F | 3.25 | II | 0.75 | | Cerebrovascular accident |
Con | 00–49 | 86 | F | 2.5 | III | 5 | | Pulmonary fibrosis |
Table 3
Human brain tissues of corticobasal degeneration, Pick's disease, and progressive supranuclear palsy cases used in this study
CBD | TN10-34 | 81 | F | 3.5 | CBD | Acute hypoxic respiratory failure secondary to pneumonia |
CBD | TN09-27 | 84 | M | 12 | CBD | Cardiac Arrest |
CBD | TN15-09 | 95 | M | 11 | CBD | Complications of inanition secondary to severe cognitive decline |
PiD | TN15-83 | 83 | F | 12 | FTLD-tau, A3, B3, C3, subacute infarctions | Complications of inanition secondary to severe cognitive decline |
PiD | TN12-17 | 83 | M | 12 | FTLD-tau, hippocampal sclerosis,A1, B1, C1 | Complications of inanition secondary to severe cognitive decline |
PiD | TN15-06 | 87 | M | 18 | FTLD-tau, A0, B1, C0 | Complications of inanition secondary to severe cognitive decline |
PSP | TN15-85 | 95 | M | 15 | PSP, A2, B2, C2 | Asphyxia secondary to aspiration episode |
PSP | TW19-31 | 72 | M | 16 | PSP, A3, B3, C3, right frontal lobe remote infarction | Complications of inanition secondary to severe cognitive decline |
Plasmids, antibodies, and other reagents
pCI/HA-tau
1-441, pCI/HA-tau
151-391, pCI/HA-Trans-active response DNA-binding protein-of 43 (TDP-43)
1–414, and pCI/HA-TDP-43
100–414 were constructed as described previously [
25,
26]. The primary antibodies used in the present study are listed in Table
4. Horseradish peroxidase (HRP)-conjugated anti-mouse and anti-rabbit IgGs were obtained from Jackson ImmunoResearch Laboratories (West Grove, PA, USA). Alexa 555- and Alexa 488-conjugated-secondary antibodies were from Thermo Fisher Scientific corporation (Waltham, MA, USA).
Table 4
Primary antibodies used in the present study
43D | Mono- | M | Tau (8–16) | In-house/BioLegend (816,601)[ 42] |
77G7 | Mono- | M | Tau (316–355) | In-house/BioLegend (816,701)[ 42] |
R134d | Poly- | R | Total tau | |
AT8 | Mono- | M | pSer202/Thr205-tau | Thermo Scientific (MN1020) |
Anti-pS199 | Poly- | R | pSer199-tau | Invitrogen (44-734G) |
Anti-pT205 | Poly- | R | pThr205-tau | Invitrogen (44-738G) |
Anti-pT212 | Poly- | R | pThr212-tau | Invitrogen (44-740G) |
Anti-pS214 | Poly- | R | pSer214-tau | Invitrogen (44-742G) |
Anti-pT217 | Poly- | R | pSer217-tau | Invitrogen (44–744) |
AT180 | Mono- | M | pThr231-tau | Invitrogen (MN1040) |
12E8 | Mono- | M | pSer262/Ser356-tau | Dr. D. Schenk |
PHF-1 | Mono- | M | pSer396/Ser404-tau | |
R145d | Poly- | R | pSer422-tau | |
Anti-HA | Mono- | M | HA | Sigma (H9658) |
RD3 | Mono- | M | 3R-tau | Millipore (05–803) |
Anti-GAPDH | Poly- | R | GAPDH | Sigma (G9545) |
Cell culture and transfection
Human embryonic kidney cell line (HEK-293FT) and human cervix epithelia cell line (HeLa) were cultured in Dulbecco’s modified Eagle’s medium (DMEM) (Thermo Fisher Scientific) supplemented with 10% fetal bovine serum (FBS) (Invitrogen), 100 U/ml penicillin, and 100 μg/ml streptomycin (Thermo Fisher Scientific) and incubated in a humidified atmosphere containing 5% CO2 at 37 °C. Cells were seeded to culture plates, and all transfections were performed with FuGENE HD (Promega, Madison, WI, USA) or Lipofectamine™ 2000 (Thermo Fisher Scientific) according to the manufacturer’s instructions. Empty vectors were used as controls for the corresponding transfection.
Preparation of oligomeric tau from AD brain
Oligomeric tau derived from AD brain (AD O-Tau) was isolated from the cerebral cortex of frozen autopsied AD brains, as we described previously [
32,
43]. Briefly, 10% brain homogenate prepared in the buffer (20 mM Tris–HCl, pH 8.0, 0.32 M sucrose, 10 mM β-ME, 5 mM MgSO
4, 1 mM EDTA, 10 mM glycerophosphate, 1 mM Na
3VO
4, 50 mM NaF, 1 mM AEBSF, and 10 μg/ml each of aprotinin, leupeptin, and pepstatin) was centrifuged at 27,000×
g for 30 min. The supernatant was further centrifuged at 235,000×
g for 45 min, and the resulting pellet, i.e., AD O-Tau–enriched fractions, was collected, washed three times, and then resuspended in normal saline. The AD O-Tau was probe-sonicated for 10 min at 20% power and stored at − 80 °C till used.
Western Blot and immuno-dot blot
Western blot: Brain extracts were adjusted to 1 × Laemmli sample buffer, followed by heating in a boiling-water bath for 5 min. Cultured cells were lysed directly in the Laemmli sample buffer containing 1 mM AEBSF and 10 μg/ml each of aprotinin, leupeptin, and pepstatin and then heated as above. Protein concentration was determined using the Pierce™ 660 nm Protein Assay kit (Thermo Fisher Scientific, Waltham, MA, USA). Samples were subjected to SDS-PAGE and transferred onto a polyvinylidene fluoride membrane (MilliporeSigma, Burlington, MA, USA). The membrane was subsequently blocked with 5% fat-free milk in Tris-buffered saline (TBS) for 30 min, incubated with primary antibody (Table
4) diluted in 5% fat-free milk in TBS containing 0.1% NaN
3 overnight at room temperature (RT), washed with TBST (TBS with 0.05% Tween 20) three times, and incubated with HRP–conjugated secondary antibody for 2 h at RT, washed with TBST, incubated with the enhanced chemiluminescence (ECL) substrate (Thermo Fisher Scientific), and exposed to HyBlot CL® autoradiography film (Denville Scientific Inc., Holliston, MA, USA) or detected by iBright Imager (Thermo Fisher Scientific). Alternatively, the membrane incubated with Alexa 488- or Alexa 555- conjugated secondary antibody for 2 h at RT, washed with TBST and detected by iBright Imager (Thermo Fisher Scientific). Specific immunosignal was quantified by using the Multi Gauge software V3.0 from Fuji Film (Minato, Tokyo, Japan).
Immuno-dot blot: Various amounts of samples were applied onto a nitrocellulose (NC) membrane (Schleicher and Schuell, Keene, NH, USA) at 5 μl per grid of 7 × 7 mm size in duplicates or triplicates. The membrane was placed in a 37 °C oven for 1 h to allow the protein to bind to the membrane. The membrane was subsequently blocked and incubated with primary antibody and then with secondary antibody as described above for Western blots.
Tau capture assay for measuring tau seeding activity in vitro
Cell lysate containing hemagglutinin-tau (HA-tau): HEK-293FT cells were transfected with pCI/HA-tau151-391 (in the numbering of the 441–amino acid isoform of human tau) or pCI/HA-tau1-441 for 48 h. To obtain cell lysate containing TDP-43, HEK-293FT cells were transfected with pCI/HA-TDP-431–414 similarly. The cells were washed with cold-phosphate buffered saline (PBS) and probe-sonicated in cold lysate buffer (50 mM Tris–HCl, pH7.4, 0.15 M NaCl, 1 mM EDTA, 1 mM Na3VO4, 50 mM NaF, 1 mM AEBSF and 10 μg/ml each of aprotinin, leupeptin, and pepstatin) for 2 min with 20% amplitude at 4 °C 48 h after transfection. Cell lysate was centrifuged for 5 min at 10,000×g. The level of tau in the cell lysates was analyzed by immuno-dot blots, and lysates were stored at −80 °C until used.
Capture of tau from the cell lysate: Various amounts of AD O-tau or brain extracts were applied onto a NC membrane as described in immuno-dot blot. The membrane was blocked with 5% fat-free milk in TBS for 30 min and incubated with cell lysates containing HA-tau or HA-TDP-43 overnight at RT. After washing, the membrane was developed with anti-HA followed by incubation with HRP-conjugated secondary antibody and ECL as described above for Western blots to detect captured tau.
Seeded-tau aggregation assay for assessing tau seeding activity in cultured cells
HEK-293FT cells cultured in 24-well plate were transfected with pCI/HA-tau151–391, pCI/HA-tau1-441 or pCI/HA-TDP-43100–414 with FuGENE HD. Six hr after transfection, the cells were treated with AD O-tau or brain extracts in 25 μl of Opti-MEM containing 3% Lipofectamine 2000 for 42 h and then lysed in RIPA buffer (50 mM Tris–HCl, pH7.4, 150 mM NaCl, 1% Nonidet P-40, 0.5% sodium deoxycholate, and 0.1% SDS) containing 50 mM NaF, 1 mM Na3VO4, 1 mM AEBSF, 5 mM benzamidine, and 10 μg/ml each of aprotinin, leupeptin, and pepstatin for 20 min on ice. The cell lysates were centrifuged at 75,000×g for 30 min. The supernatant was saved as RIPA buffer–soluble fraction, and the pellet, RIPA buffer–insoluble fraction, was washed with PBS. Levels of RIPA buffer–insoluble and -soluble Tau or TDP-43 were analyzed by Western blots developed with anti-HA.
To visualize tau aggregates in cells, HeLa cells were transfected to express HA-tau1–441 or HA-tau151–391 and treated with AD O-Tau for 42 h as described above. The cells were then fixed for 15 min with 4% paraformaldehyde in phosphate buffer, washed with PBS, and treated with 0.3% Triton X-100 in PBS for 15 min at RT. After blocking with 5% newborn goat serum, 0.1% Triton X-100, and 0.05% Tween 20 in PBS for 30 min, the cells were incubated with anti-HA in blocking solution overnight at 4 °C, washed with PBS, and incubated with Alexa 488–conjugated secondary antibody for 2 h at RT. After washing with PBS, the cells were mounted with ProLongTM Gold antifade reagent (Thermo Fisher Scientific) and observed with a Nikon confocal microscope.
Depletion of tau from AD brain extract
Tau antibodies 77G7 and a mixture of 43D and HT7, and as a control, mouse IgG (mIgG) were incubated with protein G-agarose for 6 h at RT. After washing with TBS, the antibodies-coupled beads were incubated with the same volume of AD brain extract overnight at 4 °C. The supernatant was saved as tau-depleted AD extract for further analysis.
Guanidine hydrochloride and urea treatment
AD O-tau was dotted on a NC membrane. The membrane was treated with 6 N guanidine hydrochloride (GuHCl), 8 M urea, or TBS as control for 2 h, followed by tau capture assay, described above.
Statistical analysis
GraphPad Prism 6 (GraphPad Software Inc., San Diego, CA, United States) was used for statistical analysis. Comparison between two groups was analyzed by unpaired two-tailed Student’s t test (for data with normal distribution) or Mann–Whitney test (for data with non-normal distribution). One-way or two-way analysis of variance (ANOVA) followed by Tukey’s or by Sidak’s multiple comparisons was used in this study. Data was presented as mean ± standard deviation (SD). For correlation analysis, linear or non-linear regression correlation coefficient was calculated. For linear regression, Pearson (for data with normal distribution) or Spearman (for data with non-normal distribution) correlation was performed. p < 0.05 was considered statistically significant.
Discussion
Proteopathic tau recruits monomeric tau and templates its aggregation, underlying the propagation of tau pathology in AD brain from the trans-entorhinal region to the limbic system and eventually to the primary cortical areas. Individuals with DS develop tau pathology in the 4th decade of life [
62]. In the present study, we developed two assays, an in vitro tau capture assay and a seeded-tau aggregation assay in cultured cells. By using these two assays, we analyzed tau seeding activity in various regions of DS brains and found, for the first time, that the TC, FC, and CC of DS brains captured tau and seeded-tau aggregation dramatically, indicating that these three brain regions contain high tau seeding activity, whereas tau seeding activity was very limited or undetectable in the CC and CBC of DS. Tau seeding activity was positively correlated with the levels of phosphorylated tau, which displayed SDS- and β-ME resistant HMW-tau species.
Tau seeding activity in postmortem AD brain is quantitively and qualitatively correlated with disease severity and rate of progression [
12]. The quantification of tau seeds in human specimens may be relevant to the clinical progression of AD and related tauopathies. In general, proteopathic seeds recruit, misfold, and template the aggregation of tau monomers, leading to their use in a wide range of seeding activity assays. So far, tau seeding activity can be quantified by in vitro seed amplification assays, such as Real-Time Quaking-Induced Conversion-based assay, RT-QuIC-based assay [
12,
46], cell-based assays in cultured cells, such as FRET-biosensor assay [
31], and in vivo seed amplification assays [
9,
40]. Tau in AD and most other tauopathies is not mutated [
22]. However, to our knowledge, almost all assays use tau with tauopathy-related mutations for seeding activity measurement. Recently, tau
151-391 was shown to be captured and to be seeded to aggregate the most effectively by AD O-tau [
26]. Here, by using HA-tau
151-391 without tau mutation, we developed two quantitative assays, a capture assay and a seeded aggregation assay, for the detection of tau seeding activity.
The capture assay was developed on the basis of recruitment of monomeric tau by proteopathic tau seeds. Seed-competent tau was applied onto a NC membrane, and the membrane was incubated with HEK-293FT cell lysate containing HA-tau
151-391. The recruited HA-tau
151-391 was developed by anti-HA. Thus, the assay is low cost and practical and can be performed in a regular laboratory setting. We found that AD O-tau captured tau
151-391, but not TDP-43, in a dose-dependent manner. The capture ability of AD O-tau was abolished by GuHCl treatment. AD and PiD brain extracts in which tau was hyperphosphorylated and displayed SDS- and β-ME resistant HMW-tau species could capture HA-tau
151-391 from the cell lysate, whereas control and disease brain extracts in which phosphorylated tau was undetectable could not recruit tau. Thus, capture assay is highly specific for measuring tau seeding activity. The sensitivity of capture assay was 312 ng protein of AD brain extract and ~ 1 ng tau in AD O-tau, which can be enhanced by using the enhanced ECL kit. However, this assay is much less sensitive than the RT-QulC-based assay at 2 fg tau [
46], which relies on the use of heparin to promote the templating of tau substrate. Heparin induces tau aggregation effectively [
20]. It was found that the structure of heparin-induced tau filaments differs from those found in AD or other tauopathies [
66]. In two independent experiments, the yield of seeding activity of AD and control brain extracts was similar, indicating that the capture assay is repeatable.
The seeded-tau aggregation assay belongs to the cell-based seeding activity assay class. In this assay, HEK-293FT cells were transiently transfected to express HA-tau
151-391 and treated with seed-competent tau by using Lipofectamine 2000 for 42 h. Ultracentrifugation of cell lysate at 10,000×
g for 30 min yielded RIPA-insoluble tau, representing aggregated tau, and was analyzed by immunoblots. Similar to the in vitro capture assay, we found AD O-tau induced RIPA-insoluble tau aggregation dose-dependently. AD O-tau could not induce TDP-43 aggregation. AD and PiD brain extracts seeded tau
151-391 aggregation, but not control and disease brain extracts in which phosphorylated tau was undetectable. Thus, this assay is also highly specific for measuring tau seeding activity. Two independent experiments displayed similar tau aggregation induced by the brain extracts, indicating that these assays are reliable and repeatable. The sensitivity of our seeded-tau aggregation assay was 31 ng total protein of AD brain extract, which is less sensitive than ultrasensitive FRET-biosensor assay at 153 pg to 1.2 ng of total protein from AD brain homogenates centrifugated at 21,000×
g for 15 min [
29]. Here, we used brain extracts yielded from 10,000×
g centrifugation for 10 min. Thus, seeded-tau aggregation assay is highly sensitive, specific, and repeatable. FRET-biosensor assay relies on the overexpression of the repeat domain (RD) of tau with the pro-aggregating P301L mutation fused to fluorescent proteins [
31]. The size of the reporter fluorescent protein is two times larger than TauRD, while HA, 8 a.a. tag, is 30 times less than tau
151-391, which is 240 a.a. We speculate that the seeded-tau aggregates may be more disease-relevant. It is known that tau aggregation relies on the microtubule binding repeats, but we do not know whether tau
151-391 is able to fully evaluate some aggregate conformations in which N- and/or C-termini involved in. In addition, the structure of seeded tau
151-391 aggregates remains elusive.
In addition to their specificity, sensitivity, and reproducibility, both the capture assay and the seeded-tau aggregation assay do not require special equipment and can be performed in a regular biomedical laboratory setting. The levels of captured tau were strongly and positively correlated with the levels of aggregated tau induced by the brain extracts from AD and related tauopathies. Even though these two assays are less sensitive for measuring tau seeding activity, they can be used to determine the role of post-translational modifications of tau in the captured tau and in the seeded-tau aggregates [
26,
65]. Moreover, these two assays provide a platform for drug screening by targeting tau propagation.
Alternative splicing of tau exon 10 generates tau isoforms with 3R-tau and 4R-tau [
8]. Its dysregulation causes several types of tauopathies. In AD, chronic traumatic encephalopathy (CTE), and several other tauopathies, all six tau isoforms are present in aggregated tau filaments. The Pick bodies of PiD are made of 3R-tau only. In PSP, CBD, argyrophilic grain disease (AGD), and several other diseases, isoforms with 4R-tau are found in the filaments [
22]. By cryo-electron microscopy, the ultrastructure of tau filaments extracted from diseased brains was identified; it appears that the structures of tau filaments are distinct among diseases but identical in different individuals with AD [
15], CTE [
14], PiD [
13], or CBD [
67]. In vitro study has shown that seeds of 3R-tau and 3R/4R-tau recruit both types of isoforms, while seeds of 4R-tau recruit 4R-tau, but not 3R-tau [
11]. Different RT-QuIC assays could detect specifically 3R-, 4R-, or 3R/4R-tau seeds in brain homogenates from corresponding tauopathies [
46,
50]. It was found that tau aggregate propagation in cultured HEK-293T cells required isoform pairing between the infecting seeds and the recipient substrate. PiD tau aggregates seeded 3RD
VM-YFP aggregation, whereas 4R-tau aggregates from AGD, CBD, and PSP brains induced 4RD
LM-YFP aggregation. Tau aggregates from AD and CTE brains were unable to induce aggregation of either 3RD
VM- or 4RD
LM-expressing cells but were able to seed tau aggregation in HEK-293T cells expressing both 3RD
VM-YFP and 4RD
LM-YFP [
63]. However, an in vivo study demonstrated that tau aggregates from transmission of distinct tau strains are independent of strain isoform composition, but instead intrinsic to unique pathological conformations [
28]. Here, we found that AD brain extracts captured and seeded both 3R-tau
151-391 and 4R-tau
151-391 aggregation similarly. Unexpectedly, we also found that like AD extracts, PiD brain extract captured 3R-tau and 4R-tau and seeded their aggregation. Of note, here we used 10,000 xg extracts, but not detergent-insoluble tau, as the above cited studies used, for measuring seeding activity. The brain extract contains predominantly oligomeric tau, which is small, soluble, and freely diffusible protein assemblies that are not shaped like fibrils but are more globular [
61]. It was reported that brain extracts from AD, CTE, and PiD induced 4RD
LM-YFP aggregation in HEK-293T cells expressing high levels of 4RD
VM-YFP [
63]. Thus, we speculate that oligomeric tau has a more dynamic and loose conformation and may have less strength than filamentous tau to order isoform-matched tau aggregation. In the present study, only one of three PiD cases displayed tau hyperphosphorylation and seeding activity. Whether oligomeric tau strains have less strength in seeding strain isoform–dependent aggregation and whether these two assays can specifically detect 3R- or 4R-tau seeds remains to be investigated by using increased numbers of tauopathy cases.
Individuals with DS develop early-onset AD pathology [
62]. In DS brain, tau is hyperphosphorylated at multiple sites and aggregated to form NFTs [
44,
53]. The neuron-derived small extracellular vesicles from the plasma of patients with DS-AD contain phospho-tau and seed tangle-like tau pathology in mouse brain [
41]. Here we analyzed regional phosphorylation of tau and found that the levels of phosphorylated tau were markedly higher in the TC, FC, and OC, but not in the CC or CBC of DS, compared with the corresponding regions of control brains. Correlating with the presence of hyperphosphorylated tau, extracts from these three cerebral cortical regions, but not from CC and CBC of DS as well as corresponding regions of control brains, captured tau, indicating DS cerebral cortex contains proteopathic tau seeds. The CC consists of axons mainly and contains less tau. However, we found increased tau aggregates seeded by CC extracts from DS than control brains, which is consistent with the findings from previous studies that AD white matter extracts seeded-tau aggregation but less potently than AD gray matter extracts did [
64]. Thus, AD axons also contain proteopathic tau seeds, which may be critical for regional propagation of tau pathology. Different from the cerebral cortex, to date, no tau pathology was observed in CBC. Here, we did not find hyerphosphorylated tau or proteopathic tau seeds in DS CBC, indicating that tau pathology does not propagate in DS CBC. The postmortem interval (PMI) in the DS subjects was longer than that in AD cases used in the present study. Previously we have reported that tau is rapidly dephosphorylated in mouse brain during postmortem delay [
59], but the effect of PMI on tau seeding activity remains elusive.
AD O-tau, the major proteopathic tau seeds in AD brain, is hyperphosphorylated at multiple sites [
43]. Dephosphorylation passivates the seeding activity of AD O-tau in vitro [
65] and in vivo [
32]. Here, we found that tau seeding activity in AD and related-tauopathy brains is associated with hyperphosphorylated and HMW-tau. Although all tauopathies are characterized by tau pathology of hyperphosphorylated and seeding competent tau, we did not detect it in the tissue pieces used from several cases, suggesting that the pathology is not evenly distributed throughout the frontal cortex in tauopathies. However, we could not rule out the capability of these two assays in detecting tau seeding activity in the brain of individuals with PSP/CBD and the majority of PiD, which remains to be confirmed by recruiting more tauopathy cases to the study. In various regions of DS brain, tau seeding activity was positively correlated with the levels of hyperphosphorylated tau. However, GuHCl treatment destroyed the ability of AD O-tau to capture tau but not phosphorylation, suggesting misfolded conformation of tau is crucial for its seeding activity.
Aggregation of proteins to form amyloid relies on the β-sheet [
61]. GuHCl and urea are chaotropic denaturants used in physiochemical studies of protein-folding. At high concentrations of GuHCl or urea, proteins lose their ordered structure, and they tend to become randomly coiled, i.e., they do not contain any residual structure. Here, we found 6 M GuHCl, but not 8 M urea, abolished the seeding activity of AD O-tau. GuHCl is often found to be approximately twice as efficient as urea in denaturing proteins, but this activity varies with the protein targets [
24]. In addition to GuHCl and urea, heat treatment also denatures proteins. Boiling of AD O-tau does not affect phosphorylation or seeding activity of AD O-tau [
42]. Here, we found that treatment with 6 N GuHCl completely inhibited the seeding activity, indicating that secondary structure, e.g., β-sheet, is essential for tau seeding activity, and the denaturing agents selectively kill tau seeding activity.
In summary, here, we report two specific, sensitive, and reproducible assays with low cost for assessing tau seeding activity, which can be used for evaluating the effect of post-translational modifications on templated tau aggregation and drug screening. By using these two assays, we found high tau seeding activity in the TC, FC, and OC; low seeding activity in the CC; and no seeding activity in the CBC of the DS brain. Tau seeding activity is highly correlated with levels of hyperphosphorylated and HMW-tau species. As in AD, propagation of tau in DS brain may underlie the development of dementia in this disease.