Several studies have demonstrated the different characteristics of tau seeding and spreading following intracerebral inoculation in murine models of tau-enriched fractions of brain homogenates from AD and other tauopathies. The present study is centered on the importance of host tau in tau seeding and the molecular changes associated with the transformation of host tau into abnormal tau. The brains of three adult murine genotypes expressing different forms of tau—WT (murine 4Rtau), hTau (homozygous transgenic mice knock-out for murine tau protein and heterozygous expressing human forms of 3Rtau and 4Rtau proteins), and mtWT (homozygous transgenic mice knock-out for murine tau protein)—were analyzed following unilateral hippocampal inoculation of sarkosyl-insoluble tau fractions from the same AD and control cases. The present study reveals that (a) host tau is mandatory for tau seeding and spreading following tau inoculation from sarkosyl-insoluble fractions obtained from AD brains; (b) tau seeding does not occur following intracerebral inoculation of sarkosyl-insoluble fractions from controls; (c) tau seeding and spreading are characterized by variable genotype-dependent tau phosphorylation and tau nitration, MAP2 phosphorylation, and variable activation of kinases that co-localize with abnormal tau deposits; (d) transformation of host tau into abnormal tau is an active process associated with the activation of specific kinases; (e) tau seeding is accompanied by modifications in tau splicing, resulting in the expression of new 3Rtau and 4Rtau isoforms, thus indicating that inoculated tau seeds have the capacity to model exon 10 splicing of the host mapt or MAPT with a genotype-dependent pattern; (e) selective regional and cellular vulnerabilities, and different molecular compositions of the deposits, are dependent on the host tau of mice injected with identical AD tau inocula.
Background: Several studies have demonstrated the capacity for seeding and spreading of tau-enriched fractions of brain homogenates from AD and other human and mouse tauopathies following intracerebral inoculation into transgenic mice bearing human tau or mutant human tau and into WT mice. However, little attention has been paid about the importance of host tau in tau seeding. Methods: The brains of four adult murine genotypes expressing different forms of tau—WT (murine 4Rtau), P301S (human 4Rtau expressing the P301S mutation), hTau (homozygous transgenic mice knock-out for murine tau protein and heterozygous expressing human forms of 3Rtau and 4Rtau proteins), and mtWt (homozygous transgenic mice knock-out for murine tau protein)—were analyzed following unilateral hippocampal inoculation of sarkosyl-insoluble tau fractions from the same AD case. Results: No tau deposits were identified in inoculated mtWT mice. Involvement of CA1 neurons was higher and that of oligodendrocytes lower in inoculated hTau when compared with inoculated WT and P301S mice. tau-P Ser422, PHF1, and MAP2-P immunoreactivity was moderate or weak in WT and P301S, but strong in inoculated hTau mice. p38-P and SAPK/JNK-P were observed in recruited phospho-tau deposits in inoculated WT, P301S, and hTau mice. However, CK1-δ, GSK-3β-P Ser9, AKT-P Ser473, PKAα/β-P Tyr197, and CLK1 were identified in neurons with tau deposits only in inoculated hTau. Finally, 3Rtau deposits predominated in inoculated WT and P301S, and 4Rtau deposits in hTau transgenic mice. Conclusions: Our results reveal that a) host tau is mandatory for tau seeding and spreading following tau inoculation; b) tau seeding and spreading is characterized by major genotype-dependent biochemical changes linked to post-translational tau modifications including tau phosphorylation and tau nitration at different sites, c) it is accompanied by genotype-dependent activation of various kinases thus pointing to a complex molecular response in the receptive host cells; d) tau seeding and spreading is accompanied by modifications in tau splicing with variable expression of new 3Rtau and 4Rtau isoforms; e) selective regional and cellular vulnerabilities, and different molecular compositions of the deposits are dependent on the host tau genotypes injected with identical AD tau inoculum.
BackgroundSeveral studies have demonstrated the capacity for seeding and spreading of tau-enriched fractions of brain homogenates from AD and other human and mouse tauopathies following intracerebral inoculation into transgenic mice bearing human tau or mutant human tau and into WT mice. However, little attention has been paid about the importance of host tau in tau seeding. MethodsThe brains of four adult murine genotypes expressing different forms of tau—WT (murine 4Rtau), P301S (human 4Rtau expressing the P301S mutation), hTau (homozygous transgenic mice knock-out for murine tau protein and heterozygous expressing human forms of 3Rtau and 4Rtau proteins), and mtWt (homozygous transgenic mice knock-out for murine tau protein)—were analyzed following unilateral hippocampal inoculation of sarkosyl-insoluble tau fractions from the same AD case. ResultsNo tau deposits were identified in inoculated mtWT mice. Involvement of CA1 neurons was higher and that of oligodendrocytes lower in inoculated hTau when compared with inoculated WT and P301S mice. tau-P Ser422, PHF1, and MAP2-P immunoreactivity was moderate or weak in WT and P301S, but strong i in inoculated hTau mice. p38-P and SAPK/JNK-P were observed in recruited phospho-tau deposits in inoculated WT, P301S, and hTau mice. However, CK1-δ, GSK-3β-P Ser9, AKT-P Ser473, PKAα/β-P Tyr197, and CLK1 were identified in neurons with tau deposits only in inoculated hTau. Finally, 3Rtau deposits predominated in inoculated WT and P301S, and 4Rtau deposits in hTau transgenic mice. ConclusionsOur results reveal that a) host tau is mandatory for tau seeding and spreading following tau inoculation; b) tau seeding and spreading is characterized by major genotype-dependent biochemical changes linked to post-translational tau modifications including tau phosphorylation and tau nitration at different sites, c) it is accompanied by genotype-dependent activation of various kinases thus pointing to a complex molecular response in the receptive host cells; d) tau seeding and spreading is accompanied by modifications in tau splicing with variable expression of new 3Rtau and 4Rtau isoforms; e) selective regional and cellular vulnerabilities, and different molecular compositions of the deposits are dependent on the host tau genotypes injected with identical AD tau inoculum.
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