Next, simultaneous detection of AT8 and glycogen synthase kinase (GSK) 3β, a prominent enzyme responsible for tau phosphorylation, elucidated numerous cells co-expressing both markers in naïve, as well as in immunolesioned animals as exemplified in Figure 5f,g. However, staining patterns SB431542 datasheet differing obviously between both animal groups were not detectable. To elucidate hippocampal Aβ-associated gliosis, triple fluorescence labelling of Aβ (4G8), astroglial
GFAP and microglial Iba1 was applied. For 16-month-old mice, staining patterns in sections from naive (Figure 6a), sham-injected (Figure 6b) or immunolesioned mice (Figure 6c–f) were qualitatively compared. The animals with cholinergic dysfunction displayed a somewhat stronger Aβ load, enhanced astroglia activation and pronounced microgliosis. In control experiments, BKM120 purchase omission of primary antibodies resulted in the expected absence of any cellular staining. Furthermore, sections from WT mice (of all age groups) immunolabelled for Aβ, APP and phospho-tau were also devoid of staining (data not shown). Additionally, icv immunotoxin injections into 12-month-old WT mice caused the
same cholinergic cell loss as shown in Figure 2c. Immunohistochemical analysis of hippocampal sections from these animals revealed neither Aβ deposits nor hyperphosphorylated tau. Dividing the immunotoxin-treated and control-injected naive forebrains enabled VAV2 the immunohistochemical verification of immunolesioned CPN in the MS/DB complex of immersion-fixed basal forebrain tissue. Thereby, the quality of immunolesioning became detectable in animals whose concomitantly prepared hippocampi
were considered for biochemical analyses. Differences in ChAT expression between 12-month-old WT and 3xTg mice (prior to injection) were not obvious and should hardly influence the results. Biotinylated 4G8 (recognizing Aβ17–24 and an appropriate marker for total Aβ) was previously found to enable sensitive immunofluorescence labelling [34]; it is a derivative from 4G8, one of the most widely used immunoreagents for Aβ analyses, despite its week cross-reactivity with APP at low dilutions [36]. All applied haptenylated monoclonal mouse antibodies circumvented the use of anti-mouse-antibodies to avoid undesired cross-reactions with endogenous immunoglobulins around plaques in the inflamed tissues from triple-transgenic mice. While immunolesioning in the rat basal forebrain is a well established technique [24, 37], the first successful selective deletion of CPN in mice was performed with rat-anti-p75-saporin [38]. However, the manufacturer Advanced Targeting Systems substituted this conjugate by rabbit anti-saporin in 2004. The application of this immunotoxin, that was also used in the present study, was described in detail by Moreau and co-workers [39].