Collecting evidence has shown that type 2 diabetes mellitus is a high risk factor of late-onset Alzheimer's disease (AD); the energy metabolic dysfunction is thought to be a convergent point of the two diseases. However, the underlying mechanisms of diabetes-associated AD are still unclear. In the current study, we investigated the roles of AMPK in diabetes-related AD-like pathologic features in models of intracerebroventricular-streptozotocin (ICV-STZ) animals. Rats infused with STZ (3 mg/kg, once) were followed by injection of AICAR (AMPK activator) or vehicle via ICV. We found that the level of p-AMPK (active type of AMPK) and SIRT1 activity were decreased and the level of phosphorylated tau was increased at Ser396 and Thr231 sites in ICV-STZ rats when compared with control rats. Mitochondria from ICV-STZ rats displayed a significant decrease in mitochondrial membrane potential, complex I activity, ATP level, and superoxide dismutase activity as well as an increase of reactive oxygen species production when compared with that from control rats. Meanwhile the number of apoptotic cell confirmed by cleaved caspase-3 (active type of caspase-3) staining was also stronger in ICV-STZ rats than control rats. All pathological changes including biochemistry and cognitive function could be mitigated through rescuing AMPK activity with its specific activator (AICAR) in ICV-STZ rats. Taken together, these results suggested that AMPK activation improves AD-like pathological changes via repairing mitochondrial functions in ICV-STZ rats.
The W-Beijing family of Mycobacterium tuberculosis (Mtb) strains is known for its high-prevalence and -virulence, as well as for its genetic diversity, as recently reported by our laboratories and others. However, little is known about how the immune system responds to these strains. To explore this issue, here we used reverse engineering and genome-wide expression profiling of human macrophage-like THP-1 cells infected by different Mtb strains of the W-Beijing family, as well as by the reference laboratory strain H37Rv. Detailed data mining revealed that host cell transcriptome responses to H37Rv and to different strains of the W-Beijing family are similar and overwhelmingly induced during Mtb infections, collectively typifying a robust gene expression signature (“THP1r2Mtb-induced signature”). Analysis of the putative transcription factor binding sites in promoter regions of genes in this signature identified several key regulators, namely STATs, IRF-1, IRF-7, and Oct-1, commonly involved in interferon-related immune responses. The THP1r2Mtb-induced signature appeared to be highly relevant to the interferon-inducible signature recently reported in active pulmonary tuberculosis patients, as revealed by cross-signature and cross-module comparisons. Further analysis of the publicly available transcriptome data from human patients showed that the signature appears to be relevant to active pulmonary tuberculosis patients and their clinical therapy, and be tuberculosis specific. Thus, our results provide an additional layer of information at the transcriptome level on mechanisms involved in host macrophage response to Mtb, which may also implicate the robustness of the cellular defense system that can effectively fight against genetic heterogeneity in this pathogen.
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