Transactive response DNA-binding protein of 43 kDa (TDP-43) functions as a heterogeneous nuclear ribonucleoprotein and is the major pathological protein in frontotemporal lobar degeneration (FTLD) and amyotrophic lateral sclerosis/motor neuron disease (ALS/MND). TDP-43 pathology may also be present as a comorbidity in approximately 20-50% of sporadic Alzheimer's disease cases. In a mouse model of MND, full-length TDP-43 increases association with the mitochondria and blocking the TDP-43/mitochondria interaction ameliorates motor dysfunction. Utilizing a proteomics screen, several mitochondrial TDP-43-interacting partners were identified, including voltage-gated anion channel 1 (VDAC1) and prohibitin 2 (PHB2), a crucial mitophagy receptor. Overexpression of TDP-43 led to an increase in PHB2 whereas TDP-43 knockdown reduced PHB2 expression in cells treated with carbonyl cyanide m-chlorophenylhydrazone (CCCP), an inducer of mitophagy. These results suggest that TDP-43 expression contributes to metabolism and mitochondrial function however we show no change in bioenergetics when TDP-43 is overexpressed and knocked down in HEK293T cells. Furthermore, the fusion protein mitofusin 2 (MFN2) interacts in complex with TDP-43 and selective expression of human TDP-43 in the hippocampus and cortex induced an age-dependent change in Mfn2 expression. Mitochondria morphology is altered in 9-month-old mice selectively expressing TDP-43 in an APP/PS1 background compared with APP/PS1 littermates. We further confirmed TDP-43 localization to the mitochondria using immunogold labeled TDP-43 transmission electron microscopy (TEM) and mitochondrial isolation methods There was no increase in full-length TDP-43 localized to the mitochondria in APP/PS1 mice compared to wild-type (littermates); however, using C- and N-terminal-specific TDP-43 antibodies, the N-terminal (27 kDa, N27) and C-terminal (30 kDa, C30) fragments of TDP-43 are greatly enriched in mitochondrial fractions. In addition, when the mitochondrial peptidase (PMPCA) is overexpressed there is an increase in the N-terminal fragment (N27). These results suggest that TDP-43 processing may contribute to metabolism and mitochondrial function.
BACKGROUND Prostate tumor-initiating cells (TICs) have intrinsic resistance to current therapies. TICs are commonly isolated by cell sorting or dye exclusion, however, isolating TICs from limited primary prostate cancer (PCa) tissues is inherently inefficient. We adapted the collagen adherence feature to develop a combined immunophenotypic and time-of-adherence assay to identify human prostate TICs. METHODS PCa cells from multiple cell lines and primary tissues were allowed to adhere to several matrix molecules, and fractions of adherent cells were examined for their TIC properties. RESULTS Collagen-I rapidly-adherent PCa cells have significantly higher clonogenic, migration, and invasion abilities, and initiated more tumor xenografts in mice when compared to slowly-adherent and no-adherent cells. To determine the relative frequency of TICs among PCa cell lines and primary PCa cells, we utilized zebrafish xenografts to define the tumor initiation potential of serial dilutions of rapidly-adherent α2β1hi/CD44hi cells compared to non-adherent cells with α2β1low/CD44low phenotype. Tumor initiation from rapidly-adherent α2β1hi/CD44hi TICs harboring the TMPRSS2:ERG fusion generated xenografts comprising of PCa cells expressing Erg, AMACR, and PSA. Moreover, PCa-cell dissemination was consistently observed in the immune-permissive zebrafish microenvironment from as-few-as 3 rapidly-adherent α2β1hi/CD44hi cells. In zebrafish xenografts, self-renewing prostate TICs comprise 0.02–0.9% of PC3 cells, 0.3–1.3% of DU145 cells, and 0.22–14.3% of primary prostate adenocarcinomas. CONCLUSION Zebrafish PCa xenografts were used to determine that the frequency of prostate TICs varies among PCa cell lines and primary PCa tissues. These data support a paradigm of utilizing zebrafish xenografts to evaluate novel therapies targeting tumor initiating cells in prostate cancer.
Although the main focus in Alzheimer’s disease (AD) has been an investigation of mechanisms causing Aβ plaque deposition and tau tangle formation, recent studies have shown that phosphorylated TDP-43 pathology is present in up to 50% of sporadic cases. Furthermore, elevated phosphorylated TDP-43 has been associated with more severe AD pathology. Therefore, we hypothesized that TDP-43 may regulate amyloid-beta precursor protein (APP) trafficking and tau phosphorylation/aggregation. In order to examine the role of TDP-43 in AD, we developed a transgenic mouse that overexpresses hippocampal and cortical neuronal TDP-43 in a mouse expressing familial mutations (K595N and M596L) in APP and presenilin 1 (PSEN1ΔE9). In our model, increased TDP-43 was related to increased tau aggregation as evidenced by thioflavin S-positive phosphorylated tau, which may implicate TDP-43 expression in pre-tangle formation. In addition, there was increased endosomal/lysosomal localization of APP and reduced Aβ plaque formation with increased TDP-43. Furthermore, there was decreased calcineurin with elevated TDP-43 expression. Since calcineurin is a phosphatase for TDP-43, the decreased calcineurin expression may be one mechanism leading to an increase in accumulation of diffuse phosphorylated TDP-43 in the hippocampus and cortex. We further show that when TDP-43 is knocked down there is an increase in calcineurin. In our model of selective TDP-43 overexpression in an APP/PSEN1 background, we show that TDP-43 decreases Aβ plaque deposition while increasing abnormal tau aggregation. These observations indicate that TDP-43 may play a role in regulating APP trafficking and tau aggregation. Our data suggest that TDP-43 could be a putative target for therapeutic intervention in AD affecting both Aβ plaque formation and tauopathy.
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