The molecular neural mechanism underlying the acceleration of brain aging due to Dcf1 deficiency.

Owing to the continuous increase in human life expectancy, the management of aging-related diseases has become an urgent issue. The brain dominates the central nervous system; therefore, brain aging is a key area of aging-related research. We previously uncovered that dendritic cell factor 1 (Dcf1) maintains the stemness of neural stem cells and its expression in Drosophila can prolong lifespan, suggesting an association between Dcf1 and aging; however, the specific underlying neural mechanism remains unclear. In the present study, we show for the first time that hippocampal neurogenesis is decreased in aged Dcf1-/- mice, which leads to a decrease in the number of brain neurons and an increased number of senescent cells. Moreover, astrocytes proliferate abnormally and express elevated mRNA levels of aging-related factors, in addition to displaying increased activation of Akt and Foxo3a. Finally, behavioral tests confirm that aged Dcf1-/- mice exhibit a significant decline in cognitive abilities related to learning and memory. In conclusion, we reveal a novel mechanism underlying brain aging triggered by Dcf1 deficiency at the molecular, cellular, tissue, and behavioral levels, providing a new perspective for the exploration of brain aging.

TMEM59 ablation leads to loss of olfactory sensory neurons and impairs olfactory functions via interaction with inflammation.

The olfactory epithelium undergoes constant neurogenesis throughout life in mammals. Several factors including key signaling pathways and inflammatory microenvironment regulate the maintenance and regeneration of the olfactory epithelium. In this study, we identify TMEM59 (also known as DCF1) as a critical regulator to the epithelial maintenance and regeneration. Single-cell RNA-Seq data show downregulation of TMEM59 in multiple epithelial cell lineages with aging. Ablation of TMEM59 leads to apparent alteration at the transcriptional level, including genes associated with olfactory transduction and inflammatory/immune response. These differentially expressed genes are key components belonging to several signaling pathways, such as NF-κB, chemokine, etc. TMEM59 deletion impairs olfactory functions, attenuates proliferation, causes loss of both mature and immature olfactory sensory neurons, and promotes infiltration of inflammatory cells, macrophages, microglia cells and neutrophils into the olfactory epithelium and lamina propria. TMEM59 deletion deteriorates regeneration of the olfactory epithelium after injury, with significant reduction in the number of proliferative cells, immature and mature sensory neurons, accompanied by the increasing number of inflammatory cells and macrophages. Anti-inflammation by dexamethasone recovers neuronal generation and olfactory functions in the TMEM59-KO animals, suggesting the correlation between TMEM59 and inflammation in regulating the epithelial maintenance. Collectively, TMEM59 regulates olfactory functions, as well as neuronal generation in the olfactory epithelium via interaction with inflammation, suggesting a potential role in therapy against olfactory dysfunction associated with inflamm-aging.

Depression-like symptoms due to Dcf1 deficiency are alleviated by intestinal transplantation of Lactobacillus murine and Lactobacillus reuteri.

Depression, characterized by low mood, is a complex mental disorder that is a serious threat to human health. Depression is thought to be caused by a combination of genetic, environmental and psychological factors. However, the pathophysiology of depression remains unclear. In the present study, we found that Dcf1 knockout (KO) mice had depression-like symptoms and disruptive changes in gamma-aminobutyric acid (GABA) concentration and GABA receptor expression were found in the hippocampus of Dcf1 KO and WT mice. Furthermore, the gut microbiota composition of Dcf1 KO mice was significantly different from that of wildtype (WT) mice and Dcf1 KO mice showed lower Firmicutes and Lactobacillus content compared to WT mice. In addition, the depression-like behavior of Dcf1 KO mice was alleviated by the administration of microbiota. More surprisingly, after treatment with Lactobacillus murine and Lactobacillus reuteri, two Lactobacillus species with proportionally greater differences in content between the WT and KO groups, KO mice showed similar GABA content, as well as restored GABA-related receptor expression, as the WT group. Our data elucidated a possible mechanism of depression induction by gut microbiota in Dcf1 KO mice and provide a new avenue to explore the treatment of depression by gut microbiota.

A preliminary study on abnormal brain function and autistic behavior in mice caused by dcf1 deletion.

Autism is one of the urgent problems in neuroscience. Early research in our laboratory found that dcf1 gene-deficient mice exhibited autistic behavior. Reviewing the literature, we know that the caudate putamen (CPu) brain region is closely related to the occurrence of autism. In this study, we observed that the electrical signal in the abnormal brain region of adult mice was enhanced by using field potential detection for the corresponding brain region. We then used retrovirus markers to track neurons in the CPu brain region and found that there are neural projections in the hippocampus-CPu brain region. Therefore, we selected DREADDs (Designer receptors exclusively activated by designer drugs) to inhibit the abnormal brain region of the mouse and found, through behavioral testing, that this can inhibit the autistic behavior of mice. This research provides new evidence for the understanding of the cause of autism and has accumulated new basis for the treatment of autism. It has theoretical significance and potential application value for the understanding and treatment of autism.

Zebrafish olfactory receptors ORAs differentially detect bile acids and bile salts.

The fish olfactory receptor ORA family is orthologous to the mammalian vomeronasal receptors type 1. It consists of six highly conserved chemosensory receptors expected to be essential for survival and communication. We deorphanized the zebrafish ORA family in a heterologous cell system. The six receptors responded specifically to lithocholic acid (LCA) and closely related C24 5ß-bile acids/salts. LCA attracted zebrafish as strongly as food in behavioral tests, whereas the less potent cholanic acid elicited weaker attraction, consistent with the in vitro results. The ORA-ligand recognition patterns were probed with site-directed mutagenesis guided by in silico modeling. We revealed the receptors' structure-function relationship underlying their specificity and selectivity for these compounds. Bile acids/salts are putative fish semiochemicals or pheromones sensed by the olfactory system with high specificity. This work identified their receptors and provided the basis for probing the roles of ORAs and bile acids/salts in fish chemosensation.

Dcf1 deletion presents alterations in gut microbiota of mice similar to Parkinson's disease.

The gut-brain communication is increasingly being recognized as a profound effector on Parkinson's disease (PD). Gut microbiota changes have become the focus of attention. However, the mechanism leading to changes in the gut microbiota is not clear. In the present study, we found that knockout of Dcf1 (Dcf1-/-) caused changes in the gut microbiota in mice. Results indicated that the increased Proteobacteria (phylum-level) and decreased Prevotellaceae (family-level) in the microbiota composition of Dcf1-/- (KO) mice, which is consistent with the situation of PD patients. On species-level, Prevotellaceae_UCG-001 and Helicobacter_ganmani were significantly different between KO and WT mice, suggesting glycolipid metabolism disorders and inflammatory lesions in KO mice. In the behavior of Y-maze and Open field test, KO mice showed typical PD symptoms such as memory deficits, slowness of movement and anxiety. Further Nissl staining of brain tissue sections confirmed that the deletion of Dcf1 caused damage to amygdala neurons. These results provide a new mechanism for understanding gut microbiota changes, and provide a new basis for PD treatment from a new perspective of Gut-brain axis.

Dcf1 alleviates C99-mediated deficits in drosophila by reducing the cleavage of C99.

Alzheimer's disease (AD) is a progressive neurodegenerative disorder. The generation of amyloid-ß from the amyloid precursor protein (APP) C-terminal fragment (C99) by γ-secretase cleavage is one of the main pathological mechanisms of AD. Dendritic cell factor 1 (Dcf1) is a membrane protein that was previously found to play a role in the development of AD. Bioinformatic analysis of AD patients indicated that Dcf1 may affect γ-secretase. In this study, we confirmed that Dcf1 attenuates the cleavage of C99 in vivo and in vitro. By using C99 transgenic AD drosophila, we found that Dcf1 reduces the cleavage of C99 by γ-secretase using Dcf1 overexpression. The climbing ability and lifespan of C99 drosophila were significantly increased, while learning and memory were also enhanced with Dcf1 expression. Increased levels of C99 protein in Dcf1-AD drosophila reveals inhibition of C99 cleavage by Dcf1 in vivo. Dcf1 inhibition of γ-secretase was further confirmed in vitro. These results provide a potential therapeutic target for the treatment of AD and also propose a new mechanism for understanding the occurrence of AD.

DNF: A differential network flow method to identify rewiring drivers for gene regulatory networks.

Differential network analysis has become an important approach in identifying driver genes in development and disease. However, most studies capture only local features of the underlying gene-regulatory network topology. These approaches are vulnerable to noise and other changes which mask driver-gene activity. Therefore, methods are urgently needed which can separate the impact of true regulatory elements from stochastic changes and downstream effects. We propose the differential network flow (DNF) method to identify key regulators of progression in development or disease. Given the network representation of consecutive biological states, DNF quantifies the essentiality of each node by differences in the distribution of network flow, which are capable of capturing comprehensive topological differences from local to global feature domains. DNF achieves more accurate driver-gene identification than other state-of-the-art methods when applied to four human datasets from The Cancer Genome Atlas and three single-cell RNA-seq datasets of murine neural and hematopoietic differentiation. Furthermore, we predict key regulators of crosstalk between separate networks underlying both neuronal differentiation and the progression of neurodegenerative disease, among which APP is predicted as a driver gene of neural stem cell differentiation. Our method is a new approach for quantifying the essentiality of genes across networks of different biological states.

Notch Signaling Regulates Lgr5+ Olfactory Epithelium Progenitor/Stem Cell Turnover and Mediates Recovery of Lesioned Olfactory Epithelium in Mouse Model.

The Notch signaling pathway regulates stem cell proliferation and differentiation in multiple tissues and organs, and is required for tissue maintenance. However, the role of Notch in regulation of olfactory epithelium (OE) progenitor/stem cells to maintain tissue function is still not clear. A recent study reported that leucine-rich repeat-containing G-protein-coupled receptor 5 (Lgr5) is expressed in globose basal cells (GBCs) localized in OE. Through lineage tracing in vivo, we found that Lgr5+ cells act as progenitor/stem cells in OE. The generation of daughter cells from Lgr5+ progenitor/stem cells is delicately regulated by the Notch signaling pathway, which not only controls the proliferation of Lgr5+ cells and their immediate progenies but also affects their subsequent terminal differentiation. In conditionally cultured OE organoids in vitro, inhibition of Notch signaling promotes neuronal differentiation. Besides, OE lesion through methimazole administration in mice induces generation of more Notch1+ cells in the horizontal basal cell (HBC) layer, and organoids derived from lesioned OE possesses more proliferative Notch1+ HBCs. In summary, we concluded that Notch signaling regulates Lgr5+ GBCs by controlling cellular proliferation and differentiation as well as maintaining epithelial cell homeostasis in normal OE. Meanwhile, Notch1 also marks HBCs in lesioned OE and Notch1+ HBCs are transiently present in OE after injury. This implies that Notch1+ cells in OE may have dual roles, functioning as GBCs in early development of OE and HBCs in restoring the lesioned OE. Stem Cells 2018;36:1259-1272.

Dcf1 Affects Memory and Anxiety by Regulating NMDA and AMPA Receptors.

The hippocampus is critical for memory and emotion and both N-methyl-D-aspartate (NMDA) and α-amino-3-hydroxy-5-methyl- 4-isoxazolepropionic acid (AMPA) receptors are known to contribute for those processes. However, the underlying molecular mechanisms remain poorly understood. We have previously found that mice undergo memory decline upon dcf1 deletion through ES gene knockout. In the present study, a nervous system-specific dcf1 knockout (NKO) mouse was constructed, which was found to present severely damaged neuronal morphology. The damaged neurons caused structural abnormalities in dendritic spines and decreased synaptic density. Decreases in hippocampal NMDA and AMPA receptors of NKO mice lead to abnormal long term potentiation (LTP) at DG, with significantly decreased performance in the water maze, elevated- plus maze, open field and light and dark test. Investigation into the underlying molecular mechanisms revealed that dendritic cell factor 1 (Dcf1) contributes for memory and emotion by regulating NMDA and AMPA receptors. Our results broaden the understanding of synaptic plasticity's role in cognitive function, thereby expanding its known list of functions.

The Stem Cell Marker Lgr5 Defines a Subset of Postmitotic Neurons in the Olfactory Bulb.

Lgr5, leucine-rich repeat-containing G-protein coupled receptor 5, is a bona fide biomarker for stem cells in multiple tissues. Lgr5 is also expressed in the brain, but the identities and properties of these Lgr5+ cells are still elusive. Using an Lgr5-EGFP reporter mouse line, we found that, from early development to adulthood, Lgr5 is highly expressed in the olfactory bulb (OB), an area with ongoing neurogenesis. Immunostaining with stem cell, glial, and neuronal markers reveals that Lgr5 does not label stem cells in the OB but instead labels a heterogeneous population of neurons with preference in certain subtypes. Patch-clamp recordings in OB slices reveal that Lgr5-EGFP+ cells fire action potentials and display spontaneous excitatory postsynaptic events, indicating that these neurons are integrated into OB circuits. Interestingly, R-spondin 3, a potential ligand of Lgr5, is also expressed in the adult OB. Collectively, our data indicate that Lgr5-expressing cells in the OB are fully differentiated neurons and imply distinct roles of Lgr5 and its ligand in postmitotic cells.SIGNIFICANCE STATEMENT Lgr5 (leucine-rich repeat-containing G-protein coupled receptor 5) is a bona fide stem cell marker in many body organs. Here we report that Lgr5 is also highly expressed in the olfactory bulb (OB), the first relay station in the brain for processing odor information and one of the few neural structures that undergo continuous neurogenesis. Surprisingly, Lgr5 is not expressed in the OB stem cells, but instead in a few subtypes of terminally differentiated neurons, which are incorporated into the OB circuit. This study reveals that Lgr5+ cells in the brain represent a nonstem cell lineage, implying distinct roles of Lgr5 in postmitotic neurons.

Dcf1 Improves Behavior Deficit in Drosophila and Mice Caused by Optogenetic Suppression.

Optogenetics play a significant role in neuroscientific research by providing a tool for understanding neural circuits and brain functions. Natronomonas pharaonis halorhodopsin (NpHR) actively pumps chloride ions into the cells and hyperpolarizes neuronal membranes in response to yellow light. In this study, we generated transgenic Drosophila expressing NpHR under the control of the Gal4/UAS system and virus-infected mice expressing NpHR to explore the effect of dendritic cell factor 1 (Dcf1) on the behavior mediated by the mushroom body in Drosophila and the dentate gyrus (DG) in mice. Study of optogenetic behavior showed that NpHR suppressed the behavior in Drosophila larvae and mice, whereas Dcf1 rescued this suppression. These results suggest that Dcf1 plays an important role in behavior induced by the mushroom body and the hippocampus and provides novel insights into their functions. J. Cell. Biochem. 118: 4210-4215, 2017. © 2017 Wiley Periodicals, Inc.

Thamnolia vermicularis extract improves learning ability in APP/PS1 transgenic mice by ameliorating both Aß and Tau pathologies.

Considering the complicated pathogenesis of Alzheimer's disease (AD), multi-targets have become a focus in the discovery of drugs for treatment of this disease. In the current work, we established a multi-target strategy for discovering active reagents capable of suppressing both Aß level and Tau hyperphosphorylation from natural products, and found that the ethanol extract of Thamnolia vermicularis (THA) was able to improve learning ability in APP/PS1 transgenic mice by inhibiting both Aß levels and Tau hyperphosphorylation. SH-SY5Y and CHO-APP/BACE1 cells and primary astrocytes were used in cell-based assays. APP/PS1 transgenic mice [B6C3-Tg(APPswe, PS1dE9)] were administered THA (300 mg·kg-1·d-1, ig) for 100 d. After the administration was completed, the learning ability of the mice was detected using a Morris water maze (MWM) assay; immunofluorescence staining, Congo red staining and Thioflavine S staining were used to detect the senile plaques in the brains of the mice. ELISA was used to evaluate Aß and sAPPß contents, and Western blotting and RT-PCR were used to investigate the relevant signaling pathway regulation in response to THA treatment. In SH-SY5Y cells, THΑ (1, 10, 20 µg/mL) significantly stimulated PI3K/AKT/mTOR and AMPK/raptor/mTOR signaling-mediated autophagy in the promotion of Aß clearance as both a PI3K inhibitor and an AMPK indirect activator, and restrained Aß production as a suppressor against PERK/eIF2α-mediated BACE1 expression. Additionally, THA functioned as a GSK3ß inhibitor with an IC50 of 1.32±0.85 µg/mL, repressing Tau hyperphosphorylation. Similar effects on Aß accumulation and Tau hyperphosphorylation were observed in APP/PS1 transgenic mice treated with THA. Furthermore, administration of THA effectively improved the learning ability of APP/PS1 transgenic mice, and markedly reduced the number of senile plaques in their hippocampus and cortex. The results highlight the potential of the natural product THA for the treatment of AD.

Overexpression of Rho-GDP-dissociation inhibitor-γ inhibits migration of neural stem cells.

Neural stem cell (NSC) migration relies heavily on the regulation of actin and microtubule cytoskeletons by Rho GTPases, which are critical regulators of key steps during NSC migration. However, the migration mechanism remains unclear. Rho-GDP-dissociation inhibitor-γ (Rho-GDIγ) was identified as an important downregulator of the Rho family of GTPases, because of its ability to prevent nucleotide exchange and thus membrane association. This study investigates the role of Rho-GDIγ in neural stem cells migration. Our results indicate that the overexpression of Rho-GDIγ maintains NSCs in the stem cell state, meanwhile preventing NSC migration through inhibition of Rac1 expression, one of the Rho-family GTPases. This study provides the basis for further study of the molecular mechanism of NSC migration.

Different effects of histone deacetylase inhibitors nicotinamide and trichostatin A (TSA) in C17.2 neural stem cells.

Histone deacetylase inhibitors are involved in proliferation, apoptosis, cell cycle, mRNA transcription, and protein expression in various cells. However, the molecular mechanism underlying such functions is still not fully clear. In this study, we used C17.2 neural stem cell (NSC) line as a model to evaluate the effects of nicotinamide and trichostatin A (TSA) on cell characteristics. Results show that nicotinamide and TSA greatly inhibit cell growth, lead to cell morphology changes, and effectively induce cell apoptosis in a dose-dependent manner. Western blot analyses confirmed that nicotinamide significantly decreases the expression of bcl-2 and p38. Further insight into the molecular mechanisms shows the suppression of phosphorylation in eukaryotic initiation factor 4E-binding protein 1 (4EBP1) by nicotinamide, whereas, an increased expression of bcl-2 and p38 and phosphorylation of 4EBP1 by TSA. However, both nicotinamide and TSA significantly increase the expression of cytochrome c (cyt c). These results strongly suggest that bcl-2, p38, cyt c, and p-4EBP1 could suppress proliferation and induce apoptosis of C17.2 NSCs mediated by histone deacetylase inhibitors, nicotinamide and TSA, involving different molecular mechanisms.

MicroRNA-351 regulates TMEM 59 (DCF1) expression and mediates neural stem cell morphogenesis.

MicroRNAs (miRNA) are small noncoding RNAs that play important roles in cell development, differentiation and apoptosis. Recent studies showed that transmembrane protein 59 (TMEM59) affects neural stem cell (NSC) differentiation and ß-amyloid precursor protein (APP) glycosylation. In this study, we predicted that microRNA-351 (miR-351) could target TMEM59 and demonstrated that miR-351 negatively regulates TMEM59 expression in different cell types. Moreover, we found that miR-351 overexpression could lead to morphological change in the mouse NSC cell line C17.2, indicating an important role of miR-351 in the regulation of differentiation. Our investigations focused on the functions of miR-351 in the nervous system and the posttranscriptional regulation of TMEM59 by microRNA. These original findings provide promising grounds for future in-depth research into the functions of miR-351 and TMEM59 in nervous system development.

Dcf1 induces glioblastoma cells apoptosis by blocking autophagy.

BACKGROUND: Dcf1 has been demonstrated to play vital roles in many CNS diseases, it also has a destructive role on cell mitochondria in glioma cells and promotes the autophagy. Hitherto, it is unclear whether the viability of glioblastoma cells is affected by Dcf1, in particular Dcf1 possesses broad localization on different organelles, and the organelles interaction frequently implicated in cancer cells survival. METHODS: Surgically excised WHO grade IV human glioblastoma tissues were collected and cells isolated for culturing. RT-PCR and DNA sequencing assay to estimate the abundance and mutation of Dcf1. iTRAQ sequencing and bioinformatic analysis were performed. Subsequently, immunoprecipitation assay to evaluate the degradation of HistoneH2A isomers by UBA52 ubiquitylation. Transmission electron microscopy (TEM) was applied to observe the structure change of mitochondria and autophagosome. Organelle isolated assay to determine the distribution of protein. Cell cycle and apoptosis were evaluated by flow cytometric assays. RESULTS: Dcf1 was downregulated in WHO grade IV tumor without mutation, and overexpression of Dcf1 was found to significantly regulate glioblastoma cells. One hundred and seventy-six differentially expressed proteins were identified by iTRAQ sequencing. Furthermore, we confirmed that overexpression of Dcf1 destabilized the structure of the nucleosome via UBA52 ubiquitination to downregulate HistoneH2A.X but not macroH2A or HistoneH2A.Z, decreased the mitochondrial DNA copy number and inhibited the mitochondrial biogenesis, thus causing mitochondrial destruction and dysfunction in order to supply cellular energy and induce mitophagy preferentially but not apoptosis. Dcf1 also has disrupted the integrity of lysosomes to block autolysosome degradation and autophagy and to increase the release of Cathepsin B and D from lysosomes into cytosol. These proteins cleaved and activated BID to induce glioblastoma cells apoptosis. CONCLUSIONS: In this study, we demonstrated that unmutated Dcf1 expression is negatively related to the malignancy of glioblastoma, Dcf1 overexpression causes nucleosomes destabilization, mitochondria destruction and dysfunction to induce mitophagy preferentially, and block autophagy by impairing lysosomes to induce apoptosis in glioblastoma.

CASCADE_SCAN: mining signal transduction network from high-throughput data based on steepest descent method.

BACKGROUND: Signal transduction is an essential biological process involved in cell response to environment changes, by which extracellular signaling initiates intracellular signaling. Many computational methods have been generated in mining signal transduction networks with the increasing of high-throughput genomic and proteomic data. However, more effective means are still needed to understand the complex mechanisms of signaling pathways. RESULTS: We propose a new approach, namely CASCADE_SCAN, for mining signal transduction networks from high-throughput data based on the steepest descent method using indirect protein-protein interactions (PPIs). This method is useful for actual biological application since the given proteins utilized are no longer confined to membrane receptors or transcription factors as in existing methods. The precision and recall values of CASCADE_SCAN are comparable with those of other existing methods. Moreover, functional enrichment analysis of the network components supported the reliability of the results. CONCLUSIONS: CASCADE_SCAN is a more suitable method than existing methods for detecting underlying signaling pathways where the membrane receptors or transcription factors are unknown, providing significant insight into the mechanism of cellular signaling in growth, development and cancer. A new tool based on this method is freely available at http://www.genomescience.com.cn/CASCADE_SCAN/.

Deletion of Dcf1 Reduces Amyloid-ß Aggregation and Mitigates Memory Deficits.

BACKGROUND: Alzheimer's disease (AD) is a progressive neurodegenerative disease. One of the pathologies of AD is the accumulation of amyloid-ß (Aß) to form senile plaques, leading to a decline in cognitive ability and a lack of learning and memory. However, the cause leading to Aß aggregation is not well understood. Dendritic cell factor 1 (Dcf1) shows a high expression in the entorhinal cortex neurons and neurofibrillary tangles in AD patients. OBJECTIVE: Our goal is to investigate the effect of Dcf1 on Aß aggregation and memory deficits in AD development. METHODS: The mouse and Drosophila AD model were used to test the expression and aggregation of Aß, senile plaque formation, and pathological changes in cognitive behavior during dcf1 knockout and expression. We finally explored possible drug target effects through intracerebroventricular delivery of Dcf1 antibodies. RESULTS: Deletion of Dcf1 resulted in decreased Aß42 level and deposition, and rescued AMPA Receptor (GluA2) levels in the hippocampus of APP-PS1-AD mice. In Aß42 AD Drosophila, the expression of Dcf1 in Aß42 AD flies aggravated the formation and accumulation of senile plaques, significantly reduced its climbing ability and learning-memory. Data analysis from all 20 donors with and without AD patients aged between 80 and 90 indicated a high-level expression of Dcf1 in the temporal neocortex. Dcf1 contributed to Aß aggregation by UV spectroscopy assay. Intracerebroventricular delivery of Dcf1 antibodies in the hippocampus reduced the area of senile plaques and reversed learning and memory deficits in APP-PS1-AD mice. CONCLUSION: Dcf1 causes Aß-plaque accumulation, inhibiting dcf1 expression could potentially offer therapeutic avenues.

Internalization, translocation and biotransformation of silica-coated titanium dioxide nanoparticles in neural stem cells.

Nanotechnology has gained massive applications in the fields of biology and pharmacology. Recently, more research attention has been paid to explore the interaction between nanoparticles (NPs) and cells, in particular, the entry of NPs into cells. Herein, we focus on the internalization of the FITC-labeled silica-coated titania NPs (FITC-TiO2@SiO2 NPs) in neural stem cells (NSCs) and their subsequent translocation. Various microscopic techniques, such as confocal-laser-scanning microscopy (CFLSM), transmission electron microscopy (TEM) and atomic force microscopy (AFM) were used to track the time-dependent pathway of NPs in cells. It was found that NPs traversed cell membrane and localized around the cell nucleus. Most NPs congregated in lysosomes and were transformed by lysosomes after 48 h co-incubation.