Knockdown of long non-coding RNA HOTAIR reverses cisplatin resistance of ovarian cancer cells through inhibiting miR-138-5p-regulated EZH2 and SIRT1

BACKGROUND: Cisplatin resistance (DDP-resistance) remains one of the major causes of poor prognosis in females with ovarian cancer. Long non-coding RNAs (lncRNAs) have been shown to participate in the regulation of cellular processes, including chemoresistance. The aim of this study was to explore the role of HOX transcript antisense RNA (HOTAIR) in DDP-resistant ovarian cancer cells. METHODS: DDP-resistant ovarian cancer cell lines (SKOV3/DDP and A2780/DDP) were established. Real-time PCR, western blot, dual-luciferase reporter assay, and flow cytometry were then used to evaluate the effect of HOTAIR/miR-138-5p axis on chemoresistance of DDP-resistant ovarian cancer cells to DDP. RESULTS: We found that HOTAIR was upregulated in DDP-resistant cells, while miR-138-5p was downregulated. Knockdown of HOTAIR increased the expression of miR-138-5p in DDP-resistant cells and miR-138-5p is directly bound to HOTAIR. Upregulation of miR-138-5p induced by HOTAIR siRNA or by its mimics enhanced the chemosensitivity of DDP-resistant cells and decreased the expression of EZH2 (enhancer of zeste 2 polycomb repressive complex 2 subunit) and SIRT1 (sirtuin 1). Furthermore, the HOTAIR silencing-induced chemosensitivity of DDP-resistant cells was weakened by miR-138-5p inhibitor. CONCLUSIONS: These data demonstrate that HOTAIR acts as a sponge of miR-138-5p to prevent its binding to EZH2 and SIRT1, thereby promoting DDP-resistance of ovarian cancer cells. Our work will shed light on the development of therapeutic strategies for ovarian cancer treatment.

Knockout of p16INK4a promotes aggregative growth of dermal papilla cells

Summary Objective: Dermal papilla cells (DPCs) are located in the hair follicles and play an important role in hair growth. These cells have the ability to induce hair follicle formation when they display aggregative behavior. DPCs derived from the androgenetic alopecia (AGA) area undergo premature senescence in vitro, associated with p16INK4a expression. The aim of the current study was to investigate the expression of p16INK4a in aggregative and non-aggregative DPCs and the effect of p16INK4a down-regulation in these cells by adenovirus-mediated RNA interference (RNAi). Method: DPCs were isolated and cultured from healthy human scalp. p16INK4a gene and protein were detected in aggregative and non-aggregative cells. Expression of p16INK4a in DPCs was silenced by infection with rAd5-CDKN1A-1p2shRNA. Cell fate was monitored after infection. The growth of cells was measured by MTT assay. Cell cycle was evaluated by flow cytometry (FCM). Results: DPCs were isolated by digestion and showed aggregative behavior for six passages. The expression of p16INK4a showed a clear upward trend in non-aggregative cells when compared with aggregative group. p16INK4a expression was silenced by rAd5-CDKN1A-1p2shRNA (p<0.05). The p16INK4a-silenced cells grew more rapidly and exhibited a trend towards aggregative growth. There was an increase in the proportion of cells in G1 phase, while those in S phase were reduced after p16INK4a gene silencing (p<0.05). Conclusion: Our results suggest that p16INK4a plays an important role in the premature senescence and aggregative behavior of DPCs. These observations can lead to novel therapeutic strategies for treatment of AGA.

Simultaneous deletion of floxed genes mediated by CaMKIIalpha-Cre in the brain and in male germ cells: application to conditional and conventional disruption of Goalpha

The Cre/LoxP system is a well-established approach to spatially and temporally control genetic inactivation. The calcium/calmodulin-dependent protein kinase II alpha subunit (CaMKIIalpha) promoter limits expression to specific regions of the forebrain and thus has been utilized for the brain-specific inactivation of the genes. Here, we show that CaMKIIalpha-Cre can be utilized for simultaneous inactivation of genes in the adult brain and in male germ cells. Double transgenic Rosa26(+/stop-lacZ)::CaMKIIalpha-Cre(+/Cre) mice generated by crossing CaMKIIalpha-Cre(+/Cre) mice with floxed ROSA26 lacZ reporter (Rosa26(+/stop-lacZ)) mice exhibited lacZ expression in the brain and testis. When these mice were mated to wild-type females, about 27% of the offspring were whole body blue by X-gal staining without inheriting the Cre transgene. These results indicate that recombination can occur in the germ cells of male Rosa26(+/stop-lacZ)::CaMKIIalpha-Cre(+/Cre) mice. Similarly, when double transgenic Gnao(+/f)::CaMKIIalpha-Cre(+/Cre) mice carrying a floxed Go-alpha gene (Gnao(f/f)) were backcrossed to wild-type females, approximately 22% of the offspring carried the disrupted allele (Gnao(Delta)) without inheriting the Cre transgene. The Gnao(Delta/Delta) mice closely resembled conventional Go-alpha knockout mice (Gnao(-/-)) with respect to impairment of their behavior. Thus, we conclude that CaMKIIalpha-Cre mice afford recombination for both tissue- and time-controlled inactivation of floxed target genes in the brain and for their permanent disruption. This work also emphasizes that extra caution should be exercised in utilizing CaMKIIalpha-Cre mice as breeding pairs.

RIC-8B, uma GEF de sistema olfatório, é essencial para o desenvolvimento do sistema nervoso / RIC-8B, an olfactory GEF, is essential for the development of the nervous system

RIC-8B é um fator trocador de nucleotídeo de guanina (GEF) predominantemente expresso em neurônios olfatórios maduros de camundongos adultos. Trabalhos desenvolvidos em nosso laboratório mostraram que RIC-8B interage com Gαolf e Gγ13, duas subunidades de proteína G que estão enriquecidas nos cílios dos neurônios olfatórios, onde participam da transdução do sinal de odorantes. In vitro, RIC-8B é capaz de amplificar a sinalização de receptores olfatórios através de Gαolf, no entanto, seu papel fisiológico ainda é desconhecido. Para determinar a função desempenhada por essa proteína in vivo, nós utilizamos a tecnologia de Gene Trap com o objetivo de produzir um camundongo knockout para Ric-8B. Apesar de a expressão de Ric-8B ser restrita a poucos tecidos no camundongo adulto, descobrimos que homozigotos para a mutação em Ric-8B são inviáveis e morrem por volta do dia embrionário E10,5. Além disso, são menores e apresentam evidente falha no fechamento do tubo neural na região cranial (exencefalia). Utilizamos o gene repórter ß-galactosidase expresso pelo alelo mutado para determinar o padrão de expressão de Ric-8B em embriões durante o desenvolvimento. Observamos que, no estágio E8,5, Ric-8B é expresso nas pregas neurais da região cefálica e na notocorda. De E9,5 a E12,5, a expressão de Ric-8B é detectada predominante no assoalho da placa. Esse padrão de expressão se assemelha ao de outro gene importante para a embriogênese, Sonic hedgehog (Shh). SHH é um morfógeno diretamente responsável pela padronização dorsoventral do sistema nervoso central e sua sinalização depende de cílio primário. Cílio primário é uma organela baseada em microtúbulos que se projeta da superfície da maioria das células de mamíferos e funciona como um centro de sinalização intracelular. Nossos dados mostram que fibroblastos embrionários Ric-8B-/- formam cílios primários, assim como alguns tecidos do embrião. Além disso, não encontramos alterações na sinalização de Shh em embriões homozigotos mutantes. No entanto, observamos que esses embriões apresentam apoptose aumentada em células migratórias da crista neural cranial. Shh é importante para a sobrevivência de células da crista neural migratória, sugerindo um possível papel para Ric-8B a downstream da sinalização de SHH

Ric-8B is a guanine nucleotide exchange factor (GEF) which is predominantly expressed in mature olfactory sensory neurons in adult mice. We have previously shown that RIC-8B interacts with both Gαolf and Gγ13, two G protein subunits, which are enriched in olfactory cilia and are required for odorant signal transduction. In vitro, RIC-8B is able to amplify odorant receptor signaling through Gαolf, however, its physiological role remains unknown. To determine the role played by RIC-8B in vivo we used the Gene trap technology to generate a Ric-8B knockout mouse. We found that, despite the limited distribution of Ric-8B gene expression in adult mice, Ric-8B homozygous mutants are not viable and die around the E10,5 stage. Mutant embryos are also smaller and fail to close the neural tube at the cranial region (exencephaly). We used the activity of the ß-galactosidase reporter gene to determine the pattern of expression of the Ric-8B gene in heterozygous embryos. At E8,5 the Ric-8B gene is expressed in the notochord and neural folds of the cephalic regions. From E9,5 to E12,5 Ric-8B is predominantly expressed in the floor plate, in a pattern that strongly resembles the one shown by Sonic hedgehog (Shh). SHH is a morphogen directly responsible for the dorsoventral patterning of the central nervous system and its signaling depends on primary cilia. Primary cilia are microtubule-based organelles that protrude from the surface of mammalian cells and act as a signaling center. We show that Ric-8B-/- embryonic fibroblasts and some embryonic tissues grow primary cilia normally. In addition, we did not find alterations in the SHH signaling of homozygous mutants. Instead, we found an increased apopotosis in migratory cells of the cranial neural crest in these embryos. Shh is an important factor to survival of neural crest cells, suggesting a role for RIC-8B downstream of the SHH signaling