Association between KRAS and PIK3CA Mutations and Progesterone Resistance in Endometriotic Epithelial Cell Line.

Although endometriosis is a benign disease, it is associated with cancer-related gene mutations, such as KRAS or PIK3CA. Endometriosis is associated with elevated levels of inflammatory factors that cause severe pain. In a previous study, we demonstrated that KRAS or PIK3CA mutations are associated with the activation of cell proliferation, migration, and invasion in a patient-derived immortalized endometriotic cell line, HMOsisEC10. In this study, we investigated the effects of these mutations on progesterone resistance. Since the HMOsisEC10 had suppressed progesterone receptor (PR) expression, we transduced PR-B to HMOsisEc10 cell lines including KRAS mutant and PIK3CA mutant cell lines. We conducted a migration assay, invasion assay, and MTT assay using dienogest and medroxyprogestrone acetate. All cell lines showed progesterone sensitivity with or without mutations. Regarding inflammatory factors, real-time quantitative RT-PCR revealed that the KRAS mutation cell line exhibited no suppression of Cox-2 and mPGES-1 on progesterone treatment, whereas IL-6, MCP-1, VEGF, and CYP19A1 were significantly suppressed by progesterone in both mutated cell lines. Our results suggest that KRAS mutation and PIK3CA mutation in endometriotic cells may not be associated with progesterone resistance in terms of aggressiveness. However, KRAS mutations may be associated with progesterone resistance in the context of pain.

Transcriptome-wide profiling for melanocytes derived from newborn and adult human epidermis with enhanced proliferation.

The senescence-associated protein p16INK4A acts as a limiter element in cell-cycle progression. The loss of p16INK4A function is causally related to cellular immortalization. The increase in p16INK4A levels with advancing age was demonstrated in melanocytes. However, the characteristic difference between young and senescent melanocytes affecting immortalization of melanocytes remains unclear. In this study, we generated 10 different cell lines in total from newborn (NB) and adult (AD) primary normal human epidermal melanocytes (NHEM) using four different methods, transduction of CDK4R24C and cyclin D1 (K4D), K4D with TERT (K4DT), SV40 T-antigen (SV40T), and HPV16 E6 and E7 (E6/E7) and performed whole transcriptome sequencing analysis (RNA-Seq) to elucidate the differences of genome-wide expression profiles among cell lines. The analysis data revealed distinct differences in expression pattern between cell lines from NB and AD although no distinct biological differences were detected in analyses such as comparison of cell morphology, evaluation of cell proliferation, and cell cycle profiles. This study may provide useful in vitro models to benefit the understanding of skin-related diseases.

Controlled cell proliferation and immortalization of human dental pulp stem cells with a doxycycline-inducible expression system.

Human dental pulp stem cells are a potentially useful resource for cell-based therapies and tissue repair in dental and medical applications. However, the primary culture of isolated dental pulp stem cells has notably been limited. A major requirement of an ideal human dental pulp stem cell culture system is the preservation of efficient proliferation and innate stemness over prolonged passaging, while also ensuring ease of handling through standard, user-friendly culture methods. In this study, we have engineered a novel human dental pulp stem cell line, distinguished by the constitutive expression of telomerase reverse transcriptase (TERT), and the conditional expression of the R24C mutant cyclin-dependent kinase 4 (CDK4R24C) and Cyclin D1. We have named this cell line Tet-off K4DT hDPSCs. Furthermore, we have conducted a comprehensive comparative analysis of their biological attributes in relation to a previously immortalized human dental pulp stem cells, hDPSC-K4DT, which were immortalized by the constitutive expression of CDK4R24C, Cyclin D1 and TERT. In Tet-off K4DT cells, the expression of the K4D genes can be precisely suppressed by the inclusion of doxycycline. Remarkably, Tet-off K4DT cells demonstrated an extended cellular lifespan, increased proliferative capacity, and enhanced osteogenic differentiation potential when compared to K4DT cells. Moreover, Tet-off K4DT cells had no observable genomic aberrations and also displayed a sustained expression of stem cell markers even at relatively advanced passages. Taken together, the establishment of this new cell line holds immense promise as powerful experimental tool for both fundamental and applied research involving dental pulp stem cells.

Characterizing the toxicological responses to inorganic arsenicals and their metabolites in immortalized human bladder epithelial cells.

Arsenic is highly toxic to the human bladder. In the present study, we established a human bladder epithelial cell line that closely mimics normal human bladder epithelial cells by immortalizing primary uroplakin 1B-positive human bladder epithelial cells with human telomerase reverse transcriptase (HBladEC-T). The uroplakin 1B-positive human bladder epithelial cell line was then used to evaluate the toxicity of seven arsenicals (iAsV, iAsIII, MMAV, MMAIII, DMAV, DMAIII, and DMMTAV). The cellular uptake and metabolism of each arsenical was different. Trivalent arsenicals and DMMTAV exhibited higher cellular uptake than pentavalent arsenicals. Except for MMAV, arsenicals were transported into cells by aquaglyceroporin 9 (AQP9). In addition to AQP9, DMAIII and DMMTAV were also taken up by glucose transporter 5. Microarray analysis demonstrated that arsenical treatment commonly activated the NRF2-mediated oxidative stress response pathway. ROS production increased with all arsenicals, except for MMAV. The activating transcription factor 3 (ATF3) was commonly upregulated in response to oxidative stress in HBladEC-T cells: ATF3 is an important regulator of necroptosis, which is crucial in arsenical-induced bladder carcinogenesis. Inorganic arsenics induced apoptosis while MMAV and DMAIII induced necroptosis. MMAIII, DMAV, and DMMTAV induced both cell death pathways. In summary, MMAIII exhibited the strongest cytotoxicity, followed by DMMTAV, iAsIII, DMAIII, iAsV, DMAV, and MMAV. The cytotoxicity of the tested arsenicals on HBladEC-T cells correlated with their cellular uptake and ROS generation. The ROS/NRF2/ATF3/CHOP signaling pathway emerged as a common mechanism mediating the cytotoxicity and carcinogenicity of arsenicals in HBladEC-T cells.

Increased lentivirus titer using ultra expression vectors.

Lentivirus is an efficient gene transfer system that is widely used in basic science. We aimed to improve viral titer by applying an ultra-expression vectors to lentiviral packaging. Application of the ultra-expression vectors increased biological titer 4 times for standard preparation. We also evaluated the efficacy of the ultra-expression vectors to relatively longer insert fragments, such as CSII-CMV-CNROE containing 5 genes in multiple cloning sites. Packaging of the ultra-expression vectors showed 3.5 times higher biological titer compared with the original method. Our improved packaging system could be applied to lentivirus to produce higher titers.

Downregulating vaccinia-related kinase 1 by luteolin suppresses ovarian cancer cell proliferation by activating the p53 signaling pathway.

OBJECTIVES: Ovarian cancer constitutes one of the most common causes of cancer-related deaths, and preventing chemotherapy resistance and recurrence in patients with ovarian cancer remains a challenge. Herein, we aimed to identify the effect of luteolin, a novel therapeutic agent targeting vaccinia-related kinase 1 (VRK1), on high-grade serous ovarian cancer (HGSOC). METHODS: Phosphokinase array, RNA sequencing, and cell cycle and apoptosis assays were conducted to determine the underlying mechanism of the effect of luteolin on HGSOC cells. The anticancer effects of oral and intraperitoneal luteolin administration were assessed in patient-derived xenograft models via several methods, including the assessment of tumor size and immunohistochemistry of phospho-p53, phosphor-HistoneH3 and cleaved caspase 3. RESULTS: Luteolin reduced HGSOC cell proliferation and increased apoptosis and cell cycle arrest at G2/M. Compared with controls, several genes were dysregulated in luteolin-treated cells, and luteolin activated the p53 signaling pathway. The human phosphokinase array revealed distinct p53 upregulation in luteolin-treated cells, as confirmed by p53 phosphorylation at ser15 and ser46 using western blot analysis. In patient-derived xenograft models, oral or intraperitoneal luteolin administration substantially suppressed tumor growth. Moreover, combination treatment involving luteolin and cisplatin inhibited tumor cell proliferation, especially in cisplatin-resistant HGSOC cell lines. CONCLUSIONS: Luteolin demonstrated considerable anticancer effect on HGSOC cells, reduced VRK1 expression, and activated the p53 signaling pathway, thereby inducing apoptosis and cell cycle arrest in G2/M and inhibiting cell proliferation. Furthermore, luteolin exhibited a synergistic effect with cisplatin both in vivo and in vitro. Thus, luteolin can be considered a promising cotreatment option for HGSOC.

Sheep-derived cell immortalization through the expression of cell cycle regulators and biological characterization using transcriptomes.

Sheep are important domestic animals for the production of wool and meat. Although numerous cultured cell lines from humans and mice have been established, the number of cell lines derived from sheep is limited. To overcome this issue, the efficient establishment of a sheep-derived cell line and its biological characterization is reported. Mutant cyclin-dependent kinase 4, cyclin D1, and telomerase reverse transcriptase were introduced into sheep muscle-derived cells in an attempt to immortalize primary cells using the K4DT method. Furthermore, the SV40 large T oncogene was introduced into the cells. The successful immortalization of sheep muscle-derived fibroblasts was shown using the K4DT method or SV40 large T antigen. Furthermore, the expression profile of established cells showed close biological characteristics of ear-derived fibroblasts. This study provides a useful cellular resource for veterinary medicine and cell biology.

Development of an in vitro carcinogenesis model of human papillomavirus-induced cervical adenocarcinoma.

Cervical adenocarcinoma (ADC) is the second most common pathological subtype of cervical cancer after squamous cell carcinoma. It accounts for approximately 20% of cervical cancers, and the incidence has increased in the past few decades, particularly among young patients. The persistent infection of high-risk human papillomavirus (HPV) is responsible for most cervical ADC. However, almost all available in vitro models are designed to study the carcinogenesis of cervical squamous cell carcinoma. To gain better insights into molecular background of ADC, we aimed to establish an in vitro carcinogenesis model of ADC. We previously reported the establishment of an in vitro model for cervical squamous cell carcinoma by introducing defined viral and cellular oncogenes, HPV16 E6 and E7, c-MYC, and activated RAS to human cervical keratinocytes. In this study, the expression of potential lineage-specifying factors and/or SMAD4 reduction was introduced in addition to the defined four oncogenes to direct carcinogenesis toward ADC. The cell properties associated with the cell lineage were analyzed in monolayer and organoid cultures and the tumors in mouse xenografts. In the cells expressing Forkhead box A2 (FOXA2), apparent changes in cell properties were observed, such as elevated expression of columnar cell markers and decreased expression of squamous cell markers. Strikingly, the histopathology of tumors expressing FOXA2 resembled cervical ADC, proposing that FOXA2 plays a vital role in dictating the histopathology of cervical cancers.

Relationship of DUX4 and target gene expression in FSHD myocytes.

Facioscapulohumeral dystrophy (FSHD) is associated with the upregulation of the DUX4 transcription factor and its target genes. However, low-frequency DUX4 upregulation in patient myocytes is difficult to detect and examining the relationship and dynamics of DUX4 and target gene expression has been challenging. Using RNAScope in situ hybridization with highly specific probes, we detect the endogenous DUX4 and target gene transcripts in situ in patient skeletal myotubes during 13-day differentiation in vitro. We found that the endogenous DUX4 transcripts primarily localize as foci in one or two nuclei as compared with the accumulation of the recombinant DUX4 transcripts in the cytoplasm. We also found the continuous increase of DUX4 and target gene-positive myotubes after Day 3, arguing against its expected immediate cytotoxicity. Interestingly, DUX4 and target gene expression become discordant later in differentiation with the increase of DUX4-positive/target gene-negative as well as DUX4-negative/target gene-positive myotubes. Depletion of DUX4-activated transcription factors, DUXA and LEUTX, specifically repressed a DUX4-target gene, KDM4E, later in differentiation, suggesting that after the initial activation by DUX4, target genes themselves contribute to the maintenance of downstream gene expression. Together, the study provides important new insights into the dynamics of the DUX4 transcriptional network in FSHD patient myocytes.

SAA1 is upregulated in gastric cancer-associated fibroblasts possibly by its enhancer activation.

Cancer-associated fibroblasts (CAFs) tend to have tumor-promoting capacity, and can provide therapeutic targets. Even without cancer cells, CAF phenotypes are stably maintained, and DNA methylation and H3K27me3 changes have been shown to be involved. Here, we searched for a potential therapeutic target in primary CAFs from gastric cancer and a mechanism for its dysregulation. Expression microarray using eight CAFs and seven non-CAFs (NCAFs) revealed that serum amyloid A1 (SAA1), which encodes an acute phase secreted protein, was second most upregulated in CAFs, following IGF2. Conditioned medium (CM) derived from SAA1-overexpressing NCAFs was shown to increase migration of gastric cancer cells compared with that from control NCAFs, and its tumor-promoting effect was comparable to that of CM from CAFs. In addition, increased migration of cancer cells by CM from CAFs was mostly canceled with CM from CAFs with SAA1 knockdown. Chromatin immunoprecipitation (ChIP)-quantitative PCR showed that CAFs had higher levels of H3K27ac, an active enhancer mark, in the promoter and the two far upstream regions of SAA1 than NCAFs. Also, BET bromodomain inhibitors, JQ1 and mivebresib, decreased SAA1 expression and tumor-promoting effects in CAFs, suggesting SAA1 upregulation by enhancer activation in CAFs. Our present data showed that SAA1 is a candidate therapeutic target from gastric CAFs and indicated that increased enhancer acetylation is important for its overexpression.

Roles for E1-independent replication and E6-mediated p53 degradation during low-risk and high-risk human papillomavirus genome maintenance.

Human papillomaviruses (HPV) have genotype-specific disease associations, with high-risk alpha types causing at least 5% of all human cancers. Despite these conspicuous differences, our data show that high- and low- risk HPV types use similar approaches for genome maintenance and persistence. During the maintenance phase, viral episomes and the host cell genome are replicated synchronously, and for both the high- and low-risk HPV types, the E1 viral helicase is non-essential. During virus genome amplification, replication switches from an E1-independent to an E1-dependent mode, which can uncouple viral DNA replication from that of the host cell. It appears that the viral E2 protein, but not E6 and E7, is required for the synchronous maintenance-replication of both the high and the low-risk HPV types. Interestingly, the ability of the high-risk E6 protein to mediate the proteosomal degradation of p53 and to inhibit keratinocyte differentiation, was also seen with low-risk HPV E6, but in this case was regulated by cell density and the level of viral gene expression. This allows low-risk E6 to support genome amplification, while limiting the extent of E6-mediated cell proliferation during synchronous genome maintenance. Both high and low-risk E7s could facilitate cell cycle re-entry in differentiating cells and support E1-dependent replication. Despite the well-established differences in the viral pathogenesis and cancer risk, it appears that low- and high-risk HPV types use fundamentally similar molecular strategies to maintain their genomes, albeit with important differences in their regulatory control. Our results provide new insights into the regulation of high and low-risk HPV genome replication and persistence in the epithelial basal and parabasal cells layers. Understanding the minimum requirement for viral genome persistence will facilitate the development of therapeutic strategies for clearance.

Three newly established immortalized mesothelial cell lines exhibit morphological phenotypes corresponding to malignant mesothelioma epithelioid, intermediate, and sarcomatoid types, respectively.

BACKGROUND: Malignant mesothelioma (MM) is a very aggressive tumor that develops from mesothelial cells, mainly due to asbestos exposure. MM is categorized into three major histological subtypes: epithelioid, sarcomatoid, and biphasic, with the biphasic subtype containing both epithelioid and sarcomatoid components. Patients with sarcomatoid mesothelioma usually show a poorer prognosis than those with epithelioid mesothelioma, but it is not clear how these morphological phenotypes are determined or changed during the oncogenic transformation of mesothelial cells. METHODS: We introduced the E6 and E7 genes of human papillomavirus type 16 and human telomerase reverse transcriptase gene in human peritoneal mesothelial cells and established three morphologically different types of immortalized mesothelial cell lines. RESULTS: HOMC-B1 cells exhibited epithelioid morphology, HOMC-A4 cells were fibroblast-like, spindle-shaped, and HOMC-D4 cells had an intermediate morphology, indicating that these three cell lines closely mimicked the histological subtypes of MM. Gene expression profiling revealed increased expression of NOD-like receptor signaling-related genes in HOMC-A4 cells. Notably, the combination treatment of HOMC-D4 cells with TGF-ß and IL-1ß induced a morphological change from intermediate to sarcomatoid morphology. CONCLUSIONS: Our established cell lines are useful for elucidating the fundamental mechanisms of mesothelial cell transformation and mesothelial-to-mesenchymal transition.

Striated myocyte structural integrity: Automated analysis of sarcomeric z-discs.

As sarcomeres produce the force necessary for contraction, assessment of sarcomere order is paramount in evaluation of cardiac and skeletal myocytes. The uniaxial force produced by sarcomeres is ideally perpendicular to their z-lines, which couple parallel myofibrils and give cardiac and skeletal myocytes their distinct striated appearance. Accordingly, sarcomere structure is often evaluated by staining for z-line proteins such as α-actinin. However, due to limitations of current analysis methods, which require manual or semi-manual handling of images, the mechanism by which sarcomere and by extension z-line architecture can impact contraction and which characteristics of z-line architecture should be used to assess striated myocytes has not been fully explored. Challenges such as isolating z-lines from regions of off-target staining that occur along immature stress fibers and cell boundaries and choosing metrics to summarize overall z-line architecture have gone largely unaddressed in previous work. While an expert can qualitatively appraise tissues, these challenges leave researchers without robust, repeatable tools to assess z-line architecture across different labs and experiments. Additionally, the criteria used by experts to evaluate sarcomeric architecture have not been well-defined. We address these challenges by providing metrics that summarize different aspects of z-line architecture that correspond to expert tissue quality assessment and demonstrate their efficacy through an examination of engineered tissues and single cells. In doing so, we have elucidated a mechanism by which highly elongated cardiomyocytes become inefficient at producing force. Unlike previous manual or semi-manual methods, characterization of z-line architecture using the metrics discussed and implemented in this work can quantitatively evaluate engineered tissues and contribute to a robust understanding of the development and mechanics of striated muscles.

Endogenous YAP1 activation drives immediate onset of cervical carcinoma in situ in mice.

Cervical cancer (CC) is usually initiated by infection with high-risk types of human papillomavirus (HPV). The HPV E6 and E7 proteins target p53 and RB, respectively, but other cellular targets likely exist. We generated uterus-specific MOB1A/B double KO (uMob1DKO) mice, which immediately developed cervical squamous cell carcinoma in situ. Mutant cervical epithelial cells showed YAP1-dependent hyperproliferation, altered self-renewal, impaired contact inhibition, and chromosomal instability. p53 activation was increased in uMob1DKO cells, and additional p53 loss in uMob1DKO mice accelerated tumor invasion. In human CC, strong YAP1 activation was observed from the precancerous stage. Human cells overexpressing HPV16 E6/E7 showed inactivation of not only p53 and RB but also PTPN14, boosting YAP1 activation. Estrogen, cigarette smoke condensate, and PI3K hyperactivation all increased YAP1 activity in human cervical epithelial cells, and PTPN14 depletion along with PI3K activation or estrogen treatment further enhanced YAP1. Thus, immediate CC onset may initiate when YAP1 activity exceeds an oncogenic threshold, making Hippo-YAP1 signaling a major CC driver.

Cell-type specific tumorigenesis with Ras oncogenes in human lung epithelial cells.

The oncogenic Ras mutation is one of the most common genomic abnormalities having the highest incidence in cancer; it has three isoforms: Hras, Kras, and Nras. Although the Ras isoforms are highly similar in the primary sequence, each mutational frequency is clearly distinct according to tissue- or cell-type. Regarding non-small-cell lung carcinoma, almost all Kras mutations have been detected in lung adenocarcinoma, whereas lung squamous cell carcinoma is extremely rare. Here, we focus on the cell-type specific tumorigenesis of mutant Ras isoforms and determine the mechanisms of oncogenic signaling outputs between lung adenocarcinoma and squamous cell carcinoma. An in vitro transformation model with mutant Ras isoforms in immortalized bronchial epithelial cells (BEC-E6E7/myc) and immortalized small airway epithelial cells (SAEC-E6E7/myc) revealed that only the HrasG12V mutation, not the KrasG12V mutation, could induce tumorigenesis in BEC-E6E7/myc. In contrast, SAEC-E6E7/myc showed high sensitivity to the KrasG12V mutation compared with the HrasG12V mutation. The transformation of BEC-E6E7/myc and SAEC-E6E7/myc with mutant Ras isoforms was confirmed by soft agar assay and migration assay. HrasG12V-expressing BEC-E6E7/myc significantly increased MAPK/ERK signaling, whereas PI3K/AKT signaling was significantly elevated in KrasG12V-expressing SAEC-E6E7/myc. These results suggest a context dependency with oncogenic Ras mutations in tumorigenesis between lung adenocarcinoma and squamous cell carcinoma.

A novel CDK-independent function of p27Kip1 in preciliary vesicle trafficking during ciliogenesis.

p27Kip1, a member of the Cip/Kip family of cyclin-dependent kinase (CDK) inhibitors, is now known as a multifunctional protein that plays crucial roles in cell architecture and migration by regulating rearrangements of the actin cytoskeleton and microtubules. The intracellular level of p27Kip1 is increased by anti-proliferative stimuli, such as mitogen deprivation and contact inhibition, which also induce formation of primary cilia, microtubule-based membranous organelles that protrude from the cell surface. However, it remains unknown whether p27Kip1 is associated with ciliogenesis. Here, we have generated p27Kip1-knockout hTERT-immortalized human retinal pigment epithelial cells, and found that ciliogenesis is almost completely disrupted in p27Kip1-knockout cells. The defect of ciliogenesis is rescued by the exogenous expression of wild-type p27Kip1 and, surprisingly, its 86-140 amino acid region, which is neither responsible for CDK inhibition nor remodeling of the actin cytoskeleton and microtubules. Moreover, transmission electron microscopy and immunofluorescence analyses reveal that p27Kip1 abrogation impairs one of the earliest events of ciliogenesis, docking of the Ehd1-associated preciliary vesicles to the distal appendages of the basal body. Our findings identify a novel CDK-independent function of p27Kip1 in primary cilia formation.

Primary and immortalized cell lines derived from the Amami rabbit (Pentalagus furnessi) and evolutionally conserved cell cycle control with CDK4 and Cyclin D1.

The Amami rabbit (Pentagulus furnessi) is a dark brown-furred rabbit classified as an endangered species and only found in the Amami Islands of Japan. They are often called living fossils because they retain primitive characteristics of ancient rabbits that lived approximately 1 million years ago, such as short feet and hind legs and small ears. Although the ancient rabbit has disappeared due to the competition with European rabbit (Oryctolagus cuniculus) in the most of the Asian area, Amami rabbit survived since Amami Islands has isolated from Japan and Taiwan. Although Amari rabbit is one of the protected animals, their population decreases each year due to human activities, such as deforestation and roadkill. In this study, we collected roadkill samples of Amami rabbits and established primary and immortalized fibroblast cell lines. Combined expression of human-derived mutant Cyclin-dependent kinase 4, Cyclin D1, and hTERT allowed us to immortalize fibroblasts successfully in three individuals of Amami rabbits. The immortalized fibroblasts dramatically extended the cell culture period, when it was compared with the cell culture period of wild type cells. Furthermore, the immortalized cells maintained their normal chromosomal pattern (2n = 46). Our results suggest that cellular senescence which mainly regulated by p16-RB signaling pathway is conserved in animal evolution at least from 1 million years ago.

Extended proliferation of chicken- and Okinawa rail-derived fibroblasts by expression of cell cycle regulators.

Although immortalized cultured cells are useful for various functional assays or transcriptome analysis, highly efficient and reproducible immortalization methods have not been developed in avian-derived cells. We introduced the simian virus 40 T antigen (SV40T) and human papillomavirus (HPV)-E6E7 to chick and Okinawa rail (endangered species)derived fibroblast. As a result, neither the SV40T nor E6E7 genes could induce avian cell immortality. Accordingly, we attempted to use a recently developed immortalization method, which involved the coexpression of mutant cyclin-dependent kinase 4 (CDK4), Cyclin D, and TERT (K4DT method) in these avian cells. Although the K4DT method could not efficiently induce the efficient immortalization in mass cell population, cellular division until the senescence was significantly extended by K4DT, we succeeded to obtain the immortalized avian cells (chick K4DT: one clone, Okinawa rail K4DT: three clones, Okinawa rail K4DT + telomerase RNA component: one clone) with K4DT expression. We conclude that K4DT expression is used to extend the cell division and immortalization of avian-derived cells.

Autonomous trisomic rescue of Down syndrome cells.

Down syndrome is the most frequent chromosomal abnormality among live-born infants. All Down syndrome patients have mental retardation and are prone to develop early onset Alzheimer's disease. However, it has not yet been elucidated whether there is a correlation between the phenotype of Down syndrome and the extra chromosome 21. In this study, we continuously cultivated induced pluripotent stem cells (iPSCs) with chromosome 21 trisomy for more than 70 weeks, and serendipitously obtained revertant cells with normal chromosome 21 diploids from the trisomic cells during long-term cultivation. Repeated experiments revealed that this trisomy rescue was not due to mosaicism of chromosome 21 diploid cells and occurred at an extremely high frequency. We herewith report the spontaneous correction from chromosome 21 trisomy to disomy without genetic manipulation, chemical treatment or exposure to irradiation. The revertant diploid cells will possibly serve a reference for drug screening and a raw material of regenerative medicinal products for cell-based therapy.

Albatross/FBF1 contributes to both centriole duplication and centrosome separation.

The centrosome is a small but important organelle that participates in centriole duplication, spindle formation, and ciliogenesis. Each event is regulated by key enzymatic reactions, but how these processes are integrated remains unknown. Recent studies have reported that ciliogenesis is controlled by distal appendage proteins such as FBF1, also known as Albatross. However, the precise role of Albatross in the centrosome cycle, including centriole duplication and centrosome separation, remains to be determined. Here, we report a novel function for Albatross at the proximal ends of centrioles. Using Albatross monospecific antibodies, full-length constructs, and siRNAs for rescue experiments, we found that Albatross mediates centriole duplication by recruiting HsSAS-6, a cartwheel protein of centrioles. Moreover, Albatross participates in centrosome separation during mitosis by recruiting Plk1 to residue S348 of Albatross after its phosphorylation. Taken together, our results show that Albatross is a novel protein that spatiotemporally integrates different aspects of centrosome function, namely ciliogenesis, centriole duplication, and centrosome separation.