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Clinical implications of induced pluripotent stem (iPS) cell technology are enormous for personalized medicine. However,extensive use of viral approach for ectopic expression of reprogramming factors is a major hurdle in realization of its true potential. Non-viral methods for making iPS cells,although plausible,are impractical because of high cost. MicroRNAs are important cellular modulators that have been shown to rival transcription factors and are important players in embryonic development. We have generated distinct microRNA-omes" signature of iPS cells that remain in a near embryonic stem (ES) cell state and distinct from differentiated cells. Recent advances in the microRNA field and experimentally validated microRNAs warrant a review in experimental protocols for microRNA expression profile." View Publication

Current evidence suggests that much like leukemia,breast tumors are maintained by a small subpopulation of tumor cells that have stem cell properties. These cancer stem cells are envisaged to be responsible for tumor formation and relapse. Therefore,knowledge about their nature will provide a platform to develop therapies to eliminate these breast cancer stem cells. This concept highlights the need to understand the mechanisms that regulate the normal functions of the breast stem cells and their immediate progeny as alterations to these same mechanisms can cause these primitive cells to act as cancer stem cells. The study of the primitive cell functions relies on the ability to isolate them from primary sources of breast tissue. This chapter describes processing of discarded tissue from reduction mammoplasty samples as sources of normal primary human breast epithelial cells and describes cell culture systems to grow single-cell suspensions prepared from these reduction samples in vitro. View Publication

We report for the first time a microdevice that enables the selective enrichment,culture,and identification of tumor-initiating cells on native polydimethylsiloxane (PDMS). For nearly a decade,researchers have identified tumor-initiating breast cancer cells within heterogeneous populations of breast cancer cells by utilizing low-attachment serum-free culture conditions,which lead to the formation of spheroidal colonies (mammospheres) that are enriched for tumor-initiating cells. However,the utility of this assay has been limited by difficulties in combining this culture-plate-based technique with other cellular and molecular analyses. Integrating the mammosphere technique into a microsystem can enable it to be combined directly with a number of functions,such as cell sorting,drug screens,and molecular assays. In this work,we demonstrate mammosphere culture within a PDMS microdevice. We first prove that a native hydrophobic PDMS surface is as effective as commercial low-attachment plates at selectively promoting the formation of mammospheres. We then experimentally assess the PDMS microdevice. Time-lapse images of mammosphere formation within the microdevice show that mammospheres form from single cells or small clusters of cells. Following formation of the mammospheres,it is desirable to evaluate the cells within the spheroids for enrichment of tumor initiating cells. To perform assays such as this (which require the loading and rinsing of reagents) without flushing the cells (which are in suspension) from the device,the culture chamber is separated from a reagent reservoir by a commercially available microporous membrane,and thus reagents are exchanged between the reservoir and the culture chamber by diffusion only. Using this capability,we verify that the mammospheres are enriched for tumor initiating cells by staining aldehyde dehydrogenase activity,a cancer stem cell marker. To the best of our knowledge,this is the first assay that enables the direct observation of tumor-initiating cells within a suspended mammosphere. View Publication

ATP citrate lyase (ACL) knockdown (KD) causes tumor suppression and induces differentiation. We have previously reported that ACL KD reverses epithelial-mesenchymal transition (EMT) in lung cancer cells. Because EMT is often associated with processes that induce stemness,we hypothesized that ACL KD impacts cancer stem cells. By assessing tumorsphere formation and expression of stem cell markers,we showed this to be the case in A549 cells,which harbor a Ras mutation,and in two other non-small-cell lung cancer cell lines,H1975 and H1650,driven by activating EGFR mutations. Inducible ACL KD had the same effect as stable ACL KD. Similar effects were noted in another well-characterized Ras-induced mammary model system (HMLER). Moreover,treatment with hydroxycitrate phenocopied the effects of ACL KD,suggesting that the enzymatic activity of ACL was critical. Indeed,acetate treatment reversed the ACL KD phenotype. Having previously established that ACL KD impacts signaling through the phosphatidylinositol 3-kinase (PI3K) pathway,not the Ras-mitogen-activated protein kinase (MAPK) pathway,and that EMT can be reversed by PI3K inhibitors,we were surprised to find that stemness in these systems was maintained through Ras-MAPK signaling,and not via PI3K signaling. Snail is a downstream transcription factor impacted by Ras-MAPK signaling and known to promote EMT and stemness. We found that snail expression was reduced by ACL KD. In tumorigenic HMLER cells,ACL overexpression increased snail expression and stemness,both of which were reduced by ACL KD. Furthermore,ACL could not initiate either tumorigenesis or stemness by itself. ACL and snail proteins interacted and ACL expression regulated the transcriptional activity of snail. Finally,ACL KD counteracted stem cell characteristics induced in diverse cell systems driven by activation of pathways outside of Ras-MAPK signaling. Our findings unveil a novel aspect of ACL function,namely its impact on cancer stemness in a broad range of genetically diverse cell types. View Publication

The association between type 2 diabetes (T2D) pathogenesis and immune-mediated tissue damage and insulin resistance suggests that T2D patients might benefit from the suppression of pathogenic inflammation. Foxp3+ Treg cells are crucial suppressors of inflammation,but the differentiation of Foxp3+ Treg cells is not static and is subject to conversion into IL-17-producing Th17-like cells upon receiving external signals. In this study,we examined the production of IL-17 by Treg cells. Compared to non-T2D controls,T2D patients presented significantly higher levels of IL-17-expressing cells in both Foxp3- CD4 T cells and Foxp3+ Treg cells. The frequencies of IL-17-nonexpressing Foxp3+ Treg cells,on the other hand,were not changed. Interestingly,IL-17-expressing Foxp3+ Treg cells were mutually exclusive from IL-10-expressing and TGF-$\beta$-expressing Foxp3+ Treg cells,suggesting that multiple subpopulations exist within the Foxp3+ Treg cells from T2D patients. In T2D patients,the frequencies of IL-17-expressing Foxp3+ Treg cells were positively correlated with the body mass index (BMI) and the HbA1c levels of T2D patients. The frequencies of IL-10-expressing Treg cells,on the other hand,were inversely associated with the BMI of both non-T2D controls and T2D patients. In addition,the suppressive activity of Treg cells was significantly lower in T2D patients than in non-T2D controls. Together,our study uncovered a dysregulation in Foxp3+ Treg cells from T2D patients,characterized by high IL-17 expression and low suppression activity. View Publication

The selection of cells that have acquired a desired gene edit is often done by the introduction of additional genes that confer drug resistance or encode fluorophores. However,such marker genes can have unintended physiological effects and are not compatible with editing of single nucleotides. Here,we present SNIPE,a method that allows the marker-free selection of edited cells based on single nucleotide differences to unedited cells. SNIPE drastically enriches for cells,which have been precisely edited (median 7-fold). We validate the approach for 42 different edits using Cas9 or Cas12a in different cell types and species. We use it to enrich for combinations of substitutions that change missense mutations carried by all people today back to the ancestral state seen in Neandertals and Denisovans. We also show that it can be used to kill cultured tumor cells with aberrant genotypes and to repair heterozygous tumorigenic mutations. Genome editing often requires marker genes for selection of edited cells. Here,the authors present SNIPE,a marker-free method that selects cells based on DNA sequence,enabling precise enrichment of edited cells and applications from evolutionary research to the elimination of cancer cells. View Publication

AbstractIntroductionNovel strategies are needed to address the rising burden of osteoporosis and fragility fractures. High-intensity resistance and impact (HiRIT) exercise has shown benefit in improving bone density in postmenopausal women with osteoporosis/osteopenia. Whether HiRIT can enhance the therapeutic effects of osteoporosis pharmacotherapy has not been established. ROLEX-DUO is a randomised controlled trial designed to assess the efficacy of romosozumab on various bone and muscle outcomes in combination with different exercise interventions in women with postmenopausal osteoporosis/osteopenia.Methods and analysisROLEX-DUO is an 8-month randomised placebo-controlled trial conducted at two tertiary referral centres for patients with osteoporosis/osteopenia in Sydney,New South Wales,Australia. The study is implementing the combination of romosozumab or placebo with different forms of exercise in postmenopausal women with osteoporosis/osteopenia without recent fragility fracture (n=102). Eligible women will be randomised 1:1:1 into one of three groups: (1) romosozumab with supervised HiRIT,(2) romosozumab with unsupervised low-intensity exercise or (3) placebo with unsupervised low-intensity exercise. Co-primary outcomes are the mean percentage change in lumbar spine bone mineral density (BMD),and mean change in five times sit-to-stand test performance (seconds) at 8 months. Secondary/exploratory outcomes include BMD changes at the femoral neck,total hip and distal radius,three-dimensional dual-energy X-ray absorptiometry (DXA) hip outcomes,DXA-derived lean and fat mass,serum markers of bone turnover (procollagen type 1 peptide,C-telopeptide of type 1 collagen) and bone biomarkers (dickkopf-1),serum extracellular vesicle analyses,36-Item Short Form Survey (SF-36) quality-of-life scores,Menopause-Specific Quality Of Life (MENQOL) Questionnaire menopause symptom burden scores,number of falls and fractures. Mixed-effects models will be performed to compare longitudinal outcome results between groups using intention-to-treat analysis.Ethics and disseminationThe trial was approved by the Northern Sydney Local Health District Human Research Ethics Committee (2022/ETH01794,protocol V.8,dated 03 July 2024). Participants will provide written informed consent prior to inclusion. Findings will be disseminated via peer-reviewed journals,scientific conferences and summary reports to funding bodies.Trial registration numberACTRN12623000867695. View Publication

Differentiation of totipotent mouse embryonic stem (ES) cells to various lymphohematopoietic cells is an in vitro model of the hematopoietic cell development during embryogenesis. To understand this process at cellular levels,differentiation intermediates were investigated. ES cells generated progeny expressing CD34,which was significantly enhanced by vascular endothelial growth factor (VEGF). The isolated CD34+ cells were enriched for myeloid colony-forming cells but not significantly for erythroid colony-forming cells. When cultured on OP9 stroma cells in the presence of interleukin-2 and interleukin-7,the CD34+ cells developed two types of B220+ CD34- lymphocytes: CD3- cytotoxic lymphocytes and CD19+ pre-B cells,and such lymphoid potential was highly enriched in the CD34+ population. Interestingly,the cytotoxic cells expressed the natural killer (NK) cell markers,such as NKR-P1,perforin,and granzymes,classified into two types,one of which showed target specificity of NK cells. Thus,ES cells have potential to generate NK-type cytotoxic lymphocytes in vitro in addition to erythro-myeloid cells and pre-B cells,and both myeloid and lymphoid cells seem to be derived from the CD34+ intermediate,on which VEGF may play an important role. View Publication

INTRODUCTION Bone marrow mesenchymal stem cells (BMSCs) have been extensively investigated from a perspective on cardiac regeneration therapy. The current study aimed to investigate the protective effect conferred by BMSCs in subacute myocardial injury,and to identify an appropriate BMSC reinfusion time. METHODS BMSCs were isolated from human bone marrow blood. Daunorubicin (DNR)-induced subacute myocardial models were subsequently established. The rats with DNR-induced subacute myocardial injury were injected with dexrazoxane (DZR) and/or BMSCs at varying time points,after which cardiac function was evaluated by assessing left ventricular ejection fraction (LVEF) and fraction shortening (FS). The myocardial structural changes were analyzed,after which the levels of CD3 and human leukocyte antigen DR (HLA-DR) were examined to further validate the mechanism by which BMSCs could influence subacute myocardial injury. RESULTS BMSCs combined with DZR treatment enhanced the cardiac function of rats with DNR-induced myocardial injury,as reflected by increased LVEF and FS. DNR-induced myocardial injuries were mitigated via the application of BMSCs combined with treatment of DZR,accompanied by diminished infiltration or vacuolization. Moreover,BMSCs were observed to alleviate infiltration of T lymphocyte and antigen-presenting cells,as evidenced by reduced expression of CD3 and HLA-DR. CONCLUSION Taken together,this study demonstrates that BMSCs could protect against DNR-induced myocardial injury,especially in the first three days of DNR administration. BMSCs combined with DZR exert a better therapeutic effect,but there are individual differences. View Publication

Autologous feeder cells have been developed by various methods to minimize the presence of xenogenic entities in human embryonic stem cell (hESC) cultures. However,there was no systematic comparison of supportive effects of the feeder cells on hESC growth,nor comparison to the supportive effects of various feeder-free culture systems and standard mouse feeder cells. In this study,we aimed to compare the supportive abilities of autologous feeders derived either directly from H9 hESCs (H9 dF) or from outgrowth of embryoid body predifferentiated in suspension from H9 hESCs (H9 ebF). Mouse feeder system and matrigel-mTeSR1 feeder-free system were used as controls. H9 ebF was found to secrete more basic fibroblast growth factor in the conditioned medium than H9 dF did. The undifferentiated state of H9 hESCs was sustained more stably on H9 ebF than on H9 dF,and the differentiation potential of H9 hESCs on H9 ebF was higher than on H9 dF. We concluded that H9 ebF was an optimal autologous feeder to maintain the long-term undifferentiated state of hESCs in our current culture system. This study helps to standardize the autologous culture of hESCs. It also suggests a more definite direction for future development of xeno-free culture system for hESCs. View Publication