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INTRODUCTION Human peripheral blood mononuclear cells (PBMCs) are a heterogeneous population of cells that includes T and B lymphocytes. The total number of lymphocytes and their percentage in the blood can be a marker for the diagnosis of several human diseases. Currently,cytometric methods are widely used to distinguish subtypes of leukocytes and quantify their number. These techniques use cell immunophenotyping,which is limited by the number of fluorochrome-labeled antibodies that can be applied simultaneously. OBJECTIVE B and T lymphocytes were isolated from peripheral blood obtained from healthy human donors. METHODS The immunomagnetic negative selection was used for the enrichment of B and T cells fractions,and their purity was assessed by flow cytometry. Isolated cells were fixed with 0.5% glutaraldehyde and measured using confocal Raman imaging. K-means cluster analysis,principal component analysis and partial least squares discriminant methods were applied for the identification of spectroscopic markers to distinguish B and T cells. HPLC was the reference method for identifying carotene in T cells. RESULTS Reliable discrimination between T and B lymphocytes based on their spectral profile has been demonstrated using label-free Raman imaging and chemometric analysis. The presence of carotene in T lymphocytes (in addition to the previously reported in plasma) was confirmed and for the first time unequivocally identified as $\beta$-carotene. In addition,the molecular features of the lymphocytes nuclei were found to support the discriminant analysis. It has been shown that although the presence of carotenoids in T cells depends on individual donor variability,the reliable differentiation between lymphocytes is possible based on Raman spectra collected from individual cells. CONCLUSIONS This proves the potential of Raman spectroscopy in clinical diagnostics to automatically differentiate between cells that are an important component of our immune system. View Publication

Label-free detection of biological events at single-cell resolution in the brain can non-invasively capture brain status for medical diagnosis and basic neuroscience research. NADH is an universal coenzyme that not only plays a central role in cellular metabolism but may also be used as a biomarker to capture metabolic processes in brain cells and structures. We have developed a new label-free,multiphoton photoacoustic microscope (LF-MP-PAM) with a near-infrared femtosecond laser to observe endogenous NAD(P)H in living cells. The imaging depth of NAD(P)H in tissues with all-optical methods is limited to ~100??m in brain tissue by the strong absorption of the near-ultraviolet fluorescence. Here,acoustic detection of the thermal signature of multi-photon (three-photon) excitation of NAD(P)H,a low quantum yield fluorophore,allows detection at an unprecedented depth while the focused excitation ensures high spatial resolution. We validated the photoacoustic detection of NAD(P)H by monitoring an increase in intracellular NAD(P)H in HEK293T cells and HepG2 cells incubated in NADH solution. We also demonstrated the detection of endogenous NAD(P)H photoacoustic signals in brain slices to 700 ?m depth and in cerebral organoids to 1100 ?m depth. Finally,we developed and demonstrated simultaneous photoacoustic and optical imaging of NAD(P)H in brain cells with a real-time image acquisition and processing pipeline. This approach could open a new door to monitor brain metabolic changes during development and disease,and changes due to neuronal activity,at single-cell level deep in the brains of both humans and animals. Label-free,multiphoton photoacoustic microscope (LF-MP-PAM) with a near-infrared femtosecond laser to observe endogenous NAD(P)H of neurons in brain slices and cerebral organoids. View Publication

Establishing robust models of human myelinating Schwann cells is critical for studying peripheral nerve injury and disease. Stem cell differentiation has emerged as a key human cell model and disease motivating development of Schwann cell differentiation protocols. Human embryonic stem cells (hESCs) are considered the ideal pluripotent cell but ethical concerns regarding their use have propelled the popularity of human induced pluripotent stem cells (hiPSCs). Given that the equivalence of hESCs and hiPSCs remains controversial,we sought to compare the molecular and functional equivalence of hESC- and hiPSC-derived Schwann cells generated with our previously reported protocol. We identified only modest transcriptome differences by RNA sequencing and insignificant proteome differences by antibody array. Additionally,both cell types comparably improved nerve regeneration and function in a chronic denervation and regeneration animal model. Our findings demonstrate that Schwann cells derived from hESCs and hiPSCs with our protocol are molecularly comparable and functionally equivalent. Subject areas: Neuroscience,Cell biology,Stem cells research,Transcriptomics View Publication

The roles of the transcriptional factor SIX2 have been identified in several tumors. However,its roles in gastric cancer (GC) progression have not yet been revealed. Our objective is to explore the impact and underlying mechanisms of SIX2 on the stemness of GC cells. Lentivirus infection was employed to establish stable expression SIX2 or PFN2 in GC cells. Gain- and loss-of-function experiments were conducted to detect changes of stemness markers,flow cytometry profiles,tumor spheroid formation,and tumor-initiating ability. ChIP,RNA-sequencing,tissue microarray,and bioinformatics analysis were performed to reveal the correlation between SIX2 and PFN2. The mechanisms underlying the SIX2/PFN2 loop-mediated effects were elucidated through tissue microarray analysis,RNA stability assay,IP-MS,Co-Immunoprecipitation,and inhibition of the JNK signaling pathway. The stemness of GC cells was enhanced by SIX2. Mechanistically,SIX2 directly bound to PFN2’s promoter and promoted PFN2 activity. PFN2,in turn,promoted the mRNA stability of SIX2 by recruiting RNA binding protein YBX-1,subsequently activating the downstream MAPK/JNK pathway. This study unveils the roles of SIX2 in governing GC cell stemness,defining a novel SIX2/PFN2 regulatory loop responsible for this regulation. This suggests the potential of targeting the SIX2/PFN2 loop for GC treatment (Graphical Abstracts). The online version contains supplementary material available at 10.1186/s12967-024-05618-5. View Publication

Scleroderma (SSc) is an autoimmune connective tissue disease characterized by immune dysregulation,vasculopathy,and fibrosis. We have previously demonstrated that low Fli1 expression in SSc fibroblasts and endothelial cells plays an important role in SSc pathogenesis. Cells of myeloid and lymphoid origin also express Fli1 and are dysregulated in patients with SSc,playing key roles in disease pathogenesis. However,the role for immune Fli1 in SSc is not yet clear. Our aim was to elucidate whether Fli1 contributes to the immune dysregulation seen in SSc. Comparison of the expression of Fli1 in monocytes,B- and T-cell fractions of PBMCs isolated from SSc patients and healthy controls (HC),showed an increase in Fli1 levels in monocytes. We used siRNA transfected human myeloid cells and mouse peritoneal macrophages obtained from Fli1 flox/flox LysMCre+/+ mice,and found that markers of alternative macrophage activation were increased with Fli1 deletion. Coculture of Fli1-deficient myeloid cells and primary human or mouse fibroblasts resulted in a potent induction of collagen type I,independent of TGF$\beta$ upregulation. We next analyzed global gene expression profile in response to Fli1 downregulation,to gain further insight into the molecular mechanisms of this process and to identify differentially expressed genes in myeloid cells. Of relevance to SSc,the top most upregulated pathways were hallmark IFN-$\gamma$ and IFN-$\alpha$ response. Additionally,several genes previously linked to SSc pathogenesis and fibrosis in general were also induced,including CCL2,CCL7,MMP12,and CXCL10. ANKRD1,a profibrotic transcription co-regulator was the top upregulated gene in our array. Our results show that Fli1-deficient myeloid cells share key features with cells from SSc patients,with higher expression of profibrotic markers and activation of interferon responsive genes,thus suggesting that dysregulation of Fli1 in myeloid cells may contribute to SSc pathogenesis. View Publication

Understanding the root causes of autoimmune diseases is hampered by the inability to access relevant human tissues and identify the time of disease onset. To examine the interaction of immune cells and their cellular targets in type 1 diabetes,we differentiated human induced pluripotent stem cells into pancreatic endocrine cells,including $\beta$ cells. Here,we describe an in vitro platform that models features of human type 1 diabetes using stress-induced patient-derived endocrine cells and autologous immune cells. We demonstrate a cell-type-specific response by autologous immune cells against induced pluripotent stem cell-derived $\beta$ cells,along with a reduced effect on $\alpha$ cells. This approach represents a path to developing disease models that use patient-derived cells to predict the outcome of an autoimmune response. View Publication

INTRODUCTION Estrogen deprivation using aromatase inhibitors is one of the standard treatments for postmenopausal women with estrogen receptor (ER)-positive breast cancer. However,one of the consequences of prolonged estrogen suppression is acquired drug resistance. Our group is interested in studying antihormone resistance and has previously reported the development of an estrogen deprived human breast cancer cell line,MCF-7:5C,which undergoes apoptosis in the presence of estradiol. In contrast,another estrogen deprived cell line,MCF-7:2A,appears to have elevated levels of glutathione (GSH) and is resistant to estradiol-induced apoptosis. In the present study,we evaluated whether buthionine sulfoximine (BSO),a potent inhibitor of glutathione (GSH) synthesis,is capable of sensitizing antihormone resistant MCF-7:2A cells to estradiol-induced apoptosis. METHODS Estrogen deprived MCF-7:2A cells were treated with 1 nM 17beta-estradiol (E2),100 microM BSO,or 1 nM E2 + 100 microM BSO combination in vitro,and the effects of these agents on cell growth and apoptosis were evaluated by DNA quantitation assay and annexin V and terminal deoxynucleotidyl transferase dUTP nick end-labeling (TUNEL) staining. The in vitro results of the MCF-7:2A cell line were further confirmed in vivo in a mouse xenograft model. RESULTS Exposure of MCF-7:2A cells to 1 nM E2 plus 100 microM BSO combination for 48 to 96 h produced a sevenfold increase in apoptosis whereas the individual treatments had no significant effect on growth. Induction of apoptosis by the combination treatment of E2 plus BSO was evidenced by changes in Bcl-2 and Bax expression. The combination treatment also markedly increased phosphorylated c-Jun N-terminal kinase (JNK) levels in MCF-7:2A cells and blockade of the JNK pathway attenuated the apoptotic effect of E2 plus BSO. Our in vitro findings corroborated in vivo data from a mouse xenograft model in which daily administration of BSO either as a single agent or in combination with E2 significantly reduced tumor growth of MCF-7:2A cells. CONCLUSIONS Our data indicates that GSH participates in retarding apoptosis in antihormone-resistant human breast cancer cells and that depletion of this molecule by BSO may be critical in predisposing resistant cells to E2-induced apoptotic cell death. We suggest that these data may form the basis of improving therapeutic strategies for the treatment of antihormone resistant ER-positive breast cancer. View Publication