Rapid and flexible calibration of DFPP using a dual-sight fusion target.

The parameter calibration of a digital fringe projection profilometry (DFPP) system is a fundamental step and directly related to 3D measurement accuracy. However, existing solutions based on geometric calibration (GC) suffer from the weakness of limited operability and practicality. In this Letter, a novel, to the best of our knowledge, dual-sight fusion target is designed for flexible calibration. The novelty of this target is the ability to directly characterize control rays for ideal pixels of the projector, and to transform the rays into the camera coordinate system, which replaces the traditional phase-shifting algorithm and avoids the error from the nonlinear response of the system. Attributed to the excellent position resolution of a position-sensitive detector within the target, the geometric relationship between the projector and camera can be easily established by projecting only one diamond pattern. Experimental results demonstrated that the proposed method using only 20 captured images is capable of achieving comparable calibration accuracy to the traditional GC method (20 images versus 1080 images, 0.052 pixels versus 0.047 pixels), which is suitable for rapidly and accurately calibrating the DFPP system in the 3D shape measurement field.

KIT ligand produced by limbal niche cells under control of SOX10 maintains limbal epithelial stem cell survival by activating the KIT/AKT signalling pathway.

Homeostasis and function of limbal epithelial stem cells (LESCs) rely on the limbal niche, which, if dysfunctional, leads to limbal epithelial stem cell deficiency (LSCD) and impaired vision. Hence, recovery of niche function is a principal therapeutic goal in LSCD, but the molecular mechanisms of limbal niche homeostasis are still largely unknown. Here, we report that the neural crest transcription factor SOX10, which is expressed in neural crest-derived limbal niche cells (LNCs), is required for LNCs to promote survival of LESCs both in vivo and in vitro. In fact, using mice with a Sox10 mutation and in vitro coculture experiments, we show that SOX10 in LNCs stimulates the production of KIT ligand (KITL), which in turn activates in LESCs the KIT-AKT signalling pathway that protects the cells against activated CASPASE 3-associated cell death. These results suggest that SOX10 and the KITL/KIT-AKT pathway play key roles in limbal niche homeostasis and LESC survival. These findings provide molecular insights into limbal niche function and may point to rational approaches for therapeutic interventions in LSCD.

The T-Box Transcription Factor TBX2 Regulates Cell Proliferation in the Retinal Pigment Epithelium.

PURPOSE: Vertebrate eye development and function critically depend on the regulation of proliferation of retinal pigment epithelium (RPE) cells. Hence, a thorough analysis of the molecular parameters controlling RPE cell proliferation is crucial for our understanding of the physiology of this cell type both in health and in disease. The T-box transcription factor TBX2 is an important cell cycle regulator in development and oncogenesis, but its specific role in RPE cell proliferation is far from clear. The purpose of the present study is to investigate whether TBX2 plays any role in regulating RPE cell proliferation. MATERIALS AND METHODS: The expression of TBX2 in RPE cells was analyzed in wildtype mice and ARPE-19 cells by co-staining for RPE-specific markers and cell proliferation. In vitro, the role of TBX2 was studied by manipulating its levels using RNAi and analyzing the effects on DNA synthesis and cell growth and on gene expression at the RNA and protein levels. RESULTS: Here, we find that TBX2 is expressed in RPE cells both in vivo and in vitro. Specific knockdown of TBX2 in the human RPE cell line ARPE-19 leads to an accumulation of cells at G1. This cell cycle arrest is accompanied by changes in the levels of known cell cycle regulators and, in particular, by an increase in the levels of the tumor-suppressor gene CCAAT/enhancer-binding protein delta (CEBPD). In fact, simultaneous knockdown of both TBX2 and CEBPD interferes with the reduction in cell proliferation brought about by TBX2 reduction alone. CONCLUSIONS: Our results provide novel insights into the regulatory mechanisms of cell proliferation in the RPE and may contribute to our understanding of normal RPE maintenance and its pathology in degenerative and proliferative disorders of the eye.

Sox10 regulates skin melanocyte proliferation by activating the DNA replication licensing factor MCM5.

BACKGROUND: The control of cell proliferation is a fundamental aspect of tissue formation in development and regeneration. A cell type that illustrates this point particularly well is the neural crest-derived melanocyte, the pigment cell of vertebrates, as melanocytes can be followed easily during development and their pigment is directly visible in the integument of the adult. In mammals, melanocytes undergo physiological cycles of loss and proliferative regeneration during the hair cycle, and their proliferation is also critical during wound healing, repigmentation of depigmented lesions, and in melanoma formation and progression. Hence, a thorough analysis of the molecular parameters controlling melanocyte proliferation is crucial for our understanding of the physiology of this cell type both in health and disease. OBJECTIVE: SOX10 is a critical regulator in melanocytes and melanoma cells, but its specific role in their proliferation is far from clear. In this study we analyze the role of SOX10 in regulating mammalian melanocyte proliferation in a mouse model. METHODS: The role of SOX10 in melanoblast proliferation was analyzed in Sox10/+ mice by co-staining for melanocyte-specific markers and cell proliferation. In vitro, the role of SOX10 was studied by manipulating its levels using RNAi and analyzing the effects on DNA synthesis and cell growth and on gene expression at the RNA and protein levels. RESULTS: Reduction of Sox10 gene dose led to a reduction in the number of melanoblasts. Knockdown of Sox10 in melanocytes led to inhibition of cell proliferation and a decrease in the expression of the minichromosome maintenance complex component 5 (MCM5). In fact, SOX10 directly activated MCM5 transcription by binding to conserved SOX10 consensus DNA sequences in the MCM5 promoter. Furthermore, the defect in cell proliferation could be rescued partially by overexpression of MCM5 in Sox10 knockdown melanocytes. CONCLUSION: The results suggest that the SOX10-MCM5 axis plays an important role in controlling melanocyte proliferation. Our findings provide novel insights into the regulatory mechanisms of melanocyte proliferation and may have implications for our understanding of the roles of SOX10 and MCM5 in abnormal melanocyte proliferation disorders such as cutaneous melanoma.

The transcription factor TBX2 regulates melanogenesis in melanocytes by repressing Oca2.

The T-box transcription factor TBX2 is known for its role as a critical regulator of melanoma cell proliferation, but its role in regulating melanogenesis has not been widely studied. Here we use a series of experiments to show in primary and immortalized mouse melanocytes that TBX2 acts as regulator of melanogenesis by repressing the expression of the gene encoding the melanosomal protein OCA2. We find that α-MSH or forskolin, both of which stimulate melanogenesis, also reduce TBX2 expression, and that specific knockdown of TBX2 increases melanogenesis. This effect primarily involves an increase in Oca2 expression as the combined knockdown of both Tbx2 and Oca2 interferes with the Tbx2 knockdown-mediated increase in melanogenesis. Standard chromatin immunoprecipitation and reporter assays suggest that TBX2 represses Oca2 at least in part directly. Hence, the results suggest that TBX2 may act as a nexus linking cell proliferation and melanogenesis.

Mesenchymal-like progenitors derived from human embryonic stem cells promote recovery from acute kidney injury via paracrine actions.

BACKGROUND AIMS: The engraftment of mesenchymal stem cells (MSCs) is reported to promote recovery of renal function in animal models of acute kidney injury (AKI). However, it is unknown whether mesenchymal-like progenitors (MPs) derived from human embryonic stem cells (hESCs) can mediate similar therapeutic effects. We investigated the responses of recipient renal tissue to engraftment of hESC-MPs and underlying mechanisms of these effects. METHODS: We measured blood urea nitrogen and creatinine levels of AKI mice with hESC-MPs transplantation and control mice. We performed renal morphology analysis by immunohistochemistry and electron microscopy to confirm the renoprotective effects of engrafted hESC-MPs. Proliferation, apoptosis and gene expression of tubular cells were also monitored by immunohistochemistry and real-time quantitative polymerase chain reaction to investigate the mechanisms that occurred. RESULTS: After transplantation of hESC-MPs into mice with cisplatin-induced AKI, improvements in renal function and recovery from tubular epithelial cell injury were observed. Engrafted hESC-MPs were localized to areas of injured kidney 5 days after cisplatin induction, where they promoted tubular cell proliferation and decreased kidney cell apoptosis. The beneficial effect was further confirmed by the capability of the engrafted cells to up-regulate renal gene expression of anti-inflammatory cytokines and pro-survival cytokines. Meanwhile, infusion of these cells reduced renal gene expression of pro-inflammatory cytokines and monocyte chemotactic protein-1, a chemokine that stimulates monocyte and macrophage infiltration. CONCLUSIONS: Our results show that infused hESC-MPs may promote recovery from AKI by regulating related cytokines.

Immunomodulative effects of mesenchymal stem cells derived from human embryonic stem cells in vivo and in vitro.

OBJECTIVE: Human embryonic stem cells (hESCs) have recently been reported as an unlimited source of mesenchymal stem cells (MSCs). The present study not only provides an identical and clinically compliant MSC source derived from hESCs (hESC-MSCs), but also describes the immunomodulative effects of hESC-MSCs in vitro and in vivo for a carbon tetrachloride (CCl(4))-induced liver inflammation model. METHODS: Undifferentiated hESCs were treated with Rho-associated kinase (ROCK) inhibitor and induced to fibroblast-looking cells. These cells were tested for their surface markers and multilineage differentiation capability. Further more, we analyzed their immune characteristics by mixed lymphocyte reactions (MLRs) and animal experiments. RESULTS: hESC-MSCs show a homogenous fibroblastic morphology that resembles bone marrow-derived MSCs (BM-MSCs). The cell markers and differentiation potential of hESC-MSCs are also similar to those of BM-MSCs. Unlike their original cells, hESC-MSCs possess poor immunogenicity and can survive and be engrafted into a xenogenic immunocompetent environment. CONCLUSIONS: The hESC-MSCs demonstrate strong inhibitory effects on lymphocyte proliferation in vitro and anti-inflammatory infiltration properties in vivo. This study offers information essential to the applications of hESC-MSC-based therapies and evidence for the therapeutic mechanisms of action.

Production of rabbit monoclonal antibodies against mouse embryonic stem cells and identification of pluripotency-associated surface antigens.

Embryonic stem (ES) cells are pluripotent stem cells derived from the inner cell mass of the blastocyst. ES cell surface molecules are important for the identification, labeling, sorting, quality control and functional studies of ES cells. Currently, knowledge of ES surface molecules is limited. To identify new surface molecules, we generated a panel of rabbit monoclonal antibodies (rMabs) against mouse ES (mES) cells. We identified three monoclonal antibodies that interact with molecules on the mES cell surface and found that the expression of their respective antigens decreased upon mES cell differentiation. The antigen of the rMab ZjuESrMab29 was identified as granulocyte macrophage colony-stimulating factor receptor α (GM-CSFR α) by liquid chromatography-tandem mass spectrometry (LC-MS/MS). This study demonstrated that rabbit monoclonal antibody production via whole-cell immunization could be a practical method for the discovery of stem cell surface antigens.

Generation and characterisation of rabbit monoclonal antibodies against the native cell surface antigens of embryonic stem cells.

Embryonic stem (ES) cells are potent resources for cell therapy, and monoclonal antibodies (mAbs) against native cell surface markers of ES cells could be useful tools for therapeutic applications. Here, we report the development of a feasible approach, which could be used in mass production, for experimentally producing rabbit mAbs against native cell surface antigens on the cell surface. Two of the 14 mAbs, which were selected at random, could be bound to the cell surface antigens of mES cells. The immunocytochemistry (ICC) and Western blot results showed that mAb 39 recognises conformational epitopes. The target antigen of mAb 39 was then successfully purified using an improved immunoprecipitation approach in which mAb was bounded to intact mES cells before the cells were lysed. The LC-LTQ mass spectrum analysis showed that the target antigen of mAb 39 was Glut3. This result was further confirmed by Western blot using commercially available antibodies against Glut3. Further experiments showed that mAb 39 exhibited an antiproliferative effect on mES cells. We also found that Glut3 was differentially expressed among the mES cell population as detected by flow cytometry.

All-trans retinoic acid promotes smooth muscle cell differentiation of rabbit bone marrow-derived mesenchymal stem cells.

Bone marrow-derived mesenchymal stem cells are multipotent stem cells, an attractive resource for regenerative medicine. Accumulating evidence suggests that all-trans retinoic acid plays a key role in the development and differentiation of smooth muscle cells. In the present study, we demonstrate, for the first time, that rabbit bone marrow-derived mesenchymal stem cells differentiate into smooth muscle cells upon the treatment with all-trans retinoic acid. All-trans retinoic acid increased the expression of myocardin, caldesmon, 22-kDa smooth muscle cell-specific protein (SM22alpha), and SM-myosin heavy chains in rabbit bone marrow-derived mesenchymal stem cells, as detected by reverse transcription polymerase chain reaction (PCR). Immunostaining of SM22alpha and SM-myosin heavy chains using monoclonal antibodies also indicated smooth muscle cell differentiation of rabbit bone marrow-derived mesenchymal stem cells following the treatment with all-trans retinoic acid. In addition, more than 47% of bone marrow-derived mesenchymal stem cells demonstrated the contractile phenotype of smooth muscle cells. Western blot results showed that SM-1 and SM-2 were highly expressed in the differentiated cells. These results suggest that all-trans retinoic acid may serve as a potent agent for functional smooth muscle cell differentiation in tissue engineering.

Early homing behavior of Stro-1- mesenchyme-like cells derived from human embryonic stem cells in an immunocompetent xenogeneic animal model.

Mesenchymal stem cells (MSCs) have been induced to differentiate successfully from human embryonic stem cells (hES-MSCs), which could serve as an in vitro source of MSCs. However, the homing behaviors of such cells and their potential utility for liver regeneration in vivo have not been reported. We investigated factors that influenced early homing and the hepatic-directed differentiation potency of hES-MSCs in a mouse model of acute liver injury. The hES-MSCs could be detected 36 h after cell infusion and this was unaffected by the number of cell passages in culture. Pretreatment of hES-MSCs with TNF-alpha resulted in higher rates of homing of these cells to the injured liver. Interestingly most of the cells homing at an early stage expressed alpha-fetoprotein (AFP), indicating hepatic differentiation. Thus, hES-MSCs can home to the acutely injured liver at high efficiency and undergo hepatic differentiation, suggesting that these cells could be useful for treating acute human liver injury.