Real-time GFP imaging of spontaneous HT-1080 fibrosarcoma lung metastases

Metastasis to the lung is often a lethal event in sarcoma as well as other cancers. We report here a new animal model of sarcoma enabling the external real-time fluorescence imaging of spontaneous lung metastasis. The human fibrosarcoma cell line HT-1080 was transduced with the green fluorescent protein (GFP) gene. HT-1080-GFP cells were injected into the right hind footpad of severe combined immunodeficient (SCID) mice. The lung metastases were evaluated by whole-body fluorescence imaging as well as direct-view imaging in live animals through a skin-flap window over the chest wall. Spontaneous lung metastases were observed on the lungs of 11 of 12 mice. SCID mice well tolerated the skin-flap procedure enabling real-time imaging of spontaneous lung metastases with a resolution of approximately 50–100 μm. This procedure enabled external imaging at the micrometastasis level. Real-time evaluation of spontaneous lung metastasis in the same animals should allow drug evaluation and mechanistic studies not previously possible. This revised version was published online in July 2006 with corrections to the Cover Date.     

Imaging tumor angiogenesis with fluorescent proteins

We have developed three unique mouse models to image angiogenesis with fluorescent proteins, which are described in this review. First, we have adapted the surgical orthotopic implantation (SOI) model to image angiogenesis of human tumors labeled with green fluorescent protein (GFP) transplanted in nude mice. The nonluminous induced capillaries are clearly visible by contrast against the very bright tumor fluorescence examined either intravitally or by whole-body imaging in real time. Intravital images of an SOI model of human pancreatic tumors expressing GFP visualized angiogenic capillaries at both primary and metastatic sites. Whole-body optical imaging showed that blood vessel density increased linearly over a 20-week period in an SOI model of human breast cancer expressing GFP. Opening a reversible skin-flap in the light path markedly reduces signal attenuation, increasing detection sensitivity many-fold and enabling vessels to be externally visualized in GFP-expressing tumors growing on internal organs. The second model utilizes dual-color fluorescence imaging, effected by using red fluorescent protein (RFP)-expressing tumors growing in GFP-expressing transgenic mice that express GFP in all cells. This dual-color model visualizes with great clarity the details of the tumor-stroma interaction, especially tumor-induced angiogenesis. The GFP-expressing tumor vasculature, both nascent and mature, are readily distinguished interacting with the RFP-expressing tumor cells. Using a spectral imaging system based on liquid crystal tunable filters, we were able to separate individual spectral species on a pixel-by-pixel basis. Such techniques non-invasively visualized the presence of host GFP-expressing vessels within an RFP-labeled orthotopic human breast tumor by real-time whole-body imaging. The third model involves a transgenic mouse in which the regulatory elements of the stem cell marker nestin drive GFP. The nestin-GFP mouse expresses GFP in areas of the brain, hair follicle stem cells, and in a network of blood vessels in the skin interconnecting hair follicles. RFP-expressing tumors transplanted to nestin-GFP mice enable specific visualization of nascent vessels in skin-growing tumors such as melanoma. Thus, fluorescent proteins expressed in vivo offer very high resolution and sensitivity for real-time imaging of angiogenesis.     

Multi-organ metastatic capability of Chinese hamster ovary cells revealed by green fluorescent protein (GFP) expression

Stable high-level green fluorescent protein (GFP)-expressing Chinese hamster ovary cells (CHO) were used to visualize the degree of metastatic behavior of this cell line in nude and SCID mice. A stable GFP high-expression CHO clone, selected in 1.5 M methotrexate, was injected subcutaneously in nude and severe combined immunodeficient (SCID) mice and implanted orthotopically in the ovary of nude mice. CHO proved to be highly metastatic from both the subcutaneous and orthotopic sites as brightly visualized by GFP fluorescence. High-level GFP-expression allowed the visualization of metastatic tumor in fresh live host tissue in great detail. Metastases were visualized by GFP expression in the lung, pleural membrane, spleen, kidney, ovary, adrenal gland, and peritoneum after orthotopic implantation in nude mice. Metastases were visualized by GFP expression mainly in the lung, pleural membrane after subcutaneous implantation in nude mice. Metastases were visualized in the lung and pleural membrane, liver, kidney, and ovary after subcutaneous implantation in SCID mice. The construction of highly fluorescent stable GFP transfectants of CHO has revealed the multi-organ metastatic capability of CHO cells. CHO has such a high degree of malignancy that it is metastatic from both the orthotopic and subcutaneous transplant sites. This highly malignant GFP-expressing cell-line with multi-organ metastatic affinity should serve as a powerful tool to study tumor-host interaction.     

In vivo imaging with fluorescent proteins: the new cell biology

We propose a new cell biology where the behavior of cells can be visualized in the living animal. An example of the new cell biology is dual-color fluorescence imaging using red fluorescent protein (RFP)-expressing tumors transplanted in green fluorescent protein (GFP)-expressing transgenic mice. These models show with great clarity the details of tumor-stroma interactions and especially tumor-induced angiogenesis, tumor-infiltrating lymphocytes, stromal fibroblasts and macrophages. Another example is the color coding of cells with RFP or GFP such that both cell types can be simultaneously visualized in vivo. Stem cells can also be visualized and tracked in vivo. Mice in which the regulatory elements of the stem-cell marker nestin drive GFP enable nascent vasculature to be visualized interacting with transplanted RFP-expressing cancer cells. Nestin-driven GFP expression can also be used to visualize hair follicle stem cells. Dual-color cells expressing GFP in the nucleus and RFP in the cytoplasm enable real-time visualization of nuclear-cytoplasm dynamics including cell cycle events and apoptosis. Multiple-color labeling of cells will enable multiple events to be simultaneously visualized in vivo including gene expression, ion fluxes, protein and organelle trafficking, chromosome dynamics and numerous other processes currently still only studied in vitro.     

Visualization of nascent tumor angiogenesis in lung and liver metastasis by differential dual-color fluorescence imaging in nestin-linked-GFP mice

Nestin regulatory-element-driven green fluorescent protein (ND-GFP) transgenic mice highly express GFP in proliferating endothelial cells and nascent blood vessels. In the present study, we visualized angiogenesis in experimental lung and liver metastases by GFP imaging in the ND-GFP transgenic mice. The murine melanoma cell line, B16F10 expressing red fluorescent protein (RFP), was injected i.v. in ND-GFP mice. ND-GFP was highly expressed in proliferating nascent blood vessels in the tumors that developed in the lung after tail vein injection, and in the tumors that developed in the liver after portal vein injection of RFP-expressing melanoma cells. Liver metastasis and angiogenesis were imaged intravitally. Doxorubicin significantly decreased metastatic angiogenesis in the liver. These results demonstrate a new imageable model of angiogenesis in metastasis in the liver and the lung. This new model should enable further understanding of the onset of angiogenesis in metastasis and its effect on metastatic growth. The model will serve as a unique screen for inhibitors of angiogenesis of metastatic tumors. The fact that liver-metastasis angiogenesis can be imaged in the live animal enables real-time studies of the effect of angiogenesis inhibitors.     

人心肌肌球蛋白轻链基因启动子驱动的GFP和Luc报告基因在人心肌细胞系中的表达

目的:构建人肌球蛋白2v基因启动子(pMLC2v)驱动的绿色荧光蛋白(GFP)和萤光素酶(Luc)报告基因慢病毒载体并观察其在人心肌细胞系(HCM)和人肺癌细胞株A549中的整合表达特征。方法:应用去毒化的人类I型免疫缺陷病毒和pMLC2v-GFP或pMLC2v-Luc报告基因构建慢病毒示踪载体,转染HCM和A549细胞,激光共聚焦显微镜及生物发光检测仪观察2种报告基因在不同细胞生长进程中的表达特征。非特异性启动子驱动的GFP(GFP_C)和红色荧光蛋白(RFP_C)报告基因作为对照。结果:2种细胞转染GFP_C和RFP_C后第3 d,都表达GFP和RFP;而HCM只在转染pMLC2v-GFP和pMLC2v-Luc 21 d后表达GFP和Luc,A549细胞不表达。结论:pMLC2v主要在培养21 d后新增殖的人心肌细胞中驱动GFP和Luc报告基因表达,这为监测干细胞向心肌细胞的分化进程提供了可靠的病理及活体示踪工具。     

Use of the red fluorescent protein as a marker of Kaposi's sarcoma-associated herpesvirus lytic gene expression

A hallmark of all herpesvirus is the ability to exist in either a latent, or lytic, state of replication, enabling the lifelong infection of its host. Kaposi's sarcoma (KS)-associated herpesvirus (KSHV) can efficiently establish a latent infection in a variety of cell types in vitro, making it a valuable model for the study of latency and reactivation. To facilitate the identification of KSHV lytic replication, and allow subsequent experiments with live cells, a recombinant virus, rKSHV.219, was constructed using JSC-1 cells that expresses the red fluorescent protein (RFP) from the KSHV lytic PAN promoter, the green fluorescent protein (GFP) from the EF-1α promoter, and with the gene for puromycin resistance as a selectable marker. rKSHV.219 from JSC-1 cells was used to infect Vero cells for purification of the recombinant virus. Vero cells were also used for the production of rKSHV.219 at levels of 10⁵-10⁶ infectious units (IU) of virus per milliliter using a combination of KSHV/RTA expressed from a baculovirus vector, BacK50, and butyrate. Virus produced from Vero cells was used to infect human fibroblasts (HF), 293, DU145, T24, HaCaT, and HEp-2 cells, and in all cells except 293 cells, only a latent infection was established with GFP expression, but no RFP expression. In 293 cells, 10-15% of cells showed lytic gene expression. Both primary and immortalized microvascular endothelial cells (MVEC) were also infected with rKSHV.219, and reduced spontaneous lytic replication was found in immortalized cells. In all cells used in this study, rKSHV.219 efficiently established latent infections from which the virus could be reactivated to productive lytic replication. This work also demonstrated strong synergy between KSHV/RTA and butyrate for the activation of KSHV lytic replication and the production of infectious virus.     

GFP和RFP报道基因在人体不同细胞中转导率的比较研究

目的 比较慢病毒载体介导的绿色荧光蛋白（GFP）和红色荧光蛋白（RFP）报道基因在人体不同细胞中的转导率,为再生医学和组织工程学研究中报道基因的选择提供依据.方法 将构建的GFP和RFP慢病毒载体分别转染人骨髓间充质干细胞（hMSC）、人脐静脉内皮细胞株（Eahy926）和人肺泡上皮细胞株（A549）.4d后,用流式细胞仪检测GFP和RFP的转导率,并利用激光共聚焦显微镜观察GFP和RFP的表达特征.结果 GFP和RFP在hMSC、Eahy926和A549三种细胞间的转导率均有显著性差异（P﹤0.01）;在hMSC或Eahy926或A549的同种细胞中GFP和RFP的转导率也有显著性差异（P﹤0.01）;RFP在部分Eahy926和A549细胞局部高表达.结论 慢病毒载体介导的GFP和RFP报道基因在人体不同细胞中的转导率明显不同.     

An imageable highly metastatic orthotopic red fluorescent protein model of pancreatic cancer

In order to investigate the antitumor and antimetastatic efficacy of new chemotherapeutic agents, a novel, red-fluorescent, orthotopic model of pancreatic cancer was constructed in nude mice. MIA-PaCa-2 human pancreatic cancer cells were transduced with red fluorescent protein (RFP) and initially grown subcutaneously. Fluorescent tumor fragments were then transplanted onto the pancreas by surgical orthotopic implantation (SOI), facilitating high-resolution, real-time visualization of tumor and metastatic growth and dissemination in vivo. Tumor growth at the primary site was visible within the first postoperative week, while distant metastasis and the development of ascites became visible over the following week. This MIA-PaCa-2-RFP model produced extensive local disease and metastases to the retroperitoneum (100%), spleen (100%), intestinal and periportal lymph nodes (100%), liver (40%) and diaphragm (80%), and gave rise to malignant ascites and peritoneal carcinomatosis in 80% of cases. Growth and metastasis of tumor was more rapid and frequent than in previously described orthotopic pancreatic cancer models, leading to a median survival of only 21 days after tumor implantation. This unique, red fluorescent model rapidly and reliably simulates the highly aggressive course of human pancreatic cancer and can be easily non-invasively visualized in the live animal. The model can therefore be used for the discovery and evaluation of novel therapeutics for the treatment of this devastating disease.     

CD44 antibody-targeted liposomal nanoparticles for molecular imaging and therapy of hepatocellular carcinoma

Most hepatocellular carcinoma (HCC) therapies fail to target cancer stem cells (CSCs) and monitor cancer progression or regression. The purpose of this study was to evaluate the possibility of cancer imaging and simultaneously monitoring targeted therapy in a single animal by anti-CD44 antibody-mediated liposomal nanoparticle. In this study, an in situ liver tumor model was applied for therapy by injecting 1.0 × 10(6) HepG2 cells carrying a reporter system encoding a double fusion (DF) reporter gene consisting of firefly luciferase (Fluc) and green fluorescent protein (GFP) into the liver of NOD/SCID mice. A strategy was developed which specifically targeted HCC via anti-CD44 antibody-mediated liposomal nanoparticle delivery, loaded of either doxorubicin (Dox) or a triple fusion (TF) gene containing the herpes simplex virus truncated thymidine kinase (HSV-ttk) and renilla luciferase (Rluc) and red fluorescent protein (RFP). The NOD/SCID mice were subsequently treated with ganciclovir (GCV) and the growth status of tumor was monitored by optical bioluminescence imaging (BLI) of Fluc and specific targeting of the liposomal nanoparticle was tracked by Rluc imaging. CD44 antibody-mediated liposomal nanoparticle, loaded of TF plasmids, were shown to be useful for monitoring and evaluating targeting efficacy and gene therapy by non-invasive molecular imaging. Here, we demonstrate the time intensive preclinical steps involved in molecular target identification, validation, and characterization by dual molecular imaging. This targeted and traceable therapeutic strategy has potential advantages to overcome the problems of conventional tumor therapy and may open a new application for the treatment of HCC by targeting CSCs.     

Metastatic patterns of lung cancer visualized live and in process by green fluorescence protein expression

We demonstrate here the visualization of human lung cancer metastasis live and in process in nude mice by green fluorescent protein (GFP) expression. The human lung adenocarcinoma cell line Anip 973 stably transfected with the humanized GFP-S65T cDNA was selected for very bright green fluorescence. GFP-transfected lung cancer cells were initially inoculated subcutaneously in nude mice. Five weeks after transplantation, the resulting tumor had reached over 1 cm in diameter and had very bright GFP fluorescence. Fragments of subcutaneous tumor were implanted onto the visceral pleura of the left lung of nude mice by surgical orthotopic implantation (SOI) of histologically-intact tissue via transverse thoracotomy. The ipsilateral resulting tumor was highly fluorescent due to GFP expression. GFP expression allowed the visualization of the advancing margin of the ipsilateral tumor into the fresh normal lung tissue. Lymphogenous and direct-seeding metastases in the pulmonary hilum, cervical lymph nodes, the mediastinum and contralateral pleural cavity and contralateral lung in the SOI-treated mice were brightly visualized by GFP expression in fresh tissue. GFP-transfected and untransfected tumor had similar metastatic characteristics suggesting that GFP expression had no effect on metastasis itself. The results with the GFP-transfected tumor cells, combined with the use of SOI, demonstrate a fundamental advance in the visualization and study of lung cancer metastasis in process.     

Long-working-distance fluorescence microscope with high-numerical-aperture objectives for variable-magnification imaging in live mice from macro- to subcellular

We demonstrate the development of a long-working-distance fluorescence microscope with high-numerical-aperture objectives for variable-magnification imaging in live mice from macro- to subcellular. To observe cytoplasmic and nuclear dynamics of cancer cells in the living mouse, 143B human osteosarcoma cells are labeled with green fluorescent protein in the nucleus and red fluorescent protein in the cytoplasm. These dual-color cells are injected by a vascular route in an abdominal skin flap in nude mice. The mice are then imaged with the Olympus MVX10 macroview fluorescence microscope. With the MVX10, the nuclear and cytoplasmic behavior of cancer cells trafficking in blood vessels of live mice is observed. We also image lung metastases in live mice from the macro- to the subcellular level by opening the chest wall and imaging the exposed lung in live mice. Injected splenocytes, expressing cyan fluorescent protein, could also be imaged on the lung of live mice. We demonstrate that the MVX10 microscope offers the possibility of full-range in vivo fluorescence imaging from macro- to subcellular and should enable widespread use of powerful imaging technologies enabled by genetic reporters and other fluorophores.     

Integrin α5β1: a potent inhibitor of experimental lung metastasis

The integrin alpha5beta1 seems to be the most relevant receptor of tumor cells for binding to fibronectin. Although numerous studies suggest a role of tumor cell fibronectin interaction in tumor metastasis, differential integrin expression on tumor cells has, however, not been correlated with metastatic capabilities. We addressed this question by transfection of the integrin alpha5beta1 cDNA into HT-29 human colon carcinoma cells which led to de novo expression of functional integrin alpha5beta1. Similar to other reports, expression of the integrin alpha5beta1 in HT-29 tumor cells exerted an inhibitory action on cell proliferation as indicated in our study by formation of fewer colonies in soft agar. The tumor growth inhibitory property of the integrin alpha5beta1 was also shown by reduction of subcutaneous xenograft growth in nude mice to approximately 50% of that of control transfectants. For the first time, we found that several clones of integrin alpha5 subunit transfectants displayed dramatically reduced formation of lung colonies and cutaneous metastasis after intravenous injection into nude mice. While most animals inoculated with control transfectant cells formed macroscopically visible lung colonies ranging from 12.6 +/- 2.6 to 22.0 +/- 6.6 (mean colony number +/- SEM), mice inoculated with HT-29 cell clones expressing the integrin alpha5beta1 were almost completely free of lung colonies (ranging from 0.0 +/- 0 to 0.2 +/- 0.1). Our results imply that integrin alpha5beta1 expression inhibits circulating tumor cells in pursuing late steps of the metastatic process as represented by the artificial metastasis (lung colonisation) model.     

Hyperspectral imaging of hemoglobin saturation in tumor microvasculature and tumor hypoxia development

Tumor hypoxia has been shown to have prognostic value in clinical trials involving radiation, chemotherapy, and surgery. Tumor oxygenation studies at microvascular levels can provide understanding of oxygen transport on scales at which oxygen transfer to tissue occurs. To fully grasp the significance of blood oxygen delivery and hypoxia at microvascular levels during tumor growth and angiogenesis, the spatial and temporal relationship of the data must be preserved and mapped. Using tumors grown in window chamber models, hyperspectral imaging can provide serial spatial maps of blood oxygenation in terms of hemoglobin saturation at the microvascular level. We describe our application of hyperspectral imaging for in vivo microvascular tumor oxygen transport studies using red fluorescent protein (RFP) to identify all tumor cells, and hypoxia-driven green fluorescent protein (GFP) to identify the hypoxic fraction. 4T1 mouse mammary carcinoma cells, stably transfected with both reporter genes, are grown in dorsal skin-fold window chambers. Hyperspectral imaging is used to create image maps of hemoglobin saturation, and classify image pixels where RFP alone is present (tumor cells), or both RFP and GFP are present (hypoxic tumor cells). In this work, in vivo calibration of the imaging system is described and in vivo results are shown.     

荧光标记肿瘤转移体内模型的建立

目的 建立一种带荧光标记的肿瘤转移模型并探讨其应用价值.方法 人胃癌MGC-803细胞和小鼠宫颈癌U14细胞进行体外传代培养,转染pEGFP-N1质粒,24h检测转染效率,用无限稀释法筛选稳定表达绿色荧光蛋白(GFP)的单克隆细胞株MGC-803-GFP和U14-GFP.分别体内移植于BALB/c-nn裸鼠和C57BL/6J小鼠,观察成瘤潜伏期,绘制体内生长曲线,利用活体荧光成像系统活体连续观察GFP在体内的表达,观察肺部和淋巴结的转移情况,计算转移率.免疫组织化学检测与转移相关的分子CD44和E-cadherin在移植瘤中的表达.结果 MGC-803细胞和U14细胞pEGFP-N1转染24 h后的转染效率分别为30%和60%.获得了GFP(+)的单克隆MGC-803-GFP细胞株和U14-GFP细胞株.MGC-803-GFP在BALB/c-nu裸鼠和U14-GFP在C57BL/6J小鼠移植成瘤的潜伏期分别是3～5 d和2～4 d,成瘤率均为100%.利用活体荧光成像系统连续观察,可以清楚直观地观察表达GFP的MGC-803-GFP移植瘤在体内的生长,接种后第60天处死全部荷瘤鼠,解剖后仅有1只可见同侧腋窝下淋巴结的转移.接种U14-GFP后,分别在第28、37和52天观察了荷瘤小鼠肿瘤转移的发展过程.在U14-GFP原发瘤体积达到≥5 cm3时,肺部和淋巴结转移率分别为67%和100%.在MGC-803-GFP和U14-GFP的移植瘤中都可以检测到CD44的表达,而无E-cadherin的表达.结论 成功建立了表达绿色荧光蛋白单克隆细胞株MGC-803-GFP和U14-GFP,体内移植建立了荧光标记的肿瘤转移模型.该模型可用于可视化肿瘤体内的研究.     

GFP-transfected tumor cells are useful in examining early metastasis <Emphasis Type="Italic">in vivo</Emphasis>, but immune reaction precludes long-term tumor development studies in immunocompetent mice

To develop effective therapeutic strategies aimed at treating tumor metastasis, critical steps in this process must be better understood. For this purpose we have established a new model to visualize and quantify early metastasis. Murine CT-26 colon adenocarcinoma cells were stably transfected with green fluorescent protein (GFP). Tumor cells were intraportally delivered to the liver of Balb/c mice and subsequently tracked by intravital fluorescence microscopy. Coinjection of fluorescent beads and in vivo propidium iodide staining allowed examination of initial tumor cell arrest, extravasation, viability and proliferation. Results showed that GFP-transfection compared to conventional labeling procedures (Calcein, cytoplasmic microspheres) did not alter early metastatic properties. However, the long-term development of liver metastases expressing GFP was markedly reduced compared to wild type CT-26 tumor cells. An increase in the size and the number of liver metastases in T- and B-cell-deficient SCID mice suggested an immune response to the GFP transfected cells responsible for the reduced metastatic growth in wild-type mice. Based on our findings, this model can be used to examine the early steps of metastasis in vivo. However, in immunocompetent mice, the use of GFP-labeled tumor cells should be limited to tracking cell arrest and extravasation, whereas evaluations of long-term metastatic growth should be performed in immunodeficient mice. This revised version was published online in July 2006 with corrections to the Cover Date.     

Functional imaging in bulk tissue specimens using optical emission tomography: fluorescence preservation during optical clearing

Optical emission computed tomography (optical-ECT) is a technique for imaging the three-dimensional (3D) distribution of fluorescent probes in biological tissue specimens with high contrast and spatial resolution. In optical-ECT, functional information can be imaged by (i) systemic application of functional labels (e.g. fluorophore labelled proteins) and/or (ii) endogenous expression of fluorescent reporter proteins (e.g. red fluorescent protein (RFP), green fluorescent protein (GFP)) in vivo. An essential prerequisite for optical-ECT is optical clearing, a procedure where tissue specimens are made transparent to light by sequential perfusion with fixing, dehydrating and clearing agents. In this study, we investigate clearing protocols involving a selection of common fixing (4% buffered paraformaldehyde (PFA), methanol and ethanol), dehydrating (methanol and ethanol) and clearing agents (methyl salicylate and benzyl-alcohol-benzyl-benzoate (BABB)) in order to determine a 'fluorescence friendly' clearing procedure. Cell culture experiments were employed to optimize the sequence of chemical treatments that best preserve fluorescence. Texas red (TxRed), fluorescein isothiocyanate (FITC), RFP and GFP were tested as fluorophores and fluorescent reporter proteins of interest. Fluorescent and control cells were imaged on a microscope using a DSred2 and FITC filter set. The most promising clearing protocols of cell culture experiments were applied to whole xenograft tumour specimens, to test their effectiveness in large unsectioned samples. Fluorescence of TxRed/FITC fluorophores was not found to be significantly affected by any of the test clearing protocols. RFP and GFP fluorescence, however, was found to be significantly greater when cell fixation was in ethanol. Fixation in either PFA or methanol resulted in diminished fluorescence. After ethanol fixation, the RFP and GFP fluorescence proved remarkably robust to subsequent exposure to either methyl salicylate or BABB. The optimized optical clearing procedure of ethanol fixation followed by methyl salicylate clearing preserved the fluorescence of constitutive RFP in whole xenograft tumour specimens, about 1 cc in dimension, indicating successful extension from cell plating experiments to whole tissue samples. Finally, the feasibility of imaging the 3D distribution of viable tumour cells (as indicated by the RFP emission) is demonstrated by optical-ECT imaging of cleared xenograft tumours using an in-house system.     

Expression of recombination-activating gene in mature peripheral T cells in Peyer's patch

Recombination-activating gene (RAG) 1 and 2 are essential for the gene rearrangement of antigen receptors of both T and B cells. To investigate RAG gene expression in peripheral lymphoid organs other than the thymus and bone marrow, we established mice in which a green fluorescent protein (GFP) gene is knocked-in the RAG2 gene locus (RAG2-GFP mice). In the thymus and bone marrow of heterozygous RAG2-GFP mice, as expected, GFP expression was detected in the appropriate stages of developing T and B cells. Interestingly, only a fraction of Thy-1.2(+) cells in the Peyer's patch were found to be GFP(+) amongst the peripheral lymphoid organs. The GFP(+) cells expressed high levels of surface TCRbeta and CD3, suggesting mature T cells with rearranged TCRalphabeta. However, they showed activated/memory phenotypes, i.e. CD45RB(low), CD69(high), CD44(high) and CD62L(low), and belonged to a CD4(+)CD8(+) population expressing c-kit, IL-7R and pTalpha characteristic of immature developing lymphocytes. Moreover, RAG(+) Peyer's patch T cells seem to be of thymic origin as judged by their expression of CD8alphabeta. These results show that there exists a fraction of mature T cells expressing RAG genes in the Peyer's patch, implying a potential for a secondary rearrangement of TCR in extrathymic tissues.     

Time lapse imaging techniques for comparison of mineralization dynamics in primary murine osteoblasts and the late osteoblast/early osteocyte-like cell line MLO-A5

Mineralization of bone matrix and osteocyte differentiation occur simultaneously and appear interrelated both spatially and temporally. Although these are dynamic events, their study has been limited to using static imaging approaches, either alone or in combination with chemical and biochemical analysis and/or genetic manipulation. Here we describe the application of live cell imaging techniques to study mineralization dynamics in primary osteoblast cultures compared to a late osteoblast/early osteocyte-like cell line, MLO-A5. Mineral deposition was monitored using alizarin red as a vital stain for calcium. To monitor differentiation into an osteocyte-like phenotype, the calvarial cells were isolated from transgenic mice expressing green fluorescent protein (GFP) driven by an 8-kb dentin matrix protein-1 (Dmp1) promoter that gives osteocyte-selective expression. Time lapse imaging showed that there was a lag phase of 15-20 h after beta-glycerophosphate addition, followed by mineral deposition that was rapid in primary osteoblast cultures but more gradual in MLO-A5 cultures. In primary osteoblast cultures, mineral was deposited exclusively in association with clusters of cells expressing Dmp1-GFP, suggesting that they were already differentiating into osteocyte-like cells. In MLO-A5 cells, the first indication of mineralization was the appearance of punctate areas of alizarin red fluorescence of 4-7 mum in diameter, followed by mineral deposition throughout the culture in association with collagen fibrils. A high amount of cell motility was observed within mineralizing nodules and in mineralizing MLO-A5 cultures. These studies provide a novel approach for analyzing mineralization kinetics that will enable us to dissect in a time-specific manner the essential players in the mineralization process.     

Detection of dual-gene expression in arteries using an optical imaging method

We evaluate the in vivo use of an optical imaging method to detect the vascular expression of green fluorescent protein (GFP) or red fluorescent protein (RFP), and to detect the simultaneous expression of GFP and RFP after transduction into arteries by a dual-promoter lentiviral vector driving their concurrent expression. This method involves using a charge-coupled device camera to detect fluorescence, a fiber optic probe to transmit light, and optical filters to distinguish each marker. In animal models, these vectors are locally delivered to target arteries, whereas the gene for a nonfluorescent cell-surface protein is transduced into contralateral arteries as the sham control. The images show distinct areas of bright fluorescence from GFP and RFP along the target arteries on excitation; no exogenous fluorescence is observed in the controls. Measured signal intensities from arteries transduced with the single- and dual-promoter vectors exceed the autofluorescence signal from the controls. Transgene expression of GFP and RFP in vivo is confirmed with confocal microscopy. We demonstrate the use of an optical imaging method to concurrently detect two distinct fluorescent proteins, potentially permitting the expression of multiple transgenes and their localization in the vasculature to be monitored.