One-step visualization of natural cell activities in non-labeled living spheroids.

3D cultured cell aggregates, including spheroids, reflect the gene expression patterns of living tissues/organs. Mass preparation of spheroids enables high-throughput drug screening (HTS). However, conventional optical imaging of spheroids makes it difficult to obtain sufficient resolution of individual living cells in the thick cellular stack. Rapid and accurate assessment of cellular responses in spheroids is required for effective drug screening. Here, we show that negative contrast imaging (NCI) of spheroids overcomes this issue. Hydrophilic fluorescent dye added into the culture medium rapidly diffused into the intercellular space of living spheroids within a few minutes. Confocal microscopy showed the NCI of individual cells as dark and detailed contours clearly separated with fluorescence signals in the intercellular space. NCI enables the visualization of the alteration of cell morphology after anti-tumor drug application to living spheroids and the measurement of the fluorescent dye diffusion rate without any complicated pretreatments. Using this system, we found that the antitumor drug doxorubicin reduced the intercellular space of spheroids consisting of the human hepatocyte carcinoma cell line HepG2, through the activation of TGF-ß signaling and upregulation of ECM protein expression, implicating a drug resistance mechanism. Collectively, the combination of NCI of spheroids and HTS may enhance the efficiency of drug discovery.

Effect of Soft X-ray Irradiation on Film Properties of a Hydrogenated Si-Containing DLC Film.

The effect of soft X-ray irradiation on hydrogenated silicon-containing diamond-like carbon (Si-DLC) films intended for outer space applications was investigated by using synchrotron radiation (SR). We found that the reduction in film thickness was about 60 nm after 1600 mA·h SR exposure, whereas there was little change in their elemental composition. The reduction in volume was attributable to photoetching caused by SR, unlike the desorption of hydrogen in the case of exposure of hydrogenated DLC (H-DLC) film to soft X-rays. The ratio of the sp2 hybridization carbon and sp3 hybridization carbon in the hydrogenated Si-DLC films, sp2/(sp2 + sp3) ratio, increased rapidly from ~0.2 to ~0.5 for SR doses of less than 20 mA·h. SR exposure significantly changed the local structure of carbon atoms near the surface of the hydrogenated Si-DLC film. The rate of volume reduction in the irradiated hydrogenated Si-DLC film was 80 times less than that of the H-DLC film. Doping DLC film with Si thus suppresses the volume reduction caused by exposure to soft X-rays.

Performance of BL07A at NewSUBARU with installation of a new multi-layered-mirror monochromator.

Soft X-rays excite the inner shells of materials more efficiently than any other form of light. The investigation of synchrotron radiation (SR) processes using inner-shell excitation requires the beamline to supply a single-color and high-photon-flux light in the soft X-ray region. A new integrated computing multi-layered-mirror (MLM) monochromator was installed at beamline 07A (BL07A) of NewSUBARU, which has a 3 m undulator as a light source for irradiation experiments with high-photon-flux monochromatic light. The MLM monochromator has a high reflectivity index in the soft X-ray region; it eliminates unnecessary harmonic light from the undulator and lowers the temperature of the irradiated sample surfaces. The monochromator can be operated in a high vacuum, and three different mirror pairs are available for different experimental energy ranges; they can be exchanged without exposing the monochromator to the atmosphere. Measurements of the photon current of a photodiode on the sample stage indicated that the photon flux of the monochromatic beam was more than 1014 photons s-1 cm-2 in the energy range 80-400 eV and 1013 photons s-1 cm-2 in the energy range 400-800 eV. Thus, BL07A is capable of performing SR-stimulated process experiments.

A method for detailed analysis of the structure of mast cell secretory granules by negative contrast imaging.

Secretory granules (SGs) in mast cells contain various molecules that elicit allergy symptoms and are generally considered therapeutic targets. However, the biogenesis, maintenance, regulation, and recycling of these granules remain controversial, mainly due to the lack of suitable live-cell imaging methods. In this study, we applied negative contrast imaging with soluble green fluorescent protein (GFP) expressed in the cytoplasm as a method to validate structural information of mast cell SGs. We evaluated the accuracy of the method in detail, and we demonstrated that it can be used for quantitative analysis. Using this technique, secretory granules, the nucleus, mitochondria, and the cell body were visualized in individual RBL-2H3 mast cells without any influence. When combined with conventional multicolor fluorescence imaging, visualization of SG-associated proteins and SG-SG fusion was achieved. Moreover, 3D images were constructed based on this method, and detailed information on the number, size, and shape of individual SGs was obtained. We found that cell volume was correlated with SG number. In summary, the technique provides valuable and unique data, and will therefore advance SG research.

A novel method to visually determine the intracellular pH of xenografted tumor in vivo by utilizing fluorescent protein as an indicator.

The alkalization of intracellular pH (pHin) advances together with enhancement of aerobic glycolysis within tumor cells (the Warburg effect), and that is responsible for the progression of tumor malignancy together with hypoxia and angiogenesis. But how they correlate each other during tumor growth is poorly understood, partly due to the lack of suitable imaging methods. In present study, we propose a novel method to visually determine the pHin of tumor xenograft model from fluorescent image ratios. We utilized tandemly-linked two fluorescent proteins as a pH indicator; yellow fluorescent protein (YFP, pH sensitive) as an indicator, and red fluorescent protein (RFP, pH insensitive) as a reference. This method can eliminate the influence of optical factors from tissue as well as of the diverse expression level of pH indicator in the grafted cells. In addition, that can be operated by filter-based fluorescent imagers that are generally used in small animal study. The efficacy of the pH indicator, RFP-YFP, was confirmed by studies using recombinant protein in vitro and HeLa cells expressing RFP-YFP in vivo. Furthermore, we prepared nude mice subcutaneously xenografted HeLa cells expressing RFP-YFP cells as tumor model. The image ratios (YFP/RFP) of the tumor at the day 5 after surgery clearly showed the heterogeneous distribution of diverse pHin cells in the tumor tissue. Concomitantly acquired angiography using near-infrared fluorescence (680 nm for emission) also indicated that the relative alkaline pHin cells located in the region far from tumor vessels in which tumor aerobic glycolysis would be facilitated by progression of hypoxia and nutrient starvation. Applying the present method for a multi-wavelength imaging concerning pO2 and/or nutrient starvation states in addition to pHin and angiogenesis would provide valuable information about complicated alteration of tumoral cell states during tumorigenesis.

Increased 3-hydroxypropionic acid production from glycerol, by modification of central metabolism in Escherichia coli.

BACKGROUND: 3-hydroxypropionic acid (3HP) is an important chemical precursor for the production of bioplastics. Microbial production of 3HP from glycerol has previously been developed through the optimization of culture conditions and the 3HP biosynthesis pathway. In this study, a novel strategy for improving 3HP production in Escherichia coli was investigated by the modification of central metabolism based on a genome-scale metabolic model and experimental validation. RESULTS: Metabolic simulation identified the double knockout of tpiA and zwf as a candidate for improving 3HP production. A 3HP-producing strain was constructed by the expression of glycerol dehydratase and aldehyde dehydrogenase. The double knockout of tpiA and zwf increased the percentage carbon-molar yield (C-mol%) of 3HP on consumed glycerol 4.4-fold (20.1 ± 9.2 C-mol%), compared to the parental strain. Increased extracellular methylglyoxal concentrations in the ΔtpiA Δzwf strain indicated that glycerol catabolism was occurring through the methylglyoxal pathway, which converts dihydroxyacetone phosphate to pyruvate, as predicted by the metabolic model. Since the ΔtpiA Δzwf strain produced abundant 1,3-propanediol as a major byproduct (37.7 ± 13.2 C-mol%), yqhD, which encodes an enzyme involved in the production of 1,3-propanediol, was disrupted in the ΔtpiA Δzwf strain. The 3HP yield of the ΔtpiA Δzwf ΔyqhD strain (33.9 ± 1.2 C-mol%) was increased 1.7-fold further compared to the ΔtpiA Δzwf strain and by 7.4-fold compared to the parental strain. CONCLUSION: This study successfully increased 3HP production by 7.4-fold in the ΔtpiA Δzwf ΔyqhD E. coli strain by the modification of the central metabolism, based on metabolic simulation and experimental validation of engineered strains.

In vivo imaging of brain ischemia using an oxygen-dependent degradative fusion protein probe.

Within the ischemic penumbra, blood flow is sufficiently reduced that it results in hypoxia severe enough to arrest physiological function. Nevertheless, it has been shown that cells present within this region can be rescued and resuscitated by restoring perfusion and through other protective therapies. Thus, the early detection of the ischemic penumbra can be exploited to improve outcomes after focal ischemia. Hypoxia-inducible factor (HIF)-1 is a transcription factor induced by a reduction in molecular oxygen levels. Although the role of HIF-1 in the ischemic penumbra remains unknown, there is a strong correlation between areas with HIF-1 activity and the ischemic penumbra. We recently developed a near-infrared fluorescently labeled-fusion protein, POH-N, with an oxygen-dependent degradation property identical to the alpha subunit of HIF-1. Here, we conduct in vivo imaging of HIF-active regions using POH-N in ischemic brains after transient focal cerebral ischemia induced using the intraluminal middle cerebral artery occlusion technique in mice. The results demonstrate that POH-N enables the in vivo monitoring and ex vivo detection of HIF-1-active regions after ischemic brain injury and suggest its potential in imaging and drug delivery to HIF-1-active areas in ischemic brains.

Intracellular interactions between protein 4.1 and glycophorin C on transport vesicles, as determined by fluorescence correlation spectroscopy.

Interaction of protein 4.1 (4.1R) with the transmembrane protein glycophorin C (GPC) regulates the functions of erythrocyte membrane. Fluorescence correlation spectroscopy (FCS) was used to define the interaction of EGFP-4.1R with DsRed-GPC on transport vesicles (TVs) by measuring their fluctuation in living cells. DsRed-GPC expressed in HeLa cells was delivered to the plasma membrane through slow vesicle transport. EGFP-4.1R, which freely diffused in the cytosol when expressed alone, diffused slowly when co-expressed with DsRed-GPC, indicating association of EGFP-4.1R with TVs. Fluorescence cross-correlation spectroscopy (FCCS) showed direct interaction of EGFP-4.1R with DsRed-GPC on TVs. The present study demonstrates that 4.1R binds to GPC on TVs in living cells.

Crystal structure of sulfotransferase STF9 from Mycobacterium avium.

Sulfotransferases catalyze the sulfate conjugation of a wide variety of endogenous and exogenous molecules. Human pathogenic mycobacteria produce numerous sulfated molecules including sulfolipids which are well related to the virulence of several strains. The genome of Mycobacterium avium encodes eight putative sulfotransferases (stf1, stf4-stf10). Among them, STF9 shows higher similarity to human heparan sulfate 3-O-sulfotransferase isoforms than to the bacterial STs. Here, we determined the crystal structure of sulfotransferase STF9 in complex with a sulfate ion and palmitic acid at a resolution of 2.6 Å. STF9 has a spherical structure utilizing the classical sulfotransferase fold. STF9 exclusively possesses three N-terminal α-helices (α1, α2, α3) parallel to the 3'-phosphoadenosine-5'-phosphosulfate (PAPS) binding motif. The sulfate ion binds to the PAPS binding structural motif and the palmitic acid molecule binds in the deep cleft of the predicted substrate binding site suggesting the nature of endogenous acceptor substrate of STF9 resembles palmitic acid. The substrate binding site is covered by a flexible loop which may have involvement in endogenous substrate recognition. Based on the mutational study (Hossain et al., Mol Cell Biochem 350:155-162; 2011) and structural resemblance of STF9-sulfate ion-palmitic acid complex to the hHS3OST3 complex with PAP (3'-phosphoadenosine-5'-phosphate) and an acceptor sugar chain, Glu170 and Arg96 are appeared to be catalytic residues in STF9 sulfuryl transfer mechanism.

PET imaging of hypoxia-inducible factor-1-active tumor cells with pretargeted oxygen-dependent degradable streptavidin and a novel 18F-labeled biotin derivative.

PURPOSE: We aimed to evaluate the feasibility of using streptavidin-biotin-based pretargeting for positron emission tomography (PET) imaging of hypoxia-inducible factor (HIF)-1-active tumors. PROCEDURES: We used POS, a genetically engineered form of streptavidin that selectively stabilizes in HIF-1-active cells, and (4-(18)F-fluorobenzoyl)norbiotinamide ((18)F-FBB), a radiolabeled biotin derivative, for performing a biodistribution study and for PET imaging. The tumoral (18)F-FBB accumulation was compared to the HIF-1-dependent luciferase bioluminescence and HIF-1α immunohistochemical signal. RESULTS: (18)F-FBB accumulation was observed in POS-pretargeted tumors in mice (2.85 ± 0.55% injected dose per gram at 3 h), and clear PET images were obtained at the same time point. The tumoral (18)F-FBB accumulation positively correlated with luciferase bioluminescence (R = 0.72, P < 0.05), and most of the area showing (18)F-FBB accumulation corresponded to HIF-1α-positive areas. CONCLUSION: Pretargeting with POS and (18)F-FBB is an effective approach for PET imaging of HIF-1-active areas in tumors.

Molecular cloning, expression, and functional analysis of a predicted sulfotransferase STF9 from Mycobacterium avium.

Sulfotransferases catalyze the transfer of sulfate group from para-nitrophenyl sulfate (pNPS) or 3'-phosphoadenosine-5'-phosphosulfate (PAPS) onto acceptor molecules in the biosynthesis of sulfate esters. Human pathogenic mycobacteria are known to produce numerous sulfated molecules on their cell surface which have been implicated as important mediators in host-pathogen interactions. The open reading frame stf9, a predicted homologue of sulfotransferase in the Mycobacterium avium genomic data, was cloned and over expressed in Escherichia coli. The recombinant STF9 conserved the characteristic PAPS binding motif of sulfotransferase and was purified as a 44 kDa soluble protein which exhibited transfer of sulfate group from pNPS (K (m) 1.34 mM, V (max) 7.56 nmol/min/mg) onto 3'-phosphoadenosine-5'-phosphate (K (m) 0.24 mM, V (max) 10.36 nmol/min/mg). The recombinant STF9 protein was also capable of transferring sulfate group from PAPS onto certain acceptor substrates in E. coli, and showed binding affinity to the PAP-agarose resin, supporting the sulfotransferase activity of the recombinant STF9 protein. This is the first report of molecular evidence for sulfotransferase activity of a protein from M. avium. Mutation of Arg96 to Ala and Glu170 to Ala abolishes sulfotransferase activity, indicating the importance of Arg96 and Glu170 in STF9 activity catalysis.

Noninvasive tracking of donor cell homing by near-infrared fluorescence imaging shortly after bone marrow transplantation.

BACKGROUND: Many diseases associated with bone marrow transplantation (BMT) are caused by transplanted hematopoietic cells, and the onset of these diseases occurs after homing of donor cells in the initial phase after BMT. Noninvasive observation of donor cell homing shortly after transplantation is potentially valuable for improving therapeutic outcomes of BMT by diagnosing the early stages of these diseases. METHODOLOGY/PRINCIPAL FINDINGS: Freshly harvested near-infrared fluorescence-labeled cells were noninvasively observed for 24 h after BMT using a photon counting device to track their homing process. In a congenic BMT model, the homing of Alexa Fluor 750-labeled donor cells in the tibia was detected less than 1 h after BMT. In addition, subsequent cell distribution in an intraBM BMT model was successfully monitored for the first time using this method. In the allogeneic BMT model, T-cell depletion decreased the near-infrared fluorescence (NIRF) signals of the reticuloendothelial system. CONCLUSIONS/SIGNIFICANCE: This approach in several murine BMT models revealed that the transplanted cells homed within 24 h after transplantation. NIRF labeling is useful for tracking transplanted cells in the initial phase after BMT, and this approach can contribute to in vivo studies aimed at improving the therapeutic outcomes of BMT.

Rapid detection of hypoxia-inducible factor-1-active tumours: pretargeted imaging with a protein degrading in a mechanism similar to hypoxia-inducible factor-1alpha.

PURPOSE: Hypoxia-inducible factor-1 (HIF-1) plays an important role in malignant tumour progression. For the imaging of HIF-1-active tumours, we previously developed a protein, POS, which is effectively delivered to and selectively stabilized in HIF-1-active cells, and a radioiodinated biotin derivative, (3-(123)I-iodobenzoyl)norbiotinamide ((123)I-IBB), which can bind to the streptavidin moiety of POS. In this study, we aimed to investigate the feasibility of the pretargeting method using POS and (123)I-IBB for rapid imaging of HIF-1-active tumours. METHODS: Tumour-implanted mice were pretargeted with POS. After 24 h, (125)I-IBB was administered and subsequently, the biodistribution of radioactivity was investigated at several time points. In vivo planar imaging, comparison between (125)I-IBB accumulation and HIF-1 transcriptional activity, and autoradiography were performed at 6 h after the administration of (125)I-IBB. The same sections that were used in autoradiographic analysis were subjected to HIF-1alpha immunohistochemistry. RESULTS: (125)I-IBB accumulation was observed in tumours of mice pretargeted with POS (1.6%ID/g at 6 h). This result is comparable to the data derived from (125)I-IBB-conjugated POS-treated mice (1.4%ID/g at 24 h). In vivo planar imaging provided clear tumour images. The tumoral accumulation of (125)I-IBB significantly correlated with HIF-1-dependent luciferase bioluminescence (R=0.84, p<0.01). The intratumoral distribution of (125)I-IBB was heterogeneous and was significantly correlated with HIF-1alpha-positive regions (R=0.58, p<0.0001). CONCLUSION: POS pretargeting with (123)I-IBB is a useful technique in the rapid imaging and detection of HIF-1-active regions in tumours.

A novel strategy to tag matrix metalloproteinases-positive cells for in vivo imaging of invasive and metastatic activity of tumor cells.

Matrix metalloproteinases (MMPs) are endopeptidases responsible for degrading the extracellular matrix (ECM) and remodeling tissue in both physiological and pathological processes. MMP2 and membrane-type 1 MMP (MT1-MMP) have been associated with tumor invasion, metastasis and angiogenesis; therefore, a molecular imaging strategy assessing their activity may help to predict the malignancy of tumors. Here, we established a novel method of specifically tagging the surface of MMP2- and MT1-MMP-positive cells, and applied it to the development of an optical imaging probe. We constructed a protein-based probe composed of a glutathione-S-transferase (GST)-tag (Inhibitory [I]-domain), a polypeptide as a specific substrate for both MMP2 and MT1-MMP (Cleaved [C]-domain), a transmembrane domain of the epidermal growth factor receptor (Transmembrane [TM]-domain), and DsRed2 (Fluorescent [F]-domain). In vitro experiments clearly demonstrated that, after the probe was cleaved at the C-domain by the MMPs, the resultant TM-F-domain was inserted into the cellular membrane. Optical imaging experiments in vivo demonstrated that the probe was cleaved and specifically remained in tumor xenografts in a MMP-dependent manner. These results indicate that the release of the I-C-domain through the proteolytic cleavage of the C-domain by MMP2 and MT1-MMP triggers the tagging of cellular membranes with the TM-F-domain. The present feasibility study opens the door to the development of a novel imaging probe for tumor malignancy using positron emission tomography as well as an optical imaging device.

In vivo imaging of HIF-active tumors by an oxygen-dependent degradation protein probe with an interchangeable labeling system.

Hypoxia-inducible factor (HIF) functions as a master transcriptional regulator for adaptation to hypoxia by inducing adaptive changes in gene expression for regulation of proliferation, angiogenesis, apoptosis and energy metabolism. Cancers with high expression of the alpha subunit of HIF (HIFα) are often malignant and treatment-resistant. Therefore, the development of a molecular probe that can detect HIF activity has great potential value for monitoring tumor hypoxia. HIF prolyl hydroxylases (HPHDs) act as oxygen sensors that regulate the fate of HIFα protein through its oxygen-dependent degradation (ODD) domain. We constructed a recombinant protein PTD-ODD-HaloTag (POH) that is under the same ODD regulation as HIFα and contains protein transduction domain (PTD) and an interchangeable labeling system. Administration of near-infrared fluorescently labeled POH (POH-N) to mouse models of cancers allowed successful monitoring of HIF-active regions. Immunohistochemical analysis for intratumoral localization of POH probe revealed its specificity to HIF-active cells. Furthermore, lack of the PTD domain or a point mutation in the ODD domain abrogated the specificity of POH-N to HIF-active cells. Overall results indicate that POH is a practical probe specific to HIF-active cell in cancers and suggest its large potential for imaging and targeting of HIF-related diseases.

Selective killing of hypoxia-inducible factor-1-active cells improves survival in a mouse model of invasive and metastatic pancreatic cancer.

PURPOSE: Pancreatic cancer is characterized by intratumoral hypoxia, early and aggressive local invasion, and metastatic potential. Hypoxia-inducible factor-1 (HIF-1) is the major transcriptional activator of hypoxia-responsive genes and intratumoral hypoxia is associated with increased risk of metastasis. However, the behavior of the cells having HIF-1 activity during the malignant progression in pancreatic cancer has not been tested. EXPERIMENTAL DESIGN: We orthotopically transplanted pancreatic cancer cells stably transfected with a HIF-1-dependent luciferase reporter gene and monitored HIF-1 activity in vivo in control and POP33-treated mice. POP33 is a novel prodrug, which has potential to increase caspase-3 activity and induce apoptosis in HIF-1-active/hypoxic cells. RESULTS: In vivo optical imaging showed that HIF-1 activity proceeded along with local invasion, the peritoneal dissemination, and the liver metastasis. HIF-1-active hypoxic cells were selectively eradicated by POP33. Moreover, selective killing of HIF-1-active hypoxic cells significantly suppressed malignant progression, resulting in a significant improvement in survival rate. CONCLUSIONS: These results show that HIF-1-active cells constitute a large proportion of invading and metastatic cells and suggest that eradication of these cells may improve the outcome in advanced pancreatic cancer, a condition for which no effective therapy currently exists.

The HIF-1-active microenvironment: an environmental target for cancer therapy.

Solid tumors possess unique microenvironments that are exposed to chronic hypoxic conditions, so-called tumor hypoxia. Although more than half a century has passed since it was suggested that tumor hypoxia correlated with bad treatment outcomes and contributed to the recurrence of cancer, no fundamental solution to this problem has yet been found. Hypoxia-inducible factor HIF-1 is the main transcription factor that regulates the cellular response to hypoxia. It induces various genes, whose function is strongly associated with the malignant alteration of the entire tumor. The cellular changes induced by HIF-1 are extremely important therapeutic targets of cancer therapy, particularly in the therapy against refractory cancers. Therefore targeting strategies to overcome the HIF-1-active microenvironment are important for cancer therapy.

Imaging of HIF-1-active tumor hypoxia using a protein effectively delivered to and specifically stabilized in HIF-1-active tumor cells.

UNLABELLED: Hypoxia-inducible factor-1 (HIF-1) plays an important role in malignant tumor progression and in the development of resistance to radiotherapy. We designed a novel fusion protein (PTD-ODD-SAV [POS]) consisting of a protein transduction domain (PTD), streptavidin (SAV), and a portion of the oxygen-dependent degradation domain (ODD) of HIF-1alpha that confers the same oxygen-dependent regulation as HIF-1alpha on POS. (3-(123/125)I-iodobenzoyl)norbiotinamide ((123/125)I-IBB) was conjugated to the SAV moiety of POS to synthesize (123/125)I-IBB-labeled POS ((123/125)I-IPOS). The purpose of this study was to evaluate the feasibility of (123)I-IPOS as an imaging probe for HIF-1-active tumor hypoxia. METHODS: After a 24-h incubation of (125)I-IPOS with various tumor cell lines under either normoxic (20% O(2)) or hypoxic (0.1% O(2)) conditions, the intracellular radioactivity was investigated. Then, the biodistribution of (123/125)I-IPOS was examined with tumor-implanted mice, and an in vivo imaging study was performed. The tumoral accumulation of (125)I-IPOS was compared with HIF-1 activity using the mice carrying tumors with the HIF-1-dependent luciferase reporter gene. Furthermore, the intratumoral localization of (125)I-IPOS was examined by the autoradiographic study, and then the same slide was subjected to immunostaining for pimonidazole, which is the hypoxic marker. RESULTS: The ratios of radioactivity in hypoxic cells to that in normoxic cells were more than 2. These results indicate incorporation of (125)I-IPOS into these cells and degradation of (125)I-IPOS by normoxic tumor cells. In the biodistribution study, (125)I-IPOS accumulated in the tumor (1.4 +/- 0.3 percentage injected dose per gram) 24 h after administration. At that time, (125)I-IPOS showed high tumor-to-blood and tumor-to-muscle ratios (5.1 +/- 0.3 and 14.0 +/- 3.9, respectively). The tumors were clearly visualized by in vivo imaging 24 h after (123)I-IPOS injection (tumor-to-muscle ratio was 9.6). The tumoral accumulation of (125)I-IPOS correlated with HIF-1 activity (R = 0.71, P < 0.05), and its intratumoral distribution coincided with the hypoxic regions. CONCLUSION: (123)I-IPOS is a potential probe for the imaging of HIF-1 activity in tumors. Given the role of HIF-1 in tumor biology, its detection may be considered an indicator of aggressive cancer phenotypes.

Imaging and Targeting of the Hypoxia-inducible Factor 1-active Microenvironment.

Human solid tumors contain hypoxic regions that have considerably lower oxygen tension than normal tissues. They are refractory to radiotherapy and anticancer chemotherapy. Although more than half a century has passed since it was suggested that tumour hypoxia correlates with poor treatment outcomes and contributes to recurrence of cancer, no fundamental solution to this problem has been found. Hypoxia-inducible factor-1(HIF-1) is the main transcription factor that regulates the cellular response to hypoxia. It induces various genes, whose function is strongly associated with malignant alteration of the entire tumour. The cellular changes induced by HIF-1 are extremely important therapeutic targets of cancer therapy, particularly in therapy against refractory cancers. Therefore, targeting strategies to overcome the HIF-1-active microenvironment are important for cancer therapy. To Target HIF-1-active/ hypoxic tumor cells, we developed a fusion protein drug, PTD-ODD-Procaspase-3 that selectively induces cell death in HIF-1-active/hypoxic cells. The drug consists of the following three functional domains: the protein transduction domain (PTD), which efficiently delivers the fusion protein to hypoxic tumor cells, the ODD domain, which has a VHL-mediated protein destruction motif of human HIF-1α protein and confers hypoxia-dependent stabilization to the fusion proteins, and the human procaspase-3 proenzyme responsible for the cytocidal activity of the protein drug. In vivo imaging systems capable of monitoring HIF-1 activity in transplanted human cancer cells in mice are useful in evaluating the efficiency of these drugs and in study of HIF-1-active tumor cells.

[Development of fluorescent in vivo imaging probes for cancers].

Optical techniques are emerging as powerful new modalities for molecular imaging in vivo. Although they are less sensitive and poor in resolution, they have an advantage over other modalities such as PET, CT, and MR in terms of safety, easiness, economy, speed and especially multiplicity. Thus, they are expected to be modalities for the next generation to functionally image diseases. Because of low tissue penetrance, high dispersion and influence of autofluorescence, their application to in vivo imaging had not been successful until recently. Recent technological progression in an ultrasensitive charge-coupled device(CCD)camera and improvement of software have encouraged progress in optical in vivo imaging techniques. Furthermore, the recent advances in fluorescent imaging have been accelerated by near-infrared(NIR)dyes, which have higher tissue-penetrance in addition to lower autofluorescence from nontarget tissue. Studies with optical technologies will show further advances in molecular imaging and clinical medicine by themselves and by fusing with other modalities. This review gives an overview of recent progress in fluorescent in vivo imaging techniques and introduces our study for developing NIR fluorescent probes specific to tumor hypoxia, a hallmark of malignant tumors.