Tissue gradients of energy metabolites mirror oxygen tension gradients in a rat mammary carcinoma model.

PURPOSE: It has been shown that oxygen gradients exist in R3230AC tumors grown in window chambers. The fascial surface is better oxygenated than the tumor surface. The purpose of the present study was to determine whether gradients exist for energy metabolites and other end points related to oxygen transport. METHODS AND MATERIALS: Imaging bioluminescence was used to measure ATP, glucose, and lactate in cryosections of R3230AC tumors. Mean vessel density and hypoxic tissue fraction were assessed using immunohistochemistry. Tumor redox ratio was assessed by redox ratio scanning. RESULTS: Lactate content and hypoxic fraction increased, whereas ATP, glucose, redox ratio, and vessel density decreased from the fascial to the tumor surface. CONCLUSIONS: The data support a switch from aerobic to anaerobic metabolism concomitant with the PO2 gradient. The vascular hypoxia that exists in perfused vessels at the tumor surface leads to macroscopic tissue regions with restricted oxygen availability and altered metabolic status. Methods to reduce tumor hypoxia may have to take this into account if such gradients exist in human tumors. The results also have implications for hypoxia imaging, because macroscopic changes in PO2 (or related parameters) will be easier to see than PO2 gradients limited to the diffusion distance of oxygen.

Transcriptional response to hypoxia in human tumors.

BACKGROUND: The presence of hypoxic regions within solid tumors is associated with a more malignant tumor phenotype and worse prognosis. To obtain a blood supply and protect against cellular damage and death, oxygen-deprived cells in tumors alter gene expression, resulting in resistance to therapy. To investigate the mechanisms by which cancer cells adapt to hypoxia, we looked for novel hypoxia-induced genes. METHODS: The transcriptional response to hypoxia in human glioblastoma cells was quantified with the use of serial analysis of gene expression. The time course of gene expression in response to hypoxia in a panel of various human tumor cell lines was measured by real-time polymerase chain reaction. Hypoxic regions of human carcinomas were chemically marked with pimonidazole. Immunohistochemistry and in situ hybridization were used to examine gene expression in the tumor's hypoxic regions. RESULTS: From the 24 504 unique transcripts expressed, 10 new hypoxia-regulated genes were detected-all induced, to a greater extent than vascular endothelial growth factor, a hypoxia-induced mitogen that promotes blood vessel growth. These genes also responded to hypoxia in breast and colon cancer cells and were activated by hypoxia-inducible factor 1, a key regulator of hypoxic responses. In tumors, gene expression was limited to hypoxic regions. Induced genes included hexabrachion (an extracellular matrix glycoprotein), stanniocalcin 1 (a calcium homeostasis protein), and an angiopoietin-related gene. CONCLUSIONS: We have identified the genes that are transcriptionally activated within hypoxic malignant cells, a crucial first step in understanding the complex interactions driving hypoxia response. Within our catalogue of hypoxia-responsive genes are novel candidates for hypoxia-driven angiogenesis.

Radiation-induced hypoxia may perpetuate late normal tissue injury.

PURPOSE: The purpose of this study was to determine whether or not hypoxia develops in rat lung tissue after radiation. METHODS AND MATERIALS: Fisher-344 rats were irradiated to the right hemithorax using a single dose of 28 Gy. Pulmonary function was assessed by measuring the changes in respiratory rate every 2 weeks, for 6 months after irradiation. The hypoxia marker was administered 3 h before euthanasia. The tissues were harvested at 6 weeks and 6 months after irradiation and processed for immunohistochemistry. RESULTS: A moderate hypoxia was detected in the rat lungs at 6 weeks after irradiation, before the onset of functional or histopathologic changes. The more severe hypoxia, that developed at the later time points (6 months) after irradiation, was associated with a significant increase in macrophage activity, collagen deposition, lung fibrosis, and elevation in the respiratory rate. Immunohistochemistry studies revealed an increase in TGF-beta, VEGF, and CD-31 endothelial cell marker, suggesting a hypoxia-mediated activation of the profibrinogenic and proangiogenic pathways. CONCLUSION: A new paradigm of radiation-induced lung injury should consider postradiation hypoxia to be an important contributing factor mediating a continuous production of a number of inflammatory and fibrogenic cytokines.

Localization of tissue transglutaminase in human carotid and coronary artery atherosclerosis: implications for plaque stability and progression.

Although atherosclerosis progresses in an indolent state for decades, the rupture of plaques creates acute ischemic syndromes that may culminate in myocardial infarction and stroke. Mechanical forces and matrix metalloproteinase activity initiate plaque rupture, whereas tissue inhibitors of metalloproteinases have an important (albeit indirect) role in plaque stabilization. In this paper, an enzyme that could directly stabilize the plaque is described. Tissue transglutaminase (TG) catalyzes the formation of epsilon(gamma-glutamyl)lysine isopeptide bonds that are resistant to enzymatic, mechanical, and chemical degradation. We performed immunohistochemistry for TG in atherosclerotic human coronary and carotid arteries. TG was most prominent along the luminal endothelium and in the medium of the vessels with a distribution mirroring that of smooth muscle cells. Variable, often prominent, immunoreactivity for TG was also seen in the intima, especially in regions with significant neovascularization. Additionally, TG was detected in fibrous caps and near the "shoulder regions" of some plaques. A monoclonal antibody to the transglutaminase product epsilon(gamma-glutamyl)lysine isopeptide demonstrated co-localization with TG antigen. Transglutaminase activity was found in 6 of 14 coronary artery atherectomy samples. Cross-linking of TG substrates such as fibrinogen, fibronectin, vitronectin, collagen type I, and protease inhibitors stabilized the plaque. Furthermore, the activation of transforming growth factor-beta-1 by TG might be an additional mechanism for the promotion of plaque stabilization and progression by increasing the synthesis of extracellular matrix components.

Tamoxifen inhibits angiogenesis in estrogen receptor-negative animal models.

Inhibition of tumor angiogenesis is a therapeutic strategy that can inhibit tumor growth and metastases. The aim of this study was to determine whether the estrogen receptor (ER) ligand drug tamoxifen has antiangiogenic effects. We used three different models of angiogenesis, including measurement of microvessel densities in murine tumors, ex vivo aortic ring assays, and corneal pocket assays. ER-negative fibrosarcoma tumors in tamoxifen-treated ovariectomized rats had significantly less vessel formation compared with untreated animals (median microvessel density, 53.6 versus 94.3 counts/per x 200 field; P = 0.002). Rat aortic rings treated with tamoxifen at several different concentrations demonstrated significantly less vascular sprouting than control rings (P = 0.0001). Corneal pocket assays performed in tamoxifen-treated rats compared with control and estrogen-treated rats demonstrated decreased vascular length (0.88 mm versus 1.26 mm versus 1.47 mm; P = 0.022) and vessel area (21% versus 34% versus 47%; P = 0.018). These three animal models all showed significant inhibition of angiogenesis by tamoxifen and suggest a possible contributory mechanism of ER-independent manipulation by tamoxifen in the treatment and prevention of breast cancer. These studies raise the question as to whether or not newer ER ligand drugs might possess even more potent antiangiogenic effects, which in turn could lead to the broadening of the clinical usefulness of these compounds in a number of diseases. More importantly, these studies suggest that the antiangiogenic effects of tamoxifen are due, in part, to ER-independent mechanisms.

Review of methods used to study oxygen transport at the microcirculatory level.

The existence of hypoxic regions in tumors has long been recognized as a key factor leading to radiation resistance. More recently, it has been found that low oxygen levels also affect drug resistance, angiogenesis, cytokine production, cell cycle control, apoptosis, and metastatic propensity of tumors. Until now, most approaches to eliminating hypoxia have been empirical. However, improved understanding of the underlying mechanisms may permit the development of more soundly based, effective approaches. As discussed in this review, critical evaluation of the factors governing oxygen transport in tumors requires a thorough understanding of the methods used to study this process. Many experimental methodologies can be used to address these issues. In this review, the emphasis is placed on techniques that measure parameters on the scale of the diffusion distance of oxygen. Studies at the microregional level provide the most detailed physiological information on such processes. Over the past few years, significant progress in technology has allowed us to measure tumor oxygenation, yet spatial and temporal heterogeneities continue to provide significant challenges to obtaining clear knowledge of oxygen transport.

Early wound healing exhibits cytokine surge without evidence of hypoxia.

OBJECTIVE: To ascertain the spatial and temporal relation of wound hypoxia to the cell types involved, expression of selected angiogenic cytokines, the proliferative status of cells in the wound site, and angiogenesis. SUMMARY BACKGROUND DATA: Hypoxia is considered to drive the angiogenic response by upregulating angiogenic cytokines observed during wound healing. But this correlation has not been shown on a cell-to-cell basis in vivo because of limitations in measuring tissue PO2 at the cellular level. METHODS: Using punch biopsy wounds in rats as a wound healing model, the distributions of vascular endothelial growth factor, transforming growth factor-beta, tumor necrosis factor-alpha, and pimonidazole adducts (as a hypoxia marker) were followed immunohistochemically during the healing process. RESULTS: Hypoxia was absent on day 1 after wounding, even though angiogenesis and maximal expression of cytokines were observed in the wounds. Hypoxia peaked in the granulation tissue stage at day 4 and correlated with increased cellularity and cellular proliferation. Hypoxia started to decrease after day 4 and was limited to the remnant blood vessels and epithelial layer in the scar tissue. CONCLUSIONS: Induction of angiogenic cytokines early during wound healing may be due to triggering mechanisms other than hypoxia. Alternatively, the unique pattern of development and decline of cellular hypoxia as wound cellularity and proliferation regress suggest its involvement in initiating vascular regression during the later stages of healing.

Tissue transglutaminase is expressed, active, and directly involved in rat dermal wound healing and angiogenesis.

Tissue transglutaminase (TG) is an enzyme that stabilizes the structure of tissues by covalently ligating extracellular matrix molecules. Expression and localization of TG are not well established during wound healing. We performed punch biopsy wounds on anesthetized rats and monitored the wound healing process by histological and immunohistochemical methods. The TG antigen and activity are expressed at sites of neovascularization in the provisional fibrin matrix within 24 h of wounding. Endothelial cells, macrophages, and skeletal muscle cells expressed TG throughout the healing process. The TG antigen within the wound was active in vivo based on the detection of isopeptide bonds. The TG antigen increased four- to fivefold by day 3 postwounding and was proteolytically degraded. TG expression occurred in association with TGF-beta, TNF-alpha, IL-6, and VEGF production in the wound. Recombinant TG increased vessel length density (a measure of angiogenesis) when applied topically in rat dorsal skin flap window chambers. We have established that TG is an important tissue stabilizing enzyme that is active during wound healing and can function to promote angiogenesis.

Tissue transglutaminase is expressed as a host response to tumor invasion and inhibits tumor growth.

A stable extracellular matrix (ECM) constitutes an important part of host response mechanism against tumor growth and invasion. Tissue transglutaminase (TG), a calcium-dependent enzyme, can cross-link all major ECM proteins to form a stable ECM, because these cross-links are resistant to proteolytic and mechanical damage. TG can also enhance stability and strength of the ECM by its ability to facilitate the activation of transforming growth factor-beta. We hypothesized that TG ECM-promoting abilities form an important part of the host response mechanism against tumor growth. Increased expression of TG was observed in the ECM of the host tumor interface of subcutaneously implanted rat mammary adenocarcinoma R3230 Ac. TG expression was also detected in the endothelial cells and macrophages. We also detected the cross-link product at the host tumor interface and within the tumor tissue, showing that TG was active. Western blots showed TG was degraded into three fragments of 55-, 50-, and 20-kDa forms. When recombinant wild-type TG was applied to R3230 Ac implanted in rat dorsal skin flap window chamber, it caused significant growth delay at day 7 compared with recombinant inactive TG controls. Collagen was detected in increased amounts in TG treated tumors, suggesting augmentation of production and stability of the ECM. We conclude that TG forms a distinct part of host response system against and acts to inhibit tumor growth.

Tie2 expression and phosphorylation in angiogenic and quiescent adult tissues.

Angiogenesis, the process of new vessels sprouting from the existing vasculature, is a critical process during early development. However, angiogenesis rarely occurs in the adult, except in response to cyclic hormonal stimulation in the ovary and uterus, in response to injury, and in response to pathological conditions such as tumorigenesis and diabetes mellitus. Tie2 (also known as Tek) is a novel endothelium-specific receptor tyrosine kinase, which has been demonstrated to be essential for the development of the embryonic vasculature; Tie2 knockout mice die by embryonic day 10.5 with specific defects in the formation of microvessels. Tie2 is downregulated later in embryogenesis, and its function in the adult has been relatively unexplored. To gain insight into the potential functions of Tie2 in the adult vasculature, Tie2 expression was examined in adult tissues undergoing angiogenesis and in quiescent tissues. Tie2 expression was localized by immunohistochemistry to the endothelium of neovessels in rat tissues undergoing angiogenesis during hormonally stimulated follicular maturation and uterine development and in healing skin wounds. Immunoprecipitation and RNase protection assay demonstrated upregulation of Tie2 protein and mRNA in rat and mouse skin wounds, respectively. Moreover, Tie2 immunoprecipitated from skin wounds was tyrosine-phosphorylated, indicating active downstream signaling. Surprisingly, Tie2 was also expressed in the entire spectrum of the quiescent vasculature (arteries, veins, and capillaries) in a wide range of adult tissues, and Tie2 immunoprecipitated from quiescent adult tissues was also tyrosine-phosphorylated. Together, these results suggest a dual function for Tie2 in adult tissues involving both angiogenesis and vascular maintenance.

C-terminal deletion of human tissue transglutaminase enhances magnesium-dependent GTP/ATPase activity.

Tissue transglutaminase (tTG) exhibits a magnesium-dependent GTP/ATPase activity that is involved in the regulation of the cell cycle and cell receptor signaling. The portion of the molecule involved in GTP/ATP hydrolysis is unknown. We expressed and purified a series of C-terminal truncation mutants of human tTG as glutathione S-transferase fusion proteins (DeltaS538, DeltaE447, DeltaP345, DeltaC290, DeltaV228, and DeltaF185) to determine the effect on GTP/ATPase activity. The truncation of the C terminus did not change significantly the apparent Km value for either GTP or ATP. In contrast, the Kcat value for GTP was increased by 4.6- and 3-fold for the DeltaS538 and DeltaE447 mutants, respectively. The DeltaP345 mutant had the highest hydrolysis activity with a 34-fold increase. The hydrolysis activity then declined to 8.1-, 8.7-, and 1. 9-fold for the DeltaC290, DeltaV228, and DeltaF185 mutants, respectively. The Kcat for ATP changed in parallel with the GTPase results. Thin layer chromatography analysis of the hydrolysis reaction products revealed that ATP was rapidly converted to ADP followed by a much slower conversion of ADP to AMP when incubated with wild type tTG or the DeltaP345 mutant. There was a substantial decrease in the calcium-dependent TGase activity when the last 149 amino acid residues were deleted from the C terminus. Less than 5% of the TGase activity was detected for the DeltaS538 and DeltaE447 mutants. In conclusion, we have located the ATP and GTP hydrolytic domain to amino acid residues 1-185. The C terminus functions to inhibit the expression of endogenous GTP/ATPase activity of tTG, and the potential role of the C terminus in modulating this activity is discussed.

Tissue transglutaminase expression in human breast cancer.

Tissue transglutaminase (tTG) is postulated to play a role in apoptosis, cell adhesion, metastasis, and extracellular matrix (ECM) assembly. In this study, the distribution and expression of tissue transglutaminase was investigated in normal human mammary tissue and in intraductal and invasive human breast cancer by immunohistochemistry and in situ hybridization. Frozen and formalin-fixed paraffin-embedded sections of normal, intraductal, and invasive human breast carcinoma were examined with an avidin-biotin complex immunoperoxidase method for tTG antigen and by in situ hybridization to determine the cell types expressing tTG mRNA. The expression of tTG in normal and malignant mammary epithelium in culture was evaluated by quantitative immunoblot analysis. Low-level expression of tTG was found in normal tissues with the antigen located in the ECM surrounding the ducts and in the endothelium. In intraductal cancer, there was a marked increased expression of the tTG antigen, and the increased staining was found in the ECM and was also localized in a distinct pattern at the boundary between the in situ tumor cells and the normal tissue. Further immunohistochemical analysis revealed that the cells in this boundary also stained for the endothelial cell markers CD31, CD34, and von Willebrand factor. In invasive tumors, the tTG antigen was no longer localized to the normal tissue/tumor boundary but dispersed around the tumor cells. In situ hybridization studies revealed three distinct compartments of tTG synthesis: (a) tumor cells, (b) endothelial cells, and (c) stromal cells. In addition, normal and malignant epithelial cells in culture expressed variable amounts of tTG, and the expression of tTG in these epithelial cells was at least 17-fold less than endothelial cells. The up-regulation of tTG in intraductal and invasive human breast cancer and its localization to the ECM and neovasculature suggest that tTG may regulate tumor growth and metastasis.