Annette Altmann

FDG uptake, tumor proliferation and expression of glycolysis associated genes in animal tumor models

To determine the influence of tumor cell proliferation and changes in the genetic program in malignant cells on the fluorodeoxyglucose (FDG) uptake we performed PET studies in several animal tumors: spontaneous mammary fibroadenoma, chemically-induced mammary adenocarcinoma and Dunning prostate adenocarcinoma. The expression of the glucose transporter (GLUT1) and of hexokinase (Hk) was measured using 32P-labeled cDNA probes and densitometry. Furthermore the proliferative activity was determined with one-dimensional flow cytometry. The FDG uptake and the proliferation parameters were not correlated. The normalized amounts of GLUT and Hk mRNA were lower in spontaneous fibroadenomas and prostate tumors than in chemically induced mammary. The FDG uptake was correlated to GLUT1 expression with r = 0.83 and to Hk expression with r = 0.77. Multiple regression analysis revealed a relation of FDG uptake to GLUT1 and HK with r = 0.87. Our results show that the FDG uptake in our study was related not to differences in proliferation, but rather to differences in the transcription of glycolysis associated genes.

The pharmacokinetics of cell-penetrating peptides.

Cell-penetrating peptides (CPPs) are able to penetrate the cell membrane carrying cargoes such as peptides, proteins, oligonucleotides, siRNAs, radioisotopes, liposomes, and nanoparticles. Consequently, many delivery approaches have been developed to use CPPs as tools for drug delivery. However, until now a systematic analysis of their in vivo properties including potential tumor binding specificity for drug targeting purposes has not been conducted. Ten of the most commonly applied CPPs were obtained by solid phase peptide synthesis and labeled with (111)In or (68)Ga. Uptake studies were conducted using a panel of six tumor cell lines of different origin. The stability of the peptides was examined in human serum. Biodistribution experiments were conducted in nude mice bearing human prostate carcinoma. Finally, positron emission tomography (PET) measurements were performed in male Wistar rats. The in vitro uptake studies revealed high cellular uptake values, but no specificity toward any of the cell lines. The biodistribution in PC-3 tumor-bearing nude mice showed a high transient accumulation in well-perfused organs and a rapid clearance from the blood. All of the CPPs revealed a relatively low accumulation rate in the brain. The highest uptake values were observed in the liver (with a maximal uptake of 51 %ID/g observed for oligoarginine (R(9))) and the kidneys (with a maximal uptake of 94 %ID/g observed for NLS). The uptake values in the PC-3 tumor were low at all time points, indicating a lack of tumor specific accumulation for all peptides studied. A micro-PET imaging study with (68)Ga-labeled penetratin, Tat and transportan(10) (TP(10)) confirmed the organ distribution data. These data reveal that CPPs do not show evidence for application in tumor targeting purposes in vivo. However, CPPs readily penetrate into most organs and show rapid clearance from the circulation. The high uptake rates observed in vitro and the relatively low specificity in vivo imply that CPPs would be better suited for topical application in combination with cargoes which show passive targeting and dominate the pharmacokinetic behavior. In conclusion, CPPs are suitable as drug carriers for in vivo application provided that their pharmacokinetic properties are also considered in design of CPP drug delivery systems.

Enhanced iodide transport after transfer of the human sodium iodide symporter gene is associated with lack of retention and low absorbed dose

Transfer of the sodium iodide symporter (hNIS) has been proposed as a new principle of cancer gene therapy. Using clinically relevant doses of 131I for the treatment of NIS-expressing prostate carcinoma cells, we investigated the kinetics and the absorbed doses obtained in these tumors. hNIS-expressing cell lines accumulated up to 200 times more iodide when compared to wild-type cells. However, a rapid efflux of the radioactivity (80%) occurred during the first 20 min after replacement of the medium. In rats, the hNIS-expressing tumors accumulated up to 20 times more iodide when compared to contralateral transplanted wild-type tumors. After 24 h and doses of 550, 1200 or 2400 MBq/m2 hNIS-expressing tumors lost 89, 89 and 91% of the initial activity, respectively. Dosimetric calculations showed that 1200 MBq/m2 resulted in 3±0.5 Gy (wild-type tumor 0.15±0.1 Gy) and 2400 MBq/m2 resulted in 3.1±0.9 Gy (wild-type tumor 0.26±0.02 Gy). Although transduction of the hNIS gene induces iodide transport in rat prostate adenocarcinoma a rapid efflux occurs, which leads to a low absorbed dose in genetically modified tumors. With regard to a therapeutic application additional conditions need to be defined leading to iodide trapping.

Specificity of human cytotoxic T lymphocytes induced by a human papillomavirus type 16 E7-derived peptide

In order to establish tumour-specific cytotoxic T lymphocyte (CTL) cell lines, T cells from a human papillomavirus (HPV) type 16-positive patient with a cervical carcinoma in situ and from a healthy volunteer were stimulated in vitro with autologous dendritic cells loaded with peptides derived from the viral transforming proteins E6 and E7 and corresponding to potential HLA-A*0201-restricted T cell epitopes. From each donor a small number of low-affinity CTL lines against the peptide E7/86-93 was obtained, which specifically lysed HLA-A*0201-expressing B-lymphocytes (cell line 721) loaded with this peptide. Cytotoxicity was also observed against two HLA-A*0201-E7-positive epithelial cell lines, the cervical carcinoma cell line CaSki and the HPV-16-immortalized foreskin-keratinocyte cell line HPK IA. However, since none of the CTL recognized both cell lines, and E7-expressing 721 transfectants were never lysed, it was concluded that the reactivity against CaSki and HPK IA cells was due to cross-reactivity on allogeneic HLA molecules rather than to E7 recognition, which emphasizes that the specificity of tumour cell lysis by peptide-induced CTL has to be interpreted with caution.

Ganciclovir Uptake in Human Mammary Carcinoma Cells Expressing Herpes Simplex Virus Thymidine Kinase

Assessment of suicide enzyme activity would have considerable impact on the planning and the individualization of suicide gene therapy of malignant tumors. This may be done by determining the pharmacokinetics of specific substrates. We generated ganciclovir (GCV)-sensitive human mammary carcinoma cell lines after transfection with a retroviral vector bearing the herpes simplex virus thymidine kinase (HSV-tk) gene. Thereafter, uptake measurements and HPLC analyses were performed up to 48 h in an HSV-tk-expressing cell line and in a wild-type cell line using tritiated GCV. HSV-tk-expressing cells showed higher GCV uptake and phosphorylation than control cells, whereas in wild-type MCF7 cells no phosphorylated GCV was detected. In bystander experiments the total GCV uptake was related to the amount of HSV-tk-expressing cells. Furthermore, the uptake of GCV correlated closely with the growth inhibition (r = 0.92). Therefore, the accumulation of specific substrates may serve as an indicator of the HSV-tk activity and of therapy outcome. Inhibition and competition experiments demonstrated slow transport of GCV by the nucleoside carriers. The slow uptake and low affinity to HSV-tk indicate that GCV is not an ideal substrate for the nucleoside transport systems or for HSV-tk. This may be the limiting factor for therapy success, necessitating the search for better substrates of HSV-tk.

Functional genomics and proteomics – the role of nuclear medicine

Abstract. Now that the sequencing of the human genome has been completed, the basic challenges are finding the genes, locating their coding regions and predicting their functions. This will result in a new understanding of human biology as well as in the design of new molecular structures as potential novel diagnostic or drug discovery targets. The assessment of gene function may be performed using the tools of the genome program. These tools represent high-throughput methods used to evaluate changes in the expression of many or all genes of an organism at the same time in order to investigate genetic pathways for normal development and disease. This will lead to a shift in the scientific paradigm: In the pre-proteomics era, functional assignments were derived from hypothesis-driven experiments designed to understand specific cellular processes. The new tools describe proteins on a proteome-wide scale, thereby creating a new way of doing cell research which results in the determination of three-dimensional protein structures and the description of protein networks. These descriptions may then be used for the design of new hypotheses and experiments in the traditional physiological, biochemical and pharmacological sense. The evaluation of genetically manipulated animals or newly designed biomolecules will require a thorough understanding of physiology, biochemistry and pharmacology and the experimental approaches will involve many new technologies, including in vivo imaging with single-photon emission tomography and positron emission tomography. Nuclear medicine procedures may be applied for the determination of gene function and regulation using established and new tracers or using in vivo reporter genes such as enzymes, receptors, antigens or transporters. Pharmacogenomics will identify new surrogate markers for therapy monitoring which may represent potential new tracers for imaging. Also, drug distribution studies for new therapeutic biomolecules are needed, at least during preclinical stages of drug development. Finally, new biomolecules will be developed by bioengineering methods which may be used for isotope-based diagnosis and treatment of disease.

Uncoupling of 2-fluoro-2-deoxyglucose transport and phosphorylation in rat hepatoma during gene therapy with HSV thymidine kinase

This animal study investigates the application of positron emission tomography (PET) with tracers of tumour metabolism for monitoring suicide gene therapy with herpes simplex virus thymidine kinase (HSVtk). After transplantation of HSVtk-expressing Morris hepatoma cells into ACI rats, dynamic PET measurements of 18F-labeled 2-fluoro-2-deoxyglucose (FDG) uptake were performed in animals 2 days (n = 7) and 4 days (n = 5) after the onset of therapy with 100 mg ganciclovir (GCV)/kg body weight as well as after administration of sodium chloride (n = 8). The arterial FDG plasma concentration was measured dynamically in an extracorporeal loop and the rate constants for FDG transport (K1, k2) and FDG phosphorylation (k3) were calculated using a three-compartment model modified for heterogeneous tissues. Also, quantification using the metabolic rate of FDG turnover and the standardized uptake value (SUV) was done. Furthermore, the thymidine incor- poration into the tumour DNA was determined after i.v. administration of 3H-thymidine. An uncoupling of FDG transport and phosphorylation was found with enhanced K1 and k2 values and a normal k3 after 2 days of GCV treatment. The increase in FDG transport normalized after 4 days whereas the phosphorylation rate k3 increased. Quantification using the metabolic rate or the SUV showed congruent but less sensitive results compared with the modeling approach. The thymidine incorporation into the DNA of the tumours declined to 10.5% of the controls after 4 days of GCV treatment. The data indicate that PET with 18FDG and 11C-thymidine may be applied for monitoring of gene therapy with the HSVtk/GCV suicide system. Increased transport rates are evidence of stress reactions early after therapy. The measurement of thymidine incorporation into the tumour DNA can be used as an indicator of therapy efficacy.

Identification and Characterization of a Peptide with Affinity to Head and Neck Cancer

Combination therapy has improved the quality of life for patients with squamous cell carcinomas of the head and neck (HNSCCs) but has not decisively changed prognosis. Targeted therapies, which enhance accumulation of the drug in the tumor, may be realized using tumor-specific binding peptides. This paper identifies and characterizes an HNSCC affine peptide. Methods: From a phage library comprising 109 different displayed peptides, 1 peptide was enriched after 5 in vitro selection rounds on HNO223 tumor cells. Subsequently, the gained peptide sequence H2N-SPRGDLAVLGHKY-CONH2 (HBP-1) was synthesized as an amide and labeled with 125I. In vitro studies for binding kinetics and competition were performed with 5 different HNSCC cell lines. Furthermore, the stability of the peptide was evaluated in human serum. The in vivo biodistribution of 131I-labeled peptide was determined in HNSCC tumor–bearing nude mice. The results were further validated in human HNSCC tumor tissue sections using fluorescence-labeled HBP-1. Competition experiments were performed to determine the binding sequence and validate the target. Results: The HBP-1 motif was enriched in 62% of all phages sequenced. Labeled 125I-HBP-1 showed binding to 5 different HNSCC cell lines and a maximum binding to HNO97 cells, with 11% of the applied dose per 106 cells and an inhibitory concentration of 50% of 38.9 nM. Stability experiments in human serum showed a half-life of 55 min. In 2 different HNSCC tumor xenografts, 131I-HBP-1 accumulated rapidly, with stable uptake until 45 min after intravenous application. Peptide immunohistochemistry of HNSCC tissue sections exhibited tumor staining by HBP-1, whereas normal tissue remained negative. Sequence mutation and competition experiments revealed that the intrinsic RGD motif in combination with the intrinsic LXXL motif is responsible for the binding ability of HBP1. The RGDLXXL sequence within this peptide is known and indicates that binding occurs via the αvβ6 rather than the αvβ3 integrin. Conclusion: Within the sequence of HBP-1 is a RGDLXXL motif, and most likely it is targeting the αvβ6 receptor of the integrin family of cell adhesion receptors. HBP-1 represents a promising lead structure for the development of targeted therapies or diagnostic procedures in patients with HNSCC.

Molecular imaging of tumor metabolism and apoptosis.

Increased metabolism in a number of cellular pathways is a common feature of malignant tumors. This metabolic hallmark of neoplastic tissue led to the development of radiopharmaceuticals for the assessment of transport and enzymatic activity for tumor diagnosis and staging. The malignant transformation causes the activation of oncogenic proteins and signaling pathways that stimulate glycolysis. The resulting high-glucose metabolism of cancer cells allows PET imaging using FDG. Other molecules frequently applied in preclinical and clinical studies are 11C-methionine, tyrosine analogs and choline-based tracers. Using quantitative procedures they enable therapy monitoring by assessment of changes in transport and metabolization. As apoptosis is an important mechanism of cell death in tumors responding to treatment, non-invasive assessment of apoptosis using tracers for detection of phosphatidyl-serine presentation and/or caspase activation could be used as a surrogate marker for therapeutic efficacy.

Imaging methods in gene therapy of cancer.

Clinical gene therapy needs non invasive tools to evaluate the efficiency of gene transfer. This includes the evaluation of infection efficiency as well as the verification of successful gene transfer in terms of gene transcription. These informations can be used for therapy planning, follow up studies in treated tumors and as an indicator of prognosis. Therapy planning is performed by the assessment of gene expression for example using radiolabeled specific substrates to determine the activity of suicide enzymes as the Herpes Simplex Virus thymidine kinase or cytosine deaminase. Furthermore, other in vivo reporter genes as receptors, antigens or transport proteins may be used in bicistronic vector systems for the evaluation of gene transduction and expression. This is done using radiolabeled ligands, antigens or substrates. Follow up studies with magnetic resonance imaging, single photon emission tomography or positron emission tomography may be done to evaluate early or late effects of gene therapy on tumor volume, metabolism or proliferation. Finally, enhancement of radioactive isotope accumulation in tumors by transfer of the appropriate genes may be used for the treatment of malignant tumors.