Haibin Tian

Transcriptional profiling of human mesenchymal stem cells transduced with reporter genes for imaging

Mesenchymal stem cells (MSCs) can differentiate into osteogenic, adipogenic, chondrogenic, myocardial, or neural lineages when exposed to specific stimuli, making them attractive for tissue repair and regeneration. We have used reporter gene-based imaging technology to track MSC transplantation or implantation in vivo. However, the effects of lentiviral transduction with the fluc-mrfp-ttk triple-fusion vector on the transcriptional profiles of MSCs remain unknown. In this study, gene expression differences between wild-type and transduced hMSCs were evaluated using an oligonucleotide human microarray. Significance Analysis of Microarray identified differential genes with high accuracy; RT-PCR validated the microarray results. Annotation analysis showed that transduced hMSCs upregulated cell differentiation and antiapoptosis genes while downregulating cell cycle, proliferation genes. Despite transcriptional changes associated with bone and cartilage remodeling, their random pattern indicates no systematic change of crucial genes that are associated with osteogenic, adipogenic, or chondrogenic differentiation. This correlates with the experimental results that lentiviral transduction did not cause the transduced MSCs to lose their basic stem cell identity as demonstrated by osteogenic, chondrogenic, and adipogenic differentiation assays with both transduced and wild-type MSCs, although a certain degree of alterations occurred. Histological analysis demonstrated osteogenic differentiation in MSC-loaded ceramic cubes in vivo. In conclusion, transduction of reporter genes into MSCs preserved the basic properties of stem cells while enabling noninvasive imaging in living animals to study the biodistribution and other biological activities of the cells.

[(Methyl)1-11C]-Acetate Metabolism in Hepatocellular Carcinoma

PurposeStudies have established the value of [(methyl)1-11C]-acetate ([11C]Act) combined with 2-deoxy-2[18F]fluoro-d-glucose (FDG) for detecting hepatocellular carcinoma (HCC) using positron emission tomography (PET). In this study, the metabolic fate of [11C]Act in HCC was characterized.MethodsExperiments with acetic acid [1-14C] sodium salt ([14C]Act) were carried out on WCH-17 cells and freshly derived rat hepatocytes. PET scans with [11C]Act were also carried out on woodchucks with HCC before injection of [14C]Act. The radioactivity levels in different metabolites were quantified with thin-layer chromatography.ResultsIn WCH-17 cells, the predominant metabolite was phosphatidylcholine (PC). Regions of HCCs with the highest [11C]Act uptake had higher radioactivity accumulation in lipid-soluble compounds than surrounding hepatic tissues. In those regions, PC and triacylglycerol (TG) accumulated more radioactivity than in surrounding hepatic tissues.ConclusionsHigh [11C]Act uptake in HCC is associated with increased de novo lipogenesis. PC and TG are the main metabolites into which the radioactive label from [11C]Act is incorporated in HCC.

Imaging Lipid Synthesis in Hepatocellular Carcinoma with [Methyl-11C]Choline: Correlation with In Vivo Metabolic Studies

PET with [methyl-11C]-choline (11C-choline) can be useful for detecting well-differentiated hepatocellular carcinoma (HCC) that is not 18F-FDG–avid. This study was designed to examine the relationship between choline metabolism and choline tracer uptake in HCC for PET with 11C-choline. Methods: Dynamic PET scans of 11C-choline were acquired using the woodchuck models of HCC. After imaging, [methyl-14C]-choline was injected, and metabolites from both HCC tissue samples and the surrounding hepatic tissues were extracted and analyzed by radio–high-performance liquid chromatography. The enzymatic activities of choline kinase and choline-phosphate cytidylyltransferase were assayed for correlation with the imaging and metabolism data. Results: PET with 11C-choline showed an HCC detection rate of 9 of 10. The tumor-to-liver ratio for the 9 detected HCCs was 1.89 ± 0.55. Hematoxylin-eosin staining confirmed that all spots with high tracer uptake were well-differentiated HCCs. Variation of radioactivity distribution within HCCs indicated a heterogeneous uptake of choline. The activities of both choline kinase and choline-phosphate cytidylyltransferase were found to be significantly higher in HCC than in the surrounding hepatic tissues. The major metabolites of 11C-choline were phosphocholine in HCC and betaine and choline in the surrounding hepatic tissues at 12 min after injection; in HCC, phosphocholine rapidly converted to phosphatidylcholine at 30 min after injection. Conclusion: HCCs display enhanced uptake of radiolabeled choline despite a moderate degree of physiologic uptake in the surrounding hepatic tissues. Initially, increased radiolabeled choline uptake in HCCs is associated with the transport and phosphorylation of choline; as time passes, the increased uptake of radiolabeled choline reflects increased phosphatidylcholine synthesis derived from radiolabeled cytidine 5′-diphosphocholine (CDP-choline) in HCCs. In contrast, the surrounding hepatic tissues exhibit extensive oxidation of radiolabeled choline via the phosphatidylethanolamine methylation pathway, a major contributor to the observed physiologic uptake.

Transport and metabolism of radiolabeled choline in hepatocellular carcinoma.

Altered choline (Cho) metabolism in cancerous cells can be used as a basis for molecular imaging with PET using radiolabeled Cho. In this study, the metabolism of tracer Cho was investigated in a woodchuck hepatocellular carcinoma (HCC) cell line (WCH17) and in freshly derived rat hepatocytes. The transporter responsible for [(11)C]-Cho uptake in HCC was also characterized in WCH17 cells. The study helped to define the specific mechanisms responsible for radio-Cho uptake seen on the PET images of primary liver cancer such as HCC. Cells were pulsed with [(14)C]-Cho for 5 min and chased for varying durations in cold media to simulate the rapid circulation and clearance of [(11)C]-Cho. Radioactive metabolites were extracted and analyzed by radio-HPLC and radio-TLC. The Cho transporter (ChoT) was characterized in WCH17 cells. WCH17 cells showed higher (14)C uptake than rat primary hepatocytes. [(14)C]-Phosphocholine (PC) was the major metabolite in WCH17. In contrast, the intracellular Cho in primary hepatocytes was found to be oxidized to betaine (partially released into media) and, to a lesser degree, phosphorylated to PC. [(14)C]-Cho uptake by WCH17 cells was found to have both facilitative transport and nonfacilitative diffusion components. The facilitative transport was characterized by Na(+) dependence and low affinity (K(m) = 28.59 ± 6.75 μM) with partial energy dependence. In contrast, ChoT in primary hepatocytes is Na(+) independent and low affinity. Our data suggest that transport and phosphorylation of Cho are responsible for the tracer accumulation during [(11)C]-Cho PET imaging of HCC. WCH17 cells incorporate [(14)C]-Cho preferentially into PC. Conversion of [(14)C]-PC into phosphatidylcholine occurred slowly in vitro. Basal oxidation and phosphorylation activities in surrounding hepatic tissue contribute to the background seen in [(11)C]-Cho PET images.

Radio-deoxynucleoside Analogs used for Imaging tk Expression in a Transgenic Mouse Model of Induced Hepatocellular Carcinoma.

Purpose: A group of radiolabeled thymidine analogs were developed as radio-tracers for imaging herpes viral thymidine kinase (HSV1-tk) or its variants used as reporter gene. A transgenic mouse model was created to express tk upon liver injury or naturally occurring hepatocellular carcinoma (HCC). The purpose of this study was to use this unique animal model for initial testing with radio-labeled thymidine analogs, mainly a pair of newly emerging nucleoside analogs, D-FMAU and L-FMAU. Methods: A transgeneic mouse model was created by putting a fused reporter gene system, firefly luciferase (luc) and HSV1-tk, under the control of mouse alpha fetoprotein (Afp) promoter. Initial multimodal imaging, which was consisted of bioluminescent imaging (BLI) and planar gamma scintigraphy with [125I]-FIAU, was used for examining the model creation in the new born and liver injury in the adult mice. Carcinogen diethylnitrosamine (DEN) was then administrated to induce HCC in these knock-in mice such that microPET imaging could be used to track the activity of Afp promoter during tumor development and progression by imaging tk expression first with [18F]-FHBG. Dynamic PET scans with D-[18F]-FMAU and L-[18F]-FMAU were then performed to evaluate this pair of relatively new tracers. Cells were derived from these liver tumors for uptake assays using H-3 labeled version of PET tracers. Results: The mouse model with dual reporters: HSV1-tk and luc placed under the transcriptional control of an endogenous Afp promoter was used for imaging studies. The expression of the Afp gene was highly specific in proliferative hepatocytes, in regenerative liver, and in developing fetal liver, and thus provided an excellent indicator for liver injury and cancer development in adult mice. Both D-FMAU and L-FMAU showed stable liver tumor uptake where the tk gene was expressed under the Afp promoter. The performance of this pair of tracers was slightly different in terms of signal-to-background ratio as well as tracer clearance. Conclusion: The newly created knock-in mouse model was used to demonstrate the use of the dual-reporter genes driven by well-characterized cancer-specific transcriptional units in conjunction with in vivo imaging as a paradigm in studying naturally occurring cancer in live animals. While BLI is suitable for small animal imaging with luc expression, PET with L-FMAU seemed be the choice for liver injury or liver cancer imaging with this animal model for future investigations.