Qimin He

Production and characterisation of a novel chicken IgY antibody raised against C-terminal peptide from human thymidine kinase 1

Egg yolk is a good source of highly specific antibodies against mammalian antigens because of the phylogenetic distance between birds and mammals. Chicken egg yolk immunoglobulins (IgY) were generated to a synthetic 31-amino acid peptide from the C-terminal of human HeLa thymidine kinase 1 (TK1) enzyme. The anti-TK1 IgY antibody was purified using affinity chromatography against the 31-amino acid peptide. The purified antibody inhibited the catalytic activity of the TK1 enzyme in the CEM TK1(+) cells and recognized the 25-kDa subunit and tetrameric form of TK1, which has a pI value of 8.3. No immunoreaction was observed in CEM TK1(-) cells. Western blot of the serum TK1 (S-TK1) also showed that only a single band was found in the serum of patients with malignancies. No band was seen in healthy serum. Furthermore, dot blots and enhanced chemiluminescence (ECL) detection of S-TK1 performed on sera of preoperative patients with gastric cancer (GC) (n=31) and healthy controls (n=62) showed that the levels of S-TK1 in the sera of cancer patients were significantly different (P<0.01). Using ECL dot blots, 0.1 pg of TK1 in 3 microl sera could be detected. Immunohistostaining of tissues in the 11 advanced-stage cancer patients (four breast carcinomas, three hepatocarcinomas and four thyroid carcinomas) indicated that a strong staining of TK1 enzyme was found in the cytoplasm of malignant cells. No staining or weak staining was seen in normal tissues. We suggest that screening for TK1 using anti-TK1 IgY may be potentially useful for serological and immunohistochemical detection of TK1 as an early prognosis and for monitoring patients undergoing treatment.

Investigation on Cell Proliferation with a New Antibody against Thymidine Kinase 1

The cytosolic thymidine kinase 1 (TK1) is one of the enzymes involved in DNA replication. Based on biochemical studies, TK1 is activated at late G1 of cell cycle, and its activity correlates with the cell proliferation. We have developed a polyclonal anti‐TK1 antibody against a synthetic peptide from the C‐terminus of human TK1. Using this antibody, here we demonstrate the exclusive location of TK1 in the cytoplasm of cells. Cell cycle dependent TK1 expression was studied by simultaneous fluorescence staining for TK1 and bromodeoxyuridine, by using elutriated cells, and by quantitation of the amount TK1 in relation to the cellular DNA content. TK1, which was strongly expressed in the cells in S+G2 period, raised at late G1 and decreased during mitosis. The amount of TK1 increased three folds from late G1 to G2. TK1 positive cells were demonstrated in areas of proliferation activity of various normal and malignant tissues. The new anti‐TK1 antibody works in archival specimens and is a specific marker of cell proliferation.

A Comparative Study: Immunohistochemical Detection of Cytosolic Thymidine Kinase and Proliferating Cell Nuclear Antigen in Breast Cancer

To explore the expression of cytosolic thymidine kinase 1 (TK1) as a cell proliferative marker in human breast cancers, immunohistochemistry was used to detect the expression of TK1 in 52 malignant breast lesions, 20 benign breast lesions, and 16 normal breast tissues. The results were compared to the expression of proliferating cell nuclear antigen (PCNA) in the same specimens. The TK1-labelling index (TK1-LI) and PCNA-labeling index (PCNA-LI) were significantly higher in malignant lesions than in nonmalignant lesions (p<0.0001 and p<0.0013, respectively). The TK1-LI (78.9%) in malignant lesions was higher compared to PCNA-LI (64.5%). No significant difference was found for TK1-LI and PCNA-LI between benign lesions and normal tissues. Concerning the tumor stages and the tumor grades, TK1-LI showed a significant correlation with the increased tumor stages (p=0.023) and tumor grades (p=0.009). However, PCNA-LI was neither significantly different in tumor stages (p=0.062) nor in tumor grades (p=0.073). We conclude that TK1 might be a more accurate marker than PCNA for estimation of cell proliferation and malignant potentials in breast carcinomas.

Genes Related to Growth Regulation, DNA Repair and Apoptosis in an Oestrogen Receptor-Negative (MDA-231) versus an Oestrogen Receptor-Positive (MCF-7) Breast Tumour Cell Line

The molecular mechanism(s) behind the development of endocrine resistance in breast cancer remains controversial. Here, we compare the capability of oestrogen receptor (ER)-negative cells (MDA-231) versus ER-positive tamoxifen-sensitive cells (MCF-7) to handle DNA repair, transmit signals from damaged DNA, initiate cell death via apoptosis, and then to control transmitted signals from the cell cycle and to synthesize growth factors and receptors. Genes related to these events were studied by cDNA micro-array. Normal human breast cells (H2F) and human lymphoblastoid tumour cells (CEM) were used as controls. Of the 18 genes investigated, 10 genes showed differences in their expression between the cell types. The ER-negative cells showed higher expressions of BRCA1, BRCA2, cdc2, cyclin B1, cyclin D1, cyclin E, IGFBP-3, TGF-α, TGFβ2 and a lower expression of TGFβR1. No differences in the expressions of bax, bcl-2, p53, p21 and GADD45 were found between the two cell lines. We found that the ER-negative cells were characterized by: (1) a stimulated expression of growth factors and cell cycle regulation compounds, (2) improved DNA repair capacity, but (3) no change in DNA damage signals and apoptotic pathways. Improved DNA repair capacity of ER-negative cells would have a growth advantage over ER-positive tumours when receiving antitumour therapy.