Peter Zickert

Mevalonic acid is limiting for N-linked glycosylation and translocation of the insulin-like growth factor-1 receptor to the cell surface. Evidence for a new link between 3-hydroxy-3-methylglutaryl-coenzyme a reductase and cell growth.

Depletion of mevalonic acid (MVA), obtained by inhibition of 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase using lovastatin, depressed the biosynthesis of dolichyl-phosphate and the rate of N-linked glycosylation and caused growth arrest in the melanoma cell line SK-MEL-2. The growth arrest was partially prevented by addition of high concentrations of insulin-like growth factor-1 (IGF-1) to the cells, indicating that MVA depletion may inhibit cell growth through decreasing the number of IGF-1 receptors (IGF-1R) at the cell surface. Such a decrease in receptor number might be a result of a lowered translocation of de novo synthesized receptors to the cell membrane which in turn might be a result of a decreased N-linked glycosylation of the receptor proteins. We could also demonstrate that IGF-1R became underglycosylated and that the amount of de novo synthesized IGF-1R proteins at the cell membrane was drastically decreased upon MVA depletion. Analysis of receptor proteins cross-linked with IGF-1, as well as binding assays and immunocytostaining confirmed that the number of functional membrane-bound IGF-1R was substantially reduced. The N-linked glycosylation and the expression of de novo synthesized IGF-1R proteins at the cell surface as well as the number of IGF-1 binding sites were completely restored upon replenishment of MVA. These effects of MVA were efficiently abrogated by the glycosylation inhibitor tunicamycin. The translocation of IGF-1R to the cell membrane was shown to take place just prior to initiation of DNA synthesis in arrested cells stimulated with MVA. Additionally, there was a clear correlation between IGF-1 binding and initiation of DNA synthesis with regard to the MVA dose requirement. It was confirmed that inhibition of HMG-CoA reductase activity and N-linked glycosylation also depressed the expression of functional IGF-1R in other cell types (i.e. hepatoblastoma cells and colon cancer cells). Our data suggest that this mechanism is involved in MVA-regulated cell growth.

Accumulation of Cyclin E Is Not a Prerequisite for Passage through the Restriction Point

ABSTRACT The restriction point (R) is defined as the point in G1after which cells can complete a division cycle without growth factors and divides G1 into two physiologically different intervals in cycling cells, G1-pm (a postmitotic interval with a constant length of 3 to 4 h) and G1-ps (a pre-DNA-synthetic interval with a variable length of 1 to 10 h). Cyclin E is a G1 regulatory protein whose accumulation has been suggested to be critical for passage through R. We have studied cyclin E protein levels in individual cells of asynchronously growing cell populations, with respect to both passage through R and entry into S phase. We found that the postmitotic G1 cells that had not yet reached R were negative for cyclin E accumulation. On the other hand, cells that had passed R were found to accumulate cyclin E at variable times (1 to 8 h) after passage through R and 2 to 5 h before entry into S. These kinetic data rule out the hypothesis that passage through R is dependent on the accumulation of cyclin E but suggest, instead, the converse, that passage through R is a prerequisite for cyclin E accumulation. Furthermore, we found that most of the cyclin E protein is downregulated within 1 to 2 h after entry into S.

Frequent co-amplification of two different regions on 17q in aneuploid breast carcinomas

Chromosome 17q is highly susceptible to rearrangement mutations in breast cancer. c-erbB-2 at 17q11.2 approximately q21.1 is frequently amplified, as is a region at 17q22 approximately q24. As a step in the search for the target gene(s) of the 17q22-q24 amplification we determined whether the placental lactogen (PL) genes at 17q23 were amplified in 59 breast carcinomas. These genes were selected as their upregulation could theoretically be involved in breast cancer tumorigenesis. Amplification of the PL genes, and also of c-erbB-2, was detected using semi-quantitative PCR. The reliability of this method was confirmed since c-erbB-2 results obtained using PCR, Southern blotting and immunohistochemistry were in good agreement. The PL genes were amplified in 13 (22%) of the tumors. Furthermore, the PL and c-erbB-2 genes were frequently co-amplified although there is a non-amplified region between them. Expression of PL was investigated in 26 tumors and was detected in 16 of these cases including all 10 tumors with amplification of the PL genes. The tumors with PL gene amplification were all aneuploid. A trend was seen towards an increased incidence of lymph node involvement for tumors with amplification of the PL genes and for tumors with co-amplification of PL and c-erbB-2, which suggests a possible association with high malignancy.

Changes in cell shape and anchorage in relation to the restriction point.

The restriction point (R) separates the G1 phase of continuously cycling cells into two functionally different parts. The first part, G1‐pm, represents the growth factor dependent post‐mitotic interval from mitosis to R, which is of constant length (3–4 h). The second part, G1‐ps, represents the growth factor independent, pre‐S phase interval of G1 that lasts from R to S and that varies in time from 1 to 10 h. G1‐pm cells rapidly exit (within 1 h) from the cell cycle and enter G0 as a response to serum withdrawal. The finding that R occurs at a set time after mitosis indicates that R may be related to the metabolic and/or structural changes that the cell underwent during the previous mitosis. We have recently shown that phosphorylation of the retinoblastoma tumor suppressor protein (pRb) is not the molecular mechanism behind R, as has been suggested previously. Here, we present an alternative explanation for R. In the present study, we applied a single cell approach using time‐lapse analysis, which revealed that upon serum starvation the G1‐pm cells rapidly underwent a transient change in cell shape from flat to spherical before exiting to G0. Platelet derived growth factor (PDGF) counteracted this change in shape and also prevented exit to G0 to the same extent. Furthermore epidermal growth factor (EGF) and insulin like growth factor (IGF‐1), which only partially counteracted this change, only partially counteracts exit to G0. These data clearly indicate a direct link between change in cell shape and exit to G0 in G1‐cells that have not passed R.