Influence of sampling time on assessment of potential doubling time

FGF2 modulates simultaneously the mode, the rate of division and the growth fraction in cultures of radial glia

Radial glial progenitors in the mammalian developing neocortex have been shown to follow a deterministic differentiation program restricted to an asymmetric-only mode of division. This feature seems incompatible with their well-known ability to increase in number when cultured in vitro, driven by fibroblast growth factor 2 and other mitogenic signals. The changes in their differentiation dynamics that allow this transition from in vivo asymmetric-only division mode to an in vitro self-renewing culture have not been fully characterized. Here, we combine experiments of radial glia cultures with numerical models and a branching process theoretical formalism to show that fibroblast growth factor 2 has a triple effect by simultaneously increasing the growth fraction, promoting symmetric divisions and shortening the length of the cell cycle. These combined effects partner to establish and sustain a pool of rapidly proliferating radial glial progenitors in vitro. We also show that, in conditions of variable proliferation dynamics, the branching process tool outperforms other commonly used methods based on thymidine analogs, such as BrdU and EdU, in terms of accuracy and reliability.

Highlighted Article: When mode and/or rate of division are changing, a branching process, rather than a thymidine analog method, provides temporal resolution, it is more robust and does not interfere with cell homeostasis.

Dynamic cell cycle kinetics in vitro and in vivo in myelodysplastic syndromes with special reference to the influence of hematopoietic growth factors

We have investigated the effect of HGF in vivo and in vitro in MDS using a recently developed FCM assay involving the simultaneous measurement of cell surface antigens, DNA content, and BrdUrd or IodUrd incorporation. This allows for the determination of the dynamic cell kinetic parameters: LI, T(s), and T(pot) and we observed that in vitro HGF stimulation resulted in a significant decrease in mean T(pot) values from 6.6 to 3.5 days. Importantly, we demonstrated that in vivo GM-CSF administration to patients with RAEB resulted in a shortening of T(pot) within the 2 first weeks of GM-CSF treatment.

Dynamic cell cycle kinetics of normal CD34+ cells and CD38+/- subsets of haemopoietic progenitor cells in G-CSF-mobilized peripheral blood

Using a recently developed flow cytometric assay for the simultaneous measurement of cell surface antigens, DNA content and bromodeoxyuridine incorporation, we have for the first time determined the labelling index (LI), the duration of the S-phase (Ts) and the potential doubling time (Tpot) of purified CD34+ cells mobilized by G-CSF from 10 normal donors. Although CD34+ cells were not actively cycling immediately following purification, up to 5% could nevertheless traverse cell cycle without exogenous stimulation during the first 24 h of culture. In addition, it was possible to induce CD34+ cells to enter cycling by stimulation with haemopoietic growth factors (IL-3, IL-6 and SCF), resulting in median Tpot values of 18.2 d at 21 h, 7.7 d at 29 h, and 4.5 d at 37 h. Importantly, stimulation of CD34+ cells was seen almost exclusively within the CD38+ subset (mean Tpot value 2.8 d), whereas CD38- cells were not recruited into cycle (mean Tpot value 35.9 d). In conclusion, although cell cycle entry and progression can easily be induced in differentiated CD34+/CD38+ cells, immature CD34+/CD38- cells will remain dormant in most of the clinical and laboratory stimulation protocols hitherto employed. This assay can be used to obtain detailed cell cycle kinetics in leucocyte subsets in health and disease.

Lack of predictive value of potential doubling time and iododeoxyuridine labelling index in radiotherapy of squamous cell carcinoma of the head and neck

PURPOSE

To investigate the prognostic value of T(POT), S-phase time (TS), iododeoxyuridine (IdUrd) labelling index (LI) and DNA index with loco-regional tumour control as the end-point.

MATERIALS AND METHODS

Iododeoxyuridine was given to 99 patients with squamous cell carcinomas of the head and neck before the start of radiotherapy. The analysis included FCM parameters (LI, TS, T[POT] and DNA index, n = 87) and LI determined by immunohistology (IHC, n = 45). A hybrid T(POT) was determined by combining the FCM TS and the IHC LI (n = 45). In diploid tumours (n = 39), the FCM LI was underestimated and the FCM T(POT) was overestimated because the flow cytometer was unable to distinguish between tumour and normal cells. The 'tumour LI' was defined as the IHC LI or the FCM LI of aneuploid tumours when a biopsy for IHC evaluation was not available and similarly the 'tumour T(POT)' was determined by the hybrid T(POT) or the FCM T(POT) of aneuploid tumours (n = 63).

RESULTS

There was good agreement between the IHC LI and the FCM LI for aneuploid tumours, but there was disagreement for diploid tumours. The median tumour T(POT) was 4.1 days (range 0.6-19.5 days) and the median tumour LI was 12.9% (range 3.1-46.0%). In a univariate analysis there was no prediction of loco-regional tumour control by the LI, the TS or the T(POT) determined by either of the methods. T-classification, N-classification, clinical stage and tumour diameter were related with loco-regional tumour control, whereas clinical stage was the only parameter that yielded independent prognostic significance in a multivariate analysis.

CONCLUSIONS

This study does not confirm the significant prognostic value of T(POT) as indicated in some previous reports. Larger clinical studies are needed to draw final conclusions.

S-phase fraction, 5-bromo-2'-deoxy-uridine labelling index, duration of S-phase, potential doubling time, and DNA index in benign and malignant brain tumors

Seventy-one histologically malignant brain tumors, 52 histologically benign brain tumors, and 14 cerebral metastases were characterized according to DNA content and proliferative capacity. DNA ploidy, DNA index (DI), S-phase fraction (SPF), 5-bromo-2'-deoxy-uridine (BrdUrd) labelling index (LI), duration of S-phase (Ts), and potential doubling time (Tpot) were assessed by flow cytometry (FCM). In histologically benign tumors, a high percentage of DNA diploid tumors and a low proliferative capacity in DNA diploid tumors were found. Histologically malignant tumors and cerebral metastases were both found to be characterized by a low percentage of DNA diploid tumors and a high proliferative capacity in DNA diploid tumors. The proliferative capacity of DNA aneuploid benign tumors and that of DNA aneuploid malignant tumors, however, appeared not to differ significantly. The number of DNA aneuploid tumors was small. Duration of S-phase was short (range 3.9-4.7 hr) and appeared not to differ between the three groups. From this, the observed differences in Tpot values should be accredited mainly to differences in LI. High-grade as well as low-grade gliomas both appeared to be characterized by malignant (FCM) features, i.e., 1) a high percentage DNA aneuploidy, 2) a high mean DI (for DI > 1), and 3) a high proliferative capacity.

The relationship between tumor oxygenation and cell proliferation in human soft tissue sarcomas

PURPOSE

In malignant tumors the oxygenation status and tumor cell proliferation are known to influence local tumor control after radiotherapy. However, the relationship between oxygenation status and tumor cell kinetics in human tumors has not yet been described. Newly developed clinically applicable techniques such as oxygen electrode measurements and assessment of tumor cell proliferation rates have been suggested as promising predictive assays. The purpose of the present study was to characterize tumor oxygenation status in soft tissue sarcomas and to compare this with tumor cell kinetics and clinical parameters.

METHODS AND MATERIALS

Pretreatment tumor oxygenation status was measured by polarographic oxygen needle electrodes and evaluated as the median pO2 and the percentage of pO2 values < or = 5 mmHg and < or = 2.5 mmHg in 22 patients with primary soft tissue sarcomas. All tumors were characterized by histology, grade of malignancy, the level of microscopic necrosis, the level of effective hemoglobin, and magnetic resonance imaging estimation of tumor volume. The tumor cell potential doubling time and labeling index were measured by flow cytometric and immunohistochemical analysis of tumor biopsy specimens after in vivo incorporation of iododeoxyuridine.

RESULTS

There was a significant correlation between the median pO2 and the tumor cell potential doubling time (p = 0.041), whereas no correlation was found between the level of hypoxia expressed by the percentage of pO2 values < or = 2.5 and < or = 5 mmHg, respectively, and tumor cell potential doubling time. Furthermore, no correlation was found between either of the three tumor oxygenation parameters and labeling index. The material represented large intertumor heterogeneity in oxygenation status, cell kinetics, and tumor volume, and no correlation was found between oxygenation status and either volume, histopathology, grade of malignancy, or effective hemoglobin.

CONCLUSION

This report is the first to suggest a correlation between tumor oxygenation and tumor cell doubling time, as the fastest proliferating tumor cells were found in the poorest oxygenated soft tissue sarcomas. More data are needed to clarify if this relation is really a true biological phenomenon. Furthermore, tumor oxygenation status of soft tissue sarcomas was heterogeneous and independent of clinical and histopathological parameters.

Repopulation in the SCCVII squamous cell carcinoma assessed by an in vivo-in vitro excision assay

An in vivo-in vitro excision assay was used to study repopulation after a single dose of clamped irradiation (40 Gy) in the SCCVII tumour implanted in the foot of C3H/Km mice. The growth pattern of clonogenic cells was analysed by two different mathematical models: the logistic model and the Gompertz model. The logistic model described the data better than the Gompertz model. Accelerated repopulation was found when the regrowth rate after irradiation was compared to the growth rate at the time of treatment, and when it was compared to the growth rate in untreated tumours with a number of cells equivalent to the number that was found after irradiation. The clonogenic doubling time (cDT) was estimated at 15.1 h (95% c.i.: 14.2; 16.0) after irradiation, and 27.8 h (95% c.i.: 16.7; 43.5) in untreated controls of matching size. However, the estimate relies on the mathematical model chosen and on extrapolation below actually measured data. A small cDT points to shortening of the cell cycle time and recruitment of non-cycling clonogenic tumour cells to be the main mechanism behind the accelerated repopulation.

Selective assessment of in vitro radiosensitivity of tumour cells and fibroblasts from single tumour biopsies using immunocytochemical identification of colonies in the soft agar clonogenic assay

The assumed selective growth of tumour cells has formed the basis for the use of the soft agar clonogenic assay to test in vitro radio- and chemosensitivity of tumours. However, recent studies have demonstrated that fibroblasts proliferate in soft agar in addition to tumour cells. The present study was initiated to quantify the contaminating growth of non-malignant cells in the modified form of the Courtenay-Mills soft agar assay, in order to establish a reliable assay for estimating tumour cell radiosensitivity in squamous cell carcinomas of the head and neck. DNA flow cytometry analysis confirmed that 'tumour fibroblasts' (fibroblasts obtained from tumour biopsies) grow in soft agar. In contrast, white blood cells did not form colonies. Different media were tested with soft agar, but a selective medium for tumour cells was not found. Therefore, a colony filter-technique combined with an immunocytochemical analysis was developed to quantify the number of tumour cell and fibroblast colonies. In 12 tumour biopsies, 2-33% of the colonies were Cytokeratin AE1-3 positive, whereas 83-100% of the colonies were 5B5 fibroblast antibody positive. The parameter normally reported, the overall SF2 (surviving cell fraction at 2 Gy) based on colonies in agar, was found to be statistically significantly correlated to the fibroblast SF2, but not to the tumour cell SF2. The overall SF2 was significantly different from the tumour cell SF2 in half of the tumours. Furthermore, the tumour cell SF2 was not correlated to fibroblast SF2. In consequence of our findings, correcting for fibroblast contamination is a necessity, when studying in vitro sensitivity of tumour cells. Combining the soft agar clonogenic assay with the new colony filter-technique and the immunocytochemical analysis appear to be useful for making this routine correction and for measuring the in vitro radiosensitivity of both tumour cells and fibroblasts from single tumour biopsies, which is of interest in future clinical studies on predictive assays.