Genome-wide transcriptomic profiling of microdissected human breast tissue reveals differential expression of KIT (c-Kit, CD117) and oestrogen receptor-alpha (ERalpha) in response to therapeutic radiation.

The pathogenesis of late normal tissue fibrosis after high-dose ionizing radiation involves multiple cell types and signalling pathways but is not well understood. To identify the molecular changes occurring after radiotherapy, paired normal tissue samples were collected from the non-irradiated breast and from the treated breast of women who had undergone curative radiotherapy for early breast cancer months or years previously. As radiation may induce distinct transcriptional changes in the different components of the breast, laser capture microdissection and gene expression microarray profiling were performed separately for epithelial and stromal components and selected genes were validated using immunohistochemistry. In the epithelial compartment, a reduction of KIT (c-Kit; CD117) and a reciprocal increase in ESR1 (oestrogen receptor-alpha, ERalpha) mRNA and protein levels were seen in irradiated compared to non-irradiated samples. In the stromal compartment, extracellular matrix genes including FN1 (fibronectin 1) and CTGF (connective tissue growth factor; CCN2) were increased. Further investigation revealed that c-Kit and ERalpha were expressed in distinct subpopulations of luminal epithelial cells. Interlobular c-Kit-positive mast cells were also increased in irradiated cases not showing features of post-radiation atrophy. Pathway analysis revealed 'cancer, reproductive system disease and tumour morphology' as the most significantly enriched network in the epithelial compartment, whereas in the stromal component, a significant enrichment for 'connective tissue disorders, dermatological diseases and conditions, genetic disorder' and 'cancer, tumour morphology, infection mechanism' networks was observed. These data identify previously unreported changes in the epithelial compartment and show altered expression of genes implicated in late normal tissue injury in the stromal compartment of normal breast tissue. The findings are relevant to both fibrosis and atrophy occurring after radiotherapy for early breast cancer.

Changes in mast cell number and stem cell factor expression in human skin after radiotherapy for breast cancer.

BACKGROUND AND PURPOSE: Mast cells are involved in the pathogenesis of radiation fibrosis and may be a therapeutic target. The mechanism of increased mast cell number in relation to acute and late tissue responses in human skin was investigated. MATERIALS AND METHODS: Punch biopsies of skin 1 and 15-18 months after breast radiotherapy and a contralateral control biopsy were collected. Mast cells were quantified by immunohistochemistry using the markers c-Kit and tryptase. Stem cell factor (SCF) and collagen-1 expression was analysed by qRT-PCR. Clinical photographic scores were performed at post-surgical baseline and 18 months and 5 years post-radiotherapy. Primary human dermal microvascular endothelial cell (HDMEC) cultures were exposed to 2Gy ionising radiation and p53 and SCF expression was analysed by Western blotting and ELISA. RESULTS: Dermal mast cell numbers were increased at 1 (p=0.047) and 18 months (p=0.040) using c-Kit, and at 18 months (p=0.024) using tryptase immunostaining. Collagen-1 mRNA in skin was increased at 1 month (p=0.047) and 18 months (p=0.032) and SCF mRNA increased at 1 month (p=0.003). None of 16 cases scored had a change in photographic appearance at 5 years, compared to baseline. SCF expression was not increased in HDMECs irradiated in vitro. CONCLUSIONS: Increased mast cell number was associated with up-regulated collagen-1 expression in human skin at early and late time points. This increase could be secondary to elevated SCF expression at 1 month after radiotherapy. Although mast cells accumulate around blood vessels, no endothelial cell secretion of SCF was seen after in vitro irradiation. Modification of mast cell number and collagen-1 expression may be observed in skin at 1 and 18 months after radiotherapy in breast cancer patients with no change in photographic breast appearance at 5 years.

Cytokine levels as biomarkers of radiation fibrosis in patients treated with breast radiotherapy.

BACKGROUND: Radiation fibrosis is not easily measurable although clinical scores have been developed for this purpose. Biomarkers present an alternative more objective approach to quantification, and estimation in blood provides accessible samples. We investigated if blood cytokines could be used to measure established fibrosis in patients who have undergone radiotherapy for breast cancer. METHODS: We studied two cohorts treated by breast-conserving surgery and radiotherapy in the UK START Trial A, one with breast fibrosis (cases) and one with no or minimal fibrosis (controls). Two candidate cytokines, plasma connective tissue growth factor (CTGF) and serum interleukin-6 (IL6) were estimated by ELISA. Comparisons between cases and controls used the t-test or Mann-Whitney test and associations between blood concentration and clinical factors were assessed using the Spearman rank correlation coefficient. RESULTS: Seventy patients were included (26 cases, 44 controls). Mean time since radiotherapy was 9.9 years (range 8.3-12.0). No statistically significant differences between cases and controls in serum IL6 (median (IQR) 0.84 pg/ml (0.57-1.14), 0.75 pg/ml (0.41-1.43) respectively) or plasma CTGF (331.4 pg/ml (234.8-602.9), 334.5 pg/ml (270.0-452.8) were identified. There were no significant associations between blood cytokine concentration and age, fibrosis severity, breast size or time since radiotherapy. CONCLUSIONS: No significant difference in IL6 or CTGF concentrations was detected between patients with breast fibrosis and controls with minimal or no fibrosis.

Gene expression profiling of human dermal fibroblasts exposed to bleomycin sulphate does not differentiate between radiation sensitive and control patients.

BACKGROUND: Gene expression profiling of the transcriptional response of human dermal fibroblasts to in vitro radiation has shown promise as a predictive test of radiosensitivity. This study tested if treatment with the radiomimetic drug bleomycin sulphate could be used to differentiate radiation sensitive patients and controls in patients who had previously received radiotherapy for early breast cancer. FINDINGS: Eight patients who developed marked late radiation change assessed by photographic breast appearance and 8 matched patients without any change were selected from women entered in a prospective randomised trial of breast radiotherapy fractionation. Gene expression profiling of primary skin fibroblasts exposed in vitro to bleomycin sulphate and mock treated fibroblast controls was performed. 973 genes were up-regulated and 923 down-regulated in bleomycin sulphate treated compared to mock treated control fibroblasts. Gene ontology analysis revealed enriched groups were cellular localisation, apoptosis, cell cycle and DNA damage response for the deregulated genes. No transcriptional differences were identified between fibroblasts from radiation sensitive cases and control patients; subgroup analysis using cases exhibiting severe radiation sensitivity or with high risk alleles present in TGF ß1 also showed no difference. CONCLUSIONS: The transcriptional response of human dermal fibroblasts to bleomycin sulphate has been characterised. No differences between clinically radiation sensitive and control patients were detected using this approach.