Our protocol describes how to dissect the rat abdominal mammary gland and how to prepare mammary gland whole mounts. It also describes how to analyze mammary gland morphology using three end-points (number of terminal end buds, epithelial elongation and differentiation) and to use these results to predict mammary cancer risk in rats which were exposed to dietary modifications in utero or during prepuberty.
Studies in rodent models of breast cancer show that exposures to dietary/hormonal factors during the in utero and pubertal periods, when the mammary gland undergoes extensive modeling and re-modeling, alter susceptibility to carcinogen-induced mammary tumors. Similar findings have been described in humans: for example, high birthweight increases later risk of developing breast cancer, and dietary intake of soy during childhood decreases breast cancer risk. It is thought that these prenatal and postnatal dietary modifications induce persistent morphological changes in the mammary gland that in turn modify breast cancer risk later in life. These morphological changes likely reflect epigenetic modifications, such as changes in DNA methylation, histones and miRNA expression that then affect gene transcription . In this article we describe how changes in mammary gland morphology can predict mammary cancer risk in rats. Our protocol specifically describes how to dissect and remove the rat abdominal mammary gland and how to prepare mammary gland whole mounts. It also describes how to analyze mammary gland morphology according to three end-points (number of terminal end buds, epithelial elongation and differentiation) and to use the data to predict risk of developing mammary cancer.
1. Removal of the Abdominal Mammary Gland and Preparing a Whole Mount
2. Analysis of Mammary Gland Whole Mount Morphology
Mammary gland whole mounts morphology is analyzed according to the following end-points and the results correlated with mammary cancer risk.
3. Palpation and Mammary Tumor Measurement in Rats and Correlation to Mammary Gland Morphology
4. Representative Results
Careful dissection of the mammary fat pad and its processing to wholemount will allow assessment of developmental state of the mammary gland. When each step is done correctly, the whole mammary epithelial tree is clearly visible within the fat pad, and this allows easy determination of the number of TEBs and calculation of the density of alveolar buds and lobules. Missteps in preparing wholemounts may include failure to dissect the whole fat pad, insufficient fixing, and inadequate clearing.
Assessment of mammary gland morphology will provide information about the number of structures present that can give rise to mammary tumors (TEBs), degree of differentiation of the epithelial structures (alveolar buds and lobules), and measure of growth (ductal elongation). It is important to separate TEBs to terminal ends; the latter are located at the distal end of the epithelium, similarly to TEBs, but they are smaller than TEBs and do not give rise to malignant tumors. Terminal ends are also seen within the epithelial tree.
Figure 1: Representative result of well prepared mammary gland whole mount. All components of the gland have been properly dissected and carmine staining is optimal.
Figure 2: Representative result of a poorly prepared mammary gland whole mount. The gland has been properly dissected (the distal portion of the gland is missing), has not been properly stretched and delipidation has not completely occurred.
Assessment of mammary gland morphological end-points and the growth of the epithelial tree can be used to predict whether early life dietary manipulations, or other manipulations which alter in utero or prepubertal hormonal environment, modify later mammary cancer risk. Since breast cancer in humans is initiated in mammary structures (terminal ductal lobular units, TDLUs) similar to TEBs in rats, this technique can be used to determine the potential of early life exposures to affect breast cancer risk. Further, in women high mammographic density increases the risk of breast cancer by 4-6 fold, and assessment of the growth of mammary epithelial tree can be used to identify factors which determine mammographic density and factors which reduce this density. To obtain this information, mammary gland should be fully dissected, properly stretched on a glass slide so that all its components can be visualized under a microscope. In addition, proper carmine staining and delipidation in xylene will provide whole mounts that are suitable for mammary cancer risk assessment.
The authors have nothing to disclose.
NCI (U54 CA00100970), NCI (1 R03 CA150040-01), ACS(116602-PF-09-018-01-CNE)
Material Name | Tipo | Company | Catalogue Number | Comment |
---|---|---|---|---|
Glacial acetic acid | EM | AX0073-9 | Carnoy’s Fixative | |
Absolute ethanol | The Waner-Graham Co. | 64-17-5 | Carnoy’s Fixative | |
Carmine | Sigma | C1022 | Carmine solution | |
Aluminum potassium sulfate | Sigma | A7167 | Carmine solution |