Nipple aspirate fluid - a liquid biopsy for diagnosing breast health

Shaheed, Sadr-ul, Tait, C., Kyriacou, K., Mullarkey, J., Burrill, W., Patterson, Laurence H., Linforth, R., Salhab, M., Sutton, Chris W.

05 October 2017

Yes / Purpose: Nipple secretions are protein-rich and a potential source of breast cancer biomarkers for breast cancer screening. Previous studies of specific proteins have shown limited correlation with clinicopatholigical features. Our aim, in this pilot study, was to investigate the intra- and inter-patient protein composition of nipple secretions and the implications for their use as liquid biopsies. Experimental design: Matched pairs of NAF (n=15) were characterised for physicochemical properties and SDS PAGE. Four pairs were selected for semi-quantitative proteomic profiling and trypsin-digested peptides analysed using 2D LC Orbitrap Fusion mass spectrometry. The resulting data was subject to bioinformatics analysis and statistical evaluation for functional significance. Results: A total of 1990 unique proteins were identified many of which are established cancer associated markers. Matched pairs shared the greatest similarity (average Pearson correlation coefficient of 0.94), but significant variations between individuals was observed. Conclusions: This was the most complete proteomic study of NAF to date providing a valuable source for biomarker discovery. The high level of milk proteins in healthy volunteer samples compared to the cancer patients was associated with galactorrhoea. Using matched pairs increased confidence in patient-specific protein levels but changes relating to cancer stage require investigation of a larger cohort. / Proteomics research was supported by Yorkshire Cancer Research projects, BPP047 and B381PA.

Breast cancer

Liquid biopsy

Nipple Aspirate Fluid (NAF)

Comparative proteomics

Evaluation of nipple aspirate fluid as a diagnostic tool for early detection of breast cancer

Shaheed, Sadr-ul, Tait, C., Kyriacou, K., Linforth, R., Salhab, M., Sutton, Chris W.

11 January 2018

Yes / There has been tremendous progress in detection of breast cancer in postmenopausal women, resulting in two-thirds of women surviving more than 20 years after treatment. However, breast cancer remains the leading cause of cancerrelated deaths in premenopausal women. Breast cancer is increasing in younger women due to changes in life-style as well as those at high risk as carriers of mutations in high-penetrance genes. Premenopausal women with breast cancer are more likely to be diagnosed with aggressive tumours and therefore have a lower survival rate. Mammography plays an important role in detecting breast cancer in postmenopausal women, but is considerably less sensitive in younger women. Imaging techniques, such as contrast-enhanced MRI improve sensitivity, but as with all imaging approaches, cannot differentiate between benign and malignant growths. Hence, current well-established detection methods are falling short of providing adequate safety, convenience, sensitivity and specificity for premenopausal women on a global level, necessitating the exploration of new methods. In order to detect and prevent the disease in high risk women as early as possible, methods that require more frequent monitoring need to be developed. The emergence of “omics” strategies over the last 20 years, enabling the characterisation and understanding of breast cancer at the molecular level, are providing the potential for long term, longitudinal monitoring of the disease. Tissue and serum biomarkers for breast cancer stratification, diagnosis and predictive outcome have emerged, but have not successfully translated into clinical screening for early detection of the disease. The use of breast-specific liquid biopsies, such as nipple aspirate fluid (NAF), a natural secretion produced by breast epithelial cells, can be collected non-invasively for biomarker profiling. As we move towards an age of active surveillance, home-based liquid biopsy collection kits are increasingly being applied and these could provide a paradigm shift where NAF biomarker profiling is used for routine breast health monitoring. The current status of established and newly emerging imaging techniques for early detection of breast cancer and the potential for alternative biomarker screening of liquid biopsies, particularly those applied to high-risk, premenopausal women, will be reviewed. / Proteomics research was supported by Yorkshire Cancer Research projects, BPP047 and B381PA, and co-funded by the European Regional Development Fund and the Republic of Cyprus through the Research Promotion Foundation projects ΥΓΕΙΑ/ΒΙΟΣ/0311(ΒΙΕ/07) and NEKYP/0311/17.

Breast cancer

Biomarkers

Proteomics

Liquid biopsy

Nipple aspirate fluid (NAF)

Oncoproteomic applications for detection of breast cancer : proteomic profiling of breast cancer models and biopsies

Shaheed, Sadr-ul

January 2017

The heterogeneity of breast cancer (disease stage and phenotype) makes it challenging to differentiate between each subtype; luminal A, luminal B, HER2, basal-like and claudin-low, on the basis of a single gene or protein. Therefore, a collection of markers is required that can serve as a signature for diagnosing different types of breast cancer. New developments in proteomics have provided the opportunity to look at phenotype-specific breast cancer cell lines and stage-specific liquid biopsies (nipple aspirate fluid [NAF], plasma samples) to identify disease and phenotype specific signature. An 8-plex iTRAQ quantification strategy was employed to compare proteomic profiles of a range of breast cancer and ‘normal-like’ cell lines with primary breast epithelial cells. From this, 2467 proteins were identified on Orbitrap Fusion and Ultraflex II, of which 1430 were common. Matched pairs of NAF samples from four patients with different stages of breast cancer, were analysed by SCX-LC-MS and a total of 1990 unique gene products were identified. More than double the number of proteins previously published data, were detected in NAF, including 300 not detected in plasma. The NAF from the diseased patients have 138 potential phenotype biomarkers that were significantly changed compared to the healthy volunteer (7 for luminal A, 9 for luminal B, 11 for HER2, 14 for basal-like and 52 for claudin-low type). The average coefficient of variation for triplicate analyses by multiple reaction monitoring mass spectrometry (MRM-MS), was 9% in cell lines, 17 % in tissue biopsies, 22% in serum samples and 24% in NAF samples. Overall, the results provide a strong paradigm to develop a clinical assay based on proteomic changes in NAF samples for the early detection of breast cancer supplementary to established mammography programmes.

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Oncoproteomic applications for detection of breast cancer. Proteomic profiling of breast cancer models and biopsies

Shaheed, Sadr-ul

January 2017

The CD-ROM disc containing supplementary material is kept in the cardboard box in the Systems Office. / The heterogeneity of breast cancer (disease stage and phenotype) makes it challenging to differentiate between each subtype; luminal A, luminal B, HER2, basal-like and claudin-low, on the basis of a single gene or protein. Therefore, a collection of markers is required that can serve as a signature for diagnosing different types of breast cancer. New developments in proteomics have provided the opportunity to look at phenotype-specific breast cancer cell lines and stage-specific liquid biopsies (nipple aspirate fluid [NAF], plasma samples) to identify disease and phenotype specific signature. An 8-plex iTRAQ quantification strategy was employed to compare proteomic profiles of a range of breast cancer and ‘normal-like’ cell lines with primary breast epithelial cells. From this, 2467 proteins were identified on Orbitrap Fusion and Ultraflex II, of which 1430 were common. Matched pairs of NAF samples from four patients with different stages of breast cancer, were analysed by SCX-LC-MS and a total of 1990 unique gene products were identified. More than double the number of proteins previously published data, were detected in NAF, including 300 not detected in plasma. The NAF from the diseased patients have 138 potential phenotype biomarkers that were significantly changed compared to the healthy volunteer (7 for luminal A, 9 for luminal B, 11 for HER2, 14 for basal-like and 52 for claudin-low type). The average coefficient of variation for triplicate analyses by multiple reaction monitoring mass spectrometry (MRM-MS), was 9% in cell lines, 17 % in tissue biopsies, 22% in serum samples and 24% in NAF samples. Overall, the results provide a strong paradigm to develop a clinical assay based on proteomic changes in NAF samples for the early detection of breast cancer supplementary to established mammography programmes. / The supplementary material submitted with the thesis is not available online.

Development of a Non-Invasive Proteomic Approach to Profiling Molecular Changes in the Microenvironment to Investigate Stages of Breast Health

George, Amy L.

January 2020

Early detection of breast cancer is critical for increasing survival rates. However, currently available screening strategies provide ambiguous results, leaving invasive tissue biopsy procedures necessary for definitive diagnosis. Considerable efforts have investigated using nipple aspirate fluid (NAF), a liquid biopsy rich in proteins representative of the breast microenvironment, as a non-invasive source of early detection biomarkers. However, by using traditional two-dimensional discovery proteomic approaches, many technical challenges of using NAF have limited analysis of large sample sizing: such as low expressed volume (<10µL) or insufficient analytical material (<200µg protein). Following non-invasive collection by manual massage, we developed a one-dimensional sample preparation workflow that reduced sample handling steps, minimised sample losses and increased sample throughput to 96-samples by using a PVDF-membrane based system, which was ideally suited to the NAF proteome. Samples were prepared within a single working day, and results correlated significantly with conventional in-solution protocols. ​Proteins typically associated with the dysregulation of innate immune response and haemostatic pathways had a significantly altered proteome profile in response to breast cancer. Overall, our new workflow will allow future studies to take a more high-throughput approach, revealing biomarkers for breast cancer early detection, and providing a real impact.

Breast cancer

Biomarkers

Proteomics

Nipple aspirate fluid

Liquid biopsy

Non-invasive

Molecular changes

Microenvironment