Laser capture microdissection coupled mass spectrometry (LCM-MS) for spatially resolved analysis of formalin-fixed and stained human lung tissues

Jeremy A Herrera; Venkatesh Mallikarjun; Silvia Rosini; Maria Angeles Montero; Craig Lawless; Stacey Warwood; Ronan O'Cualain; David Knight; Martin A Schwartz; Joe Swift

doi:10.1186/s12014-020-09287-6

Laser capture microdissection coupled mass spectrometry (LCM-MS) for spatially resolved analysis of formalin-fixed and stained human lung tissues

Clin Proteomics. 2020 Jun 17:17:24. doi: 10.1186/s12014-020-09287-6. eCollection 2020.

Authors

Jeremy A Herrera^#^{1

2}, Venkatesh Mallikarjun^#^{1

2}, Silvia Rosini^{1

2}, Maria Angeles Montero³, Craig Lawless^{1

2}, Stacey Warwood^{1

2}, Ronan O'Cualain^{1

2}, David Knight^{1

2}, Martin A Schwartz^{1

2}, Joe Swift^{1

2}

Affiliations

¹ The Wellcome Centre for Cell-Matrix Research, University of Manchester, Manchester, M13 9PT UK.
² Division of Cell Matrix Biology and Regenerative Medicine, School of Biological Sciences, Faculty of Biology, Medicine and Health, University of Manchester, Manchester Academic Health Science Centre, Manchester, M13 9PL UK.
³ Histopathology Department, Manchester University NHS Foundation Trust, Southmoor Road, Wythenshawe, Manchester, M23 9LT UK.

^# Contributed equally.

Abstract

Background: Haematoxylin and eosin (H&E)-which respectively stain nuclei blue and other cellular and stromal material pink-are routinely used for clinical diagnosis based on the identification of morphological features. A richer characterization can be achieved by laser capture microdissection coupled to mass spectrometry (LCM-MS), giving an unbiased assay of the proteins that make up the tissue. However, the process of fixing and H&E staining of tissues provides challenges with standard sample preparation methods for mass spectrometry, resulting in low protein yield. Here we describe a microproteomics technique to analyse H&E-stained, formalin-fixed paraffin-embedded (FFPE) tissues.

Methods: Herein, we utilize heat extraction, physical disruption, and in column digestion for the analysis of H&E stained FFPE tissues. Micro-dissected morphologically normal human lung alveoli (0.082 mm³) and human lung blood vessels (0.094 mm³) from FFPE-fixed H&E-stained sections from Idiopathic Pulmonary Fibrosis (IPF) specimens (n = 3 IPF specimens) were then subject to a qualitative and then quantitative proteomics approach using BayesENproteomics. In addition, we tested the sensitivity of this method by processing and analysing a range of micro-dissected human lung blood vessel tissue volumes.

Results: This approach yields 1252 uniquely expressed proteins (at a protein identification threshold of 3 unique peptides) with 892 differentially expressed proteins between these regions. In accord with prior knowledge, our methodology approach confirms that human lung blood vessels are enriched with smoothelin, CNN1, ITGA7, MYH11, TAGLN, and PTGIS; whereas morphologically normal human lung alveoli are enriched with cytokeratin-7, -8, -18, -19, 14, and -17. In addition, we identify a total of 137 extracellular matrix (ECM) proteins and immunohistologically validate that laminin subunit beta-1 localizes to morphologically normal human lung alveoli and tenascin localizes to human lung blood vessels. Lastly, we show that this micro-proteomics technique can be applied to tissue volumes as low as 0.0125 mm³.

Conclusion: Herein we show that our multistep sample preparation methodology of LCM-MS can identify distinct, characteristic proteomic compositions of anatomical features within complex fixed and stained tissues.

Grants and funding

WT_/Wellcome Trust/United Kingdom