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Laser Microdissection in Clinical Cardiovascular Research^*

^* From the Cardiothoracic and Vascular Department (Drs. Chimenti, Pieroni, and Maseri), Vita e Salute University, Milan; Department of Cardiology, Catholic University (Dr. Frustaci), Rome; Biopathology and Diagnostic Imaging Department (Dr. A Russo), "Regina Elena" Institute, Rome; and Pathology and Experimental Medicine Department (Drs. Sale and M. Russo), "La Sapienza" University, Rome, Italy.

Correspondence to: Andrea Frustaci, MD, FCCP, Cardiology Department, Catholic University, Largo A Gemelli 8, 00168, Rome, Italy; e-mail: biocard{at}rm.unicatt.it

	Abstract

TOP Abstract Introduction Laser Microdissection:... Application of LMD to... References

 
Laser microdissection (LMD) is an accurate and fast method to procure pure populations of cells from complex, heterogeneous tissues under direct microscopic visualization. It can be applied to a wide range of cell preparation, including paraffin-embedded material. The morphology of the captured cells is retained, and DNA, RNA, and proteins can be extracted for molecular analysis. The potential applications of LMD to human cardiovascular research are multiple, including viral/autoimmune myocarditis and arteritis, atherosclerotic lesions, and myocardial and vascular cell proliferation and death. Molecular and genetic analysis of LMD-procured cells in cardiac and vascular tissues may provide a better understanding of several cardiac diseases.

Key Words: cardiovascular diseases • endomyocardial biopsy • inflammatory cardiomyopathy • laser microdissection • myocarditis

	Introduction

TOP Abstract Introduction Laser Microdissection:... Application of LMD to... References

 
A growing number of genomic and proteomic techniques have become available to assess messenger RNA (mRNA) transcripts and proteins in human cells and tissues. In particular, the differential expression of these molecules between normal and pathologic tissues can provide indications for specific mechanisms of diseases. However, as tissues are usually composed of heterogeneous cell populations, the average information obtained from the molecular analysis of biological samples as a whole may be of limited value. To address this difficulty, several manual or automatic methods have been developed for selecting specific cell populations from a given tissue sample. Among these methods, laser microdissection (LMD) provides considerable advantages and can be successfully applied to human cardiovascular research.

	Laser Microdissection: Methodologic Aspects

TOP Abstract Introduction Laser Microdissection:... Application of LMD to... References

 
LMD is a technique that enables the procurement of homogeneous types of cells from both frozen and fixed tissue sections and from cytologic smears, using a laser integrated into a standard microscope. It can be routinely utilized to collect pure populations of targeted cells for subsequent DNA, RNA, and protein analysis. Although the initial cost for the microscope and accompanying computer hardware and software is quite high, LMD has the advantages of being user friendly, precise, rapid, and guarantees the purity of the collected material, which is not feasible using previous manual microdissection techniques. Compared to LMD, in situ techniques such as in situ hybridization and in situ polymerase chain reaction (PCR)¹² are time consuming and technically complex, while immunohistochemistry lacks comparable sensitivity and specificity and is not suitable for nucleic acid analysis (Table 1 ).

View larger version (174K): [in this window] [in a new window] [Download PPT slide]   Figure 1.. LMD of endomyocardial biopsy tissue using the laser microbeam microdissection system. Top left, A: Giant-cell myocarditis with an extensive inflammatory infiltrate represented by lymphocytes, histiocytes, eosinophils, and multinuclear giant cells associated with cell necrosis. A giant cell is indicated by the arrow (hematoxylin-eosin, original x 200). Top right, B: The same field in which the path of the giant cell has been traced before the laser activation. Bottom left, C: The same field after microdissection of the selected cell. A hole is visible in the remaining tissue. Bottom right, D: The excised cell on the adhesive cap. All the steps of the procedure are examined with a microscope before proceeding to the next phase.

In both the laser capture and laser microbeam microdissection systems, the laser is integrated into a standard microscope. The investigator can examine the tissue section microscopically before and after the microdissection procedure and control the homogeneity of the selected material, as the tissue collected on the cap retains its original morphology. These systems also offer the possibility to archive the images of each dissection, allowing the correlation of the histopathologic findings with the subsequent molecular results.

	Application of LMD to Cardiovascular Research

TOP Abstract Introduction Laser Microdissection:... Application of LMD to... References

 
Up to now, the major field of application of this method has been cancer research. Separation of malignant, in situ, and normal cell subpopulations within a single biopsy specimen allows a direct comparison of tissue DNA, RNA, and protein content and function in both normal and neoplastic tissues.¹¹ This technique has been applied to detect both known and unknown alterations in the genomes of a variety of tumors.¹² Moreover, microarray technology has been used to obtain molecular fingerprints of gene expression in microdissected tissue biopsies of human cancer, contributing to identify different disease stages and specific molecular-targeted therapies.¹³

Recently, this method has been applied to human cardiac and vascular tissue (Table 3 ). Moniotte et al¹⁴ used LMD to selectively capture myocytes and endothelial cells from cardiac frozen sections stained with hematoxylin-eosin. The authors quantitatively assessed the expression of rare mRNAs (ie, ß₃-adrenoceptor mRNAs) in the small number of collected cells using real-time PCR, and demonstrated the efficacy of combining these two methods for gene expression studies in cardiac diseases. Similarly, De Souza et al¹⁵ performed LMD on frozen left and right ventricular tissue from explanted hearts to selectively collect blood vessels and myocytes, and analyzed the protein extracts by two-dimensional gel electrophoresis. Their results showed good protein recovery from the microdissected cells and well-distinct protein profiles, demonstrating the feasibility of using LMD to perform proteomic studies of individual cardiac tissue components. LMD has been also employed to analyze the level of deleted mitochondrial DNA (mtDNA) in the conducting myocardium in comparison with working myocardium in a patient with Kearns-Sayre syndrome,¹⁶ and showed a greater abundance of mutated mtDNA in the conducting system, consistent with its prevalent clinical involvement.

View larger version (123K): [in this window] [in a new window] [Download PPT slide]   Figure 2.. LMD of endomyocardial biopsy tissue from a patient with EBV myocarditis. LMD was guided by immunohistochemical detection of the targeted cells. Top left, A, and bottom left, D: -Sarcomeric actin-labeled myocytes and CD45RO-labeled infiltrating lymphocytes, respectively (immunoperoxidase, original x 400). Top center, B, and bottom center, E: The same field after LMD of the selected cells. After the adhesive caps are removed, holes are visible on the remaining tissue. Top right, C, and bottom right, F: The captured cells on the nanotube caps. The homogeneity of the captured material was confirmed by microscopic visualization before DNA extraction.

In another study, Martinet et al¹⁹ used LMD to isolate caspase-2—positive macrophage-derived foam cells around the necrotic core of atherosclerotic plaques in human carotid endoarterectomy specimens. The authors analyzed, using Western blotting, the proteins extracted from the targeted cells and identified the overexpression of a 35-kd protein (caspase-2S) with antiapoptotic effect, suggesting that the upregulation of this protein in macrophages can represent a mechanism to survive the increased levels of oxidative DNA damage present in the atherosclerotic plaque. LMD can also be useful to investigate inflammatory diseases of unknown etiology and uncertain treatment, involving the heart and/or the vessels, such as giant-cell myocarditis and arteritis.

Giant cell myocarditis is a disease of young, predominantly healthy adults, frequently with a fatal course.²⁰ Its etiology is unknown; it may recur after cardiac transplantation and sometimes responds to immunosuppressive therapy. Histologically, it is characterized by extensive inflammatory infiltrates with the presence of abnormal multinucleated cells, ie, giant cells, of possible myogenic or macrophagic origin. As illustrate in Figure 1, giant cells can be easily dissected from the endomyocardial tissue sample, and molecular analysis of the isolated material can give important information on the knowledge of this heterogeneous disease, providing indications for its treatment that are not established. Similarly, Gordon et al²¹ used LMD to isolate giant cells from inflammatory lesions of giant cell arteritis and identified the presence of microbial sequences in the DNA extracted from the collected material, showing that this disease, considered autoimmune in nature, may be associated with a microbial infection.

Finally, the fact that the heart is no longer a postmitotic organ and that myocardial regeneration occurs in adult human heart opens a new potential field for application of LMD. Indeed, studies²²²³ on the chimerism of the heart after sex-mismatched transplantation have provided consistent results concerning the migration of primitive cells from the host to the graft, showing the presence of Y chromosome in myocytes of female hearts transplanted into male recipients. A population of resident cardiac primitive cells able to differentiate in myocytes, smooth-muscle cells, and endothelial cells has been identified in the adult human heart, and it has been shown that cardiac regeneration is highly activated in acute pathologic conditions, while the regenerative capacity decreases in the chronically decompensated heart and in aged diseased hearts.²⁴²⁵ LMD may offer the possibility to selectively study the newly generated myocytes as well as the resident cardiac primitive/progenitor cells, recognized by specific cell markers. In addition, LMD allows the investigation of the expression of genes that can activate primitive cell growth and differentiation or inhibit cell replication and promote telomere erosion and primitive cell death in the acutely decompensated human heart, as well as in chronic heart failure. In conclusion, LMD is an extremely useful tool that can open new areas in the study of several cardiac diseases, combining advanced molecular biology techniques with the fast and precise selection of targeted cells under direct microscopic visualization of cardiac and vascular tissues.

	Footnotes

 
Abbreviations: EBV = Epstein-Barr virus; LMD = laser microdissection; mRNA = messenger RNA; mtDNA = mitochondrial DNA; PCR = polymerase chain reaction

Received for publication February 7, 2005. Accepted for publication April 11, 2005.

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