posted on 2014-11-07, 00:00authored byMuge Serhatli, Kemal Baysal, Ceyda Acilan, Eylem Tuncer, Seldag Bekpinar, Ahmet Tarik Baykal
Aortic
aneurysm is a complex multifactorial disease, and its molecular
mechanism is not understood. In thoracic aortic aneurysm (TAA), the
expansion of the aortic wall is lead by extracellular matrix (ECM)
degeneration in the medial layer, which leads to weakening of the
aortic wall. This dilatation may end in rupture andif untreateddeath.
The aortic media is composed of vascular smooth muscle cells (VSMCs)
and proteins involved in aortic elasticity and distensibility. Delineating
their functional and quantitative decrease is critical in elucidating
the disease causing mechanisms as well as the development of new preventive
therapies. Laser microdissection (LMD) is an advanced technology that
enables the isolation of the desired portion of tissue or cells for
proteomics analysis, while preserving their integrity. In our study,
the aortic media layers of 36 TAA patients and 8 controls were dissected
using LMD technology. The proteins isolated from these tissue samples
were subjected to comparative proteomic analysis by nano-LC–MS/MS,
which enabled the identification of 352 proteins in aortic media.
Among these, 41 proteins were differentially expressed in the TAA
group with respect to control group, and all were downregulated in
the patients. Of these medial proteins, 25 are novel, and their association
with TAA is reported for the first time in our study. Subsequent analysis
of the data by ingenuity pathway analysis (IPA) shows that the majority
of differentially expressed proteins were found to be cytoskeletal-associated
proteins and components of the ECM which are critical in maintaining
aortic integrity. Our results indicate that the protein expression
profile in the aortic media from TAA patients differs significantly
from controls. Further analysis of the mechanism points to markers
of pathological ECM remodeling, which, in turn, affect VSMC cytosolic
structure and architecture. In the future, the detailed investigation
of the differentially expressed proteins may provide insight into
the elucidation of the pathological processes underlying aneurysms.