A structural analysis of glycosaminoglycans from lethal and non-lethal breast cancer tissues: Towards a novel class of theragnostics for personalized medicine in oncology

Weyers, A.
Yang, B.
Yoon, D.S.
Park, J.H.
Zhang, F.
Lee, K.B.
Linhardt, Robert J.
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Biology , Chemistry and chemical biology , Chemical and biological engineering , Biomedical engineering
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A structural analysis of glycosaminoglycans from lethal and non-lethal breast cancer tissues: Towards a novel class of theragnostics for personalized medicine in oncology, A. Weyers, B. Yang, D. S. Yoon, J.-H. Park, F. Zhang, K. B. Lee, R. J. Linhardt, Omics, 16, 79-89, 2012.
Cancer is one of the leading noncommunicable diseases that vastly impacts both developed and developing countries. Truly innovative diagnostics that inform disease susceptibility, prognosis, and/or response to treatment (theragnostics) are seriously needed for global public health and personalized medicine for patients with cancer. This study examined the structure and content of glycosaminoglycans (GAGs) in lethal and nonlethal breast cancer tissues from six patients. The glycosaminoglycan content isolated from tissue containing lethal cancer tumors was approximately twice that of other tissues. Molecular weight analysis showed that glycosaminoglycans from cancerous tissue had a longer weight average chain length by an average of five disaccharide units, an increase of approximately 15%. Dissacharide analysis found differences in sulfation patterns between cancerous and normal tissues, as well as sulfation differences in GAG chains isolated from patients with lethal and nonlethal cancer. Specifically, cancerous tissue showed an increase in sulfation at the “6S” position of CS chains and an increase in the levels of the HS disaccharide NSCS. Patients with lethal cancer showed a decrease in HS sulfation, with lower levels of “6S” and higher levels of the unsulfated “0S” disaccharide. Although these findings come from a limited sample size, they indicate that structural changes in GAGs exist between cancerous and noncancerous tissues and between tissues from patients with highly metastatic cancer and cancer that was successfully treated by chemotherapy. Based on these findings, we hypothesize that (1) there are putative changes in the body's construction of GAGs as tissue becomes cancerous; (2) there may be innate structural person-to-person variations in GAG composition that facilitate the metastasis of tumors in some patients when they develop cancer.
Omics, 16, 79-89
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