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conferenceseries

.com

Volume 7, Issue 1 (Suppl)

J Biotechnol Biomater

ISSN: 2155-952X JBTBM, an open access journal

March 20-21, 2017 Rome, Italy

&

15

th

World Congress on

2

nd

International Conference on

Biotechnology And Biotech Industries Meet

Enzymology and Molecular Biology

Enzymology & Mol. Biology 2017

Biotechnology Congress 2017

March 20-21, 2017

Knockdown of RPS3, a DNA repair endonuclease, impedes colon cancer growth and progression by

decreasing lactate dehydrogenase activity

Zeina Nasr

and

Lama Maaliki

University of Balamand, Lebanon

Statement of the Problem:

In addition to their role in ribosome biogenesis, ribosomal proteins (RPs) play important roles in DNA

repair, proliferation, apoptosis and resistance to drugs and chemotherapy. Ribosomal protein S3 (RPS3), a DNA repair endonuclease,

is known to be overexpressed in colon adenocarcinoma. In order to ensure their survival, cancer cells rely on aerobic glycolysis

catalyzed by the enzyme lactate dehydrogenase (LDH). Our aim is to identify the role of RPS3 in colon cancer growth and metabolism.

Methodology & Theoretical Orientation:

Human colon adenocarcinoma Caco-2 and normal colon NCM-640 cells were tested for

the expression of RPS3 by Western blot. In order to inhibit RPS3 expression, cells were transfected with siRNA against RPS3 or a non-

targeting siRNA (siNT) as a negative control. Upon RPS3 knockdown, cell behaviors were tested including proliferation and survival

by trypan blue and WST-1 assays and cell migration and invasion by the Boyden chamber assays. The glycolysis state of colon cancer

cells was assessed by measuring LDH activity upon RPS3 knockdown using the LDH assay.

Findings:

RPS3 was shown to be expressed in both Caco-2 and NCM-640 cells. RPS3 knockdown in Caco-2 significantly reduced

cell proliferation, survival, migration and invasion compared to siNT-transfected cells. In NCM-640, RPS3 knockdown did not

significantly affect cell proliferation and survival implying that RPS3 expression is selectively crucial for colon cancer cell growth.

Interestingly, LDH activity was suppressed upon RPS3 knockdown, suggesting a decrease in glycolysis which explains in part the

decrease in proliferation.

Conclusion & Significance:

This is the first report that shows a role of RPS3 in regulating LDH activity therefore affecting the

glycolytic state, the survival and proliferation of cancer cells. Our results also demonstrate that RPS3 is a selective molecular marker

in colon cancer and a potential attractive target for colon cancer therapy.

Biography 

Zeina Nasr is Assistant Professor, at the Department of Biology in the University of Balamand, Lebanon. She did her PhD from McGill University in the Department

of Biochemistry. She has her interest in understanding the molecular aspect of tumor initiation and progression. Her research focuses on studying the effect of

translation initiation dysregulation on cancer behavior. She has worked with several cell lines and transgenic mouse models and deciphered important pathways

that contribute to cancer initiation and progression to metastasis. She has experience in conducting research and teaching at various institutions. Currently, her

work focuses on the extra-ribosomal functions of ribosomal proteins and their effects on tumorigenesis.

zeina.nasr@balamand.edu.lb

Zeina Nasr et al., J Biotechnol Biomater 2017, 7:1(Suppl)

http://dx.doi.org/10.4172/2155-952X.C1.070