pten and its role in cowden syndrome and sporadic cancers john cuningham biology 445
DESCRIPTION
The Phosphatidylinositols PIP2 and PIP3 bind to and activate protein kinases Konander D. et al. EMBOJ, 2004TRANSCRIPT
PTEN and its Role in Cowden Syndrome and Sporadic Cancers
John Cuningham Biology 445
Phosphatidylinositols are membrane lipids that can be phosphorylated in multiple positions and function as messengers in signaling pathways
1
2
3
5
4
6
The Phosphatidylinositols PIP2 and PIP3bind to and activate protein kinases
Konander D. et al. EMBOJ, 2004
PTEN can function as both a protein and lipid phosphatase
PTEN’s lipid phosphatase activity opposes Phosphoinositude-3-Kinase (PI3K) activity, thus inactivating Akt and other downstream targets
PTEN also exhibits tumor suppressive functions in the nucleus
PTEN is one of the most commonly mutated tumor suppressor genes with a
wide variety of cancer-specific mutations
Homozygous loss of PTEN is embryonic lethal with defects in cephalic and caudal patterning and failure of chorio-allantoic development
Functional inactivation of one PTEN allele increases tumor susceptibility in various tissues
PTEN loss in cancer exemplifies complexity with haploinsufficiency and genetic interactions playing a
crucial role in tumor susceptibility
Cowden Syndrome • This is the most common PTEN harmatoma tumor syndrome (PHTS) • 85% of patients with this syndrome have germline PTEN mutations • Classically associated with formation of breast cancer, endometrial cancer
and thyroid cancer
PTEN also plays a role in many sporadic tumors and is one of the most commonly mutated tumor suppressors
Treatment Options• As a tumor suppressor the loss of PTEN function can not currently be
replaced by targeted drug therapy, but knowledge of the pathway affected by PTEN loss allows targeting of drugsPI3k-mTOR-Akt1 pathway
Rapamycin-mTor
http://www.reagentsdirect.com/index.php/small-molecules/small-molecules-1/rapamycin/rapamycin.html
Perifosine-Akt
https://www.caymanchem.com/app/template/Product.vm/catalog/10008112
References • Alimonti A., Carracedo A., Clohessy J. G., Trotman L. C., Nardella C., Egia A., Salmenna L.,
Sampieri K., Haveman W. J., Brogi E., Richardson A. L., Zhang J., Pandolfi P. P., (2010) “Subtle variations in Pten dose determine cancer susceptibility” Nat gen. Vol 42, 445-455.
• Cristofano A. Di, Pesce B., Cordon-Cardo C., Pandolfi P. P., (1998) “Pten is essential for embryonic development and tumour suppression.” Nat gen. Vol. 19, 348-355.
• Hollander C. H., Blumenthal G.M., Dennis P. A. (2011) “PTEN loss in the continuum of common cancers, rare syndromes and mouse models” Nature. Vol. 11, 289-301.
• Jie-Oh Lee,Yang H., Georgescu M-M., Di Cristofano A., Maehama T., Shi Y., Dixon J. E., Pandolfi P., Pavletich N. P., (1999) “Crystal Structure of the PTEN Tumor Suppressor: Implications for Its Phosphoinositide Phosphatase Activity and Membrane Association” Cell, Vol. 99, 323–334.
• Komander D., Fairservice A., Deak M., Kular G.S., Prescott A.R., Peter Downes C., Safrany S.T., Alessi D.R., van Aalten D.M., (2004) “Structural insights into the regulation of PDK1 by phosphoinositides and inositol phosphates.” EMBO J. Vol 23. 3918-3928.
• Song M. S., Salmena L., Pandolfi P. P., (2012) “The functions and regulation of the PTEN tumour suppressor” Nature. Vol. 13, 283-296.
• Suzuki A., Pompa J. L., Stambolic V., Elia A. J., Sasaki T., Iván del Barco Barrantes, Ho A., Wakeham A., Itie A., Khoo W., Fukumoto M., Mak T. W.,(1998).” Currrent Biology., Vol. 8, 1169-1178
• Voet D., and Voet J. G. Biochemistry. 4th Edition. Massachusetts: Courier/ Kendallville, 2011. Print.