Development of barcode and proteome profiling of glioblastoma

Naryzhny S.N.; Ronzhina N.L.; Mainskova M.A.; Belyakova N.V.; Pantina R.A.; Filatov M.V.

doi:10.18097/PBMC20146003308

Development of barcode and proteome profiling of glioblastoma

Naryzhny S.N.¹, Ronzhina N.L.², Mainskova M.A.³, Belyakova N.V.², Pantina R.A.², Filatov M.V.²

1. B.P. Konstantinov Petersburg Nuclear Physics Institute at National Research Center "Kurchatov Institute", Orekhovich Institute of Biomedical Chemistry of Russian Academy of Medical Sciences
2. B.P. Konstantinov Petersburg Nuclear Physics Institute at National Research Center "Kurchatov Institute"
3. Orekhovich Institute of Biomedical Chemistry of Russian Academy of Medical Sciences

Section: Experimental Study

DOI: 10.18097/PBMC20146003308 PubMed Id: 25019393

Year: 2014 Volume: 60 Issue: 3 Pages: 308-321

High grade glioma (glioblastoma) is the most common brain tumor. Its malignancy makes it the fourth biggest cause of cancer death. In our experiments we used several glioblastoma cell lines generated in our laboratory to obtain proteomics information specific for this disease. This study starts our developing the complete 2DE map of glioblastoma proteins. 2DE separation with following imaging, immunochemistry, spot picking, and mass-spectrometry allowed us detecting and identifying more than 100 proteins. Several of them have prominent differences in their level between norm and cancer. Among them are alpha-enolase (ENOA_HUMAN), pyruvate kinase isozymes M1/M2 (KPYM_HUMAN), cofilin 1 (COF1_HUMAN), translationally-controlled tumor protein TCTP_HUMAN, annexin 1 (ANXA1_HUMAN), PCNA (PCNA_HUMAN), p53 (TP53_HUMAN) and others. Most interesting results were obtained with protein p53. In all glioblastoma cell lines, its level was dramatically up regulated and enriched by multiple additional isoforms. This distribution is well correlated with presence of these proteins inside of cells themselves. At this initial step we suggest the panel of specific brain tumor markers (signature) to help creating noninvasive techniques to diagnose disease. These preliminary data point to these proteins as promising markers of glioblastoma.

Download PDF:

Keywords: proteome, glioblastoma, p53, PCNA

Citation:

Naryzhny, S. N., Ronzhina, N. L., Mainskova, M. A., Belyakova, N. V., Pantina, R. A., Filatov, M. V. (2014). Development of barcode and proteome profiling of glioblastoma. Biomeditsinskaya Khimiya, 60(3), 308-321.

This paper is also available as the English translation: 10.1134/S1990750814030111

References

Furnari F.B., Fenton T., Bachoo R.M., Mukasa A., Stommel J.M., Stegh A., Hahn W.C., Ligon K.L., Louis D.N., Brennan C., Chin L., DePinho R.A., Cavenee W.K. (2007) Genes Dev., 21, 2683-710. CrossRef Scholar google search
Louis D.N., Ohgaki H., Wiestler O.D., Cavenee W.K., Burger P.C., Jouvet A., Scheithauer B.W., Kleihues P. (2007) Acta Neuropathol., 114, 97-109. CrossRef Scholar google search
Hegi M.E., Diserens A.C., Gorlia T., Hamou M.F., de Tribolet N., Weller M., Kros J.M., Hainfellner J.A., Mason W., Mariani L., Bromberg J.E., Hau P., Mirimanoff R.O., Cairncross J.G., Janzer R.C., Stupp R. (2005) N. Engl. J. Med., 352, 997-1003. CrossRef Scholar google search
D'Alessandro A., Righetti P.G., Zolla L. (2010) J. Proteome Res., 9, 144-63. Scholar google search
Fu H., Subramanian R.R., Masters S.C. (2000) Annu. Rev. Pharmacol. Toxicol., 40, 617-647. CrossRef Scholar google search
Finnie C., Borch J., Collinge D.B. (1999) Plant Mol. Biol., 40, 545-554. CrossRef Scholar google search
Naryzhny S.N. (2008). Cell. Mol. Life Sci., 65, 3789-3808. CrossRef Scholar google search
Naryzhny S.N., Zhao H., Lee H. (2005) J. Biol. Chem., 280, 13888-13894. CrossRef Scholar google search
Han J.D., Bertin N., Hao T, Goldberg D.S., Berriz G.F., Zhang L.V., Dupuy D., Walhout A.J., Cusick M.E., Roth F.P., Vidal M. (2004) Nature, 430(6995), 88-93. CrossRef Scholar google search
Lemstra A.W., van Meegen M.T., Vreyling J.P., Meijerink P.H., Jansen G.H., Bulk S., Baas F., van Gool W.A. (2000) Neurology, 55, 514-516. CrossRef Scholar google search
Ino H., Chiba T. (2000) Brain Res. Mol. Brain Res., 78, 163-174. CrossRef Scholar google search
Naryzhny S.N., Lee H. (2010) FEBS Lett., 584, 4292-4298. CrossRef Scholar google search
Skog J., Würdinger T., van Rijn S., Meijer D.H., Gainche L., Sena-Esteves M., Curry W.T. Jr., Carter B.S., Krichevsky A.M., Breakefield X.O. (2008) Nat. Cell Biol., 10, 1470-1476. CrossRef Scholar google search
Shtam T.A., Naryzhnyj S.N., Landa S.B., Burdakov V.S., Artamonova T.O., Filatov M.V. (2012) Tsitologiya, 54, 430–438 Scholar google search
Naryzhny S.N., Lee H. (2007) FEBS Lett., 581, 4917-4920. CrossRef Scholar google search
Naryzhny S.N. (2009) Anal. Biochem., 392, 90-95. CrossRef Scholar google search
Bradford M.M. (1976) Anal Biochem., 72, 248-254. CrossRef Scholar google search
Naryzhny S.N. (1996) Anal. Biochem., 238, 50-53. CrossRef Scholar google search
Marcel V., Dichtel-Danjoy M.L, Sagne C., Hafsi H., Ma D., Ortiz-Cuaran S., Olivier M., Hall J., Mollereau B., Hainaut P., Bourdon J.C. (2011) Cell. Death Differ., 18, 1815-1824. CrossRef Scholar google search
Hamroun D., Kato S., Ishioka C., Claustres M., Beroud C., Soussi T. (2006) Hum. Mutat., 27, 14–20. CrossRef Scholar google search
Chumakov P.M. (2007) Usp. biol. khimii, 47, 3–52. Scholar google search
Brooks C.L., Gu W. (2003) Curr. Opin. Cell Biol., 15, 164-171. CrossRef Scholar google search
Naryzhny S.N., Lee H. (2003) Proteomics, 3, 930-936. CrossRef Scholar google search
Vogel T.W., Zhuang Z., Li J., Okamoto H., Furuta M., Lee Y.S., Zeng W., Oldfield E.H., Vortmeyer A.O., Weil R.J. (2005) Clin. Cancer Res.,11, 3624-3632. CrossRef Scholar google search
Billecke C., Malik I., Movsisyan A., Sulghani S., Sharif A., Mikkelsen T., Farrell N.P., Bogler O. (2006) Mol. Cell Proteomics, 5, 35–42. CrossRef Scholar google search
Kalinina J., Peng J., Ritchie J.C., Van Meir E.G. (2011) Neuro-Oncology, 13, 926–942. CrossRef Scholar google search
Koncarevic S., Urig S., Steiner K., Rahlfs S., Herold-Mende C., Sueltmann H., Becker K. (2009) Free Radic. Biol. Med., 46, 1096–1108. CrossRef Scholar google search
Wang Y., Yang J. et al. (2009). Cancer Cell, 15(6), 514-526. CrossRef Scholar google search
Khalil A.A. (2007). Cancer Sci., 98, 201-213. CrossRef Scholar google search
Rajcevic U., Petersen K., Knol J.C., Loos M., Bougnaud S., Klychnikov O., Li K.W., Pham T.V., Wang J., Miletic H., Peng Z., Bjerkvig R., Jimenez C.R., Niclou S.P. (2009) Mol. Cell Proteomics, 8, 2595–2612. CrossRef Scholar google search
Roseman B.J., Bollen A., Hsu J., Lamborn K., Israel M.A. (1994) Oncol. Res., 6, 561–567. Scholar google search
Moskaleva N.E., Zgoda V.G. (2012) Biomeditsinskaya khimiya, vol: 58(6), 617-634. CrossRef Scholar google search
Goufman E.I., Moshkovskij S.A., Tikhonova O.V., Lokhov P.G., Zgoda V.G., Serebryakova M.V., Toropygin I.YU., Vlasova M.L., Safarova M.R., Makarov O.V., Archakov A.I. (2006) Biokhimiya, 71, 445-453. Scholar google search

2024 (vol 70)
2023 (vol 69)
2022 (vol 68)
2021 (vol 67)
2020 (vol 66)
2019 (vol 65)
2018 (vol 64)
2017 (vol 63)
2016 (vol 62)
2015 (vol 61)
2014 (vol 60)

Issue 6
Issue 5
Issue 4
Issue 3
Issue 2
Issue 1

2013 (vol 59)
2012 (vol 58)
2011 (vol 57)
2010 (vol 56)
2009 (vol 55)
2008 (vol 54)
2007 (vol 53)
2006 (vol 52)
2005 (vol 51)
2004 (vol 50)
2003 (vol 49)

◄ ►