Sage Journals: Discover world-class research

Abstract

Osteosarcoma (OS) is the most common primary malignant tumor of bone, which occupying about 20% of all bone cancers. To increase understanding of the biology of OS, we developed and evaluated a top-down mass spectrometry approach to detect, identify and quantify low molecular weight (MW) proteins (i.e., 1 kDa < MW < 30 kDa) in osteosarcoma cells. Top-down proteomic (TDP) data was acquired using reversed phase nano-liquid chromatography in conjunction with high-resolution mass spectrometry and resulted in the assignment of 328 proteins and 820 proteoforms or degradation products with high confidence. Eight post-translational modifications (PTMs) were identified in the present study, including N-terminal acetylation, lysine acetylation, succinylation, malonylation, serine/tyrosine phosphorylation, histidine methylation and N-acetylleucine. We confirmed that a truncated N-terminal proteoform lost 73 Da of mass through removal of the N-terminal Met (−131 Da), acetylation of the second amino acid (+42 Da), and Met oxidation (+16 Da). The results showed that the levels of proteoforms/biodegradable peptides correlated with the metastatic phenotypes of osteosarcoma cell lines. This study demonstrates the benefits of TDP for the characterization and relative quantification of proteoforms with relevance to OS biology and the potential of small molecular weight proteoforms to serve as a still underappreciated source of biomarkers.

Keywords

Top-down proteomics osteosarcoma proteoforms degradation products post-translational modifications

Get full access to this article

View all access options for this article.

References

Moore

Luu

. Osteosarcoma. Cancer Treat Res 2014; 162: 65–92.

Colding-Rasmussen

Thorn

Horstmann

, et al. Survival and prognostic factors at time of diagnosis in high-grade appendicular osteosarcoma: a 21 year single institution evaluation from east Denmark. Acta Oncol 2018; 57: 420–425.

Wang

Whiteaker

Paulovich

. The evolving role of mass spectrometry in cancer biomarker discovery. Cancer Biol Ther 2009; 8: 1083–1094.

Brady

Troyer

Ramsey

, et al. A preliminary proteomic investigation of circulating exosomes and discovery of biomarkers associated with the progression of osteosarcoma in a clinical model of spontaneous disease. Transl Oncol 2018; 11: 1137–1146.

Song

Pearce

Jiang

, et al. Delineation of hypoxia-induced proteome shifts in osteosarcoma cells with different metastatic propensities. Sci Rep 2020; 10: 727.

Zhang

. Comprehensive analysis of protein modifications by top-down mass spectrometry. Circulation. Cardiovascular Genetics 2011; 4: 711.

Whitelegge

. Intact protein mass spectrometry and top-down proteomics. Expert Rev Proteomics 2013; 10: 127–129.

Cristobal

Marino

Post

, et al. Toward an optimized workflow for middle-down proteomics. Anal Chem 2017; 89: 3318–3325.

Sidoli

Garcia

. Middle-down proteomics: a still unexploited resource for chromatin biology. Expert Rev Proteomics 2017; 14: 617–626.

10.

Cui

Rohrs

Gross

. Top-down mass spectrometry: recent developments, applications and perspectives. Analyst 2011; 136: 3854–3864.

11.

Scheffler

. Top-down proteomics by means of orbitrap mass spectrometry. Methods Mol Biol 2014; 1156: 465–487.

12.

Ahlf

Compton

Tran

, et al. Evaluation of the compact high-field orbitrap for top-down proteomics of human cells. J Proteome Res 2012; 11: 4308–4314.

13.

Geis-Asteggiante

Dhabaria

Edwards

, et al. Top-down analysis of low mass proteins in exosomes shed by murine myeloid-derived suppressor cells. Int J Mass Spectrom 2015; 378: 264–269.

14.

Kalli

Smith

Sweredoski

, et al. Evaluation and optimization of mass spectrometric settings during data-dependent acquisition mode: focus on LTQ-orbitrap mass analyzers. J Proteome Res 2013; 12: 3071–3086.

15.

Fellers

Greer

Early

, et al. Prosight lite: graphical software to analyze top-down mass spectrometry data. Proteomics 2015; 15: 1235–1238.

16.

Meng

Cargile

Miller

, et al. Informatics and multiplexing of intact protein identification in bacteria and the archaea. Nat Biotechnol 2001; 19: 952–957.

17.

Udeshi

Compton

Shabanowitz

, et al. Methods for analyzing peptides and proteins on a chromatographic timescale by electron-transfer dissociation mass spectrometry. Nat Protoc 2008; 3: 1709–1717.

18.

Frese

Altelaar

van den Toorn

, et al. Toward full peptide sequence coverage by dual fragmentation combining electron-transfer and higher-energy collision dissociation tandem mass spectrometry. Anal Chem 2012; 84: 9668–9673.

19.

Cabras

Iavarone

Martelli

, et al. High-resolution mass spectrometry for thymosins detection and characterization. Expert Opin Biol Ther 2015; 15: S191–S201.

20.

Beckman

Voinov

Hare

, et al. Improved protein and PTM characterization with a practical electron-based fragmentation on Q-TOF instruments. J Am Soc Mass Spectrom 2021; 32: 2081–2091.

21.

Domanski

Hertzog

Coutant

, et al. Coupling of folding and binding of thymosin beta4 upon interaction with monomeric actin monitored by nuclear magnetic resonance. J Biol Chem 2004; 279: 23637–23645.

22.

Hardesty

Kelley

, et al. Protein signatures for survival and recurrence in metastatic melanoma. J Proteomics 2011; 74: 1002–1014.

23.

Leeanansaksiri

DeSimone

Huff

, et al. Thymosin beta 4 and its N-terminal tetrapeptide, AcSDKP, inhibit proliferation, and induce dysplastic, non-apoptotic nuclei and degranulation of mast cells. Chem Biodiversity 2004; 1: 1091–1100.

24.

Zheng

Hincapie

, et al. Study of the human plasma proteome of rheumatoid arthritis. J Chromatogr A 2009; 1216 (16): 3538–3545.

25.

Martoglio

Dobberstein

. Signal sequences: more than just greasy peptides. Trends Cell Biol 1998; 8: 410–415.

26.

Watanabe

Sato

Itoh

, et al. The roles of salusins in atherosclerosis and related cardiovascular diseases. J Am Soc Hypertens 2011; 5: 359–365.

27.

Cha

Jeong

Kleinman

. Role of thymosin beta4 in tumor metastasis and angiogenesis. J Natl Cancer Inst 2003; 95: 1674–1680.

28.

Sribenja

Wongkham

, et al. Roles and mechanisms of beta-thymosins in cell migration and cancer metastasis: an update. Cancer Investig 2013; 31: 103–110.

29.

Reti

Kwon

Qiu

, et al. Thymosin beta4 is cytoprotective in human gingival fibroblasts. Eur J Oral Sci 2008; 116: 424–430.

30.

Roy

Rajfur

Jones

, et al. Local photorelease of caged thymosin beta4 in locomoting keratocytes causes cell turning. J Cell Biol 2001; 153: 1035–1048.

31.

Smart

Rossdeutsch

Riley

. Thymosin beta4 and angiogenesis: modes of action and therapeutic potential. Angiogenesis 2007; 10: 229–241.

32.

Xiao

Chen

Wen

, et al. Thymosin beta4: a potential molecular target for tumor therapy. Crit Rev Eukaryot Gene Expr 2012; 22: 109–116.

33.

Cui

Chen

, et al. Thymosin beta4 promotes hepatoblastoma metastasis via the induction of epithelial-mesenchymal transition. Mol Med Rep 2015; 12: 127–132.

34.

Wirsching

Krishnan

Florea

, et al. Thymosin beta 4 gene silencing decreases stemness and invasiveness in glioblastoma. Brain : A Journal of Neurology 2014; 137: 433–448.

35.

Yamamoto

Gotoh

Kitajima

, et al. Thymosin beta-4 expression is correlated with metastatic capacity of colorectal carcinomas. Biochem Biophys Res Commun 1993; 193: 706–710.

36.

Kang

Ock

, et al. Thymosin beta4 expression in human tissues and in tumors using tissue microarrays. Applied Immunohistochemistry & Molecular Morphology : AIMM 2011; 19: 160–167.

37.

McDoniels-Silvers

Nimri

Stoner

, et al. Differential gene expression in human lung adenocarcinomas and squamous cell carcinomas. Clinical Cancer Research : An Official Journal of the American Association for Cancer Research 2002; 8: 1127–1138.

38.

Eadie

Kim

Allen

, et al. C-terminal variations in beta-thymosin family members specify functional differences in actin-binding properties. J Cell Biochem 2000; 77: 277–287.

39.

Koyano

Okatsu

Kosako

, et al. Ubiquitin is phosphorylated by PINK1 to activate parkin. Nature 2014; 510: 162–166.

40.

Ohtake

Saeki

Sakamoto

, et al. Ubiquitin acetylation inhibits polyubiquitin chain elongation. EMBO Rep 2015; 16: 192–201.

41.

Nyman

Schuler

Korenbaum

, et al. The role of MeH73 in actin polymerization and ATP hydrolysis. J Mol Biol 2002; 317: 577–589.

42.

Kwiatkowski

Drozak

. Protein histidine methylation. Curr Protein Pept Sci 2020; 21: 675–689. doi:10.2174/1389203721666200318161330

43.

Fan

Hsu

Chen

. Mass spectrometry in the discovery of peptides involved in intercellular communication: from targeted to untargeted peptidomics approaches. Mass Spectrom Rev 2022: e21789.

44.

Mommen

Frese

Meiring

, et al. Expanding the detectable HLA peptide repertoire using electron-transfer/higher-energy collision dissociation (EThcD). Proc Natl Acad Sci U S A 2014; 111: 4507–4512.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

2.59 MB

Top-down mass spectrometry for characterizing the low molecular weight proteome of canine osteosarcoma cell phenotypes

Abstract

Keywords

Get full access to this article

References

Supplementary Material