Prestige Antibodies^® in Breast Cancer Research

• The Human Protein Atlas
• Prestige Antibodies^® Powered by Atlas Antibodies
• Monoclonal Antibody Development
• Clinical Markers (ESR1, HER2, Ki67, PGR)
• Antibodies used in Breast Cancer Research
• Antibodies Against Gene Products in MammaPrint, Oncotype, EndoPredict and uPA Tests
• Antibodies Identified in the Human Protein Atlas

Download the Prestige Antibodies^® Breast Cancer Research Brochure (PDF)

The Human Protein Atlas

proteinatlas.org

The Human Protein Atlas is Characterizing the Human Proteome

The Human Protein Atlas (HPA) project was initiated in 2003 by Swedish researchers, headed by Professor Mathias Uhlén, and funded by the Knut and Alice Wallenberg Foundation.^1,2 It is a unique world leading effort performing systematic exploration of the human proteome using antibodies.

The aim of the HPA project is to present an expression map of the complete human proteome. To accomplish this, highly specific polyclonal antibodies are developed to all protein coding human genes and protein profiling is established in a multitude of tissues and cells using tissue arrays. Applications applied are immunohistochemistry (IHC), Western blot (WB) analysis, protein array assay and immunofluorescent based confocal microscopy (ICC-IF).

The Human Protein Atlas, November 2014

The 13th version of the Human Protein Atlas, released in November 2014, presents a tissue-based map of the complete human proteome. The extensive amount of data is divided into four separate 'sub atlases': the Tissue Atlas, the Cancer Atlas, the Subcell Atlas and the Cell Line Atlas. For all proteins represented in the Tissue Atlas, the expression profiles are based on IHC analysis on a large number of human tissues. The presentation of protein expression data in correlation to RNA sequencing data for each gene has now been included. In the Cancer Atlas, differentially expressed genes in several cancers can be studied, while the Subcell Atlas presents subcellular localization by confocal microscopy. Additional information about protein expression in common cell lines is included in the Cell Line Atlas, which has become an appreciated toolbox for research.

Tissue microarrays containing samples from 48 different normal human tissues, 20 different cancer types and 44 different human cell lines are utilized within the project. The 48 normal tissues are present in triplicate samples and represent 82 different cell types. All normal tissue images have undergone pathology-based annotation of expression levels and are displayed on the normal Tissue Atlas presenting information regarding the expression profiles of human genes both on mRNA and protein level. The mRNA expression data is derived from deep sequencing of RNA (RNA-Seq) from 27 major different normal tissue types.

The Cancer Atlas contains gene expression data based on protein expression patterns in a multitude of human cancer specimens. Altogether 216 different cancer samples, corresponding to the 20 most common forms of human cancer, have been analyzed for all included genes. All cancer tissue images have been manually annotated by pathologists and just as for the normal Tissue Atlas, protein data includes protein expression levels corresponding to 16.621 genes for which there are available antibodies.

Validation in Breast Tissue Samples and Cell Lines

IHC images from normal breast samples from three different individuals are available for each antibody in the normal Tissue Atlas. In addition, for each antibody, breast tumor samples from up to 12 patients in duplicates are presented in the Cancer Atlas and for the majority of the antibodies, also images from the MCF-7 and SK-BR-3 breast cell lines in the Cell Line Atlas.

References

1. Uhlen M, Oksvold P, Fagerberg L, Lundberg E, Jonasson K, Forsberg M, Zwahlen M, Kampf C, Wester K, Hober S, et al. 2010. Towards a knowledge-based Human Protein Atlas. Nat Biotechnol. 28(12):1248-1250. https://doi.org/10.1038/nbt1210-1248

2. Uhlen M, Ponten F, Lindskog C. 2015. Charting the human proteome: Understanding disease using a tissue-based atlas. Science. 347(6227):1274-1274. https://doi.org/10.1126/science.347.6227.1274-c

Prestige Antibodies^® Powered by Atlas Antibodies

Prestige Antibodies – the Building Blocks of HPA

The uniqueness and low cross reactivity of Prestige Polyclonals to other proteins are due to a thorough selection of antigen regions, affinity purification on the recombinant antigen, validation using several methods and a stringent approval process.

Development

The Prestige Antibodies are developed against recombinant human Protein Epitope Signature Tags (PrESTs) of approximately 50 to 150 amino acids. These protein fragments are designed, using a proprietary software, to contain unique epitopes present in the native protein suitable for triggering the generation of antibodies of high specificity. This is achieved by a complete human genome scanning to ensure that PrESTs with the lowest homology to other human proteins are used as antigens.

Approval

The approval of the Prestige Antibodies relies on a combined validation of the experimental results using IHC, WB or ICC-IF, from RNA sequencing and from information obtained via bioinformatics prediction methods and literature. Since the literature is often inconclusive, an important objective of the HPA project has been to generate paired antibodies with non-overlapping epitopes towards the same protein target, allowing the results and validation of one antibody to be used to validate the other one.

Prestige Antibodies Catalog

Today, there are more than 17,000 Prestige Polyclonals with 2,000 new antibodies added each year.

The antibodies developed and characterized within the Human Protein Atlas project are available to the scientific community as Prestige Antibodies and Atlas Antibodies.

Monoclonal Antibody Development

Prestige Antibodies also include a selected number of mouse monoclonal antibodies. The monoclonal catalog is regularly expanding with new products every year.

Unique Features

Special care is taken in offering clones recognizing only unique nonoverlapping epitopes and/or isotypes. Using the same stringent PrEST production process and characterization procedure as for the polyclonals, the monoclonal antibodies offer outstanding performance in approved applications, together with defined specificity, secured continuity and stable supply. In general they also permit high working dilutions and contribute to more standardized assay procedures.

Clone Selection

Functional characterization is performed on a large number of ELISA positive cell supernatants to select the optimal clones for each application prior to subcloning and expansion of selected hybridomas.

Epitope Mapping

Clones are epitope-mapped using synthetic overlapping peptides in a bead-based array format for selection of clones with nonoverlapping epitopes only.

Isotyping

All monoclonal antibodies are isotyped to allow for multiplexing using isotype-specific secondary antibodies.

Hybridoma Cell Cultivation

Atlas Antibodies use in vitro methods for the production scale-up phase thus replacing the use of mice for production of ascites fluid.

Antibody Characterization

The characterization of Prestige Monoclonal Antibodies starts with an extensive literature search to select the most relevant and clinically significant tissues to use for IHC characterization. Often there are more than one tissue type displayed in the IHC application data for each antibody. In addition to positive stained tissue, a negative control tissue staining is also displayed and if relevant, clinical cancer tissue staining.

The Western blot (WB) characterization includes results from endogenous human cell or tissue protein lysates or optionally recombinant full-length human protein lysates.

Each monoclonal antibody is thus supplied with the most relevant characterization data for its specific target.

The product numbers of all Prestige Polyclonals start with ”HPA” and of monoclonal antibodies with “AMAB”.

Clinical Markers (ESR1, HER2, Ki67, PGR)

Established Clinical Breast Cancer Markers

Cat. No.	Target Protein	Product Description	Validated Applications
HPA000449	Estrogen receptor	Anti-ESR1	IHC,WB
HPA000450	Estrogen receptor	Anti-ESR1	IHC,WB
HPA004751	Progesteron receptor	Anti-PGR1	IHC,ICC-IF
HPA008428	Progesteron receptor	Anti-PGR	IHC
HPA017176	Progesteron receptor	Anti-PGR	IHC
HPA001383	HER2/ERBB2	Anti-ERBB2	IHC,WB
AMAb90627	HER2/ERBB2	Anti-HER2	IHC,WB
HPA000451	Ki67/MKI67	Anti-MKI672	IHC,ICC-IF
HPA001164	Ki67/MKI67	Anti-MKI673	IHC,ICC-IF
AMAb90870	Ki67/MKI67	Anti-MKI67	IHC

1. Pereira CBL, Leal MF, de Souza CRT, Montenegro RC, Rey JA, Carvalho AA, Assumpção PP, Khayat AS, Pinto GR, Demachki S, et al. Prognostic and Predictive Significance of MYC and KRAS Alterations in Breast Cancer from Women Treated with Neoadjuvant Chemotherapy. PLoS ONE. 8(3):e60576. https://doi.org/10.1371/journal.pone.0060576

2. Camilleri M, Carlson P, Zinsmeister AR, McKinzie S, Busciglio I, Burton D, Zucchelli M, D'Amato M. 2010. Neuropeptide S Receptor Induces Neuropeptide Expression and Associates With Intermediate Phenotypes of Functional Gastrointestinal Disorders. Gastroenterology. 138(1):98-107.e4. https://doi.org/10.1053/j.gastro.2009.08.051

3. Roca H, Craig MJ, Ying C, Varsos ZS, Czarnieski P, Alva AS, Hernandez J, Fuller D, Daignault S, Healy PN, et al. 2011. IL-4 induces proliferation in prostate cancer PC3?cells under nutrient-depletion stress through the activation of the JNK-pathway and survivin upregulation. J. Cell. Biochem..n/a-n/a. https://doi.org/10.1002/jcb.24025

Immunohistochemical staining of human breast tumour using Anti-HER2 (AMAb90627) shows strong membranous (combined with moderate cytoplasmic) positivity in tumour cells in HER2-positive ductal carcinoma, while HER2-negative ductal carcinoma shows no membranous positivity. By Western Blot analysis, HER2 is detected in the breast cancer cell line SK-BR-3.

Progesteron Receptor

IHC staining using the Anti-PGR antibody (HPA004751) in normal human corpus (uterine) tissue shows strong nuclear positivity in glandular cells. In the presented breast cancer sample, the staining of tumor cells is also nuclear. ICC-IF shows nuclear staining in U-251MG cells.

Estrogen Receptor

The Anti-ESR1 antibody (HPA000449) shows distinct nuclear positivity in glandular cells in human breast tissue and in tumor cells in breast cancer samples using IHC.

IHC staining using the Anti-ESR1 antibody (HPA000450) shows strong nuclear positivity in glandular and stromal cells of human corpus, uterine tissue and in tumor cells in breast cancer.

Ki67

The Anti-MKI67 antibody (HPA000451) shows strong nuclear positivity in a fraction of cells in the reaction center in human lymph node using IHC. In breast cancer, the staining of tumor cells is also nuclear and by ICC-IF, staining of the human cell line U-2OS shows positivity in nucleoli.

IHC staining of human tonsil tissue using the Anti-MKI67 antibody (HPA001164) shows nuclear staining of reaction center cells. In tumor cells in breast cancer, the staining is mainly nuclear and in U-2OS cells, using ICC-IF, nucleoli show strong positivity.

IHC staining of lymph node in human colon shows strong nuclear and nucleolar immunoreactivity in the reaction centrum cells using the monoclonal Anti-MKI67 antibody (AMAb90870). In uterus, nuclear positivity in a subset of glandular cells is shown.

Antibodies used in Breast Cancer Research

In this section, antibodies are selected either on a reference/article-basis or on breast cancer relevance for the corresponding target protein.

BRCA1

The Anti-BRCA1 antibody (HPA034966) shows positivity in glandular cells in normal human breast tissue and in tumor cells in breast cancer samples using IHC.

IHC staining using the Anti-BRCA2 antibody (HPA026815) in normal human breast tissue shows positivity in glandular cells. In breast cancer, nuclear staining of tumor cells is shown.

ACAT1

Immunohistochemical staining of human liver tissue using Anti-ACAT1 (HPA004428) shows strong cytoplasmic positivity in hepatocytes. By Western blot analysis, ACAT1 is detected in the human cell lines RT-4 and U251-MG and in liver and tonsil tissue lysates. By ICC-IF in the human cell line A-431, positivity is shown in mitochondria.

CD44

Immunohistochemical staining of human esophagus tissue using Anti-CD44 (HPA005785) shows strong strong cytoplasmic and membranous positivity in squamous epithelial cells. By Western Blot analysis, CD44 is detected in the human cell line U-251MG. ICC-IF in the human cell line U-251MG shows positivity in plasma membrane.

Cat. No.	Target Protein	Product Description	Validated Applications
HPA008788	53BP1	Anti-TP53BP1	IHC,ICC-IF
HPA022133	53BP1	Anti-TP53BP1	IHC,WB*,ICC-IF
HPA004428	ACAT1	Anti-ACAT11,2	IHC,WB*,ICC-IF
HPA007569	ACAT1	Anti-ACAT12-4	IHC,WB,ICC-IF
HPA007912	AGR2	Anti-AGR25	IHC,WB
HPA024210	AIB1/NCOA3	Anti-NCOA3	IHC,ICC-IF
AMAb90660	Anillin/ANLN	Anti-ANLN	IHC,WB
AMAb90662	Anillin/ANLN	Anti-ANLN	IHC,WB
HPA005680	Anillin/ANLN	Anti-ANLN6	IHC,WB,ICC-IF
HPA024006	ARG1	Anti-ARG17	IHC,WB
HPA005468	ASAH1	Anti-ASAH18,9	IHC,WB
HPA028264	ATR	Anti-ATR	IHC
HPA029455	BAAT1/BRAT1	Anti-BRAT1	IHC,WB
HPA003175	BACH1	Anti-BACH110	IHC,WB,ICC-IF
HPA028814	BAP1	Anti-BAP1	IHC,WB,ICC-IF
HPA044864	BARD1	Anti-BARD1	IHC,ICC-IF
HPA029159	Beta-Catenin	Anti-CTNNB1	IHC,WB*,ICC-IF
HPA029160	Beta-Catenin	Anti-CTNNB1	IHC, IF
HPA002317	BIRC3/API2	Anti-BIRC311	IHC,WB,ICC-IF
HPA012897	BIT1/ PTRH2	Anti-PTRH212,13	IHC,WB,ICC-IF
HPA005689	Blooms Syndrome Prot	Anti-BLM	IHC,ICC-IF
HPA030472	Bmi1	Anti-BMI1	IHC,WB*,ICC-IF
HPA034966	BRCA1	Anti-BRCA1	IHC
HPA026815	BRCA2	Anti-BRCA2	IHC,ICC-IF
HPA005474	BRIP1/FANCJ	Anti-BRIP1	IHC,WB,ICC-IF
HPA036596	C11orf51/ANAPC15	Anti-ANAPC15	IHC,WB,ICC-IF
HPA051365	CAR/NR1I3	Anti-NR1I3	IHC,ICC-IF
HPA001302	CASP8	Anti-CASP8	IHC,WB,ICC-IF
HPA005688	CASP8	Anti-CASP8	IHC,WB,ICC-IF
HPA008773	CAXII/CA12	Anti-CA1214-17	IHC,WB
HPA005785	CD44	Anti-CD4418-22	IHC,WB,ICC-IF
HPA028900	CD82	Anti-CD82	IHC,WB
HPA004812	CDH1	Anti-CDH1	IHC,ICC-IF
HPA019758	CEA/CEACAM5	Anti-CEACAM5	IHC,WB
HPA001878	CHEK2	Anti-CHEK2	IHC,WB
HPA001254	CKB	Anti-CKB	IHC
HPA004135	CRABP2	Anti-CRABP2	IHC,WB,ICC-IF
HPA015955	CTNND1	Anti-CTNND1	IHC,WB*,ICC-IF
HPA010663	CX32/GJB1	Anti-GJB123	IHC,WB
HPA018169	Cyclin E1	Anti-CCNE1	IHC,WB,ICC-IF
HPA020626	Cyklin A2	Anti-CCNA2	IHC,WB
HPA023040	Cytokeratin 14/CK14	Anti-KRT14	IHC,WB*,ICC-IF
HPA000452	Cytokeratin 17/CK17	Anti-KRT1724	IHC,WB
HPA000453	Cytokeratin 17/CK17	Anti-KRT17	IHC,WB,ICC-IF
HPA000258	DACH2	Anti-DACH225	IHC,ICC-IF
HPA019907	DBC1/KIAA1967	Anti-KIAA1967	IHC,WB*,ICC-IF
HPA019943	DBC1/KIAA1967	Anti-KIAA1967	IHC,ICC-IF
HPA022962	DCAF7	Anti-DCAF726	IHC, WB
HPA003315	Decorin/DCN	Anti-DCN27,28	IHC, WB
HPA028483	DIRAS3	Anti-DIRAS3	IHC,WB
HPA028557	DIRAS3	Anti-DIRAS3	IHC,WB
HPA029384	DIRAS3	Anti-DIRAS3	IHC
AMAb90816	EGFR	Anti-EGFR	IHC,WB
AMAb90819	EGFR	Anti-EGFR	WB
HPA001200	EGFR	Anti-EGFR29	IHC
HPA018530	EGFR	Anti-EGFR30	IHC,WB,ICC-IF
HPA003901	Endoplasmin/ HSP90B1	Anti-HSP90B127,31	IHC,WB,ICC-IF
HPA002025	ERLIN2	Anti-ERLIN232,33	IHC,WB*,ICC-IF
HPA026676	ERFF/C1orf64	Anti-C1orf6434	IHC,WB,ICC-IF
HPA007425	FAAH	Anti-FAAH35	IHC,ICC-IF
HPA035305	FGFR2	Anti-FGRF2	IHC,WB,ICC-IF
HPA029731	GATA3	Anti-GATA3	IHC, WB
HPA009177	GCDFP/PIP	Anti-PIP	IHC,WB
HPA017046	GEF-H1	Anti-ARHGEF236,37	IHC,WB
HPA025226	GGH	Anti-GGH35	IHC,WB
HPA008763	Granulin	Anti-GRN38	IHC,ICC-IF, WB
HPA028747	Granulin	Anti-GRN38	IHC,ICC-IF
HPA001275	HIF-1 alpha/HIF1A	Anti-HIF1A39-42	IHC,ICC-IF
HPA008436	HJURP	Anti-HJURP43-45	IHC,WB,ICC-IF
HPA004727	HMGCL	Anti-HMGCL2	IHC,WB
HPA008338	HMGCR	Anti-HMGCR46	IHC
HPA021467	HSD17B14	Anti-HSD17B14	IHC,WB,ICC-IF
HPA000764	KLK3/PSA	Anti-KLK347,48	IHC
HPA019693	LSP1	Anti-LSP1	IHC,WB,ICC-IF
HPA001939	MMP2	Anti-MMP2	IHC
HPA004179	MUC1/CA15-3	Anti-MUC1	IHC,WB
HPA007235	MUC1/CA15-3	Anti-MUC1	IHC
HPA008855	MUC1/CA15-3	Anti-MUC1	IHC,ICC-IF
HPA001429	NBN	Anti-NBN	IHC,WB,ICC-IF
HPA030278	NRP1	Anti-NRP1	IHC
HPA029814	Oncostatin M	Anti-OSM49	IHC,WB
AMAb90956	P53	Anti-P53	IHC,WB
HPA021241	PHGDH	Anti-PHGDH50-52	IHC,WB*,ICC-IF
HPA031314	PGD	Anti-PGD	IHC,WB*
HPA006563	PKC alpha/PKCA	Anti-PKCA	IHC,WB*,ICC-IF
HPA006564	PKC alpha/PKCA	Anti-PKCA	IHC,WB*,ICC-IF
HPA003412	PLAT	Anti-PLAT	IHC,WB,ICC-IF
HPA006366	POLRMT	Anti-POLRMT53	IHC
HPA020376	PSPH	Anti-PSPH50	IHC,WB
HPA047183	PTMA	Anti-PTMA	IHC,ICC-IF
HPA008890	PTTG1	Anti-PTTG1	IHC,ICC-IF
HPA037503	RAP80/UIMC1	Anti-UIMC1	IHC,WB
HPA037504	RAP80/UIMC1	Anti-UIMC1	IHC,WB,ICC-IF
HPA006079	REST	Anti-REST54,55	IHC,ICC-IF
HPA003624	RBM3	Anti-RBM356,57	IHC,WB*,ICC-IF
AMAb90655	RBM3	Anti-RBM358-65	IHC,WB
HPA009026	RRBP1	Anti-RRBP166	IHC,ICC-IF, WB
HPA035857	rs4973768/SLC4A7	Anti-SLC4A7	IHC
HPA001893	SIX1	Anti-SIX167-74	IHC,WB,ICC-IF
AMAb90544	SIX1	Anti-SIX1	IHC,WB
HPA014404	SNCG	Anti-SNCG	IHC,WB
HPA017254	STK11	Anti-STK11	IHC,WB,ICC-IF
HPA002830	SURVIvin/BIRC5	Anti-BIRC5	IHC,WB,ICC-IF
HPA000500	T-STAR/KHDRBS3	Anti-KHDRBS375,76	IHC,WB
HPA004823	Tenascin C/TNC	Anti-TNC77-79	IHC,WB
HPA003425	TFF1	Anti-TFF180-82	IHC,WB
HPA002982	THBD	Anti-THBD	IHC,WB
HPA019881	THEM2/ACOT13	Anti-ACOT13	IHC,WB*,ICC-IF
HPA006458	TOP2A	Anti-TOP2A	IHC,WB,ICC-IF
HPA026773	TOP2A	Anti-TOP2A	IHC,ICC-IF
HPA014405	UGT8	Anti-UGT883	IHC,ICC-IF
HPA007547	ULBP1	Anti-ULBP184	IHC
HPA023930	ZNF703	Anti-ZNF70332	IHC,ICC-IF

* WB both in human and rodent samples

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24. Nodin B, Fridberg M, Uhlén M, Jirström K. 2012. Discovery of dachshund 2 protein as a novel biomarker of poor prognosis in epithelial ovarian cancer. Journal of Ovarian Research. 5(1):6. https://doi.org/10.1186/1757-2215-5-6

25. Sircoulomb F, Nicolas N, Ferrari A, Finetti P, Bekhouche I, Rousselet E, Lonigro A, Adélaïde J, Baudelet E, Esteyriès S, et al. 2011. ZNF703 gene amplification at 8p12 specifies luminal B breast cancer. EMBO Mol Med. 3(3):153-166. https://doi.org/10.1002/emmm.201100121

26. Cawthorn TR, Moreno JC, Dharsee M, Tran-Thanh D, Ackloo S, Zhu PH, Sardana G, Chen J, Kupchak P, Jacks LM, et al. Proteomic Analyses Reveal High Expression of Decorin and Endoplasmin (HSP90B1) Are Associated with Breast Cancer Metastasis and Decreased Survival. PLoS ONE. 7(2):e30992. https://doi.org/10.1371/journal.pone.0030992

27. Henke A, Grace OC, Ashley GR, Stewart GD, Riddick ACP, Yeun H, O?Donnell M, Anderson RA, Thomson AA. Stromal Expression of Decorin, Semaphorin6D, SPARC, Sprouty1 and Tsukushi in Developing Prostate and Decreased Levels of Decorin in Prostate Cancer. PLoS ONE. 7(8):e42516. https://doi.org/10.1371/journal.pone.0042516

28. Hudson EP, Uhlen M, Rockberg J. 2012. Multiplex epitope mapping using bacterial surface display reveals both linear and conformational epitopes. Sci Rep. 2(1): https://doi.org/10.1038/srep00706

29. Arabi A, Ullah K, Branca RM, Johansson J, Bandarra D, Haneklaus M, Fu J, Ariës I, Nilsson P, Den Boer ML, et al. 2012. Proteomic screen reveals Fbw7 as a modulator of the NF-?B pathway. Nat Commun. 3(1): https://doi.org/10.1038/ncomms1975

30. Ito A, Mimae T, Yamamoto Y, Hagiyama M, Nakanishi J, Ito M, Hosokawa Y, Okada M, Murakami Y, Kondo T. 2012. Novel application for pseudopodia proteomics using excimer laser ablation and two-dimensional difference gel electrophoresis. Lab Invest. 92(9):1374-1385. https://doi.org/10.1038/labinvest.2012.98

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32. Mulder J, Björling E, Jonasson K, Wernérus H, Hober S, Hökfelt T, Uhlén M. 2009. Tissue Profiling of the Mammalian Central Nervous System Using Human Antibody-based Proteomics. Mol Cell Proteomics. 8(7):1612-1622. https://doi.org/10.1074/mcp.m800539-mcp200

33. Su D, Fu X, Fan S, Wu X, Wang X, Fu L, Dong X, Ni JJ, Fu L, Zhu Z, et al. 2012. Role of ERRF, a Novel ER-Related Nuclear Factor, in the Growth Control of ER-Positive Human Breast Cancer Cells. The American Journal of Pathology. 180(3):1189-1201. https://doi.org/10.1016/j.ajpath.2011.11.025

34. Shubbar E, Helou K, Kovács A, Nemes S, Hajizadeh S, Enerbäck C, Einbeigi Z. 2013. High levels of ?-glutamyl hydrolase (GGH) are associated with poor prognosis and unfavorable clinical outcomes in invasive breast cancer. BMC Cancer. 13(1): https://doi.org/10.1186/1471-2407-13-47

35. Liao YC, Ruan JW, Lua I, Li MH, Chen WL, Wang JRY, Kao RH, Chen JH. 2012. Overexpressed hPTTG1 promotes breast cancer cell invasion and metastasis by regulating GEF-H1/RhoA signalling. Oncogene. 31(25):3086-3097. https://doi.org/10.1038/onc.2011.476

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37. Zibert JR, Wallbrecht K, Schön M, Mir LM, Jacobsen GK, Trochon-Joseph V, Bouquet C, Villadsen LS, Cadossi R, Skov L, et al. 2011. Halting angiogenesis by non-viral somatic gene therapy alleviates psoriasis and murine psoriasiform skin lesions. J. Clin. Invest.. 121(1):410-421. https://doi.org/10.1172/jci41295

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51. Salem AF, Whitaker-Menezes D, Howell A, Sotgia F, Lisanti MP. 2012. Mitochondrial biogenesis in epithelial cancer cells promotes breast cancer tumor growth and confers autophagy resistance. Cell Cycle. 11(22):4174-4180. https://doi.org/10.4161/cc.22376

52. Wagoner MP, Gunsalus KTW, Schoenike B, Richardson AL, Friedl A, Roopra A. The Transcription Factor REST Is Lost in Aggressive Breast Cancer. PLoS Genet. 6(6):e1000979. https://doi.org/10.1371/journal.pgen.1000979

53. Prada I, Marchaland J, Podini P, Magrassi L, D'Alessandro R, Bezzi P, Meldolesi J. 2011. REST/NRSF governs the expression of dense-core vesicle gliosecretion in astrocytes. 193(3):537-549. https://doi.org/10.1083/jcb.201010126

54. Jögi A, Brennan DJ, Rydén L, Magnusson K, Fernö M, Stål O, Borgquist S, Uhlen M, Landberg G, Påhlman S, et al. 2009. Nuclear expression of the RNA-binding protein RBM3 is associated with an improved clinical outcome in breast cancer. Mod Pathol. 22(12):1564-1574. https://doi.org/10.1038/modpathol.2009.124

55. Hjelm B, Brennan DJ, Zendehrokh N, Eberhard J, Nodin B, Gaber A, Pontén F, Johannesson H, Smaragdi K, Frantz C, et al. 2011. High nuclear RBM3 expression is associated with an improved prognosis in colorectal cancer. Prot. Clin. Appl.. 5(11-12):624-635. https://doi.org/10.1002/prca.201100020

56. Ehlén Å, Brennan DJ, Nodin B, O'Connor DP, Eberhard J, Alvarado-Kristensson M, Jeffrey IB, Manjer J, Brändstedt J, Uhlén M, et al. 2010. Expression of the RNA-binding protein RBM3 is associated with a favourable prognosis and cisplatin sensitivity in epithelial ovarian cancer. Journal of Translational Medicine. 8(1):78. https://doi.org/10.1186/1479-5876-8-78

57. Jonsson L, Gaber A, Ulmert D, Uhlén M, Bjartell A, Jirström K. 2011. High RBM3 expression in prostate cancer independently predicts a reduced risk of biochemical recurrence and disease progression. Diagn Pathol. 6(1): https://doi.org/10.1186/1746-1596-6-91

58. Nodin B, Fridberg M, Jonsson L, Bergman J, Uhlén M, Jirström K. 2012. High MCM3 expression is an independent biomarker of poor prognosis and correlates with reduced RBM3 expression in a prospective cohort of malignant melanoma. Diagnostic Pathology. 7(1):82. https://doi.org/10.1186/1746-1596-7-82

59. Jonsson L, Bergman J, Nodin B, Manjer J, Pontén F, Uhlén M, Jirström K. 2011. Low RBM3 protein expression correlates with tumour progression and poor prognosis in malignant melanoma: An analysis of 215 cases from the Malmö Diet and Cancer Study. Journal of Translational Medicine. 9(1):114. https://doi.org/10.1186/1479-5876-9-114

60. Ehlén Õ, Nodin B, Rexhepaj E, Brändstedt J, Uhlén M, Alvarado-Kristensson M, Pontén F, Brennan DJ, Jirström K. 2011. RBM3-Regulated Genes Promote DNA Integrity and Affect Clinical Outcome in Epithelial Ovarian Cancer. Translational Oncology. 4(4):212-IN1. https://doi.org/10.1593/tlo.11106

61. Hjelm B, Brennan DJ, Zendehrokh N, Eberhard J, Nodin B, Gaber A, Pontén F, Johannesson H, Smaragdi K, Frantz C, et al. 2011. High nuclear RBM3 expression is associated with an improved prognosis in colorectal cancer. Prot. Clin. Appl.. 5(11-12):624-635. https://doi.org/10.1002/prca.201100020

62. Boman K, Segersten U, Ahlgren G, Eberhard J, Uhlén M, Jirström K, Malmström P. 2013. Decreased expression of RNA-binding motif protein 3 correlates with tumour progression and poor prognosis in urothelial bladder cancer. BMC Urol. 13(1): https://doi.org/10.1186/1471-2490-13-17

63. Nodin B, Fridberg M, Jonsson L, Bergman J, Uhlén M, Jirström K. 2012. High MCM3 expression is an independent biomarker of poor prognosis and correlates with reduced RBM3 expression in a prospective cohort of malignant melanoma. Diagnostic Pathology. 7(1):82. https://doi.org/10.1186/1746-1596-7-82

64. Telikicherla D, Marimuthu A, Kashyap M, Ramachandra YL, Mohan S, Roa J, Maharudraiah J, Pandey A. 2012. Overexpression of ribosome binding protein 1 (RRBP1) in breast cancer. Clin Proteomics. 9(1):7. https://doi.org/10.1186/1559-0275-9-7

65. Iwanaga R, Wang C, Micalizzi DS, Harrell JC, Jedlicka P, Sartorius CA, Kabos P, Farabaugh SM, Bradford AP, Ford HL. 2012. Expression of Six1 in luminal breast cancers predicts poor prognosis and promotes increases in tumor initiating cells by activation of extracellular signal-regulated kinase and transforming growth factor-beta signaling pathways. Breast Cancer Res. 14(4): https://doi.org/10.1186/bcr3219

66. Smith AL, Iwanaga R, Drasin DJ, Micalizzi DS, Vartuli RL, Tan A, Ford HL. 2012. The miR-106b-25 cluster targets Smad7, activates TGF-? signaling, and induces EMT and tumor initiating cell characteristics downstream of Six1 in human breast cancer. Oncogene. 31(50):5162-5171. https://doi.org/10.1038/onc.2012.11

67. Wan F, Miao X, Quraishi I, Kennedy V, Creek KE, Pirisi L. 2008. Gene expression changes during HPV-mediated carcinogenesis: A comparison between anin vitrocell model and cervical cancer. Int. J. Cancer. 123(1):32-40. https://doi.org/10.1002/ijc.23463

68. McCoy EL, Iwanaga R, Jedlicka P, Abbey N, Chodosh LA, Heichman KA, Welm AL, Ford HL. 2009. Six1 expands the mouse mammary epithelial stem/progenitor cell pool and induces mammary tumors that undergo epithelial-mesenchymal transition. J. Clin. Invest.. 119(9):2663-2677. https://doi.org/10.1172/jci37691

69. Micalizzi DS, Christensen KL, Jedlicka P, Coletta RD, Barón AE, Harrell JC, Horwitz KB, Billheimer D, Heichman KA, Welm AL, et al. 2009. The Six1 homeoprotein induces human mammary carcinoma cells to undergo epithelial-mesenchymal transition and metastasis in mice through increasing TGF-? signaling. J. Clin. Invest.. 119(9):2678-2690. https://doi.org/10.1172/jci37815

70. Farabaugh SM, Micalizzi DS, Jedlicka P, Zhao R, Ford HL. 2012. Eya2 is required to mediate the pro-metastatic functions of Six1 via the induction of TGF-? signaling, epithelial?mesenchymal transition, and cancer stem cell properties. Oncogene. 31(5):552-562. https://doi.org/10.1038/onc.2011.259

71. Ono H, Imoto I, Kozaki K, Tsuda H, Matsui T, Kurasawa Y, Muramatsu T, Sugihara K, Inazawa J. 2012. SIX1 promotes epithelial?mesenchymal transition in colorectal cancer through ZEB1 activation. Oncogene. 31(47):4923-4934. https://doi.org/10.1038/onc.2011.646

72. Le Grand F, Grifone R, Mourikis P, Houbron C, Gigaud C, Pujol J, Maillet M, Pagès G, Rudnicki M, Tajbakhsh S, et al. 2012. Six1 regulates stem cell repair potential and self-renewal during skeletal muscle regeneration. 198(5):815-832. https://doi.org/10.1083/jcb.201201050

73. Sernbo S, Borrebaeck CAK, Uhlén M, Jirström K, Ek S. Nuclear T-STAR Protein Expression Correlates with HER2 Status, Hormone Receptor Negativity and Prolonged Recurrence Free Survival in Primary Breast Cancer and Decreased Cancer Cell Growth In Vitro. PLoS ONE. 8(7):e70596. https://doi.org/10.1371/journal.pone.0070596

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75. Schenke-Layland K, Stock UA, Nsair A, Xie J, Angelis E, Fonseca CG, Larbig R, Mahajan A, Shivkumar K, Fishbein MC, et al. 2009. Cardiomyopathy is associated with structural remodelling of heart valve extracellular matrix. 30(18):2254-2265. https://doi.org/10.1093/eurheartj/ehp267

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Antibodies Against Gene Products in MammaPrint, Oncotype, EndoPredict and uPA Tests

This section presents antibodies in Prestige Antibody product catalog against gene products included in the diagnostic MammaPrint, EndoPredict, Oncotype and uPA tests. MammaPrint is a gene expression profile test based on the Amsterdam 70-gene breast cancer gene signature marketed by Agendia. It is a test to assess the risk that a breast tumor will metastasize to other parts of the body. MammaPrint aims at stratifying patients into “Low Risk” and “High Risk”. Oncotype DX (developed by Genomic Health) is the most frequently used gene expression profile in clinical practice in the United States analyzing a panel of 21 genes within a tumor to determine a Recurrence Score.

BIRC5/Survivin

The Anti-BIRC5 antibody (HPA002830) shows nuclear positivity in germinal center cells in human tonsil tissue and in tumor cells in colorectal cancer using IHC.

CD68/Macrosialin

IHC staining of human lung tissue using the Anti-CD68 antibody (HPA048982) shows strong cytoplasmic positivity in macrophages and in hematopoietic tissues, such as spleen.

DTL

IHC staining of human bone marrow using the Anti-DTL antibody (HPA028016) shows strong nuclear positivity in bone marrow poietic cells. By ICC-IF, staining of nucleus in U-251 MG cells is detected.

GSTM5

The Anti-GSTM5 antibody (HPA048652) shows cytoplasmic positivity in glandular cells in human rectum by IHC and in WB, the antibody detects a band of predicted size in cell lysates of RT-4, U-251 MG, as well as in liver tissue lysate.

Product No.	Target Protein	Product Description	Validated Applications
HPA002636	AURKA/STK15	Anti-AURKA	IHC,WB
HPA012582	AZGP1	Anti-AZGP1	IHC,WB
HPA018121	BAG1	Anti-BAG1	IHC,ICC-IF
HPA002830	BIRC5/Survivin	Anti-BIRC5	IHC,WB,ICC-IF
HPA048982	CD68/Macrosialin	Anti-CD68	IHC
HPA005565	CDCA7	Anti-CDCA71,2	IHC,WB,ICC-IF
HPA006871	CMC2/C16orf61	Anti-CMC2	IHC
HPA044280	DHCR7	Anti-DHCR7	IHC,WB
HPA018670	DHX58/LGP2	Anti-DHX58	IHC,WB,ICC-IF
HPA019570	DHX58/LGP2	Anti-DHX58	IHC
HPA032152	DIAPH3	Anti-DIAPH3	IHC,WB*
HPA028016	DTL	Anti-DTL3	IHC,WB,ICC-IF
HPA022130	ECI2/PECI	Anti-ECI2	IHC,WB,ICC-IF
HPA022129	EGLN1/PHD2	Anti-EGLN14	IHC,ICC-IF
HPA036660	ESM1	Anti-ESM1	IHC,WB
HPA000449	Estrogen receptor	Anti-ESR1	IHC,WB
HPA000450	Estrogen receptor	Anti-ESR1	IHC,WB
HPA044394	Exostosin-1	Anti-EXT1	IHC,WB
HPA018795	FGF18	Anti-FGF18	IHC,WB,ICC-IF
HPA050682	GMPS	Anti-GMPS	IHC
HPA003011	GNAZ	Anti-GNAZ	IHC,WB
HPA017346	GPR126/VIGR	Anti-GPR126	IHC
HPA047250	GPR180	Anti-GPR180	IHC,ICC-IF
HPA035190	GSTM3	Anti-GSTM3	IHC,WB
HPA048652	GSTM5/GSTM1	Anti-GSTM5	IHC,WB
HPA001383	HER2/ERBB2	Anti-ERBB2	IHC,WB
AMAb90627	HER2/ERBB2	Anti-HER2	IHC,WB
HPA051179	HRASLS	Anti-HRASLS	IHC
HPA010558	IL6ST/GP130	Anti-IL6ST5	IHC
HPA012114	JHDM1D/KDM7A	Anti-JHDM1D	IHC,ICC-IF

* WB both in human and rodent samples

1. Gill RM, Gabor TV, Couzens AL, Scheid MP. 2013. The MYC-Associated Protein CDCA7 Is Phosphorylated by AKT To Regulate MYC-Dependent Apoptosis and Transformation. Mol. Cell. Biol.. 33(3):498-513. https://doi.org/10.1128/mcb.00276-12

2. Shubbar E, Kovács A, Hajizadeh S, Parris TZ, Nemes S, Gunnarsdóttir K, Einbeigi Z, Karlsson P, Helou K. 2013. Elevated cyclin B2 expression in invasive breast carcinoma is associated with unfavorable clinical outcome. BMC Cancer. 13(1): https://doi.org/10.1186/1471-2407-13-1

3. Karaayvaz M, Pal T, Song B, Zhang C, Georgakopoulos P, Mehmood S, Burke S, Shroyer K, Ju J. 2011. Prognostic Significance of miR-215 in Colon Cancer. Clinical Colorectal Cancer. 10(4):340-347. https://doi.org/10.1016/j.clcc.2011.06.002

4. Bozóky B, Savchenko A, Csermely P, Korcsmáros T, Dúl Z, Pontén F, Székely L, Klein G. 2013. Novel signatures of cancer-associated fibroblasts. Int. J. Cancer. 133(2):286-293. https://doi.org/10.1002/ijc.28035

5. Rognum IJ, Haynes RL, Vege ?, Yang M, Rognum TO, Kinney HC. 2009. Interleukin-6 and the serotonergic system of the medulla oblongata in the sudden infant death syndrome. Acta Neuropathol. 118(4):519-530. https://doi.org/10.1007/s00401-009-0535-y

MMP9

IHC staining of human lung tissue using the Anti-MMP9 antibody (HPA001238) shows strong nuclear positivity in macrophages and in bone marrow poietic cells in bone marrow tissue.

Monclonal Anti-MMP9 antibodies show strong cytoplasmic positivity in a subset of lymphoid cells in duodenum (AMAb90805) and in human tonsil tissue (AMAb90804).

LYRIC/MTDH

IHC staining using the Anti-MTDH antibody (HPA010932) shows strong cytoplasmic positivity in neuronal cells in human cerebral cortex tissue. In ICC-IF in A-431 cell line, the antibody stains endoplasmic reticulum.

IHC staining using the monclonal Anti-MTDH antibody (AMAb90762) shows strong cytoplasmic reactivity in tumor cells from breast and colorectal cancer samples.

P5C Dehydrogenase/ALDH4A1

IHC staining using the Anti- ALDH4A1 antibody (HPA006401) shows strong cytoplasmic positivity with granular pattern in human kidney and liver tissues.

Product No.	Target Protein	Product Description	Validated Applications
HPA000451	Ki67/MKI67	Anti-MKI671	IHC,ICC-IF
HPA001164	KI67/MKI67	Anti-MKI672	IHC,ICC-IF
AMAb90870	KI67/MKI67	Anti-MKI67	IHC
HPA030241	LIN9	Anti-LIN9	IHC,ICC-IF
HPA012501	LPCAT/AYTL2	Anti-LPCAT1	IHC,WB
HPA022268	LPCAT/AYTL2	Anti-LPCAT13	IHC,WB,ICC-IF
HPA015104	LYRIC	Anti-MTDH4	IHC,WB,ICC-IF
HPA010932	LYRIC	Anti-MTDH5	IHC,WB*,ICC-IF
AMAb90762	LYRIC	Anti-MTDH	IHC,WB
AMAb90763	LYRIC	Anti-MTDH	IHC,WB
HPA013949	Matrix Gla protein	Anti-MGP6	IHC
HPA004818	MCM6	Anti-MCM6	IHC,WB*,ICC-IF
HPA017214	MELK/PK38	Anti-MELK	IHC,ICC-IF
HPA001238	MMP9	Anti-MMP9	IHC,WB,ICC-IF
AMAb90804	MMP9	Anti-MMP9	IHC,WB
AMAb90805	MMP9	Anti-MMP9	IHC,WB
AMAb90806	MMP9	Anti-MMP9	IHC
HPA017418	MS4A7	Anti-MS4A7	IHC,WB
HPA030530	MYBL2	Anti-MYBL2	IHC,WB
HPA025926	Neuromedin-U	Anti-NMU	IHC,WB
HPA042904	NUSAP1	Anti-NUSAP1	IHC,ICC-IF
HPA006401	P5C dehydrogenase	Anti-ALDH4A1	IHC,WB

* WB both in human and rodent samples

1. Pohler E, Mamai O, Hirst J, Zamiri M, Horn H, Nomura T, Irvine AD, Moran B, Wilson NJ, Smith FJD, et al. 2012. Haploinsufficiency for AAGAB causes clinically heterogeneous forms of punctate palmoplantar keratoderma. Nat Genet. 44(11):1272-1276. https://doi.org/10.1038/ng.2444

2. Roca H, Craig MJ, Ying C, Varsos ZS, Czarnieski P, Alva AS, Hernandez J, Fuller D, Daignault S, Healy PN, et al. 2011. IL-4 induces proliferation in prostate cancer PC3?cells under nutrient-depletion stress through the activation of the JNK-pathway and survivin upregulation. J. Cell. Biochem..n/a-n/a. https://doi.org/10.1002/jcb.24025

3. Friedman JS, Chang B, Krauth DS, Lopez I, Waseem NH, Hurd RE, Feathers KL, Branham KE, Shaw M, Thomas GE, et al. 2010. Loss of lysophosphatidylcholine acyltransferase 1 leads to photoreceptor degeneration in rd11 mice. Proceedings of the National Academy of Sciences. 107(35):15523-15528. https://doi.org/10.1073/pnas.1002897107

4. Nohata N, Hanazawa T, Kikkawa N, Mutallip M, Sakurai D, Fujimura L, Kawakami K, Chiyomaru T, Yoshino H, Enokida H, et al. 2011. Tumor suppressive microRNA-375 regulates oncogene AEG-1/MTDH in head and neck squamous cell carcinoma (HNSCC). J Hum Genet. 56(8):595-601. https://doi.org/10.1038/jhg.2011.66

5. LIU B, WU Y, PENG D. 2013. Astrocyte elevated gene-1 regulates osteosarcoma cell invasion and chemoresistance via endothelin-1/endothelin A receptor signaling. 5(2):505-510. https://doi.org/10.3892/ol.2012.1056

6. Lorenzen JM, Martino F, Scheffner I, Bröcker V, Leitolf H, Haller H, Gwinner W. Fetuin, Matrix-Gla Protein and Osteopontin in Calcification of Renal Allografts. PLoS ONE. 7(12):e52039. https://doi.org/10.1371/journal.pone.0052039

PITRM1/MP1

The Anti- PITRM1 antibody (HPA006753) shows strong cytoplasmic positivity in myocytes in human heart muscle using IHC. ICC-IF staining of human cell line U-251 MG shows positivity in mitochondria.

PRC1

IHC staining of human testis tissue using the Anti-PRC1 antibody (HPA034521) shows strong nuclear positivity in cells of seminiferus ducts. ICC-IF shows staining of nucleus, plasma membrane and microtubules in A-431 cells.

SCOT/OXCT1

IHC staining of human heart muscle and kidney by Anti-OXCT1 antibody (HPA012047) shows strong cytoplasmic positivity in myocytes and cells in tubules, respectively. ICC-IF shows staining of mitochondria in A431 cells.

Product No.	Target Protein	Product Description	Validated Applications
HPA006753	PITRM1/MP1	Anti-PITRM1	IHC,WB,ICC-IF
HPA006754	PITRM1/MP1	Anti-PITRM1	IHC,WB*,ICC-IF
HPA008719	PLAU/UPA	Anti-PLAU	IHC,WB
HPA034521	PRC1	Anti-PRC1	IHC,ICC-IF
HPA004751	Progesteron receptor	Anti-PGR1	IHC,ICC-IF
HPA008428	Progesteron receptor	Anti-PGR	IHC
HPA017176	Progesteron receptor	Anti-PGR	IHC
HPA012716	QSOX2/QSCN6L1	Anti-QSOX2	IHC,WB,ICC-IF
HPA039890	RBBP8	Anti-RBBP8	IHC, WB
HPA029970	RECQL5	Anti-RECQL5	IHC,ICC-IF
HPA029971	RECQL5	Anti-RECQL5	IHC,WB,ICC-IF
HPA044428	RTN4RL1/NgR3	Anti-RTN4RL1	IHC
HPA023726	RUNDC1	Anti-RUNDC1	IHC,WB,ICC-IF
HPA006353	SCUBE2/CEGP1	Anti-SCUBE2	IHC,ICC-IF
HPA029871	SCUBE2/CEGP1	Anti-SCUBE2	IHC
HPA012047	SCOT/OXCT1	Anti-OXCT12	IHC,WB*,ICC-IF
HPA050039	SERPINE1/PAI1	Anti-SERPINE1	IHC
HPA006539	SLC2A3/GLUT3	Anti-SLC2A3	IHC
HPA045372	Stanniocalcin-2	Anti-STC2	IHC, WB, IF
HPA015820	STK32B	Anti-STK32B	IHC,ICC-IF
HPA027923	TGFB3	Anti-TGFB3	IHC,WB
HPA045213	TMEM74B/C20orf46	Anti-TMEM74B	IHC
HPA031347	TSPYL5	Anti-TSPYL5	IHC
HPA005908	UCHL5	Anti-UCHL5	IHC,ICC-IF
HPA014290	VEGFR-1	Anti-FLT1	IHC,ICC-IF
AMAb90703	VEGFR-1	Anti-FLT1	IHC
AMAb90704	VEGFR-1	Anti-FLT1	IHC,WB
HPA007121	WISP1	Anti-WISP1	IHC,ICC-IF

* WB both in human and rodent samples

1. Pereira CBL, Leal MF, de Souza CRT, Montenegro RC, Rey JA, Carvalho AA, Assumpção PP, Khayat AS, Pinto GR, Demachki S, et al. Prognostic and Predictive Significance of MYC and KRAS Alterations in Breast Cancer from Women Treated with Neoadjuvant Chemotherapy. PLoS ONE. 8(3):e60576. https://doi.org/10.1371/journal.pone.0060576

2. Chang HT, Olson L, Schwartz KA. 2013. Ketolytic and glycolytic enzymatic expression profiles in malignant gliomas: implication for ketogenic diet therapy. Nutrition & Metabolism. 10(1):47. https://doi.org/10.1186/1743-7075-10-47

3. Zibert JR, Wallbrecht K, Schön M, Mir LM, Jacobsen GK, Trochon-Joseph V, Bouquet C, Villadsen LS, Cadossi R, Skov L, et al. 2011. Halting angiogenesis by non-viral somatic gene therapy alleviates psoriasis and murine psoriasiform skin lesions. J. Clin. Invest.. 121(1):410-421. https://doi.org/10.1172/jci41295

Antibodies Identified in the Human Protein Atlas

Showing Differential IHC Staining Patterns in Breast Cancer Samples

IHC analysis using Anti-KLHL26 antibody (HPA023074) shows a varying membranous/cytoplasmic staining pattern in breast tumor samples from different patients.

The Anti-ACSF2 (HPA024693) antibody shows granular cytoplasmic positivity in breast tumor cells from different patients varying from strong to negative.

The Anti-GCM1 (HPA011343) antibody shows membranous positivity in breast tumor cells while normal breast tissue is negative.

The Anti-AGR3 (HPA053942) antibody shows strong cytoplasmic positivity in 11/12 breast cancer patients, while 1 patient is completely negative.

Product No.	Product Description	Validated Applications
HPA037918	Anti-AAMDC	IHC,WB
HPA037919	Anti-AAMDC	IHC
HPA040312	Anti-ABCG4	IHC,ICC-IF
HPA007695	Anti-NIM1	IHC,WB,ICC-IF
HPA023993	Anti-AC145676.2	IHC,WB
HPA024693	Anti-ACSF2	IHC,WB
HPA042014	Anti-ADAMTS13	IHC,WB
HPA053942	Anti-AGR3	IHC
HPA020522	Anti-AIF1L	IHC,WB
HPA006171	Anti-AJUBA	IHC, WB
HPA046271	Anti-ALDH1A3	IHC,WB
HPA013758	Anti-ANKRD46	IHC,WB
HPA004341	Anti-ASB6	IHC,WB,ICC-IF
HPA005935	Anti-ATF6	IHC
HPA008147	Anti-ATP6V1B2	IHC,WB*,ICC-IF
HPA046678	Anti-AVPR2	IHC
HPA020274	Anti-BCL9	IHC
HPA038478	Anti-BTG4	IHC
HPA026810	Anti-ADIRF	IHC,WB
HPA007968	Anti-C10orf54	IHC,WB,ICC-IF
HPA039713	Anti-C12orf76	IHC,WB
HPA008959	Anti-C17orf85	IHC
HPA045811	Anti-C1ORF195	IHC,ICC-IF
HPA051143	Anti-C2orf68	IHC
HPA037889	Anti-SIMC1	IHC,WB
HPA021480	Anti-CAPN8	IHC,WB
HPA023457	Anti-CCDC144NL	IHC,WB
HPA027185	Anti-CCDC170	IHC,WB
HPA027121	Anti-CCDC170	IHC,WB
HPA002637	Anti-CDK6	IHC,WB*,ICC-IF
HPA014361	Anti-CLDN3	IHC
HPA041132	Anti-CPNE2	IHC,WB
HPA004135	Anti-CRABP2	IHC,WB,ICC-IF
HPA015077	Anti-CTNND2	IHC
HPA006128	Anti-CXorf67	IHC,WB
HPA017661	Anti-CYP4X1	IHC
HPA012672	Anti-DACH1	IHC,ICC-IF
HPA051589	Anti-DBF4	IHC
HPA050246	Anti-DCHS1	IHC
HPA015655	Anti-DCLK1	IHC
HPA047631	Anti-DECR2	IHC
HPA046708	Anti-DOM3Z	IHC
HPA018221	Anti-DUSP26	IHC,WB
HPA006465	Anti-ECD	IHC,WB,ICC-IF
HPA049331	Anti-EFHD1	IHC,WB,ICC-IF
HPA007397	Anti-EPHA6	IHC
HPA030879	Anti-FAM101B	IHC
HPA009410	Anti-FAM189A1	IHC
HPA008707	Anti-FKBP7	IHC,WB*,ICC-IF
HPA004937	Anti-FMN2	IHC
HPA052324	Anti-G6PC	IHC
HPA044371	Anti-GABRD	IHC,WB
HPA027463	Anti-GAK	IHC,ICC-IF
HPA011343	Anti-GCM1	IHC
HPA039916	Anti-GLB1L3	IHC
HPA002318	Anti-GLDC	IHC,WB*
HPA039501	Anti-GLYATL1	IHC,WB
HPA007990	Anti-GTF3A	IHC,ICC-IF
HPA007611	Anti-HIPK2	IHC,ICC-IF
HPA036913	Anti-HMGCS1	IHC,WB,ICC-IF
HPA027423	Anti-HMGCS2	IHC,WB
HPA027442	Anti-HMGCS2	IHC,WB
HPA004337	Anti-IFITM3	IHC,WB
HPA054669	Anti-IRX2	IHC,WB
HPA007931	Anti-ISYNA1	IHC
HPA008232	Anti-ISYNA1	IHC,WB
HPA008572	Anti-ITGA3	IHC
HPA005676	Anti-ITGBL1	IHC,WB
HPA000506	Anti-ITIH6	IHC
HPA051637	Anti-KLHL2	IHC
HPA023074	Anti-KLHL26	IHC,WB
HPA049550	Anti-KRT31	IHC
HPA040330	Anti-KRT32	IHC
HPA042482	Anti-KRTAP9-3	IHC
HPA012072	Anti-LASP11	IHC,WB*,ICC-IF
HPA008556	Anti-LGR6	IHC
HPA036706	Anti-LRRIQ4	IHC
HPA002820	Anti-MAGEB1	IHC
HPA039454	Anti-MANSC4	IHC,WB
HPA059457	Anti-MROH2B	IHC
HPA017642	Anti-MRS2	IHC,WB
HPA005914	Anti-MSTO1	IHC
HPA049831	Anti-MTMR2	IHC
HPA005466	Anti-MYBBP1A	IHC,WB,ICC-IF
HPA024338	Anti-NAPEPLD	IHC,WB,ICC-IF
HPA028136	Anti-NASP	IHC,WB,ICC-IF
HPA006111	Anti-NFIA	IHC,WB*,ICC-IF
HPA006873	Anti-NKAIN1	IHC
HPA007489	Anti-NPSR12	IHC,ICC-IF
HPA048760	Anti-OR2Z1	IHC
HPA015808	Anti-OR9K2	IHC
HPA024524	Anti-OTOP2	IHC
HPA048975	Anti-PDE4C	IHC,WB
HPA051038	Anti-PEG10	IHC,ICC-IF
HPA003994	Anti-PHLDA2	IHC
HPA020200	Anti-PHLPP1	IHC
HPA012312	Anti-PHTF2	IHC
HPA045390	Anti-PKN3	IHC
HPA044690	Anti-PNMA5	IHC,ICC-IF
HPA051607	Anti-PPP1R35	IHC
HPA023923	Anti-PPR11	IHC,WB,ICC-IF
HPA048536	Anti-PVALB	IHC
HPA019717	Anti-RAB313	IHC,WB*
HPA047820	Anti-RAC3	IHC,WB
HPA008752	Anti-RAD18	IHC,WB
HPA058061	Anti-REEP1	IHC
HPA005681	Anti-RIOK2	IHC,ICC-IF
HPA015733	Anti-RNF152	IHC,WB
HPA005985	Anti-RPS13	IHC
HPA006462	Anti-S100A1	IHC,WB,ICC-IF
HPA019592	Anti-S100A13	IHC,WB*
HPA027613	Anti-S100A14	IHC,ICC-IF
HPA006997	Anti-S100A7	IHC,ICC-IF
HPA013321	Anti-SGK196	IHC,WB,ICC-IF
HPA051248	Anti-SH3BGRL	IHC,WB
HPA037690	Anti-SHROOM1	IHC
HPA005911	Anti-SLC16A7	IHC,WB
HPA042377	Anti-SLC39A6	IHC,WB
HPA023748	Anti-SPAG1	IHC,ICC-IF
HPA018038	Anti-SQLE	IHC,WB
HPA011173	Anti-SRPRB	IHC,WB
HPA039789	Anti-SSSCA1	IHC,WB*,ICC-IF
HPA049106	Anti-STAG3	IHC,WB,ICC-IF
HPA042583	Anti-STARD6	IHC,IF
HPA001467	Anti-STX74	IHC,WB*,ICC-IF
HPA005781	Anti-TACC3	IHC,WB
HPA007066	Anti-TAPBP	IHC
HPA000262	Anti-TBC1D9	IHC,ICC-IF
HPA046156	Anti-TCTE3	IHC
HPA017019	Anti-TGFBI	IHC
HPA051855	Anti-TMEM110-MUSTN1	IHC
HPA016579	Anti-TMEM222	IHC,ICC-IF
HPA046658	Anti-TMEM47	IHC
HPA018216	Anti-TMEM68	IHC,ICC-IF
HPA005487	Anti-TPX2	IHC,WB,ICC-IF
HPA003054	Anti-TTLL12	IHC,WB
HPA023605	Anti-UBE20	IHC,WB*
HPA042302	Anti-WFDC2	IHC
HPA050514	Anti-WNT3A	IHC
HPA006811	Anti-ZBTB7B	IHC,WB*,ICC-IF
HPA009637	Anti-ZKSCAN3	IHC,ICC-IF
HPA007023	Anti-ZNF131	IHC
HPA049770	Anti-ZNF627	IHC,WB
HPA039116	Anti-ZNF662	IHC,WB

* WB both in human and rodent samples

1. Ngan E, Diamond B. 2012. LPP is Required for TGF-Beta Induced Motility and Invasion of Neu/ErbB-2 Expressing Breast Cancer Cells. https://doi.org/10.21236/ada568114

2. Camilleri M, Carlson P, Zinsmeister AR, McKinzie S, Busciglio I, Burton D, Zucchelli M, D'Amato M. 2010. Neuropeptide S Receptor Induces Neuropeptide Expression and Associates With Intermediate Phenotypes of Functional Gastrointestinal Disorders. Gastroenterology. 138(1):98-107.e4. https://doi.org/10.1053/j.gastro.2009.08.051

3. Bozóky B, Savchenko A, Csermely P, Korcsmáros T, Dúl Z, Pontén F, Székely L, Klein G. 2013. Novel signatures of cancer-associated fibroblasts. Int. J. Cancer. 133(2):286-293. https://doi.org/10.1002/ijc.28035

4. Stro?mberg S, Agnarsdo?ttir M, Magnusson K, Rexhepaj E, Bolander Å, Lundberg E, Asplund A, Ryan D, Rafferty M, Gallagher WM, et al. 2009. Selective Expression of Syntaxin-7 Protein in Benign Melanocytes and Malignant Melanoma. J. Proteome Res.. 8(4):1639-1646. https://doi.org/10.1021/pr800745e

Finding Cancer Biomarkers

Breast Cancer

Breast cancer is the second most common cancer and by far the most frequent cancer among women. The incidence of breast cancer is increasing steadily, but without a corresponding increase in mortality. If detected at an early stage, the prognosis is relatively good for a patient living in a developed country, with a general five-year survival rate of approximately 85%.

Breast Cancer and Treatment

Cancer, though often denoted as a singular disease, is truly a multitude of diseases. This understanding has evolved over the years, but many patients are not receiving optimal treatment for their disease. For cancer patients to receive a more individualized treatment, there is still a need for new and better ways to stratify patients. The classical prognostic factors such as stage and grade of the tumor are insufficient for a correct estimation of patient prognosis. Additional information from cancer biomarkers promise to substantially improve this estimation, ultimately leading to a more individualized treatment, thus avoiding both under and overtreatment of patients.

The primary curative treatment for breast cancer patients is surgery, often in combination with adjuvant therapy. However, adjuvant therapy is associated with substantial costs and sometimes severe side effects, and physicians have identified reduction of overtreatment as the major clinical need in breast cancer treatment today. Thus, the stratification of patients into different prognostic categories is of great importance as it may aid physicians in selecting the most appropriate treatment for a given patient.

The majority of breast cancers are hormone receptor responsive, i.e., express the estrogen receptor (ER) and/or the progesteron receptor (PR). Patients with tumors expressing these receptors may receive adjuvant endocrine treatment, such as tamoxifen.

Breast cancers may also express the HER2 protein (human epidermal growth factor receptor 2), and patients with tumors expressing this protein may receive adjuvant therapy with trastuzumab.

Adjuvant treatment may also consist of chemotherapy or radiation therapy.

RBM3

The RNA-binding motif protein 3 (RBM3) is an RNA- and DNAbinding protein, whose function has not been fully elucidated. It has been shown that the protein is expressed as an early event in mild hypothermia, and also in other conditions relating to cellular stress, such as glucose deprivation and hypoxia1. During stress, RBM3 is thought to protect the cells by aiding in maintenance of protein synthesis needed for survival¹. Recently, it has also been shown that RBM3 attenuates stem cell-like properties in prostate cancer cells².

RBM3 was identified via the Human Protein Atlas (HPA) as a potential oncology biomarker through the differential expression pattern present in several cancers investigated as part of the HPA project (proteinatlas.org)^3,4.

The IHC analysis using the Anti-RBM3 antibody HPA003624 showed a weak expression pattern in normal breast tissue, but a stratified pattern in breast cancer tissue (Figure 1). Researchers further investigated the expression in larger breast cancer cohorts and the expression of RBM3 was shown to be associated with a prolonged survival⁵.

1. Ehlén Å. 2011. Te Role of RNA-Binding Motif 3 in Epithelial Ovarian Cancer: A Biomarker Discovery Approach .

2. Zeng Y, Wodzenski D, Gao D, Shiraishi T, Terada N, Li Y, Vander Griend DJ, Luo J, Kong C, Getzenberg RH, et al. 2013. Stress-Response Protein RBM3 Attenuates the Stem-like Properties of Prostate Cancer Cells by Interfering with CD44 Variant Splicing. Cancer Res. 73(13):4123-4133. https://doi.org/10.1158/0008-5472.can-12-1343

3. Berglund L, Björling E, Oksvold P, Fagerberg L, Asplund A, Al-Khalili Szigyarto C, Persson A, Ottosson J, Wernérus H, Nilsson P, et al. 2008. A Genecentric Human Protein Atlas for Expression Profiles Based on Antibodies. Mol Cell Proteomics. 7(10):2019-2027. https://doi.org/10.1074/mcp.r800013-mcp200

4. Uhlen M, Oksvold P, Fagerberg L, Lundberg E, Jonasson K, Forsberg M, Zwahlen M, Kampf C, Wester K, Hober S, et al. 2010. Towards a knowledge-based Human Protein Atlas. Nat Biotechnol. 28(12):1248-1250. https://doi.org/10.1038/nbt1210-1248

5. Jögi A, Brennan DJ, Rydén L, Magnusson K, Fernö M, Stål O, Borgquist S, Uhlen M, Landberg G, Påhlman S, et al. 2009. Nuclear expression of the RNA-binding protein RBM3 is associated with an improved clinical outcome in breast cancer. Mod Pathol. 22(12):1564-1574. https://doi.org/10.1038/modpathol.2009.124

Figure 1. Immunohistochemical analysis using the Anti-RBM3 antibody (HPA003624) shows weak expression in normal breast tissue (A) and differential expression, varying from weak to strong in tumor breast samples (B, C).

RBM3 as a Prognostic Biomarker in Breast Cancer

After identification of RBM3 as a potential prognostic biomarker, researchers further investigated the RBM3 protein expression in larger breast cancer cohorts1. In a cohort of 500 premenopausal women with stage II invasive breast cancer, RBM3 expression was found to be associated with small, low-grade, estrogen receptor (ER)-positive tumors. When analyzing the subset of ER-positive patients, RBM3 was an independent predictor of recurrence free survival (RFS). As shown in Figure 2, patients with tumors expressing high levels of the RBM3 protein have an improved survival compared to patients with tumors expressing low levels of RBM3.

RBM3 protein expression has further been analyzed in many different patient cohorts from various forms of cancer. Levels of RBM3 expression was found to have a significant connection to patient survival in breast¹, colon², ovarian^3,4, testicular, urothelial⁵, and prostate⁶ cancer as well as in malignant melanoma⁷.

In conclusion, RBM3 is a marker of good prognosis in breast cancer as well as in several other cancers.

Figure 2. Kaplan-Meier (survival) analysis of recurrence free survival (RFS) according to RBM3 expression for ER-positive breast cancer patients. Patients were split into two groups based on high and low RBM3 expression.

RBM3 Antibodies

There are two Anti-RBM3 antibodies in Atlas Antibodies' product catalog; the polyclonal HPA003624 and the PrecisA Monoclonal AMAb90655. The monoclonal Anti-RBM3 antibody AMAb90655 has shown excellent specificity in Western blot analysis of human cell lines, and is routinely used for staining of formalin fixed paraffin embedded tissue in IHC (Figure 3).

Figure 3. Immunohistochemical analysis of RBM3 expression in breast cancer (left) and prostate cancer (right) using AMAb90655 shows nuclear positivity in tumor cells. The WB image shows an expected band of 17 kDa in human cell line RT4 lysate using AMAb90655.

References

1. Jögi A, Brennan DJ, Rydén L, Magnusson K, Fernö M, Stål O, Borgquist S, Uhlen M, Landberg G, Påhlman S, et al. 2009. Nuclear expression of the RNA-binding protein RBM3 is associated with an improved clinical outcome in breast cancer. Mod Pathol. 22(12):1564-1574. https://doi.org/10.1038/modpathol.2009.124

2. Hjelm B, Brennan DJ, Zendehrokh N, Eberhard J, Nodin B, Gaber A, Pontén F, Johannesson H, Smaragdi K, Frantz C, et al. 2011. High nuclear RBM3 expression is associated with an improved prognosis in colorectal cancer. Prot. Clin. Appl.. 5(11-12):624-635. https://doi.org/10.1002/prca.201100020

3. Ehlén Å, Brennan DJ, Nodin B, O'Connor DP, Eberhard J, Alvarado-Kristensson M, Jeffrey IB, Manjer J, Brändstedt J, Uhlén M, et al. 2010. Expression of the RNA-binding protein RBM3 is associated with a favourable prognosis and cisplatin sensitivity in epithelial ovarian cancer. Journal of Translational Medicine. 8(1):78. https://doi.org/10.1186/1479-5876-8-78

4. Ehlén Õ, Nodin B, Rexhepaj E, Brändstedt J, Uhlén M, Alvarado-Kristensson M, Pontén F, Brennan DJ, Jirström K. 2011. RBM3-Regulated Genes Promote DNA Integrity and Affect Clinical Outcome in Epithelial Ovarian Cancer. Translational Oncology. 4(4):212-IN1. https://doi.org/10.1593/tlo.11106

5. Boman K, Segersten U, Ahlgren G, Eberhard J, Uhlén M, Jirström K, Malmström P. 2013. Decreased expression of RNA-binding motif protein 3 correlates with tumour progression and poor prognosis in urothelial bladder cancer. BMC Urol. 13(1): https://doi.org/10.1186/1471-2490-13-17

6. Jonsson L, Gaber A, Ulmert D, Uhlén M, Bjartell A, Jirström K. 2011. High RBM3 expression in prostate cancer independently predicts a reduced risk of biochemical recurrence and disease progression. Diagn Pathol. 6(1): https://doi.org/10.1186/1746-1596-6-91

7. Jonsson L, Bergman J, Nodin B, Manjer J, Pontén F, Uhlén M, Jirström K. 2011. Low RBM3 protein expression correlates with tumour progression and poor prognosis in malignant melanoma: An analysis of 215 cases from the Malmö Diet and Cancer Study. Journal of Translational Medicine. 9(1):114. https://doi.org/10.1186/1479-5876-9-114

Granulin

Granulins are a family of secreted, glycosylated peptides that are cleaved from a single precursor protein. Cleavage of the signal peptide produces mature granulin which can be further cleaved into a variety of active peptides. These cleavage products are named granulin A, granulin B, granulin C, etc. Both the peptides and intact granulin protein regulate cell growth. Different members of the granulin protein family may act as inhibitors, stimulators, or have dual actions on cell growth. Granulin family members are important in normal development, wound healing, and tumorigenesis [provided by RefSeq, Jul 2008].

In a paper by Elkabets et al, the role of GRN expression in responding tumor instigation was investigated by studying recrution of GRNexpressing bone marrow cells into responding tumors in mice¹. Certain tumors can foster the growth of other tumors or metastatic cells located at distant anatomical sites, which is referred to as tumor instigation. In this study, rigorously growing human breast carcinoma cells were implanted in mice and it was shown that these cells stimulated the outgrowth of otherwise poorly tumorigenic, indolent transformed cells. GRN was identified as the most upregulated gene in the instigating bone marrow cells. The GRN expressing cells induced resident fibroblasts to express genes that promoted malignant tumor progression. It was speculated whether anticancer therapies might involve targeting GRN, or the activated GRN expressing cells, and thereby disrupting these cell lines of communication that promote cancer progression.

By using the Anti-GRN antibody HPA028747 in the analysis of tumor tissues from a cohort of breast cancer patients, high GRN expression was shown to correlate with the most aggressive triple-negative, basal-like tumor subtype and reduced patient survival (Figure 4).

References

1. Elkabets M, Gifford AM, Scheel C, Nilsson B, Reinhardt F, Bray M, Carpenter AE, Jirström K, Magnusson K, Ebert BL, et al. 2011. Human tumors instigate granulin-expressing hematopoietic cells that promote malignancy by activating stromal fibroblasts in mice. J. Clin. Invest.. 121(2):784-799. https://doi.org/10.1172/jci43757

Figure 4. GRN expression was shown to correlate with aggressive tumor subtypes and reduced survival of breast cancer patients using antibody HPA028747. The diagram to the left shows percentage of tumors in each category (Triple-Negative [TN]/ basal or nonbasal) that show high GRN positivity and the Kaplan-Meier analysis to the right shows correlation between GRN-positive (green) or GRN-negative (blue) expression and survival.

Granulin Antibodies

In Atlas Antibodies´ product catalog, there are two polyclonal Anti-GRN antibodies; HPA008763 and HPA028747.

IHC staining of human pancreas tissue using the Anti-GRN antibody (HPA008763) shows strong cytoplasmic positivity in exocrine glandular cells. ICC-IF shows positivity in vesicles in A-431 cells.

IHC analysis using the Anti-GRN antibody HPA028747 shows strong cytoplasmic positivity in normal duodenum tissue in glanduclar cells and vesicle positivity in U-251 MG cells.

Anillin

Anillin is an actin binding protein that is a subunit of microfilaments, one of the cytoskeleton components. Anillin is expressed in most cells and is involved in basic cell functions, e.g. motility, division and signaling. Studies of anillin expression have shown that it is over expressed in several human tumors.

Anillin as a Treatment Predictive Prognostic Biomarker in Breast Cancer

Anillin expression was analyzed in a patient cohort consisting of 467 samples from patients diagnosed with breast cancer, using the Anti-ANLN antibody HPA005680. Patients with tumors expressing high levels of anillin had a reduced recurrence free survival (RFS) compared to patients with tumors expressing low levels of anillin (Figure 5A). The same association between anillin expression and reduced survival could be seen when analyzing breast cancer specific survival (BCSS, Figure 5B). In a study by O´Leary et al, the prognostic impact of anillin was confirmed by Cox regression analysis. High anillin expression was associated with reduced BCSS and RFS in univariate- as well as in multivariate analysis, adjusted for tumor size and grade, age at diagnosis, nodal-, ER-, PR-, HER2-, and Ki67 status.

In conclusion, anillin is a marker for poor prognosis in breast cancer.

Figure 5. Kaplan-Meier (survival) analysis of recurrence free- (A) and breast cancer specific survival (B) according to aniliin expression for breast cancer patients. Patients were split into two groups based on high and low anillin expression.

References

1. O´Leary PC, Penny SA, Dolan RT, Kelly CM, Madden SF, Rexhepaj E, Brennan DJ, McCann AH, Pontén F, Uhlén M, et al. 2013. Systematic antibody generation and validation via tissue microarray technology leading to identification of a novel protein prognostic panel in breast cancer. BMC Cancer. 13(1): https://doi.org/10.1186/1471-2407-13-175

Anillin Antibodies

There are three Anti-ANLN antibodies in Atlas Antibodies product catalog; the monoclonals AMAb90660 and AMAb90662, and the polyclonal HPA005680.

The Anti-ANLN antibody (HPA005680) shows strong nuclear positivity in cells in seminiferous ducts in human testis by IHC. In ICC-IF, nuclei (but not nucleoli) of A-431 cells stain positively and in WB, the antibody detects a band of predicted size in cell lysates of RT-4 and U-251 MG.

Anti-ANLN antibody AMAb90660 shows strong nuclear immunoreactivity in a subset of tumour cells in lung adenocarcinoma and a band of predicted size in human cell line U-251 MG.

AMAb90662 Anti-ANLN antibody shows strong nuclear immunoreactivity in a subset of tumor cells in colorectal cancer and a band of predicted size in human U-251 MG cells.