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3. Supplementary Figure 3 from A Molecular Taxonomy for Urothelial Carcinoma

Author

Sjödahl, Gottfrid, primary, Lauss, Martin, primary, Lövgren, Kristina, primary, Chebil, Gunilla, primary, Gudjonsson, Sigurdur, primary, Veerla, Srinivas, primary, Patschan, Oliver, primary, Aine, Mattias, primary, Fernö, Mårten, primary, Ringnér, Markus, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, Lindgren, David, primary, and Höglund, Mattias, primary

Published
2023
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4. Supplementary Figure S1 from Distinct Mitotic Segregation Errors Mediate Chromosomal Instability in Aggressive Urothelial Cancers

Author

Jin, Yuesheng, primary, Stewénius, Ylva, primary, Lindgren, David, primary, Frigyesi, Attila, primary, Calcagnile, Olga, primary, Jonson, Tord, primary, Edqvist, Anna, primary, Larsson, Nina, primary, Lundberg, Lena Maria, primary, Chebil, Gunilla, primary, Liedberg, Fredrik, primary, Gudjonsson, Sigurdur, primary, Månsson, Wiking, primary, Höglund, Mattias, primary, and Gisselsson, David, primary

Published
2023
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5. Supplementary Text 2 from A Molecular Taxonomy for Urothelial Carcinoma

Author

Sjödahl, Gottfrid, primary, Lauss, Martin, primary, Lövgren, Kristina, primary, Chebil, Gunilla, primary, Gudjonsson, Sigurdur, primary, Veerla, Srinivas, primary, Patschan, Oliver, primary, Aine, Mattias, primary, Fernö, Mårten, primary, Ringnér, Markus, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, Lindgren, David, primary, and Höglund, Mattias, primary

Published
2023
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6. Supplementary Text 1 from A Molecular Taxonomy for Urothelial Carcinoma

Author

Sjödahl, Gottfrid, primary, Lauss, Martin, primary, Lövgren, Kristina, primary, Chebil, Gunilla, primary, Gudjonsson, Sigurdur, primary, Veerla, Srinivas, primary, Patschan, Oliver, primary, Aine, Mattias, primary, Fernö, Mårten, primary, Ringnér, Markus, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, Lindgren, David, primary, and Höglund, Mattias, primary

Published
2023
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7. Supplementary Tables S1-S2 from Distinct Mitotic Segregation Errors Mediate Chromosomal Instability in Aggressive Urothelial Cancers

Author

Jin, Yuesheng, primary, Stewénius, Ylva, primary, Lindgren, David, primary, Frigyesi, Attila, primary, Calcagnile, Olga, primary, Jonson, Tord, primary, Edqvist, Anna, primary, Larsson, Nina, primary, Lundberg, Lena Maria, primary, Chebil, Gunilla, primary, Liedberg, Fredrik, primary, Gudjonsson, Sigurdur, primary, Månsson, Wiking, primary, Höglund, Mattias, primary, and Gisselsson, David, primary

Published
2023
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8. Supplementary Figure 1 from A Molecular Taxonomy for Urothelial Carcinoma

Author

Sjödahl, Gottfrid, primary, Lauss, Martin, primary, Lövgren, Kristina, primary, Chebil, Gunilla, primary, Gudjonsson, Sigurdur, primary, Veerla, Srinivas, primary, Patschan, Oliver, primary, Aine, Mattias, primary, Fernö, Mårten, primary, Ringnér, Markus, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, Lindgren, David, primary, and Höglund, Mattias, primary

Published
2023
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10. Supplementary Figure 2 from A Molecular Taxonomy for Urothelial Carcinoma

Author

Sjödahl, Gottfrid, primary, Lauss, Martin, primary, Lövgren, Kristina, primary, Chebil, Gunilla, primary, Gudjonsson, Sigurdur, primary, Veerla, Srinivas, primary, Patschan, Oliver, primary, Aine, Mattias, primary, Fernö, Mårten, primary, Ringnér, Markus, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, Lindgren, David, primary, and Höglund, Mattias, primary

Published
2023
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11. Data from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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12. Supplementary Table 1 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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13. Supplementary Table 5 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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14. Supplementary Figures 1-6 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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15. Supplementary Table 2 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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16. Supplementary Table 6 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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17. Supplementary Table 8 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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18. Supplementary Table 3 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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19. Supplementary Figure Legends 1-6 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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20. Supplementary Table 4 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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21. Supplementary Table 7 from Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, primary, Frigyesi, Attila, primary, Gudjonsson, Sigurdur, primary, Sjödahl, Gottfrid, primary, Hallden, Christer, primary, Chebil, Gunilla, primary, Veerla, Srinivas, primary, Ryden, Tobias, primary, Månsson, Wiking, primary, Liedberg, Fredrik, primary, and Höglund, Mattias, primary

Published
2023
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38. Recurrent and multiple bladder tumors show conserved expression profiles

Author

Knuutila Sakari, Borg Åke, Chebil Gunilla, Andersson Anna, Liedberg Fredrik, Aits Sonja, Jee Kowan, Gudjonsson Sigurdur, Lindgren David, Fioretos Thoas, Månsson Wiking, and Höglund Mattias

Subjects
Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract Background Urothelial carcinomas originate from the epithelial cells of the inner lining of the bladder and may appear as single or as multiple synchronous tumors. Patients with urothelial carcinomas frequently show recurrences after treatment making follow-up necessary. The leading hypothesis explaining the origin of meta- and synchronous tumors assumes a monoclonal origin. However, the genetic relationship among consecutive tumors has been shown to be complex in as much as the genetic evolution does not adhere to the chronological appearance of the metachronous tumors. Consequently, genetically less evolved tumors may appear chronologically later than genetically related but more evolved tumors. Methods Forty-nine meta- or synchronous urothelial tumors from 22 patients were analyzed using expression profiling, conventional CGH, LOH, and mutation analyses. Results We show by CGH that partial chromosomal losses in the initial tumors may not be present in the recurring tumors, by LOH that different haplotypes may be lost and that detected regions of LOH may be smaller in recurring tumors, and that mutations present in the initial tumor may not be present in the recurring ones. In contrast we show that despite apparent genomic differences, the recurrent and multiple bladder tumors from the same patients display remarkably similar expression profiles. Conclusion Our findings show that even though the vast majority of the analyzed meta- and synchronous tumors from the same patients are not likely to have originated directly from the preceding tumor they still show remarkably similar expressions profiles. The presented data suggests that an expression profile is established early in tumor development and that this profile is stable and maintained in recurring tumors.

Published
2008
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39. Tiling resolution array CGH and high density expression profiling of urothelial carcinomas delineate genomic amplicons and candidate target genes specific for advanced tumors

Author

Heidenblad Markus, Lindgren David, Jonson Tord, Liedberg Fredrik, Veerla Srinivas, Chebil Gunilla, Gudjonsson Sigurdur, Borg Åke, Månsson Wiking, and Höglund Mattias

Subjects
Internal medicine, RC31-1245, Genetics, QH426-470
Abstract

Abstract Background Urothelial carcinoma (UC) is characterized by nonrandom chromosomal aberrations, varying from one or a few changes in early-stage and low-grade tumors, to highly rearranged karyotypes in muscle-invasive lesions. Recent array-CGH analyses have shed further light on the genomic changes underlying the neoplastic development of UC, and have facilitated the molecular delineation amplified and deleted regions to the level of specific candidate genes. In the present investigation we combine detailed genomic information with expression information to identify putative target genes for genomic amplifications. Methods We analyzed 38 urothelial carcinomas by whole-genome tiling resolution array-CGH and high density expression profiling to identify putative target genes in common genomic amplifications. When necessary expression profiling was complemented with Q-PCR of individual genes. Results Three genomic segments were frequently and exclusively amplified in high grade tumors; 1q23, 6p22 and 8q22, respectively. Detailed mapping of the 1q23 segment showed a heterogeneous amplification pattern and no obvious commonly amplified region. The 6p22 amplicon was defined by a 1.8 Mb core region present in all amplifications, flanked both distally and proximally by segments amplified to a lesser extent. By combining genomic profiles with expression profiles we could show that amplification of E2F3, CDKAL1, SOX4, and MBOAT1 as well as NUP153, AOF1, FAM8A1 and DEK in 6p22 was associated with increased gene expression. Amplification of the 8q22 segment was primarily associated with YWHAZ (14-3-3-zeta) and POLR2K over expression. The possible importance of the YWHA genes in the development of urothelial carcinomas was supported by another recurrent amplicon paralogous to 8q22, in 2p25, where increased copy numbers lead to enhanced expression of YWHAQ (14-3-3-theta). Homozygous deletions were identified at 10 different genomic locations, most frequently affecting CDKN2A/CDKN2B in 9p21 (32%). Notably, the latter occurred mutually exclusive with 6p22 amplifications. Conclusion The presented data indicates 6p22 as a composite amplicon with more than one possible target gene. The data also suggests that amplification of 6p22 and homozygous deletions of 9p21 may have complementary roles. Furthermore, the analysis of paralogous regions that showed genomic amplification indicated altered expression of YWHA (14-3-3) genes as important events in the development of UC.

Published
2008
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40. Molecular changes during progression from nonmuscle invasive to advanced urothelial carcinoma.

Author

Sjödahl, Gottfrid, Eriksson, Pontus, Patschan, Oliver, Marzouka, Nour‐Al‐Dain, Jakobsson, Lovisa, Bernardo, Carina, Lövgren, Kristina, Chebil, Gunilla, Zwarthoff, Ellen, Liedberg, Fredrik, and Höglund, Mattias

Subjects
TRANSITIONAL cell carcinoma, UROTHELIUM, GENE expression profiling, BLADDER cancer, CANCER invasiveness
Abstract

Molecular changes occurring during invasion and clinical progression of cancer are difficult to study longitudinally in patient‐derived material. A unique feature of urothelial bladder cancer (UBC) is that patients frequently develop multiple nonmuscle invasive tumors, some of which may eventually progress to invade the muscle of the bladder wall. Here, we use a cohort of 73 patients that experienced a total of 357 UBC diagnoses to study the stability or change in detected molecular alterations during cancer progression. The tumors were subtyped by gene expression profiling and analyzed for hotspot mutations in FGFR3, PIK3CA and TERT, the most frequent early driver mutations in this tumor type. TP53 alterations, frequent in advanced UBC, were inferred from p53 staining pattern, and potential genomic alterations were inferred by gene expression patterns at regions harboring frequent copy number alterations. We show that early driver mutations were largely preserved in UBC recurrences. Changes in FGFR3, PIK3CA or TERT mutation status were not linked to changes in molecular subtype and aggressive behavior. Instead, changes into a more aggressive molecular subtype seem to be associated with p53 alterations. We analyze changes in gene expression from primary tumors, to recurrences and progression tumors, and identify two modes of progression: Patients for whom progression is preceded by or coincides with a radical subtype shift, and patients who progress without any systematic molecular changes. For the latter group of patients, progression may be either stochastic or depending on factors already present at primary tumor initiation. What's new? Molecular changes occurring during invasion and clinical progression of cancer are difficult to study longitudinally in patient‐derived material. A unique feature of urothelial bladder cancer is that patients frequently develop multiple nonmuscle invasive tumors, some of which may eventually progress to invade the muscle of the bladder wall. Here, the authors perform multi‐level longitudinal analyses on patients with progression from non‐muscle invasive to advanced disease and describe novel modes of progression related to shifts in molecular profiles. Combined with the theory of field cancerization, these results identify limitations in predicting clinical progression based on molecular data from non‐muscle invasive tumors. [ABSTRACT FROM AUTHOR]

Published
2020
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43. A Molecular Pathologic Framework for Risk Stratification of Stage T1 Urothelial Carcinoma

Author

Patschan, Oliver, primary, Sjödahl, Gottfrid, additional, Chebil, Gunilla, additional, Lövgren, Kristina, additional, Lauss, Martin, additional, Gudjonsson, Sigurdur, additional, Kollberg, Petter, additional, Eriksson, Pontus, additional, Aine, Mattias, additional, Månsson, Wiking, additional, Fernö, Mårten, additional, Liedberg, Fredrik, additional, and Höglund, Mattias, additional

Published
2015
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44. Reply from Authors re: Bas W.G. van Rhijn, Mark A. Behrendt, Kees Hendricksen, Theo H. van der Kwast. Toward Optimal Prediction of Prognosis in T1 Urothelial Carcinoma of the Bladder. Eur Urol 2015;68:833–4

Author

Patschan, Oliver, primary, Sjödahl, Gottfrid, additional, Chebil, Gunilla, additional, Lövgren, Kristina, additional, Lauss, Martin, additional, Gudjonsson, Sigurdur, additional, Kollberg, Petter, additional, Eriksson, Pontus, additional, Aine, Mattias, additional, Fernö, Mårten, additional, Liedberg, Fredrik, additional, and Höglund, Mattias, additional

Published
2015
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45. The combination of Ki67, histological grade and estrogen receptor status identifies a low-risk group among 1,854 chemo-naïve women with N0/N1 primary breast cancer.

Author

Forsare, Carina, Bak, Martin, Borgquist, Signe, Chebil, Gunilla, Falck, Anna-Karin, Fjällskog, Marie-Louise, Grabau, Dorthe, Hedenfalk, Ingrid, Jirström, Karin, Klintman, Marie, Malmström, Per, Olsson, Hans, Rydén, Lisa, Stål, Olle, Bendahl, Pär-Ola, Fernö, Mårten, Forsare, Carina, Bak, Martin, Borgquist, Signe, Chebil, Gunilla, Falck, Anna-Karin, Fjällskog, Marie-Louise, Grabau, Dorthe, Hedenfalk, Ingrid, Jirström, Karin, Klintman, Marie, Malmström, Per, Olsson, Hans, Rydén, Lisa, Stål, Olle, Bendahl, Pär-Ola, and Fernö, Mårten

Abstract

The aim was to confirm a previously defined prognostic index, combining a proliferation marker, histological grade, and estrogen receptor (ER) in different subsets of primary N0/N1 chemo-naïve breast cancer patients.

Published
2013

46. Integrated genomic and gene expression profiling identifies two major genomic circuits in urothelial carcinoma.

Author

Lindgren, David, Sjödahl, Gottfrid, Lauss, Martin, Staaf, Johan, Chebil, Gunilla, Lövgren, Kristina, Gudjonsson, Sigurdur, Liedberg, Fredrik, Hultman Patschan, Oliver, Månsson, Wiking, Fernö, Mårten, Höglund, Mattias, Lindgren, David, Sjödahl, Gottfrid, Lauss, Martin, Staaf, Johan, Chebil, Gunilla, Lövgren, Kristina, Gudjonsson, Sigurdur, Liedberg, Fredrik, Hultman Patschan, Oliver, Månsson, Wiking, Fernö, Mårten, and Höglund, Mattias

Abstract

Similar to other malignancies, urothelial carcinoma (UC) is characterized by specific recurrent chromosomal aberrations and gene mutations. However, the interconnection between specific genomic alterations, and how patterns of chromosomal alterations adhere to different molecular subgroups of UC, is less clear. We applied tiling resolution array CGH to 146 cases of UC and identified a number of regions harboring recurrent focal genomic amplifications and deletions. Several potential oncogenes were included in the amplified regions, including known oncogenes like E2F3, CCND1, and CCNE1, as well as new candidate genes, such as SETDB1 (1q21), and BCL2L1 (20q11). We next combined genome profiling with global gene expression, gene mutation, and protein expression data and identified two major genomic circuits operating in urothelial carcinoma. The first circuit was characterized by FGFR3 alterations, overexpression of CCND1, and 9q and CDKN2A deletions. The second circuit was defined by E3F3 amplifications and RB1 deletions, as well as gains of 5p, deletions at PTEN and 2q36, 16q, 20q, and elevated CDKN2A levels. TP53/MDM2 alterations were common for advanced tumors within the two circuits. Our data also suggest a possible RAS/RAF circuit. The tumors with worst prognosis showed a gene expression profile that indicated a keratinized phenotype. Taken together, our integrative approach revealed at least two separate networks of genomic alterations linked to the molecular diversity seen in UC, and that these circuits may reflect distinct pathways of tumor development.

Published
2012

47. A Molecular Taxonomy for Urothelial Carcinoma.

Author

Sjödahl, Gottfrid, Lauss, Martin, Lövgren, Kristina, Chebil, Gunilla, Gudjonsson, Sigurdur, Veerla, Srinivas, Hultman Patschan, Oliver, Aine, Mattias, Fernö, Mårten, Ringnér, Markus, Månsson, Wiking, Liedberg, Fredrik, Lindgren, David, Höglund, Mattias, Sjödahl, Gottfrid, Lauss, Martin, Lövgren, Kristina, Chebil, Gunilla, Gudjonsson, Sigurdur, Veerla, Srinivas, Hultman Patschan, Oliver, Aine, Mattias, Fernö, Mårten, Ringnér, Markus, Månsson, Wiking, Liedberg, Fredrik, Lindgren, David, and Höglund, Mattias

Abstract

PURPOSE: Even though urothelial cancer is the fourth most common tumor type among males, progress in treatment has been scarce. A problem in day-to-day clinical practice is that precise assessment of individual tumors is still fairly uncertain; consequently efforts have been undertaken to complement tumor evaluation with molecular biomarkers. An extension of this approach would be to base tumor classification primarily on molecular features. Here, we present a molecular taxonomy for urothelial carcinoma based on integrated genomics. EXPERIMENTAL DESIGN: We use gene expression profiles from 308 tumor cases to define five major urothelial carcinoma subtypes: urobasal A, genomically unstable, urobasal B, squamous cell carcinoma like, and an infiltrated class of tumors. Tumor subtypes were validated in three independent publically available data sets. The expression of 11 key genes was validated at the protein level by immunohistochemistry. RESULTS: The subtypes show distinct clinical outcomes and differ with respect to expression of cell-cycle genes, receptor tyrosine kinases particularly FGFR3, ERBB2, and EGFR, cytokeratins, and cell adhesion genes, as well as with respect to FGFR3, PIK3CA, and TP53 mutation frequency. The molecular subtypes cut across pathologic classification, and class-defining gene signatures show coordinated expression irrespective of pathologic stage and grade, suggesting the molecular phenotypes as intrinsic properties of the tumors. Available data indicate that susceptibility to specific drugs is more likely to be associated with the molecular stratification than with pathologic classification. CONCLUSIONS: We anticipate that the molecular taxonomy will be useful in future clinical investigations. Clin Cancer Res; 1-10. ©2012 AACR.

Published
2012

48. DNA methylation analyses of urothelial carcinoma reveal distinct epigenetic subtypes and an association between gene copy number and methylation status.

Author

Lauss, Martin, Aine, Mattias, Sjödahl, Gottfrid, Veerla, Srinivas, Hultman Patschan, Oliver, Gudjonsson, Sigurdur, Chebil, Gunilla, Lövgren, Kristina, Fernö, Mårten, Månsson, Wiking, Liedberg, Fredrik, Ringnér, Markus, Lindgren, David, Höglund, Mattias, Lauss, Martin, Aine, Mattias, Sjödahl, Gottfrid, Veerla, Srinivas, Hultman Patschan, Oliver, Gudjonsson, Sigurdur, Chebil, Gunilla, Lövgren, Kristina, Fernö, Mårten, Månsson, Wiking, Liedberg, Fredrik, Ringnér, Markus, Lindgren, David, and Höglund, Mattias

Abstract

We assessed DNA methylation and copy number status of 27,000 CpGs in 149 urothelial carcinomas and integrated the findings with gene expression and mutation data. Methylation was associated with gene expression for 1,332 CpGs, of which 26% showed positive correlation with expression, i.e., high methylation and high gene expression levels. These positively correlated CpGs were part of specific transcription factor binding sites, such as sites for MYC and CREBP1, or located in gene bodies. Furthermore, we found genes with copy number gains, low expression and high methylation levels, revealing an association between methylation and copy number levels. This phenomenon was typically observed for developmental genes, such as HOX genes, and tumor suppressor genes. In contrast, we also identified genes with copy number gains, high expression and low methylation levels. This was for instance observed for some keratin genes. Tumor cases could be grouped into four subgroups, termed epitypes, by their DNA methylation profiles. One epitype was influenced by the presence of infiltrating immune cells, two epitypes were mainly composed of non-muscle invasive tumors, and the remaining epitype of muscle invasive tumors. The polycomb complex protein EZH2 that blocks differentiation in embryonic stem cells showed increased expression both at the mRNA and protein levels in the muscle invasive epitype, together with methylation of polycomb target genes and HOX genes. Our data highlights HOX gene silencing and EZH2 expression as mechanisms to promote a more undifferentiated and aggressive state in UC.

Published
2012

49. A systematic study of gene mutations in urothelial carcinoma : inactivating mutations in TSC2 and PIK3R1

Author

Sjödahl, Gottfrid, Lauss, Martin, Gudjonsson, Sigurdur, Liedberg, Fredrik, Halldén, Christer, Chebil, Gunilla, Månsson, Wiking, Höglund, Mattias, Lindgren, David, Sjödahl, Gottfrid, Lauss, Martin, Gudjonsson, Sigurdur, Liedberg, Fredrik, Halldén, Christer, Chebil, Gunilla, Månsson, Wiking, Höglund, Mattias, and Lindgren, David

Abstract

Our data demonstrate a significant association between FGFR3 and PIK3CA mutations in UC. Moreover, the identification of mutations in PIK3R1 further emphasizes the importance of the PI3-kinase pathway in UC. The presence of TSC2 mutations, in addition to TSC1 mutations, underlines the involvement of mTOR signaling in UC.

Published
2011
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50. Combined Gene Expression and Genomic Profiling Define Two Intrinsic Molecular Subtypes of Urothelial Carcinoma and Gene Signatures for Molecular Grading and Outcome

Author

Lindgren, David, Frigyesi, Attila, Gudjonsson, Sigurdur, Sjödahl, Gottfrid, Halldén, Christer, Chebil, Gunilla, Veerla, Srinivas, Rydén, Tobias, Månsson, Wiking, Liedberg, Fredrik, Höglund, Mattias, Lindgren, David, Frigyesi, Attila, Gudjonsson, Sigurdur, Sjödahl, Gottfrid, Halldén, Christer, Chebil, Gunilla, Veerla, Srinivas, Rydén, Tobias, Månsson, Wiking, Liedberg, Fredrik, and Höglund, Mattias

Abstract

In the present investigation, we sought to refine the classification of urothelial carcinoma by combining information on gene expression, genomic, and gene mutation levels. For these purposes, we performed gene expression analysis of 144 carcinomas, and whole genome array-CGH analysis and mutation analyses of FGFR3, PIK3CA, KRAS, HRAS, NRAS, TP53, CDKN2A, and TSC1 in 103 of these cases. Hierarchical cluster analysis identified two intrinsic molecular subtypes, MS1 and MS2, which were validated and defined by the same set of genes in three independent bladder cancer data sets. The two subtypes differed with respect to gene expression and mutation profiles, as well as with the level of genomic instability. The data show that genomic instability was the most distinguishing genomic feature of MS2 tumors, and that this trait was not dependent on TP53/MDM2 alterations. By combining molecular and pathologic data, it was possible to distinguish two molecular subtypes of T(a) and T(1) tumors, respectively. In addition, we define gene signatures validated in two independent data sets that classify urothelial carcinoma into low-grade (G(1)/G(2)) and high-grade (G(3)) tumors as well as non-muscle and muscle-invasive tumors with high precisions and sensitivities, suggesting molecular grading as a relevant complement to standard pathologic grading. We also present a gene expression signature with independent prognostic effect on metastasis and disease-specific survival. We conclude that the combination of molecular and histopathologic classification systems might provide a strong improvement for bladder cancer classification and produce new insights into the development of this tumor type., QC 20120123

Published
2010
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