Your search keyword '"Janes S.M."' showing total 8 results

1. Cross-talk between human airway epithelial cells and 3T3-J2 feeder cells involves partial activation of human MET by murine HGF

Author

Hynds, R.E., Gowers, K.H.C., Nigro, E., Butler, C.R., Bonfanti, P., Giangreco, A., Prêle, C.M., Janes, S.M., Hynds, R.E., Gowers, K.H.C., Nigro, E., Butler, C.R., Bonfanti, P., Giangreco, A., Prêle, C.M., and Janes, S.M.

Abstract

There is considerable interest in the ex vivo propagation of primary human basal epithelial stem/progenitor cells with a view to their use in drug development, toxicity testing and regenerative medicine. These cells can be expanded in co-culture with mitotically inactivated 3T3-J2 murine embryonic feeder cells but, similar to other epithelial cell culture systems employing 3T3-J2 cells, the aspects of cross-talk between 3T3-J2 cells and human airway basal cells that are critical for their expansion remain largely unknown. In this study, we investigated secreted growth factors that are produced by 3T3-J2 cells and act upon primary human airway basal cells. We found robust production of hepatocyte growth factor (HGF) from fibroblast feeder cells following mitotic inactivation. Consistent with the limited cross-species reactivity of murine HGF on the human HGF receptor (MET; HGFR), MET inhibition did not affect proliferative responses in human airway basal cells and HGF could not replace feeder cells in this culture system. However, we found that murine HGF is not completely inactive on human airway epithelial cells or cancer cell lines but stimulates the phosphorylation of GRB2-associated-binding protein 2 (GAB2) and signal transducer and activator of transcription 6 (STAT6). Although HGF induces phosphorylation of STAT6 tyrosine 641 (Y641), there is no subsequent STAT6 nuclear translocation or STAT6-driven transcriptional response. Overall, these findings highlight the relevance of cross-species protein interactions between murine feeder cells and human epithelial cells in 3T3-J2 co-culture and demonstrate that STAT6 phosphorylation occurs in response to MET activation in epithelial cells. However, STAT6 nuclear translocation does not occur in response to HGF, precluding the transcriptional activity of STAT6.

Published

2018

2. Cross-talk between human airway epithelial cells and 3T3-J2 feeder cells involves partial activation of human MET by murine HGF

Author

Hynds, R.E., Gowers, K.H.C., Nigro, E., Butler, C.R., Bonfanti, P., Giangreco, A., Prêle, C.M., Janes, S.M., Hynds, R.E., Gowers, K.H.C., Nigro, E., Butler, C.R., Bonfanti, P., Giangreco, A., Prêle, C.M., and Janes, S.M.

Abstract

There is considerable interest in the ex vivo propagation of primary human basal epithelial stem/progenitor cells with a view to their use in drug development, toxicity testing and regenerative medicine. These cells can be expanded in co-culture with mitotically inactivated 3T3-J2 murine embryonic feeder cells but, similar to other epithelial cell culture systems employing 3T3-J2 cells, the aspects of cross-talk between 3T3-J2 cells and human airway basal cells that are critical for their expansion remain largely unknown. In this study, we investigated secreted growth factors that are produced by 3T3-J2 cells and act upon primary human airway basal cells. We found robust production of hepatocyte growth factor (HGF) from fibroblast feeder cells following mitotic inactivation. Consistent with the limited cross-species reactivity of murine HGF on the human HGF receptor (MET; HGFR), MET inhibition did not affect proliferative responses in human airway basal cells and HGF could not replace feeder cells in this culture system. However, we found that murine HGF is not completely inactive on human airway epithelial cells or cancer cell lines but stimulates the phosphorylation of GRB2-associated-binding protein 2 (GAB2) and signal transducer and activator of transcription 6 (STAT6). Although HGF induces phosphorylation of STAT6 tyrosine 641 (Y641), there is no subsequent STAT6 nuclear translocation or STAT6-driven transcriptional response. Overall, these findings highlight the relevance of cross-species protein interactions between murine feeder cells and human epithelial cells in 3T3-J2 co-culture and demonstrate that STAT6 phosphorylation occurs in response to MET activation in epithelial cells. However, STAT6 nuclear translocation does not occur in response to HGF, precluding the transcriptional activity of STAT6.

Published

2018

3. Mobile DNA in cancer. Extensive transduction of nonrepetitive DNA mediated by L1 retrotransposition in cancer genomes.

Author

Tubio, J.M., Li, Y., Ju, Y.S., Martincorena, I., Cooke, S.L., Tojo, M., Gundem, G., Pipinikas, C.P., Zamora, J., Raine, K., Menzies, A., Roman-Garcia, P., Fullam, A., Gerstung, M., Shlien, A., Tarpey, P.S., Papaemmanuil, E., Knappskog, S., Loo, P. Van, Ramakrishna, M., Davies, H.R., Marshall, J., Wedge, D.C., Teague, J.W., Butler, A.P., Nik-Zainal, S., Alexandrov, L., Behjati, S., Yates, L.R., Bolli, N., Mudie, L., Hardy, C., Martin, S., McLaren, S., O'Meara, S., Anderson, E., Maddison, M., Gamble, S., Foster, C., Warren, A.Y., Whitaker, H., Brewer, D., Eeles, R., Cooper, C., Neal, D., Lynch, A.G., Visakorpi, T., Isaacs, W.B., n't Veer, L. va, Caldas, C., Desmedt, C., Sotiriou, C., Aparicio, S., Foekens, J.A., Eyfjord, J.E., Lakhani, S.R., Thomas, G., Myklebost, O., Span, P.N., Borresen-Dale, A.L., Richardson, A.L., Vijver, M. van de, Vincent-Salomon, A., Eynden, G.G. Van den, Flanagan, A.M., Futreal, P.A., Janes, S.M., Bova, G.S., Stratton, M.R., McDermott, U., Campbell, P.J., Tubio, J.M., Li, Y., Ju, Y.S., Martincorena, I., Cooke, S.L., Tojo, M., Gundem, G., Pipinikas, C.P., Zamora, J., Raine, K., Menzies, A., Roman-Garcia, P., Fullam, A., Gerstung, M., Shlien, A., Tarpey, P.S., Papaemmanuil, E., Knappskog, S., Loo, P. Van, Ramakrishna, M., Davies, H.R., Marshall, J., Wedge, D.C., Teague, J.W., Butler, A.P., Nik-Zainal, S., Alexandrov, L., Behjati, S., Yates, L.R., Bolli, N., Mudie, L., Hardy, C., Martin, S., McLaren, S., O'Meara, S., Anderson, E., Maddison, M., Gamble, S., Foster, C., Warren, A.Y., Whitaker, H., Brewer, D., Eeles, R., Cooper, C., Neal, D., Lynch, A.G., Visakorpi, T., Isaacs, W.B., n't Veer, L. va, Caldas, C., Desmedt, C., Sotiriou, C., Aparicio, S., Foekens, J.A., Eyfjord, J.E., Lakhani, S.R., Thomas, G., Myklebost, O., Span, P.N., Borresen-Dale, A.L., Richardson, A.L., Vijver, M. van de, Vincent-Salomon, A., Eynden, G.G. Van den, Flanagan, A.M., Futreal, P.A., Janes, S.M., Bova, G.S., Stratton, M.R., McDermott, U., and Campbell, P.J.

Abstract

Item does not contain fulltext, Long interspersed nuclear element-1 (L1) retrotransposons are mobile repetitive elements that are abundant in the human genome. L1 elements propagate through RNA intermediates. In the germ line, neighboring, nonrepetitive sequences are occasionally mobilized by the L1 machinery, a process called 3' transduction. Because 3' transductions are potentially mutagenic, we explored the extent to which they occur somatically during tumorigenesis. Studying cancer genomes from 244 patients, we found that tumors from 53% of the patients had somatic retrotranspositions, of which 24% were 3' transductions. Fingerprinting of donor L1s revealed that a handful of source L1 elements in a tumor can spawn from tens to hundreds of 3' transductions, which can themselves seed further retrotranspositions. The activity of individual L1 elements fluctuated during tumor evolution and correlated with L1 promoter hypomethylation. The 3' transductions disseminated genes, exons, and regulatory elements to new locations, most often to heterochromatic regions of the genome.

Published

2014

4. Processed pseudogenes acquired somatically during cancer development

Author

Cooke, S.L., Shlien, A., Marshall, J., Pipinikas, C.P., Martincorena, I., Tubio, J.M., Li, Y., Menzies, A., Mudie, L., Ramakrishna, M., Yates, L., Davies, H., Bolli, N., Bignell, G.R., Tarpey, P.S., Behjati, S., Nik-Zainal, S., Papaemmanuil, E., Teixeira, V.H., Raine, K., O'Meara, S., Dodoran, M.S., Teague, J.W., Butler, A.P., Iacobuzio-Donahue, C., Santarius, T., Grundy, R.G., Malkin, D., Greaves, M., Munshi, N., Flanagan, A.M., Bowtell, D., Martin, S., Larsimont, D., Reis-Filho, J.S., Boussioutas, A., Taylor, J.A., Hayes, N.D., Janes, S.M., Futreal, P.A., Stratton, M.R., McDermott, U., Campbell, P.J., Span, P.N., Sweep, C.G.J., et al., Cooke, S.L., Shlien, A., Marshall, J., Pipinikas, C.P., Martincorena, I., Tubio, J.M., Li, Y., Menzies, A., Mudie, L., Ramakrishna, M., Yates, L., Davies, H., Bolli, N., Bignell, G.R., Tarpey, P.S., Behjati, S., Nik-Zainal, S., Papaemmanuil, E., Teixeira, V.H., Raine, K., O'Meara, S., Dodoran, M.S., Teague, J.W., Butler, A.P., Iacobuzio-Donahue, C., Santarius, T., Grundy, R.G., Malkin, D., Greaves, M., Munshi, N., Flanagan, A.M., Bowtell, D., Martin, S., Larsimont, D., Reis-Filho, J.S., Boussioutas, A., Taylor, J.A., Hayes, N.D., Janes, S.M., Futreal, P.A., Stratton, M.R., McDermott, U., Campbell, P.J., Span, P.N., Sweep, C.G.J., and et al.

Abstract

Contains fulltext : 136602.pdf (publisher's version ) (Open Access), Cancer evolves by mutation, with somatic reactivation of retrotransposons being one such mutational process. Germline retrotransposition can cause processed pseudogenes, but whether this occurs somatically has not been evaluated. Here we screen sequencing data from 660 cancer samples for somatically acquired pseudogenes. We find 42 events in 17 samples, especially non-small cell lung cancer (5/27) and colorectal cancer (2/11). Genomic features mirror those of germline LINE element retrotranspositions, with frequent target-site duplications (67%), consensus TTTTAA sites at insertion points, inverted rearrangements (21%), 5' truncation (74%) and polyA tails (88%). Transcriptional consequences include expression of pseudogenes from UTRs or introns of target genes. In addition, a somatic pseudogene that integrated into the promoter and first exon of the tumour suppressor gene, MGA, abrogated expression from that allele. Thus, formation of processed pseudogenes represents a new class of mutation occurring during cancer development, with potentially diverse functional consequences depending on genomic context.

Published

2014

5. Mobile DNA in cancer. Extensive transduction of nonrepetitive DNA mediated by L1 retrotransposition in cancer genomes.

Author

Tubio, J.M., Li, Y., Ju, Y.S., Martincorena, I., Cooke, S.L., Tojo, M., Gundem, G., Pipinikas, C.P., Zamora, J., Raine, K., Menzies, A., Roman-Garcia, P., Fullam, A., Gerstung, M., Shlien, A., Tarpey, P.S., Papaemmanuil, E., Knappskog, S., Loo, P. Van, Ramakrishna, M., Davies, H.R., Marshall, J., Wedge, D.C., Teague, J.W., Butler, A.P., Nik-Zainal, S., Alexandrov, L., Behjati, S., Yates, L.R., Bolli, N., Mudie, L., Hardy, C., Martin, S., McLaren, S., O'Meara, S., Anderson, E., Maddison, M., Gamble, S., Foster, C., Warren, A.Y., Whitaker, H., Brewer, D., Eeles, R., Cooper, C., Neal, D., Lynch, A.G., Visakorpi, T., Isaacs, W.B., n't Veer, L. va, Caldas, C., Desmedt, C., Sotiriou, C., Aparicio, S., Foekens, J.A., Eyfjord, J.E., Lakhani, S.R., Thomas, G., Myklebost, O., Span, P.N., Borresen-Dale, A.L., Richardson, A.L., Vijver, M. van de, Vincent-Salomon, A., Eynden, G.G. Van den, Flanagan, A.M., Futreal, P.A., Janes, S.M., Bova, G.S., Stratton, M.R., McDermott, U., Campbell, P.J., Tubio, J.M., Li, Y., Ju, Y.S., Martincorena, I., Cooke, S.L., Tojo, M., Gundem, G., Pipinikas, C.P., Zamora, J., Raine, K., Menzies, A., Roman-Garcia, P., Fullam, A., Gerstung, M., Shlien, A., Tarpey, P.S., Papaemmanuil, E., Knappskog, S., Loo, P. Van, Ramakrishna, M., Davies, H.R., Marshall, J., Wedge, D.C., Teague, J.W., Butler, A.P., Nik-Zainal, S., Alexandrov, L., Behjati, S., Yates, L.R., Bolli, N., Mudie, L., Hardy, C., Martin, S., McLaren, S., O'Meara, S., Anderson, E., Maddison, M., Gamble, S., Foster, C., Warren, A.Y., Whitaker, H., Brewer, D., Eeles, R., Cooper, C., Neal, D., Lynch, A.G., Visakorpi, T., Isaacs, W.B., n't Veer, L. va, Caldas, C., Desmedt, C., Sotiriou, C., Aparicio, S., Foekens, J.A., Eyfjord, J.E., Lakhani, S.R., Thomas, G., Myklebost, O., Span, P.N., Borresen-Dale, A.L., Richardson, A.L., Vijver, M. van de, Vincent-Salomon, A., Eynden, G.G. Van den, Flanagan, A.M., Futreal, P.A., Janes, S.M., Bova, G.S., Stratton, M.R., McDermott, U., and Campbell, P.J.

Abstract

Item does not contain fulltext, Long interspersed nuclear element-1 (L1) retrotransposons are mobile repetitive elements that are abundant in the human genome. L1 elements propagate through RNA intermediates. In the germ line, neighboring, nonrepetitive sequences are occasionally mobilized by the L1 machinery, a process called 3' transduction. Because 3' transductions are potentially mutagenic, we explored the extent to which they occur somatically during tumorigenesis. Studying cancer genomes from 244 patients, we found that tumors from 53% of the patients had somatic retrotranspositions, of which 24% were 3' transductions. Fingerprinting of donor L1s revealed that a handful of source L1 elements in a tumor can spawn from tens to hundreds of 3' transductions, which can themselves seed further retrotranspositions. The activity of individual L1 elements fluctuated during tumor evolution and correlated with L1 promoter hypomethylation. The 3' transductions disseminated genes, exons, and regulatory elements to new locations, most often to heterochromatic regions of the genome.

Published

2014

6. Processed pseudogenes acquired somatically during cancer development

Author

Cooke, S.L., Shlien, A., Marshall, J., Pipinikas, C.P., Martincorena, I., Tubio, J.M., Li, Y., Menzies, A., Mudie, L., Ramakrishna, M., Yates, L., Davies, H., Bolli, N., Bignell, G.R., Tarpey, P.S., Behjati, S., Nik-Zainal, S., Papaemmanuil, E., Teixeira, V.H., Raine, K., O'Meara, S., Dodoran, M.S., Teague, J.W., Butler, A.P., Iacobuzio-Donahue, C., Santarius, T., Grundy, R.G., Malkin, D., Greaves, M., Munshi, N., Flanagan, A.M., Bowtell, D., Martin, S., Larsimont, D., Reis-Filho, J.S., Boussioutas, A., Taylor, J.A., Hayes, N.D., Janes, S.M., Futreal, P.A., Stratton, M.R., McDermott, U., Campbell, P.J., Span, P.N., Sweep, C.G.J., et al., Cooke, S.L., Shlien, A., Marshall, J., Pipinikas, C.P., Martincorena, I., Tubio, J.M., Li, Y., Menzies, A., Mudie, L., Ramakrishna, M., Yates, L., Davies, H., Bolli, N., Bignell, G.R., Tarpey, P.S., Behjati, S., Nik-Zainal, S., Papaemmanuil, E., Teixeira, V.H., Raine, K., O'Meara, S., Dodoran, M.S., Teague, J.W., Butler, A.P., Iacobuzio-Donahue, C., Santarius, T., Grundy, R.G., Malkin, D., Greaves, M., Munshi, N., Flanagan, A.M., Bowtell, D., Martin, S., Larsimont, D., Reis-Filho, J.S., Boussioutas, A., Taylor, J.A., Hayes, N.D., Janes, S.M., Futreal, P.A., Stratton, M.R., McDermott, U., Campbell, P.J., Span, P.N., Sweep, C.G.J., and et al.

Abstract

Contains fulltext : 136602.pdf (publisher's version ) (Open Access), Cancer evolves by mutation, with somatic reactivation of retrotransposons being one such mutational process. Germline retrotransposition can cause processed pseudogenes, but whether this occurs somatically has not been evaluated. Here we screen sequencing data from 660 cancer samples for somatically acquired pseudogenes. We find 42 events in 17 samples, especially non-small cell lung cancer (5/27) and colorectal cancer (2/11). Genomic features mirror those of germline LINE element retrotranspositions, with frequent target-site duplications (67%), consensus TTTTAA sites at insertion points, inverted rearrangements (21%), 5' truncation (74%) and polyA tails (88%). Transcriptional consequences include expression of pseudogenes from UTRs or introns of target genes. In addition, a somatic pseudogene that integrated into the promoter and first exon of the tumour suppressor gene, MGA, abrogated expression from that allele. Thus, formation of processed pseudogenes represents a new class of mutation occurring during cancer development, with potentially diverse functional consequences depending on genomic context.

Published

2014

7. Processed pseudogenes acquired somatically during cancer development

Author

Cooke, S.L., Shlien, A., Marshall, J., Pipinikas, C.P., Martincorena, I., Tubio, J.M., Li, Y., Menzies, A., Mudie, L., Ramakrishna, M., Yates, L., Davies, H., Bolli, N., Bignell, G.R., Tarpey, P.S., Behjati, S., Nik-Zainal, S., Papaemmanuil, E., Teixeira, V.H., Raine, K., O'Meara, S., Dodoran, M.S., Teague, J.W., Butler, A.P., Iacobuzio-Donahue, C., Santarius, T., Grundy, R.G., Malkin, D., Greaves, M., Munshi, N., Flanagan, A.M., Bowtell, D., Martin, S., Larsimont, D., Reis-Filho, J.S., Boussioutas, A., Taylor, J.A., Hayes, N.D., Janes, S.M., Futreal, P.A., Stratton, M.R., McDermott, U., Campbell, P.J., Span, P.N., Sweep, C.G.J., et al., Cooke, S.L., Shlien, A., Marshall, J., Pipinikas, C.P., Martincorena, I., Tubio, J.M., Li, Y., Menzies, A., Mudie, L., Ramakrishna, M., Yates, L., Davies, H., Bolli, N., Bignell, G.R., Tarpey, P.S., Behjati, S., Nik-Zainal, S., Papaemmanuil, E., Teixeira, V.H., Raine, K., O'Meara, S., Dodoran, M.S., Teague, J.W., Butler, A.P., Iacobuzio-Donahue, C., Santarius, T., Grundy, R.G., Malkin, D., Greaves, M., Munshi, N., Flanagan, A.M., Bowtell, D., Martin, S., Larsimont, D., Reis-Filho, J.S., Boussioutas, A., Taylor, J.A., Hayes, N.D., Janes, S.M., Futreal, P.A., Stratton, M.R., McDermott, U., Campbell, P.J., Span, P.N., Sweep, C.G.J., and et al.

Abstract

Contains fulltext : 136602.pdf (publisher's version ) (Open Access), Cancer evolves by mutation, with somatic reactivation of retrotransposons being one such mutational process. Germline retrotransposition can cause processed pseudogenes, but whether this occurs somatically has not been evaluated. Here we screen sequencing data from 660 cancer samples for somatically acquired pseudogenes. We find 42 events in 17 samples, especially non-small cell lung cancer (5/27) and colorectal cancer (2/11). Genomic features mirror those of germline LINE element retrotranspositions, with frequent target-site duplications (67%), consensus TTTTAA sites at insertion points, inverted rearrangements (21%), 5' truncation (74%) and polyA tails (88%). Transcriptional consequences include expression of pseudogenes from UTRs or introns of target genes. In addition, a somatic pseudogene that integrated into the promoter and first exon of the tumour suppressor gene, MGA, abrogated expression from that allele. Thus, formation of processed pseudogenes represents a new class of mutation occurring during cancer development, with potentially diverse functional consequences depending on genomic context.

Published

2014

8. Mobile DNA in cancer. Extensive transduction of nonrepetitive DNA mediated by L1 retrotransposition in cancer genomes.

Author

Tubio, J.M., Li, Y., Ju, Y.S., Martincorena, I., Cooke, S.L., Tojo, M., Gundem, G., Pipinikas, C.P., Zamora, J., Raine, K., Menzies, A., Roman-Garcia, P., Fullam, A., Gerstung, M., Shlien, A., Tarpey, P.S., Papaemmanuil, E., Knappskog, S., Loo, P. Van, Ramakrishna, M., Davies, H.R., Marshall, J., Wedge, D.C., Teague, J.W., Butler, A.P., Nik-Zainal, S., Alexandrov, L., Behjati, S., Yates, L.R., Bolli, N., Mudie, L., Hardy, C., Martin, S., McLaren, S., O'Meara, S., Anderson, E., Maddison, M., Gamble, S., Foster, C., Warren, A.Y., Whitaker, H., Brewer, D., Eeles, R., Cooper, C., Neal, D., Lynch, A.G., Visakorpi, T., Isaacs, W.B., n't Veer, L. va, Caldas, C., Desmedt, C., Sotiriou, C., Aparicio, S., Foekens, J.A., Eyfjord, J.E., Lakhani, S.R., Thomas, G., Myklebost, O., Span, P.N., Borresen-Dale, A.L., Richardson, A.L., Vijver, M. van de, Vincent-Salomon, A., Eynden, G.G. Van den, Flanagan, A.M., Futreal, P.A., Janes, S.M., Bova, G.S., Stratton, M.R., McDermott, U., Campbell, P.J., Tubio, J.M., Li, Y., Ju, Y.S., Martincorena, I., Cooke, S.L., Tojo, M., Gundem, G., Pipinikas, C.P., Zamora, J., Raine, K., Menzies, A., Roman-Garcia, P., Fullam, A., Gerstung, M., Shlien, A., Tarpey, P.S., Papaemmanuil, E., Knappskog, S., Loo, P. Van, Ramakrishna, M., Davies, H.R., Marshall, J., Wedge, D.C., Teague, J.W., Butler, A.P., Nik-Zainal, S., Alexandrov, L., Behjati, S., Yates, L.R., Bolli, N., Mudie, L., Hardy, C., Martin, S., McLaren, S., O'Meara, S., Anderson, E., Maddison, M., Gamble, S., Foster, C., Warren, A.Y., Whitaker, H., Brewer, D., Eeles, R., Cooper, C., Neal, D., Lynch, A.G., Visakorpi, T., Isaacs, W.B., n't Veer, L. va, Caldas, C., Desmedt, C., Sotiriou, C., Aparicio, S., Foekens, J.A., Eyfjord, J.E., Lakhani, S.R., Thomas, G., Myklebost, O., Span, P.N., Borresen-Dale, A.L., Richardson, A.L., Vijver, M. van de, Vincent-Salomon, A., Eynden, G.G. Van den, Flanagan, A.M., Futreal, P.A., Janes, S.M., Bova, G.S., Stratton, M.R., McDermott, U., and Campbell, P.J.

Abstract

Item does not contain fulltext, Long interspersed nuclear element-1 (L1) retrotransposons are mobile repetitive elements that are abundant in the human genome. L1 elements propagate through RNA intermediates. In the germ line, neighboring, nonrepetitive sequences are occasionally mobilized by the L1 machinery, a process called 3' transduction. Because 3' transductions are potentially mutagenic, we explored the extent to which they occur somatically during tumorigenesis. Studying cancer genomes from 244 patients, we found that tumors from 53% of the patients had somatic retrotranspositions, of which 24% were 3' transductions. Fingerprinting of donor L1s revealed that a handful of source L1 elements in a tumor can spawn from tens to hundreds of 3' transductions, which can themselves seed further retrotranspositions. The activity of individual L1 elements fluctuated during tumor evolution and correlated with L1 promoter hypomethylation. The 3' transductions disseminated genes, exons, and regulatory elements to new locations, most often to heterochromatic regions of the genome.

Published

2014