Search

Your search keyword '"Sijen T"' showing total 209 results
Start Over Author "Sijen T"
209 results on '"Sijen T"'

8. A collaborative EDNAP exercise on SNaPshot™-based mtDNA control region typing

Author

Weiler, N.E.C., Baca, K., Ballard, D., Balsa, F., Bogus, M., Børsting, C., Brisighelli, F., Červenáková, J., Chaitanya, L., Coble, M., Decroyer, V., Desmyter, S., van der Gaag, K.J., Gettings, K., Haas, C., Heinrich, J., João Porto, M., Kal, A.J., Kayser, M., Kúdelová, A., Morling, N., Mosquera-Miguel, A., Noel, F., Parson, W., Pereira, V., Phillips, C., Schneider, P.M., Syndercombe Court, D., Turanska, M., Vidaki, A., Woliński, P., Zatkalíková, L., and Sijen, T.

Published
2017
Full Text
View/download PDF

11. Forensic ancestry analysis with two capillary electrophoresis ancestry informative marker (AIM) panels: Results of a collaborative EDNAP exercise

Author

Santos, C., Fondevila, M., Ballard, D., Banemann, R., Bento, A.M., Børsting, C., Branicki, W., Brisighelli, F., Burrington, M., Capal, T., Chaitanya, L., Daniel, R., Decroyer, V., England, R., Gettings, K.B., Gross, T.E., Haas, C., Harteveld, J., Hoff-Olsen, P., Hoffmann, A., Kayser, M., Kohler, P., Linacre, A., Mayr-Eduardoff, M., McGovern, C., Morling, N., O’Donnell, G., Parson, W., Pascali, V.L., Porto, M.J., Roseth, A., Schneider, P.M., Sijen, T., Stenzl, V., Court, D. Syndercombe, Templeton, J.E., Turanska, M., Vallone, P.M., Oorschot, R.A.H.van, Zatkalikova, L., Carracedo, Á., and Phillips, C.

Published
2015
Full Text
View/download PDF

12. RNA/DNA co-analysis from human skin and contact traces – results of a sixth collaborative EDNAP exercise

Author

Haas, C., Hanson, E., Banemann, R., Bento, A.M., Berti, A., Carracedo, Á., Courts, C., Cock, G. De, Drobnic, K., Fleming, R., Franchi, C., Gomes, I., Hadzic, G., Harbison, S.A., Hjort, B., Hollard, C., Hoff-Olsen, P., Keyser, C., Kondili, A., Maroñas, O., McCallum, N., Miniati, P., Morling, N., Niederstätter, H., Noël, F., Parson, W., Porto, M.J., Roeder, A.D., Sauer, E., Schneider, P.M., Shanthan, G., Sijen, T., Syndercombe Court, D., Turanská, M., van den Berge, M., Vennemann, M., Vidaki, A., Zatkalíková, L., and Ballantyne, J.

Published
2015
Full Text
View/download PDF

16. RNA/DNA co-analysis from human saliva and semen stains – Results of a third collaborative EDNAP exercise

Author

Haas, C., Hanson, E., Anjos, M.J., Banemann, R., Berti, A., Borges, E., Carracedo, A., Carvalho, M., Courts, C., De Cock, G., Dötsch, M., Flynn, S., Gomes, I., Hollard, C., Hjort, B., Hoff-Olsen, P., Hríbiková, K., Lindenbergh, A., Ludes, B., Maroñas, O., McCallum, N., Moore, D., Morling, N., Niederstätter, H., Noel, F., Parson, W., Popielarz, C., Rapone, C., Roeder, A.D., Ruiz, Y., Sauer, E., Schneider, P.M., Sijen, T., Court, D. Syndercombe, Sviežená, B., Turanská, M., Vidaki, A., Zatkalíková, L., and Ballantyne, J.

Published
2013
Full Text
View/download PDF

18. RNA/DNA co-analysis from blood stains—Results of a second collaborative EDNAP exercise

Author

Haas, C., Hanson, E., Anjos, M.J., Bär, W., Banemann, R., Berti, A., Borges, E., Bouakaze, C., Carracedo, A., Carvalho, M., Castella, V., Choma, A., De Cock, G., Dötsch, M., Hoff-Olsen, P., Johansen, P., Kohlmeier, F., Lindenbergh, P.A., Ludes, B., Maroñas, O., Moore, D., Morerod, M.-L., Morling, N., Niederstätter, H., Noel, F., Parson, W., Patel, G., Popielarz, C., Salata, E., Schneider, P.M., Sijen, T., Sviežena, B., Turanská, M., Zatkalíková, L., and Ballantyne, J.

Published
2012
Full Text
View/download PDF

19. mRNA profiling for the identification of blood—Results of a collaborative EDNAP exercise

Author

Haas, C., Hanson, E., Bär, W., Banemann, R., Bento, A.M., Berti, A., Borges, E., Bouakaze, C., Carracedo, A., Carvalho, M., Choma, A., Dötsch, M., Durianciková, M., Hoff-Olsen, P., Hohoff, C., Johansen, P., Lindenbergh, P.A., Loddenkötter, B., Ludes, B., Maroñas, O., Morling, N., Niederstätter, H., Parson, W., Patel, G., Popielarz, C., Salata, E., Schneider, P.M., Sijen, T., Sviezená, B., Zatkalíková, L., and Ballantyne, J.

Published
2011
Full Text
View/download PDF

24. A collaborative EDNAP exercise on SNaPshot™-based mtDNA control region typing

Author

Weiler, J.M., Baca, K., Ballard, D., Balsa, F., Bogus, M., Børsting, C., Brisighelli, F. (Francesca), Červenáková, J., Chaitanya, L.C. (Lakshmi), Coble, M.D. (Michael), Decroyer, V., Desmyter, S., Gaag, K. (Kristiaan) van der, Gettings, K.B., Haas, C. (Cordula), Heinrich, J., João Porto, M., Kal, A.J. (Arnoud J.), Kayser, M.H. (Manfred), Kúdelová, A., Morling, N. (Niels), Mosquera-Miguel, A., Noel, F., Parson, W. (Walther), Pereira, V., Phillips, C., Schneider, P.M. (Peter), Syndercombe-Court, D. (Denise), Turanska, M. (Martina), Vidaki, A. (Athina), Woliński, P., Zatkalíková, L. (Lívia), Sijen, T. (Titia), Weiler, J.M., Baca, K., Ballard, D., Balsa, F., Bogus, M., Børsting, C., Brisighelli, F. (Francesca), Červenáková, J., Chaitanya, L.C. (Lakshmi), Coble, M.D. (Michael), Decroyer, V., Desmyter, S., Gaag, K. (Kristiaan) van der, Gettings, K.B., Haas, C. (Cordula), Heinrich, J., João Porto, M., Kal, A.J. (Arnoud J.), Kayser, M.H. (Manfred), Kúdelová, A., Morling, N. (Niels), Mosquera-Miguel, A., Noel, F., Parson, W. (Walther), Pereira, V., Phillips, C., Schneider, P.M. (Peter), Syndercombe-Court, D. (Denise), Turanska, M. (Martina), Vidaki, A. (Athina), Woliński, P., Zatkalíková, L. (Lívia), and Sijen, T. (Titia)

Abstract

A collaborative European DNA Profiling (EDNAP) Group exercise was undertaken to assess the performance of an earlier described SNaPshot™-based screening assay (denoted mini-mtSNaPshot) (Weiler et al., 2016) [1] that targets 18 single nucleotide polymorphism (SNP) positions in the mitochondrial (mt) DNA control region and allows for discrimination of major European mtDNA haplogroups. Besides the organising laboratory, 14 forensic genetics laboratories were involved in the analysis of 13 samples, which were centrally prepared and thoroughly tested prior to shipment. The samples had a variable complexity and comprised straightforward single-source samples, samples with dropout or altered peak sizing, a point heteroplasmy and two-component mixtures resulting in one to five bi-allelic calls. The overall success rate in obtaining useful results was high (97.6%) given that some of the participating laboratories had no previous experience with the typing technology and/or mtDNA analysis. The majority of the participants proceeded to haplotype inference to assess the feasibility of assigning a haplogroup and checking phylogenetic consistency when only 18 SNPs are typed. To mimic casework procedures, the participants compared the SNP typing data of all 13 samples to a set of eight mtDNA reference profiles that were described according to standard nomenclature (Parson et al., 2014) [2], and indicated whether these references matched each sample or not. Incorrect scorings were obtained for 2% of the comparisons and derived from a subset of the participants, indicating a need for training and guidelines regarding mini-mtSNaPshot data interpretation.

Published
2017
Full Text
View/download PDF

25. A collaborative EDNAP exercise on SNaPshot (TM)-based mtDNA control region typing

Author

Weiler, N. E. C., Baca, K., Ballard, D., Balsa, F., Bogus, M., Borsting, C., Brisighelli, F., Cervenakova, J., Chaitanya, L., Coble, M., Decroyer, V., Desmyter, S., van der Gaag, K. J., Gettings, K., Haas, C., Heinrich, J., Porto, M. Joao, Kal, A. J., Kayser, M., Kudelova, A., Morling, N., Mosquera-Miguel, A., Noel, F., Parson, W., Pereira, V., Phillips, C., Schneider, P. M., Court, D. Syndercombe, Turanska, M., Vidaki, A., Wolinski, P., Zatkalikova, L., Sijen, T., Weiler, N. E. C., Baca, K., Ballard, D., Balsa, F., Bogus, M., Borsting, C., Brisighelli, F., Cervenakova, J., Chaitanya, L., Coble, M., Decroyer, V., Desmyter, S., van der Gaag, K. J., Gettings, K., Haas, C., Heinrich, J., Porto, M. Joao, Kal, A. J., Kayser, M., Kudelova, A., Morling, N., Mosquera-Miguel, A., Noel, F., Parson, W., Pereira, V., Phillips, C., Schneider, P. M., Court, D. Syndercombe, Turanska, M., Vidaki, A., Wolinski, P., Zatkalikova, L., and Sijen, T.

Abstract

A collaborative European DNA Profiling (EDNAP) Group exercise was undertaken to assess the performance of an earlier described SNaPshot (TM)-based screening assay (denoted mini-mtSNaPshot) (Weiler et al., 2016) [1] that targets 18 single nucleotide polymorphism (SNP) positions in the mitochondrial (mt) DNA control region and allows for discrimination of major European mtDNA haplogroups. Besides the organising laboratory, 14 forensic genetics laboratories were involved in the analysis of 13 samples, which were centrally prepared and thoroughly tested prior to shipment. The samples had a variable complexity and comprised straightforward single-source samples, samples with dropout or altered peak sizing, a point heteroplasmy and two-component mixtures resulting in one to five bi-allelic calls. The overall success rate in obtaining useful results was high (97.6%) given that some of the participating laboratories had no previous experience with the typing technology and/or mtDNA analysis. The majority of the participants proceeded to haplotype inference to assess the feasibility of assigning a haplogroup and checking phylogenetic consistency when only 18 SNPs are typed. To mimic casework procedures, the participants compared the SNP typing data of all 13 samples to a set of eight mtDNA reference profiles that were described according to standard nomenclature (Parson et al., 2014) [2], and indicated whether these references matched each sample or not. Incorrect scorings were obtained for 2% of the comparisons and derived from a subset of the participants, indicating a need for training and guidelines regarding mini-mtSNaPshot data interpretation. (C) 2016 Elsevier Ireland Ltd. All rights reserved.

Published
2017

26. A collaborative EDNAP exercise on SNaPshot™-based mtDNA control region typing

Author

Weiler, NEC, Baca, K, Ballard, D, Balsa, F, Bogu, M, Børsting, Claus, Brisighelli, F, Červenáková, J, Chaitanya, L, Coble, M, Decroyer, V, Desmyter, S, van der Gaag, KJ, Gettings, K, Haas, C, Heinrich, J, Porto, MJ, Kal, AJ, Kayser, M, Kúdelová, A, Morling, Niels, Mosquera-Miguel, A, Noel, F, Parson, W, Pereira, Vania, Phillips, C, Schneider, PM, Syndercombe-Court, D, Turanska, M, Vidaki, A, Wolioski, P, Zatkalíková, L, Sijen, T, Weiler, NEC, Baca, K, Ballard, D, Balsa, F, Bogu, M, Børsting, Claus, Brisighelli, F, Červenáková, J, Chaitanya, L, Coble, M, Decroyer, V, Desmyter, S, van der Gaag, KJ, Gettings, K, Haas, C, Heinrich, J, Porto, MJ, Kal, AJ, Kayser, M, Kúdelová, A, Morling, Niels, Mosquera-Miguel, A, Noel, F, Parson, W, Pereira, Vania, Phillips, C, Schneider, PM, Syndercombe-Court, D, Turanska, M, Vidaki, A, Wolioski, P, Zatkalíková, L, and Sijen, T

Abstract

A collaborative European DNA Profiling (EDNAP) Group exercise was undertaken to assess the performance of an earlier described SNaPshot™-based screening assay (denoted mini-mtSNaPshot) (Weiler et al., 2016) [1] that targets 18 single nucleotide polymorphism (SNP) positions in the mitochondrial (mt) DNA control region and allows for discrimination of major European mtDNA haplogroups. Besides the organising laboratory, 14 forensic genetics laboratories were involved in the analysis of 13 samples, which were centrally prepared and thoroughly tested prior to shipment. The samples had a variable complexity and comprised straightforward single-source samples, samples with dropout or altered peak sizing, a point heteroplasmy and two-component mixtures resulting in one to five bi-allelic calls. The overall success rate in obtaining useful results was high (97.6%) given that some of the participating laboratories had no previous experience with the typing technology and/or mtDNA analysis. The majority of the participants proceeded to haplotype inference to assess the feasibility of assigning a haplogroup and checking phylogenetic consistency when only 18 SNPs are typed. To mimic casework procedures, the participants compared the SNP typing data of all 13 samples to a set of eight mtDNA reference profiles that were described according to standard nomenclature (Parson et al., 2014) [2], and indicated whether these references matched each sample or not. Incorrect scorings were obtained for 2% of the comparisons and derived from a subset of the participants, indicating a need for training and guidelines regarding mini-mtSNaPshot data interpretation.

Published
2017

27. A collaborative EDNAP exercise on SNaPshotTM-based mtDNA control region typing

Author

Weiler, N. E. C., Baca, K., Ballard, D., Balsa, F., Bogus, M., Børsting, C., Brisighelli, Francesca, Červenáková, J., Chaitanya, L., Coble, M., Decroyer, V., Desmyter, S., van der Gaag, K. J., Gettings, K., Haas, C., Heinrich, J., João Porto, M., Kal, A. J., Kayser, M., Kúdelová, A., Morling, N., Mosquera Miguel, A., Noel, F., Parson, W., Pereira, V., Phillips, C., Schneider, P. M., Syndercombe Court, D., Turanska, M., Vidaki, A., Woliński, P., Zatkalíková, L., Sijen, T., Brisighelli, Francesca (ORCID:0000-0001-5469-4413), Weiler, N. E. C., Baca, K., Ballard, D., Balsa, F., Bogus, M., Børsting, C., Brisighelli, Francesca, Červenáková, J., Chaitanya, L., Coble, M., Decroyer, V., Desmyter, S., van der Gaag, K. J., Gettings, K., Haas, C., Heinrich, J., João Porto, M., Kal, A. J., Kayser, M., Kúdelová, A., Morling, N., Mosquera Miguel, A., Noel, F., Parson, W., Pereira, V., Phillips, C., Schneider, P. M., Syndercombe Court, D., Turanska, M., Vidaki, A., Woliński, P., Zatkalíková, L., Sijen, T., and Brisighelli, Francesca (ORCID:0000-0001-5469-4413)

Abstract

A collaborative European DNA Profiling (EDNAP) Group exercise was undertaken to assess the performance of an earlier described SNaPshotTM-based screening assay (denoted mini-mtSNaPshot) (Weiler et al., 2016) [1] that targets 18 single nucleotide polymorphism (SNP) positions in the mitochondrial (mt) DNA control region and allows for discrimination of major European mtDNA haplogroups. Besides the organising laboratory, 14 forensic genetics laboratories were involved in the analysis of 13 samples, which were centrally prepared and thoroughly tested prior to shipment. The samples had a variable complexity and comprised straightforward single-source samples, samples with dropout or altered peak sizing, a point heteroplasmy and two-component mixtures resulting in one to five bi-allelic calls. The overall success rate in obtaining useful results was high (97.6%) given that some of the participating laboratories had no previous experience with the typing technology and/or mtDNA analysis. The majority of the participants proceeded to haplotype inference to assess the feasibility of assigning a haplogroup and checking phylogenetic consistency when only 18 SNPs are typed. To mimic casework procedures, the participants compared the SNP typing data of all 13 samples to a set of eight mtDNA reference profiles that were described according to standard nomenclature (Parson et al., 2014) [2], and indicated whether these references matched each sample or not. Incorrect scorings were obtained for 2% of the comparisons and derived from a subset of the participants, indicating a need for training and guidelines regarding mini-mtSNaPshot data interpretation.

Published
2017

28. Towards complete male individualization with rapidly mutating Y-chromosomal STRs

Author

Ballantyne, KN, Ralf, A, Aboukhalid, R, Achakzai, NM, Anjos, MJ, Ayub, Q, Balažic, J, Ballantyne, J, Ballard, DJ, Berger, B, Bobillo, C, Bouabdellah, M, Burri, H, Butler, J, Capal, T, Caratti, S, Carracedo, A, Cartault, F, Carvalho, EF, Cheng, B, Coble, MD, Comas, D, Corach, D, D'Amato, ME, Davison, S, de Carvalho, EF, de Knijff, Peter, de Ungria, M, Decorte, Ronny, Dobosz, T, Dupuy, BM, Elmrghni, S, Gliwinski, M, Gomes, SC, Grol, L, Haas, C, Hanson, E, Henke, J, Hill, CR, Holmlund, G, Honda, K, Immel, U, Inoue, S, Jobling, MA, Kaddura, M, Kim, JS, Kim, SH, Kim, W, King, TE, Klausriegler, E, Kling, D, Kovacevic, LL, Kovatsi, L, Krajewski, P, Kravchenko, S, Larmuseau, Maarten, Lee, EY, Lee, SH, Lessig, R, Livshits, LA, Marjanovic, D, Minarik, M, Mizuno, N, Moreira, H, Morling, N, Mukherjee, M, Nagaraju, J, Neuhuber, F, Nie, S, Nilasitsataporn, P, Nishi, T, Oh, HH, Olofsson, J, Onofri, V, Palo, JU, Pamjav, H, Parson, W, Payet, C, Petlach, M, Phillips, C, Ploski, R, Prasad, SPR, Primorac, D, Purnnomo, GA, Purps, J, Rangel, H, Rebala, K, Rerkamnuaychoke, B, Rey, D, Robino, C, Rodríguez, F, Roewer, L, Rosa, A, Sajantila, A, Sala, A, Salvador, J, Sanz, P, Schmitt, C, Sharma, AK, Silva, DA, Shin, KJ, Sijen, T, Sirker, M, Siváková, D, Skaro, V, Solano-Matamoros, C, Souto, L, Stenzl, V, Sudoyo, H, Syndercombe-Court, D, Tagliabracci, A, Taylor, D, Tillmar, A, Tsybovsky, IS, Tyler-Smith, C, van der Gaag, K, Vanek, D, Völgyi, A, Ward, D, Willemse, P, Winkler, C, Yap, EPH, Yong, RYY, Zupanic Pajnic, I, and Kayser, M

Subjects
haplotypes, paternal lineage, RM YSTRs, Y-STRs, forensic, Y-chromosome
Abstract

Relevant for various areas of human genetics, Y-chromosomal short tandem repeats (Y-STRs) are commonly used for testing close paternal relationships among individuals and populations, and for male lineage identification. However, even the widely used 17-loci Yfiler set cannot resolve individuals and populations completely. Here, 52 centers generated quality-controlled data of 13 rapidly mutating (RM) Y-STRs in 14,644 related and unrelated males from 111 worldwide populations. Strikingly, >99% of the 12,272 unrelated males were completely individualized. Haplotype diversity was extremely high (global: 0.9999985, regional: 0.99836–0.9999988). Haplotype sharing between populations was almost absent except for six (0.05%) of the 12,156 haplotypes. Haplotype sharing within populations was generally rare (0.8% nonunique haplotypes), significantly lower in urban (0.9%) than rural (2.1%) and highest in endogamous groups (14.3%). Analysis of molecular variance revealed 99.98% of variation within populations, 0.018% among populations within groups, and 0.002% among groups. Of the 2,372 newly and 156 previously typed male relative pairs, 29% were differentiated including 27% of the 2,378 father–son pairs. Relative to Yfiler, haplotype diversity was increased in 86% of the populations tested and overall male relative differentiation was raised by 23.5%. Our study demonstrates the value of RMY-STRs in identifying and separating unrelated and related males and provides a reference database. ispartof: Human Mutation vol:35 issue:8 pages:1021-1032 status: published

Published
2014

29. Toward Male Individualization with Rapidly Mutating Y-Chromosomal Short Tandem Repeats

Author

Ballantyne, K.N., Ralf, A., Aboukhalid, R., Achakzai, N.M., Anjos, M.J., Ayub, Q., Balazic, J., Ballantyne, J., Ballard, D.J., Berger, B., Bobillo, C., Bouabdellah, M., Burri, H., Capal, T., Caratti, S., Cardenas, J., Cartault, F., Carvalho, E.F., Carvalho, M., Cheng, B.W., Coble, M.D., Comas, D., Corach, D., D'Amato, M.E., Davison, S., Knijff, P. de, Ungria, M.C.A. de, Decorte, R., Dobosz, T., Dupuy, B.M., Elmrghni, S., Gliwinski, M., Gomes, S.C., Grol, L., Haas, C., Hanson, E., Henke, J., Henke, L., Herrera-Rodriguez, F., Hill, C.R., Holmlund, G., Honda, K., Immel, U.D., Inokuchi, S., Jobling, M.A., Kaddura, M., Kim, J.S., Kim, S.H., Kim, W., King, T.E., Klausriegler, E., Kling, D., Kovacevic, L., Kovatsi, L., Krajewski, P., Kravchenko, S., Larmuseau, M.H.D., Lee, E.Y., Lessig, R., Livshits, L.A., Marjanovic, D., Minarik, M., Mizuno, N., Moreira, H., Morling, N., Mukherjee, M., Munier, P., Nagaraju, J., Neuhuber, F., Nie, S.J., Nilasitsataporn, P., Nishi, T., Oh, H.H., Olofsson, J., Onofri, V., Palo, J.U., Pamjav, H., Parson, W., Petlach, M., Phillips, C., Ploski, R., Prasad, S.P.R., Primorac, D., Purnomo, G.A., Purps, J., Rangel-Villalobos, H., Rebala, K., Rerkamnuaychoke, B., Gonzalez, D.R., Robino, C., Roewer, L., Rosa, A., Sajantila, A., Sala, A., Salvador, J.M., Sanz, P., Schmitt, C., Sharma, A.K., Silva, D.A., Shin, K.J., Sijen, T., Sirker, M., Sivakova, D., Skaro, V., Solano-Matamoros, C., Souto, L., Stenzl, V., Sudoyo, H., Syndercombe-Court, D., Tagliabracci, A., Taylor, D., Tillmar, A., Tsybovsky, I.S., Tyler-Smith, C., Gaag, K.J. van der, Vanek, D., Volgyi, A., Ward, D., Willemse, P., Yap, E.P.H., Yong, R.Y.Y., Pajnic, I.Z., Kayser, M., Hjelt Institute (-2014), Forensic Medicine, PaleOmics Laboratory, and Genetic Identification

Subjects
Male, Rural Population, haplotypes, Y-chromosome, Y-STRs, RM Y-STRs, paternal lineage, forensic, Asia, Forensic Science, Urban Population, Cell- och molekylärbiologi, education, Paternity, Gene Frequency, Humans, Alleles, Chromosomes, Human, Y, 1184 Genetics, developmental biology, physiology, Genetic Variation, DNA Fingerprinting, RM Y-STRs, Y-STRs, Y-chromosome, forensic, haplotypes, paternal lineage, Pedigree, Europe, Genetics, Population, Africa, 3111 Biomedicine, Americas, Cell and Molecular Biology, Microsatellite Repeats, Rättsmedicin
Abstract

Relevant for various areas of human genetics, Y-chromosomal short tandem repeats (Y-STRs) are commonly used for testing close paternal relationships among individuals and populations, and for male lineage identification. However, even the widely used 17-loci Yfiler set cannot resolve individuals and populations completely. Here, 52 centers generated quality-controlled data of 13 rapidly mutating (RM) Y-STRs in 14,644 related and unrelated males from 111 worldwide populations. Strikingly, >99% of the 12,272 unrelated males were completely individualized. Haplotype diversity was extremely high (global: 0.9999985, regional: 0.99836-0.9999988). Haplotype sharing between populations was almost absent except for six (0.05%) of the 12,156 haplotypes. Haplotype sharing within populations was generally rare (0.8% nonunique haplotypes), significantly lower in urban (0.9%) than rural (2.1%) and highest in endogamous groups (14.3%). Analysis of molecular variance revealed 99.98% of variation within populations, 0.018% among populations within groups, and 0.002% among groups. Of the 2,372 newly and 156 previously typed male relative pairs, 29% were differentiated including 27% of the 2,378 father-son pairs. Relative to Yfiler, haplotype diversity was increased in 86% of the populations tested and overall male relative differentiation was raised by 23.5%. Our study demonstrates the value of RMY-STRs in identifying and separating unrelated and related males and provides a reference database. Published 2014 Wiley Periodicals, Inc.**

Published
2014

30. Forensic ancestry analysis with two capillary electrophoresis ancestry informative marker (AIM) panels: Results of a collaborative EDNAP exercise

Author

Santos, C, Fondevila, M, Ballard, D, Banemann, R, Bento, AM, Børsting, C, Branicki, W, BRISIGHELLI, FRANCESCA, Burrington, M, Capal, T, Chaitanya, L, Daniel, R, Decroyer, V, England, R, Gettings, KB, Gross, TE, Haas, C, Harteveld, J, Hoff-Olsen, P, Hoffmann, A, Kayser, M, Kohler, P, Linacre, A, Mayr-Eduardoff, M, McGovern, C, Morling, N, O'Donnell, G, Parson, W, Pascali, VL, Porto, MJ, Roseth, A, Schneider, PM, Sijen, T, Stenzl, V, Court, DS, Templeton, JE, Turanska, M, Vallone, PM, van Oorschot, RAH, Zatkalikova, L, Carracedo, Á, Phillips, C, Santos, C, Fondevila, M, Ballard, D, Banemann, R, Bento, AM, Børsting, C, Branicki, W, BRISIGHELLI, FRANCESCA, Burrington, M, Capal, T, Chaitanya, L, Daniel, R, Decroyer, V, England, R, Gettings, KB, Gross, TE, Haas, C, Harteveld, J, Hoff-Olsen, P, Hoffmann, A, Kayser, M, Kohler, P, Linacre, A, Mayr-Eduardoff, M, McGovern, C, Morling, N, O'Donnell, G, Parson, W, Pascali, VL, Porto, MJ, Roseth, A, Schneider, PM, Sijen, T, Stenzl, V, Court, DS, Templeton, JE, Turanska, M, Vallone, PM, van Oorschot, RAH, Zatkalikova, L, Carracedo, Á, and Phillips, C

Published
2015

31. RNA/DNA co-analysis from human skin and contact traces – results of a sixth collaborative EDNAP exercise

Author

Haas, C, Hanson, E, Banemann, R, Bento, A M, Berti, A, Carracedo, Á, Courts, C, De Cock, G, Drobnic, K, Fleming, R, Franchi, C, Gomes, I, Hadzic, G, Harbison, S A, Hjort, Benjamin Benn, Hollard, C, Hoff-Olsen, P, Keyser, C, Kondili, A, Maroñas, O, McCallum, N, Miniati, P, Morling, Niels, Niederstätter, H, Noël, F, Parson, W, Porto, M J, Roeder, A D, Sauer, E, Schneider, P M, Shanthan, G, Sijen, T, Syndercombe Court, D, Turanská, M, van den Berge, M, Vennemann, M, Vidaki, A, Zatkalíková, L, Ballantyne, J, Haas, C, Hanson, E, Banemann, R, Bento, A M, Berti, A, Carracedo, Á, Courts, C, De Cock, G, Drobnic, K, Fleming, R, Franchi, C, Gomes, I, Hadzic, G, Harbison, S A, Hjort, Benjamin Benn, Hollard, C, Hoff-Olsen, P, Keyser, C, Kondili, A, Maroñas, O, McCallum, N, Miniati, P, Morling, Niels, Niederstätter, H, Noël, F, Parson, W, Porto, M J, Roeder, A D, Sauer, E, Schneider, P M, Shanthan, G, Sijen, T, Syndercombe Court, D, Turanská, M, van den Berge, M, Vennemann, M, Vidaki, A, Zatkalíková, L, and Ballantyne, J

Abstract

The European DNA profiling group (EDNAP) organized a sixth collaborative exercise on RNA/DNA co-analysis for body fluid/tissue identification and STR profiling. The task was to identify skin samples/contact traces using specific RNA biomarkers and test three housekeeping genes for their suitability as reference genes. Eight stains, a skin RNA dilution series and, optionally, bona fide or mock casework samples of human or non-human origin were analyzed by 22 participating laboratories using RNA extraction or RNA/DNA co-extraction methods. Two sets of previously described skin-specific markers were used: skin1 pentaplex (LCE1C, LCE1D, LCE2D, IL1F7 and CCL27) and skin2 triplex (LOR, KRT9 and CDSN) in conjunction with a housekeeping gene, HKG, triplex (B2M, UBC and UCE). The laboratories used different chemistries and instrumentation. All laboratories were able to successfully isolate and detect mRNA in contact traces (e.g., human skin, palm-, hand- and fingerprints, clothing, car interiors, computer accessories and electronic devices). The simultaneous extraction of RNA and DNA provides an opportunity for positive identification of the tissue source of origin by mRNA profiling as well as a simultaneous identification of the body fluid donor by STR profiling. The skin markers LCE1C and LOR and the housekeeping gene marker B2M were detected in the majority of contact traces. Detection of the other markers was inconsistent, possibly due to the low amounts and/or poor quality of the genetic material present in shed skin cells. The results of this and the previous collaborative RNA exercises support RNA profiling as a reliable body fluid/tissue identification method that can easily be combined with current STR typing technology.

Published
2015

32. Forensic ancestry analysis with two capillary electrophoresis ancestry informative marker (AIM) panels:Results of a collaborative EDNAP exercise

Author

Santos, C, Fondevila, M, Ballard, D, Banemann, R, Bento, A M, Børsting, C, Branicki, W, Brisighelli, F, Burrington, M, Capal, T, Chaitanya, L, Daniel, R, Decroyer, V, England, R, Gettings, K B, Gross, T E, Haas, C, Harteveld, J, Hoff-Olsen, P, Hoffmann, A, Kayser, M, Kohler, P, Linacre, A, Mayr-Eduardoff, M, McGovern, C, Morling, N, O'Donnell, G, Parson, W, Pascali, V L, Porto, M J, Roseth, A, Schneider, P M, Sijen, T, Stenzl, V, Court, D Syndercombe, Templeton, J E, Turanska, M, Vallone, P M, Oorschot, R A H van, Zatkalikova, L, Carracedo, Á, Phillips, C, Santos, C, Fondevila, M, Ballard, D, Banemann, R, Bento, A M, Børsting, C, Branicki, W, Brisighelli, F, Burrington, M, Capal, T, Chaitanya, L, Daniel, R, Decroyer, V, England, R, Gettings, K B, Gross, T E, Haas, C, Harteveld, J, Hoff-Olsen, P, Hoffmann, A, Kayser, M, Kohler, P, Linacre, A, Mayr-Eduardoff, M, McGovern, C, Morling, N, O'Donnell, G, Parson, W, Pascali, V L, Porto, M J, Roseth, A, Schneider, P M, Sijen, T, Stenzl, V, Court, D Syndercombe, Templeton, J E, Turanska, M, Vallone, P M, Oorschot, R A H van, Zatkalikova, L, Carracedo, Á, and Phillips, C

Abstract

There is increasing interest in forensic ancestry tests, which are part of a growing number of DNA analyses that can enhance routine profiling by obtaining additional genetic information about unidentified DNA donors. Nearly all ancestry tests use single nucleotide polymorphisms (SNPs), but these currently rely on SNaPshot single base extension chemistry that can fail to detect mixed DNA. Insertion-deletion polymorphism (Indel) tests have been developed using dye-labeled primers that allow direct capillary electrophoresis detection of PCR products (PCR-to-CE). PCR-to-CE maintains the direct relationship between input DNA and signal strength as each marker is detected with a single dye, so mixed DNA is more reliably detected. We report the results of a collaborative inter-laboratory exercise of 19 participants (15 from the EDNAP European DNA Profiling group) that assessed a 34-plex SNP test using SNaPshot and a 46-plex Indel test using PCR-to-CE. Laboratories were asked to type five samples with different ancestries and detect an additional mixed DNA sample. Statistical inference of ancestry was made by participants using the Snipper online Bayes analysis portal plus an optional PCA module that analyzes the genotype data alongside calculation of Bayes likelihood ratios. Exercise results indicated consistent genotyping performance from both tests, reaching a particularly high level of reliability for the Indel test. SNP genotyping gave 93.5% concordance (compared to the organizing laboratory's data) that rose to 97.3% excluding one laboratory with a large number of miscalled genotypes. Indel genotyping gave a higher concordance rate of 99.8% and a reduced no-call rate compared to SNP analysis. All participants detected the mixture from their Indel peak height data and successfully assigned the correct ancestry to the other samples using Snipper, with the exception of one laboratory with SNP miscalls that incorrectly assigned ancestry of two samples and did not obtain

Published
2015

33. Collaborative EDNAP exercise on the IrisPlex system for DNA-based prediction of human eye colour

Author

Chaitanya, L.C. (Lakshmi), Walsh, S. (Susan), Andersen, J.D. (Jeppe Dyrberg), Ansell, R. (Ricky), Ballantyne, K. (Kaye), Ballard, D.J. (David), Banemann, R. (Regine), Bauer, C.M. (Christiane Maria), Bento, A.M. (Ana Margarida), Brisighelli, F. (Francesca), Capal, T. (Tomas), Clarisse, L. (Lindy), Gross, T.E. (Theresa), Haas, C. (Cordula), Hoff-Olsen, P. (Per), Hollard, C. (Clémence), Keyser, C. (Christine), Kiesler, K.M. (Kevin), Kohler, P. (Priscila), Kupiec, T. (Tomasz), Linacre, A. (Adrian), Minawi, A. (Anglika), Morling, N. (Niels), Nilsson, H. (Helena), Norén, L. (Lina), Ottens, R. (Renée), Palo, J. (Jukka), Parson, W. (Walther), Pascali, V.L. (Vincenzo), Phillips, C. (Christopher), Porto, M.J. (Maria João), Sajantila, A. (Antti), Schneider, P.M. (Peter), Sijen, T. (Titia), Söchtig, J. (Jens), Syndercombe-Court, D. (Denise), Tillmar, A. (Andreas), Turanska, M. (Martina), Vallone, P.M. (Peter), Zatkalíková, L. (Lívia), Zidkova, A. (Anastassiya), Branicki, W. (Wojciech), Kayser, M.H. (Manfred), Chaitanya, L.C. (Lakshmi), Walsh, S. (Susan), Andersen, J.D. (Jeppe Dyrberg), Ansell, R. (Ricky), Ballantyne, K. (Kaye), Ballard, D.J. (David), Banemann, R. (Regine), Bauer, C.M. (Christiane Maria), Bento, A.M. (Ana Margarida), Brisighelli, F. (Francesca), Capal, T. (Tomas), Clarisse, L. (Lindy), Gross, T.E. (Theresa), Haas, C. (Cordula), Hoff-Olsen, P. (Per), Hollard, C. (Clémence), Keyser, C. (Christine), Kiesler, K.M. (Kevin), Kohler, P. (Priscila), Kupiec, T. (Tomasz), Linacre, A. (Adrian), Minawi, A. (Anglika), Morling, N. (Niels), Nilsson, H. (Helena), Norén, L. (Lina), Ottens, R. (Renée), Palo, J. (Jukka), Parson, W. (Walther), Pascali, V.L. (Vincenzo), Phillips, C. (Christopher), Porto, M.J. (Maria João), Sajantila, A. (Antti), Schneider, P.M. (Peter), Sijen, T. (Titia), Söchtig, J. (Jens), Syndercombe-Court, D. (Denise), Tillmar, A. (Andreas), Turanska, M. (Martina), Vallone, P.M. (Peter), Zatkalíková, L. (Lívia), Zidkova, A. (Anastassiya), Branicki, W. (Wojciech), and Kayser, M.H. (Manfred)

Abstract

The IrisPlex system is a DNA-based test system for the prediction of human eye colour from biological samples and consists of a single forensically validated multiplex genotyping assay together with a statistical prediction model that is based on genotypes and phenotypes from thousands of individuals. IrisPlex predicts blue and brown human eye colour with, on average, >94% precision accuracy using six of the currently most eye colour informative single nucleotide polymorphisms (HERC2 rs12913832, OCA2 rs1800407, SLC24A4 rs12896399, SLC45A2 (MATP) rs16891982, TYR rs1393350, and IRF4 rs12203592) according to a previous study, while the accuracy in predicting non-blue and non-brown eye colours is considerably lower. In an effort to vigorously assess the IrisPlex system at the international level, testing was performed by 21 laboratories in the context of a collaborative exercise divided into three tasks and organised by the European DNA Profiling (EDNAP) Group of the International Society of Forensic Genetics (ISFG). Task 1 involved the assessment of 10 blood and saliva samples provided on FT

Published
2014
Full Text
View/download PDF

34. Developmental validation of mitochondrial DNA genotyping assays for adept matrilineal inference of biogeographic ancestry at a continental level

Author

Chaitanya, L.C. (Lakshmi), Oven, M. (Mannis) van, Weiler, J.M., Harteveld, J. (Joyce), Wirken, L. (Laura), Sijen, T. (Titia), Knijff, P. (Peter) de, Kayser, M.H. (Manfred), Chaitanya, L.C. (Lakshmi), Oven, M. (Mannis) van, Weiler, J.M., Harteveld, J. (Joyce), Wirken, L. (Laura), Sijen, T. (Titia), Knijff, P. (Peter) de, and Kayser, M.H. (Manfred)

Abstract

Mitochondrial DNA (mtDNA) can be used for matrilineal biogeographic ancestry prediction and can thus provide investigative leads towards identifying unknown suspects, when conventional autosomal short tandem repeat (STR) profiling fails to provide a match. Recently, six multiplex genotyping assays targeting 62 ancestry-informative mitochondrial single nucleotide polymorphisms (mt-SNPs) were developed. This hierarchical system of assays allows detection of the major haplogroups present in Africa, America, Western Eurasia, Eastern Eurasia, Australia and Oceania, thus revealing the broad geographic region of matrilineal origin of a DNA donor. Here, we provide a forensic developmental validation study of five multiplex assays targeting all the 62 ancestry-informative mt-SNPs following the Scientific Working Group on DNA Analysis Methods (SWGDAM) guidelines. We demonstrate that the assays are highly sensitive; being able to produce full profiles at input DNA amounts of as little as 1 pg. The assays were shown to be highly robust and efficient in providing information from degraded samples and from simulated casework samples of different substrates such as blood, semen, hair, saliva and trace DNA samples. Reproducible results were successfully achieved from concordance testing across three independent laboratories depicting the ease and reliability of these assays. Overall, our results demonstrate the suitability of these five mt-SNP assays for application to forensic casework and other purposes aiming to establish an individual's matrilineal genetic ancestry. With this validated tool, it is now possible to determine the matrilineal biogeographic origin of unknown individuals on the level of continental resolution from forensic DNA samples to provide investigative leads in criminal and missing person cases where autosomal STR profiling is uninformative.

Published
2014
Full Text
View/download PDF

35. Developmental validation of the HIrisPlex system: DNA-based eye and hair colour prediction for forensic and anthropological usage

Author

Walsh, S. (Susan), Chaitanya, L.C. (Lakshmi), Clarisse, L. (Lindy), Wirken, L. (Laura), Draus-Barini, J. (Jolanta), Kovatsi, L. (Leda), Maeda, H. (Hitoshi), Ishikawa, T. (Takaki), Sijen, T. (Titia), Knijff, P. (Peter) de, Branicki, W. (Wojciech), Liu, F. (Fan), Kayser, M.H. (Manfred), Walsh, S. (Susan), Chaitanya, L.C. (Lakshmi), Clarisse, L. (Lindy), Wirken, L. (Laura), Draus-Barini, J. (Jolanta), Kovatsi, L. (Leda), Maeda, H. (Hitoshi), Ishikawa, T. (Takaki), Sijen, T. (Titia), Knijff, P. (Peter) de, Branicki, W. (Wojciech), Liu, F. (Fan), and Kayser, M.H. (Manfred)

Abstract

Forensic DNA Phenotyping or 'DNA intelligence' tools are expected to aid police investigations and find unknown individuals by providing information on externally visible characteristics of unknown suspects, perpetrators and missing persons from biological samples. This is especially useful in cases where conventional DNA profiling or other means remain non-informative. Recently, we introduced the HIrisPlex system, capable of predicting both eye and hair colour from DNA. In the present developmental validation study, we demonstrate that the HIrisPlex assay performs in full agreement with the Scientific Working Group on DNA Analysis Methods (SWGDAM) guidelines providing an essential prerequisite for future HIrisPlex applications to forensic casework. The HIrisPlex assay produces complete profiles down to only 63 pg of DNA. Species testing revealed human specificity for a complete HIrisPlex profile, while only non-human primates showed the closest full profile at 20 out of the 24 DNA markers, in all animals tested. Rigorous testing of simulated forensic casework samples such as blood, semen, saliva stains, hairs with roots as well as extremely low quantity touch (trace) DNA samples, produced complete profiles in 88% of cases. Concordance testing performed between five independent forensic laboratories displayed consistent reproducible results on varying types of DNA samples. Due to its design, the assay caters for degraded samples, underlined here by results from artificially degraded DNA and from simulated casework samples of degraded DNA. This aspect was also demonstrated previously on DNA samples from human remains up to several hundreds of years old. With this paper, we also introduce enhanced eye and hair colour prediction models based on enlarged underlying databases of HIrisPlex genotypes and eye/hair colour phenotypes (eye colour: N = 9188 and hair colour: N = 1601). Furthermore, we present an online web-based system for individual eye and hair colour predicti

Published
2014
Full Text
View/download PDF

36. Toward Male Individualization with Rapidly Mutating Y-Chromosomal Short Tandem Repeats

Author

Ballantyne, K. (Kaye), Ralf, A. (Arwin), Aboukhalid, R. (Rachid), Achakzai, N.M. (Niaz), Anjos, T. (Tania), Ayub, Q. (Qasim), Balažic, J. (Jože), Ballantyne, J. (Jack), Ballard, D.J. (David), Berger, B. (Burkhard), Bobillo, C. (Cecilia), Bouabdellah, M. (Mehdi), Burri, H. (Helen), Capal, T. (Tomas), Caratti, S. (Stefano), Cárdenas, J. (Jorge), Cartault, F. (François), Carvalho, E.F. (Elizeu), Carvalho, M. (Margarete) de, Cheng, B. (Baowen), Coble, M.D. (Michael), Comas, D. (David), Corach, D. (Daniel), D'Amato, M. (Mauro), Davison, S. (Sean), Knijff, P. (Peter) de, Ungria, M.C.A. (Maria Corazon) de, Decorte, R. (Ronny), Dobosz, T. (Tadeusz), Dupuy, B.M. (Berit), Elmrghni, S. (Samir), Gliwiński, M. (Mateusz), Gomes, S.C. (Sara), Grol, L. (Laurens), Haas, C. (Cordula), Hanson, E. (Erin), Henke, J. (Jürgen), Henke, L. (Lotte), Herrera-Rodríguez, F. (Fabiola), Hill, C.R. (Carolyn), Holmlund, G. (Gunilla), Honda, K. (Katsuya), Immel, U.-D. (Uta-Dorothee), Inokuchi, S. (Shota), Jobling, R., Kaddura, M. (Mahmoud), Kim, J.S. (Jong), Kim, S.H. (Soon), Kim, W. (Wook), King, T.E. (Turi), Klausriegler, E. (Eva), Kling, D. (Daniel), Kovačević, L. (Lejla), Kovatsi, L. (Leda), Krajewski, P. (Paweł), Kravchenko, S. (Sergey), Larmuseau, M.H.D. (Maarten), Lee, E.Y. (Eun Young), Lessig, R. (Rüdiger), Livshits, L.A. (Ludmila), Marjanović, D. (Damir), Minarik, M. (Marek), Mizuno, N. (Natsuko), Moreira, H. (Helena), Morling, N. (Niels), Mukherjee, M. (Meeta), Munier, P. (Patrick), Nagaraju, J. (Javaregowda), Neuhuber, F. (Franz), Nie, S. (Shengjie), Nilasitsataporn, P. (Premlaphat), Nishi, T. (Takeki), Oh, H.H. (Hye), Olofsson, S. (Sylvia), Onofri, V. (Valerio), Palo, J. (Jukka), Pamjav, H. (Horolma), Parson, W. (Walther), Petlach, M. (Michal), Phillips, C. (Christopher), Ploski, R. (Rafal), Prasad, S.P.R. (Samayamantri P.), Primorac, D. (Dragan), Purnomo, G.A. (Gludhug), Purps, J. (Josephine), Rangel-Villalobos, H. (Hector), Reogonekbała, K. (Krzysztof), Rerkamnuaychoke, B. (Budsaba), Gonzalez, D.R. (Danel Rey), Robino, C. (Carlo), Roewer, L. (Lutz), Rosa, A. (Anna) de, Sajantila, A. (Antti), Sala, A. (Andrea), Salvador, J.M. (Jazelyn), Sanz, P. (Paula), Schmitt, C. (Christian), Sharma, A.K. (Anisha K.), Silva, D.A. (Dayse), Shin, K.-J. (Kyoung-Jin), Sijen, T. (Titia), Sirker, M. (Miriam), Siváková, D. (Daniela), Škaro, V. (Vedrana), Solano-Matamoros, C. (Carlos), Souto, L. (L.), Stenzl, V. (Vlastimil), Sudoyo, H. (Herawati), Syndercombe-Court, D. (Denise), Tagliabracci, A. (Adriano), Taylor, D. (Duncan), Tillmar, A. (Andreas), Tsybovsky, I.S. (Iosif), Tyler-Smith, C. (Chris), Gaag, K. (Kristiaan) van der, Vanek, D. (Daniel), Völgyi, A. (Antónia), Ward, D. (Denise), Willemse, P. (Patricia), Yap, E.P.H. (Eric), Yong, Z-Y. (Ze-Yie), Pajnič, I.Z. (Irena Zupanič), Kayser, M.H. (Manfred), Ballantyne, K. (Kaye), Ralf, A. (Arwin), Aboukhalid, R. (Rachid), Achakzai, N.M. (Niaz), Anjos, T. (Tania), Ayub, Q. (Qasim), Balažic, J. (Jože), Ballantyne, J. (Jack), Ballard, D.J. (David), Berger, B. (Burkhard), Bobillo, C. (Cecilia), Bouabdellah, M. (Mehdi), Burri, H. (Helen), Capal, T. (Tomas), Caratti, S. (Stefano), Cárdenas, J. (Jorge), Cartault, F. (François), Carvalho, E.F. (Elizeu), Carvalho, M. (Margarete) de, Cheng, B. (Baowen), Coble, M.D. (Michael), Comas, D. (David), Corach, D. (Daniel), D'Amato, M. (Mauro), Davison, S. (Sean), Knijff, P. (Peter) de, Ungria, M.C.A. (Maria Corazon) de, Decorte, R. (Ronny), Dobosz, T. (Tadeusz), Dupuy, B.M. (Berit), Elmrghni, S. (Samir), Gliwiński, M. (Mateusz), Gomes, S.C. (Sara), Grol, L. (Laurens), Haas, C. (Cordula), Hanson, E. (Erin), Henke, J. (Jürgen), Henke, L. (Lotte), Herrera-Rodríguez, F. (Fabiola), Hill, C.R. (Carolyn), Holmlund, G. (Gunilla), Honda, K. (Katsuya), Immel, U.-D. (Uta-Dorothee), Inokuchi, S. (Shota), Jobling, R., Kaddura, M. (Mahmoud), Kim, J.S. (Jong), Kim, S.H. (Soon), Kim, W. (Wook), King, T.E. (Turi), Klausriegler, E. (Eva), Kling, D. (Daniel), Kovačević, L. (Lejla), Kovatsi, L. (Leda), Krajewski, P. (Paweł), Kravchenko, S. (Sergey), Larmuseau, M.H.D. (Maarten), Lee, E.Y. (Eun Young), Lessig, R. (Rüdiger), Livshits, L.A. (Ludmila), Marjanović, D. (Damir), Minarik, M. (Marek), Mizuno, N. (Natsuko), Moreira, H. (Helena), Morling, N. (Niels), Mukherjee, M. (Meeta), Munier, P. (Patrick), Nagaraju, J. (Javaregowda), Neuhuber, F. (Franz), Nie, S. (Shengjie), Nilasitsataporn, P. (Premlaphat), Nishi, T. (Takeki), Oh, H.H. (Hye), Olofsson, S. (Sylvia), Onofri, V. (Valerio), Palo, J. (Jukka), Pamjav, H. (Horolma), Parson, W. (Walther), Petlach, M. (Michal), Phillips, C. (Christopher), Ploski, R. (Rafal), Prasad, S.P.R. (Samayamantri P.), Primorac, D. (Dragan), Purnomo, G.A. (Gludhug), Purps, J. (Josephine), Rangel-Villalobos, H. (Hector), Reogonekbała, K. (Krzysztof), Rerkamnuaychoke, B. (Budsaba), Gonzalez, D.R. (Danel Rey), Robino, C. (Carlo), Roewer, L. (Lutz), Rosa, A. (Anna) de, Sajantila, A. (Antti), Sala, A. (Andrea), Salvador, J.M. (Jazelyn), Sanz, P. (Paula), Schmitt, C. (Christian), Sharma, A.K. (Anisha K.), Silva, D.A. (Dayse), Shin, K.-J. (Kyoung-Jin), Sijen, T. (Titia), Sirker, M. (Miriam), Siváková, D. (Daniela), Škaro, V. (Vedrana), Solano-Matamoros, C. (Carlos), Souto, L. (L.), Stenzl, V. (Vlastimil), Sudoyo, H. (Herawati), Syndercombe-Court, D. (Denise), Tagliabracci, A. (Adriano), Taylor, D. (Duncan), Tillmar, A. (Andreas), Tsybovsky, I.S. (Iosif), Tyler-Smith, C. (Chris), Gaag, K. (Kristiaan) van der, Vanek, D. (Daniel), Völgyi, A. (Antónia), Ward, D. (Denise), Willemse, P. (Patricia), Yap, E.P.H. (Eric), Yong, Z-Y. (Ze-Yie), Pajnič, I.Z. (Irena Zupanič), and Kayser, M.H. (Manfred)

Abstract

Relevant for various areas of human genetics, Y-chromosomal short tandem repeats (Y-STRs) are commonly used for testing close paternal relationships among individuals and populations, and for male lineage identification. However, even the widely used 17-loci Yfiler set cannot resolve individuals and populations completely. Here, 52 centers generated quality-controlled data of 13 rapidly mutating (RM) Y-STRs in 14,644 related and unrelated males from 111 worldwide populations. Strikingly, >99% of the 12,272 unrelated males were completely individualized. Haplotype diversity was extremely high (global: 0.9999985, regional: 0.99836-0.9999988). Haplotype sharing between populations was almost absent except for six (0.05%) of the 12,156 haplotypes. Haplotype sharing within populations was generally rare (0.8% nonunique haplotypes), significantly lower in urban (0.9%) than rural (2.1%) and highest in endogamous groups (14.3%). Analysis

Published
2014
Full Text
View/download PDF

37. A collaborative European exercise on mRNA-based body fluid/skin typing and interpretation of DNA and RNA results

Author

van den Berge, M, Carracedo, A, Gomes, I, Graham, E A M, Haas, C, Hjort, Benjamin Benn, Hoff-Olsen, P, Maroñas, O, Mevåg, B, Morling, N, Niederstätter, H, Parson, W, Schneider, P M, Court, D Syndercombe, Vidaki, A, Sijen, T, van den Berge, M, Carracedo, A, Gomes, I, Graham, E A M, Haas, C, Hjort, Benjamin Benn, Hoff-Olsen, P, Maroñas, O, Mevåg, B, Morling, N, Niederstätter, H, Parson, W, Schneider, P M, Court, D Syndercombe, Vidaki, A, and Sijen, T

Abstract

The European Forensic Genetics Network of Excellence (EUROFORGEN-NoE) undertook a collaborative project on mRNA-based body fluid/skin typing and the interpretation of the resulting RNA and DNA data. Although both body fluids and skin are composed of a variety of cell types with different functions and gene expression profiles, we refer to the procedure as 'cell type inference'. Nine laboratories participated in the project and used a 20-marker multiplex to analyse samples that were centrally prepared and thoroughly tested prior to shipment. Specimens of increasing complexity were assessed that ranged from reference PCR products, cDNAs of indicated or unnamed cell type source(s), to challenging mock casework stains. From this specimen set, information on the overall sensitivity and specificity of the various markers was obtained. In addition, the reliability of a scoring system for inference of cell types was assessed. This scoring system builds on replicate RNA analyses and the ratio observed/possible peaks for each cell type [1]. The results of the exercise support the usefulness of this scoring system. When interpreting the data obtained from the analysis of the mock casework stains, the participating laboratories were asked to integrate the DNA and RNA results and associate donor and cell type where possible. A large variation for the integrated interpretations of the DNA and RNA data was obtained including correct interpretations. We infer that with expertise in analysing RNA profiles, clear guidelines for data interpretation and awareness regarding potential pitfalls in associating donors and cell types, mRNA-based cell type inference can be implemented for forensic casework.

Published
2014

38. Collaborative EDNAP exercise on the IrisPlex system for DNA-based prediction of human eye colour

Author

Chaitanya, L, Walsh, S, Andersen, Jd, Ansell, R, Ballantyne, K, Ballard, D, Banemann, R, Bauer, Cm, Bento, Am, Brisighelli, Francesca, Capal, T, Clarisse, L, Gross, Te, Haas, C, Hoff Olsen, P, Hollard, C, Keyser, C, Kiesler, Km, Kohler, P, Kupiec, T, Linacre, A, Minawi, A, Morling, N, Nilsson, H, Norén, L, Ottens, R, Palo, Ju, Parson, W, Pascali, Vincenzo Lorenzo, Phillips, C, Porto, Mj, Sajantila, A, Schneider, Pm, Sijen, T, Söchtig, J, Syndercombe Court, D, Tillmar, A, Turanska, M, Vallone, Pm, Zatkalíková, L, Zidkova, A, Branicki, W, Kayser, M., Brisighelli, Francesca (ORCID:0000-0001-5469-4413), Pascali, Vincenzo Lorenzo (ORCID:0000-0001-6520-5224), Chaitanya, L, Walsh, S, Andersen, Jd, Ansell, R, Ballantyne, K, Ballard, D, Banemann, R, Bauer, Cm, Bento, Am, Brisighelli, Francesca, Capal, T, Clarisse, L, Gross, Te, Haas, C, Hoff Olsen, P, Hollard, C, Keyser, C, Kiesler, Km, Kohler, P, Kupiec, T, Linacre, A, Minawi, A, Morling, N, Nilsson, H, Norén, L, Ottens, R, Palo, Ju, Parson, W, Pascali, Vincenzo Lorenzo, Phillips, C, Porto, Mj, Sajantila, A, Schneider, Pm, Sijen, T, Söchtig, J, Syndercombe Court, D, Tillmar, A, Turanska, M, Vallone, Pm, Zatkalíková, L, Zidkova, A, Branicki, W, Kayser, M., Brisighelli, Francesca (ORCID:0000-0001-5469-4413), and Pascali, Vincenzo Lorenzo (ORCID:0000-0001-6520-5224)

Abstract

The IrisPlex system is a DNA-based test system for the prediction of human eye colour from biological samples and consists of a single forensically validated multiplex genotyping assay together with a statistical prediction model that is based on genotypes and phenotypes from thousands of individuals. IrisPlex predicts blue and brown human eye colour with, on average, >94% precision accuracy using six of the currently most eye colour informative single nucleotide polymorphisms (HERC2 rs12913832, OCA2 rs1800407, SLC24A4 rs12896399, SLC45A2 (MATP) rs16891982, TYR rs1393350, and IRF4 rs12203592) according to a previous study, while the accuracy in predicting non-blue and non-brown eye colours is considerably lower. In an effort to vigorously assess the IrisPlex system at the international level, testing was performed by 21 laboratories in the context of a collaborative exercise divided into three tasks and organised by the European DNA Profiling (EDNAP) Group of the International Society of Forensic Genetics (ISFG). Task 1 involved the assessment of 10 blood and saliva samples provided on FTA cards by the organising laboratory together with eye colour phenotypes; 99.4% of the genotypes were correctly reported and 99% of the eye colour phenotypes were correctly predicted. Task 2 involved the assessment of 5 DNA samples extracted by the host laboratory from simulated casework samples, artificially degraded, and provided to the participants in varying DNA concentrations. For this task, 98.7% of the genotypes were correctly determined and 96.2% of eye colour phenotypes were correctly inferred. For Tasks 1 and 2 together, 99.2% (1875) of the 1890 genotypes were correctly generated and of the 15 (0.8%) incorrect genotype calls, only 2 (0.1%) resulted in incorrect eye colour phenotypes. The voluntary Task 3 involved participants choosing their own test subjects for IrisPlex genotyping and eye colour phenotype inference, while eye photographs were provided to the organising la

Published
2014

39. RNA/DNA co-analysis from human saliva and semen stains--results of a third collaborative EDNAP exercise

Author

Haas, Claus, Hanson, E, Anjos, M J, Banemann, R, Berti, A, Borges, E, Carracedo, A, Carvalho, M, Courts, C, De Cock, G, Dötsch, M, Flynn, S, Gomes, I, Hollard, C, Hjort, Benjamin Benn, Hoff-Olsen, P, Hríbiková, K, Lindenbergh, A, Ludes, B, Maroñas, O, McCallum, N, Moore, D, Morling, N, Niederstätter, H, Noel, F, Parson, W, Popielarz, C, Rapone, C, Roeder, A D, Ruiz, Y, Sauer, E, Schneider, Peter, Sijen, T, Court, D Syndercombe, Sviežená, B, Turanská, M, Vidaki, A, Zatkalíková, L, Ballantyne, J, Haas, Claus, Hanson, E, Anjos, M J, Banemann, R, Berti, A, Borges, E, Carracedo, A, Carvalho, M, Courts, C, De Cock, G, Dötsch, M, Flynn, S, Gomes, I, Hollard, C, Hjort, Benjamin Benn, Hoff-Olsen, P, Hríbiková, K, Lindenbergh, A, Ludes, B, Maroñas, O, McCallum, N, Moore, D, Morling, N, Niederstätter, H, Noel, F, Parson, W, Popielarz, C, Rapone, C, Roeder, A D, Ruiz, Y, Sauer, E, Schneider, Peter, Sijen, T, Court, D Syndercombe, Sviežená, B, Turanská, M, Vidaki, A, Zatkalíková, L, and Ballantyne, J

Abstract

A third collaborative exercise on RNA/DNA co-analysis for body fluid identification and STR profiling was organized by the European DNA Profiling Group (EDNAP). Twenty saliva and semen stains, four dilution series (10-0.01 µl saliva, 5-0.01 µl semen) and, optionally, bona fide or mock casework samples of human or non-human origin were analyzed by 20 participating laboratories using an RNA extraction or RNA/DNA co-extraction method. Two novel mRNA multiplexes were used: a saliva triplex (HTN3, STATH and MUC7) and a semen pentaplex (PRM1, PRM2, PSA, SEMG1 and TGM4). The laboratories used different chemistries and instrumentation and a majority (16/20) were able to successfully isolate and detect mRNA in dried stains. The simultaneous extraction of RNA and DNA from individual stains not only permitted a confirmation of the presence of saliva/semen (i.e. tissue/fluid source of origin), but allowed an STR profile of the stain donor to be obtained as well. The method proved to be reproducible and sensitive, with as little as 0.05 µl saliva or semen, using different analysis strategies. Additionally, we demonstrated the ability to positively identify the presence of saliva and semen, as well as obtain high quality DNA profiles, from old and compromised casework samples. The results of this collaborative exercise involving an RNA/DNA co-extraction strategy support the potential use of an mRNA based system for the identification of saliva and semen in forensic casework that is compatible with current DNA analysis methodologies.

Published
2013

40. mRNA profiling for the identification of blood-Results of a collaborative EDNAP exercise

Author

Haas, Cordula, Hanson, E, Bär, W, Banemann, R, Bento, A M, Berti, A, Borges, E, Bouakaze, C, Carracedo, A, Carvalho, M, Choma, A, Dötsch, M, Durianciková, M, Hoff-Olsen, P, Hohoff, C, Johansen, Peter, Lindenbergh, P A, Loddenkötter, B, Ludes, B, Maroñas, O, Morling, N, Niederstätter, H, Parson, W, Patel, G, Popielarz, C, Salata, E, Schneider, Peter M., Sijen, T, Sviezená, B, Zatkalíková, L, Ballantyne, J, Haas, Cordula, Hanson, E, Bär, W, Banemann, R, Bento, A M, Berti, A, Borges, E, Bouakaze, C, Carracedo, A, Carvalho, M, Choma, A, Dötsch, M, Durianciková, M, Hoff-Olsen, P, Hohoff, C, Johansen, Peter, Lindenbergh, P A, Loddenkötter, B, Ludes, B, Maroñas, O, Morling, N, Niederstätter, H, Parson, W, Patel, G, Popielarz, C, Salata, E, Schneider, Peter M., Sijen, T, Sviezená, B, Zatkalíková, L, and Ballantyne, J

Abstract

Udgivelsesdato: 2010-Feb-6, A collaborative exercise on mRNA profiling for the identification of blood was organized by the European DNA Profiling Group (EDNAP). Seven blood samples and one blood dilution series were analyzed by the participating laboratories for the reportedly blood-specific markers HBB, SPTB and PBGD, using different kits, chemistries and instrumentation. The results demonstrate that HBB is expressed abundantly in blood, SPTB moderately and PBGD significantly less. All but one of the 16 participating laboratories were able to successfully isolate and detect RNA from the dried bloodstains even though a majority of the laboratories had no prior experience with RNA. Despite some expected variation in sensitivity between laboratories, the method proved to be reproducible and sensitive using different analysis strategies. The results of this collaborative exercise support the potential use of mRNA profiling as an alternative to conventional serological tests.

Published
2010

41. RDE-1 slicer activity is required only for passenger-strand cleavage during RNAi in Caenorhabditis elegans.

Author

Steiner, F.A., Okihara, K.L., Hoogstrate, S.W., Sijen, T., Ketting, R.F., Steiner, F.A., Okihara, K.L., Hoogstrate, S.W., Sijen, T., and Ketting, R.F.

Abstract

RNA interference (RNAi) is a process in which double-stranded RNA is cleaved into small interfering RNAs (siRNAs) that induce the destruction of homologous single-stranded mRNAs. Argonaute proteins are essential components of this silencing process; they bind siRNAs directly and can cleave RNA targets using a conserved RNase H motif. In Caenorhabditis elegans, the Argonaute protein RDE-1 has a central role in RNAi. In animals lacking RDE-1, the introduction of double-stranded RNA does not trigger any detectable level of RNAi. Here we show that RNase H activity of RDE-1 is required only for efficient removal of the passenger strand of the siRNA duplex and not for triggering the silencing response at the target-mRNA level. These results uncouple the role of the RDE-1 RNase H activity in small RNA maturation from its role in target-mRNA silencing in vivo., RNA interference (RNAi) is a process in which double-stranded RNA is cleaved into small interfering RNAs (siRNAs) that induce the destruction of homologous single-stranded mRNAs. Argonaute proteins are essential components of this silencing process; they bind siRNAs directly and can cleave RNA targets using a conserved RNase H motif. In Caenorhabditis elegans, the Argonaute protein RDE-1 has a central role in RNAi. In animals lacking RDE-1, the introduction of double-stranded RNA does not trigger any detectable level of RNAi. Here we show that RNase H activity of RDE-1 is required only for efficient removal of the passenger strand of the siRNA duplex and not for triggering the silencing response at the target-mRNA level. These results uncouple the role of the RDE-1 RNase H activity in small RNA maturation from its role in target-mRNA silencing in vivo.

Published
2009

43. Expression and silencing of cowpea mosaic virus transgenes

Author

Sijen, T., Agricultural University, A. van Kammen, and J. Wellink

Subjects
vigna, vignabonen, genetic engineering, genexpressie, cowpeas, recombinant dna, cowpea mosaic virus, pleiotropy, gene expression, genetische modificatie, Laboratorium voor Moleculaire Biologie, koebonenmozaïekvirus, Laboratory of Molecular Biology, pleiotropie, EPS
Abstract

Plant viruses are interesting pathogens because they can not exist without their hosts and exploit the plant machinery for their multiplication. Fundamental knowledge on viral processes is of great importance to understand, prevent and control virus infections which can cause drastic losses in crops. In this thesis, cowpea mosaic virus (CPMV) was studied. This virus consists of two, icosahedral particles that each carry a distinct single stranded RNA molecule of positive polarity. Several years of research have revealed much information on the genomic organisation, the strategy of gene expression and the multiplication processes of CPMV, which are described in Chapter 1, but also many aspects remain to be elucidated.To study individual viral processes, like replication, encapsidation or cell to cell movement, transgenic plants can be generated that express individual viral genes like the replicase, coat protein or movement protein gene. A prerequisite in this approach is the presence of an efficient and reliable plant regeneration and transformation system. (CPMV) 5 natural host is the tropical grain legume cowpea, Vigna unguiculata, a plant species that is recalcitrant at regeneration. Although in experiments described in Chapter 2 fertile plants could be regenerated from nodal thin cell layer segments, the explants were not competent for Agrobacterium-mediated transformation. Possibly in further studies, these nodal explants could prove suited for another transformation method.Therefore, tobacco, which is also a host for CPMV and highly competent for regeneration and transformation, was preferred as the species to generate transgenic plants carrying CPMV specific genes. Especially the CPMV movement proteins (MP) genes appealed to us for overexpression studies. CPMV cell to cell movement is enabled by the CPMV MPs that act to modify plasmodesmata. They are assumed to channel plasmodesmata with MP-containing tubular structures and through or with these tubules virus particles are transported to adjacent cells. To obtain more information on the plasmodesmatal modifications brought about by the MPs, transgenic tobacco plants were generated that carried the MP gene under the control of either a constitutive or an inducible 35S promoter. However, in none of these plants the MPs were expressed to detectable levels (Chapter 3). Using the potato virus X (PVX)-based expression vector, accumulation of CPMV MPs was observed in the form of tubular structures extending from the surface of infected protoplasts into the medium. These PVX-derivatives look promising for providing effective tools in future studies on the effects of the CPMV MPs in plants.Studies on MP functioning could involve complementation experiments with a CPMV mutant that is defective in cell to cell movement. In experiments described in Chapter 4 is was analysed by a molecular approach whether the CPMV mutant N123, that was first described in 1976, could be used to this effect. As the basis of the N123 specific phenotype was found not only to rest in the movement protein gene but also in one of the two coat protein genes, this mutant seemed not very suitable for complementation studies. Presumably a recently developed CPMV mutant in which the MP gene has been replaced by the fluorescent marker protein GFP (green fluorescent protein), will be a more appropriate tool.Transgenic Nicotiana benthamiana plants that were expressing either the CPMV MP or the replicase gene under the control of a constitutive promoter, were found to exhibit a resistant phenotype when inoculated with CPMV (Chapter 5). Protoplast studies revealed that the resistance occurred as full immunity and was maintained in the cell. Resistance was specific to viruses highly homologous to CPMV, and in addition it was found to be specifically directed against the replication of the CPMV segment of which the transgene was derived (Chapter 5). Pathogen derived resistance can be mediated either by the protein encoded by the transgene or by the transcribed mRNA. Protein -mediated resistance generally offers moderate protection against a broad range of viruses, while RNA-mediated resistance results in immunity at the cellular level. Resistance obtained in transgenic plants transformed with defective genes confirmed that an RNA-based mechanism was underlying the highly specific transgenic resistance against CPMV (Chapter 6).Specifically in the resistant lines, the transgene mRNA steady state levels were low compared to the relative transgene nuclear transcription rates (Chapter 6). This indicated that resistance occurs from a specific, cytoplasmic RNA turnover mechanism. This process can be regarded as a post- transcriptional gene-silencing process, that is primarily induced on the transgene mRNAs but to which also incoming, homologous CPMV genomes fall victim. In addition, heterologous RNA molecules, like PVX genomes, that contain the sequences corresponding to the transgene, are eliminated (Chapter 6). By inserting sequences homologous to only parts of the transgene in the genome of PVX and studying the fate of these recombinant genomes, it was shown that the degradation process is primarily targeted to a defined region of the transgene mRNA, the 3' region. Further analyses revealed that degradation can occur at various sites within this 3' region and that not a specific sequence or structure is of predominant importance. We observed that small inserts, like of only 60 nucleotides, can tag recombinant PVX molecules for the elimination process, albeit with reduced efficiency, which suggested that the RNA turnover process carries quantitative features.On the intruiging question why post-transcriptional gene-silencing is induced in only some of the transgenic lines, we revealed (Chapter 6) that the organisation of integrated transgene sequences has an important role. Transformation with a transgene containing a directly repeated MP gene, increased the frequency at which resistant lines arise to 60%, compared to 20% of resistant lines that occur upon transformation with a transgene with a single MP gene. Thus, the resistance process seems influenced by qualitative features of the integrated transgenes. Also, it was observed that resistance concurred with extensive methylation at the transcribed transgene sequences (Chapter 6), which could indicate an essential role of methylation at transcribed sequences in obtaining RNA-mediated pathogen derived resistance.From these observations and from data described in literature, a model for RNA-mediated virus resistance was made and presented in Chapter 6. In Chapter 7, the post-transcriptional gene-silencing phenomenon is discussed in more details and in addition an approach is presented by which the process could be exploited to efficiently engineer virus resistance or study plant gene expression.

Published
1997

47. Transcriptional and posttranscriptional gene silencing are mechanistically related

Author

Sijen, T., Vijn, I., Rebocho, A., van Blokland, R., Roelofs, D., Mol, J.N.M., Kooter, J.M., Sijen, T., Vijn, I., Rebocho, A., van Blokland, R., Roelofs, D., Mol, J.N.M., and Kooter, J.M.

Abstract

Two distinct gene-silencing phenomena are observed in plants: transcriptional gene silencing (TGS), which involves decreased RNA synthesis because of promoter methylation, and posttranscriptional gene silencing (PTGS), which involves sequence-specific RNA degradation. PTGS is induced by deliberate [1-4] or fortuitous production (R.v.B., unpublished data) of double-stranded RNA (dsRNA). TGS could be the result of DNA pairing [5], but could also be the result of dsRNA, as was shown by the dsRNA-induced inactivation of a transgenic promoter [6]. Here, we show that when targeting flower pigmentation genes in Petunia, transgenes expressing dsRNA can induce PTGS when coding sequences are used and TGS when promoter sequences are taken. For both types of silencing, small RNA species are found, which are thought to be dsRNA decay products [7] and determine the sequence specificity of the silencing process [8, 9]. Furthermore, silencing is accompanied by the methylation of DNA sequences that are homologous to dsRNA. DNA methylation is assumed to be essential for regulating TGS and important for reinforcing PTGS [10]. Therefore, we conclude that TGS and PTGS are mechanistically related. In addition, we show that dsRNA-induced TGS provides an efficient tool to generate gene knockouts, because not only does the TGS of a PTGS-inducing transgene fully revert the PTGS phenotype, but also an endogenous gene can be transcriptionally silenced by dsRNA corresponding to its promoter.

Published
2001

48. Expression and silencing of cowpea mosaic virus transgenes

Author

van Kammen, A., Wellink, J., Sijen, T., van Kammen, A., Wellink, J., and Sijen, T.

Abstract

Plant viruses are interesting pathogens because they can not exist without their hosts and exploit the plant machinery for their multiplication. Fundamental knowledge on viral processes is of great importance to understand, prevent and control virus infections which can cause drastic losses in crops. In this thesis, cowpea mosaic virus (CPMV) was studied. This virus consists of two, icosahedral particles that each carry a distinct single stranded RNA molecule of positive polarity. Several years of research have revealed much information on the genomic organisation, the strategy of gene expression and the multiplication processes of CPMV, which are described in Chapter 1, but also many aspects remain to be elucidated.To study individual viral processes, like replication, encapsidation or cell to cell movement, transgenic plants can be generated that express individual viral genes like the replicase, coat protein or movement protein gene. A prerequisite in this approach is the presence of an efficient and reliable plant regeneration and transformation system. (CPMV) 5 natural host is the tropical grain legume cowpea, Vigna unguiculata, a plant species that is recalcitrant at regeneration. Although in experiments described in Chapter 2 fertile plants could be regenerated from nodal thin cell layer segments, the explants were not competent for Agrobacterium-mediated transformation. Possibly in further studies, these nodal explants could prove suited for another transformation method.Therefore, tobacco, which is also a host for CPMV and highly competent for regeneration and transformation, was preferred as the species to generate transgenic plants carrying CPMV specific genes. Especially the CPMV movement proteins (MP) genes appealed to us for overexpression studies. CPMV cell to cell movement is enabled by the CPMV MPs that act to modify plasmodesmata. They are assumed to channel plasmodesmata with MP-containing tubular structures and through or with these tubules virus

Published
1997

50. Dicer functions in RNA interference and in synthesis of small RNA involved in developmental timing in C. elegans.

Author

Ketting, R F, Fischer, S E, Bernstein, E, Sijen, T, Hannon, G J, and Plasterk, R H

Abstract

Double-stranded RNAs can suppress expression of homologous genes through an evolutionarily conserved process named RNA interference (RNAi) or post-transcriptional gene silencing (PTGS). One mechanism underlying silencing is degradation of target mRNAs by an RNP complex, which contains approximately 22 nt of siRNAs as guides to substrate selection. A bidentate nuclease called Dicer has been implicated as the protein responsible for siRNA production. Here we characterize the Caenorhabditis elegans ortholog of Dicer (K12H4.8; dcr-1) in vivo and in vitro. dcr-1 mutants show a defect in RNAi. Furthermore, a combination of phenotypic abnormalities and RNA analysis suggests a role for dcr-1 in a regulatory pathway comprised of small temporal RNA (let-7) and its target (e.g., lin-41).

Published
2001
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results