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2. High-throughput target-selected gene inactivation in zebrafish

Author

Kettleborough, R.N., de Bruijn, E., van Eeden, F.J., Cuppen, E., Stemple, D.L., and Hubrecht Institute for Developmental Biology and Stem Cell Research

Abstract

There is an increasing requirement for efficient reverse genetics in the zebrafish, Here we describe a method that takes advantage of conventional mutagenized libraries (identical to ones used in forward screens) and re-sequencing to identify ENU-induced mutations in genes of interest. The efficiency of TILLING (Targeting Induced Local Legions IN Genomes) depends on the rate of mutagenesis in the library being screened, the amount of base pairs screened, and the ability to effectively identify and retrieve mutations on interest. Here we show that by improving the mutagenesis protocol, using in silico methods to predict codon changes for target selection, efficient PCR and re-sequencing, and accurate mutation detection we can vastly improve current TILLING protocols. Importantly it is also possible to use this method for screening for splice and mis-sense mutations, and with even a relatively small library, there is a high chance of identifying mutations across any given gene.

Published
2011

3. Single nucleotide polymorphism (SNP) panels for rapid positional cloning in zebrafish

Author

Clark, M.D., Guryev, V., de Bruijn, E., Nijman, I.J., Tada, M., Wilson, C., Deloukas, P., Postlethwait, J.H., Cuppen, E., Stemple, D.L., and Hubrecht Institute for Developmental Biology and Stem Cell Research

Subjects
ComputingMethodologies_PATTERNRECOGNITION
Abstract

Despite considerable genetic and genomic resources the positional cloning of forward mutations remains a slow and manually intensive task, typically using gel based genotyping and sequential rounds of mapping. We have used the latest genetic resources and genotyping technologies to develop two commercially available SNP panels of thousands of markers that can be used to speed up positional cloning.

Published
2011

5. Mutations in GDP-mannose pyrophosphorylase B cause congenital and limb-girdle muscular dystrophies associated with hypoglycosylation of alpha-dystroglycan

Author

Carss, K.J., Stevens, E., Foley, A.R., Cirak, S., Riemersma, M., Torelli, S., Hoischen, A., Willer, T., Scherpenzeel, M. van, Moore, S.A., Messina, S., Bertini, E., Bonnemann, C.G., Abdenur, J.E., Grosmann, C.M., Kesari, A., Punetha, J., Quinlivan, R., Waddell, L.B., Young, H.K., Wraige, E., Yau, S., Brodd, L., Feng, L., Sewry, C., MacArthur, D.G., North, K.N., Hoffman, E., Stemple, D.L., Hurles, M.E., Bokhoven, H. van, Campbell, K.P., Lefeber, D.J., Lin, Y.Y., Muntoni, F., et al., Carss, K.J., Stevens, E., Foley, A.R., Cirak, S., Riemersma, M., Torelli, S., Hoischen, A., Willer, T., Scherpenzeel, M. van, Moore, S.A., Messina, S., Bertini, E., Bonnemann, C.G., Abdenur, J.E., Grosmann, C.M., Kesari, A., Punetha, J., Quinlivan, R., Waddell, L.B., Young, H.K., Wraige, E., Yau, S., Brodd, L., Feng, L., Sewry, C., MacArthur, D.G., North, K.N., Hoffman, E., Stemple, D.L., Hurles, M.E., Bokhoven, H. van, Campbell, K.P., Lefeber, D.J., Lin, Y.Y., Muntoni, F., and et al.

Abstract

Item does not contain fulltext, Congenital muscular dystrophies with hypoglycosylation of alpha-dystroglycan (alpha-DG) are a heterogeneous group of disorders often associated with brain and eye defects in addition to muscular dystrophy. Causative variants in 14 genes thought to be involved in the glycosylation of alpha-DG have been identified thus far. Allelic mutations in these genes might also cause milder limb-girdle muscular dystrophy phenotypes. Using a combination of exome and Sanger sequencing in eight unrelated individuals, we present evidence that mutations in guanosine diphosphate mannose (GDP-mannose) pyrophosphorylase B (GMPPB) can result in muscular dystrophy variants with hypoglycosylated alpha-DG. GMPPB catalyzes the formation of GDP-mannose from GTP and mannose-1-phosphate. GDP-mannose is required for O-mannosylation of proteins, including alpha-DG, and it is the substrate of cytosolic mannosyltransferases. We found reduced alpha-DG glycosylation in the muscle biopsies of affected individuals and in available fibroblasts. Overexpression of wild-type GMPPB in fibroblasts from an affected individual partially restored glycosylation of alpha-DG. Whereas wild-type GMPPB localized to the cytoplasm, five of the identified missense mutations caused formation of aggregates in the cytoplasm or near membrane protrusions. Additionally, knockdown of the GMPPB ortholog in zebrafish caused structural muscle defects with decreased motility, eye abnormalities, and reduced glycosylation of alpha-DG. Together, these data indicate that GMPPB mutations are responsible for congenital and limb-girdle muscular dystrophies with hypoglycosylation of alpha-DG.

Published
2013

6. Missense mutations in beta-1,3-N-acetylglucosaminyltransferase 1 (B3GNT1) cause Walker-Warburg syndrome

Author

Buysse, K., Riemersma, M., Powell, G., Reeuwijk, J. van, Chitayat, D., Roscioli, T., Kamsteeg, E.J., Elzen, C. van den, Beusekom, E. van, Blaser, S., Babul-Hirji, R., Halliday, W., Wright, G.J., Stemple, D.L., Lin, Y.Y., Lefeber, D.J., Bokhoven, J.H.L.M. van, Buysse, K., Riemersma, M., Powell, G., Reeuwijk, J. van, Chitayat, D., Roscioli, T., Kamsteeg, E.J., Elzen, C. van den, Beusekom, E. van, Blaser, S., Babul-Hirji, R., Halliday, W., Wright, G.J., Stemple, D.L., Lin, Y.Y., Lefeber, D.J., and Bokhoven, J.H.L.M. van

Abstract

Item does not contain fulltext, Several known or putative glycosyltransferases are required for the synthesis of laminin-binding glycans on alpha-dystroglycan (alphaDG), including POMT1, POMT2, POMGnT1, LARGE, Fukutin, FKRP, ISPD and GTDC2. Mutations in these glycosyltransferase genes result in defective alphaDG glycosylation and reduced ligand binding by alphaDG causing a clinically heterogeneous group of congenital muscular dystrophies, commonly referred to as dystroglycanopathies. The most severe clinical form, Walker-Warburg syndrome (WWS), is characterized by congenital muscular dystrophy and severe neurological and ophthalmological defects. Here, we report two homozygous missense mutations in the beta-1,3-N-acetylglucosaminyltransferase 1 (B3GNT1) gene in a family affected with WWS. Functional studies confirmed the pathogenicity of the mutations. First, expression of wild-type but not mutant B3GNT1 in human prostate cancer (PC3) cells led to increased levels of alphaDG glycosylation. Second, morpholino knockdown of the zebrafish b3gnt1 orthologue caused characteristic muscular defects and reduced alphaDG glycosylation. These functional studies identify an important role of B3GNT1 in the synthesis of the uncharacterized laminin-binding glycan of alphaDG and implicate B3GNT1 as a novel causative gene for WWS.

Published
2013

7. The zebrafish reference genome sequence and its relationship to the human genome.

Author

Howe, K., Clark, M.D., Torroja, C.F., Torrance, J., Berthelot, C., Muffato, M., Collins, J.E., Humphray, S., McLaren, K., Matthews, L., McLaren, S., Sealy, I., Caccamo, M., Churcher, C., Scott, C., Barrett, J.C., Koch, R., Rauch, G.J., White, S., Chow, W., Kilian, B., Quintais, L.T., Guerra-Assuncao, J.A., Zhou, Y., Gu, Y., Yen, J., Vogel, J.H., Eyre, T., Redmond, S., Banerjee, R., Chi, J., Fu, B., Langley, E., Maguire, S.F., Laird, G.K., Lloyd, D., Kenyon, E., Donaldson, S., Sehra, H., Almeida-King, J., Loveland, J., Trevanion, S., Jones, M., Quail, M., Willey, D., Hunt, A., Burton, J., Sims, S., McLay, K., Plumb, B., Davis, J., Clee, C., Oliver, K., Clark, R., Riddle, C., Elliot, D., Threadgold, G., Harden, G., Ware, D., Mortimore, B., Kerry, G., Heath, P., Phillimore, B., Tracey, A., Corby, N., Dunn, M., Johnson, C., Wood, J., Clark, S., Pelan, S., Griffiths, G., Smith, M., Glithero, R., Howden, P., Barker, N., Stevens, C., Harley, J., Holt, K., Panagiotidis, G., Lovell, J., Beasley, H., Henderson, C., Gordon, D., Auger, K., Wright, D., Collins, J., Raisen, C., Dyer, L., Leung, K., Robertson, L., Ambridge, K., Leongamornlert, D., McGuire, S., Gilderthorp, R., Griffiths, C., Manthravadi, D., Nichol, S., Barker, G., Whitehead, S., Kay, M., Brown, J., Murnane, C., Gray, E., Humphries, M., Sycamore, N., Barker, D., Saunders, D., Wallis, J., Babbage, A., Hammond, S., Mashreghi-Mohammadi, M., Barr, L., Martin, S., Wray, P., Ellington, A., Matthews, N., Ellwood, M., Woodmansey, R., Clark, G., Cooper, J., Tromans, A., Grafham, D., Skuce, C., Pandian, R., Andrews, R., Harrison, E., Kimberley, A., Garnett, J., Fosker, N., Hall, R., Garner, P., Kelly, D., Bird, C., Palmer, S., Gehring, I., Berger, A., Dooley, C.M., Ersan-Urun, Z., Eser, C., Geiger, H., Geisler, M., Karotki, L., Kirn, A., Konantz, J., Konantz, M., Oberlander, M., Rudolph-Geiger, S., Teucke, M., Osoegawa, K., Zhu, B., rapp, A., Widaa, S., Langford, C., Yang, F., Carter, N.P., Harrow, J., Ning, Z., Herrero, J., Searle, S.M., Enright, A., Geisler, R., Plasterk, R.H.A., Lee, C., Westerfield, M., de Jong, P.J., Zon, L.I., Postlethwait, J.H., Nusslein-Volhard, C., Hubbard, T.J., Roest Crollius, H., Rogers, J., Stemple, D.L., Begum, S., Lloyd, C., Lanz, C., Raddatz, G., Schuster, S.C., Howe, K., Clark, M.D., Torroja, C.F., Torrance, J., Berthelot, C., Muffato, M., Collins, J.E., Humphray, S., McLaren, K., Matthews, L., McLaren, S., Sealy, I., Caccamo, M., Churcher, C., Scott, C., Barrett, J.C., Koch, R., Rauch, G.J., White, S., Chow, W., Kilian, B., Quintais, L.T., Guerra-Assuncao, J.A., Zhou, Y., Gu, Y., Yen, J., Vogel, J.H., Eyre, T., Redmond, S., Banerjee, R., Chi, J., Fu, B., Langley, E., Maguire, S.F., Laird, G.K., Lloyd, D., Kenyon, E., Donaldson, S., Sehra, H., Almeida-King, J., Loveland, J., Trevanion, S., Jones, M., Quail, M., Willey, D., Hunt, A., Burton, J., Sims, S., McLay, K., Plumb, B., Davis, J., Clee, C., Oliver, K., Clark, R., Riddle, C., Elliot, D., Threadgold, G., Harden, G., Ware, D., Mortimore, B., Kerry, G., Heath, P., Phillimore, B., Tracey, A., Corby, N., Dunn, M., Johnson, C., Wood, J., Clark, S., Pelan, S., Griffiths, G., Smith, M., Glithero, R., Howden, P., Barker, N., Stevens, C., Harley, J., Holt, K., Panagiotidis, G., Lovell, J., Beasley, H., Henderson, C., Gordon, D., Auger, K., Wright, D., Collins, J., Raisen, C., Dyer, L., Leung, K., Robertson, L., Ambridge, K., Leongamornlert, D., McGuire, S., Gilderthorp, R., Griffiths, C., Manthravadi, D., Nichol, S., Barker, G., Whitehead, S., Kay, M., Brown, J., Murnane, C., Gray, E., Humphries, M., Sycamore, N., Barker, D., Saunders, D., Wallis, J., Babbage, A., Hammond, S., Mashreghi-Mohammadi, M., Barr, L., Martin, S., Wray, P., Ellington, A., Matthews, N., Ellwood, M., Woodmansey, R., Clark, G., Cooper, J., Tromans, A., Grafham, D., Skuce, C., Pandian, R., Andrews, R., Harrison, E., Kimberley, A., Garnett, J., Fosker, N., Hall, R., Garner, P., Kelly, D., Bird, C., Palmer, S., Gehring, I., Berger, A., Dooley, C.M., Ersan-Urun, Z., Eser, C., Geiger, H., Geisler, M., Karotki, L., Kirn, A., Konantz, J., Konantz, M., Oberlander, M., Rudolph-Geiger, S., Teucke, M., Osoegawa, K., Zhu, B., rapp, A., Widaa, S., Langford, C., Yang, F., Carter, N.P., Harrow, J., Ning, Z., Herrero, J., Searle, S.M., Enright, A., Geisler, R., Plasterk, R.H.A., Lee, C., Westerfield, M., de Jong, P.J., Zon, L.I., Postlethwait, J.H., Nusslein-Volhard, C., Hubbard, T.J., Roest Crollius, H., Rogers, J., Stemple, D.L., Begum, S., Lloyd, C., Lanz, C., Raddatz, G., and Schuster, S.C.

Abstract

Zebrafish have become a popular organism for the study of vertebrate gene function. The virtually transparent embryos of this species, and the ability to accelerate genetic studies by gene knockdown or overexpression, have led to the widespread use of zebrafish in the detailed investigation of vertebrate gene function and increasingly, the study of human genetic disease. However, for effective modelling of human genetic disease it is important to understand the extent to which zebrafish genes and gene structures are related to orthologous human genes. To examine this, we generated a high-quality sequence assembly of the zebrafish genome, made up of an overlapping set of completely sequenced large-insert clones that were ordered and oriented using a high-resolution high-density meiotic map. Detailed automatic and manual annotation provides evidence of more than 26,000 protein-coding genes, the largest gene set of any vertebrate so far sequenced. Comparison to the human reference genome shows that approximately 70% of human genes have at least one obvious zebrafish orthologue. In addition, the high quality of this genome assembly provides a clearer understanding of key genomic features such as a unique repeat content, a scarcity of pseudogenes, an enrichment of zebrafish-specific genes on chromosome 4 and chromosomal regions that influence sex determination., Zebrafish have become a popular organism for the study of vertebrate gene function. The virtually transparent embryos of this species, and the ability to accelerate genetic studies by gene knockdown or overexpression, have led to the widespread use of zebrafish in the detailed investigation of vertebrate gene function and increasingly, the study of human genetic disease. However, for effective modelling of human genetic disease it is important to understand the extent to which zebrafish genes and gene structures are related to orthologous human genes. To examine this, we generated a high-quality sequence assembly of the zebrafish genome, made up of an overlapping set of completely sequenced large-insert clones that were ordered and oriented using a high-resolution high-density meiotic map. Detailed automatic and manual annotation provides evidence of more than 26,000 protein-coding genes, the largest gene set of any vertebrate so far sequenced. Comparison to the human reference genome shows that approximately 70% of human genes have at least one obvious zebrafish orthologue. In addition, the high quality of this genome assembly provides a clearer understanding of key genomic features such as a unique repeat content, a scarcity of pseudogenes, an enrichment of zebrafish-specific genes on chromosome 4 and chromosomal regions that influence sex determination.

Published
2013

8. A systematic genome-wide analysis of zebrafish protein-coding gene function

Author

Kettleborough, R.N., Busch-Nentwich, E.M., Harvey, S.A., Dooley, C.M., de Bruijn, E., van Eeden, F., Sealy, I., White, R.J., Herd, C., Nijman, I.J., Fenyes, F., Mehroke, S., Scahill, C., Gibbons, R., Wali, N., Carruthers, S., Hall, A., Yen, J., Cuppen, E., Stemple, D.L., Kettleborough, R.N., Busch-Nentwich, E.M., Harvey, S.A., Dooley, C.M., de Bruijn, E., van Eeden, F., Sealy, I., White, R.J., Herd, C., Nijman, I.J., Fenyes, F., Mehroke, S., Scahill, C., Gibbons, R., Wali, N., Carruthers, S., Hall, A., Yen, J., Cuppen, E., and Stemple, D.L.

Abstract

Since the publication of the human reference genome, the identities of specific genes associated with human diseases are being discovered at a rapid rate. A central problem is that the biological activity of these genes is often unclear. Detailed investigations in model vertebrate organisms, typically mice, have been essential for understanding the activities of many orthologues of these disease-associated genes. Although gene-targeting approaches and phenotype analysis have led to a detailed understanding of nearly 6,000 protein-coding genes, this number falls considerably short of the more than 22,000 mouse protein-coding genes. Similarly, in zebrafish genetics, one-by-one gene studies using positional cloning, insertional mutagenesis, antisense morpholino oligonucleotides, targeted re-sequencing, and zinc finger and TAL endonucleases have made substantial contributions to our understanding of the biological activity of vertebrate genes, but again the number of genes studied falls well short of the more than 26,000 zebrafish protein-coding genes. Importantly, for both mice and zebrafish, none of these strategies are particularly suited to the rapid generation of knockouts in thousands of genes and the assessment of their biological activity. Here we describe an active project that aims to identify and phenotype the disruptive mutations in every zebrafish protein-coding gene, using a well-annotated zebrafish reference genome sequence, high-throughput sequencing and efficient chemical mutagenesis. So far we have identified potentially disruptive mutations in more than 38% of all known zebrafish protein-coding genes. We have developed a multi-allelic phenotyping scheme to efficiently assess the effects of each allele during embryogenesis and have analysed the phenotypic consequences of over 1,000 alleles. All mutant alleles and data are available to the community and our phenotyping scheme is adaptable to phenotypic analysis beyond embryogenesis., Since the publication of the human reference genome, the identities of specific genes associated with human diseases are being discovered at a rapid rate. A central problem is that the biological activity of these genes is often unclear. Detailed investigations in model vertebrate organisms, typically mice, have been essential for understanding the activities of many orthologues of these disease-associated genes. Although gene-targeting approaches and phenotype analysis have led to a detailed understanding of nearly 6,000 protein-coding genes, this number falls considerably short of the more than 22,000 mouse protein-coding genes. Similarly, in zebrafish genetics, one-by-one gene studies using positional cloning, insertional mutagenesis, antisense morpholino oligonucleotides, targeted re-sequencing, and zinc finger and TAL endonucleases have made substantial contributions to our understanding of the biological activity of vertebrate genes, but again the number of genes studied falls well short of the more than 26,000 zebrafish protein-coding genes. Importantly, for both mice and zebrafish, none of these strategies are particularly suited to the rapid generation of knockouts in thousands of genes and the assessment of their biological activity. Here we describe an active project that aims to identify and phenotype the disruptive mutations in every zebrafish protein-coding gene, using a well-annotated zebrafish reference genome sequence, high-throughput sequencing and efficient chemical mutagenesis. So far we have identified potentially disruptive mutations in more than 38% of all known zebrafish protein-coding genes. We have developed a multi-allelic phenotyping scheme to efficiently assess the effects of each allele during embryogenesis and have analysed the phenotypic consequences of over 1,000 alleles. All mutant alleles and data are available to the community and our phenotyping scheme is adaptable to phenotypic analysis beyond embryogenesis.

Published
2013

9. Compound inheritance of a low-frequency regulatory SNP and a rare null mutation in exon-junction complex subunit RBM8A causes TAR syndrome

Author

Albers, C.A., Paul, D.S., Schulze, H., Freson, K., Stephens, J.C., Smethurst, P.A., Jolley, J.D., Cvejic, A., Kostadima, M., Bertone, P., Breuning, M.H., Debili, N., Deloukas, P., Favier, R., Fiedler, J., Hobbs, C.M., Huang, N., Hurles, M.E., Kiddle, G., Krapels, I., Nurden, P., Ruivenkamp, C.A., Sambrook, J.G., Smith, K., Stemple, D.L., Strauss, G., Thys, C., van Geet, C., Newbury-Ecob, R., Ouwehand, W.H., Ghevaert, C., Albers, C.A., Paul, D.S., Schulze, H., Freson, K., Stephens, J.C., Smethurst, P.A., Jolley, J.D., Cvejic, A., Kostadima, M., Bertone, P., Breuning, M.H., Debili, N., Deloukas, P., Favier, R., Fiedler, J., Hobbs, C.M., Huang, N., Hurles, M.E., Kiddle, G., Krapels, I., Nurden, P., Ruivenkamp, C.A., Sambrook, J.G., Smith, K., Stemple, D.L., Strauss, G., Thys, C., van Geet, C., Newbury-Ecob, R., Ouwehand, W.H., and Ghevaert, C.

Abstract

Item does not contain fulltext, The exon-junction complex (EJC) performs essential RNA processing tasks. Here, we describe the first human disorder, thrombocytopenia with absent radii (TAR), caused by deficiency in one of the four EJC subunits. Compound inheritance of a rare null allele and one of two low-frequency SNPs in the regulatory regions of RBM8A, encoding the Y14 subunit of EJC, causes TAR. We found that this inheritance mechanism explained 53 of 55 cases (P < 5 x 10(-228)) of the rare congenital malformation syndrome. Of the 53 cases with this inheritance pattern, 51 carried a submicroscopic deletion of 1q21.1 that has previously been associated with TAR, and two carried a truncation or frameshift null mutation in RBM8A. We show that the two regulatory SNPs result in diminished RBM8A transcription in vitro and that Y14 expression is reduced in platelets from individuals with TAR. Our data implicate Y14 insufficiency and, presumably, an EJC defect as the cause of TAR syndrome.

Published
2012

10. Mutations in ISPD cause Walker-Warburg syndrome and defective glycosylation of alpha-dystroglycan

Author

Roscioli, T., Kamsteeg, E.J., Buysse, K., Maystadt, I., Reeuwijk, J. van, Elzen, C. van den, van Beusekom, E., Riemersma, M., Pfundt, R., Peart-Vissers, L.E.L.M., Schraders, M., Altunoglu, U., Buckley, M.F., Brunner, H.G., Grisart, B., Zhou, H., Veltman, J.A., Gilissen, C.F.H.A., Mancini, G.M.S., Delree, P., Willemsen, M.A.A.P., Ramadza, D.P., Chitayat, D., Bennett, C., Sheridan, E., Peeters, E.A., Tan-Sindhunata, G.M., de Die-Smulders, C.E., Devriendt, K., Kayserili, H., El-Hashash, O.A., Stemple, D.L., Lefeber, D.J., Lin, Y.Y., Bokhoven, J.H.L.M. van, Roscioli, T., Kamsteeg, E.J., Buysse, K., Maystadt, I., Reeuwijk, J. van, Elzen, C. van den, van Beusekom, E., Riemersma, M., Pfundt, R., Peart-Vissers, L.E.L.M., Schraders, M., Altunoglu, U., Buckley, M.F., Brunner, H.G., Grisart, B., Zhou, H., Veltman, J.A., Gilissen, C.F.H.A., Mancini, G.M.S., Delree, P., Willemsen, M.A.A.P., Ramadza, D.P., Chitayat, D., Bennett, C., Sheridan, E., Peeters, E.A., Tan-Sindhunata, G.M., de Die-Smulders, C.E., Devriendt, K., Kayserili, H., El-Hashash, O.A., Stemple, D.L., Lefeber, D.J., Lin, Y.Y., and Bokhoven, J.H.L.M. van

Abstract

Contains fulltext : 108772.pdf (publisher's version ) (Closed access), Walker-Warburg syndrome (WWS) is an autosomal recessive multisystem disorder characterized by complex eye and brain abnormalities with congenital muscular dystrophy (CMD) and aberrant a-dystroglycan glycosylation. Here we report mutations in the ISPD gene (encoding isoprenoid synthase domain containing) as the second most common cause of WWS. Bacterial IspD is a nucleotidyl transferase belonging to a large glycosyltransferase family, but the role of the orthologous protein in chordates is obscure to date, as this phylum does not have the corresponding non-mevalonate isoprenoid biosynthesis pathway. Knockdown of ispd in zebrafish recapitulates the human WWS phenotype with hydrocephalus, reduced eye size, muscle degeneration and hypoglycosylated a-dystroglycan. These results implicate ISPD in a-dystroglycan glycosylation in maintaining sarcolemma integrity in vertebrates.

Published
2012

14. Mutations affecting the formation and function of the cardiovascular system in the zebrafish embryo

Author

Stainier, D.Y., primary, Fouquet, B., additional, Chen, J.N., additional, Warren, K.S., additional, Weinstein, B.M., additional, Meiler, S.E., additional, Mohideen, M.A., additional, Neuhauss, S.C., additional, Solnica-Krezel, L., additional, Schier, A.F., additional, Zwartkruis, F., additional, Stemple, D.L., additional, Malicki, J., additional, Driever, W., additional, and Fishman, M.C., additional

Published
1996
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16. Mutations affecting neural survival in the zebrafish Danio rerio

Author

Abdelilah, S., primary, Mountcastle-Shah, E., additional, Harvey, M., additional, Solnica-Krezel, L., additional, Schier, A.F., additional, Stemple, D.L., additional, Malicki, J., additional, Neuhauss, S.C., additional, Zwartkruis, F., additional, Stainier, D.Y., additional, Rangini, Z., additional, and Driever, W., additional

Published
1996
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18. Hematopoietic mutations in the zebrafish

Author

Weinstein, B.M., primary, Schier, A.F., additional, Abdelilah, S., additional, Malicki, J., additional, Solnica-Krezel, L., additional, Stemple, D.L., additional, Stainier, D.Y., additional, Zwartkruis, F., additional, Driever, W., additional, and Fishman, M.C., additional

Published
1996
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20. A genetic screen for mutations affecting embryogenesis in zebrafish

Author

Driever, W., primary, Solnica-Krezel, L., additional, Schier, A.F., additional, Neuhauss, S.C., additional, Malicki, J., additional, Stemple, D.L., additional, Stainier, D.Y., additional, Zwartkruis, F., additional, Abdelilah, S., additional, Rangini, Z., additional, Belak, J., additional, and Boggs, C., additional

Published
1996
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21. Mutations affecting development of the notochord in zebrafish

Author

Stemple, D.L., primary, Solnica-Krezel, L., additional, Zwartkruis, F., additional, Neuhauss, S.C., additional, Schier, A.F., additional, Malicki, J., additional, Stainier, D.Y., additional, Abdelilah, S., additional, Rangini, Z., additional, Mountcastle-Shah, E., additional, and Driever, W., additional

Published
1996
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22. Mutations affecting the development of the embryonic zebrafish brain

Author

Schier, A.F., primary, Neuhauss, S.C., additional, Harvey, M., additional, Malicki, J., additional, Solnica-Krezel, L., additional, Stainier, D.Y., additional, Zwartkruis, F., additional, Abdelilah, S., additional, Stemple, D.L., additional, Rangini, Z., additional, Yang, H., additional, and Driever, W., additional

Published
1996
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23. Characterization of the microtubule movement produced by sea urchin egg kinesin.

Author

Porter, M.E., Scholey, J.M., Stemple, D.L., Vigers, G.P., Vale, R.D., Sheetz, M.P., and McIntosh, J.R.

Abstract

We have used an in vitro assay to characterize some of the motile properties of sea urchin egg kinesin. Egg kinesin is purified via 5'-adenylyl imidodiphosphate-induced binding to taxol-assembled microtubules, extraction from the microtubules in ATP, and gel filtration chromatography (Scholey, J. M., Porter, M. E., Grissom, P. M., and McIntosh, J. R. (1985) Nature 318, 483-486). This partially purified kinesin is then adsorbed to a glass coverslip, mixed with microtubules and ATP, and viewed by video-enhanced differential interference contrast microscopy. The microtubule translocating activity of the purified egg kinesin is qualitatively similar to the analogous activity observed in crude extracts of sea urchin eggs and resembles the activity of neuronal kinesin with respect to both the maximal rate (greater than 0.5 micron/s) and the direction of movement. Axonemes glide on a kinesin-coated coverslip toward their minus ends, and kinesin-coated beads translocate toward the plus ends of centrosome microtubules. Sea urchin egg kinesin is inhibited by high concentrations of SH reagents ([N-ethylmaleimide] greater than 3-5 mM), vanadate greater than 50 microM, and [nonhydrolyzable nucleotides] greater than or equal to [MgATP]. The nucleotide requirement of sea urchin egg kinesin is fairly broad (ATP greater than GTP greater than ITP), and the rate of microtubule movement increases in a saturable fashion with the [ATP]. We conclude that the motile activity of egg kinesin is indistinguishable from that of neuronal kinesin. We propose that egg kinesin may be associated with microtubule-based motility in vivo.

Published
1987
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