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2. The DNA sequence and biological annotation of human chromosome 1.

Author

Gregory SG, Barlow KF, McLay KE, Kaul R, Swarbreck D, Dunham A, Scott CE, Howe KL, Woodfine K, Spencer CC, Jones MC, Gillson C, Searle S, Zhou Y, Kokocinski F, McDonald L, Evans R, Phillips K, Atkinson A, Cooper R, Jones C, Hall RE, Andrews TD, Lloyd C, Ainscough R, Almeida JP, Ambrose KD, Anderson F, Andrew RW, Ashwell RI, Aubin K, Babbage AK, Bagguley CL, Bailey J, Beasley H, Bethel G, Bird CP, Bray-Allen S, Brown JY, Brown AJ, Buckley D, Burton J, Bye J, Carder C, Chapman JC, Clark SY, Clarke G, Clee C, Cobley V, Collier RE, Corby N, Coville GJ, Davies J, Deadman R, Dunn M, Earthrowl M, Ellington AG, Errington H, Frankish A, Frankland J, French L, Garner P, Garnett J, Gay L, Ghori MR, Gibson R, Gilby LM, Gillett W, Glithero RJ, Grafham DV, Griffiths C, Griffiths-Jones S, Grocock R, Hammond S, Harrison ES, Hart E, Haugen E, Heath PD, Holmes S, Holt K, Howden PJ, Hunt AR, Hunt SE, Hunter G, Isherwood J, James R, Johnson C, Johnson D, Joy A, Kay M, Kershaw JK, Kibukawa M, Kimberley AM, King A, Knights AJ, Lad H, Laird G, Lawlor S, Leongamornlert DA, Lloyd DM, Loveland J, Lovell J, Lush MJ, Lyne R, Martin S, Mashreghi-Mohammadi M, Matthews L, Matthews NS, McLaren S, Milne S, Mistry S, Moore MJ, Nickerson T, O'Dell CN, Oliver K, Palmeiri A, Palmer SA, Parker A, Patel D, Pearce AV, Peck AI, Pelan S, Phelps K, Phillimore BJ, Plumb R, Rajan J, Raymond C, Rouse G, Saenphimmachak C, Sehra HK, Sheridan E, Shownkeen R, Sims S, Skuce CD, Smith M, Steward C, Subramanian S, Sycamore N, Tracey A, Tromans A, Van Helmond Z, Wall M, Wallis JM, White S, Whitehead SL, Wilkinson JE, Willey DL, Williams H, Wilming L, Wray PW, Wu Z, Coulson A, Vaudin M, Sulston JE, Durbin R, Hubbard T, Wooster R, Dunham I, Carter NP, McVean G, Ross MT, Harrow J, Olson MV, Beck S, Rogers J, Bentley DR, Banerjee R, Bryant SP, Burford DC, Burrill WD, Clegg SM, Dhami P, Dovey O, Faulkner LM, Gribble SM, Langford CF, Pandian RD, Porter KM, and Prigmore E

Subjects
Base Sequence, DNA Replication Timing, Disease, Gene Duplication, Genes genetics, Genetic Variation genetics, Genomics, Humans, Molecular Sequence Data, Open Reading Frames genetics, Pseudogenes genetics, Recombination, Genetic genetics, Selection, Genetic, Sequence Analysis, DNA, Chromosomes, Human, Pair 1 genetics
Abstract

The reference sequence for each human chromosome provides the framework for understanding genome function, variation and evolution. Here we report the finished sequence and biological annotation of human chromosome 1. Chromosome 1 is gene-dense, with 3,141 genes and 991 pseudogenes, and many coding sequences overlap. Rearrangements and mutations of chromosome 1 are prevalent in cancer and many other diseases. Patterns of sequence variation reveal signals of recent selection in specific genes that may contribute to human fitness, and also in regions where no function is evident. Fine-scale recombination occurs in hotspots of varying intensity along the sequence, and is enriched near genes. These and other studies of human biology and disease encoded within chromosome 1 are made possible with the highly accurate annotated sequence, as part of the completed set of chromosome sequences that comprise the reference human genome.

Published
2006
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3. Genomics in C. elegans: so many genes, such a little worm.

Author

Hillier LW, Coulson A, Murray JI, Bao Z, Sulston JE, and Waterston RH

Subjects
Animals, DNA, Helminth chemistry, DNA, Helminth genetics, Evolution, Molecular, Gene Expression Regulation, Genomics trends, Proteomics methods, Proteomics trends, Sequence Analysis, DNA, Caenorhabditis elegans genetics, Genome, Helminth, Genomics methods
Abstract

The Caenorhabditis elegans genome sequence is now complete, fully contiguous telomere to telomere and totaling 100,291,840 bp. The sequence has catalyzed the collection of systematic data sets and analyses, including a curated set of 19,735 protein-coding genes--with >90% directly supported by experimental evidence--and >1300 noncoding RNA genes. High-throughput efforts are under way to complete the gene sets, along with studies to characterize gene expression, function, and regulation on a genome-wide scale. The success of the worm project has had a profound effect on genome sequencing and on genomics more broadly. We now have a solid platform on which to build toward the lofty goal of a true molecular understanding of worm biology with all its implications including those for human health.

Published
2005
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4. The DNA sequence of the human X chromosome.

Author

Ross MT, Grafham DV, Coffey AJ, Scherer S, McLay K, Muzny D, Platzer M, Howell GR, Burrows C, Bird CP, Frankish A, Lovell FL, Howe KL, Ashurst JL, Fulton RS, Sudbrak R, Wen G, Jones MC, Hurles ME, Andrews TD, Scott CE, Searle S, Ramser J, Whittaker A, Deadman R, Carter NP, Hunt SE, Chen R, Cree A, Gunaratne P, Havlak P, Hodgson A, Metzker ML, Richards S, Scott G, Steffen D, Sodergren E, Wheeler DA, Worley KC, Ainscough R, Ambrose KD, Ansari-Lari MA, Aradhya S, Ashwell RI, Babbage AK, Bagguley CL, Ballabio A, Banerjee R, Barker GE, Barlow KF, Barrett IP, Bates KN, Beare DM, Beasley H, Beasley O, Beck A, Bethel G, Blechschmidt K, Brady N, Bray-Allen S, Bridgeman AM, Brown AJ, Brown MJ, Bonnin D, Bruford EA, Buhay C, Burch P, Burford D, Burgess J, Burrill W, Burton J, Bye JM, Carder C, Carrel L, Chako J, Chapman JC, Chavez D, Chen E, Chen G, Chen Y, Chen Z, Chinault C, Ciccodicola A, Clark SY, Clarke G, Clee CM, Clegg S, Clerc-Blankenburg K, Clifford K, Cobley V, Cole CG, Conquer JS, Corby N, Connor RE, David R, Davies J, Davis C, Davis J, Delgado O, Deshazo D, Dhami P, Ding Y, Dinh H, Dodsworth S, Draper H, Dugan-Rocha S, Dunham A, Dunn M, Durbin KJ, Dutta I, Eades T, Ellwood M, Emery-Cohen A, Errington H, Evans KL, Faulkner L, Francis F, Frankland J, Fraser AE, Galgoczy P, Gilbert J, Gill R, Glöckner G, Gregory SG, Gribble S, Griffiths C, Grocock R, Gu Y, Gwilliam R, Hamilton C, Hart EA, Hawes A, Heath PD, Heitmann K, Hennig S, Hernandez J, Hinzmann B, Ho S, Hoffs M, Howden PJ, Huckle EJ, Hume J, Hunt PJ, Hunt AR, Isherwood J, Jacob L, Johnson D, Jones S, de Jong PJ, Joseph SS, Keenan S, Kelly S, Kershaw JK, Khan Z, Kioschis P, Klages S, Knights AJ, Kosiura A, Kovar-Smith C, Laird GK, Langford C, Lawlor S, Leversha M, Lewis L, Liu W, Lloyd C, Lloyd DM, Loulseged H, Loveland JE, Lovell JD, Lozado R, Lu J, Lyne R, Ma J, Maheshwari M, Matthews LH, McDowall J, McLaren S, McMurray A, Meidl P, Meitinger T, Milne S, Miner G, Mistry SL, Morgan M, Morris S, Müller I, Mullikin JC, Nguyen N, Nordsiek G, Nyakatura G, O'Dell CN, Okwuonu G, Palmer S, Pandian R, Parker D, Parrish J, Pasternak S, Patel D, Pearce AV, Pearson DM, Pelan SE, Perez L, Porter KM, Ramsey Y, Reichwald K, Rhodes S, Ridler KA, Schlessinger D, Schueler MG, Sehra HK, Shaw-Smith C, Shen H, Sheridan EM, Shownkeen R, Skuce CD, Smith ML, Sotheran EC, Steingruber HE, Steward CA, Storey R, Swann RM, Swarbreck D, Tabor PE, Taudien S, Taylor T, Teague B, Thomas K, Thorpe A, Timms K, Tracey A, Trevanion S, Tromans AC, d'Urso M, Verduzco D, Villasana D, Waldron L, Wall M, Wang Q, Warren J, Warry GL, Wei X, West A, Whitehead SL, Whiteley MN, Wilkinson JE, Willey DL, Williams G, Williams L, Williamson A, Williamson H, Wilming L, Woodmansey RL, Wray PW, Yen J, Zhang J, Zhou J, Zoghbi H, Zorilla S, Buck D, Reinhardt R, Poustka A, Rosenthal A, Lehrach H, Meindl A, Minx PJ, Hillier LW, Willard HF, Wilson RK, Waterston RH, Rice CM, Vaudin M, Coulson A, Nelson DL, Weinstock G, Sulston JE, Durbin R, Hubbard T, Gibbs RA, Beck S, Rogers J, and Bentley DR

Subjects
Animals, Antigens, Neoplasm genetics, Centromere genetics, Chromosomes, Human, Y genetics, Contig Mapping, Crossing Over, Genetic genetics, Dosage Compensation, Genetic, Female, Genetic Linkage genetics, Genetics, Medical, Humans, Male, Polymorphism, Single Nucleotide genetics, RNA genetics, Repetitive Sequences, Nucleic Acid genetics, Sequence Homology, Nucleic Acid, Testis metabolism, Chromosomes, Human, X genetics, Evolution, Molecular, Genomics, Sequence Analysis, DNA
Abstract

The human X chromosome has a unique biology that was shaped by its evolution as the sex chromosome shared by males and females. We have determined 99.3% of the euchromatic sequence of the X chromosome. Our analysis illustrates the autosomal origin of the mammalian sex chromosomes, the stepwise process that led to the progressive loss of recombination between X and Y, and the extent of subsequent degradation of the Y chromosome. LINE1 repeat elements cover one-third of the X chromosome, with a distribution that is consistent with their proposed role as way stations in the process of X-chromosome inactivation. We found 1,098 genes in the sequence, of which 99 encode proteins expressed in testis and in various tumour types. A disproportionately high number of mendelian diseases are documented for the X chromosome. Of this number, 168 have been explained by mutations in 113 X-linked genes, which in many cases were characterized with the aid of the DNA sequence.

Published
2005
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5. DNA sequence and analysis of human chromosome 9.

Author

Humphray SJ, Oliver K, Hunt AR, Plumb RW, Loveland JE, Howe KL, Andrews TD, Searle S, Hunt SE, Scott CE, Jones MC, Ainscough R, Almeida JP, Ambrose KD, Ashwell RI, Babbage AK, Babbage S, Bagguley CL, Bailey J, Banerjee R, Barker DJ, Barlow KF, Bates K, Beasley H, Beasley O, Bird CP, Bray-Allen S, Brown AJ, Brown JY, Burford D, Burrill W, Burton J, Carder C, Carter NP, Chapman JC, Chen Y, Clarke G, Clark SY, Clee CM, Clegg S, Collier RE, Corby N, Crosier M, Cummings AT, Davies J, Dhami P, Dunn M, Dutta I, Dyer LW, Earthrowl ME, Faulkner L, Fleming CJ, Frankish A, Frankland JA, French L, Fricker DG, Garner P, Garnett J, Ghori J, Gilbert JG, Glison C, Grafham DV, Gribble S, Griffiths C, Griffiths-Jones S, Grocock R, Guy J, Hall RE, Hammond S, Harley JL, Harrison ES, Hart EA, Heath PD, Henderson CD, Hopkins BL, Howard PJ, Howden PJ, Huckle E, Johnson C, Johnson D, Joy AA, Kay M, Keenan S, Kershaw JK, Kimberley AM, King A, Knights A, Laird GK, Langford C, Lawlor S, Leongamornlert DA, Leversha M, Lloyd C, Lloyd DM, Lovell J, Martin S, Mashreghi-Mohammadi M, Matthews L, McLaren S, McLay KE, McMurray A, Milne S, Nickerson T, Nisbett J, Nordsiek G, Pearce AV, Peck AI, Porter KM, Pandian R, Pelan S, Phillimore B, Povey S, Ramsey Y, Rand V, Scharfe M, Sehra HK, Shownkeen R, Sims SK, Skuce CD, Smith M, Steward CA, Swarbreck D, Sycamore N, Tester J, Thorpe A, Tracey A, Tromans A, Thomas DW, Wall M, Wallis JM, West AP, Whitehead SL, Willey DL, Williams SA, Wilming L, Wray PW, Young L, Ashurst JL, Coulson A, Blöcker H, Durbin R, Sulston JE, Hubbard T, Jackson MJ, Bentley DR, Beck S, Rogers J, and Dunham I

Subjects
Base Composition, Euchromatin genetics, Evolution, Molecular, Female, Gene Duplication, Genes, Duplicate genetics, Genetic Variation genetics, Genetics, Medical, Genomics, Heterochromatin genetics, Humans, Male, Neoplasms genetics, Neurodegenerative Diseases genetics, Pseudogenes genetics, Sequence Analysis, DNA, Sex Determination Processes, Chromosomes, Human, Pair 9 genetics, Genes, Physical Chromosome Mapping
Abstract

Chromosome 9 is highly structurally polymorphic. It contains the largest autosomal block of heterochromatin, which is heteromorphic in 6-8% of humans, whereas pericentric inversions occur in more than 1% of the population. The finished euchromatic sequence of chromosome 9 comprises 109,044,351 base pairs and represents >99.6% of the region. Analysis of the sequence reveals many intra- and interchromosomal duplications, including segmental duplications adjacent to both the centromere and the large heterochromatic block. We have annotated 1,149 genes, including genes implicated in male-to-female sex reversal, cancer and neurodegenerative disease, and 426 pseudogenes. The chromosome contains the largest interferon gene cluster in the human genome. There is also a region of exceptionally high gene and G + C content including genes paralogous to those in the major histocompatibility complex. We have also detected recently duplicated genes that exhibit different rates of sequence divergence, presumably reflecting natural selection.

Published
2004
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6. The DNA sequence and analysis of human chromosome 13.

Author

Dunham A, Matthews LH, Burton J, Ashurst JL, Howe KL, Ashcroft KJ, Beare DM, Burford DC, Hunt SE, Griffiths-Jones S, Jones MC, Keenan SJ, Oliver K, Scott CE, Ainscough R, Almeida JP, Ambrose KD, Andrews DT, Ashwell RI, Babbage AK, Bagguley CL, Bailey J, Bannerjee R, Barlow KF, Bates K, Beasley H, Bird CP, Bray-Allen S, Brown AJ, Brown JY, Burrill W, Carder C, Carter NP, Chapman JC, Clamp ME, Clark SY, Clarke G, Clee CM, Clegg SC, Cobley V, Collins JE, Corby N, Coville GJ, Deloukas P, Dhami P, Dunham I, Dunn M, Earthrowl ME, Ellington AG, Faulkner L, Frankish AG, Frankland J, French L, Garner P, Garnett J, Gilbert JG, Gilson CJ, Ghori J, Grafham DV, Gribble SM, Griffiths C, Hall RE, Hammond S, Harley JL, Hart EA, Heath PD, Howden PJ, Huckle EJ, Hunt PJ, Hunt AR, Johnson C, Johnson D, Kay M, Kimberley AM, King A, Laird GK, Langford CJ, Lawlor S, Leongamornlert DA, Lloyd DM, Lloyd C, Loveland JE, Lovell J, Martin S, Mashreghi-Mohammadi M, McLaren SJ, McMurray A, Milne S, Moore MJ, Nickerson T, Palmer SA, Pearce AV, Peck AI, Pelan S, Phillimore B, Porter KM, Rice CM, Searle S, Sehra HK, Shownkeen R, Skuce CD, Smith M, Steward CA, Sycamore N, Tester J, Thomas DW, Tracey A, Tromans A, Tubby B, Wall M, Wallis JM, West AP, Whitehead SL, Willey DL, Wilming L, Wray PW, Wright MW, Young L, Coulson A, Durbin R, Hubbard T, Sulston JE, Beck S, Bentley DR, Rogers J, and Ross MT

Subjects
Chromosome Mapping, Genetics, Medical, Humans, Pseudogenes genetics, RNA, Untranslated genetics, Sequence Analysis, DNA, Chromosomes, Human, Pair 13 genetics, Genes genetics, Physical Chromosome Mapping
Abstract

Chromosome 13 is the largest acrocentric human chromosome. It carries genes involved in cancer including the breast cancer type 2 (BRCA2) and retinoblastoma (RB1) genes, is frequently rearranged in B-cell chronic lymphocytic leukaemia, and contains the DAOA locus associated with bipolar disorder and schizophrenia. We describe completion and analysis of 95.5 megabases (Mb) of sequence from chromosome 13, which contains 633 genes and 296 pseudogenes. We estimate that more than 95.4% of the protein-coding genes of this chromosome have been identified, on the basis of comparison with other vertebrate genome sequences. Additionally, 105 putative non-coding RNA genes were found. Chromosome 13 has one of the lowest gene densities (6.5 genes per Mb) among human chromosomes, and contains a central region of 38 Mb where the gene density drops to only 3.1 genes per Mb.

Published
2004
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7. The DNA sequence and analysis of human chromosome 6.

Author

Mungall AJ, Palmer SA, Sims SK, Edwards CA, Ashurst JL, Wilming L, Jones MC, Horton R, Hunt SE, Scott CE, Gilbert JG, Clamp ME, Bethel G, Milne S, Ainscough R, Almeida JP, Ambrose KD, Andrews TD, Ashwell RI, Babbage AK, Bagguley CL, Bailey J, Banerjee R, Barker DJ, Barlow KF, Bates K, Beare DM, Beasley H, Beasley O, Bird CP, Blakey S, Bray-Allen S, Brook J, Brown AJ, Brown JY, Burford DC, Burrill W, Burton J, Carder C, Carter NP, Chapman JC, Clark SY, Clark G, Clee CM, Clegg S, Cobley V, Collier RE, Collins JE, Colman LK, Corby NR, Coville GJ, Culley KM, Dhami P, Davies J, Dunn M, Earthrowl ME, Ellington AE, Evans KA, Faulkner L, Francis MD, Frankish A, Frankland J, French L, Garner P, Garnett J, Ghori MJ, Gilby LM, Gillson CJ, Glithero RJ, Grafham DV, Grant M, Gribble S, Griffiths C, Griffiths M, Hall R, Halls KS, Hammond S, Harley JL, Hart EA, Heath PD, Heathcott R, Holmes SJ, Howden PJ, Howe KL, Howell GR, Huckle E, Humphray SJ, Humphries MD, Hunt AR, Johnson CM, Joy AA, Kay M, Keenan SJ, Kimberley AM, King A, Laird GK, Langford C, Lawlor S, Leongamornlert DA, Leversha M, Lloyd CR, Lloyd DM, Loveland JE, Lovell J, Martin S, Mashreghi-Mohammadi M, Maslen GL, Matthews L, McCann OT, McLaren SJ, McLay K, McMurray A, Moore MJ, Mullikin JC, Niblett D, Nickerson T, Novik KL, Oliver K, Overton-Larty EK, Parker A, Patel R, Pearce AV, Peck AI, Phillimore B, Phillips S, Plumb RW, Porter KM, Ramsey Y, Ranby SA, Rice CM, Ross MT, Searle SM, Sehra HK, Sheridan E, Skuce CD, Smith S, Smith M, Spraggon L, Squares SL, Steward CA, Sycamore N, Tamlyn-Hall G, Tester J, Theaker AJ, Thomas DW, Thorpe A, Tracey A, Tromans A, Tubby B, Wall M, Wallis JM, West AP, White SS, Whitehead SL, Whittaker H, Wild A, Willey DJ, Wilmer TE, Wood JM, Wray PW, Wyatt JC, Young L, Younger RM, Bentley DR, Coulson A, Durbin R, Hubbard T, Sulston JE, Dunham I, Rogers J, and Beck S

Subjects
Animals, Exons genetics, Genetic Diseases, Inborn genetics, HLA-B Antigens genetics, Humans, Pseudogenes genetics, RNA, Transfer genetics, Sequence Analysis, DNA, Chromosomes, Human, Pair 6 genetics, Genes genetics, Physical Chromosome Mapping
Abstract

Chromosome 6 is a metacentric chromosome that constitutes about 6% of the human genome. The finished sequence comprises 166,880,988 base pairs, representing the largest chromosome sequenced so far. The entire sequence has been subjected to high-quality manual annotation, resulting in the evidence-supported identification of 1,557 genes and 633 pseudogenes. Here we report that at least 96% of the protein-coding genes have been identified, as assessed by multi-species comparative sequence analysis, and provide evidence for the presence of further, otherwise unsupported exons/genes. Among these are genes directly implicated in cancer, schizophrenia, autoimmunity and many other diseases. Chromosome 6 harbours the largest transfer RNA gene cluster in the genome; we show that this cluster co-localizes with a region of high transcriptional activity. Within the essential immune loci of the major histocompatibility complex, we find HLA-B to be the most polymorphic gene on chromosome 6 and in the human genome.

Published
2003
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9. C. elegans: the cell lineage and beyond.

Author

Sulston JE

Subjects
Animals, Apoptosis physiology, Caenorhabditis elegans cytology, Caenorhabditis elegans genetics, Cell Differentiation physiology, Cell Lineage genetics, Databases, Genetic, Genome, Genomics, Larva cytology, Larva growth & development, Larva physiology, Morphogenesis physiology, Nervous System cytology, Nervous System Physiological Phenomena, Zygote cytology, Zygote growth & development, Zygote physiology, Caenorhabditis elegans growth & development, Cell Lineage physiology
Published
2003
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11. Sequence of Plasmodium falciparum chromosomes 1, 3-9 and 13.

Author

Hall N, Pain A, Berriman M, Churcher C, Harris B, Harris D, Mungall K, Bowman S, Atkin R, Baker S, Barron A, Brooks K, Buckee CO, Burrows C, Cherevach I, Chillingworth C, Chillingworth T, Christodoulou Z, Clark L, Clark R, Corton C, Cronin A, Davies R, Davis P, Dear P, Dearden F, Doggett J, Feltwell T, Goble A, Goodhead I, Gwilliam R, Hamlin N, Hance Z, Harper D, Hauser H, Hornsby T, Holroyd S, Horrocks P, Humphray S, Jagels K, James KD, Johnson D, Kerhornou A, Knights A, Konfortov B, Kyes S, Larke N, Lawson D, Lennard N, Line A, Maddison M, McLean J, Mooney P, Moule S, Murphy L, Oliver K, Ormond D, Price C, Quail MA, Rabbinowitsch E, Rajandream MA, Rutter S, Rutherford KM, Sanders M, Simmonds M, Seeger K, Sharp S, Smith R, Squares R, Squares S, Stevens K, Taylor K, Tivey A, Unwin L, Whitehead S, Woodward J, Sulston JE, Craig A, Newbold C, and Barrell BG

Subjects
Animals, Base Sequence, Chromosomes, Genes, Protozoan, Genome, Protozoan, Molecular Sequence Data, Multigene Family, Proteome, Protozoan Proteins genetics, Sequence Analysis, DNA, DNA, Protozoan, Plasmodium falciparum genetics
Abstract

Since the sequencing of the first two chromosomes of the malaria parasite, Plasmodium falciparum, there has been a concerted effort to sequence and assemble the entire genome of this organism. Here we report the sequence of chromosomes 1, 3-9 and 13 of P. falciparum clone 3D7--these chromosomes account for approximately 55% of the total genome. We describe the methods used to map, sequence and annotate these chromosomes. By comparing our assemblies with the optical map, we indicate the completeness of the resulting sequence. During annotation, we assign Gene Ontology terms to the predicted gene products, and observe clustering of some malaria-specific terms to specific chromosomes. We identify a highly conserved sequence element found in the intergenic region of internal var genes that is not associated with their telomeric counterparts.

Published
2002
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12. On the sequencing of the human genome.

Author

Waterston RH, Lander ES, and Sulston JE

Subjects
Chromosomes, Artificial, Bacterial genetics, Chromosomes, Human, Pair 22 genetics, Cloning, Molecular, Computer Simulation, Genomics methods, Humans, Models, Genetic, Physical Chromosome Mapping standards, Reproducibility of Results, Sequence Tagged Sites, Computational Biology methods, Genome, Human, Human Genome Project, Physical Chromosome Mapping methods, Sequence Analysis, DNA methods
Abstract

Two recent papers using different approaches reported draft sequences of the human genome. The international Human Genome Project (HGP) used the hierarchical shotgun approach, whereas Celera Genomics adopted the whole-genome shotgun (WGS) approach. Here, we analyze whether the latter paper provides a meaningful test of the WGS approach on a mammalian genome. In the Celera paper, the authors did not analyze their own WGS data. Instead, they decomposed the HGP's assembled sequence into a "perfect tiling path", combined it with their WGS data, and assembled the merged data set. To study the implications of this approach, we perform computational analysis and find that a perfect tiling path with 2-fold coverage is sufficient to recover virtually the entirety of a genome assembly. We also examine the manner in which the assembly was anchored to the human genome and conclude that the process primarily depended on the HGP's sequence-tagged site maps, BAC maps, and clone-based sequences. Our analysis indicates that the Celera paper provides neither a meaningful test of the WGS approach nor an independent sequence of the human genome. Our analysis does not imply that a WGS approach could not be successfully applied to assemble a draft sequence of a large mammalian genome, but merely that the Celera paper does not provide such evidence.

Published
2002
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13. The DNA sequence and comparative analysis of human chromosome 20.

Author

Deloukas P, Matthews LH, Ashurst J, Burton J, Gilbert JG, Jones M, Stavrides G, Almeida JP, Babbage AK, Bagguley CL, Bailey J, Barlow KF, Bates KN, Beard LM, Beare DM, Beasley OP, Bird CP, Blakey SE, Bridgeman AM, Brown AJ, Buck D, Burrill W, Butler AP, Carder C, Carter NP, Chapman JC, Clamp M, Clark G, Clark LN, Clark SY, Clee CM, Clegg S, Cobley VE, Collier RE, Connor R, Corby NR, Coulson A, Coville GJ, Deadman R, Dhami P, Dunn M, Ellington AG, Frankland JA, Fraser A, French L, Garner P, Grafham DV, Griffiths C, Griffiths MN, Gwilliam R, Hall RE, Hammond S, Harley JL, Heath PD, Ho S, Holden JL, Howden PJ, Huckle E, Hunt AR, Hunt SE, Jekosch K, Johnson CM, Johnson D, Kay MP, Kimberley AM, King A, Knights A, Laird GK, Lawlor S, Lehvaslaiho MH, Leversha M, Lloyd C, Lloyd DM, Lovell JD, Marsh VL, Martin SL, McConnachie LJ, McLay K, McMurray AA, Milne S, Mistry D, Moore MJ, Mullikin JC, Nickerson T, Oliver K, Parker A, Patel R, Pearce TA, Peck AI, Phillimore BJ, Prathalingam SR, Plumb RW, Ramsay H, Rice CM, Ross MT, Scott CE, Sehra HK, Shownkeen R, Sims S, Skuce CD, Smith ML, Soderlund C, Steward CA, Sulston JE, Swann M, Sycamore N, Taylor R, Tee L, Thomas DW, Thorpe A, Tracey A, Tromans AC, Vaudin M, Wall M, Wallis JM, Whitehead SL, Whittaker P, Willey DL, Williams L, Williams SA, Wilming L, Wray PW, Hubbard T, Durbin RM, Bentley DR, Beck S, and Rogers J

Subjects
Animals, Base Sequence, Computational Biology, Contig Mapping, DNA, Genetic Diseases, Inborn genetics, Genetic Variation, Humans, Mice, Physical Chromosome Mapping, Proteome, Sequence Analysis, DNA, Chromosomes, Human, Pair 20
Abstract

The finished sequence of human chromosome 20 comprises 59,187,298 base pairs (bp) and represents 99.4% of the euchromatic DNA. A single contig of 26 megabases (Mb) spans the entire short arm, and five contigs separated by gaps totalling 320 kb span the long arm of this metacentric chromosome. An additional 234,339 bp of sequence has been determined within the pericentromeric region of the long arm. We annotated 727 genes and 168 pseudogenes in the sequence. About 64% of these genes have a 5' and a 3' untranslated region and a complete open reading frame. Comparative analysis of the sequence of chromosome 20 to whole-genome shotgun-sequence data of two other vertebrates, the mouse Mus musculus and the puffer fish Tetraodon nigroviridis, provides an independent measure of the efficiency of gene annotation, and indicates that this analysis may account for more than 95% of all coding exons and almost all genes.

Published
2001
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14. The physical maps for sequencing human chromosomes 1, 6, 9, 10, 13, 20 and X.

Author

Bentley DR, Deloukas P, Dunham A, French L, Gregory SG, Humphray SJ, Mungall AJ, Ross MT, Carter NP, Dunham I, Scott CE, Ashcroft KJ, Atkinson AL, Aubin K, Beare DM, Bethel G, Brady N, Brook JC, Burford DC, Burrill WD, Burrows C, Butler AP, Carder C, Catanese JJ, Clee CM, Clegg SM, Cobley V, Coffey AJ, Cole CG, Collins JE, Conquer JS, Cooper RA, Culley KM, Dawson E, Dearden FL, Durbin RM, de Jong PJ, Dhami PD, Earthrowl ME, Edwards CA, Evans RS, Gillson CJ, Ghori J, Green L, Gwilliam R, Halls KS, Hammond S, Harper GL, Heathcott RW, Holden JL, Holloway E, Hopkins BL, Howard PJ, Howell GR, Huckle EJ, Hughes J, Hunt PJ, Hunt SE, Izmajlowicz M, Jones CA, Joseph SS, Laird G, Langford CF, Lehvaslaiho MH, Leversha MA, McCann OT, McDonald LM, McDowall J, Maslen GL, Mistry D, Moschonas NK, Neocleous V, Pearson DM, Phillips KJ, Porter KM, Prathalingam SR, Ramsey YH, Ranby SA, Rice CM, Rogers J, Rogers LJ, Sarafidou T, Scott DJ, Sharp GJ, Shaw-Smith CJ, Smink LJ, Soderlund C, Sotheran EC, Steingruber HE, Sulston JE, Taylor A, Taylor RG, Thorpe AA, Tinsley E, Warry GL, Whittaker A, Whittaker P, Williams SH, Wilmer TE, Wooster R, and Wright CL

Subjects
Humans, Chromosomes, Human, Pair 1, Chromosomes, Human, Pair 10, Chromosomes, Human, Pair 13, Chromosomes, Human, Pair 20, Chromosomes, Human, Pair 6, Contig Mapping, Genome, Human, X Chromosome
Abstract

We constructed maps for eight chromosomes (1, 6, 9, 10, 13, 20, X and (previously) 22), representing one-third of the genome, by building landmark maps, isolating bacterial clones and assembling contigs. By this approach, we could establish the long-range organization of the maps early in the project, and all contig extension, gap closure and problem-solving was simplified by containment within local regions. The maps currently represent more than 94% of the euchromatic (gene-containing) regions of these chromosomes in 176 contigs, and contain 96% of the chromosome-specific markers in the human gene map. By measuring the remaining gaps, we can assess chromosome length and coverage in sequenced clones.

Published
2001
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15. An SNP map of human chromosome 22.

Author

Mullikin JC, Hunt SE, Cole CG, Mortimore BJ, Rice CM, Burton J, Matthews LH, Pavitt R, Plumb RW, Sims SK, Ainscough RM, Attwood J, Bailey JM, Barlow K, Bruskiewich RM, Butcher PN, Carter NP, Chen Y, Clee CM, Coggill PC, Davies J, Davies RM, Dawson E, Francis MD, Joy AA, Lamble RG, Langford CF, Macarthy J, Mall V, Moreland A, Overton-Larty EK, Ross MT, Smith LC, Steward CA, Sulston JE, Tinsley EJ, Turney KJ, Willey DL, Wilson GD, McMurray AA, Dunham I, Rogers J, and Bentley DR

Subjects
Cell Line, Chromosome Mapping methods, Evaluation Studies as Topic, Gene Library, Genome, Human, Humans, Sequence Alignment, Chromosomes, Human, Pair 22, Polymorphism, Single Nucleotide, Sequence Analysis, DNA methods
Abstract

The human genome sequence will provide a reference for measuring DNA sequence variation in human populations. Sequence variants are responsible for the genetic component of individuality, including complex characteristics such as disease susceptibility and drug response. Most sequence variants are single nucleotide polymorphisms (SNPs), where two alternate bases occur at one position. Comparison of any two genomes reveals around 1 SNP per kilobase. A sufficiently dense map of SNPs would allow the detection of sequence variants responsible for particular characteristics on the basis that they are associated with a specific SNP allele. Here we have evaluated large-scale sequencing approaches to obtaining SNPs, and have constructed a map of 2,730 SNPs on human chromosome 22. Most of the SNPs are within 25 kilobases of a transcribed exon, and are valuable for association studies. We have scaled up the process, detecting over 65,000 SNPs in the genome as part of The SNP Consortium programme, which is on target to build a map of 1 SNP every 5 kilobases that is integrated with the human genome sequence and that is freely available in the public domain.

Published
2000
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16. The complete nucleotide sequence of chromosome 3 of Plasmodium falciparum.

Author

Bowman S, Lawson D, Basham D, Brown D, Chillingworth T, Churcher CM, Craig A, Davies RM, Devlin K, Feltwell T, Gentles S, Gwilliam R, Hamlin N, Harris D, Holroyd S, Hornsby T, Horrocks P, Jagels K, Jassal B, Kyes S, McLean J, Moule S, Mungall K, Murphy L, Oliver K, Quail MA, Rajandream MA, Rutter S, Skelton J, Squares R, Squares S, Sulston JE, Whitehead S, Woodward JR, Newbold C, and Barrell BG

Subjects
Animals, Base Sequence, Centromere, Chromosome Mapping, Chromosomes, DNA, Protozoan, Molecular Sequence Data, Protozoan Proteins genetics, Sequence Analysis, DNA, Telomere, Genome, Protozoan, Plasmodium falciparum genetics
Abstract

Analysis of Plasmodium falciparum chromosome 3, and comparison with chromosome 2, highlights novel features of chromosome organization and gene structure. The sub-telomeric regions of chromosome 3 show a conserved order of features, including repetitive DNA sequences, members of multigene families involved in pathogenesis and antigenic variation, a number of conserved pseudogenes, and several genes of unknown function. A putative centromere has been identified that has a core region of about 2 kilobases with an extremely high (adenine + thymidine) composition and arrays of tandem repeats. We have predicted 215 protein-coding genes and two transfer RNA genes in the 1,060,106-base-pair chromosome sequence. The predicted protein-coding genes can be divided into three main classes: 52.6% are not spliced, 45.1% have a large exon with short additional 5' or 3' exons, and 2.3% have a multiple exon structure more typical of higher eukaryotes.

Published
1999
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18. Deciphering the biology of Mycobacterium tuberculosis from the complete genome sequence.

Author

Cole ST, Brosch R, Parkhill J, Garnier T, Churcher C, Harris D, Gordon SV, Eiglmeier K, Gas S, Barry CE 3rd, Tekaia F, Badcock K, Basham D, Brown D, Chillingworth T, Connor R, Davies R, Devlin K, Feltwell T, Gentles S, Hamlin N, Holroyd S, Hornsby T, Jagels K, Krogh A, McLean J, Moule S, Murphy L, Oliver K, Osborne J, Quail MA, Rajandream MA, Rogers J, Rutter S, Seeger K, Skelton J, Squares R, Squares S, Sulston JE, Taylor K, Whitehead S, and Barrell BG

Subjects
Chromosome Mapping, Chromosomes, Bacterial, Drug Resistance, Microbial, Humans, Lipid Metabolism, Molecular Sequence Data, Mycobacterium tuberculosis immunology, Mycobacterium tuberculosis metabolism, Mycobacterium tuberculosis pathogenicity, Sequence Analysis, DNA, Tuberculosis microbiology, Genome, Bacterial, Mycobacterium tuberculosis genetics
Abstract

Countless millions of people have died from tuberculosis, a chronic infectious disease caused by the tubercle bacillus. The complete genome sequence of the best-characterized strain of Mycobacterium tuberculosis, H37Rv, has been determined and analysed in order to improve our understanding of the biology of this slow-growing pathogen and to help the conception of new prophylactic and therapeutic interventions. The genome comprises 4,411,529 base pairs, contains around 4,000 genes, and has a very high guanine + cytosine content that is reflected in the biased amino-acid content of the proteins. M. tuberculosis differs radically from other bacteria in that a very large portion of its coding capacity is devoted to the production of enzymes involved in lipogenesis and lipolysis, and to two new families of glycine-rich proteins with a repetitive structure that may represent a source of antigenic variation.

Published
1998
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19. Short-insert libraries as a method of problem solving in genome sequencing.

Author

McMurray AA, Sulston JE, and Quail MA

Subjects
Animals, BRCA2 Protein, Base Sequence, Caenorhabditis elegans genetics, Chromosomes, Human, Pair 13 genetics, Genes, Helminth, Genes, Neoplasm, Genome, Human, Humans, Molecular Sequence Data, Neoplasm Proteins genetics, Transcription Factors genetics, Gene Library, Problem Solving, Sequence Analysis, DNA methods
Abstract

As the Human Genome Project moves into its sequencing phase, a serious problem has arisen. The same problem has been increasingly vexing in the closing phase of the Caenorhabditis elegans project. The difficulty lies in sequencing efficiently through certain regions in which the templates (DNA substrates for the sequencing process) form complex folded secondary structures that are inaccessible to the enzymes. The solution, however, is simply to break them up. Specifically, the offending fragments are sonicated heavily and recloned, as much smaller fragments, into pUC vector. The sequences obtained from the resulting library can subsequently be assembled, free from the effects of secondary structure, to produce high-quality, complete sequence. Because of the success and simplicity of this procedure, we have begun to use it for the sequencing of all regions in which standard primer walking has been at all difficult.

Published
1998
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20. Caenorhabditis elegans levamisole resistance genes lev-1, unc-29, and unc-38 encode functional nicotinic acetylcholine receptor subunits.

Author

Fleming JT, Squire MD, Barnes TM, Tornoe C, Matsuda K, Ahnn J, Fire A, Sulston JE, Barnard EA, Sattelle DB, and Lewis JA

Subjects
Amino Acid Sequence, Animals, Cloning, Molecular, Molecular Sequence Data, Phenotype, Xenopus, Genes genetics, Mutation genetics, Receptors, Nicotinic genetics
Abstract

We show that three of the eleven genes of the nematode Caenorhabditis elegans that mediate resistance to the nematocide levamisole and to other cholinergic agonists encode nicotinic acetylcholine receptor (nAChR) subunits. unc-38 encodes an alpha subunit while lev-1 and unc-29 encode non-alpha subunits. The nematode nAChR subunits show conservation of many mammalian nAChR sequence features, implying an ancient evolutionary origin of nAChR proteins. Expression in Xenopus oocytes of combinations of these subunits that include the unc-38 alpha subunit results in levamisole-induced currents that are suppressed by the nAChR antagonists mecamylamine, neosurugatoxin, and d-tubocurarine but not alpha-bungarotoxin. The mutant phenotypes reveal that unc-38 and unc-29 subunits are necessary for nAChR function, whereas the lev-1 subunit is not. An UNC-29-GFP fusion shows that UNC-29 is expressed in body and head muscles. Two dominant mutations of lev-1 result in a single amino acid substitution or addition in or near transmembrane domain 2, a region important to ion channel conductance and desensitization. The identification of viable nAChR mutants in C. elegans provides an advantageous system in which receptor expression and synaptic targeting can be manipulated and studied in vivo.

Published
1997

21. Sequence variation of the human Y chromosome.

Author

Whitfield LS, Sulston JE, and Goodfellow PN

Subjects
Animals, DNA, Mitochondrial genetics, Humans, Male, Pan troglodytes, Genetic Variation, Y Chromosome
Abstract

We have generated over 100 kilobases of sequence from the nonrecombining portion of the Y chromosomes from five humans and one common chimpanzee. The human subjects were chosen to match the earliest branches of the human mitochondrial tree. The survey of 18.3 kilobases from each human detected only three sites at which substitutions were present, whereas the human and chimpanzee sequences showed 1.3% divergence. The coalescence time estimated from our Y chromosome sample is more recent than that of the mitochondrial genome. A recent coalescence time for the Y chromosome could have been caused by the selected sweep of an advantageous Y chromosome or extensive migration of human males.

Published
1995
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23. "Joy of the worm".

Author

Horvitz HR and Sulston JE

Subjects
Animals, Caenorhabditis cytology, Caenorhabditis growth & development, Cell Line, Mutation, Caenorhabditis genetics
Published
1990
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24. Chromatin diminution and a chromosomal mechanism of sexual differentiation in Strongyloides papillosus.

Author

Albertson DG, Nwaorgu OC, and Sulston JE

Subjects
Animals, Karyotyping, Mitosis, Nematode Infections genetics, Parthenogenesis, Rabbits, Chromosomes ultrastructure, Sex Differentiation, Strongyloidea genetics
Abstract

Eggs obtained from feces of rabbits infected with Strongyloides papillosus were squashed and the karyotypes were determined. They contained cells with either two long and two medium sized chromosomes (2L2M), or one long, three medium and one short chromosome (L3MS). Two types of parasitic female gonad could be distinguished on the basis of oocyte chromosome morphology at prometaphase of the maturation division. All the oocytes in a gonad contained either two upaired long chromosomes and two unpaired medium sized chromosomes, or two unpaired medium sized chromosomes and two unpaired chromosomes segmented into beads in one region. At the maturation division in mitotic parthenogenesis the beads appear to be lost from one of the chromosomes. This generates a medium sized and a shorter chromosome, which together with the undiminished chromosomes make up the L3MS karyotype. Animals with beaded oocyte chromosomes lay eggs that develop into males. It is suggested that males are heteromorphic for the long homologue due to chromatin diminution, that occurs in the maturation division of mitotic parthenogenesis.

Published
1979
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25. The Caenorhabditis elegans male: postembryonic development of nongonadal structures.

Author

Sulston JE, Albertson DG, and Thomson JN

Subjects
Animals, Cell Survival, Cloaca growth & development, Digestive System growth & development, Disorders of Sex Development, Ganglia growth & development, Male, Microscopy, Electron, Muscle Development, Skin growth & development, Tail cytology, Tail innervation, Tail ultrastructure, Vas Deferens growth & development, Caenorhabditis growth & development, Tail growth & development
Published
1980
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26. The rDNA of C. elegans: sequence and structure.

Author

Ellis RE, Sulston JE, and Coulson AR

Subjects
Base Sequence, Biological Evolution, Cloning, Molecular, Genes, Nucleic Acid Conformation, Sequence Homology, Nucleic Acid, Caenorhabditis genetics, DNA, Ribosomal genetics, RNA, Ribosomal genetics
Abstract

We have sequenced one complete rDNA tandem repeat from the nematode C. elegans. By comparative analysis we derive secondary structures for the 18s, 5.8s, and 26s rRNA molecules, and comment on other important features of the sequence. We also present the sequence of a junction between the rDNA and non-ribosomal DNA. Finally, we use our data to quantify the evolutionary relationships among several organisms currently studied in developmental biology.

Published
1986
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27. Lorist2, a cosmid with transcriptional terminators insulating vector genes from interference by promoters within the insert: effect on DNA yield and cloned insert frequency.

Author

Gibson TJ, Coulson AR, Sulston JE, and Little PF

Subjects
Animals, Caenorhabditis genetics, Cell Division, Escherichia coli genetics, Promoter Regions, Genetic, Cloning, Molecular methods, Cosmids, DNA Replication, Genes, Regulator, Genetic Vectors, Terminator Regions, Genetic
Abstract

Transcription terminators have been included in a phage-lambda-replicon-based cosmid vector, Lorist2, to insulate vector genes against transcriptional interference from cloned insert DNA. DNA yields of recombinant clones containing Escherichia coli genomic DNA inserts are more even for Lorist2 than with its progenitor LoristB. However, the terminators provide only a partial reduction in the over-representation of r X DNA-containing clones generally observed in cosmid libraries of Caenorhabditis elegans DNA, suggesting that causes other than transcriptional readthrough into the vector contribute to this problem.

Published
1987
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30. Isolation and genetic characterization of cell-lineage mutants of the nematode Caenorhabditis elegans.

Author

Horvitz HR and Sulston JE

Subjects
Animals, Cell Division, Crosses, Genetic, Genes, Recessive, Mutation, Phenotype, Caenorhabditis genetics, Germ Layers physiology
Abstract

Twenty-four mutants that alter the normally invariant post-embryonic cell lineages of the nematode Caenorhabditis elegans have been isolated and genetically characterized. In some of these mutants, cell divisions fail that occur in wild-type animals; in other mutants, cells divide that do not normally do so. The mutants differ in the specificities of their defects, so that it is possible to identify mutations that affect some cell lineages but not others. These mutants define 14 complementation groups, which have been mapped. The abnormal phenotype of most of the cell-lineage mutants results from a single recessive mutation; however, the excessive cell divisions characteristic of one strain, CB1322, require the presence of two unlinked recessive mutations. All 24 cell-lineage mutants display incomplete penetrance and/or variable expressivity. Three of the mutants are suppressed by pleiotropic suppressors believed to be specific for null alleles, suggesting that their phenotypes result from the complete absence of gene activity.

Published
1980
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31. Mutations affecting programmed cell deaths in the nematode Caenorhabditis elegans.

Author

Hedgecock EM, Sulston JE, and Thomson JN

Subjects
Animals, Autophagy, Caenorhabditis genetics, DNA metabolism, Female, Male, Microscopy, Electron, Caenorhabditis growth & development, Cell Survival, Mutation
Abstract

Mutations in two nonessential genes specifically block the phagocytosis of cells programmed to die during development. With few exceptions, these cells still die, suggesting that, in nematodes, engulfment is not necessary for most programmed deaths. Instead, these deaths appear to occur by cell suicide.

Published
1983
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32. Post-embryonic cell lineages of the nematode, Caenorhabditis elegans.

Author

Sulston JE and Horvitz HR

Subjects
Animals, Cell Count, Cell Division, Cell Nucleus ultrastructure, Cell Survival, Disorders of Sex Development, Male, Nematoda anatomy & histology, Organ Specificity, Sex Differentiation, Species Specificity, Cell Differentiation, Embryonic Induction, Nematoda physiology
Published
1977
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33. Serotonin and octopamine in the nematode Caenorhabditis elegans.

Author

Horvitz HR, Chalfie M, Trent C, Sulston JE, and Evans PD

Subjects
Age Factors, Animals, Behavior, Animal physiology, Female, Ovulation drug effects, Temperature, Caenorhabditis physiology, Octopamine physiology, Serotonin physiology
Abstract

The biogenic amines serotonin and octopamine are present in the nematode Caenorhabditis elegans. Serotonin, detected histochemically in whole mounts, is localized in two pharyngeal neurons that appear to be neurosecretory. Octopamine, identified radioenzymatically in crude extracts, probably is also localized in a few neurons. Exogenous serotonin and octopamine elicit specific and opposite behavioral responses in Caenorhabditis elegans, suggesting that these compounds function physiologically as antagonists.

Published
1982
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34. Induction of neuronal branching in Caenorhabditis elegans.

Author

Chalfie M, Thomson JN, and Sulston JE

Subjects
Animals, Caenorhabditis physiology, Insecta growth & development, Insecta physiology, Movement, Nervous System Physiological Phenomena, Neurons, Afferent physiology, Synapses physiology, Touch physiology, Caenorhabditis growth & development, Nervous System growth & development
Abstract

The two postembryonic touch receptor neurons in the nematode Caenorhabditis elegans arise from essentially identical cell lineages and have the same ultrastructural features. The cells are found in different positions in the animal, however, and differ in neuronal branching, connectivity, and function. These structural and functional differences are not seen when cells are placed in similar positions by mutation or laser-induced damage. Thus, some, but probably not all, of the differentiated properties of these cells are a consequence of their cellular environment.

Published
1983
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35. Preparation of large numbers of plasmid DNA samples in microtiter plates by the alkaline lysis method.

Author

Gibson TJ and Sulston JE

Subjects
Cosmids, Escherichia coli genetics, Genetic Engineering methods, Hydrogen-Ion Concentration, DNA, Bacterial isolation & purification, Plasmids
Abstract

A protocol is described for the growth and preparation of plasmid DNAs from small culture volumes (250 microliters) and utilizing standard 96-well plates. Several hundred plasmids can be prepared simultaneously, yielding sufficient DNA for subsequent analysis by restriction digestion and gel electrophoresis. This protocol may be useful for rapid screening of clones arising in recombinant DNA work such as site-directed mutagenesis, oligonucleotide cassette cloning, deletion analysis, etc. The technique was initially developed to meet our requirement to provide large numbers of cosmid DNAs for restriction enzyme fingerprint analyses in genome mapping projects.

Published
1987
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36. Mutations that lead to reiterations in the cell lineages of C. elegans.

Author

Chalfie M, Horvitz HR, and Sulston JE

Subjects
Animals, Caenorhabditis physiology, Caenorhabditis ultrastructure, Cell Division, Embryo, Nonmammalian physiology, Larva physiology, Larva ultrastructure, Microscopy, Electron, Caenorhabditis genetics, Genes, Mutation
Abstract

Cells in the nematode Caenorhabditis elegans arise from invariant cell lineages. Mutations in two genes, unc-86 and lin-4, alter multiple and mutually exclusive sets of these lineages. In these mutants, particular cells repeat division patterns normally associated with their parental or grandparental progenitors. The effects of unc-86 are highly specific, altering in equivalent ways the lineages of three post-embryonic neuroblasts that in the wild-type undergo similar division patterns. The effects of lin-4 are more varied, resulting in a number of types of lineage reiterations as well as in supernumerary molts and the continued synthesis of larval-specific cuticle. The reiteration of a given cell division or pattern of cell divisions leads to the repeated generation of cells indistinguishable (by both light and electron microscopy) from those produced after the same division or pattern of cell divisions in the wild-type. This correlation between lineage history and cell fate suggests that in C. elegans a particular sequence of cell divisions may be necessary for the generation of a particular cell type. Reiterative lineages, often referred to as stem cell lineages, may be basic to the development of nematodes and other organisms. We suggest that the wild-type unc-86 and lin-4 genes act to modify latent reiterative cell lineages, which are revealed when the activity of one of these genes is eliminated.

Published
1981
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37. Genomic organization of major sperm protein genes and pseudogenes in the nematode Caenorhabditis elegans.

Author

Ward S, Burke DJ, Sulston JE, Coulson AR, Albertson DG, Ammons D, Klass M, and Hogan E

Subjects
Animals, Base Sequence, Chromosome Mapping, Cosmids, DNA genetics, Molecular Sequence Data, Nucleic Acid Hybridization, Caenorhabditis genetics, Genes, Nuclear Proteins genetics, Pseudogenes
Abstract

The major sperm proteins (MSPs) are a family of closely related, small, basic proteins comprising 15% of the protein in Caenorhabditis elegans sperm. They are encoded by a multigene family of more than 50 genes, including many pseudogenes. MSP gene transcription occurs only in late primary spermatocytes. In order to study the genomic organization of transcribed MSP genes, probes specific for the 3' untranslated regions of sequenced cDNA clones were used to isolate transcribed genes from genomic libraries. These and other clones of MSP genes were located in overlapping cosmid clones by DNA fingerprinting. These cosmids were aligned with the genetic map by overlap with known genes or in-situ hybridization to chromosomes. Of 40 MSP genes identified, 37, including all those known to be transcribed, are organized into six clusters composed of 3 to 13 genes each. Within each cluster, MSP genes are not in tandem but are separated by at least several thousand bases of DNA. Pseudogenes are interspersed among functional genes. Genes with similar 3' untranslated sequences are in the same cluster. The six MSP clusters are confined to only three chromosomal loci; one on the left arm of chromosome II and two near the middle of chromosome IV. Additional sperm-specific genes are located in one cluster of MSP genes on chromosome IV. The multiplicity of MSP genes appears to be a mechanism for enhancing MSP synthesis in spermatocytes, and the loose clustering of genes could be a result of the mechanism of gene duplication or could play a role in regulation.

Published
1988
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38. Post-embryonic development in the ventral cord of Caenorhabditis elegans.

Author

Sulston JE

Subjects
Animals, Disorders of Sex Development, Larva, Spinal Cord cytology, Spinal Cord growth & development, Nematoda growth & development
Abstract

56 nerve cells are added to the ventral cord and associated ganglia of Caenorhabditis elegans at about the time of the first larval moult. These cells are produced by the uniform division of 13 neuroblasts followed by a defined pattern of cell deaths. Comparison with the data in the previous paper suggests that there is a relationship between the ancestry of a cell and its function. The significance of programmed cell death is discussed.

Published
1976
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40. The DNA of Caenorhabditis elegans.

Author

Sulston JE and Brenner S

Subjects
Animals, Base Sequence, Centrifugation, Density Gradient, Female, Genes, Genetic Code, Genotype, Haploidy, Male, Nucleic Acid Hybridization, Nucleic Acid Renaturation, Phosphorus Radioisotopes, RNA, Ribosomal, RNA, Transfer, DNA analysis, Nematoda analysis
Abstract

Chemical analysis and a study of renaturation kinetics show that the nematode, Caenorhabditis elegans, has a haploid DNA content of 8 x 10(7) base pairs (20 times the genome of E. coli). Eighty-three percent of the DNA sequences are unique. The mean base composition is 36% GC; a small component, containing the rRNA cistrons, has a base composition of 51% GC. The haploid genome contains about 300 genes for 4S RNA, 110 for 5S RNA, and 55 for (18 + 28)S RNA.

Published
1974
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41. The embryonic cell lineage of the nematode Caenorhabditis elegans.

Author

Sulston JE, Schierenberg E, White JG, and Thomson JN

Subjects
Animals, Cell Communication, Cell Differentiation, Cell Division, Cell Movement, Cell Survival, Digestive System cytology, Female, Gastrula physiology, Gonads cytology, Larva cytology, Male, Mesoderm cytology, Microscopy, Electron, Muscles cytology, Neurons cytology, Caenorhabditis embryology, Zygote cytology
Abstract

The embryonic cell lineage of Caenorhabditis elegans has been traced from zygote to newly hatched larva, with the result that the entire cell lineage of this organism is now known. During embryogenesis 671 cells are generated; in the hermaphrodite 113 of these (in the male 111) undergo programmed death and the remainder either differentiate terminally or become postembryonic blast cells. The embryonic lineage is highly invariant, as are the fates of the cells to which it gives rise. In spite of the fixed relationship between cell ancestry and cell fate, the correlation between them lacks much obvious pattern. Thus, although most neurons arise from the embryonic ectoderm, some are produced by the mesoderm and a few are sisters to muscles; again, lineal boundaries do not necessarily coincide with functional boundaries. Nevertheless, cell ablation experiments (as well as previous cell isolation experiments) demonstrate substantial cell autonomy in at least some sections of embryogenesis. We conclude that the cell lineage itself, complex as it is, plays an important role in determining cell fate. We discuss the origin of the repeat units (partial segments) in the body wall, the generation of the various orders of symmetry, the analysis of the lineage in terms of sublineages, and evolutionary implications.

Published
1983
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43. Regulation and cell autonomy during postembryonic development of Caenorhabditis elegans.

Author

Sulston JE and White JG

Subjects
Animals, Caenorhabditis cytology, Cell Differentiation radiation effects, Cell Survival radiation effects, Cloaca cytology, Digestive System cytology, Disorders of Sex Development, Female, Ganglia cytology, Lasers, Male, Sense Organs cytology, Skin cytology, Vas Deferens cytology, Vulva cytology, Caenorhabditis growth & development
Published
1980
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46. Physical linkage of the 5 S cistrons to the 18 S and 28 S ribosomal RNA cistrons in Saccharomyces cerevisiae.

Author

Rubin GM and Sulston JE

Subjects
Centrifugation, Density Gradient, DNA analysis, Electrophoresis, Polyacrylamide Gel, Nitrogen Isotopes, Nucleic Acid Hybridization, Phosphorus Radioisotopes, RNA, Ribosomal analysis, RNA, Transfer metabolism, Ribonucleases, Saccharomyces cerevisiae analysis, Spectrophotometry, Ultraviolet, Ultracentrifugation, DNA metabolism, RNA, Ribosomal metabolism, Saccharomyces cerevisiae metabolism, Transcription, Genetic
Published
1973
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47. Template-directed synthesis with adenosine-5'-phosphorimidazolide.

Author

Weimann BJ, Lohrmann R, Orgel LE, Schneider-Bernloehr H, and Sulston JE

Subjects
Carbon Isotopes, Hydrogen-Ion Concentration, Imidazoles, Adenine Nucleotides chemical synthesis, Polynucleotides, Templates, Genetic, Uracil Nucleotides
Abstract

Adenosine-5'-monophosphorimidazolide reacts efficiently with adenosine derivatives on a polyuridylic acid template, with the formation of internucleotide bonds.

Published
1968
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