The complete DNA sequence of yeast chromosome III

@article{Oliver1992TheCD,
  title={The complete DNA sequence of yeast chromosome III},
  author={S. G. Oliver and Q.J.M. van der Aart and M. L. Agostoni-Carbone and Michel Aigle and Lilia Alberghina and Despina Alexandraki and Gessain Antoine and R. Anwar and Juan P. G. Ballesta and Paule Bénit and Gilbert Berben and Elisabetta Bergantino and Nicolas G. Biteau and P. A. Bolle and Monique Bolotin-Fukuhara and A. J. P. Brown and A. J. P. Brown and J. M. Buhler and C. Carcano and Giovanna Carignani and H{\aa}kan Cederberg and Roland Chanet and Roland Contreras and Marc Crouzet and Bertrand Daignan-Fornier and Els Marie Celine Defoor and M. A. Delgado and Jan Demolder and C. Doira and Evelyne Dubois and Bernard Dujon and Andreas Dusterhoft and Dirk Erdmann and Marta Esteban and Francis Fabre and C{\'e}cile Fairhead and Gérard Faye and Horst Feldmann and Walter Charles Fiers and M. C. Francingues-Gaillard and Luis Franco and Laura Frontali and Hiroshi Fukuhara and Linda J. Fuller and Philippe Galland and Manda E. Gent and Daniel Gigot and V{\'e}ronique Gilliquet and Nicolas Glansdorff and Andr{\'e} Goffeau and Marcelle Grenson and Paola Grisanti and L. A. Grivell and M. de Haan and Martina Haasemann and Didier Hatat and Janet Hoenicka and Johannes H. Hegemann and Christopher J. Herbert and François Hilger and Sabrina Hohmann and Cornelis P. Hollenberg and Klaus Huse and François Iborra and K. J. Indje and Katsumi Isono and Claude Jacq and Michel Jacquet and Celia M. James and Jean Claude Jauniaux and Y K Jia and Antonio Jim{\'e}nez and Andthomasj . Kelly and Ulrich Kleinhans and Peter Kreisl and Gerolamo Lanfranchi and C Lewis and Colleen Vanderlinden and Giovanna Lucchini and K Lutzenkirchen and M. J. Maat and Laurent Mallet and G. Mannhaupet and Enzo Martegani and Aurélie Mathieu and C. T. C. Maurer and D. J. McConnell and Raymond A. McKee and Francine Messenguy and Hans-Werner Mewes and Francis Molemans and Mary Ann Montague and Marco Falconi and L. Navas and Carol S Newlon and D. Noone and C. Pallier and Lucia Panzeri and Bruce M. Pearson and Javier Perea and Peter Philippsen and Andr{\'e} Pi{\'e}rard and R. Planta and Paolo Plevani and B Poetsch and Fritz M. Pohl and Bénédicte Purnelle and Massoud Ramezani Rad and S. W. Rasmussen and Alain Raynal and Miguel Remacha and Peter Richterich and A B Roberts and F Rodriguez and Elo{\'i}sa Sanz and I. Schaaff-Gerstenschlager and Bart Scherens and Bert Schweitzer and Youmin Shu and Jacek Skała and Piotr P. Slonimski and Fr{\'e}d{\'e}ric Sor and Christine Soustelle and R. Spiegelberg and Lubomira Stateva and H. Y. de Steensma and Sabine Steiner and A. Thierry and George Thireos and Maria Tzermia and L. A. Urrestarazu and Giorgio Valle and Irene Vetter and J. C. van Vliet-Reedijk and Marleen Voet and G. Volckaert and Peter Vreken and H Wang and John R. Warmington and Diter von Wettstein and Barton L Wicksteed and C. Wilson and Helmut Wurst and G. Xu and Akikazu Yoshikawa and Friedrich K. Zimmermann and John G. Sgouros},
  journal={Nature},
  year={1992},
  volume={357},
  pages={38-46}
}
The entire DNA sequence of chromosome III of the yeast Saccharomyces cerevisiae has been determined. This is the first complete sequence analysis of an entire chromosome from any organism. The 315-kilobase sequence reveals 182 open reading frames for proteins longer than 100 amino acids, of which 37 correspond to known genes and 29 more show some similarity to sequences in databases. Of 55 new open reading frames analysed by gene disruption, three are essential genes; of 42 non-essential genes… Expand
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References

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The sequence of 8·8 kb of yeast chromosome III cloned in lambda PM3270 contains an unusual long ORF (YCR601)
TLDR
The nucleotide sequence of a segment of chromosome III contained in the right part of the lambda PM3270 clone is determined, for a total of 8824 bp, which contains an unusual long open reading frame, YCR601, that encodes for a protein of 2167 amino acids that show no homology with other known proteins. Expand
Expansions and contractions of the genetic map relative to the physical map of yeast chromosome III.
TLDR
It is concluded that the chromosomal sequence or structure has a dramatic effect on meiotic recombination. Expand
Most of the yeast genomic sequences are not essential for cell growth and division
TLDR
To determine the fraction of the yeast Saccharomyces cerevisiae genome that is required for normal cell growth and division, diploid strains that were heterozygous for random single disruptions were constructed and the phenotype of the resulting haploid strains was examined. Expand
Chromosome III of Saccharomyces cerevisiae: An ordered clone bank, a detailed restriction map and analysis of transcripts suggest the presence of 160 genes
TLDR
An ordered clone bank is constructed that covers almost the whole of chromosome III with a single gap of several kilobases in length and it is found that the genes located near both termini are expressed only at low levels and that highly expressed genes are rather scattered over the chromosome. Expand
Physical map of the Saccharomyces cerevisiae genome at 110-kilobase resolution.
A physical map of the Saccharomyces cerevisiae genome is presented. It was derived by mapping the sites for two restriction endonucleases, SfiI and NotI, each of which recognizes an 8-bp sequence.Expand
Nucleotide sequence characterization of Ty 1-17, a class II transposon from yeast.
TLDR
The sequences of the two classes of yeast transposon are compared with one another and with analogous elements, such as retroviral proviruses, cauliflower mosaic virus and copia sequences. Expand
Polymorphisms on the right arm of yeast chromosome III associated with Ty transposition and recombination events.
TLDR
The region of Saccharomyces cerevisiae chromosome III centromere-distal to the PGK gene is the site of frequent chromosome polymorphisms and defines a region of the chromosome which is a hot-spot for transposition events (the RAHS). Expand
Analysis of a circular derivative of Saccharomyces cerevisiae chromosome III: a physical map and identification and location of ARS elements.
TLDR
Comparison of the physical maps of chromosome III from three strains revealed that the chromosomes differ in the number and positions of Ty elements and also show restriction site polymorphisms, showing that meiotic recombination rates vary at least tenfold along the length of the chromosome. Expand
Isolation and characterisation of a yeast chromosomal replicator
TLDR
A yeast DNA sequence that behaves as a chromosomal replicator, ars1 (autonomously replicating sequence), has been isolated and allows autonomous replication of all co-linear DNA. Expand
Isolation of a yeast centromere and construction of functional small circular chromosomes
The centromeric DNA (CEN3) from yeast chromosome III has been isolated on a 1.6 kilobase-pair segment of DNA located near the centromere-linked CDC10 locus of Saccharomyces cerevisiae. When presentExpand
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