The Drosophila chiffon gene is required for chorion gene amplification, and is related to the yeast Dbf4 regulator of DNA replication and cell cycle

G. Landis; J. Tower

Summary

The Drosophila chorion genes encode the major protein components of the chorion (eggshell) and are arranged in two clusters in the genome. To meet the demand for rapid chorion synthesis, Drosophila ovary follicle cells amplify the chorion gene clusters approximately 80-fold. Amplification proceeds through repeated firing of one or more DNA replication origins located near the center of each gene cluster. Hypomorphic mutant alleles of the chiffon gene cause thin, fragile chorions and female sterility, and were found to eliminate chorion gene amplification. Null alleles of chiffon had the additional phenotypes of rough eyes and thin thoracic bristles: phenotypes often associated with disruption of normal cell cycle. The chiffon locus was cloned by chromosomal walking from the nearby cactus locus. A 6.5 kb transcript was identified and confirmed to be chiffon by sequencing of mutant alleles and by phenotypic rescue with genomic transformation constructs. The protein predicted by translation of the 5.1 kb chiffon ORF contains two domains related to the S. cerevisiae Dbf4 regulator of DNA replication origin firing and cell cycle progression: a 44 residue domain designated CDDN1 (43% identical) and a 41 residue domain designated CDDN2 (12% identical). The CDDN domains were also found in the S. pombe homolog of Dbf4, Dfp1, as well as in the proteins predicted by translation of the Aspergillus nimO gene and specific human and mouse clones. The data suggest a family of eukaryotic proteins related to Dbf4 and involved in initiation of DNA replication.

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[1] Adams J. L.,
Battjes C. J.,
Buthala D. A.
(1987). Proceedings of the 45th AnnualMeeting of the Electron Microscopy Society of America, 956.

[2] Adams J. L.,

[3] Battjes C. J.,

[4] Buthala D. A.

[5] Adams M. D.,
et al.
(1995). Initial assessment of human gene diversity and expression patterns based upon 83 million nucleotides of cDNA sequence. Nature 377 (6547 Suppl), 3–174.

[6] Adams M. D.,

[7] et al.

[8] Ashburner M.,
Thompson P.,
Roote J.,
Lasko P. F.,
Grau Y.,
El Messel M.,
Roth S.,
Simpson P.
(1990). The genetics of a small autosomal region of Drosophila melanogaster containing the structural gene for alcohol dehydrogenase. VII. Characterization of the region around the snail and cactus loci. Genetics 126, 679–694.

[9] Ashburner M.,

[10] Thompson P.,

[11] Roote J.,

[12] Lasko P. F.,

[13] Grau Y.,

[14] El Messel M.,

[15] Roth S.,

[16] Simpson P.

[17] Bell S. P.,
Kobayashi R.,
Stillman B.
(1993). Yeast origin recognition complex functions in transcription silencing and DNA replication. Science 262, 1844–1849.

[18] Bell S. P.,

[19] Kobayashi R.,

[20] Stillman B.

[21] Bell S. P.,
Stillman B.
(1992). ATP-dependent recognition of eukaryotic origins of DNA replication by a multiprotein complex. Nature 357, 128–134.

[22] Bell S. P.,

[23] Stillman B.

[24] Berleth T.,
Burri M.,
Thoma G.,
Bopp D.,
Richstein S.,
Frigerio G.,
Noll M.,
Nüsslein-Volhard C.
(1988). The role of localization of bicoid RNA in organizing the anterior pattern of the Drosophila embryo. EMBO J. 7, 1749–1756.

[25] Berleth T.,

[26] Burri M.,

[27] Thoma G.,

[28] Bopp D.,

[29] Richstein S.,

[30] Frigerio G.,

[31] Noll M.,

[32] Nüsslein-Volhard C.

[33] Brown G. W.,
Kelly T. J.
(1998). Purification of Hsk1, a Minichromosome Maintenance Protein Kinase from Fission Yeast. J. Biol. Chem. 273, 22083–22090.

[34] Brown G. W.,

[35] Kelly T. J.

[36] Fisher P.
Calvi B. R.,
Spradling A. C.
(1998). Chorion gene amplification in Drosophila: a model for metazoan origins of DNA replication and S phase control. In Genetic Approaches to Eukaryotic Replication and Repair (ed. Fisher P.). New York: Academic Press.

[37] Fisher P.

[38] Calvi B. R.,

[39] Spradling A. C.

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Verheyen E.,
Ayers K.
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[42] Verheyen E.,

[43] Ayers K.

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Wellauer P. K.,
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(1984). Localization of a cis-acting element responsible for the developmentally regulated amplification of Drosophila chorion genes. Cell 38, 45–54.

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[50] Spradling A. C.

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[52] Delidakis C.,

[53] Kafatos F. C.

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[56] Kafatos F. C.

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[59] Cocker J. H.

[60] Diffley J. F. X.,
Cocker J. H.,
Dowell S. J.,
Rowley A.
(1994). Two steps in the assembly of complexes at yeast replication origins in vivo. Cell 78, 303–316.

[61] Diffley J. F. X.,

[62] Cocker J. H.,

[63] Dowell S. J.,

[64] Rowley A.

[65] Dowell S. J.,
Romanowski P.,
Diffley J. F. X.
(1994). Interaction of Dbf4, the Cdc7 protein kinase regulatory subunit, with yeast replication origins in vivo. Science 265, 1243–1246.

[66] Dowell S. J.,

[67] Romanowski P.,

[68] Diffley J. F. X.

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Laurenson P.,
Rine J.
(1993). Origin recognition complex (ORC) in transcriptional silencing and DNA replication in S.cerevisiae. Science 262, 1838–1844.

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[71] McNally F. J.,

[72] Laurenson P.,

[73] Rine J.

[74] Geisler R.,
Bergmann A.,
Hiromi Y.,
Nüsslein-Volhard C.
(1992). cactus, a gene involved in dorsoventral pattern formation in Drosophila, is related to the I kappa B gene family of vertabrates. Cell 71, 613–621.

[75] Geisler R.,

[76] Bergmann A.,

[77] Hiromi Y.,

[78] Nüsslein-Volhard C.

[79] Gossen M.,
Pak D. T. S.,
Hansen S. K.,
Achary J. K.,
Botchan M. R.
(1995). A Drosophila homolog of the yeast origin recogition complex. Science 270.

[80] Gossen M.,

[81] Pak D. T. S.,

[82] Hansen S. K.,

[83] Achary J. K.,

[84] Botchan M. R.

[85] Heck M. M. S.,
Spradling A. C.
(1990). Multiple replication origins are used during Drosophila chorion gene amplification. J. Cell Biol. 110, 903–914.

[86] Heck M. M. S.,

[87] Spradling A. C.

[88] Hess G. F.,
Drong R. F.,
Weiland K. L.,
Slightom J. L.,
Sclafani R. A.,
Hollingsworth R. E.
(1998). A human homolog of the yeast CDC7 gene is overexpressed in some tumors and transformed cell lines. Gene 211, 133–140.

[89] Hess G. F.,

[90] Drong R. F.,

[91] Weiland K. L.,

[92] Slightom J. L.,

[93] Sclafani R. A.,

[94] Hollingsworth R. E.

[95] Jackson A. L.,
Pahl P. M.,
Harrison K.,
Rosamond J.,
Sclafani R. A.
(1993). Cell cycle regulation of the yeast Cdc7 protein kinase by association with the Dbf4 protein. Mol. Cell. Biol. 13, 2899–2908.

[96] Jackson A. L.,

[97] Pahl P. M.,

[98] Harrison K.,

[99] Rosamond J.,

[100] Sclafani R. A.

[101] James S. W.,
Bullock K. A.,
Gygax S. E.,
Kraynack B. A.,
Matura R. A.,
MacLeod J. A.,
McNeal K. K.,
Prasauckas K. A.,
Scacheri P. C.,
Shenefiel H. L.,
Tobin H. M.,
Wade S. D.
(1999). nimO, an Aspergillus gene related to budding yeast Dbf4, is required for DNA synthesis and mitotic checkpoint control. J. Cell Sci. 112, 1313–1324.

[102] James S. W.,

[103] Bullock K. A.,

[104] Gygax S. E.,

[105] Kraynack B. A.,

[106] Matura R. A.,

[107] MacLeod J. A.,

[108] McNeal K. K.,

[109] Prasauckas K. A.,

[110] Scacheri P. C.,

[111] Shenefiel H. L.,

[112] Tobin H. M.,

[113] Wade S. D.

[114] Jiang W.,
Hunter T.
(1997). Identification and characterization of a human protein kinase related to budding yeast Cdc7p. Proc. Natl. Acad. Sci. USA 94, 14320–14325.

[115] Jiang W.,

[116] Hunter T.

[117] Kim J. M.,
Sato N.,
Yamada M.,
Arai K.,
Masai H.
(1998). Growth regulation of the expression of mouse cDNA and gene encoding a serine/threonine kinase related to Saccharomyces cerevisiae CDC7 essential for G1/S transition. Structure, chromosomal location, and expression of mouse gene for S. cerevisiae Cdc7-related kinase. J. Biol. Chem. 273, 23248–23257.

[118] Kim J. M.,

[119] Sato N.,

[120] Yamada M.,

[121] Arai K.,

[122] Masai H.

[123] Landis G.,
Kelley R.,
Spradling A. C.,
Tower J.
(1997). The k43 gene, required for chorion gene amplification and diploid cell chromosome replication encodes the Drosophila homolog of yeast origin recognition complex subunit 2. Proc. Natl. Acad. Sci. USA 94, 3888–3892.

[124] Landis G.,

[125] Kelley R.,

[126] Spradling A. C.,

[127] Tower J.

[128] Lei M.,
Kawasaki Y.,
Young M. R.,
Kihara M.,
Sugino A.,
Tye B. K.
(1997). Mcm2 is a target of regulation by Cdc7-Dbf4 during the initiation of DNA synthesis. Genes Dev. 11, 3365–3374.

[129] Lei M.,

[130] Kawasaki Y.,

[131] Young M. R.,

[132] Kihara M.,

[133] Sugino A.,

[134] Tye B. K.

[135] Lennon G.,
Auffray C.,
Polymeropoulos M.,
Soares M. B.
(1996). The I.M.A.G.E. Consortium: an integrated analysis of genomes and their expression. Genomics 33, 151–152.

[136] Lennon G.,

[137] Auffray C.,

[138] Polymeropoulos M.,

[139] Soares M. B.

[140] Lindsley D. L.,
Zimm G. G.
(1992). The Genome of Drosophila melanogaster. San Diego: Academic Press.

[141] Lindsley D. L.,

[142] Zimm G. G.

[143] Lu L.,
Tower J.
(1997). A transcriptional insulator element, the su(Hw) binding site, protects a chromosomal DNA replication origin from position effects. Mol. Cell. Biol. 17, 2202–2206.

[144] Lu L.,

[145] Tower J.

[146] Orr W.,
Komitopoulou K.,
Kafatos F. C.
(1984). Mutants suppressing in trans chorion gene amplification in Drosophila. Proc. Natl. Acad. Sci. USA 81, 3773–3777.

[147] Orr W.,

[148] Komitopoulou K.,

[149] Kafatos F. C.

[150] Orr-Weaver T.
(1991). Drosophila chorion genes: cracking the eggshell's secrets. BioEssays 13, 97–105.

[151] Orr-Weaver T.

[152] Orr-Weaver Y. L.,
Johnston C. G.,
Spradling A. C.
(1989). The role of ACE3 in Drosophila chorion gene amplification. EMBO J. 8, 4153–4162.

[153] Orr-Weaver Y. L.,

[154] Johnston C. G.,

[155] Spradling A. C.

[156] Owens J. C.,
Detweiler C. S.,
Li J. J.
(1997). CDC45 is required in conjunction with CDC7/DBF4 to trigger the initiation of DNA replication. Proc. Natl. Acad. Sci. USA 94, 12512–12526.

[157] Owens J. C.,

[158] Detweiler C. S.,

[159] Li J. J.

[160] Patton J. S.,
Gomes X. V.,
Geyer P. K.
(1992). Position-independent germline transformation in Drosophila using a cuticle pigmentation gene as a selectable marker. Nucleic Acids Res. 20, 5859–5860.

[161] Patton J. S.,

[162] Gomes X. V.,

[163] Geyer P. K.

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