Abstract
The mobile DNAs of the Mutator system of maize (Zea mays) are exceptional both in structure and diversity. So far, six subfamilies of Mu elements have been discovered; all Mu elements share highly conserved terminal inverted repeats (TIRs), but each sub-family is defined by internal sequences that are apparently unrelated to the internal sequences of any other Mu subfamily. The Mu1/Mu2 subfamily of elements was created by the acquisition of a portion of a standard maize gene (termed MRS-A) within two Mu TIRs. Beside the unusually long (185–359 bp) and diverse TIRs found on all of these elements, other direct and inverted repeats are often found either within the central portion of a Mu element or within a TIR.
Our computer analyses have shown that sequence duplications (mostly short direct repeats interrupted by a few base pairs) are common in non-autonomous members of the Mutator, Ac/Ds, and Spm(En) systems. These duplications are often tightly associated with the element-internal end of the TIRs. Comparisons of Mu element sequences have indicated that they share more terminal components than previously reported; all subfamilies have at least the most terminal 215 bp, at one end or the other, of the 359-bp Mu5 TIR. These data suggest that many Mu element subfamilies were generated from a parental element that had termini like those of Mu5. With the Mu5 TIRs as a standard, it was possible to determine that elements like Mu4 could have had their unusual TIRs created through a three-step process involving (1) addition of sequences to interrupt one TIR, (2) formation of a stem-loop structure by one strand of the element, and (3) a subsequent DNA repair/gene conversion event that duplicated the insertion(s) within the other TIR. A similar repair/conversion extending from a TIR stem into loop DNA could explain the additional inverted repeat sequences added to the internal ends of the Mu4 and Mu7 TIRs. This same basic mechanism was found to be capable of generating new Mu element subfamilies. After endonucleolytic attack of the loop within the stem-loop structure, repair/conversion of the gap could occur as an intermolecular event to generate novel internal sequences and, therefore, a new Mu element subfamily. Evidence supporting and expanding this model of new Mu element subfamily creation was identified in the sequence of MRS-A.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alleman M, Freeling M (1986) The Mu transposable elements of maize; evidence for transposition and copy number regulation during development. Genetics 112:107–119
Barker RF, Thompson DV, Talbot DR, Swanson J, Bennetzen JL (1984) Nucleotide sequence of the maize transposable element Mu1. Nucleic Acids Res 12:5955–5967
Bennetzen JL (1984) Transposable element Mu1 is found in multiple copies only in Robertson's Mutator maize lines. J Mol Appl Genet 2:519–524
Bennetzen JL, Swanson J, Taylor WC, Freeling M (1984) DNA insertion in the first intron of maize Adh1 affects message levels: cloning of progenitor and mutant Adh1 alleles. Proc Natl Acad Sci USA 81:4125–4128
Bennetzen JL, Fracasso RP, Morris DW, Robertson DS, Skogen-Hagenson MJ (1987) Concomitant regulation of Mu1 transposition and Mutator activity in maize. Mol Gen Genet 208:57–62
Bennetzen JL, Springer PS, Cresse AD, Hendrickx M (1993) Specificity and regulation of the Mutator transposable element system in maize. Crit Rev Plant Sci 12:57–95
Bingham PM, Zachar Z (1989) Retrotransposons and the FB transposon from Drosophila melanogaster. In: Berg DE, Howe MM (eds) Mobile DNA. American Society for Microbiology, Washington, pp 485–502
Blaisdell BE (1983) A prevalent persistent global nonrandomness that distinguishes coding and non-coding eukaryotic nuclear DNA sequences. J Mol Evol 19:122–133
Britt AB, Walbot V (1991) Germinal and somatic products of Mu1 excision from the Bronze-1 gene of Zea mays. Mol Gen Genet 227:267–276
Brown WE, Robertson DS, Bennetzen JL (1989) Molecular analysis of multiple Mutator-derived alleles of the Bronze locus of maize. Genetics 122:439–445
Chandler VL, Hardeman KJ (1992) The Mu elements of Zea Mays. Adv Genet 30:77–122
Chandler VL, Rivin CJ, Walbot V (1986) Stable non-Mutator stocks of maize have sequences homologous to the Mu1 transposable element. Genetics 114:1007–1021
Chandler VL, Talbert LE, Raymond F (1988) Sequence, genomic distibution and DNA modification of a Mu1 element from non-Mutator maize stocks. Genetics 119:951–958
Chomet P, Lisch D, Hardeman KJ, Chandler VL, Freeling M (1991) Identification of a regulatory transposon that controls the Mutator transposable element system in maize. Genetics 129:261–270
Dennis ES, Gerlach WL, Pryor AJ, Bennetzen JL, Inglis A, Llewellyn D, Sachs M, Ferl RJ, Peacock WJ (1984) The Adh1 gene of maize. Nucleic Acids Res 12:3983–4000
Devereux J, Haeberli P, Smithies O (1984) A comprehensive set of sequence analysis programs for the VAX. Nucleic Acids Res 12:387–395
Ehrlich SD (1989) Illegitimate recombination in bacteria. In: Berg DE, Howe MM (eds) Mobile DNA. American Society for Microbiology, Washington, pp 799–832
Fedoroff N, Wessler S, Shure M (1983) Isolation of the transposable maize controlling elements Ac and Ds. Cell 35:235–242
Fleenor D, Spell M, Robertson D, Wessler S (1990) Nucleotide sequence of the Mutator element, Mu8. Nucleic Acids Res 18:6725
Gierl A, Schwarz-Sommer Z, Saedler H (1985) Molecular interactions between the components of the En-I transposable element system of Zea mays. EMBO J 4:579–583
Hardeman KJ, Chandler VL (1989) Characterization of bz1 mutants isolated from Mutator stocks with high and low numbers of Mu1 elements. Dev Genet 10:460–472
Hershberger RJ, Warren CA, Walbot V (1991) Mutator activity in maize correlates with the presence and expression of the Mu transposable element Mu9. Proc Natl Acad Sci USA 88:10198–10202
Heslip TR, Williams JA, Bell JB, Hodgetts RB (1992) A P element chimera containing captured genomic sequences was recovered at the vestigial locus in Drosophila following targeted transposition. Genetics 131:917–927
Hoffman-Liebermann B, Liebermann D, Cohen SN (1989) TU elements and Puppy sequences. In: Berg DE, Howe MM (eds) Mobile DNA. American Society for Microbiology, Washington, pp 575–592
Karess RE, Rubin GM (1984) Analysis of P transposable element functions in Drosophila. Cell 38:35–146
Klein AS, Clancy M, Paje-Manalo L, Furtek DB, Hannah LC, Nelson OE Jr (1988) The mutation bronze-mutable 4 derivative 6856 in maize is caused by the insertion of a novel 6.7-kilobase pair transposon in the untranslated leader region of the Bronze-1 gene. Genetics 120:779–790
Levinson G, Gutman GA (1987) Slipped-strand mispairing: a major mechanism for DNA sequence evolution. Mol Biol Evol 4:203–221
Merckelbach A, Doering H-P, Starlinger P (1986) The aberrant Ds element in the 667–01 allele. Maydica 31:109–122
Meuth M (1989) Illegitimate recombination in mammalian cells. In: Berg DE, Howe MM (eds) Mobile DNA. American Society for Microbiology, Washington, pp 833–860
Muller-Neumann M, Yoder JI, Starlinger P (1984) The DNA sequence of the transposable element Ac of Zea mays L. Mol Gen Genet 198:19–24
O'Hare K, Rubin GM (1983) Structure of P transposable elements and their sites of insertion and excision in the Drosophila melanogaster genome. Cell 34:25–35
Pereira A, Cuypers H, Gierl A, Schwarz-Sommer Z, Saedler H (1986) Molecular analysis of the En/Spm transposable elements of Zea mays. EMBO J 5:835–841
Pohlman RF, Fedoroff NV, Messing J (1984) The nucleotide sequence of the maize controlling element Activator. Cell 37:635–643
Qin M, Ellingboe AH (1990) A transcript identified by MuA of maize is associated with Mutator activity. Mol Gen Genet 224:357–363
Qin M, Robertson DS, Ellingboe AH (1991) Cloning of the Mutator transposable element MuA2, a putative regulator of somatic mutability of the a1-Mum2 allele in maize. Genetics 129:845–854
Ralston EJ, English JJ, Dooner HK (1988) Sequence of three bronze alleles of maize and correlation with the genetic fine structure. Genetics 119:185–197
Robertson DS (1978) Characterization of a Mutator system in maize. Mutat Res 51:21–28
Robertson DS, Stinard PS (1989) Genetic analysis of putative two-element systems regulating somatic mutability in Mutator-induced aleurone mutants in maize. Dev Genet 10:482–506
Rosenzweig B, Liao L, Hirsh D (1983) Sequence of the C. Elegans transposable element Tc1. Nucleic Acids Res 11:7137–7140
Sachs MM, Dennis ES, Gerlach WL, Peacock WJ (1986) Two alleles of maize alcohol dehydrogenase 1 have 3′ structural and poly(A) addition polymorphisms. Genetics 113:449–467
Schiefelbein JW, Raboy V, Fedoroff NV, Nelson OE Jr (1985) Deletions within a defective Suppressor-mutator element in maize affect the frequency and developmental timing of its excision from the bronze locus. Proc Natl Acad Sci USA 82:4783–4787
Schnable PS, Peterson PA, Saedler H (1989) The bz-rcy allele of the Cy transposable element system of Zea mays contains a Mu-like element insertion. Mol Gen Genet 217:459–463
Swain A, Coffin JM (1992) Mechanism of transduction by retro-viruses. Science 255:841–845
Talbert LE, Chandler VL (1988) Characterization of a highly conserved sequence related to Mutator transposable elements in maize. Mol Biol Evol 5:519–529
Talbert LE, Patterson GI, Chandler VL (1989) Mu transposable elements are structurally diverse and distributed throughout the genus Zea. J Mol Evol 29:28–39
Tautz D, Martin T, Dover GA (1986) Cryptic simplicity in DNA is a major source of genetic variation. Nature 322:652–656
Taylor LP, Walbot V (1987) Isolation and characterization of a 1.7-kb transposable element from a Mutator line of maize. Genetics 117:297–307
Tsubota SI, Dang-Vu H (1991) Capture of flanking DNA by a P element in Drosophila melanogaster: creation of a transposable element. Proc Natl Acad Sci USA 88:693–697
Weil CF, Marillonnet S, Burr B, Wessler SR (1992) Changes in state of the Wx-m5 allele of maize are due to intragenic transposition of Ds. Genetics 130:175–185
Yuan J, Finney M, Tsung N, Horvitz HR (1991) Tc4, a Caenorhabditis elegans transposable element with an unusual fold-back structure. Proc Natl Acad Sci USA 88:3334–3338
Author information
Authors and Affiliations
Additional information
Communicated by H. K. Dooner
Rights and permissions
About this article
Cite this article
Bennetzen, J.L., Springer, P.S. The generation of Mutator transposable element subfamilies in maize. Theoret. Appl. Genetics 87, 657–667 (1994). https://doi.org/10.1007/BF00222890
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00222890