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1.
Genetics ; 140(3): 1087-98, 1995 Jul.
Article in English | MEDLINE | ID: mdl-7672579

ABSTRACT

The MuDR element controls the transposition of the Mutator transposable element family in maize. Previous studies reported the presence of two major MuDR-homologous transcripts that correlate with Mutator activity. In this study, we describe the structure and processing of these two major transcripts. The transcripts are convergent, initiating from opposite ends of the element within the 220-bp terminal inverted repeats. The convergent transcripts do not overlap, and only 200 bp of internal MuDR sequences are not transcribed. Cloning and sequencing of multiple MuDR cDNAs revealed unusual intron/exon junctions, differential splicing, and multiple polyadenylation sites. RNase protection experiments indicated that some splicing failure occurs in young seedlings, and that a low level of antisense RNA exists for both transcripts. On a whole plant level, the presence of the major MuDR transcripts strictly correlates with Mutator activity in that no MuDR transcripts are observed in non-Mutator or inactive Mutator stocks. Examination of various tissues from active Mutator stocks indicates that the two transcripts are present in all organs and tissues tested, including those with no apparent transposition activity. This suggests that Mutator activity is not simply controlled by the level of the major MuDR transcripts.


Subject(s)
DNA Transposable Elements , Regulatory Sequences, Nucleic Acid , Repetitive Sequences, Nucleic Acid , Transcription, Genetic , Zea mays/genetics , Amino Acid Sequence , Base Sequence , Cloning, Molecular , DNA Primers , Genes, Plant , Introns , Molecular Sequence Data , Nucleic Acid Conformation , Polymerase Chain Reaction , RNA Splicing , RNA, Plant/biosynthesis , RNA, Plant/chemistry , Zea mays/metabolism
2.
Trends Cell Biol ; 4(4): 132-8, 1994 Apr.
Article in English | MEDLINE | ID: mdl-14731736

ABSTRACT

Pollen grains of flowering plants are highly specialized two- to three-cell gametophytes that deliver sperm to the ovule. This function is achieved as a result of a complex developmental programme, including the coordinated events of meiotic divisions, the production of a unique extracellular matrix, the establishment of cytoplasmic domains, and a determinative asymmetric cell division. After maturation, pollen must interact specifically with the receptive female tissues and germinate a highly polarized pollen tube that rapidly grows through the style to the ovule. Thus, pollen is an excellent model system for the study of meiotic events, cellular organization, cell-cell interactions and polar growth in plant biology.

3.
Genetics ; 135(4): 1141-50, 1993 Dec.
Article in English | MEDLINE | ID: mdl-8307329

ABSTRACT

The Mutator transposable element system of maize has been used to isolate mutations at many different genes. Six different classes of Mu transposable elements have been identified. An important question is whether particular classes of Mu elements insert into different genes at equivalent frequencies. To begin to address this question, we used a small number of closely related Mutator plants to generate multiple independent mutations at two different genes. The overall mutation frequency was similar for the two genes. We then determined what types of Mu elements inserted into the genes. We found that each of the genes was preferentially targeted by a different class of Mu element, even when the two genes were mutated in the same plant. Possible explanations for these findings are discussed. These results have important implications for cloning Mu-tagged genes as other genes may also be resistant or susceptible to the insertion of particular classes of Mu elements.


Subject(s)
DNA Transposable Elements , Mutagenesis, Insertional , Zea mays/genetics , Blotting, Southern , DNA , Restriction Mapping
5.
Genetics ; 129(1): 261-70, 1991 Sep.
Article in English | MEDLINE | ID: mdl-1657702

ABSTRACT

The Mutator system of maize consists of more than eight different classes of transposable elements each of which can be found in multiple copies. All Mu elements share the approximately 220-bp terminal inverted repeats, whereas each distinct element class is defined by its unique internal sequences. The regulation of instability of this system has been difficult to elucidate due to its multigenic inheritance. Here we present genetic experiments which demonstrate that there is a single locus, MuR1, which can regulate the transposition of Mu1 elements. We describe the cloning of members of a novel class of Mu elements, MuR, and demonstrate that a member of the class is the regulator of Mutator activity, MuR1. This conclusion is based on several criteria: MuR1 activity and a MuR-homologous restriction fragment cosegregate; when MuR1 undergoes a duplicative transposition, an additional MuR restriction fragment is observed, and MuR1 activity and the cosegregating MuR fragment are simultaneously lost within clonal somatic sectors. In addition, the MuR element hybridizes to transcripts in plants with Mutator activity. Our genetic experiments demonstrate that the MuR1 transposon is necessary to specify Mutator activity in our lines.


Subject(s)
DNA Transposable Elements/genetics , Genes, Regulator/genetics , Zea mays/genetics , Blotting, Northern , Blotting, Southern , Cloning, Molecular , Mutagenesis, Insertional/genetics , Nucleic Acid Hybridization , Repetitive Sequences, Nucleic Acid/genetics
6.
Dev Genet ; 10(6): 460-72, 1989.
Article in English | MEDLINE | ID: mdl-2557990

ABSTRACT

The high frequency of mutations in Mutator stocks of maize is the result of transposition of Mu elements. Nine different Mu elements that share the 220 bp Mu terminal inverted repeats have been described. Mu1 elements have been found inserted into most of the molecularly characterized mutant alleles isolated from Mutator stocks, and most Mutator stocks contain a high number of Mu1 elements (10-60). However, it is clear that additional Mu elements, which share the Mu1 termini but have unrelated internal sequences, can also transpose in Mutator stocks. We were interested in comparing the mutation frequency and type of elements that inserted into a particular locus when Mutator stocks with differing numbers of Mu1 elements were utilized. Furthermore, previous studies with Mu-induced mutations have demonstrated that the element that inserted most frequently was Mu1. Therefore, to try to obtain Mu elements different from Mu1 we utilized a stock that had a low number (3-6) of Mu1 elements as well as a Mutator stock with a more typical number of Mu1 elements (20-60). Utilizing both stocks, we isolated numerous mutants at one gene, Bronze 1 (Bz1), and compared the type of elements inserted. In this paper we report that both the high and low Mu1 stocks produced bz1 mutants at frequencies characteristic of Mutator stocks, 6.6 and 4.3 x 10(-5), respectively. We describe the isolation of 20 bz1 mutations, and the initial molecular characterization of eight unstable mutations: two from the high Mu1 stock and six from the low Mu1 stock. The six alleles isolated from the low Mu1 stock appear to contain deleted Mu1 elements, and the two alleles isolated from the high Mu1 stock contain elements very similar to Mu1. When the mutants from the low Mu1 stocks were examined, it was found that the Mu1-related elements increased from 3-6 copies to 9-20 copies in one generation. The high number of Mu1-related elements was maintained in subsequent outcrosses. This spontaneous activation and amplification of Mu1-related elements occurred in at least 1% of the low Mu1 plants.


Subject(s)
DNA Transposable Elements/genetics , Mutation , Zea mays/genetics , Alleles , Blotting, Southern , Cloning, Molecular , Gene Amplification/genetics , Restriction Mapping
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