Covalent DNA modification and the regulation of Mutator element transposition in maize

Summary Analyses of the multiple genomic Mu transposable elements in active Mutator lines with several C-methylation sensitive restriction enzymes indicate that Mu elements are undermodified compared with total maize nuclear DNA. Intercrossing of diverse Mutator lines leads to a discrete hypermodification of the Mu elements in a particular plant concurrent with a loss of mutagenic and transpositional potential. The modification events observed appear to be methylation of cytosine at the 5 position in the sequences 5-CG-3 and 5-CNG-3. Some potential C-methylation sites in Mu elements show a higher degree of methylation than others. Once established, the modified Mu state, like the loss of Mutator activity, is stable on outcrossing. Crosses between active Mutator lines with unmodified Mu elements and Mutator-loss lines with modified Mu elements show partial maternal dominance for the modification event. Mutator activity may also be lost thorugh outcrossing in a mechanism not associated with any detected modification events.     

Molecular analysis of the loss of somatic instability in the bz2::mu1 allele of maize

Summary Multiple genetic and epigenetic changes were detected within one plant generation at the bz2:: mu1 mutable allele in a population of 118 plants. Loss of somatic instability in bz2::mu1 was usually correlated with methylation of the Mu1 transposable element; in 6 plants, somatic instability was lost as a result of mutations in bz2::mu1. This is a surprisingly high frequency of mutation per allele (2.5%) for the Mutator family, for which germinal revertants occur at a frequency of about 10^–4 per gamete. One germinal excision event was found that contained an 8 by deletion, frameshift mutation in Bronze-2. The three other mutants described occurred as a result of abortive transposition, in which 75–77 by deletions were generated at the junction between Bronze-2 and Mu1. We discuss the possible mechanisms, and the role of host factors in abortive transposition in maize.     

Molecular characterization of Mutator systems in maize embryogenic callus cultures indicates Mu element activity in vitro

Summary Active Mutator lines of maize (Zea mays L.) are characterized by their ability to generate new mutants at a high rate and by somatic instability at Mutator-induced mutant alleles. Mutagenically active lines with fewer than ten Mu elements per diploid genome have not been observed. Alteration of Mutator activity has been shown to correlate with the state of modification of Hinfl restiction sites that lie within inverted terminal repeats of Mu elements. To determine whether active Mutator systems can be established and maintained in culture, copy number and modification state of Mu elements were investigated in embryogenic callus lines derived from F₁S of crosses of active Mutator stock with the inbred lines A188 and H99. All callus lines studied maintain high Mu-element copy numbers, and more than half show a continued lack of modification at the Mu element Hinfl sites; thus, parameters associated with mutagenic activity in planta are present in some, but not all, callus lines. Mutator activity was then tested directly by restriction fragment analysis of subclonal populations from A188/Mu ² and H99/Mu ² embryonic cultures. Novel Mu-homologous restriction fragments occurred in 38% of the subpopulations which contained unmodified Mu elements, but not in control cultures containing modified, genetically inactive Mu elements. We conclude that Mu elements from active Mutator parents can remain transpositionally active in embryogenic cell culture. Active Mutator cell lines may be useful for the production of mutations in vitro.     

Germinal and somatic products of Mu1 excision from the Bronze-1 gene of Zea mays

Summary Germinal and somatic excision products of Mu1 from the insertion allele bz::mu1 were selectively amplified from maize cob tissue. The sequence of these footprints often included deletions at the target site, suggesting that substantial exonucleolytic degradation occurs upon excision of the element. In addition to deletions of target site sequences, single base insertions were also found. The isolation of an excision product including a 4 by inverted duplication of the target site provides evidence that the double-stranded chromosomal break generated by Mu excision may be terminated by a covalently closed hairpin structure. The majority of excision products, however, do not include inverted duplications of target site sequences, suggesting that such structures are the result of occasional repair activities, rather than an essential step in the mechanism of Mu excision. The sequence of the Mu insertion sites of the bz::mu1 and bz::mu2 alleles is also presented.     

Studies on the Mx transposable element system in maize recovered from X-irradiated stocks

Summary The unstable mutant bz-x3m arose in a plant subjected to X-irradiation. The element at the bronze locus is non-autonomous and recombination data indicate that an autonomous element is tightly linked. The autonomous element has been designated Mx (mobile element induced by X-rays) and the non-autonomous element, rMx (responder to Mx). Linkage data indicate that a second Mx lies near the end of the short arm of chromosome 9; in one plant, an Mx that is unlinked was detected. Distinguishing characteristics of bz-x3m are a large window of time in endosperm development during which somatic reversions can arise and a wide range in the frequency at which they occur; these features are heritable. With increasing doses of bz-x3m and Mx, the window expands and the frequency range increases. In kernels containing the bz-x3m allele and the tightly linked Mx, breakage occurs in chromosome 9 distal to the C locus, resulting in breakage-fusion-bridge patterns for endosperm markers that lie proximal to the break. The frequency of breaks and the developmental time at which they occur exhibit the same dosage effect as the somatic reversions of the bz-x3m allele. These observations suggest that an rMx (designated rMxBr) that causes chromosome breakage is positioned distal to the C locus. At the molecular level, the bz-x3m allele is associated with a 0.5 kb increase in fragment size in DNA samples digested with BglII, EcoRI, HindIII and PstI; in germinal revertants, the fragment size returns to that of the progenitor.     

Genetic regulation of somatic mutability of two Mu-induced a1 mutants of maize

Summary Previous studies of stocks of two Mutator-induced mutable a1 alleles (a1-Mum2 and al-Mum3) gave results consistent with the presence of one or more autonomous elements regulating the expression of mutability. This article reports on the results of studies designed to map these autonomous elements by using a series of waxy marked translocations. Linkage of waxy with autonomous elements was found for a1-Mum2 by using the translocations wx T2-9d, wx T4-9e and wx T4-9b. Several different linkage values were found in crosses involving wx T2-9d, suggesting that autonomous elements have transposed to different locations on chromosome 2. Linkage of autonomous elements with waxy was found for a1-Mum3 using translocation wx T2-9d. Again, several different linkage values were found. Some of these values were the same as those observed for a1-Mum2, but some were unique. In some crosses, the number of autonomous elements increased by one or two unlinked elements in addition to the linked element in one generation (i. e. the generation of the cross to the translocation series). Such an increase in number is probably the result of transposition of the original autonomous element to an independent locus while retaining the autonomous element at the original locus. Reduction in the number of autonomous elements is probably the result of the independent assortment in crosses of plants with two or more autonomous elements.Journal Paper No. J-14569 of The Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa Project No 2870     

Enhanced frequency of transposition of the maize transposable elementActivator following excision from T-DNA inPetunia hybrida

Many of the systems currently employed for heterologous transposon tagging in plants rely on an excision assay to monitor transposon activity. We have used the streptomycin phosphotransferase (SPT) reporter system to assayAc activity inPetunia hybrida. In other species, such as tobacco orArabidopsis, excision ofAc from the SPT gene in sporogenous tissue gives rise to streptomycin-resistant seedlings in the following generation. The frequency of fully streptomycin-resistant seedlings in petunia was low (0.4%) but molecular analysis of these indicated that the actual excision frequency may be as low as 0.05%. This indicates that the SPT assay is not a reliable selection criterion for germinal excision in petunia. Extensive molecular screening for reinsertion ofAc was consistent with a low primary transposition frequency (0%–0.6%). In contrast to these findings, the progeny of confirmed germinal transpositions for three independent transformants showed frequent transposition to new sites (9.5%–17.0%). This suggests a high frequency of secondary transposition compared with primary transposition from the T-DNA. Segregation analysis indicates that the high transposition activity is closely associated with transposed copies ofAc. No evidence was found for an altered methylation state forAc following transposition. The implications of these results for heterologous transposon tagging in petunia are discussed in the context of the reliability of excision reporter systems in general.     

High transposition rates of Osvaldo, a new Drosophila buzzatii retrotransposon

Transposition of a new Drosophila retrotransposon was investigated. Total genomic Southern analysis and polytene in situ hybridizations in D. buzzatii strains and other related species using a 6 kb D. buzzatii clone (cDb314) showed a dispersed, repetitive DNA pattern, suggesting that this clone contains a transposable element (TE). We have sequenced the cDb314 clone and demonstrated that it contains all the conserved protein sequences and motifs typical of retrovirus-related sequences. Although cDb314 does not include the complete TE, the protein sequence alignment demonstrates that it includes a defective copy of a new long terminal repeat (LTR) retrotransposon, related to the gypsy family, which we have named Osvaldo. Using a D. buzzatii inbred line in which all insertion sites are known, we have measured Osvaldo transposition rates in hybrids between this D. buzzatii line and its sibling species D. koepferae. The results show that Osvaldo transposes in bursts at high rate, both in the D. buzzatii inbred line and in species hybrids.This paper is dedicated posthumously to Osvaldo A. Reig in recognition of his contributions to evolutionary biology and his early appreciation of the role of transposable elements in evolution     

Genetic evidence of a relationship between two maize transposable element systems: Cy and Mutator

Summary The Cy transposable element system is composed of two genetically defined elements: an rcy receptor element inserted at the Bronze-1 locus; and an independently segregating regulatory element, Cy. The Cy system is not functionally homologous to any of the non-Mutator transposable element systems. Evidence is presented that supports a relationship between the Cy system and the family of Mu1-homologous transposable elements that are responsible for the Mutator phenomenon. Although related, Cy elements and the Mu1-homologous elements are not identical; Cy is inherited in a near-Mendelian fashion, in contrast to the non-Mendelian inheritance of the Mu1-homologous elements.     

Mechanism of Ds1 excision from the genome of maize streak virus

Summary We have previously shown that the maize transposable element Ds1 introduced into maize plants by agroinfection can be excised from the genome of geminivirus maize streak virus (MSV). Excision depended strictly on the presence of an active Ac element in the plants. In this study, the excision products or footprints left in the MSV genome after Ds1 excision were extensively characterized and the effects of flanking sequences on Ds1 excision were analysed. Most types of footprints obtained were comparable to those described for Ds1 excision in the maize genome, and could be explained by the models proposed for excision of plant transposable elements. In two revertants, however, some terminal sequences of the Ds1 element were found to have been left behind at the excision site. The finding of this novel type of Ds1 footprint indicated that gene conversion events occurred during and/or after Ds1 excision from the MSV genome. A partial deletion of one copy of the 8 by duplications flanking the Ds1 element had no effect on the frequency or on the types of footprints of Ds1 excision from the MSV genome. Thus, the duplicated 8 by sequences flanking the transposable element are not involved in Ds1 excision. These results, as well as a statistical analysis of the modifications of the bases flanking the Ds1 element after excision, are discussed in terms of excision models.     

Preferential transposition ofAc to linked sites in Arabidopsis

We have investigated the pattern of transposition of an intact, 4.6-kbAc element inArabidopsis thaliana. Because the trans-acting transposition function (transposase) ofAc is not fully penetrant in Arabidopsis, it is not possible to use it as a diagnostic feature to scoreAc genetically, as has been done in maize and tobacco. Instead, the presence or absence of a transposedAc (trAc) was monitored by Southern blots. Germinal transpositions from the marker SPT::Ac were selected using a streptomycin germination assay and scored for the presence of atrAc. Segregation of thetrAc element and the SPT donor locus was scored in the F₂ progeny of the germinal revertants, and the recombination fraction between thetrAc element and SPT was estimated by the method of maximum likelihood. We have found that, as in maize and tobacco, receptor sites fortrAcs in Arabidopsis tend to be linked to theAc donor locus.     

The binding motifs for Ac transposase are absolutely required for excision of Ds1 in maize

A reverse genetic system for studying excision of the transposable elementDs1 in maize plants has been established previously. In this system, theDs1 element, as part of the genome of maize streak virus (MSV), is introduced into maize plants via agroinfection. In the presence of theAc element, excision ofDs1 from the MSV genome results in the appearance of viral symptoms on the maize plants. Here, we used this system to study DNA sequences requiredin cis for excision ofDs1. TheDs1 element contains theAc transposase binding motif AAACGG in only one of its subterminal regions (defined here as the 5′ subterminal region). We showed that mutation of these motifs abolished completely the excision capacity ofDs1. This is the first direct demonstration that the transposase binding motifs are essential for excision. Mutagenesis with oligonucleotide insertions in the other (3′) subterminal region resulted in elements with either a reduced or an increased excision efficiency, indicating that this subterminal region also has an important function.     

Binding sites for maize nuclear proteins in the terminal inverted repeats of the Mul transposable element

Summary Nuclear protein extracts from Mu-active, Mu-inactive and non-Mutator lines of maize were used to identify the binding sites for maize nuclear proteins in the terminal inverted repeats (TIR) of the Mul transposable element. We found binding activities of nuclear proteins that specifically interact with both TIRs of the Mu1 element. DNase I footprinting was performed to localize the binding sites. We found that the nuclear proteins from Mu-active lines and non-Mu lines bound to the Mu1 TIR at two different sites, i.e. a 13 by sequence (CGGGAACGGTAAA, designated as site I) and another 8 by sequence (CGGCGTCT, designated as site II). However, the nuclear proteins from Mu-inactive lines bound only one of these sites, i.e. site I. Mobility shift assays with synthetic oligonucleotides containing site I and 11 respectively confirmed the specificities of these binding activities. Site I was shown to be an imperfect direct repeat of a hexamer binding site (CGGGAA CGGTAA). Oligonucleotides containing either of the hexamers showed specific binding activity to nuclear protein from both Mu-active and Mu-inactive lines. The possible role of these proteins in Mu transposition is discussed.     

H-NS蛋白对副溶血弧菌hcp1的转录调控

【目的】研究调控子H-NS对副溶血弧菌T6SS1结构蛋白基因hcp1的转录调控机制。【方法】利用Western blot检测Hcp1蛋白在野生株(WT)和hns基因敲除株(Δhns)中表达水平的差异。提取WT和Δhns的总RNA,采用实时定量RT-PCR的方法验证H-NS对hcp1的转录调控关系。进而采用引物延伸实验研究hcp1的转录起始位点,并根据产物的丰度判断H-NS对hcp1的调控关系。PCR扩增hcp1的整个启动子区DNA序列,并纯化His-H-NS蛋白,通过凝胶阻滞实验(EMSA)验证His-H-NS对hcp1启动子区是否具有直接的结合作用。【结果】Western blot和实时定量RT-PCR结果显示H-NS能抑制hcp1的表达;引物延伸结果显示hcp1只有一个转录起始位点T(–62)(翻译起始位点为+1),且其转录活性是H-NS和σ54依赖性的;EMSA实验表明H-NS对hcp1的启动子区具有直接的结合作用。【结论】H-NS能直接结合到hcp1启动子区而抑制其转录表达。     

Chromosome labeling with transposable elements in maize

Transposable elements randomly insert into a targeted locus at a frequency of 10^-6 to 10^-5. The En element has been shown in previous studies to transpose more frequently into closely linked sites. Thus, it is appropriate to place an En element onto each of the 20 chromosome arms in maize to maximize tagging efficiency. This is called chromosome labeling for tagging purposes with transposons. After a chromosome arm has been labeled with a transposon, genes residing in that arm will have a greater chance to be tagged by the transposon. To date, all of the maize chromosome arms have been labeled with at least one of five Encontaining alleles. The elements were linked to the arms using reciprocal translocations. The usage of these arm-labeled lines is discussed in the context of gene tagging.Journal Paper No. 15224 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa; Project No. 3176