Analysis of a case of somatic instability in a strain of maize from India

A case of somatic instability affecting aleurone colour in a strain of maize from India with flint background was analysed. The somatic instability is localized to theC ¹ (Inhibitor) allele ofC locus on the short arm of chromosome 9. Molecular tests indicated thatAc is not present in the Indian stock and the evidence is consistent with the involvement of theEn (Spm) transposable element in the instability. The presence of theEn (Spm)-like element in the stock would suggest that these elements have been present in the maize genome for a long time. A new allele ofshrunken (sh1) gene with a somewhat unorthodox breeding behaviour is also described.     

The inveterate wanderer: study of Enhancer wandering on chromosome 3 in maize

The transposition of the maize transposable element Enhancer (En) had been focused on one chromosome 3 for several generations. From the a1-m(Au) allele with an autonomous En, a new En reporter allele a1-m(r)3927-1, was isolated that undergoes very infrequent and late excision events, producing one or two small spots in the aleurone. This allele is seriously impaired in its capacity to excise. Coincident with the origin of this allele, an En was located at a site close to the a1 locus. From this initial insertion site, the movement of this En was followed for three to four generations in 974 families with a higher transposition rate of this En (50% of the testcross progeny) than that found in a previous study of En transposition. This is the first case reported where a particular En was followed for more than three generations. The higher rate of wanderings of this En along the same chromosome led to the term vagabond En (En ^vag ). Genetic evidence that En may transpose from a replicated donor site to an unreplicated site is provided. Speculative mechanisms on the origin of a1-m(r)3927-1 and En ^vag are discussed.Journal Paper No. J-15864 of Iowa Agricultural and Iowa Economical Experiment Station Project #3176     

Basis for the diversity of states of controlling elements in maize

Summary In maize the insertion of a controlling element such as the regulatory element, En, (Enhancer) at a locus generates diverse derivatives. These derivatives include stable phenotypes that range from colorless to full color. Distinguishable patterns are determined by timing and frequency of mutation events. It has been hypothesized that diverse expressions are based either on position of the controlling element at the locus or composition differences among controlling elements. — Experiments with two target loci, A2 and C, indicate that the previous pattern of a controlling element does not influence the pattern generated at a new site. This finding supports the hypothesis that these diverse trans-effects of En are not caused by a change in the genetic information of En itself but rather by its position; diverse expressions are a manifestation of the effect of an element at a specific locus site. — Controlling elements are discussed in relation to chromosome structure, gene activation, gene programming and possible parallels in prokaryotes.Journal Paper No. J-8416 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa 50011. Project No. 1884. Support from NSF GB38328     

Definition and characterization of an artificial En/Spm-based transposon tagging system in transgenic tobacco

A transposon tagging system for heterologous hosts, based on the maize En/Spm transposable element, was developed in transgenic tobacco. In this system, the two En-encoded trans-acting factors necessary for excision are expressed by fusing their cDNAs to the CaMV 35S promoter. The dSpm receptor component is inserted in the 5-untranslated leader of the bar gene. Germinal revertants can therefore be selected by seed germination on L-PPT-containing medium or by spraying seedlings with the herbicide Basta. Using this bar-based excision reporter construct, an average frequency of germinal excision of 10.1% was estimated for dSpm-S, an En/Spm native internal deletion derivative. Insertion of En-foreign sequences in a receptor, such as a DHFR selectable marker gene in dSpm-DHFR, does not abolish its capacity to transpose. However, dSpm-DHFR has a lower frequency of somatic and germinal excision than dSpm-S. Revertants carrying a transposed dSpm-DHFR element can be selected with methotrexate. Germinal excision is frequently associated with reinsertion but, as in maize, dSpm has a tendency to integrate at chromosomal locations linked to the donor site. Concerning the timing of excision, independent germinal transpositions are often found within a single seed capsule. All activity parameters analysed suggest that transposon tagging with this system in heterologous hosts should be feasible.     

Enhancer transposable element induced changes at the A locus in maize: The a-m-1 6078 allele

Summary Transposable (controlling) elements in maize are highly variable in their versatility in inducing changes at any locus. With the Enhancer (En) (Suppressor-Mutator-Spm) controlling-element system,a multitude of changes result from the action of En on specific alleles. One such allele, McClintock's a-m-1 6078 allele, illustrates the diversity of events that can take place that involve three parameters; namely, spotting-timing, spotting-frequency, and background pigment formation with and without En. A series of derivative alleles has been isolated and described according to the three paramters. The multitude of changes that has been isolated illustrates the striking versatility of these transposing elements to initiate changes at the controlled locus.Journal Paper No. J-11135 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa, Project No. 2381     

Transposition of the enhancer controlling element system in maize

Summary Controlling elements have the ability to activate or inactivate standard genes. One of the unique features of controlling elements is their ability to transpose from one position to another on the same chromosome or to another chromosome. In this study, the transposition of the controlling element En was examined in its transposition from its initial site at the al locus to a primary site and then to secondary sites, all within the distal two-thirds of the 3L maizechromosome arm.Stable germinal mutations representing losses of En were selected from three different autonomously mutating al alleles. The insertion of En at a new location was confirmed by crosses of the stable mutants to responsive tester lines. The position of En at the primary transposition site was determined by backcrossing to an al et line using standard three-point tester crosses. Secondary transpositions were detected by Chi-square comparisons of progeny to parental En linkage values.Although En positions were found throughout the segment of chromosome examined, their distribution was not random and some regions of the chromosome were more likely to contain an inserted En. Ens from all three autonomously mutating source alleles showed the same regional preferences. Distributions of transposed Ens on chromosome 3L from the three original unstable al alleles were not significantly different in Chi-square tests. Both primary and secondary sites of insertion were located within these regions. No differences were found between the distribution of primary sites of insertion and the distribution of secondary sites. Statistically significant differences were found between the distributions of transposing and non-transposing Ens.Formerly graduate student, ISU, now with Monsanto Agricultural Products Co., 800 N. Lindbergh Blvd. St. Louis, MO 63166, and Professor of the Department of Agronomy, Iowa State University, Ames, 1A 50011     

A two-element Enhancer-Inhibitor transposon system in Arabidopsis thaliana

The Enhancer-Inhibitor (En-I), also known as Suppressor-mutator (Spm-dSpm), transposable element system of maize was modified and introduced into Arabidopsis by Agrobacterium tumefaciens transformation. A stable En/Spm transposase source under control of the CaMV 35S promoter mediated frequent transposition of I/dSpm elements. Transposition occurred continuously throughout plant development over at least seven consecutive plant generations after transformation. New insertions were found at both linked and unlinked positions relative to a transposon donor site. The independent transposition frequency was defined as a transposition parameter, which quantified the rate of unique insertion events and ranged from 7.8% to 29.2% in different populations. An increase as well as a decrease in I/dSpm element copy number was seen at the individual plant level, but not at the population level after several plant generations. The continuous, frequent transposition observed for this transposon system makes it an attractive tool for use in gene tagging in Arabidopsis.     

Spm and I element changes with the a-m2 8004 allele in maize

Summary Among the mobile element systems in maize, the En (Spm) system (En — the regulatory element and I the receptive element — a nonfunctional En) has several interesting aspects of control of gene expression (En and Spm are homologous in structure and activity). One of the alleles arising from the Spm group included the a-m2 8004 allele that has a low spotting pattern and unique ringed areas. The interest in this allele is that Spm or En will induce it to co-express the A phenotype and mutability. Several exceptions of the allele were analyzed. Two are Spm changes and two are I changes. The analysis shows that the heritable changes include I changes that are co-expressed in various grades of color and different degrees of mutability. All these changes occur with I at the locus. The Spm changes also include changes in mutability patterns and a mottling pattern.Journal Paper No., J-11792 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa, Project No. 2381     

Y chromosome-specific mutations induced by a giant transposon in Drosophila hydei

Summary The w ^m Co duplication of Drosophila hydei (Dp (1; Y) 16B2-17B1) contains 13–16 bands in salivary gland chromosomes. The duplication resides preferentially in the X heterochromatin or on the Y chromosome. In some stocks frequent (up to 4×10^-3) exchanges of the duplication occur between different Y chromosomes (T(X; Y) and free Y) or between the X and the Y chromosome. About 60% of the T(X; Y)-Y exchanges induce mutations in the Y chromosomal male fertility genes of the recipient Y chromosome. From the mutational spectrum generated by the T(X; Y)-Y transpositions and from the variable efficiency as acceptor of different X-Y translocations it can be concluded that the exchanges show a remarkable site specificity: distal positions in the long arm of the Y chromosome are occupied preferentially. More proximal positions in the long arm of insertions into the short arm of the Y chromosome are found only with a lower frequency. No transpositions to the autosomes have been recovered. Duplications are lost with highly differing frequencies. The losses are not linked with insertions of the w ^m Co element into a new position and are more frequent than transpositions. Therefore, we regard the w ^m Co element as a giant transposon.     

Frequency and distance of transposition of a modifiedDissociation element in transgenic tobacco

Effective transposon tagging with theAc/Ds system in heterologous plant species relies on the accomplishment of a potentially high transposon-induced mutation frequency. The primary parameters that determine the mutation frequency include the transposition frequency and the transposition distance. In addition, the development of a generally applicable transposon tagging strategy requires predictable transposition behaviour. We systematically analysedDs transposition frequencies andDs transposition distances in tobacco. An artificialDs element was engineered with reporter genes that allowed transposon excision and integration to be monitored visually. To analyse the variability ofDs transposition between different tobacco lines, eight single copy T-DNA transformants were selected. Fortrans-activation of theDs elements, differentAc lines were used carrying an unmodifiedAc ⁺ element, an immobilizedsAc element and a stableAc element under the control of a heterologous chalcone synthas (chsA) promoter. With allAc elements, eachDs line showed characteristic and heritable variegation patterns at the seedling level. SimilarDs line-specificity was observed for the frequency by whichDs transpositions were germinally transmitted, as well as for the distances of theDs transpositions. ThesAc element induced transposition ofDs late in plant development, resulting in low germinal transposition frequencies (0.37%) and high incidences of independent transposition (83%). The majority of theseDs elements (58%) transposed to genetically closed linked sites (10 cM).     

Analysis of the chromosomal distribution of transposon-carrying T-DNAs in tomato using the inverse polymerase chain reaction

We are developing a system for isolating tomato genes by transposon mutagenesis. In maize and tobacco, the transposon Activator (Ac) transposes preferentially to genetically linked sites. To identify transposons linked to various target genes, we have determined the RFLP map locations of Ac- and Dissociation (Ds)-carrying T-DNAs in a number of transformants. T-DNA flanking sequences were isolated using the inverse polymerase chain reaction (IPCR) and located on the RFLP map of tomato. The authenticity of IPCR reaction products was tested by several criteria including nested primer amplification, DNA sequence analysis and PCR amplification of the corresponding insertion target sequences. We report the RFLP map locations of 37 transposon-carrying T-DNAs. We also report the map locations of nine transposed Ds elements. T-DNAs were identified on all chromosomes except chromosome 6. Our data revealed no apparent chromosomal preference for T-DNA integration events. Lines carrying transposons at known map locations have been established which should prove a useful resource for isolating tomato genes by transposon mutagenesis.     

Developing a transposon tagging system to isolate rust-resistance genes from flax

Summary A line of flax, homozygous for four genes controlling resistance to flax rust, was transformed with T-DNA vectors carrying the maize transposable elements Ac and Ds to assess whether transposition frequency would be high enough to allow transposon tagging of the resistance genes. Transposition was much less frequent in flax than in Solanaceous hosts such as tobacco, tomato and potato. Transposition frequency in callus tissue, but not in plants, was increased by modifications to the transposase gene of Ac. Transactivation of the excision of a Ds element was achieved by expressing a cDNA copy of the Ac transposase gene from the Agrobacterium T-DNA 2 promoter. Progeny of three plants transformed with Ac and 15 plants transformed with Ds and the transposase gene, were examined for transposition occurring in the absence of selection. Transposition was observed in the descendants of only one plant which contained at least nine copies of Ac. Newly transposed Ac elements were observed in 25–30% of the progeny of some members of this family and one active Ac element was located 28.8 (SE=6.3) map units from the L ⁶ rust-resistance gene. This family will be potentially useful in our resistance gene tagging program.     

Invasion of thehobo transposable element studied byin situ hybridization on polytene chromosomes ofDrosophila melanogaster

The invasion kinetics ofhobo transposable element in theDrosophila melanogaster genome was studied byin situ hybridization on the polytene chromosomes. Six independent lines ofDrosophila melanogaster flies that had been previously transformed by microinjection of the pHFL1 plasmid containing a completehobo element were followed over 50 generations. We observed thathobo elements were scattered on each of the chromosome arms, with more insertion sites on the 3R arm. The total number of insertion sites remains quite small, between four and six, at generation 52. On the 2R arm, a short inversion appeared once at generation 52. Most of the integration sites reported here were already described for several transposons but some of them appear to be hotspots forhobo elements.     

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     

Genetic and molecular analysis of a three-component transposable-element system in maize

Summary Two different factors control the mutability of an unstable allele (c2-m8810581) of the C2 gene of maize. Both an autonomous En/Spm element and an unrelated independent factor, named Mediator, are coordinately required for the excision of the insert in c2-m881058Y. According to genetic analysis, Mediator does not have the suppressor (S) function or mutator (M) function of En/Spm. Mediator has no effect on the timing or frequency of excision of Enl, En-low, or various I/dSpm elements. Hence, Mediator only mediates a specific interaction between En and the insert at c2m881058Y. Molecular analysis of c2-m881058Y has revealed a 3.3 kb, complex, En-related receptor element inserted into the second exon of the C2 gene. The ends of this element are homologous to the ends of En/Spm, but an internal l.7 kb region shows no En/Spm homology. A great degree (11–14%) of nucleotide changes, relative to Enl, occur within and between the 12 bp TNPA binding motifs. Alterations of these critical cis-determinants may account for the need for a helper factor for excision. This element is named Irma, for Inhibitor that requires Mediator also, and represents a unique, low copy number class of receptor element.     

Introduction and transposition of the maize transposable element Ac in rice (Oryza sativa L.).

Summary To develop a transposon tagging system in an important cereal plant, rice (Oryza sativa L.), the maize transposable element Ac (Activator) was introduced into rice protoplasts by electroporation. We employed a phenotypic assay for excision of Ac from the selectable hph gene encoding resistance to hygromycin B. Southern blot analysis of hygromycin B-resistant calli showed that the Ac element can transpose from the introduced hph gene into the rice chromosomes. Sequence analysis of several Ac excision sites in the hph gene revealed sequence alterations characteristic of the excision sites of this plant transposable element. The Ac element appears to be active during development of transgenic rice plants from calli. Moreover, hybridization patterns of different leaves from the same plant indicated that some Ac elements are stable whereas others are able to transpose further during development of leaves. The results indicate that the introduced Ac element can transpose efficiently in transgenic rice plants.     

The use of transgenic plants to understand transposition mechanisms and to develop transposon tagging strategies

This review compares the activity of the plant transposable elements Ac, Tam3, En/Spm and Mu in heterologous plant species and in their original host. Mutational analysis of the autonomous transposable elements and two-element systems have supplied data that revealed some fundamental properties of the transposition mechanism. Functional parts of Ac and En/Spm were detected by in vitro binding studies of purified transposase protein and have been tested for their importance in the function of these transposable elements in heterologous plant species. Experiments that have been carried out to regulate the activity of the Ac transposable element are in progress and preliminary results have been compiled. Perspectives for manipulated transposable elements in transposon tagging strategies within heterologous plant species are discussed.     

Somatic mobility of the maize element Ac and its utility for gene tagging in aspen

We have investigated the somatic activity of the maize Activator (Ac) element in aspen with the objective of developing an efficient transposon-based system for gene isolation in a model tree species. The analysis of the new insertion sites revealed the exact reconstitution of the Ac, however, aberrant transposition events were also found. Characterization of the genomic sequences flanking the Ac insertions showed that about one third (22/75) of the sequences were significantly similar to sequences represented in public databases and might correspond to genes. The frequency of Ac landing into coding regions was about two-fold higher when compared to the frequency of T-DNA hitting the predicted genes (5/32) in the aspen genome. Thus, Ac is demonstrated to be a potentially useful heterologous transposon tag in a tree species. This is the first report on transposon-based gene tagging in a tree species describing the excision and reinsertion of transposable element into new genomic positions. We also suggest a heterologous transposon tagging strategy that can be used in aspen somatic cells to obtain dominant gain-of-function mutants and recessive loss-of-function mutants overcoming the regeneration time barrier of a long-lived tree species.     

Post-integration behavior of a Minos transposon in the malaria mosquito Anopheles stephensi

Transposable elements represent important tools to perform functional studies in insects. In Drosophila melanogaster, the remobilization properties of transposable elements have been utilized for enhancer-trapping and insertional mutagenesis experiments, which have considerably helped in the functional characterization of the fruitfly genome. In Anopheles mosquitoes, the sole vectors of human malaria, as well as in other mosquito vectors of disease, the use of transposons has also been advocated to achieve the spread of anti-parasitic genes throughout field populations. Here we report on the post-integration behavior of the Minos transposon in both the germ-line and somatic tissues of Anopheles mosquitoes. Transgenic An. stephensi lines developed using the piggyBac transposon and expressing the Minos transposase were tested for their ability to remobilize an X-linked Minos element. Germ-line remobilization events were not detected, while somatic excisions and transpositions were consistently recovered. The analysis of these events showed that Minos activity in Anopheles cells is characterized by unconventional functionality of the transposon. In the two cases analyzed, re-integration of the transposon occurred onto the same X chromosome, suggesting a tendency for local hopping of Minos in the mosquito genome. This is the first report of the post-integration behavior of a transposable element in a human malaria vector. Christina Scali and Tony Nolan contributed equally to the work.