Regulation of the timing of transposable element excision during maize development

Ultra-deep sequencing of somatic mutations induced by a maize transposon

Cells accumulate mutations throughout development, contributing to cancer, aging, and evolution. Quantitative data on the abundance of de novo mutations within plants or animals are limited, as new mutations are often rare within a tissue and fall below the limits of current sequencing depths and error rates. Here, we show that mutations induced by the maize Mutator (Mu) transposon can be reliably quantified down to a detection limit of 1 part in 12,000. We measured the abundance of millions of de novo Mu insertions across four tissue types. Within a tissue, the distribution of de novo Mu allele frequencies was highly reproducible between plants, showing that, despite the stochastic nature of mutation, repeated statistical patterns of mutation abundance emerge. In contrast, there were significant differences in the allele frequency distribution between tissues. At the extremes, root was dominated by a small number of highly abundant de novo insertions, while endosperm was characterized by thousands of insertions at low allele frequencies. Finally, we used the measured pollen allele frequencies to reinterpret a classic genetic experiment, showing that evidence for late Mu activity in pollen are better explained by cell division statistics. These results provide insight into the complexity of mutation accumulation in multicellular organisms and a system to interrogate the factors that shape mutation abundance.

Mutator and MULE Transposons

The Mutator system of transposable elements (TEs) is a highly mutagenic family of transposons in maize. Because they transpose at high rates and target genic regions, these transposons can rapidly generate large numbers of new mutants, which has made the Mutator system a favored tool for both forward and reverse mutagenesis in maize. Low copy number versions of this system have also proved to be excellent models for understanding the regulation and behavior of Class II transposons in plants. Notably, the availability of a naturally occurring locus that can heritably silence autonomous Mutator elements has provided insights into the means by which otherwise active transposons are recognized and silenced. This chapter will provide a review of the biology, regulation, evolution and uses of this remarkable transposon system, with an emphasis on recent developments in our understanding of the ways in which this TE system is recognized and epigenetically silenced as well as recent evidence that Mu-like elements (MULEs) have had a significant impact on the evolution of plant genomes.

Early embryogenesis-specific expression of the rice transposon Ping enhances amplification of the MITE mPing

Miniature inverted-repeat transposable elements (MITEs) are numerically predominant transposable elements in the rice genome, and their activities have influenced the evolution of genes. Very little is known about how MITEs can rapidly amplify to thousands in the genome. The rice MITE mPing is quiescent in most cultivars under natural growth conditions, although it is activated by various stresses, such as tissue culture, gamma-ray irradiation, and high hydrostatic pressure. Exceptionally in the temperate japonica rice strain EG4 (cultivar Gimbozu), mPing has reached over 1000 copies in the genome, and is amplifying owing to its active transposition even under natural growth conditions. Being the only active MITE, mPing in EG4 is an appropriate material to study how MITEs amplify in the genome. Here, we provide important findings regarding the transposition and amplification of mPing in EG4. Transposon display of mPing using various tissues of a single EG4 plant revealed that most de novo mPing insertions arise in embryogenesis during the period from 3 to 5 days after pollination (DAP), and a large majority of these insertions are transmissible to the next generation. Locus-specific PCR showed that mPing excisions and insertions arose at the same time (3 to 5 DAP). Moreover, expression analysis and in situ hybridization analysis revealed that Ping, an autonomous partner for mPing, was markedly up-regulated in the 3 DAP embryo of EG4, whereas such up-regulation of Ping was not observed in the mPing-inactive cultivar Nipponbare. These results demonstrate that the early embryogenesis-specific expression of Ping is responsible for the successful amplification of mPing in EG4. This study helps not only to elucidate the whole mechanism of mPing amplification but also to further understand the contribution of MITEs to genome evolution.

Transposable elements are major components of eukaryotic genomes, comprising a large portion of the genome in some species. Miniature inverted-repeat transposable elements (MITEs), which belong to the class II DNA transposable elements, are abundant in gene-rich regions, and their copy numbers are very high; therefore, they have been considered to contribute to genome evolution. Because MITEs are short and have no coding capacity, they cannot transpose their positions without the aid of transposase, provided in trans by their autonomous element(s). It has been unknown how MITEs amplify themselves to high copy numbers in the genome. Our results demonstrate that the rice active MITE mPing is mobilized in the embryo by the developmental stage-specific up-regulation of an autonomous element, Ping, and thereby successfully amplifies itself to a high copy number in the genome. The short-term expression of Ping is thought to be a strategy of the mPing family for amplifying mPing by escaping the silencing mechanism of the host genome.

Isolation of sequences flanking Ac insertion sites by Ac casting

Localizing Ac insertions is a fundamental task in studying Ac-induced mutation and chromosomal rearrangements involving Ac elements. Researchers may sometimes be faced with the situation in which the sequence flanking one side of an Ac/Ds element is known, but the other flank is unknown. Or, a researcher may have a small sequence surrounding the Ac/Ds insertion site and needs to obtain additional flanking genomic sequences. One way to rapidly clone unknown Ac/Ds flanking sequences is via a PCR-based method termed Ac casting. This approach utilizes the somatic transposition activity of Ac during plant development, and provides an efficient means for short-range genome walking. Here we describe the principle of Ac casting, and show how it can be applied to isolate Ac macrotransposon insertion sites.

Widespread, abundant, and diverse TE-associated siRNAs in developing wheat grain

Small RNAs related to RNA interference are key molecules in many developmental processes, in which they can both regulate developmental gene expression and maintain the integrity of the genome and epigenome. In plants, short interfering RNAs (siRNAs) of 24 nt in length are an abundant type of small RNA associated with transposable elements (TEs), other repetitive sequences, and viral defense. One means by which TE-associated siRNAs affect genome integrity is by altering chromatin structure through a process called RNA-directed DNA methylation (RdDM). In this paper, we describe a comparative survey of siRNAs from wheat seedling leaves, seedling roots, young spikelets, and grains at 8 and 15 days after pollination (DAP). We find that the general patterns of siRNA distributions are similar across different TEs and within TEs of the same family regardless of tissue, but the relative abundance of 24-nt siRNAs is highest in developing grains. We also find that TEs that are transcriptionally active in endosperm are associated with the highest siRNA abundance not only in grains, but also in other tissues as well. These results suggest that RdDM is an important feature of developing wheat grain and are consistent with the hypothesis that TE expression in endosperm results in increased TE siRNAs, and that RdDM is a conserved feature of plant seed development.

Using MuDR/Mu transposons in directed tagging strategies

An introduction to MuDR/Mu transposons as mutagens is provided along with protocols for using these elements to tag maize genes. Selection for retention of Mutator activity is described as well as details for establishing and screening tagging populations efficiently.

Distinguishing variable phenotypes from variegation caused by transposon activities

Variable phenotypes are common in nature and in laboratory materials. Guidelines and illustrations are presented to help distinguish developmental, environmental, disease, and somatic recombination-generated variation from the phenotypes caused by transposable elements.

Mobilization of Stowaway-like MITEs in newly formed allohexaploid wheat species

Transposable elements (TEs) dominate the genetic capacity of most eukaryotes, especially plants, where they can account for up to 90 % of the genome, such as in wheat. The relationship between TEs and their hosts and the role of TEs in organismal biology are poorly understood. In this study, we have applied next generation sequencing, together with a transposon display technique in order to test whether a Stowaway-like MITE, termed Minos, transposes following allopolyploidization events in wheat. We have generated a 454-pyrosequencing database of Minos-specific amplicons (transposon display products) from a newly formed wheat allohexaploid and its parental lines and retrieved hundreds of novel MITE insertions in the allohexaploid. Clear mobilization of Minos was also seen by site-specific PCR analysis and sequence validation. In addition, using real-time qPCR analysis we observed an insignificant change in the relative quantity of Minos from the expected value of merging the two parental genomes, indicating that, despite its activation, no significant burst in Minos copy number can be seen in the newly formed allohexaploid. Interestingly, we found that CCGG sites surrounding Minos underwent massive hypermethylation following the allohexaploidization process. Our data suggest that MITEs have maintained their capacity for activity throughout the evolution of wheat and might be epigenetically deregulated in the first generations following allopolyploidization.

Wheat hybridization and polyploidization results in deregulation of small RNAs

Speciation via interspecific or intergeneric hybridization and polyploidization triggers genomic responses involving genetic and epigenetic alterations. Such modifications may be induced by small RNAs, which affect key cellular processes, including gene expression, chromatin structure, cytosine methylation and transposable element (TE) activity. To date, the role of small RNAs in the context of wide hybridization and polyploidization has received little attention. In this work, we performed high-throughput sequencing of small RNAs of parental, intergeneric hybrid, and allopolyploid plants that mimic the genomic changes occurring during bread wheat speciation. We found that the percentage of small RNAs corresponding to miRNAs increased with ploidy level, while the percentage of siRNAs corresponding to TEs decreased. The abundance of most miRNA species was similar to midparent values in the hybrid, with some deviations, as seen in overrepresentation of miR168, in the allopolyploid. In contrast, the number of siRNAs corresponding to TEs strongly decreased upon allopolyploidization, but not upon hybridization. The reduction in corresponding siRNAs, together with decreased CpG methylation, as shown here for the Veju element, represent hallmarks of TE activation. TE-siRNA downregulation in the allopolyploid may contribute to genome destabilization at the initial stages of speciation. This phenomenon is reminiscent of hybrid dysgenesis in Drosophila.

Transposable elements as catalysts for chromosome rearrangements

Barbara McClintock first showed that transposable elements in maize can induce major chromosomal rearrangements, including duplications, deletions, inversions, and translocations. More recently, researchers have made significant progress in elucidating the mechanisms by which transposons can induce genome rearrangements. For the Ac/Ds transposable element system, rearrangements are generated when the termini of different elements are used as substrates for transposition. The resulting alternative transposition reaction directly generates a variety of rearrangements. The size and type of rearrangements produced depend on the location and orientation of transposon insertion. A single locus containing a pair of alternative transposition-competent elements can produce a virtually unlimited number of genome rearrangements. With a basic understanding of the mechanisms involved, researchers are beginning to utilize both naturally occurring and in vitro-generated configurations of transposable elements in order to manipulate chromosome structure.

Temperature controls nuclear import of Tam3 transposase in Antirrhinum

It has been proposed that environmental stimuli can activate transposable elements (TEs), whereas few substantial mechanisms have been shown so far. The class-II element Tam3 from Antirrhinum majus exhibits a unique property of low-temperature-dependent transposition (LTDT). LTDT has proved invaluable in developing the gene isolation technologies that have underpinned much of modern plant developmental biology. Here, we reveal that LTDT involves differential subcellular localization of the Tam3 transposase (TPase) in cells grown at low (15°C) and high (25°C) temperatures. The mechanism is associated with the nuclear import of Tam3 TPase in Antirrhinum cells. At high temperature, the nuclear import of Tam3 TPase is severely restricted in Antirrhinum cells, whereas at low temperature, the nuclear localization of Tam3 TPase is observed in about 20% of the cells. However, in tobacco BY-2 and Allium cepa (onion) cells, Tam3 TPase is transported into most nuclei. In addition to three nuclear localization signals (NLSs), the Tam3 TPase is equipped with a nuclear localization inhibitory domain (NLID), which functions to abolish nuclear import of the TPase at high temperature in Antirrhinum. NLID in Tam3 TPase is considered to interact with Antirrhinum-specific factor(s). The host-specific regulation of the nuclear localization of transposase represents a new repertoire controlling class-II TEs.

Multiple regulatory mechanisms influence the activity of the transposon, Tam3, of Antirrhinum

In Antirrhinum, several unique regulations of the transposon, Tam3, have been described. Tam3 activity in Antirrhinum is strictly controlled by the growing temperature of plants (low-temperature-dependent transposition: LTDT), by chromosomal position of Tam3 copy and by two specific repressor genes Stabiliser (St) and New Stabiliser (NSt). Here, the effects of the St and NSt loci on Tam3 transposition are compared. In cotyledons and hypocotyls, Tam3 is active even at high growing temperatures, indicating that LTDT does not operate when these organs are developing. This developmental regulation of Tam3 activity is differentially influenced by the St and NSt loci: St permits Tam3 transposition in cotyledons and hypocotyls, whereas NSt suppresses it in these organs. The effects of these host genes on Tam3 activity at the molecular level were examined. It was found that neither of these genes inhibits the transcription of the Tam3 transposase gene nor its translation, and that the Tam3 transposase has the potential to catalyze transposition in the St and NSt lines. The differences between the effects of St and NSt imply that they regulate Tam3 activity independently. Our molecular data indicate that their influence on Tam3 transposition seems to be nonepigenetic; possible mechanisms for their activity are discussed.

A carnation anthocyanin mutant is complemented by the glutathione S-transferases encoded by maize Bz2 and petunia An9

Particle bombardment was used to elucidate the function of Flavonoid3, a late-acting anthocyanin gene of the ornamental plant, carnation ( Dianthus caryophyllus L.). The fl3 mutation conditions dilute anthocyanin coloration that closely resembles phenotypes produced by the anthocyanin mutants bz2 of maize and an9 of petunia. Bz2 and An9 encode glutathione S-transferases (GSTs) involved in vacuolar sequestration of anthocyanins. Constructs containing either of these or another late-function maize gene, Bronze1 (UDPglucose:flavonol 3- O-glucosyltransferase), were introduced via microprojectile bombardment into fl3 petals. Complementation resulted only from Bz2 and An9, indicating that Fl3 encodes a GST involved in the transport of anthocyanins to the vacuole. The observed result in carnation, an angiosperm phylogenetically distant from maize and petunia, indicates that GST activity might be a universal step in the anthocyanin pathway. Microprojectile bombardment was used to identify late-pathway anthocyanin mutations, which may be responsible for the pale anthocyanin coloration of important cultivars in many species but which can be difficult to characterize by other means.

Mutator transposons

Mutator (Mu) element insertion has become the main way of mutating and cloning maize genes, but we are only beginning to understand how this transposon system is regulated. Mu elements are under tight developmental control and are subject to a form of epigenetic regulation that shares some features with the regulation of paramutable maize genes. Mu-like elements (MULEs) are widespread among angiosperms, and multiple diverged functional variants appear to have coexisted in genomes for long periods. In addition to its utility, the means by which this widespread and highly mutagenic system is held in check should help us to address fundamental issues concerning the stability of genomes.

A PCR-based assay to detect En/Spm-like transposon sequences in plants

Degenerate primers deduced from the TPase region of plant En/Spm-like transposons allowed the amplification of similar sequences from various plant species including sugar beet, wheat and pea. These primers are efficient tools for the detection of this family of transposons in many plant genomes irrespective of sequence knowledge or phenotypic pecularities. An efficient PCR assay was therefore developed for these class II transposons, similar to assays already available for Ty1-copia-, Ty3-gypsy- or LINEs. This approach allowed us not only to show the widespread almost-ubiquitous presence of En/Spm-elements in plant genomes, but also to characterize their genomic organization and chromosomal distribution in the genome of chickpea (Cicer arietinum L.) and its abundance in related Cicer species. This approach can be used for the detection and characterization of endogenous DNA transposable elements in plant species, their complete isolation and evaluation of their use for genome analysis.

ENDOSPERM DEVELOPMENT: Cellularization and Cell Fate Specification

The endosperm develops from the central cell of the megagametophyte after introduction of the second male gamete into the diploid central cell. Of the three forms of endosperm in angiosperms, the nuclear type is prevalent in economically important species, including the cereals. Landmarks in nuclear endosperm development are the coenocytic, cellularization, differentiation, and maturation stages. The differentiated endosperm contains four major cell types: starchy endosperm, aleurone, transfer cells, and the cells of the embryo surrounding region. Recent research has demonstrated that the first two phases of endosperm occur via mechanisms that are conserved among all groups of angiosperms, involving directed nuclear migration during the coenocytic stage and anticlinal cell wall deposition by cytoplasmic phragmoplasts formed in interzones between radial microtubular systems emanating from nuclear membranes. Complete cellularization of the endosperm coenocyte is achieved through centripetal growth of cell files, extending to the center of the endosperm cavity. Key points in cell cycle control and control of the MT (microtubular) cytoskeletal apparatus central to endosperm development are discussed. Specification of cell fates in the cereal endosperm appears to occur via positional signaling; cells in peripheral positions, except over the main vascular tissues, assume aleurone cell fate. Cells over the main vascular tissue become transfer cells and all interior cells become starchy endosperm cells. Studies in maize have implicated Crinkly4, a protein receptor kinase-like molecule, in aleurone cell fate specification.

The maize LAG1-O mutant suggests that reproductive cell lineages show unique gene expression patterns early in vegetative development

Patterns of transposable element activity often provide useful information about how and when organisms regulate gene expression. The maize lowered Ac/Ds germinal reversion 1 (LAG1)-O mutation causes unusually low rates of germinal reversion by Ac/Ds-induced alleles even though these same alleles revert frequently and early in somatic development. LAG1-O suppresses Ds transposition at multiple, unlinked loci, and does not affect Spm elements, indicating that the mutation acts in trans and may be specific to Ac/Ds elements. Our data suggest that LAG1-O suppression gradually reduces Ac/Ds activity in the meristem and newly formed leaves until, by the floral transition, transposition is undetectable even with PCR-based assays. This suppression persists during tassel development and does not appear to be released until some point after meiosis. Competitive RT-PCR results show no difference in Ac transposase mRNA levels between LAG1-O and lag1(+) tassels, suggesting that suppression is post-transcriptional. The pattern of LAG1-O expression is consistent with a model in which at least some gene expression specific to those meristem cells that will ultimately give rise to floral tissue and therefore gametes begins very early in plant development, and then persists throughout development.

Positional cues specify and maintain aleurone cell fate in maize endosperm development

A genetic analysis of maize aleurone development was conducted. Cell lineage was examined by simultaneously marking cells with C1 for anthocyanin pigmentation in the aleurone and wx1 for amylose synthesis in the starchy endosperm. The aleurone and starchy endosperm share a common lineage throughout development indicating that positional cues specify aleurone fate. Mutants in dek1 block aleurone formation at an early stage and cause peripheral endosperm cells to develop as starchy endosperm. Revertant sectors of a transposon-induced dek1 allele showed that peripheral endosperm cells remain competent to differentiate as aleurone cells until late in development. Ds-induced chromosome breakage was used to generate Dek1 loss-of-function sectors. Events occurring until late development caused aleurone cells to switch fate to starchy endosperm indicating that cell fate is not fixed. Thus, positional cues are required to specify and maintain aleurone fate and Dek1 function is required to respond to these cues. An analysis of additional mutants that disrupt aleurone differentiation suggests a hierarchy of gene functions to specify aleurone cell fate and then control aleurone differentiation. These mutants disrupt aleurone differentiation in reproducible patterns suggesting a relationship to endosperm pattern formation.

Characterization of the germinal and somatic activity of the Arabidopsis transposable element Tag1

Tag1 is an autonomous transposon of Arabidopsis thaliana. The excision behavior of Tag1 during reproductive and vegetative development was examined using CaMV 35STag1-GUS constructs. Germinal reversion frequencies varied from 0 to 27% and correlated with Tag1 copy number. Southern blot and somatic sector analyses indicated that each revertant was derived from an independent excision event, and approximately 75% of the revertants had new Tag1 insertions. Revertants were obtained with similar frequencies from the male and female parents. In flowers, small somatic sectors were observed in siliques, carpels, petals and sepals while stemlike organs (filaments and pedicels) had larger sectors. No sectors encompassing entire flowers or inflorescences were observed, however, indicating that excision occurs late in flower development and rarely in inflorescence meristems. Late excision was also observed during vegetative development with 99.8% of leaves showing small sectors encompassing no more than 20 cells. Roots and cotyledons, however, showed larger sectors that included entire lateral roots and cotyledons. These results indicate that Tag1 can excise in the embryo and all the organs of the plant with the timing of excision being restricted to late stages of vegetative and reproductive development in the shoot.

Binding of Nicotiana nuclear proteins to the subterminal regions of the Ac transposable element

Specific binding of Nicotiana nuclear protein(s) to subterminal regions of the Ac transposable element was detected using gel mobility shift assays. A sequence motif (GGTAAA) repeated in both terminal regions of Ac, was identified as the protein binding site. Mutation of two nucleotides in this motif was sufficient to abolish binding. Based on a series of competition assays, it is deduced that there is cooperative binding between two repeats, each similar to the GGTAAA motif. The binding protein is probably similar to a previously characterized maize protein which binds to a GGTAAA-containing motif located in the ends of Mutator. Moreover, we show that DNA from Ds1 competes for protein binding to Ac termini, and we show, by sequence analysis, that GGTAAA binding sites are present in the terminal region of Tgm1, Tpn1, En/Spm, Tam3, and Ds1-like elements. This suggests that the binding protein(s) might be involved in the transposition process.

Binding sites for maize nuclear proteins in the subterminal regions of the transposable element Activator

Genetic data suggest that transposition of the maize element Activator (Ac) is modulated by host factors. Using gel retardation and DNase I protection assays we identified maize proteins which bind to seven subterminal sites in both ends of Ac. Four DNase I-protected sites contain a GGTAAA sequence, the other three include either GATAAA or GTTAAA. The specificity of the maize protein binding to Ac was verified by using a synthetic fragment containing four GGTAAA motifs as probe and competitor in gel retardation assays. All seven binding sites are located within regions required in cis for transposition. A maize protein binding site with the same sequence has previously been identified in the terminal inverted repeats of the maize Mutator element. Thus, the protein, that recognizes this sequence is a good candidate for a regulatory host factor for Ac transposition.

Identification of functional domains and evolution of Tc1-like transposable elements

Tc1-like transposable elements from teleost fish have been phylogenetically examined to determine the mechanisms involved in their evolution and conserved domains of function. We identified two new functional domains in these elements. The first is a bipartite nuclear localization signal, indicating that transposons can take advantage of the transport machinery of host cells for nuclear uptake of their transposases. The second is a novel combination of a paired domain-related protein motif juxtaposed to a leucine zipper-like domain located in the putative DNA-binding regions of the transposases. This domain coexists with a special inverted repeat structure in certain transposons in such phylogenetically distant hosts as fish and insects. Our data indicate that reassortment of functional domains and horizontal transmission between species are involved in the formation and spread of new types of transposable elements.

Plant transposable elements and the genome

Transposable elements are ubiquitous in the plant kingdom and share many common features, both structural and mechanistic, with mobile elements from other eukaryotes. Transposition of these elements can influence plant genes and genomes in many ways. It is also becoming clear that transposable element derived sequences can be a major component of plant genomes. These sequences are probably, therefore, very significant factors in plant evolution.

Selection for enhanced germinal excision of Ac in transgenic Arabidopsis thaliana

Gene tagging in Arabidopsis thaliana using the autonomous Ac (Activator) transposable element has so far been hampered by low frequencies of germinal transposition events. Here we describe a procedure by which the frequency of independent germinal reinsertions has been much improved by a process of long-term selection on kanamycin for the continued growth of tissues in which somatic excisions have occurred. Growth on artificial media increased the somatic excision frequency, and the long-term selection procedure channelled somatic transposition events into the germline. This resulted in an overall germinal excision frequency in the progeny of longterm selected plants of 15%, as confirmed by Southern blotting, with 63% of the plants bearing excision events having detectable reinsertions of the Ac element. This compares with a germinal excision frequency of approximately 1% when no long-term selection is employed. However, offspring from individual plants tended to have identical germinal Ac reinsertion patterns, thus the critical parameter for evaluating the system for tagging purposes is the frequency of individual plants yielding offspring with reinsertions, which was 64%. This high frequency, when coupled to the enhanced germinal transposition rate overall, easily allows the generation of a large population of plants with independent reinsertions.

Related individuals with different androgen receptor gene deletions

We have identified different members of one family affected by androgen insensitivity syndrome who have deletions of different exons of the X-linked androgen receptor (AR) gene. Two affected (XY) siblings have a deletion of exon E of the AR gene and their affected (XY) aunt has a normal exon E, but a deletion of exons F and G of the same gene. The mother and maternal grandmother of the children both carry the exon E deletion, but not the exon F, G deletion. Both deletions are 5 kb in length and have one breakpoint within a 200-bp region in intron 5; however, they extend in opposite directions. The probability that these two different deletions have arisen at random is extremely low, but the cause of this intriguing phenomenon remains to be found.

Reactivation of Mutator transposable elements of maize by ultraviolet light

After epigenetic loss of Mutator activity, the family of Mu elements in Zea mays becomes immobile and highly methylated; in addition, Mu9, the presumptive autonomous regulatory element, is transcriptionally silent and its copy number decreases in successive crosses to non-Mutator lines. Spontaneous reactivation, scored as restoration of somatic instability of potentially mutable alleles of Bronze-2, of such cryptic Mutator lines is rare, occurring with a frequency of about 10(-4). Irradiation of pollen with 254 nm ultraviolet light increases reactivation rate in the progeny kernels by up to 40-fold. Accompanying reactivation, the copy number of Mu9 elements increased, two-fold in one line and 20 to 40-fold in a second line. Reactivation may involve direct DNA damage or immediate physiological stress in the treated pollen.

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

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 bp deletion, frameshift mutation in Bronze-2. The three other mutants described occurred as a result of abortive transposition, in which 75-77 bp 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.

Detection and abundance of mRNA and protein encoded by transposable element activator (Ac) in maize

The 3.5 kb long mRNA of the maize transposable element Ac contains an open reading frame (ORFa) which encodes a polypeptide of 807 amino acids, the putative transposase of Ac. The Ac mRNA is a rare transcript: we now estimate the fraction of Ac mRNA in wx-m7::Ac seedlings to be 2-13 x 10(-5) of the polyA RNA. Assuming that maize cells contain similar amounts of polyA RNA as another monocot (0.16 pg/cell), this is equivalent to 1.5-10 transcripts in each cell. A protein with an apparent molecular weight of 112 kDa is detected, by five antisera directed against different segments of ORFa, exclusively in nuclear extracts from Ac-containing maize. This protein is most likely the full-length Ac ORFa protein. We estimate its concentration to be in the range of 3 x 10(-7) of the nuclear proteins, or about 1000 molecules per triploid endosperm cell containing one Ac element.