The frequency of reversion of the opaque2 locus mutable alleles controlled by the Bg-rbg system of mobile elements in maize

Maize lines differing in the frequency of reversion of the opaque2 (o2) mutable alleles controlled by the system of Bg-rbg transportable elements were studied. In the presence of the Bg regulatory element, these alleles can revert to normal. When reversion occurs prior to the first division of the primary endosperm nucleus, either phenotypically normal kernels or whole endosperm revertants (WER) develop. Low frequency of whole endosperm revertant formation may be produced by different genetic mechanisms. The frequency of WER formation was shown to nonlinearly depend on the dose of the Bg-hf regulatory element. A dose increase from two to three failed to cause an essential increase in the number of revertants. The regulatory elements Bg-lf and Bg-hf differed in ability to induce excision of the receptor element at the same dose. The frequency of reversion of the receptive alleles was shown to be regulated by epigenetic mechanisms so that high frequency of reversion of receptive alleles requires preliminary premeiotic association between the regulatory and receptor elements. The inheritance of the maize alleles o2-hf and o2-lf proved to be similar to that an3 mutable alleles in petunia.     

Reversion of the Maize Mutable Allele o2-hf in Plant Ontogeny

Reversions of the mutable allele o2-hfleading to formation of the phenotypically normal kernels or whole endosperm revertants (WER) are studied in the plant ontogeny. The pattern of WER kernel distribution on the ear maps and analysis of their progeny showed that the reversion of the mutable allele o2-hf occurs at the late premeiotic stages of the ear development. Most of whole endosperm revertants on the ears homozygous for both the mutable allele o2-hfand regulatory element Bg-hf are grouped into clusters. The WER kernels are mostly formed during the period from the gamete fusion to the first division of the primary endosperm nucleus and are not embryo revertants. This clustering of revertant kernels seems to be caused by the joint effect of two factors on the early stages of endosperm development. These factors are (1) diffusion of an additional amount of transposase into the nearby Kernels from the developing endosperm, where the level of this enzyme is sufficient to induce excision of the receptor element and (2) the high proportion of the developing kernels with supra- and subthreshold levels of the Bg-hf-encoded transposase.     

Reversion of the maize mutable allele o2-hf in plant ontogeny

Reversions of the mutable allele o2-hf leading to formation of the phenotypically normal kernels or whole endosperm revertants (WER) are studied in the plant ontogeny. The pattern of WER kernel distribution on the ear maps and analysis of their progeny showed that the reversion of the mutable allele o2-hf occurs at the late premeiotic stages of the ear development. Most of whole endosperm revertants on the ears homozygous for both the mutable allele o2-hf and regulatory element Bg-hf are grouped into clusters. The WER kernels are mostly formed during the period from the gamete fusion to the first division of the primary endosperm nucleus and are not embryo revertants. This clustering of revertant kernels seems to be caused by the joint effect of two factors on the early stages of endosperm development. These factors are (1) diffusion of an additional amount of transposase into the nearby Kernels from the developing endosperm, where the level of this enzyme is sufficient to induce excision of the receptor element and (2) the high proportion of the developing kernels with supra- and subthreshold levels of the Bg-hf-encoded transposase.     

Genetic instability at the opaque-2 locus of maize

Summary A case of genetic variegation discovered at the opaque-2 locus of maize that includes a two-element system with a receptor and regulatory element is described. The somatic mutability depends on the existence of two genetic factors: a responsive allele (with receptor element), o2m(r), and a regulatory element, Bg, that induces mutability of o2m(r). In the absence of Bg, o2m(r) is indistiguishable from the recessive alleles of the O2 locus; in the presence of the regulatory element, o2m(r) mutates giving rise to sectors of flint-like endosperm in an opaque back-ground. The regulatory element Bg may be located independently or at the controlled locus. The genetic properties of the new system, somatic mutability, transposition, existence of different patterns of mutability, are apparently similar to those previously described in maize for the classical systems of controlling elements. In addition, the recovery of the o2 mutability from crosses between spontaneous o2 alleles suggests that transposable genetic elements may be involved in the origin of natural mutability.     

Alfalfa transposable elements and variegation

Alfalfa with unstable anthocyanin pigmentation has been independently discovered on six occasions since 1958. Genetic studies showed that each of the six unstable stocks was due to an allele mutable at the basic anthocyanin locus C2 in alfalfa. The alleles are designated c2-m1 through c2-m6. Variegated phenotypes of m1, m2, and m3 are similar and express reversion from the recessive to the dominant state. This reversion produces streaks and sectors of pigment in flower petals and seeds that are otherwise white. Reversion occurs at various times in development and may result in periclinal chimeras. The c2-m4 allele is unique in that it arose during tissue culture, whereas the other mutables were discovered in plant populations. Interestingly, m4 is very stable in planta and only rarely produces a sectored flower, but is very unstable in vitro as measured by about 23% revertant plants regenerated from tissue cultures. Most m4 reversion occurs relatively early in development and results in completely pigmented in vitro revertants, and in large sectors on in planta revertants. Alleles m5 and m6 are phenotypically and genetically similar. Their flowers are basic purple with white streaks thus representing mutation from dominant purple to recessive white. White progeny of m5 and m6 are very stable both in planta and in vitro; reversion of white to purple was never observed. Thus, the loss of function of the dominant allele results in a stable recessive or a deficiency. The absolute stability of m5 white derivatives favors the deficiency model, because transposable element mutations might show reversion. Finally, several mutations are described that reoccur in the mutable populations. It is speculated that they are recent mutations due to transposition of transposable elements.     

Occurrence and behavior of the components of the 02-m(r)-Bg system of maize controlling elements

Summary o2-m(r) is an unstable allele of the O2 locus responding to the regulatory element Bg by somatic reversion. The spontaneous occurrence and the properties of the components of this system of controlling elements have been investigated. The system appears to have some degree of specificity for the O2 locus, because the majority of spontaneous O2 mutations are responsive to Bg. The component at the controlled locus undergoes frequent changes in state, while the Bg element appears more stable. Bg activity was revealed in 11 out of 108 open-pollinated varieties of maize. Most of the newly isolated Bg elements are linked with the O2 locus. The timing of induction of reversion events (which are restricted to mitotic division leading to egg or pollen maturation and to the developing endosperm) appears to correlate with the degree of linkage between Bg and the O2 locus. Germinal reversions of o2-m(r) to wild type give rise with a frequency around 5×10^-4 to unstable phenotypes. Some peculiar features of the o2-m(r)-Bg system of controlling elements are discussed.     

A modifier of the Bg element of the Bg-rbg transposable element system of maize

A modifier of the Bg autonomous element of the Bg-rbg system of transposable elements has been found in the genotype of the inbred maize line 346. In the presence of this modifier (designated Mbg), the frequency of reversion of mutable allele o2-lf in combination with the Bg-lf element increases by 7–24 times. An increase in the Mbg dosage by three times increases the o2-lf reversion frequency by a factor of about two. The joint presence of Mbg and Bg-lf in the same genotype before meiosis is necessary for the expression of the Mbg modifying effect. The possible nature and mechanism of action of the novel modifier are discussed.     

Molecular cloning of the o2-m5 allele of Zea mays using transposon marking

Summary The deposition of zein protein in maize endosperm is under the control of several regulatory loci. The isolation of DNA sequences corresponding to Opaque-2 (O2), one of such loci, is described in this paper. The mutable allele, o2-m5 was first induced moving the Ac transposable element present at the wx-m7 allele to the O2 locus. Genetic data suggest that a functional Ac element is responsible for the observed somatic mutability of o2-m5. The isolation of genomic clones containing flanking sequences corresponding to the O2 gene was possible by screening an o2-m5 genomic libary with a probe corresponding to internal Ac sequences usually absent in the defective element Ds. Out of 27 clones isolated with homology to the central part of Ac element, only clones 6IP and 21IP generated a 2.5 kb internal fragment size of an active Ac element when digested with PvuII restriction enzyme. A sequence representing a XhoI fragment of 0.9 kb lying, in the 6IP clone, adjacent to the Ac elements, was subcloned and utilized to prove that it corresponded to a part of the O2 gene. To obtain this information we made use of: (1) DNAs from several reversions originating from the unstable (o2mk-(r) allele, which, when digested with SstI, showed a correct 3.4 kb fragment typical of non-inserted alleles of the O2 locus; and (2) recessive alleles of the O2 locus which were devoid of a 2.0 kb mRNA, present on the contrary in the wild type and in other zein regulating mutants different from O2.This paper is dedicated to the memory of R. Marotta, who actively participated in the realization of this work     

Differential excision patterns of the <Emphasis Type="Italic">En</Emphasis>-transposable element at the <Emphasis Type="Italic">A2</Emphasis> locus in maize relate to the insertion site

Defined mutant alleles with resident transposons display characteristic patterns of germinal and somatic reversion, and heritable changes in the timing and frequency of reversions, which have been termed “change of state” by McClintock, constantly arise. Several mechanisms were proposed to account for these changes. They may be ascribed to the structure and composition of the elements themselves (composition hypothesis) or to their location (position hypothesis). In the current study, insertion positions were determined for three autonomous En-controlled mutable alleles of the A2 locus in maize that show different somatic reversion patterns. A relationship was observed between En insertion positions in the single coding region of the intronless A2 gene and anthocyanin variegation patterns in the aleurone. An insertion in the 5′ region of the coding sequence produced a very late somatic variegation pattern, whereas two early variegation patterns were caused by En insertions in the 3′ region of the coding sequence.     

A modifier of the Bg element of the Bg-rbg transposable element system of maize

A modifier of the Bg autonomous element of the Bg-rbg system of transposable elements has been found in the genotype of the inbred maize strain 346. In the presence of this modifier (termed Mbg), the frequency of reversion of mutable allele o2-lf in combination with the Bg-lf element increases by 7-24 times. An increase in the Mbg dosage by three times increases the o2-lf reversion frequency by a factor of about two. The presence of Mbg and Bg-lf in the same genotype before meiosis is necessary for the expression of the Mbg modifying effect. The possible nature and mechanism of action of the novel modifier are discussed.     

Induction and repair of gene conversion in UV-sensitive mutants of yeast

Summary Photoreactivation effect on UV-induced allelic recombination has been examined using various combinations of leu 1 alleles in UV-sensitive and wild type diploid yeast, Saccharomyces cerevisiae. The frequencies of UV-induced heteroallelic reversion in UV-sensitive strains, presumably lacking dark-repair, are strikingly enhanced compared to those in wild type at the same doses under dark condition. However, these enhanced frequencies of reversion are diminished by photoreactivation almost to the level of those in wild type. The induced frequencies of homoallelic reversion (mutation) of relevant alleles are apparently lower than those of heteroallelic reversion. Phenotypic analysis for linked gene leu 1 on UV-induced heteroallelic revertants has shown that most of the revertants are of the nonreciprocal type recombination (mitotic gene conversion). These results would indicate that most of the dark-repairable damage leading to mitotic gene conversion after UV-light is due to pyrimidine dimers.On leave of absence from Radiation Center of Osaka Prefecture, Shinke-cho Sakai, Osaka, Japan.     

Germinal reversion of an unstable mutation for anthocyanin pigmentation in soybean

Summary Plants of the w4-mutable line of soybean [Glycine max (L.) Merr.] are chimeral for anthocyanin pigmentation. Mutable plants produce both near-white and purple flowers, as well as flowers of mutable phenotype with purple sectors on near-white petals. It is established here that the mutable trait is conditioned by an unstable recessive allele of the w4 locus that conditions anthocyanin biosynthesis. The gene symbol w4-m is assigned to the mutable allele. Allele w4-m was derived from a stable, wild-type W4 progenitor allele and reverts at high frequency to a stable, wild-type W4 allele. Reversion occurs both early and late during the development of the germ line. Several experiments give estimates of germinal reversion frequency, indicating that approximately 6% of mutable alleles revert to wild-type from one generation to the next. Allele w4-m exhibits many features typical of an allele controlled by a transposable element.     

Novel, developmentally specific control of Ds transposition in maize

Plants form their gametes late in somatic development and, as a result, often pass somatic mutations on to their progeny. Classic examples of this process are the germinal revertants of unstable, Ac/Ds transposon-induced kernel mutations in maize: frequent and early reversion events during somatic development are generally correlated with a high frequency of revertant gametes. We have characterized a Ds allele of the maize waxy(wx) gene, wx-m5:CS7, for which the correlation between somatic and germinal reversion frequencies no longer holds. The ability of wx-m5:CS7 (CS7) to produce revertant gametes is suppressed ∼100-fold in comparison with a second Ds allele, wx-m5:CS8 (CS8), which has an identical insertion at Wx and the same frequent and early somatic reversion pattern in endosperm. The excision of Ds from wx is not reduced 100-fold in the somatic tissues of CS7 plants as compared with CS8 plants. Suppressed formation of CS7 revertant gametes is independent of the Ac transposase source and is heritably passed to the embryos of progeny kernels; however, frequent and early somatic reversion is observed again in endosperms of these progeny kernels. This suppression appears to be caused by a dominant mutation in a trans-acting product that can suppress the germinal reversion of other Ds-induced alleles as well; the mutation is tightly linked to Wx but is not in the CS7 Ds itself. Taken together, the data suggest a novel mode of developmental control of Ac/Ds elements by the host plant, suppressing element excision in the shoot meristem. Received: 16 December 1996 / Accepted: 4 March 1997     

Tagging and Cloning of a Petunia Flower Color Gene with the Maize Transposable Element Activator

We report here the use of the maize transposable element Activator (Ac) to isolate a dicot gene. Ac was introduced into petunia, where it transposed into Ph6, one of several genes that modify anthocyanin pigmentation in flowers by affecting the pH of the corolla. Like other Ac-mutable alleles, the new mutation is unstable and reverts to a functional form in somatic and germinal tissues. The mutant gene was cloned using Ac as a probe, demonstrating the feasibility of heterologous transposon tagging in higher plants. Confirmation that the cloned DNA fragment corresponded to the mutated gene was obtained from an analysis of revertants. In every case examined, reversion to the wild-type phenotype was correlated with restoration of a wild-type-sized DNA fragment. New transposed Acs were detected in many of the revertants. As in maize, the frequency of somatic and germinal excision of Ac from the mutable allele appears to be dependent on genetic background.     

Developmental regulation of excision timing of Mutator transposons of maize: Comparison of standard lines and an early excision bzl::Mu1 line

Three characteristics of standard Mutator lines reflect developmental regulation: new mutants usually involve single gametes, somatic excision is restricted to terminal cell divisions during tissue development, and germinal excision is rare. By selection for earlier (larger) somatic sectors in the aleurone, a Mutator line was identified that exhibits a dramatic elevation in somatic excision frequency during the first three nuclear divisions of the endosperm and more than a 10-fold increase in germinal reversion from the bzl::Mul reporter gene. The programming of early sectoring is dominant in crosses with Mutator lines containing diverse reporter alleles. Germinal reversion is biased 5- to 10-fold for events through the pollen compared to the ear. The timing of germinal excision in the tassel is late because somatic excision sectors in the anthers are small; however, 98% of the germinal revertants are concordant. These observations indicate that in the early sectoring line Mu excision usually occurs before the mitotic divisions that separate gametic nuclei and may be restricted to the early stages of microsporogenesis. © 1992 Wiley-Liss, Inc.     

The effect of Ac dosage on the production of multiple forms of Wx protein by the wxm-9 controlling element mutation in maize

Summary The wx ^m-9 autonomous controlling element mutation produces either a single or doublet type protein in 20 day endosperm, depending on the dosage of Ac. The single protein observed in one dose Ac endosperm is the product of wx ^m-9 to Wx revertants. The doublet observed in two and three dose Ac endosperm is the product of the Ac-containing, partially suppressed wx ^m-9 gene. Mutual exclusion of the activities of the wx ^m-9 gene and its included Ac element is postulated. A competition model is presented to account for the unexpected Ac dosage effect.     

Developmental and genetic aspects of Mutator excision in maize

The regulation of excision of Mu elements of the Mutator transposable element family of maize is not well understood. We have used somatic instability of Mu receptor elements from the Bronze 1 and Bronze 2 loci to monitor the frequency and the timing of excision of Mu elements in several tissues. We show that spot size in the aleurone of a bz2::mu1 stock varies between one to approximately 256 cells. This indicates that excision events begin eight divisions prior to full aleurone differentiation and end after the last division of the aleurone. We show that excision is equally biased for late events in all other tissues studied. A locus on chromosome 5 has been identified that affects spot size, possibly by altering the timing of Mu excision. Using somatic excision as an assay of Mutator activity, we found that activity can change in small sectors of the tassel; however, there are no overall activity changes in the tassel during the period of pollen shedding. We also report the recovery of germinal revertants for the bz1::mu1 and bz2::mu1 alleles. One of these revertant alleles was characterized by Southern blot analysis and found to be similar to the progenitor of the mutable allele.     

Psl: a novel Spm‐like transposable element from Petunia hybrida

The identification of a spontaneous mutable Hf1 allele in Petunia hybrida provided an opportunity to isolate and characterize a novel transposable element. This 9.9 kb element has features in common with members of the Spm family, such as homologous terminal inverted repeats and a 3 bp target site direct duplication within the Hf1 gene. The element is named Petunia Spm-like (Psl). The footprints left by excising elements have been isolated from several germinal revertants and sequence analysis shows similarities to those left by other Spm family members. Southern analysis shows that the transposon is present at low copy number in the genome of different inbred lines and species of Petunia. The germinal excision frequency of Psl was 21–33% in outcross populations. The element appears to be very mobile somatically in the inbred line V26, with 38% of plants from an inbred population showing new Psl-hybridizing bands by Southern analysis. The high somatic and germinal excision frequency demonstrated by Psl suggests that this element may have utility for gene tagging in petunia.