Identification of a maize neocentromere in an oat-maize addition line.

We report a neocentromere event on maize chromosome 3 that occurred due to chromosome breakage. The neocentromere lies on a fragment of the short arm that lacks the primary centromere DNA elements, CentC and CRM. It is transmitted in the genomic background of oat via a new centromere (and kinetochore), as shown by immunolocalization of the oat CENH3 protein. Despite normal transmission of the maize fragment in most progeny, neocentromeres appear to vary in size within the same tissue, as shown by fluorescent measurements. A secondary truncation in one line lowered mitotic transmission to 3% and precipitously reduced the size of the chromosome. The results support the view that neocentromere formation is generally associated with major genomic disturbances such as wide species crosses or deletion of an existing centromere. The data further suggest that new centromeres may undergo a period of instability that is corrected over a period of several generations.

Maize individualized chromosome and derived radiation hybrid lines and their use in functional genomics.

The duplicated and rearranged nature of plant genomes frequently complicates identification, chromosomal assignment and eventual manipulation of DNA segments. Separating an individual chromosome from its native complement by adding it to an alien genetic background together with the generation of radiation hybrids from such an addition line can enable or simplify structural and functional analyses of complex duplicated genomes. We have established fertile disomic addition lines for each of the individual maize chromosomes, except chromosome 10, with oat as the host species; DNA is available for chromosome 10 in a haploid oat background. We report on instability and transmission in disomic additions of maize chromosomes 1, 5, and 8; the chromosome 2, 3, 4, 6, 7, and 9 additions appear stable. The photoperiodic response of the two recovered maize chromosome 1 addition lines contrasts to the long-day flowering response of the oat parents and the other addition lines. Only when grown under short days did maize chromosome 1 addition lines set seed, and only one line transmitted the maize chromosome 1 to offspring. Low resolution radiation hybrid maps are presented for maize chromosomes 2 and 9 to illustrate the use of radiation hybrids for rapid physical mapping of large numbers of DNA sequences, such as ESTs. The potential of addition and radiation hybrid lines for mapping duplicated sequences or gene families to chromosome segments is presented and also the use of the lines to test interactions between genes located on different maize chromosomes as observed for ectopic expression of cell fate alterations.

Mapping maize sequences to chromosomes using oat-maize chromosome addition materials.

Oat- (Avena sativa) maize (Zea mays) chromosome additions are produced by crossing maize and oat. During early embryo development maize chromosomes are preferentially eliminated, and oat plants are often recovered that retain a single maize chromosome. Each of the 10 maize chromosomes recently has been isolated as a separate oat-maize addition. We describe here the mapping of 400 maize sequences to chromosomes using polymerase chain reaction and DNA from the oat-maize addition material. Fifty of the sequences were from cloned markers that had been previously mapped by linkage analysis, and our results were consistent with those obtained using Southern-blot analysis. Previously unmapped expressed sequence tags and sequence tagged sites (350) were mapped to chromosomes. Maize gene sequences and expression data are rapidly being accumulated. Coupling this information with positional information from high throughput mapping programs provides plant biologists powerful tools for identifying candidate genes of interest.

A complete set of maize individual chromosome additions to the oat genome.

All 10 chromosomes of maize (Zea mays, 2n = 2x = 20) were recovered as single additions to the haploid complement of oat (Avena sativa, 2n = 6x = 42) among F(1) plants generated from crosses involving three different lines of maize to eight different lines of oat. In vitro rescue culture of more than 4,300 immature F(1) embryos resulted in a germination frequency of 11% with recovery of 379 F(1) plantlets (8.7%) of moderately vigorous growth. Some F(1) plants were sectored with distinct chromosome constitutions among tillers of the same plant and also between root and shoot cells. Meiotic restitution facilitated development of un-reduced gametes in the F(1). Self-pollination of these partially fertile F(1) plants resulted in disomic additions (2n = 6x + 2 = 44) for maize chromosomes 1, 2, 3, 4, 6, 7, and 9. Maize chromosome 8 was recovered as a monosomic addition (2n = 6x + 1 = 43). Monosomic additions for maize chromosomes 5 and 10 to a haploid complement of oat (n = 3x + 1 = 22) were recovered several times among the F(1) plants. Although partially fertile, these chromosome 5 and 10 addition plants have not yet transmitted the added maize chromosome to F(2) offspring. We discuss the development and general utility of this set of oat-maize addition lines as a novel tool for maize genomics and genetics.

Antisense waxy genes with highly active promoters effectively suppress waxy gene expression in transgenic rice.

To regulate Waxy (Wx) gene expression by introducing antisense genes, we connected the 2.3 kb Wx cDNA having 450 bp of the Wx first intron in reverse orientation to rice Wx and maize alcohol dehydrogenase1 (Adh1) promoters and used these constructs to transform rice plants. Of 10 independent transgenic lines analysed, four lines showed various degrees of reduction in amylose and WAXY (WX) protein levels in the endosperm. In two transgenic lines, complete absence of amylose was observed which made the seeds opaque white like glutinous rice (amylose-deficient waxy (wx) mutant). In one of the transgenic lines, A1 line, the presence of the antisense Wx gene cosegregated with reduction of amylose content in the endosperm. In the same line, a reduction in the level of endogenous Wx mRNA was observed in immature endosperm. Interestingly, this reduction was observed only with mature spliced transcripts but not with unspliced transcripts. Reduced amylose synthesis was also observed in pollen grains of four transgenic lines. These results suggest that integrated antisense Wx gene caused a reduction in amylose synthesis in endosperms and pollen grains of transgenic rice carrying the antisense Wx cDNA. These results indicate that manipulation of starch and other carbohydrates in rice grain is possible using antisense genes.

A core activity associated with the N terminus of the yeast RAD52 protein is revealed by RAD51 overexpression suppression of C-terminal rad52 truncation alleles.

C-terminal rad52 truncation and internal deletion mutants were characterized for their ability to repair MMS-induced double-strand breaks and to produce viable spores during meiosis. The rad52-Delta251 allele, encoding the N-terminal 251 amino acids of the predicted 504-amino-acid polypeptide, supports partial activity for both functions. Furthermore, RAD51 overexpression completely suppresses the MMS sensitivity of a rad52-Delta251 mutant. The absence of the C terminus in the truncated protein makes it likely that suppression occurs by bypassing the C-terminal functions of Rad52p. RAD51 overexpression does not suppress the low level of spore viability that the rad52-Delta251 allele causes and only partially suppresses the defect in rad52 alleles encoding the N-terminal 292 or 327 amino acids. The results of this study also show that intragenic complementation between rad52 alleles is governed by a complex relationship that depends heavily on the two alleles involved and their relative dosage. In heteroallelic rad52 diploids, the rad52-Delta251 allele does not complement rad52 missense mutations altering residues 61 or 64 in the N terminus. However, complementation is achieved with each of these missense alleles when the rad52-Delta251 allele is overexpressed. Complementation also occurs between rad52-Delta327 and an internal deletion allele missing residues 210 through 327. We suggest that the first 251 amino acids of Rad52p constitute a core domain that provides critical RAD52 activities.

A naturally occurring functional allele of the rice waxy locus has a GT to TT mutation at the 5' splice site of the first intron.

In cultivated rice two wild-type alleles, Wxa and Wxb, predominate at the waxy locus, which encodes granule-bound starch synthase. The activity of Wxa is 10-fold higher than that of Wxb at the level of both protein and mRNA. Wxb has a +1G to T mutation at the 5' splice site of the first intron. Sequence analysis of Wxb transcripts revealed that splicing occurs at the mutant AG/UU site and at two cryptic sites: the first is A/GUU, one base upstream of the original site and the second is AG/GU found approximately 100 bases upstream of the mutant splice site. We introduced single base mutations to the 5' splice sites of both Wxa and Wxb, fused with the gus reporter gene and introduced them into rice protoplasts. Analysis of GUS activities and transcripts indicated that a G to T mutation in Wxa reduced GUS activity and the level of spliced RNA. Conversely, a T to G mutation of Wxb restored GUS activity and the level of spliced RNA to that of wild-type Wxa. These results demonstrated that the low level expression of Wxb results from a single base mutation at the 5' splice site of the first intron. It is of interest that the Wxb allele of rice carrying the G to T mutation of intron 1 has been conserved in the history of rice cultivation because there is a low amylose content of the seed caused by this mutation.

Analysis of recombination sites within the maize waxy locus.

Genetic fine structure analysis of the maize wx locus has determined that the ratio of genetic to physical distance within wx was one to two orders of magnitude higher than the average for the maize genome. Similar results have been found at other maize loci. In this study, we examined several mechanisms that could account for this pattern. First, crossovers in two other maize genes resolve preferentially at specific sites. By mapping exchanges between wx-B1 and wx-I relative to a polymorphic SstI site, we found no evidence for such a hotspot at wx. Second, deletion of promoter sequences from wx alleles had little effect on recombination frequencies, in contrast to results in yeast where promoter sequences are important for initiating recombination in some genes. Third, high levels of insertion polymorphism may suppress intergenic recombination. However, the presence of a 2-kb Ds element 470 bp upstream of the wx transcription start site did not further suppress recombination between Ds insertions in nearby wx sequences. Thus, none of these mechanisms is sufficient to explain the difference between intergenic and intragenic recombination rates at wx.

Alternative 3' splice acceptor sites modulate enzymic activity in derivative alleles of the maize bronze1-mutable 13 allele.

The defective Suppressor-mutator (dSpm)-induced allele bronze1-mutable 13 (bz1-m13) and many of its derivative alleles are leaky mutants with measurable levels of flavonol O3-glucosyltransferase activity. This activity results from splicing at acceptor site-1, one of two cryptic 3' splice sites within the dSpm insertion in bz1-m13. In this study, splicing in bz1-m13 change-in-state (CS) alleles CS-3 and CS-64 was shown to be altered from bz1-m13; previous work found altered splicing in CS-9. CS-64 is a null allele and lacks the acceptor site-1-spliced transcript because this site is deleted. CS-3 and CS-9 had increased levels of the acceptor site-1 transcript relative to bz1-m13 and increased enzymic activities. A deletion in CS-9 altered splicing by eliminating acceptor site-2. Both acceptor sites were intact in CS-3, but a deletion removed most of a 275-bp GC-rich sequence in dSpm. This suggests that GC-rich sequences affect splicing and is consistent with models postulating a role for AU content in the splicing of plant introns. Splicing does not necessarily occur, however, at the junction of AU-rich intron sequences and GC-rich exon sequences.

A deletion common to two independently derived waxy mutations of maize.

A mutation at the maize waxy locus, wx1240, was isolated following treatment of pollen with EMS and self-pollinating ears on M1 plants. This allele was cloned and found to contain a 30-bp deletion within the gene and additional lesions upstream of the transcription start site. Using fine structure genetic mapping, we determined that the deletion is responsible for the mutant phenotype. In addition, the position of wx1240 on the genetic map coincided with the previously determined positions of two other waxy mutations, the spontaneous wx-C, which is reference allele, and the putative ethyl methanesulfonate (EMS)-induced wx-BL2. Molecular analysis of these alleles revealed that both contain the same deletion as wx1240, and that the wx-BL2 allele is similar to wx-C and possibly resulted from wx-C contamination. The deleted sequence responsible for these mutations is flanked by a short, 4-bp, direct repeat. Similar structures are favored sites for spontaneous deletions in other organisms. The data suggests that EMS is capable of inducing structural alterations in plant genes in addition to the point mutations normally ascribed to EMS-induced mutations.

Comparison of non-mutant and mutant waxy genes in rice and maize.

The waxy gene, which is responsible for the synthesis of amylose in endosperm and pollen, is genetically well characterized in many grasses including maize and rice. Homology between the previously cloned maize waxy gene and the rice gene has facilitated our cloning of a 15-kb HindIII fragment that contains the entire rice gene. A comparison of the restriction maps of the maize and rice genes indicates that many restriction sites within translated exons are conserved. In addition, the rice gene encodes a 2.4-kb transcript that programs the in vitro synthesis of a 64-kD pre-protein which is efficiently precipitated with maize waxy antisera. We demonstrate that these gene products are altered in rice strains containing mutant waxy genes. Southern blot analysis of 16 rice strains, ten containing waxy mutations, reveals that the waxy gene and flanking restriction fragments are virtually identical. These results contrast dramatically with the high level of insertions and deletions associated with restriction fragment length polymorphism and spontaneous mutations among the waxy alleles of maize.