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.

DNA class organization on maize Adh1 yeast artificial chromosomes

The organization of higher plant genomes is poorly understood. These genomes are typified by their large size and extensive repetitive DNA component. To further our understanding of the composition and arrangement of genomic DNA sequences, we have performed a detailed analysis of a contiguous interval of 280 kb surrounding the Adh1 locus of maize. A series of overlapping lambda subclones was isolated, and individual fragments were characterized with respect to their genomic copy number. Cross-hybridization analyses were used to define a minimum of 37 repetitive DNA classes within the 280-kb interval. Hybridizations with highly repetitive DNAs cloned from other regions of the maize genome suggested that > 50% of all highly repetitive elements in maize are represented on this single yeast artificial chromosome. These repeated sequences were found in an organizational pattern not previously observed; individual repetitive elements are interspersed with one another in an apparently random fashion and are spatially separate from single copy number sequences. Extensive tandem arrays were not found. Sequences from one end of the 280-kb interval were used to isolate overlapping yeast artificial chromosome clones, representing the first step in a chromosome walk.

The generation of Mutator transposable element subfamilies in maize

The mobile DNAs of the Mutator system of maize (Zea mays) are exceptional both in structure and diversity. So far, six subfamilies of Mu elements have been discovered; all Mu elements share highly conserved terminal inverted repeats (TIRs), but each sub-family is defined by internal sequences that are apparently unrelated to the internal sequences of any other Mu subfamily. The Mu1/Mu2 subfamily of elements was created by the acquisition of a portion of a standard maize gene (termed MRS-A) within two Mu TIRs. Beside the unusually long (185-359 bp) and diverse TIRs found on all of these elements, other direct and inverted repeats are often found either within the central portion of a Mu element or within a TIR.Our computer analyses have shown that sequence duplications (mostly short direct repeats interrupted by a few base pairs) are common in non-autonomous members of the Mutator, Ac/Ds, and Spm(En) systems. These duplications are often tightly associated with the element-internal end of the TIRs. Comparisons of Mu element sequences have indicated that they share more terminal components than previously reported; all subfamilies have at least the most terminal 215 bp, at one end or the other, of the 359-bp Mu5 TIR. These data suggest that many Mu element subfamilies were generated from a parental element that had termini like those of Mu5. With the Mu5 TIRs as a standard, it was possible to determine that elements like Mu4 could have had their unusual TIRs created through a three-step process involving (1) addition of sequences to interrupt one TIR, (2) formation of a stem-loop structure by one strand of the element, and (3) a subsequent DNA repair/gene conversion event that duplicated the insertion(s) within the other TIR. A similar repair/conversion extending from a TIR stem into loop DNA could explain the additional inverted repeat sequences added to the internal ends of the Mu4 and Mu7 TIRs. This same basic mechanism was found to be capable of generating new Mu element subfamilies. After endonucleolytic attack of the loop within the stem-loop structure, repair/conversion of the gap could occur as an intermolecular event to generate novel internal sequences and, therefore, a new Mu element subfamily. Evidence supporting and expanding this model of new Mu element subfamily creation was identified in the sequence of MRS-A.

Isolation of matrices from maize leaf nuclei: identification of a matrix-binding site adjacent to the Adh1 gene

Nuclear matrices were isolated from maize leaves by the two conventional methods usually employed for the preparation of the corresponding structures of animal origin. It is demonstrated that functionally competent matrices, recognizing and specifically binding the MAR-containing DNA of the mouse kappa-immunoglobulin gene may be prepared by both 2 M NaCl and LIS extractions of maize nuclei. A DNA region with a high affinity for the nuclear matrix was identified at the 5' end of the maize Adh1-S gene, distal to the promoter region. The presence of sites of reported altered chromatin structure in this particular region is discussed. While the proximity and the cohabitation of MARs with different regulatory elements is a common feature of matrix association regions in animal systems, this is the first plant MAR identified in a region of known significance for gene regulation.

Structure and evolution of the genomes ofsorghum bicolor andZea mays

Cloned maize genes and random maize genomic fragments were used to construct a genetic map of sorghum and to compare the structure of the maize and sorghum genomes. Most (266/280) of the maize DNA fragments hybridized to sorghum DNA and 145 of them detected polymorphisms. The segregation of 111 markers was analyzed in 55 F2 progeny. A genetic map was generated with 96 loci arranged in 15 linkage groups spanning 709 map units. Comparative genetic mapping of sorghum and maize is complicated by the fact that many loci are duplicated, often making the identification of orthologous sequences ambiguous. Relative map positions of probes which detect only a single locus in both species indicated that multiple rearrangements have occurred since their divergence, but that many chromosomal segments have conserved synteny. Some sorghum linkage groups were found to be composed of sequences that detect loci on two different maize chromosomes. The two maize chromosomes to which these loci mapped were generally those which commonly share duplicated sequences. Evolutionary models and implications are discussed.

Complex duplications in maize lines

Rp1 is a disease resistance complex and is the terminal morphological marker on the short arm of maize chromosome 10. Several restriction fragment length polymorphisms (RFLPs), which map within 5 map units of Rp1, were examined to determine if they are also complex in structure. Two RFLP loci, which mapped distally to Rp1, BNL3.04 and PIO200075, existed in a single copy in all maize lines examined. These two loci cosegregated perfectly in 130 test cross progeny. Two RFLP loci that map proximally to Rp1 had unusual structures, which have not yet been reported for maize RFLPs; the loci were complex, with variable numbers of copies in different maize lines. One of the loci, NP1285, occasionally recombined in meiosis to yield changes in the number of copies of sequences homologous to the probe. The other proximal locus, detected by the probes NPI422, KSU3, and KSU4, was relatively stable in meiosis and no changes in the number of restriction fragments were observed. The similarity in map position between Rp1 and the complex RFLP loci indicate there may be genomic areas where variable numbers of repeated sequences are common. The structure of these complex loci may provide insight into the structure and evolution of Rp1.

Unequal exchange and meiotic instability of disease-resistance genes in the Rp1 region of maize

The Rp1 region of maize was originally characterized as a complex locus which conditions resistance to the fungus Puccinia sorghi, the causal organism in the common rust disease. Some alleles of Rp1 are meiotically unstable, but the mechanism of instability is not known. We have studied the role of recombination in meiotic instability in maize lines homozygous for either Rp1-J or Rp1-G. Test cross progenies derived from a line that was homozygous for Rp1-J, but heterozygous at flanking markers, were screened for susceptible individuals. Five susceptible individuals were derived from 9772 progeny. All five had nonparental combinations of flanking markers; three had one combination of recombinant flanking markers while the other two had the opposite pair. In an identical study with Rp1-G, 20 susceptible seedlings were detected out of 5874 test cross progeny. Nineteen of these were associated with flanking marker exchange, 11 and 8 of each recombinant marker combination. Our results indicate that unequal exchange is the primary mechanism of meiotic instability of Rp1-J and Rp1-G.

Homologous recombination between plasmid DNA molecules in maize protoplasts

The requirements for homologous recombination between plasmid DNA molecules have been studied using the PEG (polyethylene glycol)-mediated transformation system of maize (Zea mays L.) protoplasts coupled with the transient expression assay for beta-glucuronidase (GUS). Two plasmids were introduced into maize protoplasts; one plasmid (pB x 26) contained a genomic clone of the Adh1 maize gene; the other plasmid (piGUS) was a promoterless construction containing part of intron A of the Adh1 gene fused to the gusA coding sequence. Thus, the two vectors shared an effective homologous region consisting of a 459 bp (HindIII-PvuII) fragment of the Adh1 intron A sequence. An active gusA fusion gene would result upon homologous recombination between the plasmids within the intron A sequence, and indeed GUS activity was observed in extracts following co-transformation of maize protoplasts with the two plasmids. The presence of recombinant DNA molecules in protoplast DNA isolated 1 day after co-transformation was verified using polymerase chain reactions (PCR) and Southern blots. For efficient homologous recombination, both plasmids had to be linearized. The recombination reaction was induced by restriction of the plasmid molecules either inside the effective homologous region or at the borders of the intron sequence. However, the presence of even small, terminal, nonhomologous sequences at the 3' end of the pB x 26 fragment inhibited the recombination reaction. Also, both ends of the linearized piGUS DNA molecules were involved in the recombination reaction. The results revealed some features of homologous recombination reactions occurring in plant cells which cannot be accommodated by mechanisms postulated for similar reactions in animal system and in lower eukaryotes.

Recombination at the Rp1 locus of maize

The Rp1 locus of maize determines resistance to races of the maize rust fungus (Puccinia sorghi). Restriction fragment length polymorphism markers that closely flank Rp1 were mapped and used to study the genetic fine structure and role of recombination in the instability of this locus. Susceptible progeny, lacking the resistance of either parent, were obtained from test cross progeny of several Rp1 heterozygotes. These susceptible progeny usually had non-parental genotypes at flanking marker loci, thereby verifying their recombinational origin. Seven of eight Rp1 alleles (or genes) studied were clustered within about 0.2 map units of each other. Rp1G, however, mapped from 1-3 map units distal to other Rp1 alleles. Rp5 also mapped distally to most Rp1 alleles. Other aspects of recombination at Rp1 suggested that some alleles carry duplicated sequences, that mispairing can occur, and that unequal crossing-over may be a common phenomenon in this region; susceptible progeny from an Rp1A homozygote had recombinant flanking marker genotypes, and susceptible progeny from an Rp1D/Rp1F heterozygote showed both possible nonparental flanking marker genotypes.

Genetic mapping and characterization of sorghum and related crops by means of maize DNA probes

Cloned DNA fragments from 14 characterized maize genes and 91 random fragments used for genetic mapping in maize were tested for their ability to hybridize and detect restriction fragment length polymorphisms in sorghum and other related crop species. Most DNA fragments tested hybridized strongly to DNA from sorghum, foxtail millet, Johnsongrass, and sugarcane. Hybridization to pearl millet DNA was generally weaker, and only a few probes hybridized to barley DNA under the conditions used. Patterns of hybridization of low-copy sequences to maize and sorghum DNA indicated that the two genomes are very similar. Most probes detected two loci in maize; these usually detected two loci in sorghum. Probes that detected one locus in maize generally detected a single locus in sorghum. However, maize repetitive DNA sequences present on some of the genomic clones did not hybridize to sorghum DNA. Most of the probes tested detected polymorphisms among a group of seven diverse sorghum lines tested; over one-third of the probes detected polymorphism in a single F2 population from two of these lines. Cosegregation analysis of 55 F2 individuals enabled several linkage groups to be constructed and compared with the linkage relationships of the same loci in maize. The linkage relationships of the polymorphic loci in the two species were usually conserved, but several rearrangements were detected.

Structure and coding properties of Bs1, a maize retrovirus-like transposon

We have sequenced Bs1, an insertion element isolated from a null allele of the Adh1 locus encoding alcohol dehydrogenase in maize. The Bs1 element is 3203 base pairs (bp) in length, has 302-bp identical long terminal direct repeats (LTRs), and created a 5-bp flanking direct duplication of target Adh1 DNA upon insertion. The 5' LTR is followed by a canonical primer binding site with homology to the plant initiator methionyl-tRNA, and the 3' LTR is directly preceded by a polypurine stretch like that observed in retroviruses and retrotransposons. Bs1 encodes two overlapping open reading frames specifying peptides of 740 and 168 amino acids. The longer open reading frame specifies a peptide with amino acid homology to the protease and nucleic acid binding moiety of retroviruses and retrotransposons. The deduced amino acid sequence encoded by Bs1 lacks convincing homology to the polymerase (reverse transcriptase) encoded by retroposons, despite the fact that this polymerase-encoding domain is routinely the most conserved region of any such element. The sequence and relatively small size of Bs1 suggest that this element is a deleted retrotransposon that inserted into Adh1 with the aid of a reverse transcriptase function provided in trans. In vitro transcribed Bs1 complementary RNA was translated in vitro to produce both a protein of 81 kDa representing open reading frame 1 (ORF1) and one of the 95-kDa size predicted for the frame-shifted fusion of ORF1 and ORF2. As with many other retroposons, the efficiency of translational initiation at the AUG beginning ORF1 was not noticeably affected by the presence of one or more upstream, unproductive AUGs in the complementary RNA transcript.

Genomic organization of the ribosomal DNA of sorghum and its close relatives

The structure and organization of the ribosomal DNA (rDNA) of sorghum (Sorghum bicolor) and several closely related grasses were determined by gel blot hybridization to cloned maize rDNA. Monocots of the genus Sorghum (sorghum, shattercane, Sudangrass, and Johnsongrass) and the genus Saccharum (sugarcane species) were observed to organize their rDNA as direct tandem repeats of several thousand rDNA monomer units. For the eight restriction enzymes and 14 cleavage sites examined, no variations were seen within all of the S. bicolor races and other Sorghum species investigated. Sorghum, maize, and sugarcane were observed to have very similar rDNA monomer sizes and restriction maps, befitting their close common ancestry. The restriction site variability seen between these three genera demonstrated that sorghum and sugarcane are more closely related to each other than either is to maize. Variation in rDNA monomer lengths were observed frequently within the Sorghum genus. These size variations were localized to the intergenic spacer region of the rDNA monomer. Unlike many maize inbreds, all inbred Sorghum diploids were found to contain only one rDNA monomer size in an individual plant. These results are discussed in light of the comparative timing, rates, and modes of evolutionary events in Sorghum and other grasses. Spacer size variation was found to provide a highly sensitive assay for the genetic contribution of different S. bicolor races and other Sorghum species to a Sorghum population.

DNA structures associated with autonomously replicating sequences from plants

DNA fragments capable of conferring autonomous replicating ability to plasmids inSaccharomyces cerevisiae were isolated from four different plant genomes and from the Ti plasmid ofAgrobacterium tumefaciens. The DNA structure of these autonomously replicating sequences (ARSs) as well as two from yeast were studied using retardation during polyacrylamide gel electrophoresis and computer analysis as measures of sequence-dependent DNA structures. Bent DNA was found to be associated with the ARS elements. An 11 bp ARS consensus sequence required for ARS function was also identified in the elements examined and was flanked by unusually straight structures which were rich in A+T content. These results show that the ARS elements from genomes of higher plants have structural and sequence features in common with ARS elements from yeast and higher animals.

Cell-Autonomous Recognition of the Rust Pathogen Determines Rp1-Specified Resistance in Maize

The Rp1 gene of maize determines resistance to the leaf rust pathogen Puccinia sorghi. X-ray treatment of heterozygous (Rp1 Oy/rp1 oy) maize embryos generated seedlings with yellow sectors lacking. Rp1. Yellow sectored seedlings inoculated with rust spores gave rust pustule formation in yellow (Rp1-lacking) sectors and hypersensitive resistance in green tissues, thereby demonstrating that the Rp1 gene product is cellautonomous in its action. In cases where the hypersensitive reaction was initiated in green (Rp1) tissue next to a yellow sector, the hypersensitive response appeared to be propagated poorly, if at all, through Rp1-lacking cells.

Construction and Homologous Expression of a Maize Adh1 Based NcoI Cassette Vector

The alcohol dehydrogenase I (Adh1) gene of maize (Zea mays L.) was employed as a source of transcriptional, posttranscriptional, and translational regulatory sequences in the construction of an expression vector. By transforming the translation-initiating ATG and an ATG three triplets upstream from the translational termination triplet into NcoI sites (5'-CCATGG-3'), the maize Adh1 gene was converted into a cassette vector allowing one-step placement of any structural gene under Adh1 regulatory control. We inserted the structural gene for chloramphenicol acetyl transferase (CAT) into this cassette vector and found that this construct expressed the cat gene when transfected into maize protoplasts. Significant expression was observed with a construct that contained only 146 base pairs of Adh1 sequence upstream of the transcription-initiation site. Derivatives with a further 266 or 955 base pairs of contiguous Adh1 upstream sequences increased CAT expression approximately 5-fold or 8-fold, respectively.

Selection and characterization of cadmium-resistant suspension cultures of the wild tomato Lycopersicon peruvianum

Suspension cultures of Lycopersicon peruvianum were selected for resistance to cadmium by stepwise exposure to increasing concentrations of cadmium sulfate. Resistant cells grow in 1500 micromolar Cd(++). This resistance was retained for thirty generations without selection. Both resistant and parental sensitive cultures take up Cd(++) at similar rates and to the same final levels. Exposure of sensitive or resistant cultures to Cd(++), Cu(++), or Zn(++) leads to the intracellular accumulation of a low molecular weight, cysteine-rich, cadmium-binding protein. This metallothionein is induced over fifteen fold by 100 μM cadmium and builds up to about five fold higher levels in the resistant cultures.

Nucleotide sequence of the maize transposable element Mul

A cloned DNA fragment from the maize allele Adhl-S3034 contains all of Mul, an insertion element involved in Robertson's Mutator activity. The element is 1367 base pairs (bp) long and is flanked by nine bp direct repeats of insertion site DNA. It has inverted terminal repeats of 215 and 213 bp showing 95% homology. Within the element are two direct repeats of 104 bp showing 96% homology. Four open reading frames (ORFs) were found, two in each DNA strand. Mul can be divided into two halves, each containing one terminal inverted repeat, an internal direct repeat, and two overlapping ORFs. The GC content of each half is high (70%), while that of a central 60 base portion of the element is low (26%). The central region contains the only sequence resembling the TAATA Goldberg and Hogness eukaryotic promoter signal. Multiple copies of DNA sequences related to Mul found in Mutator maize plants are generally similar in organization to the cloned element. A larger version containing a discrete 300 to 400 base pair insertion was found in some Mutator lines.

DNA insertion in the first intron of maize Adh1 affects message levels: cloning of progenitor and mutant Adh1 alleles

A genetically unstable mutant allele of maize alcohol dehydrogenase-1 (Adh1) causes reduced levels of messenger RNA. This mutant was derived from a Robertson's mutator genetic background and previously was shown to be associated with an approximately 1.5-kilobase insertion. This report compares a genomic clone of the allele, Adh1-S3034, with a clone of its progenitor nonmutant allele, Adh1-S. No rearrangements of either recombinant molecule occurred during the cloning process. The mutant differs from its progenitor allele by the insertion of 1.4 kilobases of new DNA. Sequence determination of the insertion borders localized it to intron-1, 73 base pairs downstream from the 5' exon/intron junction in the Adh1-S gene. Insertion of the 1.4-kilobase element was associated with a 9-base-pair direct duplication of intron sequence. We suspect that this insertion, Mu1, affects message levels by depressing RNA processing or transcription.

Molecular analysis of the alcohol dehydrogenase (Adh1) gene of maize

A cDNA clone of maize Adh1 which contains the entire protein coding region of the gene has been constructed. The protein sequence predicted from the nucleotide sequence is in agreement with limited protein sequencing data for the ADH1 enzyme. An 11.5 kb genomic fragment containing the Adh1 gene has been isolated using the cDNA clone as a probe, and the gene region fully sequenced. The gene is interrupted by 9 introns, their junction sequences fitting the animal gene consensus sequence. Within the gene there is a triplication of a segment (104 bp) spanning an intron-exon junction. Presumptive promoter elements have been identified and are similar in nucleotide sequence and location, relative to the start of transcription, to those of other plant and animal genes. No recognizable poly(A+) addition signal is evident. Comparison of the nucleotide sequences of the cDNA (derived from an Adh1 -F allele) and genomic (derived from an Adh1 -S allele) clones has identified an amino acid difference consistent with the observed difference in electrophoretic mobility of the two enzymes. The maize ADH1 amino acid sequence is 50% homologous to that of horse liver ADH but is only 20% homologous to yeast ADH.

Codon selection in yeast

Extreme codon bias is seen for the Saccharomyces cerevisiae genes for the fermentative alcohol dehydrogenase isozyme I (ADH-I) and glyceraldehyde-3-phosphate dehydrogenase. Over 98% of the 1004 amino acid residues analyzed by DNA sequencing are coded for by a select 25 of the 61 possible coding triplets. These preferred codons tend to be highly homologous to the anticodons of the major yeast isoacceptor tRNA species. Codons which necessitate site by side GC base pairs between the codons and the tRNA anticodons are always avoided whenever possible. Codons containing 100% G, C, A, U, GC, or AU are also avoided. This provides for approximately equivalent codon-anticodon binding energies for all preferred triplets. All sequenced yeast genes show a distinct preference for these same 25 codons. The degree of preference varies from greater than 90% for glyceraldehyde-3-phosphate dehydrogenase and ADH-I to less than 20% for iso-2 cytochrome c. The degree of bias for these 25 preferred triplets in each gene is correlated with the level of its mRNA in the cytoplasm. Genes which are strongly expressed are more biased than genes with a lower level of expression. A similar phenomenon is observed in the codon preferences of highly expressed genes in Escherichia coli. High levels of gene expression are well correlated with high levels of codon bias toward 22 of the 61 coding triplets. As in yeast, these preferred codons are highly complementary to the major cellular isoacceptor tRNA species. In at least four cases (Ala, Arg, Leu, and Val), these preferred E. coli codons are incompatible with the preferred yeast codons.

The primary structure of the Saccharomyces cerevisiae gene for alcohol dehydrogenase

The DNA sequence of the gene for the fermentative yeast alcohol dehydrogenase has been determined. The structural gene contains no introns. The amino acid sequence of the protein as determined from the nucleotide sequence disagrees with the published alcohol dehydrogenase isozyme I (ADH-I) sequence for 5 of the 347 amino acid residues. At least one, and perhaps as many as four, of these differences is probably due to ADH-I protein heterogeneity in different yeast strains and not to sequencing errors. S1 nuclease was used to map the 5' and 3' ends of the ADH-I mRNA. There are two discrete, mature 5' ends of the mRNA, mapping 27 and 37 nucleotides upstream of the translation initiating ATG. These two equally prevalent termini are 101 and 91 nucleotides, respectively, downstream from a TATAAA sequence. Analysis of the 3' end of ADH-I mRNA disclosed two minor ends upstream of the major poly(A) addition site. These three ends map 24, 67, and 83 nucleotides, respectively, downstream from the translation-terminating TAA triplet. The sequence AA-TAAG is found 28 to 34 nucleotides upstream of each ADH-I mRNA poly(A) addition site. Sequence comparisons of these three 3' ends with those for four other yeast mRNAs yielded a 13-nucleotide consensus sequence to which TAAATAAGA is central. All of the known yeast poly(A) addition sites map at or near the A residue of a CTA site 25 to 40 nucleotides downstream from this consensus octamer.