Zein storage protein gene family of maize. An assessment of heterogeneity with cloned messenger RNA sequences

Maize kernel development

Maize (Zea mays) is a leading cereal crop in the world. The maize kernel is the storage organ and the harvest portion of this crop and is closely related to its yield and quality. The development of maize kernel is initiated by the double fertilization event, leading to the formation of a diploid embryo and a triploid endosperm. The embryo and endosperm are then undergone independent developmental programs, resulting in a mature maize kernel which is comprised of a persistent endosperm, a large embryo, and a maternal pericarp. Due to the well-characterized morphogenesis and powerful genetics, maize kernel has long been an excellent model for the study of cereal kernel development. In recent years, with the release of the maize reference genome and the development of new genomic technologies, there has been an explosive expansion of new knowledge for maize kernel development. In this review, we overviewed recent progress in the study of maize kernel development, with an emphasis on genetic mapping of kernel traits, transcriptome analysis during kernel development, functional gene cloning of kernel mutants, and genetic engineering of kernel traits.

Linkage and homology analysis divides the eight genes for the small subunit of petunia ribulose 1,5-bisphosphate carboxylase into three gene families

Twenty-six lambda phage clones with homology to coding sequences of the small subunit (SSU) of ribulose 1,5-bisphosphate carboxylase have been isolated from an EMBL3 lambda phage bank of Petunia (Mitchell) DNA. Restriction mapping of the phage inserts shows that the clones were obtained from five nonoverlapping regions of petunia DNA that carry seven SSU genes. Comparison of the HindIII genomic fragments of petunia DNA with the HindIII restriction fragments of the isolated phage indicates that petunia nuclear DNA encodes eight SSU genes, seven of which are present in the phage clones. Two incomplete genes, which contain only the 3' end of an SSU gene, were also found in the phage clones. We demonstrate that the eight SSU genes of petunia can be divided into three gene families based on homology to three petunia cDNA clones. Two gene families contain single SSU genes and the third contains six genes, four of which are closely linked within petunia nuclear DNA.

Expressional profiling study revealed unique expressional patterns and dramatic expressional divergence of maize alpha-zein super gene family

The alpha-zein super gene family encodes the most predominant storage protein in maize (Zea mays) endosperm. In maize inbred line B73, it consists of four gene families with 41 member genes. In this study, we combined quantitative real-time PCR and random clone sequencing to successfully profile the expression of alpha-zein super gene family during endosperm development. We found that only 18 of the 41 member genes were expressed, and their expression levels diverge greatly. At the gene family level, all families had characteristic "up-and-down" oscillating expressional patterns that diverged into two major groups. At the individual gene level, member genes showed dramatic divergence of expression patterns, indicating fast differentiation of their expression regulation. A comparison study among different inbred lines revealed significantly different expressed gene sets, indicating the existence of highly diverged haplotypes. Large gene families containing long gene clusters, e.g. z1A or z1C, mainly contributed the highly divergent haplotypes. In addition, allelic genes also showed significant divergence in their expressional levels. These results indicated a highly dynamic and fast evolving nature to the maize alpha-zein super gene family, which might be a common feature for other large gene families.

Contiguous genomic DNA sequence comprising the 19-kD zein gene family from maize

A new approach has been undertaken to analyze the sequences and linear organization of the 19-kD zein genes in maize (Zea mays). A high-coverage, large-insert genomic library of the inbred line B73 based on bacterial artificial chromosomes was used to isolate a redundant set of clones containing members of the 19-kD zein gene family, which previously had been estimated to consist of 50 members. The redundant set of clones was used to create bins of overlapping clones that represented five distinct genomic regions. Representative clones containing the entire set of 19-kD zein genes were chosen from each region and sequenced. Seven bacterial artificial chromosome clones yielded 1,160 kb of genomic DNA. Three of them formed a contiguous sequence of 478 kb, the longest contiguous sequenced region of the maize genome. Altogether, these DNA sequences provide the linear organization of 25 19-kD zein genes, one-half the number previously estimated. It is suggested that the difference is because of haplotypes exhibiting different degrees of gene amplification in the zein multigene family. About one-half the genes present in B73 appear to be expressed. Because some active genes have only been duplicated recently, they are so conserved in their sequence that previous cDNA sequence analysis resulted in "unigenes" that were actually derived from different gene copies. This analysis also shows that the 22- and 19-kD zein gene families shared a common ancestor. Although both ancestral genes had the same incremental gene amplification, the 19-kD zein branch exhibited a greater degree of far-distance gene translocations than the 22-kD zein gene family.

Interchromosomal recombination in Zea mays

A new allele of the 27-kD zein locus in maize has been generated by interchromosomal recombination between chromosomes of two different inbred lines. A continuous patch of at least 11,817 bp of inbred W64A, containing the previously characterized Ra allele of the 27-kD zein gene, has been inserted into the genome of A188 by a single crossover. While both junction sequences are conserved, sequences of the two homologs between these junctions differ considerably. W64A contains the 7313-bp-long retrotransposon, Zeon-1. A188 contains a second copy of the 27-kD zein gene and a 2-kb repetitive element. Therefore, recombination results in a 7.3-kb insertion and a 14-kb deletion compared to the original S+A188 allele. If nonpairing sequences are looped out, 206 single base changes, frequently clustered, are present. The structure of this allele may explain how a recently discovered example of somatic recombination occurred in an A188/W64A hybrid. This would indicate that despite these sequence differences, pairing between these alleles could occur early during plant development. Therefore, such a somatically derived chimeric chromosome can also be heritable and give rise to new alleles.

The bifactorial endosperm box of gamma-zein gene: characterisation and function of the Pb3 and GZM cis-acting elements

The proximal region of the gamma-zein promoter (gamma Z) has a functional bifactorial prolamin box element containing two cis-acting elements, a prolamin-box motif (Pb3) and a GCN4-like motif (GZM). By particle bombardment of maize endosperms with 5' deletions and internal deletions of gamma Z fused to the GUS gene, we have shown that a 135 bp region containing the bifactorial element is involved in the transcriptional activation of the gamma Z promoter. However, the 135 bp region was unable to activate the gamma Z promoter in the absence of a 84 bp downstream sequence. Using in vivo footprinting and gel mobility shift assays with 15 DAP endosperm nuclear extracts, we have demonstrated the presence of trans-acting factors that interact with Pb3 and GZM target sites. Base-substitution mutations within Pb3 and GZM decreased transcription activity of the gamma Z promoter suggesting a co-ordinated function between the two cis-acting elements. Two additional cis-motifs upstream of the bifactorial prolamin element have been identified: a motif with high homology to the AACA elements of rice glutelin genes and an AZM motif containing an ACGT core which binds nuclear proteins other than the Opaque 2 (O2).

Amplicons of maize zein genes are conserved within genic but expanded and constricted in intergenic regions

The 78,101 base pair long sequence of a cluster of 22-kDa alpha zein genes in the maize inbred BSSS53 was determined. Each zein gene is contained within a repeat unit that varies in length. If such a repeat, or amplicon, is aligned along the entire sequence, a 10.5-fold sequence amplification is delineated. Because of insertions and deletions in intergenic regions, many of the zein genes are spaced over different distances. Only three out of 10 zein-related sequences have an intact open reading frame, indicating an unusual large number of genes unable to contribute to the accumulation of normal-size 22-kDa zein proteins. It is proposed that the seven remaining zein-related sequences be considered gene reserves because of their potential to be restored by gene conversion. Intergenic insertions in the cluster range from 1098 to 14,896 base pairs. Although they are composed of transposable element sequences, they also contain additional open reading frames, two of them showing homology to rice cDNA sequences. The average amplicon is 4423 base pairs long, with the sequence surrounding each zein gene more than 90% conserved. Coincidently, the size of the amplicon is equivalent to the average gene density (one gene within 4640 bp) in the Arabidopsis thaliana genome, one of the smallest in plants. Successive steps of amplification and insertion of DNA might explain to a certain degree how genome size variation has been generated in plants.

Identification of a transcriptional activator-binding element in the 27-kilodalton zein promoter, the -300 element

By utilizing a homologous transient-expression system, we have shown that a 58-bp sequence from the gamma-class 27-kDa zein promoter, spanning from -307 to -250 relative to the transcription start site, confers a high level of transcriptional activity on a truncated plant viral promoter. The transcriptional activity mediated by the 58-bp sequence is orientation independent, and it is further enhanced as a result of its multimerization. A similarly high level of transcriptional activity was also observed in protoplasts isolated from leaf tissue-derived maize suspension cells. In vitro binding and DNase I footprinting assays with nuclear protein prepared from cultured endosperm cells revealed the sequence-specific binding of a nuclear factor(s) to a 16-nucleotide sequence present in the 58-bp region. The nuclear factor binding sequence includes the -300 element, a cis-acting element highly conserved among different zein genes and many other cereal storage protein genes. A 23-bp oligonucleotide sequence containing the nuclear factor binding site is sufficient for binding the nuclear factor in vitro. It also confers a high level of transcriptional activity in vivo, but in an orientation-dependent manner. Four nucleotide substitutions in the -300 element drastically reduced binding and transcriptional activation by the nuclear factor. The same nuclear factor is abundant in the developing kernel endosperm and binds to the -300 element region of the 27-kDa or the alpha-class zein promoter. These results suggest that the highly conserved -300 element is involved in the common regulatory mechanisms mediating the coordinated expression of the zein genes.

Identification of a transcriptional activator-binding element in the 27-kilodalton zein promoter, the -300 element

By utilizing a homologous transient-expression system, we have shown that a 58-bp sequence from the gamma-class 27-kDa zein promoter, spanning from -307 to -250 relative to the transcription start site, confers a high level of transcriptional activity on a truncated plant viral promoter. The transcriptional activity mediated by the 58-bp sequence is orientation independent, and it is further enhanced as a result of its multimerization. A similarly high level of transcriptional activity was also observed in protoplasts isolated from leaf tissue-derived maize suspension cells. In vitro binding and DNase I footprinting assays with nuclear protein prepared from cultured endosperm cells revealed the sequence-specific binding of a nuclear factor(s) to a 16-nucleotide sequence present in the 58-bp region. The nuclear factor binding sequence includes the -300 element, a cis-acting element highly conserved among different zein genes and many other cereal storage protein genes. A 23-bp oligonucleotide sequence containing the nuclear factor binding site is sufficient for binding the nuclear factor in vitro. It also confers a high level of transcriptional activity in vivo, but in an orientation-dependent manner. Four nucleotide substitutions in the -300 element drastically reduced binding and transcriptional activation by the nuclear factor. The same nuclear factor is abundant in the developing kernel endosperm and binds to the -300 element region of the 27-kDa or the alpha-class zein promoter. These results suggest that the highly conserved -300 element is involved in the common regulatory mechanisms mediating the coordinated expression of the zein genes.

Sequence analysis of 22 kDa-like alpha-coixin genes and their comparison with homologous zein and kafirin genes reveals highly conserved protein structure and regulatory elements

Several genomic and cDNA clones encoding the 22 kDa-like alpha-coixin, the alpha-prolamin of Coix seeds, were isolated and sequenced. Three contiguous 22 kDa-like alpha-coixin genes designated alpha-3A, alpha-3B and alpha-3C were found in the 15 kb alpha-3 genomic clone. The alpha-3A and alpha-3C genes presented in-frame stop codons at position +652. The two genes with truncated ORFs are flanking the alpha-3B gene, suggesting that the three alpha-coixin genes may have arisen by tandem duplication and that the stop codon was introduced before the duplication. Comparison of the deduced amino acid sequences of alpha-coixin clones with the published sequences of 22 kDa alpha-zein and 22 kDa-like alpha-kafirin revealed a highly conserved protein structure. The protein consists of an N-terminus, containing the signal peptide, followed by ten highly conserved tandem repeats of 15-20 amino acids flanked by polyglutamines, and a short C-terminus. The difference between the 22 kDa-like alpha-prolamins and the 19 kDa alpha-zein lies in the fact that the 19 kDa protein is exactly one repeat motif shorter than the 22 kDa proteins. Several putative regulatory sequences common to the zein and kafirin genes were identified within both the 5' and 3' flanking regions of alpha-3B. Nucleotide sequences that match the consensus TATA, CATC and the ca. -300 prolamin box are present at conserved positions in alpha-3B relative to zein and kafirin genes. Two putative Opaque-2 boxes are present in alpha-3B that occupies approximately the same positions as those identified for the 22 kDa alpha-zein and alpha-kafirin genes. Southern hybridization, using a fragment of a maize Opaque-2 cDNA clone as a probe, confirmed the presence of Opaque-2 homologous sequences in the Coix and sorghum genomes. The overall results suggest that the structural and regulatory genes involved in the expression of the 22 kDa-like alpha-prolamin genes of Coix, sorghum and maize, originated from a common ancestor, and that variations were introduced in the structural and regulatory sequences after species separation.

Studies of the zein-like alpha-prolamins based on an analysis of amino acid sequences: implications for their evolution and three-dimensional structure

alpha-Prolamins are the major seed storage proteins of species of the grass tribe Andropogonea. They are unusually rich in glutamine, proline, alanine, and leucine residues and their sequences show a series of tandem repeats presumed to be the result of multiple intragenic duplication. Two new sequences of alpha-prolamin clones from Coix (pBCX25.12 and pBCX25.10) are compared with similar clones from maize and Sorghum in order to investigate evolutionary relationships between the repeat motifs and to propose a schematic model for their three-dimensional structure based on hydrophobic membrane-helix propensities and helical "wheels." A scheme is proposed for the most recent events in the evolution of the central part of the molecule (repeats 3 to 8) which involves two partial intragenic duplications and in which contemporary odd-numbered and even-numbered repeats arise from common ancestors, respectively. Each pair of repeats is proposed to form an antiparallel alpha-helical hairpin and that the helices of the molecule as a whole are arranged on a hexagonal net. The majority of helices show six faces of alternating hydrophobic and polar residues, which give rise to intersticial holes around each helix which alternate in chemical character. The model is consistent with proteins which contain different numbers of repeats, with oligomerization and with the dense packaging of alpha-prolamins within the protein body of the seed endosperm.

Genomic organization of an alpha-zein gene cluster in maize

The genes encoding the alpha-zein proteins of maize constitute a large multigene family of some 75 genes. This multigene family can be divided into four subfamilies based on the nucleotide sequences of their genes and the deduced amino acid sequences of their proteins. We describe for the first time evidence of a clustering of five alpha-zein subfamily 4 (SF4) genes that are members of one of the major alpha-zein subfamilies in a 56 kb region of the genome of the maize inbred line W22. None of the other three known alpha-zein gene subfamilies (SF1, SF2, or SF3) are present in this cluster. The genomic region was reconstructed using restriction endonuclease maps to identify and align three overlapping cosmid clones isolated from a genomic library. The alpha-zein genes are not evenly spaced; the minimum distance between genes is 3.5 kb; the maximum is 13 kb. All the alpha-zein genes in the cluster have the same transcriptional orientation. The location and sequences of some of the repetitive DNA elements in this gene cluster were determined. We estimate that there are a minimum of eight repetitive DNA elements in this region. The sequences of the repetitive elements (not functionally defined) are located between or among the alpha-zein genes. The regions containing two of these repetitive elements (Rep1 and Rep4) have been sequenced; they are about 15 kb apart in the genome. These repetitive elements have similar sequences for about 300 bp out of the 400 bp compared. The regions of sequence similarity, however, are in reverse orientation to one another.(ABSTRACT TRUNCATED AT 250 WORDS)

Highly clustered zein gene sequences reveal evolutionary history of the multigene family

We have determined the nucleotide sequences of zein cDNA clones ZG14, ZG15, and ZG35. The three clones have 95 to 98% homology to the previously published sequence of clone A20, and 84% homology to sequences of the zein subfamily A30. Comparison of all sequences of the A30 and A20 subfamilies highlights the following features: the 5' nontranslated regions are 68 and 57 nucleotides in length for the A20- and A30-like mRNAs, respectively, and contain at least three repeats of the consensus sequence ACGAACAAta/gG; the majority of these genes are highly clustered as judged from pulsed-field gel electrophoresis of high molecular weight maize DNA. Furthermore, we discuss a model for the evolution of the multigene family which stresses the special importance of unequal crossingover and gene conversion in this system.

A homologous expression system for cloned zein genes

Expression of the genes encoding the 10-, 15-, and 27-kDa zeins is maintained in suspension cultures derived from developing endosperm tissue of maize (Zea mays L.). Although expression of these genes is reduced in endosperm cultures as compared with that in endosperm tissue from developing kernels, it remains specific to the origin of explant, since no transcripts are detected in leaf tissue-derived suspension cultures. Transcript sizes are identical to those in developing seed endosperm tissue. Furthermore, accurate transcription initiation of the 10- and 27-kDa zein genes is observed by S1 nuclease mapping. Protoplasts isolated from endosperm cultures are capable of expressing foreign genes when transfected by electroporation. We demonstrate that the 5' flanking sequences of the 10- and 27-kDa zein genes are capable of promoting chloramphenicol acetyltransferase (CAT) gene expression in these transfected protoplasts. Our observations show that these maize endosperm cultures can be used as an efficient homologous system to study transcriptional regulation of zein genes.

Post-transcriptional regulation of methionine content in maize kernels

Message levels for a methionine-rich 10 kDa zein were determined in three inbred lines of maize and their reciprocal crosses at various stages during endosperm development. Inbred line BSSS-53, which overexpresses the 10 kDa protein in mature kernels, was shown to have higher mRNA levels in developing endosperm, as compared to inbred lines W23 and W64A. Differences in mRNA levels could not be explained by differences in transcription rate of the 10 kDa zein gene, indicating differential post-transcriptional regulation of this storage protein in the different inbred lines analyzed. Among progeny segregating for the BSSS-53 allele of the 10 kDa zein structural gene Zps10/(22), mRNA levels are independent of Zps10/(22) segregation, indicating that post-transcriptional regulation of mRNA levels takes place via a trans-acting mechanism. In the same progeny, mRNA levels are also independent of allelic segregation of the regulatory locus Zpr10/(22). Thus, the trans-acting factor encoded by Zpr10/(22) determines accumulation of 10 kDa zein at a translational or post-translational step. Multiple trans-acting factors are therefore involved in post-transcriptional regulation of the methionine-rich 10 kDa zein.

An arginine to lysine substitution in the bZIP domain of an opaque-2 mutant in maize abolishes specific DNA binding

The opaque-2 (o2) locus in maize encodes a transcription factor involved in the regulation of zein storage proteins. We have shown previously that the O2 protein contains a leucine zipper domain that binds to promoters of 22-kD zein genes. In this paper we characterize an EMS-induced o2 allele, o2-676, that causes a 50% reduction in zein. We have found that the o2-676 mutant protein does not show specific recognition of zein promoter fragments because of the substitution of a lysine residue for an arginine residue within the bZIP domain of o2-676. This particular arginine is conserved within the bZIP domains of all mammalian, fungal, and plant DNA binding proteins of this class. The correlation between this mutation in o2 and the altered pattern of zein expression strongly suggests that O2 regulates transcription of certain members of the zein multigene family through direct interaction with the zein promoters and not through the transcriptional activation of some other regulator of zein gene expression.

Maize regulatory gene opaque-2 encodes a protein with a "leucine-zipper" motif that binds to zein DNA

The opaque-2 locus (o2) in maize regulates the expression of many members of the zein multigene family of storage proteins. cDNA clones for a wild-type allele of the (o2) locus (O2) were isolated from a maize endosperm cDNA library and sequenced. We found a 258-nucleotide 5' leader sequence containing three short open reading frames followed by a sequence specifying a protein of 437 amino acids. The presumptive amino acid sequence of the protein (O2) specified by the O2 cDNA contains a "leucine-zipper" domain characteristic of some mammalian and fungal transcription activation factors. lacZ-O2 fusion constructs, using nearly the entire coding region of O2 or only a fragment specifying the leucine-zipper domain, were expressed in Escherichia coli. In an in vitro binding assay, the beta-galactosidase-O2 fusion proteins bound to two specific regions on the 5' side of the coding sequence in a zein genomic clone. This suggests that the O2 protein affects zein transcription through direct interaction with one or more zein promoter elements.

Analysis of distal flanking regions of maize 19-kDa zein genes

Two genomic fragments from maize, each containing a 19-kDa zein gene with extensive flanking regions, have been sequenced and examined by computer-aided analysis and Southern blotting techniques. Sequence analysis of the distal flanking sequences has revealed interesting sequence motifs, some not seen before. In particular, four nearly identical, G + C-rich, 17 to 21-bp perfect palindromes were found clustered in a 133-bp stretch lying 2 kb upstream from the zein-coding region in the genomic clone pMS2. These palindromic sequences exhibit other interesting features, including a precise spatial organization with respect to each other, and their proximity to several other repeated motifs in the same region. Southern blot analysis indicates that these palindromes, or closely related sequences, are found frequently in the maize genome. Possible secondary structures for the palindrome units are presented, which resemble functionally important sequences found upstream from other eukaryotic genes.

Isolation and sequence of a gene encoding a methionine-rich 10-kDa zein protein from maize

We have isolated the gene encoding a methionine-rich 10-kDa zein protein from a lambda EMBL3 maize genomic 'mini' library of the inbred line BSSS-53 and determined its nucleotide sequence. The sequence matches perfectly with a cDNA clone from the inbred line W22 (which has the same restriction fragment length polymorphism as many inbred lines tested) indicating that we have isolated a functional storage protein gene that is very conserved in maize. This comparison also excludes any splicing of any precursor mRNA and therefore any presence of introns. A number of potential regulatory sequences have been located in the flanking regions. The 10-kDa-zein gene represents the last size class in the zein multigene family to be characterized. Its structure allows us now to re-examine the relationship of all the zein proteins and also to compare the structure of a new class of storage proteins that are rich in methionine, an essential amino acid in livestock fodder.

The chalcone synthase multigene family of Petunia hybrida (V30): sequence homology, chromosomal localization and evolutionary aspects

Chalcone synthase (CHS) genes in Petunia hybrida comprise a multigene family containing at least 7 complete members in the strain Violet 30 (V30). Based on a high sequence homology in both coding and non-coding sequence, a number of CHS genes can be placed into two subfamilies. By restriction fragment length polymorphism (RFLP) analysis it was shown that both chromosomes II and V carry one of these subfamilies, in addition to the other CHS genes identified so far. Members of a subfamily were found to be closely linked genetically. Analysis of the Petunia species that contributed to the hybrid nature of P. hybrida (P. axillaris, P. parodii, P. inflata and P. violacea) shows that none of the CHS gene clusters is specific for either one of the parents and therefore did not arise as a consequence of the hybridization. The number of CHS genes within a subfamily varies considerably among these Petunia species. From this we infer that the CHS subfamilies arose from very recent gene duplications.

Transposon tagging and molecular analysis of the maize regulatory locus opaque-2

Genetic analyses suggested that the opaque-2 (o2) locus in maize acts as a positive, transacting, transcriptional activator of the zein seed storage-protein genes. Because isolation of the gene is requisite to understanding the molecular details of this regulation, transposon mutagenesis with the transposable element suppressor-mutator (Spm) was carried out, and three mutable o2 alleles were obtained. One of these alleles contained an 8.3-kilobase autonomous Spm, another a 6.8-kilobase nonautonomous Spm, and the third an unidentified transposon that is unrelated to Spm. A DNA sequence flanking the autonomous Spm insertion was verified to be o2-specific and provided a probe to clone a wild-type allele. Northern blots indicated that the gene is expressed in wild-type endosperm but not in leaf tissues or in endosperms homozygous for a mutant allele of the O2 gene. A transcript was detected in endosperms homozygous for mutations at opaque-7 and floury-2, an indication that O2 expression is independent of these two other putative regulators of zein synthesis.

A 23.8-kD alpha-zein with N-terminal sequence and immunological properties similar to 26.7-kD alpha-zeins

A 23.8-kD alpha-zein polypeptide, K55PC7, has been shown to be a truncated member of the 26.7-kD alpha-zein class based on its amino acid composition, N-terminal sequence, and immunological properties. This unusual polypeptide was isolated by chromatographing whole alpha-zein from inbred K55. The N-terminal sequence of K55PC7 is highly homologous to those of 4 putative 26.7-kD alpha-zeins but shows no homology to those of 10 putative alpha-zeins that belong to the 23.8-kD class. Its higher valine and lower phenylalanine contents also suggest that K55PC7 is a member of the 26.7-kD class. In addition, studies with antibodies raised to peptides corresponding to regions unique to each of the two alpha-zein classes indicate that K55PC7 has immunological similarity to 26.7-kD alpha-zeins. Peptide mapping data suggest that K55PC7 is not the putative product of the truncated 26.7-kD alpha-zein gene zA1 isolated from inbred W64A and described by Spena et al. [26]. It appears that K55PC7 occurs as a major component in inbred K55 and is a truncated version of a 26.7-kD alpha-zein, arisen either by an internal deletion or premature termination due to a nonsense mutation.

The chalcone synthase multigene family of Petunia hybrida (V30): sequence homology, chromosomal localization and evolutionary aspects

Chalcone synthase (CHS) genes in Petunia hybrida comprise a multigene family containing at least 7 complete members in the strain Violet 30 (V30). Based on a high sequence homology in both coding and non-coding sequence, a number of CHS genes can be placed into two subfamilies. By restriction fragment length polymorphism (RFLP) analysis it was shown that both chromosomes II and V carry one of these subfamilies, in addition to the other CHS genes identified so far. Members of a subfamily were found to be closely linked genetically. Analysis of the Petunia species that contributed to the hybrid nature of P. hybrida (P. axillaris, P. parodii, P. inflata and P. violacea) shows that none of the CHS gene clusters is specific for either one of the parents and therefore did not arise as a consequence of the hybridization. The number of CHS genes within a subfamily varies considerably among these Petunia species. From this we infer that the CHS subfamilies arose from very recent gene duplications.

The suitability of restriction fragment length polymorphisms as genetic markers in maize

Strain identification in Zea mays by restriction fragment length polymorphism should be feasible due to the high degree of polymorphism found at many loci. The polymorphism in maize is apparently higher than that currently known for any other organism. Five randomly selected maize inbred lines were examined by Southern filter hybridization with probes of cloned low copy sequences. Typically, several alleles could be distinguished among the inbred lines with any one probe and an appropriately selected restriction enzyme. Despite considerable polymorphism at the DNA level, 16 RFLP markers in three inbred lines of maize were examined for six to 11 generations and found be stable. Mapping of RFLP markers in maize can be accelerated by the use of B-A translocation stocks, which enable localization of a marker to chromosome arm in one generation. The use of recombinant inbred lines in further refinement of the map is discussed.

Identification and characterization of DNA clones encoding group-II glycinin subunits

DNA clones that encode the group-II subunits of soybean glycinin were identified and compared with clones for group-I subunits. The group-I clones hybridize weakly to those from group-II at low stringency, but fail to hybridize with them at moderate or high stringency. The genes for the group-II subunits are contained in 13 and 9 kb EcoRI fragments of genomic DNA in cultivar CX635-1-1-1. These fragments contain genes for subunits A5A4B3 and A3B4, respectively. The larger size of mature group-II subunits compared with group-I subunits is correlated with a larger sized mRNA. However, the gross arrangement of introns and exons within the group-II coding regions appears to be the same as for the genes which encode group-I subunits. Messenger RNA for both groups of glycinin subunits appear in the seed at the same developmental interval, and their appearance lags slightly behind that of mRNAs for the a/a' subunits of β-conglycinin. These data indicate that the glycinin gene family is more complex than previously thought.

Mapping of zein polypeptides after isoelectric focusing on agarose gels

Isoelectric focusing of zein in agarose gels gives sharp separations of at least 25 bands noted among 25 corn-belt inbreds. Six inbreds provided standard bands which were used to construct a pattern map. A method is provided for comparing bands, identified by distance from the cathode, which differ only slightly in position. The 25 inbreds were separated into five groups on the basis of pattern similarity. Some groups contained inbreds derived from widely different sources. Zein isoelectric focusing in agarose should be useful for genotype identification and for determination of varietal purity.

Zein gene organization in maize and related grasses

Zein cDNA clones were used to study the organization of zein genes within the genome of the inbred maize W64A. When individual clones for the two larger molecular-weight classes of zein proteins (Mr = 22,000; Mr = 19,000) were used as probes for Southern blot hybridizations of genomic DNA, multiple restriction fragments were found to hybridize. Reconstruction analyses using moderately stringent criteria were used to estimate a total of 70-80 zein sequences within the genome of this inbred maize. The hybridization patterns suggest that zein sequences are clustered within the same restriction fragment. When criteria permitting less cross-hybridization of homologous sequences (Tm - 10 degrees C) were used, the banding pattern changed, with some of the bands being reduced in intensity or eliminated entirely. Therefore, by control of hybridization criteria, particular zein genes may be more readily distinguished in a Southern blot analysis. The Southern blot hybridization pattern for the Mr = 15,000 zein was less complex. Only a single major band was found, with sufficient hybridization intensity for two or three genes. Genomic Southern analyses of other inbred maizes and related grasses showed similarly complex hybridization patterns with cDNA probes for the 19,000- and 22,000-molecular-weight zeins, suggesting that these sequences have been conserved over evolutionary time. The zein multigene family may therefore have arisen by gene duplication before divergence of the maize, teosinte, and Tripsacum species from a common ancestor.

Nucleotide sequence analysis of a zein genomic clone with a short open reading frame

The nucleotide sequence of the zein genomic clone (W22)Z7 and its flanking sequences from the W22 inbred line of maize is reported. The sequence is 1587 bp long and contains 444 bp of 5' noncoding sequence and 342 bp of 3' noncoding sequence. The Z7 sequence belongs to a large complex multigene family and is a member of the B49 subfamily. It is 86% homologous to other known sequences from the same subfamily, but contains four in-frame termination codons caused by single base changes. Its flanking regions contain the usual eukaryotic transcriptional signals.

Characterization of the multigene family coding for HMW glutenin subunits in wheat using cDNA clones

cDNA clones encoding wheat HMW glutenin subunits have been isolated from a cDNA bank made to poly A(+) RNA from developing wheat endosperm var. Chinese Spring. One such clone, pTag 1290, has enabled us to identify the HMW glutenin mRNA species. The DNA sequence of this clone has been partially determined and it contains several tandem DNA repeats. The sequence is discussed in relation to the generation of the HMW glutenin subunit gene family. Analysis of the organization of the HMW glutenin sequences in the wheat genome revealed that the genes encoding HMW glutenin subunits exist in low copy number and are located on the long arm of each of the homoeologous group 1 chromosomes.

Sequence analysis of zein cDNAs obtained by an efficient mRNA cloning method

A cDNA library was generated from mRNA isolated from the developing endosperm of W22 maize inbred. cDNA clones for zein, the maize storage protein family, were isolated and analyzed by DNA sequencing. The DNA sequences of four clones containing cDNA copies of mRNAs belonging to one zein subfamily were determined. The data support the following conclusions: a) genes encoding the larger of the two zein species contain eleven instead of nine repeat units within the coding sequence of the gene; b) transcription can be terminated at either of the two polyadenlation signals and c) transcription starts 31 basepairs downstream from the first T in the TATA box. To facilitate this analysis a new method for the construction of cDNA libraries was developed. The mRNA was annealed to linearized and oligo-dT tailed pUC9 plasmid DNA, which then primed synthesis of the first strand of the cDNA. Oligo-dG tails were added to the cDNA-plasmid molecules, which were then centrifuged through an alkaline sucrose gradient. The gradient step removed small molecules and separated the two cDNAs which were formerly attached to the same double stranded plasmid molecule. An excess of oligo-dC tailed denatured pUC9 DNA was added and the DNA was renatured under conditions that favor the circularization of monomers by the oligo-dC and oligo-dG tails. The oligo-dC tail served as primer for the synthesis of the second strand of the cDNA. The library was screened by colony hybridization using 32P-labelled cDNA and DNA from genomic zein clones as probes. We obtained 20,000 clones hybridizing total cDNA starting with 1 microgram of plasmid DNA and 1 microgram of mRNA.

Isolation and characterization of maize genes coding for zein proteins of the 21000 dalton size class

Cloning in lambda gt WES phage of EcoRI fragments from maize seedlings DNA led to the isolation of four fragments containing genes coding for 21000 dalton zein proteins. The zein genes, identified by electron microscopic analysis, do not contain intervening sequences detectable by this method. The flanking sequences were analyzed by restriction sites mapping and hybridization and showed areas of homology between each other and with sequences surrounding a previously isolated gene of the 19000 dalton zein class.

Three mutations in Zea mays affecting zein accumulation: a comparison of zein polypeptides, in vitro synthesis and processing, mRNA levels, and genomic organization

We studied three mutations, opaque-2 (o2), opaque-7 (o7), and floury-2(fI2), each of which causes a depression in zein synthesis. We examined the processing efficiencies of the rough endoplasmic reticulum membranes in vitro, the levels of RNA transcription using cloned zein probes, and the genomic organization of the zein sequences as possible sites for the genetic defects. The results obtained indicate that the steps in prezein translation and processing occurring on the protein body membranes are not accountable for the lowered zein content in any of the mutations. The o2 mutation that typically shows a paucity of 22.5-kdalton zein polypeptides was found to have a concomitant reduction in a particular subgroup of mRNAs coding for this size class. Southern analyses suggest that the o2 mutation is not the result of a large deletion of tandem-linked zein genes.

Primary structure of a genomic zein sequence of maize

The nucleotide sequence of a genomic clone (termed Z4 ) of the zein multigene family was compared to the nucleotide sequence of related cDNA clones of zein mRNAs. A tandem duplication of a 96-bp sequence is found in the genomic clone that is not present in the related cDNA clones. When the duplication is disregarded, the nucleotide sequence homology between Z4 and its related cDNAs was approximately 97%. The nucleotide sequence is also compared to other isolated cDNAs. No introns in the coding region of the zein gene are detected. The first nucleotide of a putative TATA box, TATAAATA , was located 88 nucleotides upstream of the first nucleotide of the first ATG codon which initiated the open reading frame. The first nucleotide of a putative CCAAT box, CAAAAT , appeared 45 nucleotides upstream of the first nucleotide of the zein cDNA clones in the 3' non-coding region also appeared in the genomic sequence at the same locations. The amino acid composition of the polypeptide specified by the Z4 nucleotide sequence is similar to the known composition of zein proteins.