Genetic control of a membrane component and zein deposition in maize endosperm

Summary An association is reported between an albuminlike protein (b-70) and the semidominant locus fluory-2 (fl2) which reduces the level of zein polypeptides in the maize endosperm. The protein b-70 is present at low level in wild-type endosperms and derppressed in fl2 endosperms. A correlation between the doses of the fl2 allele and the b-70 level has been found. Moreover a concomitant loss of the regulatory role of fl2 on zein level and on b-70 overproduction is evident when fl2 is genetically associated with o2 and o7, two recessive alleles of other zein regulatory loci. Protein b-70 is located on the membrane of the protein body where zein polypeptides accumulate. The existence of a functional relationship between this protein and the zein-secretory system is suggested or, as an alternative, that b-70 is a type of storage protein different from zeins, repressed in normal endosperms and derepressed by the fl2 allele.Abbreviations DAP days after pollination - ER endoplasmic reticulum - RER rough endoplasmic reticulum - DTT dithiothreitol - EDTA ethylene-diamintetra-acetate - NADH nicotinamide-adenine dinucleotide, reduced - PMSF phenylmethylsulfonyl-fluoride - SDS sodium dodecylsulfate - PAGE polyacrylamide gel electrophoresis - PBS phosphate buffered saline (0.15 M NaCl, 0.01 M Na phosphate, pH 6.8)     

Effects of floury-2 locus on zein accumulation and RNA metabolism during maize endosperm development

Zein accumulation patterns during mutant and normal maize endosperm development were determined. Accompanying an increase in the number of floury-2 alleles present in the endosperm was a well-defined stepwise depression in zein accumulation. Analysis of the zein accumulated in endosperms containing zero, one, two, and three doses of the floury-2 allele by sodium dodecylsulfate-polyacrylamide gel electrophoresis revealed a proportionate reduction in the two major zein components, Z1 and Z2. In contrast, the relative proportions of the minor zein bands were altered. Membrane-bound polysomes isolated from kernels of floury-2 and normal maize were predominantly large size classes. The presence of increasing numbers of the floury-2 allele in the endosperm decreased recovery of membrane-bound polysomal material in a stepwise fashion. However, major alterations in polysome size-class distributions were not observed. The reduction in membrane-bound polysome material correlated linearly with reductions in in vitro zein synthesis and in vivo zein accumulation.     

Adenine methylation in zein genes

This paper reports the novel finding of adenine methylation in higher plants. Comparison of restriction patterns of genomic maize DNA digested with enzymes MboI and Sau3A enabled us to detect the existence of adenine methylation in zein genes. Adenine methylation within or around zein genes turned out to be similar in endosperm (where zeins are actively synthesized) and in seedling tissue (where zein genes are not expressed). Furthermore, adenine methylation patterns were found to be similar both in wild-type and opaque-2 mutant plants. These lines of evidence suggest that adenine methylation is unrelated to the regulation of gene expression.     

Sequence variation between alleles reveals two types of copy correction at the 27-kDa zein locus of maize

In many inbred lines of maize, two 27-kDa storage protein (zein) genes are found within tandem duplications of 12 kb. Both genes of the duplicated allele from the maize inbred line A188 were sequenced and compared to a similar duplicated allele in another inbred line, W22, and to a single-copy allele in the inbred line W64A. The comparisons reveal interesting patterns in the distribution of sequence changes between these alleles. Differences between the two duplicated alleles that are conserved between the two genes of each allele are found exclusively in the 5' region. In contrast, differences between the individual genes of each allele in the 3' region are conserved between the two alleles. The first case is indicative of an intraallelic copy correction mechanism, whereas the second may result from interallelic copy correction. These may be mediated by gene conversion processes, as previously described for other multigene families.     

A new allele of the duplicated 27kD zein locus of maize generated by homologous recombination.

The 27kD zein storage protein locus in many inbred lines of maize consists of a tandem duplication of 12kb, with an expressed gene in each repeat, termed A and B. A single-copy allele with only the A gene can be generated from this duplication in particular stocks of the maize inbred line A188 by a mitotic process that includes a crossover at the 3' regions of the two genes (1). Here, we characterize a second single-copy allele with only the B gene, found in different stocks of A188. This allele arises from a homologous recombination at the highly conserved 5' regions of the two repeats, and cloning and sequencing of this allele define the crossover region. The A and B genes in the duplicated allele were previously shown to be expressed at different levels; this difference remains unchanged in either recombinant allele. Therefore, the crossover points of these two recombinant alleles define the borders of cis-acting sequences responsible for the differential expression of the two genes.     

Binding of a nuclear factor to a consensus sequence in the 5' flanking region of zein genes from maize

The genomic organization of the zein structural genes and of regulatory loci influencing their expression suggests that control of zein gene expression will involve interactions between cis elements in the flanking DNA sequences and products from trans-acting genes. The interaction between fragments from the 5' flanking region of a zein gene and specific, double-stranded oligonucleotides with crude nuclear extracts from maize endosperm have been studied by nitrocellulose filter binding, gel retention and DNase I footprinting assays. Specific binding of a nuclear factor was observed and the exact position of the protein binding site was determined. The 22-nt binding site included 14 bp of a 15-bp sequence conserved in all zein genes.     

Localization of zein genes in maize

The band patterns of zein polypeptides were determined for many commercial inbred corn lines and maize stocks using isofocusing in agarose gels and sodium dodecyl sulfate (SDS)-urea gels. Each inbred line or homozygous maize strain genotype has a distinct zein profile which has been catalogued according to the distance of charge migration and molecular weight (kilodaltons). Several zein polypeptides were mapped to chromosomes 4 and 10 with the use of reciprocal translocations. The mapping of at least two polypeptides on distal 4L and 10L had not been previously reported. The general methods used in the present research will permit the mapping of all the zein polypeptides to chromosomal sites.Pioneer Hi-Bred International provided financial support.     

Complementation between uncF alleles affecting assembly of the F1F0-ATPase complex of Escherichia coli.

A mutant affected in the b subunit (coded by the uncF gene) of the F1F0-ATPase in Escherichia coli was isolated by a localized mutagenesis procedure in which a plasmid carrying the unc genes was mutagenized in vivo. The biochemical properties of cells carrying the uncF515 allele were examined in a strain carrying the allele on a multicopy plasmid and a mutator-induced polar unc mutation on the chromosome. The strain carrying the mutant unc allele was uncoupled with respect to oxidative phosphorylation. Membrane-bound ATPase activity was very low or absent, and membranes were somewhat proton permeable. It was concluded that the F0 sector was assembled. Determination of the DNA sequence of the uncF515 allele showed it differed from wild type in that a G----A substitution occurred at position 392, resulting in glycine being replaced by aspartate at position 131. Genetic complementation tests indicated that the uncF515 allele complemented the uncF476 allele (Gly 9----Asp). Two-dimensional gel electrophoresis of membrane preparations indicated that the uncF515 and uncF476 alleles interrupted assembly of the F1F0-ATPase at different stages.     

Kernel lysine content does not increase in some maize opaque2 mutants

The recessive mutant allele of the opaque2 gene (o2) alters the endosperm protein pattern and increases the kernel lysine content of maize (Zea mays L.). In this study, sequencing results showed that the o2 mutant was successfully introgressed into 12 elite normal maize inbred lines by marker assisted selection (MAS). The average genetic similarity between these normal inbred lines and their o2 near-isogenic lines (NILs) was more than 95%. Kernel lysine content increased significantly in most of o2 NILs lines relative to normal elite inbreds, but remained unchanged in the genetic backgrounds Dan598o2 and Liao2345o2. Moreover, the kernel characteristics of these two o2 NILs did not differ from the other inbred lines. The results of lysine content analysis in the F1 hybrids between Liao2345o2 and Dan598o2 and other o2 NILs demonstrated that gene(s) other than opaque2 may control kernel lysine content in these two o2 NILs. The results of zein analysis showed that 22-kD α-zein synthesis was reduced or absent, and the 19-kD α-zein synthesis was greatly reduced compared with the recurrent parents in most o2 NILs except for Dan598o2 and Liao2345o2. Our results indicate that gene(s) other than opaque2 may play more important roles in zein synthesis and kernel lysine content in some maize genetic backgrounds.     

Identification of opaque-2 genotypes in segregating populations of Quality Protein Maize by analysis of restriction fragment length polymorphisms

Quality Protein Maize (QPM) is a name given to genetically modified opaque-2 maize with hard endosperm. The opaque-2 mutation conditions a reduction in the amount of zein seed storage protein; zeins are deficient in the essential amino acids lysine and tryptophan, and mutant seed have a higher nutritional value. To utilize the potential of opaque-2 maize, elite inbreds can be converted to o2/o2 forms and subsequently to hard endosperm opaque-2. Since opaque-2 is recessive and endosperm specific, conventional backcross procedures to convert elite inbreds to opaque-2 forms are inefficient. To alleviate this problem, a marker-assisted selection procedure was developed for the Texas A&M University Quality Protein Maize breeding program. Hybridization of an O2 cDNA probe to blots of DNA from plants carrying O2 and o2 alleles showed that restriction fragment length polymorphisms (RFLPs) exist between the W64A o2 allele and O2 alleles of Mo17 and TX5855 inbred lines. To identify the opaque2 genotypes in segregating populations, an RFLP marker assay combining the O2 cDNA probe and HindIII-digestion of genomic DNA was developed. The effectiveness of the O2 RFLP marker assay was tested under field conditions using F₂ and backcross populations of several hard endosperm opaque-2 lines. A comparison of the genotypes identified by RFLP analysis with the seed phenotypes of the next generation indicated that this procedure is accurate and can be used for identifying O2/O2, O2/o2, and o2/o2 genotypes of individual juvenile plants in breeding populations.