Mucronate, Mc, a dominant gene of maize which interacts with opaque-2 to suppress zein synthesis

The Zea mays mutants opaque2 and opaque16 disclose lysine change in waxy maize as revealed by RNA-Seq

In maize, opaque2 (o2) and opaque16 (o16) alleles can increase lysine content, while the waxy (wx) gene can enhance the amylopectin content of grains. In our study, o2 and o16 alleles were backcrossed into waxy maize line (wxwx). The o2o2o16o16wxwx lines had amylopectin contents similar to those of waxy line. Their nutritional value was better than waxy line, but the mechanism by which the o2 and o16 alleles increased the lysine content of waxy maize remained unclear. The o2o2o16o16wxwx lines and their parents on kernels (18th day after pollination) were subjected to RNA sequencing (RNA-Seq). The RNA-Seq analysis revealed 272 differentially expressed genes (DEGs). Functional analyses revealed that these DEGs were mainly related to biomass metabolism. Among them, in o2o2o16o16wxwx lines, 15 genes encoding α-zein were down-regulated, which resulted in the reduction of α-zein synthesis and increased lysine content; lkr/sdh1 and Zm00001d020984.1 genes involved in the lysine degradation pathway were down-regulated, thereby inhibited lysine degradation; sh2, bt2 and ae1 genes involved in starch metabolism were upregulated, leaded to wrinkling kernel and farinaceous endosperm. Our transcriptional-level identification of key genes responsible for increased grain lysine content and farinaceous endosperm formation following introgression of o2 and o16 alleles should promote molecular breeding for maize quality.

Transcriptome Dynamics of Double Recessive Mutant, o2o2o16o16, Reveals the Transcriptional Mechanisms in the Increase of Its Lysine and Tryptophan Content in Maize

In maize, pyramiding of o2 and o16 alleles can greatly improve the nutritional quality of grains. To dissect its molecular mechanism, we created a double recessive mutant line, o2o2o16o16, by introgression of the o2 and o16 alleles into the wild-type maize inbred line, by molecular marker-assisted backcross selection. The kernels (18 day after pollination (DAP), 28 DAP, and 38 DAP) of the o2o2o16o16 mutant and its parent lines were subject to RNA sequencing (RNA-Seq). The RNA-Seq analysis revealed that 59 differentially expressed genes (DEGs) were involved in lysine metabolism and 43 DEGs were involved in tryptophan metabolism. Among them, the genes encoding AK, ASADH, and Dap-F in the lysine synthesis pathway were upregulated at different stages of endosperm development, promoting the synthesis of lysine. Meanwhile, the genes encoding LKR/SDH and L-PO in the lysine degradation pathway were downregulated, inhibiting the degradation of lysine. Moreover, the genes encoding TAA and YUC in the tryptophan metabolic pathway were downregulated, restraining the degradation of tryptophan. Thus, pyramiding o2 and o16 alleles could increase the lysine and tryptophan content in maize. These above results would help to uncover the molecular mechanisms involved in the increase in lysine and the tryptophan content, through the introgression of o2 and o16 alleles into the wild-type maize.

Maize 16-kD γ-zein forms very unusual disulfide-bonded polymers in the endoplasmic reticulum: implications for prolamin evolution

In the lumen of the endoplasmic reticulum (ER), prolamin storage proteins of cereal seeds form very large, ordered heteropolymers termed protein bodies (PBs), which are insoluble unless treated with alcohol or reducing agents. In maize PBs, 16-kD γ-zein locates at the interface between a core of alcohol-soluble α-zeins and the outermost layer mainly composed of the reduced-soluble 27-kD γ-zein. 16-kD γ-zein originates from 27-kD γ-zein upon whole-genome duplication and is mainly characterized by deletions in the N-terminal domain that eliminate most Pro-rich repeats and part of the Cys residues involved in inter-chain bonds. 27-kD γ-zein also forms insoluble PBs when expressed in transgenic vegetative tissues. We show that in Arabidopsis leaves, 16-kD γ-zein assembles into disulfide-linked polymers that fail to efficiently become insoluble. Instead of forming PBs, these polymers accumulate as very unusual threads that markedly enlarge the ER lumen, resembling amyloid-like fibers. Domain-swapping between the two γ-zeins indicates that the N-terminal region of 16-kD γ-zein has a dominant effect in preventing full insolubilization. Therefore, a newly evolved prolamin has lost the ability to form homotypic PBs, and has acquired a new function in the assembly of natural, heteropolymeric PBs.

Molecular mapping of the shrunken endosperm genes seg8 and sex1 in barley (Hordeum vulgare L.)

A number of mutations affecting seed development in barley (Hordeum vulgare L.) have been known for many years; however, to date, no research has been reported that elucidates the molecular structure of the causal genes. As a first step, we initiated the linkage mapping of the two shrunken endosperm genes seg8 and sex1 using microsatellite markers. The recessive gene seg8 was mapped in the centromeric region of chromosome 7H to a 4.6 cM interval flanked by markers GBM1516 and Bmag341. The recessive sex1 gene showed xenia effects and was located in the centromeric region of barley chromosome 6H, which is in accordance to the previously reported chromosomal location in the classical linkage map. It was flanked by markers GBM5012 and GBM1063 in a 4.2 cM interval. EST-derived microsatellite markers were used to establish the syntenic relationships to the genomic rice sequences. Two orthologous sites on rice chromosome 2 flanking a 4.1 Mb sequence had homology to the respective barley markers in the sex1 region. For the markers in the seg8 region orthologous sites on rice chromosome 6 were detected.

The maize Mucronate mutation is a deletion in the 16-kDa gamma-zein gene that induces the unfolded protein response

Mucronate (Mc) was identified as a dominant maize (Zea mays L.) opaque kernel mutation that alters zein storage protein synthesis. Zein protein bodies in Mc endosperm are misshapen and are associated with increased levels of ER Lumenal Binding Protein (BiP). Using GeneCalling to profile endosperm RNA transcripts, we identified an aberrant RNA in Mc that encodes the 16-kDa gamma-zein protein. The transcript contains a 38-bp deletion (nucleotides 406-444 after the initiation codon) that creates a frame-shift mutation and an abnormal sequence for the last 63 amino acids. Genetic mapping revealed the Mc mutation is linked with the locus encoding the 16-kDa gamma-zein, and two-dimensional gel electrophoresis confirmed the 16-kDa gamma-zein protein is altered in Mc. The mutant protein exhibited changes in solubility properties and co-immunoprecipitated with the molecular chaperone, BiP. Transgenic maize plants expressing the Mc 16-kDa gamma-zein manifested an opaque kernel phenotype with enhanced levels of BiP in the endosperm, similar to the Mc mutant. Unlike the wild-type protein, the Mc 16-kDa gamma-zein interacted only weakly with the 22-kDa alpha-zein when expressed in the yeast two-hybrid system. These results indicate that the Mc phenotype results from a frame-shift mutation in the gene encoding the 16-kDa gamma-zein protein, leading to the unfolded protein response in developing endosperm.

Effect of the opaque and floury mutations on the accumulation of dry matter and protein fractions in maize endosperm

Grains of nine opaque (o) and floury (fl) mutants of maize (Oh43o1, Oh43o2, B79o5, B37o7, W22o10, W22o11, W22o13, Oh43fl1 and Oh43fl2) were examined for the weight proportions of their component tissues and the content of eight nitrogen fractions in their endosperms. A linear regression was found connecting the amounts (mg per endosperm) of zeins and true proteins (crude proteins minus non-protein nitrogen) for the non-opaque2 mutants. The data points connecting zeins to true proteins present in the mature endosperms of six wild-type (+) inbred lines and their o2 versions were located outside (+) or within (o2) the 95% confidence range of the regression line. The data obtained from the developing and mature endosperms of the W22o7 inbred line (Di Fonzo et al., Plant Sci. Lett., 1979, 77) and the floury portion of mature endosperms of three other wild-type inbred lines fell practically on the regression line. The effects of genotype and environmental factors upon the relative accumulation rate of zeins were assessed from the present results and the data taken from the literature concerning the quantitative interdependence between zeins and true proteins in immature and mature endosperms.

Matrix-assisted laser desorption ionization time-of-flight mass spectrometry analysis of zeins in mature maize kernels

A high-throughput method has been developed to allow rapid analysis of maize seed storage proteins by matrix-assisted laser desorption time-of-flight mass spectrometry. The extraction solution containing an organic solvent, a reducing agent, and a volatile base has been optimized to enable extraction of all classes of zein proteins (alpha-, beta-, gamma-, and delta-). A near-saturating concentration of matrix, 2-(4-hydroxyphenylazo)benzoic acid, was necessary to obtain strong peaks for the most lipophilic zeins, the alpha-zeins. Zein proteins with small mass differences, difficult to separate by sodium dodecyl sulfate polyacrylamide gel electrophoresis, were resolved through this analysis. Mass signals corresponding to the 10-kDa delta-, 15-kDa beta-, 16-kDa gamma-, 27-kDa gamma-, and several 19 and 22-kDa alpha-zeins were detected. The zein identities were further confirmed by the association of the number of cysteine residues in each zein MS peak, as determined by iodoacetamide derivatization, with the number predicted from its coding sequence. The relative zein abundance in the zein MS peaks was also correlated with the relative zein EST abundance among endosperm EST libraries. This method was utilized to examine the zein composition of a number of corn inbred lines and opaque mutants.

Organization and regulation of zein genes in maize endosperm

Zein, the major storage protein of maize endosperm, is constituted by a group of similar polypeptides encoded by a multigene family. The structural genes are located into three main clusters on chromosomes 4, 7 and 10. The rate of accumulation of zein polypeptides is under the control of several positive regulatory loci. The mutant alleles at these loci (O2, O6, O7, F12, De-B30, Mc) reduce more or less drastically the rate of zein deposition. By analysing the interactions among the mutants, epistatic, additive and synergistic effects were observed indicating the existence of multiple pathways controlling zein deposition. Proteins, other than zeins, associated with theO2, O6andF12loci have been identified and characterized.

A rice (Oryza sativa L.) mutant having a low content of glutelin and a high content of prolamine

Among the mutant lines of rice that have been selected for morphological characters, one line, NM67, was found to have a low content of glutelin and a higher content of prolamine in its seed protein than other Japanese cultivars. This mutant is a semi-dwarf and partially sterile line, and its leaves turn yellow before heading. Genetic analysis after backcross to the original cultivar, 'Nihonmasari', revealed the following: (1) the character of low glutelin content was always accompanied by the character of high prolamine content; (2) the low glutelin (and high prolamine) character seemed to be manifested by a single dominant gene; and (3) semi-dwarfness, low fertility and early yellowing leaf of the mutant, which might also be pleiotropy, were controlled by a single recessive gene independent of the gene for protein content. The protein character of NM67 was genetically separated from semi-dwarfness and low fertility, and a new line having low glutelin content and high prolamine content with normal morphological characters comparable to those of the original cultivar was obtained from the progenies of the cross. The possible use of this line as a low protein rice cultivar is discussed.

Expression of alcohol-soluble endosperm proteins in maize single and double mutants

Many maize (Zea mays L.) mutant genes exist. Some affect protein content or composition, while others modify carbohydrates or kernel phenotype. In doublemutant lines, two mutant genes are present. We know little about interactions of such genes, however. We therefore examined a normal maize inbred, B37, 10 near-isogenic single mutants and 46 double mutants to analyze quantitative effects on alcohol-soluble endosperm proteins. Proteins were extracted with 70% ethanol0.5% sodium acetate-5% mercaptoethanol, and fractionated by reversed-phase high-performance liquid chromatography (RP-HPLC). Early peaks were alcohol-soluble glutelin (ASG) subunits, while late peaks contained zein. Results were quantified and statistically analyzed. In many double mutants, protein compositions differed significantly from averages of compositions of corresponding single mutants. For example, a high-methionine, water-insoluble ASG is absent when the opaque-2 (o2) gene combines with shrunken-1 (sh1) or surgary-1 (su1). Another water-insoluble ASG nearly doubled when floury-2 (fl2) andsu1 combined. A high-proline, high-histidine, water-soluble ASG nearly doubled in combinations offl2 witho2,su1 and sugary-2 (su2). Zein was about half its expected value wheno2 combined with amylose-extender (ae), floury-1 (fl1), soft-starch (h),sh1 andsu1. Thus, rapid protein extraction and quantitative RP-HPLC showed major new epistatic and synergistic effects of several mutant genes on protein composition. Unexpectedly, these effects often involve genes that primarily affect starch composition or kernel phenotype. Alcohol-soluble proteins often vary in amount, as ino2 lines. They also differ in nutritional value. Thus, RP-HPLC analysis of these proteins can identify nutritionally superior genotypes, and may help explain the basis of such quality.