A defective signal peptide in a 19-kD alpha-zein protein causes the unfolded protein response and an opaque endosperm phenotype in the maize De*-B30 mutant

Defective endosperm* (De*)-B30 is a dominant maize (Zea mays) mutation that depresses zein synthesis in the developing endosperm. The mutant kernels have an opaque, starchy phenotype, malformed zein protein bodies, and highly increased levels of binding protein and other chaperone proteins in the endosperm. Immunoblotting revealed a novel alpha-zein protein in De*-B30 that migrates between the 22- and 19-kD alpha-zein bands. Because the De*-B30 mutation maps in a cluster of 19-kD alpha-zein genes, we characterized cDNA clones encoding these proteins from a developing endosperm library. This led to the identification of a 19-kD alpha-zein cDNA in which proline replaces serine at the 15th position of the signal peptide. Although the corresponding gene does not appear to be highly expressed in De*-B30, it was found to be tightly linked with the mutant phenotype in a segregating F2 population. Furthermore, when the protein was synthesized in yeast cells, the signal peptide appeared to be less efficiently processed than when serine replaced proline. To test whether this gene is responsible for the De*-B30 mutation, transgenic maize plants expressing this sequence were created. T1 seeds originating from the transformants manifested an opaque kernel phenotype with enhanced levels of binding protein in the endosperm, similar to De*-B30. These results are consistent with the hypothesis that the De*-B30 mutation causes a defective signal peptide in a 19-kD alpha-zein protein.     

A defective signal peptide tethers the floury-2 zein to the endoplasmic reticulum membrane.

The maize (Zea mays L.) floury-2 (fl2) mutation is associated with a general decrease in storage protein synthesis, altered protein body morphology, and the synthesis of a novel 24-kD alpha-zein storage protein. Unlike storage proteins in normal kernels and the majority of storage proteins in fl2 kernels, the 24-kD alpha-zein contains a signal peptide that would normally be removed during protein synthesis and processing. The expected processing site of this alpha-zein reveals a putative mutation alanine-->valine (Ala-->Val) that is not found at other junctions between signal sequences and mature proteins. To investigate the impact of such a mutation on signal peptide cleavage, we have assayed the 24-kD fl2 alpha-zein in a co-translational processing system in vitro. Translation of RNA from fl2 kernels or synthetic RNA encoding the fl2 alpha-zein in the presence of microsomes yielded a 24-kD polypeptide. A normal signal peptide sequence, generated by site-directed mutagenesis, restored the capacity of the RNA to direct synthesis of a properly processed protein in a cell-free system. Both the fl2 alpha-zein and the fl2 alpha-zein (Val-->Ala) were translocated into the lumen of the endoplasmic reticulum. The processed fl2 alpha-zein (Val-->Ala) was localized in the soluble portion of the microsomes, whereas the fl2 alpha-zein co-fractionated with the microsomal membranes. By remaining anchored to protein body membranes during endosperm maturation, the fl2 zein may thus constrain storage protein packing and perturb protein body morphology.     

The maize gamma-zein sequesters alpha-zein and stabilizes its accumulation in protein bodies of transgenic tobacco endosperm.

Zeins are seed storage proteins that form accretions called protein bodies in the rough endoplasmic reticulum of maize endosperm cells. Four types of zeins, alpha, beta, gamma, and delta, aggregate in a distinctive spatial pattern within the protein body. We created transgenic tobacco plants expressing alpha-zein, gamma-zein, or both to examine the interactions between these proteins leading to the formation of protein bodies in the endosperm. Whereas gamma-zein accumulated in seeds of these plants, stable accumulation of alpha-zein required simultaneous synthesis of gamma-zein. The zein proteins formed accretions in the endoplasmic reticulum similar to those in maize endosperm. Protein bodies were also found in protein storage vacuoles. The accumulation of both types of zeins peaked early in development and declined during maturation. Even in the presence of gamma-zein, there was a turnover of alpha-zein, suggesting that the interaction between the two proteins might be transitory. We suggest that gamma-zein plays an important role in protein body formation and demonstrate the utility of tobacco for studying interactions between different zeins.     

The accumulation of alpha-zein in transgenic tobacco endosperm is stabilized by co-expression of beta-zein

The cysteine-poor alpha-zein is the major prolamin storage protein fraction in maize endosperm and is localized in the interior of protein bodies with delta-zein, whereas the hydrophobic cysteine-rich beta- and gamma-zein are found on the exterior of the PB. In transgenic tobacco endosperm expressing zein genes, alpha-zein was unstable unless co-expressed with gamma-zein. Here we showed that alpha-zein was also stabilized by beta-zein. Small accretions of alpha- and beta-zeins, similar in appearance to maize protein bodies, were localized to the endoplasmic reticulum within tobacco endosperm cells. The zein proteins were also localized to protein storage vacuoles in a more dispersed pattern, suggesting that they were transported there after they were post-translationally sequestered into the ER.     

Quantitative trait locus mapping of loci influencing elongation factor 1alpha content in maize endosperm

The nutritional value of maize (Zea mays) seed is most limited by its protein quality because its storage proteins are devoid of the essential amino acid lysine (Lys). The Lys content of the kernel can be significantly increased by the opaque-2 mutation, which reduces zein synthesis and increases accumulation of proteins that contain Lys. Elongation factor 1alpha (eEF1A) is one of these proteins, and its concentration is highly correlated with the Lys content of the endosperm. We investigated the genetic regulation of eEF1A and the basis for its relationship with other Lys-containing proteins by analyzing the progeny of a cross between a high (Oh51Ao2) and a low (Oh545o2) eEF1A maize inbred. We identified 83 simple sequence repeat loci that are polymorphic between these inbreds; the markers are broadly distributed over the genome (1,402 cM) with an average interval of 17 cM. Genotypic analysis of the F(2) progeny revealed two significant quantitative trait loci that account for 25% of the variance for eEF1A content. One of these is on the short arm of chromosome 4 and is linked with a cluster of 22-kD alpha-zein coding sequences; the other quantitative trait locus is on the long arm of chromosome 7. The content of alpha-zein and gamma-zein was measured in pools of high- and low-eEF1A individuals obtained from this cross, and a higher level of alpha-zein was found to cosegregate with high eEF1A content. Allelic variation at the 22-kD alpha-zein locus may contribute to the difference of eEF1A content between Oh51Ao2 and Oh545o2 by increasing the surface area of protein bodies in the endosperm and creating a more extensive network of cytoskeletal proteins.     

Asymmetric localization of seed storage protein RNAs to distinct subdomains of the endoplasmic reticulum in developing maize endosperm cells

Plant storage proteins are synthesized and stored in different compartments of the plant endomembrane system. Developing maize seeds synthesize and accumulate prolamin (zein) and 11S globulin (legumin-1) type proteins, which are sequestered in the endoplasmic reticulum (ER) lumen and storage vacuoles, respectively. Immunofluorescence studies showed that the lumenal chaperone BiP was not randomly distributed within the ER in developing maize endosperm but concentrated within the zein-containing protein bodies. Analysis of the spatial distribution of RNAs in maize endosperm sections by in situ RT-PCR showed that, contrary to the conclusions made in an earlier study [Kim et al. (2002) Plant Cell 14: 655-672], the zein and legumin-1 RNAs are not symmetrically distributed on the ER but, instead, targeted to specific ER subdomains. RNAs coding for 22 kDa alpha-zein, 15 kDa beta-zein, 27 kDa gamma-zein and 10 kDa delta-zein were localized to ER-bounded zein protein bodies, whereas 51 kDa legumin-1 RNAs were distributed on adjacent cisternal ER proximal to the zein protein bodies. These results indicate that the maize storage protein RNAs are targeted to specific ER subdomains in developing maize endosperm and that RNA localization may be a prevalent mechanism to sort proteins within plant cells.     

Increases in binding protein (BiP) accompany changes in protein body morphology in three high-lysine mutants of maize

Summary A maize 75 kDa protein recently has been identified as a plant homolog of the mammalian binding protein (BiP). To better understand the function of BiP in protein body formation in maize endosperm, immunomicroscopy studies were conducted on three maize endosperm mutants, floury-2, Mucronate, and Defective endosperm-B 30, in which the level of BiP is highly elevated. Our results showed that protein body morphology in all three mutants was altered. In addition, BiP was localized in both the ER and peripheral regions of the abnormal protein bodies. The degree to which protein body morphology differed from normal was positively correlated with increased amounts of BiP. In addition, the accumulation of BiP in abnormal protein bodies increased with protein body maturation. In the three endosperm mutants, the arrangement of zeins within protein bodies had been perturbed, yet none of the specific zein subclasses exhibited the staining pattern found for BiP. The association of BiP with abnormal packaging of proteins in protein bodies may reflect a biological function to mediate protein folding and assembly in maize endosperm.Abbreviations BiP binding protein - BSA bovine serum albumin - De*-B 30 Defective endosperm B 30 - DAP day after pollination - ER endoplasmic reticulum - fl 2 floury-2 - hsp 70 70 kDa heat shock protein - Mc Mucronate - TBST 20mM Tris-HCl, pH8.2 at 20°C, 500mM NaCl, 0.3% Tween 20 - TBST-B TBST with 1% (w/v) BSA     

Changes in the zein composition of protein bodies during maize endosperm development.

Zeins, the seed storage proteins of maize, are synthesized during endosperm development by membrane-bound polyribosomes and transported into the lumen of the endoplasmic reticulum, where they assemble into protein bodies. To better understand the distribution of the various zeins throughout the endosperm, and within protein bodies, we used immunolocalization techniques with light and electron microscopy to study endosperm tissue at 14 days and 18 days after pollination. Protein bodies increase in size with distance from the aleurone layer of the developing endosperm; this reflects a process of cell maturation. The protein bodies within the subaleurone cell layer are the smallest and contain little or no alpha-zein; beta-zein and gamma-zein are distributed throughout these small protein bodies. The protein bodies in cells farther away from the aleurone layer are progressively larger, and immunostaining for alpha-zein occurs over locules in the central region of these protein bodies. In the interior of the largest protein bodies, the locules of alpha-zein are fused. Concomitant with the appearance of alpha-zein in the central regions of the protein bodies, most of the beta- and gamma-zeins become peripheral. These observations are consistent with a model in which specific zeins interact to assemble the storage proteins into a protein body.     

Regulation of maize lysine metabolism and endosperm protein synthesis by opaque and floury mutations.

The capacity of two maize opaque endosperm mutants (o1 and o2) and two floury (fl1 and fl2) to accumulate lysine in the seed in relation to their wild type counterparts Oh43+ was examined. The highest total lysine content was 3.78% in the o2 mutant and the lowest 1.87% in fl1, as compared with the wild type (1.49%). For soluble lysine, o2 exhibited over a 700% increase, whilst for fl3 a 28% decrease was encountered, as compared with the wild type. In order to understand the mechanisms causing these large variations in both total and soluble lysine content, a quantitative and qualitative study of the N constituents of the endosperm has been carried out and data obtained for the total protein, nonprotein N, soluble amino acids, albumins/globulins, zeins and glutelins present in the seed of the mutants. Following two-dimensional PAGE separation, a total of 35 different forms of zein polypeptides were detected and considerable differences were noted between the five different lines. In addition, two enzymes of the aspartate biosynthetic pathway, aspartate kinase and homoserine dehydrogenase were analyzed with respect to feedback inhibition by lysine and threonine. The activities of the enzymes lysine 2-oxoglutate reductase and saccharopine dehydrogenase, both involved in lysine degradation in the maize endosperm were also determined and shown to be reduced several fold with the introduction of the o2, fl1 and fl2 mutations in the Oh43+ inbred line, whereas wild-type activity levels were verified in the Oh43o1 mutant.     

Expression of protein disulfide isomerase is elevated in the endosperm of the maize floury-2 mutant

A maize protein disulfide isomerase (PDI, EC 5.3.4.1) cDNA clone was isolated and characterized. The deduced amino acid sequence contains two regions characteristic of the active sites for PDI and a carboxyl-terminal endoplasmic reticulum (ER) retention sequence, Lys-Asp-Glu-Leu. Southern blot analysis indicated the maize PDI is encoded by a single gene that maps to the short arm of chromosome 4. When isolated from the cisternal and protein body ER, the PDI protein resolves into a fast and a slow form on SDS-PAGE. During endosperm development, the PDI RNA level increases between 10 and 14 days after pollination. In floury-2 (fl2) endosperm, which contains an abnormally processed -zein protein, PDI expression is significantly increased, and the level of PDI protein and RNA is positively correlated with the dosage of fl2 alleles. The increase of PDI in fl2 occurs mainly in the cisternal ER fraction, whereas the most dramatic increase of binding protein (BiP) is in the protein body ER. We propose that the induction of PDI in the fl2 mutant reflects its role as a molecular chaperone, and that PDI functions in concert with BiP at different stages of zein processing and assembly into protein bodies.     

A new opaque variant of maize by a single dominant RNA-interference-inducing transgene

In maize, alpha-zeins, the main protein components of seed stores, are major determinants of nutritional imbalance when maize is used as the sole food source. Mutations like opaque-2 (o2) are used in breeding varieties with improved nutritional quality. However, o2 works in a recessive fashion by affecting the expression of a subset of 22-kD alpha-zeins, as well as additional endosperm gene functions. Thus, we sought a dominant mutation that could suppress the storage protein genes without interrupting O2 synthesis. We found that maize transformed with RNA interference (RNAi) constructs derived from a 22-kD zein gene could produce a dominant opaque phenotype. This phenotype segregates in a normal Mendelian fashion and eliminates 22-kD zeins without affecting the accumulation of other zein proteins. A system for regulated transgene expression generating antisense RNA also reduced the expression of 22-kD zein genes, but failed to give an opaque phenotype. Therefore, it appears that small interfering RNAs not only may play an important regulatory role during plant development, but also are effective genetic tools for dissecting the function of gene families. Since the dominant phenotype is also correlated with increased lysine content, the new mutant illustrates an approach for creating more nutritious crop plants.     

Increased expression of the maize immunoglobulin binding protein homolog b-70 in three zein regulatory mutants.

Plants carrying floury-2, Defective endosperm-B30, or Mucronate mutations overproduce b-70, a maize homolog of the mammalian immunoglobulin binding protein. During endosperm development in these mutants, levels of both b-70 protein and RNA increase dramatically between 14 days and 20 days after pollination. At later stages, b-70 RNA levels decline while protein levels remain high. The increase in b-70 RNA levels is endosperm specific and dependent on gene dosage in the floury-2 mutant. In all three mutants, the increases in b-70 RNA and protein levels are inversely proportional to changes in zein synthesis. Although b-70 polypeptides can be extracted from purified protein bodies, they carry a carboxy-terminal endoplasmic reticulum retention signal, HDEL. We propose that induction of b-70 in these mutants is a cellular response to abnormally folded or improperly assembled storage proteins and probably reflects its role as a polypeptide chain binding protein.