Elastin-like polypeptide and γ-zein fusions significantly increase recombinant protein accumulation in soybean seeds

Transgenic Research - Soybean seeds are an ideal host for the production of recombinant proteins because of their high content of proteins, long-term stability of seed proteins under ambient...     

The effect of sulfhydryl groups and disulphide linkage in the thermal aggregation of Z19 α-zein

Zeins are the major storage proteins in corn seeds organized in protein bodies located in the endosperm. They are soluble in alcoholic solution and depict a high tendency to aggregation. The Z19 α-zein aggregates obtained by heating show a particular and interesting temperature-dependent behavior. This work was aimed at determining not only the effect of temperature on the aggregation behavior, but also the effect of the sulfhydryl groups and disulphide bonds on the thermal aggregation process under non-aqueous conditions. Z19 α-zein was chemically modified to obtain different sulfhydryl groups and disulphide-bonds content. Far-UV CD, ANS emission fluorescence, and dynamic light scattering, as well as differential scanning calorimetry, were performed to characterize this protein. Removal of these disulphide-bonds and alkylation of all the sulfhydryl groups in the protein promoted the lowest T_m of 57.36 °C, eliminated aggregation, enhanced protein flexibility, and diminished thermal stability. These results suggest that the disulphide linkage could be the driving force for the Z19 α-zein aggregation.     

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

The α-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 α-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 α-zein super gene family, which might be a common feature for other large gene families. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Lingna Feng and Jia Zhu contributed equally to this work.     

Sequence analysis of linked maize 22 kDa α-zein genes

We have determined the nucleotide sequence of a 7343 bp zein genomic clone (gZ22.8H3) from the maize inbred W64A. Computer-aided analysis of the DNA sequence revealed two contiguous 22 kDa -zein genes. The 5 gene (gZ22.8) encodes a complete polypeptide and contains putative regulatory sequences in both the 5 and 3 flanking regions that are typical of zein genes. In contrast, the 3 gene (gZ22.8) appears to be a pseudogene, because it contains numerous insertions and deletions that would prevent translation of the mRNA. Alignment of the 5 and 3 flanking sequences of both genes indicated that they resulted from a 3.3 kb DNA duplication event.     

A maize α-zein promoter drives an endosperm-specific expression of transgene in rice

An alpha-zein promoter isolated from maize containing P-box, E motif sequence TGTAAAGT, opaque-2 box and TATA box was studied for its tissue-specific expression in rice. A 1,098 bp promoter region of alpha-zein gene, fused to the upstream of gusA reporter gene was used for transforming rice immature embryos (ASD 16 or IR 64) via the particle bombardment-mediated method. PCR analysis of putative transformants demonstrated the presence of transgenes (the zein promoter, gusA and hpt). Nineteen out of 37 and two out of five events generated from ASD 16 and IR 64 were found to be GUS-positive. A histological staining analysis performed on sections of mature T₁ seeds revealed that the GUS expression was limited to the endosperm and not to the pericarp or the endothelial region. GUS expression was observed only in the following seed development stages : milky (14–15 DAF), soft dough (17–18 DAF), hard dough (20–23 DAF), and mature stages (28–30 DAF) of zein-gusA transformed (T₀) plants. On the contrary a constitutive expression of GUS was evident in CaMV35S-gusA plants. PCR and Southern blotting analyses on T₁ plants demonstrated a stable integration and inheritance of transgene in the subsequent T₁ generation. GUS assay on T₂ seeds revealed that the expression of gusA gene driven by alpha-zein promoter was stable and tissue-specific over two generations. Results suggest that this alpha-zein promoter could serve as an alternative promoter to drive endosperm-specific expression of transgenes in rice and other cereal transformation experiments.     

An immunodominant site of γ-zein1 is in the region of tandem hexapeptide repeats

The immunochemical data from studies with polyclonal antisera to γ-zein₁, the 27 kD component of the maize prolamin, indicated that the region containing 8 tandem repeats of the sequence PPPVHL is an immunodominant site. In one case, the entire antibody repertoire of an antiserum recognized epitope(s) within this region. Three 17-mer oligopeptides corresponding to the predicted antigenic epitopes of γ-zein₁ were synthesized and reacted with three different anti-γ-zein₁ sera in order to map antigenic sites in the intact protein. These antisera yielded positive reactions with a 17-mer peptide (peptide 37), which was not in a hydrophilic maximum but derived from the repeat region. The same antisera gave little or no reaction with other peptides (peptides 38 and 39), both of which were in a hydrophilic maximum. In addition, an antiserum to peptide 37 reacted strongly with both the homologous antigen and the intact γ-zein₁. Peptide 37 also blocked the binding of antisera to γ-zein₁ in competition assays. Subsequently, the shorter 6-mer (peptide 82) and 12-mer (peptide 80) versions of peptide 37 were synthesized, and both reacted with anti-peptide 37 serum and also with each of the three anti-γ-zein₁ sera. In these reactions and in competition assays, the reactivity and the blocking ability increased in proportion to the length of the peptide. Based on these data, it was concluded that the repeat region of γ-zein₁ is the site of one or more continuous immunodominant epitopes. The data also suggest that the repeat region is exposed on the surface of the folded protein and probably occur as a mobile, random coil.     

Molecular characterization of two types of 22 kilodalton α-zein genes in a gene cluster in maize

Summary Five genes of the -zein subfamily four (SF4) are located in a 56 kb genomic region of the maize inbred line W22. Their nucleotide and deduced amino acid sequences have been determined. The sequences define two types of -zein SF4 genes — type 1 (T1) and type 2 (T2). The single T1 -zein SF4 gene codes for an -zein protein with a M_r of about 22 000. This is the first -zein SF4 gene sequenced that contains no early in-frame stop codons in its coding sequence. The four T2 -zein SF4 genes in this cluster contain one or two early in-frame stop codons. In addition, our T1 and T2 genes differ markedly in the base sequences of their distal 5 non-translated flanking regions. The nucleotide and the deduced amino acid sequences of these two types of -zein SF4 genes are similar ( > 90 %) to one another and to all known -zein SF4 genes and cDNAs. Of the known W22 -zein SF4 genes, only one in six does not contain an early in-frame stop codon. If the number of -zein SF4 genes is 15–20, then we estimate that only about 4 of the W22 -zein SF4 genes are without in-frame early stop codons.     

The maize α-zein promoter can be utilized as a strong inducer of cellulase enzyme expression in maize kernels

Transgenic Research - Expression of recombinant proteins in plants is a technology for producing vaccines, pharmaceuticals and industrial enzymes. For the past several years, we have produced...     

Improving the accumulation of recombinant human serum albumin (HSA) in transgenic tobacco plants by fusion with the N-terminal proline-rich domain of γ-zein (Zera)

In Vitro Cellular & Developmental Biology - Plant - Plants have long played a major role in human health as a source of herbal remedies. Recently, transgenic plants have become convenient...     

Syntheses and spectroscopic properties of α- and β-phosphatidylcholines and phosphatidylethanolamines

The widely used partial synthesis of phospholipids via deacylation of naturally occurring phospholipids, followed by reacylation with fatty acid anhydrides, is accompanied by phosphoryl migration. The resulting mixture of α- and β-phospholipids was separated by short-column chromatography. Milder acylation procedures in which no phosphoryl migration occurs, were developed. 1,2-Dilinoleoyl-sn-glycero-3-phosphocholine was prepared in 50% yield by acylation of sn-glycero-3-phosphocholine (GPC) with N-linoleoylimidazole. Detailed NMR and infrared spectra of α- and β-phosphatidylcholines (PCs) and -ethanolamines (PEs) are reported and the differences between isomers discussed.     

Phenotypic plasticity and longevity in plants and animals: cause and effect?

Immobile plants and immobile modular animals outlive unitary animals. This paper discusses competing but not necessarily mutually exclusive theories to explain this extreme longevity, especially from the perspective of phenotypic plasticity. Stem cell immortality, vascular autonomy, and epicormic branching are some important features of the phenotypic plasticity of plants that contribute to their longevity. Monocarpy versus polycarpy can also influence the kind of senescent processes experienced by plants. How density-dependent phenomena affecting the establishment of juveniles in these immobile organisms can influence the evolution of senescence, and consequently longevity, is reviewed and discussed. Whether climate change scenarios will favour long-lived or short-lived organisms, with their attendant levels of plasticity, is also presented.     

Dogmatisms and Catechisms — Ethics and Companion Animals

Abstract

The current reconsideration of the place in nature of human beings unfortunately continues to be an acrimonious one. All too often the debate is more akin to a warlike encounter where each side attempts to gain control or the upper hand than a search for points of agreement. Given this context, it is important to entertain views that emanate from different cultural traditions as a way to infuse the debate with new life. Students of Native American culture have consistently pointed out that the essential concepts of life balance and reciprocity represented there may serve as useful points of consideration as we struggle with the appropriate relationships with animals and nature. This article presents a representative Zuni story, told by Governor Robert E. Lewis, that illustrates these notions.