Heterogeneity of zein mRNA and protein in maize

Zein, the prolamine fraction of maize, is localized in the endosperm in membrane-bound structures called protein bodies, which have polyribosomes on their surfaces. These polysomes or the mRNA fraction isolated from them will direct the synthesis of zein-like proteins in vitro. The in vitro products consist primarily of two molecular weight classes but show considerable charge heterogeneity when analyzed by isoelectric focusing. Although the molecular weight classes are very similar for different inbred lines, the isoelectric focusing patterns differ.Results given here suggest that the extensive charge heterogeneity of zein proteins does not result from the presence of a large number of totally distinct mRNAs. Zein proteins synthesized in vitro fall into several families related by sequence homologies in their mRNAs. In Illinois High Protein (IHP) the major zein mRNAs can be classified into three families based on their binding to cloned complimentary DNA copies of IHP zein mRNA. Each of three other lines we have studied (W22, Oh43, and W64A) has zein mRNAs that are related to those of IHP. Among these four lines the molecular weights of the members of a given family are generally similar, but the number of members in a family and their isoelectric points differ.     

Genome level analysis of rice mRNA 3'-end processing signals and alternative polyadenylation

The position of a poly(A) site of eukaryotic mRNA is determined by sequence signals in pre-mRNA and a group of polyadenylation factors. To reveal rice poly(A) signals at a genome level, we constructed a dataset of 55 742 authenticated poly(A) sites and characterized the poly(A) signals. This resulted in identifying the typical tripartite cis-elements, including FUE, NUE and CE, as previously observed in Arabidopsis. The average size of the 3′-UTR was 289 nucleotides. When mapped to the genome, however, 15% of these poly(A) sites were found to be located in the currently annotated intergenic regions. Moreover, an extensive alternative polyadenylation profile was evident where 50% of the genes analyzed had more than one unique poly(A) site (excluding microheterogeneity sites), and 13% had four or more poly(A) sites. About 4% of the analyzed genes possessed alternative poly(A) sites at their introns, 5′-UTRs, or protein coding regions. The authenticity of these alternative poly(A) sites was partially confirmed using MPSS data. Analysis of nucleotide profile and signal patterns indicated that there may be a different set of poly(A) signals for those poly(A) sites found in the coding regions. Based on the features of rice poly(A) signals, an updated algorithm termed PASS-Rice was designed to predict poly(A) sites.     

Increased sulfur amino acids in soybean plants overexpressing the maize 15 kDa zein protein

Summary Four transgenic soybean [Glycine max (L.) Merrill] lines were generated containing the maize 15 kDa zein protein gene using somatic embryogenic protocols. The zein gene was inserted behind the β-phaseolin promoter for seed-specific expression. All four lines represent separate transformation events as they were generated in different experiments at different locations. Two of the transformation events produced multiple plants, and these produced identical Southern hybridization patterns (UKY/Z1, UKY/Z2 and UKY/Z3 from the first; and OSU/Z4, OSU/Z8 and OSU/Z10 from the second). Molecular characterization revealed that multiple copies of the zein gene were present in all of the transgenic lines. Immunoblot analysis confirmed the accumulation of the zein protein product in the seeds of the UKY/Z1, UKY/Z2, UKY/Z3, OSU/Z4, OSU/Z8 and OSU/Z10 transgenic lines. However, there was no accumulation of zein protein in the UGA/Z1 line and Northern analysis confirmed that the zein transgene was silenced in this line. It was not possible to analyze the zein expression in the seeds of the UKY/Z4 line, as it was sterile. Amino acid analysis of the UKY and OSU lines confirmed that there was a 12–20% increase in methionine, and 15–35% increase in cysteine content in these lines compared to the control. There were no consistent changes in the content of the other amino acids in the transgenic lines. These results suggest that while the increase in methionine content in these lines is modest, it is possible to increase the methionine content without adversely affecting the protein composition of soybean.     

Kinetic study of the HIV-1 DNA 3'-end processing

The 3'-processing of viral DNA extremities is the first step in the integration process catalysed by human immunodeficiency virus (HIV)-1 integrase (IN). This reaction is relatively inefficient and processed DNAs are usually detected in vitro under conditions of excess enzyme. Despite such experimental conditions, steady-state Michaelis-Menten formalism is often applied to calculate characteristic equilibrium/kinetic constants of IN. We found that the amount of processed product was not significantly affected under conditions of excess DNA substrate, indicating that IN has a limited turnover for DNA cleavage. Therefore, IN works principally in a single-turnover mode and is intrinsically very slow (single-turnover rate constant = 0.004 min(-1)), suggesting that IN activity is mainly limited at the chemistry step or at a stage that precedes chemistry. Moreover, fluorescence experiments showed that IN-DNA product complexes were very stable over the time-course of the reaction. Binding isotherms of IN to DNA substrate and product also indicate tight binding of IN to the reaction product. Therefore, the slow cleavage rate and limited product release prevent or greatly reduce subsequent turnover. Nevertheless, the time-course of product formation approximates to a straight line for 90 min (apparent initial velocity), but we show that this linear phase is due to the slow single-turnover rate constant and does not indicate steady-state multiple turnover. Finally, our data ruled out the possibility that there were large amounts of inactive proteins or dead-end complexes in the assay. Most of complexes initially formed were active although dramatically slow.     

3'-end processing and kinetics of 5'-end joining during retroviral integration in vivo.

Retroviral replication depends on integration of viral DNA into a host cell chromosome. Integration proceeds in three steps: 3'-end processing, the endonucleolytic removal of the two terminal nucleotides from each 3' end of the viral DNA; strand transfer, the joining of the 3' ends of viral DNA to host DNA; and 5'-end joining (or gap repair), the joining of the 5' ends of viral DNA to host DNA. The 5'-end joining step has never been investigated, either for retroviral integration or for any other transposition process. We have developed an assay for 5'-end joining in vivo and have examined the kinetics of 5'-end joining for Moloney murine leukemia virus (MLV). The interval between 3'-end and 5'-end joining is estimated to be less than 1 h. This assay will be a useful tool for examining whether viral or host components mediate 5'-end joining. MLV integrates its DNA only after its host cell has completed mitosis. We show that the extent of 3'-end processing is the same in unsynchronized and aphidicolin-arrested cells. 3'-end processing therefore does not depend on mitosis.     

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.     

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.     

Multiple histone deacetylases and the CREB-binding protein regulate pre-mRNA 3'-end processing

Trichostatin A (TSA), a specific inhibitor of histone deacetylases (HDACs), induces acetylation of various non-histone proteins such as p53 and alpha-tubulin. We purified several acetylated proteins by the affinity to an anti-acetylated lysine (AcLys) antibody from cells treated with TSA and identified them by mass spectrometry. Here we report on acetylation of CFIm25, a component of mammalian cleavage factor Im (CF Im), and poly(A) polymerase (PAP), a polyadenylating enzyme for the pre-mRNA 3'-end. The residues acetylated in these proteins were mapped onto the regions required for interaction with each other. Whereas CBP acetylated these proteins, HDAC1, HDAC3, HDAC10, SIRT1, and SIRT2 were involved in in vivo deacetylation. Acetylation of the CFIm25 occurred depending on the cleavage factor complex formation. Importantly, the interaction between PAP and CF Im complex was decreased by acetylation. We also demonstrated that acetylation of PAP inhibited the nuclear localization of PAP by inhibiting the binding to the importin alpha/beta complex. These results suggest that CBP and HDACs regulate the 3'-end processing machinery and modulate the localization of PAP through the acetylation and deacetylation cycle.     

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.     

Complex organization of zein genes in maize

We have examined the fragments of maize nuclear DNA that are homologous to three cloned cDNAs prepared from zein mRNA. Southern blots of high molecular weight ( > 40 kb) maize nuclear DNA cleaved with BamHI, HindIII or EcoRI were hybridized to three zein cDNA plasmid probes. Multiple restriction fragments in a wide range of size classes were observed to hybridize with all three probes. Our results indicate the occurrence of families of genes in the maize genome that are related by their sequences to a given zein mRNA sequence.     

Sequence requirements of the bidirectional yeast TRP4 mRNA 3'-end formation signal.

The yeast TRP4 3'-end formation signal functions in both orientations in an in vivo test system. We show here that the TRP4 3'-end formation element consists of two functionally different sequence regions. One region of approximately 70 nucleotides is located in the untranslated region between the translational stop codon and the major poly(A) site. The major poly(A) site is not part of this region and can be deleted without a decrease in TRP4 3'-end formation. 5'and 3'deletions and point mutations within this region affected 3'-end formation similarly in both orientations. In the center of this region the motif TAGT is located on the antisense strand. Point mutations within this motif resulted in a drastic reduce of 3'-end formation activity in both orientations. A second region consists of the 3'-end of the TRP4 open reading frame and is required for 3'-end formation in forward orientation. A single point mutation in a TAGT motif of the TRP4 open reading frame abolished TRP4 mRNA 3'-end formation in forward orientation and had no effect on the reverse orientation.