In vivo aggregation of maize Activator (Ac) transposase in nuclei of maize endosperm and Petunia protoplasts

The transposase (TPase) of the maize transposon Activator (Ac) accumulates in the nuclei of maize endosperm and transfected Petunia protoplasts, where it aggregates into rod-like structures about 2 μm in length. In petunia protoplasts the amount of TPase aggregates increases with the strength of the promoter fused to the Ac-coding region. The excision frequency of a Ds element, however, does not increase proportionally. The data suggest that the aggregated TPase is not responsible for the mobilization of the Ds element, but rather is a transpositionally inactive form of the protein. In contrast to the full-length TPase, a functional, N-terminally truncated TPase derivative is inefficiently transported into the nucleus at high expression levels and aggregates predominantly in the cytoplasm. Accordingly, the N-terminus of the TPase is involved in nuclear localization and/or aggregation.     

Somatic and germinal activities of maize Activator (Ac) transposase mutants in transgenic tobacco

The properties have been investigated of two deletion derivatives of the transposase protein (TPase) of maize transposable element Ac in transgenic tobacco. The wild-type and mutant TPases were expressed as fusions to the cauliflower mosaic virus 35S promoter. A deletion of 102 amino acids from the N-terminus, TPase(103–807), induces Ds excisions from a SPT::Ds reporter locus with a higher frequency than the wild-type TPase. The increased transpositional activity of TPase(103–807) is a dominant trait, as seedlings coexpressing truncated and wild-type TPase show the characteristic TPase(103–807) variegation pheno-type. A transpositionally inactive TPase deletion derivative lacking 188 amino acids from the N-terminus inhibits the transpositional activity of the wild-type TPase.     

Interactions of the transposase with the ends of Mu: formation of specific nucleoprotein structures and non-cooperative binding of the transposase to its binding sites.

Transposition of the E. coli bacteriophage Mu requires the phage encoded A and B proteins, the host protein HU and the host replication proteins. The ends of the genome of the phage, on which some of these proteins act, both contain three transposase (A) binding sites. The organization of these binding sites on each end, however, is different. Here we show, using DNase footprinting experiments with purified A protein, that mutant A binding sites, which affect transposition, have decreased affinity for the transposase. Furthermore the transposase binds non-cooperatively to all A binding sites both in the left and right end of Mu. Electron microscopic studies show that the A protein forms specific nucleoprotein structures upon binding to the ends of Mu. The A and B proteins interact with the ends of Mu to generate larger structures than with the A protein alone.     

Characterization of an immunoglobulin binding protein homolog in the maize floury-2 endosperm mutant.

The maize b-70 protein is an endoplasmic reticulum protein overproduced in the floury-2 (fl2) endosperm mutant. The increase in b-70 levels in fl2 plants occurs during seed maturation and is endosperm specific. We have used amino acid sequence homology to identify b-70 as a homolog of mammalian immunoglobulin binding protein (BiP). Purified b-70 fractions contain two 75-kilodalton polypeptides with pl values of 5.3 and 5.4. Both 75-kilodalton polypeptides share several properties with BiP, including the ability to bind ATP and localization within the lumen of the endoplasmic reticulum. In addition, both b-70 polypeptides can be induced in maize cell cultures with tunicamycin treatment. Like BiP, the pl 5.3 form of b-70 is post-translationally modified by phosphorylation and ADP-ribosylation. However, modification of the pl 5.4 species was not detected in vitro or in vivo. Although the b-70 gene is unlinked to fl2, b-70 overproduction is positively correlated with the fl2 gene and is regulated at the mRNA level. In contrast, the fl2 allele negatively affects the accumulation of the major endosperm storage proteins. The physical similarity of b-70 to BiP and its association with abnormal protein accumulation in fl2 endoplasmic reticulum may reflect a biological function to mediate protein folding and assembly in maize endosperm.     

One of three nuclear localization signals of maize Activator (Ac) transposase overlaps the DNA-binding domain

The nuclear localization sequences (NLSs) of the Ac transposase (TPase) protein have been characterized by indirect immunofluorescence detection of TPase deletion derivatives and TPase/β-glucuronidase (GUS) fusion proteins in transiently transfected Petunia cells. The TPase contains three NLSs near its amino-terminal end, NLS(44–62), NLS(159–178) and NLS(174–206), each of which is sufficient to redirect GUS to the nucleus. Deletion of the N-terminal 102 TPase residues including NLS(44–62) results in strongly reduced nuclear import of the truncated TPase. NLS(44–62) and NLS(159–178) are bipartite NLSs, whereas the structure of NLS(174–206) does not allow a classification into one of the three major NLS categories. NLS(174–206) overlaps with the basic DNA-binding domain of TPase. A substitution of two amino acids in this segment (HiS₁₉₁→Arg and Arg₁₉₃→His) results in a total loss of DNA-binding activity, but retains reduced NLS activity. Accordingly, the two functions can be separated. In addition, we show that a NLS-deficient 71 kDa TPase derivative is co-imported into the nucleus in the presence of wildtype TPase.     

beta-Aspartokinase from developing endosperm of maize.

β-aspartokinase (EC 2.7.2.4.) has been isolated from the developing endosperm (30 days post-pollination) of Zea mays (cv. Pioneer 3145). Enzyme activity was dependent upon ATP, Mg⁺⁺ or Mn⁺⁺, aspartate, and protein concentration. Double reciprocal plots of velocity vs. aspartate concentrations deviated from a straight line at low aspartate concentration indicating two apparent Km's of 0.5 and 6.6 mM. Enzyme activity was inhibited by lysine but not by methionine or threonine. The endosperm-derived β-aspartokinase behaved similarly to enzyme isolated from 6-day-old etiolated shoot tissue. The presence of β-aspartokinase in developing endosperm provides new insight into the source of the aspartate-derived amino acids in maize endosperm.     

Ac-immobilized, a stable source of Activator transposase that mediates sporophytic and gametophytic excision of Dissociation elements in maize

We have identified and characterized a novel Activator (Ac) element that is incapable of excision yet contributes to the canonical negative dosage effect of Ac. Cloning and sequence analysis of this immobilized Ac (Ac-im) revealed that it is identical to Ac with the exception of a 10-bp deletion of sequences at the left end of the element. In screens of approximately 6800 seeds, no germinal transpositions of Ac-im were detected. Importantly, Ac-im catalyzes germinal excisions of a Ds element resident at the r1 locus resulting in the recovery of independent transposed Ds insertions in approximately 4.5% of progeny kernels. Many of these transposition events occur during gametophytic development. Furthermore, we demonstrate that Ac-im transactivates multiple Ds insertions in somatic tissues including those in reporter alleles at bronze1, anthocyaninless1, and anthocyaninless2. We propose a model for the generation of Ac-im as an aberrant transposition event that failed to generate an 8-bp target site duplication and resulted in the deletion of Ac end sequences. We also discuss the utility of Ac-im in two-component Ac/Ds gene-tagging programs in maize.     

The binding motifs forAc transposase are absolutely required for excision ofDs1 in maize

A reverse genetic system for studying excision of the transposable elementDs1 in maize plants has been established previously. In this system, theDs1 element, as part of the genome of maize streak virus (MSV), is introduced into maize plants via agroinfection. In the presence of theAc element, excision ofDs1 from the MSV genome results in the appearance of viral symptoms on the maize plants. Here, we used this system to study DNA sequences requiredin cis for excision ofDs1. TheDs1 element contains theAc transposase binding motif AAACGG in only one of its subterminal regions (defined here as the 5′ subterminal region). We showed that mutation of these motifs abolished completely the excision capacity ofDs1. This is the first direct demonstration that the transposase binding motifs are essential for excision. Mutagenesis with oligonucleotide insertions in the other (3′) subterminal region resulted in elements with either a reduced or an increased excision efficiency, indicating that this subterminal region also has an important function.     

Interaction of endosperm size factors in maize

Crosses involving certain B-A translocations produce a reduced size of endosperm when those regions of the A chromosomes are missing in the sperm that fertilizes the polar nuclei. Previous studies involving the long arm of chromosome 10 showed that additional copies of this segment introduced through the maternal side could not rescue the reduced size phenotype conditioned by the corresponding deficiency in the paternal gamete. In this paper, experiments are described showing that other segments introduced maternally produce an even smaller kernel when fertilized by a sperm missing the same A chromosome segment or other ones that carry factors affecting endosperm size.—The example analyzed in detail involves reciprocal crosses between TB-4Sa and TB-10L19. Extra doses of 4S enhance the small kernel effect normally produced by TB-10L19. The additional copies of 4S have no effect on kernel mass when the 10L segment is present in the paternal contribution to the endosperm. The maternal enhancement by 4S is also effective with crosses by TB-1La but not by TB-1Sb. A survey of inter se crosses of B-A translocations shows that, when the maternal enhancement occurs, it is confined to those regions that themselves give a small kernel effect when used as a male. This correlation is strengthened by the observations that TB-10L19 enhances the small kernel effect of TB-1Sb, but TB-10L32 will not. Since these two B-10L translocations span the best localized small kernel effect region, this result supports the correlation of maternal enhancement regions with the paternal small kernel effect ones.—Because the enhancement can be attributed to a dosage effect and because the enhancement regions are coincident with the small kernel segments, it is postulated that this interacting system is analogous to aneuploid effects in diploid tissues but exhibits unique properties because of the evolutionary history and triploid condition of the endosperm.     

Maize Activator transposase has a bipartite DNA binding domain that recognizes subterminal sequences and the terminal inverted repeats

The mobility of maize transposable element Activator (Ac) is dependent on the 11-bp terminal inverted repeats (IRs) and approximately 250 subterminal nucleotides at each end. These sequences flank the coding region for the transposase (TPase) protein, which is required for the transposition reaction. Here we show that Ac TPase has a bipartite DNA binding domain, and recognizes the IRs and subterminal sequences in the Ac ends. TPase binds cooperatively to repetitive ACG and TCG sequences, of which 25 copies are found in the 5′ and 20 copies in the 3′ subterminal regions. TPase affinity is highest when these sites are flanked on the 3′ side by an additional G residue (A/TCGG), which is found at 75% of binding sites. Moreover, TPase binds specifically to the Ac IRs, albeit with much lower affinity. Two mutations within the IRs that immobilize Ac abolish TPase binding completely. The basic DNA binding domain of TPase is split into two subdomains. Binding to the subterminal motifs is accomplished by the C-terminal subdomain alone, whereas recognition of the IRs requires the N-terminal subdomain in addition. Furthermore, TPase is extremely flexible in DNA binding. Two direct or inverted binding sites are bound equally well, and sites that are five to twelve bases apart are similarly well bound. The consequences of these findings for the Ac transposition reaction are discussed.     

The ORFa protein, the putative transposase of maize transposable element Ac, has a basic DNA binding domain.

Ac encodes the 807 amino acid ORFa protein which binds specifically to multiple AAACGG motifs that are subterminally located in both ends of Ac. The wild-type ORFa protein and a number of deletion and amino acid exchange mutants were expressed in Escherichia coli, renatured and used for mobility shift assays. At least 136 amino acids from the N-terminus and 537 C-terminal amino acids may be removed from the ORFa protein without destroying the DNA binding domain, whereas a protein starting at amino acid 189 is DNA binding deficient. Certain basic amino acids between positions 190 and 200 are essential for DNA binding, as their substitution with uncharged amino acids leads to the loss of this function. The DNA binding domain of ORFa protein has an overall basic character, but no obvious sequence homology to any other known DNA binding protein. The homologies to the major open reading frames of transposable elements Tam3 from Antirrhinum majus and Hobo from Drosophila are found between the C-terminal two thirds of the three proteins. The ORFa protein forms discrete complexes with target DNA that appear, depending on the protein concentration, as a 'ladder' of bands on gels, indicating the occupation of target DNA by multiple ORFa protein molecules.     

Methylation pattern of mouse mitochondrial DNA.

The pattern of methylation of mouse mitochondrial DNA (mtDNA) was studied using several techniques. By employing a sensitive analytical procedure it was possible to show that this DNA contains the modified base 5-methylcytosine (m5Cyt). This residue occurred exclusively at the dinucleotide sequence CpG at a frequency of 3 to 5%. The pattern of methylation was further investigated by determining the state of methylation of several MspI (HpaII) sites. Different sites were found to be methylated to a different extent, implying that methylation of mtDNA is nonrandom. Based on the known base composition and nucleotide sequence of mouse mtDNA, the dinucleotide sequence CpG was found to be underrepresented in this DNA. The features of mtDNA methylation (CpG methylation, partial methylation of specific sites and CpG underrepresentation) are also characteristic of vertebrate nuclear DNA. This resemblance may reflect functional relationship between the mitochondrial and nuclear genomes.     

Ploidy barrier to endosperm development in maize

Maize kernels inheriting the indeterminate gametophyte mutant (ig) on the female side had endosperms that ranged in ploidy level from diploid (2x) to nonaploid (9x). In crosses with diploid males, only kernels of the triploid endosperm class developed normally. Kernels of the tetraploid endosperm class were half-sized but with well-developed embryos that regularly germinated. Kernels of endosperm composition other than triploid or tetraploid were abortive.-Endosperm ploidy level resulting from mating ig/ig x tetraploid Ig similarly was variable. Most endosperms started to degenerate soon after pollination and remained in an arrested state. Hexaploid endosperm was exceptional; it developed normally during the sequence of stages studied and accounted for plump kernels on mature ears. Since such kernels have diploid maternal tissues (pericarp) but triploid embryos, the present finding favors the view that endosperm failure or success in such circumstances is governed by conditions within the endosperm itself.-Whereas tetraploid endosperm consisting of three maternal genomes and one paternal genome is slightly reduced in size but supports viable seed development, that endosperm having two maternal and two paternal chromosome sets was highly defective and conditioned abortion. Thus, development of maize endosperm evidently is affected by the parental source of its sets of chromosomes.     

Ketose reductase activity in developing maize endosperm

Ketose reductase (NAD-dependent polyol dehydrogenase EC 1.1.1.14) activity, which catalyzes the NADH-dependent reduction of fructose to sorbitol (d-glucitol), was detected in developing maize (Zea mays L.) endosperm, purified 104-fold from this tissue, and partially characterized. Product analysis by high performance liquid chromatography confirmed that the enzyme-catalyzed reaction was freely reversible. In maize endosperm, 15 days after pollination, ketose reductase activity was of the same order of magnitude as sucrose synthase activity, which produces fructose during sucrose degradation. Other enzymes of hexose metabolism detected in maize endosperm were present in activities of only 1 to 3% of the sucrose synthase activity. CaCl₂, MgCl₂, and MnCl₂ stimulated ketose reductase activity 7-, 6-, and 2-fold, respectively, but had little effect on NAD-dependent polyol dehydrogenation (the reverse reaction). The pH optimums for ketose reductase and polyol dehydrogenase reactions were 6.0 and 9.0, respectively. K_m values were 136 millimolar fructose and 8.4 millimolar sorbitol. The molecular mass of ketose reductase was estimated to be 78 kilodaltons by gel filtration. It is postulated that ketose reductase may function to metabolize some of the fructose produced during sucrose degradation in maize endosperm, but the metabolic fate of sorbitol produced by this reaction is not known.     

Lysine-ketoglutarate reductase activity in developing maize endosperm

Lysine-ketoglutarate reductase activity was detected and characterized in the developing endosperm of maize (Zea mays L.). The enzyme showed specificity for its substrates: lysine, α-ketoglutarate, and NADPH. Formation of the reaction product saccharopine was demonstrated. The pH optimum of the enzyme was close to 7, and the K_m for lysine and α-ketoglutarate were 5.2 and 1.8 millimolar, respectively.