Binding ofNicotiana nuclear proteins to the subterminal regions of theAc transposable element

Specific binding ofNicotiana nuclear protein(s) to subterminal regions of theAc transposable element was detected using gel mobility shift assays. A sequence motif (GGTAAA) repeated in both terminal regions ofAc, was identified as the protein binding site. Mutation of two nucleotides in this motif was sufficient to abolish binding. Based on a series of competition assays, it is deduced that there is cooperative binding between two repeats, each similar to the GGTAAA motif. The binding protein is probably similar to a previously characterized maize protein which binds to a GGTAAA-containing motif located in the ends ofMutator. Moreover, we show that DNA fromDs1 competes for protein binding toAc termini, and we show, by sequence analysis, that GGTAAA binding sites are present in the terminal region ofTgm1, Tpn1, En/Spm, Tam3 andDs1-like elements. This suggests that the binding protein(s) might be involved in the transposition process.     

Binding sites for maize nuclear proteins in the subterminal regions of the transposable elementActivator

Genetic data suggest that transposition of the maize elementActivator (Ac) is modulated by host factors. Using gel retardation and DNase I protection assays we identified maize proteins which bind to seven subterminal sites in both ends ofAc. Four DNase I-protected sites contain a GGTAAA sequence, the other three include either GATAAA or GTTAAA. The specificity of the maize protein binding toAc was verified by using a synthetic fragment containing four GGTAAA motifs as probe and competitor in gel retardation assays. All seven binding sites are located within regions requiredin cis for transposition. A maize protein binding site with the same sequence has previously been identified in the terminal inverted repeats of the maizeMutator element. Thus, the protein, that recognizes this sequence is a good candidate for a regulatory host factor forAc transposition.     

Binding sites for maize nuclear proteins in the subterminal regions of the transposable elementActivator

Genetic data suggest that transposition of the maize elementActivator (Ac) is modulated by host factors. Using gel retardation and DNase I protection assays we identified maize proteins which bind to seven subterminal sites in both ends ofAc. Four DNase I-protected sites contain a GGTAAA sequence, the other three include either GATAAA or GTTAAA. The specificity of the maize protein binding toAc was verified by using a synthetic fragment containing four GGTAAA motifs as probe and competitor in gel retardation assays. All seven binding sites are located within regions requiredin cis for transposition. A maize protein binding site with the same sequence has previously been identified in the terminal inverted repeats of the maizeMutator element. Thus, the protein, that recognizes this sequence is a good candidate for a regulatory host factor forAc transposition.     

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.     

The binding motifs for Ac transposase are absolutely required for excision of Ds1 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.     

A nuclear protein that binds specifically to several maize transposons is not essential for Ds1 excision

Specific binding of plant nuclear proteins to GGTAAA-like motifs in the terminal regions of the transposable elements Ac and Mu1 has been detected in several laboratories. However, the role of these proteins in transposition remains unknown. To test the hypothesis that this binding activity is necessary for transposition, we identified and mutagenized all the binding motifs within the Ds1 element. This analysis enabled us to define more precisely the requirements for binding of the host protein. We then tested the ability of the mutated elements to excise from the maize streak virus (MSV) genome. We found that mutated Ds1 elements that do not bind the host proteins, as determined by gel-shift competition assay, are still capable of undergoing excision in maize, although for one of the maize lines the rate of excision was reduced. Excision of mutated Ds1 elements generated typical excision footprints. These data indicate that binding of host protein(s) to the GGTAAA-like motifs is not essential for Ds1 excision; however, it may contribute to the efficiency of the process. Received: 30 September 1999 / Accepted: 17 January 2000     

Simultaneous amplification of multiple DNA fragments by polymerase chain reaction in the analysis of transgenic plants and their progeny

We describe the simultaneous amplification of different segments of foreign DNA in transgenic plants using the polymerase chain reaction (PCR). We used PCR to simultaneously amplify different regions of transformed T-DNA in order to assay the integrity of transformed constructions in primary tomato transformants. We also used simultaneous PCR amplification to examine the segregation of transformed sequences in progeny of primary transformants. A tomato transformant containing the maize transposable elementAc was crossed to transformants containing the non-autonomousDs1 element flanked by maizeAdh1 sequences. We then ran PCR reactions on DNA from F1 progeny using two sets of primers, one set homologous toAc and one set homologous toAdh1 sequences on either side ofDs1. Because theAc andAdh1 primers resulted in amplification of fragments of different sizes, it was possible to monitor the inheritance ofAc and theDs1 containingAdh1 genein a single reaction. Additionally, it was possible to identify F1 plants in whichDs1 had excised by the amplification of a fragment the size predicted for an empty donor site. In order to run these reactions, we have constructed a simple and inexpensive thermal cycler which, when used in conjunction with the rapid miniscreen plant DNA isolation procedure described, allows the processing of a large number of samples in a single day. Therefore, we have shown that PCR can be a useful tool to monitor the integrity of foreign genes in transgenic plants, to follow the segregation of foreign DNA in progeny, and to assay for the excision of transposable elements.     

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.     

Monocyte chemoattractant protein-induced protein 1 directly degrades viral miRNAs with a specific motif and inhibits KSHV infection

Kaposi''s sarcoma-associated herpesvirus (KSHV) expresses miRNAs during latency. However, regulation of viral miRNAs remains largely unknown. Our prior studies demonstrated that MCPIP1 regulates KSHV miRNA biogenesis by degrading most KSHV pre-miRNAs through its RNase activity. Some viral pre-miRNAs are partially resistant to degradation by MCPIP1. Here, we further characterized MCPIP1 substrate specificity and its antiviral potential against KSHV infection. In vitro cleavage assays and binding assays showed that MCPIP1 cleavage efficiency is related to binding affinity. Motif-based sequence analysis identified that KSHV pre-miRNAs that are well degraded by MCPIP1 have a 5-base motif (M5 base motif) within their terminal loops and this motif region consists of multiple pyrimidine-purine-pyrimidine (YRY) motifs. We further demonstrated that mutation of this M5 base motif within terminal loop of pre-miRNAs inhibited MCPIP1-mediated RNA degradation. We also revealed that MCPIP1 has an antiviral effect against KSHV infection. MCPIP1 can reduce the expression of Dicer, which in turn restricts KSHV infection. Conclusively, our findings demonstrated that MCPIP1 inhibited KSHV infection and suppressed viral miRNA biogenesis by directly degrading KSHV pre-miRNAs and altering the expression of miRNA biogenesis factors.     

Two repeated motifs enriched within some enhancers and origins of replication are bound by SETMAR isoforms in human colon cells

Setmar is a gene specific to simian genomes. The function(s) of its isoforms are poorly understood and their existence in healthy tissues remains to be validated. Here we profiled SETMAR expression and its genome-wide binding landscape in colon tissue. We found isoforms V3 and V6 in healthy and tumour colon tissues as well as incell lines. In two colorectal cell lines SETMAR binds to several thousand Hsmar1 and MADE1 terminal ends, transposons mostly located in non-genic regions of active chromatin including in enhancers. It also binds to a 12-bp motifs similar to an inner motif in Hsmar1 and MADE1 terminal ends. This motif is interspersed throughout the genome and is enriched in GC-rich regions as well as in CpG islands that contain constitutive replication origins. It is also found in enhancers other than those associated with Hsmar1 and MADE1. The role of SETMAR in the expression of genes, DNA replication and in DNA repair are discussed.     

Molecular characterization of a venom acid phosphatase Acph-1-like protein from the Asiatic honeybee Apis cerana

Bee venom contains a variety of peptides and enzymes, including acid phosphatases. An acid phosphatase has been identified from European honeybee (Apis mellifera) venom. However, although the amino acid sequence is known, no functional information is currently available for bee venom acid phosphatase Acph-1-like proteins. In this study, an Asiatic honeybee (Apis cerana) venom acid phosphatase Acph-1-like protein (AcAcph-1) was identified. The analysis of the predicted AcAcph-1 amino acid sequence revealed high levels of identity with other bee venom acid phosphatase Acph-1-like proteins. Recombinant AcAcph-1 was expressed as a 64-kDa protein in baculovirus-infected insect cells. The enzymatic properties of recombinant AcAcph-1, determined using p-nitrophenyl phosphate (p-NPP) as a substrate, showed the highest activity at 45 °C and pH 4.8. Northern and western blot analyses showed that AcAcph-1 was expressed in the venom gland and was present as a 64-kDa protein in bee venom. In addition, N-glycosylation of AcAcph-1 was revealed by tunicamycin treatment of recombinant virus-infected insect Sf9 cells and by glycoprotein staining of purified recombinant AcAcph-1. Our findings show that AcAcph-1 functions as a venom acid phosphatase. This paper provides the first evidence of the role of a bee venom acid phosphatase Acph-1-like protein.     

Trans-activation and stable integration of the maize transposable element Ds cotransfected with the Ac transposase gene in transgenic rice plants

To develop an efficient gene tagging system in rice, a plasmid was constructed carrying a non-autonomous maize Ds element in the untranslated leader sequence of a hygromycin B resistance gene fused with the 35S promoter of cauliflower mosaic virus. This plasmid was cotransfected by electroporation into rice protoplasts together with a plasmid containing the maize Ac transposase gene transcribed from the 35S promoter. Five lines of evidence obtained from the analyses of hygromycin B-resistant calli, regenerated plants and their progeny showed that the introduced Ds was trans-activated by the Ac transposase gene in rice. (1) Cotransfection of the two plasmids is necessary for generation of hygromycin B resistant transformants. (2) Ds excision sites are detected by Southern blot hybridization. (3) Characteristic sequence alterations are found at Ds excision sites. (4) Newly integrated Ds is detected in the rice genome. (5) Generation of 8 by target duplications is observed at the Ds integration sites on the rice chromosomes. Our results also show that Ds can be trans-activated by the transiently expressed Ac transposase at early stages of protoplast culture and integrated stably into the rice genome, while the cotransfected Ac transposase gene is not integrated. Segregation data from such a transgenic rice plant carrying no Ac transposase gene showed that four Ds copies were stably integrated into three different chromosomes, one of which also contained the functional hph gene restored by Ds excision. The results indicate that a dispersed distribution of Ds throughout genomes not bearing the active Ac transposase gene can be achieved by simultaneous transfection with Ds and the Ac transposase gene.     

Sequence-specific binding of Taz1p dimers to fission yeast telomeric DNA

The fission yeast (Schizosaccharomyces pombe) taz1 gene encodes a telomere-associated protein. It contains a single copy of a Myb-like motif termed the telobox that is also found in the human telomere binding proteins TRF1 and TRF2, and Tbf1p, a protein that binds to sequences found within the sub-telomeric regions of budding yeast (Saccharomyces cerevisiae) chromosomes. Taz1p was synthesised in vitro and shown to bind to a fission yeast telomeric DNA fragment in a sequence specific manner that required the telobox motif. Like the mammalian TRF proteins, Taz1p bound to DNA as a preformed homodimer. The isolated Myb-like domain was also capable of sequence specific DNA binding, although with less specificity than the full-length dimer. Surprisingly, a protein extract produced from a taz1–fission yeast strain still contained the major telomere binding activity (complex I) we have characterised previously, suggesting that there could be other abundant telomere binding proteins in fission yeast. One candidate, SpX, was also synthesised in vitro, but despite the presence of two telobox domains, no sequence specific binding to telomeric DNA was detected.     

A maize cryptic Ac-homologous sequence derived from an Activator transposable element does not transpose.

Summary Sequences sharing homology to the transposable element Activator (Ac) are prevalent in the maize genome. A cryptic Ac-like DNA, cAc-11, was isolated from the maize inbred line 4Co63 and sequenced. Cryptic Ac-11 has over 90% homology to known Ac sequences and contains an 11 by inverted terminal repeat flanked by an 8 by target site duplication, which are characteristics of Ac and Dissociation (Ds) transposable elements. Unlike the active Ac element, which encodes a transposase, the corresponding sequence in cAc-11 has no significant open reading frame. A 44 by tandem repeat was found at one end of cAc-11, which might be a result of aberrant transposition. The sequence data suggest that cAc-11 may represent a remnant of an Ac or a Ds element. Sequences homologous to cAc-11 can be detected in many maize inbred lines. In contrast to canonical Ac elements, cAc-11 DNA in the maize genome is hypermethylated and does not transpose even in the presence of an active Ac element.     

Characterization ofGandalf,a new inverted-repeat transposable element ofDrosophila koepferae

The cloning and characterization ofGandalf, a new DNA-transposing mobile element obtained from theDrosophila koepferae (repleta group) genome is described. A fragment ofGandalf was found in a middle repetitive clone that shows variable chromosomal localization. Restriction, Southern blot, PCR and sequencing analyses have shown that mostGandalf copies are about 1 kb long, are flanked by 12 by inverted terminal repeats and contain subterminal repetitive regions on both sides of the element. As with other elements of the DNA-transposing type (known as the ‘Ac family’), theGandalf element generates 8 by direct duplications at the insertion point. Coding region analysis has shown that the longer open reading frame found inGandalf copies could encode part of a protein. However, whether or not the 1 kb copies of the element are actually the active transposons remains to be elucidated.Gandalf shows a very low copy number inD. buzzatii, a sibling species ofD. koepferae. An attempt to induce interspecific hybrid dysgenesis in hybrids of these two species has been unsuccessful.     

Identification of a telomeric DNA-binding protein in Eimeria tenella

Coccidiosis is considered to be a major problem for the poultry industry, and coccidiosis control is yet urgent. Due to the roles in telomere length regulation and end protection, telomere-binding proteins have been considered as a good target for drug design. In this work, a putative Gbp1p that is similar to telomeric DNA-binding protein Gbp (G-strand binding protein) of Cryptosporidium parvum, was searched in the database of Eimeria tenella. Sequence analysis indicated E.tenella Gbp1p (EtGbp1p) has significant sequence similarity to other eukaryotic Gbps in their RNA recognition motif (RRM) domains. Electrophoretic mobility shift assays (EMSAs) demonstrated recombinant EtGbp1p bound G-rich telomeric DNA, but not C-rich or double-stranded telomeric DNA sequences. Competition and antibody supershift assays confirmed the interaction of DNA–protein complex. Chromatin immunoprecipitation assays confirmed that EtGbp1p interacted with telomeric DNA in vivo. Collectively, these evidences suggest that EtGbp1p represents a G-rich single-stranded telomeric DNA-binding protein in E.tenella.     

The maize ID1 flowering time regulator is a zinc finger protein with novel DNA binding properties

The INDETERMINATE protein, ID1, plays a key role in regulating the transition to flowering in maize. ID1 is the founding member of a plant-specific zinc finger protein family that is defined by a highly conserved amino sequence called the ID domain. The ID domain includes a cluster of three different types of zinc fingers separated from a fourth C2H2 finger by a long spacer; ID1 is distinct from other ID domain proteins by having a much longer spacer. In vitro DNA selection and amplification binding assays and DNA binding experiments showed that ID1 binds selectively to an 11 bp consensus motif via the ID domain. Unexpectedly, site-directed mutagenesis of the ID1 protein showed that zinc fingers located at each end of the ID domain are not required for binding to the consensus motif despite the fact that one of these zinc fingers is a canonical C2H2 DNA binding domain. In addition, an ID1 in vitro deletion mutant that lacks the extra spacer between zinc fingers binds the same 11 bp motif as normal ID1, suggesting that all ID domain-containing proteins recognize the same DNA target sequence. Our results demonstrate that maize ID1 and ID domain proteins have novel zinc finger configurations with unique DNA binding properties.     

Sequential gel mobility shift scanning of 5′ upstream sequences of the Neurospora crassa am (GDH) gene

We have used gel mobility shift assays to scan 1.7 kb of 5′ non-coding sequence of the am (glutamate dehydrogenase) gene of Neurospora crassa for binding by partially fractionated Neurospora proteins. Using genetic analysis this region had been shown to play an important role in the control of glutamate dehydrogenase (GDH) expression. Gel mobility shift analysis identified three regions to which Neurospora proteins bind specifically. Two of these corresponded to the two elements previously defined by genetic analysis (URSamα and URSamβ). The third protein binding site appears to be unrelated to am gene expression. Competition experiments showed that the proteins that bind to the URSamα and URSamβ elements are different. The URSamα element was shown to contain two independent binding sites for the URSamα binding protein(s). Both fragments contain a CCAAT motif, suggesting that URSamα binding protein(s) may be members of one of the CCAAT-binding protein families. The effect of deletion of either the URSamα or URSamβ elements on catabolite induction of am expression was also determined. Both elements appear to act as constitutive enhancers of gene expression.