The BED finger, a novel DNA-binding domain in chromatin-boundary-element-binding proteins and transposases

An active DNA transposon nDart causing leaf variegation and mutable dwarfism and its related elements in rice

While characterized mutable alleles caused by DNA transposons have been abundant in maize since the discovery of Dissociation conferring variegation by Barbara McClintock, only a few mutable alleles have been described in rice even though the rice genome contains various transposons. Here, we show that a spontaneous mutable virescent allele, pyl-v, is caused by the disruption of the nuclear-coded essential chloroplast protease gene, OsClpP5, due to insertion of a 607-bp non-autonomous DNA transposon, non-autonomous DNA-based active rice transposon one (nDart1), belonging to the hAT superfamily. The transposition of nDart1 can be induced by crossing with a line containing an autonomous element, aDart, and stabilized by segregating out of aDart. We also identified a novel mutable dwarf allele thl-m caused by an insertion of nDart1. The japonica cultivar Nipponbare carries no aDart, although it contains epigenetically silenced Dart element(s), which can be activated by 5-azacytidine. Nipponbare bears four subgroups of about 3.6-kb Dart-like sequences, three of which contain potential transposase genes, and around 3.6-kb elements without an apparent transposase gene, as well as three subgroups of about 0.6-kb nDart1-related elements that are all internal deletions of the Dart-like sequences. Both nDart1 and 3.6-kb Dart-like elements were also present in indica varieties 93-11 and Kasalath. nDart1 appears to be the most active mutagen among nDart1-related elements contributing to generating natural variations. A candidate for an autonomous element, aDart, and a possible application of nDart1 for transposon tagging are discussed.

The temperature-dependent change in methylation of the Antirrhinum transposon Tam3 is controlled by the activity of its transposase

The Antirrhinum majus transposon Tam3 undergoes low temperature-dependent transposition (LTDT). Growth at 15 degrees C permits transposition, whereas growth at 25 degrees C strongly suppresses it. The degree of Tam3 DNA methylation is altered somatically and positively correlated with growth temperature, an exceptional epigenetic system in plants. Using a Tam3-inactive line, we show that methylation change depends on Tam3 activity. Random binding site selection analysis and electrophoretic mobility shift assays revealed that the Tam3 transposase (TPase) binds to the major repeat in the subterminal regions of Tam3, the site showing the biggest temperature-dependent change in methylation state. Methylcytosines in the motif impair the binding ability of the TPase. Proteins in a nuclear extract from plants grown at 15 degrees C but not 25 degrees C bind to this motif in Tam3. The decrease in Tam3 DNA methylation at low temperature also requires cell division. Thus, TPase binding to Tam3 occurs only during growth at low temperature and immediately after DNA replication, resulting in a Tam3-specific decrease in methylation of transposon DNA. Consequently, the Tam3 methylation level in LTDT is regulated by Tam3 activity, which is dependent on the ability of its TPase to bind DNA and affected by growth temperature. Thus, the methylation/demethylation of Tam3 is the consequence, not the cause, of LTDT.

An Arabidopsis hAT-like transposase is essential for plant development

A significant proportion of the genomes of higher plants and vertebrates consists of transposable elements and their derivatives. Autonomous DNA type transposons encode a transposase that enables them to mobilize to a new chromosomal position in the host genome by a cut-and-paste mechanism. As this is potentially mutagenic, the host limits transposition through epigenetic gene silencing and heterochromatin formation. Here we show that a transposase from Arabidopsis thaliana that we named DAYSLEEPER is essential for normal plant growth; it shares several characteristics with the hAT (hobo, Activator, Tam3) family of transposases. DAYSLEEPER was isolated as a factor binding to a motif (Kubox1) present in the upstream region of the Arabidopsis DNA repair gene Ku70. This motif is also present in the upstream regions of many other plant genes. Plants lacking DAYSLEEPER or strongly overexpressing this gene do not develop in a normal manner. Furthermore, DAYSLEEPER overexpression results in the altered expression of many genes. Our data indicate that transposase-like genes can be essential for plant development and can also regulate global gene expression. Thus, transposases can become domesticated by the host to fulfil important cellular functions.

Molecular architecture of a eukaryotic DNA transposase

Mobile elements and their inactive remnants account for large proportions of most eukaryotic genomes, where they have had central roles in genome evolution. Over 50 years ago, McClintock reported a form of stress-induced genome instability in maize in which discrete DNA segments move between chromosomal locations. Our current mechanistic understanding of enzymes catalyzing transposition is largely limited to prokaryotic transposases. The Hermes transposon from the housefly is part of the eukaryotic hAT superfamily that includes hobo from Drosophila, McClintock's maize Activator and Tam3 from snapdragon. We report here the three-dimensional structure of a functionally active form of the transposase from Hermes at 2.1-A resolution. The Hermes protein has some structural features of prokaryotic transposases, including a domain with a retroviral integrase fold. However, this domain is disrupted by the insertion of an additional domain. Finally, transposition is observed only when Hermes assembles into a hexamer.

Discovery of the principal specific transcription factors of Apicomplexa and their implication for the evolution of the AP2-integrase DNA binding domains

The comparative genomics of apicomplexans, such as the malarial parasite Plasmodium, the cattle parasite Theileria and the emerging human parasite Cryptosporidium, have suggested an unexpected paucity of specific transcription factors (TFs) with DNA binding domains that are closely related to those found in the major families of TFs from other eukaryotes. This apparent lack of specific TFs is paradoxical, given that the apicomplexans show a complex developmental cycle in one or more hosts and a reproducible pattern of differential gene expression in course of this cycle. Using sensitive sequence profile searches, we show that the apicomplexans possess a lineage-specific expansion of a novel family of proteins with a version of the AP2 (Apetala2)-integrase DNA binding domain, which is present in numerous plant TFs. About 20–27 members of this apicomplexan AP2 (ApiAP2) family are encoded in different apicomplexan genomes, with each protein containing one to four copies of the AP2 DNA binding domain. Using gene expression data from Plasmodium falciparum, we show that guilds of ApiAP2 genes are expressed in different stages of intraerythrocytic development. By analogy to the plant AP2 proteins and based on the expression patterns, we predict that the ApiAP2 proteins are likely to function as previously unknown specific TFs in the apicomplexans and regulate the progression of their developmental cycle. In addition to the ApiAP2 family, we also identified two other novel families of AP2 DNA binding domains in bacteria and transposons. Using structure similarity searches, we also identified divergent versions of the AP2-integrase DNA binding domain fold in the DNA binding region of the PI-SceI homing endonuclease and the C-terminal domain of the pleckstrin homology (PH) domain-like modules of eukaryotes. Integrating these findings, we present a reconstruction of the evolutionary scenario of the AP2-integrase DNA binding domain fold, which suggests that it underwent multiple independent combinations with different types of mobile endonucleases or recombinases. It appears that the eukaryotic versions have emerged from versions of the domain associated with mobile elements, followed by independent lineage-specific expansions, which accompanied their recruitment to transcription regulation functions.

Nuclear hormone receptor coregulator: role in hormone action, metabolism, growth, and development

Nuclear hormone receptor coregulator (NRC) (also referred to as activating signal cointegrator-2, thyroid hormone receptor-binding protein, peroxisome proliferator activating receptor-interacting protein, and 250-kDa receptor associated protein) belongs to a growing class of nuclear cofactors widely known as coregulators or coactivators that are necessary for transcriptional activation of target genes. The NRC gene is also amplified and overexpressed in breast, colon, and lung cancers. NRC is a 2063-amino acid protein that harbors a potent N-terminal activation domain (AD1) and a second more centrally located activation domain (AD2) that is rich in Glu and Pro. Near AD2 is a receptor-interacting domain containing an LxxLL motif (LxxLL-1), which interacts with a wide variety of ligand-bound nuclear hormone receptors with high affinity. A second LxxLL motif (LxxLL-2) located in the C-terminal region of NRC is more restricted in its nuclear hormone receptor specificity. The intrinsic activation potential of NRC is regulated by a C-terminal serine, threonine, leucine-regulatory domain. The potential role of NRC as a cointegrator is suggested by its ability to enhance transcriptional activation of a wide variety of transcription factors and from its in vivo association with a number of known transcriptional regulators including CBP/p300. Recent studies in mice indicate that deletion of both NRC alleles leads to embryonic lethality resulting from general growth retardation coupled with developmental defects in the heart, liver, brain, and placenta. NRC(-/-) mouse embryo fibroblasts spontaneously undergo apoptosis, indicating the importance of NRC as a prosurvival and antiapoptotic gene. Studies with 129S6 NRC(+/-) mice indicate that NRC is a pleiotropic regulator that is involved in growth, development, reproduction, metabolism, and wound healing.

Purification, crystallization and preliminary crystallographic analysis of the Hermes transposase

DNA transposition is the movement of a defined segment of DNA from one location to another. Although the enzymes that catalyze transposition in bacterial systems have been well characterized, much less is known about the families of transposase enzymes that function in higher organisms. Active transposons have been identified in many insect species, providing tools for gene identification and offering the possibility of altering the genotypes of natural insect populations. One of these active transposons is Hermes, a 2749-base-pair element from Musca domestica that encodes its own transposase. An N-terminally deleted version of the Hermes transposase (residues 79-612) has been overexpressed and purified, and crystals that diffract to 2.1 A resolution have been obtained at 277 K by the hanging-drop method.

The THAP domain of THAP1 is a large C2CH module with zinc-dependent sequence-specific DNA-binding activity

We have recently described an evolutionarily conserved protein motif, designated the THAP domain, which defines a previously uncharacterized family of cellular factors (THAP proteins). The THAP domain exhibits similarities to the site-specific DNA-binding domain of Drosophila P element transposase, including a putative metal-coordinating C2CH signature (CX(2-4)CX(35-53)CX(2)H). In this article, we report a comprehensive list of approximately 100 distinct THAP proteins in model animal organisms, including human nuclear proapoptotic factors THAP1 and DAP4/THAP0, transcriptional repressor THAP7, zebrafish orthologue of cell cycle regulator E2F6, and Caenorhabditis elegans chromatin-associated protein HIM-17 and cell-cycle regulators LIN-36 and LIN-15B. In addition, we demonstrate the biochemical function of the THAP domain as a zinc-dependent sequence-specific DNA-binding domain belonging to the zinc-finger superfamily. In vitro binding-site selection allowed us to identify an 11-nucleotide consensus DNA-binding sequence specifically recognized by the THAP domain of human THAP1. Mutations of single nucleotide positions in this sequence abrogated THAP-domain binding. Experiments with the zinc chelator 1,10-o-phenanthroline revealed that the THAP domain is a zinc-dependent DNA-binding domain. Site-directed mutagenesis of single cysteine or histidine residues supported a role for the C2CH motif in zinc coordination and DNA-binding activity. The four other conserved residues (P, W, F, and P), which define the THAP consensus sequence, were also found to be required for DNA binding. Together with previous genetic data obtained in C. elegans, our results suggest that cellular THAP proteins may function as zinc-dependent sequence-specific DNA-binding factors with roles in proliferation, apoptosis, cell cycle, chromosome segregation, chromatin modification, and transcriptional regulation.

Isolation and characterisation of GTF2IRD2, a novel fusion gene and member of the TFII-I family of transcription factors, deleted in Williams-Beuren syndrome

Williams-Beuren syndrome (WBS) is a developmental disorder with characteristic physical, cognitive and behavioural traits caused by a microdeletion of approximately 1.5 Mb on chromosome 7q11.23. In total, 24 genes have been described within the deleted region to date. We have isolated and characterised a novel human gene, GTF2IRD2, mapping to the WBS critical region thought to harbour genes important for the cognitive aspects of the disorder. GTF2IRD2 is the third member of the novel TFII-I family of genes clustered on 7q11.23. The GTF2IRD2 protein contains two putative helix-loop-helix regions (I-repeats) and an unusual C-terminal CHARLIE8 transposon-like domain, thought to have arisen as a consequence of the random insertion of a transposable element generating a functional fusion gene. The retention of a number of conserved transposase-associated motifs within the protein suggests that the CHARLIE8-like region may still have some degree of transposase functionality that could influence the stability of the region in a mechanism similar to that proposed for Charcot-Marie-Tooth neuropathy type 1A. GTF2IRD2 is highly conserved in mammals and the mouse ortholgue (Gtf2ird2) has also been isolated and maps to the syntenic WBS region on mouse chromosome 5G. Deletion mapping studies using somatic cell hybrids show that some WBS patients are hemizygous for this gene, suggesting that it could play a role in the pathogenesis of the disorder.

Extensive exon reshuffling over evolutionary time coupled to trans-splicing in Drosophila

The relative position of exons in genes can be altered only after large structural mutations. These mutations are frequently deleterious, impairing transcription, splicing, RNA stability, or protein function, as well as imposing strong inflexibility to protein evolution. Alternative cis- or trans-splicing may overcome the need for genomic structural stability, allowing genes to encode new proteins without the need to maintain a specific exon order. Trans-splicing in the Drosophila melanogaster modifier of mdg4 (mod[mdg4]) gene is the best documented example in which this process plays a major role in the maturation of mRNAs. Comparison of the genomic organization of this locus among several insect species suggests that the divergence between the lineages of the mosquito Anopheles gambiae and D. melanogaster involved an extensive exon rearrangement, requiring >11 breakpoints within the mod(mdg4) gene. The massive reorganization of the locus also included the deletion or addition of a new function as well as exon duplications. Whereas both DNA strands are sense strands in the Drosophila gene, the coding region in mosquito lays in a single strand, suggesting that trans-splicing may have originated in the Drosophila lineage and might have been the triggering factor for such a dramatic reorganization.

The C-terminus of the Hermes transposase contains a protein multimerization domain

Transposase activity that mediates the mobility of class II transposable elements, is most commonly initiated by the assembly of higher order synaptic complexes, called transpososomes. The formation of these complexes, that contain the transposable element's DNA as well as two or more molecules of the transposase, is dependent on interactions between transposase molecules. Using the yeast Two-Hybrid system, we were able to identify three regions mediating multimerization of the Hermes transposase, an element used for germline transformation of insects belonging to the hAT family of transposable elements. One region facilitating protein binding of Hermes transposase molecules was found within the first 252 amino acids of the transposase. The second region was located at the C-terminus of the transposase, and was found to be specific for Hermes transposase multimerization. Amino acids 551-569 were not only required for multimerization but were also necessary for transposition of the element. The third region was located between amino acids 253 and 380 and was found to eliminate the non-specific protein binding ability of the N-terminal protein interaction region but was required for the specific protein binding ability of the C-terminal region of the transposase. Five point mutations affecting the structural integrity of the C-terminal multimerization region abolished or significantly reduced transpositional activity. The same region had been previously identified to mediate dimerization in Activator (Ac), another hAT element, indicating that hAT transposase multimerization is likely to be a prerequisite for mobility of their elements.

An Ac -like Transposable Element Family With Transcriptionally Active Y-Linked Copies in the White Campion, Silene latifolia

An RFLP genomic subtraction was used to isolate male-specific sequences in the species Silene latifolia. One isolated fragment, SLP2, shares similarity to a portion of the Activator (Ac) transposase from Zea mays and to related proteins from other plant species. Southern blot analysis of male and female S. latifolia genomic DNA shows that SLP2 belongs to a low-copy-number repeat family with two Y-linked copies. Screening of a S. latifolia male genomic library using SLP2 as a probe led to the isolation of five clones, which were partially sequenced. One clone contains two large open reading frames that can be joined into a sequence encoding a putative protein of 682 amino acids by removing a short intron. Database searches and phylogenetic analysis show that this protein belongs to the hAT superfamily of transposases, closest to Tag2 (Arabidopsis thaliana), and contains all of the defined domains critical for the activity of these transposases. PCR with genomic and cDNA templates from S. latifolia male, female, and hermaphrodite individuals revealed that one of the Y-linked copies is transcriptionally active and alternatively spliced. This is the first report of a transcriptionally active transposable element (TE) family in S. latifolia and the first DNA transposon residing on a plant Y chromosome. The potential activity and regulation of this TE family and its use for Y chromosome gene discovery is discussed.

Nuclear localization of the Hermes transposase depends on basic amino acid residues at the N-terminus of the protein

For the Hermes transposable element to be mobilized in its eukaryotic host, the transposase, encoded by the element, must make contact with its DNA. After synthesis in the cytoplasm, the transposase has to be actively imported into the nucleus because its size of 70.1 kDa prevents passive diffusion through the nuclear pore. Studies in vitro using transient expression of a Hermes-EGFP fusion protein in Drosophila melanogaster Schneider 2 cells showed the transposase was located predominantly in the nucleus. In silico sequence analysis, however, did not reveal any nuclear localization signal (NLS). To identify the sequence(s) responsible for localization of Hermes transposase in the nucleus, truncated or mutated forms of the transposase were examined for their influence on sub-cellular localization of marker proteins fused to the transposase. Using the same expression system and a GFP-GUS fusion double marker, residues 1-110 were recognized as sufficient, and residues 1-32 as necessary, for nuclear localization. Amino acid K25 greatly facilitated nuclear localization, indicating that at least this basic amino acid plays a significant role in this process. This sequence overlaps the proposed DNA binding region of the Hermes transposase and is not necessarily conserved in all members of the hAT transposable element family.

The THAP domain: a novel protein motif with similarity to the DNA-binding domain of P element transposase

We have identified a novel evolutionarily conserved protein motif - designated the THAP domain - that defines a new family of cellular factors. We have found that the THAP domain presents striking similarities with the site-specific DNA-binding domain (DBD) of Drosophila P element transposase, including a similar size, N-terminal location, and conservation of the residues that define the THAP motif, such as the C2CH signature (Cys-Xaa(2-4)-Cys-Xaa(35-50)-Cys-Xaa(2)-His). Our results suggest that the THAP domain is a novel example of a DBD that is shared between cellular proteins and transposases from mobile genomic parasites.

NRC-interacting factor 1 is a novel cotransducer that interacts with and regulates the activity of the nuclear hormone receptor coactivator NRC

We previously reported the cloning and characterization of a novel nuclear hormone receptor transcriptional coactivator, which we refer to as NRC. NRC is a 2,063-amino-acid nuclear protein which contains a potent N-terminal activation domain and several C-terminal modules which interact with CBP and ligand-bound nuclear hormone receptors as well as c-Fos and c-Jun. In this study we sought to clone and identify novel factors that interact with NRC to modulate its transcriptional activity. Here we describe the cloning and characterization of a novel protein we refer to as NIF-1 (NRC-interacting factor 1). NIF-1 was cloned from rat pituitary and human cell lines and was found to interact in vivo and in vitro with NRC. NIF-1 is a 1,342-amino-acid nuclear protein containing a number of conserved domains, including six Cys-2/His-2 zinc fingers, an N-terminal stretch of acidic amino acids, and a C-terminal leucine zipper-like motif. Zinc fingers 1 to 3 are potential DNA-binding BED finger domains recently proposed to play a role in altering local chromatin architecture. We mapped the interaction domains of NRC and NIF-1. Although NIF-1 does not directly interact with nuclear receptors, it markedly enhances ligand-dependent transcriptional activation by nuclear hormone receptors in vivo as well as activation by c-Fos and c-Jun. These results, and the finding that NIF-1 interacts with NRC in vivo, suggest that NIF-1 functions to regulate transcriptional activation through NRC. We suggest that NIF-1, and factors which associate with coactivators but not receptors, be referred to as cotransducers, which act in vivo either as part of a coactivator complex or downstream of a coactivator complex to modulate transcriptional activity. Our findings suggest that NIF-1 may be a functional component of an NRC complex and acts as a regulator or cotransducer of NRC function.

Biochemical analysis of the recombinant Fur (ferric uptake regulator) protein from Anabaena PCC 7119: factors affecting its oligomerization state

Fur (ferric uptake regulator) protein is a DNA-binding protein which regulates iron-responsive genes. Recombinant Fur from the nitrogen-fixing cyanobacterium Anabaena PCC 7119 has been purified and characterized, and polyclonal antibodies obtained. The experimental data show that Fur from Anabaena dimerizes in solution with the involvement of disulphide bridges. Cross-linking experiments and MALDI-TOF (matrix-assisted laser desorption/ionization time of flight) MS also show several oligomerization states of Fur, and the equilibrium of these forms depends on protein concentration and ionic strength. In intact recombinant Fur, four cysteine residues out of five were inert towards DTNB [5,5'-dithiobis-(2-nitrobenzoic acid)], and their modification required sodium borohydride. Metal analysis and electrospray ionization MS revealed that neither zinc nor other metals are present in this Fur protein. Purified recombinant Fur bound to its own promoter in gel-shift assays. Fur was shown to be a constitutive protein in Anabaena cells, with no significant difference in its expression in cells grown under iron-sufficient compared with iron-deficient conditions.

Extensive domain shuffling in transcription regulators of DNA viruses and implications for the origin of fungal APSES transcription factors

BACKGROUND

Viral DNA-binding proteins have served as good models to study the biochemistry of transcription regulation and chromatin dynamics. Computational analysis of viral DNA-binding regulatory proteins and identification of their previously undetected homologs encoded by cellular genomes might lead to a better understanding of their function and evolution in both viral and cellular systems.

RESULTS

The phyletic range and the conserved DNA-binding domains of the viral regulatory proteins of the poxvirus D6R/N1R and baculoviral Bro protein families have not been previously defined. Using computational analysis, we show that the amino-terminal module of the D6R/N1R proteins defines a novel, conserved DNA-binding domain (the KilA-N domain) that is found in a wide range of proteins of large bacterial and eukaryotic DNA viruses. The KilA-N domain is suggested to be homologous to the fungal DNA-binding APSES domain. We provide evidence for the KilA-N and APSES domains sharing a common fold with the nucleic acid-binding modules of the LAGLIDADG nucleases and the amino-terminal domains of the tRNA endonuclease. The amino-terminal module of the Bro proteins is another, distinct DNA-binding domain (the Bro-N domain) that is present in proteins whose domain architectures parallel those of the KilA-N domain-containing proteins. A detailed analysis of the KilA-N and Bro-N domains and the associated domains points to extensive domain shuffling and lineage-specific gene family expansion within DNA virus genomes.

CONCLUSIONS

We define a large class of novel viral DNA-binding proteins and their cellular homologs and identify their domain architectures. On the basis of phyletic pattern analysis we present evidence for a probable viral origin of the fungus-specific cell-cycle regulatory transcription factors containing the APSES DNA-binding domain. We also demonstrate the extensive role of lineage-specific gene expansion and domain shuffling, within a limited set of approximately 24 domains, in the generation of the diversity of virus-specific regulatory proteins.

Systematic identification of novel protein domain families associated with nuclear functions

A systematic computational analysis of protein sequences containing known nuclear domains led to the identification of 28 novel domain families. This represents a 26% increase in the starting set of 107 known nuclear domain families used for the analysis. Most of the novel domains are present in all major eukaryotic lineages, but 3 are species specific. For about 500 of the 1200 proteins that contain these new domains, nuclear localization could be inferred, and for 700, additional features could be predicted. For example, we identified a new domain, likely to have a role downstream of the unfolded protein response; a nematode-specific signalling domain; and a widespread domain, likely to be a noncatalytic homolog of ubiquitin-conjugating enzymes.