Multicellular organisms develop complex genomes through transcriptional regulation, which is crucial for spatial and temporal cellular specialization to promote phenotypic complexity. The interaction of regulatory DNA sequence motifs with DNA-binding transcription factors induces transcriptional regulation. These transcriptional factors serve a critical role in the activation or repression of target genes. Zinc-finger proteins are among the most commonly occurring DNA-binding motifs and constitute 2–3% of the transcription factors in the human genome (1). These proteins are associated with several biological functions, including differentiation, chromatin remodeling and development (2). The zinc finger, BED-type (ZBED) gene family is widely expressed in vertebrate tissues. It comprises a closely related group of genes that contribute to the regulation of various functions by encoding regulatory proteins. For example, the ZBED6 gene is involved in the regulation of diverse phenotypic effects. ZBED6 binds to the conserved target motif of insulin-like growth factor 2 and inhibits its expression, thereby promoting cell proliferation, growth and development in placental mammals (3). Furthermore, conflicting phenotypic changes were induced by the inactivation of ZBED6 in HCT116 and RKO human colorectal cancer cell lines, with consequences of reduced and increased growth, respectively, indicating that ZBED6 exhibits transcriptional modulating properties, and that the effect of ZBED6 on tumor development is dependent on the transcriptional state and genetic background of its target genes (4). The ZBED3 protein interacts with axin, which is vital for Wnt/β-catenin signal modulation in mammalian carcinogenesis and embryogenesis (5). Notably, Fan et al (6) reported higher expression levels of ZBED3 in cancer tissues compared with normal lung tissues and demonstrated that ZBED3 expression levels have clinicopathological significance. Downregulation of ZBED3 by small interfering RNA significantly inhibits expression of p120ctn-1 and β-catenin in lung cancer cells; these results indicate that lung cancer cell invasion may be induced by ZBED3, which functions by regulating p120ctn-1 and β-catenin (6). Therefore, ZBED3 has potential application in the management of cancer, particularly non-small cell lung cancer. Furthermore, ZBED4 is restricted in glial Müller cells and the cone photoreceptors of the human retina (7). It binds to DNA and RNA sequences and effectively affects the transcription process of genes expressed in the retina via G-rich promoters (8).

ZBED1 was identified as a human homolog of Drosophila DNA replication-related element-binding factor (DREF) via BLAST search. Also known as human DREF, Activator (Ac)-like transposable element, TRAMP and KIAA0785, ZBED1 has been found to play a critical role in cell proliferation via the regulation of gene expression (9). As ZBED1 has similar structural and functional properties to DREF, the present review comprehensively describes recent progress on the origin, structure and functions on ZBED1, specifically highlights the similarities and differences between ZBED1 and DREF, and discusses future research directions.

A large proportion of vertebrate genomes consist of eukaryotic genome components and transposable elements (TEs), such as DNA transposons and retrotransposons (10–12). Several genes, particularly those that possess rapidly evolving coding sequence properties, have been shown to contain functionally important TEs that are involved in gene expression and regulatory changes (11,13,14). Notably, a quarter of analyzed human promoter regions have been found to have TE-derived sequences that potentially function as alternative promoters in several genes (13). TEs contribute entire functional genes to the host genome through molecular domestication (11,15,16). Domesticated TEs, which are immobile, often exist as single-copy orthologs within the genomes of associated organisms (15). Since DNA transposons encode multi-domain proteins with diverse functions, such as protein- and DNA-binding affinity, they may be suitable for domestication to perform host functions.

The hAT transposons and their associated domesticated sequences form a large superfamily that is divided into Buster and Ac families. These two families exhibit distinct target-site selections and were named according to the first identified transposon or transposon-like sequence in each family (17). Through phylogenetic methodology, Hayward et al (18) demonstrated that ZBED5, ZBED7, ZBED8 and ZBED9 are associated with the Buster family and are distinct from other ZBEDs. The remaining ZBEDs form two monophyletic clades within the Ac transposon family. Notably, ZBED2, ZBED3, ZBED4, ZBED6 and ZBEDX form a monophyletic group with C7ORF29 and differ from ZBED1 (Fig. 1). The ZBEDs exhibit structural similarity via the zinc finger domain that functions in DNA binding. Closely related ZBED molecules regulate a variety of different host functions, indicating that ZBED protein domains are particularly suitable for controlling host functions.

A palindromic 8 base-pair (bp) sequence 5′-TATCGATA was identified as being common to the promoter regions of the proliferating cell nuclear antigen (PCNA) and DNA polymerase α genes in Drosophila (19). This sequence is known as the DNA replication-related element (DRE) and is vital for transcriptional activation. Subsequently, several methods, including band mobility shift assays, were used to identify specific DREF (20), and the cDNA of DREF was then cloned (21). Notably, DREF was found to comprise a polypeptide with 709 amino acid (aa) residues. The DREF gene of Drosophila virilis (D. virilis) has been shown to share 71% of its aa sequence identity with its D. melanogaster homolog, with three highly conserved regions (CRs) at the aa positions 14–182 (CR1; identity, 86.4%), 432–568 (CR2; identity, 86.1%) and 636–730 (CR3; identity, 83.3%) of the D. virilis DREF (22).

DREF is proposed to have originated from a combination of the amino-terminal boundary element-associated factor (BEAF) and DREF (BED) zinc finger domain protein and the carboxy-terminal hATC domain (23). Aravind (24) conducted sequence analyses that led to the prediction of protein signature C_X2C_XNH_X3-5(H/C) for the BED finger, a name derived from DREF protein and domesticated Drosophila BEAF. The BED domain forms the zinc finger common to fungal, animal and plant proteins. This domain has been postulated to originate from transposons in cellular genes or to have been acquired for the cellular functions of transposases at independent occasions. A domain of BED zinc finger containing 50–60 aa residues has been found to contain a characteristic motif with two highly conserved aromatic residues. It has a shared pattern of histidines and cysteines that is considered to create a DNA-binding zinc finger domain. Furthermore, the BED domains of BEAF and DREF have been reported to exhibit DNA-binding properties (21,25).

ZBED1 comprises a polypeptide of 694 aa residues that has 21% similarity and 22% identity when compared with DREF (9). Three CRs between D. virilis and D. melanogaster as aforementioned have aa sequences highly similar to those of the ZBED1 polypeptide, particularly the CR1 region, which is essential for DRE-binding and dimerization. The ZBED1 binding sequence [hDRE; 5′-TGTCG(C/T)GA(C/T)A] was identified using the CASTing method and found to overlap with the DREF (5′-TATCGATA) sequence (9). Furthermore, the 6-bp sequence 5′-TCG(C/T)GA at the center of ZBED1 was indicated to serve an important role in ZBED1 binding (9). Two regions of ZBED1, CR1 and CR3, correspond with two domains that are conserved within the family, namely the amino-terminal BED zinc finger (aa 23–72) and the carboxyl-terminal hATC domain (26). The BED zinc finger is regarded as a DNA-binding domain of chromatin boundary element-binding transposase (24), whereas the hATC domain of hAT transposase family members is considered as the dimerization domain, as assessed through in vitro cross-linking experiments and yeast two-hybrid assays using Ac and housefly Hermes family members (27,28).

The DNA-binding protein ZBED1 has granular structures and is predominantly distributed in the nucleus (9). A study by Yamashita et al (26) explored the mechanism of action of ZBED1 using detailed mutagenesis analyses to investigate the functions of the hATC domain. Trp-590, Trp-591 and Leu-601, which are highly conserved hydrophobic aa residues in hATC domains, were found to be crucial for the in vivo self-association of ZBED1. Furthermore, through substitution and truncated mutant evaluation, it was found that the hATC domain (aa 571–651) has two regions with distinct functions. The first region, namely the amino-terminal region aa 571–624, is required for various processes, including ZBED1 DNA-binding, nuclear accumulation and self-association. The second region, namely the carboxyl-terminal region aa 625–651, is vital for granular pattern formation and self-association. These findings indicate that ZBED1 self-association via the hATC domain is required for nuclear accumulation prior to nuclear importation. Furthermore, the aa 652–694 region has been identified to contain highly ordered complexes of ZBED1 binding sequences, whereas the aa 520–551 region is a classical nuclear localization signal (Fig. 2).

Matsukage et al (29) used bioinformatics analysis to determine the type and number of genes regulated by the DRE/DREF system. They established that 456 DRE sequences and 156 genes with DRE sequences are <1 kb upstream of their transcription initiation sites. Most of these genes are associated with processes required for cell proliferation (30), including chromatin remodeling, cell cycle regulation and protein metabolism, while others are associated with apoptosis and differentiation. This indicates that the DRE/DREF system functions as a regulator of several cell proliferation-associated genes (Fig. 3). Ohshima et al (9) searched the GenBank^® and EMBL databases to identify genes controlled by ZBED1 protein. Through BLAST analysis, they found >500 TGTCG(C/T)GA(T/C)A-like sequences in the human genome. Notably, ZBED1 binding sequences exist in a series of genes involved in DNA synthesis (DNA replication) and repair, protein synthesis, regulation of chromatin structure and cell cycle regulation, which seems to be consistent with DREF (31), as some of these genes have been shown to be controlled by the DRE/DREF system (20,32–35). These findings indicate that ZBED1 is a potential functional homolog of Drosophila DREF and can regulate the expression of genes involved in cell proliferation via a similar mechanism.

A notable study indicates that DREF preferentially binds to and activates housekeeping enhancers that are located closely to ubiquitously expressed genes with specificity to its core promoter, and suggests that the DRE motif is required and sufficient for housekeeping enhancer function (36). The CGCG sequence is central to the ZBED1 binding sequence TGTCGCGACA that occurs mostly in promoter regions of housekeeping genes within the mammalian genome, suggesting that ZBED1 could regulate numerous housekeeping genes with CpG islands (37).

To examine whether ZBED1 regulates human DNA replication-related genes, Ohshima et al (9) assessed the histone H1 gene, the expression of which is stringently coupled with DNA replication. This gene has a single 10-bp sequence in its promoter region that completely matches with the ZBED1 binding sequence (77,78). Co-transfection experiments indicate that the activity of the human histone H1 gene promoter is stimulated when it specifically binds to ZBED1, and RNA interference experiments targeting ZBED1 indicate that transcription of the histone H1 gene is likely under the control of ZBED1 in the G₁/S phase during the cell cycle (9).

Notably, a study established that 22 of the 79 human ribosomal protein (RP) genes have sequences similar to that of hDRE in their transcriptional start sites <200 bp upstream. The study also demonstrated that ZBED1 potentially binds to the hDRE-like sequences in the RP genes in vivo and in vitro, and the hDRE-like sequences function as positive elements for RP gene transcription (79). In a similar manner to ZBED1 expression, RP gene expression is enhanced in the late G₁ to S phases, whereas a reduction in the expression of the RP gene occurs when ZBED1 is depleted, thus impairing cell proliferation and the G₁/S transition in normal human fibroblasts. These findings indicate that ZBED1 significantly regulates cell proliferation at the transcriptional level via the histone H1 and several RP genes. Also, ZBED1 has a key role in the cell cycle-dependent regulation of these genes. Furthermore, a study by Yamashita et al (80) explored the underlying transcriptional regulation mechanism and demonstrated that ZBED1 has a slight ubiquitin-like modifier (SUMO) ligase activity and may stimulate transcriptional activation by specifically SUMOylating Mi2α. This results in the dissociation of Mi2α from the gene loci, thus maintaining active states of housekeeping target genes for ZBED1.

The present review highlights that Drosophila DREF has different structural features than its human ortholog ZBED1. However, there are notable similarities between the two species based on protein functions associated with, for example, the regulation of DNA replication, chromatin structure, protein synthesis and the cell cycle. Furthermore, ZBED1 potentially participates in the regulation of the expression of housekeeping genes within the mammalian genome. Also, the potential regulatory sites of different genes for DREF binding are likely to be conserved between Drosophila and humans. Therefore, numerous other genes may be regulated similarly in humans via the ZBED1 pathway. However, further research is essential to identify substrates of ZBED1 other than Mi2α in order to clarify the underlying molecular mechanism and comprehensively analyze the effect of ZBED1 in humans. Additionally, ZBED3 and ZBED6 are associated with tumor development. A recent study has shown that ZBED1 is upregulated in gastric cancer cells, thereby promoting their proliferation and decreasing their chemosensitivity, although the molecular mechanism requires full elucidation (81). Therefore, it is concluded that ZBED1 may be a novel cancer biomarker and therapeutic target in the future. However, further investigation is required to verify this.