An Alu-linked repetitive sequence corresponding to 280 amino acids is expressed in a novel bovine protein, but not in its human homologue

Cfdp1 Is Essential for Cardiac Development and Function

Cardiovascular diseases (CVDs) are the prevalent cause of mortality worldwide. A combination of environmental and genetic effectors modulates the risk of developing them. Thus, it is vital to identify candidate genes and elucidate their role in the manifestation of the disease. Large-scale human studies have revealed the implication of Craniofacial Development Protein 1 (CFDP1) in Coronary Artery Disease (CAD). CFDP1 belongs to the evolutionary conserved Bucentaur (BCNT) family, and to date, its function and mechanism of action in Cardiovascular Development are still unclear. We utilized zebrafish to investigate the role of cfdp1 in the developing heart due to the high genomic homology, similarity in heart physiology, and ease of experimental manipulations. We showed that cfdp1 was expressed during development, and we tested two morpholinos and generated a cfdp1 mutant line. The cfdp1-/- embryos developed arrhythmic hearts and exhibited defective cardiac performance, which led to a lethal phenotype. Findings from both knockdown and knockout experiments showed that abrogation of cfdp1 leads to downregulation of Wnt signaling in embryonic hearts during valve development but without affecting Notch activation in this process. The cfdp1 zebrafish mutant line provides a valuable tool for unveiling the novel mechanism of regulating cardiac physiology and function. cfdp1 is essential for cardiac development, a previously unreported phenotype most likely due to early lethality in mice. The detected phenotype of bradycardia and arrhythmias is an observation with potential clinical relevance for humans carrying heterozygous CFDP1 mutations and their risk of developing CAD.

Role of a DEF/Y motif in histone H2A-H2B recognition and nucleosome editing

The SWR complex edits the histone composition of nucleosomes at promoters to facilitate transcription by replacing the two nucleosomal H2A-H2B (A-B) dimers with H2A.Z-H2B (Z-B) dimers. Swc5, a subunit of SWR, binds to A-B dimers, but its role in the histone replacement reaction was unclear. In this study, we showed that Swc5 uses a tandem DEF/Y motif within an intrinsically disordered region to engage the A-B dimer. A 2.37-Å X-ray crystal structure of the histone binding domain of Swc5 in complex with an A-B dimer showed that consecutive acidic residues and flanking hydrophobic residues of Swc5 form a cap over the histones, excluding histone-DNA interaction. Mutations in Swc5 DEF/Y inhibited the nucleosome editing function of SWR in vitro. Swc5 DEF/Y interacts with histones in vivo, and the extent of this interaction is dependent on the remodeling ATPase of SWR, supporting a model in which Swc5 acts as a wedge to promote A-B dimer eviction. Given that DEF/Y motifs are found in other evolutionary unrelated chromatin regulators, this work provides the molecular basis for a general strategy used repeatedly during eukaryotic evolution to mobilize histones in various genomic functions.

The True Story of Yeti, the "Abominable" Heterochromatic Gene of Drosophila melanogaster

The Drosophila Yeti gene (CG40218) was originally identified by recessive lethal mutation and subsequently mapped to the deep pericentromeric heterochromatin of chromosome 2. Functional studies have shown that Yeti encodes a 241 amino acid protein called YETI belonging to the evolutionarily conserved family of Bucentaur (BCNT) proteins and exhibiting a widespread distribution in animals and plants. Later studies have demonstrated that YETI protein: (i) is able to bind both subunits of the microtubule-based motor kinesin-I; (ii) is required for proper chromosome organization in both mitosis and meiosis divisions; and more recently (iii) is a new subunit of dTip60 chromatin remodeling complex. To date, other functions of YETI counterparts in chicken (CENtromere Protein 29, CENP-29), mouse (Cranio Protein 27, CP27), zebrafish and human (CranioFacial Development Protein 1, CFDP1) have been reported in literature, but the fully understanding of the multifaceted molecular function of this protein family remains still unclear. In this review we comprehensively highlight recent work and provide a more extensive hypothesis suggesting a broader range of YETI protein functions in different cellular processes.

Dual function of Swc5 in SWR remodeling ATPase activation and histone H2A eviction

The chromatin remodeler SWR deposits histone H2A.Z at promoters and other regulatory sites via an ATP-driven histone exchange reaction that replaces nucleosomal H2A with H2A.Z. Simultaneous binding of SWR to both H2A nucleosome and free H2A.Z induces SWR ATPase activity and engages the histone exchange mechanism. Swc5 is a conserved subunit of the 14-polypeptide SWR complex that is required for the histone exchange reaction, but its molecular role is unknown. We found that Swc5, although not required for substrate binding, is required for SWR ATPase stimulation, suggesting that Swc5 is required to couple substrate recognition to ATPase activation. A biochemical complementation assay was developed to show that a unique, conserved domain at the C-terminus of Swc5, called Bucentaur (BCNT), is essential for the histone exchange activity of SWR, whereas an acidic region at the N-terminus is required for optimal SWR function. In vitro studies showed the acidic N-terminus of Swc5 preferentially binds to the H2A–H2B dimer and exhibits histone chaperone activity. We propose that an auxiliary function of Swc5 in SWR is to assist H2A ejection as H2A.Z is inserted into the nucleosome.

Mammalian Bcnt/Cfdp1, a potential epigenetic factor characterized by an acidic stretch in the disordered N-terminal and Ser250 phosphorylation in the conserved C-terminal regions

We characterized the mammalian Bcnt/Cfdp1 (Bucentaur/craniofacial developmental protein 1) protein, a potential epigenetic factor, by showing that an acidic stretch in the N-terminal region and Ser²⁵⁰ phosphorylation in the C-terminal region are critical for its anomalous SDS/PAGE mobility.

The BCNT (Bucentaur) superfamily is classified by an uncharacteristic conserved sequence of ∼80 amino acids (aa) at the C-terminus, BCNT-C (the conserved C-terminal region of Bcnt/Cfdp1). Whereas the yeast Swc5 and Drosophila Yeti homologues play crucial roles in chromatin remodelling organization, mammalian Bcnt/Cfdp1 (craniofacial developmental protein 1) remains poorly understood. The protein, which lacks cysteine, is largely disordered and comprises an acidic N-terminal region, a lysine/glutamic acid/proline-rich 40 aa sequence and BCNT-C. It shows complex mobility on SDS/PAGE at ∼50 kDa, whereas its calculated molecular mass is ∼33 kDa. To characterize this mobility discrepancy and the effects of post-translational modifications (PTMs), we expressed various deleted His–Bcnt in E. coli and HEK cells and found that an acidic stretch in the N-terminal region is a main cause of the gel shift. Exogenous BCNT/CFDP1 constitutively expressed in HEK clones appears as a doublet at 49 and 47 kDa, slower than the protein expressed in Escherichia coli but faster than the endogenous protein on SDS/PAGE. Among seven in vivo phosphorylation sites, Ser²⁵⁰, which resides in a region between disordered and ordered regions in BCNT-C, is heavily phosphorylated and detected predominantly in the 49 kDa band. Together with experiments involving treatment with phosphatases and Ser²⁵⁰ substitutions, the results indicate that the complex behaviour of Bcnt/Cfdp1 on SDS/PAGE is caused mainly by an acidic stretch in the N-terminal region and Ser²⁵⁰ phosphorylation in BCNT-C. Furthermore, Bcnt/Cfdp1 is acetylated in vitro by CREB-binding protein (CBP) and four lysine residues including Lys²⁶⁸ in BCNT-C are also acetylated in vivo, revealing a protein regulated at multiple levels.

Characterization of the mouse CP27 promoter and NF-Y mediated gene regulation

The cp27 gene is a highly conserved and unique gene with important roles related to craniofacial organogenesis. The present study is a first analysis of the CP27 promoter and its regulation. Here, we have cloned the promoter of the mouse cp27 gene, examined its transcriptional activity, and identified transcription factor binding sites in the proximal promoter region. Two major transcription start sites were mapped adjacent to exon 1. Promoter function analysis of the 5' flanking region by progressive 5' deletion mutations localized transcription repression elements between -1993bp and -969bp and several positive elements between -968bp and the preferred transcription start site. EMSA and functional studies indicated two function-cooperative CCAAT boxes and identified the NF-Y transcription factor as the CCAAT activator controlling transactivation of the CP27 promoter. In addition, this study demonstrated that for its effective binding and function, NF-Y required not only the minimal DNA segment length identified by deletion studies, but also a defined nucleotide sequence in the distal 3' flanking region of the CP27 proximal promoter CCAAT box. These results provide a basis for our understanding of the specific regulation of the cp27 gene in the NF-Y-mediated gene transcription network.

Multiple duplication of the bucentaur gene family, which recruits the APE-like domain of retrotransposon: Identification of a novel homolog and distinct cellular expression

The p97bcnt/cfdp2 is a ruminant-specific gene created by a combination of gene duplication of ancestral bcnt (bucentaur) or cfdp1 (craniofacial developmental protein 1), bcnt/cfdp1, and the insertion of a retrotransposable element-1 (RTE). As a result, p97Bcnt recruits the whole apurinic/apyrimidinic endonuclease (APE)-like domain of RTE in the middle of the molecule (RTE domain) as a region encoded by an exon. In addition, p97Bcnt contains two intramolecular repeats (IRs) of 40 amino acids each in the C-terminal region, whereas Bcnt/Cfdp1 contains one IR. We have identified an additional bovine homolog with a structure highly similar to p97Bcnt, designated p97Bcnt2, which contains three IRs. p97bcnt2 is located in tandem with bcnt/cfdp1 and p97bcnt within a 177-kb range on bovine chromosome 18, a syntenic region of human chromosome 16. The gene product is expressed as a protein with an apparent molecular mass of 102 kDa. The phylogenetic tree strongly suggests that p97bcnt-2 forms a third clade of the bcnt family and that the first duplication of the IR unit occurred prior to the divergence of p97bcnt and p97bcnt-2. To address the question of whether these bcnt members have distinct functions, we first examined the expression and localization of the p97Bcnt family members. p97Bcnt is substantially expressed in many tissues involved in responses to external and internal stress. In the testis, p97Bcnt localizes preferentially in the nuclei of spermatozoa, while Bcnt/Cfdp1 localizes predominantly in the cytosol of Leydig cells and some spermatogenic cells, implying that at least these two molecules of the Bcnt family play different functional roles. These results provide evidence for the direct contribution of RTE to gene diversity to form gene families that may support cellular function.

A tandem gene duplication followed by recruitment of a retrotransposon created the paralogous bucentaur gene (bcntp97) in the ancestral ruminant

Retrotransposable element-1 (RTE-1) is a class of long interspersed nucleotide elements that contain in its open reading frame an apurinic/apyrimidinic endonuclease domain (AP-END) and a reverse transcriptase domain. Ruminants have a clade-specific RTE-1 (BovB/RTE). The bovine bcnt gene (bucentaur or craniofacial developmental protein 1) has a duplicated paralog (bcntp97) in tandem that recruited an AP-END of BovB/RTE as a coding exon (RTE exon). We obtained sequence of the bcnt region from several animals and showed that other ruminants also have the bcntp97 with a conserved RTE exon while camels and pigs do not. Genomic Southern analysis showed that camels and pigs have multiple bcnt-related sequences but not BovB/RTE which bovines and lesser mouse deer have abundantly. These results indicate that the bcnt gene duplication followed by the creation of bcntp97 including recruitment of the RTE exon occurred in the ancestral ruminant about 55 MYA. The indication of time frame is supported by a phylogenetic analysis. Taken together with a result of differential tissue expression of the two bcnt paralogs, we conclude that bcntp97 was created concurrently with the early radiation of BovB/RTE in an ancestral ruminant and then acquired a novel function.

SINEs and LINEs: symbionts of eukaryotic genomes with a common tail

Many SINEs and LINEs have been characterized to date, and examples of the SINE and LINE pair that have the same 3' end sequence have also increased. We report the phylogenetic relationships of nearly all known LINEs from which SINEs are derived, including a new example of a SINE/LINE pair identified in the salmon genome. We also use several biological examples to discuss the impact and significance of SINEs and LINEs in the evolution of vertebrate genomes.

Ovarian-specific expression of a new gene regulated by the goat PIS region and transcribed by a FOXL2 bidirectional promoter

Studies on XX sex reversal in polled goats (PIS mutation: polled intersex syndrome) have led to the discovery of a female-specific locus crucial for ovarian differentiation. This genomic region is composed of at least two genes, FOXL2 and PISRT1, sharing a common transcriptional regulatory region, PIS. In this paper, we describe a third gene, PFOXic (promoter FOXL2 inverse complementary), located near FOXL2 in the opposite orientation. This gene composed of five exons encodes a 1723-bp cDNA, enclosing two repetitive elements in its 3' end. PFOXic mRNA encodes a putative protein of 163 amino acids with no homologies in any of the databases tested. The transcriptional expression of PFOXic is driven by a bidirectional promoter also enhancing FOXL2 transcription. In goats, PFOXic is expressed in developing ovaries, from 36 days postcoitum until adulthood. Ovarian-specific expression of PFOXic is regulated by the PIS region. PFOXic is found conserved only in Bovidae. But, a human gene located in the opposite orientation relative to FOXL2 can be considered a human PFOXic. Finally, we discuss evidence arguing for regulation of the level of FOXL2 transcription via the bidirectional promoter and the level of transcription of PFOXic.

A novel Giraffidae-specific interspersed repeat with a microsatellite, originally found in an intron of a ruminant paralogous p97bcnt gene

The ruminant-specific p97bcnt gene (bcntp97) is a paralogous gene that includes a region derived from a retrotransposable element 1 (RTE-1). The region comprises an exon (RTE-1 exon) encoding 325 amino acids in the middle of the p97bcnt protein. To understand how the bcntp97 paralog evolved, we examined its organization in several ruminants. We found a 700-base pair (bp) insert in the 5' intron of the RTE-1 exon in giraffe bcntp97. This insert is missing in the corresponding regions of bovine and sika deer. Furthermore, the sequence of the insert is interspersed in the genome of giraffe but not bovine and also contains a (GA)n microsatellite. A highly homologous insert harboring significantly different (GA)n microsatellite was detected in the corresponding region of okapi bcntp97. Therefore, the interspersed fragments with (GA)n microsatellite might serve as a marker for tracking how duplicated genes evolve in a family-specific manner.

Developmental changes in the fetal pig transcriptome

Growth and development of pig fetuses is dependent on the coordinated expression of multiple genes. Between 21 and 45 days of gestation, fetuses experience increasing growth rates that can result in uterine crowding and increased mortality. We used differential display reverse transcription-PCR (DDRT-PCR) to identify differentially expressed genes in pig fetuses at 21, 35, and 45 days of gestation. Pig cDNAs were identified with homologies to CD3 gamma-subunit, collagen type XIV alpha1, complement component C6, craniofacial developmental protein 1, crystallin-gammaE, DNA binding protein B, epsilon-globin, formin binding protein 2, ribosomal protein L23, small acidic protein, secreted frizzled related protein 2, titin, vitamin D binding protein, and two hypothetical protein products. Two novel expressed sequence tags (ESTs) were also identified. Expression patterns were confirmed for eight genes, and spatiotemporal expression of three genes was evaluated. We identified novel transcriptome changes in fetal pigs during a period of rapid growth. These changes involved genes with a spectrum of proposed functions, including musculoskeletal growth, immune system function, and cellular regulation. This information can ultimately be used to enhance production efficiency through improved pig growth and survival.

CP27 localization in the dental lamina basement membrane and in the stellate reticulum of developing teeth

cp27 is a novel gene involved in early vertebrate development that features a distinct protein localization pattern in developing tooth organs. During initial tooth development, CP27 was detected at the epithelial-mesenchymal interface of dental lamina stage tooth organs. At later stages of tooth development, CP27 was localized in the stellate reticulum, the oral mucosa mesenchyme, and alveolar bone. The significant changes in the highly restricted distribution pattern suggest that CP27 might be involved at several different levels during tooth development.

Gene organization of bovine BCNT that contains a portion corresponding to an endonuclease domain derived from an RTE-1 (Bov-B LINE), non-LTR retrotransposable element: duplication of an intramolecular repeat unit downstream of the truncated RTE-1

BCNT (a protein named after Bucentaur or craniofacial development protein 1) has a unique structure in Ruminantia. Bovine BCNT contains a region of the endonuclease domain derived from a truncated RTE-1 (previously called Bov-B LINE), a non-LTR retrotransposable repetitive element, and two repeat units (intramolecular repeat, IR) each with 40 amino acids in the C-terminal region. In contrast the human and mouse BCNT proteins contain one repeat unit and lack the RTE-1-derived portion. The 3' UTR of bovine bcnt cDNA also contains an approximately 300-bp portion homologous to the 3'-part of RTE-1. We examined the bovine bcnt genomic DNA sequence to understand how the bovine bcnt gene has been organized. The sequence of 3' UTR homologous portion was found to more closely resemble the Art2 element than the bovine RTE-1. By PCR screening a bovine/hamster hybrid somatic cell panel, the bovine bcnt gene was mapped to chromosome 18, syntenic human chromosome 16q on which human BCNT is located. The bcnt genomic DNA sequence corresponding to the cDNA downstream of a RTE-1 derived portion reveals that each IR unit is flanked by both 5'-side and 3'-side introns and that 3'-UTR consists of one exon. The alignment of the above sequence with a bovine RTE-1 did not show any significant homology downstream of the endonuclease domain. On the other hand, the alignment of the intron sequences with each other revealed that the six sequential homologous segments ranging in size from 40 to 453 bp existed over a 1 kb long sequence between both the 5'- and 3'-side introns flanking each bovine IR unit. In addition, both the 174-bp of 5'-side intron and 80-bp of 3'-side intron neighboring each 120-bp IR exon are significantly homologous among the two bovine IRs, human IR and mouse IR. These results suggest that a truncated bovine RTE-1 was inserted into the intron upstream of an IR unit of an ancestor bcnt gene and that a duplication of a relatively long region that includes IR occurred in the bovine genome.

Molecular evolution of Bov-B LINEs in vertebrates

Since their discovery in family Bovidae (bovids), Bov-B LINEs, believed to be order-specific SINEs, have been found in all ruminants and recently also in Viperidae snakes. The distribution and the evolutionary relationships of Bov-B LINEs provide an indication of their origin and evolutionary dynamics in different species. The evolutionary origin of Bov-B LINE elements has been shown unequivocally to be in Squamata (squamates). The horizontal transfer of Bov-B LINE elements in vertebrates has been confirmed by their discontinuous phylogenetic distribution in Squamata (Serpentes and two lizard infra-orders) as well as in Ruminantia, by the high level of nucleotide identity, and by their phylogenetic relationships. The direction of horizontal transfer from Squamata to the ancestor of Ruminantia is evident from the genetic distances and discontinuous phylogenetic distribution of Bov-B LINE elements. The ancestor of Colubroidea snakes has been recognized as a possible donor of Bov-B LINE elements to Ruminantia. The timing of horizontal transfer has been estimated from the distribution of Bov-B LINE elements in Ruminantia and the fossil data of Ruminantia to be 40-50 My ago. The phylogenetic relationships of Bov-B LINE elements from the various Squamata species agrees with that of the species phylogeny, suggesting that Bov-B LINE elements have been stably maintained by vertical transmission since the origin of Squamata in the Mesozoic era.

Cloning, gene expression, and characterization of CP27, a novel gene in mouse embryogenesis

We report the full-length sequencing, tissue-specific expression, and immunolocalization of cp27, a novel gene in mouse embryogenesis. The cp27 gene was isolated and cloned from a mouse E11 lambdagt11 library using a peptide antibody that recognized a distinct expression pattern in mouse craniofacial development. The cp27 gene contains an open reading frame of 295 amino acids corresponding to a predicted molecular mass of 33kDa. On Western blots, a polyclonal antibody against CP27 detected a single epitope at 27kDa. The putative CP27 protein has an isoelectric point of 4.75 and features a distinct helix-loop-helix structure according to prediction algorithms. We have cloned the human cp27 gene and mapped it to a locus on the human chromosome 16 which is in proximity to several loci associated with inherited craniofacial diseases such as fanconi anemia type A. Northern blot analysis of RNA from multiple mouse tissues demonstrated high levels of expression in developing mouse teeth, heart, lung, and liver of a single transcript of approx. 1. 8kbp. In situ hybridization using a radioactive RNA probe resulted in distinct signals in the developing neuroepithelium, cerebellum, heart, lung, liver, teeth, salivary glands, and periosteum of developing bones. Immunohistochemical staining of developing mouse tissues detected epitopes specific for CP27 in the mesenchyme surrounding the primary brain vesicles, in basement membranes, in the periosteum, in salivary glands, and in the stellate reticulum of teeth. Thus, CP27 represents a unique gene product involved in mouse embryogenesis.

Partial nuclear localization of a bovine phosphoprotein, BCNT, that includes a region derived from a LINE repetitive sequence in Ruminantia

BCNT, named after Bucentaur, is a protein that contains a 324-amino-acid region derived from part of a long interspersed DNA sequence element (LINE) in Ruminantia. However, the unique portion is completely missing in human and mouse BCNTs. Since no significant information on their function has been obtained by homology search, we at first examined cellular localization and biochemical characteristics of bovine BCNT to get a hint on its function. Subcellular fractionation and immunohistochemical analyses using a normal bovine epithelial cell line and bovine brain revealed that a significant amount of bovine BCNT is localized in the nuclei, while the major portion is present in the cytosol. Furthermore, it was shown that bovine BCNT is a phosphoprotein and that both bovine and human BCNTs are phosphorylated by casein kinase II in vitro. These results show that BCNTs consist of a unique family, probably a substrate of casein kinase II, which may contribute further to the understanding of gene evolution.

Existence of a bovine LINE repetitive insert that appears in the cDNA of bovine protein BCNT in ruminant, but not in human, genomes

A novel protein, BCNT, originally isolated from bovine brain and named after Bucentaur, contains an internal portion that is translated from part of bovine LINE repetitive sequence (Bov-B LINE). Human cDNA highly homologous to the bovine bcnt (bbcnt) cDNA has been isolated but does not contain a sequence similar to the Bov-B LINE insert (Nobukuni, T., Kobayashi, M., Omori, A., Ichinose, S., Iwanaga, T., Takahashi, I., Hashimoto, K., Hattori, S., Kaibuchi, K., Miyata, Y., Masui, T., Iwashita, S., 1997. An Alu-linked repetitive sequence corresponding to 280 amino acids is expressed in a novel bovine protein, but not in its human homologue. J. Biol. Chem. 272, 2801-2807). In this study, we conducted a polymerase chain reaction analysis to investigate whether such a Bov-B LINE insert is present in bcnt orthologs in other animals and in the genomic sequence of the human BCNT (hBCNT) gene. The results indicate that the Bov-B LINE insert is present in the genomic sequences of bcnt orthologs from sheep, goats, axis deer, and mouse deer (chevrotain), that is in Ruminantia, but not in pigs or human. Analysis of the bbcnt genomic sequence around the Bov-B LINE insert revealed a large part of the inserted Bov-B LINE sequence to be included in an exon; this is followed by a 54-nucleotide sequence that is highly homologous to Bov-B LINE in the 3'-side intron. The hBCNT gene was isolated and found to consist of seven exons and six introns, among which the intron corresponding to the Bov-B LINE insertion site in the bbcnt genome is 16.5kb in length with no sequence similar to Bov-B LINE. Based on these results, it seems likely that the Bov-B LINE insert is derived from a long Bov-B LINE repetitive sequence transposed to an ancestral bcnt gene in Ruminantia and reformed as a new exon through new splicing sites in the transposed sequence.