Identification and characterization of rat Ror1 and Ror2 genes in silico

Frizzled-1 (FZD1), FZD2, FZD3, FZD4, FZD5, FZD6, FZD7, FZD8, FZD9 and FZD10 are seven-transmembrane-type WNT receptors with extracellular Frizzled (Fz) domain. ROR1, ROR2 and MUSK are receptor-type tyrosine kinases with extracellular Fz domain, while MFRP is type II transmembrane protein with extracellular Fz domain. ROR1, ROR2, MUSK and MFRP are predicted to transduce or regulate WNT signaling. Here, we identified and characterized rat Ror1 and Ror2 genes by using bioinformatics. Rat Ror1 gene was located within AC108320.4, AC098031.5 and AC129856.4 genome sequences, while rat Ror2 gene was located within AC139870.3 and AC123431.4 genome sequences. Exon-intron structure was conserved between rat Ror1 and Ror2 genes, consisting of nine exons. Rat Ror1 mRNA was expressed in fetal ventricle, while rat Ror2 mRNA was expressed in cerebral cortex, hypothalamus, dorsolateral prostate, and chondrosarcoma. Rat Ror1 (937 aa) and Ror2 (943 aa) showed 56.5% total-amino-acid identity. Rat Ror1 and Ror2 were type I transmembrane proteins with extracellular Immunoglobulin-like (Ig), Fz, Kringle (KR) domains, and cytoplasmic Juxta-membrane (JM), Tyrosine kinase (TK), and Ror homology C-terminal (RORHC) domains. Casein kinase Iepsilon-binding RORHC domain was conserved among vertebrate Ror1 and Ror2 homologs, but not in Drosophila Ror. Thr 582 within TK domain was conserved among mammalian Ror family members, and was predicted as Casein kinase I phosphorylation site. This is the first report on rat Ror1 and Ror2 genes as well as on molecular evolution of Ror1 and Ror2 homologs.     

Identification and characterization of human FCHSD1 and FCHSD2 genes in silico

FNBP1 and FNBP2 are SH3-type Formin-binding proteins. FNBP1 consists of FCH, FBH, HR1 and SH3 domains, while FNBP2 consists of FCH, FBH, RhoGAP and SH3 domains. Here, we identified novel genes FCHSD1 and FCHSD2, which were distantly related to FNBP1 and FNBP2. FCHSD1 and FCHSD2 genes with conserved exon-intron structure were located at human chromosome 5q31.3 and 11q13.4, respectively. Complete coding sequence of human FCHSD1 was derived from FLJ00007 (NM_033449.1) cDNA. KIAA0769 (NM_014824.1), encoding N-terminally truncated 684-aa protein, was an aberrant human FCHSD2 cDNA with a frame shift due to skipping of 98-bp exon 2. Complete coding sequence of human FCHSD2 cDNA was determined by assembling CF995054 EST and KIAA0769 cDNA. A030002D08Rik (NM_175684.3) was the representative mouse Fchsd1 cDNA, while BC034086 (NM_199012.1) was a variant mouse Fchsd2 cDNA with an insertion of 72-bp additional exon. CG4684 was the Drosophila homolog of mammalian FCHSD family genes. Human FCHSD1 (690 aa) showed 41.7% total-amino-acid identity with human FCHSD2 (740 aa), and 91.0% total-amino-acid identity with mouse Fchsd1. Human FCHSD2 showed 96.5% total-amino-acid identity with mouse Fchsd2. Mammalian FCHSD family proteins shared the common domain structure consisting of FCH, FBH, two SH3 and C-terminal Proline-rich domains. FCHSD family proteins (FCHSD1 and FCHSD2), FNBP1 family proteins (FNBP1, FNBP1L and TRIP10/CIP4) and FNBP2 family proteins (FNBP2, ARHGAP13/SRGAP1, ARHGAP14/SRGAP2 and ARHGAP4) were found constituting the FCFBS superfamily characterized by FCH, FBH and SH3 domains. This is the first report on identification and characterization of the FCHSD family genes.     

Identification and characterization of rat Wnt6 and Wnt10a genes in silico

WNT and Hedgehog signaling pathways are implicated in various types of human cancer, such as gastric and pancreatic cancer. WNT1, WNT2, WNT2B (WNT13), WNT3, WNT3A, WNT4, WNT5A, WNT5B, WNT6, WNT7A, WNT7B, WNT8A, WNT8B, WNT9A (WNT14), WNT9B (WNT14B). WNT10A, WNT10B, WNT11 and WNT16 genes encode WNT family glycoproteins, which transduce signals through Frizzled (FZD) family receptors with extracellular WNT-binding and cytoplasmic Dishevelled-binding domains. WNT6 and WNT10A genes at human chromosome 2q35 are clustered in tail-to-head manner with an interval of <7 kb. Here, we identified and characterized rat Wnt6 and Wnt10a genes by using bioinformatics. Wnt6 and Wnt10a genes were clustered in tail-to-head manner with an interval of about 7 kb within AC127107.3 and AC132020.3 genome sequences. Rat Wnt6 gene, consisting of four exons, encoded a 365-aa protein with signal peptide, 24 conserved Cys residues, two Asn-linked glycosylation sites and an RGD motif. Rat Wnt10a gene, consisting of four exons, encoded a 417-aa protein with 24 conserved Cys residues, two Asn-linked glycosylation sites and an RGD motif. Rat Wnt6 and human WNT6 showed 97.8% total-amino-acid identity, while rat Wnt10a and human WNT10A showed 95.4% total-amino-acid identity. Promoter region was conserved between rat Wnt6 and human WNT6 genes. GATA, FOXA2, and TGIF binding sites were located within the conserved region of rat Wnt6 and human WNT6 promoters. This is the first report on rat Wnt6 and Wnt10a genes as well as on the conserved promoter region of Wnt6 orthologs.     

Identification and characterization of rat Ankrd6 gene in silico

WNT signals are transduced to the beta-catenin pathway or the planar cell polarity (PCP) pathway. Drosophila Frizzled (Fz), Starry night (Stan), Van Gogh (Vang), Prickle (Pk) and Diego (Dgo) are PCP signaling molecules. Human FZD1, FZD2, FZD3, FZD4, FZD5, FZD6, FZD7, FZD8, FZD9 and FZD10 are Fz homologs. Human CELSR1, CELSR2 and CELSR3 are Stan homologs. Human VANGL1 and VANGL2 are Vang homologs. Human PRICKLE1 and PRICKLE2 are Pk homologs. Human ANKRN6 is a Dgo homolog. Here, we identified and characterized rat Ankrd6 gene by using bioinformatics. Ankrd6 gene, consisting of 15 exons, was located within AC105547.5 genome sequence derived from rat chromosome 5q21. Rat Ankrd6 mRNA was expressed in corpus-striatum, eye, lung, and kidney. Rat Ankrd6 (714 aa) with six ankyrin (Ank) repeats and two coiled-coil regions showed 95.0, 84.2 and 53.4% total-amino-acid identity with mouse, human and zebrafish orthologs, respectively. Ser 340 of rat Ankrd6, conserved among mammalian Ankrd6 orthologs, was a protein kinase A (PKA) phosphotylation and 14-3-3 interaction site. Ank repeats are putative binding domains for Prickle1, Prickle2, Vangl1, and Vangl2. Central coiled-coil region is located within binding domain for Casein kinase I epsilon (CkIe). C-terminal coiled-coil region is located within binding domain for Axin1 and Axin2. Fourth to sixth Ank repeats of vertebrate Ankrd6 orthologs (codon 141-239) were highly conserved in Drosophila Dgo; however, two coiled-coil regions of vertebrate Ankrd6 orthologs were absent in Drosophila Dgo. Due to the molecular evolution, functions of vertebrate Ankrd6 orthologs were predicted to partially differ from those of Drosophila Dgo.     

Identification and characterization of human FHDC1, mouse Fhdc1 and zebrafish fhdc1 genes in silico

Formin homology proteins, implicated in organogenesis and carcinogenesis, are actin regulators with scaffold function. FMNL1, FMNL2, FMNL3, DIAPH1, DIAPH2, DIAPH3, DAAM1 and DAAM2 are FDD-type Formin homology proteins, while FHOD1, FHOD3, GRID2IP, Fmn1 and Fmn2 are non-FDD-type Formin homology proteins. Here, we identified human FHDC1 gene and vertebrate FHDC1 orthologs by using bioinformatics. The complete coding sequence of human FHDC1 cDNA was determined by assembling 3'-recombinated FLJ35083 chimeric cDNA and 5'-truncated KIAA1727 (AB051514.1) partial cDNA. The complete coding sequence of mouse Fhdc1 cDNA was determined by assembling 3'-truncated CD555494 EST and 5'-truncated 6330505N24 (AK031946.1) partial cDNA. The complete coding sequence of zebrafish fhdc1 cDNA was determined by assembling fhdc1 exons within zebrafish genome clone DKEY-4A14 (BX571710.4). FHDC1 gene was located at human chromosome 4q31.3, and Fhdc1 gene at mouse chromosome 3F1. Human FHDC1 (1143 aa) showed 73.3% total amino-acid identity with mouse Fhdc1 (1148 aa), and 43.4% total amino-acid identity with zebrafish Fhdc1 (1165 aa). FDCH1-FDCH5 domains were identified as novel conserved regions among vertebrate FHDC1 orthologs. Human FHDC1, mouse Fhdc1, and zebrafish Fhdc1 were non-FDD-type Formin homology proteins with FH1 and FH2 domains in the N-terminal part as well as with FDCH1, FDCH2, FDCH3, FDCH4, and FDCH5 domains in the C-terminal part. This is the first report on the identification and characterization of the human FHDC1, mouse Fhdc1 and zebrafish fhdc1 genes.     

Identification and characterization of PDZRN3 and PDZRN4 genes in silico

NUMB and NUMBL are implicated in cell fate determination through the inhibition of Notch signaling. LNX, binding to NUMB and CXADR (CAR), functions as E3 ubiquitin ligase at least for NUMB. LNX is the paralog of PDZRN1 (PDZ domain containing RING finger 1). Here, we identified two novel homologs of LNX and PDZRN1 by using bioinformatics, which were designated PDZRN3 (LNX3 or SEMCAP3) and PDZRN4 (LNX4 or SAMCAP3L), respectively. KIAA1095 cDNA (AB029018) was the representative PDZRN3 cDNA. Complete coding sequence of PDZRN4 cDNA was determined by assembling nucleotide sequences of ESTs (BF059062 and AW297403), FLJ33777 cDNA (AK091096) and IMAGE5767589 cDNA (BC040922). PDZRN4 gene, consisting of 11 exons, was found to encode two isoforms with N-terminal divergence (PDZRN4 and PDZRN4S) due to an alternative promoter. PDZRN3-CNTN3 locus at human chromosome 3p13-p12.3 and PDZRN4-CNTN1 locus at human chromosome 12q12 were paralogous regions within the human genome. PDZRN3 (1066 aa) and PDZRN4 (1036 aa) showed 59.9% total-amino-acid identity. Two bipartite nuclear localization signals (NLS) were located within the C-terminal region of PDZRN3 and PDZRN4. PR34H1 and PR34H2 domains were identified as the regions conserved among PDZRN3, PDZRN4 and Drosophila CG1783. PDZRN3 and PDZRN4 consist of RING, two PDZ, PR34H1, PR34H2 domains and two NLS, while PDZRN1 and LNX consist of RING and four PDZ domains. PDZRN family proteins were classified into the LNX-PDZRN1 subfamily and the PDZRN3-PDZRN4 subfamily. This is the first report on the PDZRN3 and PDZRN4 genes.     

Identification and characterization of LASP2 gene in silico

LASP1 (also known as MLN50) gene, located centromeric to the PPP1R1B-ERBB2-GRB7 locus on human chromosome 17q12, is amplified and over-expressed in breast cancer. Here, we identified and characterized a novel LASP1-related gene, LASP2, by using bioinformatics. Nucleotide sequence of human LASP2 cDNA was determined in silico by assembling EST BF699808 and 5'-truncated FLJ39221 cDNA. Nucleotide sequence of mouse Lasp2 cDNA was derived from 1200007O21Rik cDNA. Human LASP2 (270 aa) showed 97.4% and 63.7% total-amino-acid identity with mouse Lasp2 and human LASP1, respectively. LASP2 and LASP1 were the LASP family proteins consisting of LIM domain, Nebulin repeat, and SH3 domain. LASP2 and NEBL mRNAs were transcribed from the LASP2/NEBL gene on human chromosome 10p12 due to alternative splicing. LASP2 mRNA consists of exons 1a-4a, 24, 27, and 28 of the LASP2/NEBL gene, while NEBL mRNA consists of exons 1-28. Exon 1a-4a of the LASP2/NEBL gene were more homologous to exon 1-4 of the LASP1 gene on human chromosome 17q12, while exon 1-28 of the LASP2/NEBL gene were more homologous to exons of NEB gene on human chromosome 2q23. Some part of the LASP2/ NEBL-TEM7L-ARL8-CACNB2 locus on 10p12 was paralogous to the LASP1-TEM7-CACNB1 locus on 17q12, while the other part of the LASP2/NEBL-TEM7L-ARL8-CACNB2 locus was paralogous to the NEB-ARL5-CACNB4 locus on 2q23. These facts indicate that the LASP2/NEBL-TEM7L-ARL8-CACNB2 is a chimeric locus, which might be generated through the homologous recombination between the ancestral lasp2-tem7l-cacnb2 locus and the ancestral nebl-arl8 locus. Therefore, gene fusion during evolution is one of the mechanisms to generate alternative splicing.     

Identification and characterization of mouse Ppfia1 gene in silico

Array CGH combined with mRNA microarray analyses was successfully applied for genome-wide screening of proto-oncogenes and tumor suppressor genes in 2002. The CCND1-ORAOV1-FGF19-FGF4-FGF3-FLJ10261-FADD-PPFIA1-EMS1 locus on human chromosome 11q13 is one of the most frequently amplified regions within the human genome. Here, we identified and characterized mouse Ppfia1 gene by using bioinformatics. Nucleotide sequence of mouse Ppfia1 cDNA was determined in silico by assembling nucleotide sequences of ESTs BY727670, CA327608, BU708520, BQ886535, and a 5'-truncated partial cDNA BC038349. Mouse Ppfia1 gene, consisting of 28 exons, was located between Fadd and Ems1 (also known as Cttn) genes on mouse chromosome 7. Mouse Ppfia1 (1201 aa) and human PPFIA1 (1202 aa), showing 95.8% total-amino-acid identity, were found to consist of MAH (myosin heavy chain tail and ATPase homologous) domain and three SAM (sterile alpha motif) domains. MAH domain is implicated in the homo- or hetero-oligomer formation through the coiled-coil interaction, while SAM domain is implicated in the interaction with other proteins. Mouse Ccnd1-Ems1 locus and human CCND1-EMS1 locus were evolutionarily conserved in the order and the orientation of genes therein. Nucleotide and amino-acid substitution rates of Ccnd1, Ppfia1 and Ems1 genes located near both ends of the Ccnd1-Ems1 locus were relatively lower than those in the middle part of the locus. This is the first report on mouse Ppfia1 gene as well as comprehensive comparison of CCND1-EMS1 locus within the human and mouse genomes.     

Identification and characterization of human GRID2IP gene and rat Grid2ip gene in silico

Formin-homology proteins are implicated in the cell polarity control through the assembly of specific actin structures. FMNL1/KW-13/FMNL, FMNL2/KIAA1902/FHOD2, FMNL3/KIAA2014, DAAM1, DAAM2, DIAPH1 and DIAPH2 are Formin-homology proteins with the FDD domain, while Fmn1, Fmn2, FHOD1 and Grid2ip/Delphilin are Formin-homology proteins without the FDD domain. Mouse Grid2ip links glutamate receptor delta2 subunit with actin cytoskeleton and various signaling molecules. Here, we identified and characterized human GRID2IP gene as well as rat Grid2ip gene by using bioinformatics. Human GRID2IP gene was identified within human genome sequence CTD-2195F21 (AC072052.6). Human GRID2IP gene, consisting of 21 exons, was mapped to human chromosome 7p22.1. Rat Grid2ip gene, consisting of 21 exons, was identified within rat genome sequence CH230-82F18 (AC126572.3). Human GRID2IP (1020 aa) showed 91.7% total-amino-acid identity with rat Grid2ip (1024 aa), and 92.7% total-amino-acid identity with mouse Grid2ip. Human GRID2IP protein was found to consist of PDZ domain (codon 94-166), GRCAH domain (codon 204-269), FH1 domain (codon 559-621), and FH2 domain (codon 640-1005). GRCAH domain identified in this study was conserved among mammalian GRID2IP orthologs and mammalian CIP98/KIAA1526 orthologs. This is the first report on comprehensive characterization of human GRID2IP gene as well as on identification of GRCAH domain.     

Identification and characterization of human FNBP1L gene in silico

FNBP1/FBP17/Rapostlin and TRIP10/CIP4 are structurally related microtubule-binding proteins involved in the regulation of cell shape, polarity, motility, and signal transduction. Here, we identified and characterized the FNBP1-like (FNBP1L) gene by using bioinformatics. Human FLJ20275 (NM_017737.1) and mouse 2610318I01Rik (NM_153118.1) were 5'-truncated partial cDNAs derived from human FNBP1L gene and mouse Fnbp1l gene, respectively. Exons 1-7 of FNBP1L gene were located within human genome sequence AL512651.13, and exons 7-15 within AL109613.11. Complete coding sequence of FNBP1L was determined in silico by assembling nucleotide sequences of FNBP1L exons. FNBP1L (547 aa) showed 59.4 and 55.4% total-amino-acid identity with FNBP1 and TRIP10, respectively. FNBP1L, FNBP1 and TRIP10 shared the common domain structure, consisting of FCH, FBH, HR1 and SH3 domains. FCH domain of FNBP1 family proteins is the microtubule-binding domain. HR1 (also known as antiparallel coiled-coil finger) is the binding domain for Rho family proteins, such as ARHN/RhoN and CDC42. SH3 domain of FNBP1 family proteins interacts with proline-rich region of Formin and WASP family proteins. FNBP1L gene was linked to SH2D3B/BCAR3 gene in tail-to-tail manner with an interval less than 8 kb within the human genome. FNBP1L-SH2D3B locus at human chromosome 1p22.1 was paralogous to GPR108-TRIP10-SH2D3A locus at 19p13.3 and GPR107-FNBP1-SH2D3C locus at 9q34.11-q34.13. This is the first report on comprehensive characterization of FNBP1L, which is predicted to function as a scaffold protein for microtubule, Rho family proteins, Formin-homology proteins and WAPS family proteins.     

Identification and characterization of the human FMN1 gene in silico

Mouse Formin (Fmn1) protein plays a key role in limb morphogenesis. Fmn1 is one of the actin regulators with scaffold function, interacting with Profilin, SRC, EMS1, FNBP1, FNBP2, FNBP3, FNBP4, WBP4 and alpha-catenin. Fmn1, Fmn2, FHOD1, FHOD3, GRID2IP and FHDC1 are non-FDD-type Formin homology proteins, while FMNL1, FMNL2, FMNL3, DIAPH1, DIAPH2, DIAPH3, DAAM1 and DAAM2 are FDD-type Formin homology proteins. Here, we identified the human FMN1 gene by using bioinformatics. The complete coding sequence of human FMN1 cDNA was determined by assembling AC055874.8 genome sequence (nucleotide position 178207-180073), AI040235 EST (complementary sequence for nucleotide position 331-156) and FLJ45135 cDNA (nucleotide position 319-3310). FMN1 isoform 1 (exons 1-18) and FMN isoform 2 (exons 1b and 3-18) were transcribed due to alternative splicing of the alternative promoter type. The FMN1 gene at human chromosome 15q13.3 was located between CKTSF1B1 (Gremlin) and RYR3 genes. The Xenopus fmn1 gene was identified within the Xenopus genome sequence CH216-24N20 (AC147835.1). The FMH1 domain (codon 1-120 of FMN1) and FMH2 domain (codon 683-835 of FMN1) were identified as novel regions conserved among human FMN1, mouse Fmn1, and Xenopus fmn1. The FMH2 domain was almost identical to the alpha-catenin binding domain of mouse Fmn1. Human FMN1 (1419 aa), showing 77.1% total amino-acid identity with mouse Fmn1, was found consisting of FMH1, FMH2, FH1 and FH2 domains. This is the first report on the identification and characterization of the human FMN1 gene as well as the FMH1 and FMH2 domains.     

Identification and characterization of human ZPBP-like gene in silico

PP1R1B-ERBB2-GRB7 locus on human chromo-some 17q12 is frequently amplified in gastric and breast cancer. Because recombination hot spot or fragile site is located around the terminus of amplified region (amplicon), we searched for a novel gene closely linked to the teromeric end of the ERBB2 amplicon. Here, we identified and characterized the ZPBP-like (ZPBPL) gene by using bioinformatics. ZPBPL gene, corresponding to BC043152 cDNA, was found to consist of seven exons. ZPBPL (316 aa) and ZPBP (351 aa) proteins, showing 34.8% total amino-acid identity, shared the zona pellucida binding protein homologous (ZPBH) domain with conserved 15 cysteine residues. ZPBPL was a secreted-type glycoprotein with the ZPBH domain, while ZPBP was a type 2 transmembrane protein with the extracellular ZPBH domain. ZPBPL mRNA was co-expressed with ZPBP mRNA in testis, germ cell tumor, and brain medulla. ZPBPL might be implicated in the gamete interaction during fertilization just like ZPBP. The MGC9753-ERBB2-MGC14832-GRB7-ZNFN1A3-ZPBPL-PRO2521-ORMDL3-GSDM locus on human chromosome 17q12-q21 and the ZPBP-ZNFN1A1-FIGNL1-DDC-GRB10-COBL-SEC61G-EGFR-LANCL2 locus on human chromosome 7p12-p11 were next compared. Comparative genomics revealed that ZPBPL-ZNFN1A3-GRB7-ERBB2 and ZPBP-ZNFN1A1-GRB10-EGFR loci were paralogous regions within the human genome. This is the first report on identification and characterization of the ZPBPL gene.     

Identification and characterization of ARHGAP27 gene in silico

ARHGAP1, ARHGAP2, ARHGAP3, ARHGAP4, ARHGAP5, ARHGAP6, ARHGAP7 (DLC1), ARHGAP8, ARHGAP9, ARHGAP10, ARHGAP12, ARHGAP13 (SRGAP1), ARHGAP14 (SRGAP2), ARHGAP15, ARHGAP17 (RICH1), ARHGAP18, ARHGAP19, ARHGAP20, ARHGAP21, ARHGAP22, ARHGAP23, ARHGAP24, ARHGAP25, ARHGAP26, STARD13 (DLC2), HA-1, GMIP, PARG1, RACGAP1, PIK3R1, PIK3R2, and FNBP2 genes encode Rho/Rac/Cdc42-like GTPase activating (RhoGAP) proteins. Here, we characterized human ARHGAP27 gene by using bioinformatics. Complete coding sequence of ARHGAP27 isoform 1, encoding a full-length 889-aa protein, was determined by assembling exon 1 (nucleotide position 143440-144096 of AC091132.16) and most part of FLJ43547 cDNA (nucleotide position 69-3628 of AK125535.1). Complete coding sequence of ARHGAP27 isoform 2, encoding an N-terminally truncated 548-aa protein, was derived from FLJ43547 cDNA. ARHGAP27 isoform 1 consists of exons 1-17, while ARHGAP27 isoform 2 consists of exons 1B, and 2-17. ARHGAP27 gene encoded two isoforms due to alternative splicing of alternative promoter type. ARHGAP27 mRNA was expressed in germinal center B cell, spleen, chronic lymphocytic leukemia, pancreatic cancer, and lung cancer. LOC303583 (NM_ 198759.1) was the representative rat Arhgap27 cDNA. Human ARHGAP27 showed 84.3% total-amino-acid identity with rat Arhgap27, and 39.0% total-amino-acid identity with human ARHGAP12. ARHGAP27 and ARHGAP12 shared the common-domain structure, consisting of SH3, WW, PH, and RhoGAP domains. ARHGAP27 gene was located at human chromosome 17q21, while ARHGAP12 gene was located at human chromosome 10p11. ARHGAP family genes are cancer-associated genes, because their genetic alterations lead to carcinogenesis through the dysregulation of Rho/Rac/ Cdc42-like GTPases. This is the first report on identification and characterization of the ARHGAP27 gene.     

Identification and characterization of human Inscuteable gene in silico

Neuroblast undergoes asymmetrical cell division to produce the neuroblast itself and ganglion mother cell along the apical-basal axis. Inscuteable (Insc) and Partner of Inscuteable (Pins) are translocated to the apical cell cortex during asymmetrical cell division of Drosophila neuroblast. Insc is implicated in the apical-basal orientation of mitotic spindle and the basal localization of Prospero (Pros) and Numb. Here, we identified and characterized human Inscuteable (INSC) gene using bioinformatics. Human INSC gene, consisting of at least 13 exons, was located within human genome draft sequence AC090744.5 (around nucleotide position 150581-16936 in reverse orientation). Human INSC gene, closely linked to CALCB gene with an interval of about 30 kb, was assigned to human chromosome 11p15.2-p15.1. Amino-acid sequence of human INSC polypeptide (579 aa) was determined based on exon sequences of human INSC gene. C. elegans hypothetical protein F43E2.3 (NP_495539), homologous to human INSC, was designated C. elegans Insc. Central INSC homologous (ISH) domain and C-terminal PDZ-binding motif were evolutionary conserved among INSC proteins. The former part of ISH domain is implicated in Pros localization, while function of the latter part of ISH domain and C-terminal PDZ-binding motif remain to be elucidated. Human INSC mRNA was expressed in eye, kidney, fetal cochlea, parathyroid tumor, chondrosarcoma, epidermoid carcinoma, and skin tumor. Because LGN/Pins, PARD3/Par-3Bazooka, PARD6A/Par-6 and PRKCZ/aPKC genes implicated in asymmetrical cell division are evolutionarily and functionally conserved, human INSC protein might be implicated in asymmetrical cell division of human neural stem cells and other stem cells.     

Identification and characterization of FBXL19 gene in silico

CXXC1, CXXC2 (FBXL10), CXXC3 (MBD1), CXXC4 (IDAX), CXXC5, CXXC6, CXXC7 (MLL), CXXC8 (FBXL11), CXXC9 (DNMT1) and CXXC10 are CXXC family genes within the human genome. Recently, we identified and characterized CXXC5 and CXXC10 genes as the homologs of CXXC4, which is implicated in the WNT signaling pathway. Here, we identified human FBXL19 (CXXC11) gene by using bioinformatics. Complete coding sequence of FBXL19 cDNA was determined by assembling 10 exons within AC135048.2 genome sequence. NM_019085.1 cDNA was a 5'-truncated partial cDNA corresponding to nucleotide position 138-2025 of FBXL19 complete coding sequence. FBXL19-BCL7C locus at chromosome 16p11.2, FBXL10-RHOF-BCL7A locus at chromosome 12q24.31, and FBXL11-RHOD locus at chromosome 11q13.2 were paralogous regions within the human genome. FBXL19 gene was found to encode a 674-amino-acid FBXL19 protein. Human FBXL19 showed 97.5% total-amino-acid identity with mouse Fbxl19. FBXHA domain (codon 11-128 of FBXL19) and FBXHB domain (codon 404-674 of FBXL19) were identified as novel domains conserved among FBXL19, FBXL10 and FBXL11. CXXC domain was located within the FBXHA domain, and F-box domain was located within the FBXHB domain. FBXL19 consists of FBXHA and FBXHB domains, while FBXL10 and FBXL11 consist of Jumonji C (JmjC), FBXHA and FBXHB domains. This is the first report on human FBXL19 gene as well as FBXHA and FBXHB domains.     

Identification and characterization of human FHOD3 gene in silico

Formin homology proteins are actin regulators with scaffold function, which are implicated in organogenesis, normal tissue homeostasis, and cancer-cell invasion. FHOD1/FHOS, GRID2IP, Fmn1 and Fmn2 are non-FDD-type Formin homology proteins, while FMNL1, FMNL2/FHOD2, FMNL3, DAAM1, DAAM2, DIAPH1, DIAPH2 and DIAPH3 are FDD-type Formin homology proteins. Here, we identified and characterized FHOD3 (also known as FHOS2), a novel gene homologous to FHOD1, by using bioinformatics. Because FLJ46173, FLJ22297, KIAA1695 and FLJ34580 were partial FHOD3 cDNAs, complete coding sequence of FHOD3 cDNA was determined by assembling nucleotide sequences of FLJ46173 and FLJ22297. FHOD3 gene at human chromosome 18q12.2 was found consisting of at least 25 exons. Exon 11 of FHOD3 gene was spliced out in KIAA1695 cDNA and BF116064 EST, while exon 13 of FHOD3 gene was spliced out in FLJ46173 cDNA. FHOD3 gene encodes at least three isoforms due to alternative splicing of the exon skipping type. FHOD3 and FHOD1 showed 52.1% total-amino-acid identity. Drosophila CG32030 showed 43.9% total-amino-acid identity with human FHOD3, and 39.1% total-amino-acid identity with human FHOD1. FHDHN domain (codon 1-327 of FHOD3) and FHDHC domain (codon 1377-1421 of FHOD3) were identified as the N-terminal conserved region and the juxta C-terminal conserved region, respectively. Human FHOD3, FHOD1 and Drosophila CG32030 were found to share the conserved domain structure consisting of FHDHN, FH1, FH2, and FHDHC domains. This is the first report on the FHOD3 gene as well as on the novel FHDHN and FHDHC domains.