A comprehensive approach for establishment of the platform to analyze functions of KIAA proteins: generation and evaluation of anti-mKIAA antibodies

Since December 2001 we have been conducting a project to isolate and determine entire sequences of mouse KIAA cDNA clones which encode polypeptides corresponding to human KIAA proteins. The ultimate goal of this project is the elucidation of the functions of KIAA proteins. A critical step in this project is the generation of antibodies based on the cDNA sequence information. Although antibodies are the most optimal tools for biological analysis, the production and isolation of multiple recombinant proteins for an antigen is a rate-limiting step in antibody production. To address this problem, we established a system utilizing the in vitro recombination-assisted method and shotgun clones that were generated during the sequencing of mouse KIAA cDNAs (DNA Res. 2003, 10, 129-136). The authenticity of the expressed proteins was confirmed by matrix-assisted laser desorption/ionization-time of flight mass spectrometry. Another critical step for antibody production is the evaluation of the antibodies. Thus, we also made efforts to develop a systematic approach for evaluation of the titer and the specificity of the antibodies. Using these systems, we have produced and evaluated more than 500 antibodies raised against mouse KIAA proteins to date. We are currently generating antibody arrays for analysis of protein expression profiles. We will verify protein-protein interactions using immunoprecipitation and tandem mass spectrometry analysis.     

Solution structure of the RWD domain of the mouse GCN2 protein

GCN2 is the alpha-subunit of the only translation initiation factor (eIF2alpha) kinase that appears in all eukaryotes. Its function requires an interaction with GCN1 via the domain at its N-terminus, which is termed the RWD domain after three major RWD-containing proteins: RING finger-containing proteins, WD-repeat-containing proteins, and yeast DEAD (DEXD)-like helicases. In this study, we determined the solution structure of the mouse GCN2 RWD domain using NMR spectroscopy. The structure forms an alpha + beta sandwich fold consisting of two layers: a four-stranded antiparallel beta-sheet, and three side-by-side alpha-helices, with an alphabetabetabetabetaalphaalpha topology. A characteristic YPXXXP motif, which always occurs in RWD domains, forms a stable loop including three consecutive beta-turns that overlap with each other by two residues (triple beta-turn). As putative binding sites with GCN1, a structure-based alignment allowed the identification of several surface residues in alpha-helix 3 that are characteristic of the GCN2 RWD domains. Despite the apparent absence of sequence similarity, the RWD structure significantly resembles that of ubiquitin-conjugating enzymes (E2s), with most of the structural differences in the region connecting beta-strand 4 and alpha-helix 3. The structural architecture, including the triple beta-turn, is fundamentally common among various RWD domains and E2s, but most of the surface residues on the structure vary. Thus, it appears that the RWD domain is a novel structural domain for protein-binding that plays specific roles in individual RWD-containing proteins.     

Molecular phylogeny of Vincetoxicum (Apocynaceae-Asclepiadoideae) based on the nucleotide sequences of cpDNA and nrDNA

Molecular phylogenetic analyses of Vincetoxicum and Tylophora (Apocynaceae-Asclepiadoideae) were conducted based on the nucleotide sequences of cpDNA (two intergenic spacers of trnL (UAA)-trnF (GAA) and psbA-trnH and three introns, i.e., atpF, trnG (UCC) and trnL (UAA)), and nrDNA (ITS and ETS regions). Our phylogenetic analysis revealed two monophyletic groups; one consisted of seven taxa of Tylophora and Vincetoxicum inamoenum, Vincetoxicum magnificum and Vincetoxicum macrophyllum (Clade I) and the other consisted of 17 accessions of Vincetoxicum (Clade II). The monophyly of the genus Vincetoxicum was not supported. Although many nucleotide substitutions were observed in Clade I, the genetic differentiation within Clade II was small. Low genetic diversification but considerable morphological divergence suggests that the species in Clade II had undergone rapid diversification. Although most species in Clade I have tiny flowers, those in Clade II have larger and more nectariferous ones. Thus, we hypothesized that the rapid morphological radiation in Clade II may have been due to the gaining of floral characters such as large flowers and large amounts of nectar corresponding to diverse pollinators.     

Skewed X-chromosome inactivation causes intra-familial phenotypic variation of an EBP mutation in a family with X-linked dominant chondrodysplasia punctata

X-linked dominant chondrodysplasia punctata (CDPX2) is a skeletal dysplasia characterized by stippled epiphyses, cataracts, alopecia and skin lesions, including ichthyosis. CDPX2 exhibits a number of perplexing clinical features, such as intra- and inter-familial variation, anticipation, incomplete penetrance and possible gonadal and somatic mosaicism. Recently, mutations in the gene encoding Delta8,Delta7 sterol isomerase/emopamil-binding protein (EBP) have been identified in CDPX2. To better understand the genetics of CDPX2, we examined the entire EBP gene by direct sequencing in four CDPX2 patients. We found EBP mutations in all four patients, including three novel mutations: IVS3+1G>A, Y165C and W82C. Surprisingly, a known mutation (R147H) was identified in a patient and her clinically unaffected mother. Expression analysis revealed the mutant allele was predominantly expressed in the patient, while both alleles were expressed in the mother. Methylation analysis revealed that the wild-type allele was predominantly inactivated in the patient, while the mutated allele was predominantly inactivated in her mother. Thus, differences in expression of the mutated allele caused by skewed X-chromosome inactivation produced the diverse phenotypes within the family. Our findings could explain some of the perplexing features of CDPX2. The possibility that an apparently normal parent is a carrier should be considered when examining seemingly sporadic cases and providing genetic counseling to CDPX2 families.     

Crystal structure of a family 4 uracil-DNA glycosylase from Thermus thermophilus HB8

Uracil-DNA glycosylase (UDG; EC 3.2.2.-) removes uracil from DNA to initiate DNA base excision repair. Since hydrolytic deamination of cytosine to uracil is one of the most frequent DNA-damaging events in all cells, UDG is an essential enzyme for maintaining the integrity of genomic information. For the first time, we report the crystal structure of a family 4 UDG from Thermus thermophilus HB8 (TthUDG) complexed with uracil, solved at 1.5 angstroms resolution. As opposed to UDG enzymes in its other families, TthUDG possesses a [4Fe-4S] cluster. This iron-sulfur cluster, which is distant from the active site, interacts with loop structures and has been suggested to be unessential to the activity but necessary for stabilizing the loop structures. In addition to the iron-sulfur cluster, salt-bridges and ion pairs on the molecular surface and the presence of proline on loops and turns is thought to contribute to the enzyme's thermostability. Despite very low levels of sequence identity with Escherichia coli and human UDGs (family 1) and E.coli G:T/U mismatch-specific DNA glycosylase (MUG) (family 2), the topology and order of secondary structures of TthUDG are similar to those of these distant relatives. Furthermore, the coordinates of the core structure formed by beta-strands are almost the same. Positive charge is distributed over the active-site groove, where TthUDG would bind DNA strands, as do UDG enzymes in other families. TthUDG recognizes uracil specifically in the same manner as does human UDG (family 1), rather than guanine in the complementary strand DNA, as does E.coli MUG (family 2). These results suggest that the mechanism by which family 4 UDGs remove uracils from DNA is similar to that of family 1 enzymes.     

Holliday junction binding activity of the human Rad51B protein

The human Rad51B protein is involved in the recombinational repair of damaged DNA. Chromosomal rearrangements of the Rad51B gene have been found in uterine leiomyoma patients, suggesting that the Rad51B gene suppresses tumorigenesis. In the present study, we found that the purified Rad51B protein bound to single-stranded DNA and double-stranded DNA in the presence of ATP and either Mg(2+) or Mn(2+) and hydrolyzed ATP in a DNA-dependent manner. When the synthetic Holliday junction was present along with the half-cruciform and double-stranded oligonucleotides, the Rad51B protein only bound to the synthetic Holliday junction, which mimics a key intermediate in homologous recombination. In contrast, the human Rad51 protein bound to all three DNA substrates with no obvious preference. Therefore, the Rad51B protein may have a specific function in Holliday junction processing in the homologous recombinational repair pathway in humans.     

Identification of functional domains of the Escherichia coli SeqA protein

The Escherichia coli SeqA protein, a negative regulator of chromosomal DNA replication, prevents the overinitiation of replication within one cell cycle by binding to hemimethylated G-mA-T-C sequences in the replication origin, oriC. In addition to the hemimethylated DNA-binding activity, the SeqA protein has a self-association activity, which is also considered to be essential for its regulatory function in replication initiation. To study the functional domains responsible for the DNA-binding and self-association activities, we performed a deletion analysis of the SeqA protein and found that the N-terminal (amino acid residues 1-59) and the C-terminal (amino acid residues 71-181) regions form structurally distinct domains. The N-terminal domain, which is not involved in DNA binding, has the self-association activity. In contrast, the C-terminal domain, which lacks the self-association activity, specifically binds to the hemimethylated G-mA-T-C sequence. Therefore, two essential SeqA activities, self-association and DNA-binding, are independently performed by the structurally distinct N-terminal and C-terminal domains, respectively.     

Forward signaling mediated by ephrin-B3 prevents contralateral corticospinal axons from recrossing the spinal cord midline

To investigate Eph-ephrin bidirectional signaling, a series of mutations were generated in the ephrin-B3 locus. The absence of both forward and reverse signaling resulted in mice with mirror movements as typified by a hopping locomotion. The corticospinal tract was defective as axons failed to respect the midline boundary of the spinal cord and bilaterally innervated both contralateral and ipsilateral motor neuron populations. A second mutation that expresses a truncated ephrin-B3 protein lacking its cytoplasmic domain did not lead to hopping, indicating that reverse signaling is not required for corticospinal innervation. Ephrin-B3 is concentrated at the spinal cord midline, while one of its receptors, EphA4, is expressed in postnatal corticospinal neurons as their fibers pathfind down the contralateral spinal cord. Our data indicate ephrin-B3 functions as a midline-anchored repellent to stimulate forward signaling in EphA4-expressing axons.     

A molecular marker diagnostic of a specific isolate of an arbuscular mycorrhizal fungus,Gigaspora margarita

To investigate the auto-ecology of a strain of Gigaspora margarita in a commercial inoculum, we found a pair of PCR primers amplifying a sequence of 235 bp diagnostic of the isolate. We designed an oligonucleotide probe based on the DNA sequence. The combination of PCR and the probing successfully detected the diagnostic sequence from both DNA preparations of single spores and colonized roots. This protocol enabled us to distinguish the isolate among several isolates from Japan, Nepal and the USA.     

Adenovirus-mediated WGA gene delivery for transsynaptic labeling of mouse olfactory pathways

Detailed knowledge of neuronal connectivity patterns is indispensable for studies of various aspects of brain functions. We previously established a genetic strategy for visualization of multisynaptic neural pathways by expressing wheat germ agglutinin (WGA) transgene under the control of neuron type-specific promoter elements in transgenic mice and Drosophila. In this paper, we have developed a WGA-expressing recombinant adenoviral vector system and applied it for analysis of the olfactory system. When the WGA-expressing adenovirus was infused into a mouse nostril, various types of cells throughout the olfactory epithelium were infected and expressed WGA protein robustly. WGA transgene products in the olfactory sensory neurons were anterogradely transported along their axons to the olfactory bulb and transsynaptically transferred in glomeruli to dendrites of the second-order neurons, mitral and tufted cells. WGA protein was further conveyed via the lateral olfactory tract to the olfactory cortical areas including the anterior olfactory nucleus, olfactory tubercle, piriform cortex and lateral entorhinal cortex. In addition, transsynaptic retrograde labeling was observed in cholinergic neurons in the horizontal limb of diagonal band, serotonergic neurons in the median raphe nucleus, and noradrenergic neurons in the locus coeruleus, all of which project centrifugal fibers to the olfactory bulb. Thus, the WGA-expressing adenovirus is a useful and powerful tool for tracing neural pathways and could be used in animals that are not amenable to the transgenic technology.