C. Dixkens

Genomic cloning, chromosomal mapping, and expression analysis of Msal-2

Abstract. Mutations of SALL1 related to spalt of Drosophila have been found to cause Townes-Brocks syndrome, suggesting a function of SALL1 for the development of anus, limbs, ears, and kidneys. No function is yet known for SALL2, another human spalt-like gene. The structure of SALL2 is different from SALL1 and all other vertebrate spalt-like genes described in mouse, Xenopus, and Medaka, suggesting that SALL2-like genes might also exist in other vertebrates. Consistent with this hypothesis, we isolated and characterized a SALL2 homologous mouse gene, Msal-2. In contrast to other vertebrate spalt-like genes both SALL2 and Msal-2 encode only three double zinc finger domains, the most carboxyterminal of which only distantly resembles spalt-like zinc fingers. The evolutionary conservation of SALL2/Msal-2 suggests that two lines of sal-like genes with presumably different functions arose from an early evolutionary duplication of a common ancestor gene. Msal-2 is expressed throughout embryonic development but also in adult tissues, predominantly in brain. However, the function of SALL2/Msal-2 still needs to be determined.

Molecular cloning, chromosomal localization, and expression of the murine SALL1 ortholog Sall1

SALL1 has been identified as one of now three human homologs of the region specific homeotic gene spalt (sal) of Drosophila, which encodes a zinc finger protein of characteristic structure. Mutations of SALL1 on chromosome 16q12.1 cause Townes-Brocks syndrome (TBS, OMIM no. 107480). In order to facilitate functional studies of this gene in a model organism, we searched for the murine homolog of SALL1. Here we report the genomic cloning, chromosome mapping, and partial expression analysis of the gene Sall1. Sequence comparison, Northern blot hybridization as well as the conserved chromosome location on the homologous mouse chromosome indicate that we have indeed isolated the murine homolog of SALL1.

Identification of the human ortholog of the t-complex-encoded protein TCTE3 and evaluation as a candidate gene for primary ciliary dyskinesia

Primary ciliary dyskinesia (PCD) is a heterogeneous autosomal recessive disease that is caused by impaired ciliary and flagellar functions. About 50% of PCD patients show situs inversus, denoted as Kartagener syndrome. In most cases, axonemal defects in cilia and sperm tails can be demonstrated by electron microscopy, i.e. PCD patients often lack inner and/or outer dynein arms in their sperm tails and cilia, supporting the hypothesis that mutations in dynein genes may cause PCD. In order to identify novel PCD genes we have isolated the human ortholog of the murine Tcte3 gene. The human TCTE3 gene encodes a dynein light chain and shares high similarity to dynein light chains of other species. The TCTE3 gene is expressed in tissues containing cilia or flagella, it is composed of four exons and located on chromosome 6q25→q27. To elucidate the role of TCTE3 as a candidate gene for PCD a mutational analysis of thirty-six PCD patients was performed. We detected five polymorphisms in the coding sequence and in the 5′ UTR of the TCTE3 gene. In one patient a heterozygous nucleotide exchange was identified resulting in an arginine to isoleucine substitution at the amino acid level. However, this exchange was also detected in one control DNA. Our results indicate that mutations in the TCTE3 gene are not a main cause of primary ciliary dyskinesia.

Isolation and characterization of a novel human gene, NIF3L1, and its mouse ortholog, Nif3l1, highly conserved from bacteria to mammals

We report the cloning and characterization of novel human and murine genes NIF3L1 and Nif3l1 which are strongly homologous to the yeast Ngg1-interacting factor 3 homolog. Mouse Nif3l1 and human NIF3L1 encode predicted proteins of 376 amino acids and 377 amino acids, respectively. Northern blot analysis on RNA from different postnatal murine tissues showed a ubiquitous expression pattern of mouse Nif3l1 with a transcript of approximately 1.85 kb. RT-PCR analysis on prenatal mouse RNA and embryonic stem cell RNA demonstrated expression of Nif3l1 throughout embryonic development. Additionally, expression analysis on cell lines revealed strong overexpression of Nif3l1 in the spermatogonia-derived cell line GC-1 spg and in the teratocarcinoma cell line F9. The mouse gene was mapped to chromosome 1, region C. Human NIF3L1 consists of seven exons spanning 14.5 kb of genomic DNA and is located on chromosome 2q33. A fusion protein consisting of the GFP (green fluorescent protein) and the ORF of human NIF3L1 showed a localization of the predicted protein in the cytoplasm. In the N-terminal and C-terminal region, mouse Nif3l1 and human NIF3L1 are strongly homologous to proteins of other species, e.g. the recently cloned Drosophila symbol=anon-35F/36F gene with 41% amino acid identity and several proteins from yeast including the yeast Ngg1-interacting factor 3 homolog with 46% amino acid identity, the hypothetical protein YGL221c and yeast Ngg1-interacting factor 3 (Nif3) with 37% amino acid identity. Other proteins from lower organisms, e.g a conserved hypothetical protein from Ureaplasma urealyticum or a hypothetical protein SCC30.09c from Streptomyces coelicolor show approximately 25–30% amino acid identity in the two flanking regions of the protein. These similarities indicate a high degree of conservation of mouse Nif3l1 and human NIF3L1 from bacteria to mammals.

The putative peroxisomal gene Pxt1 is exclusively expressed in the testis

Genes reported to be crucial for spermatogenesis are often exclusively expressed in the testis. We have identified a novel male germ cell-specific expressed gene named peroxisomal testis specific 1 (Pxt1) with expression starting at the spermatocyte stage during mouse spermatogenesis. The putative amino acid sequence encoded by the cDNA of the Pxt1 gene contains a conserved Asn-His-Leu (NHL)-motif at its C-terminal end, which is characteristic for peroxisomal proteins. Pxt1-EGFP fusion protein is co-localized with known peroxisomal marker proteins in transfected NIH3T3 cells. In addition, we could demonstrate that the peroxisomal targeting signal NHL is functional and responsible for the correct subcellular localization of the Pxt1-EGFP fusion protein. In male germ cells peroxisomes were reported only in spermatogonia. The Pxt1 gene is so far the first gene coding for a putative peroxisomal protein which is expressed in later steps of spermatogenesis, namely in pachytene spermatocytes.

Alternative splicing, chromosome assignment and subcellular localization of the testicular haploid expressed gene (THEG)

We have previously isolated and characterized the mouse Testicular Haploid Expressed Gene (Theg) that is specifically expressed in haploid germ cells. We now describe the molecular cloning and characterization of the human homologue (THEG) of mouse Theg. Expression studies by using both dot blot and Northern blot techniques revealed that human THEG is expressed specifically in the testis. Additionally, we found two alternatively spliced transcripts (THEG major and THEG minor) for THEG by using reverse transcription-polymerase chain reaction on human testicular RNA. Sequence analysis of these PCR products demonstrated that the smaller transcript (THEG minor) lacks 72 bp which was also observed for the mouse Theg. We have isolated the cDNAs of human THEG major and THEG minor, containing the complete open reading frames, which encode putative nuclear proteins of 379 amino acids and 355 amino acids, respectively. Database searches identified two genomic clones on chromosome 19 harboring the human THEG gene, which is approximately 14 kb pairs in size, contains eight exons, and comparison of the two cDNA sequences with the genomic sequence indicated that the smaller transcript lacks exon 3. Furthermore, we assigned the human THEG gene (THEG) to human chromosome 19ptel→ p13 by fluorescence in situ hybridization. Moreover, we detected mouse THEG protein prominently in the nucleus of round spermatids by using an antibody against THEG on both testicular sections and cellular suspensions. Additionally, the subcellular localization of mouse THEG was confirmed by a green fluorescent protein (GFP) fusion protein of mouse THEG which was found mainly in the nucleus of transfected NIH3T3 cells. These data suggest that both human and mouse THEG are specifically expressed in the nucleus of haploid male germ cells and are involved in the regulation of nuclear functions.

Targeted Disruption of the Mouse Npal3 Gene Leads to Deficits in Behavior, Increased IgE Levels, and Impaired Lung Function

The non-imprinted in Prader-Willi/Angelman syndrome (NIPA) proteins are highly conserved receptors or transporters. Translocation of NIPA genes were found in patients with Prader-Willi syndrome, and loss-of-function of the NIPA1 gene was identified in hereditary spastic paraplegia. The family of NIPA-like domain containing (NPAL) proteins is closely related to the NIPA proteins, but to date nothing is known about their function. Here, we could demonstrate that both human NPAL3 and mouse Npal3 are ubiquitously expressed and encode highly conserved proteins. To further elucidate the function of the Npal3 gene, knockout (Npal3–/–) mice were generated. Intensive phenotypic analyses revealed that disruption of the Npal3 gene results in a pleiotropic phenotype. The function of the nervous system was impaired in both mutant males and females which could be demonstrated in behavioral tests. In addition, in Npal3 mutants the number of NK cells was decreased and changes in IgM, IgG2, and IgA were observed, indicating that the immune system is also affected. Interestingly, increased IgE levels as well as impaired lung functions were observed in mutant males but not in mutant females. It should be noted that the human NPAL3 gene is located at 1p36.12→p35.1, and atopic diseases were previously linked to this genomic region. Thus, the Npal3–/– mice could serve as a valuable model system for studying atopic diseases.