Characterization of three genes, AKAP84, BAW and WSB1, located 3' to the neurofibromatosis type 1 locus in Fugu rubripes

WSB1: from homeostasis to hypoxia

The wsb1 gene has been identified to be important in developmental biology and cancer. A complex transcriptional regulation of wsb1 yields at least three functional transcripts. The major expressed isoform, WSB1 protein, is a substrate recognition protein within an E3 ubiquitin ligase, with the capability to bind diverse targets and mediate ubiquitinylation and proteolytic degradation. Recent data suggests a new role for WSB1 as a component of a neuroprotective pathway which results in modification and aggregation of neurotoxic proteins such as LRRK2 in Parkinson’s Disease, via an unusual mode of protein ubiquitinylation.

WSB1 is also involved in thyroid hormone homeostasis, immune regulation and cellular metabolism, particularly glucose metabolism and hypoxia. In hypoxia, wsb1 is a HIF-1 target, and is a regulator of the degradation of diverse proteins associated with the cellular response to hypoxia, including HIPK2, RhoGDI2 and VHL. Major roles are to both protect HIF-1 function through degradation of VHL, and decrease apoptosis through degradation of HIPK2. These activities suggest a role for wsb1 in cancer cell proliferation and metastasis. As well, recent work has identified a role for WSB1 in glucose metabolism, and perhaps in mediating the Warburg effect in cancer cells by maintaining the function of HIF1. Furthermore, studies of cancer specimens have identified dysregulation of wsb1 associated with several types of cancer, suggesting a biologically relevant role in cancer development and/or progression.

Recent development of an inducible expression system for wsb1 could aid in the further understanding of the varied functions of this protein in the cell, and roles as a potential oncogene and neuroprotective protein.

A 15-residue bifunctional element in D-AKAP1 is required for both endoplasmic reticulum and mitochondrial targeting

The cAMP-dependent protein kinase anchoring protein, d-AKAP1, has two N-terminal splice variants. The shorter forms (N0, d-AKAP1a, and -1c) target to mitochondria, and the longer forms (N1, d-AKAP1b, and -1d) with 33 additional residues N-terminal to N0 target to the endoplasmic reticulum (ER) (Huang, L. J., Wang, L., Ma, Y., Durick, K., Perkins, G., Deerinck, T. J., Ellisman, M. H., and Taylor, S. S. (1999) J. Cell Biol. 145, 951-959). In d-AKAP1a, translation may initiate from both Met-34 or Met-49 producing two molecules both targeted to mitochondria. The shorter molecule contains the 15-residue targeting motif, homologous to the N-terminal mitochondrial targeting motif of hexokinase I. Extensive mutagenesis showed that one hydrophobic surface of the 15-residue hexokinase-homologous segment contained the key elements for mitochondrial targeting. The same 15 residues are also part of the ER-targeting signal, but for ER targeting multiple hydrophobic residues are required that encompass both surfaces of the helix. The different involvement of the same helical motif for targeting to the two organelles appears to reflect different modes of interaction with the two organelles. This is the first example of a bifunctional helical element that is required for both ER and mitochondrion targeting.

Characterization of the Fugu rubripes NLK and FN5 genes flanking the NF1 (Neurofibromatosis type 1) gene in the 5' direction and mapping of the human counterparts

To complete the analysis of the Neurofibromatosis type 1 (NF1) gene region in Fugu rubripes, we characterized the upstream flanking region of the NF1 gene and identified the FN5 (flanking the Fugu NF1 gene in 5' direction) gene and the NLK (Nemo-like kinase) gene as its flanking genes. The FN5 gene spans 3807bp and encompasses four exons, three of which belong to the expanded 5' UTR. Only 11% of the FN5 transcript is protein-coding. The function of the FN5 protein spanning 59 amino acids is unknown. We also characterized the human and the mouse FN5 transcripts and found 85% and 83% similarity of deduced amino acid sequences compared with Fugu. Two copies of the human FN5 gene were identified, one on chromosome 17q21.3-q22 several megabases distal to the NF1 gene at 17q11.2. The second copy of the FN5 gene was mapped to 11q13.3-q23.3. In Fugu, the FN5 gene is flanked by the NLK gene, which spans 4513bp from the translation start to the stop codon and encompasses 11 exons. Comparing the deduced amino acid sequences, 82% overall similarity was observed between Fugu and mouse or human NLK and 67% similarity between the Fugu NLK and the highly related LIT-1 kinase of Caenorhabditis elegans, which has been shown, like the vertebrate counterpart, to be involved in the Wnt signalling pathway. We mapped the human NLK gene to 17q11.2 between markers D17S935 and D17S120, more than 1Mb proximal to the NF1 gene. The characterization of the 5' flanking region presented here, together with that of the 3' region, demonstrates the profound differences between Fugu and human considering the gene content within the region flanking the NF1 gene.

Generation and analysis of 25 Mb of genomic DNA from the pufferfish Fugu rubripes by sequence scanning

We have generated and analyzed >50,000 shotgun clones from 1059 Fugu cosmid clones. All sequences have been minimally edited and searched against protein and DNA databases. These data are all displayed on a searchable, publicly available web site at. With an average of 50 reads per cosmid, this is virtually nonredundant sequence skimming, covering 30%-50% of each clone. This essentially random data set covers nearly 25 Mb (>6%) of the Fugu genome and forms the basis of a series of whole genome analyses which address questions regarding gene density and distribution in the Fugu genome and the similarity between Fugu and mammalian genes. The Fugu genome, with eight times less DNA but a similar gene repertoire, is ideally suited to this type of study because most cosmids contain more than one identifiable gene. General features of the genome are also discussed. We have made some estimation of the syntenic relationship between mammals and Fugu and looked at the efficacy of ORF prediction from short, unedited Fugu genomic sequences. Comparative DNA sequence analyses are an essential tool in the functional interpretation of complex vertebrate genomes. This project highlights the utility of using the Fugu genome in this kind of study.