Fbxo45 Forms a Novel Ubiquitin Ligase Complex and Is Required for Neuronal Development

Fbxo45 is an F-box protein that is restricted to the nervous system. Unlike other F-box proteins, Fbxo45 was found not to form an SCF complex as a result of an amino acid substitution in the consensus sequence for Cul1 binding. Proteomics analysis revealed that Fbxo45 specifically associates with PAM (protein associated with Myc), a RING finger-type ubiquitin ligase. Mice deficient in Fbxo45 were generated and found to die soon after birth as a result of respiratory distress. Fbxo45^−/− embryos show abnormal innervation of the diaphragm, impaired synapse formation at neuromuscular junctions, and aberrant development of axon fiber tracts in the brain. Similar defects are also observed in mice lacking Phr1 (mouse ortholog of PAM), suggesting that Fbxo45 and Phr1 function in the same pathway. In addition, neuronal migration was impaired in Fbxo45^−/− mice. These results suggest that Fbxo45 forms a novel Fbxo45-PAM ubiquitin ligase complex that plays an important role in neural development.Ubiquitin-dependent proteolysis is indispensable for various biological processes (3, 40). Protein ubiquitylation is mediated by several enzymes that act in concert, with a ubiquitin ligase (E3) playing a key role in substrate recognition (14). E3 enzymes contain specific structural motifs that mediate recruitment of a ubiquitin-conjugating enzyme (E2), with these motifs including HECT, RING finger, U-box, and PHD finger domains (30). The SCF complex consists of Skp1 (adaptor subunit), Cul1 (scaffold subunit), an F-box protein (substrate recognition subunit), and Rbx1 (also known as Roc1 or Hrt1; RING finger-containing subunit). Whereas Skp1, Cul1, and Rbx1 are common to all SCF complexes, the F-box protein is variable (with ∼70 such proteins having been identified in humans) and confers substrate specificity.Fbxo45 is an F-box protein that was originally isolated as an estrogen-induced protein (47). Human and mouse Fbxo45 genes comprise three exons and possess several consensus binding sequences for the estrogen receptor in the promoter region. Fbxo45 mRNA is rapidly induced on exposure of MCF-7 cells to 17β-estradiol (47). FSN-1, the Caenorhabditis elegans ortholog of Fbxo45, binds to RPM-1 (regulator of presynaptic morphology 1) together with CUL-1 and SKR-1, the C. elegans orthologs of mammalian Cul1 and Skp1, respectively (21, 46). RPM-1 belongs to an evolutionarily conserved family of proteins (the PHR family) that include Highwire (HIW) (Drosophila melanogaster), Esrom (Danio rerio), Phr1 (Mus musculus), and protein associated with Myc (PAM) (Homo sapiens), each of which contains a RING-finger domain that is required for its E3 activity (7, 20, 21, 27, 44). Complete loss of function of fsn-1 in C. elegans results in defects that are characterized by the simultaneous presence of overdeveloped and underdeveloped neuromuscular junctions (NMJs) and which are similar to, but not as pronounced as, those observed in rpm-1^−/− mutants. These genetic findings support the notion that the functions of FSN-1 and RPM-1 are partially overlapping (21).Although PHR family members interact with many potential targets (11, 24, 26, 31), genetic data have shown that one key substrate of RPM-1 and HIW is the mitogen-activated protein kinase kinase kinase known as DLK (dual leucine zipper kinase) in C. elegans and known as Wallenda in D. melanogaster, respectively. The abundance of this kinase is increased in rpm-1 or hiw mutants, and synaptic defects in the mutant worms and flies are suppressed by a loss of DLK or Wallenda. Furthermore, an increase in the level of DLK or Wallenda is sufficient to phenocopy the synaptic defects of the rpm-1 or hiw mutants (5, 27). PAM has also been shown to catalyze the ubiquitylation of tuberin (TSC2) and to regulate signaling by mTOR (mammalian target of rapamycin) in human cells (12).To elucidate the physiological functions of Fbxo45 in mammals, we have now generated mice deficient in this protein. Analysis of the mutant mice revealed that Fbxo45 is required for normal neuromuscular synaptogenesis, axon pathfinding, and neuronal migration. Moreover, we found that Fbxo45 does not form an authentic SCF complex as a result of an amino acid substitution in the F-box domain, and we identified PAM as a binding partner of Fbxo45. The phenotype of Fbxo45^−/− mice was found to be similar to that of Phr1^−/− mice, especially with regard to the defects of neuromuscular synapse formation and of axon navigation. Our results indicate that three fundamental processes of neural development— axonal projection, synapse formation, and neuronal migration—may be linked by a common machinery consisting of the Fbxo45-Phr1 complex.     

Cloning of Nicotianamine Synthase Genes, Novel Genes Involved in the Biosynthesis of Phytosiderophores

Nicotianamine synthase (NAS), the key enzyme in the biosynthetic pathway for the mugineic acid family of phytosiderophores, catalyzes the trimerization of S-adenosylmethionine to form one molecule of nicotianamine. We purified NAS protein and isolated the genes nas1, nas2, nas3, nas4, nas5-1, nas5-2, and nas6, which encode NAS and NAS-like proteins from Fe-deficient barley (Hordeum vulgare L. cv Ehimehadaka no. 1) roots. Escherichia coli expressing nas1 showed NAS activity, confirming that this gene encodes a functional NAS. Expression of nas genes as determined by northern-blot analysis was induced by Fe deficiency and was root specific. The NAS genes form a multigene family in the barley and rice genomes.     

Exercise-induced enhancement of insulin sensitivity is associated with accumulation of M2-polarized macrophages in mouse skeletal muscle

Exercise enhances insulin sensitivity in skeletal muscle, but the underlying mechanism remains obscure. Recent data suggest that alternatively activated M2 macrophages enhance insulin sensitivity in insulin target organs such as adipose tissue and liver. Therefore, the aim of this study was to determine the role of anti-inflammatory M2 macrophages in exercise-induced enhancement of insulin sensitivity in skeletal muscle. C57BL6J mice underwent a single bout of treadmill running (20 m/min, 90 min). Twenty-four hours later, ex vivo insulin-stimulated 2-deoxy glucose uptake was found to be increased in plantaris muscle. This change was associated with increased number of CD163-expressing macrophages (i.e. M2-polarized macrophages) in skeletal muscle. Systemic depletion of macrophages by pretreatment of mice with clodronate-containing liposome abrogated both CD163-positive macrophage accumulation in skeletal muscle as well as the enhancement of insulin sensitivity after exercise, without affecting insulin-induced phosphorylation of Akt and AS160 or exercise-induced GLUT4 expression. These results suggest that accumulation of M2-polarized macrophages is involved in exercise-induced enhancement of insulin sensitivity in mouse skeletal muscle, independently of the phosphorylation of Akt and AS160 and expression of GLUT4.     

A population genetic study on the transition from Jomon people to Yayoi people

In the study on the origin of Japanese, one of main unsolved problems is the transition from the Jomon people to the Yayoi people. The main difficulty in solving this problem has been the lack of suitable skeletal materials belonging to the time between the two periods, i.e. the final Jomon and the early Yayoi Periods. Therefore, we know few details of the transition period. It is important to know who carried out a drastic change of the Yayoi culture during this transitional period, i.e. the native Jomon people or the immigrant people. By introducing population genetic models, we show that a view that the immigrant people had a significant genetic contribution to the origin of Japanese is compatible with results from anthropological and archeological studies. This result implies that the immigrant people were mainly responsible for the drastic cultural change during the transitional period.     

VopV, an F-actin-binding type III secretion effector, is required for Vibrio parahaemolyticus-induced enterotoxicity

Vibrio parahaemolyticus, a Gram-negative halophilic bacterium that causes acute gastroenteritis in humans, is characterized by two type III secretion systems (T3SS), namely T3SS1 and T3SS2. T3SS2 is indispensable for enterotoxicity but the effector(s) involved are unknown. Here, we identify VopV as a critical effector that is required to mediate V. parahaemolyticus T3SS2-dependent enterotoxicity. VopV was found to possess multiple F-actin-binding domains and the enterotoxicity caused by VopV correlated with its F-actin-binding activity. Furthermore, a T3SS2-related secretion system and a vopV homologous gene were also involved in the enterotoxicity of a non-O1/non-O139 V. cholerae strain. These results indicate that the F-actin-targeting effector VopV is involved in enterotoxic activity of T3SS2-possessing bacterial pathogens.     

Light and electron microscopical combined staining by immunohistochemical and enzyme histochemical methods using rat prolactin-secreting pituitary tumours

Summary Combined immunohistochemical staining (IHCS) and enzyme histochemical staining (EHCS) methods for light microscopy (LM) and electron microscopy (EM) are reported, using oestrogeninduced rat pituitary tumours. For LM, combined staining for alkaline phosphatase and acid phosphatase by EHCS, using the azo dye method, and for prolactin and ACTH by IHCS, using the enzyme-labelled antibody method, gave the best results on 1 m glycol methacrylate sections. For EM, combined staining by EHCS on 30 m tissue sections followed by IHCS for prolactin on ultrathin Epon sections (enzyme-labelled antibody method) provided acceptable results. By these combined staining methods, the neoplastic prolactin cells were shown to have close affinity to rich alkaline phosphatase-positive capillaries and to possess an alkaline phosphatase-positive cell membrane. Furthermore, they revealed acid phosphatase-positive lysosomal and secretory granules. These combined staining methods may be valuable in studies on the actual functional status of cells.