Importance of N-linked sugar residues in the development of Auerbach's plexus in the rat colon: a lectin histochemical study

The lectin-binding patterns in Auerbach's plexus in the distal portions of the rat colon from 15- to 21-day-old foetuses, newborns, and adults were examined by light and electron microscopy using 16 different lectins (ConA, RCA-1, WGA, PNA, SBA, UEA-1, DBA, LCA, PHA-L, DSA, GS-1, VVA, MPA, BPA, MAA, and PSA). The binding of ConA was shown to increase after day 19 of gestation in parallel with differentiation of Auerbach's plexus, whereas the staining intensity for DSA and RCA-1 increased after day 17 of gestation in accordance with the appearance of the plexus. At the electron microscopical level, DSA binding sites were observed to be localized mainly in the plasma membrane, Golgi apparatus, and nuclear membrane of nerve cells. Positive sites were also observed in the axolemma and in the plasma membrane of nerve cell processes, Schwann cells, and the surrounding smooth muscle cells. PSA, PHA-L, LCA, and WGA showed constant staining during the development after day 15 of gestation. Other lectins, most of which are specific for O-glycosidic mucin-type sugar residues, were essentially negative throughout the developmental stages. Moreover, N-glycanase digestion significantly diminished the positive reactions. N-linked oligosaccharides may thus play important roles in the development and maturation of the Auerbach's plexus, and may be involved in the developmental defect of the plexus, e.g. as occurs in Hirschsprung's disease.     

The trehalose transporter 1 gene sequence is conserved in insects and encodes proteins with different kinetic properties involved in trehalose import into peripheral tissues

We recently cloned a trehalose transporter gene (Tret1) that contributes to anhydrobiosis induction in the sleeping chironomid Polypedilum vanderplanki Hinton. Because trehalose is the main haemolymph sugar in most insects, they might possess Tret1 orthologs involved in maintaining haemolymph trehalose levels. We cloned Tret1 orthologs from four species in three insect orders. The similarities of the amino acid sequence to TRET1 in P. vanderplanki were 58.5–80.4%. Phylogenetic analysis suggested the Tret1 sequences were conserved in insects. The Xenopus oocyte expression system showed apparent differences in the K_m and V_max values for trehalose transport activity among the six proteins encoded by the corresponding orthologs. The TRET1 orthologs of Anopheles gambiae (K_m: 45.74 ± 3.58 mM) and Bombyx mori (71.58 ± 6.45 mM) showed low trehalose affinity, whereas those of Apis mellifera (9.42 ± 2.37 mM) and Drosophila melanogaster (10.94 ± 7.70 mM) showed high affinity. This difference in kinetics might be reflected in the haemolymph trehalose:glucose ratio of each species. Tret1 was expressed not only in the fat body but also in muscle and testis. These findings suggest that insect TRET1 is responsible for the release of trehalose from the fat body and the incorporation of trehalose into other tissues that require a carbon source, thereby regulating trehalose levels in the haemolymph.     

Adaptive evolution of the uncoupling protein 1 gene contributed to the acquisition of novel nonshivering thermogenesis in ancestral eutherian mammals

Homeotherms possess various physiological mechanisms to maintain their body temperature, thus allowing them to adapt to various environments. Under cold conditions, most eutherian mammals upregulate heat production in brown adipose tissue (BAT), and uncoupling protein (UCP) 1 is an essential factor in BAT thermogenesis. The evolutionary origin of UCP1 was believed to have been a specific event occurring in eutherian lineages. Recently, however, the UCP1 ortholog was found in fishes, which uncovers a more ancient origin of this gene than previously believed. Here we investigate the evolutionary process of UCP1 by comparative genomic approach. We found that UCP1 evolved rapidly by positive Darwinian selection in the common ancestor of eutherians, although this gene arose in the ancestral vertebrate, since the orthologous genes were shared among most of the vertebrate species. Adaptive evolution occurred after the divergence between eutherians and marsupials, which is consistent with the fact that BAT has been found only in eutherians. Our findings indicate that positive Darwinian selection acted on UCP1 contributed to the acquisition of an efficient mechanism for body temperature regulation in primitive eutherians. Phylogenetic reconstruction of UCP1 with two paralogs (UCP2 and UCP3) among vertebrate species revealed that the gene duplication events which produced these three genes occurred in the common ancestor of vertebrates much earlier than the emergence of eutherians. Thus, our data demonstrate that novel gene function can evolve without de novo gene duplication event.     

Comparative analyses of hairpin substrate recognition by Escherichia coli and Bacillus subtilis ribonuclease P ribozymes

Previously, we reported that the substrate shape recognition of the Escherichia coli ribonuclease (RNase) P ribozyme depends on the concentration of magnesium ion in vitro. We additionally examined the Bacillus subtilis RNase P ribozyme and found that the B. subtilis enzyme also required high magnesium ion, above 10 mM, for cleavage of a hairpin substrate. The results of kinetic studies showed that the metal ion concentration affected both the catalysis and the affinity of the ribozymes toward a hairpin RNA substrate.     

1H-NMR and circular dichroism spectroscopic studies on changes in secondary structures of the sodium channel inactivation gate peptides as caused by the pentapeptide KIFMK.

The pentapeptide KIFMK, which contains three clustered hydrophobic amino acid residues of isoleucine, phenylalanine, and methionine (IFM) in the sodium channel inactivation gate on the cytoplasmic linker between domains III and IV (III-IV linker), is known to restore fast inactivation to the mutant sodium channels having a defective inactivation gate or to accelerate the inactivation of the wild-type sodium channels. To investigate the docking site of KIFMK and to clarify the mechanisms for restoring the fast inactivation, we have studied the interactions between KIFMK and the fragment peptide in the III-IV linker GGQDIFMTEEQK (MP-1A; G1484-K1495 in rat brain IIA) by one- and two-dimensional (1)H-NMR and circular dichroism (CD) spectroscopies. KIFMK was found to increase the helical content of MP-1A in 80% trifluoroethanol (TFE) solution by approximately 11%. A pentapeptide, KIFMT, which can restore inactivation but less effectively than KIFMK, also increased the helical content of MP-1A, but to a lesser extent ( approximately 6%) than did KIFMK. In contrast, KDIFMTK, which is ineffective in restoring inactivation, decreased the helical content ( approximately -4%). Furthermore, we studied the interactions between KIFMK and modified peptides from MP-1A, that is, MP-1NA (D1487N), MP-1QEA (E1492Q), or MP-1EQA (E1493Q). The KIFMK was found to increase the helical content of MP-1EQA to an extent nearly identical to that of MP-1A, whereas it was found to decrease those of MP-1NA and MP-1QEA. These findings mean that KIFMK, by allowing each of the Lys residues to interact with D1487 and E1492, respectively, stabilized the helical structure of the III-IV linker around the IFM residues. This helix-stabilizing effect of KIFMK on the III-IV linker may restore and/or accelerate fast inactivation to the sodium channels having a defective inactivation gate or to wild-type sodium channels.     

A fluorinated vitamin D3 analog with biopotency greater than 1 alpha, 25-dihydroxy vitamin D3

Vitamin D metabolites and analogs induce $\text{de novo}$ synthesis of a specific calcium-binding protein in embryonic chick duodenum maintained in organ culture. Using calcium-binding protein biosynthesis as a specific and sensitive biochemical indicator of intrinsic biopotency, 24,24-difluoro-1α,25-dihydroxy vitamin D₃ was found to be approximately four times more potent on a molar basis than the most active, naturally occurring metabolite, 1α,25-dihydroxy vitamin D₃.     

Anatomical and histological profiling of orphan G-protein-coupled receptor expression in gastrointestinal tract of C57BL/6J mice

G-protein-coupled receptors (GPCRs) constitute the largest family of transmembrane receptors and regulate a variety of physiological and disease processes. Although the roles of many non-odorant GPCRs have been identified in vivo, several GPCRs remain orphans (oGPCRs). The gastrointestinal (GI) tract is the largest endocrine organ and is a promising target for drug discovery. Given their close link to physiological function, the anatomical and histological expression profiles of benchmark GI-related GPCRs, such as the cholecystokinin-1 receptor and GPR120, and 106 oGPCRs were investigated in the mucosal and muscle-myenteric nerve layers in the GI tract of C57BL/6J mice by quantitative real-time polymerase chain reaction. The mRNA expression patterns of these benchmark molecules were consistent with previous in situ hybridization and immunohistochemical studies, validating the experimental protocols in this study. Of 96 oGPCRs with significant mRNA expression in the GI tract, several oGPCRs showed unique expression patterns. GPR85, GPR37, GPR37L1, brain-specific angiogenesis inhibitor (BAI) 1, BAI2, BAI3, and GPRC5B mRNAs were preferentially expressed in the muscle-myenteric nerve layer, similar to GPCRs that are expressed in both the central and enteric nerve systems and that play multiple regulatory roles throughout the gut-brain axis. In contrast, GPR112, trace amine-associated receptor (TAAR) 1, TAAR2, and GPRC5A mRNAs were preferentially expressed in the mucosal layer, suggesting their potential roles in the regulation of secretion, immunity, and epithelial homeostasis. These anatomical and histological mRNA expression profiles of oGPCRs provide useful clues about the physiological roles of oGPCRs in the GI tract.