Takahide Watanabe

Identification of Yeast Rho1p GTPase as a Regulatory Subunit of 1,3-β-Glucan Synthase

1,3-β-D-Glucan synthase [also known as β(1→3)glucan synthase] is a multi-enzyme complex that catalyzes the synthesis of 1,3-β-linked glucan, a major structural component of the yeast cell wall. Temperature-sensitive mutants in the essential Rho-type guanosine triphosphatase (GTPase), Rho1p, displayed thermolabile glucan synthase activity, which was restored by the addition of recombinant Rho1p. Glucan synthase from mutants expressing constitutively active Rho1p did not require exogenous guanosine triphosphate for activity. Rho1p copurified with β(1→3)glucan synthase and associated with the Fks1p subunit of this complex in vivo. Both proteins were localized predominantly at sites of cell wall remodeling. Therefore, it appears that Rho1p is a regulatory subunit of β(1→3)glucan synthase.

Truncation of N-terminal extracellular or C-terminal intracellular domains of human ETA receptor abrogated the binding activity to ET-1

We have investigated the function of N-terminal and C-terminal domains of the human ETA receptor by expressing truncated mutants in COS-7 cells. Three kinds of ETA receptors truncated in the N-terminal extracellular or C-terminal intracellular domains were produced. Deletion of the entire extracellular N-terminal or intracellular C-terminal domain completely inactivated the ET-1 binding activity. However, the deletion of one half of the N-terminal extracellular domain of the ETA receptor, missing one of two N-linked glycosylation sites, maintained complete binding activity. Specific monoclonal antibodies detected all the truncated ETA receptors in the cell membrane fraction of transfected COS-7 cells. The size of the ETA receptor was heterogeneous due to differential glycosylation and distributed in 48K, 45K and 42K dalton bands in Western blot analysis. These results demonstrated that a part of the N-terminal domain in close proximity to the first transmembrane region is required for the ligand binding activity of the ETA receptor, and the C-terminal domain is perhaps necessary as an anchor for maintenance of the binding site.

Functional Domains of Human Endothelin Receptor

The ligand binding site to the ETA receptor was investigated by substitution of each 5-amino acid sequence located in the second extracellular (B) region of the ETA receptor with the cognate sequences of the beta 2-adrenergic receptor. A 5-amino acid sequence (140-KLLAG-144) in the B-loop region was implicated as the most important element required for ligand binding. In addition, both the third and the fourth extracellular regions (C- and D-loops), including the flanking transmembrane regions, were found to play an important role in ligand selection. As for the biological significance of the intracellular regions of the ETA receptor, we have found that the C-terminal 8-amino acid residues located in close proximity to the seventh transmembrane region and the C-terminal 16-amino acid residues in the third intracellular loop are important for the binding of ET-1. Therefore, the intracellular third loop and C-terminal domains seem to contribute to the three-dimensional structure of the ligand binding site located in the extracellular domains. The same lines of experiment showed that the ETA receptor requires > 13 amino acid residues at the proximal cytoplasmic tail and 10 amino acid residues in the C-terminal region of the third intracellular loop to induce an ET-1-dependent increase in [Ca2+]i. Both regions are possibly involved in the interaction with G-protein.

Differential sensitivity between Fks1p and Fks2p against a novel beta -1,3-glucan synthase inhibitor, aerothricin3 [corrected].

Fks1p and Fks2p are catalytic subunits of β-1,3-glucan synthase, which synthesize β-1,3-glucan, a main component of the cell wall in Saccharomyces cerevisiae. Although Fks1p and Fks2p are highly homologous, sharing 88.1% identity, it has been shown that Fks2p is more sensitive than Fks1p to one of echinocandin derivatives, which inhibits β-1,3-glucan synthase activity. Here we show a similar differential sensitivity between Fks1p and Fks2p to a novel β-1,3-glucan synthase inhibitor, aerothricin1. To investigate the molecular mechanism of this differential sensitivity, we constructed a series of chimeric genes ofFKSs and examined their sensitivity to aerothricin1. As a result, it was shown that a region around the fourth extracellular domain of Fks2p, containing 10 different amino acid residues from those of Fks1p, provided Fks1p aerothricin1 sensitivity when the region was replaced with a corresponding region of Fks1p. In order to identify essential amino acid residues responsible for the sensitivity, each of the 10 non-conserved amino acids of Fks1p was substituted into the corresponding amino acid of Fks2p by site-directed mutagenesis. Surprisingly, only one amino acid substitution of Fks1p (K1336I) conferred Fks1p hypersensitivity to aerothricin1. On the other hand, reverse substitution of the corresponding amino acid of Fks2p (I1355K) resulted in loss of hypersensitivity to aerothricin1. These results suggest that the 1355th isoleucine of Fks2p plays a key role in aerothricin1 sensitivity.

Detection of an endothelin-1-binding protein complex by low temperature SDS-PAGE

We found that the complex of ET-1 and its binding protein was stable enough to be separated by SDS-PAGE when electrophoresis was run at a low temperature. Cross-linking was not necessary for the detection of [125I]-ET-1 and its binding protein complex by autoradiography. This simple method could be used in qualitative (estimation of apparent molecular weight of ET-1 binding protein) and quantitative (determination of relative content of ET-binding protein) analysis of the ET-binding protein complex. ET-binding protein complexes of various animal species and organs were investigated by this method.

Heterogeneity of endothelin receptor.

The complex formed between endothelin (ET) and its binding protein was adequately stable to be separated by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) at low temperature. Cross-linking was not necessary. This simple method was applied for both qualitative (determination of molecular weight of ET binding protein) and quantitative (determination of content of ET binding protein) analyses of ET-binding protein for various organs from different mammals. Molecular weights of the major ET binding proteins were around 35 and 55 kDa in several canine organs examined. The distribution of these protein species among organs was quite different. In the case of human placenta, the predominant one showed a molecular weight of 35 kDa. We obtained several monoclonal antibodies that could immunoprecipitate ET binding activity from the solubilized human placenta membrane fraction. One of the monoclonal antibodies recognized approximately 58-kDa protein, as determined by Western blot analysis, when the gel is run in the absence of beta-mercaptoethanol.