Identification of the Subunit Loci in the Extracellular Multisubunit Hemoglobin from AnnelidPerinereis aibuhitensis

Giant hemoglobin (Hb) fromPerinereis aibuhitensisis made of several types of protein components including single-chain globin (a), disulfide-bridged globin trimer (A-b-B), disulfide-bridged dimers of nonglobin chain (or linkers; L1-L1, L2-L2, and L1-L2), and oligomers of L1-L2 [(L1-L2)n]. The intact...

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Published inArchives of biochemistry and biophysics Vol. 335; no. 1; pp. 23 - 31
Main Authors Yamaki, Mariko, Matsubara, Keiko, Shibuya, Akihiro, Gotoh, Toshio, Ebina, Satoshi
Format Journal Article
LanguageEnglish
Published Elsevier Inc 01.11.1996
Subjects
carbohydrate
giant hemoglobin
gold-labeling
hemoglobin architecture
hemoglobin loci
lectin
linker
linker
hemoglobin loci
gold-labeling
hemoglobin architecture
lectin
giant hemoglobin
carbohydrate
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Summary:Giant hemoglobin (Hb) fromPerinereis aibuhitensisis made of several types of protein components including single-chain globin (a), disulfide-bridged globin trimer (A-b-B), disulfide-bridged dimers of nonglobin chain (or linkers; L1-L1, L2-L2, and L1-L2), and oligomers of L1-L2 [(L1-L2)n]. The intact form of this giant Hb is a two-tiered hexagonal structure composed of 12 identical units, or so-called submultiples (six submultiples to a tier). To obtain a view of the three-dimensional architectural arrangement of these components in the intact form, we identified the subunit loci by using two mutually complementary chemical modifications and a colloidal gold labeling technique. Using the chemical modifications, we discovered that (i) linkers L1-L2 and L2-L2 were located at the exterior of the Hb, (ii) linker L1-L1 and globin a were buried in the interior, and (iii) linker (L1-L2)nand globin trimer A-b-B were located at both exterior and interior loci. The labeling with an L2-specific colloidal gold revealed the predominant loci of L2 at the outer and inner boundaries between neighboring submultiples in a hexagonal form. By combining these results with those from our previous reports [S. Ebina, K. Matsubara, K. Nagayama, M. Yamaki, and T. Gotoh (1995)Proc. Natl. Acad. Sci. USA92, 7367–7371; K. Matsubara, M. Yamaki, Nagayama, H. Ishii, K. Imai, T. Gotoh, and S. Ebina (1996), in press], we deduced the following conclusions concerning the Hb architecture. The L1-L1 chains perhaps together with (L1-L2)nchains form a scaffold on which submultiples assemble into a two-tiered hexagonal arrangement, probably by connecting the carbohydrates in globin a. The L1-L2 and L2-L2 chains reinforce the connections of the submultiples by binding carbohydrates, perhaps those carbohydrates in globin A. We proposed to call this type of non-protein-dependent structural level as seen in such a carbohydrate-glued protein aggregate “protein-plus structure.”
ISSN:0003-9861
1096-0384
DOI:10.1006/abbi.1996.0478