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      Molluscan mega-hemocyanin: an ancient oxygen carrier tuned by a ~550 kDa polypeptide

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          Abstract

          Background

          The allosteric respiratory protein hemocyanin occurs in gastropods as tubular di-, tri- and multimers of a 35 × 18 nm, ring-like decamer with a collar complex at one opening. The decamer comprises five subunit dimers. The subunit, a 400 kDa polypeptide, is a concatenation of eight paralogous functional units. Their exact topology within the quaternary structure has recently been solved by 3D electron microscopy, providing a molecular model of an entire didecamer (two conjoined decamers). Here we study keyhole limpet hemocyanin (KLH2) tridecamers to unravel the exact association mode of the third decamer. Moreover, we introduce and describe a more complex type of hemocyanin tridecamer discovered in fresh/brackish-water cerithioid snails ( Leptoxis, Melanoides, Terebralia).

          Results

          The "typical" KLH2 tridecamer is partially hollow, whereas the cerithioid tridecamer is almost completely filled with material; it was therefore termed "mega-hemocyanin". In both types, the staggering angle between adjoining decamers is 36°. The cerithioid tridecamer comprises two typical decamers based on the canonical 400 kDa subunit, flanking a central "mega-decamer" composed of ten unique ~550 kDa subunits. The additional ~150 kDa per subunit substantially enlarge the internal collar complex. Preliminary oxygen binding measurements indicate a moderate hemocyanin oxygen affinity in Leptoxis (p50 ~9 mmHg), and a very high affinity in Melanoides (~3 mmHg) and Terebralia (~2 mmHg). Species-specific and individual variation in the proportions of the two subunit types was also observed, leading to differences in the oligomeric states found in the hemolymph.

          Conclusions

          In cerithioid hemocyanin tridecamers ("mega-hemocyanin") the collar complex of the central decamer is substantially enlarged and modified. The preliminary O 2 binding curves indicate that there are species-specific functional differences in the cerithioid mega-hemocyanins which might reflect different physiological tolerances of these gill-breathing animals. The observed differential expression of the two subunit types of mega-hemocyanin might allow individual respiratory acclimatization. We hypothesize that mega-hemocyanin is a key character supporting the adaptive radiation and invasive capacity of cerithioid snails.

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          Most cited references38

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          Accurate determination of local defocus and specimen tilt in electron microscopy

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            Global diversity of gastropods (Gastropoda; Mollusca) in freshwater

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              Sense and stretchability: the role of titin and titin-associated proteins in myocardial stress-sensing and mechanical dysfunction.

              Mechanical stress signals transmitted through the heart walls during hemodynamic loading are sensed by the myocytes, which respond with changes in contractile performance and gene expression. External forces play an important role in physiological heart development and hypertrophy, but disruption of the well-balanced stress-sensing machinery causes mechanical dysregulation, cardiac remodelling, and heart failure. Nodal points of mechanosensing in the cardiomyocytes may reside in the Z-disk, I-band, and M-band regions of the sarcomeres. Longitudinal linkage of these regions is provided by the titin filament, and several 'hot spots' along this giant protein, in complex with some of its >20 ligands, may be pivotal to the myofibrillar stress or stretch response. This review outlines the known interaction partners of titin, highlights the putative stress/stretch-sensor complexes at titin's NH(2) and COOH termini and their role in myopathies, and summarizes the known disease-associated mutations in those titin regions. Another focus is the elastic I-band titin section, which interacts with a diverse number of proteins and whose main function is as a determinant of diastolic distensibility and passive stiffness. The discussion centers on recent insights into the plasticity, mechanical role, and regulation of the elastic titin springs during cardiac development and in human heart disease. Titin and titin-based protein complexes are now recognized as integral parts of the mechanosensitive protein network and as critical components in cardiomyocyte stress/stretch signalling.
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                Author and article information

                Journal
                Front Zool
                Frontiers in Zoology
                BioMed Central
                1742-9994
                2010
                13 May 2010
                : 7
                : 14
                Affiliations
                [1 ]Institute of Zoology, Johannes Gutenberg University, 55099 Mainz, Germany
                [2 ]Institute of Molecular Biophysics, Johannes Gutenberg University, 55099 Mainz, Germany
                [3 ]Department of Invertebrate Zoology, Smithsonian Institution, National Museum of Natural History, MRC, 163, PO Box 37012, Washington, DC 20013-7012, USA
                Article
                1742-9994-7-14
                10.1186/1742-9994-7-14
                2881123
                20465844
                82b55506-8810-4f0a-9704-366d0a0ba1e5
                Copyright ©2010 Lieb et al; licensee BioMed Central Ltd.

                This is an Open Access article distributed under the terms of the Creative Commons Attribution License ( http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

                History
                : 18 January 2010
                : 13 May 2010
                Categories
                Research

                Animal science & Zoology
                Animal science & Zoology

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