Díaz-Balzac CA et al. (2012), Calbindin-D32k is localized to a subpopulation ...

ECB-ART-42360

PLoS One 2012 Jan 01;73:e32689. doi: 10.1371/journal.pone.0032689.

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Calbindin-D32k is localized to a subpopulation of neurons in the nervous system of the sea cucumber Holothuria glaberrima (Echinodermata).

Díaz-Balzac CA , Lázaro-Peña MI , García-Rivera EM , González CI , García-Arrarás JE .

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Members of the calbindin subfamily serve as markers of subpopulations of neurons within the vertebrate nervous system. Although markers of these proteins are widely available and used, their application to invertebrate nervous systems has been very limited. In this study we investigated the presence and distribution of members of the calbindin subfamily in the sea cucumber Holothuria glaberrima (Selenka, 1867). Immunohistological experiments with antibodies made against rat calbindin 1, parvalbumin, and calbindin 2, showed that these antibodies labeled cells and fibers within the nervous system of H. glaberrima. Most of the cells and fibers were co-labeled with the neural-specific marker RN1, showing their neural specificity. These were distributed throughout all of the nervous structures, including the connective tissue plexi of the body wall and podia. Bioinformatics analyses of the possible antigen recognized by these markers showed that a calbindin 2-like protein present in the sea urchin Strongylocentrotus purpuratus, corresponded to the calbindin-D32k previously identified in other invertebrates. Western blots with anti-calbindin 1 and anti-parvalbumin showed that these markers recognized an antigen of approximately 32 kDa in homogenates of radial nerve cords of H. glaberrima and Lytechinus variegatus. Furthermore, immunoreactivity with anti-calbindin 1 and anti-parvalbumin was obtained to a fragment of calbindin-D32k of H. glaberrima. Our findings suggest that calbindin-D32k is present in invertebrates and its sequence is more similar to the vertebrate calbindin 2 than to calbindin 1. Thus, characterization of calbindin-D32k in echinoderms provides an important view of the evolution of this protein family and represents a valuable marker to study the nervous system of invertebrates.

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Genes referenced: clcn2 gtf3c1 LOC100887844 LOC100892375 LOC100893907 LOC115919910 LOC115925415 LOC577224 LOC594349 LOC594566 srpl
???displayArticle.antibodies??? LOC576079 Ab1 LOC576079 Ab2 tubb1 Ab3

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	Figure 1. Anti-calbindin 1, anti-parvalbumin, and anti-calbindin 2 immunoreactivity in the nervous system of Holothuria glaberrima (Holothuroidea).Transverse sections through the radial nerve cords showing immunoreactivity to anti-calbindin 1 (A), anti-parvalbumin (B), and anti-calbindin 2 (C) in the ectoneural and hyponeural components of the radial nerve. Double-labeling of anti-calbindin 1 (D) and RN1 (G), anti-parvalbumin (E) and RN1 (H), and anti-calbindin 2 (F) and RN1 (I) in cells (arrows) and fibers of the connective tissue plexus of the tube feet. Co-labeling is observed with the anti-CBPs markers and RN1 in the majority of the fibers, but not in all (arrowheads). ern, ectoneural component of the radial nerve cord; hrn, hyponeural component of the radial nerve cord; , ectoneural component cell bodies; *, hyponeural component cell bodies.
	Figure 2. Anti-calbindin 1, anti-parvalbumin, and anti-calbindin 2 immunoreactivity in the peripheral nerve and circular muscle of Holothuria glaberrima (Holothuroidea).Longitudinal sections through the body wall showing colabeling of anti-calbindin 1 (A) and RN1 (D), anti-parvalbumin (B) and RN1 (E), and anti-calbindin 2 (C) and RN1 (F). Most of the immunoreactivity was observed in the peripheral nerves (arrowheads), while only a minor supopulations of fibers were co-labeled by the anti-CBP and RN1 (arrows).
	Figure 3. Anti-calbindin 1, anti-parvalbumin, and anti-calbindin 2 immunoreactivity in the body wall nervous system of Holothuria glaberrima (Holothuroidea).Longitudinal sections through the body wall showing immunoreactivity to anti-calbindin 1 (A,E,I), anti-parvalbumin (B,F,J), and anti-calbindin 2 (C,G,K) as compared to RN1 (D,H,L) immunoreactivity in the different layers of the body wall. Immunoreactivity of the internal connective tissue plexus (A–D), external connective tissue (E–H) and epidermis (I–L) showed that the anti-CBP only labeled a minor subpopulation of fibers and cells within these plexi, as compared to RN1 which labeled a large subpopulations of cells and fibers of the body wall nervous system.
	Figure 4. Anti-calbindin 1, anti-parvalbumin, and anti-calbindin 2 immunoreactivity in the podial nervous system of Holothuria glaberrima (Holothuroidea).Longitudinal and transverse sections through the tube feet showing immunoreactivity to anti-calbindin 1 (A,D,G,M), anti-parvalbumin (B,E,I,N), and anti-calbindin 2 (C,F,K,O) in the different subdivisions of the podial nervous system. (A–F) Immunoreactivity was observed with all markers in the podial nerve (arrows) and in the podial cylindrical fenestrated sheath (arrowheads). (G–L) Co-labeling of anti-calbindin 1 (G) and RN1 (H), anti-parvalbumin (I) and RN1 (J), and anti-calbindin 2 (K) and RN1 (L) was observed in fibers and cells (arrows) of the connective tissue plexus. (M–O) Anti-calbindin 1 (M), anti-parvalbumin (N), and anti-calbindin 2 (O) immunoreactivity was also present in the nerve plate of the tube feet's disk. Al, ambulacral lumen; ctp, connective tissue plexus; icc, inner cluster of cells; me, mesothelium; np, nerve plate; occ, outer cluster of cells.
	Figure 5. Schematic domain structure of members of the calbindin subfamily in rat (R. norvegicus), fly (D. melanogaster), and sea urchin (S. purpuratus).Domains 1, 3, 4, and 5 are present in all the proteins. The second domain doesn't bind calcium in the calbindin 1 protein, while it does in calbindin 2, and in Drosophila and S. purpuratus' calbindin-D32k. Domain 6 is present in Drosophila calbindin-D32k and S. purpuratus calbindin-D32k, but it is only able to bind calcium in the latter. Pairwise similarities of domains between proteins were calculated by aligning the domains as predicted by ScanProsite.
	Figure 6. Alignment of the peptide sequences and phylogenetic trees of members of the calbindin subfamily from different species.(A) Sequence alignment of rat calbindin 2 (NP_446440.1), Drosophila calbindin-D32k (NP_476838.1), S. kowalevskii calbindin-D32k (XP_002735965.1), and S. purpuratus calbindin-D32k proteins (XP_781517.2). Alignment of the proteins was made using the CLUSTALW multiple sequences alignment. Dots represent conserved residues and black lines below the residues represents the presence of an EF hand domain. (B) Phylogenetic tree of members of the calbindin subfamily from different species. Calb32_Dm Drosophila melanogaster (NP_476838.1), Calb32_Sk S. kowalevskii (XP_002735965.1), Calb32_Sp S. purpuratus (XP_781517.2), Calb32_Sm S. mansoni (XP_002574332.1), Calb2_Gg G. gallus (NP_990647.1), Calb2_Dr D. rerio (NP_957005.1), Calb2_Rn R. norvegicus (NP_446440.1), Calb2_Hs H. sapiens (NP_001731.2), Calb1_Xl X. laevis (NP_00108408.1), Calb1_Gg G. gallus (NP_990844.1), Calb1_Mm M. musculus (AAH16421.1), Calb1_Rn R. norvegicus (AAH81764.1), Calb1_Hs H. sapiens (NP_004920.1), SCGN_Sk S. kowalevskii (NP_001161653.1), SCGN_Sp S. purpuratus (XP_785060.2), SCGN_Dr D. rerio (NP_001005776.1), SCGN_Xl X. laevis (NP_001088097.1), SCGN_Rn R. norvegicus (NP_963855.1), SCGN_Mm M. musculus (NP_663374.1). The phylogenetic tree was constructed from an alignment created by using the unweighted pair group method with arithmetic mean. The scale bar represents 100 times the expected number of amino acid substitution.
	Figure 7. Western blot of holothurian and echinoid radial nerve cords preparations using anti-calbindin 1 and anti-parvalbumin.(A) A 32 kDa immunoreactive band to anti-calbindin 1 was observed in H. glaberrima and L. variegatus radial nerve cords homogenates. A 28 kDa immunoreactive band corresponding to calbindin 1 was observed in the rat kidney positive control and no immunoreactive bands were observed in the synthetic peptide of an EF-hand domain-containing protein negative control. (B) A 32 kDa immunoreactive band to anti-calbindin 1 was observed in H. glaberrima and L. variegatus radial nerve cords homogenates. A 12 kDa major immunoreactive band corresponding to calbindin 1 was observed in the rat skeletal muscle positive control and no immunoreactive bands were observed in the synthetic peptide of an EF-hand domain-containing protein negative control.
	Figure 8. Identification of calbindin-D32k as the anti-calbindin 1 and anti-parvalbumin epitope in echinoderms.(A) Sequence alignment of H. glaberrima calbindin-D32k fragment (Calb32_Hg) and S. purpuratus calbindin-D32k isoform 1 (Calb32(1)_Sp) and isoform 2 (Calb32(2)_Sp), showing a high degree of homology. Alignment of the proteins was made using the CLUSTALW multiple sequences alignment. Dark gray represent conserved residues, light gray represent conservation of strong groups, and black lines below the residues represents the presence of an EF hand domain. (B) A 36 kDa immunoreactive band to anti-calbindin 1 and anti-parvalbumin was observed in the H. glaberrima GST-tagged calbindin-D32k fragment peptide (Calb32_Hg), and no immunoreactive band to anti-calbindin 1 and anti-parvalbumin was observed in the negative control, GST-tagged translationally controlled tumor protein (TCTP).

References [+] :

Agca, Neurosensory and neuromuscular organization in tube feet of the sea urchin Strongylocentrotus purpuratus. 2011, Pubmed, Echinobase

Agca, Neurosensory and neuromuscular organization in tube feet of the sea urchin Strongylocentrotus purpuratus. 2011, Pubmed , Echinobase
Andressen, Calcium-binding proteins: selective markers of nerve cells. 1993, Pubmed
Baimbridge, Calcium-binding proteins in the nervous system. 1992, Pubmed
Bennett-Clarke, Parvalbumin and calbindin immunocytochemistry reveal functionally distinct cell groups and vibrissa-related patterns in the trigeminal brainstem complex of the adult rat. 1992, Pubmed
Celio, Calcium-binding protein parvalbumin as a neuronal marker. 1981, Pubmed
Celio, Calbindin D-28k and parvalbumin in the rat nervous system. 1990, Pubmed
Christakos, Calcium binding protein in squid brain: biochemical similarity to the 28,000-Mr vitamin D-dependent calcium binding protein (calbindin-D28k). 1987, Pubmed
Dalil-Thiney, Immunohistochemical localization of calbindin-D28K and calretinin in the lamprey retina. 1994, Pubmed
DeFelipe, Types of neurons, synaptic connections and chemical characteristics of cells immunoreactive for calbindin-D28K, parvalbumin and calretinin in the neocortex. 1997, Pubmed
Declercq, Ionic interactions with parvalbumins. Crystal structure determination of pike 4.10 parvalbumin in four different ionic environments. 1991, Pubmed
Díaz-Balzac, Neuroanatomy of the tube feet and tentacles in Holothuria glaberrima (Holothuroidea, Echinodermata). 2010, Pubmed , Echinobase
Díaz-Balzac, The catecholaminergic nerve plexus of Holothuroidea. 2010, Pubmed , Echinobase
Díaz-Balzac, Identification of nerve plexi in connective tissues of the sea cucumber Holothuria glaberrima by using a novel nerve-specific antibody. 2007, Pubmed , Echinobase
Díaz-Miranda, Localization of the heptapeptide GFSKLYFamide in the sea cucumber Holothuria glaberrima (Echinodermata): a light and electron microscopic study. 1995, Pubmed , Echinobase
Díaz-Miranda, Galanin-like immunoreactivity in the sea cucumber Holothuria glaberrima. 1996, Pubmed , Echinobase
Friedberg, Parvalbumin isoforms in zebrafish. 2005, Pubmed
Gartner, Cerebral expression and serum detectability of secretagogin, a recently cloned EF-hand Ca(2+)-binding protein. 2001, Pubmed
Hsiao, Isolation and expression of two zebrafish homologues of parvalbumin genes related to chicken CPV3 and mammalian oncomodulin. 2002, Pubmed
Huesa, Calbindin and calretinin immunoreactivities in the retina of a chondrostean, Acipenser baeri. 2002, Pubmed
Hutticher, Parvalbumin-immunoreactive proteins in the nervous system of planarians. 1995, Pubmed
Lee, Molecular cloning, expression and phylogenetic analyses of parvalbumin in tilapia, Oreochromis mossambicus. 2007, Pubmed
Magnusson, Differential distribution of calcium-binding proteins in the dorsal column nuclei of rats: a combined immunohistochemical and retrograde tract tracing study. 1996, Pubmed
Morona, Immunohistochemical localization of calbindin-D28k and calretinin in the brainstem of anuran and urodele amphibians. 2009, Pubmed
Reifegerste, An invertebrate calcium-binding protein of the calbindin subfamily: protein structure, genomic organization, and expression pattern of the calbindin-32 gene of Drosophila. 1993, Pubmed
Ren, A comparative study of the calcium-binding proteins calbindin-D28K, calretinin, calmodulin and parvalbumin in the rat spinal cord. 1994, Pubmed
Revett, Characterization of a helix-loop-helix (EF hand) motif of silver hake parvalbumin isoform B. 1997, Pubmed
Rogers, Calretinin: a gene for a novel calcium-binding protein expressed principally in neurons. 1987, Pubmed
Rojas-Cartagena, Distinct profiles of expressed sequence tags during intestinal regeneration in the sea cucumber Holothuria glaberrima. 2007, Pubmed , Echinobase
Roux, A functional genomic and proteomic perspective of sea urchin calcium signaling and egg activation. 2006, Pubmed , Echinobase
Sigrist, PROSITE, a protein domain database for functional characterization and annotation. 2010, Pubmed
Sodergren, The genome of the sea urchin Strongylocentrotus purpuratus. 2006, Pubmed , Echinobase
Subramaniam, The Biology Workbench--a seamless database and analysis environment for the biologist. 1998, Pubmed
Trotter, Evidence that calcium-dependent cellular processes are involved in the stiffening response of holothurian dermis and that dermal cells contain an organic stiffening factor. 1995, Pubmed
Turbeville, Deuterostome phylogeny and the sister group of the chordates: evidence from molecules and morphology. 1994, Pubmed , Echinobase
Vega, A novel calcium-binding protein is associated with tau proteins in tauopathy. 2008, Pubmed
Wagner, Cloning and expression of secretagogin, a novel neuroendocrine- and pancreatic islet of Langerhans-specific Ca2+-binding protein. 2000, Pubmed
Wilkie, The juxtaligamental cells of Ophiocomina nigra (Abildgaard) (Echinodermata: Ophiuroidea) and their possible role in mechano-effector function of collagenous tissue. 1979, Pubmed , Echinobase