Growth and function of the embryonic heart depend upon the cardiac-specific L-type calcium channel alpha1 subunit.

The heart must function from the moment of its embryonic assembly, but the molecular underpinnings of the first heart beat are not known, nor whether function determines form at this early stage. Here, we find by positional cloning that the embryonic lethal island beat (isl) mutation in zebrafish disrupts the alpha1 C L-type calcium channel subunit (C-LTCC). The isl atrium is relatively normal in size, and individual cells contract chaotically, in a pattern resembling atrial fibrillation. The ventricle is completely silent. Unlike another mutation with a silent ventricle, isl fails to acquire the normal number of myocytes. Thus, calcium signaling via C-LTCC can regulate heart growth independently of contraction, and plays distinctive roles in fashioning both form and function of the two developing chambers.

Cysteine mutagenesis and homology modeling of the ligand-binding site of a kainate-binding protein.

Glutamate receptors comprise the most abundant group of neurotransmitter receptors in the vertebrate central nervous system. Cysteine mutagenesis in combination with homology modeling has been used to study the determinants of kainate binding in a glutamate receptor subtype, a low molecular weight goldfish kainate-binding protein, GFKARbeta. A construct of GFKARbeta with no cysteines in the extracellular domain was produced, and single cysteine residues were introduced at selected positions. N-Ethylmaleimide or derivatized methanethiosulfonate reagents (neutral or charged) were used to modify the introduced cysteines covalently, and the effect on [(3)H]kainate binding was determined. In addition, cysteine mutants of GFKARbeta transiently expressed in HEK293 cells were labeled with a membrane-impermeable biotinylating reagent followed by precipitation with streptavidin beads and specific detection of GFKARbeta by Western blot analysis. The results are consistent with the proposal that the energy driving kainate binding is contributed both from residues within the binding site and from interactions between two regions (i.e. two lobes) of the protein that are brought into contact upon ligand binding in a manner analogous to that seen in bacterial amino acid-binding proteins.

Goldfish brain GluR2: multiple forms, RNA editing, and alternative splicing.

cDNA coding for a full-length goldfish alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) receptor subunit, GluR2, was cloned by screening unidirectional and bidirectional goldfish brain cDNA libraries. The clone has an open reading frame of 2679 bp, encoding a protein of 893 amino acids. Partial cDNA clones for three other GluR2 subunits were identified. GluR2 from goldfish brain exhibits RNA editing and alternative splicing. RNA editing occurred at the two sites demonstrated for mammalian GluR2 (Q/R and R/G). Unlike rat GluR2, GFGluR2a has a long (68 amino acids) C-terminal tail. Analysis of genomic DNA suggests that an alternatively spliced shorter C-terminal tail can be produced, similar to the rat protein. Thus, in goldfish brain, GluR2 exhibits diversity arising from multiple subtypes, RNA editing, and alternative splicing.

Three-dimensional models of glutamate receptors.

Structural models of glutamate receptors have been produced as part of a multidisciplinary study of neuronal function--both ligand/receptor interactions and ion transport--at the atomic level. The models have concentrated on the agonist binding and transmembrane domains of ionotropic (i.e. ligand-gated) glutamate receptors (iGluRs), and have aided our understanding of the molecular determinants of (1) ligand binding and (2) channel activity. The model building process involved a combination of homology modelling, distance geometry, molecular mechanics, protein-ligand and protein-protein docking, electrostatic calculations and manual adjustment, in conjunction with restraints from site-directed mutagenesis, ligand binding and electrophysiological studies. The initial models were used to produce hypotheses which were tested experimentally; these models have been subsequently refined as part of an extremely effective multidisciplinary study using an iterative molecular modelling/experimental verification cycle in which restraints derived from experimental studies are used at all stages, and the findings from one round of modelling are used as restraints in the next. By studying a variety of agonists and antagonists, details have been built up of (1) those residues involved in ligand binding and (2) the role of agonist binding (i.e. agonist-induced conformational change) in channel gating. The models also aid our understanding of the conductance properties of the channels.

Ligand-binding characteristics and related structural features of the expressed goldfish kainate receptors: identification of a conserved disulfide bond and three residues important for ligand binding.

Low-molecular-weight kainate receptors from nonmammalian vertebrate brain belong structurally to the ionotropic glutamate receptor superfamily. In this study, two previously cloned goldfish kainate receptor subunits (GFKAR alpha and GFKAR beta) were transiently expressed in human embryonic kidney 293 cells, and their ligand-binding properties and some associated structural features were characterized, resulting in the following findings. 1) Both subunits form homomeric receptors with high affinity for [3H]kainate (KD = 16 and 31 nM, respectively) and L-glutamate (KD = 2 and 40 microM, respectively). 2) A deletion mutant lacking the originally proposed second-transmembrane domain was efficiently expressed and retains the overall ligand-binding properties of wild-type GFKAR alpha, strongly indicating that this region is not a transmembrane domain. 3) Mutations of Q12, A53, and Y54 of GFKAR beta indicate that these three residues are important for ligand binding (particularly L-glutamate), which is consistent with the sequence homology to bacterial periplasmic binding proteins. 4) Mutation of the three extracellular cysteine residues of GFKAR beta indicated that the two conserved cysteine residues (C305 and C385), located between two transmembrane segments, form a solvent-accessible disulfide bond. Analysis of [3H]kainate binding to wild-type and cysteine mutations of GFKAR beta indicate that in the absence of the disulfide bond, the affinity for kainate is increased 3-fold. These data lend further evidence in support of a model of glutamate receptor topology with three transmembrane segments and reveal several general structural features of the extracellular ligand-binding domain of the kainate receptors. These results are consistent with the notion that the ligand-binding domain has close structural similarities to bacterial periplasmic binding proteins.

Three-dimensional models of non-NMDA glutamate receptors.

Structural models have been produced for three types of non-NMDA inotropic glutamate receptors: an AMPA receptor, GluR1, a kainate receptor, GluR6; and a low-molecular-weight kainate receptor from goldfish, GFKAR alpha. Modeling was restricted to the domains of the proteins that bind the neurotransmitter glutamate and that form the ion channel. Model building combined homology modeling, distance geometry, molecular mechanics, interactive modeling, and known constraints. The models indicate new potential interactions in the extracellular domain between protein and agonists, and suggest that the transition from the "closed" to the "open" state involves the movement of a conserved positive residue away from, and two conserved negative residues into, the extracellular entrance to the pore upon binding. As a first approximation, the ion channel domain was modeled with a structure comprising a central antiparallel beta-barrel that partially crosses the membrane, and against which alpha-helices from each subunit are packed; a third alpha-helix packs against these two helices in each subunit. Much, but not all, of the available data were consistent with this structure. Modifying the beta-barrel to a loop-like topology produced a model consistent with available data.

Asn-265 of frog kainate binding protein is a functional glycosylation site: implications for the transmembrane topology of glutamate receptors.

Kainate binding proteins (KBPs) from frog and goldfish brain are glycosylated, integral membrane proteins. These KBPs are homologous (35-40%) to the C-terminal half of AMPA and kainate receptors which have been shown to form glutamate-gated ion channels. We report here that the frog KBP has three functional N-glycosylation sites. Of particular interest, Asn-265, a residue located between two putative membrane spanning regions of the frog KBP, is a functional N-glycosylation site. A mutation of Ser-267 to Gly renders this site non-functional as shown using an in vitro translation system and by transient expression in human embryonic kidney (HEK 293) cells. The mutant receptor protein (S267G), when expressed in HEK cells, binds kainate with high affinity (Kd = 16 nM). These results further support a topology with three transmembrane segments for KBPs and, by sequence homology, for glutamate-gated ion channels.

Unraveling the modular design of glutamate-gated ion channels.

Glutamate receptors that function as ligand-gated ion channels are essential components of cell-cell communication in the nervous system. Despite a wealth of information concerning these receptors, details of their structure are just beginning to emerge. We propose that glutamate receptors comprise four modules: two modules that are related to bacterial periplasmic-binding proteins, one module that is related to the pore-forming region of K+ channels, and one regulatory module of unknown origin. A K(+)-channel-like domain inserted into a crucial region of a periplasmic-binding protein-like domain suggests a mechanism for transduction of binding energy to channel opening. This modular design also suggests an evolutionary link between a ligand-gated ion-channel family and voltage-gated ion channels.

A topological analysis of goldfish kainate receptors predicts three transmembrane segments.

Glutamate receptors are the most abundant excitatory neurotransmitter receptors in vertebrate brain. We have previously cloned cDNAs encoding two homologous kainate receptors (GFKAR alpha, 45 kDa, and GFKAR beta, 41 kDa) from goldfish brain and proposed a topology with three transmembrane domains (Wo, Z. G., and Oswald, R. E. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 7154-7158). These studies have been extended using an in vitro translation/translocation system in conjunction with site-specific antibodies and point and deletion mutations. We report here that the entire region between the previously proposed third and fourth transmembrane segments is translocated and likely to be extracellular in mature receptors. This was based on the following results. 1) The entire segment was protected from Proteinase K and trypsin digestion and could be immunoprecipitated by a site-specific antibody. 2) Functional sites for N-glycosylation are present in the C-terminal half of the segment, and 3) a mutation, constructed with an additional consensus site for N-glycosylation in the N-terminal half of the segment, was found to be glycosylated at that site. Given the fact that the N terminus of the protein is likely to be extracellular, this would place an even number of transmembrane segments between the extracellular N terminus and the glycosylated segment. In addition, results of N-glycosylation and proteolysis protection assays of GFKAR alpha mutations indicated that the previously proposed second transmembrane segment is not a true transmembrane domain. These results provide further evidence in support of a topology with three transmembrane domains that has important implications for the relationship of structure to function in ionotropic glutamate receptors.

Transmembrane topology of two kainate receptor subunits revealed by N-glycosylation.

Glutamate receptors are the primary excitatory neurotransmitter receptors in vertebrate brain and are of critical importance to a wide variety of neurological processes. Recent reports suggest that ionotropic glutamate receptors may have a unique transmembrane topology not shared by other ligand-gated ion channels. We report here the cloning of cDNAs from goldfish brain encoding two homologous kainate receptors with protein molecular masses of 41 kDa. Using a cell-free translation/translocation system, we show that (i) a portion of these receptors previously thought to be a large intracellular loop is actually located extracellularly and (ii) the putative second transmembrane region of the receptor thought to line the ion channel may not be a true membrane-spanning domain. An alternative model for the transmembrane topology of kainate receptors is proposed that could potentially serve as a framework for future detailed study of the structure of this important class of neurotransmitter receptors.