The neuronal EF-hand Ca(2+)-binding protein VILIP: interaction with cell membrane and actin-based cytoskeleton.

VILIP is a member of the visinin/recoverin family of neuronal EF-hand Ca(2+)-binding proteins. Cell fractionation revealed cytoplasmic, membrane- and cytoskeleton-associated pools of VILIP. The association with the cytoskeletal protein fraction is Ca(2+)-dependent and may be mediated by direct interaction with actin. This is concluded from the observations that (i) Ca(2+)-loaded recombinant VILIP binds actin in an overlay assay; (ii) in the presence of Ca(2+), beta-actin co-immunoprecipitates with native VILIP from brain extracts, and (iii) actin and VILIP are co-localized in PC12 cells stably transfected with VILIP cDNA. The interaction of VILIP with the cortical cytoskeleton through actin may facilitate a Ca(2+)-dependent recruitment of VILIP to the cell membrane.

Localization of the neural calcium-binding protein VILIP (visinin-like protein) in neurons of the chick visual system and cerebellum.

The visinin-like protein (VILIP) is a member of a recently discovered family of calcium sensors specifically expressed in neurons. Family members contain four potential calcium-binding domains commonly referred to as "EF-hand motifs". VILIP interacts in a calcium-dependent manner with the actin-based neuronal cytoskeleton and modulates the phosphorylation of G-protein-coupled receptors, i.e., rhodopsin, in vitro. Here, we have used antisera against VILIP to study its distribution in the chick brain. Immunostaining of subsets of neurons is observed throughout the brain. Generally, the distribution of VILIP coincides well with the distribution of VILIP transcripts as detected previously by in situ hybridization. The most intense expression is detected in the visual system and the cerebellum. In the visual system, neurons of the nuclei of the ascending tecto-fugal pathway are stained, as are the pretectal, isthmic, and oculomotor nuclei. VILIP immunoreactivity is found in cell bodies, dendrites, and synaptic structures. Thus, VILIP appears to be an excellent marker for the characterization of neurons of the visual pathway. In the cerebellum, VILIP immunoreactivity is detected in deep cerebellar nuclei and in a subset of granule cells, Golgi type II cells, basket cells, and stellate cells, whereas it is completely absent from Purkinje cells. Intense punctate staining in the molecular layer suggests that VILIP is transported from deep cerebellar nuclei and from granule cells to the glutamatergic climbing-fiber and parallel-fiber synapses, respectively, both of which terminate on Purkinje-cell dendrites. The localization of VILIP in these presynaptic terminals has been confirmed at the electron-microscopic level.

Distribution of visinin-like protein (VILIP) immunoreactivity in the hippocampus of the Mongolian gerbil (Meriones unguiculatus).

Visinin-like protein (VILIP) is a neuronal EF-hand Ca(2+)-binding protein. In the chick brain, it is widely expressed, e.g. in neurons of the visual pathway and the cerebellum. In the cerebellum, a presynaptic localization of VILIP in glutamatergic parallel- and climbing-fiber terminals has been observed. Here, we describe the distribution of immunoreactivity (IR) detected by antibodies against chick VILIP in the gerbil hippocampus at the light and electron microscopic level. VILIP antibodies stain neurons in the whole hippocampal formation including pyramidal cells in the CA1 and CA3 region of the Ammon's horn and granule cells of the dentate gyrus. In CA3 neurons, VILIP-IR is localized in dendrites and dendritic spines.

Regulation of rhodopsin phosphorylation by a family of neuronal calcium sensors.

Recoverin is a calcium sensor that regulates rhodopsin phosphorylation in a calcium-dependent manner. Cloning experiments indicate the presence of a numerous gene family, called the NCS family, encoding recoverin-like proteins expressed predominantly in neurons. Here, we report the cloning of three novel NCS genes, and demonstrate that at least six distinct members of the NCS family (including recoverin, S-modulin, vilip 1, NCS-1, Ce-NCS-1, and Ce-NCS-2) specifically inhibit rhodopsin phosphorylation. The presence of species homologues within the NCS family suggests that this function might be shared by at least 12 (out of 18) NCS proteins. Recent studies indicate that recoverin inhibits rhodopsin phosphorylation by directly regulating rhodopsin kinase, a G protein coupled receptor kinase (GRK). Since several NCS proteins are found in neurons throughout the entire nervous system, they may regulate other members of the GRK family. Together, our data suggest a general role for NCS proteins in the regulation of calcium-dependent phosphorylation in the nervous system.

Distribution pattern of three neural calcium-binding proteins (NCS-1, VILIP and recoverin) in chicken, bovine and rat retina.

Neural Ca(2+)-binding proteins (NCaPs) constitute a subfamily of 4-EF-hand proteins, and display a histological and structural dichotomy: the A-type NCaPs are selectively expressed by the retina and pineal organ and display two canonical EF-hands, whereas the B-type NCaPs are found in the entire brain and present three regular EF-hands. In this study, antisera were raised against the A-type NCaP recoverin (26 kDa) and the B-type NCaPs VILIP and NCS-1 (22 kDa). Since the sequence identity among NCaPs is high, specific polyclonal antibodies were purified by double cross-immunoaffinity chromatography; both ELISA and immunoblot analyses determined that the resulting antibodies showed selectivity ratios inferior to 1/363 for the two other related NCaPs. Besides, the anti-VILIP antibodies displayed some affinity toward neurocalcin delta, and the antirecoverin antibodies recognized a 24 kDa protein, which is most likely visinin. Thus, immunohistochemical studies on the chicken, rat and cow retina revealed that anti-recoverin antibodies recognized the vertebrate photoreceptors and a small number of mammalian bipolar cells. Anti-VILIP antibodies exclusively labelled the inner retina, i.e. the amacrine and ganglion cells. NCS-1 was mainly present in the photoreceptor inner segments, the inner plexiform layer and the ganglion cells. NCS-1 showed the highest species disparity. The retinal localization of NCS-1 and VILIP offered an important morphological basis for the understanding of their function. Furthermore, specific antibodies against the NCaPs may enable the identification of cell populations in more complex neural tissues, such as the brain.

Cation binding and conformational changes in VILIP and NCS-1, two neuron-specific calcium-binding proteins.

VILIP and NCS-1, neural-specific, 22-kDa Ca(2+)-binding proteins possessing four EF-hands, were expressed in Escherichia coli to study their divalent cation properties. Flow dialysis (Ca2+ binding) and equilibrium gel filtration (Mg2+ binding) revealed that both recombinant proteins possess only two active metal-binding sites, which can accommodate either Ca2+ or Mg2+. VILIP binds cations without cooperativity with intrinsic affinity constants K'Ca of 1.0 x 10(6) M-1 and K'Mg of 4.8 x 10(3) M-1.Mg2+ antagonizes Ca2+ binding by shifting the isotherms to higher free Ca2+ concentrations without changing their shape. The competition equation yields a K'Mg, comp value of 180 M-1 for both sites. NCS-1 binds two Mg2+ without cooperativity with K'Mg of 8.3 x 10(4) M-1 and two Ca2+ with very strong positive cooperativity (nH = 1.96). In the absence of Mg2+ the K'Ca1 and K'Ca2 values are 8.9 x 10(4) and 1.4 x 10(8) M-1, respectively, which represent an allosteric increase of 1600-fold. Mg2+ shifts the Ca(2+)-binding isotherms to higher Ca2+ concentrations, yielding a K'Mg, comp value of 800 M-1 for both sites. Thus VILIP and NCS-1 show three remarkable differences in the Ca2+/Mg2+ binding parameters: 1) VILIP binds Ca2+ with much lower affinity than NCS-1; 2) VILIP binds Ca2+ in a noncooperative way, whereas NCS-1 shows maximal positive cooperativity; 3) in VILIP the Mg2+/Ca2+ antagonism is much weaker than in NCS-1. Conformational changes monitored by Trp fluorescence indicate that the metal-free forms already are highly structured. Ca2+ binding promotes a 20-30% increase of fluorescence in both proteins, but whereas the Mg2+ form of VILIP has the same fluorescence properties as the metal-free form, Mg(2+)-saturated NCS-1 has those of the Ca2+ form. Near UV difference spectra confirmed that in VILIP the Mg2+ form is very similar to the metal-free form; in NCS-1 it is different, especially in the Tyr region. NCS-1 possesses one unique Cys-38 in EF-hand site I. Its reactivity (kSH) toward 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) is the same for the Ca(2+)- and Mg(2+)-loaded protein, but kSH is 4-fold higher in metal-free NCS-1. VILIP possesses two additional thiols, one of which is inaccessible to DTNB in the native protein. The reactivity of the two accessible thiols is identical in the metal-free and Mg2+ forms and 5-fold higher than in the Ca2+ form.(ABSTRACT TRUNCATED AT 400 WORDS)

VILIP, a cognate protein of the retinal calcium binding proteins visinin and recoverin, is expressed in the developing chicken brain.

Using a selective cloning approach we previously isolated a number of cDNAs of transcripts that are newly expressed during terminal differentiation of the chicken optic tectum. Here, we have characterized one of these cDNAs (OZ1) by Northern analysis and in situ hybridization. The OZ1 cDNA hybridizes to two transcripts of 1.6 kb and 2.9 kb which are widely expressed in the brain but not detectable in liver, heart or skeletal muscle. Cloning of overlapping cDNAs revealed that both transcripts encode the same open reading frame for a polypeptide of 191 amino acids. The deduced protein contains 4 EF-hand consensus motifs characteristic of calmodulin-like Ca(2+)-binding proteins. It displays 40% and 46% sequence identity with the retinal photoreceptor-specific Ca(2+)-binding proteins visinin and recoverin, respectively, and was termed VILIP (visinin-like protein). VILIP transcripts are also expressed in the retina. However, the expression pattern does not overlap with that of visinin or recoverin. The possible functional implications of the similarity to recoverin, which regulates guanylate cyclase activity of retinal rod cells in a Ca(2+)-dependent manner, are discussed.