Experimental manipulation of cell surface to affect cellular recognition mechanisms.

The mechanism of selective cell adhesion was studied using Chinese hamster V79 and chick embryonic neural retinal cells. Both of these cell types have been shown to have two experimentally separable mechanisms of adhesion; Ca²⁺-dependent and Ca²⁺-independent. Cells can be dispersed so that either or both of the mechanisms remain intact by use of different treatments. A method of labeling cells with FITC was devised to identify one of the two types of cells in a binary cell population. When cells with one of the two adhesion mechanisms were mixed with cells with the other mechanism, they segregated completely, forming independent aggregates, not only in the heterotypic combination of these cell types but also in the homotypic combination of each cell type. In contrast, when cells were mixed with others with the same adhesion mechanism, either Ca²⁺-dependent or -independent, they formed chimeric aggregates, even in the heterotypic cell combination. These results suggest that the specificity in each of those two mechanisms of cell adhesion plays an important role in cellular recognition processes.     

Two distinct adhesion mechanisms in embryonic neural retina cells. II. An immunological analysis

Antibodies were raised against neural retina cells prepared by dissociation in EGTA alone (E cells, Ca²⁺-independent aggregation), in trypsin + Ca²⁺ (TC cells, Ca²⁺-dependent aggregation), or in trypsin + EGTA (TE cells, nonadhesive). Anti-E-cell Fab selectively inhibited Ca²⁺-independent aggregation, anti-TC-cell Fab selectively inhibited Ca²⁺-dependent aggregation, and anti-TE-cell Fab inhibited neither. Fab from a fourth preparation, also raised against E cells, inhibited both Ca²⁺-independent and Ca²⁺-dependent aggregation but was separated by immunoadsorption into two fractions, one specific for each mode of aggregation. In cells which utilize both modes simultaneously (LTC cells), each was inhibited exclusively by the appropriate Fab. The immunological data presented here demonstrate the existence in the same cells of two distinct and functionally independent adhesion mechanisms, each responsible for one of the two modes of aggregation. The differing adhesive properties of retinal cells prepared by different procedures are explained by the presence, absence, or degree of activity of these two mechanisms, qualities regulated by the concentrations of trypsin and Ca²⁺ used in the tissue dissociation.     

Cell-Cell adhesion molecule: Identification of a glycoprotein relevant to the Ca2+-independent aggregation of chinese hamster fibroblasts

Molecules making up the Ca²⁺-independent cell-cell adhesion sites (CIDS) of Chinese hamster V79 cells have been investigated. Previous studies showed that Fab fragments (Fab) of the antibody raised against the surface of V79 cells inhibit the Ca²⁺-independent aggregation of V79 cells, and that this inhibitory effect is neutralized by the addition of some proteinous substance released from the surface of V79 cells treated with 0.01% trypsin. In the present study, we found that the antibody raised against this substance (anti-TRF) displays the complement-dependent cytotoxicity more strongly to the cells with active CIDS than to those without it. The Fab of this antibody inhibited the Ca²⁺-independent aggregation of V79 cells strongly, particularly in the presence of a hyaluronidase. Electrophoresis of the materials immunoprecipitated with anti-TRF from lysates of cells labeled with radioactive iodine, monosaccharides or methionine showed that a glycoprotein with a molecular weight of 125,000 is the only component to react with this antibody in cells with the active CIDS. Indirect immunofluorescence of anti-TRF showed that the antigens are distributed over the entire surface of V79 cells, and are present only in fibroblastic cells in the primary culture of Chinese hamster hepatic cells. These results suggest that the glycoprotein with a molecular weight of 125,000 has a specific role in the Ca²⁺-independent adhesion of Chinese hamster fibroblastic cells.     

Two distinct adhesion mechanisms in embryonic neural retina cells. I. A kinetic analysis

The reaggregation kinetics of embryonic chick neural retina cells prepared using several different dissociation procedures were monitored through decreases in the small-angle light scattering of aggregating samples. Two distinct modes of aggregation were revealed, one Ca²⁺ independent, the other Ca²⁺ dependent, suggesting the existence of two separate adhesion mechanisms. By varying the concentrations of Ca²⁺ and trypsin in the dissociation medium, we obtained cells which exhibited both, either, or neither mode of aggregation. The Ca²⁺-independent adhesiveness is active in the absence of proteolysis, is resistant to low levels of trypsin (0.001%), but is readily inactivated at higher trypsin concentrations in either the presence or absence of Ca²⁺. It is relatively temperature independent. By contrast, the Ca²⁺-dependent adhesiveness is not detected before exposure of the cells to proteolysis. It is expressed after tryptic proteolysis in the presence of Ca²⁺ and is then highly temperature dependent. It is resistant to further digestion by trypsin in the continued presence of Ca²⁺ but is lost when Ca²⁺ is subsequently removed, apparently through the expression of tryptic cleavage incurred earlier. We suggest that its increased activity may result at least in part from the clustering of surface components into adhesive patches. A provisional model is presented correlating these data.     

Functional correlation between cell adhesive properties and some cell surface proteins

The adhesive properties of Chinese hamster V79 cells were analyzed and characterized by various cell dissociation treatments. The comparisons of aggregability among cells dissociated with EDTA, trypsin + Ca2+, and trypsin + EDTA, revealed that these cells have two adhesion mechanisms, a Ca2+-independent and a Ca2+-dependent one. The former did not depend on temperature, whereas the latter occurred only at physiological temperatures. Both mechanisms were trypsin sensitive, but the Ca2+- dependent one was protected by Ca2+ against trypsinization. In morphological studies, the Ca2+-independent adhesion appeared to be a simple agglutination or flocculation of cells, whereas the Ca2+- dependent adhesion seemed to be more physiological, being accompanied by cell deformation resulting in the increase of contact area between adjacent cells. Lactoperoxidase-catalyzed iodination of cell surface proteins revealed that several proteins are more intensely labeled in cells with Ca2+-independent adhesiveness than in cells without that property. It was also found that a cell surface protein with a molecular weight of approximately 150,000 is present only in cells with Ca2+-dependent adhesiveness. The iodination and trypsinization of this protein were protected by Ca2+, suggesting its reactivity to Ca2+. Possible mechanisms for each adhesion property are discussed, taking into account the correlation of these proteins with cell adhesiveness.     

Cleavage stage mouse embryos share a common cell adhesion system with teratocarcinoma cells

We examined similarities in adhesive properties of mouse cleaving embryos at one- to eight-cell stages and of teratocarcinoma cells by aggregation studies. Teratocarcinoma cells and fibroblastic cells have a Ca²⁺-dependent cell-cell adhesion site (CDS), which is resistant to trypsin in the presence of Ca²⁺ but sensitive in the absence of Ca²⁺. When several embryos treated with trypsin in the presence of Ca²⁺ (TC) were kept in contact with each other, they fused into a single aggregate in the medium with Ca²⁺ but not without Ca²⁺. Embryos treated with trypsin in the absence of Ca²⁺ (TE) did not show such Ca²⁺-dependent aggregation. Aggregation of TC-treated embryos was inhibited by Fab fragments of antibody raised against TC-treated teratocarcinoma F9 cells. The aggregation-inhibitory effect of the Fab was removed by absorption with TC-treated teratocarcinoma cells, but not with TE-treated teratocarcinoma cells. This effect was not removed by absorption with fibroblasts and some other tissue cells. TC-treated embryos adhered to TC-treated teratocarcinoma cells, but not to TC-treated fibroblastic cells. These results suggest that early mouse embryos share a common CDS molecule with teratocarcinoma cells but not with fibroblastic cells.     

In vitro reaggregation of dissociated mouse cerebellar cells : I. Demonstration of different aggregation mechanisms

Reaggregation of mechanically dissociated mouse cerebellar cells (M cells) was compared with cells that received an additional trypsinization either before (T cells) or after (MT cells) the dissociation step. Reaggregation behaviour was followed by measuring the number and size distribution of particles with a Coulter counter. Aggregation rates which were calculated as percentage of decrease of particles could be measured reproducibly. Since the percentage of very large particles (> 100 cells) formed during aggregation varied considerably from one experiment to the next, size distribution curves of particles were used more to distinguish qualitative differences in a less quantitative way.Whereas aggregation rates and size distribution of particles with M cells were almost identical when aggregation occurred in medium of high (1.1 mM) or low (0.1 mM) Ca²⁺ concentrations, T and MT cells aggregated better at high Ca²⁺ concentration. Their aggregation rates were reduced by approx. 50% at low Ca²⁺ concentrations and larger aggregates were hardly formed under these conditions. The aggregation rates of T and MT cells showed a clear dependence on Ca²⁺ concentration, being half maximal at approx. 0.1 mM Ca²⁺.The ability of M cells to aggregate at low or high Ca²⁺ concentrations was influenced by subsequent trypsinization to produce MT cells. When the trypsin concentration was changed from 0.001 to 0.1% during this procedure the aggregation rates at high Ca²⁺ concentration were reduced to approx. 80% of the maximal value, whereas those at low Ca²⁺ concentrations were reduced to 35%. Variation of the Ca²⁺ concentration between 1.1 and 0.1 mM during the trypsinization step (0.015% trypsin) revealed no difference on the aggregation rates.We propose that M cells aggregate mainly or exclusively by a Ca²⁺-independent binding mechanism, whereas T or MT cells aggregate using a Ca²⁺-dependent one which may be functionally silent in M cells.     

Calcium-dependent adhesion of Drosophila embryonic cells

Summary By using an in vitro functional assay, we have shown that Drosophila embryonic cells possess Ca²⁺-dependent adhesive sites, which resemble in many respects those described for vertebrate cells and tissues. The cells, obtained by mechanical disruption of gastrulastage embryos, form aggregates within 30 min when maintained under constant rolling. The aggregation is completely dependent on the presence of Ca²⁺ in the medium. In its absence, the cells remain dispersed but the process is reversible by readdition of Ca²⁺. In addition the aggregation is temperature-dependent. No aggregation occurs at 4° C but it can be restored by raising the temperature to 25° C. These properties are characteristic of these cells: established cell lines do not aggregate under the same conditions and mixing of cell lines and embryonic cells does not result in chimeric aggregates, thus pointing towards cell-type selectivity with respect to aggregability. Observations in electron microscopy have shown that the embryonic cells in the aggregates tightly adhere to one another and form, as early as after 30 min, maculae adherens junctions. Drosophila embryonic cells have adhesion sites that are protected from trypsin proteolysis in the presence of Ca²⁺ and sensitive in its absence. The cells' aggregation can be inhibited by a mouse antiserum directed against cell-surface components and a good correlation exists between neutralization of the inhibitory activity of the antiserum and the presence of trypsin-sensitive sites on the cells. These data are in favour of cell-cell adhesion mediated by specific adhesion proteins.     

Requirements for the Ca2+-independent component in the initial intercellular adhesion of C2 myoblasts

Using a sensitive and quantitative adhesion assay, we have studied the initial stages of the intercellular adhesion of the C2 mouse myoblast line. After dissociation in low levels of trypsin in EDTA, C2 cells can rapidly reaggregate by Ca2+-independent mechanisms to form large multicellular aggregates. If cells are allowed to recover from dissociation by incubation in defined media, this adhesive system is augmented by a Ca2+-dependent mechanism with maximum recovery seen after 4 h incubation. The Ca2+-independent adhesion system is inhibited by preincubation of cell monolayers with cycloheximide before dissociation. Aggregation is also reduced after exposure to monensin, implicating a role for surface-translocated glycoproteins in this mechanism of adhesion. In coaggregation experiments using C2 myoblasts and 3T3 fibroblasts in which the Ca2+-dependent adhesion system was inactivated, no adhesive specificity between the two cell types was seen. Although synthetic peptides containing the RGD sequence are known to inhibit cell-substratum adhesion in various cell types, incubation of C2 myoblasts with the integrin-binding tetrapeptide, RGDS, greatly stimulated the Ca2+-independent aggregation of these cells while control analogs had no effect. These results show that a Ca2+- independent mechanism alone is sufficient to allow for the rapid formation of multicellular aggregates in a mouse myoblast line, and that many of the requirements and perturbants of the Ca2+-independent system of intercellular myoblast adhesion are similar to those of the Ca2+-dependent adhesion mechanisms.     

A Possible Role for Ligatin and the Phosphoglycoproteins It Binds in Calcium-Dependent Retinal Cell Adhesion

Ligatin is a filamentous plasma membrane protein that serves as a baseplate for the attachment of peripheral glycoproteins to the external cell surface. Ligatin can be released from intact, embryonic chick neural retinal cells by treatment with 20 mM Ca⁺⁺ without adversely affecting their viability. α-Glucose-1-phos phate is also effective in removing ligatin-associated glycoproteins from intact cells. After either of these treatments, the retinal cells seem not to exhibit Ca⁺⁺ -dependent adhesion for one another. It is thus suggested that ligatin in neural retina may serve as a baseplate for the attachment to the cell surface of glycoproteins active in Ca⁺⁺-dependent adhesion. The finding that Ca⁺⁺ serves to protect Ca⁺⁺-dependent adhesion molecules from digestion by trypsin is discussed in relation to steric constraints on trypsin's accessibility to these adhesion molecules because of their possible binding to arrayed ligatin filaments.     

Role of calcium-dependent and calcium-independent mechanisms in the adhesion of retinal and pigment epithelium cells in the chick embryo

The mechanisms of adhesion of the retinal and pigment epithelium cells, as well of cell interaction within each of these tissues were studied during development. It was shown by means of separation of retina from pigment epithelium in different dissociation media that the adhesion of these tissues in 5-6 day old chick embryos is realized via a Ca2+-independent mechanism. The adhesion of these tissues decreases between days 7 and 16. Starting from day 16, both Ca2+-independent and Ca2+-dependent mechanisms are involved in the interaction of the retinal and pigment epithelium cells. By measuring the output of single cells into the suspension after the treatment of retina and pigment epithelium with different dissociating agents, it was shown that from the 5th day of incubation on the adhesion of pigment epithelium cells is mediated by Ca2+-dependent mechanism. In the retina three types of cells were found: interacting via Ca2+-dependent mechanism only, Ca2+-independent mechanism only, and both the mechanisms. In the course of differentiation, the numbers of the population of cells interacting only via Ca2+-dependent mechanism increase, while those of cells interacting via Ca2+-independent mechanism decrease. It is suggested that at each developmental stage those retinal cell possess Ca2+-dependent mechanism of adhesion which are closest to the definitive state.     

Purification and characterization of a species-specific aggregation factor in sponges

The events during re-aggregation of sponge cells, dissociated in Ca²⁺- and Mg²⁺-free artificial sea water, containing trypsin, can be subdivided into three phases. The first event is the formation of primary aggregates with a diameter of 82 μm. It is Ca²⁺- and Mg²⁺-dependent and insensitive towards trypsin and puromycin even at high concentrations. The formation of secondary aggregates with a diameter greater than 1 000 μm, is initiated by an aggregation factor. This factor can be separated from the formed elements with calcium- and magnesium-free artificial sea water. Its action is Ca²⁺- and Mg²⁺-dependent, temperature-independent and insensitive to puromycin. The last event is the reconstitution of functional aquiferous systems in the aggregates.The aggregation factor which was found to be species-specific could be purified 158-fold. Its functional group seems to be a protein probably with polar amino acids in critical positions. Secondary aggregates generated with the aggregation factor show high viability. Some evidence is presented that the aggregation factor may be an annular particle with a circular contour length of 3 500 Å with about 25 filaments attached to it.     

Calcium-dependent cyclic nucleotide phosphodiesterase inhibition of basal activity by heat-stable factors from rat cerebrum

The boiled supernatant fraction from rat cerebrum contained factors which inhibited the basal activity of a Ca²⁺-dependent phosphodiesterase from rat cerebrum. Two inhibitory fractions were isolated by DEAE-cellulose or Sephadex chromatography and were deemed proteins, based on their sensitivity to trypsin digestion. The inhibitory fractions eluted from DEAE-cellulose columns prior to the Ca²⁺-dependent activator protein. The inhibitory factors, unlike the activator protein, were stable to heat treatment under alkaline conditions. The inhibitory factors caused both an increase in K_m for cyclic GMP and a decrease in $\text{V}$. In the presence of calcium ions and purified activator protein, the Ca²⁺-dependent phosphodiesterase was not inhibited by the factors, but instead was slightly stimulated. The inhibitory factors caused a slight apparent stimulation of a Ca²⁺-independent phosphodiesterase from rat cerebrum but this proved instead to be a nonspecific stabilizing effect which was mimicked by bovine serum albumin. After prolonged alkaline treatment, the purified activator protein caused a modest Ca²⁺-independent activation of Ca²⁺-dependent phosphodiesterase. The inhibitory factors antagonized the activation of Ca²⁺-dependent phosphodiesterase by alkaline treated activator protein or by lysophosphatidylcholine. The inhibitory factors had no effect on activity of trypsinized Ca²⁺-dependent phosphodiesterase. Of various other proteins, only casein mimicked the effects of the inhibitory factors on phosphodiesterase activity.     

Characterization of novel calmodulin binding domains within IQ motifs of IQGAP1

IQ motif-containing GTPase-activating protein 1 (IQGAP1), which is a well-known calmodulin (CaM) binding protein, is involved in a wide range of cellular processes including cell proliferation, tumorigenesis, adhesion, and migration. Interaction of IQGAP1 with CaM is important for its cellular functions. Although each IQ domain of IQGAP1 for CaM binding has been characterized in a Ca²⁺-dependent or -independent manner, it was not clear which IQ motifs are physiologically relevant for CaM binding in the cells. In this study, we performed immunoprecipitation using 3xFLAGhCaM in mammalian cell lines to characterize the domains of IQGAP1 that are key for CaM binding under physiological conditions. Interestingly, using this method, we identified two novel domains, IQ(2.7–3) and IQ(3.5–4.4), within IQGAP1 that were involved in Ca²⁺-independent or -dependent CaM binding, respectively. Mutant analysis clearly showed that the hydrophobic regions within IQ(2.7–3) were mainly involved in apoCaM binding, while the basic amino acids and hydrophobic region of IQ(3.5–4.4) were required for Ca²⁺/CaM binding. Finally, we showed that IQ(2.7–3) was the main apoCaM binding domain and both IQ(2.7–3) and IQ(3.5–4.4) were required for Ca²⁺/CaM binding within IQ(1-2-3-4). Thus, we identified and characterized novel direct CaM binding motifs essential for IQGAP1. This finding indicates that IQGAP1 plays a dynamic role via direct interactions with CaM in a Ca²⁺-dependent or -independent manner.     

Mechanisms of adhesion among cells of the early chick blastoderm. Role of calcium ions in the adhesion of extraembryonic endoderm cells

Summary Cells from the extraembryonic endoderm of the gastrulating chick embryo adhere to one another in the absence of divalent cations. The addition of Mg²⁺ ions to the medium has no effect on the aggregation kinetics but the addition of Ca²⁺ ions increases the number of cells which aggregate and also stabilizes adhesion. Some aggregation also occurs when cells are suspended in saline devoid of Ca²⁺ and Mg²⁺ ions and supplemented with EGTA, a Ca²⁺ ion complexing agent, but adhesion is not stabilized. Shear sensitive and shear resistant bonds form in Ca-containing as well as in EGTA-containing saline. These results suggest that extraembryonic endoderm cells have Ca²⁺ indepedent and Ca²⁺ dependent mechanisms of adhesion.     

Liposome Aggregation: Promoted by Trypsin and Papain in the Absence of Cations

Abstract

Phospholipid vesicle aggregation is usually mediated by phospholipid-binding proteins such as the annexins in a Ca²⁺-dependent manner. Here, we describe aggregation of unilamellar liposomes by trypsin and papain in the absence of cations. Cations including Ca²⁺ inhibited the aggregation. While both trypsin and papain promoted aggregation of liposomes made of phosphatidylcholine and phosphatidylglycerol, only papain elicited aggregation of liposomes made of exclusively phosphatidylcholine. Incubation of trypsin for 30 min at 37°C destroyed its liposome aggregating activity, similar treatment had no effect on papain's. Chymotrypsin and pepsin had no liposome aggregating activity.     

Teratocarcinoma cell adhesion: Identification of a cell-surface protein involved in calcium-dependent cell aggregation

Teratocarcinoma cells have a Ca²⁺-dependent cell-cell adhesion site (t-CDS) that is unique in being inactivated with trypsin in the absence of Ca²⁺ but not in the presence of Ca²⁺. Fab fragments of antibodies raised against teratocarcinoma F9 cells dissociated by treatment with trypsin and calcium (anti-TC-F9) inhibit the aggregation of teratocarcinoma cells mediated by t-CDS. This inhibitory effect of Fab is removed when anti-TC-F9 is absorbed with F9 cells treated with trypsin and calcium (TC-F9), but not when it is absorbed with F9 cells treated with trypsin and EGTA (TE-F9). Comparisons of cell-surface antigens reactive to anti-TC-F9 in TC-F9 cells with those in TE-F9 cells reveal that only one component, with an approximate molecular weight of 140,000 (p140), is detected specifically on the surface of TC-F9 cells. When TC-F9 cells are retrypsinized in the absence of Ca²⁺, a substance with an approximate molecular weight of 34,000 (p34) is released that can neutralize the aggregation-inhibitory effect of the Fab. This p34 interferes with the immunoprecipitation of p140 with anti-TC-F9, suggesting that p34 is a tryptic fragment of p140. Anti-TC-F9 Fab causes the dissociation of the monolayers of teratocarcinoma cells. This effect is removed by absorption of the Fab with p34 as well as with TC-F9 cells, but not with TE-F9 cells. These results suggest that p140 is essential for the function of t-CDS, and that this is an actual cell-adhesion molecule active in the establishment of monolayers of teratocarcinoma cells.     

Modification of the calcium-independent mechanism of cell adhesion in transformed BHK cells

The calcium-independent mechanism of cell adhesion was studied in normal and polyoma virus-transformed BHK cells. The degree of Ca2+-independent adhesion was greatly reduced in pyBHK cells, whereas CA2+-dependent adhesion occurred to the same degree as in BHK cells. This decrease was shown not to be caused by simple masking of the adhesion sites or by their altered sensitivity to trypsin. Adhesion-blocking antibodies were used to identify molecules responsible for Ca2+-independent adhesion. The antibodies precipitated surface molecules specific for adhesion-competent cells. These have tentatively been named CIDSBHK and CIDSpyBHK. Both were glycoproteins with respective apparent molecular weights of 120K and 125K. CIDSpyBHK incorporated 3H-glucosamine more than CIDSBHK did. Possible modification of the Ca2+-independent adhesion mechanism in pyBHK cells is discussed.     

Bcl-2 acts subsequent to and independent of Ca fluxes to inhibit apoptosis in thapsigargin- and glucocorticoidmtreated mouse lymphoma cells

The mechanism by which Bcl-2 inhibits apoptosis is unknown. One proposal is that Bcl-2 regulates intracellular Ca²⁺ fluxes thought to mediate apoptosis. In the present study, we investigated Bcl-2's mechanism of action by determining the effect of Bcl-2 on intracellular Ca²⁺ fluxes in the WEH17.2 mouse lymphoma cell line, which does not express Bcl-2, and its stable transfectant, which expresses a high level of Bcl-2. Treatment with the endoplasmic reticulum Ca²⁺-ATPase inhibitor thapsigargin produced marked alterations in intracellular Ca²⁺ homeostasis in both WEH17.2 and W.Hb12 cells, including elevation of free cytosolic Ca²⁺, endoplasmic reticulum Ca²⁺ pool depletion, capacitative entry of extracellular Ca²⁺, and increased loading of Ca²⁺ into mitochondria. Similar changes in intracellular Ca²⁺ occurred spontaneously in both cell lines following exponential growth. In both situations, W.Hb12 cells maintained optimal viability despite marked alterations in intracellular Ca ²⁺' whereas WEH17.2 cells underwent apoptosis. Treatment with the glucocorticoid hormone, dexamethasone, induced apoptosis in WEH17.2 cells, but not in W.HB12 cells, even though dexamethasone treatment did not alter intracellular Ca²⁺ homeostasis in either cell line. These findings indicate that Bcl-2 acts downstream from intracellular Ca ²⁺ fluxes in a pathway where Ca²⁺-dependent and Ca²⁺-independent death signals converge.     

Fine-tuning of store-operated calcium entry by fast and slow Ca2+-dependent inactivation: Involvement of SARAF

Store-operated Ca²⁺ entry (SOCE) is a functionally relevant mechanism for Ca²⁺ influx present in electrically excitable and non-excitable cells. Regulation of Ca²⁺ entry through store-operated channels is essential to maintain an appropriate intracellular Ca²⁺ homeostasis and prevent cell damage. Calcium-release activated channels exhibit Ca²⁺-dependent inactivation mediated by two temporally separated mechanisms: fast Ca²⁺-dependent inactivation takes effect in the order of milliseconds and involves the interaction of Ca²⁺ with residues in the channel pore while slow Ca²⁺-dependent inactivation (SCDI) develops over tens of seconds, requires a global rise in [Ca²⁺]_cyt and is a mechanism regulated by mitochondria. Recent studies have provided evidence that the protein SARAF (SOCE-associated regulatory factor) is involved in the mechanism underlying SCDI of Orai1. SARAF is an endoplasmic reticulum (ER) membrane protein that associates with STIM1 and translocate to plasma membrane-ER junctions in a STIM1-dependent manner upon store depletion to modulate SOCE. SCDI mediated by SARAF depends on the location of the STIM1-Orai1 complex within a PI(4,5)P₂-rich microdomain. SARAF also interacts with Orai1 and TRPC1 in cells endogenously expressing STIM1 and cells with a low STIM1 expression and modulates channel function. This review focuses on the modulation by SARAF of SOCE and other forms of Ca²⁺ influx mediated by Orai1 and TRPC1 in order to provide spatio-temporally regulated Ca²⁺ signals.