Role of the aggregation factor in the regulation of phosphoinositide metabolism in sponges. Possible consequences on calcium efflux and on mitogenesis

The aggregation factor (AF) of the marine sponge Geodia cydonium recognizes the aggregation receptor (AR) which is inserted in the plasma membrane, under formation of species-specific aggregates. The specific cell-binding fragment of the AF was used to investigate for the first time the phosphoinositide metabolism in a lower avertebrate system. We found that after binding of the cell-binding fragment to the aggregation receptor a strong and rapid stimulation of the phosphate incorporation into phosphatidylinositol occurs followed by an increased turnover of phosphoinositides in the Geodia cells. The consequences of an increased degradation of phosphatidylinositol 4,5-bisphosphate into the two second messengers inositol-1,4,5-trisphosphate and diacylglycerol are 2-fold. First, after the addition of the extracellular stimulus the cytosolic Ca2+ concentration rises, resulting in a rapid increased Ca2+ efflux rate. The functional consequence of the increase of the extracellular Ca2+ level is an initiation of the aggregate formation that is mediated by the collagen assembly factor (= primary aggregation factor). Second, some experimental evidences are presented, showing that the other second messenger formed, diacylglycerol, causes a translocation of protein kinase C within the cell. Incubation of Geodia cells with the cell-binding fragment of the AF, or with the phorbol ester, 12-O-tetradecanoylphorbol-13-acetate, resulted within 5 min after treatment in a 70% decrease in protein kinase C activity in the cytosolic fraction and in a 700% increase in enzyme activity in the membrane fraction. It is proposed that by membrane association protein kinase C becomes activated. As a result of this event a series of cellular proteins are phosphorylated, a process which ultimately leads to an unusually strong induction of DNA polymerase alpha activity. From these data we conclude that inositol trisphosphate and protein kinase C also play a fundamental role in cellular signal transduction in lower eukaryotes.     

Sponge cell aggregation

Summary Dissociated sponge cell system has proved to be a useful model to study the process of cell aggregation both on cellular and subcellular level. The purpose of this review is to discuss recent results obtained from experiments with the marine sponge Geodia cydonium.Dissociated cells form functional aggregates during a process which can be sub-divided into three phases: first, formation of small primary aggregates in the presence of Ca²⁺; second, formation of secondary aggregates in the presence of an aggregation factor and third, reconstitution of a functional system of watercontaining channels by rearrangement in the secondary aggregates.On subcellular level a series of macromolecules are known which are involved in the control of aggregation and separation of sponge cells: Aggregation factor, aggregation receptor, anti-aggregation receptor, glucuronidase, ß-glucuronosyltransferase, ß- ß-galactosidase and a lectin. These components might be linked in the following sequence: (a) Activation of the aggregation receptor by its enzymic glucuronylation; (b) Adhesive recognition of the cells, mediated by the aggregation factor and the glucuronylated aggregation receptor; (c) Inactivation of the aggregation receptor by its deglucuronylation with the membrane-associated ß-glucuronidase; (d) Cell separation due to either the loss of the recognition site (glucuronic acid) of the aggregation receptor for the aggregation factor or to an inactivation of the aggregation factor by the anti-aggregation receptor. The activity of the anti-aggregation receptor is most likely controlled by the Geodia lectin.The events leading to cell-cell recognition cause a change in the following metabolic events: Increase of oxygen uptake, decrease of cyclic AMP level, increase of cyclic GMP level and stimulation of programmed syntheses.Abbreviations AF aggregation factor - CPP circular proteid particle - AR aggregation receptor - aAR anti-aggregation receptor - CMF calcium- and magnesium-free artificial sea water - ASW calcium- and magnesium-containing artificial sea water This paper is dedicated to PROF. DR. R. K. ZAHN on the occasion of his 60^th birthday.     

Species-specific aggregation factor in sponges. VI. Aggregation receptor from the cell surface.

An aggregation receptor from the siliceous sponge Geodia cydonium has been isolated and purified in an almost pure form. It sediments at about 2-6s, has a buoyant density of 1-51 g/ml in CsCl and elutes from Sephadex G-50 at a Ve/V0 value of 1-311. Chemical analysis revealed that the receptor consists of 81% neutral carbohydrate and 7-5% protein. The activity of the receptor is rapidly destroyed by Na-periodate. The receptor is released from the cell surface after removal of Ca2+ from the medium or after incubation of the cells with trypsin. The depleted cells can be charged again with isolated receptor molecules. The binding of the receptor molecules on the cell surface is prevented in the presence of trypsin. For optimal binding, physiological salt concentrations with respect to NaCl (540 mM NaCl) and Ca2+ ions are necessary. The receptor whose isolation is described in this report, is involved in secondary aggregation processes, which are initiated by a soluble aggregation factor. The primary aggregation of the cells is not influenced by the receptor. Time-course studies with receptor-depleted cells revealed that new aggregation receptor molecules are formed during the aggregation process. By competition experiments it could be shown that high concentrations of soluble aggregation receptor molecules inhibit secondary aggregation. The soluble receptor molecules can complete with surface-bound receptor molecules only if these are not linked with the aggregation factor.     

Rapid induction of acetylcholine receptor aggregates by a neural factor and extracellular Ca2+

A soluble fetal brain extract (EBX) induces acetylcholine receptor (AChR) aggregation in cultured rat myotubes within 4 hr at 36 degrees C in a defined medium containing 1.8 mM (normal) extracellular Ca2+ (Olek et al., 1983). The activity of EBX was Ca2+ dependent; reducing extracellular Ca2+ significantly inhibited EBX-induced AChR aggregation and a 15-50% increase in extracellular Ca2+ synergistically enhanced the activity of EBX. Synergism was specific for Ca2+ as increases in other divalent cations (Ba2+, Co2+, Mg2+, Mn2+, Sr2+) had no effect. A large increase (300-500%) in extracellular Ca2+ alone also induced AChR aggregation within 4 hr at 36 degrees C. An equivalent increase in other cations (Ba2+, Co2+, Mg2+, Mn2+, Sr2+) did not promote AChR aggregation. An initial 15-min pulse of increased extracellular Ca2+ alone or with EBX was adequate to induce AChR aggregation. Aggregates induced by EBX, Ca2+ alone, or EBX/Ca2+ were found predominantly on the top surface of the myotube. These treatments did not detectably alter preexisting aggregates present at substrate contact sites on the bottom surface of myotubes. AChR aggregation induced by any treatment was not inhibited by cycloheximide, Ca2+ channel blockers, or protease inhibitors but was blocked by Co2+ and sodium azide.     

Identification and further characterization of the specific cell binding fragment from sponge aggregation factor

Monoclonal antibodies (McAbs) were raised against the aggregation factor (AF) from the marine sponge Geodia cydonium. Two clones were identified that secrete McAbs against the cell binding protein of the AF complex. Fab fragments of McAbs: 5D2-D11 completely abolished the activity of the AF to form secondary aggregates from single cells. The McAbs were determined to react with the AF in vitro; this interaction was prevented by addition of the aggregation receptor, isolated and purified from the same species. After dissociation of the AF by sodium dodecyl sulfate and 2-mercaptoethanol, followed by electrophoretical fractionation, a 47-kD protein was identified by immunoblotting which interacted with the McAbs: 5D2-D11. During this dissociation procedure, the sunburst structure of the AF was destroyed. In a second approach, the 47-kD protein was isolated by immunoprecipitation; 12 molecules of this protein species were calculated to be associated with the intact AF particle. The 47-kD AF fragment bound to dissociated Geodia cells with a high affinity (Ka of 7 X 10(8) M-1) even in the absence of Ca++ ions; the number of binding sites was approximately 4 X 10(6)/cell. This interaction was prevented by addition of the aggregation receptor to the 47-kD protein in the homologous cell system. Moreover, it was established that this binding occurs species-specifically. The 47-kD fragment of the AF was localized only extracellularly by indirect immunofluorescence staining in cryostat slices. These data suggest that the 47-kD protein is the cell binding molecule of the AF from Geodia.     

Kinetics of ion translocation across charged membranes mediated by a two-site transport mechanism. Effects of polyvalent cations upon rubidium uptake into yeast cells.

(1) The effect of surface charge upon the kinetics of monovalent cation translocation via a two-site mechanism is investigated theroretically. (2) According to the model dealt with, typical relations are expected for the dependence of the kinetic parameters of the translocation process upon the concentration of a polyvalent cation, differing essentially from those derived for the case in which the membrane carries no excess charge. (3) Even when a polyvalent cation does not compete with the substrate cation for binding to the translocation sites, apparently competitive inhibition may occur when the membrane is negatively charged. (4) The model is tested experimentally by studying the effects of the polyvalent cations Mg2+, Sr2+, Ca2+, Ba2+ and Al3+ upon Rb+ uptake into yeast cells at pH 4.5 A good applicability is found. (5) Equimolar concentrations of polyvalent cations reduce the rate of the Rb+ uptake into yeast cells in the order Mg2+ less than Sr2+ less than Ca2+ less than Ba2+ less than Al3+. (6) The conclusion is reached that the reduction in the rate of Rb+ uptake caused by the polyvalent cations applied results mainly from screening of the negative fixed charges on the membrane surface and binding to these negative sites rather than competition with Rb+ for the transport sites. (7) The results of our investigation indicate the affinity of the alkaline-earth cations for the negative fixed charges on the surface to the yeast cell membrane increases in the orther Mg2+ less than Sr2 less than Ca2+ less than Ba2+. (8) Probably mainly phosphoryl groups determine the net charge on the membrane of the yeast cell at a medium pH of 4.5.     

Aggregation of sponge cells. Function of a lectin in its homologous biological system.

For the first time, the biological role of a lectin in the process of reaggregation of single cells from the same species (marine sponge: Geodia cydonium Jam.) is described. The galactose-specific lectin does not promote aggregation, but prevents the antiaggregation receptor from disaggregating cell clumps. Competition experiments showed that the lectin inactivates the antiaggregation receptor by binding to it, most likely via its terminal galactose residues. The lectin converts reversibly aggregation-deficient cells (carrying functional cell membrane-bound antiaggregation receptor molecules) to aggregation-susceptible cells.     

Effect of intracellular Na+ on platelet aggregation and Ca2+ mobilization

The effects of ionophores, which can carry alkali metal cations, on platelet aggregation were examined. At an alkaline extracellular pH, alkali metal cation/H+ exchanger nigericin accelerated aggregation in K+-enriched medium, whereas it rather inhibited aggregation in Na+-enriched medium, even though the intracellular pH was only slightly alkaline. The inhibitory effect of Na+ on platelet aggregation was more clearly shown with the alkali metal cation exchanger gramicidin D. The ionophore had no effect or a slightly accelerative effect on aggregation in K+-enriched medium, whereas it significantly inhibited aggregation induced by thrombin, ADP and platelet activating factor in Na+-enriched medium. Fluorescence studies on fura-2-labeled platelets revealed that in Na+-enriched medium gramicidin D inhibited agonist-induced Ca2+ mobilization both in the presence and absence of extracellular Ca2+. These results suggest that the intracellular Na+ inhibits platelet aggregation by inhibiting Ca2+ mobilization.     

Control of the aggregation factor-aggregation receptor interaction in sponges by protein kinase C

By means of immunobiochemical and immunocytological techniques it was found that the aggregation factor (AF) from the sponge Geodia cydonium is stored in vesicles of spherulous cells. During the reaggregation process of dissociated cells, the AF which is present extracellularly was determined to be bound to the cell-surface-associated aggregation receptor (AR) only during the initial phase (0-5 h after addition of the AF to the single cell suspension). At later stages (20 h), the AF colocalized with extracellular structures, e.g., collagen and glycoconjugates. Immobilized to nitrocellulose, the AR, a molecule with Mr of 43.5 kDa, displayed its binding affinity to the AF only if it was isolated from early aggregates (5 h). The transition of the AF-susceptible to the AF-deficient state of the plasma membrane was mimicked in vitro by incubation of plasma membranes from early aggregates with purified protein kinase C. This conversion to the AF-deficient state could be prevented by the protein kinase C inhibitor staurosporine. Together with earlier findings, which revealed that the AR is phosphorylated by protein kinase C, we propose that in the sponge system this enzyme controls intercellular processes involved in morphogenesis.     

Contribution of maternal mRNA for maintenance of Ca2+-dependent reaggregating activity in dissociated cells of Xenopus laevis embryos

Dissociated Xenopus laevis blastula cells, where reaggregation was inhibited in Ca2+-free medium, reaggregated immediately after the addition of Ca2+. This reaggregation was not inhibited by cordycepin or actinomycin D treatment during culture, although cycloheximide and puromycin were inhibitory. The reaggregation was not inhibited even when fertilized eggs were microinjected with cordycepin and their RNA synthesis was continuously inhibited through cleavage to blastula stages. In neurula cells, cordycepin treatment induced significant reduction in sizes of aggregates formed. These results suggest that the Ca2+-dependent reaggregating activity of blastula cells is maintained by the translation of maternal, rather than newly synthesized, mRNA.     

Aggregation of sponge cells: 22. Species-specific reactivity of a lectin from the sponge Geodia cydonium

Single cells of the marine sponge Geodia cydonium aggregate species-specifically in the presence of a soluble aggregation factor to form large cell clumps. A lectin isolated from the same sponge species does not cause agglutination of Geodia cells but agglutinates only cells from heterologous species (e.g. Tethya lyncurium, Hemimycale columella, Pellina semitubulosa, Cacospongia scalaris, Verongia aerophoba). The process of agglutination is independent of divalent cations (they do not affect the agglutination process at concentrations up to 50 mM), occurs at 2°C, causes a reduction in the viability of the cells and results in an inhibition of programmed syntheses. The observed differences between the properties of cell agglutination (effect of a lectin in a heterologous system) and cell aggregation (effect of an aggregation factor in the homologous system) is discussed. Cell aggregation is dependent upon the presence of an aggregation factor, the presence of cations and an incubation temperature 2̃0°C; cell aggregation results in a stimulation of programmed syntheses. Cell agglutination requires a heterologous macromolecule (e.g. lectin), it is independent of divalent cations and causes inhibition of programmed syntheses in the cells.     

Species-specific aggregation factor in sponges. Sialyltransferase associated with aggregation factor.

The sialyltransferase (= glycoprotein-sialic acid transferase) was studied in the sponge Geodia cydonium, a mesozoan organism. The experiments were performed both in intact cellular and in isolated enzyme systems. It is shown, that desialylated cells show a lower aggregation potency than the controls. During aggregation enzymic sialylation of desialylated sponge cells occurs in the presence of an aggregation factor, which is associated with a high molecular weight particle. The sialylation process is temperature-dependent and can be inhibited by N-ethylmaleimide. Sialylation occurs predominantly at a distinct cell surface component, the aggregation receptor. The sialyltransferase was isolated and purified by the following steps: Sepharose 4B, CM-cellulose, Nonidet treatment, and Sephadex G-100. By this procedure the enzyme was purified 680-fold with a 31% yield. The sialyltransferase is originally associated with the high molecular weight particle also carrying the aggregation factor. In the last step the aggregation factor was separated from the sialyltransferase. The enzyme catalyzes the transfer of sialic acid from CMP-sialic acid to the desialylated aggregation receptor. The molecular weight of the sialyltransferase has been determined to be 52,000. Kinetic studies revealed no lag phase and a dependence on enzyme concentration. The purified transferase has a pH optimum of 7.75 and requires 200 mM NaCl for activity. No requirement for Mg2+ or Ca2+ could be observed. The reaction is inhibited by 10 micronM N-ethylmaleimide.     

Aggregation of sponge cells. XX. Self-aggregation of the circular proteid particle.

In the extracellular space of the tissue of the sponge Geodia cydonium, circular proteid particles are found which carry as subunits the aggregation factor and a series of glycosyltransferases. Using the technique of velocity sucrose gradient centrifugation, the sedimentation coefficient (S020,w) of the particle-monosomes was determined to be 90. By means of the Svedberg equation a molecular weight of 1.3 . 10(8) daltons could be estimated. The monosomes aggregate in the presence of Ca2+ to higher complexes via disomes, trisomes, and pentasomes. The complexes can be redissociated by dodecyl sulfate but not by EDTA. During the Ca2+-mediated self-aggregation, the particles lose their biological activity with respect to their aggregation promoting function.     

Do we know the absolute values of intracellular free calcium concentration?

More than 20 years ago, it was shown that the addition of EGTA increases the affinity of the plasma membrane Ca2+ pump for Ca2+ by an order of magnitude. The left-hand shift of Ca2+-dependencies in the presence of EGTA has been also documented in studies of the sarcoplasmic reticulum Ca2+ pump, mitochondrial Ca2+-transporter as well as Ca2+-binding by calmodulin and troponin C. These data allow us to hypothesise that this effect is caused by an admixture of di- and trivalent cations possessing high affinity for EGTA and interacting with Ca2+-transporting and binding proteins. Here, we propose that polyvalent cations affect the estimation of absolute values of free intracellular Ca2+ concentration. Indeed, EGTA sharply increases the apparent affinity of the fluorescent Ca2+ indicators quin-2 and fluo-3 for Ca2+. The impact of polyvalent cations on Ca2+ measurement was further confirmed by the study showing the high sensitivity of Ca2+-induced fluo-3 fluorescence to Mn2+, Fe2+, Cu2+, and Co2+ seen in the absence of EGTA.     

Evidence for distinct cation and calcimimetic compound (NPS 568) recognition domains in the transmembrane regions of the human Ca2+ receptor

The Ca(2+) receptor, a member of the family 3 of G protein-coupled receptors (GPCR), responds not only to its primary physiological ligand Ca(2+) but also to other di- and trivalent metals (Mg(2+), Gd(3+)) and the organic polycations spermine and poly-l-Arginine. As has been found for other family 3 GPCRs, the large amino-terminal extracellular domain (ECD) of the Ca(2+) receptor is the primary Ca(2+) binding domain. To examine how the signal is propagated from the ECD to the seven-transmembrane core domain (7TM) we constructed a Ca(2+) receptor mutant (T903-Rhoc) lacking the entire ECD but containing the 7TM. We have found that this structure initiates signaling in human embryonic kidney (HEK) 293 cells stably expressing the construct. One or more cation recognition sites are also located within the 7TM. Not only Ca(2+), but also several other Ca(2+) receptor-specific agonists, Mg(2+), Gd(3+), spermine, and poly-l-Arginine, can activate T903-Rhoc truncated receptor-initiated phosphoinositide hydrolysis in HEK 293 cells. The phenylalkylamine compound, NPS 568, identified as a positive allosteric modulator of the Ca(2+) receptor can selectively potentiate the actions of Ca(2+) and other polycationic agonists on the T903-Rhoc receptor. Similarly, organic polycations synergistically activate T903-Rhoc with di- and trivalent metals. Alanine substitution of all the acidic residues in the second extracellular loop of the T903-Rhoc receptor significantly impairs activation by metal ions and organic polycations in the presence of NPS 568 but not the synergistic activation of Ca(2+) with poly-l-Arginine. These data indicate that although the ECD has been thought to be the main determinant for Ca(2+) recognition, the 7TM core of the Ca(2+) receptor contains activating site(s) recognizing Ca(2+) and Gd(3+) as well as the allosteric modulators NPS 568 and organic polycations that may play important roles in the regulation of receptor activation.     

Variation in selectivity of univalent cations in slime moldPhysarum polycephalum caused by reception of polyvalent cations

Summary Specificity of reception on 11 electrolytes in the slime moldPhysarum polycephalum was investigated in the presence of polyvalent cations in media. Membrane potential and motive force of tactic movement were examined with the aid of the double chamber method, and the zeta potential at the membrane surface of the slime mold was measured by electrophoretic mobility. The results obtained are summarized as follows: (1) The presence of polyvalent cations (e.g., Ca²⁺, Mg²⁺, Sr²⁺, Ba²⁺, La³⁺, Th⁴⁺) in medium led to an increase in threshold concentration,C _th , determined from the potential measurements for Na- or Li-salts, and to a decrease inC _th for K-, Rb-, or NH₄-salts,C _th for 11 electrolytes changed discontinuously when the concentration of polyvalent cations in medium exceeded their respective thresholds. (2) TheC _th determined from chemotaxis agreed with that from the potential response both in the presence and absence of polyvalent cations. (3) Sequence of selectivity of univalent cations varied extensively in the presence of polyvalent cations. (4) Changes in the zeta potential induced by NaCl reception agreed with those in the membrane potential even in the presence of Ca²⁺ in medium. (5) TheC _th for reception of NaCl changed sharply at about 12 °C in the presence of polyvalent cations, while that for KCl was independent of the temperature.Conformational changes in surface membrane of the slime mold in response to reception of polyvalent cations were then discussed in relation to the discrimination of univalent cations.     

Anti-actomyosin. Influence on adhesive behaviour of eukaryotic cells and of cuvierian tubules

The effect of antisera against chicken gizzard smooth-muscle actomyosin and against pectoralis striated-muscle actomyosin on adhesive behaviour of eukaryotic cells (from sea urchin embryos and from a silicious sponge) and of Cuvierian tubules has been studied. The results with a sea urchin cells, which require divalent cations for aggregation, showed that antiserum to chicken gizzard smooth-muscle actomyosin inhibited reaggregation of trypsin-treated cells better than mechanically dissociated cells, while anti-chicken pectoralis striated-muscle had no effect. Primary reaggregation of trypsin-dissociated sponge cells, in the presence of calcium and magnesium, is also inhibitable by anti-gizzard smooth-muscle but not by anti-pectoralis striated-muscle. Anti-gizzard smooth-muscle had no effect on secondary reaggregation of sponge cells mediated by a soluble aggregation factor. Anti-gizzard smooth-muscle inhibited Cuvierian tubule adhesion.     

Interaction of asparagine-linked oligosaccharides with an immobilized rice (Oryza sativa) lectin column.

Inside-out plasma-membrane vesicles isolated from rat liver [Prpic, Green, Blackmore & Exton (1984) J. Biol. Chem. 259, 1382-1385] accumulated a substantial amount of 45Ca2+ when they were incubated in a medium whose ionic composition and pH mimicked those of cytosol and which contained MgATP. The Vmax of the initial 45Ca2+ uptake rate was 2.9 +/- 0.6 nmol/min per mg and the Km for Ca2+ was 0.50 +/- 0.08 microM. The ATP-dependent 45Ca2+ uptake by inside-out plasma-membrane vesicles was about 20 times more sensitive to saponin than was the ATP-dependent uptake by a microsomal preparation. The 45Ca2+ efflux from the inside-out vesicles, which is equivalent to the Ca2+ influx in intact cells, was increased when the free Ca2+ concentration in the medium was decreased. The Ca2+ antagonists La3+ and Co2+ inhibited the 45Ca2+ efflux from the vesicles. Neomycin stimulated the Ca2+ efflux in the presence of either a high or a low free Ca2+ concentration. These results confirm that polyvalent cations regulate Ca2+ fluxes through the plasma membrane.     

Polyvalent cations inhibit human neutrophil chemotaxis by interfering with the polymerization of actin

The effect of a series of di- and trivalent cations on the locomotor response of human neutrophils to the chemotactic tripeptide N-formyl-methionyl-leucyl-phenylalanine (FMLP) was investigated. Migration was assessed by the leading front method. The cations inhibited FMLP-stimulated chemotaxis in the rank order: Ni2+ approximately Co2+ greater than Sr2+ greater than Zn2+ greater than Mn2+ approximately La3+ greater than Cd2+ approximately Ba2+ much greater than Mg2+. Benzamil, which blocks Na+/Ca2+ exchange, did not alter chemotaxis by itself but prevented the suppressive effects of each of the polyvalent cations on motility. The ion selectivity sequence and the lack of activity of benzamil are strikingly different than for O(-2) generation, thereby implying different modes of action in the two functional expressions. The F-actin content of the cells was monitored by the fluorescence of rhodamine-phalloidin. Each of the cations displayed comparable efficacy in blocking the polymerization of actin in FMLP-activated cells. Likewise, benzamil exhibited a protective effect, completely overcoming the inhibitory action of the polyvalent cations. The results indicate that these foreign ions gain access to the cell interior via a benzamil-sensitive pathway, namely Na+/Ca2+ exchange. Upon entry into the cytosol, they then interfere with the formation of filaments from actin monomers. These studies help to shed light on the interaction of divalent cations with cytoskeletal and contractile elements in cell motility.     

Insulin receptor aggregation and autophosphorylation in the presence of cationic polyamino acids

Aggregation and autophosphorylation of the insulin receptor-protein kinase, from cultured 3T3-L1 adipocytes, were studied in the presence of cationic polyamino acids. Poly-L-lysine and poly-L-arginine produced the following effects with the purified receptor: first, the autophosphorylation rate was increased by polycations. Half-maximal stimulation was proportional to polymer length. The rate enhancement was greater at lower ATP concentrations. Second, near-endpoint (equilibrium) autophosphorylation was greater in the presence of the polycations. Polycations inhibited the reverse reaction: ADP + phosphoreceptor yielding ATP + aporeceptor. Third, the [32P]phosphopeptides generated by trypsin digestion of the 32P-beta-subunit, showed that no new autophosphorylation sites resulted from the presence of polycations. Fourth, the polycations, but not insulin, promoted receptor aggregation, and phosphoreceptor aggregated more readily than aporeceptor. Insulin receptor enriched through the wheat germ agglutinin eluate step was compared with purified receptor. Higher concentrations of poly-L-arginine were required to stimulate autophosphorylation and to promote aggregation. Finally, several polycation-dependent substrates present in the wheat germ agglutinin eluate co-aggregated with the insulin receptor. Polycation-stimulated receptor autophosphorylation is linked to a lower KM,app for ATP, but substrate phosphorylation may require the aggregation.