Glutamate transporters are thought to be assembled as trimers of identical subunits that line a central hole, possibly the permeation pathway for anions. Here, we have tested the effect of multimerization on transporter function. To do so, we coexpressed EAAC1 WT with the mutant transporter EAAC1 R446Q , which transports glutamine, but not glutamate. Application of 50 μM glutamate or 50 μM glutamine to cells coexpressing similar numbers of both transporters resulted in anion currents of 165 pA and 130 pA, respectively. Application of both substrates at the same time generated an anion current of 297 pA, demonstrating that the currents catalyzed by the wild-type and mutant transporter subunits are purely additive. This result is unexpected for anion permeation through a central pore, but could be explained by anion permeation through independently-functioning subunits. To further test the subunit independence, we coexpressed EAAC1 WT and EAAC1 H295K , a transporter with a 90-fold reduced glutamate affinity as compared to EAAC1 WT , and determined the glutamate concentration dependence of currents of the mixed transporter population. The data were consistent with two independent populations of transporters with apparent glutamate affinities similar to those of EAAC1 H295K and EAAC1 WT , respectively. Finally, we coexpressed EAAC1 WT with the pH-independent mutant transporter EAAC1 E373Q , showing two independent populations of transporters, one being pH dependent, the other being pH-independent. In conclusion, we propose that EAAC1 assembles as trimers of identical subunits, but that the individual subunits in the trimer function independently of each other.Plasma membrane glutamate transporters actively remove glutamate from the synaptic cleft after excitatory neurotransmission is complete. Uptake into the cells surrounding the synapse against a glutamate concentration gradient is achieved by these transporters by coupling transmembrane glutamate movement to the cotransport of three sodium ions and one proton, and the countertransport of one potassium ion (1,2). In addition to the movement of ions across the membrane being directly coupled to glutamate transport, glutamate transporters also catalyze uncoupled transmembrane flux of anions (3). This anion conductance is thought to be an integral property of the transporters and is not mediated by indirect coupling of transport to a secondary anion channel (3-5).Address correspondence to: Christof Grewer, PhD, Department of Physiology and Biophysics, University of Miami School of Medicine, 1600 NW 10th Avenue, Miami, FL 33136; Phone: (305) 243-1021; Fax: (305) The mammalian glutamate transporters belong to a large family of membrane transport proteins that comprise also neutral amino acid transporters, such as the alanine serine cysteine transporters (ASCTs (6,7)), and dicarboxylate transporters (8,9). A large number of biochemical data from both mammalian (10,11) and bacterial glutamate transporters (12,13), as well as recent crystallographic evidence f...
B-Myb is a highly conserved member of the Myb family of transcription factors whose activity is regulated during the cell cycle. Previous work has shown that the activity of BMyb is stimulated by cyclin A/Cdk2-dependent phosphorylation whereas interaction of B-Myb with cyclin D1 inhibits its activity. Here, we have investigated the role of p300 as a coactivator for B-Myb. We show that B-Mybdependent transactivation is stimulated by p300 as a result of interaction between B-Myb and p300. We have mapped the sequences responsible for the interaction of B-Myb and p300 to the E1A-binding region of p300 and the transactivation domain of B-Myb, respectively. Furthermore, our data suggest that phosphorylation of B-Myb stimulates its acetylation by p300 and that the acetylation of B-Myb is necessary for the full stimulation of its transactivation potential by p300. We have also studied the effect of cyclin D1 on the cooperation of B-Myb and p300. Based on our results we propose that cyclin D1 inhibits the activity of B-Myb by interfering with the interaction of B-Myb and p300. The data reported here provide novel insight into the mechanisms by which the activity of B-Myb is regulated during the cell cycle. Taken together they suggest that the coactivator p300 plays an important role in this regulation and that the cooperation of B-Myb and p300 is orchestrated by cyclins A and D1.
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