Mutation to phenylalanine of tyrosine 371 in tyrosine hydroxylase increases the affinity for phenylalanine

The aromatic amino acid hydroxylases tyrosine and phenylalanine hydroxylase both contain non-heme iron, utilize oxygen and tetrahydrobiopterin, and are tetramers of identical subunits. The catalytic domains of these enzymes are homologous, and recent X-ray crystallographic analyses show the active sites of the two enzymes are very similar. The hydroxyl oxygens of tyrosine 371 in tyrosine hydroxylase and of tyrosine 325 of phenylalanine hydroxylase are 5 and 4.5 A, respectively, away from the active site iron in the enzymes. To determine whether this residue has a role in the catalytic mechanism as previously suggested [Erlandsen, H., et al. (1997) Nat. Struct. Biol. 4, 995-1000], tyrosine 371 of tyrosine hydroxylase was altered to phenylalanine by site-directed mutagenesis. The Y371F protein was fully active in tyrosine hydroxylation, eliminating an essential mechanistic role for this residue. There was no change in the product distribution seen with phenylalanine or 4-methylphenylalanine as a substrate, suggesting that the reactivity of the hydroxylating intermediate was unaffected. However, the KM value for phenylalanine was decreased 10-fold in the mutant protein. These results are interpreted as an indication of greater conformational flexibility in the active site of the mutant protein.     

Characterization of leucine transport by toadfish liver in vivo

Kinetic analysis of L-leucine uptake by toadfish liver at 20 degrees C in vivo has been carried out after pulse injection of L-[14C]leucine into the hepatic portal vein. D-[3H]mannitol, which is taken up slowly by toadfish liver, is used as a marker for extracellular space and space accessible by simple diffusion. At normal plasma leucine concentration (0.1 mM), leucine uptake occurs rapidly (t1/2 = 0.25 min), representing a flux of 0.6 mumol/min for the liver as a whole. Analysis of the distribution of radioactive leucine among intracellular and extracellular free pools and protein-bound form at times of 30 s to 5 min after injection is consistent with operation of a concentrative or uphill transport system accounting for 40% of uptake at normal plasma concentration. Saturation of uptake occurs at increasing leucine loads; calculation of intracellular pool dilution from protein synthesis data indicates that 20-30% of liver intracellular space is occupied by incoming leucine during the first 2 min after portal injection. Maximal flux (V max) is 4.1 mumol/min per 7-g liver as a whole with Km = 0.6 mM. Competitive inhibition of leucine uptake is afforded by isoleucine and phenylalanine with lesser effects by aspartic acid, cysteine, methionine, threonine, tyrosine, and valine. No effect is observed with alanine, glycine, histidine, lysine, and proline.     

Receptor-associated protein (RAP): a specialized chaperone for endocytic receptors

A number of cellular control mechanisms have evolved that facilitate and evaluate post-translational steps in protein biosynthesis. Chaperones or escort proteins are an important part of these cellular control mechanisms. They associate with newly synthesized proteins and assure correct folding and post-translational modification including disulfide bridge formation, glycosylation and complex formation. The receptor-associated protein (RAP) is a novel type of chaperone recently identified that is especially designed to assist in the biosynthesis and intracellular transport of endocytic receptors. Experimental evidence suggests that RAP acts as a receptor antagonist and prevents association of newly synthesized receptors with their ligands during transport to the cell surface. This mechanism seems to be required in cell types that express both receptor and ligand because premature receptor-ligand interaction in the secretory pathway interferes with proper export of the receptors to the cell surface. This review describes studies that have uncovered this unique protein biosynthesis mechanism.     

Phenylalanine and tyrosine metabolism in neonates receiving parenteral nutrition differing in pattern of amino acids

Tyrosine is considered to be an indispensable dietary amino acid in the neonate, yet achieving adequate parenteral tyrosine intake is difficult due to its poor solubility. Increasing the supply of phenylalanine is the most common means of compensating for low tyrosine levels. Unfortunately, plasma phenylalanine concentrations are sometimes elevated in infants receiving high phenylalanine intake. This led us to study the phenylalanine and tyrosine metabolism in 16 neonates randomized to receive total parenteral nutrition with either a high or a moderate phenylalanine-containing amino acid solution. A primed, 24-h continuous stable isotope infusion of L-[1-13C]phenylalanine and L-[3,3-2H2]tyrosine was given to enable the measurement of phenylalanine and tyrosine kinetics. Results demonstrated that 1) phenylalanine hydroxylation was significantly greater in infants receiving high phenylalanine, 2) phenylalanine oxidation and percent dose oxidized was also significantly greater in infants receiving high phenylalanine, 3) apparent phenylalanine retention was greater in neonates receiving high phenylalanine, and 4) alternate catabolites of phenylalanine and tyrosine metabolism were significantly greater in infants receiving high phenylalanine compared with moderate phenylalanine. We conclude that neonates respond to increased parenteral phenylalanine intake by increasing their hydroxylation and oxidation rates. The greater oxidation of phenylalanine in infants receiving high phenylalanine in conjunction with the urinary excretion of alternate catabolites of phenylalanine and tyrosine suggests that the high phenylalanine intake may be in excess of needs. However, the lower apparent phenylalanine retention observed in infants receiving moderate phenylalanine suggests that the total aromatic amino acid level of moderate phenylalanine may be deficient for neonatal needs.     

Similar processes mediate glycopeptide export from the endoplasmic reticulum in mammalian cells and Saccharomyces cerevisiae

Glycopeptides are transported from the lumen of the yeast endoplasmic reticulum (ER) to the cytosol and in contrast to secretory proteins do not enter ER-to-Golgi transport vesicles. In a cell-free system, this process is ATP- and cytosol-dependent. While yeast cytosol promotes the export of glycopeptides from mammalian ER in vitro, glycopeptide release cannot be detected in the presence of mammalian cytosol. We demonstrate that this is due to an N-glycanase activity in mammalian cytosol rather than lack of glycopeptide transport activity in mammalian microsomes. Monitoring the amount of glycopeptide enclosed in ER membranes we show the cytosol- and ATP-dependent release of glycopeptide from mammalian microsomes. The fact that glycopeptide export can be achieved with ER and cytosol derived from heterologous sources indicates that glycopeptide export from the ER is an important process conserved during evolution.     

Tyrosine transport into melanosomes is increased following stimulation of melanocyte differentiation

A variety of physiological factors can stimulate differentiation of melanocytes to increase pigmentation, and critical to this process is the transport of the melanogenic substrate (tyrosine) into melanosomes. In this study, we examined whether stimulation of melanogenesis affects melanosomal tyrosine transport. Tyrosine uptake increased almost 2-fold in melanosomes derived from melanocytes treated with melanocyte-stimulating hormone (MSH), which acts to increase intracellular cAMP levels, resulting in the up-regulation of many genes involved in melanogenesis. Stimulation of melanoma cells with dibutyryl cAMP increased melanosomal tyrosine transport 2- to 3-fold after 24 to 48 hrs, with peak levels occurring after 3 to 5 days of treatment, suggesting that de novo gene expression may be required. The cAMP-induced increase in melanosomal tyrosine transport could be effectively competed with phenylalanine or tryptophan, but not with dopamine or proline, suggesting either that a pool of transporters with greater tyrosine transporting ability pre-exists, or that a greater number of tyrosine transporters reside within the melanosomal membrane. These results illustrate a rare example of hormonal plasma membrane stimulation which transduces a signal for increased vesicular transport of an amino acid.     

Decrease in plasma phenylalanine and tyrosine after phenylalanine-tyrosine free amino acid solutions in man

After an overnight fast, 5 male healthy subjects ingested increasing amounts of a solution containing a fixed proportion of seven essential amino acids (L-isoleucine, 13.3%; L-leucine, 21.0%; L-lysine, 15.2%; L-methionine, 21.0%; L-threonine, 9.5%; L-tryptophan, 4.8% and L-valine, 15.2%) and lacking phenylalanine and tyrosine. The solutions caused a rapid fall in plasma phenylalanine and tyrosine which was proportional to the total amount of amino acids ingested. Following the highest dose administered (31.5 g) plasma phenylalanine and tyrosine fell to a minimum of, respectively, 12.7% and 29.8% the initial levels and remained markedly reduced at 6 hours after treatment. The decrease of tyrosine and phenylalanine levels was associated with a decrease of systolic and diastolic arterial pressure.     

Folding and intracellular transport of the yeast plasma-membrane H(+)-ATPase: effects of mutations in KAR2 and SEC65

We have developed two independent assays to study the integration, folding, and intracellular transport of the polytopic plasma membrane H(+)-ATPase in yeast. To follow folding, controlled trypsinolysis was used to distinguish between the E1 conformation of the ATPase (favored in the presence of ADP) and the E2 conformation (favored in the presence of vanadate). By this criterion, wild-type ATPase appears to recognize its ligands and assume distinct conformations within a short time after its biosynthesis. To follow intracellular transport, we have exploited the fact that export of newly synthesized ATPase from the endoplasmic reticulum is accompanied by kinase-mediated phosphorylation, leading to a shift in electrophoretic mobility. Because proper folding is required for transport from the endoplasmic reticulum, the mobility shift also serves as a convenient bioassay for correct folding. As a first step toward identifying cell components important in folding of the nascent ATPase, we have used the dual assays to examine the role of KAR2, encoding the yeast homolog of immunoglobulin heavy chain binding protein/78-kDa glucose-regulated protein, and SEC65, encoding a subunit of the yeast signal recognition particle. Although mutation of KAR2 caused defective translocation of several secretory precursors into the endoplasmic reticulum lumen, ATPase folding and intracellular transport were unperturbed. By contrast, in a sec65 mutant, the folding and intracellular transport of newly synthesized ATPase were delayed. Our data suggest that conformational maturation of the ATPase is a rapid process in wild-type cells and that membrane integration mediated by signal recognition peptide is important for the proper folding of this polytopic protein.     

Neomycin inhibits secretion of apolipoprotein[a] by increasing retention on the hepatocyte cell surface

Neomycin therapy reduces plasma levels of low density lipoprotein and lipoprotein[a] (Lp[a]). To determine whether neomycin directly alters the biogenesis of Lp[a], we have examined the effect of neomycin on apolipoprotein[a] (apo[a]) synthesis and secretion in primary cultures of baboon hepatocytes. Using this system, we have previously shown that apo[a] is synthesized as a lower molecular weight precursor that upon maturation becomes associated with the cell surface before release into the culture medium. Treatment of hepatocytes with 10 mM neomycin reduced levels of apo[a] in the culture medium by as much as 12-fold. Although a portion of the reduced secretion could be accounted for by a reduction in total protein synthesis, the greatest effect of neomycin on apo[a] secretion was to decrease the release of mature apo[a] from the hepatocyte cell surface into the culture medium. Treatment of hepatocyte cultures with trypsin confirmed that mature apo[a] in neomycin-treated cells was still transported to the cell surface. Examination of related antibiotics demonstrated that inhibition of apo[a] secretion is a general property shared by the deoxystreptamine antibiotics. The mechanism by which neomycin affects the apo[a]-cell surface interaction is not known, but neomycin is known to perturb cell surface membranes, inhibit the interaction of some ligands with their cell surface receptors, and inhibit the metabolism of phosphatidylinositol 4,5 biphosphate. These studies suggest that cell surface association of apo[a] may play a role in Lp[a] biogenesis in vivo.     

Metabolic evaluation of cultured porcine hepatocyte monolayers in human plasma from hepatic failure patients--basic study on development of a bioreactor in hybrid artificial liver

In order to develop a functional bioreactor for hybrid artificial liver, function of cultured porcine hepatocyte monolayers in human plasma from hepatic failure patients (group III, n = 5) was investigated. Culture media, Leibovitz L-15 medium (group I, n = 7) and normal human plasma (group II, n = 3), were used as controls. Morphologically, no degeneration of porcine hepatocytes in hepatic failure plasma was observed for 5 days in culture. Levels of ureogenesis showed no significant difference against the controls at day 1, 2, 5 in culture, but the level at day 3 was significantly higher than that of group II. Levels of gluconeogenesis showed a close tendency as those of ureogenesis, but the level at day 3 was significantly lower than that of group I. Levels of intracellular DNA contents, showing between 1.85 +/- 0.39 and 1.35 +/- 0.05 microgram/cm2, were compatible with those of controls during first three days in culture, but level of group III at day 5 was significantly higher than that of group I. After incubation of porcine hepatocyte in hepatic failure plasma, the amount of valine, leucine, isoleucine, glutamine, arginine, and citrulline was significantly decreased. Elevated phenylalanine and tyrosine were also decreased, but Fischer's ratio, the ratio of branched chain amino acid against aromatic amino acids, was not significantly increased. Data obtained by this investigation showed that cultured porcine hepatocytes held proper hepatic function in the hepatic failure plasma. It is concluded that culture porcine hepatocyte monolayers were a promising candidate for a bioreactor of a hybrid artificial liver.     

Protein synthesis and degradation change rapidly in response to food intake in muscle of food-deprived mice

The short-term changes in muscle protein synthesis and degradation after food intake are unclear. We investigated muscle protein metabolism after food intake in mice that were starved for 18 h and refed for 1 h. Protein synthesis activity was estimated by the polysome profiles, and protein degradation was estimated by plasma N tau-methylhistidine (MeHis) concentration, reflecting translational activity and myofibrillar protein degradation, respectively. MeHis is an index of myofibrillar protein degradation because it is not reused for protein synthesis and it is not metabolized. Stimulation of protein synthesis (polysome profile) and the reduction of protein degradation (plasma N tau-methylhistidine concentration) were observed immediately after feeding began. Protein synthesis returned to the prefeeding level by 6 h after refeeding, whereas protein degradation remained at a low level. The decreased plasma MeHis concentration after refeeding was not due to a decrease in MeHis release from muscle cells and an increase in the free MeHis pool size, because the changes in free MeHis concentration in muscle were similar to that of plasma. Plasma insulin concentration immediately rose with feeding and it returned to the prefeeding level by 3 h after refeeding. These results suggest that responses of postprandial protein metabolism are very rapid and that protein synthesis is regulated by insulin, whereas degradation is regulated by insulin and other dietary factors. Thus the ability of skeletal muscle to use nutrients more effectively by stimulating protein synthesis and reducing protein degradation may cause the accelerated rate of protein accretion in skeletal muscle during the short postprandial period.     

The product of the proto-oncogene c-cbl: a negative regulator of the Syk tyrosine kinase

Engagement of antigen and immunoglobulin receptors on hematopoietic cells is directly coupled to activation of nonreceptor protein tyrosine kinases (PTKs) that then phosphorylate critical intracellular substrates. In mast cells stimulated through the FcvarepsilonRI receptor, activation of several PTKs including Syk leads to degranulation and release of such mediators of the allergic response as histamine and serotonin. Regulation of Syk function occurred through interaction with the Cbl protein, itself a PTK substrate in this system. Overexpression of Cbl led to inhibition of Syk and suppression of serotonin release from mast cells, demonstrating its ability to inhibit a nonreceptor tyrosine kinase. Complex adaptor proteins such as Cbl can directly regulate the functions of the proteins they bind.     

Role of the juxtamembrane tyrosine in insulin receptor-mediated tyrosine phosphorylation of p60 endogenous substrates

Prior studies have demonstrated that a juxtamembrane tyrosine (tyrosine 972) in the insulin receptor is required for the receptor to elicit various biological responses and to stimulate the tyrosine phosphorylation of two endogenous substrates, the insulin receptor substrate-1 and the adaptor protein called Shc. In the present studies the role of this tyrosine was examined in the insulin-stimulated tyrosine phosphorylation of a group of 60-kDa endogenous proteins. These include a 60-kDa protein which, when phosphorylated, becomes associated with the GTPase activating protein of Ras, a distinct 60-kDa protein that associates with either the phosphatidylinositol 3-kinase or the tyrosine phosphatase Syp, as well as a 58/53-kDa protein that is tyrosine phosphorylated in response to insulin but has no known associated protein. In each case, a mutant insulin receptor in which tyrosine 972 has been changed to phenylalanine was found to be defective in its ability to phosphorylate these three endogenous substrates, although the mutant receptor exhibited the same level of insulin-stimulated autophosphorylation as the wild type receptor. These results further demonstrate the critical role that the juxtamembrane tyrosine 972 plays in downstream signaling by the insulin receptor.     

Secretion and processing of apolipoprotein A-I in the avian sciatic nerve during development

Apolipoprotein A-I (apo A-I), a major apolipoprotein synthesized by liver and intestine to facilitate transport of plasma lipids as lipoproteins, has been detected also in the avian sciatic nerve. The mRNA and protein levels of apo A-I have been shown to increase during the period of rapid myelination (LeBlanc et al.: J Cell Biol 109:1245-1256, 1989). In order to assess the synthesis of apo A-I protein and the processing of apo A-I isoforms during development, endoneurial slices of avian sciatic nerves from chicks during active myelination at 15 and 17 days embryonic and 1 day posthatch age were incubated with [35]S-methionine. The incubations were fractionated into secreted and intracellular fractions, and incorporation of the label was assessed for apo A-I protein. The pattern of labeling of Po protein, as a marker of myelination, was also determined in the intracellular and compact myelin fractions. Methionine incorporation into Po protein was highest in the intracellular compartment at the 15-day embryonic stage and decreased thereafter, with a corresponding increase in the myelin fraction. During these developmental periods, the levels of nascent apo A-I increased in both the secreted and intracellular fractions. The synthesis of apo A-I specifically increases in the secreted fraction compared with total protein synthesis. The processing of the pro-apo A-I is also developmentally regulated. In the intracellular compartment, there are approximately equal proportions of the acidic and basic isoforms. However, with increasing age, a higher proportion of the apo A-I is secreted as acidic isoforms. It is concluded that the secretion and processing of apo A-I is developmentally regulated in the chick sciatic nerve, in parallel with the process of active myelination.     

Detection of heterozygotes for phenylketonuria. Total body phenylalanine clearance and concentrations of phenylalanine and tyrosine in the plasms of fasting subjects compared

Two tests have been compared for detection of heterozygotes for phenylketonuria, one based on determination of plasma phenylalanine and tyrosine concentrations in fasting individuals and the other on kinetic evaluation of the plasma elimination curve after intravenous loading with L-phenylalanine. The plasma elimination curve was biexponential and the kinetics were evaluated according to the two-compartment model. The constant, beta, expressing the rate of elimination from plasma at pseudo-equilibrium, the rate constant for the elimination from the central compartment, and the total body clearance were determined. Of these three, total body clearance, which on the average was reduced by 32% in the phenylketonuric heterozygotes, showed the best discriminatory ability, but was not better than the information on concentrations of phenylalanine and tyrosine in detecting heterozygotes for phenylketonuria.     

Parenteral glycyl-L-tyrosine maintains tyrosine pools and supports growth and nitrogen balance in phenylalanine-deficient rats

Poor solubility hampers the addition of sufficient amounts of free tyrosine to parenteral amino solutions. We investigated the use of a highly soluble synthetic dipeptide, glycyl-L-tyrosine, as a parenteral tyrosine source in 18 male Wistar rats (body weight 180-200 g). The animals were randomized into three equal groups and catheterized to facilitate isoenergetic (1.2 MJ.kg-1.d-1) and isonitrogenous (1.25 g nitrogen.kg-1.d-1) total parenteral nutrition for 7 d. Controls (Group 1) received a complete amino acid solution, Group 2 received the same solution deficient in phenylalanine (nitrogen replaced with glycine), and group 3 received the phenylalanine-deficient solution supplemented with glycyl-L-tyrosine. Between d 4 and 7, weight gain and nitrogen retention were lower in Group 2 and in Group 1 or 3. In plasma and organ samples obtained at the end of the study, amino acids and dipeptides were analyzed by means of reversed phase-HPLC. In Group 2, phenylalanine and tyrosine concentrations were lower than in controls in plasma, muscle and kidney; in liver, only the tyrosine concentration was lower compared with controls. With glycyl-L-tyrosine supplementation, plasma, liver and kidney tyrosine concentrations and the phenylalanine:tyrosine ratio were normal. Intact glycyl-L-tyrosine was not detectable, suggesting a virtually quantitative elimination or utilization of the infused dipeptide. The results indicate that in phenylalanine-deficient rats, parenteral glycyl-L-tyrosine rapidly provides free tyrosine to facilitate normal growth, promote nitrogen metabolism and maintain intra- and extracellular tyrosine pools.     

Platelet-derived growth factor-stimulated secretion of basement membrane proteins by skeletal muscle occurs by tyrosine kinase-dependent and -independent pathways

The basement membrane of skeletal muscle is produced by the muscle cells it ensheathes and by nonmuscle cells located in the surrounding extracellular matrix. In this study, we have shown that platelet-derived growth factor (PDGF) stimulates secretion of three basement membrane components of skeletal muscle: laminin (70% increase), fibronectin (30%), and type IV collagen (70%). Furthermore, we have found using the signal transduction inhibitors, genistein (tyrosine kinase inhibitor), phorbol 12-myristate 13-acetate (protein kinase C (PKC) inhibitor), thapsigargin (depletes intracellular Ca2+ stores), and H89 (protein kinase A inhibitor), that PDGF-stimulated secretion of these proteins occurs through distinct signaling pathways. Densitometry of Western blots of L6 myoblast supernatant indicates that the PDGF-induced increase in secretion of laminin and type IV collagen is tyrosine kinase-dependent. The increase in type IV collagen secretion also shows dependence on PKC, as well as the release of intracellular Ca2+. Inhibition of either of these pathways reduces the increase in type IV collagen secretion to 20%. In contrast, the PDGF-induced increase in laminin secretion is unaffected by inhibition of either PKC or intracellular Ca2+ release. The increase in fibronectin secretion by PDGF uses yet a third set of signals. PDGF-induced fibronectin secretion is not dependent on tyrosine kinase activity but is dependent on protein kinase A as well as the release of intracellular Ca2+. These divergent signaling pathways provide for independent regulation of basement membrane protein secretion, allowing a muscle cell to modify both the quantity and composition of its basement membrane in response to its environment.     

Mechanism of down-regulation of c-kit receptor. Roles of receptor tyrosine kinase, phosphatidylinositol 3'-kinase, and protein kinase C

The receptor tyrosine kinase Kit and Kit ligand (KL), encoded at the murine white spotting (W) and steel (Sl) loci, respectively, function in hematopoiesis, melanogenesis, and gametogenesis. To understand the mechanism of turnover of Kit in mast cells, mutant receptors generated in vitro were heterologously expressed in Wsb/Wsh mast cells lacking endogenous c-kit expression, and the effects of mutations on KL-induced internalization and ubiquitination/degradation of Kit were studied. Upon binding of KL, KL.Kit receptor complexes were rapidly internalized, and the turnover was accelerated by ubiquitin-mediated degradation. Inactivation of the Kit kinase resulted in a reduced rate of internalization of KL.Kit complexes, degradation of kinase-inactive receptor complexes was relatively slow, and receptor ubiquitination was absent. But abolishment of KL-induced receptor association and activation of phosphatidylinositol 3'-kinase and of tyrosine 821 autophosphorylation did not affect KL-induced internalization and ubiquitination/degradation of Kit. Furthermore, Kit receptors can be down-regulated by proteolytic cleavage induced by either activation of protein kinase C or by isopropyl alcohol. In summary, KL-induced internalization of KL.Kit complexes and ubiquitination/degradation require an active kinase. By contrast, proteolytic cleavage of Kit mediated by protein kinase C activation is independent of kinase activity.     

Trafficking to the plasma membrane of the seven-transmembrane protein encoded by human herpesvirus 6 U51 gene involves a cell-specific function present in T lymphocytes

The sequence of human herpesvirus 6 (HHV-6) U51 open reading frame predicts a protein of 301 amino acid residues with seven transmembrane domains. To identify and characterize U51, we derived antipeptide polyclonal antibodies and developed a transient expression assay. We ascertained that U51 was synthesized in cord blood mononuclear cells infected with either variant A- or variant B-HHV-6 and was transported to the surface of productively infected cells. When synthesized in transient expression systems, U51 intracellular trafficking was regulated in a cell-type-dependent fashion. In human monolayer HEK-293 and 143tk- cells, U51 accumulated predominantly in the endoplasmic reticulum and failed to be transported to the cell surface. In contrast, in T-lymphocytic cell lines J-Jhan, Molt-3, and Jurkat, U51 was successfully transported to the plasma membrane. We infer that transport of U51 to the cell surface requires a cell-specific function present in activated T lymphocytes and T-cell lines.     

Temporal synthesis of band 3 oligomers during terminal maturation of mouse erythroblasts. Dimers and tetramers exist in the membrane as preformed stable species

Band 3, the anion transport protein of the erythrocyte membrane, exists in the membrane as a mixture of dimers (B3D) and tetramers (B3T). The dimers are not linked to the skeleton and constitute the free mobile band 3 fraction. The tetramers are linked to the skeleton by their interaction with ankyrin. In this report we have examined the temporal synthesis and assembly of band 3 oligomers into the plasma membrane during red cell maturation. The oligomeric state of newly synthesized band 3 in early and late erythroblasts was analyzed by size-exclusion high-pressure liquid chromatography of band 3 extracts derived by mild extraction of plasma membranes with the nonionic detergent C12E8 (octaethylene glycol n-dodecyl monoether). This analysis revealed that at the early erythroblast stage, the newly synthesized band 3 is present predominantly as tetramers, whereas at the late stages of erythroid maturation, it is present exclusively as dimers. To examine whether the dimers and tetramers exist in the membrane as preformed stable species or whether they are interconvertible, the fate of band 3 species synthesized during erythroblast maturation was examined by pulse-chase analysis. We showed that the newly synthesized band 3 dimers and tetramers are stable and that there is no interconversion between these species in erythroblast membranes. Pulse-chase analysis followed by cellular fractionation showed that, in early erythroblasts, the newly synthesized band 3 tetramers are initially present in the microsomal fraction and later incorporated stably into the plasma membrane fraction. In contrast, in late erythroblasts the newly synthesized band 3 dimers move rapidly to the plasma membrane fraction but then recycle between the plasma membrane and microsomal fractions. Fluorescence photobleaching recovery studies showed that significant fractions of B3T and B3D are laterally mobile in early and late erythroblast plasma membranes, respectively, suggesting that many B3T-ankyrin complexes are unattached to the membrane skeleton in early erythroblasts and that the membrane skeleton has yet to become tightly organized in late erythroblasts. We postulate that in early erythroblasts, band 3 tetramers are transported through microsomes and stably incorporated into the plasma membrane. However, when ankyrin synthesis is downregulated in late erythroblasts, it appears that B3D are rapidly transported to the plasma membrane but then recycled between the plasma membrane and microsomal compartments. These observations may suggest novel roles for membrane skeletal proteins in stabilizing integral membrane protein oligomers at the plasma membrane and in regulating the endocytosis of such proteins.