Shifting microbial communities sustain multiyear iron reduction and methanogenesis in ferruginous sediment incubations.

Reactive Fe(III) minerals can influence methane (CH4 ) emissions by inhibiting microbial methanogenesis or by stimulating anaerobic CH4 oxidation. The balance between Fe(III) reduction, methanogenesis, and CH4 oxidation in ferruginous Archean and Paleoproterozoic oceans would have controlled CH4 fluxes to the atmosphere, thereby regulating the capacity for CH4 to warm the early Earth under the Faint Young Sun. We studied CH4 and Fe cycling in anoxic incubations of ferruginous sediment from the ancient ocean analogue Lake Matano, Indonesia, over three successive transfers (500 days in total). Iron reduction, methanogenesis, CH4 oxidation, and microbial taxonomy were monitored in treatments amended with ferrihydrite or goethite. After three dilutions, Fe(III) reduction persisted only in bottles with ferrihydrite. Enhanced CH4 production was observed in the presence of goethite, highlighting the potential for reactive Fe(III) oxides to inhibit methanogenesis. Supplementing the media with hydrogen, nickel and selenium did not stimulate methanogenesis. There was limited evidence for Fe(III)-dependent CH4 oxidation, although some incubations displayed CH4 -stimulated Fe(III) reduction. 16S rRNA profiles continuously changed over the course of enrichment, with ultimate dominance of unclassified members of the order Desulfuromonadales in all treatments. Microbial diversity decreased markedly over the course of incubation, with subtle differences between ferrihydrite and goethite amendments. These results suggest that Fe(III) oxide mineralogy and availability of electron donors could have led to spatial separation of Fe(III)-reducing and methanogenic microbial communities in ferruginous marine sediments, potentially explaining the persistence of CH4 as a greenhouse gas throughout the first half of Earth history.

Glucose activates protein kinase C-zeta /lambda through proline-rich tyrosine kinase-2, extracellular signal-regulated kinase, and phospholipase D: a novel mechanism for activating glucose transporter translocation.

Insulin controls glucose uptake by translocating GLUT4 and other glucose transporters to the plasma membrane in muscle and adipose tissues by a mechanism that appears to require protein kinase C (PKC)-zeta/lambda operating downstream of phosphatidylinositol 3-kinase. In diabetes mellitus, insulin-stimulated glucose uptake is diminished, but with hyperglycemia, uptake is maintained but by uncertain mechanisms. Presently, we found that glucose acutely activated PKC-zeta/lambda in rat adipocytes and rat skeletal muscle preparations by a mechanism that was independent of phosphatidylinositol 3-kinase but, interestingly, dependent on the apparently sequential activation of the dantrolene-sensitive, nonreceptor proline-rich tyrosine kinase-2; components of the extracellular signal-regulated kinase (ERK) pathway, including, GRB2, SOS, RAS, RAF, MEK1 and ERK1/2; and, most interestingly, phospholipase D, thus yielding increases in phosphatidic acid, a known activator of PKC-zeta/lambda. This activation of PKC-zeta/lambda, moreover, appeared to be required for glucose-induced increases in GLUT4 translocation and glucose transport in adipocytes and muscle cells. Our findings suggest the operation of a novel pathway for activating PKC-zeta/lambda and glucose transport.

Glucose activates mitogen-activated protein kinase (extracellular signal-regulated kinase) through proline-rich tyrosine kinase-2 and the Glut1 glucose transporter.

Glucose serves as both a nutrient and regulator of physiological and pathological processes. Presently, we found that glucose and certain sugars rapidly activated extracellular signal-regulated kinase (ERK) by a mechanism that was: (a) independent of glucose uptake/metabolism and protein kinase C but nevertheless cytochalasin B-inhibitable; (b) dependent upon proline-rich tyrosine kinase-2 (PYK2), GRB2, SOS, RAS, RAF, and MEK1; and (c) amplified by overexpression of the Glut1, but not Glut2, Glut3, or Glut4, glucose transporter. This amplifying effect was independent of glucose uptake but dependent on residues 463-468, IASGFR, in the Glut1 C terminus. Accordingly, glucose effects on ERK were amplified by expression of Glut4/Glut1 or Glut2/Glut1 chimeras containing IASGFR but not by Glut1/Glut4 or Glut1/Glut2 chimeras lacking these residues. Also, deletion of Glut1 residues 469-492 was without effect, but mutations involving serine 465 or arginine 468 yielded dominant-negative forms that inhibited glucose-dependent ERK activation. Glucose stimulated the phosphorylation of tyrosine residues 402 and 881 in PYK2 and binding of PYK2 to Myc-Glut1. Our findings suggest that: (a) glucose activates the GRB2/SOS/RAS/RAF/MEK1/ERK pathway by a mechanism that requires PYK2 and residues 463-468, IASGFR, in the Glut1 C terminus and (b) Glut1 serves as a sensor, transducer, and amplifier for glucose signaling to PYK2 and ERK.

Protein interactions with the glucose transporter binding protein GLUT1CBP that provide a link between GLUT1 and the cytoskeleton.

Subcellular targeting and the activity of facilitative glucose transporters are likely to be regulated by interactions with cellular proteins. This report describes the identification and characterization of a protein, GLUT1 C-terminal binding protein (GLUT1CBP), that binds via a PDZ domain to the C terminus of GLUT1. The interaction requires the C-terminal four amino acids of GLUT1 and is isoform specific because GLUT1CBP does not interact with the C terminus of GLUT3 or GLUT4. Most rat tissues examined contain both GLUT1CBP and GLUT1 mRNA, whereas only small intestine lacked detectable GLUT1CBP protein. GLUT1CBP is also expressed in primary cultures of neurons and astrocytes, as well as in Chinese hamster ovary, 3T3-L1, Madin-Darby canine kidney, Caco-2, and pheochromocytoma-12 cell lines. GLUT1CBP is able to bind to native GLUT1 extracted from cell membranes, self-associate, or interact with the cytoskeletal proteins myosin VI, alpha-actinin-1, and the kinesin superfamily protein KIF-1B. The presence of a PDZ domain places GLUT1CBP among a growing family of structural and regulatory proteins, many of which are localized to areas of membrane specialization. This and its ability to interact with GLUT1 and cytoskeletal proteins implicate GLUT1CBP in cellular mechanisms for targeting GLUT1 to specific subcellular sites either by tethering the transporter to cytoskeletal motor proteins or by anchoring the transporter to the actin cytoskeleton.

C-terminal mutations that alter the turnover number for 3-O-methylglucose transport by GLUT1 and GLUT4.

Turnover numbers for 3-O-methylglucose transport by the homologous glucose transporters GLUT1 and GLUT4 were compared to those for truncated and chimeric transporters expressed in Xenopus oocytes to assess potential regulatory properties of the C-terminal domain. The ability of high intracellular sugar concentrations to increase the turnover number for sugar entry ("accelerated exchange") by GLUT1 and not by GLUT4 was maintained in oocytes. Replacing the GLUT1 C terminus with that of GLUT4 stimulated turnover 1.6-fold, but abolished accelerated exchange. Thus, the GLUT1 C terminus permits accelerated exchange by GLUT1, but in doing so must interact with other GLUT1 specific sequences since the GLUT4ctrm1 chimera did not exhibit this kinetic property. Removal of 38 C-terminal amino acids from GLUT4 reduced its turnover number by 40%, whereas removing only 20 residues or replacing its C terminus with that of GLUT1 increased its turnover number 3.5-3.9 fold. Therefore, using mechanisms independent of those which alter transporter targeting to the plasma membrane, C-terminal mutations in either GLUT1 or GLUT4 can activate transport normally restricted by the native C-terminal domain. These results implicate the C termini as targets of physiological factors, which through covalent modification or direct binding might alter C-terminal interactions to regulate intrinsic GLUT1 and GLUT4 transporter activity.

3T3-L1 adipocyte glucose transporter (HepG2 class): sequence and regulation of protein and mRNA expression by insulin, differentiation, and glucose starvation.

A glucose transporter cDNA (GLUT) clone was isolated from mouse 3T3-L1 adipocytes and sequenced. The nucleotide and deduced amino acid sequences were, respectively, 95 and 99% homologous to those of the rat brain transporter. The mouse cDNA and a polyclonal antibody recognizing the corresponding in vitro translation product were used to compare changes in transporter mRNA and protein levels during differentiation, glucose starvation, and chronic insulin exposure of 3T3-L1 preadipocytes. The respective cellular content of transporter mRNA and protein were increased 6.6- and 7.8-fold during differentiation, and 3.8- and 2.5-fold from chronic insulin exposure of differentiated adipocytes. Glucose starvation increased transporter mRNA and protein levels 2.2- and 3.5-fold in undifferentiated preadipocytes and 1.8- and 3.1-fold in differentiated adipocytes. Starvation of undifferentiated cells completely converted the native transporter to an incompletely glycosylated form, while increasing basal transport rates 4.5-fold. Either full glycosylation is not required to produce a functionally active transporter, or starvation causes a unique predifferentiation induction of the normally absent "responsive" transporter. The changes in transporter protein expression elicited by differentiation were attributed primarily to increased rates of transporter synthesis, while the disproportionate changes in mRNA and protein expression from chronic insulin treatment and starvation suggested these conditions increase synthesis and decrease turnover rates in regulating transporter protein expression. Although chronic insulin exposure and glucose starvation each raised the expression of transporter protein greater than 3-fold and basal transport rates 2.5- to 4.5-fold, no significant increase in the insulin responsiveness of 3T3-L1 preadipocytes or differentiated adipocytes was observed. Thus, the changes in the transporter mRNA and protein expression observed in this study were most consistent with their being associated with the regulated expression of a basal or low level insulin-responsive transporter.

An analysis of the relationship between the cellular distribution and the rate of turnover for the separate classes of unoccupied, noncovalently occupied, and covalently occupied insulin receptor.

To further investigate insulin's role in regulating the turnover of insulin receptor during down-regulation in 3T3-L1 adipocytes, the relationship between the cellular distribution and turnover of unoccupied, noncovalently occupied, and covalently occupied receptor was examined. At steady-state 12% of the unoccupied receptors and 46% of covalently occupied receptors are intracellular. The apparent first-order rate constant (Kapp) for turnover of the total pool of covalently occupied receptors (0.16 h-1) is 3.8-fold higher than that for unoccupied receptors (0.042 h-1). When unlabeled insulin is added, identical values for both Kapp (0.10 h-1) and distribution (26% internal) are measured for noncovalently and covalently occupied receptors. The rate constant (Kdeg), describing the relative sensitivity of internalized receptor to degradation, is identical (0.36-0.41 h-1) for unoccupied, noncovalently occupied, and permanently occupied pools of internal receptor. Mechanisms for down-regulation postulating: (a) an occupancy-dependent alteration in the conformation of internal receptor increasing receptor sensitivity to internal proteases, (b) a preferential sorting of internal occupied receptor to degradative pathways, or (c) induction of intracellular proteases by insulin, would all reflect a substantial change in Kdeg for occupied receptor and thus are unlikely mechanisms by which insulin increases the rate of receptor turnover. The turnover of insulin receptor in 3T3-L1 adipocytes is regulated primarily by its intracellular concentration and not by the state of occupancy of internalized receptor.

Elevation of the number of cell-surface insulin receptors and the rate of 2-deoxyglucose uptake by exposure of 3T3-L1 adipocytes to tolbutamide.

Sulfonylurea compounds are hypoglycemic agents which by unknown mechanisms alter the amount of insulin receptor and the rate of glucose utilization in tissues exposed to the drugs. In this study the effects on insulin binding and uptake of 2-deoxyglucose by 3T3-L1 adipocytes were assessed after maintaining cell monolayers for 1-3 days in medium containing different concentrations of the sulfonylurea, tolbutamide. The amount of 125I-insulin bound by treated monolayers gradually increased to values 150-250% of those of control monolayers after 2-3 days of exposure to 1.5 mM tolbutamide. Such increases in insulin binding capacity arose primarily from an increase in receptor number and not from an alteration in the affinity of the receptor for insulin. Concomitant with the changes observed for the insulin receptor, tolbutamide-treated monolayers expressed 1.5-2-fold higher rates of uptake of 2-deoxyglucose relative to control monolayers at concentrations of insulin between 0 and 10(-10) M. This study thus demonstrates the responsiveness of adipocytes to tolbutamide and also establishes the usefulness of 3T3-L1 cells as a model system in which to study the mechanism of tolbutamide action, both as it relates to the use of sulfonylurea compounds in clinical applications and as possible probes for perturbing and studying relatively uncharacterized regulatory pathways controlling receptor level and biological responses to insulin.

Direct comparison of the rates of internalization and degradation of covalent receptor-insulin complexes in 3T3-L1 adipocytes. Internalization of occupied receptors is not the rate-limiting step in receptor-hormone complex degradation.

Insulin receptors on the surface of 3T3-L1 adipocytes were photolabeled using the iodinated analog, B29-lysine-substituted N-[N'-(2-nitro-4-azidophenyl)glycyl]insulin. Under optimal labeling conditions (below 15 degrees C), greater than 95% of the labeled receptor remained on the cell surface prior to incubation at 37 degrees C. When the labeled monolayers were returned to their normal culture environment (37 degrees C), the covalent receptor-insulin complexes were rapidly internalized at initial rates equivalent to 130-170% of labeled surface receptor/h. Internalization of the complexes proceeded to an equilibrium or end point distribution of 40% internal receptor and 60% cell-surface receptor. Under the several labeling conditions tested, covalent receptor-insulin complexes were degraded in an apparent first order process at 37 degrees C with half-lives between 5 and 7 h. This rate was equivalent to only 10% of the labeled receptor being degraded per h and was 13-17-fold slower than the initial rate of labeled receptor internalization. This study directly demonstrates that the initial rate of internalization of covalent receptor-insulin complexes is not the rate-limiting step in their degradation in 3T3-L1 adipocytes. Furthermore, 3T3-L1 adipocytes are unable to internalize all of the labeled surface receptor, suggesting that two classes of internalization competent and incompetent receptor may exist or that an equilibrium distribution of internal and cell-surface receptor is established by the relative rates of internalization and recycling of labeled receptor.

Metabolism of covalent receptor-insulin complexes by 3T3-L1 adipocytes. Synthesis and use of photosensitive insulin analogs to study insulin receptor metabolism in cell culture.

To facilitate labeling cell surface insulin receptors and analyzing their metabolism by 3T3-L1 adipocytes, a characterization of both the interaction of photosensitive insulin analogs with 3T3-L1 adipocytes and the conditions for photocross-linking these derivatives to the insulin receptor are described. The synthesis and purification of two photoaffinity analogs of insulin are presented. Both B29-lysine- and A1-glycine-substituted N-(2-nitro-4-azidophenyl)glycyl insulin compete with 125I-insulin for binding to 3T3-L1 adipocytes, and the B29-derivative retains a biological activity similar to that for native insulin. An apparatus developed for these studies permits photolysis of cells in monolayer culture using the visible region of the lamp emission spectrum. Activation of the photoderivative by this apparatus occurs with a half-life of approximately 15 s and permits rapid photolabeling of a single species of receptor of 300,000 Da. The conditions for photolabeling permit a measurement of the turnover of covalent receptor-insulin complexes by 3T3-L1 adipocytes in monolayer culture. Degradation of this complex occurs as an apparent first order process with a half-life of 7 h. A comparison with previous studies (Reed, B. C., Ronnett, G. V., Clements, P. R., and Lane, M. D. (1981) J. Biol. Chem 256, 3917-3925; Ronnett, G. V., Knutson, V. P., and Lane, M. D. (1982) J. Biol. Chem. 257, 4285-4291) indicates that in a "down-regulated" state, 3T3-L1 adipocytes degrade covalent receptor-hormone complexes with kinetics similar to those for the degradation of dissociable receptor-hormone complexes.

Alterations in cyclic AMP phosphodiesterase activities during differentiation of 3T3-L1 cells.

3T3-L1 cells contain multiple forms of cyclic nucleotide phosphodiesterase in both supernatant (100,000 X g, 40 min) and particulate fractions. Supernatant fractions from both undifferentiated and differentiated cells contained calmodulin-sensitive activity. In undifferentiated 3T3-L1 cells, only a small fraction of the total cAMP phosphodiesterase activity was found in the particulate fraction and the specific activity of the particulate was lower than the supernatant. With differentiation the specific activity of the particulate doubled, and there was a dramatic increase in total activity in this fraction, while in the supernatant total cAMP phosphodiesterase activity increased less and specific activity decreased. The particulate fraction accounted for approximately 70% of the total cAMP phosphodiesterase activity in differentiated cells in contrast to about one-third in undifferentiated cells. In addition, there was a qualitative change in particulate phosphodiesterase activity. In fractions from 3T3-L1 adipocytes, with either cAMP or cGMP as substrate, Lineweaver-Burk plots were nonlinear, with low Km components of less than 1 microM, and cGMP inhibited cAMP hydrolysis. In particulate fractions from undifferentiated cells, cGMP did not inhibit and often enhanced hydrolysis of cAMP. With differentiation, there was also a marked increase in particulate cGMP phosphodiesterase activity. cAMP and cGMP phosphodiesterase activities solubilized from particulate fraction of differentiated cells coeluted from DEAE-Biogel and exhibited kinetic properties similar to the crude particulate fractions. During differentiation, there seems to be an alteration in the distribution of phosphodiesterase activity as well as the appearance of a particulate phosphodiesterase with kinetic properties similar to a particulate phosphodiesterase found in mature rat adipocytes.

Role of glycosylation and protein synthesis in insulin receptor metabolism by 3T3-L1 mouse adipocytes.

The roles of glycosylation and protein synthesis in the maintenance of insulin receptor levels and turnover rates in 3T3-L1 adipocytes were investigated. The heavy isotope density-shift technique was employed to determine the effects of inhibitors of these processes on the rates of synthesis and degradation of cellular insulin receptors. Inhibitors of protein synthesis--i.e., cycloheximide and puromycin--markedly decreased the rate of degradation of the insulin receptor, the half-life for receptor decay increasing from 7.5 hr without to 25 hr with inhibitor. The continued synthesis of a short-lived protein appears to be necessary for normal insulin receptor turnover. Tunicamycin, a potent inhibitor of core oligosaccharide addition in the formation of N-glycosidically linked glycoproteins, caused the depletion of cell-surface and total cellular detergent-extractable insulin receptors. This inhibitor totally prevented the formation of functional newly synthesized insulin receptor, yet receptor degradation was affected minimally. Thus, glycosylation of the receptor appears to be required for its activation after translation.

Insulin receptor synthesis and turnover in differentiating 3T3-L1 preadipocytes.

3T3-L1 "preadipocytes" can be induced to differentiate in culture into cells having the morphological and biochemical characteristics of adipocytes. The binding of 125I-insulin to the cell-surface of differentiated and undifferentiated 3T3-L1 cells and nondifferentiating 3T3-C2 cells was compared. In the absence of agents which induce adipocyte conversion, ie, insulin or insulin plus methylisobutylxanthine (MIX) and dexamethasone (DEX), 3T3-L1 cells fail to express the adipocyte phenotype and maintain a constant number of insulin binding sites. Induction of adipocyte conversion with 3T3-L1 cells in the presence of insulin causes apparent down-regulation of insulin receptors followed by a 12--15-fold increase in receptor number which parallels differentiation. Approximately 170,000 insulin binding sites per cell are expressed when greater than 75% of the cells have differentiated. The rise of insulin receptor level is differentiation-dependent. 3T3-C2 cells, which do not differentiate in the presence of insulin or insulin plus MIX and DEX, exhibit only insulin-induced down-regulation of insulin receptors. The increase of insulin receptor level in 3T3-L1 cells in receptor-specific since the levels of epidermal growth factor receptor or choleragen receptor, respectively, remain constant or decrease substantially. A heavy isotope, density-shift technique was used to analyze insulin receptor synthesis and turnover in cells labeled with "heavy" (2H, 13C, and 15N) amino acids. Solubilized newly-synthesized "heavy" and old "light" receptors were separated by isopycnic banding on CsCl gradients and quantitated. The size of the soluble receptor isolated after isopycnic banding in CsCl gradients is approximately 400,000 daltons. Mixing of "light" and "heavy" membranes prior to extraction of receptor revealed no change in "light" or "heavy" receptor isopycnic banding densities. Thus, no detectable interchange of subunits occurs between receptor molecules during extraction or equilibrium centrifugation. Insulin receptor synthesis and turnover, studied by the density-shift technique showed that the rise of receptor level during differentiation results primarily from an increased rate of receptor synthesis. The rate of insulin receptor degradation was not significantly altered. The t1/2 for degradation of the insulin receptor in differentiated 3T3-L1 cells in culture was 6--7 hours in the presence of insulin. Removal of insulin from the medium did not materially affect the rate of receptor degradation. Inhibition of protein synthesis with cycloheximide causes a lengthening of the t1/2 for insulin receptor degradation to 26 hours. Thus, the synthesis of a short-lived protein appears to be required for a critical step in the pathway of insulin receptor degradation.

Loss of choleragen receptors and ganglioside upon differentiation of 3T3-L1 preadipocytes.

3T3-L1 preadipocytes differentiate in culture into cells having the enzymatic and morphological characteristics of adipocytes. Differentiation is accompanied by a decrease in total cellular ganglioside content; the ganglioside level is 1.8 to 2.5-fold higher in undifferentiated than in differentiated cells. Gangliosides GM3 and GD1a constitute a majority of total cell gangliosides in both cell types, while ganglioside GM1, the putative choleragen receptor, constitutes less than 5%. Differentiation results in a 75 to 85% decrease in ganglioside GM1. An inverse correlation exists between the percentage of adipocytes in the cell population and: 1) total ganglioside and ganglioside GM1 content, and 2) surface ganglioside GM1 as estimated by choleragen binding or fluorescent staining of bound choleragen. Nondifferentiating 3T3-C2 control cells do not exhibit changes in total ganglioside, ganglioside GM1, or choleragen binding that are observed with 3T3-L1 cells.

Insulin receptor synthesis and turnover in differentiating 3T3-L1 preadipocytes.

A density-shift method is described for analyzing insulin receptor synthesis and turnover in cultured cells labeled with "heavy" amino acids (2H, 13C, and 15N). Solubilized newly synthesized heavy and old "light" receptors are separated by isopycnic banding on CsCl gradients and then quantitated. Insulin receptor synthesis and turnover were studied by this technique in 3T3-L1 preadipocytes which undergo an increase in insulin binding capacity during differentiation. The results indicate that the increase in insulin binding capacity is a consequence of new receptor synthesis, that the insulin receptor has a relatively short half-life (6.7 hr), and that an increased rate of receptor synthesis contributes to the increase of insulin receptor level during differentiation.

Alterations in insulin binding accompanying differentiation of 3T3-L1 preadipocytes.

Expression of the adipocyte phenotype by differentiating 3T3-L1 preadipocytes occurs upon exposure of the cells to insulin. Differentiation-linked changes in 125I-labeled insulin binding to 3T3-L1 cells were monitored and compared with those in nondifferentiating 3T3-C2 controls treated similarly. Without chronic insulin treatment, 3T3-L1 cells failed to express the adipocyte phenotype but maintained a level of 25,000-35,000 insulin-binding sites per cell. Treatment of 3T3-L1 cells with insulin resulted in an initial suppression of insulin binding followed by a 12-fold increase that paralleled the appearance of differentiated cells. A maximum of 170,000 insulin-binding sites per cell was attained for a population in which greater than 75% of the cells had differentiated. The increase of insulin receptor level appears to be differentiation-dependent and is not a general response of cells to the culture conditions. 3T3-C2 cells maintained in the presence of insulin for 30 days exhibited the undifferentiated phenotype and suppressed levels of insulin binding (35,000 sites per cell). The binding capacity of 3T3-L1 cells for epidermal growth factor remained unchanged between 25,000 and 40;000 sites per cell and was independent of the state of differentiation. Thus, induction by insulin in receptor-specific changes. Insulin receptors increase in number but epidermal growth factor receptors remain constant.

Substrate Binding of avian liver prenyltransferase.

Prenyltransferase (farnesyl pyrophosphate synthetase) was purified from avian liver and characterized by Sephadex and sodium dodecyl sulfate gel chromatography, peptide mapping, and end-group analysis. The enzyme is 85 800 +/- 4280 daltons and consists of two identical subunits as judged by sodium dodecyl sulfate gel electrophoresis, peptide mapping, and end-group analysis. Chemical analysis of the protein revealed no lipid or carbohydrate components. Avian prenyltransferase synthesizes farnesyl pyrophosphate from either dimethylallyl or geranyl pyrophosphate and isopentenyl pyrophosphate. A lower rate of geranylgeranyl pyrophosphate synthesis from farnesyl pyrophosphate and isopentenyl pyrophosphate was also demonstrated. Michaelis constants for farnesyl pyrophosphate synthesis are 0.5 muM for both isopentenyl pyrophosphate and geranyl pyrophosphate. The V max for the reaction is 1990 nmol min-1 mg-1 (170 mol min-1 mol-1 enzyme). Substrate inhibition by isopentenyl pyrophosphate is evident at high isopentenyl pyrophosphate and low geranyl pyrophosphate concentrations. Michaelis constants for geranylgeranyl pyrophosphate synthesis are 9 muM for farnesyl pyrophosphate and 20 muM for isopentenyl pyrophosphate. The Vmax is 16 nmol min-1 mg-1 (1.4 mol min-1 mol-1 enzyme). Two moles of each of the allylic substrates is bound per mol of enzyme. The apparent dissociation constants for dimethylallyl, geranyl, and farnesyl pyrophosphates are 1.8, 0.17, and 0.73 muM, respectively. Dimethylallyl and geranyl pyrophosphates bound competitively to prenyltransferase with one-for-one displacement. Four moles of isopentenyl pyrophosphate was bound per mole of enzyme. Citronellyl pyrophosphate, an analogue of geranyl pyrophosphate, was competitive with the binding of 2 of the 4 mol of isopentenyl pyrophosphate bound. The data are interpreted to indicate that each subunit of avian liver prenyltransferase has a single allylic binding site accommodating dimethylallyl, geranyl, and farnesyl pyrophosphates, and one binding site for isopentenyl pyrophosphate. In the absence of an allylic pyrophosphate or analogue, isopentenyl pyrophosphate also can bind to the allylic site.