Comparison of type I hexokinases from pig heart and kinetic evaluation of the effects of inhibitors.

Type I hexokinase (ATP:D-hexose 6-phospotransferase, EC 2.7.1.1) of porcine heart exists in two chromatographically distinct forms. These do not differ significantly in size, electrophoretic mobility at pH 8.6 or kinetic properties. Both forms obey a sequential mechanism and are potently inhibited by glucose 6-phosphate. In contrast to observations of type I hexokinase from brain, inhibition by glucose 6-phosphate is not relieved by inorganic phosphate. Under most conditions, low concentrations of phosphate (less than 10 mM) have little effect on the kinetic behaviour of the enzyme but at higher concentrations this ligand is an inhibitor. Mannose 6-phosphate inhibits in a manner analogous to glucose 6-phosphate but the Ki is much greater. In view of the similarity of the kinetic parameters governing phosphorylation of mannose and glucose, this difference in affinity for the inhibitor site is seen as consistent with the existence of a separate regulatory site on the enzyme. MgADP inhibits hexokinase but behaves as a normal product inhibitor and inhibition is competitive with respect to MgATP and non-competitive with respect to glucose.     

The role of glucose and pyruvate transport in regulating nutrient utilization by preimplantation mouse embryos

Preimplantation mouse embryos utilize pyruvate preferentially during the early cleavage stages before switching to glucose at around the time of compaction. This switch in substrate preference has been studied using a non-invasive ultramicrofluorometric analytical technique on single mouse embryos. On the basis of transport kinetic studies and inhibition by phloretin, cytochalasin B and sugar analogues, a component of glucose uptake by mouse blastocysts was found to be mediated by facilitated diffusion. The Jmax and Kt of this facilitated component were 3.53 pmol embryo-1 h-1 and 0.14 mM, respectively. At physiological concentrations of glucose, the facilitated component accounts for around 75% of glucose uptake. Glucose uptake by blastocysts was found to be insensitive to insulin, added at a range of concentrations. There was no evidence for glucose active transport. The carrier-mediated component of glucose entry was detectable from the 2-cell stage onwards. Pyruvate uptake was also mediated by a carrier throughout development. In the absence of glucose in the incubation medium, the characteristic decline in pyruvate uptake does not occur. The data are consistent with a role for embryonic cell transport in regulating glucose utilization prior to compaction, but do not exclude the involvement of metabolic factors, such as the allosteric regulation of the enzymes hexokinase and phosphofructokinase.     

THE KINETIC PROPERTIES OF HEXOSE TRANSPORT INTO SYNAPTOSOMES FROM GUINEA PIG CEREBRAL CORTEX

Abstract— Hexose uptake into synaptosomes has been shown to occur by a saturable mechanism with a relatively small component due to passive diffusion. Competition between glucose and deoxyglucose for entry was demonstrated and the kinetic properties of the process were studied by using glucose as a competitive inhibitor of deoxyglucose entry. During kinetic analysis of the transport process higher affinities for both hexoses were indicated by the results from the synaptosome preparation compared with those from cerebral cortex slices. The kinetic properties of glucose inhibition of deoxyglucose uptake into synaptosomes could not be interpreted completely in terms of a unimolecular transport model. The results appear to follow predictions for 'doubly competitive inhibition', and some evidence for polyvalency of the uptake process was obtained.     

Uptake kinetics of different arsenic species by Brassica carinata

The time- and concentration-dependent uptake kinetics for arsenate and arsenite were determined in 15-day-old excised roots. In both cases, arsenite showed a mono-phasic influx with the isotherm data fitting a linear model better than a non-linear one. The time- and the concentration-dependent uptake of arsenate displayed a hyperbolic kinetic. Greater uptake of arsenate, compared with arsenite, was found especially at lower external substrate concentrations. Competitive inhibition of uptake with phosphate showed that arsenite and arsenate were taken up by different uptake systems because arsenate uptake was strongly inhibited in the presence of phosphate, whereas arsenite uptake was not affected.     

Interaction of phosphate with monovalent cation uptake in yeast.

The uptake of monovalent cations by yeast via the monovalent cation uptake mechanism is inhibited by phosphate. The inhibition of Rb+ uptake shows saturation kinetics and the phosphate concentration at which half-maximal inhibition is observed is equal to the Km of phosphate for the sodium-independent phosphate uptake mechanism. The kinetic coefficients of Rb+ and TI+ uptake are affected by phosphate: the maximal rate of uptake is decreased and the apparent affinity constants for the translocation sites are increased. In the case of Na+ uptake, the inhibition by phosphate may be partly or completely compensated by stimulation of Na+ uptake via a sodium-phosphate cotransport mechanism. Phosphate effects a transient stimulation of the efflux of the lipophilic cation dibenzyldimethylammonium from preloaded yeast cells and a transient inhibition of dibenzyldimethylammonium uptake. Possibly, the inhibition of monovalent cation uptake in yeast can be explained by a transient depolarization of the cell membrane by phosphate.     

Kinetic modeling to optimize pentose fermentation in Zymomonas mobilis

Zymomonas mobilis engineered to express four heterologous enzymes required for xylose utilization ferments xylose along with glucose. A network of pentose phosphate (PP) pathway enzymatic reactions interacting with the native glycolytic Entner Doudoroff (ED) pathway has been hypothesized. We have investigated this putative reaction network by developing a kinetic model incorporating all of the enzymatic reactions of the PP and ED pathways, including those catalyzed by the heterologous enzymes. Starting with the experimental literature on in vitro characterization of each enzymatic reaction, we have developed a kinetic model to enable dynamic simulation of intracellular metabolite concentrations along the network of interacting PP and ED metabolic pathways. This kinetic model is useful for performing in silico simulations to predict how varying the different enzyme concentrations will affect intracellular metabolite concentrations and ethanol production rate during continuous fermentation of glucose and xylose mixtures. Among the five enzymes whose concentrations were varied as inputs to the model, ethanol production in the continuous fermentor was optimized when xylose isomerase (XI) was present at the highest level, followed by transaldolase (TAL). Predictions of the model that the interconnecting enzyme phosphoglucose isomerase (PGI) does not need to be overexpressed were recently confirmed through experimental investigations. Through such systematic analysis, we can develop efficient strategies for maximizing the fermentation of both glucose and xylose, while minimizing the expression of heterologous enzymes.     

The effects of aspartame on the HTR8/SVneo extravillous trophoblast cell line

Extravillous trophoblasts (EVTs) are a key cell type involved in placentation. Aspartame is an artificial sweetener with a widespread use. In rodents, aspartame ingestion during pregnancy was found to cause a reduction in placental and fetal weights, but its effect in placentation at a cellular level has not been studied. Aspartame is completely hydrolyzed in the gastrointestinal tract into L-phenylalanine, L-aspartic acid, and methanol. We aimed to study the effects of aspartame and its metabolites on placentation related characteristics of EVTs. For this, we exposed HTR-8/SVneo cells to aspartame (0.001, 0.01, 0.1, 0.5 and 1 mM), L-phenylalanine (0.14 and 0.5 mM), L-aspartic acid (0.82, 2.8 and 10 mM) or methanol (0.14 and 0.8 mM) for 24 h. Aspartame had an anti-proliferative effect, decreased the number of metabolically active cells and glucose cellular uptake and increased the number of cells arrested in S phase. L-aspartic acid significantly reduced glucose uptake and whole-cell protein content. L-phenylalanine had an anti-proliferative effect and increased the number of metabolically active cells. Interestingly, methanol exerted very marked effects on HTR8/SVneo cells: it showed an anti-proliferative effect, decreased glucose uptake, the migratory ability and the number of cells in the G2/M phase and increased oxidative stress levels, in concentrations corresponding to the blood levels after the 99th percentile of projected daily ingestion of aspartame. Overall, our results demonstrate that aspartame and its metabolites can affect several characteristics of EVTs and support the conclusion that the effect of aspartame in the placenta should be further evaluated.     

Characterization of essential arginine residues implicated in the renal transport of phosphate and glucose.

We have characterized the reaction of arginine-specific reagents with the phosphate and glucose carriers of the kidney brush-border membrane. The inhibition of phosphate and glucose transport by phenylglyoxal follows pseudo-first-order kinetics. The rate of inactivation of phosphate transport by 50 mM phenylglyoxal was about 3-fold higher than that for glucose transport (kapp was 0.052 s-1 for the uptake of phosphate and 0.019 s-1 for the uptake of glucose). The order of the reaction, n, with respect to phenylglyoxal was 1.25 and 1.31 for the inactivation of phosphate and glucose transport, respectively. The inactivation of phosphate flux by p-hydroxyphenylglyoxal also follows pseudo-first-order kinetics, but the inhibition rate (kapp = 0.0012 s-1) was slower than with phenylglyoxal. The inactivation increased with the alkalinity of the preincubation medium for both phosphate and glucose fluxes and was maximal at pH 9.0. The inactivation of phosphate flux by phenylglyoxal depends upon the presence of an alkaline intravesicular pH. Extravesicular pH does not affect the reaction. Phenylglyoxal does not interfere with the recycling of the protonated carrier since phosphate uptake is inhibited independently of the pH used for transport measurements. Moreover, phenylglyoxal completely abolished trans stimulation by phosphate. Trans sodium inhibited phosphate uptake and abolished the pH profile of phosphate uptake.     

Kidney brush-border membrane transporters: differential sensitivity to diethyl pyrocarbonate

The effects of the histidine modifier, diethyl pyrocarbonate (DEPC), on brush-border membrane transport systems were studied in rat kidney. DEPC caused a strong inhibition of sodium-dependent phosphate and D-glucose uptake. Phosphate uptake remained linear up to 10 s in control and DEPC-treated membrane vesicles. The D-glucose carrier was more sensitive than the phosphate carrier with half-times of inhibition being 4 and 7 min, respectively. Sodium-independent phosphate and D-glucose uptake remained unaffected by DEPC. Intravesicular volume and two enzyme activities endogenous to the luminal membrane (alkaline phosphatase and aminopeptidase M) remained unaffected by DEPC. Increasing the preincubation pH from 5 to 9 increased phosphate transport inhibition caused by DEPC from 73 to 88% in the presence of DEPC. Hydroxylamine was able to completely reverse phosphate uptake inhibition by DEPC (100%), but only partially reversed the D-glucose uptake inhibition (16%). Sodium or substrate (D-glucose or phosphate) in the preincubation media were unable to protect their respective carriers from DEPC. Sodium-dependent transport of L-glutamine, L-phenylalanine, L-leucine, L-alanine, L-glycine, beta-alanine and L-proline were inhibited at different levels ranging from 70 to 90%. Three transport processes were found insensitive to DEPC modification: L-glutamate, L-lysine and D-fructose. None of the amino acid transporters was protected against DEPC by sodium and/or their respective substrates. Sodium influx was inhibited by DEPC (47%) in the absence of any substrate. Our results show a differential sensitivity of sodium-dependent transporters to DEPC and suggest an important role for histidine residues in the molecular mechanisms of these transporters. More experiments are in progress to further characterize the residue(s) involved in these transport inhibitions by DEPC.     

Substrate uptake,phosphorus repression,and effect of seed culture on glycopeptide antibiotic production: Process model development and experimental validation

Actinomycetes, the soil borne bacteria which exhibit filamentous growth, are known for their ability to produce a variety of secondary metabolites including antibiotics. Industrial scale production of such antibiotics is typically carried out in a multi‐substrate medium where the product formation may experience catabolite repression by one or more of the substrates. Availability of reliable process models is a key bottleneck in optimization of such processes. Here we present a structured kinetic model to describe the growth, substrate uptake and product formation for the glycopeptide antibiotic producer strain Amycolatopsis balhimycina DSM5908. The model is based on the premise that the organism is an optimal strategist and that the various metabolic pathways are regulated via key rate limiting enzymes. Further, the model accounts for substrate inhibition and catabolite repression. The model is also able to predict key phenomena such as simultaneous uptake of glucose and glycerol but with different specific uptake rates, and inhibition of glycopeptide production by high intracellular phosphate levels. The model is successfully applied to both production and seed medium with varying compositions and hence has good predictive ability over a variety of operating conditions. The model parameters are estimated via a well‐designed experimental plan. Adequacy of the proposed model was established via checking the model sensitivity to its parameters and confidence interval calculations. The model may have applications in optimizing seed transfer, medium composition, and feeding strategy for maximizing production. Biotechnol. Bioeng. 2010;105: 109–120. © 2009 Wiley Periodicals, Inc.     

Characterization of glucose uptake by Trichuris globulosa (Nematoda) in vitro

14C-glucose uptake by adult Trichuris globulosa is found to be a non-linear function of time and limiting substrate concentration. The uptake is a two component process, an initial rapid burst is followed by a lower steady state, implying a mediated process. The uptake is dependent on Na+ ions which cannot be replaced by K+, Li+ or choline. The uptake is also dependent on pH, being maximal at pH 7.4. 14C-glucose absorption is markedly inhibited by glucose, phlorizin, ouabain and to a smaller extent by a number of monosaccharides and other sugar-phosphates, nucleosides and metabolic inhibitors like p-nitrophenyl phosphate and iodoacetate. The inhibition constant for glucose, phlorizin and ouabain has been found to be 8 mM, 5 mM and 7 mM, respectively. A modified Dixon-plot shows that glucose is a completely competitive inhibitor for 14C-glucose uptake while the nature of competitive inhibition of phlorizin and ouabain are found to be partial.     

Interaction of phosphate with monovalent cation uptake in yeast

The uptake of monovalent cations by yeast via the monovalent cation uptake mechanism is inhibited by phosphate. The inhibition of Rb⁺ uptake shows saturation kinetics and the phosphate concentration at which halfmaximal inhibition is observed is equal to the K_m of phosphate for the sodiumindependent phosphate uptake mechanism. The kinetic coefficients of Rb⁺ and Tl⁺ uptake are affected by phosphate: the maximal rate of uptake is decreased and the apparent affinity constants for the translocation sites are increased.In the case of Na⁺ uptake, the inhibition by phosphate may be partly or completely compensated by stimulation of Na⁺ uptake via a sodium-phosphate cotransport mechanism.Phosphate effects a transient stimulation of the efflux of the lipophilic cation dibenzyldimenthylammonium from preloaded yeast cells and a transient inhibition of dibenzyldimethylammonium eptake. Possibly, the inhibition of monovalent cation uptake in yeast can be explained by a transient depolarization of the cell membrane by phosphate.     

The enhancement of glucose uptake caused by the collapse of gap junction communication is due to an increase in astrocyte proliferation

We have previously shown that several gap junction uncouplers increase the uptake of glucose in astrocytes. The aim of the present work was to study whether the increase in glucose uptake was a consequence of the inhibition of gap junction communication and the purpose of this effect. Our results show that alpha-glycyrrhetinic acid and endothelin-1 increase the uptake of glucose in highly, but not in poorly, coupled astrocytes. This effect depended on connexin 43 levels and was abolished when the inhibition of gap junction communication was prevented by tolbutamide or ouabain. The inhibition of gap junctions increased the rate of glucose incorporation into DNA and RNA, which was inhibited by treatment with dehydroepiandrosterone, an inhibitor of glucose-6-phosphate dehydrogenase, the regulatory enzyme of the pentose phosphate pathway. The inhibition of gap junctions significantly increased astrocyte proliferation, which was counteracted by tolbutamide. These effects were not observed in poorly coupled astrocytes expressing low levels of connexin 43. The increase in astrocyte proliferation caused by gap junction inhibition was prevented when either glucose uptake or the pentose phosphate pathway were inhibited. We conclude that the inhibition of gap junction communication induces astrocyte proliferation, resulting in an enhancement of glucose uptake and its utilization through the pentose phosphate pathway to provide ribose-5-phosphate for the synthesis of nucleic acids.     

Control of L-phenylalanine production by dual feeding of glucose and L-tyrosine

Control of L-phenylalanine production by a recombinant of Escherichia coli AT2471 by means of the dual feeding of glucose and L-tyrosine was investigated. A novel method was developed for on-line monitoring of the maximum glucose uptake rate (MGUR), in which the length of time required for the consumption of added glucose was measured. Accumulation of acetic acid was successfully prevented throughout the whole period of the culture when the glucose concentration was kept below 0.1 g/L by controlling the glucose feeding on the basis of on-line monitoring of the MGUR and the cell concentration with a laser sensor.In a batch culture with glucose feeding, after L-tyrosine was depleted cell growth and the L-phenylalanine production rate decreased along with decreases in the specific enzyme activities of chorismate mutase-p-prephenate dehydratase (CMP) and 3-deoxy-D-arabinoheputulosonate 7-phosphate synthase (DAHP), which are the key enzymes in the L-phenylalanine synthesis pathway. Increasing the L-tyrosine feed rate by an appropriate amount, but not so far as to cause L-tyrosine accumulation in the culture, increased the activities of the enzymes and the specific rates of growth and production while the product yield based on glucose consumption decreased.The average specific rates of growth, production, and MGUR could be expressed as functions of the specific L-tyrosine consumption rate during both the earlier and later periods of L-tyrosine feeding. Estimations of the amount of L-phenylalanine produced, the product yield, and the cost factor by using these functions with several different combinations of two specific L-tyrosine consumption rates for two 10-h periods resulted in a suggested optimum L-tyrosine feeding strategy giving a lower specific L-tyrosine consumption rate in the later period, to suppress cell growth, in comparison to that in the earlier period. During L-tyrosine feeding, the three specific rates (growth, production, and MGUR) could be successfully controlled by adjusting the specific L-tyrosine consumption rate to the predicted value. The cost factor was lowest in this controlled culture, demonstrating experimentally the effectiveness of the strategy. (c) 1996 John Wiley & Sons, Inc.     

Glucocorticoid action on rat thymic lymphocytes. Experiments utilizing adenosine to support cellular metabolism lead to a reassessment of catabolic hormone actions.

Inhibition of glucose uptake has been proposed as a primary cause of many of the subsequent inhibitory effects of glucocorticoids. This hypothesis has been tested in experiments where adenosine is substituted for glucose. Like glucose, adenosine maximally supports glycolytic and oxidative ATP generation, and by its use the hormonal inhibition of glucose uptake is circumvented. With adenosine, inhibition by cortisol is seen at at least one other metabolic site, respiratory ATP synthesis. This action can be observed by hormone-induced increases in levels of lactate, pyruvate, and AMP that accompany a lowering of ATP. Evidence for this metabolic action is also seen when cells are provided with a limiting amount of glucose; despite inhibition of glucose uptake, a cortisol-induced increase in lactate accompanies the reduction in levels of ATP. Decreased respiratory ATP synthesis is also suggested by a hormonal reduction in the metabolism of labeled exogenous pyruvate to 14CO2. Several experimental approaches suggest that inhibition of oxidative ATP production, rather than of glucose uptake, is the event most responsible for glucocorticoid-induced changes in the balance of adenine nucleotides, which in turn contribute to effects on protein synthesis and uridine uptake. First, the characteristic inhibitory cortisol effects on adenine nucleotides and protein synthesis are undiminished when adenosine is substituted for glucose. Second, in adenosine-supported cells the onset of the hormone-induced increase in levels of lactate corresponds closely to the appearance of measurable reductions in ATP. In contrast, when cells are supported by glucose, the hormonal inhibition of glucose uptake is maximal by 30 to 35 min, nearly an hour before effects on levels of ATP are detectable. Third, when cells are made strongly dependent upon glucose for ATP production by deprivation of exogenous substrate and cortisol is added at 90 min, a characteristic inhibition of the uptake of glucose added 40 min later is seen; nevertheless, this is insufficient to prevent added glucose from immediately and fully restoring ATP, rates of protein synthesis, and uridine uptake. Inhibitory effects on ATP, protein synthesis, and uridine do appear after an additional hour or so, a time commensurate with the development of an inhibition of oxidative metabolism. Fourth, limiting added glucose can reduce uptake more than cortisol, without reducing levels of ATP.     

Kinetics of phosphate limited algal growth

The kinetics of phosphate limited growth of two green algae Chorella pyrenoidosa and Selenastrum capricornutum have been studied in chemostats. Several kinetic models which express the specific growth rate as a function of the intracellular phosphours content have been examined, and one of the models was found to be significantly better than the other models. The principles of this model were described in a recent paper by Nyholm. The kinetics of phosphate uptake have been investigated by adding pulses of phosphate to the chemostats. The uptake by phosphours deficient cells could be described by Michaelis–Menten kinetics for phosphate concentrations below approximately 500 μg P/liter. Further, with the assumption of a discontinuous adjustment of the uptake rate at the onset of phosphours deficiency, a complete kinetic model for growth and phosphate removal is proposed. The mean cell size and the contents of chlorophyll and RNA per unit dry weight have been measured for C. pyrenoidosa as a function of the dilution rate.     

Uptake of L-leucine and L-phenylalanine across the basolateral cell surface in isolated oxyntic glands.

The time course, kinetic, specificity and sodium-dependence of L-leucine and L-phenylalanine uptake by rabbit isolated oxyntic glands were studied in order to identify the systems involved in the transport of branched-chain and aromatic neutral amino acids through the basolateral cell membrane. The uptake was measured directly in the disrupted cells after incubation of the glands with the 3H-labelled amino acid both in a sodium-containing and a sodium-free medium. The uptake of L-leucine was largely carrier-mediated whilst L-phenylalanine was taken up by either carrier-mediated and nonsaturable processes. Both amino acids were taken up by a Na(+)-independent process. The kinetic parameters of L-leucine and L-phenylalanine carrier-mediated influx were, respectively: Kt = 2.71 mM and Jmax = 1390 nmol mg-1 s-1, Kt = 1.03 mM and Jmax = 176 nmol mg-1 s-1. From cross-inhibition studies it can be inferred that L-leucine is primarily transported by a Na(+)-independent system which shows specificity for bulky side chains dipolar amino acids. The system displays similar affinities for L-phenylalanine (Ki = 2.81 mM) and L-isoleucine (Ki = 2.62 mM). Similar results were obtained from self-inhibition experiments: the Ki of the carrier-mediated uptake of L-leucine and L-phenylalanine were 2.12 and 2.40 mM (from a Hanes plot) or 3.2 and 0.8 mM (from a Dixon plot), respectively. It is concluded that a sodium-independent transport system, like Christensen's 'L' type, is shared by branched-chain and aromatic dipolar amino acids, which only shows slight differences in their affinities for the carrier.     

Glucose utilization, pH reduction and density dependent inhibition in cultures of chick embryo fibroblasts.

The multiplication rate of sparse cultures of chick embryo cells is only slightly lower at pH 6.9 than at pH 7.4. There is, however, a marked reduction in the multiplication rate of the pH 6.9 cultures before they reach confluency. Cultures at pH 7.4 continue to multiply beyond confluency with only a slight decrease in the multiplication rate. Eighty to ninety percent of the glucose taken up by the cells growing at each pH is converted to lactic acid which is released into the medium. Metabolic reduction in pH of the medium is almost entirely accounted for by the amount of lactic acid produced by the cells. Neither the intracellular nor extracellular accumulation of lactic acid nor the accompanying reduction in pH is sufficient to explain density dependent inhibition of the rate of multiplication of chick cells. The rate of lactic acid production and the multiplication rate of chick cells are independent of glucose concentration in the range of 2--16 mM. In view of the kinetic parameters for the uptake of glucose, this shows that glycolysis is not limited by the rate of glucose uptake and that depletion of glucose from the medium cannot account for the onset of density dependent inhibition of multiplication. However, when cells reach very high population densities, conventional glucose concentrations of 5 mM can be depleted overnight by chick cells. Since the multiplication rate of cells is dependent on glucose concentration when it falls below 2 mM, depletion of glucose may cause some growth inhibition in crowded cultures supplied with conventional medium.     

Insulin stimulates glucose metabolism via the pentose phosphate pathway in Drosophila Kc cells

Drosophila melanogaster has become a prominent and convenient model for analysis of insulin action. However, to date very little is known regarding the effect of insulin on glucose uptake and metabolism in Drosophila. Here we show that, in contrast to effects seen in mammals, insulin did not alter [(3)H]2-deoxyglucose uptake and in fact decreased glycogen synthesis ( approximately 30%) in embryonic Drosophila Kc cells. Insulin significantly increased ( approximately 1.5-fold) the production of (14)CO(2) from D-[1-(14)C]glucose while the production of (14)CO(2) from D-[6-(14)C]glucose was not altered. Thus, insulin-stimulated glucose oxidation did not occur via increasing Krebs cycle activity but rather by stimulating the pentose phosphate pathway. Indeed, inhibition of the oxidative pentose phosphate pathway by 6-aminonicotinamide abolished the effect of insulin on (14)CO(2) from D-[U-(14)C]glucose. A corresponding increase in lactate production but no change in incorporation of D-[U-(14)C]glucose into total lipids was observed in response to insulin. Glucose metabolism via the pentose phosphate pathway may provide an important source of 5'-phosphate for DNA synthesis and cell replication. This novel observation correlates well with the fact that control of growth and development is the major role of insulin-like peptides in Drosophila. Thus, although intracellular signaling is well conserved, the metabolic effects of insulin are dramatically different between Drosophila and mammals.