Portally delivered glucose: the ‘portal signal’

Work carried out in human subjects (DeFronzo et al. Reference DeFronzo, Ferrannini, Hendler, Wahren and Felig1978, Reference DeFronzo, Ferrannini, Hendler, Felig and Wahren1983; Basu et al. Reference Basu, Basu, Shah, Vella, Johnson, Nair, Jensen, Schwenk and Rizza2000) and dogs (Shulman et al. Reference Shulman, Liljenquist, Williams and Lacy1978; Cherrington et al. Reference Cherrington, Liljenquist, Shulman, Williams and Lacy1979; Barrett et al. Reference Barrett, Ferrannini, Gusberg, Bevilacqua and DeFronzo1985; Adkins et al. Reference Adkins, Myers, Hendrick, Stevenson, Williams and Cherrington1987; Frizzell et al. Reference Frizzell, Hendrick, Biggers, Lacy, Donahue, Green, Carr, Williams, Stevenson and Cherrington1988; McGuinness et al. Reference McGuinness, Friedman and Cherrington1990) demonstrates that neither hyperinsulinaemia nor hyperglycaemia can independently cause much net hepatic glucose uptake. Insulin levels in excess of 6000 pmol/l, when brought about under euglycaemic conditions, were associated with minimal (4 μmol/kg body weight per min) net splanchnic glucose uptake in human subjects (DeFronzo et al. Reference DeFronzo, Ferrannini, Hendler, Wahren and Felig1978) and only a modest (10 μmol/kg body weight per min) net hepatic glucose uptake in the dog (Frizzell et al. Reference Frizzell, Hendrick, Biggers, Lacy, Donahue, Green, Carr, Williams, Stevenson and Cherrington1988). Likewise, increasing the plasma glucose level 2-fold by peripheral intravenous (IV) glucose infusion in the presence of fixed basal amounts of insulin and glucagon caused only slight (3·3 μmol/kg body weight per min) net splanchnic glucose uptake in human subjects (DeFronzo et al. Reference DeFronzo, Ferrannini, Hendler, Felig and Wahren1983) and little net hepatic glucose uptake in the dog (Shulman et al. Reference Shulman, Liljenquist, Williams and Lacy1978; Adkins et al. Reference Adkins, Myers, Hendrick, Stevenson, Williams and Cherrington1987).

Net hepatic glucose uptake remains modest even when hyperinsulinaemia and hyperglycaemia (resulting from glucose infusion into a peripheral vein) are combined. In men the combination of hyperglycaemia (9·7–12·5 mm) and hyperinsulinaemia (arterial levels of 240–330 pmol/l) resulted in a net splanchnic glucose uptake of 5·6–8·9 μmol/kg body weight per min (DeFronzo et al. Reference DeFronzo, Ferrannini, Hendler, Wahren and Felig1978, Reference DeFronzo, Ferrannini, Hendler, Felig and Wahren1983; Basu et al. Reference Basu, Basu, Shah, Vella, Johnson, Nair, Jensen, Schwenk and Rizza2000). Since glucose uptake by the gut accounted for approximately half of that amount, it is clear that little glucose was taken up by the liver, despite the presence of insulin and glucose levels at least as great as those seen after oral glucose consumption. In the dog, with arterial plasma glucose levels of 8·9–16·1 mm and arterial insulin levels of 210–2304 pmol/l, net hepatic glucose uptake ranged from 5·6 to 16·1 μmol/kg body weight per min (Cherrington et al. Reference Cherrington, Williams, Abou-Mourad, Lacy, Steiner and Liljenquist1982; Ishida et al. Reference Ishida, Chap, Chou, Lewis, Hartley, Entman and Field1983; Barrett et al. Reference Barrett, Ferrannini, Gusberg, Bevilacqua and DeFronzo1985; Adkins-Marshall et al. Reference Adkins-Marshall, Myers, Hendrick, Williams, Triebwasser, Floyd and Cherrington1990) such that the magnitude of the response correlated with the load of glucose and insulin presented to the liver.

Assessment of glucose uptake by the liver after oral glucose consumption in human subjects is problematic because of the difficulty in obtaining hepatic and portal vein blood samples. It is now known that some of the assumptions (for example, the duration of absorption) in the early splanchnic balance studies of Felig et al. (Reference Felig, Wahren and Hendler1975, Reference Felig, Wahren and Hendler1978) were flawed, leading to overestimates of the role of the liver in oral glucose disposition. Studies based on more accurate assumptions have suggested that about one-quarter to one-third of an oral glucose load is extracted by the liver (Ferrannini et al. Reference Ferrannini, Bjorkman, Reichard, Pilo, Olsson, Wahren and DeFronzo1985; Kawamori et al. Reference Kawamori, Morishima, Ikeda, Kubota, Kishimoto, Shiba, Matsuhisa, Kodama and Watarai1994) with the peak rate of net hepatic glucose uptake equaling 27·8–44·4 μmol/kg body weight per min. Using ¹³C NMR, Cline et al. (Reference Cline, Rothman, Magnusson, Katz and Shulman1994) estimated the liver glycogen synthetic rate in man to be about 0·5 μmol/ml liver per min, a value consistent with the observed splanchnic glucose uptake rates noted earlier. In general, studies carried out with tracer methodology in human subjects have shown that up to 10 % of an oral glucose load is extracted by the liver on first pass, a finding consistent with the overall contribution of the liver to glucose storage (i.e. including the glucose extracted on subsequent passes) being about 25–35 % (Pehling et al. Reference Pehling, Tessari, Gerich, Haymond, Service and Rizza1984; Firth et al. Reference Firth, Bell, Marsh, Hansen and Rizza1986; Benn et al. Reference Benn, Bozzard, Kelley, Mitrakou, Aoki, Sorensen, Gerich and Sonksen1989; Radziuk, Reference Radziuk1989; Kelley et al. Reference Kelley, Mokan and Veneman1994; Mari et al. Reference Mari, Wahren, DeFronzo and Ferrannini1994).

The dog has proven a very useful model in examination of the response of the liver to glucose because catheters can be placed in the hepatic and portal veins and the role of the liver can be directly assessed. A number of investigators have quantified the fate of orally delivered glucose in this species (Abumrad et al. Reference Abumrad, Cherrington, Williams, Lacy and Rabin1982; Bergman et al. Reference Bergman, Beir and Hourigan1982; Ishida et al. Reference Ishida, Chap, Chou, Lewis, Hartley, Entman and Field1983; Barrett et al. Reference Barrett, Ferrannini, Gusberg, Bevilacqua and DeFronzo1985, Reference Barrett, Bevilacqua, DeFronzo and Ferrannini1994; Moore et al. Reference Moore, Cherrington, Cline, Pagliassotti, Jones, Neal, Badet and Shulman1991). These studies have collectively provided direct support for the conclusions drawn from studies done in human subjects. In the dog, over the absorptive period, the liver accounted for the uptake of 25–40 % of the administered glucose. Further, the peak rates of net hepatic glucose uptake were 16·6–40 μmol/kg body weight per min in the presence of elevated arterial insulin (240–558 pmol/l) and glucose (7·8–10·3 mm) concentrations, respectively. It is clear from these studies that, when the insulin level is increased 4- to 6-fold and the hepatic glucose load is increased to 2-fold basal by oral glucose consumption, net hepatic glucose uptake is approximately 30 μmol/kg body weight per min. There is thus no doubt that the liver takes up two to three times as much glucose following oral glucose ingestion as it does under similar hyperglycaemic and hyperinsulinaemic conditions in the presence of peripheral glucose infusion.

The ability of combined changes in insulin and glucose to cause greater hepatic glucose uptake when they are associated with oral glucose delivery led DeFronzo et al. (Reference DeFronzo, Ferrannini, Hendler, Wahren and Felig1978) to propose the existence of a gut factor, released in response to oral glucose intake, which could augment net hepatic glucose uptake. Since the proposition of this gut factor, a number of studies have cast doubt on its importance. Bergman et al. (Reference Bergman, Beir and Hourigan1982), Ishida et al. (Reference Ishida, Chap, Chou, Lewis, Hartley, Entman and Field1983) and Barrett et al. (Reference Barrett, Ferrannini, Gusberg, Bevilacqua and DeFronzo1985) bypassed the gut and produced hyperglycaemia via an intraportal glucose infusion that mimicked the absorption profile of oral glucose. In their studies net hepatic glucose uptake was the same after intraportal and oral glucose entry (mean rates for portal v. oral delivery: 13·9 v. 12·8, 33·3 v. 30·0, and 31·6 v. 30·0 μmol/kg body weight per min, respectively). These data ruled out a gut factor and led to the hypothesis that the liver responds differently to portal than to peripheral delivery of glucose. Thus the ‘gut factor’ was, in fact, a ‘portal factor’. The first well-controlled direct demonstration of a portal effect in vivo came from Adkins et al. (Reference Adkins, Myers, Hendrick, Stevenson, Williams and Cherrington1987) using the conscious dog. In the presence of somatostatin (used to gain control of the endocrine pancreas) insulin and glucagon were fixed at basal values and hyperglycaemia (12·2 mm) was brought about by peripheral glucose infusion. Net hepatic glucose output fell to near zero, but the liver failed to exhibit net glucose uptake. With the same glucose load, but in the presence of portal glucose delivery, there was significant net hepatic glucose uptake (7·8 μmol/kg body weight per min) such that the liver took up 32 % of the intraportally delivered glucose load. Our laboratory subsequently established that portal glucose delivery was associated with significantly greater net hepatic glucose uptake in the presence of both eu- and hyperinsulinaemia and across a wide span of physiological hepatic glucose loads (Fig. 1). Interestingly, whole-body glucose clearance did not change, suggesting not only that the liver became more efficient in its disposal of glucose but that the muscle became less efficient; later studies confirmed that glucose uptake by non-hepatic tissues declined in the presence of portal glucose delivery (Galassetti et al. Reference Galassetti, Shiota, Zinker, Wasserman and Cherrington1998, Reference Galassetti, Chu, Neal, Reed, Wasserman and Cherrington1999; Hsieh et al. Reference Hsieh, Moore, Neal and Cherrington1998, Reference Hsieh, Moore, Neal, Emshwiller and Cherrington1999). Further, using the limb balance technique in the conscious dog, it was shown that skeletal muscle was the site of this inhibition (Galassetti et al. Reference Galassetti, Shiota, Zinker, Wasserman and Cherrington1998). Thus in response to portal glucose delivery the role of the liver in glucose clearance is increased, while the role of muscle is decreased. A signal generated by portal glucose delivery (the portal glucose signal), therefore, ensures that an oral glucose load is appropriately distributed between the skeletal muscle (35–45 %), the liver (25–35 %) and the other tissues of the body (30 %) (Cherrington, Reference Cherrington1999).

Fig. 1 At any physiological plasma insulin concentration and hepatic glucose load examined, net hepatic glucose uptake is approximately 2- to 3-fold greater with portal (□) v. peripheral ( ) venous infusion of glucose. (Data compiled from Myers et al. Reference Myers, Biggers, Neal and Cherrington1991a,Reference Myers, Diamond, Adkins-Marshall, Williams, Stinsen and Cherringtonb; Pagliassotti et al. Reference Pagliassotti, Holste, Moore, Neal and Cherrington1996; Galassetti et al. Reference Galassetti, Shiota, Zinker, Wasserman and Cherrington1998; Hsieh et al. Reference Hsieh, Moore, Neal and Cherrington1998, Reference Hsieh, Moore, Neal, Emshwiller and Cherrington1999; Moore et al. Reference Moore, Flakoll, Hsieh, Pagliassotti, Neal, Monohan, Venable and Cherrington1998.)

The nature of the signal that might modulate hepatic and skeletal muscle glucose uptake simultaneously is unclear as yet, but possible candidates are neural networks and/or humoral mediators (Lautt, Reference Lautt2004; Puschel, Reference Puschel2004). Whatever the nature of the signal, the hypothalamus is likely to be involved in its integration. Afferent signals from the liver are conducted to the hypothalamus by the vagus nerve, with the afferent firing rate in the hepatic branch of the vagus being inversely proportional to the glucose concentration in the portal vein (Niijima, Reference Niijima1982). Stimulation of ventromedial hypothalamic signalling, in turn, has been shown to enhance muscle glucose uptake, an effect that can be prevented with sympathetic blockade (Minokoshi et al. Reference Minokoshi, Okano and Shimazu1994). In addition to receiving neural signals from the periphery, the hypothalamus is sensitive to circulating hormones and substrates, including insulin and glucose. In mice, intracerebroventricular infusion of insulin (with no increase in circulating insulin concentrations) significantly enhanced muscle glycogen synthesis and whole-body glucose turnover in the basal state (Perrin et al. Reference Perrin, Knauf and Burcelin2004). On one hand, intracerebroventricular glucose infusion in the basal state did not alter muscle glycogen synthesis. However, intracerebroventricular glucose infusion during a hyperinsulinaemic–euglycaemic clamp markedly reduced the insulin-stimulated muscle glycogen synthesis without changing whole-body glucose turnover. Intracerebroventricular injections of insulin and the AMP-activated kinase activator 5-aminoimidazole-4-carboxamide-1-β-d-ribofuranoside were found to increase the phosphorylation state of AMP-activated protein kinase (AMPK) 40–80 %, while glucose injection reduced phosphorylation of AMPK 50 %. When insulin and glucose were injected together, glucose completely inhibited the effect of insulin on AMPK phosphorylation. Insulin and glucose are known to enter the brain from the circulation. Evidence indicates that cerebral AMPK plays a role as an energy sensor; thus, by modulating the phosphorylation of AMPK, insulin and glucose may play a role in muscle glucose disposal (Perrin et al. Reference Perrin, Knauf and Burcelin2004).

Most studies of the portal signal have focused on the acute (i.e. postprandial) state, but evidence suggests that it also functions in the chronically adapted state. When dogs received either total parenteral nutrition (TPN) or TPN with a portion of the glucose infused enterally (TPN+enteral glucose group; total energy delivery being the same between groups) for 5 d, net hepatic glucose uptake and arterial glucose and insulin concentrations did not differ in the TPN and TPN+enteral glucose groups. Nevertheless, glucose uptake by the non-hepatic tissues was significantly reduced in the TPN+enteral glucose v. TPN groups (Chen et al. Reference Chen, Torres-Sanchez, Hosein, Zhang, Lacy, Chang and McGuinness2005).

The importance of the route of glucose delivery in man has been more difficult to evaluate because of an inability to catheterise the portal vein and the difficulty in controlling the insulin and glucagon levels reaching the liver. Early work by DeFronzo et al. (Reference DeFronzo, Ferrannini, Hendler, Wahren and Felig1978) showed that oral glucose ingestion augmented net splanchnic glucose uptake (a 6-fold increase). Nevertheless, the design of their study was such that the liver was exposed to a larger hepatic glucose load and higher insulin levels in the group receiving oral glucose. How much of the augmented hepatic response was attributable to those parameters rather than the portal glucose signal per se is not clear, but from what we now know (for example, Myers et al. Reference Myers, Biggers, Neal and Cherrington1991a,Reference Myers, McGuinness, Neal and Cherringtonc), it was probably less than half. Recent work by Vella et al. (Reference Vella, Shah, Basu, Basu, Camilleri, Schwenk and Rizza2002), in which a pancreatic clamp was used to fix the hormonal milieu during IV or intraduodenal (ID) glucose infusion, led to the conclusion that ID glucose increased hepatic glucose extraction by 50 to 100 %. This conclusion was reached despite a technical flaw (ID infusion of tracer glucose without cold glucose carrier in the IV group) which would have falsely elevated the apparent uptake of glucose by the liver in the IV group. These authors failed to detect a difference in hepatic glycogen deposition (measured using the glucuronide technique), but this is not surprising given the small rise in glucose they brought about, the size of the arterial–portal glucose gradient they used, and the fraction of extracted glucose that normally is deposited in glycogen.

Fery et al. (Reference Fery, Deviere and Balasse2001) showed that the effects of IV and ID glucose on whole-body glucose kinetics in human subjects were not different. The fact that there was no difference in whole-body glucose kinetics is consistent with findings in the dog (Galassetti et al. Reference Galassetti, Shiota, Zinker, Wasserman and Cherrington1998, Reference Galassetti, Chu, Neal, Reed, Wasserman and Cherrington1999; Hsieh et al. Reference Hsieh, Moore, Neal and Cherrington1998, Reference Hsieh, Moore, Neal, Emshwiller and Cherrington1999). As net hepatic glucose uptake is enhanced during portal glucose delivery in the dog, skeletal muscle glucose uptake decreases in a reciprocal manner, leaving whole-body glucose disposal unchanged. Even though this portion of the human findings agree with those in the dog, however, the conclusions that can be drawn from the human study are limited (Fery et al. Reference Fery, Deviere and Balasse2001). The insulin and glucose levels were not controlled, and these parameters differed markedly between the two routes of delivery. Also, the study did not identify the primary site(s) (liver v. muscle) of glucose uptake. In a more recent study (Fery et al. Reference Fery, Tappy, Deviere and Balasse2004) the same investigators used tracer methods to compare the effects of IV and ID glucose infusion on first-pass splanchnic glucose uptake under euglycaemic conditions. They concluded that their data do not support the existence of the portal signal in man, but three points should be considered. First, the study was carried out under euglycaemic conditions, which minimise the role of the liver. Second, the glucagon levels were not controlled and were higher in the ID group, which would be expected to suppress hepatic glucose uptake (Holste et al. Reference Holste, Connolly, Moore, Neal and Cherrington1997), and finally their estimate of first-pass hepatic extraction in the ID group, which was calculated as the difference between the glucose infusion rate and rate of appearance of the infused glucose, was error prone. This is underscored by the data from their IV group (i.e. a group in which no first-pass extraction occurred), which showed a greater first-pass extraction than did their ID group (2·1 v. 1·7 μmol/kg body weight per min). Clearly the majority of evidence supports the concept that a portal signal is functional in man, but well-controlled studies definitively proving the concept are still lacking.

It has been recognised for a number of years that oral glucose ingestion results in an enhanced insulin response, in comparison with the response to the same glucose load given intravenously (Nauck et al. Reference Nauck, Homberger, Siegel, Allen, Eaton, Ebert and Creutzfeldt1986). Portal glucose delivery apparently creates a similar incretin effect. When glucose was infused either peripherally or intraportally to clamp the arterial plasma glucose concentration at the same level of hyperglycaemia, plasma insulin concentrations were significantly enhanced by portal glucose delivery (Dunning et al. Reference Dunning, Moore, Ikeda, Neal, Scott and Cherrington2002). The reflex increase in vagal pancreatic efferent firing that results from intraportal glucose delivery (Niijima, Reference Niijima1983, Reference Niijima1984) probably helps to explain this phenomenon.

A role for the central nervous system in the response to portal glucose delivery is supported by the literature. In the late 1960s Russek (Reference Russek1963, Reference Russek1981) proposed that afferent signals originating in the liver might play a part in appetite control. Schmitt (Reference Schmitt1973) subsequently identified lateral hypothalamic neurons which changed their firing rate upon the injection of glucose into the portal vein. Additionally, Niijima (Reference Niijima1982, Reference Niijima1985) reported the existence of afferent fibres in the hepatic branch of the vagus nerve which exhibited a discharge rate inversely related to the glucose concentration in the portal vein. Both Schmitt and Niijima noted that the changes in neural firing were specific to glucose and established the fact that the brain receives input regarding the portal glucose level. Work by a number of investigators (for example, Lautt, Reference Lautt1983; Shimazu, Reference Shimazu1987; Stumpel & Jungermann, Reference Stumpel and Jungermann1997) has clearly established the potential of sympathetic and parasympathetic signalling to regulate liver glucose metabolism. Interestingly, Shimazu (Shimazu, Reference Shimazu1967, Reference Shimazu1971; Shimazu & Fujimoto, Reference Shimazu and Fujimoto1971) reported that electrical stimulation of the vagus nerve activated glycogen synthase and enhanced incorporation of [¹⁴C]glucose into liver glycogen in both intact and pancreatectomised rabbits. In vivo work provided further support by showing that atropine decreased net hepatic glucose uptake following oral glucose ingestion in dogs (Chap et al. Reference Chap, Ishida, Chou, Lewis, Hartley, Entman and Field1985), although hormone levels were not controlled, making it unclear whether the effect on the liver was direct or indirect. Moreover, Adkins-Marshall et al. (Reference Adkins-Marshall, Pagliassotti, Asher, Connolly, Neal, Williams, Myers, Hendrick, Adkins and Cherrington1992) demonstrated that the portal glucose signal cannot trigger increased glucose uptake in vivo in the chronically denervated liver. Intraportal infusion of acetylcholine, on the other hand, was able to augment net hepatic glucose uptake under hyperglycaemic–hyperinsulinaemic conditions in the absence of the portal glucose signal (Shiota et al. Reference Shiota, Jackson, Galassetti, Scott, Neal and Cherrington2000). In addition, Stumpel & Jungermann (Reference Stumpel and Jungermann1997) showed that atropine could block the effect of the portal glucose signal in the perfused rat liver. Unfortunately there are significant limits to conclusions that can be drawn from these studies. First, chronically denervated livers lack both sympathetic and parasympathetic input, as well as both afferent and efferent pathways, and the interval between surgery and experiment undoubtedly results in adaptive changes. Attempting to mimic parasympathetic activation by portal acetylcholine infusion stimulated net hepatic glucose uptake in the dog, but it also caused a marked increase in hepatic artery blood flow (Shiota et al. Reference Shiota, Jackson, Galassetti, Scott, Neal and Cherrington2000). This raises the possibility that the parasympathetic nervous system (or at least the classical neurotransmitter acetylcholine) is not the effector limb of the effects caused by portal glucose delivery. In another series of experiments, cooling the vagus nerves during portal glucose delivery had no impact on net hepatic glucose uptake despite the fact that the increase in heart rate confirmed that cooling had blocked vagal transmission (Cardin et al. Reference Cardin, Pagliassotti, Moore, Edgerton, Lautz, Farmer, Neal and Cherrington2004). Therefore, despite this evidence, definitive data establishing a physiological role for the parasympathetic nerves in the regulation of liver glucose uptake in vivo are still lacking. On the other hand, selective sympathectomy of the liver in the dog enhanced net hepatic glucose uptake during peripheral glucose infusion about 70 % but did not stimulate net hepatic glucose uptake during portal glucose delivery (DiCostanzo et al. Reference DiCostanzo, Dardevet, Neal, Lautz, Allen, Snead and Cherrington2006). This suggests that the basal sympathetic input to the liver is inhibitory to glucose uptake, and portal glucose delivery relieves the inhibition. Whether a stimulatory limb of the portal signal exists remains undetermined.

Using ¹³C NMR Shulman et al. (Reference Shulman, Rossetti, Rothman, Blair and Smith1987) demonstrated in the rat that the glycogen synthetic rate was 2·5 times greater following oral as opposed to IV glucose administration, even when glucose and insulin levels were equivalent. We showed that under hyperglycaemic conditions the portal glucose signal increased the percentage of glycogen synthase in the active form even in the absence of a concomitant rise in insulin. This activation was associated with a significant increase in glycogen deposition (Pagliassotti et al. Reference Pagliassotti, Holste, Moore, Neal and Cherrington1996). Whether the activation of glycogen synthase represents a direct effect of the portal signal or whether it occurred secondary to an increase in glucose-6-phosphate is unclear (Bollen et al. Reference Bollen, Keppens and Stalmans1998). It appears that about two-thirds of the glucose taken up by the liver in response to the portal signal is stored as glycogen and one-third exits in the liver as lactate (Moore et al. Reference Moore, Satake, Lautz, Soleimanpour, Neal, Smith and Cherrington2004). While the portal glucose signal increased glycogen deposition, it did not alter the percentage of net hepatic glucose uptake that was directed to glycogen. This suggests that it must affect either the movement of glucose into the hepatocyte and/or its phosphorylation once it is inside the cell. Glut2 transporters in the liver have been shown to be hormone and glucose sensitive, but the observed modifications occur slowly (Andersen et al. Reference Andersen, Ruiz and Burant1994; Weinstein et al. Reference Weinstein, O'Boyle, Fisher and Haber1994; Bollen et al. Reference Bollen, Keppens and Stalmans1998), so an effect on glucose transport is unlikely to provide an explanation for the effect of the portal signal since the latter occurs very quickly (Pagliassotti et al. Reference Pagliassotti, Holste, Moore, Neal and Cherrington1996). Studies by Liu et al. (Reference Liu, Gardner and Barrett1993), van Schaftingen (Detheux & van Schaftingen, Reference Detheux and van Schaftingen1994; van Schaftingen, Reference van Schaftingen1994) and Agius (Agius & Peak, Reference Agius and Peak1993; Agius, Reference Agius1994), on the other hand, support the possibility of rapid modification of glucokinase activity. It is now known that glucokinase is acutely regulated by binding to a regulatory protein which is sequestered in the nucleus. Glucokinase is dissociated from the regulatory protein by fructose-1-phosphate; thus the latter serves to activate the enzyme. This explains the ability of low levels of fructose to augment net hepatic glucose uptake (Shiota et al. Reference Shiota, Galassetti, Monohan, Neal and Cherrington1998). Glucose, and to a lesser extent insulin, have been shown to cause the translocation of glucokinase from the nucleus to the cytoplasm of the hepatocyte (Chu et al. Reference Chu, Fujimoto, Igawa, Grimsby, Grippo, Magnuson, Cherrington and Shiota2004). Given the similarity in the disposition of glucose taken up by the liver in response to fructose and the portal glucose signal, the question arises as to whether translocation of glucokinase represents the mechanism by which the latter augments net hepatic glucose uptake. Preliminary data indicate that this is likely to be the case (Cherrington, Reference Cherrington1999).

Towards a portal amino acid signal?

During the day, protein metabolism is modified by food intake. In adult human subjects, oral feeding is associated with an increase of whole-body protein synthesis and a decrease of proteolysis (Rennie et al. Reference Rennie, Edwards, Halliday, Matthews, Wolman and Millward1982; Pacy et al. Reference Pacy, Price, Halliday, Quevedo and Millward1994; Boirie et al. Reference Boirie, Gachon, Corny, Fauquant, Maubois and Beaufrere1996; Volpi et al. Reference Volpi, Lucidi, Cruciani, Monacchia, Reboldi, Brunetti, Bolli and De Feo1996; Arnal et al. Reference Arnal, Mosoni and Boirie2000). Since the whole-body protein mass remains constant from day to day, the gain of protein during the postprandial period is cancelled by a loss of protein in the postabsorptive state. These changes in protein metabolism are mediated by feeding-induced increases in plasma concentrations of both nutrients and hormones.

Many studies suggest that amino acids and insulin play major roles in promoting postprandial protein anabolism. In human subjects, the effect of feeding on protein metabolism is correlated with the amount of protein intake: whole-body protein synthesis is further stimulated and protein degradation is further inhibited when the protein content of the diet is increased from 0·36 to 2·77 g/kg per d (Pacy et al. Reference Pacy, Price, Halliday, Quevedo and Millward1994). On the other hand, feeding a protein-free diet does not stimulate protein synthesis despite a significant postprandial rise in plasma insulin (Volpi et al. Reference Volpi, Lucidi, Cruciani, Monacchia, Reboldi, Brunetti, Bolli and De Feo1996). These observations showed the essential role of amino acids in the postprandial increase in whole-body protein anabolism in human subjects.

In rodent skeletal muscles, a rise in plasma insulin without dietary amino acid supply does not promote protein anabolism (Yoshizawa et al. Reference Yoshizawa, Kimball and Jefferson1998), and provision of exogenous insulin to freely fed rodents does not increase protein synthesis beyond the effect of refeeding (Garlick et al. Reference Garlick, Fern and Preedy1983; Svanberg et al. Reference Svanberg, Jefferson, Lundholm and Kimball1997). In fact, recent studies have shown that suppression of a postprandial increase in insulin greatly decreases protein synthesis in adult and old rat muscles, irrespective of the nutritional condition, suggesting that amino acids and insulin interact in promoting postprandial protein anabolism (Balage et al. Reference Balage, Sinaud, Prod'homme, Dardevet, Vary, Kimball, Jefferson and Grizard2001; Prod'homme et al. Reference Prod'homme, Balage, Debras, Farges, Kimball, Jefferson and Grizard2004). Both insulin and amino acids have been shown to regulate the mammalian target of rapamycin pathway in muscle, thus regulating protein synthesis, and maximal activation is achieved only when both factors are appropriately altered (Bolster et al. Reference Bolster, Jefferson and Kimball2004). However, conversely to what is observed in adults, it seems that, in the neonate, the stimulation of muscle protein synthesis by insulin and amino acids is independent and thus stimulation by amino acids does not require insulin (Davis et al. Reference Davis, Fiorotto, Burrin, Reeds, Nguyen, Beckett, Vann and O'Connor2002; O'Connor et al. Reference O'Connor, Bush, Suryawan, Nguyen and Davis2003a,Reference O'Connor, Kimball, Suryawan, Bush, Nguyen, Jefferson and Davisb). These examples suggest that, as for whole-body protein metabolism, amino acids play a key role in the determination of the level of postprandial protein metabolism in skeletal muscle, and insulin plays a secondary role.

Although skeletal muscle is clearly an important protein synthetic site, organs of the splanchnic bed (liver and gut) account for 25 % of whole-body protein synthesis (Barle et al. Reference Barle, Nyberg, Essen, Andersson, McNurlan, Wernerman and Garlick1997). Of the protein synthesised in the liver, 40 % is secreted, with albumin alone accounting for almost half of it. Conversion of dietary amino acids to albumin is thought to provide a means of storing protein; indeed albumin can be broken down during periods of nutrient deprivation to provide essential amino acids for protein synthesis (De Feo & Lucidi, Reference De Feo and Lucidi2002). Following a mixed meal, the liver is exposed to high levels of amino acids and insulin. In adult human subjects, increasing amino acid levels by IV infusion results in an increase in protein synthesis across the splanchnic bed (Nygren & Nair, Reference Nygren and Nair2003). This effect is evident in the presence of basal insulin levels, suggesting that elevation of this hormone is not essential for an increase in splanchnic bed protein synthesis. Splanchnic metabolism includes both gut and hepatic metabolism, for which regulation pathways could be different. Indeed, studies conducted in mature animals with IV infusion of amino acids have shown that amino acids and insulin have no stimulatory effect on mixed liver protein synthesis (Mosoni et al. Reference Mosoni, Patureau Mirand, Houlier and Arnal1993; Ballmer et al. Reference Ballmer, McNurlan, Essen, Anderson and Garlick1995; Ahlman et al. Reference Ahlman, Charlton, Fu, Berg, O'Brien and Nair2001). Conversely, in the neonate, hepatic protein synthesis can be stimulated by raising amino acid levels (Yoshizawa et al. Reference Yoshizawa, Kimball and Jefferson1997). These studies raise the questions of whether or not amino acids stimulate hepatic protein synthesis and, if so, whether this effect is age-dependent.

It has been previously observed that ageing is associated with a decline in the anabolic response of skeletal muscle to food intake and amino acids (Mosoni et al. Reference Mosoni, Valluy, Serrurier, Prugnaud, Obled, Guezennec and Mirand1995; Dardevet et al. Reference Dardevet, Sornet, Balage and Grizard2000, Reference Dardevet, Sornet, Bayle, Prugnaud, Pouyet and Grizard2002). Similarly, Davis et al. (Reference Davis, Fiorotto, Burrin, Reeds, Nguyen, Beckett, Vann and O'Connor2002) have observed a developmental decline in amino acid-induced stimulation of hepatic protein synthesis in the growing animal. From these studies, one might infer that there is a decreased sensitivity of the liver to amino acids during ageing. However, this inference is inconsistent with findings in adult human volunteers, in which dietary amino acids have been shown to increase hepatic export protein synthesis, i.e. albumin (De Feo et al. Reference De Feo, Horber and Haymond1992; Hunter et al. Reference Hunter, Ballmer, Anderson, Broom, Garlick and McNurlan1995; Volpi et al. Reference Volpi, Lucidi, Cruciani, Monacchia, Reboldi, Brunetti, Bolli and De Feo1996; Cayol et al. Reference Cayol, Boirie, Rambourdin, Prugnaud, Gachon, Beaufrere and Obled1997). It is important to note that one difference between the animal and human studies cited is the route of administration of amino acids: peripherally v. orally, respectively. This difference led us to hypothesise that, in the mature organism, the route of delivery of amino acids is critical in the stimulation of hepatic protein synthesis. In support of this hypothesis, human studies have shown that albumin synthesis is stimulated with oral meal feeding whereas it is not responsive to IV nutrients (Ballmer et al. Reference Ballmer, McNurlan, Essen, Anderson and Garlick1995; Hunter et al. Reference Hunter, Ballmer, Anderson, Broom, Garlick and McNurlan1995). Moreover, it is now well established that splanchnic tissues extract, on first pass, a significant amount of dietary amino acids (Burrin & Davis, Reference Burrin and Davis2004). Of enterally administered amino acids, 20 to 96 % are utilised by the splanchnic bed, showing the crucial role of the splanchnic tissues in the distribution and availability of dietary amino acids to peripheral tissues (Ferrannini et al. Reference Ferrannini, DeFronzo, Gusberg, Tepler, Jacob, Aaron, Smith and Barrett1988; Biolo et al. Reference Biolo, Tessari, Inchiostro, Bruttomesso, Fongher, Sabadin, Fratton, Valerio and Tiengo1992; Matthews et al. Reference Matthews, Marano and Campbell1993; Burrin & Davis, Reference Burrin and Davis2004). Dietary amino acids are the preferential source of substrate for small intestine and hepatic protein synthesis (Berthold et al. Reference Berthold, Jahoor, Klein and Reeds1995; Cayol et al. Reference Cayol, Boirie, Prugnaud, Gachon, Beaufrere and Obled1996; Stoll et al. Reference Stoll, Burrin, Henry, Yu, Jahoor and Reeds1998). Enhanced splanchnic extraction of amino acids has been suspected to be responsible for the defect in the postprandial stimulation of muscle protein synthesis during ageing (Boirie et al. Reference Boirie, Gachon and Beaufrere1997; Volpi et al. Reference Volpi, Mittendorfer, Wolf and Wolfe1999). Interestingly, recent studies conducted in piglets show that the dietary requirements for lysine, methionine, leucine, valine, isoleucine, and threonine (based on the indicator amino acid oxidation technique) are lower with TPN than with enteral nutrition (Bertolo et al. Reference Bertolo, Chen, Law, Pencharz and Ball1998; House et al. Reference House, Pencharz and Ball1998; Elango et al. Reference Elango, Pencharz and Ball2002; Shoveller et al. Reference Shoveller, Brunton, Pencharz and Ball2003; Burrin & Davis, Reference Burrin and Davis2004). These data illustrate the increased demand for amino acids by the digestive tract, pancreas, and the liver in orally fed animals. Portal vein blood flow accounts for 75 % of the total hepatic blood flow, and, during the postprandial state, the amino acid concentrations are higher in portal vein blood than in hepatic artery blood (Moore et al. Reference Moore, Pagliassotti, Swift, Asher, Murrell, Neal and Cherrington1994). The enhanced utilisation of orally delivered amino acids by the liver may thus be the result of increased amino acid availability when compared with the parenteral amino acid administration.

Another possibility is that the portal (or dietary) delivery of amino acids is able to initiate a signal to the liver that increases hepatic metabolism. The results of several studies (Moore et al. Reference Moore, Flakoll, Hsieh, Pagliassotti, Neal, Monohan, Venable and Cherrington1998, Reference Moore, Hsieh, Flakoll, Neal and Cherrington1999a,Reference Moore, Hsieh, Flakoll, Neal and Cherringtonb) conducted in our laboratory are consistent with an amino acid-initiated portal signal when delivered directly into the portal vein; this signal appears to be distinct from, but to interact with, the portal glucose signal.

Not only does the route of amino acid delivery appear to impact on amino acid utilisation in the splanchnic bed, but it also appears to affect glucose disposal. We undertook a series of studies to examine the role of amino acids and their route of delivery (peripheral vein v. portal vein infusions) on net hepatic glucose uptake in the conscious dog. In the presence of a fixed hormonal milieu (4 ×  basal insulin; 1 ×  basal glucagon) and a portal glucose infusion, we found (Moore et al. Reference Moore, Flakoll, Hsieh, Pagliassotti, Neal, Monohan, Venable and Cherrington1998) that portal gluconeogenic amino acid infusion reduced net hepatic glucose uptake (Fig. 2) and net hepatic glycogen synthesis by 50 and 30 % respectively. This decrease could have originated from the hepatic amino acid load itself (i.e. competition between substrates for hepatic extraction) or it could be specific to the intraportal route of amino acid delivery by activation of a neural signal initiated by contact between hepatoportal sensors and the amino acids. To answer this question, we studied a group of dogs under identical conditions to our previous study except that the gluconeogenic amino acids were delivered peripherally at a rate that would maintain hepatic amino acid load equivalent to that evident in our previous study (Moore et al. Reference Moore, Hsieh, Flakoll, Neal and Cherrington1999a). Under these conditions, and in contrast to the portal delivery, peripheral delivery of the amino acids did not reduce net hepatic glucose uptake initiated by the portal glucose delivery. This observation is thus consistent with the hypothesis that intraportal delivery of amino acids generates a signal that competes with or modulates the signal that enhances net hepatic glucose uptake during portal glucose delivery. From these studies, it can be speculated that intraportal amino acid infusion not only modulates net hepatic glucose uptake but also modulates hepatic uptake and utilisation of the amino acids. To test this hypothesis, we initiated another protocol under the same conditions as described earlier (i.e. intraportal replacement of insulin at a 4-fold basal rate and glucagon at a basal rate, and hepatic glucose load 1·5-fold basal), except that glucose was infused peripherally to avoid any potential interaction of the amino acids with the glucose portal signal. Gluconeogenic amino acids were infused peripherally or intraportally; the infusion rates were adjusted to match the hepatic load of the amino acids between the two groups (Moore et al. Reference Moore, Hsieh, Flakoll, Neal and Cherrington1999b). The net hepatic uptake of glutamine (Fig. 3) and the net fractional extractions of glutamine and serine were significantly increased during the portal vein administration of amino acids. These observations are consistent with a portal amino acid signal independent of the portal glucose signal that is able to alter hepatic amino acid utilisation itself.

Fig. 2 Net hepatic glucose balance under basal conditions and during a pancreatic clamp with infusion of somatostatin to suppress endocrine pancreatic secretion, intraportal infusion of insulin and glucagon at 4-fold basal and basal rates, respectively, and intraportal and peripheral infusion of glucose to elevate the hepatic glucose load 1·5-fold basal. One group received an intraportal infusion of a gluconeogenic amino acids mixture (– ● –), while the other received an intraportal saline infusion without amino acids (– ○ –). Data are means, with standard errors represented by vertical bars. Differences between groups were significant (P < 0·05). (Reprinted with permission from Moore et al. Reference Moore, Flakoll, Hsieh, Pagliassotti, Neal, Monohan, Venable and Cherrington1998.)

Fig. 3 Conscious dogs were studied during a pancreatic clamp, with insulin and glucagon infused at 4-fold basal and basal rates, respectively, and the hepatic glucose load increased to 1·5-fold basal by peripheral glucose infusion. A gluconeogenic amino acid mixture was infused via the hepatic portal vein (– ● –) or a peripheral vein (– ○ –). Data are means, with standard errors represented by vertical bars. Net hepatic glutamine uptake was enhanced during portal v. peripheral infusion of gluconeogenic amino acids (P < 0·05). (Reprinted with permission from Moore et al. Reference Moore, Hsieh, Flakoll, Neal and Cherrington1999b.)

Our studies were limited to the gluconeogenic amino acids; and thus the next question was: could these observations be generalised for other amino acids? With the peripheral amino acid infusion, the net hepatic uptake of glucose and amino acids (in carbon equivalents) is very similar to the net hepatic glycogen deposition and lactate release. With the portal amino acid infusion, only 70 % of the carbon taken up by the liver could be accounted for by glycogen synthesis and lactate release. Thus, the fate of the remaining 30 % of carbon remains unknown. Nevertheless, it is very tempting to hypothesise that the portal amino acid signal also directed the amino acids into protein synthesis. Whether portal amino acids modulate the activity of the autonomic nervous system to increase hepatic protein synthesis is unknown. However, Niijima & Meguid (Reference Niijima and Meguid1994, Reference Niijima and Meguid1995) have described hepato-portal sensors for fifteen different amino acids that modulate the afferent firing rate of the hepatic branch of the vagus nerve. The involvement of neuronal input in controlling liver metabolism has already been shown with another nutrient, i.e. glucose (see pp. 161–165). Niijima & Meguid (Reference Niijima and Meguid1995) delineated amino acids (AA) serving as stimulators (AA+: alanine, arginine, histidine, leucine, lysine, serine, tryptophan, valine) and inhibitors (AA–: cysteine, glycine, isoleucine, methionine, phenylalanine, proline, threonine) of the vagal afferent discharge rate. Moreover, Watanabe et al. (Reference Watanabe, Takahashi and Shimazu1990) postulated that plasma protein synthesis is enhanced by vagal-nerve stimulation. Whether portal amino acids modulate the activity of the autonomic nervous system to increase hepatic protein synthesis is unknown and has to be further studied.

Impact of lipids on hepatic and whole-body glucose uptake and insulin sensitivity

NEFA concentrations normally fall during the postprandial period, but concentrations in individuals with type 2 diabetes remain higher than in non-diabetic controls (Reaven et al. Reference Reaven, Hollenbeck, Jeng, Wu and Chen1988; Reaven, Reference Reaven2005). Net splanchnic glucose uptake following glucose or meal ingestion is reduced in individuals with type 2 diabetes, primarily because of an increase in splanchnic glucose output, relative to that in normal volunteers (Ludvik et al. Reference Ludvik, Nolan, Roberts, Baloga, Joyce, Bell and Olefsky1997; Woerle et al. Reference Woerle, Szoke, Meyer, Dostou, Wittlin, Gosmanov, Welle and Gerich2006). There is abundant evidence that elevated circulating NEFA impair insulin-mediated suppression of endogenous glucose production (for example, Sindelar et al. Reference Sindelar, Chu, Rohlie, Neal, Swift and Cherrington1997; Boden et al. Reference Boden, Cheung, Stein, Kresge and Mozzoli2002; Homko et al. Reference Homko, Cheung and Boden2003), and thus the question arose as to the effect of elevated NEFA on postprandial hepatic glucose disposal.

We carried out a group of studies in the conscious dog to examine the effect of maintaining NEFA at their basal concentrations under conditions mimicking those in the postprandial state (Moore et al. Reference Moore, Satake, Lautz, Soleimanpour, Neal, Smith and Cherrington2004). Arterial plasma NEFA concentrations under basal conditions were about 900 μmol/l. After basal sampling, the dogs underwent a 4 h pancreatic clamp, with insulin and glucagon infused intraportally at basal rates, glucose infused intraportally to mimic postprandial absorption, and glucose infused via a peripheral vein as needed to stabilise the hepatic glucose load at 2-fold basal. Nicotinic acid (NA) was infused via a peripheral vein to suppress lipolysis. After the initial 2 h of the clamp period (period 1), the dogs were divided into three groups for an additional 2 h of study (period 2). During period 2, all infusions continued as during period 1. One group (NA group) continued exactly as in period 1; another group (NA+lipid group) received a peripheral venous infusion of 20 % lipid emulsion to increase arterial NEFA concentrations to their basal level, and the third group (NA+glycerol group) received a glycerol infusion to elevate circulating glycerol concentrations to the same levels observed in the NA+lipid group. There were no significant differences in glucose metabolism between the NA and NA+glycerol groups. However, the rate of net hepatic glucose uptake in the NA+lipid group during period 2 was <  50 % of that in the other two groups (Fig. 4). In the NA and NA+glycerol groups, endogenous glucose rate of appearance was suppressed by about 85–90 % by the end of study, while it was reduced only by about 33 % in the NA+lipid group. Moreover, intrahepatic disposition of the glucose extracted by the liver was altered by the elevation of NEFA. Hepatic glucose oxidation in the NA+lipid group was only 54 % of that in the NA group during period 2 (P < 0·05). Also, the suppression of NEFA appeared to direct glucose toward glycolysis; in the NA and NA+glycerol groups, net hepatic lactate output was maintained throughout period 2, while the NA+lipid group shifted to net hepatic uptake of lactate (Fig. 4). As a consequence of these differences in glucose oxidation and glycolysis, similar amounts of carbon were retained within the livers in all three groups, and measured glycogen synthesis was not different among groups.

Fig. 4 Net hepatic glucose balance (a), endogenous glucose rate of appearance (R_a) (b) and net hepatic lactate balance (c) under basal conditions and during a hyperinsulinaemic–hyperglycaemic clamp. During periods 1 and 2, all animals received a peripheral infusion of nicotinic acid (NA; □). During period 2, one group (NA+lipid group) also received an infusion of a long-chain lipid emulsion (■); another group (NA+glycerol) received an infusion of glycerol at the same rate as glycerol was supplied by the lipid emulsion (data not shown). Data are means, with standard errors represented by vertical bars. The NA and NA+glycerol groups did not differ significantly in any way. * Mean value was significantly different from those of the other groups (P < 0·05). (Redrawn from Moore et al. Reference Moore, Satake, Lautz, Soleimanpour, Neal, Smith and Cherrington2004.)

These findings in the acute ‘postprandial’ setting prompted us to examine the effect of chronic postprandial NEFA elevation, as seen in type 2 diabetes, on hepatic and peripheral insulin sensitivity. In this case, a lipid infusion was delivered intraportally in an effort to mimic the conditions in individuals with increased visceral adiposity. Visceral adipose tissue releases NEFA into the portal vein, and suppression of lipolysis in the visceral adipose is poorly responsive to insulin (Meek et al. Reference Meek, Nair and Jensen1999). Visceral adiposity has been implicated in the development of inflammation and steatohepatitis (for a review, see Scheen & Luyckx, Reference Scheen and Luyckx2002). In one investigation, omentectomy at the time of adjustable gastric banding was associated with improved insulin sensitivity 2 years later, compared with gastric banding alone (Thorne et al. Reference Thorne, Lonnqvist, Apelman, Hellers and Arner2002). Therefore, for 15 d, dogs received infusions of a 20 % lipid emulsion or saline into the hepatic portal circulation for 3 h in the immediate postprandial period following their single daily meal (Everett et al. Reference Everett, Rivera, Rodewald, Neal, Donahue, Williams and Cherrington2005). On the sixteenth day, after an overnight fast, the dogs underwent a two-step hyperinsulinaemic–euglycaemic clamp. After an initial period of basal sampling, somatostatin was infused via a peripheral vein, glucagon was replaced at basal rates via portal infusion, and insulin was infused intraportally at 0·6 mU/kg per min for 120 min (period 1) and then at 2·0 mU/kg per min for another 120 min (period 2). Glucose was infused via a peripheral vein as needed to maintain euglycaemia (6·1 mm) throughout periods 1 and 2. Arterial plasma insulin concentrations were similar throughout all periods in the two groups (36 (se 6), 66 (se 6), and 300 (se 36) pmol/l during the basal period and periods 1 and 2, respectively, in the saline-infused group and 48 (se 18), 60 (se 6), and 276 (se 12) pmol/l in the lipid-infused group). Net hepatic glucose output was no different in the two groups during the basal period, but the saline group shifted to net hepatic glucose uptake in period 1, while the lipid-infused group still exhibited net hepatic glucose output (Fig. 5; P < 0·05 between groups). Arterial plasma NEFA concentrations tended to be higher throughout all periods in the lipid-infused dogs, but this did not reach statistical significance (Fig. 5). As evidenced by blood glycerol concentrations, lipolysis was significantly less suppressed at both steps of the insulin infusion in the dogs that had received the lipid infusions. Thus, the chronic postprandial NEFA elevation induced insulin resistance both at the liver and in the adipose tissue.

Fig. 5 Net hepatic glucose balance (a), NEFA levels (b) and glycerol concentrations (c) in the basal state and during a two-step hyperinsulinaemic–euglycaemic clamp in dogs chronically infused with saline (□) or a lipid emulsion (■) during the postprandial period. Data are means, with standard errors represented by vertical bars. * Mean value was significantly different from that of the saline-infused controls (P < 0·05).

The findings in the dog are in general agreement with those from individuals with type 2 diabetes and normal volunteers receiving a mixed meal (Woerle et al. Reference Woerle, Szoke, Meyer, Dostou, Wittlin, Gosmanov, Welle and Gerich2006). Neither the basal nor the postprandial NEFA concentrations differed between the two groups in that investigation. However, over the first 90 min of the postprandial period, NEFA declined significantly more slowly in the diabetic group. Tracer-determined splanchnic glucose uptake did not differ between the groups, but endogenous glucose rate of appearance was suppressed significantly less in the diabetic group and therefore net splanchnic glucose uptake was impaired. As with NEFA, glycerol concentrations did not fall as rapidly in the postprandial period in the diabetic subjects, suggesting that lipolysis was not suppressed as rapidly.