HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by DeMorrow, S. Articles by Alpini, G. Search for Related Content PubMed PubMed Citation Articles by DeMorrow, S. Articles by Alpini, G.

---

MINIREVIEW

Biogenic Amine Actions on Cholangiocyte Function

Sharon DeMorrow^*,1, Heather Francis^* and Gianfranco Alpini^,,

^* Division of Research and Education, Scott & White Hospital, Temple, Texas 76508; and Research Department, Central Texas Veterans Health Care System, Department of Medicine, Systems Biology and Translational Medicine Department, College of Medicine, Texas A&M University System Health Science Center, Temple, Texas 76504

¹To whom requests for reprints should be addressed at The Division of Research and Education, Medical Research Building, Scott and White Hospital, 702 S.W. H.K. Dodgen Loop, Temple, TX 76504. E-mail: demorrow{at}medicine.tamhsc.edu

	Abstract

Top Abstract Background on Cholangiocytes General Background on Biogenic... Serotonin Histamine Dopamine Epinephrine and Norepinephrine References

 
Biogenic amines, such as serotonin, histamine, dopamine, and the catecholamines epinephrine and norepinephrine, regulate a multitude of cellular responses. A great deal of effort has been invested into understanding the effects of these molecules and their corresponding receptor systems on cholangiocyte secretion, apoptosis, and growth. This review summarizes the results of these efforts and highlights the importance of these regulatory molecules on the physiology and pathophysiology of cholangiocytes.

Key Words: histamine • serotonin • dopamine • adrenergic receptors • cell growth • bile duct epithelia

	Background on Cholangiocytes

Top Abstract Background on Cholangiocytes General Background on Biogenic... Serotonin Histamine Dopamine Epinephrine and Norepinephrine References

 
Cholangiocytes are the epithelial cells that line the intrahepatic and extrahepatic biliary tree (1). These cells are normally mitotically dormant (2), but they proliferate in response to certain pathologic stimuli, including bile duct ligation (BDL), partial hepatectomy, and bile acid feeding (1–3). The intrahepatic biliary tree is the target of several human diseases defined as cholangiopathies (1), which are characterized by chronic cholestasis leading to liver failure (1, 4). Studies have shown that such disorders are responsible for more than 20% of liver transplantations among adults and 50% of liver transplantation among pediatric patients in the United States (5). The pathophysiology of cholangiopathies commonly consists of an impaired balance between proliferation and death of cholangiocytes (1). What regulates cholangiocyte proliferation and death and how these mechanisms fail is still undefined (1, 6).

	General Background on Biogenic Amines

Top Abstract Background on Cholangiocytes General Background on Biogenic... Serotonin Histamine Dopamine Epinephrine and Norepinephrine References

 
Serotonin, norepinephrine, epinephrine, dopamine, and histamine are often collectively referred to as biogenic amines (7–9). These agents play key roles in neurotransmission and other signaling functions (7–9). They are relatively small in size and contain a protonated amino group or a permanently charged ammonium moiety. Biogenic amines can act as neurotransmitters to elicit various physiologic responses, and they all have various other sites of action throughout the body (7–9). Generally, they can be synthesized at various sites throughout the body and are released from intracellular vesicles into the surrounding tissue, where they can then bind to cell membrane–located receptors on the neighboring cells to elicit their responses (10). These molecules are capable of affecting mental functions, such as mood and appetite, and regulating blood pressure, body temperature, and other bodily processes (10).

	Serotonin

Top Abstract Background on Cholangiocytes General Background on Biogenic... Serotonin Histamine Dopamine Epinephrine and Norepinephrine References

 
General Background.
Serotonin, or 5-hydroxy-tryptamine (5-HT), is a neuromodulator with both neuro-endocrine and neurotransmitter functions that is synthesized in serotonergic neurons in the central nervous system (11) and in enterochromaffin cells throughout the gastrointestinal tract (12). It is synthesized by the systematic hydroxylation and decarboxylation of the amino acid tryptophan by the enzymes tryptophan hydroxylase and amino acid decarboxylase, respectively (11). There are 16 serotonin receptors through which serotonin exerts its multiple effects. With the exception of the 5-HT3 receptor, a ligand-gated ion channel, all other 5-HT receptors are G protein coupled, seven-transmembrane receptors that activate intracellular second messenger systems (13).

Serotonin Functions in Other Cells.
Serotonin regulates a wide variety of mood disorders, including depression, schizophrenia, and bipolar disorders (14). In addition, the local release of this hormone leads to changes in the functions of gastrointestinal epithelial cells. For example, the application of serotoninergic agents enhances fluid and ion secretion of the intestinal mucosa (15, 16), whereas the paracrine release of serotonin by enterochromaffin cells mediates the pancreatic secretion induced by intestinal lumenal factors (17, 18). In addition, serotonin modulates cell proliferation of vascular smooth muscle cells (19), kidney epithelial cells (19), and hepatocytes (20).

Serotonin and the Liver.
In the liver, inhibition of the 5-HT2 receptors by ketanserin arrested liver regeneration only when administered late (16 hrs) after partial hepatectomy, and it was suggested that through 5-HT2 receptors, serotonin may have a role in the G₁/S transition checkpoint (21). Studies have shown (21, 22) that liver regeneration after partial hepatectomy was completely dependent upon platelet-derived serotonin, as a mouse model of thrombocytopenia inhibited normal liver regeneration in a 5-HT2 receptor–dependent manner (22). In addition, key regulatory components of the serotonin system are expressed in hepatic stellate cells, which appear to be integral in the storage and release of serotonin and the subsequent response to the neuromodulator in a profibrogenic manner (23). Indeed, antagonists for particular 5-HT receptors may prove beneficial as therapy against liver fibrosis (23).

Serotonin is involved in the pathogenesis of certain clinical features of cholangiopathies, pruritus, and fatigue in particular (24, 25). In animal models of chronic cholestasis, this may be due to an enhanced release of serotonin in the central nervous system and its interactions with subtype 1 serotonin receptors (25).

Recently, we demonstrated that cholangiocytes have the capacity to synthesize and secrete serotonin, both of which are increased in proliferating rat cholangiocytes after BDL (26). We postulate that this autocrine loop is integral in limiting the growth of the biliary tree as a result of chronic cholestasis. Our hypothesis is based on the observation that chronic treatment of rats with the 5-HT 1A and 1B receptor agonists inhibited cholangiocyte proliferation in BDL rats (26). Furthermore, we demonstrated that this effect is more than likely due to a direct effect of the receptor agonists on cholangiocytes, as the treatment of cholangiocytes with serotonin had a similar inhibitory effect. By using an antiserotonin antibody to immunoneutralize the endogenous serotonin secreted from cholangiocytes as a result of BDL, we were able to enhance the growth of the biliary tree in the course of chronic cholestasis, suggesting that the autocrine secretion of serotonin does, indeed, play an important role in the control of cholangiocyte growth (26).

Certain physiologic aspects of cholangiocyte functions were also inhibited by 5HT 1A and 1B receptor agonists in proliferating cholangiocytes after BDL, but not in mitotically dormant cholangiocytes (26). Both secretin-stimulated bile and bicarbonate secretion was inhibited by chronic in vivo administration of the serotonin receptor agonists (26). In freshly isolated cultures of cholangiocytes, serotonin receptor agonists inhibited both the secretin-stimulated cAMP synthesis and protein kinase A (PKA) activity (26). This suggests that activation of both 5-HT 1A and 1B receptors can modulate not only cholangiocyte proliferation and survival but also physiologic functions of cholangiocytes as well.

We dissected the intracellular signaling pathways that may be responsible for the antiproliferative effects of serotonin and observed that the serotonergic effects on cholangiocyte proliferation were associated with enhanced IP₃ levels and increased Ca²⁺-dependent PKC activity and reduced cAMP/PKA pathway (26). Downstream of these events was a reduced activation of the Src/ERK1/2 (extracellular signal-regulated kinase 1/2) cascade, which directly effects cholangiocyte proliferation (26). A schematic representation of this pathway can be seen in Figure 1.

View larger version (53K): [in this window] [in a new window]   Figure 1. Schematic representation of the mechanism of the serotonin-induced decrease in cholangiocyte proliferation. Activation of 5-HT 1A/ 1B receptors results in an increase in IP3/Ca2+/PKC pathway, which in turn decreases the adenylyl cyclase/cAMP/PKA/ERK1/2 pathway. This ultimately leads to a decrease in cholangiocyte proliferation (This figure was adapted from Marzioni et al. (26) and reproduced with permission from the American Gastroenterological Society).

	Histamine

Top Abstract Background on Cholangiocytes General Background on Biogenic... Serotonin Histamine Dopamine Epinephrine and Norepinephrine References

Histamine Functions in Other Cells.
The major function of histamine is in the inflammation and the innate immune response (38). Most tissue histamine is found in granules in mast cells or basophils (38). Non–mast cell histamine is found in several tissues, including the brain, where it functions as a neurotransmitter (39). Another important site of histamine storage and release is the enterochromaffin-like cell of the stomach (40).

Through its receptors histamine has been shown to regulate proliferation and migration in a number of cell types, including human embryonal kidney cells (41), various cancer cell lines (42–44), gastrointestinal epithelial cells (45), and in rat oxyntic mucosa (46).

Histamine and the Liver.
Histamine modulates inflammatory processes within the liver, modulates certain aspects of the fibrogenic process, and protects against ischemia/reperfusion liver injury (47, 48). It has also been shown that plasma histamine levels are increased in chronic cholestatic liver diseases, such as primary biliary cirrhosis and sclerosing cholangitis (49), and that histamine may regulate some of the symptomatic processes associated with these diseases, such as pruritus (49). In addition, histamine, via H1R, causes the contraction of the sphincter of Oddi and the bile duct (50) and increases the rate of bile flow (51, 52).

Our studies into the effects of histamine on cholangiocyte growth and function have predominantly focused of the antiproliferative actions of H3R activation (53) and, to a lesser extent to date, the growth stimulatory effects of H1R and H2R receptor activation (54). Under normal conditions when cholangiocytes are predominantly mitotically dormant, H1R and H2R are the most prevalent subtype of histamine receptors expressed on cholangiocytes. However, in proliferating cholangiocytes as a result of BDL, the expression of H3R and H4R increases and that of H1R and H2R decreases. This differential expression of histamine receptors is consistent with the differential effects on cholangiocyte growth.

The expression of H3R is significantly increased in proliferating cholangiocytes observed after BDL (53). Activation of this receptor by chronically administering the H3R agonist (R)-()-(–)-methylhistamine dihydrobromide (RAMH) to rats for 7 days after BDL surgery resulted in a decrease in the growth of the biliary tree with no observable difference in the incidence of apoptosis, suggesting that H3R activation may slow the rate of cell cycle progression and proliferation rather than reduce the number of cholangiocytes by a cell death mechanism (53). Furthermore, administration of histamine to this animal model of cholestasis also resulted in a decrease in cholangiocyte proliferation, and blocking H3R activation by histamine using the selective H3R antagonist thioperamide maleate resulted in a partial reversal of this effect (53). Associated with the antiproliferative effects of H3R activation was the decrease in intracellular cAMP levels, which in turn decreased PKA activation and subsequent ERK 1/2 and Elk-1 activation in a manner similar to that observed with serotonin (53). A schematic representation of this can be seen in Figure 2.

View larger version (52K): [in this window] [in a new window]   Figure 2. Working model for the opposing effects of histamine receptor activation on cholangiocyte growth. Under resting conditions, H1R and H2R predominate. Activation of these two receptors results in the activation of a signal transduction cascade that results in increased cholangiocyte proliferation. However, in proliferating cholangiocytes (e.g., after BDL) the expression of H1R and H2R is decreased and the expression of H3R and H4R is predominant. Activation of these receptors leads to antiproliferative effects on cholangiocyte growth.

Taken together, our data lend themselves to the hypothesis that there is a molecular switch that toggles between the expression of the cholangiocyte growth-promoting histamine receptor (H1R and H2R) and the growth-suppressive histamine receptors (H3R and H4R) under the appropriate conditions that require the diametric effects of histamine (normal conditions and BDL, respectively). Specifically, when cholangiocytes are mitotically dormant, H1R and H2R are the predominant receptors expressed and, hence, histamine would supposedly exert a net growth-promoting effect through activation of these two receptor subtypes. When cholangiocytes are induced to proliferate (for example, in response to BDL), the expression of H3R and H4R is upregulated and, as such, histamine would exert a net growth-suppressive effect on cholangiocyte proliferation. Presumably, these events are important in limiting the biliary outgrowth that results from chronic cholestasis in a manner similar to serotonin.

	Dopamine

Top Abstract Background on Cholangiocytes General Background on Biogenic... Serotonin Histamine Dopamine Epinephrine and Norepinephrine References

 
Background.
Dopamine is synthesized mainly by nervous tissue and adrenal glands, first by the enzymatic conversion of tyrosine to DOPA (3,4-dihydroxyphenilalanine) by tyrosine hydroxylase and then by the decarboxylation of DOPA by aromatic-L-amino acid decarboxylase. As a member of the catecholamine family, dopamine is also a precursor to epinephrine and norepinephrine. The dopamine receptors are a class of metabotropic G protein–coupled receptors, and to date there are five types, D1–D5 (55). Activation of these receptors has differing effects on signal transduction pathways. For example, the D1 receptor interacts with the G_s complex to activate adenylyl cyclase, whereas the D2 interacts with G_i to inhibit cAMP production (55).

Dopamine in Other Cell Systems.
In the brain dopamine acts as a neurotransmitter, activating dopamine receptors, but it can also act as a neurohormone released by the hypothalamus and exerting various effects on the pituitary (56). Dopamine has been implicated in the etiology of Parkinson’s disease (57) and schizophrenia (58) and plays a major role in the reward system of behavior (59).

Dopamine in the Liver.
Our studies into the effects of dopaminergic innervation on cholangiocytes have focused on the D2 dopamine receptor (60). Expression of the other dopamine receptors was absent from cholangiocytes under all conditions studied (mitotically dormant and proliferating cholangiocytes), whereas the D2 dopamine receptor was expressed in normal cholangiocytes and markedly upregulated after BDL (60). In experiments similar to those described above for serotonin, the effects of D2 dopamine receptor activation on other aspects of cholangiocyte physiology have been determined (60). Infusion of quinelorane had no effect on basal bile flow and bicarbonate concentration and secretion. However, coinfusion of quinelorane with secretin resulted in a decrease in secretin-stimulated bile flow and bicarbonate secretion, an effect that could be abolished with the D2 receptor antagonist eticlopride (60). We have repeatedly demonstrated that agents that inhibit secretin-stimulated bile flow also exhibit growth-suppressive actions on cholangiocytes (26, 61–64). This further supports a tentative role for D2 dopamine receptor activation in the suppression of cholangiocyte proliferation after BDL.

The mechanism by which quinelorane inhibits secretin-induced ductal secretion and, by extension, cholangiocyte growth, is similar to that observed after serotonin receptor activation. That is, quinelorane activated the Ca²⁺-dependent PKC-, but not any other PKC isoform and, once again, blocking PKC- activity effectively inhibited the effects of D2 dopamine receptor activation on ductal secretion (60).

The cross-talk between the Ca²⁺- and cAMP-dependent signaling pathways has been shown repeatedly to be an integral signal transduction pathway in the control of cholangiocyte physiology and proliferation (65, 66). We have previously described this phenomenon for serotonin receptor activation (see above; Ref. 26) as well as for gastrin (61, 62). A similar pathway is responsible for the effects of quinelorane. D2 dopamine receptor activation by itself has no effect on intracellular cAMP levels (60). However, quinelorane treatment effectively blocks the increase in cAMP normally seen after secretin administration, which in turn blocks the cAMP-dependent activation of PKA (60).

Information regarding the ability of cholangiocytes to synthesize and secrete dopamine is lacking, so it cannot be said that these dopamine-induced effects on cholangiocytes are through an autocrine mechanism and/or are a direct result of dopaminergic innervation of the liver.

	Epinephrine and Norepinephrine

Top Abstract Background on Cholangiocytes General Background on Biogenic... Serotonin Histamine Dopamine Epinephrine and Norepinephrine References

 
General Background.
The catecholamines, epinephrine, and norepinephrine are synthesized from the hydroxylation of dopamine (norepinephrine) and subsequent methylation (epinephrine; Ref. 67). Catecholamines are synthesized predominantly in the sympathetic nervous system and activate adrenergic receptors found on the effector tissues (67, 68). Many cells possess these receptors, and binding of the agonists will usually cause the cell to respond in a "flight-or-flight" manner (69). Typical physiologic responses to epinephrine and norepinephrine include increased heart rate, mobilization of energy stores, and changes in blood flow away from other organs and towards the skeletal muscle (69). To date, there are many adrenergic receptors, which are categorized into five subclasses of receptors (₁, ₂, ß₁, ß₂, and ß₃) based on their relative affinity to various adrenergic compounds and the subsequent cellular responses given. For example, ₁ adrenergic receptors are G_q protein–coupled receptors that have a stronger affinity for norepinephrine than for either epinephrine or the synthetic catecholamine isoproterenol (a drug used to treat bronchial asthma; Ref. 70), whereas ₂ adrenergic receptors are G_i protein–coupled receptors that respond better to epinephrine than the other catecholamines (70). Finally, ß₁ adrenergic receptors have a stronger affinity for isoproterenol than either of the endogenous chatecholamines and are coupled to the G_s subtype of G protein (70).

Adrenergic Receptor Activation in the Liver.
In the liver, adrenergic nerve stimulation causes a decrease in bile flow in the isolated perfused rat liver through interactions with ₁ adrenergic receptors (71). Furthermore, in isolated perfused rat liver, adrenaline induces a complex response of bile secretion, including rapid, reversible stimulation, reversible inhibition, and prolonged stimulation via interaction with ₁ adrenergic receptors (72).

Similarly to our histamine data, it is evident that we have differential effects of specific adrenergic receptor subtypes on ductal secretion. The ₁ adrenergic receptor agonist phenylephrine had no effect on the basal rate of bile flow, bicarbonate secretion, and bicarbonate concentration in normal and BDL rats (66). However, after stimulation of choleresis by secretin, phenylephrine further increased ductal secretion of bile acids and bicarbonate (66). Interestingly, specific activation of the ß₁ adrenergic receptors by dobutamine had no effect on secretin-induced choleresis or growth (66). We then further dissected the signaling pathway responsible for the effect of phenylephrine on bile flow. First, phenylephrine administration leads to an increase in intracellular Ca²⁺ and IP₃ levels (66). Sequestration of Ca²⁺ by BAPTA-AM effectively blocked the effects of phenylephrine (66). Associated with these events was an increased activation and membrane translocation of PKC and PKCßII, which in turn effectively enhanced the effects of secretin on cAMP levels and PKA activity (Fig. 3; Ref. 66).

View larger version (54K): [in this window] [in a new window]   Figure 3. Activation of adrenic receptors gives a wide range of responses in cholangiocyte growth and secretion. Activation of 1 AR increases the Ca2+/IP3/PKC pathway. This has a positive effect on secretin-induced cAMP and PKA activation. This increases secretin-induced choleresis and cholangiocyte growth. Conversely, activation of 2 AR has a negative effect on secretin-induced cAMP and PKA activation, which decreases secretin-induced choleresis and cholangiocyte growth. Activation of the ß1 AR has no effect on cholangiocyte growth or secretion.

Conclusions and Future Directions.
Biogenic amines regulate a plethora of biologic responses. We have strived to dissect the precise effects of these important biologic molecules on cholangiocyte growth and physiology. Our efforts have highlighted the potential importance of these molecules and their receptors in the pathologic processes associated with chronic cholestatic liver diseases. Further research into the molecular events associated with the actions of the various biogenic amines on cholangiocyte proliferation is ongoing in our laboratory. Regulation of cholangiocyte growth and cell death by therapeutic agents aimed to activate or block these receptor systems may prove beneficial in the treatment of various cholangiopathies, such as primary biliary cirrhosis and sclerosing cholangitis.

	Footnotes

 
Portions of this work were supported by Grant Awards from Scott & White Hospital to S.D. and H.F., and by a VA Merit Award, a VA Research Scholar Award, and the National Institutes of Health grant DK062975 to G.A.

	References

Top Abstract Background on Cholangiocytes General Background on Biogenic... Serotonin Histamine Dopamine Epinephrine and Norepinephrine References

 

1. Alpini G, McGill JM, LaRusso NF. The pathobiology of biliary epithelia. Hepatology 35:1256–1268, 2002.[Medline]
2. LeSage G, Glaser SS, Gubba S, Robertson WE, Phinizy JL, Lasater J, Rodgers RE, Alpini G. Regrowth of the rat biliary tree after 70% partial hepatectomy is coupled to increased secretin-induced ductal secretion. Gastroenterology 111:1633–1644, 1996.[Medline]
3. Alvaro D, Mancino MG, Glaser S, Gaudio E, Marzioni M, Francis H, Alpini G. Proliferating cholangiocytes: a neuroendocrine compartment in the diseased liver: Gastroenterology 132:415–431, 2007.[Medline]
4. Desmet VJ. Vanishing bile duct disorders. Prog Liver Dis 10:89–121, 1992.[Medline]
5. Annual Report of the U.S. Organ Procurement and Transplantation Network and the Silent Registry for Transplant Recipients: transplant data 1991–2000. Rockville, MD: Department of Health and Human Services Office of Special Programs, 2001.
6. Tinmouth J, Lee M, Wanless IR, Tsui FW, Inman R, Heathcote EJ. Apoptosis of biliary epithelial cells in primary biliary cirrhosis and primary sclerosing cholangitis. Liver 22:228–234, 2002.[Medline]
7. Toninello A, Salvi M, Pietrangeli P, Mondovi B. Biogenic amines and apoptosis: minireview article. Amino Acids 26:339–343, 2004.[Medline]
8. Zeisberger E. Biogenic amines and thermoregulatory changes. Prog Brain Res 115:159–176, 1998.[Medline]
9. Singewald N, Philippu A. Involvement of biogenic amines and amino acids in the central regulation of cardiovascular homeostasis. Trends Pharmacol Sci 17:356–363, 1996.[Medline]
10. Medina MA, Urdiales JL, Rodriguez-Caso C, Ramirez FJ, Sanchez-Jimenez F. Biogenic amines and polyamines: similar biochemistry for different physiological missions and biomedical applications. Crit Rev Biochem Mol Biol 38:23–59, 2003.[Medline]
11. Diksic M, Young SN. Study of the brain serotonergic system with labeled alpha-methyl-L-tryptophan. J Neurochem 78:1185–1200, 2001.[Medline]
12. Costedio MM, Hyman N, Mawe GM. Serotonin and its role in colonic function and in gastrointestinal disorders. Dis Colon Rectum 50:376–378, 2006.
13. Kroeze WK, Kristiansen K, Roth BL. Molecular biology of serotonin receptors structure and function at the molecular level. Curr Top Med Chem 2:507–528, 2002.[Medline]
14. Young A, Goodwin GM. Studies on central nervous system serotonin receptors in mood disorders. Ann Acad Med Singapore 20:46–50, 1991.[Medline]
15. Borman RA, Burleigh DE. Heterogeneity of 5-HT receptors mediating secretion in the human intestine. Ann N Y Acad Sci 812:224–225, 1997.[Medline]
16. Franks CM, Hardcastle J, Hardcastle PT. Neural involvement in 5-hydroxytryptamine-induced net electrogenic ion secretion in the rat intestine in-vivo. J Pharm Pharmacol 48:411–416, 1996.[Medline]
17. Li Y, Hao Y, Zhu J, Owyang C. Serotonin released from intestinal enterochromaffin cells mediates luminal non-cholecystokinin-stimulated pancreatic secretion in rats. Gastroenterology 118:1197–1207, 2000.[Medline]
18. Li Y, Wu XY, Zhu JX, Owyang C. Intestinal serotonin acts as paracrine substance to mediate pancreatic secretion stimulated by luminal factors. Am J Physiol Gastrointest Liver Physiol 281:G916–G923, 2001.[Abstract/Free Full Text]
19. Azmitia EC. Modern views on an ancient chemical: serotonin effects on cell proliferation, maturation, and apoptosis. Brain Res Bull 56:413–424, 2001.[Medline]
20. Balasubramanian S, Paulose CS. Induction of DNA synthesis in primary cultures of rat hepatocytes by serotonin: possible involvement of serotonin S2 receptor. Hepatology 27:62–66, 1998.[Medline]
21. Papadimas GK, Tzirogiannis KN, Panoutsopoulos GI, Demonakou MD, Skaltsas SD, Hereti RI, Papadopoulou-Daifoti Z, Mykoniatis MG. Effect of serotonin receptor 2 blockage on liver regeneration after partial hepatectomy in the rat liver. Liver Int 26:352–361, 2006.[Medline]
22. Lesurtel M, Graf R, Aleil B, Walther DJ, Tian Y, Jochum W, Gachet C, Bader M, Clavien PA. Platelet-derived serotonin mediates liver regeneration. Science 312:104–107, 2006.[Abstract/Free Full Text]
23. Ruddell RG, Oakley F, Hussain Z, Yeung I, Bryan-Lluka LJ, Ramm GA, Mann DA. A role for serotonin (5-HT) in hepatic stellate cell function and liver fibrosis. Am J Pathol 169:861–876, 2006.[Abstract/Free Full Text]
24. Jones EA, Bergasa NV. The pathogenesis and treatment of pruritus and fatigue in patients with PBC. Eur J Gastroenterol Hepatol 11:623–631, 1999.[Medline]
25. Swain MG, Maric M. Improvement in cholestasis-associated fatigue with a serotonin receptor agonist using a novel rat model of fatigue assessment: Hepatology 25:291–294, 1997.[Medline]
26. Marzioni M, Glaser S, Francis H, Marucci L, Benedetti A, Alvaro D, Taffetani S, Ueno Y, Roskams T, Phinizy JL, Venter J, Fava G, LeSage GD, Alpini G. Autocrine/paracrine regulation of the growth of the biliary tree by the neuroendocrine hormone serotonin. Gastroenterology 128:121–137, 2005.[Medline]
27. Parsons ME, Ganellin CR. Histamine and its receptors. Br J Pharmacol147(Suppl 1):S127–S135, 2006.[Medline]
28. Hou YF, Zhou YC, Zheng XX, Wang HY, Fu YL, Fang ZM, He SH.Modulation of expression and function of Toll-like receptor 3 in A549 and H292 cells by histamine. Mol Immunol 43:1982–1992, 2006.[Medline]
29. Jancso G, Santha P, Horvath V, Pierau F. Inhibitory neurogenic modulation of histamine-induced cutaneous plasma extravasation in the pigeon. Regul Pept 95:75–80, 2000.[Medline]
30. Nguyen T, Shapiro DA, George SR, Setola V, Lee DK, Cheng R, Rauser L, Lee SP, Lynch KR, Roth BL, O’Dowd BF. Discovery of a novel member of the histamine receptor family. Mol Pharmacol 59: 427–433, 2001.[Abstract/Free Full Text]
31. Repka-Ramirez MS. New concepts of histamine receptors and actions. Curr Allergy Asthma Rep 3:227–231, 2003.[Medline]
32. Dickenson JM. Stimulation of protein kinase B and p70 S6 Kinase by the histamine H1 receptor in DDT1MF-2 smooth muscle cells. Br J Pharmacol 135:19 67–1976, 2002.
33. Mitsuhashi M, Mitsuhashi T, Payan D. Multiple signaling pathways of histamine H2 receptors (Identification of an H2 receptor-dependent Ca²⁺ mobilization pathway in human HL-60 promyelocytic leukemia cells). J Biol Chem 264:18356–18362, 1989.[Abstract/Free Full Text]
34. Lovenberg TW, Pyati J, Chang H, Wilson SJ, Erlander MG. Cloning of rat histamine H(3) receptor reveals distinct species pharmacological profiles. J Pharmacol Exp Ther 293:771–778, 2000.[Abstract/Free Full Text]
35. Lovenberg TW, Roland BL, Wilson SJ, Jiang X, Pyati J, Huvar A, Jackson MR, Erlander MG. Cloning and functional expression of the human histamine H3 receptor. Mol Pharmacol 55:1101–1107, 1999.[Abstract/Free Full Text]
36. Liu C, Ma X, Jiang X, Wilson SJ, Hofstra CL, Blevitt J, Pyati J, Li X, Chai W, Carruthers N, Lovenberg TW. Cloning and pharmacological characterization of a fourth histamine receptor (H(4)) expressed in bone marrow. Mol Pharmacol 59:420–426, 2001.[Abstract/Free Full Text]
37. Udenfriend S. Amino acid decarboxylation steps in the biosynthesis of norepinephrine, serotonin, and histamine. Vitam Horm 22:445–450, 1964.[Medline]
38. Jutel M, Blaser K, Akdis CA. Histamine in allergic inflammation and immune modulation. Int Arch Allergy Immunol 137:82–92, 2005.[Medline]
39. Brown RE, Stevens DR, Haas HL. The physiology of brain histamine. Prog Neurobiol 63:637–672, 2001.[Medline]
40. Prinz C, Zanner R, Gerhard M, Mahr S, Neumayer N, Hohne-Zell B, Gratzl M. The mechanism of histamine secretion from gastric enterochromaffin-like cells. Am J Physiol 277:C845–C855, 1999.[Medline]
41. Wang LD, Hoeltzel M, Butler K, Hare B, Todisco A, Wang M, Del Valle J. Activation of the human histamine H2 receptor is linked to cell proliferation and c-fos gene transcription. Am J Physiol 273:C2037–C2045, 1997.[Medline]
42. Rizell M, Hellstrand K, Lindner P, Naredi P. Monotherapy with histamine dihydrochloride suppresses in vivo growth of a rat sarcoma in liver and subcutis. Anticancer Res 22:1943–1948, 2002.[Medline]
43. Cricco G, Martin G, Medina V, Nunez M, Mohamad N, Croci M, Crescenti E, Bergoc R, Rivera E. Histamine inhibits cell proliferation and modulates the expression of Bcl-2 family proteins via the H2 receptor in human pancreatic cancer cells. Anticancer Res 26:4443–4450, 2006.[Medline]
44. Medina V, Cricco G, Nunez M, Martin G, Mohamad N, Correa-Fiz F, Sanchez-Jimenez F, Bergoc R, Rivera ES. Histamine-mediated signaling processes in human malignant mammary cells. Cancer Biol Ther 5: 1462–1471, 2006.[Medline]
45. Grandi D, Schunack W, Morini G. Epithelial cell proliferation is promoted by the histamine H(3) receptor agonist (R)-alpha-methylhistamine throughout the rat gastrointestinal tract. Eur J Pharmacol 538: 141–147, 2006.[Medline]
46. Morini G, Grandi D, Schunack W. Ligands for histamine H(3) receptors modulate cell proliferation and migration in rat oxyntic mucosa. Br J Pharmacol 137:237–244, 2002.[Medline]
47. Adachi N, Liu K, Motoki A, Nishibori M, Arai T. Suppression of ischemia/reperfusion liver injury by histamine H4 receptor stimulation in rats. Eur J Pharmacol 544:181–187, 2006.[Medline]
48. Hiraga N, Adachi N, Liu K, Nagaro T, Arai T. Suppression of inflammatory cell recruitment by histamine receptor stimulation in ischemic rat brains. Eur J Pharmacol 557:236–244, 2006.[Medline]
49. Gittlen SD, Schulman ES, Maddrey WC. Raised histamine concentrations in chronic cholestatic liver disease. Gut 31:96–99, 1990.[Abstract/Free Full Text]
50. Ehrenpreis S, Kimura I, Kobayashi T, Kimura M. Histamine release as the basis for morphine action on bile duct and sphincter of Oddi. Life Sci 40:1695–1698, 1987.[Medline]
51. Jones RS, Grossman MI. Choleretic effects of secretin and histamine in the dog. Am J Physiol 217:532–535, 1969.[Free Full Text]
52. Jones RS, Grossman MI. Dose-response relationships of the choleretic effect of histamine. Am J Physiol 216:335–339, 1969.[Free Full Text]
53. Francis H, Franchitto A, Ueno Y, Glaser S, DeMorrow S, Venter J, Gaudio E, Alvaro D, Fava G, Marzioni M, Vaculin B, Alpini G. H3 histamine receptor agonist inhibits cholangiocyte growth of BDL rats by downregulation of the cAMP-dependent PKA/ERK1/2 /ELK-1pathway. Lab Invest 87:473–487, 2007.[Medline]
54. Francis H, Taffetani S, Glaser S, Venter J, Phinizy JL, Reichenbach R, Fava G, Alvaro D, Marucci L, Benedetti A, Marzioni M, Alpini G. Histamine stimulates cholangiocyte proliferation through transduction pathways involving the H1 and H2 histamine receptor subtypes. Gastroenterology 126:AT925, 2004.
55. Callier S, Snapyan M, Le Crom S, Prou D, Vincent JD, Vernier P. Evolution and cell biology of dopamine receptors in vertebrates. Biol Cell 95:489–502, 2003.[Medline]
56. Enjalbert A. Multiple transduction mechanisms of dopamine, somatostatin and angiotensin II receptors in anterior pituitary cells. Horm Res 31:6–12, 1989.[Medline]
57. Carvey PM, Punati A, Newman MB. Progressive dopamine neuron loss in Parkinson’s disease: the multiple hit hypothesis: Cell Transplant 15: 239–250, 2006.[Medline]
58. Willner P. The dopamine hypothesis of schizophrenia: current status, future prospects. Int Clin Psychopharmacol 12:297–308, 1997.[Medline]
59. Bressan RA, Crippa JA. The role of dopamine in reward and pleasure behaviour–review of data from preclinical research. Acta Psychiatr Scand Suppl:14–21, 2005.
60. Glaser S, Alvaro D, Roskams T, Phinizy JL, Stoica G, Francis H, Ueno Y, Barbaro B, Marzioni M, Mauldin J, Rashid S, Mancino MG, LeSage G, Alpini G. Dopaminergic inhibition of secretin-stimulated choleresis by increased PKC-gamma expression and decrease of PKA activity. Am J Physiol Gastrointest Liver Physiol 284:G683–G694, 2003.[Abstract/Free Full Text]
61. Glaser S, Benedetti A, Marucci L, Alvaro D, Baiocchi L, Kanno N, Caligiuri A, Phinizy JL, Chowdhury U, Papa E, LeSage G, Alpini G. Gastrin inhibits cholangiocyte growth in bile duct-ligated rats by interaction with cholecystokinin-B/Gastrin receptors via D-myoinositol 1,4,5-triphosphate-, Ca(2+)-, and protein kinase C alpha-dependent mechanisms. Hepatology 32:17–25, 2000.[Medline]
62. Glaser SS, Rodgers RE, Phinizy JL, Robertson WE, Lasater J, Caligiuri A, Tretjak Z, LeSage GD, Alpini G. Gastrin inhibits secretin-induced ductal secretion by interaction with specific receptors on rat cholangiocytes. Am J Physiol 273:G1061–G1070, 1997.[Medline]
63. LeSage G, Glaser S, Alpini G. Regulation of cholangiocyte proliferation. Liver 21:73–80, 2001.[Medline]
64. Francis H, Glaser S, Ueno Y, Lesage G, Marucci L, Benedetti A, Taffetani S, Marzioni M, Alvaro D, Venter J, Reichenbach R, Fava G, Phinizy JL, Alpini G. cAMP stimulates the secretory and proliferative capacity of the rat intrahepatic biliary epithelium through changes in the PKA/Src/MEK/ERK1/2 pathway. J Hepatol 41:528–537, 2004.[Medline]
65. LeSage GD, Marucci L, Alvaro D, Glaser SS, Benedetti A, Marzioni M, Patel T, Francis H, Phinizy JL, Alpini G. Insulin inhibits secretin-induced ductal secretion by activation of PKC alpha and inhibition of PKA activity. Hepatology 36:641–651, 2002.[Medline]
66. LeSage GD, Alvaro D, Glaser S, Francis H, Marucci L, Roskams T, Phinizy JL, Marzioni M, Benedetti A, Taffetani S, Barbaro B, Fava G, Ueno Y, Alpini G. Alpha-1 adrenergic receptor agonists modulate ductal secretion of BDL rats via Ca(2+)- and PKC-dependent stimulation of cAMP. Hepatology 40:1116–1127, 2004.[Medline]
67. Flatmark T. Catecholamine biosynthesis and physiological regulation in neuroendocrine cells. Acta Physiol Scand 168:1–17, 2000.[Medline]
68. Kobayashi K. Role of catecholamine signaling in brain and nervous system functions: new insights from mouse molecular genetic study. J Investig Dermatol Symp Proc 6:115–121, 2001.[Medline]
69. Arun CP. Fight or flight, forbearance and fortitude: the spectrum of actions of the catecholamines and their cousins. Ann N Y Acad Sci 1018:137–140, 2004.[Medline]
70. Rang H, Dale M, Ritter J, Moore P. Pharmacology. New York: Elsevier Churchill Livingstone, 2003.
71. Beckh K, Arnold R. Regulation of bile secretion by sympathetic nerves in perfused rat liver. Am J Physiol 261:G775–G780, 1991.[Medline]
72. Krell H, Jaeschke H, Pfaff E. Regulation of canalicular bile formation by alpha-adrenergic action and by external ATP in the isolated perfused rat liver. Biochem Biophys Res Commun 131:139–145, 1985.[Medline]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by DeMorrow, S. Articles by Alpini, G. Search for Related Content PubMed PubMed Citation Articles by DeMorrow, S. Articles by Alpini, G.