Dopamine supersensitivity correlates with D2High states, implying many paths to psychosis

Dopamine supersensitivity correlates with D2High states, implying many paths to psychosis

1. Philip Seeman a , b,
2. David Weinshenker c,
3. Remi Quirion d,
4. Lalit K. Srivastava d,
5. Sanjeev K. Bhardwaj d,
6. David K. Grandy e,
7. Richard T. Premont f,
8. Tatyana D. Sotnikova g,
9. Patricia Boksa d,
10. Mufida El-Ghundi a,
11. Brian F. O'Dowd a,
12. Susan R. George a,
13. Melissa L. Perreault h,
14. Pekka T. Männistö i,
15. Siobhan Robinson j,
16. Richard D. Palmiter j , k, and
17. Teresa Tallerico l

+ Author Affiliations

1.
aPharmacology Department, Medical Science Building, Room 4344, and lPsychiatry Department, Medical Science Building, Room 4343, University of Toronto, 1 King's College Circle, Toronto, ON, Canada M5S 1A8; cDepartment of Human Genetics, Emory University School of Medicine, Whitehead Building, Suite 301, 615 Michael Street, Atlanta, GA 30322; dDepartment of Psychiatry, McGill University, Douglas Hospital Research Centre, 6875 LaSalle Boulevard, Verdun, Montreal, QC, Canada H4H 1R3; eDepartment of Physiology and Pharmacology, Oregon Health and Science University, Portland, OR 97239; fDepartment of Medicine (Gastroenterology), Liver Center, 329 Sands Building, Campus Box 3083, and gDepartment of Cell Biology, 487 Carl Building, Box 3287, Duke University Medical Center, Durham, NC 27710; hDepartment of Psychiatry and Behavioral Neurosciences, McMaster University, 1200 Main Street West, Health Science Centre, Room 4N82, Hamilton, ON, Canada L8N 3Z5; iPharmacology and Toxicology Department, University of Kuopio, P.O. Box 1627, Kuopio 70211, Finland; jNeurobiology and Behavior Program, Department of Psychology, University of Washington, Seattle, WA 98195; and kHoward Hughes Medical Institute, Box 357370, University of Washington, Seattle, WA 98195

1.

Contributed by Richard D. Palmiter, January 10, 2005


Next Section
Abstract

Dopamine supersensitivity occurs in schizophrenia and other psychoses, and after hippocampal lesions, antipsychotics, ethanol, amphetamine, phencyclidine, gene knockouts of Dbh (dopamine β-hydroxylase), Drd4 receptors, Gprk6 (G protein-coupled receptor kinase 6), Comt (catechol-O-methyltransferase), or Th -/-, Dbh Th/+ (tyrosine hydroxylase), and in rats born by Cesarean-section. The functional state of D2, or the high-affinity state for dopamine (D2High), was measured in these supersensitive animal brain striata. Increased levels and higher proportions (40-900%) for D2High were found in all these tissues. If many types of brain impairment cause dopamine behavioral supersensitivity and a common increase in D2High states, it suggests that there are many pathways to psychosis, any one of which can be disrupted.

* addiction
* dopamine receptors
* gene knockouts
* schizophrenia

Psychotic symptoms occur in many diseases, including schizophrenia and prolonged drug abuse. Although many chromosome regions and genes have been found associated with schizophrenia (1, 2), no single gene of major effect has yet been identified. Nevertheless, regardless of the causes of psychosis, antipsychotic drugs are mostly effective in alleviating the symptoms. The clinical antipsychotic potencies of these drugs are directly related to their affinities for the dopamine D2 receptor (3, 4), suggesting that the properties of this receptor are disturbed in psychosis. It is uncertain whether the total density of D2 receptors in schizophrenia is elevated (5, 6). The more relevant question, however, is whether the functional state of D2, or the state of high-affinity for dopamine, D2High (7), is elevated, and this has not been investigated in schizophrenia or in any of the psychoses. An elevated density of D2High would explain why up to 70% of individuals with schizophrenia are supersensitive to dopamine (8), but supersensitivity may have other bases. Therefore, it is important to determine the causes of dopamine supersensitivity (i.e., behavioral supersensitivity to dopamine-mimetics). Experimentally, dopamine supersensitivity occurs after a neonatal hippocampal lesion (9), long-term antipsychotics (10), ethanol or amphetamine (11), in gene knockouts of Dbh (dopamine β-hydroxylase) (12), Drd4 dopamine receptors (13), Gprk6 (G protein-coupled receptor kinase 6) (14), Comt (catechol-O-methyltransferase) (15, 16), or Th -/-, DbhTh/ +(tyrosine hydroxylase, dopamine-deficient) (17-19), and in rats born by Cesarean section (20). Although antipsychotics are known to elevate the density of dopamine D2 receptors by ≈25% above control levels, no such elevations occur in ethanol withdrawal (21), amphetamine-sensitized animals (22), Gprk6 or Comt knockouts (14, 15), dopamine deficient mice (18), or rats born by Cesarean-section (20).

The basis of supersensitivity to amphetamine or dopamine agonists thus remains puzzling. However, it has recently been found that, despite the absence of any elevation in total dopamine D2 receptors in the striata of amphetamine-sensitized animals, there is a dramatic 360% increase (22) in the density of D2High states (23). Therefore, we thought it important to examine whether D2High would also be invariably elevated in other conditions showing dopamine supersensitivity. We found this to be the case in studying the striata from many types of animals that are known to be dopamine supersensitive after treatment with either antipsychotics, quinpirole, ethanol, or amphetamine, after a hippocampal lesion, or after five types of gene knockouts.
Previous SectionNext Section
Materials and Methods

Antipsychotic Treatment. Adult male Sprague-Dawley rats, weighing 200-225 g at the start of the experiment, were used. For 9 days, the animals received daily i.p. injections (0.5 ml) of saline (0.9%), haloperidol (0.045 mg/kg), risperidone (0.75 mg/kg), olanzapine (0.75 mg/kg), clozapine (35 mg/kg), or quetiapine (25 mg/kg). These doses occupy 70% of brain dopamine D2 receptors in rats, a level of occupancy associated with human clinical response to antipsychotics in schizophrenia (24). The nonantipsychotic ketanserin was used as a comparison drug and given i.p. at 15 mg/kg for 9 days.

Amphetamine Sensitization. The procedure for sensitizing rats to amphetamine has been published (22).

Ethanol Treatment and Withdrawal. Ethanol was given as follows: 2 g/kg i.p. twice daily; i.e., 1.4 ml of 18% ethanol in 0.9% NaCl per 100 g at 9 a.m. and again at 3 p.m. daily to rats for 10 days.

Hippocampal Lesion. The procedure for lesioning the rat hippocampus has been described (9).

Gene Knockouts (Homozygous). Gene knockouts for the Dbh gene (12) were developed in C57BL/6J × 129/SvEv mice. Knockouts for the Drd4 receptor gene (13) and the Gprk6 gene were developed in the C57BL/6J × 129/SvJ strain of mice. Comt-deficient male C57BL/6J mice and dopamine-deficient mice were generated and genotyped as described (15-19). The dopamine-deficient mice required daily L-DOPA (50 mg/kg i.p.) for survival (yet maintaining dopamine supersensitivity), and the animals were killed 24 h after the last dose of L-DOPA. Congenic mice lacking Drd1a (backcrossed to C57BL for 11 generations) were prepared (25).

Rats Born by Cesarean Section. The procedure for obtaining rats by cesarean section with or without anoxia are given elsewhere (20).

Quinpirole or Phencyclidine Sensitization. Adult rats received 13 doses of quinpirole (0.05 mg/kg), followed by six doses (0.5 mg/kg) s.c. twice weekly. After the series of injections, the rats had an enhanced locomotor response to quinpirole (up to 1 mg/kg). Rats were sensitized to phencyclidine (Sigma; 2.5 mg/kg/day i.p. for 4 days, followed by 7 days without drug).

[3H]Ligands. [3H]Raclopride (60-80 Ci/mmol) was from PerkinElmer Life Sciences (Boston). [3H]Domperidone was custom synthesized as [phenyl-3H(N)]domperidone (42 Ci/mmol) by PerkinElmer Life Sciences, and used at a final concentration of 1.2-3 nM for competition with dopamine.

Saturation of Dopamine D2 Receptors by [3H]Raclopride (Scatchard Analysis). The frozen striata were blotted and weighed frozen. Buffer was added (50 mM Tris·HCl, pH 7.4/1 mM EDTA/5 mM KCl/1.5 mM CaCl2/4 mM MgCl2/120 mM NaCl) to yield 4 mg of tissue per ml. The method for determining the density of D2 receptors has been reported (21-23). Nonspecific binding for dopamine D2 receptors was defined as that in the presence of 10 μM S-sulpiride. The density of [3H]raclopride binding sites and the dissociation constant (K d) were obtained by Scatchard analysis.

Competition Between Dopamine and [3H]Raclopride or [3H]Domperidone. The competition between dopamine and [3H]raclopride or [3H]domperidone for binding at the dopamine D2 receptors was done as reported (23).

Statistics. The competition data were analyzed by using a program that provided two statistical criteria to judge whether a two-site fit was better than a one-site fit, or whether a three-site fit was better than a two-site fit (ref. 21 and references therein).
Previous SectionNext Section
Results

Long-Term Antipsychotic Treatment. Three methods were used to detect the D2High states in vitro. The first method was a dopamine/[3H]raclopride competition experiment in the presence of low NaCl (10 mM) (21, 22). The low NaCl was used because high-affinity states were not detected by dopamine/[3H]raclopride competition in 120 mM NaCl, as shown in Fig. 1A . A second method was to use dopamine/[3H]domperidone competition in 120 mM NaCl, because [3H]domperidone, unlike [3H]raclopride, readily detects D2High states in the presence of 120 mM NaCl (23). A third method to detect D2High states was to use [3H]raclopride saturation data, where the D2High states were defined as those made available by the presence of 200 μM guanilylimidodiphosphate (GN), as shown in Fig. 1B . In this example, the density of D2 receptors in the absence of GN was 12 pmol/g, whereas in the presence of GN, the density was 16.1 pmol/g. The extra binding sites made available by GN were presumably sites with high affinity for dopamine but occluded by endogenous dopamine and were effectively removed when the receptors were converted to their low-affinity states by GN.
Fig. 1.
View larger version:

* In this page
* In a new window

* Download as PowerPoint Slide

Fig. 1.

Detection of D2High states. (A) Dopamine recognizes high-affinity states for dopamine D2 receptors when competing with 2 nM [3H]raclopride in the presence of 10 mM NaCl, but not in the presence of 120 mM NaCl. Rat homogenized striatum is shown. Average values ± SE (n = 3) are given. Nonspecific binding in the presence of 10 μM S-sulpiride is shown. (B)[3H]Raclopride saturation method for measuring D2High states after 9 days of olanzapine treatment. Using 120 mM NaCl, saturation of striatal dopamine D2 receptors with [3H]raclopride in the presence and absence of 200μM GN is shown. The increase in binding with GN reflects the high-affinity states of the dopamine D2 receptor, D2High.(C) Using 10 mM NaCl, the dopamine/[3H]raclopride competition method also revealed an increase in the proportion of D2High states after 9 days of olanzapine (Table 1).

Also shown in Fig. 1B is the typical effect of an antipsychotic, olanzapine, on the D2High states. Rats received daily injections of haloperidol, risperidone, olanzapine, clozapine, or quetiapine, using doses known to occupy ≈70% of brain striatum dopamine D2 receptors in rats, a level of occupancy associated with human clinical response to antipsychotics in schizophrenia (24). The nonantipsychotic ketanserin was used for comparison. Fig. 1B illustrates that olanzapine elevated the density of D2High states from a control value of 1.9 ± 0.2 pmol/g to 4.1 ± 0.6 pmol/g (Table 1), representing a 2-fold elevation. Furthermore, Fig. 1C shows that dopamine recognized 28% of the [3H]raclopride-labeled sites to be in the high-affinity state, and that this increased to 77% after 9 days of olanzapine treatment, an increase of 2.7-fold.
View this table:

* In this window
* In a new window

Table 1. Dopamine supersensitivity in striatum: Increased D2High receptors

Ethanol and Amphetamine Sensitization. When both the [3H]raclopride saturation and dopamine/[3H]raclopride competition methods were used, the density of D2High states increased by 3- to 4-fold in ethanol-withdrawn rats and in amphetamine-sensitized rats (Table 1 and Fig. 2).
Fig. 2.
View larger version:

* In this page
* In a new window

* Download as PowerPoint Slide

Fig. 2.

Increase in D2High states after 9 days of antipsychotic treatment. (Left) [3H]Raclopride saturation method (additional details in Fig. 1). (Right) Dopamine/[3H]raclopride competition method. Representative experiments are shown (Table 1).

Dopamine Supersensitivity in Gene Knockout Mice. As mentioned earlier, mice with a targeted deletion of the Dbh gene, the Drd4 dopamine receptor gene, the Gprk6 gene, the Comt gene, or the Th -/-, DbhTh/ + gene, are supersensitive to amphetamine or dopamine. Correspondingly, when one or more of the three methods was used, all of these homozygous knockout mice revealed an elevated density of D2High states, ranging from 3.6-fold (over control) for the Dbh knockouts to 9.9-fold for the Drd4 knockouts (Figs. 3 and 4 and Table 1).
Fig. 3.
View larger version:

* In this page
* In a new window

* Download as PowerPoint Slide

Fig. 3.

Increase in D2High states in gene knockouts for the Drd4 dopamine receptor, Dbh, and Gprk6.(Left)[3H]Raclopride saturation method (see Fig. 1). (Center) Dopamine/[3H]raclopride competition method. (Right) Dopamine/[3H]domperidone competition method. Representative experiments are shown, bars indicate SE (Table 1).
Fig. 4.
View larger version:

* In this page
* In a new window

* Download as PowerPoint Slide

Fig. 4.

Increased D2High states in knockouts and lesions. (A) Increase in D2High states in gene knockouts for Comt, using the dopamine/[3H]domperidone competition method (n = 4 ± SE; Table 1). (B) Increase in D2High states in striata from adult animals that had been lesioned in the hippocampus at an early age. [3H]Raclopride saturation method; control value was 2 pmol/g (see Table 1). (C) Dopamine/[3H]raclopride competition method. (D) Dopamine/[3H]domperidone competition method. Bars indicate SE (n = 3; Table 1).

Neonatal Hippocampal Lesion. When all three methods were used, the density of D2High states increased by 2- to 4-fold in rats that had been lesioned in the hippocampus neonatally (Fig. 4 B-D ).

Rats Born by Cesarean Section. Rats born by cesarean section with or without anoxia become supersensitive to amphetamine as adults (20). Here, too, the D2High states were elevated by 5- to 5.6-fold by using the [3H]raclopride saturation method, 2.7-fold by using the dopamine/[3H]raclopride competition method, and 2.3- to 2.7-fold by using the dopamine/[3H]domperidone competition method (Fig. 5 and Table 1), all compared to striata from rats born normally by vaginal birth.
Fig. 5.
View larger version:

* In this page
* In a new window

* Download as PowerPoint Slide

Fig. 5.

Increase in D2High states in adult rats born by cesarean section with or without anoxia. (Left) [3H]Raclopride saturation method. (Center) Dopamine/[3H]raclopride competition method. (Right) Dopamine/[3H]domperidone competition method. Representative experiments are shown; vertical bars indicate SE (Table 1).

Drd1a Receptor Knockout as Control. It was essential to determine whether dopamine D2High states were elevated in other gene-knockout animals that did not exhibit amphetamine supersensitivity. Therefore, we chose the Drd1a dopamine receptor-knockout mouse (25) because this animal is not supersensitive to amphetamine (26). The data (Table 1), using the dopamine/[3H]domperidone competition method, illustrate that the density and proportions of D2High states were normal in the Drd1a receptor-knockout mice.

Rats Sensitized to Quinpirole or Phencyclidine. Behavioral sensitization and dopamine supersensitivity also occurs in rats sensitized with the dopamine D2 agonist quinpirole (27). When the [3H]domperidone method was used, quinpirole increased the proportion of D2High states in striatal tissue from 13.6 ± 3.6% (control) to 21.8 ± 3.2%, an increase of 1.6-fold (Table 1). In addition, because Heusner et al. (28) found that the amphetamine-induced locomotor response in dopamine-deficient mice was fully restored by restoring dopamine selectively in the nucleus accumbens, we also examined whether quinpirole sensitization altered the D2High states in the nucleus accumbens. In fact, quinpirole increased the proportion of D2High states in this brain region from 19 ± 3% (control) to 28 ± 3%, an increase of 1.5-fold (Table 1). The increase was 2.8-fold for phencyclidine-sensitized rats.
Previous SectionNext Section
Discussion

Several previous studies have examined whether the proportion of high-affinity states for D2 were elevated after antipsychotics (29) or in Gprk6 knockouts (14), with little if any significant change. This is because most laboratories have been using a dopamine/[3H]spiperone competition method. However, as shown elsewhere (23), dopamine (with its K d of 1.75 nM) is not effective in competing versus the much more tightly bound [3H]spiperone (with its K d of 60 pM), especially in 120 mM NaCl.

It is not known whether the saturation method and the two competition methods reveal the same population of D2High states. It is likely that the saturation method reveals D2High states that are normally occluded or occupied by endogenous dopamine. However, the competition method may reveal D2High states that are either occupied or not occupied by dopamine. Further work will be needed to examine this.

It is surprising that these diverse impairments of the brain (drugs, lesions, gene knockouts, cesarean sections) all resulted in a common D2High basis for dopamine supersensitivity, especially surprising in cases where no direct interference with dopamine transmission was made. It is possible that this shift to more D2High states is a nonspecific reaction to brain impairment, making the animal more responsive to a change in its environment. However, the Drd1a knockout data (with reduced sensitivity to amphetamine and normal proportions of D2High states) indicate that the knockout process does not elicit a nonspecific increase in sensitivity to amphetamine or in D2High states.

Although the sensitization procedures were also associated with small increases in the total population of D2 receptors, these increases were especially small compared to the elevations found in the D2High states. For example, compared to controls (in the presence of guanilylimidodiphosphate), the total D2 density went up by 10% in Gprk6 knockouts, 23% in Drd4 knockouts, and 34% in Dbh knockouts, in contrast to the elevations of 3.2- to 9.9-fold in the D2High component. In the case of the cesarean section rats, previous work (20) did not reveal a significant rise in the total D2 population, a situation similar to that found in ethanol withdrawal or after amphetamine sensitization (21, 22).

All of the animals in this study are known to be supersensitive to amphetamine or dopamine agonists with the exception of the Drd1a knockout mice (26), which revealed a normal proportion of D2High states. The present data suggest that the sensitivity to amphetamine may be related to the magnitude of the D2High states. However, the converse may not hold. That is, although the present data support the principle that dopamine supersensitivity is associated with more D2High states, it is possible that other types of treatment may alter the number of D2High states but not alter the sensitivity to dopamine.

Additional animal models will be useful in determining whether the significant shift in the numbers of D2 receptors in a low-affinity state to a high-affinity state is consistently associated with dopamine supersensitivity and/or alteration in the reward state. If this relation persists, it would warrant molecular and brain imaging studies exploring the basis of dopamine supersensitivity in psychosis, Parkinson's disease, and hyperactivity disorders. Biochemically, a variety of molecular mechanisms may underlie receptor supersensitivity, including oligomerization, and altered interactions between G protein subunits, GDP, adenylyl cyclases, guanine nucleotide exchange factors, RGS proteins, GRKs, and arrestins, and phosphorylation status of any of these proteins. Finally, the present results imply that there may be many pathways leading to psychosis, including multiple gene mutations, drug abuse, or brain injury, all of which may converge via D2High to elicit psychotic symptoms (8).
Previous SectionNext Section
Acknowledgments

We thank Drs. R. J. Lefkowitz and Marc Caron for assistance in providing the GRK6/del tissues, and Dr. H.-C. Guan, Katherine L. Suchland, Paul J. Kruzich, and Audrey Younkin for outstanding technical support. This work was supported by the Ontario Mental Health Foundation (Regular grant and Special Initiatives grant), the National Alliance for Research on Schizophrenia and Depression, the Canadian Instititutes of Health Research (P.S., R.Q., L.K.S., and P.B.), the National Institute on Drug Abuse (P.S., S.R.G., B.F.O., and M.E.-G.), the Canadian Psychiatric Research Foundation, the Medland and O'Rorke families, the Dr. Karolina Jus estate, National Institute of Mental Health Grants MH67497 and DA12062 (to D.K.G.), The National Agency of Technology (TEKES, Grant 40160/99, to P.T.M.), and Academy of Finland Grant 73012 (to P.T.M.), and in part by the Institutional Grant for Neurobiology Grant GM07108-29 (to S.R.).
Previous SectionNext Section
Footnotes

*

↵ b To whom correspondence should be addressed. E-mail: philip.seeman@utoronto.ca.
*

Author contributions: P.S., M.L.P., and T.T. designed research; P.S., D.W., R.Q., L.K.S., S.K.B., D.K.G., R.T.P., T.D.S., P.B., M.E.-G., M.L.P., P.T.M., S.R., and R.D.P. performed research; P.S. and T.T. analyzed data; P.S. wrote the paper; D.W., D.K.G., R.T.P., T.D.S., M.E.-G., B.F.O., S.R.G., P.T.M., and S.R. provided gene knockout tissues; R.Q., L.K.S., and S.K.B. provided lesioned tissues; P.B. provided Cesarean-born animal tissues; M.L.P. provided drug-sensitized animal tissues; and R.D.P. provided consultations, revisions, and gene knockout tissues.
*

Abbreviation: GN, guanilylimidodiphosphate.
*

Freely available online through the PNAS open access option.
* Copyright © 2005, The National Academy of Sciences

Previous Section

References

1. ↵
Lewis, C. M., Levinson, D. F., Wise, L. H., DeLisi, L. E., Straub, R. E., Hovatta, I., Williams, N. M., Schwab, S. G., Pulver, A. E., Faraone, S. V., et al. (2003) Am. J. Hum. Genet. 73 , 34-48. pmid:12802786
CrossRefMedlineWeb of Science
2. ↵
Glatt, S. J., Faraone, S. V. & Tsuang, M. T. (2003) Mol. Psychiatry 8 , 911-915. pmid:14593428
CrossRefMedlineWeb of Science
3. ↵
Seeman, P., Chau-Wong, M., Tedesco, J. & Wong, K. (1975) Proc. Natl. Acad. Sci USA 72 , 4376-4380. pmid:1060115
Abstract/FREE Full Text
4. ↵
Seeman, P. (2002) Can. J. Psychiatry 47 , 27-38. pmid:11873706
MedlineWeb of Science
5. ↵
Nordstrom, A. L., Farde, L., Eriksson, L. & Halldin, C. (1995) Psychiatry Res. 61 , 67-83. pmid:7480390
MedlineWeb of Science
6. ↵
Abi-Dargham, A., Rodenhiser, J., Printz, D., Zea-Ponce, Y., Gil, R., Kegeles, L. S., Weiss, R., Cooper, T. B., Mann, J. J., Van Heertum, R. L., et al. (2000) Proc. Nat. Acad. Sci USA 72 , 7673-7675.
7. ↵
George, S. R., Watanabe, M., DiPaolo, T., Falardeau, P., Labrie, F. & Seeman, P. (1985) Endocrinology 117 , 690-697. pmid:4017954
Abstract/FREE Full Text
8. ↵
Curran, C., Byrappa, N. & McBride, A. (2004) Br. J. Psychiatry 185 , 196-204. pmid:15339823
Abstract/FREE Full Text
9. ↵
Bhardwaj, S. K., Beaudry, G., Quirion, R., Levesque, D. & Srivastava, L. K. (2003) Neuroscience 122 , 669-676. pmid:14622910
CrossRefMedlineWeb of Science
10. ↵
Seeger, T. F., Thal, L. & Gardner, E. L. (1982) Psychopharmacology 76 , 182-187. pmid:6805029
CrossRefMedline
11. ↵
Robinson, T. E. & Berridge, K. C. (2000) Addiction 95 , Suppl. 2, S91-S117. pmid:11002906
12. ↵
Weinshenker, D., Miller, N. S., Blizinsky, K., Laughlin, M. L. & Palmiter, R. D. (2002) Proc. Nat. Acad. Sci. USA 99 , 13873-13877. pmid:12370425
Abstract/FREE Full Text
13. ↵
Rubinstein, M., Phillips, T. J., Bunzow, J. R., Falzone, T. L., Dziewczapolski, G., Zhang, G., Fang, Y., Larson, J. L., McDougall, J. A., Chester, J. A., et al. (1997) Cell 90 , 991-1001. pmid:9323127
CrossRefMedlineWeb of Science
14. ↵
Gainetdinov, R. R., Bohn, L. M., Sotnikova, T. D., Cyr, M., Laakso, A., Macrae, A. D., Torres, G. E., Kim, K. M., Lefkowitz, R. J., Caron, M. G., et al. (2003) Neuron 38 , 291-303. pmid:12718862
CrossRefMedlineWeb of Science
15. ↵
Huotari, M., Garcia-Horsman, J. A., Karayiorgou, M., Gogos, J. A. & Männistö, P. T. (2004) Psychopharmacology 172 , 1-10. pmid:14574438
Medline
16. ↵
Gogos, J. A., Morgan, M., Luine, V., Santha, M., Ogawa, S., Pfaff, D. & Karaiorgou, M. (1998) Proc. Natl. Acad. Sci. USA 95 , 9991-9996. pmid:9707588
Abstract/FREE Full Text
17. ↵
Zhou, Q. Y. & Palmiter, R. D. (1995) Cell 83 , 1197-1209. pmid:8548806
CrossRefMedlineWeb of Science
18. ↵
Kim, D. S., Szczypka, M. S. & Palmiter, R. D. (2000) J. Neurosci. 20 , 4405-4413. pmid:10844009
Abstract/FREE Full Text
19. ↵
Robinson, S., Smith, D. M., Mizumori, S. J. Y. & Palmiter, R. D. (2004) Proc. Natl. Acad. Sci. USA 101 , 13329-13334. pmid:15317940
Abstract/FREE Full Text
20. ↵
Boksa, P., Zhang, Y. & Bestawros, A. (2002) Exp. Neurol. 175 , 388-397. pmid:12061868
CrossRefMedlineWeb of Science
21. ↵
Seeman, P., Tallerico, T. & Ko, F. (2004) Synapse 52 , 77-83. pmid:15034913
Medline
22. ↵
Seeman, P., Tallerico, T., Ko, F., Tenn, C. & Kapur, S. (2002) Synapse 46 , 235-239. pmid:12373738
CrossRefMedlineWeb of Science
23. ↵
Seeman, P., Tallerico, T. & Ko, F. (2003) Synapse 49 , 209-215. pmid:12827639
CrossRefMedlineWeb of Science
24. ↵
Kapur, S., Vanderspek, S. C., Brownlee, B. A. & Nobrega, J. N. (2003) J. Pharmacol. Exp. Ther. 305 , 625-631. pmid:12606608
Abstract/FREE Full Text
25. ↵
El-Ghundi, M., O'Dowd, B. F. & George, S. R. (2001) Brain Res. 892 , 86-93. pmid:11172752
CrossRefMedlineWeb of Science
26. ↵
Crawford, C A., J. Drago, J., Watson, J. B. & Levine, M. S. (1997) NeuroReport 8 , 2523-2527. pmid:9261820
MedlineWeb of Science
27. ↵
Szechtman, H., Eckert, M. J., Tse, W. S., Boersma, J. T., Bonura, C. A., McClelland, J. Z., Culver, K. E. & Eilam, D. (2001) BMC Neurosci. 2 , 4. pmid:11316464
CrossRefMedline
28. ↵
Heusner, C. L., Hnasko, T. S., Szczypka, M. S., Liu, Y., During, M. J. & Palmiter, R. D. (2003) Brain Res. 980 , 266-274. pmid:12867267
CrossRefMedlineWeb of Science
29. ↵
MacKenzie, R. G. & Zigmond, M. J. (1984) J. Neurochem. 43 , 1310-1318. pmid:6208330
Medline