FR2733514A1 - NON-HUMAN TRANSGENIC ANIMAL IN WHICH D2 RECEPTOR EXPRESSION IS MODIFIED - Google Patents

Abstract

The use of a non human transgenic mammalian animal in which the expression of the gene coding for the dopamine D2 receptor has been modified in relation to the normal expression, particularly on the lactotropic cells of the pituitary gland, for screening for a drug active against pituitary gland diseases involving the dopamine D2 receptor is described.

Description

NON-HUMAN TRANSGENIC ANIMAL IN WHICH
THE D2 RECEPTOR EXPRESSION IS MODIFIED.

 The subject of the invention is a transgenic or human animal in which the expression of the gene coding for the D2 receptor is modified.

 Dopamine is a neurotransmitter that regulates many physiological functions. In the central nervous system, dopamine is involved in the coordination of movement, visual perception, knowledge, emotion and in neuroendocrine control of the pituitary gland (pituitary gland). Dopamine activation of membrane receptors generates the formation of intracellular secondary messengers. Dopamine receptors belong to the family of receptors with seven transmembrane domains coupled to G proteins of the 7TM domain (J. A. Gingrich and M. G. Caron, Annu. Rev. Neurosci., 16: 299 (1993)). Pharmacological and biochemical studies have described the existence of two classes of dopaminergic receptors D1 and D2. The D1 receptor has been identified as an activator of adenylate cyclase (AC), unlike D2 which is described as an inhibitor of the same cellular effector . These two types of receptors differ in their pharmacological affinity for classical dopamine receptor antagonists such as SCH23390 for D1 and spiperone for D2.

Molecular cloning of the D2 receptor cDNA (JR Bunzow et al.,
Nature, 336: 783 (1988)) allowed screening under non-stringent hybridization conditions of cDNA and genomic libraries with the isolation of 4 additional dopaminergic receptors. Two of them, D3 (P. Sokoloff et al., Nature, 347: 146 (1990)) and D4 (HHM Van
Tol et al., Nature, 350: 610 (1991)) show characteristics similar to the D2 receptor, that is to say a picomolar to nanomolar affinity for spiperone. The other two, called D1 (A. Dearry et al., Nature, 347: 72 (1990)) and D5 (DK Grandy et al., Proc. Natl. Acad. Sci. USA, 88: 9175 (1991)) present pharmacological characteristics typical of the classically described D1 receptors. The cDNAs of the cloned receptors were expressed in cell lines and their pharmacological profile was defined as well as their properties to transduce the signal inside the cell.

As expected, the D1 and D5 receptors are stimulators of adenylate cyclase. The D5 receptor has a higher affinity for dopamine than D1. The pattern is less clear for the group of D2 type receptors. At present, the mechanism by which the D3 and D4 receptors transduce the signal, remains unclear, although they have a pharmacological profile close to D2. A role for D3 as an autoreceptor has been proposed on the basis of a higher affinity for dopamine, in comparison with D2 (JA Gingrich and
MG Caron, Annu. Rev. Neurosci., 16: 299 (1993)). The D4 receptor has a higher affinity (about ten times) than D2 and D3 for clozapine, an antipsychotic, at concentrations that are active in vivo, and it has been proposed as a target for this drug. of a transduction pathway for these receptors could be due to the lack of proteins
G specific in the cell lines tested.

 The entire dopamine receptor subfamily is widely expressed in the central nervous system, particularly in the caudateputamen, nucleus accumbens, hypothalamus, and olfactory tubers.

The pharmacological characteristics common between the D1 and D2 groups of dopaminergic receptors are also reflected at the amino acid level where a homology of more than 40% is observed on the total sequence between the members of each group.

 The first isolated D2 receptor cDNA codes for a protein of 415 amino acids and was isolated from a rat brain cDNA library (J. R. Bunzow et al., Nature, 336: 783 (1988)). The pharmacological profile obtained from transfected cells clearly identifies it as a dopamine D2 receptor. Shortly thereafter, another cDNA was isolated from different sources which is 100% homologous to the first, except for insertion of 29 amino acids into the third intracellular domain of the receptor. This cDNA codes for a protein of 444 amino acids, which has been found in rats, mice, cattle, and humans (human cDNA has 445 amino acids). (J. A. Gingrich and M. G. Caron, Annu. Rev.

Neurosci., 16: 299 (1993); J.-P. Montmayeur et al., Febs lett., 278: 239 (1991)). Genomic DNA analyzes have shown that the two cDNAs are products of the same gene generated by an alternative splicing mechanism that adds an 87 base pair exon to the larger of the messenger RNAs. These receptors have been designated by D2S for the shortest form, and by D2L for the longest form.

 The structure of the genomic fragment containing the D2 gene has been determined. Eight exons were found in all the species analyzed, with a surprising characteristic represented by the presence of a very large intron located upstream of the first coding exon. The presence of such a large intronic sequence corresponds to a mechanism for controlling the expression of the D2 gene. Cloning of the promoter region of the D2 gene has been reported; since no characteristic trait has been described, it seems to correspond to the characteristics of a ubiquitous promoter. Interestingly, the two isoforms of the D2 receptor are coexpressed in all the tissues tested with a ratio which normally promote the expression of D2L. (J.-P.

Montmayeur et al., Febs lett., 278: 239 (1991)). With regard to pharmacology, these two isoforms have similar profiles and bind to the spiperone antagonist with similar affinity. The activation of these two D2 receptors mainly results in the inhibition of adenylate cyclase.

However, it appears that they are also capable of activating other signal transduction pathways. (J. A. Gingrich and M. G. Caron, Annu. Rev.

Neurosci., 16: 299 (1993)). These observations, as well as the fact that the two receptors differ only from insertion into the third intracellular loop, suggest that the two receptors may differ in their ability to couple to one or more G proteins.

 One aspect of the invention is to provide non-human transgenic mammalian animals capable of overexpressing one and / or the other isoform of the D2 receptor.

 One of the other aspects of the invention is to provide non-human transgenic mammalian animals in which either the D2L isoform is no longer expressed, or the two isoforms D2L and D2S are no longer expressed.

 One of the other aspects of the invention is to provide an animal model capable of screening drugs which are active on pathologies involving the D2 receptors.

 The subject of the invention is the use of a non-human transgenic mammalian animal whose expression of the gene coding for the dopaminergic receptor D2 is modified, in particular on the lactotropic cells of the pituitary gland, compared to a normal expression, on the pituitary gland lactotropic cells, for the determination of a drug active on pathologies involving the D2 receptor.

 The term "mammal" includes all mammals except humans, advantageously rodents and in particular mice.

The normal expression of the dopamine D2 receptor can be defined by several methods:
1) Determination of the mRNA corresponding to the D2 gene: this is possible by the RNA transfer technique (Northern blot) in which the
MRNAs are separated on denaturing agarose gel by electrophoresis, then the
RNA are transferred and fixed on a nitrocellulose or nylon type membrane. To reveal the presence of the RNAs corresponding to the D2 gene, a probe is used which corresponds to all of the gene's cDNA. (D2L or D2S cDNA can be used interchangeably).

2) Determination of the quantity of protein corresponding to the receptor
D2: this is possible by studying the binding of a specific ligand with respect to
D2 (agonist or antagonist) such as labeled spiperone, to receptors present in a tissue homogenate (striatum or pituitary gland). In particular, the dissociation constant Kd of several specific D2 ligands is known.

We know, for example, that the Kd for the ligand 3H-spiperone is in the picomolar values (pM). We therefore know that a saturation curve with this ligand on extracts of membranes containing the D2 receptors of striatum, pituitary or substantia nigra and the analysis by the Scatchard method (determination of the number of receptor sites) results obtained from the saturation curves, must give affinity values (Kd) for spiperone of the order of a picomolar, so that it can be affirmed that it is a D2 bond.

This therefore makes it possible to quantify the quantity corresponding to the receptor
D2 in the extract.

Furthermore, to discriminate between the D2S and D2L form of the receptor
D2, the RNAse enzyme protection method is used. For this, the 370 base pair AccI fragment was cloned (AccI site positions: 700 and 1070 of the mouse D2 cDNA), from the D2L receptor cDNA in the plasmid vector pBluescript into the site AccI. For the preparation of the probe, this plasmid is then linearized by cleavage with the enzyme Bsu36I and transcribed in vitro using the T3 polymerase using nucleotides labeled with 32 p, to have a labeled RNA probe. The size of this probe is 300 nucleotides. The protected fragments are 202 nucleotides for D2L and 130 nucleotides for D2S. (See figures 7 or 8).

 This probe is used for hybridization with RNA from regions expressing the D2 receptor (striatum, pituitary gland). The hybrids are then digested with the RNAse enzyme and two fragments are obtained: one corresponding to D2L of 202 base pairs, and the other corresponding to D2S of 130 base pairs. This analysis is called quantitative because it makes it possible to evaluate exactly the proportion of RNA corresponding to one or the other of the isoforms.

 To determine if there is a change in the expression of the D2 gene, one can proceed as indicated below.

 The modification of the expression of the gene coding for the dopaminergic receptor D2 corresponds either to an overexpression of the gene, in particular on the lactotropic cells of the pituitary gland, compared to the normal expression defined above, or to the absence of of the D2 gene.

 The overexpression of D2 can be determined as follows.

 We first check the presence of a transgene. A transgene is defined as a fragment of DNA that is artificially inserted (i.e., other than by sexual reproduction) into a cell and becomes part of the genome of the animal that develops from that cell. , or which is modified from the DNA normally present in the cell. Such a transgene may be a gene homologous to a natural gene of the transgenic animal but which is inserted into the genome of the animal at a position which differs from that of the natural homolog.

 To verify the presence of the transgene, the DNA extracted from a sample, for example from a mouse tail derived from the injection of the transgene into fertilized oocytes, is analyzed.

This DNA is digested with restriction enzymes, in particular PstI, and then the presence of the transgene is revealed by hybridization, for example under the conditions of stringent hybridization of this DNA with a labeled probe corresponding to a part of the transgene which is heterologous with respect to to the animal's genome, for example to the fragment of SV40 present only in the construct used to introduce the transgene, and for example the fragment
BamHI-BglII from SV40.

 The hybridization conditions are as follows: the nylon membranes are hybridized in a solution containing: 50% formamide, 5x SSC, 5x Denhardt's, 1% SDS, salmon sperm DNA 100 mg / ml, overnight at 42 "C. Washes are carried out twice with 2x SSC, 0.1% SDS at 42" C, then twice with 0.10 SSC at 65 "C.

 In order to verify that the mice containing the transgenic DNA express the transgene, the transgenic animal and a control animal are sacrificed and the RNA is prepared from different tissues. The ART is analyzed by the RNA transfer technique (Northern blot) and the same probe always used as the probe defined above, and in particular the same fragment of SV40 as that which served to determine the presence of the transgene.

 A band corresponding to the expression of the transgene is found only in the pituitary gland of the transgenic mice and not in the control animal.

According to an advantageous embodiment, the invention relates to the use of a non-human transgenic mammal animal, capable of overexpressing, in particular on the lactotropic cells of the pituitary gland, the isoform
D2L and / or the D2S isoform of the dopamine D2 receptor.

 To fix ideas, the overexpression of D2L compared to normal expression can be around 7 times.

 To fix the idea, the overexpression of D25 compared to normal expression can be around 10 times.

 The overexpression is dependent on the promoter used, but also on the place of insertion of the transgene in the genome. This means that even using the same promoter, one is not sure of obtaining the same expression in two independent animals, because in one animal one can have integration of the transgene in a part of the genome more active compared to the other , or have multiple copies inserted in one case but not in the other. It is only a screening between several transgenic lines which makes it possible to possibly select two animals with similar levels of expression for the same gene or for two different genes having the same promoter.

Overexpression of the D2L isoform or overexpression of the isoform
D2S can be determined using the RNAse enzyme digestion protection technique, by comparing the intensity of the band corresponding to each isoform in a control mouse and a transgenic mouse. The value of the intensity of the band obtained with RNA from control mice (since there is RNA normally present in the control animal) is subtracted from that obtained from transgenic mice.

 In order to study the overexpression of the proteins corresponding to the D2L and D2S receptors, binding studies are carried out (establishment of the saturation curves: Scatchard method (The attraction of proteins for small molecules and ions; PNAS, 1949, 51: 660 ) a labeled agonist or antagonist, preferably spiperone, to tissue homogenates from the pituitaries of transgenic and normal mice. A comparison of the values (number of sites) obtained with the two groups gives an indication of overexpression of the receptor.

According to one embodiment, the invention relates to the use of a non-human transgenic mammalian animal which no longer expresses the isoform
D2L, or which no longer expresses the D2L isoform or the D2S isoform.

 The absence of expression of the D2L isoform can be determined as follows.

 Mice where expression of the D2L form has been eliminated are first identified relative to the DNA by analysis with the DNA transfer method (Southern blot), using a probe consisting of a fragment. containing all or part of the D2 receptor region which contains the insertion of 87 base pairs defined above, in particular a genomic probe shown in FIG. 4, EcoRI-BglI.

 In order to analyze that the expression of the D2S form is still present in these animals, the RNA extracted from the striatum and the pituitary gland as well as other tissues, for example the substantia nigra, is analyzed by the technique. protection against digestion by the enzyme RNAse.

 We also use tissues that do not express the receptor and that serve as controls, such as the cerebellum.

 In order to verify that the D2S protein is still present, the pharmacological properties are analyzed by binding of a specific D2 ligand, for example in striatum or pituitary homogenates.

The absence of expression of the D2L isoform and of D2S can be determined by one of the following methods:
1) Mice where the expression of the D2L and D2S form has been eliminated are verified by DNA transfer (Southern blot) with DNA extracted from the tail of mice cut with the enzyme SpeI and hybridized with the PstI probe corresponding to the fragment indicated in Figure 3.

 Hybridization of this probe clearly shows that the band corresponding to the wild-type D2 receptor (that is to say normally present in animals) is no longer present in animals homozygous for the mutation.

 2) Analysis by RNA transfer (Northern blot) of RNA extracted from tissues expressing D2, in particular striatum, shows that there is no longer any expression of RNA corresponding to the wild-type gene. The probe used in this case comprises the 5 ′ part of the cDNA of the D2 gene, in particular a SmaI-PvulI fragment of 454 base pairs can be used (FIG. 9A).

3) Finally, we can also demonstrate that the binding of specific ligands
D2, especially spiperone, is completely absent in these mice (Figure 9B, white circles).

According to an advantageous embodiment, the invention relates to a non-human transgenic mammal animal or mammalian cells containing in their genome a construct chosen from:
- a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site ;
- a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site ;;
- a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site , and a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the site of polyadenylation.

 The term “D2L cDNA or D2S cDNA” also includes any nucleotide sequence derived from the sequences respectively represented in FIGS. 5 and 6, namely by addition, deletion or mutation of one or more bases, provided that the coded protein corresponding to this nucleotide sequence has biological properties equivalent to those of D2 receptors.

 The term “D2L or D2S cDNA” also denotes any nucleotide sequence capable of hybridizing respectively with the sequences represented in FIGS. 5 and 6, or taking into account the degeneration of the genetic code, capable of coding for the proteins respectively represented on Figures 5 and 6.

 Non-human transgenic mammalian animals are such that there is overexpression of D2L and / or D2S on the lactotropic cells of the pituitary gland.

 The invention relates to a transgenic non-human mammalian animal or mammalian cells containing the D2 receptor gene in which a fragment of the D2 gene containing exon 2 or a fragment of the D2 gene containing exon 6 is replaced by any or part of a marker gene under the control of an appropriate promoter, in particular the neomycin resistance gene (neo) under the control of the phosphoglycerate kinase -1 promoter (PGK-1).

 In the case of a non-human transgenic mammalian animal whose D2 receptor gene is such that a fragment containing exon 2 is deleted, the expression of D2L and D2S is suppressed.

 In the case of a non-human transgenic mammalian animal whose D2 receptor gene is such that a fragment containing exon 6 is deleted, the expression of D2L is suppressed, but the expression of D2S is maintained.

The invention also relates to the transgenic constructs chosen from:
a) a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the site of polyadenylation and in particular: BamHI-Hindlll fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40,
b) a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the site of polyadenylation and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,
c) a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the site of polyadenylation and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40, and a promoter allowing the overexpression of the isoform D2S on the pituitary gland lactotropic cells, in particular the prolactin promoter, +
D2S cDNA + a transcription terminator, in particular a part of the SV40 virus genome containing the polyadenylation site and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,
d) the D2 gene in which a fragment containing exon 2 is replaced by a marker gene under the control of an appropriate promoter, in particular a cassette containing the gene for resistance to neomycin (neo) under the control of the promoter PGKI, and in particular the D2 gene in which the 0.9 Kb NcoI genomic fragment containing exon 2 is replaced by the PGK-neo cassette.

 e) the D2 gene in which a fragment containing exon 6 is replaced by a marker gene under the control of an appropriate promoter, in particular by a cassette containing the neo gene under the control of the PGKI promoter, and in particular the gene of D2 in which the BglII-BglII genomic fragment containing exon 6 is replaced by the PGKneo cassette.

 According to an advantageous embodiment, the invention relates to cell cultures containing one of the above transgenic constructs.

 These cell cultures can be obtained either from cells taken from transgenic animals as defined above, or from cell lines using the above transgenic constructs using standard cell transfection techniques.

 The invention also relates to cell cultures, in which the cells are such that exon 2 or ltexon 6 of the D2 gene has been removed from one of the two alleles.

 The invention also relates to a non-human transgenic mammal as obtained by introduction, in particular microinjection into a fertilized oocyte, of one of the above transgenic constructions, insertion of the embryo into a surrogate mother and development of the embryo to term.

 According to an advantageous embodiment of the invention, the above non-human transgenic mammals contain one of the constructions a), b) or c), as defined above.

The invention also relates to a non-human transgenic mammal as obtained by introduction into a blastocyte of embryonic stem cells (ES cells) comprising in their genome one of the above-mentioned transgenic constructions, obtained by homologous recombination, selection of male chimeric animals according to a criterion corresponding to the ES line, crossing of selected animals with mice, in particular mice
C57 Black 6, to obtain animals heterozygous with respect to one of the above constructions and possibly crossing of two heterozygotes to obtain an animal homozygous with respect to one of the above constructions.

 C57 Black 6 mice are advantageously chosen, because they are conventionally used in behavioral experiments.

 Advantageously, the constructions referred to in the above transgenic animals are the constructions d) and e), as defined above.

 The invention also relates to a transgenic mammal as produced by crossing transgenic animals expressing one of the transgenic constructs defined above.

 In particular, the transgenic animals containing the construction c) can be obtained either by introducing the constructions a) and b) into their genome, or by crossing a transgenic animal containing the construction a) with a transgenic animal containing the transgenic construction b).

The invention also relates to a method for obtaining a transgenic model for the study of pathologies involving D2 receptors, and to their treatment, comprising the introduction into cells or embryos of non-human mammals of a chosen construction. among:
- a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40,
- a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular: BamHI-HindII fragment (-3000 / +33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,
- a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter, + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BgllI fragment of SV40,
- And a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the site of polyadenylation and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,
- the D2 gene in which a fragment containing exon 2 is replaced by a marker gene under the control of an appropriate promoter, in particular a cassette containing the neo gene under the control of the PGKI promoter, and in particular the D2 gene in which the 0.9 Kb NcoI genomic fragment containing exon 2 is replaced by the PGK-neo cassette.

 - the D2 gene in which a fragment containing exon 6 is replaced by a marker gene under the control of an appropriate promoter, in particular by a cassette containing the neo gene under the control of the PGKI promoter, and in particular the gene for D2 in which the BglII-BglII genomic fragment containing exon 6 is replaced by the PGK-neo cassette.

The invention also relates to a method for screening for drugs active on pathologies involving D2 receptors, in particular prolactinomas, or certain neurodegenerative pathologies such as Parkinson's disease, Huntington's disease or schizophrenia, comprising:
* administration to a transgenic non-human mammal or to cells of transgenic non-human mammals containing a construct chosen from:
- a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40,
- a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,
- a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40,
- And a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the site of polyadenylation and in particular: BamHJ-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,
- the D2 gene in which a fragment containing exon 2 is replaced by a marker gene under the control of an appropriate promoter, in particular a cassette containing the neo gene under the control of the PGKI promoter, and in particular the D2 gene in which the 0.9 Kb NcoI genomic fragment containing exon 2 is replaced by the PGK-neo cassette,
- the D2 gene in which a fragment containing exon 6 is replaced by a marker gene under the control of an appropriate promoter, in particular by a cassette containing the neo gene under the control of the PGKI promoter, and in particular the gene for D2 in which the BglII-BglII genomic fragment containing exon 6 is replaced by the PGK-neo cassette of the compound to be tested,
* and the determination of the decrease in the level of prolactin (in the case of prolactinomas) or the improvement of the neurodegenerative state (in the case of neurodegenerative pathologies)
Prolactinomas are very common tumors in women. The origins of these tumors are not yet known, but a malfunction of dopaminergic control at the lactotropic level is implicated. In particular, the transgenic animals of the invention may serve as a model for the study and determination of the treatment of such a pathology. In fact, in these animals, the normal balance between the expression of the form D2L and D2S is altered, which makes it possible to study the phenotype corresponding to such an alteration.

 At the same time, dopamine D2 agonists and antagonists can be tested for their effectiveness in increasing or suppressing the phenotypes obtained.

 For example, the overexpression of the D2S form causes a significant decrease in the level of prolactin, resulting in a lactation deficit in females. Remoxipride is an antagonist known to have a high specificity for binding with D2S, which makes it possible to test whether the injection of this substance makes it possible to eliminate the deficit in the level of prolactin in transgenic animals overexpressing D2S.

 Regarding animals that no longer express either D2S or D2L, they can serve as a model for studying the treatment of certain neurodegenerative diseases.

 D2 receptors are involved in the control of several physiological functions such as coordination of movement, vision, regulation of the synthesis of certain hormones, etc. We can therefore highlight the deficits linked to the absence of these receptors. For example, one of the phenotypes linked to the absence of the D2 receptor can be poor coordination of movements. These animals can then be used to test compounds acting on the stimulation of movement, in order to see if this deficit can be compensated.

 From a pharmacological point of view, the transgenic animals of the invention are useful for screening the substances currently used with D2 specificity in order to define if this is really the case. As there are in vivo, several dopaminergic receptors which have very similar affinities for the existing dopamine agonists and antagonists; the transgenic animals of the invention therefore constitute a remarkable tool in this sense.

With regard to transgenic animals which only express the form
D2S of the receptor, the search for phenotypes can be made and we can then think about possible treatments.

 In addition, the transgenic animals of the invention no longer expressing the D2S form of the receptor can be used to develop specific D2S antagonists, with the possibility of being able to test these antagonists in vivo in the absence of the D2L receptor.

The invention relates to a method for screening for drugs active in an animal model in which prolactin levels are reduced compared to the normal state using transgenic animals overexpressing D2S, comprising:
* administration to a transgenic non-human mammal or to cells of transgenic non-human mammals containing a construct chosen from:
- a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular: BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40, of the compound to be tested,
* and the determination of the increase in prolactin level.

The invention relates to a method for screening for drugs active on prolactinomas using transgenic animals overexpressing D2L, comprising:
* administration to a transgenic non-human mammal or to cells of transgenic non-human mammals containing a construct chosen from:
- a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular: BamHI-Hindlll fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40, of the compound to be tested,
* and the determination of the decrease in prolactin level.

The invention relates to a method for screening drugs which are active on neurodegenerative diseases such as Parkinson's disease, Huntington's disease or schizophrenia using transgenic animals in which D2S and D2L are no longer expressed, comprising
* administration to a transgenic non-human mammal or to cells of transgenic non-human mammals containing a construct chosen from:
- the D2 gene in which a fragment containing exon 2 is replaced by a marker gene under the control of an appropriate promoter, in particular a cassette containing the neo gene under the control of the PGKI promoter, and in particular the D2 gene in which the 0.9 Kb NcoI genomic fragment containing ltexon 2 is replaced by the PGK-neo cassette of the compound to be tested,
* and the determination of the improvement of the neurodegenerative state.

Regarding the improvement of the neurodegenerative state in
Parkinson's, we expect a decrease in rest tremor and also an improvement in posture and voluntary movements.

 It is mainly expected that these mice can represent a study model for diseases such as Parkinson's disease or schizophrenia.

It is not excluded that drugs which could be tested in the transgenic animals of the invention can also improve diseases which do not have abnormalities of the D2 receptor at their base.

 A transgene is defined as a fragment of DNA which is inserted artificially (i.e. other than by sexual reproduction) in a cell and which becomes part of the genome of the animal which develops from that cell, or that is modified from the DNA normally present in the cell. Such a transgene may be a gene homologous to a natural gene of the transgenic animal but which is inserted into the genome of the animal at a position which differs from that of the natural counterpart, or else such a transgene may correspond to the homologous gene. modified, in particular by deletion of a DNA fragment of said natural gene.

The invention also relates to a process for the preparation of a transgenic animal, carrying the aforementioned transgene, which can be raised stably to give offspring having cells which contain the gene stably. This process can include:
- the removal of a fertilized oocyte from a first female animal,
- the transfer of a transgene into the fertilized oocyte,
- the transfer of the fertilized oocyte containing the transgene into the oviduct of a second female animal of the same species as the above first animal,
- keeping the second female animal in a state such that:
- said female animal begins gestation with respect to the embryo derived from the fertilized oocyte containing the transgene,
- the embryo develops into a transgenic animal,
- the transgenic animal is born from the second female animal.

Description of the figures:
- Figure 1A shows the construction PRLD2L.

 - Figure 1B shows the construction PRLD2S.

 - Figure 1C shows the BamHI-BglII fragment which serves as a probe to determine whether there has been integration of the transgene.

 In what precedes and what follows, one designates by “construction or transgene PRLD2L”, the transgenic construction or the gene containing said construction, allowing the overexpression of D2L, and by “construction or transgene PRLD2S”, the transgenic construction or the gene containing said construct, allowing the overexpression of D2S.

 The term “PRLD2L or PRLD2S transgenic mice” denotes mice containing the transgenic construct PRLD2L or PRLD2S.

 - Figure 2 shows the PCR analysis of mice comprising both the PRLD2L and PRLD2S construction.

In order to analyze the mice originating from the coupling between the trasngene lines PRLD2L and PRLD2S, DNA is prepared from a small tail fragment of these animals. The polymerase chain reaction (PCR) is carried out in the presence of two primers, one corresponding to the common sequences of the mRNAs of D2L and D2S included, for example, between nucleotides 830 to 850 of the mouse cDNAs and the other corresponding , for example, at the nucleotides between positions 4457 and 4477 of the SV40 virus sequences which are present in the fragment which served for the construction of the transgene. The use of these primers leads to the production of two fragments: one of 1722 base pairs corresponding to the transgene
D2L and the other of 1635 base pairs corresponding to the D2S transgene.

The advantage of this method is that only the sequences corresponding to the transgenes are amplified, while the endogenous gene is not because it does not contain the SV40 sequences. The simultaneous presence of the two fragments shows that the animal in question has the two transgenes D2L and D2S integrated into its genome.

 - Figure 3 shows the homologous recombination leading to the preparation of transgenic mice no longer expressing either D2S or D2L.

 - Figure 4 shows the homologous recombination leading to the preparation of transgenic mice no longer expressing D2L.

- Figure 5 shows the amino acid and nucleotide sequence of
D2L.

- Figure 6 shows the amino acid and nucleotide sequence of
D2S.

 - Figure 7 shows the analysis of RNA from the pituitary of PRLD2L and PRLD2S transgenic mice compared to wild mice, and shows the overexpression of the D2L or D2S isoforms.

 Protection is carried out by digestion with the enzyme RNAse from the pituitaries of transgenic mice PRLD2L, PRLD2S and their controls (C) (non-transgenic sibling, of the same litter), from the RNA probe hybridized to RNA corresponding to the messenger RNA of the D2 gene, this probe being described in the text (AccI fragment in pBluescript, plasmid linearized by Bsu36I). The arrows indicate the bands corresponding to the expected size for D2L (202 nucleotides) and D2S (130 nucleotides).

It can be observed in the line corresponding to the control mouse RNA that the D2L form is much more expressed in the pituitary gland of the control animal than the D2S form. The contrast of the photograph increases this difference even more, so that we only see the D2L shape in the control. Longer exposures of the gel allow visualization of a signal also for D2S in the control. Quantification of D2L overexpression in the line corresponding to the mouse pituitary gland
PRLD2L, gives a 7-fold increase in D2L expression in transgenic mice compared to control mice. With regard to the line corresponding to PRLD2S mice, the quantification gives us a 10-fold increase in D2S in these transgenic mice compared to their control.

 It should be noted that the overexpression of the PRLD2L or PRLD2S transgenes is added to the expression of the endogenous gene.

 FIG. 8 represents the protection with the RNAse enzyme of RNA originating from tissues of mice (normal or wild mice, heterozygous or homozygous) in which the D2L form of the receptor has been eliminated.

RNAs from striatum, substantia nigra, cortex and cerebellum from normal (+ / +), heterozygous (+/-) and homozygous (- / -) mice were hybridized with the probe corresponding to the plasmid containing the AccI fragment cut by
Bsu36I and transcribed by the T3 enzyme. The disappearance of the band corresponding to the D2L form is clearly observed in homozygous mice. In this photograph, bands corresponding to the D2 transcript are observed only in the striatum, and the substantia nigra as expected, the other regions of the brain used (cortex, cerebellum) serving as negative control.

 FIG. 9 represents the absence of expression of D2 in the transgenic mice obtained by homologous recombination.

 A) Analysis by the Northern technique of the RNAs originating from the striatum of normal (+ / +), heterozygous (+/-) and homozygous (- / -) mice for the elimination of the expression of the gene for the dopaminergic D2 receptor. The probe used corresponds to the SmaI-PvuII fragment described in the text.

 B) Analysis by the Scatchard method of a saturation curve obtained by binding of 3H-spiperone to membranes of mouse striatum.

This analysis shows that in heterozygous mice, the number of D2 sites is reduced compared to the wild mouse, and is completely absent in homozygous mice which no longer have the D2 receptors.

 Method: the striata from wild mice (white square), heterozygotes (black triangle), and homozygotes (white circle) are homogenized with an Ultra-Turrax homogenizer in 1 ml of Tris-HCl, 10 mM, cold pH 7.5, containing 5 mM EDTA. The membranes are centrifuged at 1000 g for 10 min, the supernatant is recovered and then centrifuged at 45,000 g for 40 min at 4 "C. The pellet is washed and then taken up in 50 mM Tris-HCl pH 7.7.

For the analysis of the D2 receptor, 15 μg of membranes are incubated in a 50 mM Tris-HCl solution, pH 7.7, containing 120 mM NaCl, 5 mM
KCl, 2 mM Cal2, 1 mM MgCl2, 0.1% ascorbic acid and 3H-spiperone (10-600 pM; specific activity 114 Ci / mmol; Amersham) at 37 "C for 60 min. Non-specific binding is determined by presence of 1 µM (+) butaclamol (RBI, Natick, MA).

 The radioactive ligand bound to the membranes is recovered by rapid filtration through Whatmann GF / B glass fiber filters. The filters are washed three times with 5 ml of 50 mM Tris-HCl, pH 7.7 cold.

 The data is analyzed with the LIGAND program (BIOSOFT).

 On the abscissa, the amount of 3H-spiperone linked to the receptor (f mol / mg of protein) is indicated.

 On the ordinate, the ratio 3H-bound spiperone / 3H-free spiperone was indicated.

Examples:
Example 1: Preparation of transgenic mice overexpressing D2L or D2S.

 In order to generate transgenic mice overexpressing one of the two forms of the dopamine D2 receptor on mouse pituitary (pituitary) lactotropic cells, the prolactin gene promoter was used.

 A 3.03 Kb BamHI-HindE (- 3000 / + 33) fragment of the prolactin gene promoter (Borrelli, E., Sawchenko, P. and Evans, R. (1992) Proc.

Natl. Acad. Sci. USA, 89: 2764-2768) was fused with the 2.261 Kb fragment of SmaI-EcoRV cDNA from D2L (Montmayeur, J.-P., Bausero, P.,
Amlaiky, N., Maroteaux, L., Hen, R. and Borrelli, E. (1991) Febs lett., 278: 239-243) or with the 2.174 Kb fragment of D2S cDNA (Montmayeur,
J.-P., Bausero, P., Amlaiky, N., Maroteaux, L., Hen, R. and Borrelli, E.

(1991) Febs lett., 278: 239-243); the polyadenylation site and the intron sequences of the small antigen T of the SV40 virus contained in the fragment of 847 base pairs BamHI-BglII (Subramani, S. and Southern, P. J. (1983) Anal.

Biochem., 135: 1-15) were fused downstream of the D2 receptor cDNAs, generating the PRLD2L and PRLD2S fusion constructs. These fragments were excised at Not I sites flanking the constructs and injected into the male pronucleus of fertilized oocytes from C57 Black 6 / SJL mice (originating from
Jackson Laboratory, Barharbor, Maine, 04609, USA).

 Mice born from these injections are tested for the presence of the transgenic construct by analyzing genomic DNA obtained from a small sample of the tail. The DNA obtained is tested by DNA transfer analysis (Southern blot) digested with PstI, brought into contact with a probe consisting of a fragment of SV40 BamHI-BglII labeled with 32p; only transgenic mice are revealed in this way, since the DNA of wild (i.e. non-transgenic) mice does not hybridize with this probe.

Mouse lines are obtained by crossing male or female transgenic mice with C57 Black 6 mice from Jackson
Laboratory. Heterozygous mice are tested for transgene expression by analysis of pituitary mRNA by the protection method using
RNAse, using a specific probe (AccI fragment in pBluescript linearized by Bsu36I) of the D2 receptor and by RNA transfer analysis (Northern blot), using the SV40 BamHI-BglII fragment labeled with 32P.

Two lines overexpressing the PRLD2L constructs are obtained; a line is obtained for the construction PRLD2S.

Example 2 Preparation of Transgenic Mice Overexpressing D2L and
D2S.

In order to obtain mice overexpressing the two receptor isoforms
D2, we cross heterozygous PRLD2L females with PRLD2S males.

To test mice positive for these two transgenes, a polymerase chain reaction (PCR) technique is used. The genomic DNA of the mouse tail is amplified using synthetic oligonucleotides belonging to the added fragment SV40 and for example extending from the nucleotide at position 4457 to the nucleotide at position 4477 of the genome of the SV40 virus, and to the cDNA of the receptors dopamine. Oligonucleotide primers are chosen from the D2 receptor cDNA region upstream of the present insertion in D2L (for example from position 830 to position 850 of mouse cDNA). Two fragments of different length are obtained, highlighting the doubly transgenic character (see FIG. 2).

Example 3 Preparation of Transgenic Mice No Longer Expressing or
D2S nor D2L (homologous recombination).

To suppress the total expression of the D2 receptor, cloned genomic DNA corresponding to the site of the D2 receptor is isolated from a genomic library of ES / EMBL3 mice: (Sambrook J., Fritsch, EF,
Maniatis, T., Molecular Cloning, 2nd edition, Ed. Cold Spring Harbor
Laboratory Press, 1989, vol. 2, chapter 9). The ES cells come from the mouse strain 129 of agouti color (Jackson Laboratory). A 6.5 Kb KpnI-SalI genomic mouse fragment containing exon 2 (Karen L.

O'Malley et al. (1990). Organization and Expression of the Rat D2A Receptor
Gene: Identification of Alternative Transcripts and a Variant Donor Splice
Site. Biochemistry, 29: 1367-1371) of the D2 gene is subcloned in pBlueScript. From this plasmid, the 0.9 Kb NcoI fragment containing exon 2 is eliminated and replaced by a 1.4 Kb segment of the neomycin resistance gene under the control of the phosphoglycerate kinase-1 promoter ( PGK-1) in the opposite transcriptional direction. The targeting vector is linearized at the unique KpnI or SalI sites present in the multiple cloning site before electroporation of the P1 ES cells, which can be obtained from the IGBMC (Institute of Genetics and Biology
Molecular and Cellular, Illkirch, France).

For electroporation, 1,107 P1 ES cells are mixed with 10 jug of linearized construction in 0.5 ml of DMEM (DMEM = Dulbecco modified Eagle's medium) plus 15% of FCS (FCS = fetal calf serum) in a cuvette for electroporation of 0.4 cm and electroporated at 400 Volt (1000 V / cm), at 125 farads using an electroporation device sold under the name Gene Pulsar (Bio-Rad). The cells are then transferred to a non-selective medium (Dulbecco) for 2 days and selected in 150 μg / ml of gentamycin (G418) for 10 days. The resistant ES clones are isolated and placed in microwells containing a cellular nourishing layer (irradiated fibroblasts) and then multiplied for DNA analysis by the DNA transfer technique (Southern blot). Digestion of DNA with SpeI gave a fragment of 12.5 Kb from wild type and 9.5 Kb from the targeted allele, when it is hybridized with an external probe, to the part of D2 involved in homologous recombination, and in particular the probe comprising or consisting of the fragment located between exons 3 and 4 of D2, cut by the enzyme PstI (FIG. 3). ES cells carrying the D2 gene generated by homologous recombination are injected into C57BL / 6 embryos from Jackson Laboratory in the form of blastocytes, using standard techniques (Bradley, A. (1987)
Production and analysis of chimaeric mice.In teratocarcinomas and
Embryonic Stem Cells: A practical Approach, Robertson, EJ, ed. (Oxford:
IRL Press Limited)). The chimeric descendants are identified by the color of the hair corresponding to the chimeric phenotype (gray and black color) and are crossed with C57BL / 6 mice. The transmission of the germ line of the mutant allele is determined by DNA transfer (Southern blot) from the DNA taken from the tail isolated from the "agouti" progeny by digestion with SpeI. Mice homozygous towards the D2 mutation are obtained by crossing mutant heterozygous mice.

 Example 4: Preparation of mice no longer expressing D2L by homologous recombination.

To obtain transgenic mice no longer expressing D2L, a 4.8 Kb EcoRI genomic fragment containing exon 3 and exon 4 is subcloned into pBlueScript, a 1.5 Kb BglII fragment surrounding the exon 6 is deleted and replaced by the PGK-neo cassette gene. To this plasmid, another 5.8 Kb EcoRI genomic fragment going from exon 5 to exon 7 is fused to provide a fragment of greater homology. To eliminate random integration, the viral gene for simple herpes thymidine kinase (TK) under the control of the PGK promoter is included at the 3 'end of the vector. The targeting vector is linearized at the single NotI site in the multiple cloning site before electroporation of ES D3 cells (Dr. Kemler Institut Max Planck, Friborg,
Germany). The electroporated ES D3 cells are selected from 150 μg / ml of gentamycin (G418) + gancyclovir 2 μM for 10 days. The targeted clones are identified by transfer of genomic DNA (Southern blot) cut with BglI and hybridized to an external probe originating from a fragment of
D2 surrounding exon 8 and digested with ECoRI-BglI (Figure 4). Digestion of DNA with BglI gave a fragment of 6.8 Kb from wild type and 4.5 Kb from targeted allele. The method for generating mutant mice no longer having the D2L isoform is carried out according to what has been described from mice no longer expressing either the D2S receptor or the D2L receptor.

Claims (16)

 1. Use of a non-human transgenic mammalian animal whose expression of the gene coding for the dopaminergic receptor D2 is modified, in particular on the lactotropic cells of the pituitary gland, compared to a normal expression, in particular on the lactotropic cells of the pituitary gland, for the determination of a drug which is active on pathologies involving the D2 receptor.  2. Use according to claim 1, of a non-human transgenic mammal animal capable of overexpressing, in particular on the lactotropic cells of the pituitary gland, the D2L isoform and / or the D2S isoform of the dopamine D2 receptor.  3. Use according to claim 1, of a non-human transgenic mammalian animal which no longer expresses the D2L isoform, or which no longer expresses either the D2L isoform or the D2S isoform.  4. Non-human transgenic mammalian animal or mammalian cells containing in their genome a construction chosen from:  - a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site ,  - a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site ,  - a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site , and a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the site of polyadenylation.  5. A non-human transgenic mammal animal containing one of the constructs according to claim 4, and whose lactotropic cells overexpress D2L and / or D2S.  6. Non-human transgenic mammal animal or mammalian cells containing the D2 receptor gene in which a fragment of the D2 gene containing exon 2 or a fragment of the D2 gene containing exon 6 is replaced by all or part of a marker gene under the control of an appropriate promoter, in particular the neomycin resistance gene (neo) under the control of the phosphoglycerate kinase -1 promoter (PGK-1).  7. Non-human transgenic mammal animal containing one of the constructs according to claim 6, and in which either the expression of D2L is suppressed, the normal expression of D2S being maintained, or the expression of D2L and of D2S is suppressed .  8. Cells cultured from non-human transgenic mammalian animals according to one of claims 4 or 6.  9. A non-human transgenic mammal produced by the introduction, in particular microinjection into a fertilized oocyte, of one of the constructs according to claim 4, insertion of the embryo into a surrogate mother and development of the term embryo.  10. Non-human transgenic mammal obtained by introduction into a blastocyte of embryonic stem cells (ES cells) comprising in their genome one of the constructions according to claim 6, obtained by homologous recombination, selection of male chimeric animals according to a criterion corresponding to the ES line, crossing of selected animals with mice, in particular C57 Black 6 mice, to obtain animals heterozygous with respect to one of the constructs according to claim 6 and optionally crossing two heterozygotes to obtain an animal homozygous with respect to one of the constructions according to claim 6.  11. Mammal according to one of claims 4 or 6, produced by crossing transgenic animals expressing different constructions.  12. Method for obtaining a transgenic model for the study of pathologies involving D2 receptors, and their treatment, comprising the introduction into the cells or embryos of non-human mammals of a construction chosen from:  a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40,  a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,  a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / +33) of the prolactin promoter, + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40, and a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular the BamHI-HindII fragment (-3000 / + 33 ) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,  - the D2 gene in which a fragment containing exon 2 is replaced by a marker gene under the control of an appropriate promoter, in particular a cassette containing the neo gene under the control of the PGKI promoter, and in particular the D2 gene in which the 0.9 Kb NcoI genomic fragment containing the exon 2 is replaced by the PGK-neo cassette,  the D2 gene in which a fragment containing exon 6 is replaced by a marker gene under the control of an appropriate promoter, in particular by a cassette containing the neo gene under the control of the PGKI promoter, and in particular the gene for D2 in which the BglII-BglII genomic fragment containing exon 6 is replaced by the PGK-neo cassette.  13. A method of screening for drugs active on pathologies involving D2 receptors, in particular prolactinomas or certain neurodegenerative pathologies such as Parkinson's disease, Huntington's disease or schizophrenia comprising:  * administration to a transgenic non-human mammal or to cells of transgenic non-human mammals containing a construct chosen from:  a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40,  a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / +33) of the prolactin promoter  + SmaI-EcoRV fragment of the D2S cDNA + BamHI-Bgln fragment of SV40,  a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / +33) of the prolactin promoter  + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40, and a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2S + cDNA a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular the BamHI-HindII fragment (-3000 / +33) of the prolactin promoter  + SmaI-EcoRV fragment of D2S cDNA + BamHI-BglII fragment of SV40,  - the D2 gene in which a fragment containing exon 2 is replaced by a marker gene under the control of an appropriate promoter, in particular a cassette containing the neo gene under the control of the PGKI promoter, and in particular the D2 gene in which the 0.9 Kb NcoI genomic fragment containing exon 2 is replaced by the PGK-neo cassette,  - the D2 gene in which a fragment containing exon 6 is replaced by a marker gene under the control of an appropriate promoter, in particular by a cassette containing the neo gene under the control of the PGKI promoter, and in particular the gene for D2 in which the BglII-BglII genomic fragment containing exon 6 is replaced by the PGK-neo cassette of the compound to be tested,  * and the determination of the decrease in the level of prolactin (in the case of prolactinomas) or the improvement of the neurodegenerative state (in the case of neurodegenerative pathologies).  14. A method of screening for active drugs in an animal model where prolactin levels are decreased using transgenic animals overexpressing D2S, comprising administering to a transgenic non-human mammal or to transgenic non-human mammal cells containing a construction chosen from:  a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary glands, in particular the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of D2S cDNA + BamHI fragment BglII of SV40, of the compound to be tested,  * and the determination of the increase in prolactin level.  15. A method of screening for drugs active on neurodegenerative pathologies such as Parkinson's disease, Huntington's disease or schizophrenia using transgenic animals in which D2S and D2L are no longer expressed, comprising:  * administration to a transgenic non-human mammal or to cells of transgenic non-human mammals containing a construct chosen from:  - the D2 gene in which a fragment containing exon 2 is replaced by a marker gene under the control of an appropriate promoter, in particular a cassette containing the neo gene under the control of the PGKI promoter, and in particular the D2 gene in which the 0.9 Kb NcoI genomic fragment containing the exon 2 is replaced by the PGK-neo cassette of the compound to be tested,  * and the determination of the improvement of the neurodegenerative state.  16. Transgenic construction chosen from:  - a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40,  - a promoter allowing the overexpression of the D2S isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + cDNA of D2S + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2S cDNA + BamHI-BglII fragment of SV40,  - a promoter allowing the overexpression of the D2L isoform on the lactotropic cells of the pituitary gland, in particular the prolactin promoter, + D2L cDNA + a transcription terminator, in particular a part of the genome of the SV40 virus containing the polyadenylation site and in particular BamHI-HindII fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the D2L cDNA + BamHI-BglII fragment of SV40, and a promoter allowing the overexpression of the D2S isoform pituitary gland lactotropic cells, including the prolactin promoter, + D2S cDNA + a transcription terminator, in particular a part of the SV40 virus genome containing the polyadenylation site and in particular BamHI-Hindlll fragment (-3000 / + 33) of the prolactin promoter + SmaI-EcoRV fragment of the cDNA D2S + BamHI-BglII fragment of SV40,  - the D2 gene in which a fragment containing exon 2 is replaced by a marker gene under the control of an appropriate promoter, in particular a cassette containing the neo gene under the control of the PGKI promoter, and in particular the D2 gene in which the 0.9 Kb NcoI genomic fragment containing exon 2 is replaced by the PGK-neo cassette,  the D2 gene in which a fragment containing exon 6 is replaced by a marker gene under the control of an appropriate promoter, in particular by a cassette containing the neo gene under the control of the PGKI promoter, and in particular the gene for D2 in which the BglII-BglII genomic fragment containing exon 6 is replaced by the PGK-neo cassette.