EP0386185A1 - Method for the genetic expression of heterologous proteins by cells transfected in vivo - Google Patents

Abstract

The method described is used for the in vivo genetic expression of heterologous proteins such as Harvey's c-ras oncogene, the human growth hormone (hGH) gene and the neomycin resistance gene by cells transfected with using a liposome which is injected in suspension into the circulating blood of an animal (rat or rabbit). The expression vector encapsulated in the injected liposomes may contain, for example, the gene coding for an oncogene. In this case, an organ is removed from the animal containing differentiated transfected cells which is put back into culture in vitro in order to select the cells which express the oncogene and which consequently can proliferate in vitro. When the animal is injected with liposomes encapsulating the hGH gene and the neomycin resistance gene, the cells selected in culture media containing the antibiotic produce hGH. On the other hand, when the expression vector contains the hGH gene under the control of the human promoter of the gene for the heat shock protein of 70 kd, is injected into the animals, these secrete into the circulating blood, hGH after thermal induction. In addition, the repetition of these steps induces the synthesis of anti-hGH antibodies by the animal. The main fields of application of the invention are either to produce differentiated cells capable of profifering in vitro, or the in vivo production of heterologous biologically active or antigenic proteins.

Description

 Method for the genetic expression of heterologous proteins by cells transfected in vivo

Technical area

The subject of the invention is a method of genetic expression of heterologous proteins transfected by cells in vivo using at least one gene expression vector encapsulated in liposomes, according to which a suspension of liposomes is prepared in which the expression vector is encapsulated and this suspension of liposomes is injected into the circulating blood of an animal.

The method according to the invention is intended, on the one hand, to produce an oncogene capable of immortalizing differentiated cells and proliferating in vitro as well as producing proteins of industrial interest.

The method according to the invention is intended, on the other hand, to produce in vivo at least one heterologous protein by the cells of the "transfected" animal, as well as antibodies directed against this protein.

Prior art

The state of the art relating to the genetic expression of heterologous proteins by cells transfected in vivo using gene expression vectors encapsulated in liposomes, can be illustrated by the publications cited below by way of illustration. 'example.

According to EP-A1-0 027 662, the hepatitis B virus (HBs) surface antigen was synthesized in the liver of rabbits injected with these liposomes encapsulating the HBs gene.

According to US Pat. No. 4,394,448, liposomes encapsulating unfractionated mouse DNA were injected into Balb / c mice which do not produce urinary protein 2 (mup2) and mup2 in the urine of these animals.

In the article by Nandi et al, 1986, J. Biol. Chem. 261, 16722-16726, the encapsulation of the rat preproinsulin I gene has been described and, after injection into the rat, the synthesis of insulin. All of the results presented in the above publications show that genetic information conveyed by liposomes in an animal can lead to the synthesis of heterologous proteins in an "transfected" animal.

Statement of the invention

The aim of the present invention is to allow the genetic expression of heterologous proteins by cells transfected in vivo using at least one expression vector for a gene encapsulated in liposomes, so as to allow synthesis various proteins in sufficient quantity for their practical applications.

To this end, the subject of the invention is a method of genetic expression as defined in the claims.

During the implementation of the present invention, the oncogenic sequences of the ras cell gene of Harvey (as described by Tabin et al., 1982, Nature 300, 143-149) and the gene of growth hormone (hGH) under the control of the protein promoter of the heat shock protein gene of 70,000 d (hsp70 for "heat shock protein 70 kd") (as described by Dreano et al., 1988, Bio / Technology 6, 953-958).

The expression of these genes was found in the hepatocytes of these animals after having put them back in culture in vitro. In fact, they have been shown to be able to proliferate in vitro and produce, after induction by heat, hGH.

In addition, two plasmids (pl7hGHneo and pl7HBN, as described by Dreano et al., 1988, Bio / Technology 6, 953-958) containing the hybrid gene hsp70-hGH were introduced into rats and rabbits ( in the case of pl7hGHneo). HGH or anti-hGH antibodies have been found in the circulating blood of these animals.

The advantages of the use of genes expressed under controlled induction, by the promoter of hsp genes, for the production of heterologous proteins by cells in culture has been extensively described (in particular by Nover, 1987, Enz. Microb. Technol. 9, 129-144).

In the present invention, the promoter of the hsp70 gene was used. It constitutes a particularly powerful promoter, and it is expressed in almost all eukaryotic cells when these are subjected to a thermal shock and thus makes it possible thus to control the process of expression of the genes which it directs. π is particularly important in the case of in vivo transfection, in accordance with the present invention, to obtain the best possible expression, in a controlled manner, in order to be able to program the expression and thus mimic the conventional immunization conditions using a purified antigen. Similarly, it is of great practical interest to be able to extend the field of application of the method according to the invention to the greatest number of types of producer cells.

In vivo transfection makes it possible to obtain polyclonal antibodies directed against all kinds of secreted proteins (or trans-membrane) as well as their genetic variants without any in vitro production of the antigen or of the cell lines producing it.

The accompanying drawings illustrate the results obtained in two examples of the implementation of the invention described below.

Brief description of the drawings

Figure 1 is an autoradiography obtained in an example of the implementation of the invention.

Figure 2 is an autoradiography obtained in another example of the implementation of the invention.

Way of realizing the invention

The invention will be better understood using the following examples:

Example 1

The in vivo transfection of rat hepatocytes was carried out with liposomes encapsulating expression vectors, and the consecutive in vitro synthesis of the recombinant genes was obtained in the manner described below. 1. Expression vectors used:

- The plasmid pEJ containing the Harvey cell oncogene ras in its mutated form, isolated in humans by Tabin et al., 1982, Nature 300, 143-149.

- Plasmid pl7hGHneo (Dreano et al., 1986, Gene 49, 1-8) containing the neomycin resistance gene under control of the regulatory sequences of the Simien 40 virus (SV40) and the human growth hormone gene ( hGH) led by the human promoter of the hsp70 gene. The advantage of using genes expressed under controlled induction by the gene promoter of heat shock proteins for the production of heterologous proteins in a variety of cells in culture has been extensively described by Nover, 1987, Enz. Microb. TechnoL, 9, 129-144.

- The plasmid plTHBN containing the same hybrid gene hsp70-hGH, a gene for resistance to neomycin directed by the regulatory sequences of the thymidine kinase gene of the Herpes Simplex virus 1 and a transforming fragment of the bovine papilloma virus ( Dreano et al., 1988, Bio / Technology 6, 953-958).

2. Transfection:

2.1 Monolamellar liposomes were prepared, according to the method of Deamer et al., 1976, Biochem. Biophys. Acta 433, 629-634, from 2 mg of phosphatidylcholine dissolved in 1 ml of chloroform and taken up, after evaporation, in 1 ml of diethyl ether. The final suspension of liposomes is carried out in 1 ml of complete basic synthetic culture medium but without serum, containing 100 μg of plasmid DNA pl7hGHneo and pEJ. This solution is freed from diethyl ether by bubbling air-C02 (95: 5, v / v), at 20 ° C, while equilibrating the medium at physiological pH with a buffer system, for the purpose of injection.

2.2 This suspension of liposomes encapsulating the plasmids was injected into the tail vein of an eight-week-old Fisher F-344 rat at the rate of 1 ml in 30 seconds. This corresponds to an intravenous injection of 100 μg of plasmid DNA.

2.3 This injection was repeated twice, eight days apart (or as many times and at a rate recognized as necessary to observe transfection of cells of the organ concerned).

2.4 The day after the last injection, the animal was sacrificed and the hepatocytes isolated by collagenase infusion (Williams et al., 1977, In Vitro 13, 808-817).

The culture medium used was WME medium (Williams et al., 1974, Exp. Cell. Res. 89, 139-142) containing 10% fetal calf serum as well as. insulin and cortisol. After 28 h of culture, the cells were maintained with WME medium supplemented with 2% of Ultroser G® (L B) which is a serum substitute. It contains, in a standardized way, proteins including albumin and transferrin, essential fatty acids, growth factors including EGF (Epidermal Growth Factor) as well as hormones including insulin and dexamethasone. This substitute was chosen for its constant contributions in growth factors and hormones.

A test was carried out in parallel on a control rat, using liposomes produced in the absence of plasmids.

3. Results:

3.1 Proliferation of hepatocytes:

During the first two days of culture, no difference in terms of cell morphology could be detected under an optical microscope between the two preparations of hepatocytes originating, on the one hand, from the rat having received liposomes encapsulating plasmids and, on the other hand, from the rat having received liposomes without plasmids. In the days that followed, mitotic cell domes began to appear in cultures from the liver of rats that received injections of liposomes encapsulating the plasmids. These rounded cells have continuously detached from the hepatocyte mat to form clusters of cells growing in suspension. After 25 days of culture, there were no more hepatocyte plaques in the flasks of the primary culture of hepatocytes from the control rat, while in the culture originating from the rat treated with the liposomes encapsulating the plasmids, the cell layer had remained intact. This has been observed for more than 75 days.

These cells kept a typical morphology of hepatocytes during this whole period. However, transformed cells continued to divide continuously, detaching themselves from the layer of spread cells.

These cells in suspension were recovered from the culture medium, by centrifugation at 65 g for 10 min and were then re-seeded in new flasks, in the same medium. Under these conditions, they became attached and proliferated. Cell viability, estimated by the exclusion of trypane blue, was greater than 95%. On the 17th day after placing in culture, the cultures of the used culture medium originating from ten flasks were combined, that is to say 5.10 ⁶ cells, to be seeded, in suspension, without the aid of spherical microcarriers, in a biogenerator, in a final volume of 200 ml of the same culture medium. They have kept their proliferation in suspension. In parallel, a culture plate containing 24 culture wells of 2 cm 2 was seeded at the rate of approximately 10 cells per well. The culture medium of the biogenerator was changed every three days, that of the flasks and of the 24-well plate every two days. After six days of culture, the number of cells in the biogenerator was evaluated at 21.10? cells, which corresponds to a growth of 5.4 cell generations. The doubling time of the cell population was therefore 27 hours. In 25 cm ² culture flasks, these parameters could be estimated at 4.7 generations in five days, corresponding to a doubling time of the cell population of 26 hours, therefore very comparable to that of cells cultured in suspension.

3.2 Secretion of hGH and selection by geneticin:

The cells cultivated in the 24-well culture plate underwent a hyperthermic shock of 43 ° C for 3 h. The hGH was assayed by RIA in each culture medium collected 24 h later. In 3 of the 24 wells, hGH was produced at respective rates of 5, 8 and 20 ng / 10 ^ cells / 24 h. The cells of the most productive population were subcultured and seeded in 24 other wells. A new hyperthermic shock was applied 8 days later. HGH was found in 4 of the 24 media collected, at the rate of 3, 5, 9 and 31 ng / 10 ⁶ cells / 24 h. 3.3 Rat albumin and transferrin secretion:

The recombinant cells, cultivated in a flask, expressed these two endogenous proteins for a period extending beyond 75 days of culture at rates close to, or even higher than, those of freshly isolated hepatocytes, namely between 15 and 26 μg / 10 ^ cells / 24 h for albumin and around 1.1 μg / 10 ^ cells / 24 h for transferrin.

The results obtained are collated in Table I which follows.

TABLE I

SECRETION OF ALBUMIN AND TRANSFERRIN BY RAT HEPATOCYTES TRANSFORMED IN VTVO AR CO-TRANSFECΗON WITH PLASMIDES pEJ AND p! 7hGHneo AND CULTIVES IN 75 cm ² BOTTLES.

3.4 Biosynthesis of primary bile acids from rat liver:

The production of bile acids by the cells cultivated in a biogenerator 70 days after the culture was measured by gas chromatography-mass spectrometry (Tsaconas et al., 1986, Anal. Biochem. 157, 300-315). The free bile acids were separated from the conjugates by thin layer chromatography. The bile acids that were identified were chenodeoxycholic acid (CDC) and cholic acid (CH). These are the two major primary bile acids in rat liver.

The production rates were:

- free fraction: CDC: 1.7 nmol / mg of cellular protein / 24 h and CH: 3.5 nmol / mg cellular protein / 24 h. The CDC / (CH + CDC) ratio is equal to 33%, a proportion normally observed in the hepatic secretion of these primary bile acids:

- conjugate fraction: CDC: 2.6 nmol / mg of cellular protein / 24 h and CH: 5.2 nmol / mg of cellular protein / 24 h.

Compared to the in vivo production rates of free and conjugated primary bile acids, this secretion which corresponds to 13.1 nmol / mg of cellular protein / 24 h represents approximately 1.5 to 2 times that of normal liver. However it should be noted that, in the organ, the hepatocytes constitute 90% of the liver and that it is especially the hepatocytes of the external zone of the hepatic globule which synthesize the bile acids, whereas probably all the recombined cells are responsible for this biosynthesis . On the other hand, the analyzed fraction of bile steroids contained, within the limit of normal values, neutral bile sterols of the hydroxycholesterol and ketocholesterol type, as well as other bile acids dihydroxylated and trihydroxylated which normally accompany the secretion of chenodeoxycholic acid and cholic acid.

This example demonstrates that hepatocytes can be transfected in vivo, in situ in the liver, by two plasmids, each encapsulated in liposomes. One, pEJ, vector of the mutated Harvey cell oncogene ras and the other p! 7hGHneo, vector of the expression gene for human growth hormone and the selection gene for resistance to neomycin, in order to then obtain, by explantation of the hepatic gland, hepatocytes capable of proliferating in culture and of expressing the recombinant gene, coding for the synthesis of the protein of therapeutic interest.

The hepatocytes transfected in vivo by the plasmids pEJ and pl7hGHneo, encapsulated in liposomes, injected into the tail vein and cultured, are therefore able to proliferate in vitro, they retain specific functions of the liver, well beyond two months of culture. Part of these hepatocytes, not cloned for this activity, secrete human growth hormone in the culture medium.

The results of this in vivo transfection work demonstrate the reality of the transfer of the genetic material from the plasmid encapsulated in liposomes when transported in this form by venous blood to the liver cells of the intact animal, and ultimately captured. The recombination of an oncogenetic gene makes it possible to obtain differentiated hepatocytes which proliferate in culture, while expressing specific functions of the liver: biosynthesis of albumin, transferrin and free and conjugated bile acids, metabolism of endogenous compounds and metabolism of senobio tics, involving the activity of mono-oxygenases with cytochromes P-450. In comparison, the hepatocytes of normal rats, and therefore of untreated rats, are only kept in culture for a few days, quickly losing these functions before lysing, as is well known.

The cloning of hepatocytes made proliferative should make it possible to obtain lines of transformed hepatocytes which would keep a high level of fundamental hepatic activity, thus making it possible to study the metabolism of endogenous compounds coming from other tissues and of xenobiotic compounds produced by chemistry. industrial and pharmacy. At the same time, this model constitutes a tool of great interest for work on the expression of oncogenic genes and genes coding for the biosynthesis of proteins, for industrial production.

Example 2

The expression in human growth hormone resulting from transfection in vivo was carried out as described below.

1. Expression vector:

The plasmids used are the plasmids pl7hGHneo and pl7HBN which both contain the hybrid gene hsp70-hGH (Dreano et al., 1988, Bio / Technology 6, 953-958).

2. Transfection:

2.1) Monolamellar liposomes were prepared according to the method of Deamer et al., 1976, Biochem. Biophys. Acta 433, 629-634, from 2 mg of phosphatidylcholine dissolved in 1 ml of chloroform and taken up, after evaporation, in 1 ml of diethyl ether. The final liposome suspensions are produced in 1 ml of complete basic synthetic culture medium but without serum, containing either 100 μg of plasmid DNA pl7HBN or 100 μg of plasmid DNA pl7hGHneo or no DNA. These solutions are freed from diethyl ether by bubbling air-C02 (95: 5, v / v), at 20 ° C, while equilibrating the medium at physiological pH with a buffer system, in order to injection.

2.2 Each suspension of liposomes (encapsulating the plasmids) was injected into the tail vein of an eight-week-old Fisher F-344 rat at the rate of 1 ml in 30 seconds.

2.3 This injection is repeated twice, eight days apart (or as many times and at a rate recognized as necessary to observe a transfection of cells of the organs concerned.

2.4 1, 2 and 7 days after the injection, the animals were subjected to thermal stress by raising the ambient temperature to 45 ° C. for 20 min. 1 day after each heat induction, 1 ml of blood from each rat was taken and immediately centrifuged to collect the plasma.

2.5 HGH was assayed by radioimmunoassay (radioimmunoassay, RIA) in the plasma of the three rats (see Table II below).

In analyzes of animal serum injected with liposomes. empty, a weak signal was observed, probably due to a nonspecific reaction between rat growth hormone and RIA anti-hGH antibodies.

The plasma samples from rats injected with liposomes encapsulating plasmids p! 7HBN or pl7hGHneo contained between 4 and 6 times more GH than those of the control rat. The rats synthesized hGH well after the injection of the liposomes encapsulating one or other of the vector plasmids of the hGH gene.

The assay of the hGH secreted in the blood of the transfected animal was carried out either by radioimmunoassay (hGH-RIA kit, Pasteur Diagnostics, F-92430 Marnes-la-Coquette), or by ELISA immunoenzymatic assay on spherical supports (Sensibead EIA Kit, Terumo Médical Corp., Elkton, MD 21921). TABLE H

IN VIVO EXPRESSION IN HGH RAT AFTER INJECTION OF

LIPOSOMES CONTAINING EITHER pl7HBN, EITHER pl7hGHneo.

Example 3

The expression in antibodies to human growth hormone resulting from the following in vivo transfection was carried out as described below.

Two 10-week Fisher F-344 rats received, on the first, twentieth and twenty-seventh days of the experiment, a metacardiac injection of liposomes prepared according to Example 1, encapsulating the plasmid p! 7HBN or p17hGHneo. The animals were subjected to a thermal stress of 20 min at 45 ° C every 3 to 5 days after the first injection. The blood of each animal was taken on the thirtieth day of the experiment and was used to prepare the serum.

At the same time, cells of line 6, obtained by transfection of NIH-3T3 cells with plasmids containing the c- ras oncogene and the hGH gene under the control of the promoter of the human hsp70 gene (Dreano et al., 1986, Gene 49, 1-8), ^" were incubated at 43 ° C for 2 hours, then 24 hours at 37 ° C in the presence of [35S] -methionine.

The culture supernatants of these cells (0.5 ml) were used to detect the presence of anti-hGH antibodies by the immunoprecipitation technique. Briefly, they were incubated at 4 ° C. for 3 hours either with rat sera injected with the liposomes encapsulating p! 7hGHneo or plTHBN either with an untreated rat serum or with a rabbit serum hyperimmunized against hGH (DAKO ). ^'The reaction mixtures were then brought into contact with protein-A Sepharose for 20 hours at 4 ° C. After centrifugation, the immune complexes linked to protein A of the sepharose beads (beads) were washed three times with NET-NP40 buffer (100 mM NaCl, ImM EDTA, 10 mM Tris pH 7.5, 0.5% NP40) and twice with A RIP A-urea buffer (1M urea, 1% Na deoxycholate, 1% NP40, 0.05 M Tris pH 7.5, 0.15 M NaCl, 0.02 M EDTA). The beads were finally resuspended in 50 μl of "sample buffer" (50 mM Tris HC1 pH 6.8, 1% SDS, 10% Glycerol, 0.005% Bromophenol blue, 1.4 M 2- mercaptoethanol) and then brought to boiling for 2 min at 100 ° C. The supernatants were analyzed by electrophoresis on 15% acrylamide gel - SDS (Laemmli, 1970, Nature 227, 680-685).

The results of FIG. 1 show a protein of the molecular weight of hGH (22 kd, indicated by an arrow without tail) whose size was calculated by comparison with the position of proteins of known molecular weight whose position is indicated by a arrow to the left of the figure). The radioactive hGH thus detected was immunoprecipitated by the sera of animals injected with the liposomes encapsulating both the plasmid pl7HBN (1) and p! 7hGHneo (2), and this in a manner comparable to the hGH immunoprecipitated by the serum of commercial rabbit (+). This protein is absent from the sample analyzed with the serum from the untreated rat (-) • Example 4

The expression in the rabbit of antibodies directed against human growth hormone resulting from the transfection was carried out in the manner described below.

Three New Zealand rabbits (K.f.m., Switzerland) from 8 to 10 weeks weeks received injections of liposomes, prepared according to example 2, encapsulating the plasmid p! 7hGHneo in the ear vein. The animals underwent heat stress, by raising the ambient temperature to 43 ° C for 30 min, two and seven days after injection. The same experimental protocol was repeated 1 time six months later. A few ml of blood from each animal were then taken and were used to prepare the sera.

The sera were analyzed according to the technique described in Example 3 and compared to the serum of an untreated rabbit and to the serum of a rabbit hyperimmunized against hGH (DAKO).

The results, presented in FIG. 2, show a band corresponding to a molecular weight of approximately 22 kd (molecular weight of hGH, indicated by an arrow without tail) in the samples containing either the commercial serum (+) or the sera from the 3 rabbits injected with the liposomes encapsulating the plasmid p! 7hGHneo (1, 2, 3). This band is absent in the sample containing untreated rabbit serum (-).

As is apparent from the examples above, the transfer of a plasmid DNA by means of liposomes injected in vivo into an animal, in particular the rat and the rabbit, made it possible to express the gene coding for human growth hormone (hGH). This hGH was found in the blood of a rat thus treated, secreted until the last sample taken, 20 days after transfection. Subsequently, the results of Examples 3 and 4 show the presence of anti-hGH antibodies in the serum rats or rabbits injected with the liposomes encapsulating pl7hGHneo or pl7HBN thus confirming that this technique allows the synthesis in vivo of a protein encoded by heterologous DNA injected into liposomes and that the animal's immune response can be stimulated without injecting the antigen. In addition, the detection of anti-hGH antibodies in both the blood circulating from rats to "transfected" rabbits formally demonstrates expression of the hGH gene by "transfected" animals.

It goes without saying that the method according to the invention makes it possible to obtain hyperimmunized animals which can be used subsequently as a source of biological material for the production of monodonal antibodies.

After culturing the liver of the rat subjected to transfection, the cultured recombinant hepatocytes furthermore secreted hGH 30 days after the cultivation, ie 50 days after the transfection. Co-transfection of hepatocytes from rats or any other animal with a vector plasmid of a selection gene and a vector plasmid of an expression gene of biotechnological interest is therefore possible in vivo. This model makes it possible to obtain highly specialized cells, capable of proliferating in vivo, after explantation and then selection in cell culture of the organ of the "transfected" animal. In the case of hepatocytes, these proliferative recombinant cells express hepatic functions, together with the recombinant gene.

Possibility of industrial application

The expression method by in vivo transfection according to the invention is of great interest for producing differentiated cells capable of proliferating in vitro having industrial applications inter alia in the fields of pharmacology, toxicology and carcinogenesis. On the other hand, it makes it possible to insert or reinsert in vivo an unexpressed gene leading to the in vivo synthesis of heterologous biologically active or antigenic proteins. This latter application allows either to vaccinate animals or to use them for the production of antibodies.

Claims

claims

1. Method for the genetic expression of heterologous proteins by cells transfected in vivo using at least one expression vector for a gene encapsulated in liposomes, according to which a suspension of liposomes in which the vector is prepared of expression is encapsulated and this suspension of liposomes is injected into the circulating blood of an animal, characterized in that: a) a suspension of liposomes encapsulating at least one carrier vector is injected into the animal expression containing a gene coding for an oncogene, so that differentiated cells of the animal, thus transfected, can produce the oncogene, b) an organ is removed from the animal containing the transfected cells which express the oncogene , and c) the cells of the organ removed are cultured in vitro so as to obtain cells which express the oncogene and which are capable of proliferating in vitro.

2. Method according to claim 1, characterized in that one injects a suspension of liposomes further encapsulating an expression vector containing a gene coding for another desired protein, so as to be able to obtain said cells which express the oncogene as well as the other protein.

3. Method according to claim 1 or 2, characterized in that said expression vector contains a gene coding for a cellular oncogene.

4. Method according to claim 1 or 2, characterized in that said expression vector contains the gene for the c-ras ogen from Harvey.

5. Method according to claim 1 or 2, characterized in that said differentiated transfected cells are hepatocytes.

6. Method according to claim 2, characterized in that the gene coding for said desired protein is the gene for human growth hormone.

7. Method for the genetic expression of heterologous proteins by cells transfected in vivo using at least one gene expression vector encapsulated in liposomes, according to which a liposome suspension is prepared in which the vectors expression are encapsulated and this suspension of liposomes is injected into an animal, characterized in that: a) a suspension of liposomes encapsulating an expression vector containing a gene coding for the protein d is injected into the animal interest under the control of a promoter of the heat shock protein gene, so that the transfected cells of the animal can produce the protein of interest in vivo, b) the animal is subjected to a heat shock of so as to promote the expression of genes under the control of said gene promoter, c) the circulating blood of the animal is removed from the proteins of interest or antibodies directed against this protein, and d) the process is repeated e these injection (a), thermal shock (b) and sampling (c) operations the number of times necessary to obtain an adequate synthesis of the protein or of the antibodies.

8. Method according to claim 7, characterized in that the gene coding for said desired protein is the gene for human growth hormone.

9. The method of claim 7, characterized in that said promoter of the heat shock protein gene is that of a human protein with a molecular weight of 70 kd.

10. Method according to claim 1 or 7, characterized in that the said expression vector is encapsulated in neutral monolamellar liposomes.

11. Method according to claim 1 or 7, characterized in that said liposome suspension is injected into a rat or a rabbit.

12. Method according to claim 1 or 7, characterized in that the vector used is a plasmid.

13. Method according to claim 1 or 7, characterized in that by means of the injected vector or vectors, the cells are transfected either by one or more expression genes and one or more selection genes, or one or more selection genes.

14. Heterologous protein as produced in vitro or in vivo by transfected cells according to claims 1 or 7.

15. Cells capable of proliferating in vitro, resulting from transfection in vivo, by implementing the method according to claim 1.

16. Cells according to claim 15, characterized in that they are hepatocytes.

17. Antibodies directed against the protein expressed in vivo by the cells transfected by implementing the method according to claim 7.