EP0644898A1 - Filamentous fungus proteins for binding and transporting lipids, preparation method therefor and use thereof - Google Patents

Abstract

A family of lipid binding and transporting proteins, a method for preparing same from fungi, and their use in cosmeticology, the agri-foodstuffs industry and pharmacology, are disclosed. Said proteins are capable of binding, transporting and/or rearranging lipids between membranes, optionally in combination with active principles. Furthermore, the proteins are hydrophobic and acidic, have a molecular weight of under 50 kDa, and may be prepared from a non-toxic filamentous fungus capable of developing on a lipid-enriched medium, particularly from raw extracts of said fungi.

Description

FILAMENTOUS MUSHROOM PROTEINS CAPABLE OF FIXING AND TRANSPORTING LIPIDS, PROCESS FOR OBTAINING SAME AND APPLICATIONS THEREOF.

The present invention relates to a family of proteins for fixing and transporting lipids, to their process for obtaining from mushrooms, as well as to their applications in cosmetology, in the food industry and in pharmacy field. The present invention also relates to crude extracts of fungi containing such proteins and to their applications in the field of pharmacy, cosmetology and in the agro-food field. Phospholipid transfer proteins

(PTPL) have been isolated from fungi, such as Mucor mucedo, Aspergillus ochraceus or Neurospora crassa

(Intern. J. Biochem., 1990, 22, 1, 93-98; Develop. Plant

Biol., 1984, £, 303-306; BBA, 1992, 1126, 2, 286-290), from cultures of fungi, produced on synthetic media using glucose, as a carbon source. However, the cultivation of fungi on such synthetic media makes it possible to obtain only small amounts of PTPL (very low yields); consequently, such cultivation methods are not of industrial application.

The need for a process for obtaining, in large quantities, proteins for fixing and transporting lipids, capable of carrying out intermembrane transport of lipids and obtaining proteins allowing selective transport of certain phospholi¬ pides [(phosphatidylglycerol (PG), phosphatidylinositol (PI)] is crucially felt, in particular to improve the effectiveness of the action of liposomes, the applications of which are numerous both in the field of medicine and in cosmetology and in general, to produce modified biomembranes.

The present invention has therefore given itself the aim of providing phospholipid transfer proteins (PTPL), capable of being produced in large quantities by filamentous fungi and capable of carrying out selective intermembrane transport of lipids (phospholipids and sterols ) and active ingredients; such proteins better meet the needs of the practice, in particular in that they improve the biological and surfactant activities of the membranes.

In fact, the membranes are the seat of many functions in the development of living organisms (cell recognition and exchange, breathing, excretion, etc.) and constitute a difficultly modifiable barrier; however, the engineering of biomembranes involves modifying their composition and organization.

The present invention relates to a process for the preparation of phospholipid transfer proteins (PTPL), from non-toxic filamentous fungi of the type comprising the preparation of a crude extract, the separation of proteins from said extract and the purification of said proteins, which process is characterized in that said fungi are cultured in a medium rich in phospholipids.

According to an advantageous embodiment of said method, said culture medium rich in phospho¬ lipids comprises between 3 and 20 g / 1 of phospholipids. According to another advantageous embodiment of said method, it comprises:

(1) the preparation of a crude extract at substantially neutral pH by:

(a) cultivation of said mushrooms in said medium rich in phospholipids, until a sufficient quantity of mycelium is obtained, (b) grinding said mycelia in an extraction buffer at neutral pH,

(c) separation of the crude extract containing the proteins for fixing and transferring lipids, from said ground material, by centrifuging said ground material at a speed greater than 20,000 g (first centrifugation) and recovering the supernatant IF,

. acid precipitation of the supernatant S1, followed by centrifugation at a speed greater than 20,000 g (second centrifugation) and recovery of the supernatant S2,

(d) obtaining the crude extract containing the said lipid-binding and transfer proteins, from the supernatant Ξ2, buffered at substantially neutral pH,

(2) the concentration of proteins by ultrafiltration,

(3) separation of the fractions exhibiting lipid binding and transfer activity by gel, filtration and selection of the active fractions by measuring the lipid binding and transfer activity, and

(4) the purification of the proteins of the different selected fractions, by a succession of chromatographic steps, which proteins obtained, are capable of carrying out the fixing, transport and / or rearrangement intermembranaires of lipids, possibly associated with active principles, are hydrophobic and acidic, and have a molecular weight of less than 50 kDa.

According to another advantageous embodiment of said process, said filamentous fungi are selected from the group which comprises Ascomycetes chosen from Aspergillus candidus, A. flavipes, A. fumigatus, A. giganteus, A. niger, A. ochraceus, A. oryzae, A. terreus, A. versicolor, A. wentii, Penicillium roque- fortii and Eurotium chevalieri, the Zygomycetes chosen from Mucor mucedo and Rhizopus stolonifer and the Basidio-fungi selected from the species Phanerochaete chryso spori um.

Within the meaning of the present invention, these different groups include both the parent strains and the variants or mutants of these parent strains.

The various abovementioned strains, without limitation, are in particular deposited with collections, as specified in the table below:

These different strains are accessible, depending on the case, at the Laboratory of Microbiology and Cereal Technology (LMTC) of 1 INRA in Nantes, at the Mycotheque of the Catholic University of Louvain (MUCL, Belgium) and at the Laboratory of Biotechnology of Filamentous Mushrooms (LBCF) from INRA in Marseille.

According to yet another advantageous embodiment of said method, step (a) further includes:

* culturing said mushrooms on a sporulation medium,

* incubation for 2 to 13 days until a sufficient quantity of spores is obtained, * culturing said spores on said culture medium rich in phospholipids, and

* incubation until a sufficient quantity of mycelium is obtained. According to an advantageous arrangement of this embodiment, the sporulation medium is advantageously made up of whole corn grains, moistened.

According to another advantageous embodiment of said process, the acid precipitation of step (c) is carried out at pH 5.1.

Acid precipitation, preferably at pH 5.1, has the advantage of ridding lipid transfer proteins of soluble lipoprotein complexes, which interfere in phospholipid transfer assays. It is, moreover, necessary to bring the pH of the crude extract to neutral pH, so as to stabilize said proteins.

According to yet another advantageous embodiment of said method, steps (b) and (c) are carried out cold.

According to another advantageous embodiment of said method, the filamentous fungus is a strain of filamentous fungus A. oryzae. According to an advantageous arrangement of this embodiment, step (5) provides a protein having a lipid transfer activity and having a molecular weight of approximately 19 kDa.

According to another advantageous arrangement of this embodiment, step (5) provides a protein having a lipid transfer activity and having a molecular weight of approximately 30 kDa.

Unexpectedly, the use of phos¬ pholipids as a carbon source, specifically increases the endoplasmic reticulum of cells (xlO-20) (place of synthesis of phospholipids) and therefore the syn- transfer protein thesis, and therefore allows to obtain a significant biomass with increased metabolic activities towards membrane lipids. Under these conditions, the synthesis of phospholipid transfer proteins is increased and presents an important industrial interest.

The present invention also relates to purified preparations of lipid binding and transfer proteins, characterized: - in that they are capable of carrying out the intermixture fixing, transport and / or rearrangement of lipids, possibly associated to active principles,

- in that they are capable of being obtained from a crude extract of a non-toxic filamentous fungus, cultured on a medium rich in phospholipids, which fungus is selected from the group comprising Ascomycetes chosen from Aspergillus candidus, A. flavipes, A. fumi gatus, A. giganteus, A. niger, A. oryzae, A. terreus, A. versicolor, A. wentii, Penicillium roquefortii and Eurotium chevalieri, Zygomycete Rhizopus stolonifer and Basidiomycete Phanerochaete chrysosporium, the said proteins having a specific phospholipid transfer activity expressed in nmoles of phosphatidylcholine transferred per minute and per mg of protein, equal or higher 0.3 nmol / min / mg,

- in that they are hydrophobic and acidic, and - in that they have a molecular weight of less than 50 kDa.

These acidic proteins of fungal origin make it possible, by virtue of their capacity for intermembrane fixation, transport and transfer of lipids (phospholipids and sterols), to surprisingly improve the biological and surfactant activities cell membranes and biomembranes.

According to an advantageous embodiment of the invention, said purified protein preparations can preferably be obtained from the filamentous fungus strain A. oryzae.

According to an advantageous arrangement of this embodiment, said acid lipid transfer proteins have a molecular weight of approximately 19 kDa.

According to another advantageous arrangement of this embodiment, said acid lipid transfer proteins have a molecular weight of approximately 30 kDa.

Both the 19 kDa protein and the 30 kDa protein are active for lipid transfer; however, the 30 kDa protein is more active than the 19 kDa protein for the transfer of phosphatidylcholine.

According to the invention, such PTPL ensure the specific and preferential transport of phosphatidylglycerol and phosphatidylinositol; with regard to the other phospholipids, the order of importance of the transfer of phospholipids is as follows: phosphatidylcholine> phosphatidylethanolamine> phosphatidylserine. Such proteins find application in pharmacy, in cosmetology and in the agroalimentary field, associated with lipids and preferably with liposomes. They are advantageously associated with the latter, either in the external phase or in the internal phase, in an encapsulated form.

In general, such lipid binding and transfer proteins, also known as protein shuttles, improve the effectiveness of the action of liposomes, by their use as "natural vectors" of phospholipids and other hydro- phobes, in all applications of these. In the drug field, the shuttle proteins according to the invention constitute vectors of active principles and make it possible to select the cells to be reached. In the food industry, these proteins allow, in particular, the development of soy lecithins (main sources of phospholipids).

The present invention also relates to crude extracts of filamentous fungi, characterized in that they are capable of being obtained from a non-toxic filamentous fungus by:

(a) culturing said mushrooms in a medium rich in phospholipids, until a sufficient quantity of mycelium is obtained,

(b) grinding said mycelia in an extraction buffer at neutral pH,

(c) separation of the crude extract containing the proteins for fixing and transferring lipids, from said ground material, by centrifuging said ground material at a speed greater than 20,000 g (first centrifugation) and recovering the supernatant IF,

. acid precipitation of the supernatant S1, followed by centrifugation at a speed greater than 20,000 g (second centrifugation) and recovery of the supernatant S2,

(d) obtaining the crude extract containing the said lipid-binding and transfer proteins, from the supernatant S2, buffered at substantially neutral pH.

According to an advantageous arrangement of this embodiment, step (a) includes:

* culturing said mushrooms on a natural sporulation medium,

* incubation for 2 to 13 days up to obtaining a sufficient quantity of spores,

* culturing said spores on a culture medium rich in phospholipids, and

* incubation until a sufficient quantity of mycelium is obtained.

According to an advantageous modality of this dispo¬ sition, the sporulation medium advantageously consists of whole corn grains, moistened.

In addition to the foregoing provisions, the invention also comprises other provisions, which will emerge from the description which follows, which refers to examples of implementation of the method which is the subject of the present invention.

It should be understood, however, that these examples are given solely by way of illustration of the subject of the invention, of which they do not in any way constitute a limitation.

EXAMPLE 1 Obtaining a crude extract containing the PTL. 1. Principle.

The following steps consist in extracting the proteins after grinding the mycelium obtained by culture on a medium rich in phospholipids, and in determining the activity of transfer of phospholipids from the extract by fluorescence spectrometry, using don liposomes. ¬ of fluorescent probes and acceptor liposomes, unlabeled.

2. Selected strains.

Fifteen strains of molds belonging to the classes of Zygomycetes (order Mucorales), Asco-mycetes and Basidiomycetes were selected.

These strains originate from and are the property of the Laboratory of Cereal Microbiology and Technology (LMTC) of INRA in Nantes, the Mycotheque of the Catholic University of Louvain (MUCL, Belgium) and the Biotechnology Laboratory Filamentous Mushrooms (LBCF) of 1 INRA in Marseille. Their list is given below. Ascomycetes:

Euroti um chevali eri Anamorphic species:

Aspergillus candi due A. flavipes A. fumigatus A. giganteus A. Niger

AT . ochraceus A. oryzae A. terreus A. versi color A. wentii

Penicillium roquefortii

* Zygomycetes: .Mucor mucedo

Rhizopus stolonifer

* Bθsidiomycète: Phanerochaete chrysosporium 3. Preparation of inoculums and realization of cultures.

The strains are cultivated in the laboratory on a natural medium, namely on whole corn kernels, humidified 48 hours at 4 ° C (on average 40 grains per 100 ml flask) and sterilized twice 30 min at 110 "C . incubation is carried out at 25 ^° C for 10 to 13 days (maximum). during this period, the mycelium develops on the surface of the grains by producing spores. These spores are detached from the surface of the grains by stirring glass beads (3 mm diameter) bathed in a sterile Tween 80 solution, 0.033 g / l (in order to avoid flocculation of the spores). The spore suspension thus obtained is filtered through glass wool, in order to remove mycelial fragments and grain debris. A count is carried out on a Malassez cell. We can then quantify the inoculum of cultures by using an aliquot of known volume of the solution of spores. The concentration of the mother solution is generally of the order of 2.10 'spores / ml.

Two other sporulation media were tested with A. oryzae: soybeans (rich in phospholipids) moistened and sterilized twice 30 min at 110 ° C and a synthetic medium (MYA2), composed of solid malt (20 g / L), yeast extract (1 g / 1) and agar

(13 g / 1) autoclaved 20 min at 120 ° C.

100 ml of culture medium (composition detailed below) are used in baffled vials of 500 ml capacity. These media are inoculated with spores, at a rate of 2.10 ⁵ spores / ml. The cultures are incubated at 25 ^° C. and subjected to rotary shaking of 120 rotations / min for 3 days. At the end of this incubation period, the mycelium is filtered through sintered glass (n ^* 2), weighed, then frozen at -20 ° C. * Composition of the culture medium:

- KH ₂ P0 ₄ 0.2 g / 1

- MgS0 ₄ , 7H ₂ 0 0.5 g / 1

- CaCl ₂ , 2H ₂ 0 0.0132 g / 1

- Ammonium tartrate 1.84 g / 1 - Yeast extract 0.5 g / 1

- Source of phospholipids 3-20 g / 1

The source of phospholipids is preferably a mixture of phospholipids depleted in phosphatidylcholine. * Preparation:

It is carried out from the following volumes:

- 50 ml of sterile distilled water,

- 10 ml of stock solution 1: KH2PO 2 g / 1, MgS0, 7H ₂ 0 5 g / 1, CaCl ₂ , 2H ₂ 0 0.132 g / 1, autoclave in a vial 20 min at 120 'C and stored at 4' VS, - 10 ml of stock solution 2: ammonium tartrate 18.4 g / 1 autoclave 20 min at 120 "C and stored at 4'C,

- 10 ml of stock solution 3: yeast extract 5 g / 1, autoclave 20 min at 120'C and stored at 4'C, - 20 ml of stock solution 4: Nat 89 at 50 g / L, prepared using a ultrasonic bath, then stirred. The solution is then autoclaved for 20 min at 120 ° C. and stored at 4 ° C.

4. Obtaining the raw extract. 2 grams of mycelium (fresh weight) are ground at 0 ° C in the presence of approximately 2 g of Fontainebleau sand in a mortar using a pestle. The sand was washed with a HCl solution, rinsed several times with water, then sterilized at 200 ° C, 30 min in a Pasteur oven.

The grinding is carried out in a buffer containing a solution of Tris-HCl 100 mM pH 7.0, supplemented with EDTA 2 mM (inhibitor of proteases-dependent cations), sucrose 400 mM (osmotic protective agent), dithiothreitol 2 mM and 8 mM 2-mercaptoethanol (reducing agents).

The following steps (centrifugation and obtaining the raw extract) are described in FIG. 1.

Acid precipitation at pH 5.1 offers the advantage of ridding the phosipolipid transfer proteins from the soluble lipoprotein complexes which interfere in the phospholipid transfer tests.

In the final step, the pH is reduced to 7.8 to stabilize the proteins.

5. Demonstration of the presence of lipid transfer proteins. a) Principle:

The transfer measurements are carried out by monitoring the increase in fluorescence in a dilution buffer, after addition of a protein solution contained the phospholipid transfer proteins, to a mixture of labeled donor liposomes A (with a pyrene monomer), blocked by the "quenching" effect, and an excess of unlabeled recipient liposomes B. The "quenching" effect comes down to a decrease, or even an inhibition of fluorescence, due to too high a concentration of the probe.

The phospholipid transfer activity is followed by the movements of the probe between the two populations of liposomes after addition of the fungal protein extract, in accordance with FIG. 2, which illustrates this measurement of phospholipid transfer via the ¬ medium of protein shuttles from a donor liposome A (•) consisting of phosphatidylcholine pyrene (fluorescent probe) to an acceptor liposome B (O) consisting of egg phosphatidylcholine. b) Apparatus:

A SLM 4800 C Aminco spectrofluorometer (USA) is used for the measurements. The light source is a xenon lamp. The excitation (Glan Thomson) and emission (polaroid polarizing film) monochromators select respectively the wavelengths of 346 and 378 nm. A corrected measurement of the variations in the lamp is obtained by dividing the emission signal of the analyzed solution by that observed with the reference solution (rhodamine cell). The device is equipped with a tank rack thermostated by water circulation. The spectrofluorimeter is controlled by a microcomputer which allows data acquisition and processing. c) Donor A liposomes:

. Reagents: the fluorescent probe used is 3-palmitoyl-2- (1 pyrene decanoyl) -L α phosphati¬ dylcholine (Molecular Probes, USA) with molecular weight 852 (see Figure 2). It is in the form of a dry extract of 1.17 μmol / mg in a plastic tube, stored at -20 ° C It has a maximum excitation at 346 n and a maximum emission at 378 nm.

. Preparation: the content is dissolved in

10 ml of absolute alcohol. This mother solution has a concentration of 117 mM. It is conditioned in volume of

0.5 ml in glass tubes and stored at -20 ° C protected from light.

For the assay, a 10 μl test portion provides 1.17 nmol of the probe in the assay tank. d) Acceptor liposomes B:

. Reagent: the preparation of these liposomes is carried out using a solution of L this phosphatidyl¬ choline from egg yolk (see FIG. 2) at 100 mg / ml (dissolved in tetradecane (Sigma) and of molecular weight cular 775. Storage is done at -20 "C.

. Preparation: 385 μl of this solution are taken, evaporated for 15 min under a stream of nitrogen, then diluted in 10 ml of fluorescence buffer (20 mM Tris-HCl, 5 mM EDTA, 100 mM NaCl, pH 7, 4 filtered through 0.45 μ Millipore filter) to obtain a 5 mM suspension consisting of hetero¬ gene multilamellar vesicles (MLV).

To go to the stage of unilamelular vesicles (SUV), sonication is used. MLVs are subjected to ultrasound using a Vibra Cell (Sonic and Materials, Danbury, Connecticut, USA) fitted with a 1/2 microprobe. Sonication takes place in pulsation with an average power (position 4) and a cycle proportion of 50%. The operation is carried out twice 10 min with cooling in an ice bath. The solution obtained is filtered on a 0.2 μ Sartorius filter and stored at 4 ° C. e) Assay conditions: The assay is carried out in 1.5 ml of fluorescence buffer, with 10 μl of fluorescent material and 14 μl of the liposome solution. The liposome / probe ratio is 60, in order to be in excess of recipient vesicles.

The protein solution (50 μl) is added last to start the kinetics of phospholipid transfer between the two populations of liposomes. The reaction takes place at 25 ° C. f) Measurement conditions:

The fluorescence measurements are carried out in 10 mm quartz cells with 4 mm optical path in emission and excitation respectively.

The excitation and emission wavelengths are fixed respectively at 346 and 378 nm (maximum excitation and emission of the fluorescent probe) and the slots of the excitation and emission monochromators at 4 nm. g) Calculation of the phosipolipid transfer activity:

The transfer kinetics are performed over 1400 seconds with intensity records every 5 seconds. The transfer activity is represented by the initial slope of the kinetics (unit of the intensity of relative fluorescence over time).

The value of the relative transfer activity is calculated relative to the maximum value of fluororescence. This maximum is obtained by adding a 20% (W / V) SDS solution (50 μl) to the sample. The SDS dissociates the donor liposomes diluting all of the fluorescent probes in the measurement cell, thus eliminating the "quenching" effect. The fluorescence intensity obtained under these conditions therefore corresponds to the quantity of probe injected in the test (1.17 nmole).

The specific activity is obtained by carrying out the ratio of the relative activity on the quantity of protein which are brought into the test. The specific activity is expressed in nmoles of phosphatidylcholine transferred per minute and per mg of protein. 6. Results. a) Selection of strains having phospholipid transfer activity:

The cultures were harvested at the optimum of the phospholipid transfer activity (age of spores from corn kernels, 13 days and age of cultures, 3 days).

All the strains tested show an activity of phospholipid transfer, but with a strain which is clearly more efficient (Figure 3). It is Aspergillus oryzae which has twice the activity of A, candidus or A. Niger.

Figure 3 illustrates the specific activity (nmoles of phosphatidylcholine transferred / min / mg) in different strains. b) Comparison of the quality of different inocula:

A purely synthetic medium and a natural medium (soybeans) known for their richness in phospholipids were tested in addition to the corn kernels.

A maximum of phospholipid transfer activity is observed in three days of culture for A. ory¬ zae from an inoculum of corn kernels. From the second day, activity is detected and it decreases beyond three to four days (Figures 4 and 5).

Figure 4 illustrates the growth of A. oryzae from different inocula (-M-: corn; - • -: soy; -A-: MYA2) and has the number of days of culture on the abscissa and the dry weight (in g) of A on the ordinate. oryzae.

Figure 5 illustrates the phospholipid transfer activity of A. oryzae from different inocu¬ lums and has the number of days on the abscissa and in or¬ given the transfer activity of inoculums grown on corn (-O-), soybeans (-O-) or synthetic medium (MYA2) (- Δ-). The maximum transfer activity for A. oryzae from a spore inoculum on synthetic medium is three days as observed on corn kernels, but it is half that. Activity then tends to decrease, but less suddenly (Figures 4 and 5).

The transfer activity of A. oryzae from a spore inoculum on soybeans is at its maximum later, at five days. The activity is then slightly lower than with corn for inoculum (Figures 4 and 5).

In conclusion, the maximum phospholipid transfer activity is obtained with A. oryzae from an inoculum on corn kernels. The spores from the corn inoculum also respond more quickly to the needs of the cell.

EXAMPLE 2 Purification and characterization of proteins.

1) Purification:

The proteins are purified from the crude extract as obtained in Example 1, as shown diagrammatically in FIG. 6.

For this, 900 g of mycelium (wet weight) are ground in 3 liters of extraction buffer (Triε-HC1 100 mM pH 7.0, EDTA 2 mM, dithiothreitol 2 mM, 2- mercaptoethanol 8 M, sucrose 400 mM) .

The proteins of the crude extract are concentrated (supernatant of the acid precipitation at pH 5.1), by ultrafiltration.

The membrane used for the concentration of the crude extract (supernatant from precipitation at pH 5.1) is a Pelιcon PLGC membrane from Millipore. It has a cutoff threshold of 10 kDa and a surface of 0.1 m ² . ; such ultrafiltration makes it possible to concentrate the extract and to eliminate all the proteins with a molecular weight of less than 10 kDa.

Such a technique also has the advantage cause negligible protein loss; this is important, especially when the initial protein concentration is less than 1 mg / ml.

Purification itself involves several stages, and at each stage there are:

- control of transfer activity,

- electrophoresis on polyacrylamide gel in the presence of sodium dodecyl sulfate,

- protein dosage. * 1st purification step:

Gel filtration on Sephadex G75® column (2.6 x 100 cm) balanced with buffer B: Triε 50 mM, 2-mercaptoethanol 8 mM, NaCl 200 mM, glycerol 10% (w / v) pH 7.8, with a flow rate of 15 ml / hour. 5 ml fractiones are collected. The elution profile is shown in Figure 7 (A) or Figure 8 (A) and includes 2 activity peaks: Pi and P2. The active fraction are separated: fractions 38 to 52 for PI and 62 to 79 for P2.

* 2nd purification step: DEAE-Séphacel® (FPLC).

Leε two fractionε (about 300 ml) from Sephadex chromatography are loaded on DEAE-Sephacel column 2.6 x 15 cm after 1/2 dilution for P2 (in order to lower the ionic strength). The column is equilibrated beforehand with buffer A. The column is eluted until the optical density has returned to the base, in order to remove all the unbound proteins: a) the proteins of Pi are eluted with 200 ml of a linear gradient (200-700 ml NaCl), b) the protein of P2 is eluted with 350 ml of a linear gradient (100-500 ml NaCl).

The flow rate is 30 ml / hour and the collected fractions 5 ml.

The transfer activities corresponding to Pi and P2 are respectively eluted with the fractions 23-36

(approximately 500 nM in NaCl) and fractions 51-61 (approximately 350 mM NaCl).

* 3rd purification step:

3a. Sephacryl® S400 chromatography. 166 ml of the PI fraction from the DEAE are loaded onto a Sephacryl® S400 column (4.5 x 85 cm) balanced with buffer B. The flow rate is 60 ml / hour and the collected fractions are 5 ml. Figure 7 (C1) shows the profile with an activity peak for fractions 185 to 204.

3b. MonoQ® chromatography (FPLC). 30 ml of P2 from DEAE are loaded onto a MonoQ® HR 515 column balanced with buffer A. The elution of the active protein is carried out with 40 ml of a linear gradient from 0 to 500 mM in NaCl in the same stamp. The flow rate is 60 ml / hour and the fraction fraction collected is 2 ml. The phospholipid transfer activity is detected for approximately 120 mM in NaCl.

Molecular mass: a band of 30 kDa corresponding to the PI fraction is observed on polyacrylamide gel. A 19 kDa band is observed for the P2 fraction.

Figures 7 and 8 illustrate these different purification steps for the PI peak (Figure 7) and the P2 peak (Figure 8) and include in abεciεεeεε numberε fraction and ordinate, absorbance at 280 nm (left axis and line continuous) and the phospholipid transfer activity, measured on aliquots (A) and expressed in nmoleε of phoεphatidylcholine / min. (right axis). The NaCl gradient (mM) was established by conductivity measurement (dotted line). Figures 7 (A) and 8 (A) are equivalent and correspond to the filtration gel on the Sephadex® G75 column.

Figures 7 (B1) and 7 (Cl) illustrate the 2nd and 3rd stages of purification of the PI peak (DEAE column, gradient 200-700 mM and Sephacryl® S400).

Figures 8 (B1) and 8 (Cl) illustrate the 2nd and 3rd stage of purification of the peak P2 (DEAE column, gradient 100-500 mM and MonoQ®, gradient 100-500 mM).

2) Characterization of phospholipid transfer proteins: - Molecular specificity:

The molecular specificity is determined by fluorescence using fluorescent probes (pyrene) as in Example 1. The donor and acceptor lipoεomes are prepared by injection of an ethanolic solution of phospholipids in an appropriate buffer, according to the method of G. LAFER (Biochimica and Biophysica Acta, 1991, 1069, 139-144).

The proteins according to the invention and in particular those obtained from A. oryzae have the originality of transporting more specifically phosphatidylglycerol and phosphatidylinositol. Preferably in decreasing order, they also transport: phosphatidylglycerol> phosphatidylinositol> phosphatidylcholine> phosphatidylethanolamine> phosphatidylεerine.

- N-terminal sequence of the 19 kDa protein, obtained from A. oryzae:

This sequence was determined according to Edman's method with the Applied Bioεystem 470A device. The amino acid sequence does not reveal any homology with other PLTPs:

I ^ N-Ala-Lys-Ser-Val-Pro-Gly-Aεn-Aεn-Pro-Leu-Glu-Tyr-Cyε- Asn-Aεp-Pro-Ser-Gly-Aεp-Ile-Leu-Aεp-Ile- Lyε-Gin-Val-Asp- Leu-Ser-Pro-Aεn-Pro. - iεoelectric point:

The iεoelectric point was determined with the Phaεt-εyεtem from Pharmacia. The 19 kDa protein has a pi of 4.8.

- Heat resistance of the protein: the pure 19 kDa PLTP is brought 10 min to

100 "C then cooled in ice before dosing phoεpholipid transfer activity. The results obtained indicate that the protein is stable after this treatment.

- Specific activity: With a crude extract (supernatant of the acid precipitation at pH 5.1), there is an activity of 3.3 nmol / min / mg or 198 nmol / h / mg with Aspergillus oryzae. After purification, there is, for the pure 19 kDa protein, an activity of 20,000 nmoleε / h / mg. EXAMPLE 3 Role of the culture medium rich in phospholipids in the stimulation of the endoplasmic reticulum and in the increase in the production of phospholipid transfer proteins: comparison with a culture in glucose-based medium. - We compare the activity of the endoplasmic reticulum of a fungus cultivated in a liquid medium with a glucoεe base (Figure 9, curve B) or in a medium rich in phoεpholipids (Figure 9, curve A) by assaying the enzymatic activity of cytochrome-C-oxidoreductase (specific marker of the reticulum) following the method of RL JONES (1980, Planta, 150, 58-69). In FIG. 9, the ordinate corresponds to the cytochrome-C-oxidoreductaεe activity, expressed in nmole.min ^" . G ^-1 of intracellular protein and the abscissa corresponds to the incubation time in days.

- From the first day, there is a very significant stimulation of the activity of the endoplasmic reticulum (place of synthesis of pholipid), when the fungus is cultivated on a medium rich in phospholipids (FIG. 9, curve A).

- In parallel, the transfer activity of phospholipids is illustrated in FIG. 10 which includes on the ordinate the transfer activity of phosphatidyl¬ choline expressed in nmol .min ^-1 .mg ^-1 of intra-cellular protein and in abεciεεe the incubation time in days. Curve (B) illustrates the transfer activity obtained after culture in a medium based on glucose and the curve (A) illustrates the transfer activity obtained after culture in a medium based on phospholipids; this figure 10 clearly shows a significantly higher stimulation of the transfer in the presence of phospholipids (curve A) compared to a culture on glucose (curve Λ) -. indeed, this figure clearly shows that, at 3 days, the transfer activity from a medium rich in phospholipid is 2 times greater. As is clear from the above, the invention is in no way limited to those of modes of implementation, embodiment and application which have just been described more explicitly; on the contrary, it embraces all the variants which may come to the mind of the technician in the matter, without leaving the scope or the scope of the present invention.

Claims

CLAIMS 1°) Process for preparing phospholipid transfer protein (PTPL), from non-toxic filamentous mushrooms of the type comprising the preparation of a crude extract, the separation of proteins from said extract and purification of said proteins, which process is characterized in that said mushrooms are cultured in a medium rich in phospholipids. 2°) Process for preparing phospholipid transfer proteins (PTPL), from non-toxic filamentous mushrooms according to claim 1, characterized in that said culture medium rich in phospholipids comprises between 3 and 20 g/l of phospholipids. 3°) Process for preparing proteins according to claim 1 or claim 2, characterized in that it comprises:

(1) the preparation of a crude extract with a substantially neutral pH by:

(a) - culturing said mushroom in said medium rich in phospholipids, until a sufficient quantity of mycelium is obtained,

(b) grinding said mycelia in an extraction buffer at neutral pH,

(c) preparation of the crude extract containing the lipid binding and transfer protein, from said ground material, by centrifugation of said ground material at a speed greater than 20,000 g (first centrifugation) and recovery of the SI supernatant,

. acid precipitation of the supernatant SI, followed by centrifugation at a speed greater than 20,000 g (second centrifugation) and recovery of the supernatant S2,

(d) obtaining the crude extract containing theε- called lipid fixation and transfer proteins, from the supernatant S2, buffered at substantially neutral pH,

(2) the concentration of proteins by ultrafiltration,

(3) the separation of fractions exhibiting lipid binding and transfer activity by gel filtration and selection of active fractions by measuring the lipid binding and transfer activity, and (4) the purification of proteins from the different various fractions selected, by a succession of chromatographic steps, which proteins are capable of carrying out the fixation, transport and/or intermembrane rearrangement of lipids, possibly associated with active ingredients, are hydrophobic and acidic, and have a lower molecular weight at 50 kDa.

4 ^° ) Process for preparing acidic proteins according to any one of claims 1 to 3, characterized in that said filamentous fungi have been selected from the group which includes the Ascomycete chosen from Aspergillus candi dus, A. flavipes, A. fumigatus, A. giganteus, A. Niger, A. ochraceus, A. oryzae, A. terreus, A. versicolor, A. wentii, Peni cillium roquefortii and Eurotium knighti, the Zygomycetes chosen from Mucor mucedo and Rhizopus stolonifer and the Basidiomycetes selected from the species Phanerochaete chrysosporium.

5 ^° ) Preparation process according to any one of claims 1 to 4, characterized in that step (a) further includes:

* culturing said mushrooms on a sporulation medium,

* incubation for 2 to 13 days until a sufficient quantity of spores is obtained,

* the miεe in culture ofεditeε spores on said culture medium rich in phospholipids, and

* incubation until a sufficient quantity of mycelium is obtained.

6°) Preparation process according to claim 5, characterized in that the sporulation medium advantageously consists of whole, moistened corn grains.

7°) Preparation process according to any one of claims 1 to 6, characterized in that the acid precipitation of step (c) is carried out at pH 5.1.

8°) Process for preparing acidic proteins according to any one of claims 1 to 7, characterized in that steps (b) and (c) were carried out cold. 9°) Process for preparing acidic proteins according to any one of claims 1 to 8, characterized in that the filamentous fungus is a strain of filamentous fungus A. oryzae.

10°) Process for preparing acidic protein according to claim 9, characterized in that step (5) provides a protein having lipid transfer activity and having a molecular weight of approximately 19 kDa.

11°) Process for preparing acidic proteins according to claim 9, characterized in that step (5) provides a protein having a lipid transfer activity and having a molecular weight of approximately 30 kDa.

12°) Purified preparation of lipid binding and transfer acid proteins, characterized:

- in that they are capable of carrying out the fixation, transport and/or intermembrane rearrangement of lipids, possibly associated with active principles,

- in that they are likely to be ob- made from a crude extract of a non-toxic filamentous fungus, cultured on a medium rich in phospholipids, which fungus was selected from the group comprising the Ascomycetes chosen from Aspergillus candidus, A. flavipes, A . fumigatus, A. giganteus, A. niger, A . oryzae, A. terreus, A. versicolor, A. wentii, Penicillium roquefortii and Eurotium knighti, the Zygomycete Rhizopus stolonifer and the Basidiomycete Phanerochaete chrysoεporium, said proteins exhibiting a specific phoεpholipide transfer activity expressed in nmoleε of phoεphatidylcholine transferred per minute and per mg of protein, greater than or equal to 0.3 nmoleε/min/mg,

- in that they are hydrophobic and acidic, and

- in that they have a molecular weight of less than 50 kDa.

13 ") Preparation of purified proteins according to claim 12, characterized in that they are likely to be obtained preferably from the filamentous fungus A. oryzae.

14°) Preparation of purified proteins according to claim 13, characterized in that said acidic lipid transfer proteins have a molecular weight of approximately 19 kDa.

15°) Preparation of purified proteins according to claim 14, characterized in that said acidic proteins of approximately 19 kDa have the following N-terminal amino acid sequence: H ₂ N-Ala-Lyε-Ser-Val-Pro -Gly-Aεn-Aεn-Pro-Leu-Glu-Tyr-Cyε- Aεn-Aε -Pro-Ser-Gly-Aεp-Ile-Leu-Aεp-Ile-Lyε-Gin-Val-Aεp- Leu-Ser-Pro -Aεn-Pro and have an isoelectric point of 4.8.

16°) Purified protein preparations according to claim 13, characterized in that the said acidic lipid transfer proteins have a molecular weight of approximately 30 kDa. 17°) Crude extracts of filamentous mushrooms, characterized in that they are capable of being obtained from a non-toxic filamentous fungus by: (a) culturing the said mushroom in a medium rich in phospholipids, until 'to obtain a sufficient quantity of mycelium _,.

(b) grinding of said mycelium in an extraction buffer at neutral pH, (c) preparation of the crude extract containing the lipid binding and transfer protein, from said ground material, by centrifugation of said ground material at a speed greater than 20,000 g (first centrifugation) and recovery of the SI supernatant,

. acid precipitation of the supernatant SI, followed by centrifugation at a speed greater than 20,000 g (second centrifugation) and recovery of the supernatant S2, (d) obtaining the crude extract containing the so-called lipid fixation and transfer proteins , from the supernatant S2, buffered to a significantly neutral pH.

18°) Raw extract according to claim 17, characterized in that step (a) includes:

* the medium in culture of the mushroom on a natural porulation medium,

* incubation for 2 to 13 days until a sufficient quantity of spores is obtained, * the medium in culture of said spores in a culture medium rich in phospholipids, and

* incubation until an adequate quantity of mycelium is obtained.

19°) Raw extract according to claim 18, characterized in that the sporulation medium advantageously consists of whole corn grains, moistened f ied .

20°) Modified biomembranes, characterized in that they can be obtained by modification of their lipid structure using lipid fixation and transfer proteins obtained according to any one of claims 1 to 11 or according to any one of claims 12 to 16.

21°) Pharmaceutical compositions, characterized in that they comprise a hydrophobic active principle, associated with lipid transfer proteins, obtained according to any of claims 1 to 11 or according to any of claims tionε 12 to 16.

22°) Cosmetological compositions, characterized in that they comprise appropriate lipoome, associated with lipid transfer proteins, obtained according to any one of claims 1 to 11 or according to any one of claims 12 to 16.

23°) Process for transporting intermembrane phospholipids, characterized in that it uses proteins obtained according to any claim 1 to 11 or according to any claim 12 to 16.