EP1962885A2

EP1962885A2 - Method for preparing a factor h concentrate and the use thereof in the form of a drug

Info

Publication number: EP1962885A2
Application number: EP06841898A
Authority: EP
Inventors: Sami Chtourou Abdessatar; Claudine Mazurier; Michel Poulle; Bernadette Cauvin; Frédéric DHAINAULT
Original assignee: LFB SA
Current assignee: LFB SA
Priority date: 2005-12-07
Filing date: 2006-12-07
Publication date: 2008-09-03
Also published as: CA2633102A1; CN101336111A; AU2006323849A1; FR2894145B1; CN102988958A; WO2007066017A2; WO2007066017A3; US20080318841A1; JP2009518368A; KR20080091441A; BRPI0619728A2; IL191931A0; FR2894145A1; JP2012211189A; AU2006323849B2

Abstract

The invention relates to the use of a factor H for producing a drug for treating Uremic Haemolytic Syndrome (UHS), to a method for purifying the factor H from a frozen fresh plasma and to a factor H concentrate obtainable by said method.

Description

Process for the preparation of a Factor H concentrate and use of this Factor H concentrate as a medicament

The invention relates to the use of Factor H for the manufacture of a medicament intended for the treatment of Hemolytic Uremic Syndrome (HUS), a method of purifying Factor H from fresh frozen plasma and the factor H obtained by this method.

Field of the Invention Hemolytic uremic syndrome (HUS) is defined by the association of microangiopathic hemolytic anemia, thrombσpenia and kidney damage. It is the main cause of acute renal failure in children under 3 years of age.

There are two forms of HUS.

In its typical form, HUS occurs during the summer period after an episode of diarrhea, often bloody. The typical HUS is secondary to an infection, in the majority of cases an infection with enteropathogenic Escherichia coli, in particular the serotype 0157: H7, producer of verotoxins.

Besides the typical form, some patients have a different presentation. Atypical forms of HUS occur without prodromes and have a more chronic course frequently leading to chronic renal failure. Atypical HUS can occur at any age. It represents only 5% of cases of HUS in children. The clinical signs of the syndrome are due to the development of rich micro-cells platelets in small vessels. This particularly affects the gloraerules of the kidney causing acute kidney damage. Atypical HUS can be sporadic but it is often familial. In these two situations, the disease generally presents a recurrent development by pushing. His prognosis is poor. In addition, there is a high risk of recurrence of the disease after a kidney transplant, leading to graft rejection in most cases.

HUS may be associated with hypocomplementemia.

The complement plays an essential role in the defense of the organism against infectious agents and in the inflammatory process.

It includes both plasma proteins, many different cell surface receptors, some present on inflammatory cells and others on cells of the immune system, as well as regulatory membrane proteins which protect host cells from auto -attack.

Plasma complement proteins are approximately 20 and function either as enzymes, as binding proteins, or as regulators (inhibitors or activators).

The complement can be activated by two different routes: the conventional route and the alternative route.

The classical way is activated by the binding of antiedrps to the foreign particle. It is therefore dependent on antibodies.

Alternative flight is activated by the invasion of microorganisms, so it is independent of antiedrps and extremely important in the defense of the hotel against bacterial infections.

Factor H is a 155 kDa protein found in plasma at a concentration of 110-615 μg / ml. It is synthesized in the liver, macrophages, fibroblasts, endothelial cells and platelets. The secreted form of the protein is made up of 20 repeating units of 60 amino acids. The H factor is the central regulator of the alternative pathway of complement. It participates in the regulation of the level of immune complexes in the blood and therefore in the balance between the processes resulting in their generation or degradation _< With factor I, factor H inactivates free or bound C3b molecules on the surface of cells. Thus, the immune complexes composed of an antigen-antibody complex complexed with the component of complement C3b can no longer activate the subsequent cascade of complement (components C5-C9).

The function of Factor H can be broken down into three

I

main activities Ï

1) The I Factor H behaves first of all as a co-factor of the factor I. Thus, the Factor H and the Pactedr I proceed to the transformation of the protein C3b of the complement into C3bi (inactive molecule) by a cleavage of the • chain of the C3b protein. The C3b protein thus inactivated can no longer fulfill its role in the functioning of the complement, and no longer participates in the formation of C3 convertase; 2) The ₁ Factor H is involved in the endothelial and platelet mechanisms is finally involved in the dissociation of the preformed C3 convertase (C3bBb), in the alternative way of the activation of the complement. The latter activity depends directly on the molecular integrity of Factor H, and is more particularly dependent on the presence of an intact asn323-asn324 link in Factor H.

!

The deficit or absence of Factor H, responsible for many cases of atypical SHϋ, consequently leads to hyperactivation of the complement, which results, in certain patients, in the observation of depj ^β ts of C3 proteins during renal biopsies , and

I

an decrease in the level of protein C3 present in the circulation.

In some patients with atypical HUS, the Joas C3 levels are not observed during the acute phase of the disease. Strong arguments plead in favor: of the role of a qualitative and quantitative deficit in factor H often associated with a fall in the level of C3, in the pathogenesis of certain atypical HUS (Rougier N, Kazatchkine MD, et al., Human complement factoij H deficiency associated with hemolytiσ urémie syndrcjme, J. Am. Soc. Nephrol. 1998; 9: 2318-2326). The factor H deficit is responsible for a

I

activa tion permanent ⁱ of the alternative complement pathway respoφable of low levels of C3.

A link between the atypical HUS and a region coding for the complement regulatory proteins, in particular factor H, located on chromosome 1, has been; demonstrated (Noris et al., Hypocomplementemia disclcjses genetic predisposition to haemolytic uraemic syndrcjme and thrombotic thrombocytopenic purpura: role φf factor H abnormalities, J ^" . Am. Soc Nephrol. 1999, '10: 281-293); (Warwicker et al., Genetic studies

I

into ^• 'haemolytic uraemic syndrome, Kîdney Int, 1998; | 53: 836-844); (Warwicker et al., Familial relapaing haemolytic uraemic syndrome and complement factor] H deficienσy, Nephrol JDial Transplaixt 1999; l | 4: 1229-1233).

Mutations in the factor H gene were then identified in familial forms of HUS with autosomal recessive or dominant transmission (Buddljes et al., Complement factor H gene mutation associjated with autosomal recessive atypical haemolytic uraemic syndrome, Am J ffυm Genêt, 2000 ; ^β ! 6: 1721-1722); (Caprioli et al ,, The molecular foasis i of familial haemolytic uraemic syndrome: mutatiion analysis of factor H gene reveals a hot spot in shqrt consensus repeat 20, J Am Soc Nephrol 2001; 12: 297-307); {Ohali et al., Hypocomplementemic autosohal recessive haemolytic uraemic syndrome with de crëased factor H, Pediatr Nephrol 1998; 12: 619-624) ; (Ying et al., Complement factor H gene mutation associated with autosomal recessive atypical haemolytic uremic syndrome, Am j Hum Genet 1999; 65: 1538-1546).

Recurrence after transplantation in patients with an atypical form of HUS is observed in approximately 25% of cases. The prognosis for recurrence is poor; graft loss related to recurrence is the rule,

Prior art

The first-line treatment consisting of infusions of fresh frozen plasma with or without plasma exchange was started empirically in the 1970s long before the role of complement in HUS was known. Today, fresh frozen plasma infusions with or without plasma exchange are the basis for HUS therapy, however, the amounts and frequency of fresh frozen plasma infusions are still empirically determined.

These infusions should be repeated at regular intervals of twice a week to twice a month, each infusion taking 2 to 3 hours,

This treatment is therefore long and repetitive for the patient.

The quantities of fresh frozen plasma transfused are large, which increases the traditional risks of an infusion of fresh frozen plasma.

First, fresh frozen plasma (PFC) contains anti-A or anti-B hemolysins and must be reserved for patients of the same ABO group, or at least for patients lacking A or B antigens corresponding to hemolysins (rule of reverse compatibility with that of red blood cells). Failure to comply with these rules exposes the recipient to post-transfusion hemolysis of red blood cells due to ABO incompatibility, In addition, in order to avoid any risk of immuno-immunization vis-à-vis the D antigen of the Rhesus system, it is necessary, especially in patients at risk (girls, women of childbearing age, multiririsfies ) to carry out infusions where the patient and the donor have the same characteristics with regard to this antigen,

Secondly, PFC can cause hyperhosphatemia in HUS patients because the phosphate concentration in the PPC, in particular the viro-attenuated plasma (PVA), is very high (9 to 12 ntirool / lj) and the patient HUS suffers from kidney failure. The high concentration of phosphate in PVA is (likely to cause hyperphosphatemia in patients transfused with PVA, all the more significant since:

- ^the volumes are transfused PVA are important,

- they are repeated daily,

"that there exists in the patient a renal insufficiency,

- that there is a hyperphosphatemia in the patient.

I As a result, the amounts of PFC infused can lead to protein overload and / or cijtrate overload which reduces the calcium concentration i

circulating. Finally, I the PFC involves a risk of allergies, as well as of transmission of infectious agents. Indeed, the current detection and inactivation methods do not always have sufficient sensitivity and inactivation capacity - to allow the detection and elimination of infectious agents potentially present in fresh frozen plasma.

I

The association of plasma exchanges with infusions of fresh frozen plasma is necessary when the perfused volumes are too large to be eliminated by the dijirèse and to maintain a blood pressure

!

normal. This association presents risks

I

significant additions, mostly due to vascular access (need for a central route), overload, anaphylactic reaction, clotting problems and transmission of viral diseases ”

In addition, plasma exchanges are difficult to achieve; used in young children.

Another treatment is a kidney transplant. However, the risk of recurrence after transplantation is very high,

In addition, the diagnosis after renal transplantation in HUS patients (atypical HUS) can be difficult. It can be difficult to tell the difference between a recurrence and an acute vascular rejection or a chronic rejection on a biopsy of the transpilant.

Treatment of recurrence consists of infusions of fresh frozen plasma, plasma exchanges with or without plasma infusions with [very inconsistent results. These inconsistent results can be explained by the number and volume of PFC infusions, each infusion representing a pool of donations from multiple donors and

I

not a homogeneous batch,

As factor H is synthesized in the liver, it appears; logical to propose a liver transplant or even a combined liver-kidney transplant. !

This .transplantation is always one. difficult choice for doctors and parents and presents the operating and rejection risks of any

I

liver transplant. Summary of the invention

To overcome these drawbacks of the prior art, the developer has surprisingly observed that it is possible to use factor H for the manufacture of a medicament intended for the treatment of HUS,

Factor H, for example in the form of a concentrate of factor H from fresh frozen plasma, makes it possible to restore factor H deficiency in patients with HUS while reducing the volumes injected and the injection times with an effective, stable and safe product.

In particular, the administration of factor H in the immediate post-liver transplant period makes it possible to compensate for the low production of factor H by the transplanted liver and thus for the immediate relapse and rejection of the graft.

! The present invention also relates to a factor H purification process comprising the steps of;

1) prepare the supernatant of a plasma cryoprecipitate, 2) subject this supernatant to an anion exchanger type gel / rejsine chromatography,

3) subject the unsuccessful fraction to chromatography on a gel / resin comprising a graft ligand of the heparin type,

4) Adjust the pH of the fraction not retained after the chromajtographia of step 3 to allow the binding of Factor H to a gel / resin of chroαiatographic support comprising a grafted ligand of the Heparijne type,

5) Elute the factor H with a buffer of ionic strength greater than that of the gel / resline balancing buffer,

6} Dilute the eluted fraction, then submit it to a gel / resin chromatography of the heat exchanger type. strong acid type cations,

7) Elute factor H with a buffer of ionic strength greater than that of the gel / resin balancing buffer,

8) Dilute the eluted fraction, then subject it to a chromaitography on anion exchanger type gel / resin of strong acid type,

9) Wash the gel / resin and elute the factor H,

10) Prepare a factor H concentrate.

Detailed description of the invention Figures:

Figure 1: Diagram of the factor H purification process

Figure 2: Dissociation of C3 convertase by

H factor

The main object of the present invention is the use of Factor H for the manufacture of a medicament intended for the treatment of Hemolytic Uremic Syndrome (HUS), in particular of the typical form of HUS or of the atypical form of HUS.

A preferred form of the invention is the use of Facteuir H for the manufacture of a medicament intended for the treatment of Hemolytic Uremic Syndrome, Factor H being purified from fresh human plasma! or plasma fractions from purification by conventional methods well known to those skilled in the art.

This purification is well known to those skilled in the art. It can be carried out by chromatography using a lysine-sepharose column, QAE-Sephadex, DEAE-Toyopearl, Sephacryl S-300 and hydroxyapatite. It is detailed in the following documents: Fearon, J Immwiol, 119, 1248-1252 (1977); Crossley et al., Biûchem J, 191, 173-182, (1980); Nagasawa et al., -7 Iimimol, 125, 578-582, (1980); Weiler et al., PNAJS., 73, 3268-3272, (1976) and Wïialey et al., J Exp Mèά, 144, 1147-1163 (1976).

Factor H resulting from purification from plasma; fresh frozen is for example in the form of a factor H concentrate.

;

A further embodiment of the invention is the use of Factor H for the manufacture of a medicament intended for the treatment of the Syndrome

I

Hemoly, ϋreïαique tick, the Factor H being obtained by genetics, by the expression of its gene in a cellulje chosen in the group made up of bacteria, yeast | s, fungi or mammalian cells. i

A particular embodiment of the invention consists in the use of Factor H for the manufacture of a medicament intended for the treatment of hememic hemorrhagic syndrome, the medicament thus obtained being BOUS lyophilized form.

An additional embodiment of the invention consists in the use of Factor H for the manufacture of a medicament intended for the treatment of the Uremic Hemolytic Syndrome, the medicament thus obtained having undergone at least one method of elimination or iinactivation of '' at least one infectious agent.

Among the infectious agents, mention may be made of viruses and ATNCs (unconventional transmissible agents) such as the prion protein.

In pεjxticulier, the drug may be inactivated viral ^'lying.

The term “viral inactivated” is understood to mean that the medicament has undergone at least one method of viral inactivation, known to a person skilled in the art by treatment with china products, for example by solvent / detergent / and / or heat, for example by dry heating or pasteurization, and / or by nanofiltration.

L, es viruses likely to be inactivated by one of these; methods include: human acquired immunodeficiency virus (HIV), hepatitis A virus (HAV), hepatitis B virus (HBV), parvvirus B19, cytomegalovirus (CMV), parvo ^y pig irus, poliovirus, bovine viral diarrhea virus (BVDV), etc.

I

Another subject of the invention is a lyophilized and virally inactivated pharmaceutical composition, for example as described above, and comprising factor H and pharmaceutically acceptable excipients and / or vehicles.

Another object of the present invention relates to a method for purifying Factor H comprising the steps i consisting in:

1) prepare the supernatant of a plasma cryoprecipitate, 2) subject this supernatant to an anion exchanger type gel / resin chromatography,

3 ⁾ subject the unsuccessful fraction to chromatography on a gel / resin comprising a grafted ligand of the heparin type,

4) adjudicate the pH of the fraction not retained after the chroma; tography of step 3 to allow the binding of the Fector H to a gel / resin of chromajtographic support comprising a grafted ligand of the Heparijne type,

5) Elute the factor H with a buffer of ionic strength greater than that of the gel / resjine balancing buffer,

6) Dilute the eluted fraction, then submit it to a chromaitography on gel / resin of the strong acid type σationjs exchanger,

7 ⁾ Elute the factor H with a buffer of ionic strength greater than that of the gel / buffer balancing buffer resin,

8) Dilute the eluted fraction, then submit it to a gel / resin chromatography of anion exchanger type of strong acid type,

9) Wash the gel / resin and elute the factor H,

10) Prepare a factor H concentrate.

In ; a particular embodiment of the invention, the chromatographic support onto which a heparin ligand from step 3) is grafted is a heparin Sepharose gel / resin.

In a particular embodiment of the invention, the chromatographic support onto which a heparin ligand from step 4) is grafted is a heparin Sepharose gel / resin.

In a particular embodiment of the invention, the gel / resin chromatography of the cation exchanger type of the strong acid type of step 6) is a ch.romatograpb.ie of the SP Sepharose type.

In a particular embodiment of the invention, the chromatography on a gel / resin of anion exchanger type of strong acid type of step 8) is a Q Sepharose FF type chromatography or equivalent.

Advantageously, the pH of the fraction not retained in step 4) is adjusted to be within the range from pH 5.5 to pH 6.5 and preferably to be equal to pH 6.0.

Advantageously, the pH of the fraction diluted in step 8) is adjusted to be within the range from pH 6.5 to pH 7.5.

The purification process of the invention is the only one known process for the purification of a factor H from plasma which proves to be industriaϋsable, and which makes it possible to obtain a concentrated factor H purified in the absence of inhibitors of chemical or synthetic proteases, thus leaving no trace of cesj inhibitors in the final product.

j

Indeed, the methods for purifying factor H from; known human plasma state of the art are implemented in a perspective of fundamental research, sometimes using precipitation purification techniques (eg PEG; ^Sulfate!) hardly indust | rialisables, and inhibitors proteases. These protease inhibitors inhibit the action of trypsin-like proteins, present in serum and plasma, which are responsible for the cleavage of the protein link joining the amino acids asn323 and asn 324 of the H factor molecule. addition of protease inhibitors contributes to the decrease in the proteolysis of this factor and therefore improves its stability. However, pjotease inhibitors are often highly toxic compounds, making them unsuitable for an industrial process of production of factor H intended for therapeutic use.

Furthermore, the method of the invention has a significant advantage in that it makes it possible to obtain a factor H concentrate of which the 3 main types of activities are conserved, which none of the H factors described in the state of technique does have. The Facteujr H obtained by the process of the invention can therefore fill its activity as central regulator of the alternative pathway to complement, an activity which is revealed! deficient in HUS patients, especially atypical HUS. In particular, the Factor H produced by the process of the invention advises its dissociation activity of the preformed C3 convertase in the alternative route of the complement and appears capable of being used in the treatment of HUS thanks to its activity

I

fully functional.

I

The Factor H concentrate obtained by the process of the invention also has a specific activity close to 1 (AS = O.8 to 0.9), which makes it more efficient than a solution of fresh frozen plasma (AS = O.] 008) Mistletoe, although therapeutically effective, has many disadvantages, as was written in the introduction to the present application. Among these disadvantages, the administration of plasma introduces into the body additional proteins which are useless for the treatment of HUS (albumin, fibrinogen, etc.) which, on the other hand, can trigger undesirable reactions linked to protein overload or cause reactions allergic, known as "serial illness".

Finally, the inactivation of transmissible viruses present in the plasma is generally more difficult and less efficient than that implemented to inactivate the viruses present in blood derivatives. The Factor H concentrate obtained by the process of the invention can therefore benefit from recognized and proven treatments providing documented viral safety.

Examples

EXAMPLE 1 Method for Purifying the Factor H

The procedure used to purify the Factor H is shown in schematic form in Figure 1. The fresh frozen human plasma is thawed at a temperature of between 1 ° C and 6 ° C, then the plastic supernatant of the cryoprecipitate is separated from the insoluble traction of the cryoprecipitate by centriifugation.

The plasma supernatant of the cryoprecipitate obtained, the concentration of Factor H of which is in a range from approximately 400 to approximately 500 μg of Factor H / liter, is subjected to chromatography on resin / gel of anion exchanger type (for example , a gel / resin of the DEAE Sepha & ex type), in order to separate the Factors dependent on vitamin K from the plasma supernatant by retention of these Factors on the resin / gel.

The fraction of plasma supernatant not retained (fraction A), the concentration of Factor H is in a range from about 400 to about 500 iαg of Factor H / liter, is then subjected to a! affinity chromatography on a gel / resin of ty & e Heparin Sepharose FF, in order to separate

I

1 antifchrombin III of this fraction A, by retention of the year _I titîirombine in on the resin / gel.

PH 1id the fraction A not retained (fraction B), the concentration of Factor H of which is included in a gaïtime | from about 300 to about 400 mg of Facteut H / liter, is adjusted to be within a range "from pH 5.5 to pH 6.5 and preferably to be equal to pH 6.0.

j

Fralction 3, whose pH has been adjusted, is subjected to j

chromatography on a (e) second gel / resin of the Heparin Sepharose FF type or on any other chromatographic support comprising grafted ligands of the HJeparin type. Most of the proteins contained in the plasma fraction B are then eluted with the chromatography filtrate. The proteins weakly adsorbed on the gel / resin are eliminated by a series; I of washes and pre-elutions. The factor H retemj on the gel / la, resin is then eluted using a buffer having a higher ionic strength than that of the buffer used to balance the geJj / resin,

The eluted fraction containing Factor H (Fraction C) is diluted, then subjected to a chromatography on gel / resin of the cation exchanger type of strong acid type! for example an SP type gel / resin

Sephattose PF or equivalent. The proteins weakly adsorbed on the gel / resin are eliminated by a series of washes and pre-elutions.

The Factor H retained on the gel / resin is then eluted using a buffer having a higher ionic strength than that of the buffer used for i

balance the gel / resin.

The eluted fraction containing Factor H (Fraction D) is then subjected to a viral inactivation step by treatment with a solvent of detergent type, for example Polysorbate 80 and TnBP. Such a treatment makes it possible in particular to effectively inactivate viruses, and in particular, viruses of the enveloped virus type.

Fraction D is then diluted, and the pH of this fraction is adjusted to be within a range from pH 6.5 to pH 7.5. The fraction D is then

I

subjected to chromatography on a gel / resin of the anion exchanger type of strong acid type, for example a gel / resin of the Q type Sepharose FF or an equivalent. After a series of washes, the Factor H retained on the gel / resin is eluted using a buffer having an ionic strength greater than that of the tamipon used to balance the gel / resin. The agents previously introduced to carry out viral inadivation by treatment with a solvent of detergent type are eliminated during this tographic chroma ¹ step, and the degree of purity of Factor H is increased.

The eluted fraction containing Factor H (Fraction E) is then subjected to a viral elimination step by nanofiltration on a filter having a porosity of approximately 15 nm. This viral elimination treatment effectively eliminates viruses, and

I

especially small non-enveloped viruses. The resulting solution (fraction F) is finally concentrated and adjusted by ultrafiltration then filtered on a 0.22 μm filter.

The efficiency of the purification process described above and the specific activity of the Factor H purified by this process were measured on two separate batches. The corresponding results are presented in Table 1. The specific activity (AS) is expressed in mg of factor H type antigen / mg protein.

Example 2 Method for Assaying the Factor H Activity The wells of an ELISA plate (of the 96 well type) are covered with a solution of purified C3b protein, having a concentration of 2.5 g / ml (Calbiochem: ref . 341274) in 0.2 M sodium carbonate buffer. To do this, 100 μl of solution are introduced into the wells 'and the plates are incubated for 1 hour ^' at 37 ° C and 1 night at 4 ° C.

Three; washes of 300 μl / well are carried out with a 10 mM sodium phosphate buffer solution, 25 mM NaCl, 0.1% Tween 20, pH 7.2.

The aspecific sites are then saturated by an incubation of one hour at 37 ° C with 300 μl / well of a 10 mM sodium phosphate buffer solution, 25 mM NaCl, pH 7.2, Tween 20 0.05%, and containing 1% BSA.

I

Then washing the wells is carried out with the layering solution described above.

100 μl of a solution containing:

75 'μl of a 20 mM NiCl2 stock solution (final concentration 1.5 mM)?

~ 4 μl of Factor B (Calbioσhem ref. 341262) at a concentration of lmg / ml;

- 3 μl of Factor D (Calbiochem ref. 341273) at a concentration of lmg / ml; and

- 918, μl of 10 mM sodium phosphate buffer, 25 mM NaCl, pip: 7.2, and 4% of BSA;

are placed in each well before incubating for 2 h at 37 ° C.

Three successive washes of 300 μl / well are then carried out with a sodium phosphate buffer solution. 10 mM, NaCl 25 mM, Tween 20 0.1%, pH 7.2,

A range of factor H solutions with respective Factor H concentrations of 20 μg / ml,

10 μgi / ml, 1 μg / ml, 0.25 μg / ml, 0.0625 μg / ml, 0.015625 μg / mli 0.00390625 μg / ml and 0.001 μg / ml is prepared. 100 μil of each solution are placed in a different well and an incubation of 30 min at 37 ° C is carried out. Three successive washes of 300 μl / well are then carried out with a 10 mM sodium phosphate buffer solution, 25 mM NaCl, 0.1% Tween 20, pH 7.2.

A solution of human anti-factor E goat antibody (Calbioσhem ref: 341272) is diluted to 1/2000 in a PBS buffer (Sigma P-3813), pH 7.4, containing

0.1%! Of BSA, then 100 μl of the diluted solution are deposited in the wells and an incubation is carried out for 1 hour at 37 ° C.,

Three successive washings of 300 μl / well are carried out with a PBS solution, Tween 20 0.1%, pH 7.2. Then

100 μ ^. of a solution containing a peroxidase-labeled rabbit anti-goat antibody (Calbiochem ref.

401515 Img / ml), and diluted 1/10000 in PBS containing ^Q , 1% of BSA, are deposited in the wells before proceeding to incubate for 20 to 25 minutes at room temperature.

Three ^! successive washings of 300 μ 1 / well are carried out with a PBS solution, Tween 20 0.1%.

The substrate of OPD peroxidase (Sigma), at a concentration of 5 mg / 10 ml in a solution of sodium citrate, is added to the wells, as well as 10 μl of H ₃ O ₃ , at a rate of 100 μl / well in the end. The reaction mixture is left in contact with the wells for approximately 10 minutes before stopping the reaction by adding 50 μl of 4N H-SO ₄ per well. The absorbance of the solution contained in the wells is then measured at a wavelength of 492 nm. The corresponding results are presented in FIG. 2. The graphical representations appearing in FIG. 2 give the value of the absorbance measured as a function of the concentration of Factor H or as a function of the concentration of protein (SAH).

A method for assaying similar factor H activity is described in the document McRae et al., The jojurnal of immunology, 2005, 174: 6250-6256.

Claims

1, use of Factor H for the manufacture of a medicament intended for the treatment of Bémolytique Urénαique Syndrome (HUS).

2, Use according to claim 1; characterized in that the medicament is intended for the treatment of the typical form of HUS.

3, Use according to claim 1, characterized in that the medicament is intended for the treatment of the atypical form of HUS.

;

4. Use according to any one of the preceding claims, characterized in that the said 'Factor H is purified from fresh human plasma or from a plasma fraction,

5. Use according to any one of claims 1 to 3 / characterized in that said factor H is produced by genetic engineering by the expression of the factor H gene in a cell chosen from the group composed of bacteria, yeasts, fungi or mammalian cells.

6. Use according to any one of the preceding claims, characterized in that said medicament is prepared in lyophilized form.

7. Use according to any one of the preceding claims, characterized in that the said medicament has undergone at least one method of elimination or inactivation of at least xxxx infectious agent.

8. Use according to any one of the preceding claims, characterized in that said ^; drug has undergone at least one viral inactivation method.

9. A lyophilized, virally inactivated pharmaceutical composition comprising factor H and pharmaceutically acceptable excipients and / or vehicles.

10. Method for purifying Factor H comprising the steps consisting in:

1) prepare the supernatant of a plasma cryoprecipitate, 2) subject this supernatant to gel / resin chromatography of the anion exchanger type,

3) subject the unsuccessful fraction to chromography on uα (e) gel / resin comprising a graft ligand of the heparin type,

4) Adjust the pH of the fraction not retained after the chromftography of step 3 to allow binding. from Flactor H to a chromatographic support gel / resin comprising a grafted ligand of the type

Heparin,

S) EIu ^ r factor H by a buffer of ionic strength greater than that of the gel / resin balancing buffer,

6) Dilute the eluted fraction, then subject it to a gel / resin chromaitography of the cation exchanger type of strong acid type,

8) Dilute the eluted fraction, then submit it to a gel / resin chromatography of the anion exchanger type of strong acid type,

9) Wash the gel / resin and elute the factor H,

10) Prepare a factor M concentrate.

11. The method of claim 10, wherein the chromatographic support comprising a ligandj grafted Heparin type of step 3) is a {e) gel / reisin Heparin Sepharose.

12. Method according to one of claims 10 or 11, in which the chromajtographic support comprising a grafted ligand of the Heparin type from step 4) is tin (e) gel / Heparin resin

Sepharpse.

13. Method according to one of claims 10 to 12, in which the chroma; gel-resin tography of the cation exchange type of strong acid type of step 6) is a chromaitography of the SP Sepharose type.

^; 14. Method according to one of claims 10 to 13, in which the chromaitography on uπ (e) gel / resin of anion exchanger type of strong acid type from step 8) is a chroma ⁱ tography of type Q Sepharose FF or equivalent.

15. Method according to one of claims 10 to 14, wherein the pH of the fraction not retained from step 4) is adjusted to be in the range from pH 5.5 to pH 6.5 and preferably to be equal to pH 6.0.

16. Method according to one of Claims 10 to 15, in which the pH of the fraction diluted in step 8) is adjusted to be within the range going from pH 6.5 to pH 7.5,

17. Concentrate of Factor H obtained by the process according to one of claims 10 to 16.

18. Concentrate of Factor H obtained by the method according to one of claims 10 to 16 for use in the treatment of diseases resulting from deficient control of the activation of the complement.

19, Factor H concentrate obtained by the process according to one of claims 10 to 16 for use in the treatment of Hemolytic Uremic Syndrome (HUS).

20, Factor H concentrate obtained by the process according to one of claims 10 to 16 for use in treatment of the atypical form of Hemolytic Uremic Syndrome (HUSA).

21. Use of a Factor H concentrate obtained by the process according to one of claims 10 to 16 to control ^• activation of the complement in vitro or ex vivo.

22. Use of a Factor H concentrate obtained by the process according to one of claims 10 to 16 for obtaining a medicament intended for the therapeutic or prophylactic treatment of diseases resulting from a deficient control of the activation of the complement.

23. Use of a Factor H concentrate obtained by the process according to one of claims 10 to 16 for obtaining a medicament intended for the therapeutic or prophylactic treatment of Hemolytic Uremic Syndrome (HUS).

24. Use of a Factor H concentrate obtained by the process according to one of claims 10 to 16 for obtaining a medicament intended for the therapeutic or prophylactic treatment of the atypical form of Hemolytic Uremic Syndrome (HUSA).