Device for the Presentation of Peptides or Proteins, Method for the Preparation and Use Thereof

Abstract

The invention relates to a device for the presentation of polypeptides, a method for the preparation and the use thereof, as diagnostic tool (polypeptide chip) for miniaturized and highly parallel detection of structurally or functionally complementary molecules of said polypeptides, i.e. antibodies.

Description

The present invention relates to a device for the presentation of polypeptides, to its method of preparation and its uses, in particular as a diagnostic tool (polypeptide chip) for the miniaturized detection of molecules which are structurally or functionally complementary to said polypeptides, in particular antibodies.

For the purposes of the present invention, the term “polypeptide chip” corresponds to the English terms “peptide arrays”, “peptide microarrays”, “peptide chips”, “protein chips” or “protein arrays”, commonly used in the literature.

There is currently great enthusiasm for the use of polypeptide chips allowing the detection, in various liquid biological media, of antibodies or of specific parts thereof, of antigens (in particular viral, bacterial or parasitic antigens), of receptors, of sequences responsible for binding to a molecule (enzyme, receptor, antibody), the study of the specificity of enzymes or the development of artificial receptors.

Now, in this specific context, it is essential to be able to have available polypeptide chips having a number of qualities.

These chips must in particular allow the reproducible immobilization of probes, since a reproducible immobilization is a condition for a detection which is itself reproducible. For the purposes of the present invention, the expression probe is understood to mean any polypeptide which is deposited at the surface of a support and which serves for the capture of targets present in a biological medium, these probes being specific for the targets to be detected.

These chips must also allow the sensitive detection of the targets or complementary receptors contained in the biological medium. The sensitivity of detection depends on the level of immobilization, the level of capture and the method of detecting a signal, but also and especially on the level of background noise (nonspecific signal). A reduction in the background noise improves the signal/noise ratio. Indeed, in a device in which the presence of biological species in the vicinity of the surface is detected, the background noise comes essentially from the nonspecific adsorption of molecules other than the biological species of interest which it is desired to detect, and which should consequently be limited. It would therefore be ideal to obtain a device which possesses a very low background noise and a high signal detection intensity.

Moreover, from an industrial point of view, it is advantageous to be able to have devices which can be prepared in a simple manner and which have an excellent stability during storage before use.

Currently, there are mainly two main methods of preparing polypeptide chips using polypeptides prepared ex situ.

The first main method consists in binding the polypeptides in a covalent manner to a solid surface such as a glass or an organic polymer surface. Accordingly, there has already been proposed for example in the article by G. MacBeath et al., Science, 2000, 289, 1760-1763, a method of preparation consisting in immobilizing the polypeptides via an imine bond resulting from the reaction between an amine functional group of the polypeptides and an aldehyde functional group of a silanized support. This method then requires a step for reducing in situ the imine functional group, for example with sodium borohydride in order to stabilize the polypeptide-surface linkage. The major disadvantage of this approach is the need to carry out chemical steps for linking the polypeptide to the surface of the support, which may cause in particular, in some cases, degradation of the polypeptide used. Furthermore, such reactions significantly complicate the method for manufacturing polypeptide chips.

The second main method consists in immobilizing the polypeptides by adsorption onto a surface without establishing a covalent linkage. This method quite obviously has the advantage of being simpler from an industrial point of view since it does not necessarily involve a chemical step of functionalizing the polypeptides. Accordingly, the article by Falipou S. et al., Bioconjugate Chem., 1999, 10, 346-353 describes a method according to which SiO₂ beads or glass slides are silanized with 3-cyanopropyldimethylchlorosilane so as to allow immobilization of antibodies (glycosylated proteins), the noncovalent attachment taking place, in this case, via hydroxyl functional groups of the glycosylated parts. This method nevertheless has the disadvantage of being limited to glycosylated proteins. It has moreover already been proposed, in particular in international application WO 00/63701, to immobilize polypeptides onto glass surfaces coated with a cationic polymer such as polylysine, by means of electrostatic bonds. However, even before the immobilization of the polypeptides, the properties of the glass slides thus prepared change over time. Also, the devices manufactured from this type of support are unstable over time (variation of the signal according to the degree of aging of the device). Finally, these surfaces lead to a high background noise level (Haab B B. et al., Genome Biology, 2001, research 0004.1-13).

The inventors therefore set themselves the aim of overcoming all the problems encountered with the prior art devices described above and to provide devices for the presentation of polypeptides which are stable over time (at least 3 months of aging under accelerated conditions, which corresponds to 12 months of aging at room temperature), simple to manufacture and to use, applicable to any type of polypeptides without the need for steps to functionalize them and which allow sensitive and reproducible detection of a signal with a very low background noise.

The first subject of the present invention is therefore a device for the presentation of polypeptides, characterized in that it comprises at least one solid support functionalized with semicarbazide groups onto which said polypeptides are adsorbed.

Whereas surfaces comprising semicarbazide groups are normally used to immobilize biomolecules such as nucleic acids functionalized with benzaldehyde groups (Podyminogin M A et al., Nucleic Acid Research, 2001, 29, 5090-5098) or polypeptides modified with α-oxoaldehyde functional groups (international application WO 01/42495) by forming a semicarbazone-type covalent bond, the inventors have observed, surprisingly, that the use of these surfaces also makes it possible to immobilize polypeptides by mere adsorption, in a lasting and stable manner over time, without the need to functionalize them beforehand.

Thus, the mere adsorption of polypeptides onto such a support makes it possible to obtain devices which are stable over time (at least 12 months at room temperature), simple to manufacture and to use, according to a methodology which is applicable to any type of polypeptides (without adding chemical reagents, apart from the buffers conventionally used for solubilizing polypeptides) and which allow sensitive and reproducible detection of a signal with a very low background noise.

For the purposes of the present invention, the general term of “polypeptides” denotes all the peptides comprising at least two amino acids (of the L or D series, alpha-amino acids, beta-amino acids, alpha-hydrazino acids, alpha-amino acids which may or may not be proteinogenic), peptidomimetics (mimics of secondary structures, mimics of beta-elbow for example), proteins and protein fragments.

The polypeptides adsorbed at the surface of the device in accordance with the present invention may be polypeptides from extraction or recombinant polypeptides, without constraint as to their structure (polypeptides with or without post-translational modification). They may also be synthetic polypeptides carrying various modifications, such as for example a polyethylene glycol group or chemical groups which are inert toward the surface semicarbazide groups, such as for example semicarbazone and hydrazone groups.

The deposition of the polypeptides on the semicarbazide support is accompanied by their spontaneous adsorption onto the support.

Any solid supports which may be functionalized with a semicarbazide group can be used according to the invention. Among such supports, there may be mentioned in particular organic or inorganic materials chosen for example from glass, silicon and its derivatives and synthetic polymers.

The supports functionalized with semicarbazide groups may be imprinted for example with a pin “spotter”.

Thus, the immobilization strategy:

is simple at the experimental level and is highly reproducible;

applies to any type of polypeptide which is nonfunctionalized or functionalized with a group which is chemically inert toward the semicarbazide groups of the support;

uses surfaces which are functionalized with a stable, nonhydrolyzable functional group;

makes it possible to obtain a high density of adsorption of the polypeptides at the surface of the support, ensuring a very high signal/background noise ratio (typically the background noise represents 0.1% of the signal detected).

The quality of the adsorption of the polypeptides onto the support (density, homogeneity) may be controlled by its capacity to bind a fluorescent synthetic peptide probe.

The subject of the invention is also a method for preparing the devices for the presentation of polypeptides as described above, comprising the following steps:

the functionalization of a solid support with semicarbazide groups, and

the deposition, in the form of spots, of samples of polypeptides and their adsorption onto the support thus functionalized.

According to a first variant of this method, the functionalization of the support comprises:

the introduction of an amine functional group by a reaction for silanization of the support,

the conversion of the amine functional group to an isocyanate functional group,

the reaction of the isocyanate functional group with a hydrazine derivative in order to form the semicarbazide group.

According to a second variant of this method, the functionalization of the support is performed in a single step by reacting the support with a silane carrying a semicarbazide group.

The step of depositing the polypeptides preferably comprises:

the preparation of polypeptide solutions in a buffer, at a concentration of between 10 mg/ml and 0.01 mg/ml;

their distribution into a container appropriate for their collection, of the microtiter plate well type;

their collection with the aid of a manual or automated sample collecting apparatus, for example of the “spotter” type;

their deposition onto the semicarbazide support; and optionally

the saturation of the support.

At the end of their preparation, the devices in accordance with the invention may be used directly or stored at room temperature, protected from light and from dust.

The subject of the invention is also the use of the devices for the presentation of polypeptides as “polypeptide chips”, as a miniaturized and highly parallel diagnostic tool, or for the detection of a risk during transfusion or organ donation.

The devices in accordance with the present invention may also be used as “polypeptide chips” for the serotyping or screening of epitopes.

These uses involve the detection of antigen-antibody type responses by the use of labeled, fluorescent, radioactive or chemically labeled reagents.

The devices in accordance with the present invention may also be used as polypeptide chips for the quantification of proteins in complex biological media.

Finally, the devices in accordance with the present invention may also be used for analyzing the relationships between peptide biological molecules of the ligand-receptor type.

In addition to the preceding features, the invention also comprises other features which will emerge from the description which follows, which refers to an example of preparation of glass slides functionalized with semicarbazide groups, to an example detailing the protocol for adsorption of polypeptides onto glass slides semicarbazides and the use of the corresponding devices thus obtained, for use of the devices of the invention for the serodiagnosis of hepatitis B, hepatitis C and AIDS, for studying the stability of these devices, for studying multiserodetection and for the detection of the hepatitis B surface antigen, and to the appended FIGS. 1 to 5 in which:

FIGS. 1 and 2 represent the fluorescence signal measured as a function of the antigen concentration, after 0, 1 or 3 months of aging of semicarbazide slides onto which AIDS virus antigens have been adsorbed;

FIGS. 3 and 4 represent the fluorescence signal measured for aminated slides to which AIDS virus antigens have been attached, as a function of the concentration and after 0 and 1 month of accelerated aging;

FIG. 5 represents the fluorescence measured as a function of the quantity of a recombinant HBs antigen in a test for serodetection of the hepatitis B surface antigen.

EXAMPLE 1

Functionalization of Glass Slides with Semicarbazide Groups

This functionalization was carried out according to two variants.

1) First Variant

a) Step A: Washing, Stripping and Silanization

Precleaned commercial microscope slides (Esco), with round edges and with a depolished margin are immersed in a solution consisting of a mixture of hydrogen peroxide and sulfuric acid (50/50, v/v) overnight. Preliminary three-minute rinses are performed with deionized water (3 times) and then with methanol (once), before immersing the slides in a bath containing 3% aminopropyltrimethoxysilane in methanol at 95% for 30 minutes under ultrasound. The slides are then rinsed successively with baths of 3 minutes in methanol (once), with deionized water (twice) and finally with methanol (once). The slides are then drained for a few minutes, dried for 15 minutes in an oven at 110° C., and then stored in a desiccator under vacuum.

b) Step B: Formation of an Isocyanate

The previously silanized slides are immersed for 2 hours in a solution of 1,2-dichloroethane containing triphosgene (100 mmol/l) and diisopropyl-ethylamine (DIEA) (800 mmol/l).

c) Step C: Functionalization with Semicarbazide Groups

The slides obtained in step b) above are then rapidly drained before being directly immersed in a solution containing 9-fluorenylmethoxycarbonyl-NH—NH₂ (Fmoc-NH—NH₂), prepared beforehand according to Zhang et al., Anal. Biochem., 1991, 195, 160-170, at 22 mmol/l in dimethylformamide (DMF) and treated for 2 hours with ultrasound. The slides are then rinsed successively with two baths of 3 minutes in DMF.

d) Step D: Deprotection

The slides previously obtained in step c) above are immersed in a solution of DMF containing piperidine (0.2% by volume) and 1,8-diazabicyclo[5.4.0]-undec-7-ene (DBU) (2% by volume) for 30 minutes. The slides are then rinsed successively with baths of 3 minutes in DMF (once), with deionized water (twice) and finally with methanol (once) before being dried and stored in a desiccator under vacuum.

2) Second Variant

The steps of silanization and functionalization with semicarbazide groups are coupled in a single reaction, by prior preparation of the reagent.

a) Step A: Preparation of the Silanization Reagent Containing the Protected Semicarbazide Group (Fmoc-NH—NH—CO—NH— (CH₂)₃—Si—(OEt)₃)

515 mg of Fmoc-NH—NH₂ (2.03 mmol) are suspended in 15 ml of absolute ethanol. The mixture is heated to reflux temperature (75-80° C.). 570 ml of isocyanopropyltriethoxysilane (2.28 mmol, 1.2 eq) are then added all at once. After the disappearance of the suspension (15-20 minutes), the ethanol is evaporated off. The white solid obtained is dissolved in a minimum of dry dichloromethane, and then precipitated using dry pentane. After filtration under argon, 841 mg (83%) of a pure solid are recovered.

b) Step B: Preparation of the Slides

Precleaned commercial microscope slides (Esco), with round edges and with a depolished margin are immersed in a solution consisting of a mixture of hydrogen peroxide and sulfuric acid (50/50, v/v) overnight. The slides are then rinsed, with stirring, in the following successive baths: deionized water (3 times 3 minutes), absolute ethanol (once 3 minutes) and then dried using a slide vane rotary vacuum pump.

The slides are then immersed for 2 hours in a solution containing 1 mg/ml of the silanization reagent prepared above in step a) in a mixture of tetrahydrofuran (THF) at 10% in toluene at 47° C. and under ultrasound. The slides are then rinsed, with stirring, in toluene (twice 3 minutes) before being drained, and then dried for 15 minutes in an oven at 120° C. and stored in a desiccator under vacuum.

c) Step C: Deprotection

The slides previously obtained above in step b) are immersed in a solution of DMF for 3 minutes before being placed under stirring in a bath containing piperidine (0.2% by volume) and diazabicycloundecene (2% by volume) in DMF for 30 minutes, with stirring. The slides are then rinsed successively with baths of 3 minutes in DMF (once), in deionized water (twice) and finally in methanol (once) before being dried and stored in a desiccator under vacuum.

The slides thus prepared are ready to be used to adsorb polypeptides.

EXAMPLE 2

Protocol for Using the Semicarbazide Slides

1) Adsorption of the Polypeptides onto the Slides

Solutions of synthetic peptides or of recombinant proteins (antigens) are diluted, between 0.1 and 10 mg/ml according to the protein used, in a phosphate buffer (pH 7.4) or in a carbonate/bicarbonate buffer (pH 9.2) and are then distributed into the wells of a 96-well ELISA plate. A minimum volume of 20 μl of sample per well is necessary to carry out the step of imprinting the slides.

The plate is then introduced into a 4-pin automated spotter (for example of the MWG 417 Arrayer type from the company Affymetrix). The apparatus which makes it possible to carry out the depositions of antigen solutions is called spotter.

The slides are then imprinted with the solutions of polypeptides according to a preestablished scheme. The pins are then thoroughly washed according to the recommendations of the manufacturer.

2) Storage of the Slides

The slides thus imprinted are stored at room temperature, in a closed cupboard, protected from light and from dust. The stability of the slides was studied (see example 6 below). The results show that the properties of the slides thus imprinted are not impaired during a three-month storage at 37° C. in a humid atmosphere (accelerated aging conditions).

3) Visualization of the Slides

The imprinted slides are first of all subjected to a sonication step for 1 hour in a saturation solution: phosphate buffer supplemented with 1.8% NaCl, pH 7.4 (PBS solution)+0.1% Tween® 20+5% skimmed milk).

The slides are then subjected to three successive washes with a PBS solution in the presence of 0.05% Tween® 20.

The slides are then incubated for 45 minutes at 37° C. in the presence of 100 μl of serum from patients, diluted 1/50 in a dilution buffer (PBS solution+0.1% Tween® 20+5% skimmed milk) under a glass coverslip (24×60 mm). The incubation is performed in a humid atmosphere.

Following this incubation, three successive washes of the slides with a PBS solution supplemented with 0.05% Tween® 20 are then performed.

The step for detection of the patients' antibodies on the polypeptides adsorbed onto the slides is carried out by attaching thereto fluorescent anti-human Ig antibodies: 100 μl of anti-human IgG-A-M solution of antibodies labeled with rhodamine (TRITC) (Jackson ImmunoResearch Laboratories, Baltimore, USA), diluted 1/100 in dilution buffer (PBS solution+0.1% Tween® 20+5% skimmed milk). Each slide is then covered with a glass coverslip (24×60 mm) and left to incubate for 45 minutes at 37° C. under a humid atmosphere.

Following this incubation, a series of 3 successive washes of the slides with a solution of PBS supplemented with 0.05% Tween® 20 is then performed. These washes are followed by rinsing of the slides with distilled water and by drying the slides with ethanol.

The reading of the slides is then performed by measuring the fluorescence emitted with the aid of a slide scanner (Affymetrix 418 Array Scanner), at two different power settings (P35/PMT 50 or P55/PMT 70). The quantification of the fluorescence emitted is then performed with the aid of the Scanalyse® software (Stanford-University Software). Unless otherwise stated, the results presented in the tables below were obtained at the power P35/PMT 50.

All the examples which follow were carried out according to this protocol.

EXAMPLE 3

Use of Polypeptide Chips According to the Invention for the Serodiagnosis of Hepatitis B

1) Materials and Methods

All the depositions were performed in duplicate on slides as detailed above in example 1, using an MWG 417 Arrayer Spotter (Affymetrix). The distance between the deposits is 375 μm, the control for the efficacy of the washing of the pins is performed by deposition of water, which shows by fluorescence no trace of antigen.

In this example, the glass slides were imprinted with various hepatitis B virus antigens. The terms surface (HBs), core (HBc) or (HBe) correspond to various regions of this virus. Twenty depositions per antigen and per concentration were performed.

HBs antigen, two batches were used:

HBs batch a: antigen marketed by the company Advanced Immuno Chemical under the reference A1-HS7, at 3 mg/ml.

HBs batch b*: 5 mg/ml.

Hbe antigen*: 10 mg/ml.

HBc antigen*: 10 mg/ml.

Positive control*: protein A

The HBV antigens (HBs batch b, Hbe, HBc) and HCV antigens were produced by “The Hepatopathy Research Institute”, Pediatric Hospital of Beijing (Beijing, China).

Sera from patients whose serology is known (that is to say verified with a reference ELISA test) were analyzed using the chips in accordance with the invention.

The preparation of the sera were as follows:

serodiagnostic HBs Ag with batch a: 40 sera noted positive and 40 sera noted negative;

serodiagnostic HBs Ag with batch b: 40 sera noted positive and 40 sera noted negative;

serodiagnostic Hbe: 16 sera noted positive and 16 sera noted negative;

serodiagnostic Hbc: 60 sera noted positive and 40 sera noted negative.

2) Results

the results obtained for the positive sera are present in table 1 below. In this table, the values given correspond to the fluorescence value less the mean background noise for the slide.

	TABLE I
	Test on biochips (quantity
	of fluorescence)
	Reference ELISA test	HBs	HBs
Serum	HBs	HBe	HBc	Batch a	Batch b	HBe	HBc
1	+	+	+	5482	5548	10254	15049
2	+	nt *	+	4521	7845	nt	16804
3	+	nt	+	2899	5784	nt	25014
4	+	+	+	4503	9854	5784	11568
5	+	+	+	4310	8547	14215	19580
6	+	nt	+	6854	7548	nt	28954
7	+	+	+	5871	10055	8457	9109
8	+	nt	+	3771	7156	nt	14201
9	+	+	+	4587	8457	11451	21131
10	+	nt	+	5684	11784	nt	9605
11	+	+	+	4089	9524	10254	15460
12	+	nt	+	3854	9995	nt	12541
13	+	+	+	2998	8457	11254	47988
14	+	nt	+	7033	9854	nt	25153
15	+	+	+	5714	12541	11116	27405
16	+	nt	+	3601	6985	nt	18954
17	+	nt	+	4707	7722	nt	14521
18	+	+	+	5515	8146	7895	25254
19	+	nt	+	6939	9524	nt	10939
20	+	nt	+	4196	10091	nt	34137
21	+	nt	+	5553	9104	nt	36387
22	+	nt	+	4357	9182	nt	22703
23	+	+	+	4007	10541	9548	31225
24	+	nt	+	4739	16608	nt	36695
25	+	nt	+	3958	12541	nt	23552
26	+	nt	+	5270	8620	nt	11251
27	+	nt	+	3254	9288	nt	57835
28	+	+	+	4194	11415	7854	18828
29	+	nt	+	3997	7698	nt	28461
30	+	nt	+	5980	8145	nt	35261
31	+	nt	+	3215	9354	nt	15854
32	+	nt	+	4254	7125	nt	28554
33	+	+	+	5412	16859	5896	26551
34	+	nt	+	3984	8327	nt	29376
35	+	nt	+	4521	10270	nt	15189
36	+	nt	+	4879	7458	nt	29276
37	+	nt	+	5895	17791	nt	25654
38	+	nt	+	4987	13232	nt	29854
39	+	nt	+	6587	14587	nt	21900
40	+	nt	+	3254	9587	nt	15854
41	+	nt	+	nt	9854	nt	25044
42	+	nt	+	nt	9968	nt	19578
43	+	+	+	nt	13263	4985	25654
44	+	nt	+	nt	12335	nt	21066
45	+	+	+	nt	11009	14882	25654
46	+	nt	+	nt	14528	nt	19850
47	+	nt	+	nt	7458	nt	9854
48	+	nt	+	nt	8954	nt	14592
49	+	nt	+	nt	9958	nt	15253
50	+	+	+	nt	10499	7180	12454
51	+	nt	+	nt	8521	nt	14254
52	+	nt	+	nt	8637	nt	21548
53	+	nt	+	nt	7410	nt	35689
54	+	nt	+	nt	9587	nt	14587
55	+	nt	+	nt	5985	nt	16548
56	+	+	+	nt	8457	4958	25415
57	+	nt	+	nt	9485	nt	39548
58	+	nt	+	nt	8567	nt	9854
59	+	nt	+	nt	15421	nt	12458
60	+	nt	+	nt	8214	nt	19874
Threshold				421	784	712	854
value
* nt means not tested

The threshold value (VS) is calculated as the mean of the signal for 20 negative sera minus the background noise to which is added 3 times the standard deviation calculated on these negative serum values. All the sera noted negative gave a fluorescence value less than the threshold value and were therefore indeed found to be negative using the slides in accordance with the invention.

All these results show that the use of polypeptide chips in accordance with the invention allows a serodiagnosis which is 100% sensitive and specific for all the hepatitis B antigens tested on the various sera. Indeed, all the sera recorded as being positive were detected, whereas none of the sera recorded as being negative were found to be falsely positive by this method.

EXAMPLE 4

Use of Polypeptide Chips According to the Invention for the Serodiagnosis of Heptatitis C

1) Materials and Methods

According to the method described above in example 3, glass slides were imprinted with various hepatitis C virus antigens, at various concentrations. The terms NS3, NS4 or core correspond to the various regions of the hepatitis C virus. In this example, protein A was used as positive control.

HCV Batch 1 corresponding to the whole antigen: depositions at 0.5 mg/ml, 0.1 mg/ml and 0.05 mg/ml;

HCV Batch 2 corresponding to the whole antigen: depositions at 2 mg/ml, 1 mg/ml and 0.5 mg/ml;

HCV core Ag: depositions at 1 mg/ml, 0.5 mg/ml and 0.1 mg/ml;

HCV NS3 Ag Batch 3: deposition at 1 mg/ml, 0.5 mg/ml and 0.1 mg/ml;

HCV NS4 Ag Batch 5: depositions at 0.4 mg/ml and 0.1 mg/ml;

100 sera noted positive by a conventional 3.0 Abbot EIA test (ELISA type method) and 30 sera noted negative by the same method were tested in this example.

2) Results

The results made it possible to determine the optimum concentrations to use for each antigen:

HCV Batch 2: 2 mg/ml

HCV NS3 Ag Batch 3: 0.5 mg/ml

HCV NS4 Ag Batch 5: 0.4 mg/ml

HCV core Ag: 1 mg/ml

The results obtained are presented in table II. In this table, the values given correspond to the fluorescence value minus the mean background noise for the slide.

	TABLE II
	RIBA		HCV Batch 1	HCV Batch 2	HCV core Ag	NS4 HCV Ag	NS3 HCV Ag
Serum	NS5	Core	NS3	NS4	Abbott	0.5 mg/ml	2 mg/ml	1 mg/ml	0.4 mg/ml	0.5 mg/ml
1		+++	++	++	117	11254	35268	17854	6254	13215
2	−	−	−	−	1	25	156	0	0	0
3		−	+++	+++	125	11245	39421	0	10545	21514
4		−	++	+	50	10524	32157	0	5214	8954
5		−	+++	+++	?	14521	39564	0	11245	15462
6	0.5+	−	−	0.5+	2	331	1085	0	312	0
7		++	+	+	30	8547	15242	15421	5985	9584
8		−	++	−	1	456	1025	0	0	452
9		−	−	−	2	42	135	0	0	0
10		+++	++	++	112	14215	38546	21542	12352	20135
11		+++	++	++	46	17548	41526	23215	17548	21524
12	+	0.5+	−	−	7	925	3854	4162	0	0
13		++	+	++	105	14582	35216	18546	13250	15468
14	0.5+	−	0.5+	−	1	495	1958	0	0	568
15		+++	++	0.5+	?	10254	29856	21452	2154	7548
16		++	+++	+++	130	15429	32964	29584	12496	16548
17		−	−	−	1	29	107	0	0	0
18		−	−	−	2	36	185	0	0	0
19		+++	+++	+++	113	17859	39520	28964	15421	19548
20		+++	++	+++	100	21524	451214	31250	19854	20482
21		+++	+++	+	74	19854	35219	28546	5485	17458
22		0.5+	+	0.5+	?	512	1021	456	651	325
23		+++	++	0.5+	80	15214	38546	21549	542	12415
24		−	++	+	25	5684	12409	0	4632	6895
25		−	−	−	1	47	146	0	0	0
26		−	−	−	73	28	134	0	0	0
27		+++	+++	++	78	18549	39507	25348	8549	17965
28		+++	++	++	?	21549	41305	29846	14528	22304
29		−	−	−	1	51	152	0	0	0
30		++	++	−	?	12045	25365	18546	0	4325
31	0.5+	−	+	−	4	1524	6528	0	0	1095
32		−	−	−	6	39	128	0	0	0
33		+++	+++	0.5+	142	9602	21795	11542	598	5695
34		+++	+++	+++	120	16325	35985	24065	11248	16524
35		+++	+++	+++	159	25639	45681	29032	15486	21468
36		+++	+++	++	135	21025	32598	25584	12495	15421
37		+++	+	−	?	15421	25625	20135	0	2154
38		+++	+++	+++	140	24569	38569	29584	18542	14025
39		+++	+++	0.5+	132	12542	25146	14201	354	5698
40		+++	+++	+++	?	19854	29524	21024	11245	9587
Threshold value:	115	315	0	0	0

NB: In this table, the question mark means that the Abbott test was not performed.

All the sera noted positive were found to be positive using the slides in accordance with the invention.

In the same manner, all the sera noted negative were found to be negative using the slides in accordance with the invention.

The results show that the fluorescence signal obtained at a low power setting (P35, PMT50) is high and does not require a second reading at a higher scanner power setting (L55, PMT 70).

For HCV Batch 1 and Batch 2, for which a low fluorescence value is observed for the negatives, the threshold value is calculated as the mean of 20 sera minus the background noise, supplemented with 3 times the standard deviation on these values for the negative sera. For the other antigens tested, no fluorescence greater than the background noise is observed for the negative sera; the threshold value therefore corresponds to the value for the negatives minus the background noise, that is zero.

Thus, for HCV core, NS4 and NS3, if a fluorescence signal is observed, it means that the serum is positive. This represents a huge advantage compared with a serodiagnosis performed in a conventional manner by the ELISA method for which a nonspecific signal is always observed with the negative sera, which requires defining a threshold value which depends on this nonspecific signal.

Furthermore, it is evident from these results that Batch 2 is of particular interest: it increases the sensitivity of the serodetection by making it possible to unambiguously detect sera which are weak by Abbott ELISA (less than 10), for which RIBA (Recombinant Immunoblot Assay: recombinant immunoblot test performed on a nitrocellulose membrane and which makes it possible to know against which hepatitis C virus antigen the antibodies produced following a viral infection are directed) is either positive or borderline (0.5+). The use of the antigen of Batch 2 adsorbed onto a semicarbazide support therefore makes it possible to improve the detection sensitivity compared with ELISA, which is particularly advantageous in terms of how early the detection is made. Furthermore, the polypeptide biochips in accordance with the invention are more specific than the reference Abbott ELISA. Indeed, the Abbott false-positive sera (sera 2, 9, 17, 18, 25, 26, 29 and 32, sera confirmed RIBA negative) were correctly diagnosed (negative) using the polypeptide biochips in accordance with the invention.

The semicarbazide glass slides onto which NS3, NS4 and core antigens are adsorbed therefore constitute sensitive and specific diagnostic tools which make it possible to differentiate the different hepatitis C antigens whereas with the ELISA technique, which uses combinations of different antigens, it is not possible to obtain such a differentiation.

EXAMPLE 5

Use of Polypeptide Chips According to the Invention for the Serodiagnosis of AIDS

1) Materials and Methods

In this example, 30 depositions per antigen were performed on each slide.

Two different antigens of the AIDS virus (HIV) were tested; they are the Gp41 and Gp120 antigens which are envelope glycoproteins of the virus. These HIV antigens are produced by Lily Bioproducts, Hanan, China.

Protein A was used as positive control.

The concentrations tested are the following:

Gp41: 2; 1; 0.5; 0.1 and 0.05 mg/ml.

Gp120: 0.5; 0.25; 0.1 and 0.05 mg/ml.

90 sera noted positive and 20 sera noted negative were tested (ELISA technique: Genscreen Plus® HIV Ab tests from the company BIORAD and HIV Integral test from the company BEHRING).

2) Results

The results obtained are presented in table III below. In this table, the values given correspond to the fluorescence value minus the mean background noise for the slide.

	TABLE III
	Biochips
	Gp 120	Gp 41
Serum	0.5 mg/ml	0.25 mg/ml	0.1 mg/ml	0.05 mg/ml	2 mg/ml	1 mg/ml	0.5 mg/ml	0.1 mg/ml	0.05 mg/ml	ELISA
1	41730	45803	10773	7431	31803	27549	22958	13036	8696	positive
2	41251	6674	8697	9715	8801	17586	9713	4403	2753	positive
3	30864	25786	11666	10212	17026	29694	24347	23607	18137	positive
4	32520	32206	11738	15973	11655	17779	12531	6333	1276	positive
5	42022	28683	11415	12791	16405	15092	8320	2425	416	positive
6	38148	28426	18753	12226	19196	21076	16184	13239	10817	positive
7	40494	30883	10035	9086	6827	23866	10504	9898	9131	positive
8	20017	10248	4870	1697	2542	4125	1952	1476	624	positive
9	39166	33241	18446	19500	32768	31779	16132	31833	22971	positive
10	30095	31628	28099	9779	26105	9199	10716	24191	17998	positive
11	25325	32705	20765	6586	24592	13347	13756	17951	17910	positive
12	31086	29523	20547	23421	31727	9113	11450	16056	8712	positive
13	15770	9700	4111	2335	2754	1025	1001	1069	558	positive
14	26899	20507	13152	5158	34566	18887	17524	24524	19103	positive
15	40110	22294	14237	13483	23908	10768	9704	12873	12875	positive
16	29285	14812	12227	13764	5741	16013	10362	7814	4958	positive
17	6169	2828	2472	983	12809	1337	543	536	372	positive
18	10737	5860	3221	847	19181	3125	857	912	316	positive
19	3372	1710	1861	855	14325	401	228	378	241	positive
20	4826	2600	1883	859	8209	459	74	50	48	positive
21	9420	4764	2473	2481	18438	530	420	558	447	positive
22	3716	1157	1488	687	11022	3016	529	245	153	positive
23	3962	2142	1873	699	16695	1965	1309	559	453	positive
24	4829	2160	2030	1818	23621	8958	2658	1956	1401	positive
25	7940	4661	2528	1071	19965	6998	6377	2316	1506	positive
26	21004	9097	5555	2889	19658	3999	968	655	636	positive
27	2887	813	2055	355	11946	1917	256	128	182	positive
28	25044	8379	10041	14256	33037	29819	23874	5817	1251	positive
29	18541	7548	2514	544	17854	14511	2512	956	251	positive
30	13921	8514	3357	1674	19126	5050	1146	720	446	positive
31	4545	1698	1672	596	16584	6584	3215	845	605	positive
32	15214	7996	4562	1996	21996	8965	3915	1746	1748	positive
33	9862	4143	3326	1139	13948	2438	1069	586	293	positive
34	2985	1042	1479	546	4299	117	69	79	92	positive
35	1475	832	641	440	6033	110	92	93	99	positive
36	1023	460	694	312	6999	1012	332	123	134	positive
37	4667	3665	2296	1050	12348	627	321	471	109	positive
38	19895	7985	6985	3965	31335	12691	2965	2018	1824	positive
39	8262	3918	2217	2010	12766	404	152	130	124	positive
40	8454	4512	2520	905	19958	1985	1081	817	569	positive
41	4869	3154	2088	1876	14431	301	174	108	162	positive
42	4418	1700	2009	706	17996	2020	899	658	570	positive
43	14731	8722	3526	924	18234	2762	1019	537	489	positive
44	5882	2186	1850	1108	10068	3715	946	441	257	positive
45	5793	3095	2070	1401	23721	7457	4045	1450	628	positive
46	1015	857	755	170	19449	2928	2075	468	826	positive
47	12328	7366	3145	1399	22145	2921	844	340	215	positive
48	5752	2618	2431	797	20449	1014	661	673	431	positive
49	8488	3424	4210	1141	21470	4823	4523	1853	713	positive
50	3989	1744	1346	619	18434	6315	4185	1803	160	positive
51	903	650	671	291	658	510	110	92	56	positive
52	6905	4325	2102	1998	11120	3956	2481	442	517	positive
53	2939	2002	773	440	2669	542	372	317	385	positive
54	6683	3295	1408	572	19008	5583	3236	856	813	positive
55	1985	549	731	433	716	250	225	234	212	positive
56	3228	1990	940	540	2070	395	262	166	221	positive
57	12985	7665	2885	1655	10926	3952	2365	699	548	positive
58	6254	3452	1958	1841	7985	1682	676	487	707	positive
59	6428	3858	1754	1088	15985	7542	4658	746	699	positive
60	9467	8235	2547	1024	17883	10764	7289	1396	1127	positive
61	8260	6841	2403	1013	11923	3895	3265	372	303	positive
62	6341	4937	2038	928	6143	2699	2382	720	387	positive
63	4812	3236	1286	762	2828	1311	950	154	188	positive
64	2446	1417	1388	659	1542	631	541	138	194	positive
65	5896	3199	1838	709	1958	424	197	74	80	positive
66	13101	8985	3652	1658	19856	7910	5308	1921	1295	positive
67	5099	2003	1354	784	7985	2654	1995	318	422	positive
68	8665	4980	1927	1396	17168	8105	5520	1026	851	positive
69	12542	8956	499	542	9584	5421	2865	254	310	positive
70	9895	4947	2695	990	13114	4870	2991	1819	1399	positive
71	7149	5658	2476	2975	16003	6859	3112	3722	1496	positive
72	6631	4666	2296	1312	8465	681	572	310	418	positive
73	12220	11355	4037	2916	19856	4685	3378	921	617	positive
74	9738	8170	2855	1298	12710	2156	1985	1254	800	positive
75	9965	6847	2658	797	14587	2654	1542	554	402	positive
76	5948	3772	1875	3695	13789	1077	1069	329	611	positive
77	7958	3889	2006	744	7130	386	348	162	202	positive
78	5811	4568	1935	1609	6700	833	659	227	246	positive
79	3083	1738	1414	1551	5630	245	242	169	201	positive
80	2546	1214	1021	356	1985	1021	548	365	212	positive
81	10254	8457	5468	2154	15214	2452	1025	566	213	positive
82	5621	2354	1214	548	14584	1744	365	219	145	positive
83	5327	4098	1977	1129	6174	240	390	269	250	positive
84	2635	1966	1600	691	1084	167	116	107	77	positive
85	8769	6988	2371	1520	9906	287	235	199	301	positive
86	1044	998	788	444	8955	1699	842	432	509	positive
87	6126	4416	3234	2078	1326	1181	86	104	76	positive
88	6356	3455	1893	1724	9098	495	450	141	216	positive
89	17917	7762	4384	2328	16504	3324	856	576	533	positive
90	5435	2495	2335	724	18104	921	607	596	398	positive

NB 20 negative sera were tested; they do not give a fluorescence value greater than the background noise (threshold value=0).

These results show that the use of the test in accordance with the invention allows a sensitive and 100% specific diagnosis of the positive and negative sera, at all the concentrations tested.

As regards the Gp41 antigen, the optimal concentration is 1 mg/ml and 0.5 mg/ml for the Gp120 antigen; however, for the latter, the plateau for saturation of the signal was perhaps not reached, which suggests that higher concentrations could also lead to excellent results.

EXAMPLE 6

Study of the Stability Over Time of the Devices Prepared in Examples 4 and 5

In order to test the stability over time of the devices according to the invention, semicarbazide glass slides imprinted by adsorption of AIDS virus antigens, as prepared in example 5 above, were placed at 37° C. in a humid atmosphere for a period of 1 or 3 months. These conditions make it possible to carry out an accelerated aging study.

This study related to slides prepared with various antigens, at several concentrations:

HIV Gp41 at 2; 1; 0.5; 0.1 and 0.05 mg/ml;

HIV Gp120 at 0.5; 0.25; 0.1 and 0.05 mg/ml;

The results obtained are presented in the accompanying FIGS. 1 and 2 in which the fluorescence signal depends on the antigen concentration, these being at 0 (hatched bars), 1 (checkered bars) and 3 months of accelerated aging (plain bars).

These results demonstrate an excellent stability of the slides after 3 months of accelerated aging, regardless of the concentrations tested.

COMPARATIVE EXAMPLE 7

Study of the Stability of the Aminated Slides of the Prior Art

Microscope slides silanized with 3-aminopropyl-trimethoxysilane as described for example in the article by Zammatteo N. et al., Anal. Biochem., 2000, 280, 143-150, as well as slides functionalized with semicarbazide groups as described in example 1 above, were imprinted with two AIDS virus antigens (Gp120 and Gp41 as described above in example 5) and at various concentrations (0.5; 0.25; 0.1; 0.05 and 0.01 mg/ml).

The slides thus prepared were incubated with 20 sera noted positive. The slides thus prepared were subjected to a study of stability over time, according to the protocol described above in example 6.

The results obtained are represented in the accompanying FIGS. 3 and 4 in which the fluorescence values are expressed as a function of the concentrations tested.

The stability study was stopped after 30 days (at t=0:clear bars and at t=30 days:shaded bars).

These results show that the aminated slides of the prior art are not stable after 1 month of storage; very large variations are indeed observed with either a drop in the fluorescence measured, or its increase.

On the other hand, and as was demonstrated above in example 6, the slides containing semicarbazide groups in accordance with the invention are stable after three months of storage under accelerated conditions.

EXAMPLE 8

Use of Semicarbazide Slides for a Multi Serodetection Study

In this example, semicarbazide glass slides as prepared in example 1 above were imprinted with antigens obtained from various pathologies (HIV, hepatitis B:HBV and hepatitis C:HCV).

90 sera referenced for all these pathologies by conventional ELISA type tests were tested on the slides in accordance with the invention (BIOCHIPS).

For the HIV test, the reference methods used are the Genscreen Plus® HIV Ab test from the company BIORAD and the HIV Integral Ab test from the company BEHRING. The positivity of these tests is confirmed by a Western blotting test.

For the hepatitis B tests, the reference methods used are the HBs test from the company BIORAD and the HBc test from the company BIORAD.

For the hepatitis C tests, the reference methods used are the HCV test from the company BIORAD and the HCV EIA 3.0 test from the company ABBOTT. The positivity is confirmed by a RIBA DECISCAN HCV PLUS® test.

For the hepatitis C test on the biochips in accordance with the invention, the slides were imprinted with the recombinant antigens of NS3 (0.5 mg/ml) and of the whole gene (Batch 1: 0.5 mg/ml).

For the hepatitis B test on the biochips in accordance with the invention, the slides were imprinted with the antigens HBc (core) at 10 mg/ml and HBs Batch b at 5 mg/ml, as described above in example 3.

For the test of seropositivity compared with the AIDS virus on the biochips in accordance with the invention, the slides were imprinted with the Gp120 (0.5 mg/ml) and Gp41 (2 mg/ml) antigens as described above in example 5.

Before their use, the sera were diluted 1/50 as described above. The slides were first incubated for 45 minutes with these sera, and then for 45 minutes with the complementary fluorescent antibody.

The results obtained are presented in table IV below:

	TABLE IV
	ELISA	BIOCHIP
	Number		HBV		HIV	HBV	HCV
Entry	sera	HIV	HBs	HBc	HCV	Gp120	Gp41	HBs	HBc	Whole Gene	NS3
1	19	+	−	−	−	+	+	−	−	−	−
2	2	+	−	+	−	+	+	−	+	−	−
3	1	+	−	−	+	+	+	−	−	+	+
4	4	−	−	−	+	−	−	−	−	−	−
5	1	+	−	−	+	+	+	−	−	−	−
6	7	−	−	+	+	−	−	−	+	+	+
7	10	−	−	−	+	−	−	−	−	+	+
8	4	−	+	+	−	−	−	+	+	−	−
9	17	−	−	+	−	−	−	−	+	−	−
10	4	−	−	+	+	−	−	−	+	+	+
11	20	−	−	−	−	−	−	−	−	−	−
NB: + positive serum, − negative serum

These results show a perfect correlation for 85 sera tested out of 90; however, for the 5 sera corresponding to the entries 4 and 5, a difference was observed between the two methods, these sera were found to be HCV positive by the reference ELISA method and negative for the BIOCHIP method in accordance with the invention (entries No. 4 and No. 5).

In order to verify this difference, the RIBA test—which serves to confirm the positivity of a serum toward hepatitis C—was carried out and proved to be negative. These sera are therefore HCV negative since they do not possess antibodies directed against the virus, they have not therefore been in contact with this virus.

This confirms the BIOCHIP result which had given these sera as being negative; these sera are therefore false-positives for the reference ELISA method.

EXAMPLE 9

Use of Semicarbazide Slides for Assaying the HBs Protein in a Complex Biological Medium

The aim of this example is to demonstrate that the use of the devices in accordance with the invention makes it possible to attach a monoclonal antibody to a glass slide containing semicarbazide groups (antigen directed against the hepatitis B virus surface antigen) which is then brought into contact with a serum possessing this surface antigen; the visualization being carried out using another monoclonal antibody labeled with rhodamine and directed against the hepatitis B virus surface antigen.

This so-called “sandwich” technique makes it possible to detect circulating antigens in a serum. This technique has numerous potential applications both in serodiagnosis and in screening for biological molecules (search for active or toxic substances), by attaching a whole series of known monoclonal antibodies directed against these biological molecules.

1) Materials and Methods

Glass slides functionalized beforehand with semicarbazide groups according to example 1 above are imprinted, using an automated spotter with a solution containing 3 mg/ml of a monoclonal antibody (murine antibody clone NE3 from the company Advanced Immuno Chemical) in a carbonate/bicarbonate buffer (pH 9.2).

Each deposition is performed 3 times, which makes a total of 27 depositions of monoclonal antibody solution for each slide.

Known quantities of a recombinant HBs antigen (company Advanced Immuno Chemical at 0.5 mg/ml) are added to 200 μl of negative sera diluted 1/50. These sera (100 μl) are then brought into contact with the glass slides onto which the monoclonal antibodies have been attached beforehand. The deposits are covered with a glass coverslip. The glass slides are then incubated for 2 hours at 37° C. in a humid atmosphere.

After washing, the visualization step is performed with 100 μl of a solution of murine anti-hepatitis B surface antigen monoclonal antibody (NF5 clone marketed by the company Advanced Immuno Chemical at a concentration of 1.5 mg/ml), labeled beforehand with rhodamine and diluted 1/100 in a dilution solution (PBS-Tween 0.1%—semiskimmed milk 5%).

The incubation is performed for 60 minutes between slide and coverslip, at 37° C. under a humid atmosphere.

After washing, the slides are read by the Scanner from the company Affymetrix (Affymetrix 418 Array) at the power setting P70, PMT90. The quantification of the fluorescence is performed with the aid of the Scanalyse® software (Standford-University Software).

2) Results

The results obtained are presented in the appended FIG. 5 in which the fluorescence is expressed as a function of the quantity of recombinant HBs antigen added in mg/μl.

These results show that the use of the devices in accordance with the invention makes it possible to detect circulating antigens. They also show that the adsorption of the antibody onto the glass slide makes it possible to preserve the accessibility of the site of attachment of the antigen (Fab segment of the antibody) for the antigen-antibody recognition.

Claims

1. A device for the presentation of polypeptides, characterized in that it comprises at least one solid support functionalized with semicarbazide groups onto which said polypeptides are adsorbed.

2. The device as claimed in claim 1, characterized in that the polypeptides are chosen from peptides comprising at least two amino acids, peptidomimetics, proteins and protein fragments.

3. The device as claimed in claim 1 or 2, characterized in that the solid support is an organic or inorganic material chosen from glass, silicon and its derivatives and synthetic polymers.

4. A method for preparing a device for the presentation of polypeptides as defined in any one of claims 1 to 4, characterized in that it comprises the following steps: the functionalization of a solid support with semicarbazide groups, and the deposition, in the form of spots, of samples of polypeptides and their adsorption onto the support thus functionalized.

5. The method as claimed in claim 4, characterized in that the functionalization of the support comprises: the introduction of an amine functional group by a reaction for silanization of the support, the conversion of the amine functional group to an isocyanate functional group, the reaction of the isocyanate functional group with a hydrazine derivative in order to form the semicarbazide group.

6. The method as claimed in claim 4, characterized in that the functionalization of the support is performed in a single step, by reacting the support with a silane carrying a semicarbazide group.

7. The method as claimed in any one of claims 4 to 6, characterized in that the deposition of the polypeptides comprises: the preparation of polypeptide solutions in a buffer, at a concentration of between 10 mg/ml and 0.01 mg/ml; their distribution into a container appropriate for their collection, of the microtiter plate well type; their collection with the aid of a manual or automated sample collecting apparatus, for example of the “spotter” type; their deposition onto the semicarbazide support; and optionally the saturation of the support.

8. The use of a device for the presentation of polypeptides as claimed in any one of claims 1 to 3, as polypeptide chips as a miniaturized and highly parallel diagnostic tool.

9. The use of a device for the presentation of polypeptides as claimed in any one of claims 1 to 3, as polypeptide chips for the detection of a risk during transfusion or organ donation.

10. The use of a device for the presentation of polypeptides as claimed in any one of claims 1 to 3, as polypeptide chips for the serotyping or screening of epitopes.

11. The use as claimed in any one of claims 8 to 10, characterized in that it involves the detection of antigen-antibody type responses by the use of labeled, fluorescent, radioactive or chemically labeled reagents.

12. The use of a device for the presentation of polypeptides as claimed in any one of claims 1 to 3, as polypeptide chips for the quantification of proteins in complex biological media.

13. The use of a device for the presentation of polypeptides as claimed in any one of claims 1 to 3, as polypeptide chips for analyzing the relationships between peptide biological molecules of the ligand-receptor type.