EP1787118A1

EP1787118A1 - Method for increasing the dynamic recording range for microarrays

Info

Publication number: EP1787118A1
Application number: EP05772441A
Authority: EP
Inventors: Heinz Gerhard KÖHN
Original assignee: Eppendorf SE
Current assignee: Eppendorf SE
Priority date: 2004-09-10
Filing date: 2005-08-17
Publication date: 2007-05-23
Also published as: US20080096767A1; DE102004043870B4; WO2006027088A1; DE102004043870A1

Abstract

The invention relates to microarrays, whereby the samples are applied in various concentrations on a support. The invention relates in particular to a method of detection of particular molecules in a biological sample, by means of which the dynamic range of the recording is increased.

Description

Applicant: Eppendorf AG

Our sign: 80486 WO

Method for expanding the dynamic detection range in microarrays

The present invention relates to microarrays in which the various

Probe molecules are each applied several times and in different concentrations on a support. In particular, the present invention relates to an improved method for detecting certain target components in a sample.

Due to the ever-increasing amount of data on biological systems, in particular cellular systems, scientists increasingly face the problem of using as many of the known parameters as possible, such as the transcription of nucleic acids or the translation into proteins investigate.

Conventional (molecular) biological methods have usually involved experiments in which a particular target biological component has been targeted, such as a gene or the mRNA derived therefrom, or a protein, which is an evaluation of outcomes in the cell, particularly involving it several biological Zielkom¬ components only under difficult conditions allowed.

In recent years, so-called microarrays have been developed, with the help of a variety of biological targets can be investigated simultaneously. Such microarrays essentially contain a carrier, such as a glass or silicon wafer or a membrane, on which biological components of known composition, such as, for example, nucleic acids or proteins, are present at predetermined locations in a specific arrangement, a so-called array so-called probes (molecules), are applied. The size of these sites is usually about 20 microns so that a carrier can contain a variety of such sites. The microarrays enable a rapid and cost-effective investigation of, for example, gene expression and / or genetic Changes in a sample.

If the probes are nucleic acids, suitable nucleotides of known base sequence in a length of about 20 to 2000 bases in a predetermined arrangement on the support are immobilized (spotted). Subsequently, the sample to be examined is brought into contact with the carrier under conditions which permit hybridization of complementary strands. Non-complementary strands that do not undergo hybridization with the probes on the support are removed. The areas on the microarray containing nucleotide duplexes are determined and allow conclusions to be drawn about the sequence in the original sample.

The same applies to proteins as probes. For this purpose, suitable proteins, for example peptides or antibodies, are immobilized on the support (spotted) and the support is then brought into contact with the sample to be examined. Biological components bound to the probes are subsequently detected according to conventional methods.

Such "screening methods", in which a multiplicity of different probes are simultaneously contacted with a sample to be examined in a single assay, are also suitable for determining the amount of biological component trapped by the probe in the sample.

If the target components are present in the biological sample in a sufficient amount, the assay can usually be performed directly.

Problems arise in the implementation, however, if the sample on the one hand contains a large amount and also a small amount of target components, since the signal generated in the detection method of trapped target molecules is technically not linear to the number of molecules, but sigmoid , If a large amount of target molecules are contained in the sample, the determination can not be made quantitatively due to a saturation effect of the signal upon detection. In this case, the assay must be repeated with less sample material, which in part is difficult or even impossible due to the availability of the sample itself.

On the other hand, even if the target components were present in the sample in a very low concentration, the signal can not be evaluated because too weak. One way around this is to amplify the target molecules in the sample before contacting with the microarray, for example in a nucleic acid by means of a PCR reaction. The disadvantage here again is that an amplification in the sample can be subject to errors, while a previous purification, for example removal of protein material, can itself introduce errors. Another known possibility in the presence of small amounts of target component (s) is the amplification of the signal itself.

However, both methods of amplification involve the risk of once again reaching a saturation range of the detection during the determination.

It is therefore an object of the present invention to provide an improved means by which the detection range of target components can be extended using a microarray.

This object is achieved according to the invention by providing a microarray which has a multiplicity of probe molecules immobilized on a support in a specific arrangement, one species of a probe molecule being present on the support at least three times and being present in different concentrations for one species of probe molecule. In the figures,

Fig. 1 is a graph showing the signal strength for fluorescence samples as a function of concentration.

2 schematically shows a microarray with 3 probes which have been applied in different concentrations.

In the studies that led to the present invention, it has been found that by providing at least 3 probes of the same specificity on the array, which are present in different concentrations, the dynamic range of the detection, in which a quantitative detection of the target components is possible, can expand so that even samples containing a large amount of target components, as well as samples that have a low

Amount of target components can be reliably quantified with an assay.

The carrier employed herein may be any of those commercially available and commonly used for the purpose of binding target molecules to probe molecules, including membranes, metal supports, plastic materials, beads or glass. For applying probe molecules to the support, it is also possible to use any method known in the prior art which temporarily or permanently effects immobilization, fixation or adhesion of the probe molecule at a site or in a region of the support, for example covalent , ionic, organometallic bonds, bonds based on van der Waals forces, or enzyme-substrate interactions or so-called "affinity bonds". Of course, any spacer molecules, for example polymer-based spacers, can be arranged between the support and the probe molecule applied to the support. In addition, suitable carriers for carrying out the present invention are those based on self-assembling layer systems. The application can currently also be achieved using automated methods. The probe molecules on the array are usually nucleotides of different sequence, but may also be a binding partner in a system, for example, antigen-antibody.

According to a preferred embodiment, the microarray has the same probe molecules, i. Probe molecules with the same specificity, in an amount of 3 to 10, more preferably 3 to 7, even more preferably 3 to 5, spotted on the support. The concentration differences between the individual probes applied at the respective sites may vary depending on the number of spots containing the same probe, for example by the factor of 1, 10 or 100. Preferably, the site with the highest concentration should be at least twice that have high concentration, such as the site with the lowest concentration of the same probe molecule. Thus, for example, in the case of using 10 probe molecules of the same specificity (ie, 10 spots to which the same probe molecules have been immobilized) on the array on which probe molecules of the same specificity are located, there will be a concentration gradient of 10%, with the site with the highest Concentration is set as 100%. In the preferred arrangement of three sites of the same probe molecules due to spatial arrangement on the array, there is a concentration gradient of 100%, 75% and 50%.

As detection methods, it is generally possible to use any currently used methods, for example silver, fluorescence or enzymatic reactions, for example horseradish peroxidase.

When using fluorescent dyes, the dynamic range can additionally be extended by using the excitation intensity in a stepped manner. If, for example, it is determined during a measurement that saturation has already been reached or the linear range has been left, then the measuring range can be returned to the linear range by reducing the excitation intensity.

The present invention also relates to a method for the quantitative determination of target molecules in a sample, which involves contacting a sample with a sample Microarray having certain probe molecules at predetermined locations under conditions that allow binding of the target molecules to the probe molecules. Each species of a probe molecule is present on the support at least three times at different locations and in different concentrations.

The detection of the target molecules bound to the support or their amount can be carried out according to conventional methods, such as dyeing methods with silver or fluorescence dyes or color formation by enzymatic reactions, such as with the aid of horseradish peroxidase. The dyeing thus obtained is then quantitatively evaluated by commercially available hardware and software products.

example

A DNA microarray was made with three different probes A, B and C. Three spots were generated with each probe. The three spots of each probe differed in concentration. The first spot of probe A was spotted at a defined concentration and set at 100%. For the other spots, the solution containing the probes was diluted such that the original concentration dropped to 70% and 50%, respectively.

The procedure was analogous for probes B and C.

Thus, 9 spots are obtained in the example:

The microarray thus obtained was hybridized with a solution containing the complementary strands of the applied probes B and C under standard conditions, using the probe C was used 1 ¹ times the amount.

The hybridized molecules were detected by the known method of silver staining. The signals should be proportional to the amount of hybridized DNA. The result shown in FIG. 2 was obtained, from which it can be seen that the different concentrations of DNA in the spots are considerably expanded in the dynamic range.

Claims

claims

A microarray containing a carrier; and thereon, in a certain arrangement, several probe molecules specific for particular target molecules are applied, each probe molecule specific for a particular target molecule being deposited on the support at least three times at different locations in the array and at different concentrations.

2. microarray according to claim 1, wherein the probe molecules specific for certain target molecules on the support in a number ranging from 3 to 7 times, preferably 3 to 5 times applied.

3. microarray according to claim 1 or 2, wherein the concentration of each same probe molecules at the different locations on the support by a factor in the range of 1 to 100, preferably 1 to 10 differs.

4. A microarray according to any one of the preceding claims, wherein each probe molecule is present on the support three times and the concentrations of the applied probe molecules is 100%, 75%, 50%, each based on the highest concentration.

5. Use of a microarray according to one of the preceding claims for the quantitative determination of a target component in a sample.

Use according to claim 5, wherein the sample is a biological sample.

7. A method for the quantitative determination of a target component in a sample, which comprises

Contacting a sample with a microarray according to one of claims 1 to 4, and determining binding of a target component at a location on the array.

8. The method of claim 7, wherein the determination of the component is carried out by silver colouration, fluorescence or enzymatic staining.