EP1483411A2 - Verbesserungen in bezug auf markierung - Google Patents

Verbesserungen in bezug auf markierung

Info

Publication number
EP1483411A2
EP1483411A2 EP03712311A EP03712311A EP1483411A2 EP 1483411 A2 EP1483411 A2 EP 1483411A2 EP 03712311 A EP03712311 A EP 03712311A EP 03712311 A EP03712311 A EP 03712311A EP 1483411 A2 EP1483411 A2 EP 1483411A2
Authority
EP
European Patent Office
Prior art keywords
dna fragment
fragments
different
marking system
dna
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP03712311A
Other languages
English (en)
French (fr)
Inventor
Jonathan Harold Forensic Science Service WETTON
Andrew John Forensic Science Service HOPWOOD
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Forensic Science Service Ltd
Original Assignee
UK Secretary of State for the Home Department
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from GB0204889A external-priority patent/GB0204889D0/en
Application filed by UK Secretary of State for the Home Department filed Critical UK Secretary of State for the Home Department
Publication of EP1483411A2 publication Critical patent/EP1483411A2/de
Withdrawn legal-status Critical Current

Links

Classifications

    • EFIXED CONSTRUCTIONS
    • E05LOCKS; KEYS; WINDOW OR DOOR FITTINGS; SAFES
    • E05GSAFES OR STRONG-ROOMS FOR VALUABLES; BANK PROTECTION DEVICES; SAFETY TRANSACTION PARTITIONS
    • E05G1/00Safes or strong-rooms for valuables
    • E05G1/14Safes or strong-rooms for valuables with means for masking or destroying the valuables, e.g. in case of theft
    • CCHEMISTRY; METALLURGY
    • C12BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
    • C12QMEASURING OR TESTING PROCESSES INVOLVING ENZYMES, NUCLEIC ACIDS OR MICROORGANISMS; COMPOSITIONS OR TEST PAPERS THEREFOR; PROCESSES OF PREPARING SUCH COMPOSITIONS; CONDITION-RESPONSIVE CONTROL IN MICROBIOLOGICAL OR ENZYMOLOGICAL PROCESSES
    • C12Q1/00Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions
    • C12Q1/68Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions involving nucleic acids

Definitions

  • This invention concerns improvements in and relating to marking, particularly but not exclusively, to the marking, labelling or identification of items by the use of DNA.
  • markings are intended to be visible, whilst a number of forms call for the marking to be invisible during normal use and only become visible in certain circumstances. Examples include inks which become visible under certain light conditions.
  • Certain other situations call for items to become marked in the event of certain circumstances arising and may additionally involve the transfer of the marking to individuals who come into contact with the marked item and/or to other locations which contact the item. Examples include the marking of bank notes with highly visible dye in the event of a robbery.
  • the marker included a number of DNA fragments, with each DNA fragment in a marker having a different length.
  • the variations in length may be supplemented by limited variations in the sequence of selected parts of the DNA fragments.
  • the different DNA fragment which make up the marker can be determined and compared with records of markers deployed. Use of different length DNA fragments is central to the technique.
  • the present invention has amongst its aims to provide a marking system which is covert but can readily be inspected
  • the present invention has amongst its aims the provision of a marking system which readily transfers and yet can be traced.
  • the present invention has amongst its aims a marking system which can be readily examined using a minimum of investigating agents (such as primers) and/or investigation steps (such as sets of amplifications).
  • the present invention has amongst its aims to provide a marking system which is easy to produce and use.
  • the present invention has amongst its aims to provide a marking system which can readily provide a vast number of individual markers.
  • a marking system comprising a plurality of different DNA fragment types, each of the plurality of different DNA fragment types comprising a plurality of different DNA fragments, the different DNA fragments differing from one another in terms of at least part of their sequence.
  • the marker including a DNA fragment type, the DNA fragment type including a plurality of different
  • DNA fragments the different DNA fragments differing from one another in terms of at least part of their sequence.
  • the first and second aspects of the invention may include any of the features, options and possibilities set out in this document.
  • the marker system may include at least 1x10° possible different combinations of fragments, more preferably at least lOOxlO 6 possible combinations of fragments and ideally at least lxlO 12 possible combinations of fragments. Preferably these numbers of possibilities equate to the number of possible fragment types in the marker system.
  • the marker system may be produced by mixing together separately produced fragments to produce fragment types as required. Preferably equal quantities of each of the fragments are mixed together.
  • a fragment type may form a marker.
  • the components may include one or more liquids, such as buffers.
  • the fragment types may differ from one another due to the different fragments they include.
  • each fragment type includes at least 5 different fragments, more preferably at least 8 different fragments and ideally at least 10 different fragments.
  • the fragments may differ due to the differences in an identity variable portion included within them.
  • the marker system and/or markers and/or fragment types are formed of double stranded fragments.
  • one strand has a sequence which pairs fully with the other.
  • all the fragments in a fragment type are of the same length in terms of the number of bases.
  • all the fragment types in the marker system are of the same length in terms of the number of bases in each of the fragments.
  • the fragments are between 45 and 100 bases long, more preferably between 50 and 80 bases long.
  • the fragments differ from one another in terms of the identity of a part of the sequence forming the fragments, particularly the identity of one or more identity variable portions of the fragments.
  • the different identity variable portions are of the same length as one another.
  • a 5' end portion is provided between the identity variable portion and the 5' end of the fragment.
  • a 3' end portion is provided between the identity variable portion and the 3' end of the fragment.
  • the identity variable portion is provided between a 5' end portion and a 3' end portion of the fragment.
  • the reference to the 3' and 5' ends, here and in the document as a whole, is preferably a reference to the orientation of the upper strand (unless stated otherwise) and is represented by the right hand and left hand of the fragments as illustrated.
  • each of the fragments are provided with a portion which has a common sequence in all of the fragments.
  • each of the fragments have two portions which have a common sequences in all of the fragments.
  • the sequences of the two portions are preferably different from one another.
  • One of the common sequence portions may be provided on the 5' end side of the identity variable portion.
  • One of the common sequences may be provided at or near the 5 1 end of the fragment.
  • the common sequence may be or may be included in the 5' end portion.
  • One of the common sequence portions may be provided on the 3' end side of the identity variable portion.
  • One of the common sequences may be provided at or near the 3' end of the fragment.
  • the common sequence may be or may be included in the 3' end portion.
  • each fragment is formed of a 5' end portion, identity variable portion and 3' end portion, the identity variable portion being different for each fragment, the 5' end portion being the same for each fragment and the 3' end portion being the same for each fragment.
  • the different identities for the identity variable portions are due to a variation in one or more of the bases forming the sequence of the identity variable portions.
  • the identity of the identity variable portion may vary due to differences in five or more bases of the identity variable portion sequence, more particularly in ten or more bases.
  • no other identity variable portions will anneal to and/or hybridise with a sequence which anneals to or hybridises with a given identity variable portion.
  • each fragment in a marker of fragment type has a different identity variable portion to each of the others.
  • each fragment in a marker system has a different identity variable portion to each of the others.
  • the number of different identity variable portions in a fragment type and/or marker may be at least 5, is more preferably at least 8 and ideally is at least 10.
  • the number of different identity variable portions in a marker system may be at least 25, is more preferably at least 50 and is ideally at least 100.
  • Each identity variable portion preferably has a GC base ratio within a predetermined variation range about that ratio.
  • the predetermined variation range may be the ratio +/-10% of the ratio value. Ideally the GC base ratio is the same between the different identity variable portions.
  • fragments of the same length are provided in each of the different fragment types.
  • all the fragments in a fragment type correspond in length with a fragment in the other fragment types.
  • the same number of fragments are provided in each of the fragment types.
  • the same number of fragments of the same lengths are provided in each of the fragment types.
  • a third aspect of the invention we provide a method of marking an article, the method including providing a marking system, the marking system including a plurality of different DNA fragment types, each of the plurality of DNA fragment types including a plurality of different DNA fragments, a known one of the different DNA fragment type being applied to the article, the different DNA fragment types differing from one another in terms of at least part of their sequence.
  • a method of marking an article the method including providing a known DNA fragment type, the DNA fragment type including a plurality of different DNA fragments, the DNA fragment type being applied to the article, the different DNA fragment types differing from one another in terms of at least part of their sequence.
  • the third and / or fourth aspects of the invention may include any of the features, options or possibilities set out elsewhere, particularly the following.
  • the article may be a person and/or an item and/or a location.
  • the details of the known fragment type applied to the article may be recorded, for instance in a database. Details of the article may also be recorded, such as a description of the article and/or the articles owner.
  • the fragment type may be applied by contacting the fragment type, for instance in liquid form, with the article.
  • the article may be wetted and/or soaked in the fragment type.
  • the fragment type may be applied by painting or printing of the fragment type on the article.
  • the fragment may be applied from solution to the article.
  • the fragment may be applied to the article as an aerosol.
  • the fragment type may be applied to a part or the entirety of the article.
  • the fragment type may be applied to the external surface of the article and/or to an internal location of the article.
  • the fragment type may be applied during the article's production, for instance during the formation of the article and / or during the finishing of the article and/or during the packaging of the article.
  • the fragment type may be applied to the article after production, for instance by the purchaser and/or on behalf of the purchaser.
  • a fifth aspect of the invention we provide a method of providing a potential marking for an article, the article being provided in proximity with a unit, the method comprising providing a known DNA fragment type, the DNA fragment type including a plurality of different DNA fragments, the DNA fragment type being applied to the article as a result of a disturbance to the unit, the different DNA fragment types differing from one another in terms of at least part of their sequence.
  • the fifth aspect of the invention may include any of the features, options or possibilities set out elsewhere.
  • the article may be provided in the unit.
  • the unit may be a container, box, case or canister.
  • the unit may be a cash transport box or an automated telling machine.
  • the unit may enclose the article against access and / or from view.
  • the unit may be open able, for instance using a key, security code or other activating device. In this way authorised access to the article(s) may be obtained and / or access to the article(s) may be obtained without disturbing the unit.
  • the article(s) may be bank notes, cheques, vouchers or other paper or paper type goods having financial value.
  • the article may be bank cards, credit cards, security cards or the like. A significant number of articles of the same or similar type may be provided within the unit.
  • a disturbance to the unit may include entry by unauthorised persons an/or entry at an unauthorised time and/or entry by unauthorised means and/or entry otherwise than by an activating device.
  • Disturbance to the unit may include the breaking of the unit or a part thereof, forced access to the unit, damage to the unit, the removal of the unit from a location or a change in inclination to the unit.
  • Disturbance may comprise the removal of the unit from a particular person or type of person's, such as security staff, possession.
  • the fragment type may be applied to the article by the broaching of a barrier between the fragment type and the article.
  • the barrier may comprise an element separating a portion of the unit containing the articles from the portion of the unit containing the fragment type and / or the breakage of a vessel containing the fragment type and / or the breaking or removal of a portion thereof.
  • the fragment type may be provided within the unit and / or attached thereto.
  • the fragment type may be distributed over the article by an explosive charge.
  • the fragment type may be applied to the article by wetting of the article by the
  • the DNA fragment type may flow and / or be sprayed and / or drop on to the article.
  • the fragment type may be applied to items present at the time of the disturbance.
  • the item may be money within a container.
  • One or more items also present at the time of the disturbance may also be marked, for instance the person causing the disturbance or persons in proximity to the disturbance.
  • the fragment type does not transfer to other items after application to the item or items.
  • contact of a further item with an item which bears the fragment type does not result in the fragment type being present on the further item.
  • a sixth aspect of the present invention we provide a method of detecting the marking of an article by a DNA fragment type from amongst a plurality of different DNA fragment types, each of the plurality of DNA fragment types comprising a plurality of different DNA fragments, the different DNA fragment types differing from one another in terms of at least part of their sequence, the method comprising obtaining a sample of the DNA fragment type from the article; contacting the sample with an amplifying mixture, the amplifying mixture comprising a least one forward primer and at least one reverse primer; amplifying the DNA fragment type; contacting the amplified DNA fragment type with a plurality of different probes, each different probe having a sequence which hybridises to a particular amplified DNA fragment and each of the different probes having a distinct detectable element; hybridising those probes and amplified DNA fragments whose sequences hybridise to produce a hybridisation product; analysing the hybridisation product to identify the detectable elements present.
  • the sixth aspect of the invention may include any of the features, options or possibilities set out
  • the sample may be obtained from the article by touching the article with an item, particularly a damp item, for instance a swab.
  • the sample may be removed from the item by washing.
  • the sample may be removed from the article by washing.
  • the DNA fragments may be recovered by centrifuging or filtration, particularly by centrifugal micro filtration.
  • the article may be solid or liquid.
  • solid articles include paper goods, such as bank notes, cheques and other printed matter having or providing financial value.
  • other articles include plastic goods; personal possessions such as jewellery, antiques and the like; precious goods such as paintings, antiques, furniture, jewellery and works of art; electronic goods, such as computers, computer peripheral devices, printers, microchips, disc drives and the like; goods requiring protection against counterfeiting such as clothing, watches, perfumes and the like.
  • the article may be a person who has been in direct or indirect contact with an article having the fragment type.
  • the article may be a location which has been in direct or indirect contact with an article having the fragment type.
  • the sample or one or more parts thereof may be amplified using PCR.
  • the amplification process is performed using suitable primers for the DNA under consideration.
  • a single forward primer and single reverse primer on their own are preferably used to achieve amplification.
  • the forward primer has a sequence which anneals to the common sequence between fragments or a part there of.
  • the forward primer anneals to the fragments near their 5 * end and more preferably at the 5' end.
  • the forward primer anneals to the fragment between the identity variable portion and the 5' end.
  • the forward primer anneals to the 5' end portion or a part thereof.
  • the reverse primer has a sequence which anneals to the common sequence between fragments or a part there of.
  • the reverse primer anneals to the fragments near their 3' end and more preferably at the 3' end.
  • the reverse primer anneals to the fragment between the identity variable portion and the 3' end.
  • the reverse primer anneals to the 3' end portion or a part thereof.
  • one of the primers is provided with a distinctive unit.
  • the reverse primer is so provided.
  • the distinctive unit is incorporated into the amplified fragment type by the reverse primer.
  • the distinctive unit is introduced at the 5' end of the primer.
  • the distinctive unit is a dye, for instance a green dye.
  • the dye fluoresces in response to the application of radiation, such as laser light.
  • the fluorescence is detectable by an analysis instrument.
  • a measurement of a detectable element is only taken into account in determining the identity of the detectable element if a distinctive unit is also detected. If no distinctive unit is detected then the measurement may be attributed to an unhybridised probe.
  • the probes may be DNA based probes or may consist of DNA.
  • the probes may be formed wholly or in part from DNA analogues.
  • the probes may be of or include LNA or PNA Preferably the probes are single stranded.
  • a probe is provided for each identity of fragment which might be present.
  • at least 25, more preferably at least 50 and ideally at least 100 different probes are provided.
  • the primers may be of different lengths, but are preferably of the same length.
  • the primers may be between 15 and 25 bases long, preferably between 16 and 24 bases in length and ideally 20+/- 1 base.
  • the probe sequence is perfectly complimentary to at least a part of its respective fragment, more preferably to at least a part incorporated at least a part of the identity variable portion and ideally to the identity variable portion thereof.
  • each different probe is provided with a different detectable element.
  • the detectable element on each probe includes one or more particles, such as a micro-sphere.
  • the particle may be of polystyrene.
  • the particle is covalently linked to the probe.
  • the detectable element may be rendered detectable by the presence of one or more colours.
  • the colour and/or the amount of colour and/or the relative proportions of two or more of the colours may vary between different detectable elements to give them differences. Red and orange may be the preferred two colours.
  • One colour may be provided within the particle.
  • One colour may be provided on the surface of the particle. Preferably both colours are provided within the particle.
  • the probes and the part of the fragments with which they are complimentary have melting temperatures within 2°C of one another, more preferably within 1°C of one another and ideally have the same melting temperature.
  • the detectable elements may be visible to the naked eye and/or more preferably to an analysis instrument.
  • the colour may be immediately visible or require subsequent processing or action to render it visible.
  • the detectable elements may be of other form, including radio emitters.
  • the identity of the detectable elements and/or the presence of the distinctive unit may be considered using a human eye, instrumentation for detecting colouration or instrumentation for detecting radio emissions or other characteristics of the detectable elements or distinctive element.
  • the analysis instrument may consider the hybridised probes and fragments one by one.
  • the hybridised probes and fragments pass through a monitoring location in single file.
  • the hybridised probes and fragments may pass through the monitoring location in a stream of liquid.
  • Radiation, such as light, preferably from a laser, may be introduced to the monitoring location.
  • the monitoring location may include one, two, or more detectors.
  • the detectors detect light given out by the distinctive unit and/or detectable element. Three different colours are preferably considered.
  • the colour and/or the relative proportions of at least two colours are considered.
  • the detectable elements detected may indicate the particular probes involved in the hybridisation and preferably all such probes.
  • the number of probes detected should equal the number of fragments in the fragment type.
  • the detected results may be compared with records or a database for a marking system or systems to determine a match between the particular fragment type of the sample analysed and a known fragment type and/or one or more recorded fragment types.
  • a match or a lack of a match may be used to confirm or deny the source of the article and / or the genuine nature of the article and / or contact of the article with an article marked with the fragment type.
  • the results may, therefore, be used to confirm physical contact between an article, such as a person, vehicle or the like with an article marked with the fragment type, such as bank notes or the like, either directly or indirectly.
  • a seventh aspect of the invention we provide a method for establishing the amount or concentration of a DNA fragment type in a sample, the method including: obtaining a sample; adding to the sample a known amount of a reference DNA fragment type; amplifying the DNA fragment type and reference DNA fragment type in the presence of one another; comparing the detected amount of the reference DNA fragment type with the detected amount of the DNA fragment type, the comparison providing an indication of the amount or concentration of the DNA fragment type.
  • DNA fragment type and reference DNA fragment type are such that even amplification of the two occurs.
  • DNA fragment type and reference DNA fragment type are such that even amplification of the two occurs.
  • DNA fragment type are of the same length.
  • DNA fragment type and the reference DNA fragment type have the same 3' end portion.
  • DNA fragment type and the reference DNA fragment type have the same 5' end portion.
  • DNA fragments of the reference DNA fragment type are different from the DNA fragments of the DNA fragment type, ideally in terms of their identity variable portion, preferably all of the DNA fragments are different from each other.
  • a known volume of a known concentration of reference DNA fragment type is added to the sample.
  • the volume of the sample is known, preferably the reference DNA fragment type is throughly mixed with the sample.
  • the reference DNA fragment type is not one used as a marker.
  • the DNA fragment type and reference DNA fragment type are extracted from the sample and then amplified. In certain cases the amplification may occur in the sample.
  • the level of reference DNA fragment type detected in the results is compared with the level of marking DNA fragment type detected in the sample to give the amount or concentration of DNA fragment type present.
  • the result may be used to establish whether the concentration of the DNA fragment type in the sample was the same at the time of analysis as at the time of marking.
  • the DNA fragment type could be formed of a number of DNA fragments of different lengths to one another.
  • the seventh aspect may include any of the features, options or possibilities set out elsewhere in this application.
  • an eighth aspect of the invention we provide a method of producing a marking system, the method including: selecting a sequence for a DNA fragment; synthesising a DNA fragment having that sequence; incorporating the DNA fragment in a vector; using the vector to replicate the DNA fragment; obtaining the DNA fragment; producing a plurality of different DNA fragments according to this method.
  • the method includes the step of producing a DNA fragment type, the DNA fragment type being produced by mixing together a plurality of different DNA fragments.
  • the DNA fragment type being produced by mixing together a plurality of different DNA fragments.
  • DNA fragments are mixed to form the DNA fragment type.
  • the method of producing a marker system includes producing at least 40, more preferably at least 70 and ideally more than 90 different DNA fragments, preferably the number of different DNA fragments is less than 150.
  • the sequence may be just that of the identity variable portion.
  • the sequence of the 3 ' end portion and/or 5' end portion may come from the vector.
  • the sequence is preferably introduced to the vector by ligation. Primers directed to the vector sequence could be used to achieve amplification.
  • the sequence of the DNA fragment synthesised is checked against the selected sequence after forming the vector.
  • the DNA fragment within the vector is only produced in large quantities if the sequence is as selected.
  • the method may be used to produce DNA fragments differing from one another in terms of their seqeunce and particularly a sequence variable portion thereof.
  • the method may be used to produce DNA fragments differing from one another in terms of their length and particularly a length variable portion thereof, for instance as set out in PCT/GB01/03929, the contents of which are incorporated herein by reference, particularly as they relate to the DNA fragment forms.
  • a ninth aspect of the invention we provide a marking system, the marking system comprising a plurality of different DNA fragments, different combinations of DNA fragments being used to form DNA fragment types, different DNA fragment types being used to distinctly mark, the marking system further including a plurality of organisation identifying DNA fragments, the organisation identifying DNA fragment of an organisation being present in all DNA fragment types of that organisation.
  • a method of marking the method using a DNA fragment type to mark, the DNA fragment type including a plurality of different DNA fragments and at least one organisation identifying fragment.
  • the ninth and tenth aspects of the invention may include any of the features, options or possibilities set out elsewhere in this application and particularly from amongst the following.
  • the marking system includes at least 50 DNA fragment types for use by the organisations and at least one organisation identifying DNA fragment for each organisation using the marking system.
  • a DNA fragment type is made of 9 DNA fragments and one organisation identifying DNA fragment.
  • the organisation identifying DNA fragments differ from one another in the same way the DNA fragments differ from one another, for instance a variation in sequence, preferably in the sequence variable portion, or a variation in length, preferably in the length variable portion.
  • the organisation identifying DNA fragment length, particularly the length variable portion thereof may be 2 bases different in length compared with the nearest length DNA fragments.
  • the nearest DNA fragments differing in length relative to one another by 4 bases.
  • Figure lb illustrates schematically an example of a second DNA fragment from a marker according to the first embodiment of the present invention
  • Figure 2 illustrates schematically the primers added to the marker of the first embodiment to achieve amplification
  • Figure 3 illustrates schematically the probes added to the amplified marker of the first aspect of the invention to achieve labelling.
  • the invention aims to provide a marking system which is versatile and capable of use in a variety of situations, some of which are described in more detail below.
  • the general concept behind the invention is the provision of a distinct marker in each case where specific identification is required.
  • the marker is selected from the markers which make up a marker system.
  • Each marker is provided by a DNA fragment type which is formed by a combination of different double stranded DNA fragments so giving a very large number of marker/DNA fragment type permutations in the marker system.
  • each DNA fragment type is formed of a number of DNA fragments which differ in terms of their sequence.
  • the DNA fragments have the same overall length and have standard sequence portions at the 3' and 5' ends of each DNA fragment.
  • the two strands pair to one another and so each fragment has one strand with the same 3' end and 5' end sequence as each other and a pairing strand having the same 3' end and 5' end sequence as each other.
  • a specified number of different sequence DNA fragments may be used in each DNA fragment type, with different mid part sequences for each DNA fragment.
  • each DNA fragment type is formed of a number of different sized DNA fragments so as to provide the desired variation. Further variation occurs in terms of one or both of the 3' and 5* end sequences of each DNA fragment also being different.
  • a given number of different sized DNA fragments is used in each DNA fragment type, with certain possible identities for the 3' and or 5' end sequence.
  • a given DNA fragment will have a certain size (selected from the possible sizes used and different from all the other DNA fragment sizes) and a certain 3* and/or 5' end sequence (selected from the possible sequences used).
  • a significant number of different sizes and different 3' and/or 5' sequences soon leads to a very large number of possible permutations for the make-up of an individual DNA fragment type which is used to mark in a particular case.
  • the form used in the present invention offers significant advantages over this prior form.
  • the common 3' end sequences of all the DNA fragments and the common 5' end sequences of all the DNA fragments means that only one forward primer and one reverse primer are needed to effect the amplification of the marker. This assists in getting even efficiency of amplification of all the fragments, minimises primer dimer formation and reduces primer production costs.
  • the use of identical lengths for the fragments also eliminates the chance of preferential amplification and minimises the chance of DNA degradation. Even without the presence of these features in their most preferred form significant improvements over the prior form occur.
  • the technique is also not reliant on a size based separation and hence the need for a manually intensive task is removed.
  • DNA fragment 200 is made up of two strands 200 and its complement 200 b each having three portions. These are, a 5' end portion 202 a and its compliment 202 b and a 3' end portion 204 a and its compliment 204 b .
  • the left portion 202 and right portion 204 are joined by an identity variable portion 206 a and 206 b .
  • the a and b strands pair to one another.
  • FIG. lb Another DNA fragment, for which a single strand only is shown is provided in Figure lb.
  • the fragment 208 is suitable for use in the same DNA fragment type as the fragment 200 of Figure la.
  • the DNA fragment 208 is provided with 5' end portion 202 which has the same sequence and length as the portion 202 in fragment 200.
  • the DNA fragment 208 is provided with a 3' end portion 204 which has the same sequence and length as the portion 204 in fragment 200. Only the identity variable portion 210 of fragment 208 is different in sequence when compared with the identity variable portion 206 of fragment 200.
  • each of the DNA fragments 200, 208 and others differ from one another in terms of the sequence of the identity variable portion 206, 210 and others it is preferred that the length of this identity variable portion is the same for each of the strands of each of the DNA fragments in a DNA fragment type. Indeed it is most preferred that each of the DNA fragments in each of the DNA fragment types in the marking system have identity variable portions of the same length, and are otherwise the same as one another apart from the sequence of the identity variable portion.
  • the 5' end portion 202 is a target for a 20 base forward primer sequence
  • the 3' end portion 204 is a target for a 20 base reverse primer sequence.
  • the identity variable portion 206, 210, etc can be set at between 20 and 30 bases in length as desired, but with a common length being used for all DNA fragments of a fragment type once the number of bases has been selected.
  • the ratio of the occurrence of the nucleotide bases G and C within the identity variable portion 206, 210, etc is also the same between the different DNA fragments even though their overall sequence within the identity variable portion 206 changes between fragments.
  • the marking system includes 100 DNA fragments each of which has a different identity variable portion 206, 210 etc, but common 5' end and 3' end portions in the manner outlined above.
  • a DNA fragment type is made up of a selection of 10 of the 100 unique DNA fragments. It is a DNA fragment type which is used to mark a location, item or the like. As a consequence this selection of 10 out of 100 possibilities gives 1.73 x 10 13 possible different DNA fragment types that can be made using the preferred form of the marking system.
  • a marker system offering a very large number of markers is thus provided. Increasing the number of identity variable portions can easily be used to increase the number of possible variations if necessary.
  • This massive number of DNA fragment types which can be used for specific markings is achieved using only a very limited number of different DNA fragments, one hundred.
  • the present invention also enables the marker system to be produced at lower cost and with better quality assurance than prior art systems. It is far easier to manufacture accurately and check thoroughly the sequences for a hundred DNA fragments which are then used to make the marker system, rather than having to check many tens of thousands of such individual fragments.
  • the amplification technique in this case only involves using a single forward primer 300 and a single reverse primer 302. Only one of each primer is needed to replicate the marker as all of the different DNA fragments within that marker have common 5' end portions 202 and 3' end portions 204.
  • PCR can be used to readily amplify a sample which consequently ensures that the efficiency of amplification is substantially equal between all amplicons, that primer dimer formation is easier to minimise, whilst also ensuring that production and quality control costs are reduced by minimising the number of ingredients involved.
  • a suitable forward primer 300 and reverse primer 302 are illustrated in Figure 2 and will anneal to the portion 202 b and end portion 204 a .
  • the full match between their sequence and the fragment ends allows the two to anneal well and selectively and give rise to the desired extension and hence replication during PCR. Because all of the DNA fragments which are to be amplified are of equivalent length, preferential amplification is minimised, as is the effect of DNA degradation.
  • the evenness of amplification for all of the DNA fragments which make up a DNA fragment type and a part of the marker system means that it is possible to use the present invention to mark items in a quantitative approach.
  • a known amount of a known DNA fragment type is mixed with a material to mark it.
  • the material may particularly be a liquid, for instance oil, perfume or the like.
  • the DNA fragment types should be thoroughly mixed with the material being marked so as to have an even concentration therein.
  • the reference DNA fragment type is added to the sample and mixed in. Again, the concentration of this reference DNA fragment type is known. Furthermore, the reference DNA fragment type is of the same length as the marking DNA fragment type and has the same 3' end and 5' end sequences to the marking DNA fragment type. The reference DNA fragment type is one which is specifically held back for the quantitative analysis and which is not used as a marker. As a consequence, there is no possibility of the reference DNA fragment type being the same as the DNA fragment type which was used to mark the sample.
  • the markers are either amplified in the sample, or more normally extracted for amplification.
  • the extraction process will be equally effective with both DNA fragment types and all their constituent DNA fragments due to the equivalent nature of the DNA fragments employed.
  • amplification will be equally effective for the item marking DNA fragment type and the reference DNA fragment type added as part of the quantitative measurement.
  • the levels of reference DNA fragment type detected in the results can be compared with the level of marking DNA fragment type detected in the sample. From the known concentration of the reference DNA fragment type added to the sample, the concentration of the marking DNA fragment type in that sample can be determined. As a consequence, it is possible to establish whether the concentration of the DNA fragment type in the sample was the same at the time of analysis as at the time of marking.
  • the reverse primer 302 inco ⁇ orate a distinctive unit 306, for instance in the form of a green fluorescent dye at its 5' end with that dye consequently being attached to amplification products once the sequence extension has occurred.
  • a distinctive unit 306 for instance in the form of a green fluorescent dye at its 5' end with that dye consequently being attached to amplification products once the sequence extension has occurred.
  • the function of the green fluorescent dye is explained in more detail below.
  • the technique is advantageous in that only one primer needs labelling in the case of the primers used in the amplification process, with consequential cost reductions. Rather than relying upon electrophoretic separation due to size to analyse the results with consequential inspection of the colours occurring for each of the bands, an alternative technique which reduces manual work and analysis time, improves data collection and a degree of automated processing is possible.
  • This technique involves introducing to the amplified products, represented in Figure 3 by a strand 350 made up of sequence 202 b , 206 b , 204 b and dye 306, a mixture of single stranded DNA probes 400.
  • Probes formed partially from DNA and/or from DNA analogues, such as PNA and LNA are also possible.
  • a probe 400 with a sequence pairing to each of the possible variable identity portions 206, 210, etc is provided.
  • 100 different probes 400 1 , 400 2 , 400 ⁇ 400 100 are provided.
  • Each of the different types of probe 400 has a sequence which is perfectly complimentary to one and only one of the identity variable portions 206, 210, etc.
  • a probe 400 having the perfect complimentary sequence to one of the identity variable portions 206, 210, etc will hybridise thereto as illustrated in Figure 3. This will occur for 10 different probes 400 from amongst the 100 different probes 400 introduced, in the case of the preferred form.
  • the other probes 400 do not hybridise due to their sequences not matching one of the variable identity portions 206, 210, etc actually present in the marker.
  • Each of the probes 400 is provided with a distinct label 402 when compared with the other probes 400. Thus a different label is provided for each different identity variable portion in the marker system.
  • the labelling is provided by the probe being attached covalently to a micro-sphere.
  • a micro-sphere which can be obtained from Luminex Corporation, 12212 Technology Blvd, Austin, Texas,78727, USA for instance, provide a distinctive recognition pattern. This can be due to the presence of two different colours which are provided in different proportions relative to one another and also in different absolute amounts. Both colours can conveniently be provided within the micro-spheres.
  • a fine stream of liquid is generated in which the micro-beads are aligned in single file and pass a pair of fluorescence detectors.
  • Laser illumination allows the colours associated with a micro-bead to be detected. Because each of the different probes is provided with a distinct micro- sphere, the colour or colours of that micro-sphere revealed by the instrument reveal the identity of the probe and hence of the variable identity portion as a result.
  • a typical result might thus be the presence of the label associated with probes 400 , 400 26 , 400 31 , 400 32 , 400 47 , 400 69 , 400 73 , 400 90 , 400 94 , and 400 98 being detected.
  • the lengths of the identity variable portions are all the same and the GC base content of the identity variable portions is identical then all the probes and all the fragments can be provided with identical melting temperatures. This ensures that hybridisation conditions between the two are optimised as a result.
  • a very limited amount of the vector is produced and the DNA fragment contained within is carefully checked to ensure that its sequence is as intended.
  • the result can then be combined with an appropriate expression system to ensure large scale replication of the DNA fragment of interest.
  • the accuracy of replication is high and hence good quality control of the DNA fragment obtained as corresponding to the DNA fragment desired is achieved.
  • This approach can be pursued whether it is a fixed length, sequence varying tag of the present type which is of interest, or whether it is a length varying DNA fragment of the type employed in the marker system of PCT/GB01/03929.
  • the marking system may be a applied to an item or location in the event of certain circumstances arising and will then remain on the item or location during its subsequent life, or at least at a significant time period.
  • the circumstances may be the disturbance of the item or location and/or a container or article associated with the item or location.
  • the marking system may be provided in a container within a case for an amount of money, as a security device. In the event of the case being broken into the container is designed to break and hence bring the marking system into contact with the money. Any subsequent contact of the money with persons, other items or other locations is designed to give partial transfer of the marking system to them.
  • the marking system is thus intended to allow the money stolen, persons handling that money and cars, houses and the like which are linked to the robbery to be detected.
  • the marking system can be applied to an item or location during a stage of that item's or location's production and remain a feature of it during its subsequent life or be added by the purchaser themselves at a later date.
  • the marking system can be used to verify the genuine nature of the item, for instance genuine rather than counterfeit perfume, and/or to identify a feature of the item's production, for instance the particular location of the producer which made the item so as to trace the source of production should a problem arise.
  • the marking system enables these benefits, but without interfering with the item's or location's normal use or appearance.
  • the marker is applied to the item (particularly money) by the triggering of a device, but is not subsequently transferred from the item.
  • a sample of the DNA is recovered. This may involve swabbing the person, item or location with a damp cotton swab. The lifted sample of the DNA fragment type marker system is then subjected to washing and centrifugal micro filtration to obtain the sample for subsequent analysis.
  • an area of the item or location bearing the marking system, or even the whole item or location may be washed (sterile water or buffered solution) to remove the DNA fragment type with the sample subsequently being purified using centrifugal micro filtration and / or Qiagen extraction chemistry.
  • the sample of the DNA fragment type is contacted with primers and analysed as described above.
  • the number of organisations involved in a marking system could be increased by increasing the number of organisation identifying DNA fragments included in the marking system.
  • one hundred and ten DNA fragments would allow the selection of nine fragments from ninety to provide the unique identifying sequence, with the twenty other DNA fragments being available to allow twenty independent organisations to operate the marking system.
  • Other permutations on the numbers involved are, of course, possible.
  • the minimum length variation between unique identifying DNA fragments is at least four base pairs.
  • a blue yellow indication base pair 70 may be part of the unique identification
  • a green yellow indication base pair 74 could also be part of the unique identification
  • a green blue indication base pair 72 would be indicative of a particular organisation who combined and deployed that DNA fragment type. Again, this would enable the detected result to be linked to the records of an organisation which would unambiguously indicate an item, location or other event marked using that DNA fragment type.

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EP03712311A 2002-03-01 2003-03-03 Verbesserungen in bezug auf markierung Withdrawn EP1483411A2 (de)

Applications Claiming Priority (5)

Application Number Priority Date Filing Date Title
GB0204889A GB0204889D0 (en) 2002-03-01 2002-03-01 Improvements in and relating to identification and analysis
GB0204889 2002-03-01
GB0206957A GB0206957D0 (en) 2002-03-01 2002-03-25 Improvements in and relating to marking
GB0206957 2002-03-25
PCT/GB2003/000886 WO2003074733A2 (en) 2002-03-01 2003-03-03 Improvements in and relating to marking

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GB0303497D0 (en) * 2003-02-15 2003-03-19 Univ Liverpool Immuno PCR method
WO2008033042A2 (en) * 2006-09-12 2008-03-20 Agresearch Limited Method for identifying the origin of a compound biological product
FR2930063B1 (fr) * 2008-04-14 2013-02-15 Bioquanta Procede de marquage d'un produit, procede d'identification du marquage et produit marque
GB2472371B (en) * 2009-04-24 2011-10-26 Selectamark Security Systems Plc Synthetic nucleotide containing compositions for use in security marking of property and/or for marking a thief or attacker
UA107688C2 (en) * 2009-12-08 2015-02-10 3Si Security Systems N V Protection and tracking system for valuables
GB2538800B (en) * 2015-05-29 2019-09-25 Selectamark Security Systems Plc Compositions for use in security marking

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GB9010138D0 (en) * 1990-05-04 1990-06-27 Slater James H An ultrasensitive microtrace procedure for monitoring the origin,movement and fate of any liquid or solid material
GB9314394D0 (en) * 1993-07-12 1993-08-25 Slater James H A security device using an ultrasensitive microtrace for protecting materials,articles and items
AU701932B2 (en) * 1994-12-08 1999-02-11 Pabio Chemical labelling of objects
US5776737A (en) * 1994-12-22 1998-07-07 Visible Genetics Inc. Method and composition for internal identification of samples
US6458530B1 (en) * 1996-04-04 2002-10-01 Affymetrix Inc. Selecting tag nucleic acids
WO1998055657A1 (en) * 1997-06-05 1998-12-10 Cellstore Methods and reagents for indexing and encoding nucleic acids
DE19738816A1 (de) * 1997-09-05 1999-03-11 November Ag Molekulare Medizin Verfahren zur Markierung von festen, flüssigen oder gasförmigen Substanzen
DE19860546A1 (de) * 1998-12-23 2000-06-29 Knoell Hans Forschung Ev Verfahren zur Identifikation der Herkunft von organischen Flüssigkeiten
ATE347617T1 (de) * 1999-05-06 2006-12-15 Sinai School Medicine Steganographie auf dna basis
GB0021367D0 (en) * 2000-09-01 2000-10-18 Sec Dep Of The Home Department Improvements in and relating to marking

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