Typing of multiple single-nucleotide polymorphisms using ribonuclease cleavage of DNA/RNA chimeric single-base extension primers and detection by MALDI-TOF mass spectrometry

Dual toeholds regulated CRISPR-Cas12a sensing platform for ApoE single nucleotide polymorphisms genotyping

Single nucleotide polymorphisms (SNPs) are closely associated with many biological processes, including genetic disease, tumorigenesis, and drug metabolism. Accurate and efficient SNP determination has been proved pivotal in pharmacogenomics and diagnostics. Herein, a universal and high-fidelity genotyping platform is established based on the dual toeholds regulated Cas12a sensing methodology. Different from the conventional single stranded or double stranded activation mode, the dual toeholds regulated mode overcomes protospacer adjacent motif (PAM) limitation via cascade toehold mediated strand displacement reaction, which is highly universal and ultra-specific. To enhance the sensitivity for biological samples analysis, a modified isothermal recombinant polymerase amplification (RPA) strategy is developed via utilizing deoxythymidine substituted primer and uracil-DNA glycosylase (UDG) treatment, designated as RPA-UDG. The dsDNA products containing single stranded toehold domain generated in the RPA-UDG allow further incorporation with dual toeholds regulated Cas12a platform for high-fidelity human sample genotyping. We discriminate all the single-nucleotide polymorphisms of ApoE gene at rs429358 and rs7412 loci with human buccal swab samples with 100% accuracy. Furthermore, we engineer visual readout of genotyping results by exploiting commercial lateral flow strips, which opens new possibilities for field deployable implementation.

Massively parallel sequencing of forensically relevant single nucleotide polymorphisms using TruSeq™ forensic amplicon

The TruSeq™ Forensic Amplicon library preparation protocol, originally designed to attach sequencing adapters to chromatin-bound DNA for chromatin immunoprecipitation sequencing (TruSeq™ ChIP-Seq), was used here to attach adapters directly to amplicons containing markers of forensic interest. In this study, the TruSeq™ Forensic Amplicon library preparation protocol was used to detect 160 single nucleotide polymorphisms (SNPs), including human identification SNPs (iSNPs), ancestry, and phenotypic SNPs (apSNPs) in 12 reference samples. Results were compared with those generated by a second laboratory using the same technique, as well as to those generated by whole genome sequencing (WGS). The genotype calls made using the TruSeq™ Forensic Amplicon library preparation protocol were highly concordant. The protocol described herein represents an effective and relatively sensitive means of preparing amplified nuclear DNA for massively parallel sequencing (MPS).

Typing of 49 autosomal SNPs by single base extension and capillary electrophoresis for forensic genetic testing

We describe a method for simultaneous amplification of 49 autosomal single nucleotide polymorphisms (SNPs) by multiplex PCR and detection of the SNP alleles by single base extension (SBE) and capillary electrophoresis. All the SNPs may be amplified from only 100 pg of genomic DNA and the length of the amplicons range from 65 to 115 bp. The high sensitivity and the short amplicon sizes make the assay very suitable for typing of degraded DNA samples, and the low mutation rate of SNPs makes the assay very useful for relationship testing. Combined, these advantages make the assay well suited for disaster victim identifications, where the DNA from the victims may be highly degraded and the victims are identified via investigation of their relatives. The assay was validated according to the ISO 17025 standard and used for routine case work in our laboratory.

A 48-plex autosomal SNP GenPlex™ assay for human individualization and relationship testing

SNPs are being increasingly used by forensic laboratories. Different platforms have been developed for SNP typing. We describe the GenPlex™ HID system protocol, a new SNP-typing platform developed by Applied Biosystems where 48 of the 52 SNPforID SNPs and amelogenin are included. The GenPlex™ HID system protocol has been successfully tested by a number of forensic laboratories using both ordinary and forensic samples.

Autosomal SNP typing of forensic samples with the GenPlex™ HID System: results of a collaborative study

The GenPlex™ HID System (Applied Biosystems - AB) offers typing of 48 of the 52 SNPforID SNPs and amelogenin. Previous studies have shown a high reproducibility of the GenPlex™ HID System using 250-500pg DNA of good quality. An international exercise was performed by 14 laboratories (9 in Europe and 5 in the US) in order to test the robustness and reliability of the GenPlex™ HID System on forensic samples. Three samples with partly degraded DNA and 10 samples with low amounts of DNA were analyzed in duplicates using various amounts of DNA. In order to compare the performance of the GenPlex™ HID System with the most commonly used STR kits, 500pg of partly degraded DNA from three samples was typed by the laboratories using one or more STR kits. The median SNP typing success rate was 92.3% with 500pg of partly degraded DNA. Three of the fourteen laboratories counted for more than two thirds of the locus dropouts. The median percentage of discrepant results was 0.2% with 500pg degraded DNA. An increasing percentage of locus dropouts and discrepant results were observed when lower amounts of DNA were used. Different success rates were observed for the various SNPs. The rs763869 SNP was the least successful. With the exception of the MiniFiler™ kit (AB), GenPlex™ HID performed better than five other tested STR kits. When partly degraded DNA was analyzed, GenPlex™ HID showed a very low mean mach probability, while all STR kits except MiniFiler™ had very limited discriminatory power.

Frontiers of mass spectrometry in nucleic acids analysis

Nucleic acids research is a highly competitive field of research. A number of well established methods are available. The current output of high throughput ("next generation") sequencing technologies is impressive, and still technologies are continuing to make progress regarding read lengths, bp per second, accuracy and costs. Although in the 1990s MS was considered as an analytical platform for sequencing, it was soon realized that MS will never be competitive. Thus, the focus shifted from de novo sequencing towards other areas of application where MS has proven to be a powerful analytical tool. Potential niches for the application of MS in nucleic acids research include genotyping of genetic markers (single nucleotide polymorphisms, short tandem repeats, and combinations thereof), quality control of synthetic oligonucleotides, metabolic profiling of therapeutics, characterization of modified nucleobases in DNA and RNA molecules, and the study of non covalent interactions among nucleic acids as well as interactions of nucleic acids with drugs and proteins. The diversity of possible applications for MS highlights its significance for nucleic acid research.

Qualitative and quantitative genotyping using single base primer extension coupled with matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MassARRAY)

Matrix-assisted laser desorption/ionization (MALDI) time-of-flight (TOF) mass spectrometry (MS) has developed over the past decade into a versatile tool for the analysis of nucleic acids and especially as a reliable genotyping platform. This chapter summarizes its use in the context of the most widely used MALDI-TOF MS genomics platform, the Sequenom MassARRAY system. MassARRAY genotyping is based upon region-specific PCR followed by allele-specific single base primer extension reactions which are then desalted, dispensed onto a silica array preloaded with matrix, and the genotyping products are resolved on the basis of mass using MALDI-TOF MS. The platform is versatile in that it can resolve multiplexed reactions (40+ separate loci per reaction), acquires and interprets data quickly, gives a quantitative output which reflects the amount of product generated for each allele within an assay for multiplexed reactions, and is highly sensitive. These characteristics coupled with integrated software for sequence annotation, assay design, data interpretation, and data storage have lead to its wide adoption and use for multiple nucleic acid analysis applications in both the realm of genomics research and molecular diagnostics.

Single nucleotide polymorphism genotyping by mini-primer allele-specific amplification with universal reporter primers for identification of degraded DNA

Single nucleotide polymorphism (SNP) is informative for human identification, and much shorter regions are targeted in analysis of biallelic SNP compared with highly polymorphic short tandem repeat (STR). Therefore, SNP genotyping is expected to be more sensitive than STR genotyping of degraded human DNA. To achieve simple, economical, and sensitive SNP genotyping for identification of degraded human DNA, we developed 18 loci for a SNP genotyping technique based on the mini-primer allele-specific amplification (ASA) combined with universal reporter primers (URP). The URP/ASA-based genotyping consisted of two amplifications followed by detection using capillary electrophoresis. The sizes of the target genome fragments ranged from 40 to 67bp in length. In the Japanese population, the frequencies of minor alleles of 18 SNPs ranged from 0.36 to 0.50, and these SNPs are informative for identification. The success rate of SNP genotyping was much higher than that of STR genotyping of artificially degraded DNA. Moreover, we applied this genotyping method to case samples and showed successful SNP genotyping of severely degraded DNA from a 4-year buffered formalin-fixed tissue sample for human identification.

Split hybridisation probes for electrochemical typing of single-nucleotide polymorphisms

This paper describes the development of a highly selective single-nucleotide polymorphisms (SNPs) typing method based on the use of split hybridisation probes and demonstrates the concept through the electrochemical analysis of single-base mutations in actual patient samples. The requirement that two probes hybridised adjacent to one another to allow for stabilisation (via base-stacking) and binding of the allele-specific oligonucleotide (ASO), imparted highly stringent selectivity criteria to the assay. Simple rules for tuning the characteristics of such stacking/ASO probe pairs and achieve full mismatch discrimination at ambient conditions (with no need to strictly control the temperature) are provided. All genotyping experiments were indeed performed at room temperature, using the planar surface of disposable probe-modified gold electrodes as the genosensing platform. The ability to detect nanomolar amounts of a synthetic target even within a vast excess of single-base substituted sequences gave strong evidence of the specificity of the split probes assay. Proving the general validity of this genotyping approach, application of the analytical pathway was further demonstrated for clinical targets (amplified from the human TP53 gene) whose mutational site was poorly accessible, being part of a thermodynamically stable hairpin. In combination with use of auxiliary oligonucleotides (which restored the availability of each pre-defined hybridisation site), the assay demonstrated the ability to fully discriminate single-base mutations with detection limits in the high picomolar range (total analysis time: 60 min). Our specific probe design, hybridisation and signal transduction paths make the analytical process remarkably simple, relatively low cost and, thus, well suited for low throughput analysis of clinically relevant samples.

Typing of 48 autosomal SNPs and amelogenin with GenPlex SNP genotyping system in forensic genetics

GenPlex (Applied Biosystems) is a new SNP genotyping system based on an initial PCR amplification followed by an oligo ligation assay (OLA). The OLA consists of the hybridization of allele and locus specific oligonucleotides (ASOs and LSOs) to PCR products and posterior ligation of ASOs and LSOs. The ligation products are immobilized to microtitre plates and reporter oligonucleotides (ZipChute probes) are hybridized to the ligation products. ZipChute probes are subsequently eluted and detected using capillary electrophoresis. Applied Biosystems developed the GenPlex SNP genotyping system with amelogenin and 48 of the 52 SNPs used in the 52 SNP-plex assay developed by the SNPforID consortium. The system requires equipment that is usually found in forensic genetic laboratories. The use of a robot for performance of the pipetting steps is highly recommendable. A total of 286 individuals from Denmark, Somalia and Greenland were investigated with GenPlex using a Biomek 3000 (Beckman Coulter) robot. The results were compared to results obtained with an ISO 17025 accredited SNP typing assay based on single base extension (SBE). With the GenPlex SNP genotyping system, full SNP profiles were obtained in 97.6% of the investigations. Perfect concordance was obtained in duplicate investigations and the SNP genotypes obtained with the GenPlex system were concordant with those of the accredited SBE based SNP typing system except for one result in rs901398 in one of 286 individuals most likely due to a mutation 6 bp downstream of the SNP. Reproducible SNP genotypes were obtained from as little as 250 pg of DNA.

Typing of multiple single-nucleotide polymorphisms by a microsphere-based rolling circle amplification assay

The combination of suspension array with rolling circle amplification can lead to a sensitive and specific assay for single-nucleotide polymorphisms (SNPs) detection, as demonstrated in this study. A circular template generated by ligation upon the recognition of a point mutation on DNA targets was amplified isothermally by the Phi29 polymerase on microspheres. The elongation products were labeled with fluorochrome-tagged probes and detected in a flow cytometer, indicating the mutation occurrence. As low as 10 amol of mutated strands was detected by this assay, and positive mutation detection was achieved with a wild-type to mutant ratio of 10 000:1, which could be attributed to the high amplification efficiency of Phi29, the high binding capacity of the microspheres, and the remarkable precision of DNA ligase in distinguishing mismatched bases at the ligation site. A novel design of using two differently labeled detection probes on the same microsphere to target both the wild-type and mutant samples allowed parallel determination of the heterozygosity for two SNPs (K-ras G12C and TP53 R273H) in PCR amplicons prepared from human genomic DNA extracts. This ability lays the groundwork for further enhancing the assay throughput by using multiple fluorophores and microspheres with distinct properties.

Profiling 627 mitochondrial nucleotides via the analysis of a 23-plex polymerase chain reaction by liquid chromatography-electrospray ionization time-of-flight mass spectrometry

We present a rapid and informative mitochondrial DNA profiling system, which has high forensic impact. The assay is based on the analysis of a 23-plex PCR by ion-pair reversed-phase high-performance liquid chromatography online hyphenated to electrospray ionization time-of-flight mass spectrometry (ICEMS). In a single 25-min run, an overall number of 627 nucleotide positions were screened. The vast majority of observed sequence variations were explainable by alterations of the allelic states of the 23 target SNPs, which were selected on their ability to increase forensic discrimination within West Eurasian populations. Within an Austrian population sample comprising 90 unrelated men, 14 different, nontarget SNP-related sequence variations--13 base substitutions and 1 deletion--were detected by ICEMS and confirmed by sequencing. All amplified sequences were located outside of the routinely sequenced hypervariable segments (HVS-I and HVS-II) of the noncoding control region. Accordingly, the genetic information obtained by the 23-plex PCR-ICEMS assay could be combined with HVS-I/HVS-II sequencing results to one highly discriminating mtDNA profile, which covered approximately 7.5% of the total mtDNA genome. With the 23-plex PCR-ICEMS assay, DNA mixtures were detected and the allelic ratios were accurately quantified. The observed robustness and sensitivity underlined the practical applicability of the assay in forensic science, which was proven by typing eight representative casework samples.

A multiplex assay with 52 single nucleotide polymorphisms for human identification

A total of 52 SNPs reported to be polymorphic in European, Asian and African populations were selected. Of these, 42 were from the distal regions of each autosome (except chromosome 19). Nearly all selected SNPs were located at least 100 kb distant from known genes and commonly used STRs. We established a highly sensitive and reproducible SNP-typing method with amplification of all 52 DNA fragments in one PCR reaction followed by detection of the SNPs with two single base extension reactions analysed using CE. The amplicons ranged from 59 to 115 bp in length. Complete SNP profiles were obtained from 500 pg DNA. The 52 loci were efficiently amplified from degraded samples where previously only partial STR profiles had been obtained. A total of 700 individuals from Denmark, Greenland, Somalia, Turkey, China, Germany, Taiwan, Thailand and Japan were typed, and the allele frequencies estimated. All 52 SNPs were polymorphic in the three major population groups. The mean match probability was at least 5.0 x 10(-19) in the populations studied. Typical paternity indices ranged from 336 000 in Asians to 549 000 in Europeans. Details of the 52 SNP loci and population data generated in this work are freely available at http://www.snpforid.org.

SNP genotyping using alkali cleavage of RNA/DNA chimeras and MALDI time-of-flight mass spectrometry

Single nucleotide polymorphisms (SNPs) are now widely used for many DNA analysis applications such as linkage disequilibrium mapping, pharmacogenomics and traceability. Many methods for SNP genotyping exist with diverse strategies for allele-distinction. Mass spectrometers are used most commonly in conjunction with primer extension procedures with allele-specific termination. Here we present a novel concept for allele-preparation for SNP genotyping. Primer extension is carried out with an extension primer positioned immediately upstream of the SNP that is to be genotyped, a complete set of four ribonucleotides and a ribonucleotide incorporating DNA polymerase. The allele-extension products are then treated with alkali, which results in the cleavage immediately after the first added ribonucleotide. In addition, to obtain fragments easily detectable by mass spectrometry, we have included a ribonucleotide in the primer usually at the fourth nucleotide from the 3′ terminus. The method was tested on four SNPs each with a different combination of nucleotides. The advantage over other mass spectrometry-based SNP genotyping assays is that this one only requires a PCR, a primer extension reaction with a universal extension mix and an inexpensive facile cleavage reaction, which makes it overall very cost effective and easy in handling.