Methods, probe sets, kits, and compositions for gene deletion assays are disclosed. In some embodiments, the methods relate to preparing probes for a deletion assay, performing a deletion assay, or optimizing a deletion assay. In some embodiments, the methods and probe sets can provide reduced artifactual deletion frequency, for example, when analyzing samples subject to truncation artifacts. In some embodiments, the methods and probe sets can distinguish between small and large deletions.

Methods, probe sets, kits, and compositions for gene deletion assays are disclosed. In some embodiments, the methods relate to preparing probes for a deletion assay, performing a deletion assay, or optimizing a deletion assay. In some embodiments, the methods and probe sets can provide reduced artifactual deletion frequency, for example, when analyzing samples subject to truncation artifacts. In some embodiments, the methods and probe sets can distinguish between small and large deletions.

This disclosure relates to compositions and methods for single-step, multi-stage amplification reactions that combine many stages of sample preparation process in a single tube reaction. The disclosed technology provides a mean of performing multiplexed nested PCR in a single vessel, without any need of purification steps, and is based on the use of three sets of primers: a pair of outer primers, a pair of inner primers that are nested within the pair of outer primers, and tail primers that are complementary to tails on the inner primers. By adjusting the temperature conditions, annealing temperatures of the primers, number of amplification cycles, and the concentrations of the outer, inner, and tail primers, it is possible to carry out multiplexed nested PCR in a single vessel.

This disclosure relates to compositions and methods for single-step, multi-stage amplification reactions that combine many stages of sample preparation process in a single tube reaction. The disclosed technology provides a mean of performing multiplexed nested PCR in a single vessel, without any need of purification steps, and is based on the use of three sets of primers: a pair of outer primers, a pair of inner primers that are nested within the pair of outer primers, and tail primers that are complementary to tails on the inner primers. By adjusting the temperature conditions, annealing temperatures of the primers, number of amplification cycles, and the concentrations of the outer, inner, and tail primers, it is possible to carry out multiplexed nested PCR in a single vessel.

A two-step multiplex amplification reaction includes a first step which truncates the standard initial multiplex amplification round to boost the sample copy number by only a 100-1000 fold increase in the target. Following the first step the product is divided into optimized secondary single amplification reactions, each containing one of the primer sets that were used previously in the first or multiplexed booster step. The booster step can occur using an aqueous target nucleic acid or using a solid phase archived nucleic acid. In particular, nucleic acid sequences that uniquely identify E. Coli were identified using the multiplex amplification method.

A two-step multiplex amplification reaction includes a first step which truncates the standard initial multiplex amplification round to boost the sample copy number by only a 100-1000 fold increase in the target. Following the first step the product is divided into optimized secondary single amplification reactions, each containing one of the primer sets that were used previously in the first or multiplexed booster step. The booster step can occur using an aqueous target nucleic acid or using a solid phase archived nucleic acid. In particular, nucleic acid sequences that uniquely identify E. Coli were identified using the multiplex amplification method.

A two-step multiplex amplification reaction includes a first step which truncates the standard initial multiplex amplification round to boost the sample copy number by only a 100-1000 fold increase in the target. Following the first step the product is divided into optimized secondary single amplification reactions, each containing one of the primer sets that were used previously in the first or multiplexed booster step. The booster step can occur using an aqueous target nucleic acid or using a solid phase archived nucleic acid. In particular, nucleic acid sequences that uniquely identify E. Coli were identified using the multiplex amplification method.

A two-step multiplex amplification reaction includes a first step which truncates the standard initial multiplex amplification round to boost the sample copy number by only a 100-1000 fold increase in the target. Following the first step the product is divided into optimized secondary single amplification reactions, each containing one of the primer sets that were used previously in the first or multiplexed booster step. The booster step can occur using an aqueous target nucleic acid or using a solid phase archived nucleic acid. In particular, nucleic acid sequences that uniquely identify E. Coli were identified using the multiplex amplification method.

Compositions and methods for amplifying selected polynucleotides, including DNA and RNA, particularly in multiplex amplification reactions using common primers amplification. Generally, methods of the invention employ multiple steps such as template-specific hybridization, a linear amplification, partial degradation of nucleic acid, and ligation. At the end of the process the sequences of selected polynucleotides are flanked by the common sequences which can be used for exponential amplification using common primers. In some aspects the polynucleotides are associated with a barcode and the presence of the barcode is detected to measure the amount of the polynucleotide.

Compositions and methods for amplifying selected polynucleotides, including DNA and RNA, particularly in multiplex amplification reactions using common primers amplification. Generally, methods of the invention employ multiple steps such as template-specific hybridization, a linear amplification, partial degradation of nucleic acid, and ligation. At the end of the process the sequences of selected polynucleotides are flanked by the common sequences which can be used for exponential amplification using common primers. In some aspects the polynucleotides are associated with a barcode and the presence of the barcode is detected to measure the amount of the polynucleotide.