Shuichi Hoshika

Address:

718 SW 16 Ave APT 206, Gainesville, FL 32601

VIN:

JTDJT923775086475

Make:

TOYOTA

Model:

YARIS

Year:

2007

US Patent:

20110319298, Dec 29, 2011

Filed:

Apr 21, 2009

Appl. No.:

12/311982

Inventors:

Steven A. Benner - Gsinesville FL, US
Shuichi Hoshika - Gainesville FL, US
Nicole Leal - Gainesville FL, US

International Classification:

C40B 50/06
C07H 21/00

US Classification:

506 26, 536 231

Abstract:

This patent application claims processes and compositions of matter that enable the discovery of single nucleotide polymorphisms (SNPs) that distinguish the genomes of two individual organisms in the same species, as well as that distinguish the paternal and maternal genetic inheritance of a single individual, as well as distinguish the genomes of cells in special tissues (e.g. cancer tissues) within an individual from the genomes of the standard cells in the same individuals, as well as the SNPs that are discovered using these processes and compositions. Two steps are essential to the invention disclosed in this application. The first step provides four sets of primers, which are designated “T-extendable”, “A-extendable”, “C-extendable”, and “G-extendable”. These primers, when targeted against a reference genome as a template, add (respectively) T, A, C, and G to their 3′-ends in a template-directed primer extension reaction. The second step presents these four primer sets, separately, to a sample of the target genome DNA under conditions where they bind to their complementary segments within the target DNA. Once bound, members of each primer set serve as primers for a template-directed primer extension reaction using the target genome as the template. If the template from the target genome presents the same templating nucleotide for the first nucleotide added in the extension reaction as the reference genome, then the T-extendable, A-extendable, C-extendable, and G-extendable primers will be extended (respectively) by T, A, C, and G. If, however, the template from the target genome presents a nucleotide different from the reference genome, then the T-extendable, A-extendable, C-extendable, and G-extendable primers will be extended (respectively) by not T, not A, not C, and not G (referred to here as “3N” or “3”, to indicate the other three nucleotides, where which of the other three is understood by context). In these cases, the primers have discovered a SNP, a difference between the target and reference genomes. Then, the T-extendable, A-extendable, C-extendable, and G-extendable primers that add (respectively) not-T, not-A, not-C, and not-G are separated or made otherwise physically distinct (through, for example, the use of irreversible terminators, such as 2′,3′-dideoxynucleosides) from those that added T, A, C, and G (respectively). Those that added T, A, C, and G (respectively) did not discover a SNP, and are discarded. The primers that added “not-T”, “not-A”, “not-C”, and “not-G” discovered a SNP, and presented in a mixture enriched (relative to those primers that did not discover a SNP) in a useful deliverable. Following these steps, the SNPs discoveries are realized by sequencing the extracted species. The information obtained from this sequencing allows the identification of the locus of the SNP in the in silico genome.

US Patent:

20090270601, Oct 29, 2009

Filed:

Apr 21, 2009

Appl. No.:

12/386595

Inventors:

Steven Albert Benner - Gainesville FL, US
Shuichi Hoshika - Gainesville FL, US
Nicole Aurora Leal - Gainesville FL, US

International Classification:

C12P 19/34
C07H 21/04

US Classification:

536 231, 435 912

Abstract:

This application claims processes and compositions that enable discovery of single nucleotide polymorphisms (SNPs) and other sequence variation that follows two essentially identical sequences, one a reference, the other a target, as well as SNPs discovered using these processes and compositions. The inventive process comprises preparation of four sets of primers, “T-extendable”, “A-extendable”, “C-extendable”, and “G-extendable”. These primers, when templated on a reference genome, add (respectively) T, A, C, and G to their 3′-ends. The invention also comprises a step where these primer sets are separately bound to complementary sequences on target DNA and, once bound, prime extension reactions using target DNA as the template. If the target DNA directs incorporation of the same nucleotide as the reference DNA, then the T-, A-, C-, and G-extendable primers are extended (respectively) by T, A, C, and G. The architecture of the process distinguishes products from these extensions from products derived if not T, not A, not C and not G (“3N” or “3”, to indicate the other three nucleotides) are not added. Thus, this process discovers differences between the target and reference DNA in the site queried by the primer extension reaction. The distinction makes the two kinds of products either separable or differentially extendable. This distinction is used to disregard products that added T, A, C, and G and to identify the sequence(s) of primers that added not-T, not-A, not-C, and not-G. Further and optionally, information from these sequences identifies loci of the SNPs in an in silico genome.