Provided herein are methods for accurately determining the alleles present at a locus that is broadly applicable to any locus, including highly polymorphic loci such as HLA loci, BGA loci and HV loci. Embodiments of the disclosed methods are useful in a wide range of applications, including, for example, organ transplantation, personalized medicine, diagnostics, forensics and anthropology.

Provided herein are methods for accurately determining the alleles present at a locus that is broadly applicable to any locus, including highly polymorphic loci such as HLA loci, BGA loci and HV loci. Embodiments of the disclosed methods are useful in a wide range of applications, including, for example, organ transplantation, personalized medicine, diagnostics, forensics and anthropology.

System and method for constructing a hierarchical index table usable for matching a search sequence to reference data. The index table may be constructed to contain entries associated with an exhaustive list of all subsequences of a given length, wherein each entry contains the number and locations of matches of each subsequence in the reference data. The hierarchical index table may be constructed in an iterative manner, wherein entries for each lengthened subsequence are selectively and iteratively constructed based on the number of matches being greater than each of a set of respective thresholds. The hierarchical index table may be used to search for matches between a search sequence and reference data, and to perform misfit identification and characterization upon each respective candidate match.

System and method for constructing a hierarchical index table usable for matching a search sequence to reference data. The index table may be constructed to contain entries associated with an exhaustive list of all subsequences of a given length, wherein each entry contains the number and locations of matches of each subsequence in the reference data. The hierarchical index table may be constructed in an iterative manner, wherein entries for each lengthened subsequence are selectively and iteratively constructed based on the number of matches being greater than each of a set of respective thresholds. The hierarchical index table may be used to search for matches between a search sequence and reference data, and to perform misfit identification and characterization upon each respective candidate match.

The present invention provides breeding methods and compositions to enhance the germplasm of a plant by the use of direct nucleic acid sequence information. The methods describe the identification and accumulation of preferred nucleic acid sequences in the germplasm of a breeding population of plants.

Systems, methods, and apparatuses are disclosed for reducing the computational time of assigning a species to an infection isolate. A method for dividing a search index into one or more sub-indices based on a phylogenetic tree of reference sequences is disclosed. A method for dividing reads into test sets and aligning to sub-indices for assigning a species to an infection isolate is disclosed. A system for aligning sequence reads to a database of reference sequences using sub-indices is disclosed.

The present invention relates to methods for evaluating and/or predicting the outcome of a clinical condition, such as cancer, metastasis, AIDS, autism, Alzheimer's, and/or Parkinson's disorder. The methods can also be used to monitor and track changes in a patient's DNA and/or RNA during and following a clinical treatment regime. The methods may also be used to evaluate protein and/or metabolite levels that correlate with such clinical conditions. The methods are also of use to ascertain the probability outcome for a patient's particular prognosis.

A composition-of-matter comprising a crystallized form of a large ribosomal (50S) subunit of a pathogenic bacterium, and the atomic coordinates of the three-dimensional structure thereof are provided herein, as well as methods for crystallizing the same, and using the atomic coordinates of the same to design de novo ligands with high specificity thereto.

Provided are synthetic strands for nucleic acid sequencing. In some embodiments, the strands include a plurality of rotatable solid supports. The plurality of rotatable solid supports comprises solid supports each comprising on its surface a first moiety that binds to adenine (A), a second moiety that binds to cytosine (C), a third moiety that binds to guanine (G), a fourth moiety that binds to thymine (T), uracil (U), or both (T/U). Each of such solid supports further comprises on its surface a position marker that indicates the rotational position of the solid support, where the first, second, third, and fourth moieties are spaced about the circumference of the solid support. The solid supports enable hybridization of the synthetic strand to a nucleic acid. Also provided are methods of using the synthetic strands, as well as related compositions, kits, and nucleic acid sequencing systems.

Provided are synthetic strands for nucleic acid sequencing. In some embodiments, the strands include a plurality of rotatable solid supports. The plurality of rotatable solid supports comprises solid supports each comprising on its surface a first moiety that binds to adenine (A), a second moiety that binds to cytosine (C), a third moiety that binds to guanine (G), a fourth moiety that binds to thymine (T), uracil (U), or both (T/U). Each of such solid supports further comprises on its surface a position marker that indicates the rotational position of the solid support, where the first, second, third, and fourth moieties are spaced about the circumference of the solid support. The solid supports enable hybridization of the synthetic strand to a nucleic acid. Also provided are methods of using the synthetic strands, as well as related compositions, kits, and nucleic acid sequencing systems.