In shotgun proteomics, generally only a fraction of peptides from a parent protein are actually detected. Because a large portion of the protein sequence is not detected, it is often impossible to determine whether the expressed protein is present in a modified, spliced, or truncated form. Provided herein are methods and systems for analyzing polypeptides which allow for the increase of the mean sequence coverage of a protein concomitant with bioinformatics analysis in order to distinguish putative proteoforms with improved amino acid resolution. Aspects of the invention include (1) a deep sequencing strategy to provide more protein sequence coverage than is typically achieved, and (2) a computational approach to view protein expression across its full length and identify regions of the protein that are potentially subject to such regulation. This technology has global utility in proteomics and will be of particular use for the analysis of biosimilar protein drug therapeutics.

The invention, in part, includes methods of single molecule protein sequencing that include using weak binding spectra in the amino acid identification.

Aspects of the application provide methods of identifying and sequencing proteins, polypeptides, and amino acids, and compositions useful for the same. In some aspects, the application provides methods of obtaining data during a degradation process of a polypeptide, and outputting a sequence representative of the polypeptide. In some aspects, the application provides amino acid recognition molecules comprising a shielding element that enhances photostability in polypeptide sequencing reactions.

In shotgun proteomics, generally only a fraction of peptides from a parent protein are actually detected. Because a large portion of the protein sequence is not detected, it is often impossible to determine whether the expressed protein is present in a modified, spliced, or truncated form. Provided herein are methods and systems for analyzing polypeptides which allow for the increase of the mean sequence coverage of a protein concomitant with bioinformatics analysis in order to distinguish putative proteoforms with improved amino acid resolution. Aspects of the invention include (1) a deep sequencing strategy to provide more protein sequence coverage than is typically achieved, and (2) a computational approach to view protein expression across its full length and identify regions of the protein that are potentially subject to such regulation. This technology has global utility in proteomics and will be of particular use for the analysis of biosimilar protein drug therapeutics.

Described are optical methods and reagents for sequencing polypeptides. A probe that exhibits different spectral properties when conjugated to different N-terminal amino acids is conjugated to the N-terminal amino acid of a polypeptide. Sequentially detecting one or more spectral properties of the probe conjugated to the N-terminal amino acid and cleaving the N-terminal amino acid produces sequence information of the polypeptide. The use of super-resolution microscopy allows for the massively parallel sequencing of individual polypeptide molecules in situ such as within a cell. Also described are probes comprising hydroxymethyl rhodamine green, an isothiocyanate group and a protecting group.

Identifying proteins and peptides, and more specifically large-scale sequencing of single peptides in a mixture of diverse peptides at the single molecule level is an unmet challenge in the field of protein sequencing. Herein are methods for identifying amino acids in peptides, including peptides comprising unnatural amino acids. In one embodiment, the N-terminal amino acid is labeled with a first label and an internal amino acid is labeled with a second label. In some embodiments, the labels are fluorescent labels. In other embodiments, the internal amino acid is Lysine. In other embodiments, amino acids in peptides are identified based on the fluorescent signature for each peptide at the single molecule level.

A method for analyzing macromolecules, including peptides, polypeptides, and proteins, employing nucleic acid encoding is disclosed.

A method for analyzing macromolecules, including peptides, polypeptides, and proteins, employing nucleic acid encoding is disclosed.

A method for analyzing macromolecules, including peptides, polypeptides, and proteins, employing nucleic acid encoding is disclosed.

A method for analyzing macromolecules, including peptides, polypeptides, and proteins, employing nucleic acid encoding is disclosed.