Nucleic Acid Notations

The International Union of Pure and Applied Chemistry (IUPAC) first formalized the currently used nucleic acid notation in 1970 1970. IUPAC-IUB Commission on Biochemical Nomenclaure (CBN). Abbreviations and symbols for nucleic acids, polynucleotides and their constituents. Recommendations 1970. "Eur J. Biochem." 15:203-208] . This universally accepted notation uses the Roman characters G, C, A, and T, to represent the five nucleotides commonly found in deoxyribonucleic acids (DNA). Given the rapidly expanding role for genetic sequencing, synthesis, and analysis in biology, researchers have been compelled to develop alternate notations to further support the analysis and manipulation of genetic data. These notations generally exploit size, shape, symmetry to accomplish these objectives.

=The IUPAC Notation=

Under the commonly used IUPAC system, nucleic acids are represented by the first letters of their chemical names: [G] uanine, [C] ytosine, [A] denosine, and [T] hymine. This shorthand also includes eleven "ambiguity" characters associated with every possible combination of the four DNA bases1986. Nomenclature Committee of the International Union of Biochemistry (NC-IUB). Nomenclature for incompletely specified basis in nucleic acid sequences. Recommendations 1984. "Proc. Natl. Acad. Sci. USA" 83:4-8.] . The ambiguity characters were designed to encode positional variations found among families of related genes. The IUPAC notation, including ambiguity characters and suggested mnemonics, is shown in Table 1.

Despite its broad and nearly universal acceptance, the IUPAC system has a number of limitations, which stem from its reliance on the Roman alphabet. The poor legibility of upper-case Roman characters, which are generally used when displaying genetic data, may be chief among these limitations. The value of external projections in distinguishing letters has been well documentTinker, M. A. 1963. Legibility of Print. Iowa Sate University Press, Ames IA.] . However, these projections are absent from from upper case letters, which in some cases are only distinguishable by subtle internal cues. Take for example the upper case C and G used to represent cytosine and guanine. These characters generally comprise half the characters in a genetic sequence but are differentiated by a small internal tick.

Another shortcoming of the IUPAC notation arises from the fact that its eleven ambiguity characters have been selected from the remaining characters of the Roman alphabet. The authors of the notation endeavored to select ambiguity characters with logical mnemonics. For example, S is used to represent the possibility of finding cytosine or guanine at at genetic loci, both of which form [S] tong cross-strand binging interactions. Conversely, the weaker interactions of thymine and adenine are represented by a W. However, convenient mnemonics are not as readily available for the other ambiguity characters displayed in Table 1. This has made ambiguity characters difficult to use and may account for their limited application.

=Visually Enhanced Notations=Legibility issues associated with IUPAC-encoded genetic data have lead biologists to consider alternate strategies for displaying genetic data. These creative approaches to visualizing DNA sequences have generally relied on the use of spatially distributed symbols and/or visually distinct shapes to encode lengthy nucleic acid sequences. Several of these approaches are summarized below.

tave Projection

In 1986, Cowin et al. described a novel method for visualizing DNA sequence known as the Atave ProjectionCowin, J. E., C. H. Jellis, and D. Rickwood. 1986. A new method of representing DNA sequences which combines ease of visual analysis with machine readability. "Nucleic Acids Res." 14:509-515.] . Their strategy was to encode nucleotides as circles on series of horizontal bars akin to notes on musical stave. As illustrated in Figure 1, each gap on the five-line staff corresponded to one of the four DNA bases. The spacial distribution of the circles made it far easier to distinguish individual bases and compare genetic sequences than IUPAC-encoded data.

Geometric Symbols

Zimmerman et al. took a different approach to visualizing genetic data Zimmerman, P. A., M. L. Spell, J. Rawls, and T. R. Unnasch. 1991. Transformation of DNA sequence data into geometric symbols. "BioTechniques" 11:22-27] . Rather than relying on spatially distributed circles to highlight genetic features, they exploited four geometrically diverse symbols found in a standard computer font to distinguish the four bases. The authors developed a simple WordPerfect^TM macro to translate IUPAC characters into the more visually distinct symbols.

DNA Skyline

With the growing availability of font editors, Jarvius and Landegren devised a novel set of genetic symbols, known as the DNA Skyline font, which uses increasingly taller blocks to represent the different DNA basesJarvius, J. and U. Landegren. 2006. DNA Skyline: fonts to facilitate visual inspection of nucleic acid sequences. "BioTechniques" 40:740.] . While reminiscent of Cowin et al.'s spatially distributed Stave Projection, the DNA Skyline font is easy to download and permits translation to and from the IUPAC notation by simply changing the font in most standard word processing applications.

=Functional Ambigraphic Notations=Additional functionality can be found in nucleic acid notations that use ambigrams to mirror structural symmetries found in the DNA double helix. As defined by Douglas R. Hofstadter, ambigrams are words or symbols that convey the same or different meaning when viewed in a different orientationHofstadter, D. R. 1985 Metamagical Themas: Questioning the Essence of ind and Pattern. Basic Books, NY.] . It turns out that by assigning ambigraphic characters to complementary bases (i.e. guanine = b, cytosine = q, adenine = n, and thymine = u), it is possible to complement entire DNA sequences by simply rotating the text 180 degreesRozak, D. A. 2006. The practical and pedagogical advantages of an ambigraphic nucleic acid notation. "Nucleosides Nucleotides and Nucleic Acids" 25:807-813.] . An ambigraphic nucleic acid notation also makes it easy to identify genetic palindromes, such as endonuclease restriction sites, as sections of text that can be rotated 180 degrees without changing the sequence.

AmbiScript

The latest in a series of rationally designed nucleic acid notations, AmbiScript combines many of the visual and functional features of its predecessorsRozak, D. A. and A. J. Rozak. 2008. Simplicity, function, and legibility in an enhanced ambigraphic nucleic acid notation. "BioTechniques" 44:811-813.] . As its name implies, AmbiScript is an ambigraphic nucleic acid notation that permits rapid complementation of genetic sequence (Figure 2) and identification of biologically significant palindromes. However, notation also uses spatially offset characters to facilitate the visual review and analysis of genetic data. One novel feature that AmbiScript brings to the world of genetic notations is its use of compound symbols to convey the possibility of finding two or more different bases at a given position. This strategy appears to a offer far less cumbersome solution to the use of ambiguity characters first proposed by the IUPAC. As with Jarvius and Landegren's DNA Skyline fonts, AmbiScript fonts are easily [http://www.peerascent.com/ambiscript downloaded] and applied to IUPAC-encoded sequence data.

=References=