Sequence graph, also called an alignment graph, breakpoint graph, or adjacency graph, are bidirected graphs used in comparative genomics. The structure consists of multiple graphs or genomes with a series of edges and vertices represented as adjacencies between segments in a genome[1] and DNA segments respectively. Traversing a connected component of segments and adjacency edges (called a thread) yields a sequence, which typically represents a genome or a section of a genome. The segments can be thought of as synteny blocks, with the edges dictating how to arrange these blocks in a particular genome, and the labelling of the adjacency edges representing bases that are not contained in synteny blocks.

Construction

Before constructing a sequence graph, there must be at least two genomes represented as directed graphs with edges as threads (adjacency edges) and vertices as DNA segments. The genomes should be labeled P and Q, while the sequence graph is labeled as BreakpointGraph(P, Q).[2]

The directional vertices of Q and their edges are arranged in the order of P. Once completed, the edges of Q are reconnected to their original vertices. After all edges have been matched the vertex directions are removed and instead each vertex is labeled as vh (vertex head) and vt (vertex tail).

Similarity between genomes is represented by the number of cycles (independent systems) within the sequence graph. The number of cycles is equal to cycles (P, Q). The max number of cycles possible is equal to the number of vertices in the sequence graph.

Example

Figure example.

Upon receiving genomes P (+a +b -c) and Q (+a +b -c),[1] Q should be realigned to follow the direction edges (red) of P. The vertices should be renamed from a, b, c to ah at, bh bt, ch ct and the edges of P and Q should be connected to their original vertices (P edges = black, Q edges = green). Remove the directional edges (red). The number of cycles in G(P, Q) is 1 while the max possible is 3.

Applications

Breakpoint graphs and ancestral genome reconstructions

Max A. Alekseyev and Pavel A. Pevzner use sequence graphs to create their own algorithm to study the genome rearrangement history of several mammals, as well as a way to overcome problems with current ancestral reconstruction of genomes.[1]

Multiple sequence alignment

Sequence graphs can be used to represent multiple sequence alignments with the addition of a new kind of edge representing homology between segments.[3] For a set of genomes, one can create an acyclic breakpoint graph with a thread for each genome. For two segments and , where ,,, and represent the endpoints of the two segments, homology edges can be created from to and to or from to and to - representing the two possible orientations of the homology. The advantage of representing a multiple sequence alignment this way is that it is possible to include inversions and other structural rearrangements that wouldn't be allowable in a matrix representation.

Representing variation

If there are multiple possible paths when traversing a thread in a sequence graph, multiple sequences can be represented by the same thread. This means it is possible to create a sequence graph that represents a population of individuals with slightly different genomes - with each genome corresponding to one path through the graph. These graphs have been proposed as a replacement for the reference human genome.[4]

References

  1. 1 2 3 Alekseyev, M. A.; Pevzner, P. A. (2009-02-13). "Breakpoint graphs and ancestral genome reconstructions". Genome Research. Cold Spring Harbor Laboratory. 19 (5): 943–957. doi:10.1101/gr.082784.108. ISSN 1088-9051. PMC 2675983. PMID 19218533.
  2. Breakpoint Graphs, retrieved 2022-05-05
  3. Paten, Benedict; Zerbino, Daniel R; Hickey, Glenn; Haussler, David (2014-06-19). "A unifying model of genome evolution under parsimony". BMC Bioinformatics. Springer Science and Business Media LLC. 15 (1): 206. doi:10.1186/1471-2105-15-206. ISSN 1471-2105. PMC 4082375. PMID 24946830.
  4. Paten, Benedict; Novak, Adam; Haussler, David (2014-04-20). "Mapping to a Reference Genome Structure". arXiv:1404.5010 [q-bio.GN].
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