Shared ancestry graphs and symbolic arboreal maps

Abstract

A network N on a finite set X, |X|≥ 2, is a connected directed acyclic graph with leaf set X in which every root in N has outdegree at least 2 and no vertex in N has indegree and outdegree equal to 1; N is arboreal if the underlying unrooted, undirected graph of N is a tree. Networks are of interest in evolutionary biology since they are used, for example, to represent the evolutionary history of a set X of species whose ancestors have exchanged genes in the past. For M some arbitrary set of symbols, d:X 2 M \\ is a symbolic arboreal map if there exists some arboreal network N whose vertices with outdegree two or more are labelled by elements in M and so that d(\x,y\), \x,y\ ∈ X 2, is equal to the label of the least common ancestor of x and y in N if this exists and else. Important examples of symbolic arboreal maps include the symbolic ultrametrics, which arise in areas such as game theory, phylogenetics and cograph theory. In this paper we show that a map d:X 2 M \\ is a symbolic arboreal map if and only if d satisfies certain 3- and 4-point conditions and the graph with vertex set X and edge set consisting of those pairs \x,y\ ∈ X 2 with d(\x,y\) ≠ is Ptolemaic. To do this, we introduce and prove a key theorem concerning the shared ancestry graph for a network N on X, where this is the graph with vertex set X and edge set consisting of those \x,y\ ∈ X 2 such that x and y share a common ancestor in N. In particular, we show that for any connected graph G with vertex set X and edge clique cover K in which there are no two distinct sets in K with one a subset of the other, there is some network with |K| roots and leaf set X whose shared ancestry graph is G.