Left symmetric algebras from DNA insertion

Abstract

DNA recombination is a fundamental biological process that encodes genetic information for organism development and function. In this study, we construct the left symmetric algebras arising from the operation of DNA insertion. We define a new operation of insertion by modifying the simplified insertion x⇒ y:=f( x,\ y )Σi=0q y1y2·s yi x yi+1·s yq, where x = x1x2·s xp, y = y1y2·s yq, and x, y denote the lengths of x and y, respectively. We prove that the algebra F(R) (over a field F of characteristic 0, with R being an infinite free semigroup generated by DNA nucleotides \A, G, C, T\) forms a left symmetric algebra if and only if the function f satisfies the condition f(m, n) f(m+n, p)=f(n, p) f(m, n+p)= f(m, p) f(n, m+p), where m, n, p∈ N. A key example of such a function is f(m, n)=\g(m, n)\, where g(m, n)=k· mn, and k is a fixed positive number, which effectively models length-dependent DNA insertion dynamics. This work enriches the theory of non-associative algebras and provides a mathematical framework for quantitative analysis of DNA recombination processes.