X-Git-Url: https://bilbo.iut-bm.univ-fcomte.fr/and/gitweb/chloroplast13.git/blobdiff_plain/f8689d1f199221556dc52e80c5237c45addb0218..181fe86127b57e8c7df3e97082134e7a5b7b8618:/classEquiv.tex?ds=sidebyside diff --git a/classEquiv.tex b/classEquiv.tex index 41abda4..f3d3ed1 100644 --- a/classEquiv.tex +++ b/classEquiv.tex @@ -1,28 +1,73 @@ -Identifying core genes is important to understand evolutionary and -functional phylogenies. Therefore, in this work we present two methods -to build a genes content evolutionary tree. More precisely, we focus -on the following questions considering a collection of -99~chloroplasts annotated from NCBI \cite{Sayers01012011} and Dogma -\cite{RDogma} : how can we identify the best core genome and what -is the evolutionary scenario of these chloroplasts. -Two methods are considered here. The first one is based on NCBI annotation, it is explained below. -We start by the following definition. +The first method, described below, considers NCBI annotations and uses +a distance-based similarity measure. We start with the following +preliminary definition: + \begin{definition} \label{def1} -Let $A=\{A,T,C,G\}$ be the nucleotides alphabet, and $A^\ast$ be the set of finite words on $A$ (\emph{i.e.}, of DNA sequences). Let $d:A^{\ast}\times A^{\ast}\rightarrow[0,1]$ be a distance on $A^{\ast}$. Consider a given value $T\in[0,1]$ called a threshold. For all $x,y\in A^{\ast}$, we will say that $x\sim_{d,T}y$ if $d(x,y)\leqslant T$. +Let $A=\{A,T,C,G\}$ be the nucleotides alphabet, and $A^\ast$ be the +set of finite words on $A$ (\emph{i.e.}, of DNA sequences). Let +$d:A^{\ast}\times A^{\ast}\rightarrow[0,1]$ be a distance on +$A^{\ast}$. Consider a given value $T\in[0,1]$ called a threshold. For +all $x,y\in A^{\ast}$, we will say that $x\sim_{d,T}y$ if +$d(x,y)\leqslant T$. \end{definition} -\noindent$\sim_{d,T}$ is obviously an equivalence relation. When $d=1-\Delta$, where $\Delta$ is the similarity scoring function embedded into the emboss package (Needleman-Wunch released by EMBL), we will simply denote $\sim_{d,0.1}$ by $\sim$. The method starts by building an undirected graph based on -the similarity rates $r_{ij}$ between sequences $g_{i}$ and $g_{j}$ (\emph{i.e.}, $r_{ij}=\Delta(g_{i},g_{j})$). -In this latter, nodes are constituted by all the coding sequences of the set of genomes under consideration, and there is an edge between $g_{i}$ and $g_{j}$ if the -similarity rate $r_{ij}$ is -greater than the given similarity threshold. The Connected Components -(CC) of the ``similarity'' graph are thus computed. -This produces an equivalence -relation between sequences in the same CC based on Definition~\ref{def1}. -Any class for this relation is called ``gene'' here, where its representatives (DNA sequences) are the ``alleles'' of this gene. Thus this first method produces for each genome $G$, which is a set $\{g_{1}^G,...,g_{m_G}^G\}$ of $m_{G}$ DNA coding sequences, the projection of each sequence according to $\pi$, where $\pi$ maps each sequence -into its gene (class) according to $\sim$. In other words, $G$ is mapped into $\{\pi(g_{1}^G),...,\pi(g_{m_G}^G)\}$. -Remark that a projected genome has no duplicated gene, as it is a set. The core genome (resp. the pan genome) of $G_{1}$ and $G_{2}$ is defined thus as the intersection (resp. as the union) of these projected genomes.\\ -We then consider the intersection of all the projected genomes, which is the set of all the genes $\dot{x}$ -such that each genome has at least one allele in $\dot{x}$. The pan genome is computed similarly as the union of all the projected genomes. However such approach suffers from producing too small core genomes, -for any chosen similarity threshold, compared to what is usually waited by biologists regarding these chloroplasts. We are then left with the following questions: how can we improve the confidence put in the produced core? Can we thus guess the evolution scenario of these genomes? \ No newline at end of file +%\noindent $\sim_{d,T}$ is obviously an equivalence relation and when $d=1-\Delta$, where $\Delta$ is the similarity scoring function embedded into the emboss package , we will simply denote $\sim_{d,0.1}$ by $\sim$. + +Let be given a \emph{similarity} threshold $T$ and a distance $d$ +(Needleman-Wunch released by EMBL for instance). +The method begins by building an undirected graph +between all the DNA~sequences $g$ of the set of genomes as follows: +there is an edge between $g_{i}$ and $g_{j}$ +if $g_i \sim_{d,T} g_j$ is established. +This graph is further denoted as the ``similarity'' graph. + +We thus consider that the pair of two coding sequences +$(g_i,g_j)$ belongs in the relation $\mathcal{R}$ if both $g_i$ and +$g_j$ belong in the same +connected component (CC), \textit{i.e.} if there is a path between $g_i$ +and $g_j$ in the similarity graph. It is not hard to see that this relation is an +equivalence relation whereas $\sim$ is not. + + +Any class for this relation is called ``gene'' +here, where its representatives +(DNA~sequences) are the ``alleles'' of this gene. Thus this first +method produces for each genome $G$, which is a set +$\left\{g_{1}^G,...,g_{m_G}^G\right\}$ of $m_{G}$ DNA coding +sequences, the projection of each sequence according to $\pi$, where +$\pi$ maps each sequence into its gene (class) according to $\mathcal{R}$. In +other words, a genome $G$ is mapped into +$\left\{\pi(g_{1}^G),...,\pi(g_{m_G}^G)\right\}$. Note that a +projected genome has no duplicated gene since it is a set. + +Consequently, the core genome (resp. the pan genome) of two genomes +$G_{1}$ and $G_{2}$ is defined as the intersection (resp. as the +union) of their projected genomes. We then consider the intersection +of all the projected genomes, which is the set of all the genes +$\dot{x}$ such that each genome has at least one allele in +$\dot{x}$. The pan genome is computed similarly as the union of all +the projected genomes. + +\begin{figure} +\begin{center} +\includegraphics[scale=0.5]{stats.png} +\end{center} +\caption{Size of core and pan genomes w.r.t. the similarity threshold}\label{Fig:sim:core:pan} +\end{figure} + +The number of genes in the core genome and in the pan genome are +represented in Figure~\ref{Fig:sim:core:pan} with respect to the +threshold value. +First of all, the higher is the threshold, +the smaller the connected components are. In other words, the number +of alleles of one gene is small if the threshold is high. +When the threshold is high, the number of genes and the size of +pan genome is high too. However due to the construction method of the +core genome, this set of genes has few elements in such a situation. +This approach even suffers from producing +too small core genomes (of size 0 or 1), for any chosen similarity threshold, compared +to what is usually expected by biologists regarding these +chloroplasts. We are then left with the following questions: how can +we improve the confidence put in the produced core? Can we thus guess +the evolution scenario of these genomes?