JASPAR profile collection [15]. Ali

JASPAR profile collection [15]. Alignment submission accepts the de facto standard CLUSTALW format [25]. In all operating modes, users are allowed to submit a cDNA sequence to define exon locations. Users may also submit new matrix profiles of their own construction.
Results can be obtained in three distinct report formats. Graphical view (Figure 3a) displays an alignment overview and conservation plots with x-axis reference for each submitted sequence. Positions of conserved TFBSs are indicated above the plot. The transcription-factor labels are equipped with mouse-over function to display additional data (the name and structural class of the factor, and the absolute and relative site scores), and are hyperlinked to further information on the TF and its binding profile (Figure 3b). The popup windows provide data summaries, including a sequence logo (graphical representation of the specificity of the profile based on position-specific information content [26]) with the corresponding profile from the database. Alignment view (Figure 3c) provides a detailed overview of the detected potential TFBSs displayed on the sequence. The numbering indicates positions in the actual sequences, and the predicted TFBSs are marked. For convenience, a tabular output of detected sites with associated details is also provided in Table view.
Discussion
Comparison of orthologous genomic sequences is an effective method for the identification of segments likely to mediate a sequence-specific biological function. The performance of phylogenetic footprinting methods for the detection of TFBSs is dependent upon multiple factors, including the alignment algorithm, the available binding profiles and the evolutionary distance between the target sequences. Two key data resources are introduced in this study: a novel collection of transcription-factor binding profiles compiled from the biological research literature and a reference test set for phylogenetic footprinting methods. The ConSite web interface to the system facilitates user control, an essential feature for users studying diverse genomes.
The binding profile collection is an important resource for bioinformatics projects. Like the TFBS programming system [27], the JASPAR profile collection is available freely to the research community [15]. The profiles are non-redundant and are restricted to those cases for which sufficient binding data were available to generate a meaningful representation of the binding
specificity of a TF. Continuing expansion of the collection is anticipated, given the strong research progress in modeling DNA binding sites [28].
The new phylogenetic footprinting reference collection of TFBSs allows for quantitative assessment of the performance of new methods. This is the largest collection of its kind available for
broad use. In our study, we could detect around 68% of the experimentally defined TFBSs in conserved segments (at 65% relative matrix score threshold; see Figure 2). This differs slightly from the outcome of a study of conservation
properties proximal to TFBSs [29], which indicated that only around 50% of sites are situated in conserved regions. There are several key factors that may account for this difference. The procedures for defining the collections were different. For
instance, the amount of flanking sequence used for mapping the locations of the sites onto genome sequences was lower in the previous study. These short fragments were mapped onto a commercial human genome assembly and the mapped regions compared to shotgun-generated fragments of mouse genomes from multiple strains. The alignment procedures were also different, with the older set aligned by BLAST [30] and assessed
non-trivial task. Such a system must allow for weighting based on evolutionary distances to preserve sensitivity, and requires advances in multiple sequence alignment algorithms. Some steps in this direction are beginning to emerge [31,32].
No single resource offers the same set of functions or integration as ConSite. The only similarly scoped resource is the recently published rVista [33], which searches for TFBSs in a reference sequence and filters the results for sites in regions of high conservation with respect to a second genomic sequence. Unlike rVista, ConSite searches both sequences for TFBSs, for better specificity, and enables easy modification of the parameters for interactive analysis, as well as providing different output formats
to aid the design and interpretation of experiments in molecular biotechnology. ConSite’s publicly available collection of transcriptionfactor profiles allows users to access information about the TFs associated with the predicted sites. Given that many users focus on a specific TF and have developed highquality models of their own, ConSite also allows for userdefined profiles