The pH dependence of important protein properties such as binding affinity, catalytic activity, solubility, charge and stability is determined by ionizable residues 1 2 3 . Thus, it is of great importance for researches to have access to a reliable description of these residues. Protonation states of ionizable groups can be described with titration curves and ionization constants (pK_a values). Because pK_a values are difficult to obtain experimentally, especially for large biological systems, several software packages have been developed to predict them based on the protein structure 4 5 6 . PROPKA 7 8 9 is one of the popular protein pK_a prediction software packages mainly because of its speed and accuracy compared to other methods 4 6 , but also because it offers a structural rationalization of the predicted pK_a values.

PROPKA computes the pK_a values of the ionizable residues in a protein by determining a perturbation to the model pK_a value, pK_model, due to the protein environment 7 8 9 :

pK a =  pK model + Δ pK DS + Δ pK HB + Δ pK CC

This perturbation comes from the desolvation penalty (DS), back-bone and side-chain hydrogen bonds (HB), and interactions with other charged groups (CC). The functional form of these terms and the associated parameters are determined empirically, and the relationship between the perturbation and the structure is described by simple distance and angle dependent functions in order to be evaluated with minimal computational effort, and to make analysis tractable also for large proteins or protein complexes. Results of the PROPKA calculations are saved in a formatted text file containing the pK_a and pK_model values for each ionizable residue as well as corresponding lists of all interactions contributing to the pK_a shifts (equation 1). The PROPKA output file also contains the total charge of the protein and the pH-dependent free energy of unfolding, both as functions of pH. The latter can be obtained from the difference in the total protein charge between the folded and unfolded state at a given pH 10 11 :

Δ G U ( pH ) = Δ G U ( pH ref ) + 1 . 36 ∫ pH ref pH ( Q U − Q F ) dpH

Here, ΔG_U(pH_ref) is the unfolding free energy at a reference pH, and the latter term is the pH-dependent change in the unfolding free energy related to the change in protein charge Q between two folding states. Thus, the perturbed protein pK_a values are used to calculate the charge of the folded protein, whereas pK_model values are used for the unfolded state.

The results from the PROPKA calculations can be very helpful, and give detailed information about the influence of the protein environment on the ionizable groups. Nevertheless, the PROPKA output does not provide a direct link between obtained pK_a values and the three-dimensional structure of the studied system. In order to complete analysis of the ionizable residues one needs to make a separate search of these residues together with the interactions determining their pK_a values by hand, using software for visualizing biomolecules. Furthermore, studying raw text data for larger sets of structures can easily become a difficult, complex and time-consuming task.

The PROPKA Graphical User Interface (GUI) presented in this paper is developed to facilitate exploration of the pH-dependent protein properties in a convenient manner by providing a direct link between the structure and the pK_a data, predicted by the PROPKA calculations, via the Visual Molecular Dynamics (VMD) program 12 . Our interface is an easy-to-use tool to identify and rationalize residues with unusual pK_a values or those significantly contributing to the free energy of unfolding. The PROPKA GUI is designed to facilitate the use of the PROPKA program and interpreting its results both for the user's convenience and to increase accessibility to the PROPKA approach for a wide range of researchers. Additionally, our GUI allows for comparative studies of the pH-dependent properties of many structures together, which can be used to rationalize the differences in these properties between homologous structures.

The PROPKA GUI is written in the Tool Command programming Language with the Tk graphical user interface (Tcl/Tk) as a platform-independent plug-in for the VMD program. The VMD program was chosen as a host application for the PROPKA GUI as it offers a great versatility of options and tools for analyzing biological structures, and also because it provides the Tcl/Tk environment as an extension of the VMD core code functionality without the need of making any additional installations. Besides, Tcl/Tk gives a wide range of users an easy but powerful tool to develop their own programs or scripts, or to extend already existing ones. The PROPKA GUI requires the VMD package to be installed on the user's computer. VMD can be obtained online at http://www.ks.uiuc.edu/Research/vmd/. The current version of our GUI is available as a single file that has to be copied into the VMD plug-ins directory and adding only one line into the VMD starting script makes the PROPKA GUI available from the menu in the main VMD window. The PROPKA GUI source-code, which is freely distributed under the GNU General Public License (GPL), installation instructions, documentation, and a screencast tutorial are available on the web at http://propka.ki.ku.dk/~luca/wiki/index.php/GUI_Web.

The GUI extracts and visualizes data from the PROPKA output file. The pK_a calculations can be performed online at http://propka.ki.ku.dk/, or locally, via the GUI, if the PROPKA program is installed on the same computer. By default, the pK_a data from the PROPKA output file and corresponding structure, contained in a separate Protein Data Bank (PDB) 13 file, are loaded simultaneously. pK_a values and their determinants are assigned to the appropriate residues and can be accessed interactively either through the main PROPKA GUI window (Figure 1A) or through the structure display window of VMD (Figure 1B). It is also important to note that the data from the PROPKA output file is assigned to residues of the current top molecule in VMD, which allows for loading pK_a data for all proteins in VMD separately. This provides the user with an access to the pK_a data for many proteins within the same instance of VMD. Going further, such accessibility to the pK_a information together with the VMD MultiSeq tool 14 , which allows for structural alignment of homologous proteins, makes the PROPKA GUI a convenient tool to rationalize the differences in the pH-dependent properties between structurally-related proteins.

All residues and graphical objects displayed using the PROPKA GUI such as ionizable residues, pK_a determinants, ligands, etc., depending on their type, are shown using pre-defined sets of VMD settings and representations. These representations can easily be accessed and modified in the "Graphical Representations" window of VMD. In order to make the PROPKA GUI more convenient to use, the user can also easily display the desired VMD selections, or remove previously shown, directly from the GUI. By default, all labels displaying the desired pK_a information in the structure display window of VMD are drawn using different sets of colors for each molecule. Moreover, corresponding labels for different loaded structures, depending on their molecule ID in VMD, are shifted relative to each other to increase their readability in the case of overlapping residues, which considerably facilitates using the GUI for comparative protein studies. Additionally, the information shown in the structure display window is also printed in the VMD text console.

The PROPKA GUI compares the computed pK_a values to pK_model values and can display residues with the largest pK_a shifts. Based on equation 2, the GUI also computes and displays the contribution of each ionizable residue to the pH-dependent part of the free energy of unfolding. The GUI can therefore be used to display residues contributing the most to the unfolding energy. Moreover, it provides an interactive access to the pK_a determinants listed in the PROPKA output file through the structure display window of VMD.

Our newly developed PROPKA GUI is a powerful and convenient plug-in for VMD providing a direct link between the PROPKA-computed pK_a values, their determinants and the three-dimensional structures. The GUI significantly improves ease of use of the PROPKA approach, and facilitates quick and easy investigation of the pH-dependent properties of proteins such as charge and stabilization energy as well as the separate pK_a values and interactions determining them. It can easily be used to identify and rationalize ionizable residues with perturbed pK_a values or contributing to the pH-dependent stabilization energy the most, either for a single protein or in comparison with other structures. This makes our GUI a helpful tool, for example, in the structure-based function prediction or protein design studies. Moreover, the PROPKA GUI is an open source code written in Tcl/Tk that can easily be customized whenever needed.

• Project name: PROPKA GUI

• Project home page: http://propka.ki.ku.dk/~luca/wiki/index.php/GUI_Web

• Operating system(s): Platform independent

• Programming language: Tcl/Tk

• Other requirements: VMD program installed

• License: GNU General Public License

• Restrictions to use by non-academics: None

MR contributed to design, developing and testing software, and drafted the manuscript. MHMO and CRS contributed to design and software testing, provided support with the PROPKA program, and were involved in revising the manuscript. JHJ conceived the PROPKA GUI, contributed to design, and was involved in revising the manuscript. All authors read and approved the final manuscript.