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Annals of West University of Timişoara, ser. Biology, 2015, vol XVIII (1), pp.33-42

TEACHING CONTEMPORARY CHEMISTRY,

BIOCHEMISTRY AND BIOLOGY: FREE AVAILABLE

DATABASES, WEB TUTORIALS AND ON-LINE TOOLS

Alecu CIORSAC1, Narcisa CRISTA2, Adriana ISVORAN*3 1

Politehnica University of Timisoara, Department of Physical Education and Sport, 2 P-ta Victoriei, 300006, Timisoara, Romania

2

University of Agricultural Sciences and Veterinary Medicine of Banat “Regele Mihai I al Romaniei” from Timisoara, Romania

3

Department of Biology-Chemistry, West University of Timisoara, 16 Pestallozi, 300115, Timisoara, Romania

*Corresponding author’s e-mail address: adriana.isvoran@e-uvt.ro

Received 1 May 2015; accepted 26 May 2015 ABSTRACT

Within this study we underline the usefulness of studying bioinformatics both at secondary school and university levels. Also, we emphasise the need of training programs in bioinformatics allowing the secondary school teachers and udergraduate students to be able to utilise the actual resources such as to reflect current practices and state of the art in chemistry, biology and biochemistry. Furthermore, we describe some free available databases and basic bioinformatics tools and illustrate their use for the secondary school and university levels. We also mention the general and specific competences, attitudes and values that are formed to the pupils and students by the use of the bioinformatics resources.

KEY WORDS: bioinformatics, databases, webservers, on-line teaching tools.

INTRODUCTION

The last few decades are characterized bythe development of the internet,

the growth of online resources and major advances in the field of chemistry, molecular biology, structural biochemistry and genetics. There also is an accumulation of chemical and biological data and informatics tools used to treat and comprehend them. Chemists, biologists and biochemists dispose today of three-dimensional structures of biological macromolecules and their complexes and also of imaging and animation tools allowing to explore nature at molecular level. Understanding of intensive chemical, biological and biochemical data using informatics tools, such as methods and services, is the object of bioinformatics. Unfortunately, the bioinformatics tools, chemical, biochemical and biological current resources are known today only by specialists.

A simple search within the chemistry, biochemistry and biology curricula for both pupils and students in Romanian secondary schools and universities reveals that bioinformatics courses are largely absent. There are only a few bioinformatics courses within the curricula of master degree programs and similarly for the PhD level. This is also true for many other European countries, especially for the east-European ones. The absence of a computational element in secondary school and university chemistry, biology and/or biochemistry

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classrooms provided to be a constant concern to the computational chemistry, biology and biochemistry community during the last years (Gallagher et al, 2011; McQueen et al, 2012; Wood & Gebhardt, 2013; Marques et al, 2014).

Even if the secondary school curricula for chemistry and biology would contain bioinformatics or other relates topics, the teachers are not prepared to teach such subjects. At European level, starting to 2010, there were a few bioinformatics courses organized for the secondary school teachers by the European Molecular Biology Laboratory (EMBL) and the European Bioinformatics Institute (EMBL-EBI) (Wood & Gebhardt, 2013). In the period 2010-2012 there were only 80 participants to these courses, a very low number and Romania was not represented (Wood & Gebhardt, 2013).

The aim of this study is to describe a few basic bioinformatics resources that are useful for high school and university levels and to illustrate how they equip teachers, pupils and students with the competencies, values and attitudes to be able to utilise the resources such as to reflect current practices and state of the art in chemistry, biology and biochemistry.

METHODOLOGY

The bioinformatics resources are enormously grown in the last decades and they cannot be explored in only one training course. Such a course may only specify and illustrate the basics of bioinformatics. So, first of all, we try to answer to the question ”What to teach?”. The other questions that we answer are ”Where can I find relevant biological and/or biochemical information?”, ”How to access various bioinformatics resources?” and ”How to visualize and analyse the three dimensional structure of a protein or of its complex with the ligand?”. In order to answer to these questions we enumerate, shortly define and describe how to access some basic resources for bioinformatics training programs. Then we illustrate how to extract the three-dimensional structure of a protein complex, visualize and exploit this data in order to obtain relevant biological and/or biochemical information.

RESULTS AND DISCUSSIONS

Taking into account the curricula for chemistry, biology and biochemistry for the secondary school and university levels, bioinformatics resources help to teach mostly the structure and functions of proteins and nucleic acids, genomics, mutagenesis.

Within Table 1 we present a few basic bioinformatics resources, including webservers and databases free available for the academic community and we shortly describe them and designate how they may be used for training courses of secondary school science teachers and undergraduate students.

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Annals of West University of Timişoara, ser. Biology, 2015, vol XVIII (1), pp.33-42

TABLE 1. Webservers and relevant databases for teaching biology and/or biochemistry at secondary school and university levels Bioinformatics

resource and its web page

Type of resource

Short description When to use the facility in a secondary school or undergraduate classroom? Secondary school general and specific competencies, values and attitudes University level competencies Didactic methods The Universal Protein Resource (UniProt) (Appweiller et al, 2004 ) http://www.unip rot.org/

database UniProt database

contains freely accessible information concerning protein sequence and functional information.

UniProt could be used in the classroom for studying the structural levels of proteins and

mutations and for

analysing the functions of proteins. Chemistry: - explanation of phenomena, processes, procedures; -assessment of consequences of action of chemicals on living

organisms and the environment; - investigation of the behavior of substances or chemical systems; Biology: -the reception of information about the living world;

-interest in Chemistry: -determination of the composition, structure and physico-chemical properties of chemical compounds; Biochemistry: -identification and characterization of biochemical compounds present in living organisms; -exploring the biochemical processes of living organisms; -integration of inter/ enquiry-based learning learning by discovery Protein Data Bank (PDB) (Berman et al, 2000) www.rcsb.org/p db/

database The Protein Data Bank

is the single

worldwide archive

containing information

about the three

dimensional structures

of proteins and

nucleic acids and/or their complexes.

PDB is used in the

classroom for

studying the

secondary and tertiary structural levels of proteins and nucleic acids. More than it, its website allows visitors to perform simple and complex queries on the data, analyse, and visualize the results. Chimera (Pettersen et al, visualizati on and Chimera allows visualization,

Chimera is used in the

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36 http://www.cgl.u csf.edu/chimera/ toll for macromole cules tool analysis of the structure of a protein or nucleic acids, illustration the interactions between the biological macromolecules. It may be free

downloaded from the webpage.

dimensional structures of proteins and nucleic acids and for analysis of their interactions.

For the university

level it may be also

used for sequence

alignment, molecular docking results visualization and analysis. discoveries in the sciences; -motivation for scientific information and documentation; -cultivation of receptivity and flexibility to apply biological knowledge in everyday life; -data collection from various sources of information/docum entation about the organization of the living world; - corresponding use of the scientific terminology in description and explanation of phenomena and processes. domain specific knowledge; -developing professional projects with the use of principles

and methods

consecrate in the field;

-awareness of the need for continuous training; Biology: - investigation of molecular and cellular basis of organization and functioning of living matter; -efficient use of resources and learning techniques for personal and professional development. project-research theme BRENDA (Schomburg et al, 2013) http://www.bren da-enzymes.org/ind ex.php

database BRENDA contains a

collection of

molecular and

biochemical

information on

enzymes.

It may be used when

we teach about enzymes, their functions, mechanisms and parameters reflecting enzyme activity. ZINC (Irwin et al, 2012) http://zinc.docki ng.org/

database It contains a collection

of commercially available chemical compounds and their properties.

It may be used at the university level for

analysis of the

interactions of

biological

macromolecules with

drugs and other

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Annals of West University of Timişoara, ser. Biology, 2015, vol XVIII (1), pp.33-42

Furthermore, we state the asked general competences, values and attitudes in chemistry, biology and biochemistry developed by using these resources for both secondary school and university levels. In addition to these webservers and databases, there are two international institutions providing freely available data, large multi-core computational clusters, training courses at different levels and diverse web services to support bioinformatics research in the field of chemistry, biochemistry and biology: European Molecular Biology Laboratory and European Bioinformatics Institute ((EMBL- EBI) (http://www.embl.org/, http://www.ebi.ac.uk/) and National Center for Biotechnology Information (NCBI) (http://www.ncbi.nlm.nih.gov/) respectively.

Further we illustrate the use of these databases and bioinformatics tools for a biochemistry application concerning the structure and function of one of the most known human proteins, haemoglobin. The use of UniProt database for extracting the sequence of the protein and some functional information gives the results presented in the Figures 1. The code entry of this protein for the UniProt database is P69905, as reflected in Figure 1A.

A

>sp|P69905|HBA_HUMAN Hemoglobin subunit alpha OS=Homo sapiens GN=HBA1 PE=1 SV=2 MVLSPADKTNVKAAWGKVGAHAGEYGAEALERMFLSFPTTKTYFPHFDLSHGSAQVKGHG

KKVADALTNAVAHVDDMPNALSALSDLHAHKLRVDPVNFKLLSHCLLVTLAAHLPAEFTP AVHASLDKFLASVSTVLTSKYR

B

FIG. 1. First part of the access page of the subunit alpha of the human haemoglobin in the UniProt database with some functional information (A) and its e sequence in FASTA format.

The use of UniProt database for studying human haemoglobin revealsthat adult haemoglobin is a heterotetramer containing two alpha and two beta chains, that this protein contains heme as prosthetic group, its biological function being the

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oxygen binding and transport. Its alpha subunit has 142 amino acids in sequence (Figure 1B). There also is other information concerning haemoglobin that may be used in specific applications and studies.

The Protein Data Bank is used to identify the three dimensional (3D) structure of the human haemoglobin and to extract the structural information. There are 39 structures concerning the human haemoglobin in the PDB, all of them being obtained through X-ray crystallography. We have chosen to analyse a structure of the human haemoglobin in the oxygenated form and obtained at a good resolution, 1.25Å. This structure has the code entry 2DN1 and its web page is presented in the Figure 2.

FIG. 2. The access page of the human haemoglobin in the PDB

This webpage gives information about the experimental procedure used to obtain the structure, published data for this structure, related structures, ligand information and other relevant information. There also is a picture illustrating the spatial structure of the dimer (one alpha and one beta chain). The web page is used to extract the structural file. For this purpose we use Download file button and choose the PDB file (text) option to download the structural file to be used in windows applications.

The use of Chimera tool for visualization and characterization of the structure of human haemoglobin is illustrated in the Figures 3-5. Figure 3 illustrates the visualization of the backbone of the dimer (alpha and beta subunits) such as the alpha chain is coloured in dark grey, the beta chain in light grey the heme in black and the oxygen molecules in dim grey respectively. This picture allows the users to identify the secondary structure elements (helices) of the protein

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Annals of West University of Timişoara, ser. Biology, 2015, vol XVIII (1), pp.33-42

and the ligand (the heme group and the oxygen molecule). Figure 4 illustrates the surface of the protein revealing cavities and pockets that may be targeted using drug molecules.

FIG. 3. The spatial structure of the heterodimer of the human haemoglobin: the alpha subunit is shown in dark grey, beta subunits in light grey, the heme groups in black and the oxygen molecules in dim grey.

FIG. 4. The surface of the heterodimer of the human haemoglobin: the alpha subunit is shown in dark grey surface, beta subunits in light grey surface and the heme groups in black surface.

In order to perform a detailed analysis of the interactions of the protein with the prosthetic group and oxygen molecule, Figure 5 illustrates the structure of the alpha subunit where the lateral chains of the amino acids interacting with the heme group are revealed.

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Information about the ligand (the heme group) is obtained from the ZINC database. Figure 6 illustrates the page of the heme within this database.

FIG. 5. Visualization of the interacting residues (labelled, black) with the heme group (grey sticks) and the oxygen molecule (grey spheres).

FIG. 6. The heme molecules page inside ZINC database.

Zinc database also contains useful information about the chemical molecule, its molecular properties being presented in the Table 2.

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Annals of West University of Timişoara, ser. Biology, 2015, vol XVIII (1), pp.33-42

TABLE 2. Molecular properties of the heme group: logP- the partition coefficient, tPSA – topological polar surface area, MW – molecular weight.

Property logP Net charge tPSA (Å2) MW

(g/mol)

Rotatable bonds

value 7.70 0 140 562.67 8

Data presented in Table 2 reflects that heme is a highly hydrophobic molecule (the logP value is positive and high), with a neutral net charge and a small topological polar surface area and also a flexible molecule having a big number of rotatable bonds. All these properties are important for judging the absorption, diffusion, metabolism, excretion and toxic (ADMETox) properties of the heme, that is used as a component of the Proferin, an iron supplement administrated to prevent or treat low levels of iron in the blood.

CONCLUSION

Within this paper we illustrated how a few bioinformatics resources may be used in the classroom for both secondary school and university levels. The use of bioinformatics resources facilitates the understanding of the composition of living matter at molecular level and the molecular interactions governing many physiological processes. Our experience in teaching and using bioinformatics resources at the university level in the last 12 years allow as to advertise that students appreciate these resources as actual, with a very attractive presenting form and extremely useful. Our experience refers to the master students and they always made the reflection that these tools would be extremely useful for them in the undergraduate level when they studied biochemistry and molecular biology.

Moreover, due to a project for the development of the human resources, during the last year we had the opportunity to work with pupils from the secondary school. We presented them a few basic bioinformatics resources and they were very interested and they told as that this information helps them to understand better the living world and the connections between different topics studies at school.

The use of bioinformatics resources (both databases and web services) represents an ideal framework to develop classroom activities permitting the use of enquiry-based learning and learning by discovery. In addition, for the pupils in the last classes of the secondary schools and for the university level, these resources permits to use the project or/and research theme as a didactic method for chemistry, biochemistry and biology.

We underline the usefulness of studying bioinformatics at the secondary school and university levels and the necessity to prepare the secondary school teacher to be able to use the bioinformatics resources.

REFERENCES

• Apweiler R., Bairoch A., Wu C.H., 2004. Protein sequence databases, Curr Opin Chem Biol 8:76-80. • Berman H.M., Westbrook J., Feng Z., Gilliland G., Bhat T.N., Weissig H., Shindyalov I.N., Bourne P.E.,

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• Gallagher S.R., Coon W., Donley K., Scott A., Goldberg D.S., 2011. A First Attempt to Bring Computational Biology into Advanced High School Biology Classrooms, PLOS Comput Biol7(10): e1002244.

• Irwin J.J., Sterling T., Mysinger M.M., Bolstad E.S., Coleman R.G., 2012. ZINC: A Free Tool to Discover Chemistry for Biology, J Chem Inf Model, 52 (7):1757–1768

• Marques I., Almeida P., Alves R., Dias M-J., Godinho A., 2014. Pereira-Leal B., Bioinformatics Projects Supp orting Life-Sciences Learning in High Schools, PLOS Comput Biol 10(1):e1003404.

• McQueen J., Wright J.., Fox J.A., 2012. Design and Implementation of a Genomics Field Trip Program Aimed at Secondary School Students, PLOS Comput Biol 8( 8): e1002636.

• Pettersen E.F., Goddard T.D., Huang C.C., Couch G.S., Greenblatt D.M., Meng E.C., Ferrin T.E., 2004. UCSF Chimera--a visualization system for exploratory research and analysis, J Comput Chem 25(13):1605-1612.

• Schomburg I., Chang A., Placzek S., Söhngen C., Rother M., Lang M., Munaretto C., Ulas S., Stelzer, M., Grote A., Scheer A., Schomburg D., 2013. BRENDA in 2013: integrated reactions, kinetic data, enzyme function data, improved disease classification: new options and contents in BRENDA, Nucl Acids Res 41 (D1): D764-D772.

• Wood L., Gebhardt P., 2013. Bioinformatics Goes to School—New Avenues for Teaching Contemporary Biology, PLOS Comput Biol 9(6):e1003089.

References

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