Using DNA Sequences and Phylogenetic Trees as Tools for Teaching Entomology to Undergraduate Students: A Simple Approach ()
1. Introduction
Teaching entomology to students can be achieved by several methods. Undoubtedly, the conventional teaching method, which has limited innovation strategies had been the main method used so far by most teachers. However, some new and novel methods were proposed. For example, a group of scientists suggested the use of games as a teaching aid and investigated the use of game-based activity as a tool for teaching entomology [1]. They found evidence supporting the usefulness of the game as a didactic activity in the classroom. In another study, the results showed that students were motivated to play a game and the learning test suggested an improvement in matters related to morphology, taxonomy, and the insect life cycle [2]. Furthermore, studies even suggested and investigated the teaching of entomology with postage stamps as a didactic resource [3]. No doubt, educational technologies have a role to play in teaching and learning entomology. Thus, an interactive album of veterinary acarology and entomology was presented and evaluated in a study, which revealed that students had better grades in a course with visualization technologies [4]. Overall, it should be emphasized that the instructional delivery method of any science, including entomology, can affect how students are exposed to new topics and their level of understanding.
Using technology in education helps students learn faster and make the learning process more enjoyable. The field of education was revolutionized by the use of technology, and with the onset of computers in education, teachers should encourage their students to acquire more knowledge [5]. Therefore, teaching insect identification and taxonomy with the help of in silico methods is always informative and an interesting experience for students. Moreover, such experience could be enhanced by the use of computers and online tools. On the other hand, mobile learning, which is the use of electronic devices to learn across contexts, connects individuals with media, educators, peers, and experts. Furthermore, mobile technologies can be employed to improve learning [6]. Thus, the teaching of entomology should benefit from mobile learning. Consequently, teachers can use DNA sequences and phylogenetic trees in the classroom. In addition, knowing how to interpret and reason from phylogenetic trees is a very important element of biology education in general [7]. A study tested the use of project-based learning (PBL) activity that was developed to teach phylogenetics for junior and senior-level biology students. The results indicated that the PBL approach helped the students and reinforced the theories and concepts which were taken previously along with incorporating bioinformatics [8]. In addition, another study emphasized the use of portable sequencing as a teaching tool in conservation and biodiversity research. It provided step-by-step protocols for a field training program that uses low-cost, portable devices to conduct direct genomics-based training [9]. Additionally, one study provided an educational guide for nanopore sequencing in the classroom. It proposed a model that bridges experimental and bioinformatics concepts using the Oxford Nanopore Technologies (ONT) sequencing platform [10]. However, it should be mentioned that many students are not familiar with DNA sequencing and feel that this topic is sophisticated. Therefore, practice is a key factor here to make things look easier over time. In addition, the role of a teacher is to make this topic more attractive to students. In this technical note, we demonstrate two exercises that help students learn how to use the Basic Local Alignment Search Tool (BLAST) (https://www.ncbi.nlm.nih.gov/) and the “one click” mode of Phylogeny.fr (http://www.phylogeny.fr/simple_phylogeny.cgi) to learn insect DNA similarity levels.
2. Finding Insects’ DNA Similarity Using BLAST
The first exercise uses the nucleotide BLAST. This tool helps students search in the GenBank database for DNA sequences that are similar to a DNA sequence that is provided to them by the teacher. Students should know that the GenBank has more tools besides BLAST and provides many services, however, the focus in this exercise is on BLAST only. The three most important things that a student needs to keep in mind during a BLAST search are: 1) to paste the DNA sequence or accession number in the “enter query sequence” window, 2) to make sure that the database is the standard database with the option nucleotide collection (nr/nt), and 3) to choose the “highly similar sequences (megablast)” option in the program selection. Usually, these are the default settings on the BLAST page. For example, a teacher may provide an accession number such as KJ022631 to students and ask them to write a report on the insect species of this accession number and show the DNA similarity between it and the most similar GenBank records. By pasting this accession number in the “enter query sequence” window, students will find out that this accession number is for a DNA sequence from the cytochrome c oxidase subunit 1 mitochondrial (cox1) gene extracted from a camel tick, Hyalomma dromedarii, that is found in the United Arab Emirates. In addition, students can get DNA sequences that are similar to this accession number in the GenBank and present a summary of the search results (Table 1). Furthermore,
Table 1. Summary of DNA similarity between a fragment of the cytochrome c oxidase subunit 1 mitochondrial gene (cox1) of the accession number KJ022631 and GenBank records using NCBI BLAST.
students need to learn that a good match should have an “Expect” value (E-value), which is the number of hits one can find by chance, as zero or very close to zero (10−5 or lower). The lower the E-value is, the more significant the match. In addition, the “query coverage”, which is the percentage of the input sequence (KJ022631 in this example) aligned to sequences of the GenBank, should be a high value, which means the target sequence in the database spans most or the whole query sequence. Also, the “percent identity”, which is the extent (percent) to which the input sequence and the GenBank sequence have the same residues at the same positions in an alignment, should be 100% or close to 100% to provide species-level DNA similarity and the higher this percentage the better the match. In short, while working on the BLAST exercise students need to look for the highest values of the maximum score, total score, query coverage, and percent identity, except for the E-value where zero is the best score. Repeating this exercise several times during the semester builds a good level of confidence in students and encourages them to use the GenBank data without difficulty in an entomology course as well as in other courses.
3. Constructing a Simple Phylogenetic Tree
In the second exercise, we give the students several accession numbers (Table 2) and ask them to get their nucleotide sequences in FASTA format from the GenBank.
These accession numbers are for DNA sequences of the cox1 gene of eight insect species. Each DNA sequence can be retrieved easily from the GenBank by writing the accession number in the search window while keeping the default settings without change. Once a target record is found, its nucleotide sequence can be downloaded in FASTA format as a text file. In this example, students have eight files to download. First, students should download and save each file separately then merge the files into one file to be used later in making a phylogenetic tree. To do this, a text file (Microsoft NotePad file) can be created (Figure 1). Within the file, the accession number and the name of each insect
Table 2. GenBank accession numbers of DNA sequences of the cytochrome c oxidase subunit 1 mitochondrial gene (cox1) of eight insect species from four orders.
Figure 1. Content of the text file with DNA sequences in FASTA format, which were downloaded from the GenBank to be used in making a phylogenetic tree. Sequences were shortened here (3 lines each) to fit in one page, however, in actual work each DNA sequence should be copied and pasted according to its length in the GenBank.
species should be preceded by the greater than (>) symbol.
Students do not need to be experts in phylogenetics to construct an informative phylogenetic tree. This is most simply done using an online tool such as Phylogeny.fr (http://www.phylogeny.fr/simple_phylogeny.cgi) using the “one click” mode [11]. The text file, which was already created and saved by each student, should now be opened using the “browse” option on Phylogeny.fr website or by copying and pasting the file content (Figure 1) in the submission window. As soon as the data are submitted, the one-click mode will automatically perform sequence alignment, curation, phylogenetic analysis, and tree rendering. As a result, a phylogenetic tree is produced. Under the “display” options, students can select “Display branch support values in %” because using percentages is always much easier to be understood. The tree can be downloaded (Figure 2) in different formats by first clicking either PNG, PDF, SVG, or Newick option and then by right-clicking on the tree image to save it using the “save image as” option. This tree gives the students a visual demonstration of the degree of DNA similarity among the eight sequences. For instance, the tree shows that the two species of bees (Apis mellifera and Apis nigrocincta) were in one cluster and have the highest branch support value (100%) compared to the other species. The same can be said almost about all the other insect species that belong to one order on the tree. In short, this exercise shows students how insects in one order have a higher degree of DNA similarity compared to insects from other orders. By following this simple workflow (Figure 3), different exercises could be created as classroom or take-home assignments to demonstrate various levels of DNA similarity in different insect taxa at any level. One point that should be mentioned here is that students need to know that DNA-based insect identification in some cases does not lead to the right species name and consequently, it should be supplemented by morphology and this is known as integrative taxonomy [12]. Some people may consider that searching for an accession number in the GenBank using BLAST is a very simple task and does not offer much to students. However, over the years we found that it is exactly the opposite because this search breaks the barrier of fear of bioinformatics and opens up new ways for students to understand some concepts in entomology through molecular biology, and allows them to develop new skills that contribute to strengthening their scientific performance in the future, especially when they do research. Furthermore, constructing a simple phylogenetic tree can give students a basic understanding of the fact that there are common genes among living things, including insects, which can be used to show the degree of relatedness among living things. In addition, this understanding will be the basis on which students
Figure 2. Phylogenetic tree constructed using DNA sequences of the cox1 gene of eight insect species from four orders. Red numbers are the branch support values presented as percentages. The analysis was performed using Phylogeny.fr (http://www.phylogeny.fr).
Figure 3. Summary of the workflow of the two tasks. Task 1 shows how students are given an accession number to find similar sequences in the GenBank using BLAST. Task 2 shows how students can make a simple phylogenetic tree with eight insect DNA sequences using Phylogeny.fr (http://www.phylogeny.fr).
build deeper awareness of insect taxonomy.
4. Conclusion
To conclude, using DNA sequences of the cox1 gene from the GenBank and the “one click” mode of Phylogeny.fr to construct simple phylogenetic trees are good tools for teaching entomology to undergraduate students. Moreover, both the teacher and the students do not need to be experts in phylogenetics to benefit from these tools and enjoy learning about DNA similarities in insects. In addition, besides aiding the learning of entomology these tools expand students’ scientific horizons and unlock creativity.