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Facilitating Scientific Literacy Through Writing: A Write-to-Learn Assignment for Large Introductory Undergraduate Biology Courses

Write-to-learn (WTL) assignments have been used in a variety of disciplines to encourage conceptual learning and critical thinking in undergraduate education. These assignments focus on facilitating rather than assessing learning. Conversely, write-to-communicate (WTC) assignments (e.g., lab reports and exams), often with the goal of assessing learning, are more commonly employed in foundation STEM courses. We developed a WTL assignment that focuses on promoting curiosity driven learning, critical thinking, and metacognition; skills that promote students’ scientific literacy through writing. We integrated theoretical frameworks for scientific literacy, that include the sub-constructs of third space, authenticity, and multiple discourse as well as science as a human endeavour, and metacognition and self-direction (1, 2) to develop this 3-part WTL assignment. In this assignment, students first select a topic of interest and write freely on their current understanding of the topic (Part 1). They then develop a research question based on their writing and seek answers to their question from published literature (Part 2). Finally, they reflect on their overall experience with the WTL process and propose further avenues of investigation for their research topic (Part 3). Student feedback suggests that they enjoyed the WTL process and their overall satisfaction with the structure of the assignment was high. As we continue to evolve the assignment based on student feedback, we are gratified that students reported high self-efficacy with regard to future writing as a result of participating in this assignment. We recommend use of this type of WTL assignment in large, introductory STEM courses, so as to facilitate rather than simply assess students’ learning.

Primary Image: Scientific literacy through writing. Schematic depicting a write-to-learn assignment format implemented in an introductory undergraduate biology course, along with corresponding science literacy constructs.

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Christie Sampson onto ecology

Walkabout: An Easy to Use, Experiential Learning Activity for Applying Abstract Concepts to the Real-World

Students can have difficulty recognizing examples of course concepts in the real-world. They particularly struggle with phenomena that are ambiguously defined, have mimics, or are hard to distinguish from other phenomena. Students can better explore and understand these phenomena in situ. Unfortunately, short class periods, students’ full schedules, and limited resources hinder classic fieldtrips. So, I created Walkabout, which gives students experiences observing and analyzing in situ phenomenon in the surrounding environment during class periods. Walkabout aligns with elements of active learning, experiential learning, and adventure education. In Walkabout, students learn about and discuss the key characteristics of a concept or phenomenon using pre-class readings, reading responses, and class discussion of classic examples. Then, students leave the learning space to walk outside, identify, and photograph examples of the phenomenon. They return to the classroom or online learning space having selected their best example, which they present to the class and engage in a discussion of how well it represents the phenomenon. This activity can be applied to any course topic that discusses real-world phenomena that are easily observable in the environment surrounding the learners but are difficult to identify or define. Instructors can use it with in-person or online classes, synchronously or asynchronously, and in high-tech, low-tech, and no-tech learning environments. Walkabout helps to scaffold student learning, allows students to practice applying difficult concepts, and creates a more inclusive learning environment. It energizes students, helps them learn from each other, and keeps them engaged and focused in a way they enjoy.

Primary Image: A picture of a student using a smartphone to take a photograph of nature.

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Christie Sampson onto ecology

Investigating the footprint of climate change on phenology and ecological interactions in north-central North America

The module was used in lab following lecture material on pairwise interactions in ecology (emphasizing consumption, competition, mutualism), and parallel to community ecology (emphasizing food web structure, succession, resistance and resilience).

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Christie Sampson onto community ecology

Investigating human impacts on local Hawaiian stream ecology

Students learn about stream ecology on the island of Hawaii using data available through USGS and University of Hawaii websites and develop an understanding for potential stream changes due to predicted climate change.

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Christie Sampson onto ecology

Using drones for conservation work with Eben Broadbent

Eben N. Broadbent, PhD, is an assistant professor of forest ecology & geomatics in the School of Forest Resources and Conservation at the University of Florida, with a PhD in Biology (Ecology & Evolution) from Stanford University. He talks to us about the challenges and opportunities for ecological mapping using drones, including how planet microsatellites are imaging the planet daily.

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Christie Sampson onto field ecology

"Boost your evolution IQ": An evolution misconceptions game

Students often enter introductory biology courses with misconceptions about evolution. For example, many students believe that traits arise when a species needs them or that evolutionary processes are goal-oriented. To address these and other misconceptions, we have developed an activity called "Boost Your Evolution IQ." Student groups compete against one another in a fast-paced, challenging quiz that is presented using PowerPoint. Questions get harder from beginning to end, and the stakes get higher: Each correct answer earns double points in round 2 and then triple points in round 3. Student collaboration throughout the activity helps reinforce the concepts in advanced students and allows struggling students to hear evolution explained in various ways. Further, the same misconception is often tested multiple times, allowing students to learn from their mistakes. This activity is useful as a review before an evolution exam or as a pre- and post-test. It may also be adapted for large classes using clicker technology. We provide a detailed explanation of the approach in the attached video (Supporting File S1).

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Christie Sampson onto evolution

Venom Diversity & Evolution in Reptiles and Amphibians - An education module for university students

This module contains information for a three part series introducing the venom system in reptiles and discussing it in an evolutionary context. In the first part venom and its ecological roles are defined with a discussion of the diversity of venom structures and venomous lineages, primarily in squamates. Examples are provided of the various ways that venoms may vary among biological scales. In parts 2 and 3, the evolution of venom is discussed. Part 2 focuses on a description of how the venom system arose in squamates and a discussion of the challenges associated with defining "venomousness". Part 3 examines the various genetic mechanisms that produce venom variation using examples from primarily literature that are presented in Part 1. In addition to lecture materials, we include a primary literature based activity and a group activity designed to encourage students to explore the diversity of venomous taxa in reptiles and amphibians.

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Christie Sampson onto evolution

Furry with a chance of evolution: Exploring genetic drift with tuco-tucos

Genetic drift is an important mechanism of evolution, yet undergraduates often fail to understand how it leads to evolutionary change due in part to its random nature. This lesson plan describes a simulation-based activity that allows students to demonstrate the process of genetic drift across generations. Using a simulated population of tuco-tucos - a small rodent native to South America - students can explore how allele frequencies can change over time due to chance. Students will also demonstrate random changes in allele frequency (genetic drift) using two different population sizes (with an extended option for a third population size) so they may better conceptualize the impact of population size on genetic drift as an evolutionary force. Using inexpensive materials (beans and paper cups), instructors can actively engage students in the process of evolution. The simulations are followed by a brief discussion of two real-world examples of bottleneck and founder effects, two events when the impact of genetic drift can become more pronounced. The lesson then ends with a series of thought questions to reinforce student understanding of how genetic drift leads to evolution. This activity is appropriate for small or large class sizes and advanced high school and college biology courses. It can also be adapted for non-major college biology courses.

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Christie Sampson onto evolution

Defenses against predation: Interpreting graphs of predator behavior

In this lesson, students discuss anti-predator defense mechanisms and the types of cues defenses provide to predators. Students then interpret graphs of behavior of arthropod predators when presented with different phenotypes of color polymorphic tortoise beetles. Finally, students view and reflect on an interview with Dr. Lynette Strickland, the biologist who collected the data that they interpreted.

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Christie Sampson onto Biology

EvenQuads Deck 2

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EvenQuads Deck 1

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Creative Commons Licensing Information

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Calling Bull Website

Mentioned by Jevin West

Also note the related HS site callingbull.org and the QUBES group Calling Bull.

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Exploring the Complexities of Photosynthesis Through a Comic Strip

Photosynthesis is a conceptually challenging topic. The small scale at which photosynthesis takes place makes it difficult for students to visualize what is occurring, and students are often overwhelmed by all of the details of the process. This activity uses a freely-available comic to make learning photosynthesis more approachable and to help students identify their own misconceptions and questions about the process. This activity is appropriate for any college-level introductory biology course and although it was designed for an online class, it could be adapted for in-person learning. In this activity, students work through a four-part online module. Each part consists of readings and videos containing background information on the steps of photosynthesis followed by the corresponding portion of a comic on photosynthesis. Students then use the background information in the module and the comic to identify their own misconceptions and questions and post these in an online discussion forum. The online module is followed by a live session in which the instructor uses the student discussion posts to clarify any remaining questions. Learning about photosynthesis in the unique visual format of a comic allows students to more easily visualize a process that they cannot see with their own eyes. Students enjoyed this activity because it makes learning photosynthesis fun and less intimidating. This lesson is powerful because it allows the instructor to hear from all students in the course via the discussion forum and then tailor the live discussion session to cover student identified problem topics.

Primary Image: Overview of photosynthesis comic. This image comes from Jay Hosler’s comic Photosynthesis or “gimme some sugar” (© 2020 Jay Hosler, used with permission from the author).

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Crystal Goldyn onto Photosynthesis

Investigating Cell Signaling with Gene Expression Datasets

Modern molecular biology is a data- and computationally-intensive field with few instructional resources for introducing undergraduate students to the requisite skills and techniques for analyzing large data sets. This Lesson helps students: (i) build an understanding of the role of signal transduction in the control of gene expression; (ii) improve written scientific communication skills through engagement in literature searches, data analysis, and writing reports; and (iii) develop an awareness of the procedures and protocols for analyzing and making inferences from high-content quantitative molecular biology data. The Lesson is most suited to upper level biology courses because it requires foundational knowledge on cellular organization, protein structure and function, and the tenets of information flow from DNA to proteins. The first step lays the foundation for understanding cell signaling, which can be accomplished through assigned readings and presentations. In subsequent active learning sessions, data analysis is integrated with exercises that provide insight into the structure of scientific papers. The Lesson emphasizes the role of quantitative methods in research and helps students gain experience with functional genomics databases and data analysis, which are important skills for molecular biologists. Assessment is conducted through mini-reports designed to gauge students' perceptions of the purpose of each step, their awareness of the possible limitations of the methods utilized, and the ability to identify opportunities for further investigation. Summative assessment is conducted through a final report. The modules are suitable for complementing wet-laboratory experiments and can be adapted for different courses that use molecular biology data.

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Alicia Rich onto Loris Project

REMNet: Online Resources 5.3.19

Video on online resources for studying microbiomes from the Research Experiences in Microbiomes Network

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Alicia Rich onto For Students

GSD QUBES Resource Draft (1)

This QUBES module is focused towards AP Environmental studies courses. It includes hypothesis testing, transect sampling, Shannon Diversity Index, and scatter plot and bar graph creation in excel.

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Alicia Rich onto ENVN Teaching

Introduction to Primate Data Exploration and Linear Modeling with R

Introduction to Primate Data Exploration and Linear Modeling with R was created with the goal of providing training to undergraduate biology research students on data management and statistical analysis using authentic data of Cayo Santiago rhesus macaques.

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Alicia Rich onto R Tutorials

Phage Discovery Videos

Instructional Videos

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Jessica McCoy onto SEA PHAGES

Laboratory Math

Lab Math Resources

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Jessica McCoy onto SEA PHAGES

Prejudiced Polygons Presentation File

This is a PDF for an updated version of the Prejudiced Polygons activity. A link to the JMC article about its design is also included.

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Anne Ho onto tetre

Build Multiomic and Visualization Skills in Bioscience Lecture

This resource promotes inclusive learning by using all free platforms to extend the central dogma to an applied experience. Genomics is focused on with literature reviews that are performed to identify genes implicated in a clinical condition. Transcriptomics with data mining of RNAseq acquisition is followed by protein sequence acquisition and modeling. Teaching and learning of communication in the process of science is the final focus.

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Camila Acosta López onto Advanced Molecular Biology

Single Cell Insights Into Cancer Transcriptomes: A Five-Part Single-Cell RNAseq Case Study Lesson

Resources for the Advanced Molecular Biology course (Applied Biosciences Itinerary)

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Camila Acosta López onto Advanced Molecular Biology

USFWS Directorate Fellows Program - 2023

The U.S. Fish and Wildlife Service (FWS) is partnering with Hispanic Access Foundation, Minorities in Agriculture, Natural Resources and Related Sciences (MANRRS), Doris Duke Conservation Scholars Program (DDCSP) and AISES (American Indian Science and Engineering Society) to implement their 2023 Directorate Fellows Program.

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UNODC Wildlife Crime Course Series

Developed under UNODC's Education for Justice (E4J) initiative, a component of the Global Programme for the Implementation of the Doha Declaration, this Module forms part of the E4J University Module Series on Wildlife Crime and is accompanied by a Teaching Guide (forthcoming). The full range of E4J materials includes university modules on integrity and ethics, crime prevention and criminal justice, anti-corruption, organized crime, firearms, cybercrime, trafficking in persons / smuggling of migrants, counter-terrorism as well as wildlife crime.

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