This lesson is a self contained lesson on DNA structure.  It will keep the students busy for days and days and even a week or more.  There is no associated lecture.  It requires no knowledge of DNA or biology or anything.  The learning objective is the structure of DNA and nothing more.DNA in cells is elegant in its simplicity.  Catch your breath DNA is elegant in its simplicity.  Both are made of four things and both can only go together in one way.The core of this cool lesson plan is a paper template.  The students will be coloring the bases and cutting them out.  They can only go together one way and the students will see that.The paper templates are made on an ordinary copy machine and the template is included in the literature.  The templates are copied front and back with a front and back template. But it is not great trick.  The download includes all information and there is a video for the teacher and a video for the kids.The lesson plan is suitable for all students, from 4th grade up.  It would be suitable for college as well.The documentation can be found here https://app.box.com/s/hlhung3gz5heqmno82yc0xwfs7zl2puhIt references the videos.  But the videos is here:https://youtu.be/1BiTYfTpTu4Licensed under Creative Commons ...mrphysh

In this course we will explore how altered metabolism drives cancer progression. Students will learn (1) how to read, discuss, and critically evaluate scientific findings in the primary research literature, (2) how scientists experimentally approach fundamental issues in biology and medicine, (3) how recent findings have challenged the traditional “textbook” understanding of metabolism and given us new insight into cancer, and (4) how a local pharmaceutical company is developing therapeutics to target cancer metabolism in an effort to revolutionize cancer therapy.

In this course, students will develop their abilities to expose ways that scientific knowledge has been shaped in contexts that are gendered, racialized, economically exploitative, and hetero-normative. This happens through a sequence of four projects that concern:

Interpretation of the cultural dimension of sciences
Climate change futures
Genomic citizenry
Students' plans for ongoing practice

The course uses a Project-Based Learning format that allows students to shape their own directions of inquiry in each project, development of skills, and collegial support. Students' learning will be guided by individualized bibliographies co-constructed with the instructors, the inquiries of the other students, and a set of tools and processes for literary analysis, inquiry, reflection, and support. 
Acknowledgement
Professor Peter Taylor spent several years crafting the unique structure of the course, which is crucial to the way it was taught. 
The Consortium for Graduate Studies in Gender, Culture, Women, and Sexuality
This course was taught as part of the Consortium for Graduate Studies in Gender, Culture, Women, and Sexuality (GCWS) at MIT. The GCWS brings together scholars and teachers at nine degree-granting institutions in the Boston area who are devoted to graduate teaching and research in Women's Studies and to advance interdisciplinary Women's Studies scholarship.

This resource is a video abstract of a research paper created by Research Square on behalf of its authors. It provides a synopsis that's easy to understand, and can be used to introduce the topics it covers to students, researchers, and the general public. The video's transcript is also provided in full, with a portion provided below for preview:

"Walking through the produce section at the grocery store, you are likely to find tomatoes of all shapes, sizes, and colors. One variety may be large and oblong with a hint of bitter flavor while another will have small, sweet fruits. This variance is primarily the result of genetic and chemical properties of the different varieties. But it turns out, environment also plays a role. A team of Italian scientists has shown that the molecular properties of tomatoes are strongly influenced by environmental factors such as temperature and moisture. And changing these factors can, in turn, have pronounced effects on the physical and culinary qualities of the fruits – an important finding considering the pace of current climate change. To tease apart the interaction between genetics, environment, and organoleptic traits, the research team grew three tomato varieties in two different locations. This exposed the plants to varying levels of moisture, soil acidity, and temperature, among other conditions..."

The rest of the transcript, along with a link to the research itself, is available on the resource itself.

Instructions on how to extract DNA from students cheek cells. Includes follow-up questions.

Overview of DNA transcription, translation, and replication during mitosis and meiosis. Learn about chromosomes, chromatids, and chromatin.

In this online article, from the museum's Musings newsletter for educators, a resource teacher for gifted children discusses how she keeps one step ahead of her students. Cindy Sheets offers tips on devising a dynamic curriculum tackling the ever-changing field of genetics.

The topic of this video module is how to classify animals based on how closely related they are. The main learning objective is that students will learn how to make phylogenetic trees based on both physical characteristics and on DNA sequence. Students will also learn why the objective and quantitative nature of DNA sequencing is preferable when it come to classifying animals based on how closely related they are. Knowledge prerequisites to this lesson include that students have some understanding of what DNA is and that they have a familiarity with the base-pairing rules and with writing a DNA sequence.

In complete dominance, only one allele in the genotype is seen in the phenotype. In codominance, both alleles in the genotype are seen in the phenotype. In incomplete dominance, a mixture of the alleles in the genotype is seen in the phenotype.

How genetics can add to our understanding of cognition, language, emotion, personality, and behavior. Use of gene mapping to estimate risk factors for psychological disorders and variation in behavioral and personality traits. Mendelian genetics, genetic mapping techniques, and statistical analysis of large populations and their application to particular studies in behavioral genetics. Topics also include environmental influence on genetic programs, evolutionary genetics, and the larger scientific, social, ethical, and philosophical implications.

This is a coloring book that I drew and designed as a fun way for my students to review information and/or doodle on. The pictures are inspired by images I use in my General Biology I class, and are presented in the same order as they are discussed in my class. The coloring book is NOT designed as an alternative to attending lecture, studying notes, etc. You can download the PDF of the coloring book and then color the pictures on an app (like using an iPad and Apple Pencil) or print out the images and color them using your preferred method (like with colored pencils).

This genomics education lesson plan was formulated and tested on some year 6 students with the help of their teacher Michelle Pardini at the Hong Kong ICS School. Using the example of the ongoing citizen science Bahinia Genome project from Hong Kong it hopes to serve as a model to inspire and inform other national genome projects, and aid the development of crucial genomic literacy and skills across the globe. Inspiring and training a new generation of scientists to use these tools to tackle the biggest threats to mankind: climate change, disease, and food security. It is released under a CC-BY SA 4.0 license, and utilised the following slide deck and final quiz. Promoting open science, all of the data and resources produced from the project is immediately put into the public domain. Please feel free to utilise, adapt and build upon any of these as you wish. The open licence makes these open education resources usable just with attribution and posting of modified resources under a similar manner. Contact BauhiniaGenome if you have any questions or feedback.Bauhinia Genome overviewFor a slidedeck for the lesson plan laid out here you can use the set in slideshare here.

With the growing availability and lowering costs of genotyping and personal genome sequencing, the focus has shifted from the ability to obtain the sequence to the ability to make sense of the resulting information. This course is aimed at exploring the computational challenges associated with interpreting how sequence differences between individuals lead to phenotypic differences in gene expression, disease predisposition, or response to treatment.

Host Harry Kreisler Welcomes Professor Sir John Gurdon for a discussion of advances in research on cell biology. Sir John reflects on his career as a scientist including his path breaking research on cloning. He offers insights into the implications of the revolution in the biological sciences.(46 min)

Precise modification of faulty genes for repair has been one of the most important goals in medicine. It is now finally within the realm of possibility thanks to the gene editing tool CRISPR. This microbial adaptive immune system can copy and cut specific DNA sequences. This animation provides a visual introduction of this revolutionary genetic tool.

Precise modification of faulty genes for repair has been one of the most important goals in medicine. It is now finally within the realm of possibility thanks to the gene editing tool CRISPR. This microbial adaptive immune system can copy and cut specific DNA sequences. This animation provides a visual introduction of this revolutionary genetic tool.

Short Description:
This book provides an introduction to the genetic concepts of reproductive systems, recombination, mutation, segregation and linkage analysis, inbreeding, quantitative inheritance, fertility regulation, population genetics and polyploidy.

Long Description:
This book provides an introduction to the genetic concepts of reproductive systems, recombination, mutation, segregation and linkage analysis, inbreeding, quantitative inheritance, fertility regulation, population genetics and polyploidy.

Word Count: 61452

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

Learn about DNA (deoxyribonucleic acid). Overview of DNA bases, complementary base pairing, and the structure of the double helix.

Students reinforce their knowledge that DNA is the genetic material for all living things by modeling it using toothpicks and gumdrops that represent the four biochemicals (adenine, thiamine, guanine, and cytosine) that pair with each other in a specific pattern, making a double helix. They investigate specific DNA sequences that code for certain physical characteristics such as eye and hair color. Student teams trade DNA "strands" and de-code the genetic sequences to determine the physical characteristics (phenotype) displayed by the strands (genotype) from other groups. Students extend their knowledge to learn about DNA fingerprinting and recognizing DNA alterations that may result in genetic disorders.