An undergraduate laboratory class using CRISPR/Cas9 technology to mutate drosophila genes

Adame, Vanesa; Chapapas, Holly; Cisneros, Marilyn; Deaton, Carol; Deichmann, Sophia; Gadek, Chauncey R.; Lovato, TyAnna L.; Chechenova, Maria B.; Guerin, Paul; Cripps, Richard M.

doi:10.1002/bmb.20950

Cited by 27 publications

(32 citation statements)

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“…In some cases, these experiences can be used to generate both laboratory reagents and data as well as data pertaining to student outcomes resulting from the implementation of CUREs. [21][22][23][24][25][26] Given student interest and the increased need to communicate cutting-edge research to undergraduate students, colleges and universities have begun instituting CRISPR-Casrelated CUREs with great success. Part of the reason why CUREs and other forms of course-based research that utilize CRISPR-Cas technologies are successful is due to the current curricula in molecular biology-based laboratory courses at diverse academic institutions, particularly fouryear colleges and universities.…”

Section: Course-based Undergraduate Research Experiencesmentioning

confidence: 99%

“…Although data collection on the outcomes of CRISPR-Cas-based CUREs is ongoing, instructors report increased student learning and engagement after implementing CRISPR-Cas-based CUREs using various metrics. [21][22][23][24][25][26] Academic institutions have only recently started using CRISPR-Cas-based CUREs in their coursework; with increased interest in CRISPR-Cas-based CUREs, more rigorous studies on student achievement will undoubtedly help inform future activities at more institutions.…”

Section: Measuring Successmentioning

confidence: 99%

“…Importantly, although Dr. Richard Cripps only just introduced this course in 2015, he has since published his laboratorybased course model, including the data generated by his students during the course. 24 Some CUREs allow faculty researchers to generate valuable tools and/or reagents that can be used in independent research projects for students within the faculty member's laboratory. For instance, Dr. Kevin Militello at the State University of New York, Geneseo recently published a paper illustrating the power of his laboratorybased course model wherein students examined the CRISPR loci of uncharacterized E. coli strains.…”

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confidence: 99%

“…[22][23][24]28,30,31 Because CUREs that utilize CRISPR-Cas technology are relatively new, there is limited information about how these academic gains translate into student career choices or persistence in scientific (and particularly those involving genetic engineering) fields. However, as the availability of CRISPR-Cas-based CUREs increases, more information regarding the benefits to students will likely become available.…”

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confidence: 99%

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CRISPR-Cas Technology In and Out of the Classroom

Dahlberg

Carmona

2018

The CRISPR Journal

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Student-centered practices, including student-focused research opportunities, enhance biology education and comprehension. One way to support student interest is through research opportunities in faculty laboratories. However, alternatives to traditional research apprenticeships are important for the inclusion of more undergraduate students in CRISPR-Cas-based research. Student interest in CRISPR-Cas technologies serves as a timely focal point for deepening undergraduate student engagement in biology courses. In this article, we describe some of the ongoing efforts to bring CRISPR-Cas technology out of the classroom and into the teaching laboratory. IntroductionThe most effective biology teaching actively engages students in their classrooms and coursework through group-work, activities, and discussion, which all access higher-order thinking and problem-solving skills.

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Section: Course-based Undergraduate Research Experiencesmentioning

confidence: 99%

Section: Measuring Successmentioning

confidence: 99%

mentioning

confidence: 99%

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confidence: 99%

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CRISPR-Cas Technology In and Out of the Classroom

Dahlberg

Carmona

2018

The CRISPR Journal

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“…Recently, Adame et al (2016) demonstrated that Drosophila Act79B null mutants appeared to jump normally, despite lacking the predominant actin found in the jump muscle (also called the tergal depressor of the trochanter, TDT). However, the sample size was small; therefore, in this study we investigated further the role of Act78B and other actin isoforms in the jump muscle of Drosophila.…”

Section: Introductionmentioning

confidence: 99%

Absence of the Drosophila jump muscle actin Act79B is compensated by up‐regulation of Act88F

Dohn

Cripps

2018

Developmental Dynamics

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Background: Actins are structural components of the cytoskeleton and muscle, and numerous actin isoforms are found in most organisms. However, many actin isoforms are expressed in distinct patterns allowing each actin to have a specialized function. Numerous studies have demonstrated that actin isoforms both can and cannot compensate for each other under specific circumstances. This allows for an ambiguity of whether isoforms are functionally distinct. Results: In this study, we analyzed mutants of Drosophila Act79B, the predominant actin expressed in the adult jump muscle. Functional and structural analysis of the Act79B mutants found the flies to have normal jumping ability and sarcomere structure. Analysis of actin gene expression determined that expression of Act88F, an actin gene normally expressed in the flight muscles, was significantly up-regulated in the jump muscles of mutants. This indicated that loss of Act79B caused expansion of Act88F expression. When we created double mutants of Act79B and Act88F, this abolished the jump ability of the flies and resulted in severe defects in myofibril formation. Conclusions: These results indicate that Act88F can functionally substitute for Act79B in the jump muscle, and that the functional compensation in actin expression in the jump muscles only occurs through Act88F. Developmental Dynamics 247:642–649, 2018.

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Discovery of Escherichia coli CRISPR sequences in an undergraduate laboratory

Militello

Lazatin

2016

Biochem Molecular Bio Educ

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Clustered regularly interspaced short palindromic repeats (CRISPRs) represent a novel type of adaptive immune system found in eubacteria and archaebacteria. CRISPRs have recently generated a lot of attention due to their unique ability to catalog foreign nucleic acids, their ability to destroy foreign nucleic acids in a mechanism that shares some similarity to RNA interference, and the ability to utilize reconstituted CRISPR systems for genome editing in numerous organisms. In order to introduce CRISPR biology into an undergraduate upper-level laboratory, a five-week set of exercises was designed to allow students to examine the CRISPR status of uncharacterized Escherichia coli strains and to allow the discovery of new repeats and spacers. Students started the project by isolating genomic DNA from E. coli and amplifying the iap CRISPR locus using the polymerase chain reaction (PCR). The PCR products were analyzed by Sanger DNA sequencing, and the sequences were examined for the presence of CRISPR repeat sequences. The regions between the repeats, the spacers, were extracted and analyzed with BLASTN searches. Overall, CRISPR loci were sequenced from several previously uncharacterized E. coli strains and one E. coli K-12 strain. Sanger DNA sequencing resulted in the discovery of 36 spacer sequences and their corresponding surrounding repeat sequences. Five of the spacers were homologous to foreign (non-E. coli) DNA. Assessment of the laboratory indicates that improvements were made in the ability of students to answer questions relating to the structure and function of CRISPRs. Future directions of the laboratory are presented and discussed. V C 2016 by The

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An undergraduate laboratory class using CRISPR/Cas9 technology to mutate drosophila genes

Cited by 27 publications

References 27 publications

CRISPR-Cas Technology In and Out of the Classroom

CRISPR-Cas Technology In and Out of the Classroom

Absence of the Drosophila jump muscle actin Act79B is compensated by up‐regulation of Act88F

Discovery of Escherichia coli CRISPR sequences in an undergraduate laboratory

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