Cell & Developmental Biology of Xenopus:
Gene Discovery & Disease
April 2 - 16, 2024

Key Dates
Application Deadline
: January 31, 2024
Arrival: April 2nd by 6pm EST
Departure: April 16th around 12pm EST

CSHL Courses are intensive, running all day and often including evenings and weekends; students are expected to attend all sessions and reside on campus for the duration of the course.

Chenbei Chang, University of Alabama at Birmingham
Lance Davidson, University of Pittsburgh

Rachel Miller, UTHealth Houston, McGovern Medical School, Houston, TX
Peter Walentek,  UNIVERSITÄTSKLINIKUM FREIBURG, Freiburg, Germany

See the roll of honor - who's taken the course in the past.

Follow us on Twitter @cshlxeno

In vivo animal models are an important tool for the understanding of human development and disease. Studies using the frog Xenopus have made remarkable contributions to our understanding of fundamental processes such as cell cycle regulation, transcription, translation and many other topics. Xenopus is remarkable for studying development and disease, including birth defects, cancer, and stem cell biology. Because Xenopus are easy to raise, producing many thousands of eggs per day, these frogs have emerged as a premiere model for understanding of human biology from the fundamental building blocks to the whole organism.

The recent development of CRISPR/Cas9 technology has made it easy to target genes of interest using Xenopus. This course has been designed with that in mind. Our goal is for each student to design a set of experiments focusing on their gene or biological interest. Prior to starting the course, students will be expected to choose gene(s) of interest, and the instructors will generate sgRNAs targeting these genes. These can be the students’ own genes, or chosen from a bank provided by the instructors. The gene targeting experiments will be combined with other manipulations, such as tissue explants and transplants and live imaging to analyze the function of the genes.

Xenopus is increasingly being used as imaging test-bed to investigate the roles of cytoskeleton and intracellular trafficking in cell biological and morphogenetic contexts. The course maintains stock mRNAs for targeting fluorescent proteins to specific structures for studying cell shape and cytoskeletal dynamics but students are encouraged to bring or suggest additional tools, including fluorescent biosensors, tension-sensors, etc. The power of Xenopus can be leveraged when live-cell fluorescence imaging is combined with microsurgery, grafting, and dissociated cell culture. 

During the course, the students will analyze any phenotypes generated from CRISPR/Cas9 based gene depletion while learning the diverse array of techniques available in Xenopus. In previous courses, we have guided students in the ablation of a wide variety of genes and helped them design suitable assays for their biological interests. Most recently, students have targeted autism genes, thyroid genes and immune modulators, several of which have already led to publications. Approaches covered will include microinjection and molecular manipulations such as CRISPR/Cas9 knockouts, antisense morpholino-based depletions, transgenics, and mRNA overexpression. In addition, students can combine these techniques with explant and transplant methods to simplify or test tissue level interactions. Additional methods include mRNA in situ hybridization, hybridizationchain reaction (HCR), and protein immunohistochemistry as well as basic bioinformatic techniques for gene comparison and functional analysis. Genomicand Systems Biology approaches will be introduced, including single-cell technology.  Biochemical approaches such as proteomics and mass spectrometry and biomechanical concepts will also be discussed. Finally, to visualize subcellular and intercellular activities, we will introduce a variety of sample preparation and imaging methods including time-lapse, fluorescent imaging, optical coherence tomography and confocal microscopy. These are facilitated by state-of-the-art equipment from Nikon, Leica, Zeiss, BioVision Technologies, and Scientifica.

Due to the tailored nature of this course, it is suitable for those new to the Xenopus field, as well as for more advanced students who are interested in emerging technologies. Please feel free to contact the instructors for informal guidance.

2024 Lecturers:

Dominque Alfandari, University of Massachusetts Amherst, Amherst, MA
Engin Deniz, Yale School of Medicine, New Haven, CT
Matt Guille, University of Portsmouth, , United Kingdom
Marko Horb, NRX, MBL, 
Douglas Houston, University of Iowa, Iowa City, IA
Christina James Zorn, Xenbase, Cincinnati Children's Hospital Medical Center, Cincinnati, OH
Mustafa Khokha, Yale University, New Haven, CT
Jennifer Landino, Geisel School of Medicine at Dartmouth, Hanover, NH
Shuyi Nie, Georgia Tech University, Atlanta, GA
Hajime Ogino, Hiroshima University, Japan
Jakub Sedzinski, University of Copenhagen, Denmark
Kris Vleminckx, Ghent University, Belgium, Germany
Helen Willsey, University of California San Francisco, San Francisco, CA
John Young, Simmons University, Boston, MA
Natalya Zahn, Independent Creative, East Calais, VT 

10fps of Xenopus GRP cilia

10 frames per second imaging of Xenopus GRP cilia. GFP labeled cilia, RFP membrane marker. Courtesy of Melanie Tingler, Shiaulou Yuan, and Mustafa Khokha. Cold Spring Harbor Xenopus Course, Yale University. Movie generated on Bruker Opterra II confocal microscope.

125 fps blood flow

125 frames per second imaging of Xenopus red blood cells in gills. Playback at 5x slow motion. Video courtesy of Vaughn Colleluori and Mustafa Khokha, Cold Spring Harbor Xenopus Course,Yale University. Movie generated on Bruker Opterra II confocal microscope.


CLAMP GFP (green) marks tips of cilia and membrane RFP (red) marks cilia axoneme. Two color images collected at 20 fps. CSHL 2015 Xenopus course. Movie generated on Bruker Opterra II confocal microscope.

Support & Stipends:

Major support provided by the National Institute of Child Health and Human Development.

Stipends are available to offset tuition costs as follows-

Please indicate your eligibility for funding in your stipend request submitted when you apply to the course. Stipend requests do not affect selection decisions made by the instructors.


We would like to acknowledge the following companies that provided invaluable support:
Leica, Nikon, Zeiss, BioVision Technologies, and Molecular Devices
Lab Equipment and Software: Andor Technology, Electron Microscopy Sciences, Harvard Apparatus, Narishige Internation USA, Sutter Instrument Company, Thorlabs Inc.
Discounted Products: Xenopus 1
Donations: MolecularInstruments, Inc.

Cost (including board and lodging): $4,385 USD

No fees are due until you have completed the full application process and are accepted into the course. 

Before applying, ensure you have (all due by January 31, 2024):
  1. Personal statement/essay;
  2. Letter(s) of recommendation;
  3. Curriculum vitae/resume (optional);
  4. Financial aid request (optional).
    More details.

If you are not ready to fully apply but wish to express interest in applying, receive a reminder two weeks prior to the deadline, and tell us about your financial aid requirements, click below: