The Whitman Center Fellows will be supported for up to 10 weeks to pursue research, particularly within these fields of strategic vision for MBL:
- Evolutionary, genetic, and genomic approaches in regenerative biology, developmental biology, and neuroscience, with an emphasis on novel marine organisms
- Integrated imaging and computational approaches to illuminate cellular function and biology
- Integrated approaches to the study of microbial communities in coastal environments
“This year’s Whitman Fellows bring a wealth of scientific talent to the MBL’s convening environment, which is dedicated to offering scientists the space, time, inspiration, and support to intensively pursue research of fundamental importance,” said David Mark Welch, Director of the MBL Division of Research.
The MBL provides access to state-of-the-art instrumentation, innovative imaging technology and research, genome sequencing, model marine and freshwater organisms, and modern laboratory facilities. It also offers an exceptionally dynamic, interactive, and creative scientific environment. In addition to its resident research programs, the MBL annually convenes hundreds of principal investigators, postdocs, graduate students, and research associates from around the world to participate in Whitman Center research, scientific discovery courses, lectures, and field studies.
Several of the 2019 Whitman Fellows are coming to the MBL for the first time to launch a new project, while others will continue research programs they established in the Whitman Center in prior years. Many of the organisms the fellows are studying at MBL are pictured on this page (captions below). The fellows are:
Whitman Center Early Career Fellows
Amy Herbert, Stanford University
Sea robins as a model for the genetic basis of novel traits in vertebrates
Hooi Lynn Kee, Stetson University
Investigating the microbial rainbow of iridescent marine bacteria
Matthew McCoy, Stanford University
The role of gene complexity in generating neuronal diversity within cephalopod nervous systems
Rachel Miller, The University of Texas Medical School at Houston
Strategies to advance the study of kidney development in Xenopus
Sy Redding, University of California, San Francisco
Is protein aggregation important biology? Measuring the dynamic properties of protein assemblies on DNA and chromatin
Stefanie Redemann, University of Virginia
Studying spindle mechanics by light microscopy, electron tomography, biophysical modeling and simulation
Shashank Shekhar, Brandeis University
Unraveling the physical origins of multicellularity using a novel model organism
Oleg Simakov, University of Vienna, Austria
Are there gene regulatory networks that are specific for cephalopod novelties?
Victoria Sleight, University of Cambridge, UK
Molluscan biomineralization: development, repair and evolution
Trevor Wardill, University of Minnesota
Predictive control of eye movements and strike accuracy in the cuttlefish brain
Shigeki Watanabe, Johns Hopkins University
Molecular mechanisms of synaptic transmission in zebrafish photoreceptors
Elizabeth Wilbanks, University of California, Santa Barbara
Microbiomes from genotype to phenotype: Assessing the effect of strain-level bacterial diversification on cryptic sulfur cycling in the pink berry microbial consortia
Christina Zakas, New York University
Establishing transgenic lines in Streblospio benedicti, a new model for evolutionary developmental biology
Whitman Center Fellows
Tobias Baskin, University of Massachusetts Amherst
Role of microtubules in controlling cellulose organization in plant cells
Lionel Christiaen, New York University
Novel functional genomics tools for the chordate model Ciona
Karen Crawford, St. Mary's College of Maryland
Optimizing genome editing methods for Doryteuthis peallii: Building upon the successful generation of the first CRISPR-Cas9 gene knock outs from summer 2018
André Fenton, New York University
Starting to integrate across levels of biology to understand how silencing a gene causes intellectual disability and autism
Ben Evans, McMaster University, Canada
Developmental systems drift of sex determination in African clawed frogs (Xenopus)
Uri Gat, Hebrew University in Jerusalem, Israel
A comparative study between two highly regenerative aquatic model animals: The function of Cthrc genes in the regeneration programs of the salamander Axolotl and the sea anemone Nematostella
Edgar Gomes, Instituto Medicina Molecular, Portugal
Moving the cell nucleus in migrating cells
Jeffrey Gross, University of Pittsburgh School of Medicine
Regeneration of the zebrafish retinal pigment epithelium
Phillippe Laissue, University of Essex, UK
Developing models for integral studies of coral bleaching and recovery
Paul Maddox, University of North Carolina, Chapel Hill
LITE imaging of cell division
Isa Schön, Royal Belgian Institute of Natural Sciences, Belgium
Developing ostracods as emerging aquatic model organisms for evolutionary and biodiversity research
Ava Udvadia, University of Wisconsin, Milwaukee
Elucidating evolutionarily conserved mechanisms regulating successful optic nerve regeneration in vertebrate species
Denisa Wagner, Boston Children’s Hospital
Delineation of the role of the NLRP3 inflammasome in NETosis by time-lapse microscopy
Rafael Yuste, Columbia University
HydraLab 2019: Experimental and Computational Methods for Neural Circuit Analysis
Among the organisms that the 2019 Whitman Fellows are studying are, from top: Coral (Astrangia poculata) (Credit: Phillipe Laissue); Sea squirt (Ciona intestinalis) (MBL Logan Science Journalism Program); Squid (Doryteuthis pealeii) (Wang Chi Lau, MBL Embryology Course); Starlet sea anemone (Nematostella vectensis) (John Finnerty); Axolotl (Ambystoma mexicanum) (Dee Sullivan); Zebrafish (Danio rerio) (IMP Vienna); Sea robin (Triglidae) (Doug McFarlane); African clawed frog (Xenopus laevis) (National Xenopus Resource); (left to right) Seed shrimp (Ostracoda) (Anna Syme); Cuttlefish (Sepia bandensis) (Tom Kleindinst); Pink berry microbial consortia (Elizabeth Wilbanks); Bar-gilled mud worm (Streblospio benedicti) (E. Lazo-Wasem); Tobacco plant (Nicotiana tabacum) (Jon Sullivan); Hydra (Stefan Seibert); Iridescent marine bacteria (Sarah Lawhun); Slipper limpet (Crepidula fornicata) (E. Lazo-Wasem).
Homepage photo: Amy Herbert of Stanford University observing sea robin development. Credit: Matt McCoy. (Herbert and McCoy were Grass Fellows at MBL in 2018 and are among this year's Whitman Early Career Fellows).
A trap of Culex pipiens mosquitoes from France, provided by EID (Entente Interdépartementale Démoustication) in Montpellier, France. Credit: Julie Reveillaud
WOODS HOLE, Mass. -- Controlling mosquito-borne illnesses, such as Dengue or West Nile virus, has historically been difficult due to a lack of effective vaccines and concerns about the environmental impact of insecticides. Thus, scientists have turned to manipulating Wolbachia, a parasitic bacterium within mosquitoes, as a way to control the reproductive fitness of mosquito populations that transmit human disease.
In a new study in Nature Communications, an international team including scientists from the Marine Biological Laboratory (MBL) and the University of Chicago identified a new mobile DNA element in Wolbachia, which may contribute to improved control strategies for mosquito vectors of disease.
Led by former MBL scientists Julie Reveillaud of INRA, France, and Sarah Bordenstein of Vanderbilt University, the researchers reconstructed near-complete genomes of Wolbachia isolated from individual ovaries of four Culex pipiens mosquitoes. In the process, they identified a novel plasmid — a circular piece of DNA that can replicate independently of the chromosomes. Because a plasmid is a mobile DNA element, it can transfer from one cell to another and can have great implications for the fitness and evolution of a microbial species. Mobile genetic elements that can spread through different Wolbachia cells, and thus across a Wolbachia population, hold promise for controlling mosquito populations that may carry disease.
“Our data show that this novel plasmid is widespread across natural Wolbachia populations that infect C. pipiens mosquitoes throughout the world, which implies it has an essential role. The idea that it may enable transformation of the Wolbachia populations is simply very exciting,” says the senior author of the study, A. Murat Eren (Meren), an assistant professor of medicine at the University of Chicago and an MBL Fellow.
Wolbachia is transmitted from mother to offspring and can influence the reproductive behavior of its mosquito host. Wolbachia can modify sperm so if an infected male mates with an uninfected female, or with one that carries a different strain of Wolbachia, embryos cannot develop. The mechanism behind this embryonic killing lies within another mobile genetic element in the Wolbachia genome.
“Wolbachia populations do not lend themselves to direct genetic modification. While a natural plasmid sounds very promising to bypass those limitations, we do not yet have any evidence to suggest the possibility or efficacy of any transformation through this plasmid,” Meren says. ”We just discovered its existence, and the time will tell how useful it is.”
“Other exciting questions for which we do not have yet clear answers include whether there is an ancestral relationship between the plasmid and other mobile genetic elements of Wolbachia, and whether these interact or not,” adds Reveillaud.
The Wolbachia bacterium (colorized purple). Credit: Dennis Kunkel, Sarah Bordenstein and Robert Brucker
This collaboration began at MBL in 2011, when Meren and Reveillaud brought their computational and molecular evolution backgrounds together to explore questions in microbial ecology in the MBL's Bay Paul Center. (See Reveillaud’s blog post about the collaboration.) Years later, they began examining Wolbachia genomic diversity by focusing on individual mosquitoes captured in the wild, rather than using laboratory mosquito strains. With the help of former MBL scientists Sarah Bordenstein and Seth Bordenstein of Vanderbilt University, who have expertise in Wolbachia, they began unraveling the intricacies of the Wolbachia genome.
“Wolbachia is particularly difficult to study because, unlike free-living bacteria, it cannot be cultured in cell-free media. Through this interdisciplinary collaboration, we were able to tease apart the genomes of the mosquito host, Wolbachia, and its mobile elements,” says Sarah Bordenstein.
While fragments of this novel plasmid had appeared in previous Wolbachia sequencing studies, these fragments had never been assembled into a complete circular piece and its extrachromosomal nature was not recognized, most likely due to computational limitations. The team was able to overcome these limitations by employing a combination of cutting-edge strategies, such as genome-resolved metagenomics and long-read sequencing.
“The key bioinformatics platform that enabled us to study mosquito metagenomes and Wolbachia pangenomes in this study, and the connections between scientists with distinct skills that made this discovery possible, were developed at the MBL,” Meren says. “Almost everyone in this paper is somehow linked to the MBL.”
Written by Jennifer Tsang
Homepage photo: Surface sterilizing a Culex pipiens mosquito sample before dissection. Credit: Julie Reveillaud
Citation:
Reveillaud, Julie and Bordenstein, Sarah et al (2019) The Wolbachia mobilome in Culex pipiens includes a putative plasmid. Nature Communications, DOI: 10.1038/s41467-019-08973-w
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The Marine Biological Laboratory (MBL) is dedicated to scientific discovery – exploring fundamental biology, understanding marine biodiversity and the environment, and informing the human condition through research and education. Founded in Woods Hole, Massachusetts in 1888, the MBL is a private, nonprofit institution and an affiliate of the University of Chicago.
A female Brachionus manjavacas rotifer, carrying four large eggs. The hair-like cilia at the top are used for swimming and filter feeding, while the tail-like “foot,” ending in two small toes, is used for defense and attachment. Photo credit: Michael Shribak and Kristin Gribble
WOODS HOLE, Mass. – Advanced maternal age at the time of giving birth is known to decrease how long the offspring will live and their fecundity. However, why this occurs is unknown, and it remains unclear if maternal age also alters how offspring respond to interventions to aging.
Researchers at the Marine Biological Laboratory (MBL) are working on answers. In a study published in Scientific Reports, they demonstrate that maternal age affects how well offspring respond to dietary interventions that are known to increase lifespan.
“There has been evidence for well over a century, from experiments done in a wide variety of animal species and from data in humans, that offspring from older mothers have shorter lifespans and lower [rates of] reproduction,” says MBL scientist Kristin Gribble. “But it wasn’t well understood how a mother’s age might affect other aspects of her offspring’s health or response to interventions.”
Using rotifers (microscopic, water-dwelling animals), Gribble and her team studied the effects of maternal age on offspring aging and their response to dietary changes. In their experiments, they fed mother rotifers a regular diet. They then studied the offspring from young (about three days old), middle-aged, and advanced-aged (about nine days old) mothers. The offspring were fed one of three different diets: constant high food, constant low food, or alternating between high food and fasting every other day.
“These calorie-restricted and intermittent-fasting diets are known to significantly increase lifespan in rotifers and many other species,” says Gribble.
“Our study confirmed that offspring from older mothers have shorter lifespans and lower reproductive rates than offspring of younger mothers,” Gribble says. “However, offspring of older mothers, we found, have a greater increase in lifespan in response to caloric restriction than do young-mother offspring.”
In the offspring born from older mothers, the decreased lifespan seemed to be due to an earlier onset of aging. This early onset was delayed when those offspring were subject to caloric restriction.
Even though offspring from older mothers responded more positively to caloric restriction, it did not improve their overall fitness. In evolutionary terms, “fitness” takes into consideration both lifespan and rates of reproduction. For old-mother offspring on caloric restriction or full food diets, the window for reproduction was shortened and they had half as many offspring – only 14-15, instead of the average of 25 to 30 for young-mother offspring. Caloric restriction did not rescue reproduction.
“It is an important finding that a mother’s age can affect not only her offspring’s lifespan and reproduction, but also other aspects of her offspring’s health, body size, and responses to environmental conditions,” says Gribble. “This could have implications for how drugs, diet, exercise, or other interventions might differently affect children from young mothers and from older mothers.”
In their next steps, Gribble and her lab will probe the molecular mechanisms controlling maternal age effects in rotifers. Given that rotifers and humans share many genes, they think their findings may have implications for human health, and may be used to develop therapies to treat human aging.
“Rotifers are quite different than people, of course. But there are already many studies in humans that suggest that advanced maternal age negatively impacts children’s lifespans, and increases the chance for neurodegenerative and other diseases,” says Gribble. “I think it is likely that maternal age may also determine the response to environmental conditions, lifestyle, and medical treatments in people. A lot more work will need to be done to determine if our findings hold in people and if they are caused by similar molecular mechanisms.”
Written by Stephanie McPherson
Homepage photo: A female Brachionus manjavacas rotifer, carrying four large eggs. Credit: Michael Shribak and Kristin Gribble
Citation: Brock, Martha J. et al (2019) Maternal age alters offspring lifespan, fitness, and lifespan extension under caloric restriction. Scientific Reports, DOI: 10.1038/s41598-019-40011-z
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The Marine Biological Laboratory (MBL) is dedicated to scientific discovery – exploring fundamental biology, understanding marine biodiversity and the environment, and informing the human condition through research and education. Founded in Woods Hole, Massachusetts in 1888, the MBL is a private, nonprofit institution and an affiliate of the University of Chicago.
The MBL offers immersive courses, workshops, and conferences year-round. Central to the MBL’s identity are its advanced, discovery-based courses for graduate students, postdoctoral fellows, and faculty. READ MORE >
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The MBL’s convening power attracts the world’s most accomplished scientists to Woods Hole to carry out some of their most creative and far-reaching work. READ MORE >
The Marine Biological Laboratory (MBL) is dedicated to scientific discovery – exploring fundamental biology, understanding biodiversity and the environment, and informing the human condition through research and education. Founded in Woods Hole, Massachusetts in 1888, the MBL is a private, nonprofit institution and an affiliate of the University of Chicago.