Baltimore, MD—A tremendous amount of genetic material must be packed into the nucleus of every cell—a tiny compartment. One of the biggest challenges in biology is to understand how certain regions...
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Baltimore, MD—Allan C. Spradling, Director Emeritus of Carnegie’s Department of Embryology, has been awarded the 23rd March of Dimes and Richard B. Johnson, Jr., MD Prize in Developmental Biology as...
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Carnegie Science, Carnegie Institution, Carnegie Institution for Science, Neta Schwartz
Washington, DC—Not too long ago, biologists would induce mutations in an entire genome, isolate an organism that displayed a resulting disease or abnormality that they wanted to study, and then work...
Explore this Story
Carnegie Science, Carnegie Institution, Carnegie Institution for Science,
Baltimore, MD— The brain is the body’s mission control center, sending messages to the other organs about how to respond to various external and internal stimuli. Located in the forebrain, the...
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Carnegie Science, Carnegie Institution, Carnegie Institution for Science,
Washington, D.C.--Yixian Zheng has been selected to direct Carnegie’s Department of Embryology in Baltimore, Maryland. She has been Acting Director since February 1st of 2016. Carnegie president...
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Washington, D.C.—BioEYES was accepted to participate in a National Science Foundation (NSF) video competition on May 15-22, 2017. BioEYES supporters are encouraged to go to the competition website at...
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On Tuesday night, George Church told us that a fascination with animatronic Abraham Lincoln at the 1964 World’s Fair partially inspired him to become a scientist. This seems fitting, somehow, since...
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Carnegie Science, Carnegie Institution, Carnegie Institution for Science
Baltimore, MD—Studying how our bodies metabolize lipids such as fatty acids, triglycerides, and cholesterol can teach us about cardiovascular disease, diabetes, and other health problems, as well as...
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Stem cells make headline news as potential treatments for a variety of diseases. But undertstanding the nuts and bolts of how they develop from an undifferentiated cell  that gives rise to cells that are specialized such as organs, or bones, and the nervous system, is not well understood.  The...
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The Fan laboratory studies the molecular mechanisms that govern mammalian development, using the mouse as a model. They use a combination of biochemical, molecular and genetic approaches to identify and characterize signaling molecules and pathways that control the development and maintenance of...
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The Spradling laboratory studies the biology of reproduction. By unknown means eggs reset the normally irreversible processes of differentiation and aging. The fruit fly Drosophila provides a favorable multicellular system for molecular genetic studies. The lab focuses on several aspects of egg...
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Integrity of hereditary material—the genome —is critical for species survival. Genomes need protection from agents that can cause mutations affecting DNA coding, regulatory functions, and duplication during cell division. DNA sequences called transposons, or jumping genes (discovered by Carnegie’s...
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The mouse is a traditional model organism for understanding physiological processes in humans. Chen-Ming Fan uses the mouse to study the underlying mechanisms involved in human development and genetic diseases. He concentrates on identifying and understanding the signals that direct the...
Meet this Scientist
Yixian Zheng, director of the Department of Embryology, serves as co-interim president of Carnegie as of January 1, 2018. Her lab has a long-standing interest in cell division. In recent years, their findings have broadened their research using animal models, to include the study of stem cells,...
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A tremendous amount of genetic material must be packed into the nucleus of every cell—a tiny compartment. One of the biggest challenges in biology is to understand how certain regions of this highly...
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Explore Carnegie Science

June 28, 2018

Baltimore, MD—A tremendous amount of genetic material must be packed into the nucleus of every cell—a tiny compartment. One of the biggest challenges in biology is to understand how certain regions of this highly packaged DNA can be called upon, so that the genes encoded in them can be “turned on,” or expressed and used to manufacture RNA and proteins.

New work published in Molecular Cell by a team of biologists from Carnegie, Soonchunhyang University, and Johns Hopkins University has shed light on this process and their findings have implications for certain age-related diseases and organ decay.

The nucleus, where a cell’s DNA is housed, is surrounded by two membrane

May 7, 2018

Baltimore, MD—Allan C. Spradling, Director Emeritus of Carnegie’s Department of Embryology, has been awarded the 23rd March of Dimes and Richard B. Johnson, Jr., MD Prize in Developmental Biology as “an outstanding scientist who has profoundly advanced the science that underlies our understanding of prenatal development and pregnancy.”

Department director and Carnegie co-interim president Yixian Zheng remarked, “Allan is a legend in developmental biology. We are all delighted by this well- deserved recognition of Allan’s groundbreaking research.”

Spradling’s decades of scientific accomplishments cover a broad spectrum of advancements. Since the early 20th century, the fruit

Carnegie Science, Carnegie Institution, Carnegie Institution for Science, Neta Schwartz
November 27, 2017

Washington, DC—Not too long ago, biologists would induce mutations in an entire genome, isolate an organism that displayed a resulting disease or abnormality that they wanted to study, and then work backward to determine which gene was responsible for the defect.  This process often took years to yield definitive results.

Now, thanks to the CRISPR/Cas9 genome-editing tool, biologists can target specific genes for mutation and then see how this induced mutation manifests in an organism—tackling the problem from the other direction. But they are finding that the expected physical changes don’t always occur.

Why?

New work from Carnegie’s Steven Farber and Jennifer

Carnegie Science, Carnegie Institution, Carnegie Institution for Science,
July 13, 2017

Baltimore, MD— The brain is the body’s mission control center, sending messages to the other organs about how to respond to various external and internal stimuli. Located in the forebrain, the habenular region is one such message-conducting system. Two new papers from Carnegie scientists explain how the habenulae develop and their unsuspected role in recovering from fear.

Found in all vertebrates, the bilaterally paired habenulae regulate the transmission of dopamine and serotonin, two important chemicals related to motor control, mood, and learning.

Previous research has shown that the habenular system is involved in modulating sleep cycles, anxiety, and pain and reward

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The thyroid gland secretes thyroxine (TH), a hormone essential for the growth and development of all vertebrates including humans. To understand TH action, the Donald Brown lab studies one of the most dramatic roles of the hormone, the control of amphibian metamorphosis—the process by which a tadpole turns into a frog. He studies the frog Xenopus laevis, from South Africa, because it is easy to rear. Events as different as the formation of limbs, the remodeling of organs, and the resorption of tadpole tissues such as the tail are all directed by TH. How can a simple molecule control so many different developmental changes? The hormone works by regulating the expression of groups of genes

The Fan laboratory studies the molecular mechanisms that govern mammalian development, using the mouse as a model. They use a combination of biochemical, molecular and genetic approaches to identify and characterize signaling molecules and pathways that control the development and maintenance of the musculoskeletal and hypothalamic systems.

The musculoskeletal system provides the mechanical support for our posture and movement. How it arises during embryogenesis pertains to the basic problem of embryonic induction. How the components of this system are repaired after injury and maintained throughout life is of biological and clinical significance. They study how this system is

In mammals, most lipids, such as fatty acids and cholesterol, are absorbed into the body via the small intestine. The complexity of the cells and fluids that inhabit this organ make it very difficult to study in a laboratory setting. The goal of the Farber lab is to better understand the cell and molecular biology of lipids within digestive organs by exploiting the many unique attributes of the clear zebrafish larva  to visualize lipid uptake and processing in real time.  Given their utmost necessity for proper cellular function, it is not surprising that defects in lipid metabolism underlie a number of human diseases, including obesity, diabetes, and atherosclerosis.

The Farber

The Spradling laboratory studies the biology of reproduction. By unknown means eggs reset the normally irreversible processes of differentiation and aging. The fruit fly Drosophila provides a favorable multicellular system for molecular genetic studies. The lab focuses on several aspects of egg development, called oogenesis, which promises to provide insight into the rejuvenation of the nucleus and surrounding cytoplasm. By studying ovarian stem cells, they are learning how cells maintain an undifferentiated state and how cell production is regulated by microenvironments known as niches. They are  also re-investigating the role of steroid and prostaglandin hormones in controlling the

Integrity of hereditary material—the genome —is critical for species survival. Genomes need protection from agents that can cause mutations affecting DNA coding, regulatory functions, and duplication during cell division. DNA sequences called transposons, or jumping genes (discovered by Carnegie’s Barbara McClintock,) can multiply and randomly jump around the genome and cause mutations. About half of the sequence of the human and mouse genomes is derived from these mobile elements.  RNA interference (RNAi, codiscovered by Carnegie’s Andy Fire) and related processes are central to transposon control, particularly in egg and sperm precursor cells.  

The Bortvin lab, with colleagues

Frederick Tan holds a unique position at Embryology in this era of high-throughput sequencing where determining DNA and RNA sequences has become one of the most powerful technologies in biology. DNA provides the basic code shared by all our cells to program our development. While there are about 30,000 human genes, 98% of DNA sequences are comprised of repetitive and regulatory sequences within and between genes. Measuring the specific set of DNA sequences that are transcribed into RNA helps reveal what and how our tissues are doing by showing which genes are active.

Modern sequencing platforms, such as the Illumina HiSeq 2000, generate only short, ordered sequences, usually 100

Allan Spradling is a Howard Hughes Medical Institute Investigator and director of the Department of Embryology. His laboratory studies the biology of reproduction particularly egg cells, which are able to reset the normally irreversible processes of differentiation and aging that govern all somatic cells—those that turn into non-reproductive tissues. Spradling uses the fruit fly Drosophila because the genes and processes studied are likely to be similar to those in other organisms including humans. In the 1980s he and his colleague, Gerald Rubin, showed how jumping genes could be used to identify and manipulate fruit fly genes. Their innovative technique helped establish Drosophila as

The first step in gene expression is the formation of an RNA copy of its DNA. This step, called transcription, takes place in the cell nucleus. Transcription requires an enzyme called RNA polymerase to catalyze the synthesis of the RNA from the DNA template. This, in addition to other processing factors, is needed before messenger RNA (mRNA) can be exported to the cytoplasm, the area surrounding the nucleus.

Although the biochemical details of transcription and RNA processing are known, relatively little is understood about their cellular organization. Joseph G. Gall has been an intellectual leader and has made seminal breakthroughs in our understanding of chromosomes, nuclei and