Welcome to The Visible Embryo, a comprehensive educational resource on human development from conception to birth.

The Visible Embryo provides visual references for changes in fetal development throughout pregnancy and can be navigated via fetal development or maternal changes.

The National Institutes of Child Health and Human Development awarded Phase I and Phase II Small Business Innovative Research Grants to develop The Visible Embryo in 1993 as a first generation internet teaching tool consolidating human embryology teaching for first year medical students.

Today, The Visible Embryo is linked to over 600 educational institutions and is viewed by more than 1 million visitors each month. The field of early embryology has grown to include the identification of the stem cell as not only critical to organogenesis in the embryo, but equally critical to organ function and repair in the adult human.

The identification and understanding of genetic malfunction, inflammatory responses, and the progression in chronic disease, begins with a grounding in primary cellular and systemic functions manifested in the study of the early embryo.

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The World Health Organization (WHO) has created a new Web site to help researchers, doctors and patients obtain reliable information on high-quality clinical trials. Now you can go to one website and search all registers to identify clinical trial research underway around the world!

A New View of How Transcription is Initiated

Using cryo-electron microscopy, researchers watched the molecular details of how proteins enter into a pre-initiation complex with one another before transcribing DNA into RNA

The human genome is contained within a vast jumble of DNA.

Its 20,000 or so genes are concealed within strings of
As, Ts,Gs, and Cs, and each gene must be turned on
at the right time and in the right cells.

For the first time, scientists have glimpsed the cellular
machinery that accomplishes this feat, as it assembles
directly on the DNA and readies it for transcription into RNA,
the first step in protein production.

“We’ve described the assembly of the machinery that allows the human genome to be read one gene at a time. This molecular step is critical is transforming DNA ultimately into the protein repertoire that carries out all the functions of a cell,” says Eva Nogales, the Howard Hughes Medical Institute investigator who led the research. Nogales and her team published their work online in the journal Nature on February 27, 2013.

The enzyme that carries out transcription, RNA polymerase II, is very efficient at copying the information encoded in DNA into an RNA molecule. “But the polymerase is completely incapable of detecting the beginning of a gene,” says Nogales, whose lab is at the University of California, Berkeley. Likewise, the polymerase cannot do its work until the two strands of the DNA double helix have been separated to reveal their sequence. To accomplish these tasks, a bulky complex of proteins called the pre-initiation complex is assembled each time transcription begins. Together, the proteins in the pre-initiation complex find a gene’s start site, prepare the DNA, and set the polymerase on its way.

“This machinery has to find the beginning of the gene in the huge ocean of DNA that makes up the genome,” explains Nogales. Once there, it opens the double helix and positions the polymerase in exactly the right place, ensuring that transcription begins with the correct letter in the DNA code.

Researchers knew that it takes a core complex of at least six different factors—TATA-binding protein (TBP), TFIIA, TFIIB, TFIIE, TFIIF, and TFIIH—to initiate transcription of human genes. Based on biochemical experiments, they knew the order in which these transcription factors arrived at the start site and joined the complex, and they had an idea of each one’s contributions to transcription initiation. But no one had actually visualized the molecules in action, so the molecular details of how they functioned remained unknown.

The main obstacle to visualizing the pre-initiation complex, Nogales says, was obtaining enough of each of its components for structural studies. Several of the components in the complex are not amenable to the techniques scientists often rely on to produce large quantities of the protein in the lab. Instead, Nogales and her colleagues isolate those proteins directly from human cells. Because the transcription factors are not abundant inside cells, the quantities that can be purified are small. “Things like x-ray crystallography and NMR”—common techniques for structural studies that require large amounts of protein—“were completely out of the question,” Nogales says. “That’s why very few structures of any of these intermediates have been obtained.”

Instead, they turned to a technique called cryo-electron microscopy (cryo-EM), in which samples are flash frozen and then viewed through an electron microscope. Because the proteins do not have to be crystallized, researchers see them in their native state. Further, Nogales explains, “we need very little volume at very low concentrations to do cryo-EM.”

Nogales and her team wanted to watch as the pre-initiation complex assembled at a gene’s start site, so they created a series of cryo-EM snapshots. In a test tube, they allowed a minimal form of the complex to self assemble on a strand of DNA: a cluster including TBP, TFIIA, TFIIB, and the RNA polymerase II. They froze the complex in this state and captured images to generate a 3D structure. All the pieces in this simple form of the complex were known, so Nogales says this allowed them to confirm that their technique was consistent with previous crystallographic images. They then added TFIIF, TFIIE, and TFIIH one by one, capturing three more snapshots.

“This initial engagement sets things in the right position, so that when TFIIH pushes on the DNA, it will be moved into the right place,” Nogales explains. It also reveals how the same factor ensures that the double helix will unwind and separate at the right place, where part of TFIIF physically inserts itself between the strands to prevent them from coming back together.

Nogales: “We have seen the molecular details of how all the proteins come together and interact with each other and with the DNA, thus gaining insight into how the cell determines at which point of the DNA to start transcribing into RNA, and actually how the DNA is opened and inserted into the active site in the polymerase. But this complex is really only the beginning of the story.”

“If we want to get at what is different between one gene and another, we have to start building up even larger complexes,” she says. So far, her team has recreated the formation of the most fundamental portion of the pre-initiation complex—the part that assembles every time any human gene is transcribed. But in living cells, these proteins never act alone. The next step, Nogales says, will be to begin to add in the factors that allow the transcription machinery to recognize genes in a regulated fashion. “As genomes get bigger, their regulatory systems get more complex,” Nogales says.

That complexity, she believes, enables cells to fine tune gene expression—and understanding it is essential for understanding the complexity arising from the human genome.

Original article: http://www.hhmi.org/news/nogales20130227.html