 |
|
The difference between fish and humans: scientists answer century-old developmental question
October 11, 2007Embryologists at UCL (University College London) have helped solve an evolutionary riddle that has been puzzling scientists for over a century. They have identified a key mechanism in the initial stages of an embryo's development that helps differentiate more highly evolved species, including humans, from less evolved species, such as fish. The findings of the research, funded by the Biotechnology and Biological Sciences Research Council (BBSRC), were published online today by the journal Nature.
Early on in development, the mass of undifferentiated cells that make up the embryo must take the first steps in deciding how to arrange themselves into component parts to eventually go on to form a fully developed body. This is a process known as 'gastrulation'. During this stage, the cells group into three layers, the first is the 'ectoderm' which then in turn generates the 'mesoderm' and 'endoderm' layers. In higher vertebrates, such as mammals and birds, the mesoderm and endoderm are generated from an axis running through the centre of the embryo. However, in lower vertebrates, such as amphibians and fish, the two layers are generated around the edge of the embryo.
Using chicken eggs and a state-of-the-art imaging device which can reveal how cells move in three dimensions, the researchers demonstrated a key difference in the way gastrulation occurs between higher vertebrate species and less evolutionarily advanced animals. They discovered that the reason why higher vertebrates form their axis at the midline of the embryo is because during evolution they acquired a new mechanism of "cell intercalation" which positions the axis at the midline. They also discovered the molecules used by the embryo to control these cell movements.
Scientists have been speculating for over a century on the difference between the embryonic development of higher vertebrates and lower vertebrates, to help answer how the simple cell structure of an embryo goes on to form the various highly complex bodies of different species. Research leader Prof Claudio Stern explains: "This is a significant find as it is a clear difference between the embryonic development of more advanced species and less advanced species. It suggests that higher vertebrates must have developed this mechanism later on in the history of animal evolution.
In humans this process occurs during week 3 of embryonic development, and forms the cut-off point for scientific research on human embryos in the UK.
Biotechnology and Biological Sciences Research Council
Scientists have been speculating for over a century on the difference between the embryonic development of higher vertebrates and lower vertebrates, to help answer how the simple cell structure of an embryo goes on to form the various highly complex bodies of different species. Research leader Prof Claudio Stern explains: "This is a significant find as it is a clear difference between the embryonic development of more advanced species and less advanced species. It suggests that higher vertebrates must have developed this mechanism later on in the history of animal evolution.
In humans this process occurs during week 3 of embryonic development, and forms the cut-off point for scientific research on human embryos in the UK.
Biotechnology and Biological Sciences Research Council
Embryonic Development Current Events and Embryonic Development News RSSMaking flies sick reveals new role for growth factors in immunity
A Salmonella infection is not a positive experience. However, by infecting the common laboratory fruit fly Drosophila melanogaster with a Salmonella strain known for causing humans intestinal grief, researchers in the School of Life Sciences at Arizona State University have shed light on some key cell regulatory processes - with broad implications for understanding embryonic development, immune function and congenital diseases in humans.
Scientists trace molecular origin of proportional development
When it comes to embryo formation in the lowly fruit fly, a little molecular messiness actually leads to enhanced developmental precision, according to a study in the Oct. 14 Developmental Cell from Cincinnati Children's Hospital Medical Center.
Forsyth scientists trigger cancer-like response from embryonic stem cells
Scientists from The Forsyth Institute, working with collaborators at Tufts and Tuebingen Universities, have discovered a new control over embryonic stem cells' behavior.
Digital zebrafish embryo provides the first complete developmental blueprint of a vertebrate
Researchers at the European Molecular Biology Laboratory (EMBL) have generated a digital zebrafish embryo - the first complete developmental blueprint of a vertebrate. With a newly developed microscope scientists could for the first time track all cells for the first 24 hours in the life of a zebrafish.
Rong Li Lab probes mechanism of asymmetry in meiotic cell division
The Stowers Institute's Rong Li Lab has characterized a mechanism that allows for asymmetrical cell division during meiosis in oocytes. By tracking chromosome movement in live mouse oocytes, the team discovered that chromosomes can recruit to their vicinity a protein called formin-2.
'Hub' of fear memory formation identified in brain cells
A protein required for the earliest steps in embryonic development also plays a key role in solidifying fear memories in the brains of adult animals, scientists have revealed. An apparent "hub" for changes in the connections between brain cells, beta-catenin could be a potential target for drugs to enhance or interfere with memory formation.
Scientists identify genes capable of regulating stem cell function
Scientists from The Forsyth Institute, Boston, MA, and the Howard Hughes Medical Institute at the University of Utah School of Medicine have developed a new system in which to study known mammalian adult stem cell disorders.
Gene is likely cause of stroke-inducing vascular malformations
UCSF scientists have discovered that a gene controlling whether blood vessels differentiate into arteries or veins during embryonic development is linked to a vascular disorder in the brain that causes stroke.
Joslin study identifies protein that produces 'good' fat
A study by researchers at the Joslin Diabetes Center has shown that a protein known for its role in inducing bone growth can also help promote the development of brown fat, a "good" fat that helps in the expenditure of energy and plays a role in fighting obesity.
Childhood brain tumor traced to normal stem cells gone bad
An aggressive childhood brain tumor known as medulloblastoma originates in normal brain "stem" cells that turn malignant when acted on by a known mutant, cancer-causing oncogene, say researchers from Dana-Farber Cancer Institute and the University of California, San Francisco (UCSF).
More Embryonic Development Current Events and Embryonic Development News Articles
| Time, space, and pattern in embryonic development (MBL lectures in biology) | |
 | Introduction to Embryonic Development (3rd Edition) by S. Oppenheimer, G. Lefevre |
 | Experimental Approaches to Mammalian Embryonic Development The editors present, in a single volume, a valuable reference source for students of mammalian embryology, genetics, and physiology, this book provides a thorough overview of the field of embryonic development--its current status along with possible directions in the... |
| Embryonic Development. Part A. Genetic Aspects. by Max M., & Rudolf WEBER (eds.). BURGER | |
| Embryo and embryonic development: An entry from Thomson Gale's Gale Encyclopedia of Science, 3rd ed. by Bryan H. Cobb The “Gale Encyclopedia of Science” is written at a level somewhere between the introductory sources and the highly technical texts currently available. This six-volume set covers all major areas of science and engineering, as well as mathematics and the medical and health sciences, while providing a comprehensive overview of current scientific knowledge and technology. Alphabetically arranged... | |
| Embryonic Development: Pts. A & B (Progress in Clinical & Biological Research) | |
| INTRO EMBRYONIC DEVELOPMENT by OPPENHEIMER | |
 | The Embryonic Development of Drosophila melanogaster by Jose A. Campos-Ortega, Volker Hartenstein, Campos-Orteg The Drosophila embryo is one of the best understood developmental systems. Since the publication of the first edition over ten years ago, a lot of new information has accumulated. This has been taken into account in the extensively revised second edition of this standard reference book. This second edition is comprehensive, and describes and illustrates the embryonic development of Drosophila... |
| The Intrinsic Embryonic Development by G. Ten Cate | |
| The Development and the Embryonic Anatomy of the Human Gastro-Intestinal Tract by N. Lauge-Hansen |
| © 2008 BrightSurf.com |