Honors & News
March 5, 2014
Grayson Sipe Awarded Individual Pre-doctoral Fellowship from NINDS
Grayson Sipe, 4th year Neuroscience Graduate Program student in Dr. Ania Majewska's lab was awarded NIH (NRSA) Individual Pre-doctoral Fellowship from NINDS. The title of his project is:
Role of P2Y12 and Purinergic Signaling in Microglia-Mediated Synaptic Plasticity(2013-2016). Congrats Grayson!
May 17, 2013
W. Spencer Klubben Wins Walt and Bobbi Makous Prize
The second recipient of the Walt and Bobbi Makous Prize has been awarded to: W. Spencer Klubben, a Biomedical Engineering senior working in Ania Majewska's laboratory. As a biomedical engineer, Spencer concentrated in medical optics and developed a strong interest in visual perception and development. Spencer's work has primarily focused on quantifying microglia's effect on neuroplasticity within the visual cortex and visual system. Most experimental methods have been focused around the utilization of optical imaging to analyze neuronal activity within mouse cortex. Experiments were conducted on mice with a varying dosage of CX3CR1, a single allele genetic fractalkine receptor responsible for the mobility of microglia. Spencer will receive the Makous Prize at a College-wide award ceremony on Saturday, May 19.
The Walt and Bobbi Makous Prize was established this year by the Center for Visual Science, a research program of more than 30 faculty at the University dedicated to understanding how the human eye and brain allow us to see. The prize is named for Walt Makous, who was Director of the Center for Visual Science at the University of Rochester throughout the 1980s, and his wife Bobbi. The prize honors the graduating senior who has made the most outstanding contribution to vision research at Rochester.
January 14, 2011
Structure of a Synapse
New research from the Majewska Lab at University of Rochester Medical Center is revealing even more reasons to stand up and applaud the microglia. It turns out that microglia serve more than immune functions. They are essential to learning and memory. This research suggests that a lot of what is going on in that synaptic gap is engineered by the microglia.
The research team, led by Ania Majewska, Ph.D., Assistant Professor in the department of Neurobiology & Anatomy, used two imaging techniques to study the microglia in the animals' brains during these various stages. When the lights were off, microglia contacted more synapses, were more likely to reach toward a particular type of synapse, tended to be larger, and were more likely to destroy a synapse. When the lights came back on, most of those activities reversed.
The finding that activity among microglia changed in response to visual inputs was, in itself, surprising.
Just the fact that microglia can sense that something has changed in the environment is a novel idea,says Majewska.
November 10, 2010
The Majewska Lab's current research on learning and memory has been featured in the current issue of Nature Highlights. The research details immune cells called microglia help to protect the brain after an injury. They may also be involved in pruning the connections, or synapses, between neurons — a key process in learning and memory formation.
Using electron microscopy, Marie-Ève Tremblay, Rebecca Lowery and Ania Majewska at the University of Rochester in New York imaged mouse brain slices and reconstructed the interactions between microglia and synapses in three dimensions. Most of the microglia were directly adjacent to the synapses, and in particular to dendritic spines — neuronal structures — that were small and were often pruned away later on.
November 2, 2010
Immune cells known as microglia, long thought to be activated in the brain only when fighting infection or injury, are constantly active and likely play a central role in one of the most basic, central phenomena in the brain – the creation and elimination of synapses.
The finding, reported in the Nov. 2 issue of PloS Biology, catapults the humble microglia cell from its well-recognized duty of protecting the brain to direct involvement in creating the cellular networks at the core of brain behavior.
When scientists talk about microglia, the talk is almost always about disease. Our work suggests that microglia may actively contribute to learning and memory in the healthy brain, which is something that no one expected,said Ania Majewska, Ph.D., assistant professor in the Department of Neurobiology & Anatomy who led the work.
The group's paper, co-authored by post-doctoral associate, Marie-Ève Tremblay, Ph.D., is a remarkably detailed look at how brain cells interact with each other and react to their environment swiftly, reaching out constantly to form new links or abolish connections.
June 17, 2010
Earlier this month, the Center for Visual Science (CVS) held its 27th symposium. The theme of this year's symposium was
Photons and Neuronsand it brought together scientists who develop and use optical imaging methods from all over the world.
Optical imaging promises to revolutionize neuroscience by offering minimally-invasive, direct recording of neural activity at single cell resolution in the intact working brain. Optical imaging of neural activity, however, has yet to deliver the ultimate prize of recording the activity of many individual neurons in real time throughout the depth of a brain structure such as the cerebral cortex. Achieving such a goal will require the coordinated effort of experts from disparate backgrounds, including neuroscientists, optical engineers, biochemists and molecular biologists.
The symposium brought together this diverse group of scientists and provided a platform for discussion of the latest developments in optical imaging of neuronal function. Discussions were long and lively and allowed the exchange of ideas, identification of pressing neurobiological questions, discussion of current limitations, and developing of ideas for possible solutions. The symposium was supported by the National Eye Institute (R13EY020691) and the Center for Visual Science, and was co-organized by David Williams, Ania Majewska and Tony Movshon (NYU).
November 1, 2008
Ania Majewska, Ph.D. named a Kavli Fellow
Congratulations to Ania Majewska, Ph.D. on being named a Kavli Fellow by the National Academy of Sciences (NAS). Each year the NAS conducts the Kavli Frontiers of Science Symposium with some 100 of the best and brightest of young American scientists attending to hear, discuss, and debate talks across a wide range of the natural sciences. Thus, many of the country's ablest scientists--those now rising to positions of leadership in their institutions and their professions--have gone through a
seminaron the value and potential of interdisciplinary research. Attendees are selected from a pool of young researchers who have made significant contributions to science.
August 3, 2007
This summer the University of Rochester Medical Center boasts winners of two of the most prestigious awards available to young scientists - and the winners are from the same family.
Edward Brown, Ph.D., has been named a Pew Scholar in the Biomedical Sciences, and his spouse Ania Majewska, Ph.D., has received an award from the Alfred P. Sloan Foundation. Brown, one of just 20 scientists in the nation to be recognized by the Pew Charitable Trusts this year, will receive $240,000 toward his research, while Majewska will receive $45,000 to continue her work.
October 11, 2006
A couple of weeks ago, Gary Paige, M.D., Ph.D., Chair of the Department of Neurobiology & Anatomy, was informed that Ania Majewska, Ph.D., an Assistant Professor who had recently joined the department, had won the Cajal Club Explorer Award. Receiving such a prestigious award is a cause for recognition and celebration. What make's this all the more special, however, is Ania's personal and professional story.
- Subcellular localization of intercellular adhesion molecule-5 (telencephalin) in the visual cortex is not developmentally regulated in the absence of matrix metalloproteinase-9. J Comp Neurol. 522, 676-88. (2014 Feb 15).
- The effects of postnatal exposure to low-dose bisphenol-A on activity-dependent plasticity in the mouse sensory cortex. Front Neuroanat. 8, 117. (2014 Jan 01).