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Thursday, March 1, 2012

Jobs @ Multiple Openings in our PHP Department at iFlair Web Technologies Pvt. Ltd.Ahmedabad.

We have very new openings in our PHP Development Department.

Position:

Junior PHP Developer (Position 3) Experience: 6 month to 1.5 year
Senior PHP Developer (Position 3) Experience: 1.5 Year to 3 Years
PHP Team Leader with Good communication skills (Position 2) Experience: 3 Year to 5 Years

Desired Profile:

1. Good Experience in PHP/ MySql
2. Knowledge for AJAX/ Javascript/ Json/ Jquery
3. Strong Technical & Research Skills.
4. Knowledge of Open source [Wordpress, Joomla, Magento, Drupal,OsCommerce,Zencart] is added advantage

Pl. send your latest resume ASAP on php@iflair.com with following details.

Total Experience:
Current Company :
Experience in PHP:
Since how long you are with this company:
Designation:
Current On hand Salary:
Expected Salary:
Required Joining Period:

Also you can call on 9558803176 for your earliest interview schedule.

Company Profile: iFlair Web Technologies Pvt. Ltd. is the leading Custom Website Development and Open Source Development Company. We are 8 years old, 100% offshore Outsourcing company.
We have completed more than 500+ PHP projects with 45+ Employee strength. We work with Custom PHP Apps, Wordpress, Joomla, Magento, Drupal, OsCommerce, Zencart, Mobile Development etc..

Development Center: Nr. Parimal Under Bridge, Ahmedabad.

Have a good day!!!

Epigenetic culprit in Alzheimer's memory decline

In a mouse model of Alzheimer's disease, memory problems stem from an overactive enzyme that shuts off genes related to neuron communication, a new study says.
When researchers genetically blocked the enzyme, called , they 'reawakened' some of the and restored the animals' . The results, published February 29, 2012, in the journal Nature, suggest that drugs that inhibit this particular enzyme would make good treatments for some of the most devastating effects of the incurable neurodegenerative disease.
"It's going to be very important to develop selective chemical inhibitors against HDAC2," says investigator , whose team at the performed the experiments. "If we could delay the cognitive decline by a certain period of time, even six months or a year, that would be very significant."
In every cell, wraps itself around . Chemical groups such as can bind to histones and affect DNA expression. HDAC2 is a , an enzyme that removes acetyl groups from the histone, effectively turning off nearby genes.
In 2007, Tsai's group reported in Nature that this so-called can contribute to cognitive decline. They used a strain of mutant mice developed in her lab called , which shows a profound loss of neurons and , the junctions between neurons. The animals also carry the thought to cause Alzheimer's disease and show impaired learning and memory. When Tsai's team gave the mice drugs that block all HDACs, the animals sprouted more synapses and showed better memory function.
There are 19 known HDACs. In 2009, the researchers found that one of these, HDAC2, can cause a loss of synapses and memory function in normal mice.
The new study pulls from both of these previous findings, investigating HDAC2's affect on CK-p25 mice.
The researchers showed that the mutant animals have an elevated level of HDAC2 in two regions known to be affected in : the , important for learning and memory, and part of the called the . In these regions, the researchers also found that HDAC2 binds to a host of memory genes and dampens their expression.
Tsai's team then used a technique called to silence the expression of HDAC2 in neurons in the hippocampus. Four weeks later, they found a dramatic increase in . What's more, when given two different memory tests, the treated animals were indistinguishable from normal controls.
Blocking HDAC2 expression did not change the number of dying neurons. Still, the findings suggest that memory can be improved even in later stages of the disease, Tsai says.
"The neurons that are still alive are essentially zombies: they're not really functioning properly because of the epigenetic blockade," Tsai says. "What we're showing is that, if we can get some of those neurons to wake up, we can get cognitive function to recover to a certain extent."
Using hippocampal neurons grown in culture, Tsai also uncovered a potential mechanism that raises the level of HDAC2 in the first place. She showed that and —both risk factors for Alzheimer's disease—can activate a protein called the . This receptor, in turn, can switch on the runaway expression of HDAC2.
"The striking thing is that amyloid beta has a very, very acute effect in elevating HDAC2 expression, but then the consequences can be very long term," Tsai says. This mechanism could explain why of drugs that clear out amyloid beta in people with Alzheimer's haven't worked very well, she says.
Finally, Tsai's team looked at from people who died of Alzheimer's disease. These samples, like those in mice, had elevated levels of HDAC2 in the hippocampus and entorhinal cortex.

The clinical applications of this work are promising, Tsai says, but it's important not to oversell the findings. "While all the data look very promising in , human studies are a completely different ball game," she says. "We need to do clinical trials to see whether this concept holds up."

More information: Graff J et al. "An epigenetic blockade of cognitive functions in the neurodegenerating brain." Nature, February 29, 2012.
Provided by Howard Hughes Medical Institute

"Epigenetic culprit in Alzheimer's memory decline." February 29th, 2012. http://medicalxpress.com/news/2012-02-epigenetic-culprit-memory-decline.html
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In what ways does lead damage the brain?

Exposure to lead wreaks havoc in the brain, with consequences that include lower IQ and reduced potential for learning. But the precise mechanism by which lead alters nerve cells in the brain has largely remained unknown.
New research led by Tomás R. Guilarte, PhD, Leon Hess Professor and Chair of Environmental Health Sciences at Columbia University Mailman School of Public Health, and post-doctoral research scientist Kirstie H. Stansfield, PhD, used high-powered fluorescent microscopy and other advanced techniques to painstakingly chart the varied ways lead inflicts its damage. They focused on signaling pathways involved in the production of brain-derived neurotropic factor, or BDNF, a chemical critical to the creation of new synapses in the hippocampus, the brain's center for memory and learning.
The study appears online in the journal Toxicological Sciences.
Once BDNF is produced in the nucleus, explains Dr. Stansfield, it is transported as cargo in a railroad-car-like vesicle along a track called a microtubule toward sites of release in the axon and dendritic spines. Vesicle navigation is controlled in part through activation (phosphorylation) of the huntingtin protein, which as its name suggests, was first identified through research into Huntington's disease. By looking at huntingtin expression, the researchers found that lead exposure, even in small amounts, is likely to impede or reverse the train by altering phosphorylation at a specific amino acid.
The BDNF vesicle transport slowdown is just one of a variety of ways that lead impedes BDNF's function. The researchers also explored how lead curbs production of BDNF in the cell nucleus. One factor, they say, may be a protein called methyl CpG binding protein 2, or MeCP2, which has been linked with RETT syndrome and autism spectrum disorders and acts to "silence" BDNF gene transcription.
The paper provides the first comprehensive working model of the ways by which lead exposure impairs synapse development and function. "Lead attacks the most fundamental aspect of the brain—the synapse. But by better understanding the numerous and complex ways this happens we will be better able to develop therapies that ameliorate the damage," says Dr. Guilarte.
Provided by Columbia University

"In what ways does lead damage the brain?." February 29th, 2012. http://medicalxpress.com/news/2012-02-ways-brain.html

Posted by
Robert Karl Stonjek