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High-risk neuroblastoma is an aggressive childhood cancer with poor treatment outcomes. Despite intensive chemotherapy and radiotherapy, less than 50 percent of these children survive for five years. While the genetics of human neuroblastoma have been extensively studied, actionable therapeutics are limited.

Now researchers in the Feng lab at Boston University School of Medicine (BUSM), in collaboration with scientists in the Simon lab at the Perelman School of Medicine at the University of Pennsylvania (Penn), have not only discovered why this cancer is so aggressive but also reveal a promising therapeutic approach to treat these patients. These findings appear online in the journal Cancer Research, a journal of the American Association for Cancer Research.

“Our work pinpoints a targeted therapy for treating this group of at-risk patients, likely leading to improved survival,” said corresponding author Hui Feng, MD, PhD, associate professor of pharmacology and medicine at BUSM.

The artist’s remains are reportedly buried in France’s Chateau d’Amboise. Now, scientists may finally be about to identify them.

😀 This could to more complex organisms being resurrected.

Deep in the tissues of sea anemones, corals, and jellyfish are strange yellow cells which are genetically distinct from the marine animals.

More than a century after these cells were first assigned a now forgotten genus, a new paper has resurrected the name and described six new species from around the world.

Continue reading “After 140 Years, Biologists Have ‘Resurrected’ The Genus of These Weird Yellow Cells” »

Most biological traits are inherited via genes, but there are exceptions to this rule. Two teams from the University of Geneva (UNIGE) have been investigating the location of centromeres—specific sites on chromosomes that are essential for cell division. They found that in the small worm Caenorhabiditis elegans, the transmission of the correct location of these sites to the offspring is not mediated by genes, but by an epigenetic memory mechanism. These results have been published in the journal PLOS Biology.

Living organisms, from humans to microscopic worms, inherit physical and sometimes behavioral traits from their parents. The transmission of biological traits is usually mediated by DNA which is replicated at each cell division and contains the genes. However, some characteristics can be transmitted from one generation to the next independently of genes: these are epigenetic phenomena.

The researchers also showed that they could restore normal cognitive function in mice with these genetic mutations by artificially turning down hyperactivity in neurons of the AD thalamus. The approach they used, chemogenetics, is not yet approved for use in humans. However, it may be possible to target this circuit in other ways, the researchers say.

Summary: Certain genes that are mutated or missing in those with schizophrenia and autism cause similar dysfunction in neural networks within the thalamus.

Source: MIT

Continue reading “Common Mechanism Underlies Some Behavioral Traits Seen in Autism and Schizophrenia” »

Researchers have finally sequenced the complete human genome, filling the gaps in the Human Genome Project’s (HGP) historic first draft.

“Having been part of the original Human Genome Project in 2001, and especially focused on the difficult regions, it’s really satisfying for me to see this done even though it took 20 years,” researcher Evan Eichler, a genome scientist from the University of Washington in Seattle, told New Scientist.

The human genome: A genome is like a genetic instruction manual — it contains all the information an organism needs to grow and function. The human genome is written in DNA, and while your exact genome is unique to you, about 99.9% of it is identical across all people.

#mendelslawofindependentassortment #Genetics #genes #molecularbiology #biology #biotech #recombinants #Genetic

This video explains the mendel’s law of independent assortment.

Continue reading “Mendel’s Law Of Independent Assortment” »

Not sure how interesting this will be to people who know a lot on aging/longevity research.

A team of researchers at Brigham and Women’s Hospital and Harvard Medical School have found evidence of mouse and human germline cells resetting their biological age. In their paper published in the journal Science Advances, the group describes their study of the aging process in germline cells and what they found by doing so.

As animals grow older, all of the cells in their body replicate themselves repeatedly. As the process continues, errors in replicating and other external factors (such as exposure to pollutants) lead to gradual decay in cell quality, which is all part of the natural aging process. In this new effort, the researchers have found evidence showing that germline cells have a mechanism for resetting this process, allowing offspring to reset their aging clocks.

Continue reading “Mouse and human germline cells appear to reset their biological age” »

Researchers from Brigham and Women’s Hospital have engineered yeast used in baking, wine-making and brewing to treat inflammatory bowel disease (IBD). The bacteria has been modified to secrete an anti-inflammatory molecule in response to signs of gut inflammation and has proven effective in preclinical tests.

Our gut microbiome is increasingly implicated in everything from cancer to neurodegenerative disease but it is still unclear exactly how we can translate these novel findings into clinical treatments. Fecal transplants are probably the most primitive microbiome-modifying treatment we have developed, while probiotics simply rely on upping specific levels of naturally occurring bacteria.

Perhaps the most futurist microbiome therapy under investigation is the idea of genetically engineered probiotics. Here researchers modify bacteria to either eat up molecules we don’t want in our body or secrete molecules we know have positive therapeutic effects.