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We present a DNA self-assembly based molecular data writing strategy to enable parallel movable-type printing for scalable DNA storage.

Memorial Sloan Kettering Cancer Center-led researchers have identified a small molecule called gliocidin that kills glioblastoma cells without damaging healthy cells, potentially offering a new therapeutic avenue for this aggressive brain tumor.

Glioblastoma remains one of the most lethal primary brain tumors, with current therapies failing to significantly improve patient survival rates. Glioblastoma is difficult to treat for several reasons. The tumor consists of many different types of cells, making it difficult for treatments to target them all effectively.

There are few genetic changes in the cancer for drugs to target, and the tumor creates an environment that weakens the body’s immune response against it. Even getting medications near targets in the brain is challenging because the protective blood-brain barrier blocks entry for most potential drug treatments.

Researchers at University of California San Diego analyzed the genomes of hundreds of malaria parasites to determine which genetic variants are most likely to confer drug resistance.

The findings, published in Science, could help scientists use machine learning to predict antimalarial drug resistance and more effectively prioritize the most promising experimental treatments for further development. The approach could also help predict treatment resistance in other infectious diseases, and even cancer.

“A lot of drug resistance research can only look at one chemical agent at a time, but what we’ve been able to do here is create a roadmap for understanding antimalaria drug resistance across more than a hundred different compounds,” said Elizabeth Winzeler, Ph.D., a professor at UC San Diego Skaggs School of Pharmacy and Pharmaceutical Sciences and the Department of Pediatrics at UC San Diego School of Medicine.

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In a study published Nov. 21 in the journal Nature Human Behaviour, researchers have uncovered significant genetic connections between human language abilities and musical rhythm skills, providing new insights into the biological underpinnings of these fundamental human traits.

The study brought together leading experts in the areas of musicality genetics and language genetics from Vanderbilt University Medical Center in close collaboration with researchers at the Max Planck Institute for Psycholinguistics in the Netherlands.

The study revealed overlapping genetic underpinnings between rhythm-related skills and language-related traits, including dyslexia. Multiple datasets were used from over 1 million individuals. By applying advanced multivariate methods, the researchers were able to identify common genetic factors and explore their biological and evolutionary significance.

CRISPR is a way off being used in human therapeutics, but a new discovery could unlock its potential.

The molecular and cellular mechanisms underlying ovarian aging are incompletely understood. Here the authors provide single-nuclei RNA and ATAC-seq of human ovarian tissue from four young and four reproductively aged donors, revealing coordinated transcriptomic and epigenomic changes across cell types and highlighting a role for mTOR signaling in reproductive aging.

To maintain a healthy immune system, doctors advise patients to take vitamins and minerals. Vitamins have many functions that benefit the body, including resisting infection, energy boost, aiding in blood clotting, improving brain function, generation of red blood cells, promoting a healthy gut microbiome, improving wound healing, preventing eye deterioration, and developing strong bones. We can get vitamins from various sources, including orange juice, which is rich in vitamin C, folate, and potassium. Physicians often recommend supplements for patients low on specific vitamins. However, dysregulation of vitamins can weaken the immune system and promote overall bad health. One vitamin in particular that helps maintain cellular function includes B12. This vitamin is essential to generate DNA and red blood cells, and aids in nerve function, energy conversion, and protein metabolism. When a patient has a B12 deficiency it can result in muscle weakness, numbness in hands and feet, difficulty walking, nausea, loss of appetite, and unintentional weight loss. In addition, it can allow the buildup of a small molecule known as methylmalonic acid (MMA).

In healthy tissues, vitamin B12 helps break down MMA. In B12 deficient patients, MMA is increased and can be measured through blood or urine samples. Methylmalonic acid is produced when proteins in your muscle, known as amino acids, are broken down. Tests to determine B12 deficiency or a genetic disorder are done by physicians at birth and after the appearance of symptoms related to B12 deficiency. Interestingly, a group of scientists have discovered a new deleterious role of MMA in lung carcinoma.

A recent publication from Oncogene, by Dr. Ana P. Gomes and others, demonstrated that MMA in aged patients weakens immune cell function and promotes lung cancer progression. Gomes is a professor of molecular oncology at Moffitt Cancer Center in Florida. Her work specifically focuses on understanding metabolic changes as we age and how this change in metabolism influences cancer risk.

Cell-to-cell communication through nanosized particles, working as messengers and carriers, can now be analyzed in a whole new way, thanks to a new method involving CRISPR gene-editing technology. The particles, known as small extracellular vesicles (sEVs), play an important role in the spread of disease and as potential drug carriers. The newly developed system, named CIBER, enables thousands of genes to be studied at once, by labeling sEVs with a kind of RNA “barcode.” With this, researchers hope to find what factors are involved in sEV release from host cells. This will help advance our understanding of basic sEV biology and may aid in the development of new treatments for diseases, such as cancer.

Your body “talks” in more ways than one. Your cells communicate with each other, enabling your different parts to function as one team. However, there are still many mysteries surrounding this process. Extracellular vesicles (EVs), small particles released by cells, were previously thought to be useless waste. However, in recent decades they have been dramatically relabeled as very important particles (VIPs), due to their association with various diseases, including cancer, neurodegenerative diseases and age-related diseases.

Small EVs have been found to play a key role in cell-to-cell communication. Depending on what “cargo” they carry from their host cell (which can include RNA, proteins and lipids), sEVs can help maintain normal tissue functions or can further the spread of diseases. Because of this, researchers are interested in how sEVs form and are released. However, separating sEVs from other molecules and identifying the factors which lead to their release is both difficult and time-consuming with conventional methods. So, a team in Japan has developed a new technique.