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Archive for the ‘biotech/medical’ category: Page 1372

May 11, 2021

AIDS virus used in gene therapy to fix ‘bubble baby’ disease

Posted by in category: biotech/medical

A gene therapy that makes use of an unlikely helper, the AIDS virus, gave a working immune system to 48 babies and toddlers who were born without one, doctors reported Tuesday.

Results show that all but two of the 50 children who were given the experimental therapy in a study now have healthy germ-fighting abilities.

“We’re taking what otherwise would have been a fatal disease” and healing most of these children with a single treatment, said study leader Dr. Donald Kohn of UCLA Mattel Children’s Hospital.

May 10, 2021

The process of combining maternal and paternal genetic information is surprisingly error-prone

Posted by in categories: biotech/medical, chemistry, genetics

Only one in three fertilizations leads to a successful pregnancy. Many embryos fail to progress beyond early development. Cell biologists at the Max Planck Institute (MPI) for Biophysical Chemistry in Göttingen (Germany), together with researchers at the Institute of Farm Animal Genetics in Mariensee and other international colleagues, have now developed a new model system for studying early embryonic development. With the help of this system, they discovered that errors often occur when the genetic material from each parent combines immediately after fertilization. This is due to a remarkably inefficient process.

Human somatic cells typically have 46 , which together carry the genetic information. These chromosomes are first brought together at fertilization, 23 from the father’s sperm, and 23 from the mother’s egg. After fertilization, the parental chromosomes initially exist in two separate compartments, known as pronuclei. These pronuclei slowly move towards each other until they come into contact. The pronuclear envelopes then dissolve, and the parental chromosomes unite.

The majority of human embryos, however, end up with an incorrect number of chromosomes. These embryos are often not viable, making erroneous genome unification a leading cause of miscarriage and infertility.

May 10, 2021

Self-repairing cells: How single cells heal membrane ruptures and restore lost structures

Posted by in category: biotech/medical

Many organisms and tissues display the ability to heal and regenerate as needed for normal physiology and as a result of pathogenesis. However, these repair activities can also be observed at the single-cell level. The physical and molecular mechanisms by which a cell can heal membrane ruptures and rebuild damaged or missing cellular structures remain poorly understood. This Review presents current understanding in wound healing and regeneration as two distinct aspects of cellular self-repair by examining a few model organisms that have displayed robust repair capacity, including Xenopus oocytes, Chlamydomonas, and Stentor coeruleus. Although many open questions remain, elucidating how cells repair themselves is important for our mechanistic understanding of cell biology. It also holds the potential for new applications and therapeutic approaches for treating human disease.

Cells are generally soft and easily damaged. However, many can repair themselves after being punctured, torn, or even ripped in half when damaged during the ordinary wear and tear of normal physiology or as a result of injury or pathology. A cell is like a spacecraft: When it is punctured, cytoplasm spills out like oxygen escaping from a damaged space module. Like Apollo 13, a damaged cell cannot rely on anyone to fix it. It must repair itself, first by stopping the loss of cytoplasm, and then regenerate by rebuilding structures that were damaged or lost. Knowledge of how single cells repair and regenerate themselves underpins our mechanistic understanding of cell biology and could guide treatments for conditions involving cellular damage.

A standard question that students are asked is to define what it means to be alive. This is surprisingly hard to answer in a precise way, but surely one of the remarkable features of living systems that distinguishes them from human-made machines is their ability to heal and repair themselves. At the multicellular level, repair and regeneration are effected by generating new cells to replace the ones that were lost. This type of repair thus ends up being a direct consequence of another basic feature of living systems—the ability of a cell to reproduce itself. No additional processes need to be invoked beyond cell division. At the single-cell level, it is much less obvious how self-repair is accomplished.

May 10, 2021

India emerges as China’s tech challenger with record unicorn run

Posted by in categories: biotech/medical, food

TOKYO — India is rapidly closing the gap with China in minting new unicorns — privately held startups valued at $1 billion or more — highlighting growing investor appetite for tech startups in the country as the pandemic accelerates adoption of digital services.

Over the past year, 15 companies from India raised capital at a valuation of $1 billion or more for the first time, according to CB Insights and company announcements gathered by Nikkei Asia. Ten of them became unicorns in 2021. By comparison, only two of the 16 companies from China that joined the list over the past year did so in 2021, according to CB Insights.

A successful listing of online food delivery company Zomato, which recently filed a draft prospectus with India’s securities regulator, would set the stage for many of these unicorns to follow suit. Zomato, a loss-making company operating in a nascent industry once considered too risky to invest, is planning to raise 82.5 billion rupees ($1.1 billion), including through a pre-IPO placement.

May 10, 2021

Studies Find Apple Compounds Boost Neurogenesis, May Improve Brain Function

Posted by in categories: biotech/medical, neuroscience

In vivo studies in mice showed that quercetin and DHBA stimulated production of neurons from stem cells in specific brain areas.

May 10, 2021

Reinforcing the Body’s Defenses against Cancer

Posted by in category: biotech/medical

New immunotherapy developments include the use of tumor-infiltrating lymphocytes, allogeneic T cells, co-stimulatory signals, and engineered cytokines.

May 10, 2021

New species discovered in the human gut microbiome could improve nitrogen availability

Posted by in categories: biotech/medical, health

This new species, Desulfovibrio diazotrophicus, is from a family of bacteria that survive and grow on sulfur-containing compounds. They are known as sulfate-reducing bacteria (SRB) and a biproduct of their activity is the release of the gas hydrogen sulfide, which has a characteristic ‘rotten egg’ smell. Whilst this is unpleasant for those around you, there is also some concern that it is detrimental for gut health; the presence of SRB has been associated with gut inflammation, inflammatory bowel disease (IBD) and colorectal cancer.

Despite this, evidence for a definitive link between SRB and chronic disease has never been established. For a start, they are very widespread; around half the human population have SRB in their gut, so maybe not all of them are bad? They may even have positive effects. They release energy and nutrients from the material that other bacteria produce when they are fermenting the food we eat.

This uncertainty triggered interest from the , including scientists from the Quadram Institute (QI), who want to understand exactly what SRB do in the microbiome and how they interact with food and the gut. Very few species have been characterized, most from Western countries. To broaden the picture, QI researchers have been working with Professor Chen Wei and colleagues from Jiangnan University, China to isolate and characterize SRB from the intestinal tract of healthy Chinese and British people. The research was funded by the Biotechnology and Biological Sciences Research Council, part of UKRI.

May 10, 2021

Scientists find mechanism that eliminates senescent cells

Posted by in categories: biotech/medical, life extension

Scientists at UC San Francisco are learning how immune cells naturally clear the body of defunct—or senescent—cells that contribute to aging and many chronic diseases. Understanding this process may open new ways of treating age-related chronic diseases with immunotherapy.

In a healthy state, these —known as invariant Natural Killer T (iNKT) cells—function as a surveillance system, eliminating cells the body senses as foreign, including , which have irreparable DNA damage. But the iNKT cells become less active with age and other factors like obesity that contribute to chronic disease.

Finding ways to stimulate this natural surveillance system offers an alternative to senolytic therapies, which to date have been the primary approach to removing senescent cells. It could be a boon to a field that has struggled with how to systemically administer these senolytics without .

May 10, 2021

17 Best Longevity Conferences and Events for 2021

Posted by in categories: biotech/medical, life extension

We’ve updated our list of top longevity conferences and events for 2021, adding 4 new ones and removing 3 that are no longer happening:


Update 5/10/2021: This post has been updated since we originally published it in August 2020. Several new longevity conferences have been added and several which are no longer happening have been removed.

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May 10, 2021

Reversing a Genetic Cause of Poor Stress Tolerance

Posted by in categories: biotech/medical, genetics, neuroscience

Stress management.


Everyone faces stress occasionally, whether in school, at work, or during a global pandemic. However, some cannot cope as well as others. In a few cases, the cause is genetic. In humans, mutations in the OPHN1 gene cause a rare X-linked disease that includes poor stress tolerance. Cold Spring Harbor Laboratory (CSHL) Professor Linda Van Aelst seeks to understand factors that cause specific individuals to respond poorly to stress. She and her lab studied the mouse gene Ophn1, an analog of the human gene, which plays a critical role in developing brain cell connections, memories, and stress tolerance. When Ophn1 was removed in a specific part of the brain, mice expressed depression-like helpless behaviors. The researchers found three ways to reverse this effect.

To test for stress, the researchers put mice into a two-room cage with a door in between. Normal mice escape from the room that gives them a light shock on their feet. But animals lacking Ophn1 sit helplessly in that room without trying to leave. Van Aelst wanted to figure out why.

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