Who gets the lion’s share? HKU ecologists highlight disparities in global biodiversity conservation funding
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Updates every hour. Last Updated: 3-Mar-2025 22:08 ET (4-Mar-2025 03:08 GMT/UTC)
Researchers from Osaka University found that TEX38 and ZDHHC19 co-localize on the plasma membrane of spermatids and mediate S-palmitoylation of ARRDC5, a crucial protein for spermatogenesis. Disrupting either TEX38 or ZDHHC19 inhibited cytoplasm removal from the sperm head, resulting in deformed sperm and infertility in a male mouse model.
DNA repair proteins act like the body’s editors, constantly finding and reversing damage to our genetic code. Researchers have long struggled to understand how cancer cells hijack one of these proteins—called polymerase theta (Pol-theta)—for their own survival. But scientists at Scripps Research have now captured the first detailed images of Pol-theta in action, revealing the molecular processes responsible for a range of cancers.
Researchers at the University of Calgary are suggesting a more comprehensive approach for identifying at-risk wildlife populations — such as caribou — based on individual movement patterns. The paper, published on Feb. 20 in the journal Biological Conservation, uses a long-term dataset of caribou wearing GPS collars across Western Canada. It identifies six distinct behavioural groups that would each deserve their own conservation actions.
A recent review in Engineering explores multi-photon 3D nanoprinting. This technology, with its unique 3D processing and nanoscale resolution, has wide applications in fields like optics and biology. However, it faces challenges such as slow processing speed and material limitations. The article also looks at potential solutions and future development directions, offering insights into the future of this technology in manufacturing.
Adipose tissues, which serve as fat reserves, have been recognized as an endocrine organ. The three-dimensional (3D) bioprinting of adipose tissues has potential applications in regenerative medicine. However, the 3D bioprinting conditions have not been optimized for adipose tissues. Now, researchers from Korea have developed a novel method for 3D adipose tissue bioprinting using a hybrid bioink. The 3D bioprinted adipose tissues exhibited skin regeneration ability, paving the way for their applications in regenerative medicine.