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Just as humans cannot breathe underwater, the tiny pores of plants can't exchange air underwater.

Nancy Moran, an evolutionary biologist at The University of Texas at Austin, will receive the 2023 Selman A. Waksman Award in Microbiology from the National Academy of Sciences (NAS).

In a first for the genetic toolset known as CRISPR, a recently discovered protein has been found to act as a kind of multipurpose self-destruct system for bacteria, capable of degrading single-stranded RNA, single-stranded DNA and double-stranded DNA. With its abilities to target so many types of genetic material, the discovery holds potential for the development of new inexpensive and highly sensitive at-home diagnostic tests for a wide range of infectious diseases, including COVID-19, influenza, Ebola and Zika, according to the authors of a new study in the journal Nature.

Researchers from The University of Texas at Austin report in Nature Microbiology the first discovery of viruses infecting a group of microbes that may include the ancestors of all complex life. The discovery offers tantalizing clues about the origins of complex life and suggests new directions for exploring the hypothesis that viruses were essential to the evolution of humans and other complex life forms.

John Wallingford, professor of molecular biosciences at The University of Texas at Austin, has been awarded a fellowship by the John Simon Guggenheim Memorial Foundation.

One of the grand challenges with using CRISPR-based gene editing on humans is that the molecular machinery sometimes makes changes to the wrong section of a host's genome, creating the possibility that an attempt to repair a genetic mutation in one spot in the genome could accidentally create a dangerous new mutation in another.

Few developments have rocked the biotechnology world or generated as much buzz as the discovery of CRISPR-Cas systems, a breakthrough in gene editing recognized in 2020 with a Nobel Prize. But these systems that naturally occur in bacteria are limited because they can make only small tweaks to genes. In recent years, scientists discovered a different system in bacteria that might lead to even more powerful methods for gene editing, given its unique ability to insert genes or whole sections of DNA in a genome.

One of the most astounding feats of nature is happening right now in cells throughout your body: noodle-like molecules called chromosomes, which carry part of your genetic blueprints and are about two inches (5 centimeters) long when fully stretched out, get stuffed into the cell's nucleus, which is at least 5,000 times smaller, with plenty of room for a bunch of other chromosomes. 

Imagine biological and chemical imaging tools so advanced that they are able to show the molecular details of a virus as it attaches to and enters cells, or the alignment of vanishingly tiny crystals at an atomic level so as to lend insights for new solar energy technology.