Nov 6, 2024 11:36 PM
(This post was last modified: Nov 6, 2024 11:40 PM by C C.)
The egg or the chicken? An ancient unicellular says egg!
https://www.eurekalert.org/news-releases/1063953
INTRO: Chromosphaera perkinsii is a single-celled species discovered in 2017 in marine sediments around Hawaii. The first signs of its presence on Earth have been dated at over a billion years, well before the appearance of the first animals. A team from the University of Geneva (UNIGE) has observed that this species forms multicellular structures that bear striking similarities to animal embryos.
These observations suggest that the genetic programmes responsible for embryonic development were already present before the emergence of animal life, or that C. perkinsii evolved independently to develop similar processes. Nature would therefore have possessed the genetic tools to “create eggs” long before it “invented chickens”. This study is published in the journal Nature...... (MORE - details, no ads)
How plants evolved multiple ways to override genetic instructions
https://www.eurekalert.org/news-releases/1063533
INTRO: Biologists at Washington University in St. Louis have discovered the origin of a curious duplication that gives plants multiple ways to override instructions that are coded into their DNA. This research could help scientists exploit a plant’s existing systems to favor traits that make it more resilient to environmental changes, like heat or drought stress.
The study led by Xuehua Zhong, a professor of biology in Arts & Sciences, was published Nov. 6 in Science Advances.
Zhong’s new research focuses on DNA methylation, a normal biological process in living cells wherein small chemical groups called methyl groups are added to DNA. This activity controls which genes are turned on and off, which in turn affects different traits — including how organisms respond to their environments.
Part of this job involves silencing, or turning off, certain snippets of DNA that move around within an organism’s genome. These so-called jumping genes, or transposons, can cause damage if not controlled. The entire process is regulated by enzymes, but mammals and plants have developed different enzymes to add methyl groups.
“Mammals only have two major enzymes that add methyl groups in one DNA context, but plants actually have multiple enzymes that do that in three DNA contexts,” said Zhong, who is the Dean’s Distinguished Professorial Scholar and program director for plant and microbial biosciences at WashU. “This is the focus of our study. The question is — why do plants need extra methylation enzymes?”
Looking forward, Zhong’s research could pave the way for innovations in agriculture by improving crop resilience. “Certain genes or combinations of genes are contributing to certain features or traits,” Zhong explained. “If we find precisely how they are regulated, then we can find a way to innovate our technology for crop improvement.” (MORE - details, no ads)
https://www.eurekalert.org/news-releases/1063953
INTRO: Chromosphaera perkinsii is a single-celled species discovered in 2017 in marine sediments around Hawaii. The first signs of its presence on Earth have been dated at over a billion years, well before the appearance of the first animals. A team from the University of Geneva (UNIGE) has observed that this species forms multicellular structures that bear striking similarities to animal embryos.
These observations suggest that the genetic programmes responsible for embryonic development were already present before the emergence of animal life, or that C. perkinsii evolved independently to develop similar processes. Nature would therefore have possessed the genetic tools to “create eggs” long before it “invented chickens”. This study is published in the journal Nature...... (MORE - details, no ads)
How plants evolved multiple ways to override genetic instructions
https://www.eurekalert.org/news-releases/1063533
INTRO: Biologists at Washington University in St. Louis have discovered the origin of a curious duplication that gives plants multiple ways to override instructions that are coded into their DNA. This research could help scientists exploit a plant’s existing systems to favor traits that make it more resilient to environmental changes, like heat or drought stress.
The study led by Xuehua Zhong, a professor of biology in Arts & Sciences, was published Nov. 6 in Science Advances.
Zhong’s new research focuses on DNA methylation, a normal biological process in living cells wherein small chemical groups called methyl groups are added to DNA. This activity controls which genes are turned on and off, which in turn affects different traits — including how organisms respond to their environments.
Part of this job involves silencing, or turning off, certain snippets of DNA that move around within an organism’s genome. These so-called jumping genes, or transposons, can cause damage if not controlled. The entire process is regulated by enzymes, but mammals and plants have developed different enzymes to add methyl groups.
“Mammals only have two major enzymes that add methyl groups in one DNA context, but plants actually have multiple enzymes that do that in three DNA contexts,” said Zhong, who is the Dean’s Distinguished Professorial Scholar and program director for plant and microbial biosciences at WashU. “This is the focus of our study. The question is — why do plants need extra methylation enzymes?”
Looking forward, Zhong’s research could pave the way for innovations in agriculture by improving crop resilience. “Certain genes or combinations of genes are contributing to certain features or traits,” Zhong explained. “If we find precisely how they are regulated, then we can find a way to innovate our technology for crop improvement.” (MORE - details, no ads)