Top row, three different RNA objects rendered from molecular computer models: from left, RNA antiprism composed of eight RNAs, a six-stranded RNA cube, and a 10-stranded RNA cube. Bottom row, the corresponding three-dimensional reconstructions of the objects obtained from cryo-electron microscopy. (Credit: Cody Geary and Kirill A. Afonin)
Luc Jaeger, associate professor of chemistry and biochemistry at UCSB, explained that there is nothing short of a revolution going on in his field -- one that permeates all areas of biochemistry, especially his area of nanobiotechnology. The revolution involves understanding the role of RNA in cells.
"Considering the fact that up to 90 percent of the human genome is transcribed into RNA, it becomes clear that RNA is one of the most important biopolymers on which life is based," said Jaeger. "We are still far from understanding all the tremendous implications of RNA in living cells."
Jaeger's team is putting together complex three-dimensional RNA molecules -- nanosize polyhedrons that could be used to fight disease. The molecules self assemble into the new shapes. The work is funded by the National Institutes of Health (NIH), and there is a patent pending jointly between NIH and UCSB on the new designs.
"We are interested in using RNA assemblies to deliver silencing RNAs and therapeutic RNA aptamers to target cancer and other diseases," said Jaeger. "It is clear that RNA is involved in a huge number of key processes that are related to health issues."
Jaeger believes the RNA-based approaches to delivering new therapies in the body will be safer than those using artificial compounds that might have undesirable side effects down the line.
"By using RNA molecules as our primary medium, we are practicing 'green' nanobiotechnology," explained Jaeger. "The research program developed in my lab at UCSB aims at contributing in a positive way to medicine and synthetic biology. We try to avoid any approaches that raise controversial bioethical issues in the public square. It's not an easy task, but I am convinced that it will pay off in the long run."
The more recent of the two scientific papers describing the new work -- "In vitro assembly of cubic RNA-based scaffolds designed in silicon" -- published online August 30 by Nature Nanotechnology. The earlier paper -- "A polyhedron made of tRNAs" by Severcan and colleagues -- was published online on July 18 by Nature Chemistry. The print edition of this article will be published in Nature Chemistry's September issue.
The second author on the Nature Chemistry paper is Cody Geary, a postdoctoral fellow in Jaeger's lab. Kirill A. Afonin, also a postdoctoral fellow in Jaeger's lab, is the first author on the Nature Nanotechnnology article.
Bruce Shapiro, a senior author on the Nature Nanotechnology article, is based at the National Cancer Institute in Frederick, Md. and is also funded by NIH. Jaeger and his team worked with Shapiro to develop a computerized approach for facilitating the design of self-assembling RNA strands. Further assistance came from the National Resource for Automated Molecular Microscopy located at Scripps Institute in La Jolla, Calif.
Chào tất cả các bạn. Hhorg ra đời dựa trên nền tảng "Kiến thức - Kinh nghiệm - Kĩ năng - Phương pháp - Tài nguyên". Nhằm đáp ứng nhu cầu học tập của các bạn sinh viên sư phạm và giảng dạy của giáo viên Hóa học. Tiêu chí của chúng tôi là "Thế giới Hóa học của chúng ta". Rất mong nhận được sự đóng góp ý kiến, bài viết để cùng học tập và giảng dạy tốt và cũng rất mong được làm quen với tất cả các bạn trên toàn quốc và trên thế giới. "Considering the fact that up to 90 percent of the human genome is transcribed into RNA, it becomes clear that RNA is one of the most important biopolymers on which life is based," said Jaeger. "We are still far from understanding all the tremendous implications of RNA in living cells."
Jaeger's team is putting together complex three-dimensional RNA molecules -- nanosize polyhedrons that could be used to fight disease. The molecules self assemble into the new shapes. The work is funded by the National Institutes of Health (NIH), and there is a patent pending jointly between NIH and UCSB on the new designs.
"We are interested in using RNA assemblies to deliver silencing RNAs and therapeutic RNA aptamers to target cancer and other diseases," said Jaeger. "It is clear that RNA is involved in a huge number of key processes that are related to health issues."
Jaeger believes the RNA-based approaches to delivering new therapies in the body will be safer than those using artificial compounds that might have undesirable side effects down the line.
"By using RNA molecules as our primary medium, we are practicing 'green' nanobiotechnology," explained Jaeger. "The research program developed in my lab at UCSB aims at contributing in a positive way to medicine and synthetic biology. We try to avoid any approaches that raise controversial bioethical issues in the public square. It's not an easy task, but I am convinced that it will pay off in the long run."
The more recent of the two scientific papers describing the new work -- "In vitro assembly of cubic RNA-based scaffolds designed in silicon" -- published online August 30 by Nature Nanotechnology. The earlier paper -- "A polyhedron made of tRNAs" by Severcan and colleagues -- was published online on July 18 by Nature Chemistry. The print edition of this article will be published in Nature Chemistry's September issue.
The second author on the Nature Chemistry paper is Cody Geary, a postdoctoral fellow in Jaeger's lab. Kirill A. Afonin, also a postdoctoral fellow in Jaeger's lab, is the first author on the Nature Nanotechnnology article.
Bruce Shapiro, a senior author on the Nature Nanotechnology article, is based at the National Cancer Institute in Frederick, Md. and is also funded by NIH. Jaeger and his team worked with Shapiro to develop a computerized approach for facilitating the design of self-assembling RNA strands. Further assistance came from the National Resource for Automated Molecular Microscopy located at Scripps Institute in La Jolla, Calif.
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