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tag codons genetics genomics

Recoding Life
Laasya Samhita | Jan 2, 2014 | 6 min read
Rewriting the genetic code can lead to a better understanding of how living cells work, and spawn new biotechnological applications.
Tailor-Made Genome
Tia Ghose | Jul 18, 2011 | 2 min read
A method for rapidly replacing stop codons throughout the genetic code of E. coli paves the way for biomanufacturing designer proteins.
Researchers in George Church&rsquo;s lab modified wild type ADK proteins (left) in <em >E.coli</em>, furnishing them with an nonstandard amino acid (nsAA) meant to biocontain the resulting bacterial strain.
A Pioneer of The Multiplex Frontier
Rashmi Shivni, Drug Discovery News | May 20, 2023 | 10 min read
George Church is at it again, this time using multiplex gene editing to create virus-proof cells, improve organ transplant success, and protect elephants.
Advances in the functional characterization of newly discovered microproteins hint at their diverse roles  in health and disease
The Dark Matter of the Human Proteome
Annie Rathore | Apr 1, 2019 | 10 min read
Advances in the functional characterization of newly discovered microproteins hint at diverse roles in health and disease.
The Human Genome
Arielle Emmett | Jul 23, 2000 | 10+ min read
Life sciences took center stage virtually around the world June 26. President Bill Clinton, flanked on the left by Celera Genomics Group president J. Craig Venter and on the right by National Human Genome Research Institute director Francis S. Collins, announced the completion of "the first survey of the entire human genome."
When Stop Means Go
Ruth Williams | May 22, 2014 | 3 min read
A survey of trillions of base pairs of microbial DNA reveals a considerable degree of stop codon reassignment.
Planning the Future of Plant Genomics
Eugene Russo | Jul 21, 2002 | 5 min read
Image: Courtesy of National Sciences Foundation Arabidopsis Plant genomics researchers stand at a crossroads. Behind them are the completed genome sequences of rice1 and the model mustard plant Arabidopsis thaliana.2 Now, armed with insights gained from both plant and animal sequencing projects, plant biologists must decide how to proceed with future sequencing, proteomics, and functional genomics endeavors--and how to allot precious basic research dollars while, at the same time, keeping
Five More Synthetic Yeast Chromosomes Completed
Anna Azvolinsky | Mar 9, 2017 | 4 min read
Members of the Synthetic Yeast Genome Project have synthesized five additional yeast chromosomes from scratch. 
The Scientist Staff | Mar 19, 2024
Alternative Splicing Goes Mainstream
Sam Jaffe | Dec 14, 2003 | 10 min read
In eukaryotic genetics, the one-gene/one-protein concept has, for the most part, breathed its last. Researchers have rallied behind mechanisms such as alternative splicing, which may allow a lowly 30,000-gene genome to produce the dizzying variety of proteins that some believe is necessary to produce beings as complex as humans. Alternative splicing--the post-transcriptional editing process that can result in various mRNAs--was previously seen as an interesting but relatively uncommon sidesh

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