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Bioscience

Genomics

NIST develops standards, methods, tools, and technology to advance the reliability of genomic measurements for use in biotechnology including genome editing, human genome sequencing, cancer genomics, and bioinformatics.

NIST's programs in genomics are supported by our deep expertise in measurement science, molecular biology, cancer biology, and bioinformatics. For example, NIST scientists led the development of the world's first and only whole genome reference materials, authoritatively characterized by the NIST-led Genome in a Bottle Consortium; these human genomes provide laboratories with the capability to accurately “map” DNA for genetic testing, benchmark sequencing technologies and bioinformatics, and develop new medical diagnostics and future customized drug therapies. The NIST-led Genome Editing Consortium aims to address the measurements and standards needed to increase confidence and lower the risk of utilizing genome editing technologies in research and commercial products. NIST's cancer biomarker reference materials help researchers and clinicians establish analytical validation of their measurement processes.

illustrated strand of DNA and Y chromosome

Genome in a Bottle and the Genome Sequencing Process

Genome in a Bottle and the Genome Sequencing Process
Genome in a Bottle and the Genome Sequencing Process
The NIST Genome in a Bottle Consortium is a public-private-academic consortium hosted by NIST to develop the technical infrastructure (reference standards, reference methods, and reference data) to enable translation of whole human genome sequencing to clinical practice. In this animation, learn more about the genome sequencing process and why standards are such an important part of this process.

Key Accomplishments

  • The NIST Genome Editing Consortium Lexicon Working Group has developed a standard genome editing lexicon, with 42 defined terms.  This lexicon was developed to provide a unified reference set of terms and technical definitions that standardizes their use and meaning, helping the biotechnology community have productive communications. 
  • NIST’s human genome reference material, the first of its kind in the world, generated data that is accurate enough to be used as a benchmarking tool for medical and research labs. The U.S. Food and Drug Administration used this resource to approve one of the first commercially available next-generation DNA sequencers for clinical use. 
  • NIST now offers four additional human genome reference materials to help test labs assess their ability to measure genetic links within families, and compare and contrast genes from people with different lineages. These additional materials increase the confidence of DNA sequencing labs in reporting results, improving genetic tests used for disease risk prediction, diagnosis, and progression tracking. These reference materials also give companies reliable data to guide innovation in hardware, software and clinical research.
  • GIAB developed the first benchmark of large structural changes that occur in the human genome, which will enable clinical translation and technology development for detection of diseases associated with these difficult-to-detect changes; GIAB benchmarks helped demonstrate the performance of a new nanopore-based technologycollaboration with PacBio to benchmark performance of a new highly accurate long DNA sequencing technology. NIST and GIAB continue to use new technologies to shed light on accuracy of more and more challenging DNA sequences.
  • Researchers from NIST patented the first short tandem repeat DNA method for authenticating the mouse cell lines used for genetic research. The method enables better use of taxpayers’ investment in science by helping to provide assurance that cell lines are as labelled.
  • NIST researchers in the cancer biomarker team used human cancer cell lines for copy number measurements and to develop reference materials of the genes for ERBB2 (HER2), EGFR, and MET and characterized the materials using an interlaboratory testing program.
  • A NIST-led consortium of more than 100 organizations from the public, private and academic sectors created the first-ever reference material that is used to produce spike-in controls for RNA measurements. The reference material helps labs check the technical performance of their equipment, giving them confidence that they have reliable, reproducible measurements of the activity of genes, which influence our health and can be manipulated in other organisms to make commercial products. The reference material is used for product and method development, and quality control.      

Events

Forensics@NIST 2024

FORENSICS@NIST 2024

Mon, Nov 18 - Thu, Nov 21 2024
THE MAIN EVENT: NOVEMBER 18-20, 2024 Join us virtually on Monday November 18th - Wednesday November 20th, 2024 to learn

Projects and Programs

GIAB Logo

Cancer Genome in a Bottle

Ongoing
Goals: This project is an extension of the Genome in a Bottle Consortium to develop the technical infrastructure (reference standards, reference methods, and reference data) to enable translation of cancer genome sequencing to clinical practice and innovations in technologies. The priority of GIAB
Fig. 1. Time re-Envisioned: Not a biproduct of computation but the domain in which information is encoded. Leads to different mathematical functions becoming energy efficient primitives.

Temporal Computing

Ongoing
In standard integrated circuits, information that is coded as ones and zeros is implemented by voltages on wires being high or low. The circuits consume energy during transitions between these voltages. Binary numbers have a voltage per bit so there are a lot of transitions each time a number
Genome editing technologies

NIST Genome Editing Consortium

Ongoing
Targeted genome editing, a method used to alter the DNA of living cells at desired locations, is poised to revolutionize science and medicine. To fight diseases, novel genome edited therapeutics, including those for use in regenerative medicine and infectious diseases, are being developed. Many

News

young woman in a lab coat looks at vials with a small amount of green liquid in them before putting them into a machine

Spotlight: Putting NIST at the Forefront of Genome Editing

We started from the bottom and now we’re here — geneticist and molecular biologist Samantha Maragh brought NIST into a revolution for the biomedical sciences when it was only at its origins, putting the value of standards front and center in everyone's minds. It all started with bacteria, specifically bacteria with genomic elements called CRISPR, along with a protein called Cas9. These particular
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Sierra Miller sits at a desk facing a computer screen.

Spotlight: For Bioinformaticist Sierra Miller, the Scientific Breakthrough Is Hidden in the Data

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Genetic codes

NIST, Nonprofit Research Consortium to Develop Safety Tools for Synthetic Biology to Defend Against Potential Misuse of AI

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Illustration shows a gloved hand holding a puzzle piece that fits into the center of a puzzle showing the letter Y.

Researchers Fully Sequence the Y Chromosome for the First Time

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Publications

The complete sequence of a human Y chromosome

Author(s)
Arang Rhie, Sergey Nurk, Monika Cechova, Savannah Hoyt, Dylan Taylor, Nathanael David Olson, Justin Zook, Adam Phillippy
The human Y chromosome has been notoriously difficult to sequence and assemble because of its complex repeat structure that includes long palindromes, tandem

Awards