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2022 Nobel Prize in Chemistry: Former Berkeley Lab scientist Carolyn Bertozzi wins

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The Royal Swedish Academy of Sciences has awarded the 2022 Nobel Prize in Chemistry to Carolyn Bertozzi, Morten Meldal, and K. Barry Sharpless “for the development of click chemistry and bioorthogonal chemistry.”

Bertozzi, a professor of chemistry at Stanford University, is the eighth woman to be awarded the prize. From 1996 to 2015, before joining Stanford, she was a faculty scientist at the Department of Energy’s Lawrence Berkeley National Laboratory and a UC Berkeley professor. She also served as the director of the Molecular Foundry, a DOE Office of Science nanoscience user facility located at Berkeley Lab, from 2006 to 2010.

The award to Bertozzi brings the number of Nobel Prizes associated with Berkeley Lab scientists to sixteen. (Earlier this week, on Tuesday, Oct. 4, former Lab postdoc John Clauser’s 2022 Nobel Prize in Physics brought the Lab’s tally to fifteen.)

According to today’s Nobel Prize announcement, “The Nobel Prize in Chemistry 2022 is about making difficult processes easier. Barry Sharpless and Morten Meldal have laid the foundation for a functional form of chemistry – click chemistry – in which molecular building blocks snap together quickly and efficiently. Carolyn Bertozzi has taken click chemistry to a new dimension and started utilising it in living organisms.”

Carolyn Bertozzi/CREDIT:Jenny Nuss/Berkeley Lab

“Carolyn Bertozzi had a profound impact at Berkeley Lab, not only through her brilliant science, but as someone who created new institutions that encouraged team science,” said Berkeley Lab Director Mike Witherell.

By pioneering a method for mapping biomolecules on the surface of cells, Bertozzi helped create a suite of techniques comprising “bioorthogonal chemistry,” a term Bertozzi coined, which means “not interacting with biology.” The method describes chemical reactions that allow scientists to explore cells and track biological processes without disrupting the normal chemistry of the cell.

Bertozzi’s lab first developed the method in the late 1990s and early 2000s. During that time, she was one of the six scientists who helped establish the Molecular Foundry, a nanoscience research facility that provides scientists from around the world access to cutting-edge expertise and instrumentation. She served as the Molecular Foundry’s director when the facility first opened its doors to the research community in 2006, and she founded the Foundry’s Biological Nanostructures Facility, where scientists study the synthesis, analysis and mimicry of biological nanostructures.

“Carolyn Bertozzi’s impact on nanoscience is huge,” said Jeff Neaton, associate laboratory director of Berkeley Lab’s Energy Sciences Area. “The chemistry she developed paved the way for the science and engineering of living-nonliving interfaces, a frontier of nanoscience which also became a major theme of the Foundry.”

Under Bertozzi’s leadership, the Foundry grew immensely, bringing in scientists from across the disciplines. This multidisciplinary approach inspired collaborations with visiting scientists, including longtime Foundry user K. Barry Sharpless, co-recipient of the Nobel Prize in Chemistry with Bertozzi and Morten Meldal.

“Carolyn put the Foundry on the map,” said Bruce Cohen, a staff scientist in the Foundry’s Biological Nanostructures facility since 2006. “She oversaw the opening of the facility, which is a major administrative and scientific feat.”  He added that Bertozzi’s “science is so creative and original, as well as technically on point, and it’s opened up entire new areas of study. This is a well-deserved Nobel Prize. I couldn’t be happier for her.”

Cohen said that Bertozzi is also “a great mentor to all of the scientists around her, and has always been an inspirational role model for both women and LGBTQ people in science.”

Bertozzi and others have used her methods to answer fundamental questions about the role of sugars in biology, to study how cells build proteins and other molecules, to develop new cancer medicines, and to produce new materials for energy storage, among many other applications.

The Nobel committee said in a statement that “click chemistry and bio-orthogonal reactions have taken chemistry into the era of functionalism,” adding that “this is bringing the greatest benefit to humankind.”

Among her many awards, Bertozzi is a recipient of the 2014 Ernest Orlando Lawrence Award, the Department of Energy’s highest scientific honor. She was named a MacArthur Fellow in 1999. She won the Wolf Prize in Chemistry in 2022.

Bertozzi completed her undergraduate degree in chemistry at Harvard University and her Ph.D. at UC Berkeley. She has been a Howard Hughes Medical Institute Investigator since 2000. She joined Stanford in 2015.

 

World Food Programme gets 2020 Nobel Prize for Peace

Nobel Prize for Physics, 2017 – Indian Connection

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The 2017 Nobel Prize for Physics has been conferred to three scientists namely Rainer Weiss, Barry C Barish & Kip S Thorne under the LIGO Project for their discovery of gravitational waves, 100 years after Einstein’s General Relativity predicted it. The Nobel Prize for Physics 2017 celebrates the direct detection of Gravitational waves arriving from the merger two large Black holes in a distant galaxy a Billion of light years away. Gravitational waves carry information about their dramatic origins and about the nature of gravity that cannot otherwise be obtained. This opens a new window to Astronomy since Gravitational Waves are an entirely new way of observing the most violent events in space.

This is a proud moment for India also, since the discovery paper has 39 Indian authors/scientists from nine institutions-, CMI Chennai, ICTS-TIFR Bengaluru, IISER-Kolkata, IISER-Trivandrum, IIT Gandhinagar, IPR Gandhinagar, IUCAA Pune, RRCAT Indore and TIFR Mumbai. primarily funded through individual/ institutional grants by Department of Atomic Energy, Department of Science & Technology and Ministry of Human Resource Development AE, DST and MHRD, who are co-authors of this discovery paper.

Late Professor CV Vishveshvara of RRI, Bengaluru (DST AI) and Professor SV Dhurandhar of IUCAA, Pune and some other Indian scientists made seminal contributions to this field which contributed towards the principles behind the LIGO Detector.

The group led by Bala Iyer (currently at ICTS-TIFR) at the Raman Research Institute in collaboration with scientists in France had pioneered the mathematical calculations used to model Gravitational Wave signals from orbiting black holes and neutron stars. Theoretical work that combined black holes and gravitational waves was published by C. V. Vishveshwara in 1970. These contributions are prominently cited in the discovery paper.

An opportunity for India taking leadership in this field has opened up with the LIGO-India mega-science project that was granted ‘in principle’ approval by the Union Cabinet on Feb 17 2016. LIGO-India brings forth a real possibility of Indian scientists and technologists stepping forward, with strong international cooperation, into the frontier of an emergent area of high visibility and promise presented by the recent GW detections and the high promise of a new window of gravitational-wave astronomy to probe the universe.

The global science community is unanimous that the future of Gravitational wave astronomy and astrophysics, beyond the first discovery, lies with the planned global array of GW detectors, including the LIGO-India observatory. Inclusion of LIGO-India greatly improves the angular resolution in the location of the gravitational-wave source by the LIGO global network. For the discovery event observed by the two advanced LIGO detectors in the US, with a hypothetical LIGO-India in operation, there would have been 100 times improvement in the angular resolution.

The LIGO-India proposal is for the construction and operation of an Advanced LIGO Detector in India in collaboration with the LIGO Laboratories, USA. The objective is to set up the Indian node of the three node global Advanced LIGO detector network by 2024 and operate it for 10 years. The task for LIGO-India includes the challenge of constructing the very large vaccum infrastructure that would hold a space of volume 10 million litres that can accommodate the entire 4 km scale laser interferometer in ultra high vacuum environment at nano-torrs. Indian team is also responsible for installation and commissioning the complex instrument and attaining the ultimate design sensitivity.

The LIGO-India project is being jointly executed by lead institutions: the Inter-University Centre for Astronomy and Astrophysics (IUCAA), Pune of the University Grants commission, and DAE organisations, Institute for Plasma Research (IPR), Gandhinagar, the Raja Ramanna Centre for Advanced Technology (RRCAT), Indore and the Directorate of Construction & Estate Management (DCSEM) of DAE.

LIGO-India is being jointly funded by the Department of Atomic Energy (DAE) and the Department of Science and Technology (DST). A LIGO-India Apex committee, together with the LIGO-India Project Management Board (LI-PMB) and LIGO-India Scientific Management Board (LI-SMB), were constituted in August 2016 to oversee the project execution, and there has been rapid pace of progress since then. LIGO-India is on track for commencing operations by 2024.