The Fort Worth Press - Nobel winner's ingenious chemistry could lead to cancer breakthroughs

USD -
AED 3.672504
AFN 64.000368
ALL 82.099008
AMD 367.63228
ANG 1.790403
AOA 917.503981
ARS 1492.901385
AUD 1.443002
AWG 1.8025
AZN 1.70397
BAM 1.709092
BBD 2.014681
BDT 123.336392
BGN 1.69088
BHD 0.377157
BIF 2975.313497
BMD 1
BND 1.290864
BOB 6.927077
BRL 5.170399
BSD 1.000306
BTN 95.296893
BWP 13.491502
BYN 2.902259
BYR 19600
BZD 2.011797
CAD 1.41995
CDF 2246.000362
CHF 0.801016
CLF 0.023518
CLP 925.617163
CNY 6.789104
CNH 6.785505
COP 3363.656224
CRC 455.717219
CUC 1
CUP 26.5
CVE 96.35601
CZK 21.144704
DJF 178.127321
DKK 6.535604
DOP 59.256346
DZD 133.361297
EGP 49.283873
ERN 15
ETB 160.4018
EUR 0.873904
FJD 2.26045
FKP 0.748895
GBP 0.746798
GEL 2.63504
GGP 0.748895
GHS 11.363656
GIP 0.748895
GMD 72.503851
GNF 8772.665705
GTQ 7.634028
GYD 209.236685
HKD 7.84465
HNL 26.773277
HRK 6.587504
HTG 130.834098
HUF 308.910388
IDR 17994.4
ILS 2.99865
IMP 0.748895
INR 95.215504
IQD 1310.350854
IRR 1375950.000352
ISK 125.920386
JEP 0.748895
JMD 158.351903
JOD 0.70904
JPY 161.36504
KES 129.3398
KGS 87.447704
KHR 4005.767466
KMF 431.00035
KPW 900.00035
KRW 1528.775039
KWD 0.31029
KYD 0.833661
KZT 473.045834
LAK 22586.621226
LBP 89575.392144
LKR 335.046096
LRD 181.552847
LSL 16.224931
LTL 2.95274
LVL 0.60489
LYD 6.4115
MAD 9.354393
MDL 17.595141
MGA 4240.835409
MKD 53.86027
MMK 2099.883338
MNT 3582.147735
MOP 8.08057
MRU 39.921353
MUR 47.050378
MVR 15.460378
MWK 1734.609167
MXN 17.469104
MYR 4.071039
MZN 63.910377
NAD 16.224931
NGN 1370.080377
NIO 36.806921
NOK 9.841039
NPR 152.475204
NZD 1.75116
OMR 0.385704
PAB 1.000306
PEN 3.403766
PGK 4.394635
PHP 61.501038
PKR 278.103989
PLN 3.75205
PYG 6082.055315
QAR 3.656661
RON 4.568038
RSD 102.570892
RUB 76.986936
RWF 1464.412112
SAR 3.755774
SBD 8.058541
SCR 13.46616
SDG 600.503676
SEK 9.65806
SGD 1.291404
SHP 0.746601
SLE 24.350371
SLL 20969.503664
SOS 571.678245
SRD 37.566038
STD 20697.981008
STN 21.409534
SVC 8.752567
SYP 110.532098
SZL 16.22231
THB 33.325038
TJS 9.2726
TMT 3.51
TND 2.952244
TOP 2.40776
TRY 46.767504
TTD 6.779394
TWD 31.938038
TZS 2626.818718
UAH 44.550181
UGX 3650.980906
UYU 40.232446
UZS 11983.221916
VES 638.90327
VND 26296
VUV 118.93159
WST 2.77318
XAF 573.213615
XAG 0.016021
XAU 0.00024
XCD 2.70255
XCG 1.80277
XDR 0.712894
XOF 573.213615
XPF 104.216367
YER 237.050363
ZAR 16.231504
ZMK 9001.203584
ZMW 18.379866
ZWL 321.999592
  • CMSC

    0.0400

    21.99

    +0.18%

  • RBGPF

    2.5400

    68.15

    +3.73%

  • VOD

    0.1400

    13.15

    +1.06%

  • NGG

    2.6700

    82.85

    +3.22%

  • RELX

    0.5500

    31.93

    +1.72%

  • BTI

    1.2100

    61.77

    +1.96%

  • GSK

    2.3600

    53.66

    +4.4%

  • RIO

    1.0700

    94.42

    +1.13%

  • RYCEF

    0.5400

    19.68

    +2.74%

  • CMSD

    -0.0300

    22.15

    -0.14%

  • BCE

    0.4000

    21.42

    +1.87%

  • BCC

    0.4500

    75.93

    +0.59%

  • JRI

    0.0600

    13

    +0.46%

  • AZN

    11.2900

    195.15

    +5.79%

  • BP

    1.2500

    37.4

    +3.34%

Nobel winner's ingenious chemistry could lead to cancer breakthroughs
Nobel winner's ingenious chemistry could lead to cancer breakthroughs / Photo: © Stanford News Service/AFP

Nobel winner's ingenious chemistry could lead to cancer breakthroughs

"All kinds of crazy things" is how Carolyn Bertozzi, a 2022 Nobel laureate, describes her life's work. Actually performing "chemistry in cells and in people."

Text size:

When she started her research in 1997, the Stanford professor was aiming only to observe the evolution of certain molecules on the surface of cancer cells.

Today, thanks to her discoveries, at least two companies -- including one she co-founded -- are developing innovative cancer treatments.

The multitude of applications made possible by her findings are impressive: delivering treatments with extreme precision, understanding better how drugs act inside the body, visualizing certain bacteria, to name a few.

"I can't even really enumerate them. The vast majority of those applications I would never have foreseen," she told AFP in an interview.

The Nobel Prize committee recognized Bertozzi's pioneering advances on Wednesday, making her only the eighth woman to win the chemistry prize, at just 55 years old.

- Lego pieces -

Her journey began when she found she had a passion for organic chemistry, while taking pre-medicine courses at Harvard.

The subject is notoriously -- many say fiendishly -- difficult, but she credits an "amazing professor," the late David Evans, for bringing it to life -- and changing the course of her life.

"I said, forget the med school thing. I'm going to be a chemist," said Bertozzi, whose sister is a professor of applied mathematics, and father a retired professor of physics.

After completing her post-doctorate and joining the faculty at UC Berkeley, she wanted to take a closer look at glycans: complex carbohydrates, or sugars, located on the surface of cells, which "go through structural changes" when they become cancerous.

At the time, "there was no tool to image sugars, like in a microscope, for example," she said.

She had an idea that would require two chemical substances that fit together perfectly, like pieces of lego.

The first lego is fed to cells via a sugar. The cell metabolizes it and places it on the tip of the glycan. The second piece of lego, a fluorescent molecule, is injected into the body.

The two lego pieces click together, and voila: hidden glycans reveal themselves under a microscope.

This technique is inspired by "click chemistry" developed independently by Denmark's Morten Meldal and American Barry Sharpless -- Bertozzi's co-winners. But their discoveries relied on using copper as a catalyst, which is toxic to the body.

One of Bertozzi's great leaps was achieving the same type of ultra-efficient reaction without copper.

The other tour de force: making it all happen without wreaking havoc with other processes in the body.

"The beauty of it is that you can take the two Legos and click them together, even if they're surrounded by millions of other very similar plastic toys," she explained.

She coined the term "bioorthogonal chemistry," meaning a reaction that doesn't interfere with other biochemical processes. Perfecting the technique took 10 years.

- 'Cycle of science' -

Researchers are now leveraging these breakthroughs to develop cancer treatments.

Glycans on cancer cells "are able to hide the cancer cell from the immune system -- and so your body can't fight it, it can't see it," she explains.

Using bioorthogonal chemistry, "we made a new type of medicine, which basically acts like a lawnmower," says Bertozzi.

The first lego attaches to the cancer cell's surface, and the second, which clips onto it, is equipped with an enzyme that "mows off the sugars as if they're just grass, it cuts the grass and the sugars fall off," she says with a smile.

The drug is currently being tested in the early stages of a clinical trial.

Another company is seeking to use bioorthogonal chemistry to better target cancer treatment. The first lego piece is injected into a tumor, then a second, which carries the drug, attaches itself and acts only on its target.

"So that allows the oncologist to treat the tumor and kill the tumor without exposing the person's entire body to a toxic chemical," she says.

"What the future holds is hopefully an impact in human health," says Bertozzi. "But the people who decide that more so than myself, are the students and postdocs that join my lab."

Hundreds of them, current and former, filled her email box with messages of congratulations this morning.

"That really is the cycle of science -- it's being mentored and then mentoring" she adds. And "mentoring students gives you an opportunity to amplify the impact of your science."

S.Weaver--TFWP