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Ozempic for Weight Loss

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楼主
发表于 7-15-2023 12:37:53 | 只看该作者 回帖奖励 |倒序浏览 |阅读模式
(1) Rolfe Winkler and Ben Cohen, Monster Diet Drugs Like Ozempic Started With Actual Monsters; Studies of Gila monsters and anglerfish laid the groundwork for today's blockbusters. Wall Street Journal, Jul1, 2023, at page A1.
https://www.wsj.com/articles/oze ... anglerfish-8c9c1ff2

Note:
(a)
(i) The article is free.
(ii) The article talked about Gila monster and anglerfish. But it did not explain how either or both led to Ozempic. Sp O will.
(iii) Rolf
https://en.wikipedia.org/wiki/Rolf
(b)
(i) Gila monster
https://en.wikipedia.org/wiki/Gila_monster
("The name 'Gila' refers to the Gila River Basin in the U.S. states of Arizona and New Mexico, where the Gila monster was once plentiful, * * * The Gila monster produces venom in modified salivary glands at the end of its lower jaws, unlike snakes, whose venom is produced in glands behind the eyes. * * * The venom of a Gila monster is normally not fatal to healthy adult humans")
(ii) Gila River
https://en.wikipedia.org/wiki/Gila_River
("Popular theory says that the word 'Gila' was derived from a Spanish contraction of Hah-quah-sa-eel, a Yuma [Native American tribe] word meaning 'running water which is salty' ")

Gila is a Spanish word: the letter g in Spanish is always pronounced the same as letter h in English. So both Gila River and Gila monster have g pronounced as h.
(c) anglerfish
https://en.wikipedia.org/wiki/Anglerfish

```````````````````````````````````WSJ
Before there was Ozempic or Mounjaro, there were fish guts and Gila monsters.

The blockbuster diabetes drugs that have revolutionized obesity treatment seem to have come out of nowhere, turning the diet industry upside down in just the past year. But they didn’t arrive suddenly. They are the unlikely result of two separate bodies of science that date back decades and began with the study of two unsightly creatures: a carnivorous fish and a poisonous lizard.

In 1980, researchers at Massachusetts General Hospital wanted to use new technology to find the gene that encodes a hormone called glucagon. The team decided to study Anglerfish, which have special organs that make the hormone, simplifying the task of gathering samples of pure tissue.

They hired a Cape Cod fisherman to find the slimy bottom-feeders known for their sharp teeth and lightbulb-like lure. The fisherman tossed his catch on the dock, where two young scientists dissected “the ugliest fish you could ever imagine,” said Dick Goodman, one of those postdocs.

After plucking out organs the size of Lima beans with scalpels, they dropped them into liquid nitrogen and drove back to Boston. Then they determined the genetic sequence of glucagon, which is how they learned that the same gene encodes related hormones known as peptides. One of them was a key discovery that would soon be found in humans, too.

It was called glucagon-like peptide-1 and its nickname was GLP-1.

After they found GLP-1, others would determine its significance. Scientists in Massachusetts and Europe learned that it encourages insulin release and lowers blood sugar. That held out hope that it could help treat diabetes. Later they discovered that GLP-1 makes people feel fuller faster and slows down emptying of food from the stomach.

But there was a problem: GLP-1 vanishes from the human body nearly as fast as it is secreted, chewed up by enzymes and washed away by the kidneys in minutes. That meant there was little chance of developing the magic peptide into a drug.

To investigate whether it helped diabetics, scientists had to infuse GLP-1 intravenously. Studies showed it worked, lowering blood sugar. But some also foreshadowed the main side effect that plagues today’s GLP-1-mimicking drugs: nausea.

David Nathan, a MassGen physician scientist who led a 1991 study, still remembers what happened when they increased the dose: “One person leaned over the side of his chair and threw up on my shoes.”

The key to the first drug would come from a serendipitous discovery inside another odd-looking animal.

Around the time Goodman was cutting open fish, Jean-Pierre Raufman was studying insect and animal venoms to see if they stimulated digestive enzymes in mammals.

“We got a tremendous response from Gila monster venom,” he recalled.

It was a small discovery that could have been forgotten, but for a lucky break nearly a decade later when Raufman gave a lecture on that work at the Bronx Veterans Administration. John Eng, an expert in identifying peptides, was intrigued. The pair had collaborated on unrelated work a few years before. Eng proposed they study Gila monsters.

Native to the U.S. southwest, Gila monsters (pronounced: HEE-luh) are poisonous lizards measuring 20 inches with powerful jaws and black-and-orange beaded skin. Adults eat four meals per year, and live most of their lives below ground, slowly digesting energy stored in their tails.

Eng and Raufman studied powdered Gila monster venom ordered from the Miami Serpentarium, whose owner survived 172 snake bites over the years as he produced venom for research.

Eng isolated a small peptide that he called Exendin-4, which they found was similar to human GLP-1.

Eng then tested his new peptide on diabetic mice and found something intriguing: It not only reduced blood glucose, it did so for hours. If the same effect were to be observed in humans, it could be the key to turning GLP-1 into a meaningful advance in diabetes treatment, not just a seasickness simulator in an IV bag.

Hoping that he could sell it to a pharmaceutical company that would develop it into a drug, Eng filed for a patent in 1993.

Jens Juul Holst, a pioneering GLP-1 researcher, remembers standing in an exhibit hall at a European conference next to Eng. The two had put up posters that displayed their work, hoping top researchers would stop by to discuss it. But other scientists were skeptical that anything derived from a lizard would work in humans.

“He was extremely frustrated,” recalled Holst. “Nobody was interested in his work. None of the important people. It was too strange for people to accept.”

After three years, tens of thousands of dollars in patent-related fees and thousands of miles traveled, Eng found himself standing with his poster in San Francisco. This time, he caught the attention of Andrew Young, an executive from a small pharmaceutical company named Amylin.

“I saw the results in the mice and realized this could be druggable,” Young said.

When an Eli Lilly executive leaned over his shoulder to look at Eng’s work, Young worried he might miss his chance. Not long after, Amylin licensed the patent.

They worked to develop Exendin-4 into a drug by synthesizing the Gila monster peptide. They weren’t sure what would happen in humans. “We couldn’t predict weight loss or weight gain with these drugs,” recalled Young. “They enhance insulin secretion. Usually that increases body weight.” But the effect on slowing the stomach’s processing of food was more pronounced and Young’s team found as they tested their new drug that it caused weight loss.

To get a better understanding of Exendin-4, Young consulted with Mark Seward, a dentist raising more than 100 Gila monsters in his Colorado Springs, Colo., basement. The lizard enthusiast’s task was to feed them and draw blood. One took exception to the needle in its tail, slipped its restraint and snapped its teeth on Seward’s palm—the only time he’s been bitten in the decades he’s raised the animals. “It’s like a wasp sting,” he said, “but much worse.”

Nine years after the chance San Francisco meeting between Eng and Young, the Food and Drug Administration approved the first GLP-1-based treatment in 2005.

The twice-daily injection remained in the bloodstream for hours, helping patients manage Type 2 diabetes. Eng would be paid royalties as high as $6.7 million per year for the drug, according to federal government data available after 2015. “It was a long journey,” said Eng.  

The proof of concept pushed other pharmaceutical companies to make more-effective and longer-lasting GLP-1 drugs.

At first, Novo Nordisk executives had little interest in GLP-1 drugs. They gave priority to Novo’s main business of selling insulin.  “A lot of people didn’t believe in it,” says Jens Larsen, international medical director for the Danish company. He stopped his own mid-1990s study of IV-infused GLP-1 when patients on a higher dose started vomiting. The research was shelved until 2001.

The Gila monster-derived drug gave them a push, said Larsen: “It made companies more aware that this could be a serious competitor and we had to step up and put more people on it.”

Novo kept at it, working on its own drug that more closely resembled the human peptide. With some clever chemistry it bumped up this drug’s time in the body to a day. Its first GLP-1 drug, the once-daily shot liraglutide, would receive FDA approval in 2010.

Seven years later came its longer-lasting diabetes drug, the once-weekly shot semaglutide. As it turned out, it was also the best of the drugs for weight loss, making it the first blockbuster in the category. A higher dose was approved in 2021 to treat obesity.

Those two approved doses are better known today by their brand names: Ozempic and Wegovy.



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沙发
 楼主| 发表于 7-15-2023 12:39:34 | 只看该作者
本帖最后由 choi 于 7-17-2023 15:09 编辑

(2) anglerfish
(a) Habener Receives Gairdner Award. Harvard Medical School, Apr 17, 2021
https://hms.harvard.edu/news/habener-receives-gairdner-award

Quote:

(i) "Joel Habener, Harvard Medical School professor of medicine and director of the Laboratory of Molecular Endocrinology at Massachusetts General Hospital is one of three scientists awarded a 2021 Canada Gairdner International Award for research on glucagon-like peptides that has led to major advances in the treatment of type 2 diabetes, obesity, and intestinal disorders.

"Habener is being honored for the work with Daniel Drucker, professor of medicine at the University of Toronto and a senior scientist at the Lunenfeld-Tanenbaum Research Institute in Toronto, and Jens Juul Holst, professor of biomedical sciences and group leader at the Novo Nordisk Foundation Center for Basic Metabolic Research at the University of Copenhagen, Denmark.

(ii) "In the 1970s, Holst recorded intestinal surgery patients experiencing insulin spikes and drops in blood sugar after meals, leading him to conclude that an incretin, subsequently identified as GLP-1, along with insulin and glucagon was responsible for the glucose-induced gastrointestinal stimulation of insulin secretion that caused the changes in blood sugar levels.

"Around the same time, Habener used pancreatic cells from anglerfish to demonstrate that glucagon and somatostatin were encoded in the pancreatic cells as larger, precursor hormones.

"During additional mammal studies, Habener discovered two new hormones related to glucagon which are known as GLP-1 and GLP-2.

"Drucker, a fellow in Habener’s lab in the 1980s, outlined the processing of proglucagon and the biology of GLP-1 action on insulin-producing cells, which led to the development of multiple types of treatments for type 2 diabetes.

(b) Müller TD et al (which included Holst, Habener and Drucker), Glucagon-like peptide 1 (GLP-1). Molecular Metabolism (2019) 30: 72
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6812410/
("It was subsequently found by Ellis Samols and Vincent Marks in 1966 and confirmed by others that glucagon-like immunoreactivity was also present in extra-pancreatic tissues, in particular in the intestine. * * * Further corroborating the distinct nature of the intestinal and pancreatic glucagon-like material, immunocytochemical studies revealed that the intestinal cells that stained positive for the glucagon antibody differed from the pancreatic glucagon-producing α-cells in terms of their morphology and ultrastructure * * * Habener established that a different glucagon-related peptide is encoded within the anglerfish preproglucagon cDNA -in other words, anglerfish has one glutagon and one G, whereas all mammalians have three: glucagon, GLP- amd GLP-2]. Two glucagon-related peptides were subsequently identified in the rat, hamster, bovine, and human proglucagon sequence")  (citations omitted)

Note:
(i) Right after the above quotation is Fog 1, showing the full-length proglutagon peptide is cleaved by two enzymes into, among other things, glutagon (secreted by pancreas), GLP-1 or GLP-2 (the last two secreted by intestine). Thus, the observation in (2)(a0 was caused by release of GLP from intestine.
(ii) glucagon-like peptide-1
https://en.wikipedia.org/wiki/Glucagon-like_peptide-1
("In the pancreas (α-cells of the islets of Langerhans), proglucagon is cleaved by prohormone convertase (PC) 2 producing * * * glucagon * * * In the gut and brain, proglucagon is catalysed by PC 1/3 giving rise to * * * GLP-1 * * * and glucagon-like peptide-2 (GLP-2)")
(iii) For amino acid sequence similarity in glucagon superfamily, see the last illustration of Joel F Habener and Timothy J Kieffer, Glucagon and Glucagon-like Peptides. Oncohema Key, undated
https://oncohemakey.com/glucagon-and-glucagon-like-peptides/


(3) Gila monster
(a) Diabetes Drug from Gila Monster Venom. Office of Research & Development, US Department of Veterans Affairs, May 7, 2019 (under the heading 'VA research in action')
https://www.research.va.gov/rese ... a-monster-venom.cfm

Note:
(i) J Eng et al, Purification and structure of exendin-3, a new pancreatic secretagogue isolated from Heloderma horridum venom. J Biol Chem (1990) 265: 20259
https://www.sciencedirect.com/sc ... i/S0021925817304982
(introduction in full: "The glucagon superfamily consists of a diverse group of biologically active peptides that are structurally related by having an amino-terminal histidine residue (His1) and a phenylalanine residue at position 6 (Phe6) (1) or one of several variant structures such as Tyr1-Phe6 (2, 3), His1-Tyr6 (4), or His1-Leu6 (5). An assay for His1 can potentially be used to identify peptides belonging to this family. Although special chemical methods have been reported for the detection of His1 peptides (6, 7), a more general method of assaying for His1 is amino-terminal amino acid sequencing. This assay was used recently to monitor the purification of glucagon from chinchilla pancreas (8). To test the hypothesis that His1 is a chemical marker for biologically active peptides, amino-terminal sequencing was used to screen for new His1 peptides that might be members of the glucagon superfamily. Gila monster venom was chosen for screening because venoms from Heloderma suspectum and Heloderma horridurn had been shown previously to contain two biologically active His1-Phe6 peptides, helospectin (9) and helodermin (10). When H horridum venom was examined with the His1 assay, a previously unrecognized His1-Phe6 peptide was detected. In this study, we report the purification and structural characterization of this new peptide. It is named exendin-3 to identify it as the third peptide found in an exocrine secretion of Heloderma lizards which has endocrine activity. Like the earlier exendins, it is a pancreatic secretagogue")
explains both the rationale to look for glucagon-like peptides in the venom of Gila monster (by sequencing peptides and searching those with histidine at the amino terminal) AND origin of the name exendin ("peptide found in an EXocrine secretion of Heloderma lizards which has ENdocrine activity")
(ii) Approved by FDA in 2005 to treat diabetes type 2, exenatide (developed by Amylin Pharmaceuticals, Inc, and Eli Lilly and Co) is the synthetic version of exendin-4.
(iii) Obviously born in the US, John Eng is an MD who treats patients but did research on the side.

(3)(b) Dr John Eng's Research Found That the Saliva of the Gila Monster Contains a Hormone That Treats Diabetes Better Than Any Other Medicine. Diabetes in Control, Sept. 18, 2007
https://www.diabetesincontrol.co ... any-other-medicine/


(4)
(a) semaglutide
https://en.wikipedia.org/wiki/Semaglutide
(sold under the brand names Ozempic, Wegovy)

section 5 Structure and pharmacology explains the difference between GLP-1 and semaglutide: "Semaglutide is chemically similar to human GLP-1. The first six amino acids of GLP-1 are missing. Substitutions are made at GLP positions 8 and 34 (semaglutide positions 2 and 28), where alanine and lysine are replaced by 2-aminoisobutyric acid and arginine, respectively. The substitution of the alanine prevents chemical breakdown by dipeptidyl peptidase-4. The lysine at GLP position 26 (semaglutide position 20) has a long chain attached, ending with a chain of 17 carbon atoms and a carboxyl group. This increases the drug's binding to blood protein (albumin), which enables longer presence in the blood circulation [because dipeptidyl peptidase-4 can not readily access semaglutide]." (citation omitted)

The last portion of semaglutide (-glutide) means glucagon-like peptide.
(b) A Comparison of Safety and Efficacy of Semaglutide vs Exenatide ER. Diabetes in Control, Feb 10, 2018
https://www.diabetesincontrol.co ... de-vs-exenatide-er/
("Semaglutide has a 94% similarity to human GLP-1, while its comparator exenatide ER has only 53% homology. Both agents are once-weekly subcutaneous injections. The Semaglutide Unabated Sustainability in Treatment of Type 2 Diabetes (SUSTAIN) 3 trial targeted both semaglutide and exenatide ER to compare their safety and efficacy to one another. * * * Results showed that efficacy of semaglutide was superior to exenatide for the improvement of glycemic control and reducing body weight")
(c) In retrospect, there was no particular reason that anglerfish (to clone the gene for GLP) or Gila monster (to identify the exendins peptides) was chosen. Perhaps any other animals will do.
(d) Joel F Habene cloned the GLP (along with glucagon) from anglerfish's islets of Langerhans, not gut -- and reported the findings in Proc Natl Acad Sci (1982) 79: 345.
(e) Tirzepatide, synthetic and sold under the Eli Lilly brand name mounjaro, also causes weight loss.
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