In memoriam: Roger Guillemin, neuroendocrinologist, Nobel Prize in physiology or medicine

IF 3.3 4区 医学 Q2 ENDOCRINOLOGY & METABOLISM Journal of Neuroendocrinology Pub Date : 2024-05-31 DOI:10.1111/jne.13419
Sebastien G. Bouret, Hubert Vaudry, Vincent Prevot
{"title":"In memoriam: Roger Guillemin, neuroendocrinologist, Nobel Prize in physiology or medicine","authors":"Sebastien G. Bouret,&nbsp;Hubert Vaudry,&nbsp;Vincent Prevot","doi":"10.1111/jne.13419","DOIUrl":null,"url":null,"abstract":"<p>Roger Guillemin was born in Dijon, Burgundy (France) on January 11, 1924. In 1942, he began studying Medicine at the University of Burgundy. After a mandatory break during World War I, he obtained his medical degree from the Faculty of Medicine of Lyon in 1949.</p><p>He began to practice as a family doctor, during which he acquired many excellent memories. However, he also quickly realized the limitations of medicine at that time. He recalled that he “could only prescribe three types of medicine, one of which being aspirin.” His scientific curiosity made him read specialized journals, which made him aware of Hans Selye's research in Montreal on the “General Adaptation Syndrome,” now known as the endocrine reaction of the organism to stress. He heard that the Canadian professor was invited to give a series of lectures at the Pitié Hospital and decided to attend his talks. Fortunately, Hans Selye presented his lectures in French, as Roger Guillemin did not speak English at that time. At the end of the third lecture, he introduced himself to Pr. Selye and asked him if he could join his lab for a year to prepare for his medical doctorate. Roger Guillemin left his native Burgundy and flew to Montreal. During his stay in Pr. Selye's laboratory, he first prepared a medical thesis, followed by a PhD in Physiology, specializing in Experimental Endocrinology, which he obtained in 1953.</p><p>Pr. Selye was the head of the Institute of Experimental Medicine and Surgery, where he established a series of lectures called “The Claude Bernard Lectures” inviting internationally renowned researchers. This is how Roger Guillemin met Geoffrey Harris, who is nowadays considered the father of Neuroendocrinology. Through various approaches of electrical stimulation, ligation or section of the pituitary stalk, and pituitary transplantation, Pr. Harris demonstrated a key role of the portal system in the relationship between the hypothalamus and the adenohypophysis.<span><sup>1</sup></span> Harris's work made it possible to understand how the “first mediators” (according to Selye's terminology), which will later be called “releasing factors,” reached the pituitary cells. The objective of Roger Guillemin was now clear: to chemically identify hypothalamic factors that govern the anterior pituitary's function, starting with the neural mediator suspected by Hans Selye controlling the hypothalamic–pituitary–adrenal axis.</p><p>Hans Selye's laboratory did not have the equipment and expertise to identify chemical factors governing the anterior pituitary function. Roger Guillemin decided to move to the Department of Physiology of Baylor College in Houston, Texas, which was headed by Hebbel Hoff. However, Roger Guillemin did not have the expertise to purify the hypothalamic factors he was looking for. Therefore, he teamed up with talented (bio)chemists, including Walter Hearn, with whom he used paper chromatography on a few dozen sheep hypothalami with the hope of isolating the famous “first mediator” of Hans Selye. Unfortunately, this method proved not sensitive enough to detect pituitary hormones. It became evident to Roger Guillemin that he had to collect a much larger quantity of tissue samples with all the organization that goes with it. He also switched to liquid gel chromatography, a more sensitive method that Viktor Mutt used successfully at the Karolinska Institute to purify peptides from the porcine digestive tract.<span><sup>2</sup></span></p><p>Concomitantly, he was offered a position as associate director of the Experimental Endocrinology laboratory directed by Robert Courrier at the Collège de France. He, therefore, moved to Paris with his wife Lucienne Billard, whom he met during his tenure in Hans Selye's lab. However, Hebbel Hoff insisted that Roger kept his laboratory at Baylor active, where he could rely on Andrew Schally to carry out the analytical steps and Harry Lipscomb for the biological tests. At the Collège de France, he teamed up with a Polish chemist, Marian Jutisz, who would later play an important role in the French Society of Neuroendocrinology (SNE), and Edouard Sakiz, the future CEO of the Roussel-Uclaf pharmaceutical company. Roger Guillemin outsourced the collection of several hundred thousands sheep hypothalamic to a private Parisian company. He also decided to stop the search for corticotropin-releasing factor (CRF) temporarily and to focus on thyrotropin-releasing factor (TRF), for which he developed a more straightforward biological test based on the incorporation of radioactive iodine into co-cultures of pituitary and thyroid.</p><p>After these 3 years in Paris, Guillemin returned with his family to Houston, TX, carrying the lyophilized extracts of about half a million hypothalami in his luggage. Wylie Vale joined the laboratory with the initial mission to collect thousands of additional hypothalami in the San Antonio slaughterhouses. He then developed a revolutionary method of primary cultures of pituitary cells which was combined with a very sensitive radioimmunoassay developed by Solomon Berson and Rosalyn Yalow. In 1965, Guillemin recruited the chemist Roger Burgus, a student of Walter Hearn, who had expertise with new mass spectrometry techniques. After 14 years of hard work, Guillemin and his team's efforts finally paid off with the purification and elucidation of the sequence of sheep TRF. As a side note, the article reporting this fundamental discovery was first rejected by the journal <i>Science</i> in February 1969, and the results were finally published in the Comptes Rendus de l'Académie des Sciences de Paris on April 21, 1969<span><sup>3</sup></span> and then in the journal <i>Nature</i> on April 24, 1970.<span><sup>4</sup></span></p><p>This discovery had a considerable impact on the academic community, and Guillemin was immediately offered several positions to set up his laboratory on various American campuses. It was ultimately Jonas Salk, a researcher who discovered the first safe and effective vaccine against polio, who convinced Guillemin to leave Houston, TX, and move his lab to La Jolla, CA, in the recently built oceanfront building by the architect Louis Kahn. Guillemin was seduced as much by the elegance of the building as by the announced launch of two new research programs within the Institute, one in Neuroscience and the other in the Biology of birth control. In June 1970, his entire team moved to the Neuroendocrinology laboratory, which was created especially for them at the Salk Institute. Several new collaborators joined them, including Catherine Rivier, who completed her PhD thesis in physiology, her husband Jean Rivier, an expert in high-field NMR, and Nicholas Ling. This newly established team decided to undertake the characterization of the gonadotropin-releasing factor, also known as the LH-releasing factor or LRF. All the tools were available to Guillemin's team, from the pituitary cell cultures to the radioimmunoassay of LH, to screen the fractions saved during the purification of the TRF. In July 1971, the first article was published in Biochemical and Biophysical Research Communications describing the overall amino acid composition of a nonapeptide, in which the tryptophan residue was missing.<span><sup>5</sup></span> In January 1972, the full sequence of ovine LRF was finally reported in Proceedings of the National Academy of Sciences (PNAS),<span><sup>6</sup></span> just a few months after the description of the porcine TRF by Schally's team.<span><sup>7</sup></span> The first neuroanatomical description of peptidergic neurons distribution in the brain was subsequently published in 1973 by Julien Barry in Lille for LRF.<span><sup>8</sup></span></p><p>It was known that a lesion of the ventromedial region of the rat hypothalamus caused growth arrest, indicating the existence of a nerve factor stimulating the release of growth hormone. The purification of this new neurohormone from hypothalamic extracts seemed possible based on the well-mastered technique of primary pituitary cell cultures of Wylie Vale, combined with the radioimmunoassay of GH developed by Paul Brazeau. Surprisingly, the obtained active fractions only had inhibitory effects on GH release, leading Guillemin and his team to conclude that the extracts contained an inhibitory factor of GH secretion. Roger Burgus identified the sequence of this inhibitory peptide, and Jean Rivier synthesized it. The primary structure of this cyclic tetradecapeptide, called somatostatin, was published in PNAS in January 1973.<span><sup>9</sup></span> In addition to its inhibitory effect on GH release, it became clear that somatostatin also blocked insulin and glucagon secretion in primates. Roger Guillemin discussed this discovery with one of the best French morphologists of the time, Maurice Dubois, who later demonstrated by immunohistochemistry the presence of somatostatin-immunoreactivity in delta cells of Langerhans islets. This fundamental observation marked the starting point of a very fruitful new field of research on the expression and role of hypothalamic neuropeptides outside the brain.</p><p>But Guillemin was still searching for the GH-releasing factor. He knew that the injection of morphine caused an increase in circulating GH in humans and became intrigued with the discovery of John Hughes and Hans Kosterlitz, who identified two pentapeptides with morphine-mimetic activity. Was it possible that these enkephalins would be good candidates? In their 1975 publication in Nature,<span><sup>10</sup></span> Hughes and Kosterlitz pointed out that the sequence of Met-enkephalin corresponds to that of the 61–65 region of β-LPH characterized 10 years earlier by Michel Chrétien and Choh Hao Li. Guillemin, therefore, decided to search for peptides with opioid properties in his lyophilized samples and managed to isolate several active fractions that he named α-, β-, and γ-endorphins, all bearing the sequence of Met-enkephalin at the N-terminal position. In September 1976, Ling and Guillemin published in PNAS the sequence of β-endorphin, a 31-amino acid peptide whose morphine-mimetic activity is five times greater than that of Met-enkephalin.<span><sup>11</sup></span> However, β-endorphin stimulated GH release in vivo but did not affect GH secretion on pituitary cells in culture. The nature of GHRH was, therefore, still enigmatic.</p><p>In 1977, Roger Guillemin received the Nobel Prize in Physiology or Medicine, which he shared with Andrew Schally, for “their discoveries concerning the production of peptide hormones by the brain,” and with Rosalyn Yalow for “the development of radioimmunoassays for peptide hormones.” Guillemin recalled: “A month before the official ceremony, I received instructions about the one-hour lecture I would have to present. Then, three weeks later, I was informed that the duration would be reduced to 45 minutes. Finally, the day before the ceremony, while I was already in Stockholm, I was told that since Rosalyn Yalow and Andrew Schally were intervening the same day, my speaking time was now only 30 minutes. It was a unique experience to apprehend the mechanisms of the neuroendocrine response to stress!”</p><p>The beloved “first mediator” of Hans Selye, CRF, was finally characterized in 1981 by Roger Guillemin's former student, Wylie Vale.<span><sup>12</sup></span> Vale's team then isolated several urocortins, paralogous peptides of CRF, and orthologs of urotensin I extracted by Karl Lederis from the urophysis of teleost fish.<span><sup>13</sup></span></p><p>The isolation of GHRH took a very different path from that taken for the other four hypophysiotropic neuropeptides since Geneviève Sassolas carried out its identification from a pancreatic tumor of a patient with acromegaly. The sequences of the different molecular forms of GHRH were published a few days apart, in November 1982, by Guillemin's team in Science and Vale's team in Nature.<span><sup>14, 15</sup></span> The identification of the main hypophysiotropic neurohormones finally ended after nearly 40 years of research!</p><p>Guillemin and his team then turned to two other families of polypeptide mediators, fibroblast growth factor (FGF) and inhibin. These new research programs resulted in the concurrent publication of two foundational articles describing the primary structure of basic FGF, a 146-amino acid polypeptide (PNAS, May 1986),<span><sup>16</sup></span> and the characterization of inhibin and activin, two heterodimers of the TGF-β family.<span><sup>17</sup></span></p><p>Roger Guillemin maintained solid ties with the French research community throughout his career. He and his trainees welcomed many talented researchers in their laboratories, such as Bertrand Bloch, David Chatenet, Pierre Mormède, Jean-Louis Nahon, Françoise Presse, Jean Rossier, and Edouard Sakiz, to name a few. He served as President of the French Society of Endocrinology from 1982 to 1983, and awarded the first annual SFE Prize at the Marseille congress. He was elected a foreign member of the French Academy of Sciences in 1984. He was the guest of honor at the International Congress of Neuroendocrinology held in Rouen in July 2010, where he gave the inaugural lecture. He received honorary doctorates from several French universities, including Burgundy and Franche-Comté. In 2015, he was promoted to the rank of Commandeur de la Légion d'Honneur.</p><p>Roger Guillemin was not only a visionary, but also a remarkable talent-spotter who surrounded himself with the brightest scientists, many of whom have, in turn, become leaders in Neuroendocrinology. He and his collaborators generously provided reagents such as peptides and antibodies to all researchers who requested them without compensation. Fred Gage, a former Director of the Salk Institute, said: “Roger has been very supportive and generous with his encouragement and advice to me and many scientists he has helped.”</p><p>In addition to being a humanist medical doctor, an eminent researcher, and a brilliant speaker, Roger Guillemin was also an enlightened art lover. He was a recognized artist for his flamboyant digital paintings. His wife Lucienne was a talented musician, and five of their children also embraced artistic careers. Throughout his professional life, Roger Guillemin managed to maintain a good balance between his two passions: science and family.</p><p>Roger Guillemin will be missed but his name and contribution to Science, Medicine, and Neuroendocrinology will stay forever.</p><p><b>Sebastien G. Bouret:</b> Writing – original draft; writing – review and editing. <b>Hubert Vaudry:</b> Writing – original draft; writing – review and editing. <b>Vincent Prevot:</b> Writing – original draft; writing – review and editing.</p><p>The authors declare no conflicts of interest.</p>","PeriodicalId":16535,"journal":{"name":"Journal of Neuroendocrinology","volume":null,"pages":null},"PeriodicalIF":3.3000,"publicationDate":"2024-05-31","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/jne.13419","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Neuroendocrinology","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/jne.13419","RegionNum":4,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ENDOCRINOLOGY & METABOLISM","Score":null,"Total":0}
引用次数: 0

Abstract

Roger Guillemin was born in Dijon, Burgundy (France) on January 11, 1924. In 1942, he began studying Medicine at the University of Burgundy. After a mandatory break during World War I, he obtained his medical degree from the Faculty of Medicine of Lyon in 1949.

He began to practice as a family doctor, during which he acquired many excellent memories. However, he also quickly realized the limitations of medicine at that time. He recalled that he “could only prescribe three types of medicine, one of which being aspirin.” His scientific curiosity made him read specialized journals, which made him aware of Hans Selye's research in Montreal on the “General Adaptation Syndrome,” now known as the endocrine reaction of the organism to stress. He heard that the Canadian professor was invited to give a series of lectures at the Pitié Hospital and decided to attend his talks. Fortunately, Hans Selye presented his lectures in French, as Roger Guillemin did not speak English at that time. At the end of the third lecture, he introduced himself to Pr. Selye and asked him if he could join his lab for a year to prepare for his medical doctorate. Roger Guillemin left his native Burgundy and flew to Montreal. During his stay in Pr. Selye's laboratory, he first prepared a medical thesis, followed by a PhD in Physiology, specializing in Experimental Endocrinology, which he obtained in 1953.

Pr. Selye was the head of the Institute of Experimental Medicine and Surgery, where he established a series of lectures called “The Claude Bernard Lectures” inviting internationally renowned researchers. This is how Roger Guillemin met Geoffrey Harris, who is nowadays considered the father of Neuroendocrinology. Through various approaches of electrical stimulation, ligation or section of the pituitary stalk, and pituitary transplantation, Pr. Harris demonstrated a key role of the portal system in the relationship between the hypothalamus and the adenohypophysis.1 Harris's work made it possible to understand how the “first mediators” (according to Selye's terminology), which will later be called “releasing factors,” reached the pituitary cells. The objective of Roger Guillemin was now clear: to chemically identify hypothalamic factors that govern the anterior pituitary's function, starting with the neural mediator suspected by Hans Selye controlling the hypothalamic–pituitary–adrenal axis.

Hans Selye's laboratory did not have the equipment and expertise to identify chemical factors governing the anterior pituitary function. Roger Guillemin decided to move to the Department of Physiology of Baylor College in Houston, Texas, which was headed by Hebbel Hoff. However, Roger Guillemin did not have the expertise to purify the hypothalamic factors he was looking for. Therefore, he teamed up with talented (bio)chemists, including Walter Hearn, with whom he used paper chromatography on a few dozen sheep hypothalami with the hope of isolating the famous “first mediator” of Hans Selye. Unfortunately, this method proved not sensitive enough to detect pituitary hormones. It became evident to Roger Guillemin that he had to collect a much larger quantity of tissue samples with all the organization that goes with it. He also switched to liquid gel chromatography, a more sensitive method that Viktor Mutt used successfully at the Karolinska Institute to purify peptides from the porcine digestive tract.2

Concomitantly, he was offered a position as associate director of the Experimental Endocrinology laboratory directed by Robert Courrier at the Collège de France. He, therefore, moved to Paris with his wife Lucienne Billard, whom he met during his tenure in Hans Selye's lab. However, Hebbel Hoff insisted that Roger kept his laboratory at Baylor active, where he could rely on Andrew Schally to carry out the analytical steps and Harry Lipscomb for the biological tests. At the Collège de France, he teamed up with a Polish chemist, Marian Jutisz, who would later play an important role in the French Society of Neuroendocrinology (SNE), and Edouard Sakiz, the future CEO of the Roussel-Uclaf pharmaceutical company. Roger Guillemin outsourced the collection of several hundred thousands sheep hypothalamic to a private Parisian company. He also decided to stop the search for corticotropin-releasing factor (CRF) temporarily and to focus on thyrotropin-releasing factor (TRF), for which he developed a more straightforward biological test based on the incorporation of radioactive iodine into co-cultures of pituitary and thyroid.

After these 3 years in Paris, Guillemin returned with his family to Houston, TX, carrying the lyophilized extracts of about half a million hypothalami in his luggage. Wylie Vale joined the laboratory with the initial mission to collect thousands of additional hypothalami in the San Antonio slaughterhouses. He then developed a revolutionary method of primary cultures of pituitary cells which was combined with a very sensitive radioimmunoassay developed by Solomon Berson and Rosalyn Yalow. In 1965, Guillemin recruited the chemist Roger Burgus, a student of Walter Hearn, who had expertise with new mass spectrometry techniques. After 14 years of hard work, Guillemin and his team's efforts finally paid off with the purification and elucidation of the sequence of sheep TRF. As a side note, the article reporting this fundamental discovery was first rejected by the journal Science in February 1969, and the results were finally published in the Comptes Rendus de l'Académie des Sciences de Paris on April 21, 19693 and then in the journal Nature on April 24, 1970.4

This discovery had a considerable impact on the academic community, and Guillemin was immediately offered several positions to set up his laboratory on various American campuses. It was ultimately Jonas Salk, a researcher who discovered the first safe and effective vaccine against polio, who convinced Guillemin to leave Houston, TX, and move his lab to La Jolla, CA, in the recently built oceanfront building by the architect Louis Kahn. Guillemin was seduced as much by the elegance of the building as by the announced launch of two new research programs within the Institute, one in Neuroscience and the other in the Biology of birth control. In June 1970, his entire team moved to the Neuroendocrinology laboratory, which was created especially for them at the Salk Institute. Several new collaborators joined them, including Catherine Rivier, who completed her PhD thesis in physiology, her husband Jean Rivier, an expert in high-field NMR, and Nicholas Ling. This newly established team decided to undertake the characterization of the gonadotropin-releasing factor, also known as the LH-releasing factor or LRF. All the tools were available to Guillemin's team, from the pituitary cell cultures to the radioimmunoassay of LH, to screen the fractions saved during the purification of the TRF. In July 1971, the first article was published in Biochemical and Biophysical Research Communications describing the overall amino acid composition of a nonapeptide, in which the tryptophan residue was missing.5 In January 1972, the full sequence of ovine LRF was finally reported in Proceedings of the National Academy of Sciences (PNAS),6 just a few months after the description of the porcine TRF by Schally's team.7 The first neuroanatomical description of peptidergic neurons distribution in the brain was subsequently published in 1973 by Julien Barry in Lille for LRF.8

It was known that a lesion of the ventromedial region of the rat hypothalamus caused growth arrest, indicating the existence of a nerve factor stimulating the release of growth hormone. The purification of this new neurohormone from hypothalamic extracts seemed possible based on the well-mastered technique of primary pituitary cell cultures of Wylie Vale, combined with the radioimmunoassay of GH developed by Paul Brazeau. Surprisingly, the obtained active fractions only had inhibitory effects on GH release, leading Guillemin and his team to conclude that the extracts contained an inhibitory factor of GH secretion. Roger Burgus identified the sequence of this inhibitory peptide, and Jean Rivier synthesized it. The primary structure of this cyclic tetradecapeptide, called somatostatin, was published in PNAS in January 1973.9 In addition to its inhibitory effect on GH release, it became clear that somatostatin also blocked insulin and glucagon secretion in primates. Roger Guillemin discussed this discovery with one of the best French morphologists of the time, Maurice Dubois, who later demonstrated by immunohistochemistry the presence of somatostatin-immunoreactivity in delta cells of Langerhans islets. This fundamental observation marked the starting point of a very fruitful new field of research on the expression and role of hypothalamic neuropeptides outside the brain.

But Guillemin was still searching for the GH-releasing factor. He knew that the injection of morphine caused an increase in circulating GH in humans and became intrigued with the discovery of John Hughes and Hans Kosterlitz, who identified two pentapeptides with morphine-mimetic activity. Was it possible that these enkephalins would be good candidates? In their 1975 publication in Nature,10 Hughes and Kosterlitz pointed out that the sequence of Met-enkephalin corresponds to that of the 61–65 region of β-LPH characterized 10 years earlier by Michel Chrétien and Choh Hao Li. Guillemin, therefore, decided to search for peptides with opioid properties in his lyophilized samples and managed to isolate several active fractions that he named α-, β-, and γ-endorphins, all bearing the sequence of Met-enkephalin at the N-terminal position. In September 1976, Ling and Guillemin published in PNAS the sequence of β-endorphin, a 31-amino acid peptide whose morphine-mimetic activity is five times greater than that of Met-enkephalin.11 However, β-endorphin stimulated GH release in vivo but did not affect GH secretion on pituitary cells in culture. The nature of GHRH was, therefore, still enigmatic.

In 1977, Roger Guillemin received the Nobel Prize in Physiology or Medicine, which he shared with Andrew Schally, for “their discoveries concerning the production of peptide hormones by the brain,” and with Rosalyn Yalow for “the development of radioimmunoassays for peptide hormones.” Guillemin recalled: “A month before the official ceremony, I received instructions about the one-hour lecture I would have to present. Then, three weeks later, I was informed that the duration would be reduced to 45 minutes. Finally, the day before the ceremony, while I was already in Stockholm, I was told that since Rosalyn Yalow and Andrew Schally were intervening the same day, my speaking time was now only 30 minutes. It was a unique experience to apprehend the mechanisms of the neuroendocrine response to stress!”

The beloved “first mediator” of Hans Selye, CRF, was finally characterized in 1981 by Roger Guillemin's former student, Wylie Vale.12 Vale's team then isolated several urocortins, paralogous peptides of CRF, and orthologs of urotensin I extracted by Karl Lederis from the urophysis of teleost fish.13

The isolation of GHRH took a very different path from that taken for the other four hypophysiotropic neuropeptides since Geneviève Sassolas carried out its identification from a pancreatic tumor of a patient with acromegaly. The sequences of the different molecular forms of GHRH were published a few days apart, in November 1982, by Guillemin's team in Science and Vale's team in Nature.14, 15 The identification of the main hypophysiotropic neurohormones finally ended after nearly 40 years of research!

Guillemin and his team then turned to two other families of polypeptide mediators, fibroblast growth factor (FGF) and inhibin. These new research programs resulted in the concurrent publication of two foundational articles describing the primary structure of basic FGF, a 146-amino acid polypeptide (PNAS, May 1986),16 and the characterization of inhibin and activin, two heterodimers of the TGF-β family.17

Roger Guillemin maintained solid ties with the French research community throughout his career. He and his trainees welcomed many talented researchers in their laboratories, such as Bertrand Bloch, David Chatenet, Pierre Mormède, Jean-Louis Nahon, Françoise Presse, Jean Rossier, and Edouard Sakiz, to name a few. He served as President of the French Society of Endocrinology from 1982 to 1983, and awarded the first annual SFE Prize at the Marseille congress. He was elected a foreign member of the French Academy of Sciences in 1984. He was the guest of honor at the International Congress of Neuroendocrinology held in Rouen in July 2010, where he gave the inaugural lecture. He received honorary doctorates from several French universities, including Burgundy and Franche-Comté. In 2015, he was promoted to the rank of Commandeur de la Légion d'Honneur.

Roger Guillemin was not only a visionary, but also a remarkable talent-spotter who surrounded himself with the brightest scientists, many of whom have, in turn, become leaders in Neuroendocrinology. He and his collaborators generously provided reagents such as peptides and antibodies to all researchers who requested them without compensation. Fred Gage, a former Director of the Salk Institute, said: “Roger has been very supportive and generous with his encouragement and advice to me and many scientists he has helped.”

In addition to being a humanist medical doctor, an eminent researcher, and a brilliant speaker, Roger Guillemin was also an enlightened art lover. He was a recognized artist for his flamboyant digital paintings. His wife Lucienne was a talented musician, and five of their children also embraced artistic careers. Throughout his professional life, Roger Guillemin managed to maintain a good balance between his two passions: science and family.

Roger Guillemin will be missed but his name and contribution to Science, Medicine, and Neuroendocrinology will stay forever.

Sebastien G. Bouret: Writing – original draft; writing – review and editing. Hubert Vaudry: Writing – original draft; writing – review and editing. Vincent Prevot: Writing – original draft; writing – review and editing.

The authors declare no conflicts of interest.

查看原文
分享 分享
微信好友 朋友圈 QQ好友 复制链接
本刊更多论文
悼念诺贝尔生理学或医学奖获得者、神经内分泌学家罗杰-吉勒明。
Roger Guillemin 于 1924 年 1 月 11 日出生于法国勃艮第的第戎。1942 年,他开始在勃艮第大学学习医学。第一次世界大战期间,他不得不中断学业,之后于 1949 年获得里昂医学院医学学位。然而,他也很快意识到当时医学的局限性。他回忆说,他 "只能开三种药,其中一种是阿司匹林"。他对科学的好奇心让他阅读专业期刊,这让他了解到汉斯-塞利(Hans Selye)在蒙特利尔进行的 "一般适应综合征 "研究,也就是现在所说的机体对压力的内分泌反应。他听说这位加拿大教授受邀在皮蒂埃医院举办系列讲座,于是决定参加他的讲座。幸运的是,汉斯-塞利的讲座是用法语进行的,因为罗杰-吉列明当时还不会说英语。在第三场讲座结束时,他向汉斯-塞利教授做了自我介绍,并问他是否会说英语。在第三次讲座结束时,他向塞利教授做了自我介绍,并询问他是否可以加入他的实验室一年,为获得医学博士学位做准备。罗杰-吉耶明离开家乡勃艮第,飞往蒙特利尔。在塞利教授的实验室逗留期间在塞利教授的实验室工作期间,他首先撰写了医学论文,随后于1953年获得了生理学博士学位,专攻实验内分泌学。塞利教授当时是实验医学和外科研究所的所长,他在那里开设了一个名为 "克劳德-贝尔纳讲座 "的系列讲座,邀请国际知名研究人员参加。罗杰-吉列明也因此结识了如今被誉为神经内分泌学之父的杰弗里-哈里斯。通过电刺激、结扎或切除垂体柄以及垂体移植等各种方法,哈里斯教授证明了垂体门静脉的关键作用。1 哈里斯的工作使人们得以了解 "第一介质"(按照塞利的术语),即后来被称为 "释放因子",是如何到达垂体细胞的。现在,罗杰-吉列明的目标很明确:从汉斯-塞利怀疑的控制下丘脑-垂体-肾上腺轴的神经介质开始,用化学方法鉴定支配垂体前叶功能的下丘脑因子。汉斯-塞利的实验室不具备鉴定支配垂体前叶功能的化学因子的设备和专业知识。罗杰-吉列明决定转到得克萨斯州休斯顿贝勒学院的生理学系,该系由赫伯尔-霍夫领导。然而,Roger Guillemin 并不具备纯化他所寻找的下丘脑因子的专业知识。因此,他与沃尔特-赫恩(Walter Hearn)等才华横溢的(生物)化学家合作,在几十只绵羊下丘脑上使用纸层析法,希望分离出汉斯-塞利(Hans Selye)著名的 "第一介质"。遗憾的是,这种方法在检测垂体激素方面不够灵敏。罗杰-吉列明发现,他必须收集更大量的组织样本,并进行相应的组织处理。他还改用了液态凝胶色谱法,这是一种更灵敏的方法,维克多-穆特(Viktor Mutt)在卡罗林斯卡学院成功地使用这种方法从猪消化道中提纯多肽。因此,他带着妻子露西安娜-比拉尔(Lucienne Billard)搬到了巴黎,这是他在汉斯-塞利(Hans Selye)实验室任职期间认识的。不过,赫伯尔-霍夫坚持让罗杰继续留在贝勒的实验室工作,在那里他可以依靠安德鲁-沙利(Andrew Schally)完成分析步骤,依靠哈里-利普斯科姆(Harry Lipscomb)进行生物测试。在法兰西学院,他与波兰化学家玛丽安-尤蒂斯(Marian Jutisz)和爱德华-萨基兹(Edouard Sakiz)合作,前者后来在法国神经内分泌学会(SNE)中发挥了重要作用,后者则是未来的罗塞尔-乌克拉夫制药公司首席执行官。罗杰-吉列明将几十万只绵羊下丘脑的采集工作外包给了一家巴黎私人公司。他还决定暂时停止寻找促肾上腺皮质激素释放因子(CRF),转而关注促甲状腺激素释放因子(TRF),并为此开发了一种更简单的生物检测方法,即在垂体和甲状腺的共培养物中加入放射性碘。在巴黎度过 3 年后,吉列明带着行李中约 50 万个下丘脑的冻干提取物,举家返回德克萨斯州休斯顿。威利-维尔加入了实验室,最初的任务是在圣安东尼奥屠宰场再收集数千个下丘脑。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
求助全文
约1分钟内获得全文 去求助
来源期刊
Journal of Neuroendocrinology
Journal of Neuroendocrinology 医学-内分泌学与代谢
CiteScore
6.40
自引率
6.20%
发文量
137
审稿时长
4-8 weeks
期刊介绍: Journal of Neuroendocrinology provides the principal international focus for the newest ideas in classical neuroendocrinology and its expanding interface with the regulation of behavioural, cognitive, developmental, degenerative and metabolic processes. Through the rapid publication of original manuscripts and provocative review articles, it provides essential reading for basic scientists and clinicians researching in this rapidly expanding field. In determining content, the primary considerations are excellence, relevance and novelty. While Journal of Neuroendocrinology reflects the broad scientific and clinical interests of the BSN membership, the editorial team, led by Professor Julian Mercer, ensures that the journal’s ethos, authorship, content and purpose are those expected of a leading international publication.
期刊最新文献
Hypothalamic-pituitary-adrenal axis plasticity across life-history stages of a free-living subtropical finch, Amandava amandava amandava. Adolescent social stress alters the role of orexin innervation in the hindbrain in male hamsters. Activation of ionotropic and group I metabotropic glutamate receptors stimulates kisspeptin neuron activity in mice. Seasonal patterns of neurogenesis in European starlings (Sturnus vulgaris) are region- and sex-specific. Liver metastases in high-grade neuroendocrine neoplasms: A comparative study of hepatic tumor volume and biochemical findings in NET G3 versus NEC.
×
引用
GB/T 7714-2015
复制
MLA
复制
APA
复制
导出至
BibTeX EndNote RefMan NoteFirst NoteExpress
×
×
提示
您的信息不完整,为了账户安全,请先补充。
现在去补充
×
提示
您因"违规操作"
具体请查看互助需知
我知道了
×
提示
现在去查看 取消
×
提示
确定
0
微信
客服QQ
Book学术公众号 扫码关注我们
反馈
×
意见反馈
请填写您的意见或建议
请填写您的手机或邮箱
已复制链接
已复制链接
快去分享给好友吧!
我知道了
×
扫码分享
扫码分享
Book学术官方微信
Book学术文献互助
Book学术文献互助群
群 号:481959085
Book学术
文献互助 智能选刊 最新文献 互助须知 联系我们:info@booksci.cn
Book学术提供免费学术资源搜索服务,方便国内外学者检索中英文文献。致力于提供最便捷和优质的服务体验。
Copyright © 2023 Book学术 All rights reserved.
ghs 京公网安备 11010802042870号 京ICP备2023020795号-1