Marc H. V. van Regenmortel, a virtual friend and a real colleague

IF 2.3 4区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY
Vladimir N. Uversky
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However, I can add my voice to the discussion of how contingency or serendipity has led me to productively collaborate with Marc (unfortunately, exclusively in the on-line format), resulting in the publication of a joint paper in 2020.<span><sup>2</sup></span> Before moving to this part of my story, a short historical excurse is needed.</p><p>My first (once again, exclusively virtual) encounter with Marc took place in 2004, when he played a crucial role in our work on one of the first comprehensive reviews on the roles of intrinsically disordered proteins and regions (IDPs/IDRs) in molecular recognition, regulation, and cell signaling.<span><sup>3</sup></span> In the middle of 2004, I joined the Center for Computational Biology and Bioinformatics (CCBB) at the Indiana University-Purdue University at Indianapolis (IUPUI) that was created and headed by Prof. A. Keith Dunker, whom I worked with for 6 years on different aspects of the protein intrinsic disorder phenomenon. One of my first projects there was analysis of the then-available literature data on the functionality of intrinsic disorder.</p><p>By that time, it became clear that although IDPs/IDRs have been mostly ignored by the scientific community since the inception of the lock-and-key model by Hermann Emil Louis Fischer (1852–1919) in 1894,<span><sup>4, 5</sup></span> many aspects of protein functionality could not be explained using this important model and its associated sequence-structure-function paradigm. In fact, many protein functions do not require specific structures, instead relying on conformational flexibility, and as a result, many biologically active proteins (or protein regions) do not have unique structures, instead being intrinsically disordered.<span><sup>6-15</sup></span> However, the concept of functional disorder was still met with strong skepticism by the scientific community, especially by those who worked in structural biology.</p><p>This brings us to my first example of Marc-centric contingency or serendipity. When Keith contacted Marc to check if the manuscript we were working on would fit the scope of the Journal of Molecular Recognition, to our big surprise, we received very enthusiastic support. Those times were still the early days of protein intrinsic disorder, and many scientific journals were simply dismissing the idea of functional disorder as nonsensical (as an example, it took more than a year to publish my first paper on this subject (Ref. <span>16</span>), which was rejected by 14 journals before being eventually accepted by Proteins<span><sup>7</sup></span>). During the preparation of the manuscript for the Journal of Molecular Recognition, we had a productive exchange with Marc, which was very useful and is reflected in the acknowledgement in the resulting paper that reads “Both A.K.D. and V.N.U. thank M.H.V. van Regenmortel for shepherding this review from its inception to its final form with diligence and insight.”<span><sup>3</sup></span> According to the Web of Science, as of February 18, 2024, this review paper has been cited over 665 times and now occupies position # 3 in the list of the most cited papers published in the Journal of Molecular Recognition (https://www-webofscience-com.ezproxy.lib.usf.edu/wos/woscc/summary/9142e292-c3cd-47c1-8099-c250aa2a492e-cce4fea4/times-cited-descending/1). This part of the story, in my view, illustrates the bravery, open mindedness, foresight, and wisdom of Marc.</p><p>A total of 15 years later (at the end of 2019), I received a very kind personal invitation from Marc to prepare a review paper for the Journal of Molecular Recognition on the subject of molecular recognition, intrinsically disordered proteins, and biological complexity. In that letter, he wrote: “In your 2018 paper,<span><sup>17</sup></span> you referred to the fact that ‘early’ amino acid residues tended to be disorder-promoting while ‘late’ residues were more order-generating. I have always been puzzled by the fact that complementary codon triplets always code for residues of opposite polarity (hydrophilic vs. hydrophobic) leading to short peptides that bind to each other by hydropathic complementarity.<span><sup>18</sup></span> Could there be some link between the ‘age’ of residues and this phenomenon of early gene products being selected for binding to each other in the early RNA world?”</p><p>My curiosity was immediately ignited by this question and I enthusiastically accepted his invitation: “Thank you very much for your letter and a kind invitation to write a review for your Journal of Molecular Recognition on Molecular recognition, intrinsically disordered proteins, and biological complexity. The idea is very appealing, and I am delighted to accept your invitation… As far as your idea that there could be a link between the ‘age’ of residues, the hydropathic complementarity phenomenon you mentioned, and selection of early gene products for binding to each other in the early RNA world, I think that this is a very interesting hypothesis that should definitely be checked. However, I have to think about this.” To that he replied: “I am very grateful that you have accepted my invitation to write the review for JMR… I am also pleased that you think that the hydropathic binding of peptides derived from codons and anticodons is a phenomenon that merits attention because there seems to be no exception to the rule that short peptides obtained in this manner bind to each other. 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A few months later, the work was completed, and I sent the rough draft to Marc with a cover note stating: “Since this work on intrinsic disorder and sense-antisense recognition in proteins was completely inspired by our conversation and represents my attempt to answer your question on disorder, complementarity, and evolution, I think that you should be a coauthor. I really hope that you will accept this role. Once again, this work would not be possible if it would not be for you and your questions.” Needless to say that I was very happy to get his positive reply a few days later and was even happier when this joint paper was published later that year in the Journal of Molecular Recognition.<span><sup>2</sup></span></p><p>These two short stories represent just two brush strokes on the portrait of Marc van Regenmortel, my virtual friend and a real colleague.</p><p>The author has no relevant financial or non-financial interests to disclose.</p>","PeriodicalId":16531,"journal":{"name":"Journal of Molecular Recognition","volume":null,"pages":null},"PeriodicalIF":2.3000,"publicationDate":"2024-02-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/jmr.3079","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Molecular Recognition","FirstCategoryId":"99","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/jmr.3079","RegionNum":4,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"BIOCHEMISTRY & MOLECULAR BIOLOGY","Score":null,"Total":0}
引用次数: 0

Abstract

Unlike Jean-Luc Pellequer and Eric Westhof,1 who were colleagues of Marc H.V. van Regenmortel, I have never met him in person. However, I can add my voice to the discussion of how contingency or serendipity has led me to productively collaborate with Marc (unfortunately, exclusively in the on-line format), resulting in the publication of a joint paper in 2020.2 Before moving to this part of my story, a short historical excurse is needed.

My first (once again, exclusively virtual) encounter with Marc took place in 2004, when he played a crucial role in our work on one of the first comprehensive reviews on the roles of intrinsically disordered proteins and regions (IDPs/IDRs) in molecular recognition, regulation, and cell signaling.3 In the middle of 2004, I joined the Center for Computational Biology and Bioinformatics (CCBB) at the Indiana University-Purdue University at Indianapolis (IUPUI) that was created and headed by Prof. A. Keith Dunker, whom I worked with for 6 years on different aspects of the protein intrinsic disorder phenomenon. One of my first projects there was analysis of the then-available literature data on the functionality of intrinsic disorder.

By that time, it became clear that although IDPs/IDRs have been mostly ignored by the scientific community since the inception of the lock-and-key model by Hermann Emil Louis Fischer (1852–1919) in 1894,4, 5 many aspects of protein functionality could not be explained using this important model and its associated sequence-structure-function paradigm. In fact, many protein functions do not require specific structures, instead relying on conformational flexibility, and as a result, many biologically active proteins (or protein regions) do not have unique structures, instead being intrinsically disordered.6-15 However, the concept of functional disorder was still met with strong skepticism by the scientific community, especially by those who worked in structural biology.

This brings us to my first example of Marc-centric contingency or serendipity. When Keith contacted Marc to check if the manuscript we were working on would fit the scope of the Journal of Molecular Recognition, to our big surprise, we received very enthusiastic support. Those times were still the early days of protein intrinsic disorder, and many scientific journals were simply dismissing the idea of functional disorder as nonsensical (as an example, it took more than a year to publish my first paper on this subject (Ref. 16), which was rejected by 14 journals before being eventually accepted by Proteins7). During the preparation of the manuscript for the Journal of Molecular Recognition, we had a productive exchange with Marc, which was very useful and is reflected in the acknowledgement in the resulting paper that reads “Both A.K.D. and V.N.U. thank M.H.V. van Regenmortel for shepherding this review from its inception to its final form with diligence and insight.”3 According to the Web of Science, as of February 18, 2024, this review paper has been cited over 665 times and now occupies position # 3 in the list of the most cited papers published in the Journal of Molecular Recognition (https://www-webofscience-com.ezproxy.lib.usf.edu/wos/woscc/summary/9142e292-c3cd-47c1-8099-c250aa2a492e-cce4fea4/times-cited-descending/1). This part of the story, in my view, illustrates the bravery, open mindedness, foresight, and wisdom of Marc.

A total of 15 years later (at the end of 2019), I received a very kind personal invitation from Marc to prepare a review paper for the Journal of Molecular Recognition on the subject of molecular recognition, intrinsically disordered proteins, and biological complexity. In that letter, he wrote: “In your 2018 paper,17 you referred to the fact that ‘early’ amino acid residues tended to be disorder-promoting while ‘late’ residues were more order-generating. I have always been puzzled by the fact that complementary codon triplets always code for residues of opposite polarity (hydrophilic vs. hydrophobic) leading to short peptides that bind to each other by hydropathic complementarity.18 Could there be some link between the ‘age’ of residues and this phenomenon of early gene products being selected for binding to each other in the early RNA world?”

My curiosity was immediately ignited by this question and I enthusiastically accepted his invitation: “Thank you very much for your letter and a kind invitation to write a review for your Journal of Molecular Recognition on Molecular recognition, intrinsically disordered proteins, and biological complexity. The idea is very appealing, and I am delighted to accept your invitation… As far as your idea that there could be a link between the ‘age’ of residues, the hydropathic complementarity phenomenon you mentioned, and selection of early gene products for binding to each other in the early RNA world, I think that this is a very interesting hypothesis that should definitely be checked. However, I have to think about this.” To that he replied: “I am very grateful that you have accepted my invitation to write the review for JMR… I am also pleased that you think that the hydropathic binding of peptides derived from codons and anticodons is a phenomenon that merits attention because there seems to be no exception to the rule that short peptides obtained in this manner bind to each other. It might thus have contributed to the development of the genetic code as we know it today if the hydropathic complementarity of these early gene products played a role in the initial functional selection of peptide sequences that recognize each other (linking RNA and peptide sequence). I often quote Lily Kay's phrase19: “The Book of Life produces information without meaning, codes with no language, messages with no sender and writing devoid of authorship.” “Human languages needed consciousness to come about, and we no longer believe that a ‘designer’ is responsible for developing the genetic code. Some evolutionary mechanism must be responsible for it, and a stochastic mechanism seems to beg the question. A link between short complementary RNAs and short complementary functional peptides could perhaps lead to a better explanation”.

Even if I had had any second thoughts (which I did not), this message would convince me that I need to jump into this study. A few months later, the work was completed, and I sent the rough draft to Marc with a cover note stating: “Since this work on intrinsic disorder and sense-antisense recognition in proteins was completely inspired by our conversation and represents my attempt to answer your question on disorder, complementarity, and evolution, I think that you should be a coauthor. I really hope that you will accept this role. Once again, this work would not be possible if it would not be for you and your questions.” Needless to say that I was very happy to get his positive reply a few days later and was even happier when this joint paper was published later that year in the Journal of Molecular Recognition.2

These two short stories represent just two brush strokes on the portrait of Marc van Regenmortel, my virtual friend and a real colleague.

The author has no relevant financial or non-financial interests to disclose.

Marc H. V. van Regenmortel,一位虚拟的朋友,一位真实的同事。
与让-吕克-佩勒奎尔和埃里克-韦索夫1 不同,我从未见过马克-范-雷根莫特尔本人。不过,我可以加入讨论,说说偶然或巧合如何让我与马克进行了卓有成效的合作(不幸的是,完全是在线合作),并最终于 2020 年共同发表了一篇论文2。我与马克的第一次(又一次,完全是虚拟的)会面发生在 2004 年,当时他在我们的工作中发挥了至关重要的作用,我们就本质无序蛋白和区域(IDPs/IDRs)在分子识别、调控和细胞信号传导中的作用撰写了第一篇全面综述3。2004 年年中,我加入了印第安纳大学印第安纳波利斯分校(IUPUI)的计算生物学和生物信息学中心(CCBB),该中心由 A. Keith Dunker 教授创建和领导,我与他在蛋白质内在无序现象的不同方面共事了 6 年。我在那里的第一个项目是分析当时关于内在无序功能的文献数据。当时,我清楚地认识到,尽管自赫尔曼-埃米尔-路易斯-费舍尔(Hermann Emil Louis Fischer,1852-1919 年)于 1894 年提出锁钥模型4, 5 以来,内在无序/内在紊乱现象大多被科学界所忽视,但蛋白质功能的许多方面却无法用这一重要模型及其相关的序列-结构-功能范式来解释。事实上,许多蛋白质的功能并不需要特定的结构,而是依赖于构象的灵活性,因此,许多具有生物活性的蛋白质(或蛋白质区域)并不具有独特的结构,而是具有内在的无序性。6-15 然而,科学界,尤其是那些从事结构生物学研究的人,仍然对功能无序的概念持强烈的怀疑态度。当凯斯联系马克,询问我们正在撰写的手稿是否符合《分子识别杂志》的范围时,出乎我们意料的是,我们得到了非常热情的支持。当时还是蛋白质固有紊乱的早期,许多科学杂志都认为功能紊乱的观点毫无道理(例如,我的第一篇相关论文(参考文献 16)就花了一年多的时间才发表,被 14 家杂志拒绝,最终才被 Proteins7 接受)。在为《分子识别杂志》准备稿件的过程中,我们与马克进行了富有成效的交流,这种交流非常有用,这体现在论文的致谢中:"A.K.D.和V.N.U.感谢M.H.V. van Regenmortel以勤奋和洞察力将这篇综述从开始写到最后定稿。"3根据 Web of Science 的统计,截至 2024 年 2 月 18 日,这篇综述论文已被引用超过 665 次,目前在《分子识别杂志》(https://www-webofscience-com.ezproxy.lib.usf.edu/wos/woscc/summary/9142e292-c3cd-47c1-8099-c250aa2a492e-cce4fea4/times-cited-descending/1)上发表的被引用次数最多的论文中排名第 3。在我看来,这部分故事充分体现了马克的勇敢、开放、远见和智慧。15年后(2019年底),我收到了马克非常友好的个人邀请,让我为《分子识别杂志》撰写一篇综述论文,主题是分子识别、固有无序蛋白和生物复杂性。他在信中写道:"您在 2018 年的论文17 中提到,'早期'氨基酸残基倾向于促进无序,而'晚期'残基则更倾向于产生有序。互补密码子三胞胎总是编码极性相反的残基(亲水性与疏水性),导致短肽通过水道互补性相互结合,这一事实一直让我感到困惑。18 残基的'年龄'与早期基因产物在早期 RNA 世界中被选择相互结合的这一现象之间是否存在某种联系?"我的好奇心立刻被这个问题点燃,热情地接受了他的邀请:"非常感谢您的来信,并盛情邀请我为贵刊《分子识别》撰写一篇关于分子识别、本征无序蛋白和生物复杂性的评论。你的想法非常吸引人,我很高兴接受你的邀请......至于你认为残基的'年龄'、你提到的水道互补现象和早期基因产物在早期 RNA 世界中相互结合的选择之间可能存在联系,我认为这是一个非常有趣的假设,一定要加以验证。不过,我还得考虑一下。 "他回答说"我非常感谢你接受我的邀请为《JMR》撰写评论......我也很高兴你认为由密码子和反密码子产生的肽的水理结合是一个值得关注的现象,因为以这种方式获得的短肽相互结合的规则似乎没有例外。因此,如果这些早期基因产物的水合互补性在最初选择相互识别的肽序列(连接 RNA 和肽序列)的功能性过程中发挥了作用,那么它可能会促进我们今天所知的遗传密码的发展。我经常引用莉莉-凯的一句话19:"生命之书产生了没有意义的信息、没有语言的代码、没有发送者的信息和没有作者的文字"。"人类的语言需要意识才能产生,我们不再相信有'设计者'负责开发遗传密码。它必须由某种进化机制负责,而随机机制似乎是个问题。在短互补 RNA 和短互补功能肽之间建立联系,也许能找到更好的解释"。即使我有任何二心(我没有),这条信息也会让我相信,我需要投入这项研究。几个月后,工作完成了,我把初稿寄给了马克,并在封面注释中写道"由于这项关于蛋白质内在无序性和感应-反感应识别的研究完全受我们谈话的启发,也代表了我试图回答你关于无序性、互补性和进化问题的尝试,我认为你应该成为共同作者。我真的希望你能接受这个角色。再次重申,如果没有你和你的问题,这项工作是不可能完成的"。不用说,我很高兴几天后就得到了他的肯定答复,而更让我高兴的是,这篇联合论文于当年晚些时候发表在《分子识别杂志》(Journal of Molecular Recognition)上。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Molecular Recognition
Journal of Molecular Recognition 生物-生化与分子生物学
CiteScore
4.60
自引率
3.70%
发文量
68
审稿时长
2.7 months
期刊介绍: Journal of Molecular Recognition (JMR) publishes original research papers and reviews describing substantial advances in our understanding of molecular recognition phenomena in life sciences, covering all aspects from biochemistry, molecular biology, medicine, and biophysics. The research may employ experimental, theoretical and/or computational approaches. The focus of the journal is on recognition phenomena involving biomolecules and their biological / biochemical partners rather than on the recognition of metal ions or inorganic compounds. Molecular recognition involves non-covalent specific interactions between two or more biological molecules, molecular aggregates, cellular modules or organelles, as exemplified by receptor-ligand, antigen-antibody, nucleic acid-protein, sugar-lectin, to mention just a few of the possible interactions. The journal invites manuscripts that aim to achieve a complete description of molecular recognition mechanisms between well-characterized biomolecules in terms of structure, dynamics and biological activity. Such studies may help the future development of new drugs and vaccines, although the experimental testing of new drugs and vaccines falls outside the scope of the journal. Manuscripts that describe the application of standard approaches and techniques to design or model new molecular entities or to describe interactions between biomolecules, but do not provide new insights into molecular recognition processes will not be considered. Similarly, manuscripts involving biomolecules uncharacterized at the sequence level (e.g. calf thymus DNA) will not be considered.
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