核糖体的结构与功能研究——2009年诺贝尔化学奖简介

一系列高分辨率的核糖体及其30 S、50 S亚基的晶体结构揭示了这个极其复杂的蛋白质翻译机器的重要作用机理,对在分子水平上了解生命机体产生和形成的一个基本环节(蛋白质合成)具有重大意义,同时为新型抗生素的设计与研发开辟了新方向新途径,对人类健康与生命保障具有重要作用．     

机体的免疫反应是如何被激活的？——2011年诺贝尔生理学或医学奖解读

2011年10月3日,举世瞩目的 2011年诺贝尔生理学或医学奖在瑞典卡罗林斯卡医学院揭晓[1].因在免疫学领域取得杰出成就,美国科学家布鲁斯.博伊特勒(Bruce A.Beutler)、法国科学家朱尔斯.霍夫曼(Jules A.Hoffmann)和加拿大科学家拉尔夫.斯坦曼(Ralph M.Steinman),共同分享了这一     

The role of interleukin 15 in mounting an immune response against microbial infections

Interleukin (IL)-15 is a recently described cytokine that resembles IL-2 in its biological activities, stimulating natural killer cells, T cells and B cells to proliferate, secrete cytokines, and exhibit increased cytotoxicities or produce antibody. IL-15 also exerts unique functions such as stimulation of phagocytes, maintenance of mast cells and migration of activated/memory T cells. IL-15 is involved in protection against infections with a variety of microbes through not only activating innate immunity but also mounting adaptive immunity.     

Biological properties of immunochemically pure tetanus antitoxin

Immunochemically pure tetanus antitoxin obtained from enzyme-treated horse serum is less reactogenic and anaphylactogenic and possesses higher therapeutic properties than antitoxin purified by nonspecific physico-chemical methods and containing ballast antigens. Due to its increased persistence in the recipient's body, the immunochemically pure antitoxin induces passive immunity in considerably lower doses than the preparations purified by the method "Diaferm-3".     

The telomere story or the triumph of an open-minded research

The Nobel Assembly at Karolinska Institute has decided to award The Nobel Prize in Physiology or Medicine 2009 jointly to Elizabeth H. Blackburn, Carol W. Greider and Jack W. Szostak for the discovery of "how chromosomes are protected by telomeres and the enzyme telomerase". This discovery had major impacts within the scientific community and led to intense research in this field. All the studies performed are now the bases for future investigations and stimulate the development of potential new therapies.     

The birth of immunology. III. The fate of the phagocytosis theory.

During the period of 1895-1910, immunology was preoccupied with defining the cellular (Elie Metchnikoff's phagocytosis theory) as opposed to the humoral basis of bactericidal defense. Although initial discovery of immunopathologic phenomena had been made (e.g., relating to transplantation, autoimmunity, allergy), focus on microbicidal therapy and diagnosis of infectious diseases remained the major stimuli of inquiry. The debate concerning the relative roles of phagocytes, complement, amboceptors (sensibilizing factors, antibody, antitoxins), various lysins (e.g., bacteriolysins, spermatolysins, hemolysins), agglutinins, stimulines, and then Almoth Wright's opsonins reflects the ambiguity of a scientific language being created in an era still struggling with a poorly defined experimental system, for the language, both its vocabulary (newly studied phenomena) and grammar (operational mechanisms) was yet to be codified. The joint award of the Nobel Prize to Metchnikoff and Paul Ehrlich in 1908 for their respective contributions to the "theory of immunity" appeared to proclaim a consensus, but the secret Nobel Committee reports that evaluated Metchnikoff's contributions reveal only a grudging acceptance of his position, and the award was clearly made on the basis of an apparent complementarity between the theoretical views of the humoralists and those elements of the phagocytosis theory that fit the then current discussion of immunity. In this regard, opsonins played an especially important role as both an experimental and conceptual bridge between the competing schools. What was no longer under consideration (and in fact never was explicitly debated) concerned the intellectual foundation of Metchnikoff's original concept of immunity as those activities that defined organismal identity, (developed from Metchnikoff's research in developmental biology) and which regarded host defense mechanisms as only subordinate to this primary function. Immunology in the first half of the 20th century pursued issues pertinent to chemically characterizing immune specificity and only later returned to the Metchnikovian question of how the immune identity was established. This latter venture has achieved molecular sophistication, but even such a formulation may be an inadequate answer to the Metchnikovian postulate. The theoretical discussion between cellularists and humoralists continues in new guises, for the essential debate remains unresolved.     

The Le Douarin phenomenon: a shift in the paradigm of developmental self-tolerance

Ever since the foundations of Immunology, "self-tolerance" has remained a central issue in this field, pertaining to basic and clinical questions alike. Burnet and Medawar shared the Nobel Prize in 1960 for proposing that tolerance is induced by tissue antigens, if present during the development of the immune system during the embryonic/neonatal period. Very elegant experiments by Le Douarin and colleagues in the 1980's demonstrated that this is not the case; rather, the establishment of tolerance to peripheral tissues requires thymic epithelium which selects CD4 T lymphocytes mediating "dominant tolerance". The recent wealth of work on "regulatory T cells", as well as observations on the selective regulation of "tissue-specific" gene expression in thymic epithelial cells, confirm the critical relevance of those seminal findings in modern immunology.     

The quest for industrial enzymes from microorganisms†

Satoshi ōmura, Professor Emeritus at Kitasato University, was awarded the Nobel Prize for his discovery of a substance of tremendous value to mankind from a microorganism. As a researcher who regularly deals with enzymes produced by microorganisms and a person engaged in microorganism-based business, Professor ōmura’s Nobel Prize fills me with great pride and joy. It is perhaps not surprising that this Nobel Prize-winning research would emerge from Asia, specifically Japan, where people live in harmony with nature rather than try to conquer it. At Amano Enzyme Inc., we devote ourselves to searching for novel enzymes from microorganisms. While incorporating my own experiences, I will recount the stories of a few discoveries of valuable enzyme-producing microbes in soil and bacterial strain libraries. I will also briefly introduce microbial strain library construction as a tool for facilitating the identification of the desired producing bacteria.     

天然免疫模式识别受体与树突状细胞的发现和意义——2011年诺贝尔生理学或医学奖成果和相关研究简介

2011年的诺贝尔生理学或医学奖授予了Bruce A．Beutler,Jules A．Hoffmann以及Ralph M．Steinman教授,以奖励他们在天然免疫模式识别受体和树突状细胞研究领域所做出的开创性贡献。宿主的天然免疫系统依赖模式识别受体识别入侵的病原微生物,并通过树突状细胞对其加工处理将抗原提呈给T细胞,从而激活适应性免疫。回顾模式识别受体和树突状细胞发现的过程,介绍该领域最近的研究进展,并对它们在疾病预防和治疗中的应用进行了讨论。     

The first water channel protein (later called aquaporin 1) was first discovered in Cluj-Napoca, Romania.

This invited review briefly outlines the importance of membrane water permeability, highlights the landmarks leading to the discovery of water channels. After a decade of systematic studies on water channels in human RBC Benga's group discovered in 1985 the presence and location of the water channel protein among the polypeptides migrating in the region of 35-60 kDa on the electrophoretogram of RBC membrane proteins. The work was extended and reviewed in several articles. In 1988, Agre and coworkers isolated a new protein from the RBC membrane, nick-named CHIP28 (channel-forming integral membrane protein of 28 kDa). However, in addition to the 28 kDa component, this protein had a 35-60 kDa glycosylated component, the one detected by the Benga's group. Only in 1992 Agre's group suggested that "it is likely that CHIP28 is a functional unit of membrane water channels". Half of the 2003 Nobel Prize in Chemistry was awarded to Peter Agre (Johns Hopkins University, Baltimore, USA) "for the discovery of water channels", actually the first water channel protein from the human red blood cell (RBC) membrane, known today as aquaporin 1 (AQP1). The seminal contributions from 1986 of the Benga's group were grossly overlooked by Peter Agre and by the Nobel Prize Committee. Thousands of science-related professionals from hundreds of academic and research units, as well as participants in several international scientific events, have signed as supporters of Benga; his priority is also mentioned in several comments on the 2003 Nobel Prize.     

Robert Koch: the grandfather of cloning?

This year marks the centenary of Robert Koch's Nobel Prize for discovering the cause of tuberculosis. Koch was also the first scientist to isolate the anthrax and cholera microbes. Yet perhaps one of his greatest contributions to biology is the least appreciated: his method for propagating individual colonies of bacteria on plates, a technique that came to be called cloning.     

Bridging innate and adaptive immunity

The Nobel Prize in Physiology or Medicine for 2011 to Jules Hoffmann, Bruce Beutler, and the late Ralph Steinman recognizes accomplishments in understanding and unifying the two strands of immunology, the evolutionarily ancient innate immune response and modern adaptive immunity.     

RNA interference: big applause for silencing in Stockholm

Eight years ago, Craig Mello, Andrew Fire, and their coworkers provided the first demonstration that double-stranded RNA (dsRNA) triggers the gene-silencing technique that we now call RNA interference (RNAi). For this landmark discovery, Mello and Fire are honored with this year's Nobel Prize in Physiology or Medicine.     

Who was... Emil von Behring?

Emil von Behring was first in the line of distinguished immunologists to win the Nobel Prize for Physiology and Medicine. His contributions to our knowledge of immunity ignited an impassioned argument between French and German scientists at the end of the 19th century, the first of many scientific debates in the immunological world.     

自噬的前世今生

自噬是细胞通过溶酶体（或液泡）分解自身组分以达到维持细胞内正常生理活动及稳态的一种细胞代谢过程。自噬作为一种在真核生物中保守存在的细胞通路,与人类的疾病与健康息息相关。2016年,诺贝尔生理学或医学奖颁发给为自噬通路研究做出过卓越贡献的日本生物学家大隅良典（Yoshinori Ohsumi）。本文其一旨在通过介绍自噬及自噬相关基因的发现细节,带领读者了解自噬被发现和阐释的历程;其二旨在通过介绍自噬起始的相关机制及自噬与疾病的联系,引导读者对于自噬生理功能有更深入的理解;最后本文还提出了一些自噬领域目前尚待进一步研究的方向,供读者参考。     

Origin of plague moderate phages of serotype 2]

Results of study of the negative colonies morphology, the structure of corpuscles, antigenic properties, specificity, and the action range permitted to refer the phages obtained from 18 E. coli strain, 1 plaque strain, and 1 pseudotoberculosis bacillus strain to the same group and to identify them with plague phages of serological type 2. Isolation of the same phage type from different bacterial species permits to regard them as "polyhostal" ones. E. coli should be considered as the main carrier of phages belonging to serological type 2. It is suggested that phages existing on microbes belonging to different species should be called "polyhostal".     

20th century at a glance: the streptomycin story

The discovery of streptomycin is attributed to a microbiologist, Selman Waksman, Nobel Prize 1952, a paternity that was disputed by his collaborator Albert Schatz, who was the first author of the princeps article. Two pioneering clinical studies involved streptomycin, both of which have been widely used as reference works. The first one was English, under the name of Austin Bradford Hill. It inaugurated a randomization in medicine. The second trial was American, and carried out by the Veteran Administration. It made use for the first time of the "control group". The present article analyses the genesis of clinical trials and illustrates the recurrent difficulties encountered in their implementation.     

Discharge of solubilized and Dectin-1-reactive β-glucan from macrophage cells phagocytizing insoluble β-glucan particles: involvement of reactive oxygen species (ROS)-driven degradation

Phagocytes engulf pathogenic microbes, kill them and degrade their cellular macromolecules by hydrolytic enzymes in phagolysosomes. However, such enzymes are unable to degrade some microbial polysaccharides, and fate of such indigestible polysaccharides in phagocytes remains uncertain. Using the extracellular domain of Dectin-1 as β-glucan-specific probes, we succeeded in detection of soluble and Dectin-1-reactive β-glucan discharged from mouse RAW 264.7 and human THP-1 macrophage cell lines as well as mouse peritoneal macrophages, which had phagocytized insoluble β-glucan particles. The RAW 264.7 cell culture-supernatant containing the discharged β-glucan stimulated naïve RAW 264.7 cells, resulting in the induction of cytokine expression. Such discharge of Dectin-1-reactive β-glucan from macrophage cells was inhibited by either NADPH oxidase inhibitors (apocynin and diphenylene iodonium) or radical scavengers (N-acetyl cysteine and MCI-186). Moreover, reactive oxygen species (ROS) produced by a Cu²⁺/ascorbic acid system solubilized insoluble β-glucan particles in vitro, and a part of the solubilized β-glucan was Dectin-1 reactive and biologically active in macrophage activation. The soluble and biologically active β-glucan was degraded further during prolonged exposure to ROS. These results suggest that degraded but Dectin-1-reactive β-glucan is discharged from macrophage cells phagocytizing insoluble β-glucan particles and stimulates not only themselves again but also the other naïve phagocytes, leading to the effective elimination of infecting microbes and the ultimate breakdown and inactivation of metabolically resistant β-glucan.     

A simple index for the high-citation tail of citation distribution to quantify research performance in countries and institutions

Background

Conventional scientometric predictors of research performance such as the number of papers, citations, and papers in the top 1% of highly cited papers cannot be validated in terms of the number of Nobel Prize achievements across countries and institutions. The purpose of this paper is to find a bibliometric indicator that correlates with the number of Nobel Prize achievements.

Methodology/Principal Findings

This study assumes that the high-citation tail of citation distribution holds most of the information about high scientific performance. Here I propose the x-index, which is calculated from the number of national articles in the top 1% and 0.1% of highly cited papers and has a subtractive term to discount highly cited papers that are not scientific breakthroughs. The x-index, the number of Nobel Prize achievements, and the number of national articles in Nature or Science are highly correlated. The high correlations among these independent parameters demonstrate that they are good measures of high scientific performance because scientific excellence is their only common characteristic. However, the x-index has superior features as compared to the other two parameters. Nobel Prize achievements are low frequency events and their number is an imprecise indicator, which in addition is zero in most institutions; the evaluation of research making use of the number of publications in prestigious journals is not advised.

Conclusion

The x-index is a simple and precise indicator for high research performance.     

The blood from Auschwitz and the silence of the scholars

The Kaiser Wilhelm Institute for Anthropology, Human Genetics and Eugenics in Berlin-Dahlem was the centre of scientific racism in Nazi Germany. Its bad history culminated in a research project to analyse the molecular basis of racial differences in the susceptibility to various infectious diseases such as tuberculosis. Josef Mengele, a former postdoc of the director of the institute, Otmar von Verschuer, collected blood samples and other material in Auschwitz from families and twins of Jews and Gypsies. The blood samples were analysed by Günther Hillmann in the Berlin laboratory of Nobel Prize winner Adolf Butenandt. Butenandt had just moved to Tübingen. The project was paid for by the Deutsche Forschungsgemeinschaft. Butenandt, Hillmann and von Verschuer made scientific careers in the Federal Republic. To the present day this past has not been acknowledged by the Max-Planck-Gesellschaft as part of its history.