Historical Advances in Structural and Molecular Biology and How They Impacted Vaccine Development.

Vaccines are among the greatest tools for prevention and control of disease. They have eliminated smallpox from the planet, decreased morbidity and mortality for major infectious diseases like polio, measles, mumps, and rubella, significantly blunted the impact of the COVID-19 pandemic, and prevented viral induced cancers such as cervical cancer caused by human papillomavirus. Recent technological advances, in genomics, structural biology, and human immunology have transformed vaccine development, enabling new technologies such as mRNA vaccines to greatly accelerate development of new and improved vaccines. In this review, we briefly highlight the history of vaccine development, and provide examples of where advances in genomics and structural biology, paved the way for development of vaccines for bacterial and viral diseases.

The people behind the papers - Shai Eyal and Elazar Zelzer.

Most bones in the vertebrate skeleton are made in the same way - endochondrial ossification - yet they display a variety of shapes and sizes. The question of how these unique bone morphologies, including the superstructures that protrude from their surfaces, arise during development is still unclear, and the subject of a new paper in Development We caught up with first author Shai Eyal and his supervisor Elazar Zelzer, Professor in the Department of Molecular Genetics at the Weizmann Institute of Science in Rehovot, Israel, to find out more about the story.

Spotlight On Early Career Researchers: an interview with Lovorka Stojic.

Dr. Lovorka Stojic is a postdoctoral research fellow at the University of Cambridge and will start her own research group at the Barts Cancer Institute this fall. Her research focuses on understanding how long noncoding RNAs and RNA-binding proteins regulate key cellular processes and how dysregulation of these processes can contribute to human diseases such as cancer. As part of our series on early-career researchers, we asked Dr. Stojic to tell us about her research and career path. She also shares her challenges from juggling between multiple roles and advice for job applications.

cAMP guided his way: a life for G protein-mediated signal transduction and molecular pharmacology-tribute to Karl H. Jakobs.

Karl H. Jakobs, former editor-in-chief of Naunyn-Schmiedeberg's Archives of Pharmacology and renowned molecular pharmacologist, passed away in April 2018. In this article, his scientific achievements regarding G protein-mediated signal transduction and regulation of canonical pathways are summarized. Particularly, the discovery of inhibitory G proteins for adenylyl cyclase, methods for the analysis of receptor-G protein interactions, GTP supply by nucleoside diphosphate kinases, mechanisms in phospholipase C and phospholipase D activity regulation, as well as the development of the concept of sphingosine-1-phosphate as extra- and intracellular messenger will presented. His seminal scientific and methodological contributions are put in a general and timely perspective to display and honor his outstanding input to the current knowledge in molecular pharmacology.

DNA Tumor Viruses and Their Contributions to Molecular Biology.

This summer marks the 51st anniversary of the DNA tumor virus meetings. Scientists from around the world will gather in Trieste, Italy, to report their latest results and to agree or disagree on the current concepts that define our understanding of this diverse class of viruses. This article offers a brief history of the impact the study of these viruses has had on molecular and cancer biology and discusses obstacles and opportunities for future progress.

WOMEN IN REPRODUCTIVE SCIENCE: Discovering science and the ovary: a career of joy.

My career has been about discovering science and learning the joys of the discovery process itself. It has been a challenging but rewarding process filled with many exciting moments and wonderful colleagues and students. Although I went to college to become a French major, I ultimately stumbled into research while pursuing a Masters Degree in teaching. Thus, my research career began in graduate school where I was studying NAD kinase in the ovary as a possible regulator of steroidogenesis, a big issue in the late 1960s. After a short excursion of teaching in North Dakota, I became a postdoctoral fellow at the University of Michigan, where radio-immuno assays and radio receptor assays had just come on the scene and were transforming endocrinology from laborious bioassays to quantitative science and of course these assays related to the ovary. From there I went to Baylor College of Medicine, a mecca of molecular biology, cloning genes and generating mouse models. It has been a fascinating and joyous journey.

Halcyon days of TOR: Reflections on the multiple independent discovery of the yeast and mammalian TOR proteins.

The quest to elucidate the molecular mechanism of action of rapamycin in the early 1990s led to the discovery of the novel TOR (target of rapamycin) proteins in yeast and mammalian cells. This was a major breakthrough that resulted in the development of new rapamycin analogs as anti-cancer agents, and launched new research that revealed the pre-eminent biological role of mTOR (mammalian or mechanistic TOR). Beyond mediating rapamycin sensitivity, the TOR proteins are nutrient sensing protein kinases, conserved from yeast to man, with a core function in regulating cell growth, metabolism and overall cell survival. There have been many insightful historical accounts of the origins of TOR; however, the complete TOR dossier would benefit from a chapter on the untold story of the simultaneous co-discovery of the yeast TOR proteins by two independent laboratories, one that is inclusive of the discoveries made at the former SmithKline Beecham (legacy GlaxoSmithKline). Accordingly, this comprehensive retrospective retraces the provenance of yeast TOR (circa 1990-1996) and highlights the early groundbreaking publications that revealed the identity of the TOR genes and proteins. It also commemorates key companion papers which helped to clarify yeast TOR gene nomenclature, identified structural motifs in the predicted TOR protein sequences, demonstrated interactions between yeast FKBP12-rapamycin and TOR, characterized mutations responsible for drug resistance, and began to decipher TOR protein function; some of these crucial early studies appeared in this journal (e.g., Koser et al., 1993. Gene 129, 159-165; Cafferkey et al., 1994. Gene 141, 133-136; Freeman and Livi, 1996. Gene 172, 143-147). A period of intensive investigation, events are portrayed chronologically and juxtaposed alongside the independent parallel efforts to identify and purify mTOR. Finally, in a broader historical context, TOR and mTOR are examined a posteriori as paragons of multiple discovery, illustrating how this common phenomenon (also known as simultaneous invention) can greatly accelerate problem solving and advance human knowledge in a fast-breaking area of scientific research.

Julian Lewis (1946-2014): A 'serious hero'.

Julian Lewis was a gifted medical researcher and writer. His early background was the Classics; then Physics and Math; finally, Molecular Cell Biology. He worked on important questions in early embryonic patterning and the cell communication system, and so cancer research, at King's College London, the Imperial Cancer Research Fund Oxford, and finally, Cancer Research UK London. He was a lifelong coauthor of the international textbook Molecular Biology of the Cell. His final personal battle with cancer was brave and not hidden. Awards included the Waddington Medal, a European Molecular Biology Organization membership, and a Fellowship of the Royal Society.

Andrea Ventura: Decrypting noncoding RNAs.

Ventura explores the biological functions of noncoding RNAs in cancer and development.

Finding, Conducting, and Nurturing Science: A Virologist's Memoir.

My laboratory investigations have been driven by an abiding interest in understanding the consequences of genetic rearrangement in evolution and disease, and in using viruses to elucidate fundamental mechanisms in biology. Starting with bacteriophages and moving to the retroviruses, my use of the tools of genetics, molecular biology, biochemistry, and biophysics has spanned more than half a century-from the time when DNA structure was just discovered to the present day of big data and epigenetics. Both riding and contributing to the successive waves of technology, my laboratory has elucidated fundamental mechanisms in DNA replication, repair, and recombination. We have made substantial contributions in the area of retroviral oncogenesis, delineated mechanisms that control retroviral gene expression, and elucidated critical details of the structure and function of the retroviral enzymes-reverse transcriptase, protease, and integrase-and have had the satisfaction of knowing that the fundamental knowledge gained from these studies contributed important groundwork for the eventual development of antiviral drugs to treat AIDS. While pursuing laboratory research as a principal investigator, I have also been a science administrator-moving from laboratory head to department chair and, finally, to institute director. In addition, I have undertaken a number of community service, science-related "extracurricular" activities during this time. Filling all of these roles, while being a wife and mother, has required family love and support, creative management, and, above all, personal flexibility-with not too much long-term planning. I hope that this description of my journey, with various roles, obstacles, and successes, will be both interesting and informative, especially to young female scientists.

Cinco décadas de la biología molecular y la citogenética aplicadas a la hematología cubana / Five decades of molecular biology and cytogenetic applied to cuban hematology

La biología molecular (BM) es una ciencia que ha revolucionado el desarrollo científico en los últimos años. En el Instituto de Hematología e Inmunología (IHI) también ha evolucionado progresivamente conforme al avance tecnológico y adecuándose cada vez más al contexto científico internacional. Su historia se remonta al año 1966, con la creación del IHI y posteriormente del laboratorio de BM. En el año 2012, el departamento de BM y el laboratorio de citogenética, pasaron a formar parte de lo que hoy es el Centro de Tecnologías de Avanzada, un área con tecnología de punta que ha permitido actualizar la mayoría de las técnicas moleculares que se empleaban previamente, lo que garantiza mayor rapidez y confiabilidad de los resultados. Se introdujeron y perfeccionaron técnicas como la extracción y cuantificación de ácidos nucleicos, la electroforesis capilar y el FISH (del inglés: Fluorescence In Situ Hybridization) y se adquirieron modernas máquinas termocicladoras para la reacción en cadena de la polimerasa (PCR , siglas en inglés), materiales y reactivos. Con este esfuerzo mancomunado en estos 50 años, se han podido beneficiar hasta la fecha: 5 460 pacientes, estudiados en el laboratorio de BM, donde se determinan actualmente 10 marcadores moleculares, 12 estudios de FISH; además del cariotipo convencional y los estudios de quimerismo. Se ha alcanzado una media anual de 317 pacientes estudiados, en los últimos 5 años. Se cuenta con profesionales de alta calificación, lo que ha posibilitado liderar y colaborar en proyectos de investigación nacionales e internacionales, publicar innumerables artículos científicos, obtener premios relevantes y formar a los residentes de la especialidad de Hematología. Las perspectivas comprenden la incorporación de la PCR en tiempo real y la secuenciación para completar un nivel de diagnóstico a la altura de cualquier prestigioso centro internacional y así poder ofrecer un servicio de calidad a los pacientes(AU)

Molecular biology (MB) is a science that has revolutionized scientific development in recent years. It has also increasing progressively at the Institute of Hematology and Immunology (IHI) as adapting to technological advances and international scientific context. Its history dates back to 1966, with the IHI creation and subsequently the MB laboratory. Since then they have been many achievements in the field of diagnosis and research in Hematology. In 2012, the MB department with the cytogenetic laboratory was part of the Center for Advanced Technologies; an area with modern technology that has allowed change old studies by updated molecular techniques, ensuring greater speed and reliability of results. Techniques such as extraction and quantification of nucleic acids (NA), capillary electrophoresis and the FISH (Fluorescence in Situ Hybridization) were introduced, and modern thermocyclers for polymerase chain reaction (PCR), materials and reagents were acquired too. In these 50 years, 5 460 patients have been benefited to date. We study about 10 molecular markers, 12 FISH study, in addition to conventional karyotyping and chimerism studies in the MB lab at this moment. It has gone an annual average of 317 patients in the last 5 years. We have highly qualified professionals, which has made possible to lead and collaborate on national and international research, publishing numerous scientific articles, obtain relevant prizes of science and technology forum and directly contribute to the residents' formation in Hematology. Our future perspectives include the new technologies incorporation such as real-time PCR and sequencing, to complete a similar diagnostic level to any prestigious international center so we can provide quality service to our patients(AU)

PTEN: History of a Tumor Suppressor.

Starting from the discovery of "inhibitory chromosomes" by Theodor Boveri to the finding by Henry Harris that fusing a normal cell to a cancer cell reduced tumorigenic potential, the notion of tumor suppression was recognized well before any tumor-suppressor genes were discovered. Although not the first to be revealed, PTEN has been demonstrated to be one of the most frequently altered tumor suppressors in cancer. This introductory chapter provides a historical perspective on our current understanding of PTEN including some of the seminal discoveries in the tumor suppressor field, the events leading to PTEN's discovery, and an introduction to some of the most important researchers and their studies which have shed light on PTEN biology and function as we know it today.