Evolution of Virology: Science History through Milestones and Technological Advancements.

The history of virology, which is marked by transformative breakthroughs, spans microbiology, biochemistry, genetics, and molecular biology. From the development of Jenner's smallpox vaccine in 1796 to 20th-century innovations such as ultrafiltration and electron microscopy, the field of virology has undergone significant development. In 1898, Beijerinck laid the conceptual foundation for virology, marking a pivotal moment in the evolution of the discipline. Advancements in influenza A virus research in 1933 by Richard Shope furthered our understanding of respiratory pathogens. Additionally, in 1935, Stanley's determination of viruses as solid particles provided substantial progress in the field of virology. Key milestones include elucidation of reverse transcriptase by Baltimore and Temin in 1970, late 20th-century revelations linking viruses and cancer, and the discovery of HIV by Sinoussi, Montagnier, and Gallo in 1983, which has since shaped AIDS research. In the 21st century, breakthroughs such as gene technology, mRNA vaccines, and phage display tools were achieved in virology, demonstrating its potential for integration with molecular biology. The achievements of COVID-19 vaccines highlight the adaptability of virology to global health.

[130th anniversary of virology].

130 years ago, in 1892, our great compatriot Dmitry Iosifovich Ivanovsky (18641920) discovered a new type of pathogen viruses. Viruses have existed since the birth of life on Earth and for more than three billion years, as the biosphere evolved, they are included in interpopulation interactions with representatives of all kingdoms of life: archaea, bacteria, protozoa, algae, fungi, plants, invertebrates, and vertebrates, including the Homo sapiens (Hominidae, Homininae). Discovery of D.I. Ivanovsky laid the foundation for a new science virology. The rapid development of virology in the 20th century was associated with the fight against emerging and reemerging infections, epidemics (epizootics) and pandemics (panzootics) of which posed a threat to national and global biosecurity (tick-borne and other encephalitis, hemorrhagic fevers, influenza, smallpox, poliomyelitis, HIV, parenteral hepatitis, coronaviral and other infections). Fundamental research on viruses created the basis for the development of effective methods of diagnostics, vaccine prophylaxis, and antiviral drugs. Russian virologists continue to occupy leading positions in some priority areas of modern virology in vaccinology, environmental studies oz zoonotic viruses, studies of viral evolution in various ecosystems, and several other areas. A meaningful combination of theoretical approaches to studying the evolution of viruses with innovative methods for studying their molecular genetic properties and the creation of new generations of vaccines and antiviral drugs on this basis will significantly reduce the consequences of future pandemics or panzootics. The review presents the main stages in the formation and development of virology as a science in Russia with an emphasis on the most significant achievements of soviet and Russian virologists in the fight against viral infectious diseases.

A Brief History of Giant Viruses' Studies in Brazilian Biomes.

Almost two decades after the isolation of the first amoebal giant viruses, indubitably the discovery of these entities has deeply affected the current scientific knowledge on the virosphere. Much has been uncovered since then: viruses can now acknowledge complex genomes and huge particle sizes, integrating remarkable evolutionary relationships that date as early as the emergence of life on the planet. This year, a decade has passed since the first studies on giant viruses in the Brazilian territory, and since then biomes of rare beauty and biodiversity (Amazon, Atlantic forest, Pantanal wetlands, Cerrado savannas) have been explored in the search for giant viruses. From those unique biomes, novel viral entities were found, revealing never before seen genomes and virion structures. To celebrate this, here we bring together the context, inspirations, and the major contributions of independent Brazilian research groups to summarize the accumulated knowledge about the diversity and the exceptionality of some of the giant viruses found in Brazil.

Bo Zhong: Captive by the viral immune escape.

Bo Zhong studies the regulation of the antiviral innate immunity, inflammation, and tumorigenesis by the protein ubiquitination system.

Retroviral Antisense Transcripts and Genes: 33 Years after First Predicted, a Silent Retroviral Revolution?

Paradigm shifts throughout the history of microbiology have typically been ignored, or met with skepticism and resistance, by the scientific community. This has been especially true in the field of virology, where the discovery of a "contagium vivum fluidum", or infectious fluid remaining after excluding bacteria by filtration, was initially ignored because it did not coincide with the established view of microorganisms. Subsequent studies on such infectious agents, eventually termed "viruses", were met with skepticism. However, after an abundance of proof accumulated, viruses were eventually acknowledged as defined microbiological entities. Next, the proposed role of viruses in oncogenesis in animals was disputed, as was the unique mechanism of genome replication by reverse transcription of RNA by the retroviruses. This same pattern of skepticism holds true for the prediction of the existence of retroviral "antisense" transcripts and genes. From the time of their discovery, it was thought that retroviruses encoded proteins on only one strand of proviral DNA. However, in 1988, it was predicted that human immunodeficiency virus type 1 (HIV-1), and other retroviruses, express an antisense protein encoded on the DNA strand opposite that encoding the known viral proteins. Confirmation came quickly with the characterization of the antisense protein, HBZ, of the human T-cell leukemia virus type 1 (HTLV-1), and the finding that both the protein and its antisense mRNA transcript play key roles in viral replication and pathogenesis. However, acceptance of the existence, and potential importance, of a corresponding antisense transcript and protein (ASP) in HIV-1 infection and pathogenesis has lagged, despite gradually accumulating theoretical and experimental evidence. The most striking theoretical evidence is the finding that asp is highly conserved in group M viruses and correlates exclusively with subtypes, or clades, responsible for the AIDS pandemic. This review outlines the history of the major shifts in thought pertaining to the nature and characteristics of viruses, and in particular retroviruses, and details the development of the hypothesis that retroviral antisense transcripts and genes exist. We conclude that there is a need to accelerate studies on ASP, and its transcript(s), with the view that both may be important, and overlooked, targets in anti-HIV therapeutic and vaccine strategies.

[Hans-Dieter Klenk].

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A History of Cancer Research: Tumor Viruses.

Early studies of transmissible tumors in chickens provided evidence that viruses such as avian leukosis virus (ALV) and Rous sarcoma virus (RSV) can cause cancer in these animals. Doubts about the relevance to human tumors and failures to replicate some early work meant the field of tumor virology followed a bumpy course. Nevertheless, viruses that can cause cancers in rodents and humans were ultimately identified, and several Nobel prizes were awarded for work in this area. In this excerpt from his forthcoming book on the history of cancer research, Joe Lipsick looks back at the early history of tumor virus research, from some of the early false starts and debates, to discovery of reverse transcriptase, and identification of human papilloma virus (HPV) as the major cause of cervical cancer.

Vinculación del virólogo profesor Adolfo García Sastre con la Universidad de Salamanca y con la Real Academia Nacional de Farmacia / Relationship of the virologist professor Adolfo García Sastre with the University of Salamanca and the Royal National Academy of Pharmacy

Se detallan y comentan algunos datos biográficos relativos al virólogo Profesor Adolfo García Sastre correspondientes a su etapa como estudiante en la Facultad de Biología de la Universidad de Salamanca, durante los cursos finales de su Licenciatura (años 1981-1986), así como a los siguientes en que realizó su Tesis de Licenciatura (Tesina) en 1986,y Doctorado (1986-1990), en el Departamento de Bioquímica y Biología Molecular de dicha Facultad (Director: Prof.J.A. Cabezas); habiendo obtenido en ambas las máximas calificaciones y el Premio Extraordinario en la de Doctorado. También se resumen las líneas de investigación que cultivó en Salamanca hasta 1991 en colaboración con el director de ambas Tesis (el Profesor Titular Enrique Villar), el Profesor J.A. Cabezas y, a veces, otros. Los resultados obtenidos, así como los derivados de su breve etapa inmediata en el Instituto Pasteur de Paris, en coordinación con el Departamentos almantino, fueron publicados en revistas de Virología o de Bioquímica de gran prestigio y presentados en congresos nacionales e internacionales. Posteriormente, en su etapa americana en el Mount Sinai de Nueva York, entró en contacto con el Profesor Mariano Esteban, entonces trabajando en el Down state Medical Center de New York, SUNY, y ambos, conjuntamente con el grupo del New York University (NYU) dirigido por Ruth Nussenweig y Fidel Zavala, llevaron a cabo experimentos seminales de inmunología que abrieron las bases a la combinación de vacunas en protocolos prime/boosty activación de linfocitos TCD8+ con resultado de alta eficacia frente a patógenos. Estos protocolos están siendo implementados en numerosos ensayos preclínicos y clínicos. La contribución del Prof. García Sastre a la ciencia está actualmente en fase exponencial, abriendo nuevos horizontes en el entendimiento de la biología molecular de virus emergentes, su patología, interacción virus-hospedador y desarrollando nuevos procedimientos de control viral

Se detallan y comentan algunos datos biográficos relativos al virólogo Profesor Adolfo García Sastre correspondientes in the Biology School of University of Salamanca and during his PhD Thesis (1986-1990) in the Department of Biochemistry and Molecular Biology (Chairman Prof J.A. Cabezas), under the supervision of Prof. Enrique Villlar and obtaining the highest academic marks. The research lines that he established in collaboration with his Thesis director, with Prof.J.A Cabezas and others, as well as his results during his stay at the Pasteur Institute in Paris, are also highlighted. His findings in this period were published in prestigious Virology and Biochemistry journals and presented at national and international meetings. Thereafter, when he moved to Mount Sinai in New York, he met Prof Mariano Esteban, then working at Downstate Medical Center in New York, SUNY, and both, in collaboration with the group of Prof. Ruth Nus-senzweig and Fidel Zavala at New York University, set up seminal immunological studies that are the basis for combined vaccination approaches, prime/boost and activation of CD8+ T cells, now widely used in preclinical and clinical studies. The scientific research contributions of Prof. García Sastre are growing at an exponential rate, opening new horizon sin understanding the molecular biology of emerging viruses, their pathology virus-host cell interactions and strategies of virus control

A brief history of the species concept in virology and an opinion on the proposal to introduce Linnaean binomial virus species names.

The species concept used in virology is based on the logic of the Linnaean hierarchy, which views a species class as the lowest abstract category that is included in all the higher categories in the classification, such as genera and families. As a result of this class inclusion, the members of a species class are always less numerous than the members of higher classes, which become more numerous as one moves up in the hierarchy. Because species classes always have fewer members than any of the higher classes, logic requires that they need more qualifications for establishing membership than any of the higher classes. This invalidates the claim that a species could be defined by a single property present in all its members. Species were only accepted in virus classification in 1991, because virologists assumed that it would lead to the use of Latin species names, which they rejected. Anglicized binomial species names have been used by virologists for more the 40 years and are popular because they consist of a virus name followed by a genus name that most virologists are familiar with. The ICTV has proposed to introduce a new Latinized virus species binomial nomenclature using the genus name followed by a hard-to-remember Latinized species epithet that bears little resemblance to the name of the virus itself. However, the proposal did not clarify what the advantage is of having to learn hundreds of new unfamiliar virus species names. In 2013, the ICTV changed the definition of a virus species as an abstract class and defined it as a group of physical objects, which induced virologists to believe that a virus species could be defined by a few characteristics of the viral genome. In recent years, thousands of viral sequences have been discovered in metagenomic databases, and the ICTV has suggested that it should be possible to incorporate these sequences in the current ICTV virus classification. Unfortunately, the relational properties of these hypothetical viruses that result from their biological interactions with hosts and vectors remain in the vast majority of cases totally unknown. The absence of this information makes it in fact impossible to incorporate these metagenomic sequences in the current classification of virus species.

History of Early Bacteriophage Research and Emergence of Key Concepts in Virology.

The viruses of bacteria - bacteriophages - were discovered 20 years after the discovery of viruses. However, this was mainly the bacteriophage research that, after the first 40 years, yielded the modern concept of the virus and to large extent formed the grounds of the emerging molecular genetics and molecular biology. Many specific aspects of the bacteriophage research history have been addressed in the existing publications. The integral outline of the events that led to the formation of the key concepts of modern virology is presented in this review. This includes the opposition of F. d'Herelle and J. Bordet viewpoints over the nature of the bacteriophage, the history of lysogeny discovery and of determination of the mechanisms of underlying this phenomenon, the work of the Phage group led by M. Delbruck in USA, the development of the genetic analysis of bacteriophages and other research that eventually led to emergence of the concept of the virus (bacteriophage) as a transmissive genetic program. The review also covers a brief history of early applications of the bacteriophages such as phage therapy and phage typing.

The role of the World Health Organization country programs in the development of virology in Spain, 1951-1975.

Within the framework of recent historiography about the role of the World Health Organization (WHO) in modernizing public health and the multifaceted concept of global health, this study addresses the impact of the WHO's "country programs" in Spain from the time it was admitted to this organization in 1951 to 1975. This research adopts a transnational historical perspective and emphasizes attention to the circulation of health knowledge, practices, and people, and focuses on the Spain-0001 and Spain-0025programs, their role in the development of virology in Spain, and the transformation of public health. Sources include historical archives (WHO, the Spanish National Health School), various WHO publications, the contemporary medical press, and a selection of the Spanish general press.