From messenger RNA to viral vectors and recombinant proteins: the evolution of vaccines against COVID-19 / Del ARN mensajero a los vectores virales y las proteínas recombinantes: la evolución de las vacunas contra COVID-19

Entre finales de 2019 y mediados de 2022, la pandemia de COVID-19 ha causado más de 600 millones de casos confirmados y al menos 6,5 millones de muertes, constituyendo la emergencia de salud pública más importante de las últimas décadas. En paralelo con el transcurso de la pandemia, ha tenido lugar una carrera sin precedentes por la obtención de vacunas eficaces para el control de la rápida dispersión del virus. Cuatro meses después del anuncio de la emergencia del SARS-CoV-2, agente de la pandemia, ya habían 115 "vacunas candidatas", cinco de ellas en fase de ensayos clínicos [1]. Al mismo tiempo, una gran revolución en la producción de vacunas estaba ocurriendo; nuevas tecnologías de producción de biológicos, más eficaces y más rápidas, llevaron al desarrollo de vacunas útiles en un tiempo increíblemente corto. Antes de la pandemia, el desarrollo de una nueva vacuna típicamente solía tomar entre cinco y diez años, pero en 2020, a menos de un año de haberse declarado la pandemia, ya se habían publicado ensayos clínicos que demostraban la eficacia de varias vacunas producidas mediante tecnologías novedosas [2]. Son numerosas las vacunas contra el SARS-CoV-2 que han sido autorizadas para su uso. A la fecha, más de 12 mil millones de dosis de vacunas han sido administradas en el mundo [3]. Se estima que tres dosis de vacunas pueden evitar hasta en un 94 % el riesgo de uso de ventilación mecánica y muerte [4], así mismo, estudios demuestran que el riesgo de mortalidad por COVID-19 en los no vacunados es 25 veces mayor que en los vacunados

Editorial: Special Issue on the "Molecular Biology of Disease Vectors".

Arthropod disease vectors not only transmit malaria but many other serious diseases, many of which are, to a greater or lesser degree, neglected [...].

Vector-borne and other pathogens of potential relevance disseminated by relocated cats.

Large populations of unowned cats constitute an animal welfare, ecological, societal and public health issue worldwide. Their relocation and homing are currently carried out in many parts of the world with the intention of relieving suffering and social problems, while contributing to ethical and humane population control in these cat populations. An understanding of an individual cat's lifestyle and disease status by veterinary team professionals and those working with cat charities can help to prevent severe cat stress and the spread of feline pathogens, especially vector-borne pathogens, which can be overlooked in cats. In this article, we discuss the issue of relocation and homing of unowned cats from a global perspective. We also review zoonotic and non-zoonotic infectious agents of cats and give a list of practical recommendations for veterinary team professionals dealing with homing cats. Finally, we present a consensus statement consolidated at the 15th Symposium of the Companion Vector-Borne Diseases (CVBD) World Forum in 2020, ultimately to help veterinary team professionals understand the problem and the role they have in helping to prevent and manage vector-borne and other pathogens in relocated cats.

Sensitivity Analysis in an Immuno-Epidemiological Vector-Host Model.

Sensitivity Analysis (SA) is a useful tool to measure the impact of changes in model parameters on the infection dynamics, particularly to quantify the expected efficacy of disease control strategies. SA has only been applied to epidemic models at the population level, ignoring the effect of within-host virus-with-immune-system interactions on the disease spread. Connecting the scales from individual to population can help inform drug and vaccine development. Thus the value of understanding the impact of immunological parameters on epidemiological quantities. Here we consider an age-since-infection structured vector-host model, in which epidemiological parameters are formulated as functions of within-host virus and antibody densities, governed by an ODE system. We then use SA for these immuno-epidemiological models to investigate the impact of immunological parameters on population-level disease dynamics such as basic reproduction number, final size of the epidemic or the infectiousness at different phases of an outbreak. As a case study, we consider Rift Valley Fever Disease utilizing parameter estimations from prior studies. SA indicates that [Formula: see text] increase in within-host pathogen growth rate can lead up to [Formula: see text] increase in [Formula: see text] up to [Formula: see text] increase in steady-state infected host abundance, and up to [Formula: see text] increase in infectiousness of hosts when the reproduction number [Formula: see text] is larger than one. These significant increases in population-scale disease quantities suggest that control strategies that reduce the within-host pathogen growth can be important in reducing disease prevalence.

Extreme Precipitation Events and Infectious Disease Risk: A Scoping Review and Framework for Infectious Respiratory Viruses.

Extreme precipitation events (EPE) change the natural and built environments and alter human behavior in ways that facilitate infectious disease transmission. EPEs are expected with high confidence to increase in frequency and are thus of great public health importance. This scoping review seeks to summarize the mechanisms and severity of impacts of EPEs on infectious diseases, to provide a conceptual framework for the influence of EPEs on infectious respiratory diseases, and to define areas of future study currently lacking in this field. The effects of EPEs are well-studied with respect to enteric, vector-borne, and allergic illness where they are shown to moderately increase risk of illness, but not well-understood in relation to infectious respiratory illness. We propose a framework for a similar influence of EPEs on infectious respiratory viruses through several plausible pathways: decreased UV radiation, increased ambient relative humidity, and changes to human behavior (increased time indoors and use of heating and cooling systems). However, limited work has evaluated meteorologic risk factors for infectious respiratory diseases. Future research is needed to evaluate the effects of EPEs on infectious respiratory diseases using individual-level case surveillance, fine spatial scales, and lag periods suited to the incubation periods of the disease under study, as well as a full characterization of susceptible, vulnerable, and sensitive population characteristics.

IL-18: The Forgotten Cytokine in Dengue Immunopathogenesis.

Dengue fever is an infection by the dengue virus (DENV) transmitted by vector mosquitoes. It causes many infections in tropical and subtropical countries every year, thus posing a severe disease threat. Cytokine storms, one condition where many proinflammatory cytokines are mass-produced, might lead to cellular dysfunction in tissue/organ failures and often facilitate severe dengue disease in patients. Interleukin- (IL-) 18, similar to IL-1ß, is a proinflammatory cytokine produced during inflammation following inflammasome activation. Inflammatory stimuli, including microbial infections, damage signals, and cytokines, all induce the production of IL-18. High serum IL-18 is remarkably correlated with severely ill dengue patients; however, its possible roles have been less explored. Based on the clinical and basic findings, this review discusses the potential immunopathogenic role of IL-18 when it participates in DENV infection and dengue disease progression based on existing findings and related past studies.

Physiology and ecology combine to determine host and vector importance for Ross River virus.

Identifying the key vector and host species that drive the transmission of zoonotic pathogens is notoriously difficult but critical for disease control. We present a nested approach for quantifying the importance of host and vectors that integrates species' physiological competence with their ecological traits. We apply this framework to a medically important arbovirus, Ross River virus (RRV), in Brisbane, Australia. We find that vertebrate hosts with high physiological competence are not the most important for community transmission; interactions between hosts and vectors largely underpin the importance of host species. For vectors, physiological competence is highly important. Our results identify primary and secondary vectors of RRV and suggest two potential transmission cycles in Brisbane: an enzootic cycle involving birds and an urban cycle involving humans. The framework accounts for uncertainty from each fitted statistical model in estimates of species' contributions to transmission and has has direct application to other zoonotic pathogens.

[Progress in source tracking of SARS-CoV-2].

Coronavirus disease 2019 (COVID-19) pandemic has caused a total of 55 928 327 confirmed cases and 1 344 003 deaths as of November 19, 2020. But so far the origin of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) that causes this pandemic has remained undetermined. The purpose of this study is to review the current research of SARS-CoV-2 and the existing problems therein, which may provide inspiration for further researches. Existing evidence suggested that SARS-CoV-2 may be derived from bat coronavirus 40-70 years ago. During the evolution, this virus underwent extensive variations in the process of mutations and natural selection. Different genomic regions of SARS-CoV-2 may have different selection pressures, but all of which increase the difficulty of tracing the origin of this virus. A wide variety of animals have been considered as potential hosts of SARS-CoV-2, including cats, lions, tigers, dogs and minks. SARS-CoV-2 has a chance to transmit from humans to animals and can be transmitted among animals. Current research evidence has shown that China is not the original source of SARS-CoV-2. It is still unclear how the virus spreads to human, and efforts are still need to be made to explore the origin of SARS-CoV-2, its hosts and intermediate hosts, and the mechanism of its transmission across different species of animals.

[Position paper of the Italian Society of Cardiology (SIC) on COVID-19 vaccine priority in patients with cardiovascular diseases]. / Position paper della Società Italiana di Cardiologia (SIC): Priorità del vaccino COVID-19 nei pazienti con patologie cardiovascolari.

In over a year, the COVID-19 pandemic caused 2.69 million deaths and 122 million infections. Social isolation and distancing measures have been the only prevention available for months. Scientific research has done a great deal of work, developing in a few months safe and effective vaccines against COVID-19. In the European Union, nowadays, four vaccines have been authorized for use: Pfizer-BioNTech, Moderna, ChAdOx1 (AstraZeneca/Oxford), Janssen (Johnson & Johnson), and three others are currently under rolling review.Vaccine allocation policy is crucial to optimize the advantage of treatment preferring people with the highest risk of contagion. These days the priority in the vaccination program is of particular importance since it has become clear that the number of vaccines is not sufficient for the entire Italian population in the short term. Cardiovascular diseases are frequently associated with severe COVID-19 infections, leading to the worst prognosis. The elderly population suffering from cardiovascular diseases is, therefore, to be considered a particularly vulnerable population. However, age cannot be considered the only discriminating factor because in the young-adult population suffering from severe forms of heart disease, the prognosis, if affected by COVID-19, is particularly ominous and these patients should have priority access to the vaccination program. The aim of this position paper is to establish a consensus on a priority in the vaccination of COVID-19 among subjects suffering from different cardiovascular diseases.

[A Mythological Anamnesis: from AIDS Spiders to the Bats of Ebola or Covid-19 - Revised Version of the Paper Presented at the Colloquium "Cultural and Social Perspectives on Epidemics", musée du quai Branly-Jacques-Chirac, June 27, 2019]. / Une anamnèse mythologique : des araignées du sida aux chauves-souris d'Ebola ou de la Covid-19 ­ Version remaniée de la communication présentée au colloque Regards culturels et sociaux autour des épidémies, musée du quai Branly-Jacques-Chirac le 27 juin 2019.

This article focuses on some representations of the origin of AIDS and Ebola in Burkina Faso, against a new background of Covid-19 which began in early 2020 in connection with two animals: the spider and the bat. These are also, if not first and foremost, heroes of oral literature (from tales to myths) from this region of West Africa. It is up to anthropologists to explore the meandering symbolism and imagination of these liminal animals that move back and forth between the worlds inhabited by humans and the "bush" worlds of non-humans. Here arises a mythological anamnesis. These "trickster" animals challenge categories and understanding of both virologists and anthropologists.

Cet article porte sur quelques représentations de l'origine du sida et d'Ebola en pays lobi burkinabè, avec la Covid-19 en nouvel arrière-plan depuis le début de l'année 2020, en lien avec deux animaux : l'araignée et la chauve-souris. Ce sont aussi, voire d'abord, des héros de la littérature orale (des contes aux mythes) de cette région d'Afrique de l'Ouest. Des anthropologues ont exploré les méandres des symboliques et des imaginaires de ces animaux liminaires qui vont et viennent entre les mondes habités par les humains et les univers de « brousse ¼ des non-humains. Une anamnèse mythologique est mise à jour. Ces animaux rusés se jouent de nos catégories et de notre entendement, virologues et anthropologues ici confondus.

Insects and SARS-CoV-2: Analysis of the Potential Role of Vectors in European Countries.

ABSTRACT: SARS-CoV-2 is a coronavirus responsible for the pandemic that developed in China in late 2019. Transmission of the virus is predominantly direct, through exposure to infected respiratory secretions. As far as we know, arthropods play a key role in the transmission and spread of several viruses, and thus their role in the spread of COVID-19 deserves to be studied. The biological transmission of viral agents through insects is very complex. While mechanical transmission is more likely to happen, biological transmission is possible via blood-sucking arthropods, but this requires a high grade of compatibility between the vector and the pathogen. If the biological and mechanical transmission of SARS-CoV-2 by blood-sucking arthropods is excluded, a mechanical transmission by urban pests could take place. This risk is very low but it could be important in isolated environmental conditions, where other means of transmission are not possible. The presence of SARS-CoV-2 in non-blood-sucking arthropods in infected buildings, like hospitals and retirement homes, should be investigated.

Animal Hosts and Experimental Models of SARS-CoV-2 Infection.

Viruses arise through cross-species transmission and can cause potentially fatal diseases in humans. This is the case of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) which recently appeared in Wuhan, China, and rapidly spread worldwide, causing the outbreak of coronavirus disease 2019 (COVID-19) and posing a global health emergency. Sequence analysis and epidemiological investigations suggest that the most likely original source of SARS-CoV-2 is a spillover from an animal reservoir, probably bats, that infected humans either directly or through intermediate animal hosts. The role of animals as reservoirs and natural hosts in SARS-CoV-2 has to be explored, and animal models for COVID-19 are needed as well to be evaluated for countermeasures against SARS-CoV-2 infection. Experimental cells, tissues, and animal models that are currently being used and developed in COVID-19 research will be presented.

Climate change: how it impacts the emergence, transmission, resistance and consequences of viral infections in animals and plants.

The ongoing COVID-19 pandemic has made us wonder what led to its occurrence and what can be done to avoid such events in the future. As we document, one changing circumstance that is resulting in the emergence and changing the expression of viral diseases in both plants and animals is climate change. Of note, the rapidly changing environment and weather conditions such as excessive flooding, droughts, and forest fires have raised concerns about the global ecosystem's security, sustainability, and balance. In this review, we discuss the main consequences of climate change and link these to how they impact the appearance of new viral pathogens, how they may facilitate transmission between usual and novel hosts, and how they may also affect the host's ability to manage the infection. We emphasize how changes in temperature and humidity and other events associated with climate change influence the reservoirs of viral infections, their transmission by insects and other intermediates, their survival outside the host as well the success of infection in plants and animals. We conclude that climate change has mainly detrimental consequences for the emergence, transmission, and outcome of viral infections and plead the case for halting and hopefully reversing this dangerous event.