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Vector-borne diseases are mainly transmitted through the bites of infected arthropods. They are a major public health concern as they account for more than 700,000 deaths annually. Among many vector-borne pathogens, the neurotropic viruses have been contributing to the increased number of deaths across the globe due to severe neurological complications. Despite the advancement of vector control strategies, the prevalence and severity of neurotropic viral infections have not been alleviated till date. Anthropogenic activities cause persistent fluctuations in temperature and weather trends. This plays a major part in shaping the fate of transmission dynamics and pathogenesis of such diseases. Changes in climatic factors, such as global warming and delayed withdrawal of monsoon, have had huge impacts on stretching the window of disease transmission worldwide. The abundance, survival, feeding activity, and vectorial competence of the arthropods are expected to increase with rising temperatures. This review aims to discuss how climate change affects ecosystems, thereby influencing vectors and the associated neurotropic viruses. It also highlights the urgent need for the \"One Health\" strategy. It is a concept that recognizes that humans and animals do not exist in isolation and are part of a larger ecosystem where their activity and health are interconnected to one another. This holistic approach is essential in addressing the emerging threats posed by climate change, rising rates of infection, and epidemics across the globe.

Chikungunya virus (CHIKV) is a reemergent pathogen that has caused large outbreaks in the last 20 years. There are no available antiviral therapies, and a vaccine has only recently been approved. We describe the mode of action of an inhibitor designed to target CHIKV envelope proteins, blocking entry at the stage of fusion between the virus envelope and host membranes. Fusion is common to the entry of enveloped viruses. Virus envelope proteins drive fusion, undergoing a series of transitions from an initial metastable conformational state to a more stable post-fusion state. Intermediate conformations are transient and have mostly remained inaccessible to structure determination. Here, a selection of viruses that are resistant to antiviral inhibition of fusion uncovered a functional interaction between two residues residing in domains that are apart in both the pre-fusion and post-fusion states. Thus, we provide new insight into the molecular detail of the inner working of virus fusion machinery.

Usutu virus (USUV) is currently emerging in Europe, where it has caused numerous mass bird die-off events and neuroinvasive disease in humans. Multiple strains of USUV are circulating throughout Europe, but only some of them have been associated with severe disease in humans. The USUV proteins responsible for and the mechanisms through which they cause severe disease are unknown; however, this information could be invaluable in evaluating disease potential of specific strains and the creation of anti-viral therapies. Here, we swapped genes between USUV strains that cause mild and severe disease and were able to identify a viral protein that mediates virulence. We also discovered that the mild strain of USUV takes significantly longer to complete fusion during viral entry into host cells than the severe strain. This delayed fusion could have impacts on cellular tropism, viral kinetics, susceptibility of the virus to immune responses, and, ultimately, disease severity.

The emergence of a novel coronavirus (2019-nCoV) has awakened the echoes of SARS-CoV from nearly two decades ago. Yet, with technological advances and important lessons gained from previous outbreaks, perhaps the world is better equipped to deal with the most recent emergent group 2B coronavirus.

The global vaccination programme against smallpox led to its successful eradication and averted millions of deaths. Monkeypox virus (MPXV) is a close relative of the Variola (smallpox) virus. Due to antigenic similarity, smallpox vaccines cross-protect against MPXV. However, over 70% of people living today were never vaccinated against smallpox. Symptoms of monkeypox (MPX) include fever, head- and muscle ache, lymphadenopathy and a characteristic rash that develops into papules, vesicles and pustules which eventually scab over and heal. MPX is less often fatal (case fatality rates range from <1% to up to 11%) than smallpox (up to 30%). MPXV is endemic in sub-Saharan Africa, infecting wild animals and causing zoonotic outbreaks. Exotic animal trade and international travel, combined with the increasing susceptibility of the human population due to halted vaccination, facilitated the spread of MPXV to new areas. The ongoing outbreak, with >10,000 cases in >50 countries between May and July 2022, shows that MPXV can significantly spread between people and may thus become a serious threat to public health with global consequences. Here, we summarize the current knowledge about this re-emerging virus, discuss available strategies to limit its spread and pathogenicity and evaluate its risk to the human population.

Tomato brown rugose fruit virus (ToBRFV) is an emerging and rapidly spreading RNA virus that infects tomato and pepper, with tomato as the primary host. The virus causes severe crop losses and threatens tomato production worldwide. ToBRFV was discovered in greenhouse tomato plants grown in Jordan in spring 2015 and its first outbreak was traced back to 2014 in Israel. To date, the virus has been reported in at least 35 countries across four continents in the world. ToBRFV is transmitted mainly via contaminated seeds and mechanical contact (such as through standard horticultural practices). Given the global nature of the seed production and distribution chain, and ToBRFV's seed transmissibility, the extent of its spread is probably more severe than has been disclosed. ToBRFV can break down genetic resistance to tobamoviruses conferred by R genes Tm‐1, Tm‐2, and Tm‐22 in tomato and L1 and L2 alleles in pepper. Currently, no commercial ToBRFV‐resistant tomato cultivars are available. Integrated pest management‐based measures such as rotation, eradication of infected plants, disinfection of seeds, and chemical treatment of contaminated greenhouses have achieved very limited success. The generation and application of attenuated variants may be a fast and effective approach to protect greenhouse tomato against ToBRFV. Long‐term sustainable control will rely on the development of novel genetic resistance and resistant cultivars, which represents the most effective and environment‐friendly strategy for pathogen control. Taxonomy Tomato brown rugose fruit virus belongs to the genus Tobamovirus, in the family Virgaviridae. The genus also includes several economically important viruses such as Tobacco mosaic virus and Tomato mosaic virus. Genome and virion The ToBRFV genome is a single‐stranded, positive‐sense RNA of approximately 6.4 kb, encoding four open reading frames. The viral genomic RNA is encapsidated into virions that are rod‐shaped and about 300 nm long and 18 nm in diameter. Tobamovirus virions are considered extremely stable and can survive in plant debris or on seed surfaces for long periods of time. Disease symptoms Leaves, particularly young leaves, of tomato plants infected by ToBRFV exhibit mild to severe mosaic symptoms with dark green bulges, narrowness, and deformation. The peduncles and calyces often become necrotic and fail to produce fruit. Yellow blotches, brown or black spots, and rugose wrinkles appear on tomato fruits. In pepper plants, ToBRFV infection results in puckering and yellow mottling on leaves with stunted growth of young seedlings and small yellow to brown rugose dots and necrotic blotches on fruits. This pathogen profile summarizes current knowledge about ToBRFV, highlights recent research progress, discusses future research directions, and proposes short‐run and long‐term control strategies.

In recent years, viruses similar to those that cause serious disease in humans and other mammals have been detected in apparently healthy bats. These include filoviruses, paramyxoviruses, and coronaviruses that cause severe diseases such as Ebola virus disease, Marburg haemorrhagic fever and severe acute respiratory syndrome (SARS) in humans. The evolution of flight in bats seem to have selected for a unique set of antiviral immune responses that control virus propagation, while limiting self-damaging inflammatory responses. Here, we summarize our current understanding of antiviral immune responses in bats and discuss their ability to co-exist with emerging viruses that cause serious disease in other mammals. We highlight how this knowledge may help us to predict viral spillovers into new hosts and discuss future directions for the field.

Coronavirus disease 2019 (COVID-19) caused by SARS-CoV-2 infection has spread rapidly across the world and become an international public health emergency. Both SARS-CoV-2 and SARS-CoV belong to subfamily Coronavirinae in the family Coronaviridae of the order Nidovirales and they are classified as the SARS-like species while belong to different cluster. Besides, viral structure, epidemiology characteristics and pathological characteristics are also different. We present a comprehensive survey of the latest coronavirus—SARS-CoV-2—from investigating its origin and evolution alongside SARS-CoV. Meanwhile, pathogenesis, cardiovascular disease in COVID-19 patients, myocardial injury and venous thromboembolism induced by SARS-CoV-2 as well as the treatment methods are summarized in this review.

Background The rate at which COVID-19 has spread throughout the globe has been alarming. While the role of fomite transmission is not yet fully understood, precise data on the environmental stability of SARS-CoV-2 is required to determine the risks of fomite transmission from contaminated surfaces. Methods This study measured the survival rates of infectious SARS-CoV-2, suspended in a standard ASTM E2197 matrix, on several common surface types. All experiments were carried out in the dark, to negate any effects of UV light. Inoculated surfaces were incubated at 20 °C, 30 °C and 40 °C and sampled at various time points. Results Survival rates of SARS-CoV-2 were determined at different temperatures and D-values, Z-values and half-life were calculated. We obtained half lives of between 1.7 and 2.7 days at 20 °C, reducing to a few hours when temperature was elevated to 40 °C. With initial viral loads broadly equivalent to the highest titres excreted by infectious patients, viable virus was isolated for up to 28 days at 20 °C from common surfaces such as glass, stainless steel and both paper and polymer banknotes. Conversely, infectious virus survived less than 24 h at 40 °C on some surfaces. Conclusion These findings demonstrate SARS-CoV-2 can remain infectious for significantly longer time periods than generally considered possible. These results could be used to inform improved risk mitigation procedures to prevent the fomite spread of COVID-19.

Mosquito-borne viruses represent a major global public health threat, with transmission dynamics governed by climatic, ecological, and anthropogenic factors. Yantai City, Shandong Province, situated in a warm-temperate monsoon climate zone, shares geographical and ecological characteristics with regions where mosquito-borne viruses are endemic, creating potential for virus introduction. We used metagenomics to systematically analyze viral communities in mosquitoes from the Yantai region. We collected 8,111 mosquitoes representing four genera and six species, with being predominant (89.8%). High-throughput sequencing revealed 11 viral species spanning 9 families, including Peribunyaviridae and Picornaviridae. Notably, Serbia mononega-like virus 1 and Biggievirus Mos11 represent the first reports from China, with quantitative reverse transcription PCR revealing minimum infection rates of 0.34% and 0.68%, respectively. Phylogenetic analysis revealed close relationships to known viral strains, with several isolates potentially representing novel genera or species. Analysis revealed that harbored the greatest viral diversity (five species), with significantly higher viral diversity in agricultural versus urban areas ( < 0.001). Several viruses demonstrated cross-species transmission potential, including Zhee mosquito virus, Zhejiang mosquito virus 3, and rhabdovirus, all detected across multiple mosquito species. While most viruses appear mosquito-specific, several show close phylogenetic relationships to known pathogens, potentially posing public health risks warranting surveillance. This study addresses knowledge gaps regarding mosquito-borne viruses in the Bohai Rim region and provides a scientific foundation for regional viral surveillance and early warning systems.IMPORTANCEMosquito-borne viruses are a significant global health threat, with the potential to cause widespread disease outbreaks. This study investigated the viral diversity within mosquito populations in Yantai, China, and characterized the molecular features of two emerging RNA viruses. These findings highlight the remarkable viral diversity harbored by Culex mosquitoes and reveal higher viral diversity in agricultural areas compared to urban settings. Several identified viruses exhibit cross-species transmission potential and close phylogenetic relationships to known pathogens, suggesting that they may pose public health risks. Understanding these interactions is essential for predicting how environmental changes may affect virus transmission and the resilience of surveillance and control strategies.