Viruses in three of the four established genera of the family Caliciviridae have been detected in pigs (Sapovirus, Norovirus and Vesivirus), making this animal species of particular interest in the study of calicivirus pathogenesis and host range. The Cowden strain of porcine enteric calicivirus (PEC), a sapovirus, was discovered in a diarrheic pig fecal sample in the US in 1980. Since then, sapoviruses have become recognized as a predominant calicivirus detected in pigs. The Cowden PEC strain grows efficiently in a unique cell culture system, and a reverse genetics system has been developed for elucidation of the mechanisms of replication and pathogenesis at the molecular level. Porcine noroviruses share genetic relatedness with those from humans, and recent studies have shown that pigs are susceptible to infection and mild diarrheal disease when experimentally challenged with related human norovirus strains. Research on porcine caliciviruses has yielded new insights into the mechanisms of pathogenesis, replication, and evolution of the family Caliciviridae.

Further reading: Caliciviruses: Molecular and Cellular Virology

Labels: Norovirus, Pig Caliciviruses, Sapovirus, Swine calicivirus, Vesivirus

Recently, reverse genetics and replicon systems have been developed and are starting to be used in the elucidation of the calicivirus replication and pathogenicity. Reverse genetics systems are available for feline calicivirus, porcine enteric calicivirus, murine norovirus, rabbit hemorrhagic disease virus and a rhesus monkey calicivirus. For uncultivable caliciviruses, such as human norovirus, cell-based replicon systems have been established. Norovirus replicon systems are used to screen potential antivirals and therapeutic options against norovirus infection. Replicon systems with reporter genes such as those encoding green fluorescent protein or luciferase allows quantitative analysis of cellular and viral factors that promote virus replication. Further studies with reverse genetics and replicon system could yield important information for cell culture adaptation of human noroviruses which is crucial for development of efficient vaccines and antivirals.

Further reading: Caliciviruses: Molecular and Cellular Virology

Labels: Caliciviridae, Lagovirus, Norovirus, Sapovirus, Vesivirus

Sequence analysis and experimentally determined three-dimensional structures of structural and nonstructural proteins from a range of caliciviruses help to provide a molecular framework for understanding many aspects of their replication strategies. Structures of intact virions, virus-like particles and capsid fragments, as well as capsid-receptor complexes help to explain basic mechanisms of capsid assembly and receptor recognition. Structural studies of the recombinant viral proteinase and polymerase in complex with substrates and inhibitors provide a basis for understanding substrate recognition and enzymatic mechanisms, thus setting the stage for the design of new antiviral compounds.

Further reading: Caliciviruses: Molecular and Cellular Virology

Labels: Caliciviridae, Calicivirus, Caliciviruses, Lagovirus, Norovirus, Sapovirus, Vesivirus

Caliciviruses are icosahedral nonenveloped viruses with a positive-sense single strand RNA genome that does not exceed 8.6 kb. Despite its small size, the virus genome encodes a number of nonstructural proteins that successfully facilitate and regulate mechanisms required for efficient virus amplification. Although caliciviruses show significant genetic diversity, they share a common protein expression strategy. Recent findings have shown that the nonstructural proteins of caliciviruses are produced by autocatalytic cleavage of a polyprotein encoded by ORF1 of the virus genome. A single virus protease structurally similar to a class of viral chymotrypsin-like cysteine proteases mediates these cleavages, and in some caliciviruses, adds to a release of the virus capsid protein. The temporal regulation of viral protein synthesis relies on the specificity of the protease and may be modulated by additional viral and cellular factors. The proteolytic processing results not only in the synthesis of the mature virus proteins, but also their precursors, whose functions have yet to be determined. Almost all calicivirus proteins have been identified as components of the virus replication complexes; however, their roles in replication are not entirely understood and remain an active and crucial target of calicivirus research.

Further reading: Caliciviruses: Molecular and Cellular Virology

Labels: Caliciviridae, Calicivirus, Caliciviruses, Lagovirus, Norovirus, Sapovirus, Vesivirus

Recombination was first described in the human caliciviruses in 1997. Since then naturally occurring recombinants have been detected for all four genera of the Caliciviridae and has become an important mechanism in the emergence of new calicivirus variants. Due to similarities in genome organization between the different genera, recombination predomoninantly occurs at the start of the major structural gene which encodes the capsid, VP1. Knowledge of the mechanisms of calicivirus recombination is important as new variants can emerge, with potentially different pathogenesis and virulence.

Further reading: Caliciviruses: Molecular and Cellular Virology

Labels: Caliciviridae, Calicivirus, Caliciviruses, Lagovirus, Norovirus, Sapovirus, Vesivirus

The virus family Caliciviridae contains four genera Norovirus, Sapovirus, Lagovirus and Vesivirus. Norovirus and sapovirus cause gastroenteritis in humans, while lagoviruses and vesiviruses mostly infect animals and cause a variety of diseases. Norovirus and sapoviruses can also infect a number of animals including cow and pig, respectively. Noroviruses are the dominant cause of human gastroenteritis around the world, infecting all age groups. Their low infectious dose and stability in the natural environment allows noroviruses to be easily spread. Contamination in food and water destined for human consumption has lead to numerous outbreaks of gastroenteritis. Noroviruses have been detected in shellfish, sandwiches, fruit, ice, drinking water and treated wastewater. Direct transmission from food and water to humans is well documented. Increased monitoring and improvements in detection methods may help to reduce the number of infections but regulations and standards need to be addressed in order to reduce viral contamination in the natural environment.

Further reading: Caliciviruses: Molecular and Cellular Virology

Labels: Caliciviridae, Calicivirus, Caliciviruses, Lagovirus, Norovirus, Sapovirus, Vesivirus

Noroviruses are the dominant cause of outbreaks as well as sporadic community cases of viral gastroenteritis in the world. Their very low infectious dose, combined with high levels of shedding and long persistence in the environment make noroviruses extremely infectious. Although generally norovirus related illness is regarded as mild and self-limiting, more severe outcomes are increasingly described among elderly and immuno-compromised patients. The combination of large and difficult to control outbreaks and severe illness in some patients leads to major problems in healthcare settings, such as hospitals and nursing homes. Additionally, some large and diffuse, multi-national and even multi-continent, foodborne-outbreaks have been described for norovirus, affecting up to thousands of people. With structured outbreak surveillance running in a number of regions across the world for the past ten years, it has become clear that the spread of noroviruses is global, although important information from developing countries is missing. At present, norovirus strains belonging to genogroup II genotype 4 (GII.4) are dominant worldwide. In the last ten years, at least three global pandemics involving GII.4 strains of different genetic variants occurred. Although a straightforward culturing method remains lacking for noroviruses, important progress has been made in immunological studies using virus-like particles. Thus it has been shown that the subsequent genetic variants of GII.4 are antigenically distinct, and that the GII.4 noroviruses evolved and continue to do so by a process known as epochal evolution, in which periods of genetic stasis are interrupted by rapid accumulation of mutations and the subsequent emergence of novel genetic variants. In norovirus evolution, this process is directed by population or herd immunity.

Further reading: Caliciviruses: Molecular and Cellular Virology

Labels: Caliciviridae, Calicivirus, Caliciviruses, Lagovirus, Norovirus, Sapovirus, Vesivirus

Members of the Caliciviridae family (caliciviruses) are positive-sense, single stranded RNA viruses containing four recognized genera: Norovirus, Sapovirus, Lagovirus and Vesivirus. They are ubiquitous in the environment and are a major cause of disease in humans and many animals. Examples include Norwalk virus, a norovirus, thought to be responsible for roughly 90% of epidemic, non-bacterial outbreaks of gastroenteritis in humans around the world. Lack of a suitable cell culture system for human caliciviruses limited studies in previous decades, however the recent application of modern genomic technologies has revolutionized the field, leading to an explosion in calicivirus publications.

Further reading: Caliciviruses: Molecular and Cellular Virology

Labels: Caliciviridae, Calicivirus, Caliciviruses, Lagovirus, Norovirus, Sapovirus, Vesivirus

A new book on Caliciviruses edited by Grant S. Hansman, Jason Jiang and Kim Y. Green has been announced today.

Caliciviruses are positive-sense, single stranded RNA viruses containing four recognized genera: Norovirus, Sapovirus, Lagovirus and Vesivirus. They are ubiquitous in the environment and are a major cause of disease in humans and many animals. Examples include Norwalk virus, a norovirus, thought to be responsible for roughly 90% of epidemic, non-bacterial outbreaks of gastroenteritis in humans around the world. Lack of a suitable cell culture system for human caliciviruses limited studies in previous decades, however the recent application of modern genomic technologies has revolutionized the field, leading to an explosion in calicivirus publications.



Caliciviruses: Molecular and Cellular Virology
Edited by: Grant S. Hansman, Jason Jiang and Kim Y. Green
Published: 2010  
ISBN: 978-1-904455-63-9
Price: GB £159 or US $310
In this book, a panel of expert calicivirologists have selected the most important up-to-date research findings to produce timely and comprehensive reviews of the respective calicivirus field. Each chapter gives the reader a brief introduction to the topic followed by a descriptive discussion of the past and present research areas. Topics include: norovirus epidemiology; calicivirus contamination of the environment; genome organization and recombination, proteolytic cleavage and viral proteins; viral protein structures; virus-host interactions; calicivirus reverse genetics and replicon systems; feline calicivirus; swine calicivirus; murine norovirus pathogenesis and immunity; murine norovirus translation, replication and reverse genetics; and lagoviruses read more ...

Further reading: Caliciviruses

Labels: Caliciviruses, Lagovirus, Norovirus, Sapovirus, Vesivirus, virology, virology books