Aedes albopictus (Diptera:Culicidae) is incompetent as a vector of hepatitis C virus

The potentiality of Culex pipiens (Diptera: Culicidae) complex holobiont in transmitting the hepatitis C virus (HCV) with the aid of bacterial microbiota in the midgut

Background

The possibility of considering Culex pipiens (Cx. pipiens) as a vector for transmitting the hepatitis C virus (HCV) is controversial and needs further investigation. This work aimed to detect the possibility of transmission of the hepatitis C virus by Cx. pipiens and the role of the bacterial microbiota in their midgut.

Main body

Two groups of symbiotic and aposymbiotic of female Cx. pipiens were infected with the hepatitis C virus using an artificial feeding membrane technique. The viral load was detected in the head region for up to 60 min in the infected symbiotic group and 90 min in the aposymbiotic group. The midgut region can harbor the virus for 5 days after feeding. The absence of gut microbiota increases the potentiality of ten females to carry high titer of infective dose (1.2 × 106 IU/ml) of HCV genotype 4a for 6 days. The bacterial midgut microbiota appears to play a significant role in the transmission of HCV. On the other hand, HCV was not detected in the salivary glands of either symbiotic or aposymbiotic mosquitoes during the detection period. Cx. pipiens can transmit HCV from infected female adult mosquitoes to HCV-negative human blood in vitro. The biological parameters were survival rate, blood feeding, oviposition, hatchability rates, and mean digestion period of Cx. pipiens after infection with HCV showed significant changes. Moreover, an ex vivo assay demonstrated that HCV-infected mosquitoes could transmit the virus RNA into healthy blood.

Conclusion

The results suggested that the mosquitoes’ mechanical transmission of HCV was reasonable. In addition, the mosquito microbiome played a significant role in determining the potentiality of mosquitoes as a vector for disseminating HCV infections.

Graphic abstract

Reduced fitness of the mosquito Culex pipiens (Diptera: Culicidae) after feeding on a blood meal with hepatitis C virus

Hepatitis C virus (HCV) is a blood-borne virus. Given that mosquitoes can take blood meals from HCV patients, we aimed to test whether HCV in the blood meal can induce alterations in the biology of Culex pipiens. To address this aim, Cx. pipiens females were fed HCV-negative blood from healthy individuals or HCV-positive fresh blood samples harvested from viremic HCV patients. Replication of HCV in mosquitoes was confirmed by negative strand-specific RT-PCR and sequencing of RNA extracted from the mosquito bodies 7 days post-feeding. In addition, several parameters that determine the fitness of the mosquitoes were measured. Virus acquisition was associated with alterations in the architecture of the gut microvilli and the immune response, indicated by an increase in phenol oxidase activity. Interestingly, the mosquitoes that were fed the HCV-positive blood meal showed shorter median longevity (8 days) and laid fewer eggs than the control mosquitoes. Furthermore, the offspring of females fed the HCV-positive blood meal demonstrated a lower emergence rate than the controls. In sum, the results indicate that feeding on HCV by Cx. pipiens decreases fitness, which may, in turn, affect its potential as a vector.

Does the mosquito Culex pipiens represent a potential vector of hepatitis C virus?

Infection with hepatitis C virus (HCV) is a public health burden in several countries. Although transmission through blood is the most likely potential route of HCV infection, other sources warrant exploration. This study was designed to examine the possibility that the mosquito Culex pipiens (Diptera: Culicidae) might serve as a vector of HCV. A series of laboratory experiments were conducted in female Cx. pipiens that were fed on blood taken from HCV patients and tested for the presence of HCV RNAs using a reverse transcription polymerase chain reaction technique. In addition, the ability of the female mosquito to transmit HCV to human blood through membrane feeding or to its offspring (larvae) was tested. Although positive strand RNA was detected on days 1,7 and 14, negative strand HCV RNA was detected in mosquito body homogenate on days 7 and 14. Positive strands were also detected in the head, alimentary canal and salivary glands of mosquito adults at 1 week post-feeding, as well as in their offspring (larvae). An ex vivo assay demonstrated that HCV-infected mosquitoes were able to transmit the virus RNA into naive human blood samples via a membrane feeder. The present data indicate that the mosquito Cx. pipiens may be a potential vector of HCV.

New insights into HCV replication in original cells from Aedes mosquitoes

BACKGROUND

The existing literature about HCV association with, and replication in mosquitoes is extremely poor. To fill this gap, we performed cellular investigations aimed at exploring (i) the capacity of HCV E1E2 glycoproteins to bind on Aedes mosquito cells and (ii) the ability of HCV serum particles (HCVsp) to replicate in these cell lines.

METHODS

First, we used purified E1E2 expressing baculovirus-derived HCV pseudo particles (bacHCVpp) so we could investigate their association with mosquito cell lines from Aedes aegypti (Aag-2) and Aedes albopictus (C6/36). We initiated a series of infections of both mosquito cells (Ae aegypti and Ae albopictus) with the HCVsp (Lat strain - genotype 3) and we observed the evolution dynamics of viral populations within cells over the course of infection via next-generation sequencing (NGS) experiments.

RESULTS

Our binding assays revealed bacHCVpp an association with the mosquito cells, at comparable levels obtained with human hepatocytes (HepaRG cells) used as a control. In our infection experiments, the HCV RNA (+) were detectable by RT-PCR in the cells between 21 and 28 days post-infection (p.i.). In human hepatocytes HepaRG and Ae aegypti insect cells, NGS experiments revealed an increase of global viral diversity with a selection for a quasi-species, suggesting a structuration of the population with elimination of deleterious mutations. The evolutionary pattern in Ae albopictus insect cells is different (stability of viral diversity and polymorphism).

CONCLUSIONS

These results demonstrate for the first time that natural HCV could really replicate within Aedes mosquitoes, a discovery which may have major consequences for public health as well as in vaccine development.

RNA relics and origin of life

A number of small RNA sequences, located in different non-coding sequences and highly preserved across the tree of life, have been suggested to be molecular fossils, of ancient (and possibly primordial) origin. On the other hand, recent years have revealed the existence of ubiquitous roles for small RNA sequences in modern organisms, in functions ranging from cell regulation to antiviral activity. We propose that a single thread can be followed from the beginning of life in RNA structures selected only for stability reasons through the RNA relics and up to the current coevolution of RNA sequences; such an understanding would shed light both on the history and on the present development of the RNA machinery and interactions. After presenting the evidence (by comparing their sequences) that points toward a common thread, we discuss a scenario of genome coevolution (with emphasis on viral infectious processes) and finally propose a plan for the reevaluation of the stereochemical theory of the genetic code; we claim that it may still be relevant, and not only for understanding the origin of life, but also for a comprehensive picture of regulation in present-day cells.

Investigating the endemic transmission of the hepatitis C virus

The hepatitis C virus (HCV) infects at least 3% of people worldwide and is a leading global cause of liver disease. Although HCV spread epidemically during the 20th century, particularly by blood transfusion, it has clearly been present in human populations for several centuries. Here we attempt to redress the paucity of investigation into how long-term endemic transmission of HCV has been maintained. Such transmission not only represents the 'natural' route of infection but also contributes to new infections today. As a first step, we investigate the hypothesis that HCV can be mechanically transmitted by biting arthropods. Firstly, we use a combined bioinformatic and geographic approach to build a spatial database of endemic HCV infection and demonstrate that this can be used to geographically compare endemic HCV with the range distributions of potential vector species. Second, we use models from mathematical epidemiology to investigate if the parameters that describe the biting behaviour of vectors are consistent with a proposed basic reproduction number (R0) for HCV, and with the sustained transmission of the virus by mechanical transmission. Our analyses indicate that the mechanical transmission of HCV is plausible and that much further research into endemic HCV is needed.

Immunopathogenesis of hepatitis C virus infection

Hepatitis C virus, a recently identified member of the family Flaviviridae, is an important cause of chronic viral hepatitis and cirrhosis. There are similarities in the nature of the immune response to this pathogen with immunity in other flavivirus and hepatotropic virus infections, such as hepatitis B. However, the high rate of viral persistence after primary hepatitis C infection, and the observation that neutralizing antibodies are not protective, would suggest that there are a number of important differences between hepatitis C, other flaviviruses, and hepatitis B. The phenomenon of quasispecies evolution and other viral factors have been proposed to contribute to immune evasion by hepatitis C virus. In the face of established persistent infection, virus-specific cytotoxic T lymphocytes may exert some control over viral replication. However, these same effectors may also be responsible for the progressive liver damage characteristic of chronic hepatitis C infection. The nature of protective immunity, including the role of innate immune responses early after hepatitis C exposure, remains to be defined.

Rapid elimination of GB virus C (hepatitis G virus) in the mosquito Aedes aegypti

The transmissibility of the GB virus C (hepatitis G virus; HGV), a member of the Flaviviridae, by a typical flavivirus vector was investigated. Female mosquitoes of the species Aedes aegypti were fed with HGV-infected human blood and assayed 1, 24, 48, 72 and 96 h after the blood meal for viral RNA, human glyceraldehyde-3-phosphate dehydrogenase mRNA, human beta-actin DNA and A. aegypti actin mRNA by total nucleic acid extraction, reverse transcription and PCR. Viral RNA had already disappeared from nucleic acid extracts 1 h after the blood meal and was not detectable throughout the observation period. Aedes-specific mRNA served as an internal control and was detected in all nucleic acid extracts, whereas human mRNA had disappeared after 24 h, indicating digestion of human cells. From these results we conclude that GB virus C (HGV) cannot replicate in A. aegypti, which is a widespread and competent vector of several other flaviviruses.

The origin and evolution of hepatitis viruses in humans

The spread and origins of hepatitis C virus (HCV) in human populations have been the subject of extensive investigations, not least because of the importance this information would provide in predicting clinical outcomes and controlling spread of HCV in the future. However, in the absence of historical and archaeological records of infection, the evolution of HCV and other human hepatitis viruses can only be inferred indirectly from their epidemiology and by genetic analysis of contemporary virus populations. Some information on the history of the latter may be obtained by dating the time of divergence of various genotypes of HCV, hepatitis B virus (HBV) and the non-pathogenic hepatitis G virus (HGV)/GB virus-C (GBV-C). However, the relatively recent times predicted for the origin of these viruses fit poorly with their epidemiological distributions and the recent evidence for species-associated variants of HBV and HGV/GBV-C in a wide range of non-human primates. The apparent conservatism of viruses over long periods implied by these latter observations may be the result of constraints on sequence change peculiar to viruses with single-stranded genomes, or with overlapping reading frames. Large population sizes and intense selection pressures that optimize fitness may be the factors that set virus evolution apart from that of their hosts.