Zika virus transmission via breast milk in suckling mice

ObjectivesInfectious Zika viral particles were detected in human milk; however, whether they can be transmitted via breastfeeding remains unknown, so our objective was to clarify this.MethodsHere, in a natural breastfeeding model, wild-type (C57Bl/6; WT) or interferon α/β (IFNα/β) receptor-deficient (A129; KO) murine dams on day 1 post-delivery were infected with Zika virus (ZIKV) intraperitoneally, and the neonates were suckled. In a novel artificial feeding model, WT suckling mice at 1 day old were fed with ZIKV alone or ZIKV and human breast milk mixtures. Thereafter, the virus distribution, clinical progression and neuropathology in the WT or KO neonates were characterized to evaluate the risk of ZIKV transmission through breast milk.ResultsIn natural breastfeeding, viral RNAs (8/8) and infectious viral particles (7/8) were extensively present in the mammary glands of KO dams. All tested KO neonates (5/5), and none of WT neonates (0/9), were infected with ZIKV. In artificial feeding, 100% of the WT neonates (two groups, 12/12 and 16/16) were infected and developed some signs of neurodegeneration. ZIKV tended to seed and accumulate in the lungs and were subsequently disseminated to other tissues in both 16 naturally suckled and 19 artificially fed infected neonates. As human breast milk was mixed with ZIKV and fed to WT neonates, 45% individuals (9/20) were infected; in the infected neonates, the viral spread to the brain was delayed, and the clinical outcomes were alleviated.ConclusionsThese results demonstrated that suckling mice can be infected with ZIKV through suckling, and breast milk has potential antiviral activity, inhibiting ZIKV infection.     

Zika virus infection and implications for kidney disease

High-level and persistent viruria observed in patients infected by Zika virus (ZIKV) has been well documented. However, renal pathology in acutely infected, immunocompetent patients remains subclinical. Moreover, the long-term impact of ZIKV infection, replication, and persistence in the renal compartment of adults and infants as well as immunosuppressed patients and solid organ transplant (SOT) recipients is unknown. Mechanisms involving host and viral factors that limit or control ZIKV pathogenesis in the renal compartment are important yet unexplored. The observation that long-term viral shedding occurs in the renal compartment in the absence of clinical disease requires further investigation. In this review, I explore Zika virus-induced renal pathology in animal models, the dynamics of virus shedding in urine, virus replication in glomerular cells, ZIKV infection in human renal transplantation, and the potential impact of long-term persistent ZIKV infection in the renal compartment.     

Efficiencies and kinetics of infection in different cell types/lines by African and Asian strains of Zika virus

After recent outbreaks, Zika virus (ZIKV) was linked to severe neurological diseases including Guillain-Barré syndrome in adults and microcephaly in newborns. The severities of pathological manifestations have been associated with different ZIKV strains. To better understand the tropism of ZIKV, we infected 10 human and four nonhuman cell lines (types) with two African (IbH30656 and MR766) and two Asian (PRVABC59 and H/FP/2013) ZIKV strains. Cell susceptibility to ZIKV infection was determined by examining viral titers, synthesis of viral proteins, and replication of positive and negative strands of viral genome. Among nonhuman cell lines, only Vero cells were efficiently infected by ZIKV. Among human cell lines, all were permissive to ZIKV infection. However, 293T and HeLa cells showed differential susceptibility towards African strains. In 293T cells, the NS1 protein was expressed at the high level by African strains but was almost not expressed by Asian strains though there was no obvious difference in viral genome replication, suggesting that the differential susceptibility might be controlled at the stage of viral protein translation. This study provides comprehensive results of the permissiveness of different cell types to both African and Asian ZIKV strains, which might help clarify their different pathogenesis.     

The potential contribution of impaired brain glucose metabolism to congenital Zika syndrome

The Zika virus (ZIKV) became a major worldwide public concern in 2015 due to the congenital syndrome which presents the highest risk during the first trimester of pregnancy and includes microcephaly and eye malformations. Several cellular, genetic and molecular studies have shown alterations in metabolic pathways, endoplasmic reticulum (ER) stress, immunity and dysregulation of RNA and energy metabolism both in vivo and in vitro. Here we summarise the main metabolic complications, with a particular focus on the possibility that brain energy metabolism is altered following ZIKV infection, contributing to developmental abnormalities. Brain energetic failure has been implicated in neurological conditions such as autism disorder and epilepsy, as well as in metabolic diseases with severe neurodevelopmental complications such as Glut‐1 deficiency syndrome. Therefore, these energetic alterations are of wide‐ranging interest as they might be directly implicated in congenital ZIKV syndrome. Data showing increased glycolysis during ZIKV infection, presumably required for viral replication, might support the idea that the virus can cause energetic stress in the developing brain cells. Consequences may include neuroinflammation, cell cycle dysregulation and cell death. Ketone bodies are non‐glycolytic brain fuels that are produced during neonatal life, starvation or fasting, ingestion of high‐fat low‐carbohydrate diets, and following supplementation with ketone esters. We propose that dietary ketones might alter the course of the disease and could even provide some degree of prevention of ZIKV‐associated abnormalities and potentially related neurological conditions characterised by brain glucose impairment.     

Pathogenesis of mouse scrapie: dynamics of agent replication in spleen, spinal cord and brain after infection by different routes.

Groups of Compton white mice were infected with different doses of the Chandler (139A) strain of agent by one of the following routes of injection; intracerebral, intraperitoneal, intravenous, subcutaneous in the “scruff” of the neck or under the footpad. At weekly intervals, 3 mice were taken from each group and infectivity assays were performed on pools of spleen, brain and spinal cord to study the dynamics of agent replication during the early stages of incubation. All peripheral routes of infection gave a similar pattern in that agent replication started early in spleen and reached a plateau concentration of agent before replication occurred in spinal cord. Replication in spinal cord occurred after 25 to 42 per cent of the incubation period had elapsed and always preceded the onset of replication in brain (41 to 55 per cent of incubation period). This sequence is consistent with the spread of agent from spleen to spinal cord and thence to brain, possibly along neural pathways. Agent replication in brain started much sooner (13 to 19 per cent of incubation period) with the i.c. route of infection but replication in spinal cord followed the pattern found with peripheral routes of infection and occurred after 24 to 34 per cent of the incubation had elapsed.     

Pathogenesis of scrapie is faster when infection is intraspinal instead of intracerebral

Previous studies of mice infected peripherally with 139A scrapie showed that scrapie agent initially replicates outside the CNS and that invasion of the CNS occurs several weeks later by neural spread of infection along visceral autonomic fibres to the mid-thoracic cord, and thence to brain. Direct intracerebral infection of brain bypasses the need for extraneural replication and gives shorter incubation periods than peripheral routes. However, it was also found that the duration of the scrapie replication phase in brain, before clinical disease develops, is actually shorter with peripheral routes than with the intracerebral route. We have now investigated this surprising observation using the intraspinal route to reproduce just the neural phase of scrapie pathogenesis seen after peripheral infection. In studies of three strains of scrapie (263K, 139A and ME7) in either hamsters or mice, we have fulfilled the prediction that incubation periods should be shorter after intraspinal infection than after intracerebral infection. Detailed studies of 139A scrapie showed that the shorter incubation period by the intraspinal route could be accounted for by the shorter duration of the scrapie replication phase in brain before clinical disease developed. As a consequence, the severity of the vacuolar lesions in brain at the clinical stage of all three scrapie models was less after intraspinal infection than after intracerebral infection but the severities of vacuolation after intraspinal and intraperitoneal infection were remarkably similar. We speculate that (a) the site of injection (or of invasion) of the central nervous system determines which neural pathways become accessible for the spread of scrapie infection, and that (b) the duration of the neural phase of scrapie pathogenesis is related to the complexity of the pathways between the site of invasion and the clinical target areas in which, it is suggested, scrapie must replicate for disease to develop.     

Effects of PKR/RNase L-dependent and alternative antiviral pathways on alphavirus replication and pathogenesis

Type I interferons (IFN-alpha/beta) rapidly confer resistance to alphavirus infection in macrophages and dendritic cells (DC) as evidenced by the dramatically increased susceptibility of these cells in mice with the IFNAR1 subunit of the IFN-alpha/beta receptor ablated (IFNAR1-/-). Normal adult mice develop only a subclinical Sindbis virus infection, whereas infected IFNAR1-/- mice rapidly succumb to a fatal disease. Here, we investigated the individual and combined contributions of the two best characterized INF-alpha/beta-mediated antiviral pathways to the control of Sindbis virus replication: (1) the coupled 2-5A synthetase/RNase L pathway and (2) the double-stranded RNA-dependent protein kinase (PKR) pathway. Surprisingly, mice deficient in PKR, RNase L, and Mx-1 (triply-deficient [TD]) developed only subclinical infection. Although the permissivity of cells in lymph nodes draining the inoculation site was increased in the absence of PKR/RNase L, systemic dissemination of the virus infection was restricted by an alternative IFN-alpha/beta receptor-dependent mechanism. In vitro, suppression of early virus protein synthesis and virion production in primary bone marrow-derived dendritic cells (BMDC) was largely dependent on the PKR pathway. However, later in infection virion production was reduced even in the absence of PKR/RNase L by an IFN-alpha/beta receptor-dependent mechanism. Priming of BMDC with IFN-alpha/beta or IFN-gamma resulted in dose-dependent restriction of virus replication, largely independent of PKR and/or RNase L expression.     

The CD40/CD40 ligand interaction is required for resistance to toxoplasmic encephalitis

Since the CD40/CD40 ligand (CD40L) interaction is involved in the regulation of macrophage production of interleukin 12 (IL-12) and T-cell production of gamma interferon (IFN-gamma), effector cell functions associated with resistance to Toxoplasma gondii, the role of CD40L in immunity to this parasite was assessed. Infection of C57BL/6 mice with T. gondii results in an upregulation of CD40 expression on accessory cell populations at local sites of infection as well as in lymphoid tissues. Splenocytes from C57BL/6 mice infected with T. gondii for 5 days produced high levels of IL-12 and IFN-gamma when stimulated with toxoplasma lysate antigen, and blocking CD40L did not significantly alter the production of IFN-gamma or IL-12 by these cells. Similar results were observed with splenocytes and mononuclear cells isolated from the brains of chronically infected mice. Interestingly, although CD40L(-/-) mice infected with T. gondii produced less IL-12 than wild-type mice, they produced comparable levels of IFN-gamma but succumbed to toxoplasmic encephalitis 4 to 5 weeks after infection. The inability of CD40L(-/-) mice to control parasite replication in the brain correlated with the ability of soluble CD40L, in combination with IFN-gamma, to activate macrophages in vitro to control replication of T. gondii. Together, these results identify an important role for the CD40/CD40L interaction in resistance to T. gondii. However, this interaction may be more important in the control of parasite replication in the brain rather than the generation of protective T-cell responses during toxoplasmosis.     

Independent roles of perforin, granzymes, and Fas in the control of Friend retrovirus infection

Cytotoxic T-cells (CTL) play a central role in the recovery of mammalian hosts from retroviral infections. However, the molecular pathways that mediate the antiretroviral activity of CTL are still elusive. Here we explore the protective role of the two main cytolytic pathways of CTL, that is, granule exocytosis and Fas/Fas ligand (FasL), in acute and persistent Friend retrovirus (FV) infection of mice. For this purpose, we have used mutant mouse strains with targeted gene defects in one or more components of the two cytolytic pathways including perforin, granzyme A, granzyme B, Fas, and FasL. The important function of CTL in resistance of C57BL/6 (B6) mice to FV is emphasized by the finding that depletion of CD8+ T-cells prior to virus infection resulted in severe splenomegaly and high viral loads in blood and spleen tissue. Analysis of primary FV infection in knockout mice revealed that acute infection was readily controlled in the absence of functional Fas. Most notably in the presence of Fas/FasL each of the three effector molecules of the exocytosis pathway (i.e., perforin, granzyme A, and granzyme B) was capable on its own to mediate suppression of virus replication and protection from leukemia. However, triple knockout mice lacking perforin and the two granzymes were fully susceptible to FV-induced leukemia. In contrast to acute infection the Fas/FasL pathway was mandatory for effective control of FV replication during persistent infection. These findings suggest novel pathways of CTL-mediated viral defense and contribute towards a better understanding of the molecular mechanisms of CTL activity in retroviral infections.     

Selective vulnerability of neural cells and age-related susceptibility to OC43 virus in mice

Suckling CD 1 mice infected intracerebrally or extraneurally with OC43 virus developed a lethal neurotropic infection with high titres of virus in the brain. Examination of infected brain by routine H & E staining revealed no necrosis even in extensively infected tissue. Resistance to infection developed with increasing age, and by 20 days of age mice were completely insusceptible to i.c. inoculation. Virus replication was also demonstrable by FA staining, in spinal cord, dorsal root ganglia and retina. All other tissues were insusceptible and in particular, macrophages from both susceptible and resistant mice were found to be resistant to infection both in vivo and in vitro. Immunosuppression rendered 15 day old mice more susceptible to infection but adult mice remained insusceptible. The transfer of immune or non immune spleen cells from resistant mice did not confer resistance to newborn mice. Treatment of resistant mice with anti interferon globulin (AIG) did not render them more susceptible. These results indicate that the immune response is partially responsible for the development of resistance to OC43 infection but that it is only partially protective and other factors must also be required. The basis for the unique susceptibility of neural tissues in suckling mice is being investigated.     

Experimental Zika virus infection induces spinal cord injury and encephalitis in newborn Swiss mice

A widespread epidemic of Zika virus (ZIKV) infection was reported in 2015 in South and Central America, with neurological symptons including meningoencephalitis and Guillain-Barré syndrome in adults, besides an apparent increased incidence of microcephaly in infants born to infected mothers. It is becoming a necessity to have a trustworthy animal model to better understand ZIKV infection. In this study we used newborn white Swiss mice as a model to investigate the ZIKV strain recently isolated in Brazil. ZIKV was inoculated via intracerebral and subcutaneous routes and analysed through gross histopathology and immunohistochemistry. Here we demonstrated first that the intracerebral group (ICG) displayed severe cerebral lesions, with neuronal death, presence of apoptotic bodies, white matter degeneration and neutrophil perivascular cuffing. In the subcutaneous group (SCG), we observed moderate cerebral lesions, morphologically similar to that found in ICG and additional myelopathy, with architectural loss, marked by neuronal death and apoptotic bodies. Interestingly, we found an intense astrogliosis in brain of both groups, with increased immunoexpression of GFAP (glial fibrillary acidic protein) and presence of hypertrophic astrocytes. The spinal cord of subcutaneous group (SCG) exhibited reduction of astrocytes, but those positive for GFAP were hypertrophic and presented prolonged cellular processes. Finally significant lesions in the central nervous system (CNS) were present in newborn mice inoculated by both routes, but SCG method led to an important neurological manifestations (including myelopathy), during a longer period of time and appears for us to be a better model for ZIKV infection.     

Neuro-invasion of Chandipura virus mediates pathogenesis in experimentally infected mice

Neuro-tropism is a major feature in many viral infections. Chandipura virus produces neurological symptoms in naturally infected young children and experimentally infected suckling mice. This study was undertaken to find out the neuro-invasive behaviour of Chandipura virus in suckling mice. The suckling mice were infected with the virus via footpad injection. Different tissues were collected at 24-h intervals up to 96-h post infection and processed for virus quantification and histological study. Further confirming the virus predilection to nerves tissues, the adult mice were inoculated with the virus via different routes. The suckling mice experimental results revealed a progressive replication of virus in spinal cord and brain. The progressive-virus replication was not observed in the other tissues like kidney, spleen, liver etc. Histo-pathological lesions noticed in the spinal cord and brain tissues suggested the extensive damages in these tissues. In adult mice experiment, the virus replication observed only in the brain of the mice infected via intra-cerebral route. From this study, we conclude that nervous tissues are predilection sites for Chandipura virus replication in suckling and adult mice. In suckling mice, virus might transmit through nervous tissues for dissemination. In contrast, the adult mice the nervous terminal might not pick up the virus through footpad infection. The pathogenesis in mice might be due to the virus replication mediated damage in the central nervous system.     

Studies of the Influence of Host Defence Mechanisms on Infection of Mice with an Avirulent or Virulent Strain of Semliki Forest Virus

A defence mechanism either differentially induced or resisted by a virulent (V13) or an avirulent (A7) strain of Semliki Forest virus, which might explain their different patterns of infection in mice, has not been detected in virus-free extracts of muscle, blood and spleen from mice infected with either strain. The extracts contained low levels of interferon which were probably unrelated to the different infection patterns. The pattern of infection of A7 in mice during the first few days was similar in normal and in x-irradiated mice and in the latter the brain infection did not resemble that for the fatal V13 infection in normal animals. A previous infection with A7 prevented replication of V13 in the brain to its usually high and fatal levels.     

Pertussis toxin B-oligomer inhibits HIV infection and replication in hu-PBL-SCID mice

Bordetella pertussis toxin B-oligomer (PTX-B) has been shown to inhibit HIV infection and replication in vitro. The potential anti-viral effect of PTX-B was tested here in an in vivo surrogate model of HIV infection, i.e. SCID mice reconstituted with human peripheral blood leukocytes (PBL) (hu-PBL-SCID) and infected with a CCR5-dependent (R5) HIV-1 strain. SCID mice inoculated intra-peritoneal (i.p.) with PTX-B and then infected with the R5 strain SF-162 were sacrificed 7 days later and analyzed for human PBL (hu-PBL) lymphoid tissue reconstitution, infection of hu-PBL, plasma viremia and viral rescue from ex vivo-cultivated i.p. hu-PBL. Unlike mice treated with 500 ng per animal of PTX-B showing no evidence of viral inhibition, daily administration of PTX-B (50 ng per mouse) strongly inhibited virus infection and replication, as determined by undetectable viremia, absence of infected hu-PBL and lack of rescue of infectious HIV in most animals. Furthermore, PTX-B injection 2 h before and twice after infection prevented HIV-1 infection and replication in all (10/10) tested animals. Thus, PTX-B potently inhibited virus infection and replication in hu-PBL-SCID mice, supporting the hypothesis that it may represent a new pharmacological agent against HIV-1 infection.     

Dissemination of Listeria monocytogenes by Infected Phagocytes

In vitro data suggest that blood-borne Listeria monocytogenes organisms enter the central nervous system (CNS) by direct invasion of endothelial cells or by cell-to-cell spread from infected phagocytes to endothelial cells. However, a role for infected phagocytes in neuroinvasion and dissemination of L. monocytogenes in vivo has not been confirmed experimentally. Experiments described here tested whether L. monocytogenes-infected peripheral blood leukocytes (PBL) circulated in bacteremic mice and could establish organ infection in vivo. A mean of 30.5% of bacteria cultured from whole blood were PBL associated, and microscopy showed that 22.2% of monocytes and 1.6% of neutrophils were infected. PBL-associated bacteria spread to endothelial cells in vitro, indicating their potential for virulence in vivo. To test this possibility, mice were injected intravenously with infected PBL and CFU of bacteria in liver, spleen, and brain were quantified and compared with values for mice injected with broth-grown bacteria and in vitro-infected macrophage cell lines. An inoculum of infected macrophage cell lines led to greater numbers of bacteria in the liver than the numbers produced by a similar inoculum of broth-grown bacteria. In contrast, brain infection was best established by infected PBL. Results of intraperitoneal injection of infected peritoneal cells compared with results of injection with infected J774A.1 cells suggested that unrestricted intracellular bacterial replication within J774A.1 cells contributed to excessive liver infection in those mice. These data show dissemination of intracellular L. monocytogenes and indicate that phagocyte-facilitated invasion has a role in CNS infection in vivo. Heterogeneity with regard to bactericidal activity as well as to other phagocyte characteristics is a critical feature of this mechanism.     

The role of the spleen in the neuroinvasion of scrapie in mice

The pathogenesis of 139A scrapie has been studied in CW mice infected intraperitoneally (i.p.), intravenously (i.v.) or subcutaneously (s.c.). In mice splenectomised before i.p. infection, the evidence points to a neuroinvasive pathway from visceral lymph nodes (and other sites of scrapie replication in the peritoneum) to the thoracic spinal cord. However, in non-splenectomised mice, the major neuroinvasive pathway is clearly from spleen to thoracic cord because i.p. incubation periods are shorter and replication in the thoracic cord starts correspondingly earlier than in splenectomised mice. Studies of splenectomy at different times after i.p. infection show that pathogenesis becomes independent of the spleen once infection has initiated scrapie replication in the spinal cord. The simplest interpretation of all the evidence favours the spread of scrapie infection along splenic nerve fibres to the thoracic spinal cord. The same neuroinvasive pathway is suggested by the findings using the s.c. and i.v. routes of infection. In addition it was found that the 100-fold greater efficiency of infection by the i.v. compared to the i.p. route was entirely dependent on the spleen, because splenectomy before i.v. infection reduced its efficiency to the same as that found in i.p. infected (non-splenectomised) mice.     

加味二至丸通过抑制铁死亡减轻高脂血症小鼠肝脏脂质沉积

目的:观察加味二至丸对高脂血症模型小鼠肝脏脂质沉积及铁死亡相关蛋白表达的影响.方法:30只ApoE?/?小鼠随机分为模型组、辛伐他汀组和加味二至丸组,每组10只,另取10只相同背景的C57BL/6J小鼠作为正常对照组.模型组及各治疗组均给予高脂饲料喂养,正常对照组给予普通饲料喂养.造模12周后按分组分别给予相应的药物灌...