Project description:Dendritic cells can capture and transfer retroviruses in vitro across synaptic cell-cell contacts to uninfected cells, a process called trans-infection. Whether trans-infection contributes to retroviral spread in vivo remains unknown. Here, we visualize how retroviruses disseminate in secondary lymphoid tissues of living mice. We demonstrate that murine leukemia virus (MLV) and human immunodeficiency virus (HIV) are first captured by sinus-lining macrophages. CD169/Siglec-1, an I-type lectin that recognizes gangliosides, captures the virus. MLV-laden macrophages then form long-lived synaptic contacts to trans-infect B-1 cells. Infected B-1 cells subsequently migrate into the lymph node to spread the infection through virological synapses. Robust infection in lymph nodes and spleen requires CD169, suggesting that a combination of fluid-based movement followed by CD169-dependent trans-infection can contribute to viral spread.

Project description:The HIV envelope glycoprotein gp120 contains nine disulphide bridges and is highly glycosylated, carrying on average 24 N-linked glycans. Using a probability calculation, we here demonstrate that there is a co-localization of disulphide bridges and N-linked glycans in HIV-1 gp120, with a predominance of N-linked glycans in close proximity to disulphide bridges, at the C-terminal side of the involved cysteines. Also, N-glycans are frequently found immediately adjacent to disulphide bridges in gp120 at the N-terminal side of the involved cysteines. In contrast, N-glycans at positions close to, but not immediately neighboring disulphide bridges seem to be disfavored at the N-terminal side of the involved cysteines. Such a pronounced co-localization of disulphide bridges and N-glycans was also found for the N-glycans on glycoprotein E1 of the hepatitis C virus (HCV) but not for other heavily glycosylated proteins such as E2 from HCV and the surface GP from Ebola virus. The potential functional role of the presence of N-glycans near disulphide bridges in HIV-1 gp120 was studied using site-directed mutagenesis, either by deleting conserved N-glycans or by inserting new N-glycosylation sites near disulphide bridges. The generated HIV-1NL4.3 mutants were subjected to an array of assays, determining the envelope glycoprotein levels in mutant viral particles, their infectivity and the capture and transmission efficiencies of mutant virus particles by DC-SIGN. Three N-glycans located nearby disulphide bridges were found to be crucial for the preservation of several of these functions of gp120. In addition, introduction of new N-glycans upstream of several disulphide bridges, at locations where there was a significant absence of N-glycans in a broad variety of virus strains, was found to result in a complete loss of viral infectivity. It was shown that the N-glycan environment around well-defined disulphide bridges of gp120 is highly critical to allow efficient viral infection and transmission.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Retroviruses are capable of infectious horizontal transmission between hosts, usually between individuals within a single species, although a number of probable zoonotic infections resulting from transmission between different species of placental mammals have also been reported. Despite these data, it remains unclear how often interspecies transmission events occur or whether their frequency is influenced by the evolutionary distance between host taxa. To address this problem we used PCR to amplify and characterize endogenous retroviruses related to the murine leukemia viruses. We show that members of this retroviral genus are harbored by considerably more organisms than previously thought and that phylogenetic analysis demonstrates that viruses isolated from a particular host class generally cluster together, suggesting that infectious virus horizontal transfer between vertebrate classes occurs only rarely. However, two recent instances of transmission of zoonotic infections between distantly related host organisms were identified. One, from mammals to birds, has led to a rapid adaptive radiation into other avian hosts. The other, between placental and marsupial mammals, involves viruses clustering with recently described porcine retroviruses, adding to concerns regarding the xenotransplantation of pig organs to humans.

Project description:Porcine endogenous retroviruses (PERV) represent a major safety concern in pig-to-human xenotransplantation. To date, no PERV infection of a xenograft recipient has been recorded; however, PERVs are transmissible to human cells in vitro. Some recombinants of the A and C PERV subgroups are particularly efficient in infection and replication in human cells. Transcription of PERVs has been described in most pig cells, but their sequence and insertion polymorphism in the pig genome impede identification of transcriptionally active or silenced proviral copies. Furthermore, little is known about the epigenetic regulation of PERV transcription. Here, we report on the transcriptional suppression of PERV by DNA methylation in vitro and describe heavy methylation in the majority of PERV 5' long terminal repeats (LTR) in porcine tissues. In contrast, we have detected sparsely methylated or nonmethylated proviruses in the porcine PK15 cells, which express human cell-tropic PERVs. We also demonstrate the resistance of PERV DNA methylation to inhibitors of methylation and deacetylation. Finally, we show that the high permissiveness of various human cell lines to PERV infection coincides with the inability to efficiently silence the PERV proviruses by 5'LTR methylation. In conclusion, we suggest that DNA methylation is involved in PERV regulation, and that only a minor fraction of proviruses are responsible for the PERV RNA expression and porcine cell infectivity.

Project description:Chemically reprogramming somatic cells to iPSCs is time-consuming and low-efficiency. Here, we discribe a rapid chemical reprogramming condition enabling generating iPSCs from MEFs in 12 days. To further investigate the mechemisms and draw an epigenetic maps during the rapid chemical reprogramming, we performed time-course RNA-seq, ATAC-seq, RRBS and CUT&Tag (H3K4me3, H3K18la, H3K9me3, H3K27me3 and H3K27ac).

Project description:Chemically reprogramming somatic cells to iPSCs is time-consuming and low-efficiency. Here, we discribe a rapid chemical reprogramming condition enabling generating iPSCs from MEFs in 12 days. To further investigate the mechemisms and draw an epigenetic maps during the rapid chemical reprogramming, we performed time-course RNA-seq, ATAC-seq, RRBS, CUT&Tag (H3K4me3, H3K18la, H3K9me3, H3K27me3 and H3K27ac) and scRNA-seq.

Project description:Chemically reprogramming somatic cells to iPSCs is time-consuming and low-efficiency. Here, we discribe a rapid chemical reprogramming condition enabling generating iPSCs from MEFs in 12 days. To further investigate the mechemisms and draw an epigenetic maps during the rapid chemical reprogramming, we performed time-course RNA-seq, ATAC-seq, RRBS and CUT&Tag (H3K4me3, H3K18la, H3K9me3, H3K27me3 and H3K27ac).

Project description:Chemically reprogramming somatic cells to iPSCs is time-consuming and low-efficiency. Here, we discribe a rapid chemical reprogramming condition enabling generating iPSCs from MEFs in 12 days. To further investigate the mechemisms and draw an epigenetic maps during the rapid chemical reprogramming, we performed time-course RNA-seq, ATAC-seq, RRBS and CUT&Tag (H3K4me3, H3K18la, H3K9me3, H3K27me3 and H3K27ac).

Project description:Chemically reprogramming somatic cells to iPSCs is time-consuming and low-efficiency. Here, we discribe a rapid chemical reprogramming condition enabling generating iPSCs from MEFs in 12 days. To further investigate the mechemisms and draw an epigenetic maps during the rapid chemical reprogramming, we performed time-course RNA-seq, ATAC-seq, RRBS and CUT&Tag (H3K4me3, H3K18la, H3K9me3, H3K27me3 and H3K27ac).