Project description:During viral infections cellular gene expression is subject to rapid alterations induced by both viral and antiviral mechanisms. In this study, we applied metabolic labeling of newly transcribed RNA with 4-thiouridine (4sU-tagging) to dissect the real-time kinetics of cellular and viral transcriptional activity during lytic murine cytomegalovirus (MCMV) infection. Microarray profiling on newly transcribed RNA obtained from different times during the first six hours of MCMV infection revealed discrete functional networks of cellular genes regulated with distinct kinetics at surprising temporal resolution. Most of these were undetectable in total RNA, either due to low temporal sensitivity of standard gene expression profiling using total RNA, or due to rapid (viral) counter-regulation. Furthermore, metabolic labeling and purification of newly transcribed RNA detailed the real-time kinetics and regulation of viral gene expression in absence of any interfering virion-associated RNA. Both qRT-PCR and next-generation sequencing of newly transcribed RNA demonstrated an unexpected peak of viral gene expression during the first two hours of infection including transcription of immediate early, early and even well characterized late genes. Interestingly, this peak was subject to rapid gene silencing (independent of the multiplicity of infection) with similar transcriptional activity only reached late in infection. For some genes, e.g. m152, this resulted in massive down-regulation of transcriptional activity by 6 hours post infection, which was not even reversed late in infection. Our findings thus highlight the importance of transcriptional activity during the first few hours of CMV infection and hint at novel mechanisms governing the kinetics of viral gene expression. In conclusion, studying real-time transcriptional activity during lytic CMV infection provides intriguing new insights into the regulation of cellular and viral gene expression. In total 13 samples were examined: 3 samples of total RNA (mock, 25, 48 hours past MCMV infection), 3 samples pre-existing RNA (mock, 25, 48 hpi), and 7 samples newly-transcribed RNA (mock, 1-2, 5-6, 11-12, 18-19, 24-25, 47-48 hpi)

Project description:Expression data from NIH-3T3 cells left uninfected or infected with MCMV for 2, 4 or 6h on total RNA as well as newly transcribed RNA labeled for 1-2, 3-4, and 5-6hpi. For newly transcribed RNA, the isolated RNA was labeled for 1h and separated from total cellular RNA following Trizol RNA preparation and thiol-specific biotinylation. We used microarrays to analyze the effects of MCMV infection in total and newly transcribed RNA. During viral infections cellular gene expression is subject to rapid alterations induced by both viral and antiviral mechanisms. In this study, we applied metabolic labeling of newly transcribed RNA with 4-thiouridine (4sU-tagging) to dissect the real-time kinetics of cellular and viral transcriptional activity during lytic murine cytomegalovirus (MCMV) infection. Microarray profiling on newly transcribed RNA obtained from different times during the first six hours of MCMV infection revealed discrete functional networks of cellular genes regulated with distinct kinetics at surprising temporal resolution. Most of these were undetectable in total RNA, either due to low temporal sensitivity of standard gene expression profiling using total RNA, or due to rapid (viral) counter-regulation. Furthermore, metabolic labeling and purification of newly transcribed RNA detailed the real-time kinetics and regulation of viral gene expression in absence of any interfering virion-associated RNA. Both qRT-PCR and next-generation sequencing of newly transcribed RNA demonstrated an unexpected peak of viral gene expression during the first two hours of infection including transcription of immediate early, early and even well characterized late genes. Interestingly, this peak was subject to rapid gene silencing (independent of the multiplicity of infection) with similar transcriptional activity only reached late in infection. For some genes, e.g. m152, this resulted in massive down-regulation of transcriptional activity by 6 hours post infection, which was not even reversed late in infection. Our findings thus highlight the importance of transcriptional activity during the first few hours of CMV infection and hint at novel mechanisms governing the kinetics of viral gene expression. In conclusion, studying real-time transcriptional activity during lytic CMV infection provides intriguing new insights into the regulation of cellular and viral gene expression. NIH-3T3 cells (5th to 15th passage after thawing) were split from confluent plates 24h before start of the experiment. At the beginning of the experiment about 80% confluency was reached. The experiment was started by applying fresh, prewarmed, CO2-equilibrated medium containing either mock or MCMV particles (MOI 1). The MOI was increased by ~10-fold through centrifugal enhancement (2000g, 30min). Labeling was started 1, 3, or 5hpi after the end of centrifugal enhancement.

Project description:During viral infections cellular gene expression is subject to rapid alterations induced by both viral and antiviral mechanisms. In this study, we applied metabolic labeling of newly transcribed RNA with 4-thiouridine (4sU-tagging) to dissect the real-time kinetics of cellular and viral transcriptional activity during lytic murine cytomegalovirus (MCMV) infection. Microarray profiling on newly transcribed RNA obtained from different times during the first six hours of MCMV infection revealed discrete functional networks of cellular genes regulated with distinct kinetics at surprising temporal resolution. Most of these were undetectable in total RNA, either due to low temporal sensitivity of standard gene expression profiling using total RNA, or due to rapid (viral) counter-regulation. Furthermore, metabolic labeling and purification of newly transcribed RNA detailed the real-time kinetics and regulation of viral gene expression in absence of any interfering virion-associated RNA. Both qRT-PCR and next-generation sequencing of newly transcribed RNA demonstrated an unexpected peak of viral gene expression during the first two hours of infection including transcription of immediate early, early and even well characterized late genes. Interestingly, this peak was subject to rapid gene silencing (independent of the multiplicity of infection) with similar transcriptional activity only reached late in infection. For some genes, e.g. m152, this resulted in massive down-regulation of transcriptional activity by 6 hours post infection, which was not even reversed late in infection. Our findings thus highlight the importance of transcriptional activity during the first few hours of CMV infection and hint at novel mechanisms governing the kinetics of viral gene expression. In conclusion, studying real-time transcriptional activity during lytic CMV infection provides intriguing new insights into the regulation of cellular and viral gene expression.

Project description:Primary human foreskin fibroblasts (HFF) were infected with wild-type simplex virus 1 (HSV-1) strain 17 at a multiplicity of infection (MOI) of 10. Newly transcribed RNA was labelled by adding 500µM 4-thiouridine (4sU) to the cell culture media for 1h. Total cellular RNA was isolated using Trizol. Newly transcribed RNA was purified following the protocol described in Raedle et al. JoVE 2013. Newly transcribed RNA was labelled in one hour intervals during the first eight hours of HSV-1 infection. All nine 4sU-RNA samples as well as total cellular RNA of every second hour of infection were sent for sequencing. Two independent biological replicates were analysed.

Project description:One goal of viral infection is to reprogram the host cell to optimize viral replication. As part of this process, viral miRNAs may compete for components of the miRNA/siRNA pathway as well as regulate cellular targets. Mouse Cytomegalovirus has been described to generate large numbers of viral miRNAs during lytic infection and was therefore used to analyze the impact of viral miRNAs on the host cell small RNA system as well as to check for sorting of viral small RNAs into specific Ago-proteins. Deep sequencing analysis of MCMV infected cells revealed that viral miRNAs represent only app. 13% of all detected miRNAs. All previously described MCMV miRNAs with the exception of miR-m88-1* were confirmed and for the MCMV miR-m01-1 hairpin an additional miRNA, designated miR-m01-1-3p, was found. Its presence was confirmed by qPCR and Northern Blot. Deep sequencing after RISC IP with antibodies specific for either Ago1 or Ago2 showed that all MCMV miRNAs are loaded into both RISC complexes. The ratio of MCMV to mouse miRNAs was not increased after immunoprecipitation of Ago-proteins. Viral miRNAs therefore do not overwhelm the host miRNA processing system nor are they preferentially incorporated into RISC. We found that 3 mouse miRNAs showed an altered expression due to MCMV infection. Down-regulation of miR-27a, as previously described, could be confirmed. In addition, miR-26a was down-regulated and an up-regulation of miR-7a dependent on viral protein expression could be observed. Examination of small RNA expression in uninfected vs. infected cells, immunoprecipitation + sequencing of Ago1 and Ago2 loaded small RNAs in infected cells

Project description:Cytomegaloviruses express large amounts of viral miRNAs during lytic infection, yet, they only modestly alter the cellular miRNA profile. The most prominent alteration upon lytic murine cytomegalovirus (MCMV) infection is the rapid degradation of the cellular miR-27a and miR-27b. Here, we report that this regulation is mediated by the <1.7 kb spliced and highly abundant MCMV m169 transcript. Specificity to miR-27a/b is mediated by a single, apparently optimized, miRNA binding site located in its 3'-UTR. This site is easily and efficiently retargeted to other cellular and viral miRNAs by target site replacement. Expression of the 3'-UTR of m169 by an adenoviral vector was sufficient to mediate its function, indicating that no other viral factors are essential in this process. Degradation of miR-27a/b was found to be accompanied by 3'-tailing and -trimming. Despite its dramatic effect on miRNA stability, we found this interaction to be mutual, indicating potential regulation of m169 by miR-27a/b. Most interestingly, three mutant viruses no longer able to target miR-27a/b, either due to miRNA target site disruption or target site replacement, showed significant attenuation in multiple organs as early as 4 days post infection, indicating that degradation of miR-27a/b is important for efficient MCMV replication in vivo. Small RNA sequencing from total RNA or Ago2 associated small RNAs extracted from mock- or MCMV-infected NIH-3T3 cells

Project description:One goal of viral infection is to reprogram the host cell to optimize viral replication. As part of this process, viral miRNAs may compete for components of the miRNA/siRNA pathway as well as regulate cellular targets. Mouse Cytomegalovirus has been described to generate large numbers of viral miRNAs during lytic infection and was therefore used to analyze the impact of viral miRNAs on the host cell small RNA system as well as to check for sorting of viral small RNAs into specific Ago-proteins. Deep sequencing analysis of MCMV infected cells revealed that viral miRNAs represent only app. 13% of all detected miRNAs. All previously described MCMV miRNAs with the exception of miR-m88-1* were confirmed and for the MCMV miR-m01-1 hairpin an additional miRNA, designated miR-m01-1-3p, was found. Its presence was confirmed by qPCR and Northern Blot. Deep sequencing after RISC IP with antibodies specific for either Ago1 or Ago2 showed that all MCMV miRNAs are loaded into both RISC complexes. The ratio of MCMV to mouse miRNAs was not increased after immunoprecipitation of Ago-proteins. Viral miRNAs therefore do not overwhelm the host miRNA processing system nor are they preferentially incorporated into RISC. We found that 3 mouse miRNAs showed an altered expression due to MCMV infection. Down-regulation of miR-27a, as previously described, could be confirmed. In addition, miR-26a was down-regulated and an up-regulation of miR-7a dependent on viral protein expression could be observed.

Project description:Human cytomegalovirus (HCMV) infection in infants cause severe diseases, such as neonatal hepatitis. However, the single-cell dimensional description of the immune cell alteration during the first virus exposure process in infants, remains poorly understood. The hepatocytes play an essential role in metabolic homeostasis and detoxification. The Concomitant Effects of CMV infection on liver lipid metabolism in infants are still unclear. Here, using single-cell RNA-sequencing, we found MCMV can infect most cell types of infant mice liver, changing the number of immune cells. MCMV infection increases proliferating CD8 effector T cells and a subset of Nos2+ monocytes, which may play important roles in the early anti-viral process. Furthermore, MCMV infection subvert the protein expression profile of lipid metabolism in hepatocytes. Overall, our data provide insights as to how the immune system response to MCMV infection during the early stage of infection, and the impact of infection on lipid metabolism in infant mice hepatocytes.

Project description:Primary human foreskin fibroblasts (HFF) were infected with the indicated HSV-1 strains and mutants thereof at a multiplicity of infection (MOI) of 10. Newly transcribed RNA was labelled by adding 500µM 4-thiouridine (4sU) to the cell culture media for 1h. Total cellular RNA was isolated using Trizol. Newly transcribed RNA was purified following the protocol described in Raedle et al. JoVE 2013.

Project description:Primary human foreskin fibroblasts (HFF) were infected with vhs-null mutant of HSV-1 strain 17 at a multiplicity of infection (MOI) of 10. Newly transcribed RNA was labelled by adding 500µM 4-thiouridine (4sU) to the cell culture media for 1h. Total cellular RNA was isolated using Trizol. Newly transcribed RNA was purified following the protocol described in Raedle et al. JoVE 2013.