Ras-Erk MAPK signaling controls many of the principal pathways involved in metazoan cell motility, drives metastasis of multiple cancer types and is targeted in chemotherapy. However, its putative roles in immune cell functions or in infections have remained elusive. Here, using primary dendritic cells (DCs) in an infection model with the protozoan Toxoplasma gondii, we show that two pathways activated by infection converge on Ras-Erk MAPK signaling to promote migration of parasitized DCs. We report that signaling through the receptor tyrosine kinase Met (also known as HGF receptor) contributes to T. gondii-induced DC hypermotility. Furthermore, voltage-gated Ca 2+ channel (VGCC, subtype Ca V 1.3) signaling impacted the migratory activation of DCs via calmodulin-calmodulin kinase II. We show that convergent VGCC signaling and Met signaling activate the GTPase Ras to drive Erk1 and Erk2 (also known as MAPK3 and MAPK1, respectively) phosphorylation and hypermotility of T. gondii-infected DCs. The data provide a molecular basis for the hypermigratory mesenchymal-to-amoeboid transition (MAT) of parasitized DCs. This emerging concept suggests that parasitized DCs acquire metastasislike migratory properties that promote infection-related dissemination.
HPV16 late L1 mRNAs encode a short central exon that is located between HPV16 3'-splice site SA3358 and HPV16 5'-splice site SD3632. While SA3358 is used to produce both HPV16 early mRNAs encoding the E6 and E7 oncogenes, and late mRNAs encoding E4, L1 and L2, SD3632 is used exclusively to produce late L1 mRNA. We have previously identified an 8-nucleotide regulatory RNA element that is required for inclusion of the exon between SA3358 and SD3632 to produce L1 mRNAs at the expense of mRNAs polyadenylated at the HPV16 early polyadenylation signal pAE. Here we show that this HPV16 8-nucleotide splicing enhancer interacts with hnRNP G. Binding of hnRNP G to this element prevents inclusion of the exon between SA3358 and SD3632 on the HPV16 late L1 mRNAs. We concluded that hnRNP G has a splicing inhibitory role and that hnRNP G can control HPV16 mRNA splicing.
Chromatin compaction is a key biophysical property that influences multiple DNA transactions. Lack of chromatin accessibility is frequently used as proxy for chromatin compaction. However, we currently lack tools for directly probing chromatin compaction at individual genomic loci. To fill this gap, here we present FRET-FISH, a method combining fluorescence resonance energy transfer (FRET) with DNA fluorescence in situ hybridization (FISH) to probe chromatin compaction at select loci in single cells. We first validate FRET-FISH by comparing it with ATAC-seq, demonstrating that local compaction and accessibility are strongly correlated. FRET-FISH also detects expected differences in compaction upon treatment with drugs perturbing global chromatin condensation. We then leverage FRET-FISH to study local chromatin compaction on the active and inactive X chromosome, along the nuclear radius, in different cell cycle phases, and during increasing passage number. FRET-FISH is a robust tool for probing local chromatin compaction in single cells.
The density or compaction of chromatin throughout the cell nucleus is a key biophysical property that influences DNA replication, transcription, and repair. Chromatin accessibility is often used as a proxy for chromatin compaction or density, however it is not clear how these two properties relate to each other, given the lack of tools for directly probing compaction at defined genomic loci. To fill in this gap, here we developed FRET-FISH, a microscopy-based method combining fluorescence resonance energy transference (FRET) with DNA fluorescence in situ hybridization (FISH) to probe chromatin compaction at selected loci in single cells. We optimized FRET-FISH by testing different probe designs in situ in fixed cells, readily detecting FRET generated by DNA FISH probes. To validate FRET-FISH, we compared it with ATAC-seq and Hi-C, demonstrating that local chromatin compaction and accessibility are strongly correlated and that the frequency of intra-genic contacts measured by Hi-C may be an even better proxy for local chromatin density. To further validate FRET-FISH, we showed that it can detect expected differences in chromatin compaction along the nuclear radius, with peripheral loci being more compacted and central ones less compacted. Lastly, we assessed the sensitivity of FRET-FISH, demonstrating its ability to reproducibly detect differences in chromatin density (i) upon treatment of cells with drugs that perturb global chromatin condensation; (ii) during prolonged cell culture; and (iii) in different phases of the cell cycle. We conclude that FRET-FISH is a robust tool for probing chromatin compaction at selected loci in single cells and for studying inter-allelic and cell-to-cell variability in chromatin density.
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