Next-generation insights into regulatory T cells: expression profiling and FoxP3 occupancy in Human

Regulatory T-cells (Treg) play an essential role in the negative regulation of immune answers by developing an attenuated cytokine response that allows suppressing proliferation and effector function of T-cells (CD4+ Th). The transcription factor FoxP3 is responsible for the regulation of many genes involved in the Treg gene signature. Its ablation leads to severe immune deficiencies in human and mice. Recent developments in sequencing technologies have revolutionized the possibilities to gain insights into transcription factor binding by ChiP-seq and into transcriptome analysis by mRNA-seq. We combine FoxP3 ChiP-seq and mRNA-seq in order to understand the transcriptional differences between primary human CD4+ T helper and regulatory T-cells, as well as to study the role of FoxP3 in generating those differences. We show, that mRNA-seq allows analyzing the transcriptomal landscape of T-cells including the expression of specific splice variants at much greater depth than previous approaches, whereas 50% of transcriptional regulation events have not been described before by using diverse array technologies. We discovered splicing patterns like the expression of a kinase-dead isoform of IRAK1 upon T-cell activation. The immunoproteasome is up-regulated in both Treg and CD4+ Th cells upon activation, whereas the ‘standard’ proteasome is up-regulated in Tregs only upon activation

Next-generation insights into regulatory T cells: expression profiling and FoxP3 occupancy in Human

Regulatory T-cells (Treg) play an essential role in the negative regulation of immune answers by developing an attenuated cytokine response that allows suppressing proliferation and effector function of T-cells (CD4+ Th). The transcription factor FoxP3 is responsible for the regulation of many genes involved in the Treg gene signature. Its ablation leads to severe immune deficiencies in human and mice. Recent developments in sequencing technologies have revolutionized the possibilities to gain insights into transcription factor binding by ChiP-seq and into transcriptome analysis by mRNA-seq. We combine FoxP3 ChiP-seq and mRNA-seq in order to understand the transcriptional differences between primary human CD4+ T helper and regulatory T-cells, as well as to study the role of FoxP3 in generating those differences. We show, that mRNA-seq allows analyzing the transcriptomal landscape of T-cells including the expression of specific splice variants at much greater depth than previous approaches, whereas 50% of transcriptional regulation events have not been described before by using diverse array technologies. We discovered splicing patterns like the expression of a kinase-dead isoform of IRAK1 upon T-cell activation. The immunoproteasome is up-regulated in both Treg and CD4+ Th cells upon activation, whereas the ‘standard’ proteasome is up-regulated in Tregs only upon activation

Mechanism of PP2A-mediated IKKβ dephosphorylation: a systems biological approach

BACKGROUND: Biological effects of nuclear factor-kappaB (NF kappaB) can differ tremendously depending on the cellular context. For example, NF kappaB induced by interleukin-1 (IL-1) is converted from an inhibitor of death receptor induced apoptosis into a promoter of ultraviolet-B radiation (UVB)-induced apoptosis. This conversion requires prolonged NF kappaB activation and is facilitated by IL-1 + UVB-induced abrogation of the negative feedback loop for NF kappaB, involving a lack of inhibitor of kappaB (I kappaB alpha) protein reappearance. Permanent activation of the upstream kinase IKK beta results from UVB-induced inhibition of the catalytic subunit of Ser-Thr phosphatase PP2A (PP2Ac), leading to immediate phosphorylation and degradation of newly synthesized I kappaB alpha. RESULTS: To investigate the mechanism underlying the general PP2A-mediated tuning of IKK beta phosphorylation upon IL-1 stimulation, we have developed a strictly reduced mathematical model based on ordinary differential equations which includes the essential processes concerning the IL-1 receptor, IKK beta and PP2A. Combining experimental and modelling approaches we demonstrate that constitutively active, but not post-stimulation activated PP2A, tunes out IKK beta phosphorylation thus allowing for I kappaB alpha resynthesis in response to IL-1. Identifiability analysis and determination of confidence intervals reveal that the model allows reliable predictions regarding the dynamics of PP2A deactivation and IKK beta phosphorylation. Additionally, scenario analysis is used to scrutinize several hypotheses regarding the mode of UVB-induced PP2Ac inhibition. The model suggests that down regulation of PP2Ac activity, which results in prevention of I kappaB alpha reappearance, is not a direct UVB action but requires instrumentality. CONCLUSION: The model developed here can be used as a reliable building block of larger NF kappa B models and offers comprehensive simplification potential for future modeling of NF kappa B signaling. It gives more insight into the newly discovered mechanisms for IKK deactivation and allows for substantiated predictions and investigation of different hypotheses. The evidence of constitutive activity of PP2Ac at the IKK complex provides new insights into the feedback regulation of NF kappa B, which is crucial for the development of new anti-cancer strategies

Nuclear IE2 structures are related to viral DNA replication sites during baculovirus infection

The ie2 gene of Autographa californica multicapsid nuclear polyhedrosis virus is I of the 10 baculovirus genes that have been identified as factors involved in viral DNA replication. IE2 is detectable in the nucleus as one of the major early- expressed proteins and exhibits a dynamic localization pattern during the infection cycle (D. Murges, 1. Quadt, J. Schroer, and D. Knebel-Morsdorf, Exp. Cell Res. 264:219-232, 2001). Here, we investigated whether IE2 localized to regions of viral DNA replication. After viral DNA was labeled with bromode- oxyuridine (BrdU), confocal imaging indicated that defined IE2 domains colocalized with viral DNA replication centers as soon as viral DNA replication was detectable. In addition, a subpopulation of IE2 structures colocalized with two further virus-encoded replication factors, late expression factor 3 (LEF-3) and the DNA binding protein (DBP). While DBP and LEF-3 structures always colocalized and enlarged simultaneously with viral DNA replication sites, only those IE2 structures that colocalized with replication sites also colocalized with DBP. Replication and transcription of DNA viruses in association with promyelocytic leukemia protein (PML) oncogenic domains have been observed. By confocal imaging we demonstrated that the human PML colocalized with IE2. Triple staining revealed PML/IE2 domains in the vicinity of viral DNA replication centers, while IE2 alone colocalized with early replication sites, demonstrating that PML structures do not form common domains with viral DNA replication centers. Thus, we conclude that IE2 colocalizes alternately with PML and the sites of viral DNA replication. Small ubiquitin-like modifier SUMO-1 has been implicated in the nuclear distribution of PML. Similar to what was found for mammalian cells, small ubiquitin-like modifiers were recruited to PML domains in infected insect cells, which suggests that IE2 and PML colocalize in conserved cellular domains. In summary, our results support a model for IE2 as part of various functional sites in the nucleus that are connected with viral DNA replication

Endocytic Internalization of Herpes Simplex Virus 1 in Human Keratinocytes at Low Temperature

Herpes simplex virus 1 (HSV-1) can adopt a variety of pathways to accomplish cellular internalization. In human keratinocytes representing the natural target cell of HSV-1, both direct plasma membrane fusion and endocytic uptake have been found. The impact of either pathway in successful infection, however, remains to be fully understood. To address the role of each internalization mode, we performed infection studies at low temperature as a tool to interfere with endocytic pathways. Interestingly, successful HSV-1 entry in primary human keratinocytes and HaCaT cells was observed even at 7 degrees C, although it was delayed compared to infection at 37 degrees C. Moreover, ex vivo infection of murine epidermis demonstrated that virus entry at 7 degrees C is accomplished not only in cultured cells but also in tissue. Control experiments with cholera toxin B confirmed a block of endocytic uptake at 7 degrees C. In addition, uptake of dextran by macropinosomes and phagocytic uptake of latex beads were also inhibited at 7 degrees C. Infection of nectin-1-deficient murine keratinocytes affirmed that the entry at 7 degrees C was receptor dependent. Strikingly, the lysosomotropic agent ammonium chloride strongly inhibited HSV-1 entry, suggesting a role for endosomal acidification. Ultrastructural analyses in turn revealed free capsids in the cytoplasm as well as virus particles in vesicles after infection at 7 degrees C, supporting both plasma membrane fusion and endocytic internalization as already observed at 37 degrees C. Overall, entry of HSV-1 at 7 degrees C suggests that the virus can efficiently adopt nectin-1-dependent unconventional vesicle uptake mechanisms in keratinocytes, strengthening the role of endocytic internalization for successful infection. IMPORTANCE The human pathogen herpes simplex virus 1 (HSV-1) relies on multiple internalization pathways to initiate infection. Our focus is on the entry in human keratinocytes, the major in vivo target during primary and recurrent infection. While antivirals reduce the severity of clinical cases, there is no cure or vaccine against HSV. To develop strategies that interfere with virus penetration, we need to understand the various parameters and conditions that determine virus entry. Here, we addressed the impact of virus internalization via vesicles by blocking endocytic processes at low temperature. Intriguingly, we detected entry of HSV-1 even at 7 degrees C, which led to infection of primary keratinocytes and epidermal tissue. Moreover, electron microscopy of human keratinocytes at 7 degrees C support that internalization is based on fusion of the viral envelope with the plasma membrane as well as vesicle membranes. These results provide novel insights into conditions that still allow endocytic internalization of HSV-1