31 research outputs found
Frequency of T-Cell Progenitors in Nude Mice
The hypothesis that prothymocytes are distinct from and regulated independently of
multilineage hemopoietic progenitors was tested by enumeration of these two cell populations
in normal versus congenitally athymic (nude) mice. The absence of a thymus and of
peripheral T cells in nude mice had no effect on the frequency of either multilineage
progenitors (day 12 CFU-S) or prothymocytes (CFU-T), suggesting that there is no feedback
regulation of CFU-T frequency. Thymus seeding from the bone marrow is therefore likely
to be regulated by the availability of niches for prothymocyte maturation, rather than by
feedback control of prothymocyte production
Self-Reactivity and the Expression of Memory Markers Vary Independently in MRL-Mp+/+ and MRL-Mp-lpr/lpr Mice
MRL-Mp-lpr/lpr mice contain phenotypically abnormal populations of T cells, and
exhibit an SLE-like autoimmune disease in which autoantibodies are a prominent
feature. We analyzed the phenotype and T-cell receptor VΓ expression pattern in CD4+ T
cells of this mutant mouse strain to detect abnormalities that could explain the
autoimmunity. The CD4+ T cells contain two distinct abnormal populations. One of
these expresses B220 and HSA, and in these and other respects closely resembles the
accumulating CD4βCD8β population. The other expresses a high level of CD44 (Pgp-1),
and a high level of the 16A epitope of CD45, and so resembles post-activation T cells.
Both of these cell types are exclusive to MRL-Mp-lpr/lpr. We also identified V Γ5- and
V Γ11-positive CD4+ T cells, in both MRL-Mp-lpr/lpr and MRL-Mp-+/+ mice. We
conclude that autoimmune T cells can be detected in these mice, but that they are not the
cause of the accumulation of abnormal CD4+ and CD4βCD8βcells
Quantitative PCR for detection of the OT-1 transgene
BACKGROUND: Transgenic TCR mice are often used experimentally as a source of T cells of a defined specificity. One of the most widely used transgenic TCR models is the OT-1 transgenic mouse in which the CD8+ T cells express a TCR specific for the SIINFEKL peptide of ovalbumin presented on k(b). Although OT-1 CD8+ can be used in a variety of different experimental settings, we principally employ adoptive transfer and peptide-driven expansion of OT-1 cells in order to explore the distribution and fate of these antigen-specific OT-1 T cells. We set out to develop a quantitative PCR assay for OT-1 cells in order to assess the distribution of OT-1 CD8+ T cells in tissues that are either intrinsically difficult to dissociate for flow cytometric analysis or rendered incompatible with flow cytometric analysis through freezing or fixation. RESULTS: We show excellent correlation between flow cytometric assessment of OT-1 cells and OT-1 signal by qPCR assays in cell dilutions as well as in in vivo adoptive transfer experiments. We also demonstrate that qPCR can be performed from archival formalin-fixed paraffin-embedded tissue sections. In addition, the non-quantitative PCR using the OT-1-specific primers without the real-time probe is a valuable tool for OT-1 genotyping, obviating the need for peripheral blood collection and subsequent flow cytometric analysis. CONCLUSION: An OT-1 specific qPCR assay has been developed to quantify adoptively transferred OT-1 cells. OT-1 qPCR to determine cell signal is a valuable adjunct to the standard flow cytometric analysis of OT-1 cell number, particularly in experimental settings where tissue disaggregation is not desirable or in tissues which are not readily disassociate
TLR-dependent cross talk between human Kupffer cells and NK cells
The liver protects the host from gut-derived pathogens yet is tolerant of antigenic challenge from food and commensal sources. Innate responses involving liver macrophages (Kupffer cells) and effector liver natural killer (NK) cells form the first line in this defense. We address the impact of Toll-like receptor (TLR) signaling on the cross talk between these two cells, and reveal how the liver displays a down-regulated inflammatory response to constitutive bacterial elements through the secretion of interleukin (IL) 10 yet retains a vigorous response to viral challenge. The data support the model that (a) human liver Kupffer cells respond to TLR ligands and indirectly activate NK cells; (b) the activation depends on cellβcell contact; (c) the Kupffer cells synthesize NK cell activating signals, among which IL-18 is critical, and NK cell inhibitory factors, including IL-10; (d) ligands that signal via myeloid differentiation factor 88 induce IL-10, giving a blunted response in the NK cells; and (e) ligands that signal via the TollβIL-1 receptor domainβcontaining adaptor inducing interferon (IFN) Ξ²βIFN regulatory factor 3 pathway induce less IL-10, and also directly potentiate the stimulatory effect of IL-18 on NK cells, resulting in enhanced activation. Subversion of cellular mechanisms of innate immune response against viruses may be important for hepatotropic viruses (e.g., hepatitis B and C) to develop persistence
Expression of Hepatitis C Virus Core Protein in Hepatocytes Does Not Modulate Proliferation or Apoptosis of CD8+ T Cells
Hepatocytes are the primary targets of the hepatitis C virus (HCV). While immunosuppressive roles of HCV core protein have been found in several studies, it remains uncertain whether core protein expressed in hepatocytes rather than in immune cells affects the CD8+ T cell response. In order to transduce genes selectively into hepatocytes, we developed a baculoviral vector system that enabled primary hepatocytes to express a target epitope for CD8+ T cells, derived from ovalbumin (OVA), with or without HCV core protein. Culture of OVA-specific CD8+ T cells with hepatocytes infected with these baculoviral vectors revealed that core protein has no effect on proliferation or apoptosis of CD8+ T cells. Our results suggest that HCV core protein does not exert its suppressive role on the CD8+ T cell immune response through expression in hepatocytes