Human polyomavirus (HPyV) DNA genomes contain three regions denoted the early viral gene region (EVGR), encoding the regulatory T-antigens and one microRNA, the late viral gene region (LVGR), encoding the structural Vp capsid proteins, and the noncoding control region (NCCR). The NCCR harbors the origin of viral genome replication and bidirectional promoter/enhancer functions governing EVGR and LVGR expression on opposite DNA strands. Despite principal similarities, HPyV NCCRs differ in length, sequence, and architecture. To functionally compare HPyV NCCRs, sequences from human isolates were inserted into a bidirectional reporter vector using dsRed2 for EVGR expression and green fluorescent protein (GFP) for LVGR expression. Transfecting HPyV NCCR reporter vectors into human embryonic kidney 293 (HEK293) cells and flow cytometry normalized to archetype BKPyV NCCR revealed a hierarchy of EVGR expression levels with MCPyV, HPyV12, and STLPyV NCCRs conferring stronger levels and HPyV6, HPyV9, and HPyV10 NCCRs weaker levels, while LVGR expression was less variable and showed comparable activity levels. Transfection of HEK293T cells expressing simian virus 40 (SV40) large T antigen (LTag) increased EVGR expression for most HPyV NCCRs, which correlated with the number of LTag-binding sites (Spearman's , 0.625; < 0.05) and decreased following SV40 LTag small interfering RNA (siRNA) knockdown. LTag-dependent activation was specifically confirmed for two different MCPyV NCCRs in 293MCT cells expressing the cognate MCPyV LTag. HPyV NCCR expression in different cell lines derived from skin (A375), cervix (HeLaNT), lung (A549), brain (Hs683), and colon (SW480) demonstrated that host cell properties significantly modulate the baseline HPyV NCCR activity, which partly synergized with SV40 LTag expression. Clinically occurring NCCR sequence rearrangements of HPyV7 PITT-1 and -2 and HPyV9 UF1 were found to increase EVGR expression compared to the respective HPyV archetype, but this was partly host cell type specific. HPyV NCCRs integrate essential viral functions with respect to host cell specificity, persistence, viral replication, and disease. Here, we show that HPyV NCCRs not only differ in sequence length, number, and position of LTag- and common transcription factor-binding sites but also confer differences in bidirectional viral gene expression. Importantly, EVGR reporter expression was significantly modulated by LTag expression and by host cell properties. Clinical sequence variants of HPyV7 and HPyV9 NCCRs containing deletions and insertions were associated with increased EVGR expression, similar to BKPyV and JCPyV rearrangements, emphasizing that HPyV NCCR sequences are major determinants not only of host cell tropism but also of pathogenicity. These results will help to define secondary HPyV cell tropism beyond HPyV surface receptors, to identify key viral and host factors shaping the viral life cycle, and to develop preclinical models of HPyV persistence and replication and suitable antiviral targets.
Multiple sclerosis (MS) is the leading cause of non-traumatic neurological disability in the United States in young adults, but current treatments are only partially effective, making it necessary to develop new, innovative therapeutic strategies. Myelin-specific interleukin (IL)-17-producing T helper type 17 (Th17) cells are a major subset of CD4 T effector cells (T eff ) that play a critical role in mediating the development and progression of MS and its mouse model, experimental autoimmune encephalo- myelitis (EAE), while regulatory T cells (T reg ) CD4 T cells are beneficial for suppressing disease. The IL-6/signal transducer and activator of transcription 3 (STAT-3) signaling pathway is a key regulator of Th17 and T reg cells by promoting Th17 development and suppressing T reg development. Here we show that three novel small molecule IL-6 inhibitors, madindoline-5 (MDL-5), MDL-16 and MDL-101, significantly suppress IL-17 production in myelin-specific CD4 T cells in a dose-dependent manner in vitro. MDL-101 showed superior potency in suppressing IL-17 production compared to MDL-5 and MDL-16. Treatment of myelin-specific CD4 T cells with MDL-101 in vitroreduced their encephalitogenic potential following their subsequent adoptive transfer. Furthermore, MDL-101 significantly suppressed proliferation and IL-17 production of anti-CD3activated effector/memory CD45RO + CD4 + human CD4 T cells and promoted human T reg development. Together, these data demonstrate that these novel small molecule IL-6 inhibitors have the potential to shift the T eff : T reg balance, which may provide a novel therapeutic strategy for ameliorating disease progression in MS.
Reestablishing an appropriate balance between T effector cells (Teff) and Tregs is essential for correcting autoimmunity. Multiple sclerosis (MS) is an immune-mediated chronic CNS disease characterized by neuroinflammation, demyelination, and neuronal degeneration, in which the Teff:Treg balance is skewed toward pathogenic Teffs Th1 and Th17 cells. STAT3 is a key regulator of Teff:Treg balance. Using the structure-based design, we have developed a potentially novel small-molecule prodrug LLL12b that specifically inhibits STAT3 and suppresses Th17 differentiation and expansion. Moreover, LLL12b regulates the fate decision between Th17 and Tregs in an inflammatory environment, shifting Th17:Treg balance toward Tregs and favoring the resolution of inflammation. Therapeutic administration of LLL12b after disease onset significantly suppresses disease progression in adoptively transferred, chronic, and relapsing-remitting experimental autoimmune encephalomyelitis. Disease relapses were also significantly suppressed by LLL12b given during the remission phase. Additionally, LLL12b shifts Th17:Treg balance of CD4 + T cells from MS patients toward Tregs and increases Teff sensitivity to Treg-mediated suppression. These data suggest that selective inhibition of STAT3 by the small molecule LLL12b recalibrates the effector and regulatory arms of CD4 + T responses, representing a potentially clinically translatable therapeutic strategy for MS.
B cell depletion therapy has been shown to be beneficial in multiple sclerosis (MS). However, the mechanism by which B cell depletion mediates its beneficial effects in MS is still unclear. To better understand how B cell depletion may benefit patients with a disease previously thought to be primarily mediated by CD4 T cells, immune profiles were monitored in 48 patients in a phase II trial of ublituximab, a glycoengineered CD20 monoclonal antibody, at 18 time points over a year. As we previously described there was a significant shift in the percentages of T cells, NK cells, and myeloid cells following the initial dose of ublituximab, but this shift normalized within a week and these populations remained stable for the duration of the study. However, T cell subsets changed with an increase in the percentage of naïve CD4 and CD8 T cells and a decline in memory T cells. Importantly, the percentage of Th1 and CD4 + GM-CSF + T cells decreased, while the percentage of Tregs continued to increase over the year. Ublituximab not only depleted CD20 + B cells, but also CD20 + T cells. The favorable changes in the T cell subsets may contribute to the beneficial effects of B cell depletion therapy.
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