Necroptosis is a form of necrotic cell death that requires the activity of the death domain-containing kinase RIP1 and its family member RIP3. Necroptosis occurs when RIP1 is deubiquitinated to form a complex with RIP3 in cells deficient in the death receptor adapter molecule FADD or caspase-8. Necroptosis may play a role in host defense during viral infection as viruses like vaccinia can induce necroptosis while murine cytomegalovirus encodes a viral inhibitor of necroptosis. To see how general the interplay between viruses and necroptosis is, we surveyed seven different viruses. We found that two of the viruses tested, Sendai virus (SeV) and murine gammaherpesvirus-68 (MHV68), are capable of inducing dramatic necroptosis in the fibrosarcoma L929 cell line. We show that MHV68-induced cell death occurs through the cytosolic STING sensor pathway in a TNF-dependent manner. In contrast, SeV-induced death is mostly independent of TNF. Knockdown of the RNA sensing molecule RIG-I or the RIP1 deubiquitin protein, CYLD, but not STING, rescued cells from SeV-induced necroptosis. Accompanying necroptosis, we also find that wild type but not mutant SeV lacking the viral proteins Y1 and Y2 result in the non-ubiquitinated form of RIP1. Expression of Y1 or Y2 alone can suppress RIP1 ubiquitination but CYLD is dispensable for this process. Instead, we found that Y1 and Y2 can inhibit cIAP1-mediated RIP1 ubiquitination. Interestingly, we also found that SeV infection of B6 RIP3 mice results in increased inflammation in the lung and elevated SeV-specific T cells. Collectively, these data identify viruses and pathways that can trigger necroptosis and highlight the dynamic interplay between pathogen-recognition receptors and cell death induction.
Key Points miR-146a and miR-146b are upregulated during premalignancy in the thymus of T cell–specific PTEN-deficient mice. Transgenic expression of mir-146a/b delays PTEN-deficient lymphomagenesis through repression of TCR signals critical for c-myc activation.
Barley microspores from five field-grown breeding lines were isolated using an ultra-speed blender and the effect of co-culture with young florets was investigated. Floret co-culture in the induction stage increased the formation of MCS, ELS and green plant regeneration. The florets of teraploid plant were more effective than ones of diploid plant. For line S23, coculture with florets from tetraploid plants gave rise to 2.6 and 7.8 times more MCS and ELS, respectively, than non-co-culture control, whereas co-culture with florets from diploid plants resulted in 1.8 and 6.1 times more MCS and ELS, respectively, than non-co-culture control (Table 2). Florets subjected to cold treatment for 10-20 days induced a greater response than fresh ones, and florets with uninucleate microspores surpassed binucleate microspores. For microspores culture from 15-day cold pre-treated spikes, 93A floret co-culture gave rise to 3.6 and 6.8 times more MCS and ELS, respectively, than the non-co-cultured control, while SD1 floret co-culture resulted in 1.9 and 4.0 times more, respectively. Similarly, for microspore culture from 20-day cold pre-treated spikes, 93A floret co-culture gave rise to 2.6 and 5.1 times more MCS and ELS, respectively, than non-co-cultured control, while SD1 floret co-culture resulted in 1.5 and 3.0 times more, respectively (Table 3). Some microspores formed dense MCS that did not develop further. Compared with the control, floret co-culture resulted in less dense MCS formation, indicating that the isolated florets were beneficial to the normal development of MCS. Floret coculture was only effective when the spikes were cold pre-treated before microspore isolation. Spike cold pretreatment before microspore preparation was crucial for dedifferentiation of cultured isolated microspores, and this could not be replaced by floret co-culture. It is postulated that the florets provided essential substances for in vitro cultured isolated microspores to undergo dedifferentiation and embryogenesis. Both the genotype selection and the physiological status (developmental status and cold treatment) adjustment of the florets for co-culture could improve barley microspore culture. Compared with ovary co-culture, floret co-culture is more efficient. The technique is of simple application in breeding programs and can be a solution for coping with recalcitrant genotypes and or plant donor condition.
Myeloid cells, which include monocytes, macrophages, and granulocytes, are important innate immune cells, but the mechanism and downstream effect of their cell death on the immune system is not completely clear. Necroptosis is an alternate form of cell death that can be triggered when death receptor-mediated apoptosis is blocked, for example, in stimulated Fas-associated Death Domain (FADD) deficient cells. We report here that mice deficient for FADD in myeloid cells (mFADD-/-) exhibit systemic inflammation with elevated inflammatory cytokines and increased levels of myeloid and B cell populations while their dendritic and T cell numbers are normal. These phenotypes were abolished when RIP3 deficiency was introduced, suggesting that systemic inflammation is caused by RIP3-dependent necroptotic and/or inflammatory activity. We further found that loss of MyD88 can rescue the systemic inflammation observed in these mice. These phenotypes are surprisingly similar to that of dendritic cell (DC)-specific FADD deficient mice with the exception that DC numbers are normal in mFADD-/- mice. Together these data support the notion that innate immune cells are constantly being stimulated through the MyD88-dependent pathway and aberrations in their cell death machinery can result in systemic effects on the immune system.
Day 3 thymectomy (D3Tx) results in a loss of peripheral tolerance mediated by natural regulatory T cells (nTregs) and development of autoimmune ovarian dysgenesis (AOD) and autoimmune dacryoadenitis (ADA) in A/J and (C57BL/6J × A/J) F1 hybrids (B6A), but not in C57BL/6J (B6) mice. Previously, using quantitative trait locus (QTL) linkage analysis, we showed that D3Tx-AOD is controlled by five unlinked QTL (Aod1-Aod5) and H2. In this study, using D3Tx B6-ChrA/J/NaJ chromosome (Chr) substitution strains, we confirm that QTL on Chr16 (Aod1a/Aod1b), Chr3 (Aod2), Chr1 (Aod3), Chr2 (Aod4), Chr7 (Aod5), and Chr17 (H2) control D3Tx-AOD susceptibility. In addition, we also present data mapping QTL controlling D3Tx-ADA to Chr17 (Ada1/H2), Chr1 (Ada2), and Chr3 (Ada3). Importantly, B6-ChrXA/J mice were as resistant to D3Tx-AOD and D3Tx-ADA as B6 mice, thereby excluding Foxp3 as a susceptibility gene in these models. Moreover, we report quantitative differences in the frequency of nTregs in the lymph nodes (LNs), but not spleen or thymus, of AOD/ADA-resistant B6 and AOD/ADA-susceptible A/J, B6A, and B6-Chr17A/J mice. Similar results correlating with experimental allergic encephalomyelitis and orchitis susceptibility were seen with B10.S and SJL/J mice. Using H2-congenic mice, we show that the observed difference in frequency of LN nTregs is controlled by Ada1/H2. These data support the existence of an LN-specific, H2-controlled mechanism regulating the prevalence of nTregs in autoimmune disease susceptibility.
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