Mice deficient in inducible nitric oxide synthase (iNOS) were generated to test the idea that iNOS defends the host against infectious agents and tumor cells at the risk of contributing to tissue damage and shock. iNOS-/-mice failed to restrain the replication of Listeria monocytogenes in vivo or lymphoma cells in vitro. Bacterial endotoxic lipopolysaccharide (LPS) caused shock and death in anesthetized wild-type mice, but in iNOS-/-mice, the fall in central arterial blood pressure was markedly attenuated and early death averted. However, unanesthetized iNOS-/-mice suffered as much LPS-induced liver damage as wild type, and when primed with Propionobacterium acnes and challenged with LPS, they succumbed at the same rate as wild type. Thus, there exist both iNOS-dependent and iNOS-independent routes to LPS-induced hypotension and death.
Interleukin 1 (IL-1) is a lymphokine secreted by monocytes in response to a variety of inflammatory stimuli. IL-1fB the predominant form of IL-1 produced by human monocytes, is synthesized as an inactive precursor of 31 kDa and is cleaved at Asp"'6-Ala"17 to yield a 17.5-kDa extracellular form. The exact cellular site of cleavage and mechanism of secretion is at present unknown. We have prepared cell-free postnuclear extracts from freshly isolated human monocytes as well as THP. (1) provided the first substantive evidence that, in a mouse monocyte cell line, IL-1 was synthesized as a cell-associated precursor that could be chased into an extracellular 17-kDa form. Subsequently, reports emerged which suggested that a 31-kDa form of IL-1i3 was associated with human monocytes (2-5) and that this material was cleaved to release the mature form (2, 4, 5). These studies were corroborated by cDNA sequence data from a number of species which indicated that IL-1 mRNA encodes a larger protein than that identified as mature secreted IL-1 (6-10). As precursor IL-183 (pre-IL-1,j)is unable to bind to IL-1 receptors and is biologically inactive (11), some form of proteolytic processing is apparently required to release active IL-1p8. While the kinetics of IL-1 synthesis and secretion has been analyzed in some detail, little has been uncovered about the mechanism by which IL-1 is synthesized, processed, and secreted. Analysis ofthe predicted amino acid sequence from pre-IL-1,3 cDNA has not revealed the presence of a unique hydrophobic signal sequence domain, common to most secreted proteins (6)(7)(8)(9)(10)12). The N-terminal amino acid of mature monocyte IL-1p from humans has been sequenced by a number of investigators as Ala"17 (6, 13), suggesting that a cleavage site exists between Asp'6 and Ala"7. While the first 116 residues may be considered a signal sequence of sorts, it is not recognized as such by otherwise competent endoplasmic reticulum membranes (G.L., unpublished observation). Young et al. (14) showed that mature pre-IL-1P was not secreted from hamster fibroblasts that were stably transformed with pre-IL-1,i cDNA. Instead, large amounts of the precursor accumulated in the cytoplasm of the cell (14). Lomedico et al. (12) The processing of IL-1f3 has recently been investigated by using purified recombinant precursor as a substrate (5, 17).Hazuda et al. (5) showed that pre-IL-1f3, when added to intact human blood monocytes, was not cleaved or processed in any fashion, arguing against an extracellular site of processing. In another report, a potential pre-IL-1,8 cleavage activity was identified in a pelletable compartment of KG-1 cells, a neutrophil-like cell line. This enzymatic activity was able to generate IL-1 activity of similar size to authentic IL-1 from a partially purified pre-IL-1f3 substrate (17). However, the products were not sequenced and the site ofcleavage was not identified.In this report, we describe an in vitro processing system in which mature 17.
The p38 family of mitogen-activated protein kinases (MAPKs) mediates signaling in response to environmental stresses and inflammatory cytokines, but the requirements for the p38 MAPK pathway in normal mammalian development have not been elucidated. Here, we show that targeted disruption of the p38␣ MAPK gene results in homozygous embryonic lethality because of severe defects in placental development. Although chorioallantoic placentation is initiated appropriately in p38␣ null homozygotes, placental defects are manifest at 10.5 days postcoitum as nearly complete loss of the labyrinth layer and significant reduction of the spongiotrophoblast. In particular, p38␣ mutant placentas display lack of vascularization of the labyrinth layer as well as increased rates of apoptosis, consistent with a defect in placental angiogenesis. Furthermore, p38␣ mutants display abnormal angiogenesis in the embryo proper as well as in the visceral yolk sac. Thus, our results indicate a requirement for p38␣ MAPK in diploid trophoblast development and placental vascularization and suggest a more general role for p38 MAPK signaling in embryonic angiogenesis.
Disruption of the SLN1 gene neither prevents nor reduces the cartilage destruction associated with CIA. Moreover, SLN1 depletion does not prevent the cleavage of the aggrecan Asn341-Phe342 bond.
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