Tumor necrosis factor alpha (TNF-alpha) signaling gives rise to a number of events, including activation of transcription factor NF-kappaB and programmed cell death (apoptosis). Previous studies of TNF-alpha signaling have suggested that these two events occur independently. The sensitivity and kinetics of TNF-alpha-induced apoptosis are shown to be enhanced in a number of cell types expressing a dominant-negative IkappaBalpha (IkappaBalphaM). These findings suggest that a negative feedback mechanism results from TNF-alpha signaling in which NF-kappaB activation suppresses the signals for cell death.
Signal-induced degradation of I(kappa)B(alpha) via the ubiquitin-proteasome pathway requires phosphorylation on residues serine 32 and serine 36 followed by ubiquitination on lysines 21 and 22. We investigated the role of other regions of I(kappa)B(alpha) which may be involved in its degradation. Here we report that the carboxy-terminal PEST sequence is not required for I(kappa)B(alpha) signal-induced degradation. However, removal of the PEST sequence stabilizes free I(kappa)B(alpha) in unstimulated cells. We further report that a PEST deletion mutant does not associate well with NF-(kappa)B proteins but is degraded in response to signal. Therefore, we conclude that both association with NF-(kappa)B and a PEST sequence are not required for signal-induced I(kappa)B(alpha) degradation. Additionally, the PEST sequence may be required for constitutive turnover of free I(kappa)B(alpha).
Interaction of many infectious agents with eukaryotic host cells is known to cause activation of the ubiquitous transcription factor nuclear factor κB (NF-κB) (U. Siebenlist, G. Franzoso, and K. Brown, Annu. Rev. Cell Biol. 10:405–455, 1994). Recently, we reported a biphasic pattern of NF-κB activation in cultured human umbilical vein endothelial cells consequent to infection withRickettsia rickettsii, an obligate intracellular gram-negative bacterium and the etiologic agent of Rocky Mountain spotted fever (L. A. Sporn, S. K. Sahni, N. B. Lerner, V. J. Marder, D. J. Silverman, L. C. Turpin, and A. L. Schwab, Infect. Immun. 65:2786–2791, 1997). In the present study, we describe activation of NF-κB in a cell-free system, accomplished by addition of partially purified R. rickettsii to endothelial cell cytoplasmic extracts. This activation was rapid, reaching maximal levels at 60 min, and was dependent on the number ofR. rickettsii organisms added. Antibody supershift assays using monospecific antisera against NF-κB subunits (p50 and p65) confirmed the authenticity of the gel-shifted complexes and identified both p50-p50 homodimers and p50-p65 heterodimers as constituents of the activated NF-κB pool. Activation occurred independently of the presence of endothelial cell membranes and was not inhibited by removal of the endothelial cell proteasome. Lack of involvement of the proteasome was further confirmed in assays using the peptide-aldehyde proteasome inhibitor MG 132. Activation was not ATP dependent since no change in activation resulted from addition of an excess of the unhydrolyzable ATP analog ATPγS, supplementation with exogenous ATP, or hydrolysis of endogenous ATP with ATPase. Furthermore, Western blot analysis before and after in vitro activation failed to demonstrate phosphorylation of serine 32 or degradation of the cytoplasmic pool of IκBα. This lack of IκBα involvement was supported by the finding that R. rickettsii can induce NF-κB activation in cytoplasmic extracts prepared from T24 bladder carcinoma cells and human embryo fibroblasts stably transfected with a superrepressor phosphorylation mutant of IκBα, rendering NF-κB inactivatable by many known signals. Thus, evidence is provided for a potentially novel NF-κB activation pathway wherein R. rickettsii may interact with and activate host cell transcriptional machinery independently of the involvement of the proteasome or known signal transduction pathways.
Aquaporins and aquaglyceroporins are a large family of membrane channel proteins that allow rapid movement of water and small, uncharged solutes into and out of cells along concentration gradients. Recently, aquaporins have been gaining recognition for more complex biological roles than the regulation of cellular osmotic homeostasis. We have identified a specific expression pattern for Xenopus aqp3b (also called aqp3.L) during gastrulation, where it is localized to the sensorial (deep) layer of the blastocoel roof and dorsal margin. Interference with aqp3b expression resulted in loss of fibrillar fibronectin matrix in Brachet's cleft at the dorsal marginal zone, but not on the free surface of the blastocoel. Detailed observation showed that the absence of fibronectin matrix correlated with compromised border integrities between involuted mesendoderm and noninvoluted ectoderm in the marginal zone. Knockdown of aqp3b also led to delayed closure of the blastopore, suggesting defects in gastrulation movements. Radial intercalation was not affected in aqp3b morphants, while the data presented are consistent with impeded convergent extension movements of the dorsal mesoderm in response to loss of aqp3b. Our emerging model suggests that aqp3b is part of a mechanism that promotes proper interaction between cells and the extracellular matrix, thereby playing a critical role in gastrulation.
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