Multifaceted mechanisms of HIV-1 entry inhibition by human α-defensin.

The human neutrophil peptide 1 (HNP-1) is known to block the human immunodeficiency virus type 1 (HIV-1) infection, but the mechanism of inhibition is poorly understood. We examined the effect of HNP-1 on HIV-1 entry and fusion and found that, surprisingly, this α-defensin inhibited multiple steps of virus entry, including: (i) Env binding to CD4 and coreceptors; (ii) refolding of Env into the final 6-helix bundle structure; and (iii) productive HIV-1 uptake but not internalization of endocytic markers. Despite its lectin-like properties, HNP-1 could bind to Env, CD4, and other host proteins in a glycan- and serum-independent manner, whereas the fusion inhibitory activity was greatly attenuated in the presence of human or bovine serum. This demonstrates that binding of α-defensin to molecules involved in HIV-1 fusion is necessary but not sufficient for blocking the virus entry. We therefore propose that oligomeric forms of defensin, which may be disrupted by serum, contribute to the anti-HIV-1 activity perhaps through cross-linking virus and/or host glycoproteins. This notion is supported by the ability of HNP-1 to reduce the mobile fraction of CD4 and coreceptors in the plasma membrane and to precipitate a core subdomain of Env in solution. The ability of HNP-1 to block HIV-1 uptake without interfering with constitutive endocytosis suggests a novel mechanism for broad activity against this and other viruses that enter cells through endocytic pathways.

Imaging single retrovirus entry through alternative receptor isoforms and intermediates of virus-endosome fusion.

A large group of viruses rely on low pH to activate their fusion proteins that merge the viral envelope with an endosomal membrane, releasing the viral nucleocapsid. A critical barrier to understanding these events has been the lack of approaches to study virus-cell membrane fusion within acidic endosomes, the natural sites of virus nucleocapsid capsid entry into the cytosol. Here we have investigated these events using the highly tractable subgroup A avian sarcoma and leukosis virus envelope glycoprotein (EnvA)-TVA receptor system. Through labeling EnvA pseudotyped viruses with a pH-sensitive fluorescent marker, we imaged their entry into mildly acidic compartments. We found that cells expressing the transmembrane receptor (TVA950) internalized the virus much faster than those expressing the GPI-anchored receptor isoform (TVA800). Surprisingly, TVA800 did not accelerate virus uptake compared to cells lacking the receptor. Subsequent steps of virus entry were visualized by incorporating a small viral content marker that was released into the cytosol as a result of fusion. EnvA-dependent fusion with TVA800-expressing cells occurred shortly after endocytosis and delivery into acidic endosomes, whereas fusion of viruses internalized through TVA950 was delayed. In the latter case, a relatively stable hemifusion-like intermediate preceded the fusion pore opening. The apparent size and stability of nascent fusion pores depended on the TVA isoforms and their expression levels, with TVA950 supporting more robust pores and a higher efficiency of infection compared to TVA800. These results demonstrate that surface receptor density and the intracellular trafficking pathway used are important determinants of efficient EnvA-mediated membrane fusion, and suggest that early fusion intermediates play a critical role in establishing low pH-dependent virus entry from within acidic endosomes.

Effects of retinoic acid on the development of liver fibrosis produced by carbon tetrachloride in mice.

The role of retinoic acid (RA) in liver fibrogenesis was previously studied in cultured hepatic stellate cells (HSCs). RA suppresses the expression of alpha2(I) collagen by means of the activities of specific nuclear receptors RARalpha, RXRbeta and their coregulators. In this study, the effects of RA in fibrogenesis were examined in carbon tetrachloride (CCl4) induced liver fibrosis in mice. Mice were treated with CCl4 or RA and CCl4, along side control groups, for 12weeks. RA reduced the amount of histologically detectable fibrosis produced by CCl4. This was accompanied by a attenuation of the CCl4 induced increase in alpha2(I) collagen mRNA and a lower (2-fold versus 3-fold) increase in liver hydroxyproline. Furthermore, RA reduced the levels of 3-nitrotyrosine (3-NT) protein adducts and thiobarbituric acid (TBA) reactive substance (TBARS) in the liver, which are formed as results of oxidative stress induced by CCl4 treatment. These in vivo findings support our previous in vitro studies in cultured HSC of the inhibitory effect of RA on type I collagen expression. The data also provide evidence that RA reduces CCl4 induced oxidative stress in liver, suggesting that the anti-fibrotic role of RA is not limited to the inhibition of type I collagen expression.

Influences of reactive oxygen species and nitric oxide on hepatic fibrogenesis.

BACKGROUND/AIMS: This study determined the roles of NAD(P)H oxidase, which generates reactive oxygen species (ROS), and of inducible nitric oxide synthase (iNOS), which generates nitric oxide (NO) on the development of hepatic fibrosis in mice. METHODS: Hepatic fibrosis was produced by carbon tetrachloride administered for 12 weeks in wild-type (WT) mice and in mice with knockout of either the gp91phox subunit of the NAD(P)H complex (gp91phox-/-) or of iNOS (iNOS(-/-)). RESULTS: Liver fibrosis and hydroxyproline after carbon tetrachloride was lower in gp91phox-/- and in iNOS(-/-) mice than in WT mice. The increase in alpha2(I) collagen mRNA was absent in the gp91phox-/- but not in the iNOS(-/-) mice. Transformation growth factor beta (TGF-beta) mRNA was increased more in the gp91phox-/- than in the WT mice, while in the iNOS(-/-) mice there was no increase in TGF-beta mRNA. 3-Nitrotyrosine was similarly increased by carbon tetrachloride in gp91phox-/- and WT mice, while there was no increase in the iNOS(-/-) mice. CONCLUSIONS: Deficiencies in NAD(P)H oxidase and in iNOS separately reduce, but do not eliminate carbon tetrachloride-induced liver fibrosis. Likely causes for this inhibitory effects are decreases in the production of ROS in NAD(P)H deficiency and of peroxinitrite radicals in iNOS deficiency.

Effects of ethanol and acetaldehyde on reactive oxygen species production in rat hepatic stellate cells.

BACKGROUND: Alcoholism is a common cause of cirrhosis. Hepatic stellate cells are the main source of collagen that ultimately leads to hepatic fibrosis and cirrhosis. Reactive oxygen species (ROS) enhance stellate cell activation and stimulate fibrogenesis. In this study, the acute effects of ethanol (ET) and acetaldehyde (AC) were determined on the production of ROS in isolated rat hepatic stellate cells. METHODS: Rat stellate cells were isolated in situ by perfusion of the portal vein and cultured. Hydrogen peroxide (H(2)O(2)) was determined by luminol-derived chemiluminescence (CL), while superoxide anion (O(2*-)) production was assessed by the fluorescent probe hydroethidine. RESULTS: AC increased the formation of H(2)O(2) and O(2*-), and these effects were first detectable at AC concentrations of 5 and 10 microM, respectively, reaching a maximum at 50 to 75 microM. Reduction of glutathione (GSH) synthesis by 1-buthionine sulfoximide (BSO) or by GSH conjugation with dimethylmaleate (DEM) further enhanced the effects of AC on H(2)O(2) and O(2*-) formation, while N-acetylcysteine (NAC) decreased H(2)O(2) and eliminated the enhanced generation of O(2*-) caused by AC. Raloxifene, which inhibits O(2*-) production by NAD(P)H oxidase, reduced the effects of AC on H(2)O(2) and O(2*-) production. ET increased H(2)O(2) or O(2*-) only in the presence of BSO or DEM. CONCLUSION: This study shows that concentrations of AC, which occur in vivo after the ingestion of alcoholic beverages, result in the formation of ROS in rat hepatic stellate cells. The increases in ROS are known to activate stellate cells promoting fibrogenesis.

Effects of acetaldehyde and TNF alpha on the inhibitory kappa B-alpha protein and nuclear factor kappa B activation in hepatic stellate cells.

AIMS: Increased plasma tumour necrosis alpha (TNFalpha) and elevated monocyte nuclear factor kappa B (NF-kappaB) are associated with liver injury and inflammation in models of alcoholic liver disease and are found to be elevated in monocytes of patients with alcoholic hepatitis. Acetaldehyde enhances, whereas TNFalpha inhibits, transcription of the type I collagen promoters and type I collagen production. NF-kappaB, an inhibitor of the type I collagen promoters, is increased by both acetaldehyde and TNFalpha. This study determined the effects of acetaldehyde in comparison to the effects of TNFalpha on inhibitory kappa B-alpha (IkappaB-alpha) protein and NF-kappaB activation in hepatic stellate cells. METHODS: Activated rat hepatic stellate cells in culture were exposed to acetaldehyde or TNFalpha for short periods of time, following which the cells were harvested for the determination of IkappaB-alpha protein, IkappaB-alpha kinase activity and nuclear NF-kappaB. RESULTS: Acetaldehyde increased IkappaB-alpha kinase activity and decreased IkappaB-alpha after 10 min of exposure, with recovery towards control levels at 20 min. In contrast, TNFalpha resulted in higher IkappaB-alpha kinase activity at 20 min than at 10 min, and similar low IkappaB-alpha at 10 and 20 min. Both acetaldehyde and TNFalpha enhanced nuclear NF-kappaB (p65), but acetaldehyde alone also increased NF-kappaB (p50). CONCLUSIONS: TNFalpha and acetaldehyde independently activate NF-kappaB by rapid enhancement of IkappaB-alpha kinase activity and degradation of IkB-alpha protein. Increased TNFalpha is the principal mechanism for the elevation of NF-kappaB in severe alcoholic hepatitis. The elevation of NF-kappaB due to TNFalpha enhance liver injury, but inhibit fibrogenesis. In contrast, the effect of acetaldehyde in activating NF-kappaB is associated with increases in both liver injury and fibrogenesis, indicating that the effects of acetaldehyde on fibrogenesis are mediated by cytokines and by trans-acting factors other than NF-kappaB.

Identification of a novel NF-kappaB-binding site with regulation of the murine alpha2(I) collagen promoter.

Hepatic fibrosis is due to the increased synthesis and deposition of type I collagen. Acetaldehyde activates type I collagen promoters. Nuclear factor kappaB (NF-kappaB) was previously shown to inhibit expression of murine alpha(1)(I) and human alpha(2)(I) collagen promoters. The present study identifies binding of NF-kappaB, present in nuclear extracts of stellate cells, to a region between -553 and -537 of the murine alpha(2)(I) collagen promoter. The NF-kappaB (p65) expression vector inhibited promoter activity. Mutation of the promoter at the NF-kappaB-binding site increased basal promoter activity and abrogated the activating and inhibitory effects of transforming growth factor beta and tumor necrosis factor alpha, respectively, on promoter activity. Acetaldehyde increased IkappaB-alpha kinase activity and phosphorylated IkappaB-alpha, NF-kappaB nuclear protein, and its binding to the promoter. However, the activating effect of acetaldehyde was not affected by the mutation of the promoter. In conclusion, although acetaldehyde increases the binding of NF-kappaB to the murine alpha(2)(I) collagen promoter, this binding does not mediate the activating effect of acetaldehyde on promoter activity. The effects of acetaldehyde in increasing the translocation of NF-kappaB to the nucleus with increased DNA binding activity may be important in mediating the effects of acetaldehyde on other genes.