Atherogenic diet causes lethal ileo-ceco-colitis in cyclooxygenase-2 deficient mice

Cyclooxygenases (COX) regulate a variety of inflammatory diseases, including inflammatory bowel disease (IBD). While the pathological effects of COX-1 inhibition by NSAIDs on intestinal ulceration are well established, the role of COX-2 on intestinal inflammation remains under investigation. In this paper, we report a protective role for COX-2 against diet-mediated intestinal inflammation in mice. COX-2(-/-) mice fed an atherogenic diet or diet containing cholate, but not chow or fat alone, had a high mortality whereas COX-1(-/-) mice and wild-type mice were unaffected by the dietary changes. Histological analysis identified the cause of death in COX-2(-/-) mice due to severe intestinal inflammation that was surprisingly limited to the ileo-ceco-colic junction. COX-2 expression is induced in the cecum of wild-type mice fed an atherogenic diet. Our findings show that COX-2 plays an anti-inflammatory role at the ileo-ceco-colic junction in mice, and the pathology of diet-mediated intestinal inflammation in COX-2(-/-) mice offers an excellent model system to elucidate the molecular mechanisms of intestinal inflammation.     

LXRα is uniquely required for maximal reverse cholesterol transport and atheroprotection in ApoE-deficient mice

The liver X receptor (LXR) signaling pathway is an important modulator of atherosclerosis, but the relative importance of the two LXRs in atheroprotection is incompletely understood. We show here that LXRα, the dominant LXR isotype expressed in liver, plays a particularly important role in whole-body sterol homeostasis. In the context of the ApoE(-/-) background, deletion of LXRα, but not LXRβ, led to prominent increases in atherosclerosis and peripheral cholesterol accumulation. However, combined loss of LXRα and LXRβ on the ApoE(-/-) background led to an even more severe cholesterol accumulation phenotype compared to LXRα(-/-)ApoE(-/-) mice, indicating that LXRβ does contribute to reverse cholesterol transport (RCT) but that this contribution is quantitatively less important than that of LXRα. Unexpectedly, macrophages did not appear to underlie the differential phenotype of LXRα(-/-)ApoE(-/-) and LXRβ(-/-)ApoE(-/-) mice, as in vitro assays revealed no difference in the efficiency of cholesterol efflux from isolated macrophages. By contrast, in vivo assays of RCT using exogenously labeled macrophages revealed a marked defect in fecal sterol efflux in LXRα(-/-)ApoE(-/-) mice. Mechanistically, this defect was linked to a specific requirement for LXRα(-/-) in the expression of hepatic LXR target genes involved in sterol transport and metabolism. These studies reveal a previously unrecognized requirement for hepatic LXRα for optimal reverse cholesterol transport in mice.     

Structural insights into the pro-apoptotic function of mitochondrial serine protease HtrA2/Omi

HtrA2/Omi, a mitochondrial serine protease in mammals, is important in programmed cell death. However, the underlining mechanism of HtrA2/Omi-mediated apoptosis remains unclear. Analogous to the bacterial homolog HtrA (DegP), the mature HtrA2 protein contains a central serine protease domain and a C-terminal PDZ domain. The 2.0 A crystal structure of HtrA2/Omi reveals the formation of a pyramid-shaped homotrimer mediated exclusively by the serine protease domains. The peptide-binding pocket of the PDZ domain is buried in the intimate interface between the PDZ and the protease domains. Mutational analysis reveals that the monomeric HtrA2/Omi mutants are unable to induce cell death and are deficient in protease activity. The PDZ domain modulates HtrA2/Omi-mediated cell death activity by regulating its serine protease activity. These structural and biochemical observations provide an important framework for deciphering the mechanisms of HtrA2/Omi-mediated apoptosis.     

Rapid kinetics of tBid-induced cytochrome c and Smac/DIABLO release and mitochondrial depolarization.

Cleavage of Bid has been shown to promote apoptosis by inducing mitochondrial membrane permeabilization with the resultant release of apoptosis-inducing proteins from the intermembrane space into the cytosol. However, direct visualization of the Bid-induced release of various proteins from the highly compartmentalized intermembrane space and the changes in the mitochondrial metabolic machinery remain elusive. Using green fluorescent protein fusion proteins and immunostaining in individual permeabilized HepG2 cells, first we demonstrated that truncated Bid (15.5-kDa C-terminal fragment, tBid) evoked a rapid and essentially complete release of cytochrome c and Smac/DIABLO from every mitochondrion. To establish at a resolution of seconds the kinetics of tBid-induced cytochrome c and Smac/DIABLO release and depolarization, we monitored the mitochondrial membrane potential (DeltaPsi(m)) fluorimetrically in permeabilized cells and applied a rapid filtration method to obtain cytosolic fractions for Western blotting. We found that subnanomolar doses of tBid were sufficient to evoke cytochrome c release and mitochondrial depolarization, whereas full-length Bid was 100-fold less effective. Bcl-x(L) prevented tBid-induced cytochrome c release and depolarization. In response to 2.5 nm tBid, cytochrome c release started after a 10 s delay, displayed rapid progression, and was complete at 50-70 s. Release of Smac/DIABLO was synchronized with cytochrome c release, whereas the loss of DeltaPsi(m) lagged slightly behind cytochrome c release. Furthermore, tBid-induced cytochrome c release was insensitive to changes in substrate composition, but tBid-induced depolarization did not occur in the presence of extramitochondrial ATP supply. Thus, tBid-induced permeabilization of the outer membrane permits rapid release of cytochrome c and Smac/DIABLO from all domains of the intermembrane space. The tBid-induced loss of DeltaPsi(m) occurs after cytochrome c release and reflects impairment of oxidative metabolism.     

Red rot resistance in interspecific protoplast fusion product progeny of Porphyra yezoensis and P. tenuipedalis (Bangiales, Rhodophyta)

Nine primary regenerants were recovered by interspecific protoplast fusion of Porphyra yezoensis Ueda T‐14 (Py) (cultivated Porphyra) and Porphyra tenuipedalis Miura (Pt). This combination is difficult to achieve with conventional sexual hybridization, yet is important in that non‐cultivated P. tenuipedalis is partially resistant (PR) to red rot disease, caused by the microbial pathogen, Pythium porphyrae Takahashi et Sasaki. Out of the nine primary regenerants, two strains (Py‐Pt‐4 and Py‐Pt‐7) were like the parent, P. tenuipedalis, while the rest were like the other cultivated parent P. yezoensis T‐14 in their life cycle. Red rot resistance was assessed in parents and interspecific fusion product progeny (FPP) by exposing the foliose thalli to equivalent infection and measuring two parameters of the host‐pathogen interactions: supported fungal biomass and amount of disease produced. Intermediate resistance between P. yezoensis T‐14 (1.00) and P. tenuipedalis (0.13) was observed in two of the Py‐type FPP, Py‐Pt‐2F₂ (0.25) and Py‐Pt‐5F₂ (0.23). Stable inheritance of resistance was observed through two subsequent generations. The morphologic and reproductive characteristics of the regenerated foliose thalli, and nature of host‐pathogen interactions were used to further verify the hybrid origin of the FPP. Host‐pathogen interactions were followed using epi‐fluorescence and scanning electron microscopy (SEM). The zoospores encysted at higher rates on the susceptible cultivated parent (P. yezoensis T‐14) germinated immediately and the short germ tubes formed appres‐soria and penetrated the algal cells near the site of encystment. While on the PR parental (P. tenuipedalis) and partially resistant FPP (PRFPP) progeny (Py‐Pt‐2F₂ and Py‐Pt‐5F₂) the low rate of zoospore encystment was followed by cyst germination, but only a few of the germ tubes formed appressoria and penetrated the thallus surface. Long germ tubes (with no appressoria) were seen growing on the thallus surface without host penetration. The minimal rate of encystment concomitant with low rate of appressorium formation on the PR parent and PRFPP was observed as the major factor responsible for the partial resistance in these thalli.     

An efficient synthesis of N3,4-diphenyl-5-(4-fluorophenyl)-2-isopropyl-1H-3-pyrrolecarboxamide, a key intermediate for atorvastatin synthesis

An efficient synthesis of N3,4-diphenyl-5-(4-fluorophenyl)-2-isopropyl-1H-3-pyrrolecarboxamide, a key intermediate for the synthesis of an effective HMG-CoA reductase inhibitor atorvastatin, is described. The synthesis is based on the 1,3-dipolar cycloaddition reaction of mesoionic munchnone (1,3-oxazolium-5-olate) with N1,3-diphenyl-2-propynamide leading to N-benzyl pyrrole, and N-debenzylation using sodium in liquid ammonia as key steps.     

Control of oligonucleotide retention on a pH-stabilized strong anion exchange column

Strong anion exchange columns are preferred for oligonucleotide analyses due to their ability to effectively control secondary structure and poly(G) interactions. Methacrylate-based anion exchange phases minimize hydrophobic interactions with oligonucleotides, but they also tend to hydrolyze under alkaline conditions. In this article, we report the use of an anion exchange column prepared from a new class of methacrylate monomers designed to improve hydrolytic stability. This column is used to show predictable adjustment of oligonucleotide retention by eluent pH and composition. Features of the new column include (i) large, predictable, pH-dependent retention shifts (varying with specific changes in 5' or 3' terminal bases with NaCl-based eluents); (ii) reduced retention when solvent is added to NaCl-based eluents; and (iii) suppression of much of the column's hydrophobic interactions when CH3CN is used with NaClO4-based eluents at a neutral pH (i.e., this eluent system separates oligonucleotides primarily in order of their length). These observations will aid the development of elution conditions for both size-dependent and base sequence-dependent (or base composition-dependent) separations.     

Identification of protein modifications using MS/MS de novo sequencing and the OpenSea alignment algorithm

Algorithms that can robustly identify post-translational protein modifications from mass spectrometry data are needed for data-mining and furthering biological interpretations. In this study, we determined that a mass-based alignment algorithm (OpenSea) for de novo sequencing results could identify post-translationally modified peptides in a high-throughput environment. A complex digest of proteins from human cataractous lens, a tissue containing a high abundance of modified proteins, was analyzed using two-dimensional liquid chromatography, and data was collected on both high and low mass accuracy instruments. The data were analyzed using automated de novo sequencing followed by OpenSea mass-based sequence alignment. A total of 80 modifications were detected, 36 of which were previously unreported in the lens. This demonstrates the potential to identify large numbers of known and previously unknown protein modifications in a given tissue using automated data processing algorithms such as OpenSea.