Excess peroxisomes are degraded by autophagic machinery in mammals

Peroxisomes are degraded by autophagic machinery termed "pexophagy" in yeast; however, whether this is essential for peroxisome degradation in mammals remains unknown. Here we have shown that Atg7, an essential gene for autophagy, plays a pivotal role in the degradation of excess peroxisomes in mammals. Following induction of peroxisomes by a 2-week treatment with phthalate esters in control and Atg7-deficient livers, peroxisomal degradation was monitored within 1 week after discontinuation of phthalate esters. Although most of the excess peroxisomes in the control liver were selectively degraded within 1 week, this rapid removal was exclusively impaired in the mutant liver. Furthermore, morphological analysis revealed that surplus peroxisomes, but not mutant hepatocytes, were surrounded by autophagosomes in the control. Our results indicated that the autophagic machinery is essential for the selective clearance of excess peroxisomes in mammals. This is the first direct evidence for the contribution of autophagic machinery in peroxisomal degradation in mammals.     

The ascochlorin derivative, AS-6, inhibits TNF-alpha-induced adhesion molecule and chemokine expression in rat vascular smooth muscle cells

Vascular inflammation induced by the proinflammatory cytokine/NF-kappaB pathway is one of the key mechanisms in the development of atherosclerosis. Peroxisome proliferators-activated receptor-gamma (PPARgamma) plays an important role in the prevention of arterial inflammation and formation of atherogenesis. Herein we examine the effects of a newly identified synthetic PPARgamma ligand, ascochlorin-6 (AS-6), on TNF-alpha-stimulated NF-kappaB activity and inflammatory molecule expression in vascular smooth muscle cells (VSMCs). AS-6 successfully inhibited TNF-alpha-stimulated NF-kappaB activity and inflammatory molecule expression, including vascular cell adhesion molecule-1 (VCAM-1), monocyte chemotactic protein-1 (MCP-1), and fractalkine (CX3CL1). Transient transfection with an [NF-kappaB]x4 luciferase reporter construct showed that AS-6 inhibition of TNF-alpha-stimulated NF-kappaB activation was PPARgamma-dependent. The effects of AS-6 on TNF-alpha-stimulated VCAM-1 and CX3CL1 expression were abolished in cells transfected with an adenovirus expressing dominant-negative PPARgamma and in cells treated with a PPARgamma specific inhibitor, GW9662, confirming again that the anti-inflammatory effect of AS-6 was PPARgamma-dependent. The inhibitory effects of AS-6 on TNF-alpha-stimulated inflammatory gene expression and NF-kappaB activation were more potent than those of rosiglitazone and pioglitazone. This study shows that AS-6 reduces the inflammatory response to TNF-alpha in VSMCs. The data suggest the possibility that AS-6 can be used to prevent the development and progression of atherosclerosis.     

Replication-dependent marking of DNA by PCNA facilitates CAF-1-coupled inheritance of chromatin

Chromatin assembly factor 1 (CAF-1) is required for inheritance of epigenetically determined chromosomal states in vivo and promotes assembly of chromatin during DNA replication in vitro. Herein, we demonstrate that after DNA replication, replicated, but not unreplicated, DNA is also competent for CAF-1-dependent chromatin assembly. The proliferating cell nuclear antigen (PCNA), a DNA polymerase clamp, is a component of the replication-dependent marking of DNA for chromatin assembly. The clamp loader, replication factor C (RFC), can reverse this mark by unloading PCNA from the replicated DNA. PCNA binds directly to p150, the largest subunit of CAF-1, and the two proteins colocalize at sites of DNA replication in cells. We suggest that PCNA and CAF-1 connect DNA replication to chromatin assembly and the inheritance of epigenetic chromosome states.     

Oxidation of mitochondrial deoxynucleotide pools by exposure to sodium nitroprusside induces cell death

Human MutT homolog (hMTH1) hydrolyzes oxidized purine nucleoside triphosphates to monophosphates, thereby avoiding incorporation of such oxidized purines into DNA or RNA. We examined whether hMTH1 prevents cellular dysfunction induced by sodium nitroprusside, a spontaneous NO donor. Exposure to sodium nitroprusside caused an 8-oxoguanine (8-oxoG) buildup in DNA of proliferating MTH1-null cells which underwent mitochondrial degeneration and subsequently died. Quiescent MTH1-null cells also died with 8-oxoG buildup but only when the buildup affected mitochondrial and not nuclear DNA. In both proliferative and quiescent conditions, the accumulation of 8-oxoG in DNA and cell death was effectively prevented by hMTH1. Knockdown of MUTYH in quiescent MTH1-null cells significantly prevented the cell death, suggesting that 8-oxoG incorporated into mitochondrial DNA is a main cause of this form of cell death. To verify this possibility, an artificially modified hMTH1, namely mTP-EGFP-hMTH1, which localizes exclusively in mitochondria, was expressed in MTH1-null cells. mTP-EGFP-hMTH1 selectively prevented buildup of 8-oxoG in mitochondrial but not nuclear DNA after exposure of proliferating cells to sodium nitroprusside, and also efficiently prevented cell death. We thus concluded that exposure of cells to sodium nitroprusside causes oxidation of mitochondrial deoxynucleotide pools, and that buildup of oxidized bases in mitochondrial DNA initiates cell death.     

Solution structure determination of the two DNA-binding domains in the Schizosaccharomyces pombe Abp1 protein by a combination of dipolar coupling and diffusion anisotropy restraints

We have solved the solution structure of the N-terminal region of the fission yeast centromere protein, Abp1, bound to a 21-base pair DNA fragment bearing its recognition site (Mw = 30 kDa). Although the two DNA-binding domains in the Abp1 protein were defined well by a conventional NOE-based NMR methodology, the overall structure of the Abp1 protein was poorly defined, due to the lack of interdomain distance restraints. Therefore, we additionally used residual dipolar couplings measured in a weakly aligned state, and rotational diffusion anisotropies. Neither the NH residual dipolar couplings nor the backbone ¹⁵N T ₁/T ₂ data were sufficient to determine the overall structure of the Abp1 protein, due to spectral overlap. We used a combination of these two orientational restraints (residual dipolar coupling and rotational diffusion anisotropy), which significantly improved the convergence of the overall structures. The range of the observed T ₁/T ₂ ratios was wider (20–50 for the secondary structure regions of Abp1) than the previously reported data for several globular proteins, indicating that the overall shape of the Abp1DNA complex is ellipsoid. This extended form would facilitate the recognition of the two separate sites in the relatively long DNA sequence by the DNA-binding domains of Apb1.     

Almost Pure Iα Cellulose in the Cell Wall of Glaucocystis

Crystalline features of cellulose microfibrils in the cell walls of Glaucocystis (Glaucophyta) were studied by combined spectroscopy and diffraction techniques, and the results were compared with those of Oocystis (Chlorophyta). Although these algae are grouped into two different classes, by the composition of their chloroplasts for instance, their cell walls are quite similar in size and morphology. The most striking features of their cellulose crystallites are that they have the highest cellulose I_α contents reported to date. In particular, the I_α fraction of cellulose from Glaucocystis was found to be as high as 90% from ¹³C NMR analysis. The mode of preferential orientation of cellulose crystallites in their cell walls is also interesting; equatorial 0.53-nm lattice planes were oriented parallel to the cell surface in the case of Glaucocystis, while the 0.62-nm planes were parallel to the Oocystis cell surface. Such a structural variation provides another link to the evolution of cellulose structure, biosynthesis, and its biocrystallization mechanism.     

Maturation stress generation in poplar tension wood studied by synchrotron radiation microdiffraction

Tension wood is widespread in the organs of woody plants. During its formation, it generates a large tensile mechanical stress called maturation stress. Maturation stress performs essential biomechanical functions such as optimizing the mechanical resistance of the stem, performing adaptive movements, and ensuring the long-term stability of growing plants. Although various hypotheses have recently been proposed, the mechanism generating maturation stress is not yet fully understood. In order to discriminate between these hypotheses, we investigated structural changes in cellulose microfibrils along sequences of xylem cell differentiation in tension and normal wood of poplar (Populus deltoides × Populus trichocarpa 'I45-51'). Synchrotron radiation microdiffraction was used to measure the evolution of the angle and lattice spacing of crystalline cellulose associated with the deposition of successive cell wall layers. Profiles of normal and tension wood were very similar in early development stages corresponding to the formation of the S1 layer and the outer part of the S2 layer. Subsequent layers were found with a lower microfibril angle (MFA), corresponding to the inner part of the S2 layer of normal wood (MFA approximately 10°) and the G layer of tension wood (MFA approximately 0°). In tension wood only, this steep decrease in MFA occurred together with an increase in cellulose lattice spacing. The relative increase in lattice spacing was found close to the usual value of maturation strains. Analysis showed that this increase in lattice spacing is at least partly due to mechanical stress induced in cellulose microfibrils soon after their deposition, suggesting that the G layer directly generates and supports the tensile maturation stress in poplar tension wood.