Erratum to: Inhibition of Angiotensin II-Induced Cardiac Fibrosis by Atorvastatin in Adiponectin Knockout Mice.

In the original published article, Victor Serebruany was designated as the corresponding author in error. The corresponding author is Jong Sung Park. Dr. Park can be reached by email at thinkmed@dau.ac.kr.

Inhibition of Angiotensin II-Induced Cardiac Fibrosis by Atorvastatin in Adiponectin Knockout Mice.

Adiponectin is a polypeptide known to inhibit cardiac fibrosis via the activation of adenosine monophosphate-activated protein kinase (AMPK). Statins can also activate AMPK, resulting in the secretion of adiponectin. We determined whether atorvastatin inhibits angiotensin II-induced cardiac fibrosis (AICF) in the presence or absence of adiponectin. Adiponectin knockout (APN-KO, n = 44) and wild type (WT, n = 44) mice were received subcutaneous angiotensin II (1.5 mg/kg/day), and atorvastatin (10 mg/kg/day) was administered orally for 15 days. The mRNA expression levels of collagen type I and III, as well as AMPK phosphorylation levels in cardiac tissue were then measured. In the APN-KO mice, collagen type I (p < 0.001) and type III (p = 0.001) expression was significantly greater when treated with angiotensin II, while their expression was significantly reduced in the presence of angiotensin II and atorvastatin. Relative AMPK phosphorylation levels in APN-KO mice were also significantly higher in the angiotensin II + atorvastatin group when compared with angiotensin II group alone. We conclude that atorvastatin attenuates AICF independently from adiponectin by activating AMPK. These data suggest potential cardioprotection beyond lipid modulation potentially supporting statin pleiotropic hypothesis.

Archvillin anchors in the Z-line of skeletal muscle via the nebulin C-terminus.

Z-Line of skeletal muscle is a complex protein network that likely plays an important role in signaling and muscle homeostasis. We used the yeast two-hybrid system to search for potential novel ligands of the Z-line portion of nebulin. We found that the C-terminal region of nebulin (residues 6457-6528) interacted with the C-terminus of archvillin (residues 1419-1687). Archvillin is a membrane skeletal protein that localizes to costameres, specialized adhesion sites in muscle. The binding sites between nebulin and archvillin were characterized using the yeast two-hybrid system, in vitro pull-down assays, and colocalization experiments in COS-7 cells. Our data suggest a model in which archvillin attaches directly to the Z-line through an interaction with the nebulin C-terminus. The interaction between nebulin and archvillin may provide a direct link between the sarcolemma and myofibrillar Z-lines.

Biological responses of ligament fibroblasts and gene expression profiling on micropatterned silicone substrates subjected to mechanical stimuli.

In this study, ligament fibroblasts were cultivated on micropatterned silicone substrates and subjected to cyclic stretching to simulate the in vivo biomechanical environment during ligament healing. Without stretching, ligament fibroblasts were aligned parallel to the microgrooves on the silicone substrate surface. However, we previously reported that uniaxial cyclic stretching induces alignment perpendicular to the stretching axis. With stretching on a microgrooved surface, cell proliferation and collagen production were greatly enhanced. The exact functions of the micropatterned surface and mechanical stimuli are unknown. Therefore, in gene expression microarray experiments, genes whose expression is inhibited by subculture from passage 0 (P0) to passage 8 (P8) and enhanced by micropatterning and stretching were sought out. The following six genes were selected: MGP, GADD45A, UNC5B, TGFB1, COL4A1, and COL4A2. The selected genes play fundamental roles in cell proliferation, differentiation, apoptosis, and structural maintenance. On the basis of the obtained gene expression profiles, we identified candidate genes that might be involved in responses to a micropatterned surface and mechanical stretching.

An in vivo analysis of MMC-induced DNA damage and its repair.

Mitomycin C (MMC) induces various types of DNA damages that cause significant cytotoxicity to cells. Accordingly, repair of MMC-induced damages involves multiple repair pathways such as nucleotide excision repair, homologous recombination repair and translesion bypass repair pathways. Nonetheless, repair of the MMC-induced DNA damages in mammals have not been fully delineated. In this study, we investigated potential roles for Xeroderma pigmentosum (XP) proteins in the repair of MMC-induced DNA damages using an assay that detects the ssDNA patches generated following treatment with MMC or 8'-methoxy-psoralen (8-MOP) + UVA (ultraviolet light A). Human wild-type cells formed distinctive ssDNA foci following treatment with MMC or 8-MOP + UVA, but not with those inducing alkylation damage, oxidative damage or strand-break damage, suggesting that the foci represent ssDNA patches formed during the crosslink repair. In contrast to wild-type cells, mutant defective in XPE orXPG did not form the ssDNA foci following MMC treatment, while XPF mutant cells showed a significantly delayed response in forming the foci. A positive role for XPG in the repair of MMC-induced DNA damages was further supported by observations that cells treated with MMC induced a tight association of XPG with chromatin, and a targeted inhibition of XPG abolished MMC-induced ssDNA foci formation, rendering cells hypersensitive to MMC. Together, our results suggest that XPG along with XPE and XPF play unique role(s) in the repair of MMC-induced DNA damages.

Identification of chicken nebulin isoforms of the 31-residue motifs and non-muscle nebulin.

Nebulin is a very large (M(r) 600-900kDa) actin-binding protein that is specific to skeletal muscle, and which is thought to act as a molecular template that regulates the length of sarcomere thin filaments. The 31-residue motif of nebulin contains a unique PEhXRVKXNQ consensus sequence. We have previously identified 11 different human nebulin isoforms of these 31-residue motifs. Here we present the identification of seven different isoforms (types II, III, IVa, IVb, V, VI, and X) of the 31-residue motifs in 15-day-old chicken embryo breast muscle. Isoform types II and III are also expressed in the brain, and type III is also detected in the heart, stomach, and liver. Chicken nebulin contains 11 copies of the 31-residue motif (R1a/b, R2, R3, R4, R5, R6, R7, R8, R9, R10, and R11), whereas human nebulin contains 13 copies. We confirmed the expression of nebulin in the heart, stomach, and brain in 15-day-old chicken embryos by immunofluorescence microscopy. The presence of nebulin in brain was further confirmed by in situ hybridization. These data suggest that there is even more diversity in nebulin isoforms than was previously known; this diversity likely contributes to the distinct actin filament architecture of different tissues.

Isoform specificity among ankyrins. An amphipathic alpha-helix in the divergent regulatory domain of ankyrin-b interacts with the molecular co-chaperone Hdj1/Hsp40.

Ankyrins-R, -B, and -G are a family of membrane-associated adaptors required for localization of structurally diverse proteins to specialized membrane domains, including axon initial segments, cardiomyocyte T-tubules, and epithelial cell lateral membranes. Ankyrins are often co-expressed in the same cells and, although structurally similar, have non-overlapping functions. We previously determined that the regulatory domain of ankyrin-B defines specificity between ankyrins B and G in cardiomyocytes. Here, we identify key residues on the surface of an amphipathic alpha-helix unique to the regulatory domain of ankyrin-B that are essential for the function of ankyrin-B in cardiomyocytes. Using circular dichroism, we determined that a peptide representing the predicted helix folds as a helix in solution. Alanine-scanning mutagenesis revealed that residues 1773, 1777, 1780, 1784, and 1788 located in a patch on one surface the helix are critical for ankyrin-B function in cardiomyocytes. In a parallel set of experiments we determined that the molecular co-chaperone human DnaJ homologue 1 (Hdj1)/Hsp40 interacts with the ankyrin-B regulatory domain. Moreover, interaction of Hdj1/Hsp40 with the regulatory domain was mapped by random mutagenesis to same surface of the alpha-helix that is required for ankyrin-B function. These results provide new insight into the molecular basis for specificity between ankyrin-based pathways by defining a key alpha-helix structure in the divergent regulatory domain of ankyrin-B as well as interaction of the helix with Hdj1/Hsp40, the first downstream target for ankyrin-B-specific function.