Manganese superoxide dismutase knock-down in 3T3-L1 preadipocytes impairs subsequent adipogenesis

Adipogenesis is associated with the upregulation of the antioxidative enzyme manganese superoxide dismutase (MnSOD) suggesting a vital function of this enzyme in adipocyte maturation. In the current work, MnSOD was knocked-down with small-interference RNA in preadipocytes to study its role in adipocyte differentiation. In mature adipocytes differentiated from these cells, proteins characteristic for mature adipocytes, which are strongly induced in late adipogenesis like adiponectin and fatty acid-binding protein 4, are markedly reduced. Triglycerides begin to accumulate after about 6 days of the induction of adipogenesis, and are strongly diminished in cells with low MnSOD. Proteins upregulated early during differentiation, like fatty acid synthase and cytochrome C oxidase-4, are not altered. Cell viability, insulin-mediated phosphorylation of Akt, antioxidative capacity (AOC), superoxide levels, and heme oxygenase 1 with the latter being induced upon oxidative stress are not affected. L-Buthionine-(S,R)-sulfoximine (BSO) depletes glutathione and modestly lowers AOC of mature adipocytes. Addition of BSO to 3T3-L1 cells 3 days after the initiation of differentiation impairs triglyceride accumulation and expression of proteins induced in late adipogenesis. Of note, proteins that increased early during adipogenesis are also diminished, suggesting that BSO causes de-differentiation of these cells. Preadipocyte proliferation is not considerably affected by low MnSOD and BSO. These data suggest that glutathione and MnSOD are essential for adipogenesis.     

Actin bundling via LIM domains

The LIM domain is defined as a protein-protein interaction module involved in the regulation of diverse cellular processes including gene expression and cytoskeleton organization. We have recently shown that the tobacco WLIM1, a two LIM domain-containing protein, is able to bind to, stabilize and bundle actin filaments, suggesting that it participates to the regulation of actin cytoskeleton structure and dynamics. In the December issue of the Journal of Biological Chemistry we report a domain analysis that specifically ascribes the actin-related activities of WLIM1 to its two LIM domains. Results suggest that LIM domains function synergistically in the full-length protein to achieve optimal activities. Here we briefly summarize relevant data regarding the actin-related properties/functions of two LIM domain-containing proteins in plants and animals. In addition, we provide further evidence of cooperative effects between LIM domains by transiently expressing a chimeric multicopy WLIM1 protein in BY2 cells.Key words: Actin-binding proteins, actin-bundling, cysteine-rich proteins, cytoskeleton, LIM domainThe LIM domain is a ≈55 amino acid peptide domain that was first identified in 1990 as a common cystein-rich sequence found in the three homeodomain proteins LIN-11, Isl1 and MEC-3. It has since been found in a wide variety of eukaryotic proteins of diverse functions. Animals possess several families of LIM proteins, with members containing 1–5 LIM domains occasionally linked to other catalytic or protein-binding domains such as homeodomain, kinase and SH3 domains. In contrast, plants only possess two distinct sets of LIM proteins. One is plant-specific and has not been functionally characterized yet. The other one comprises proteins that exhibit the same overall structure as the animal cystein rich proteins (CRPs), i.e., two very similar LIM domains separated by a ≈50 amino acid-long interLIM domain and a relatively short and variable C-terminal domain (Fig. 1A). The mouse CRP2 protein was the first CRP reported to interact directly with actin filaments (AF) and to stabilize the latter.¹ Identical observations were subsequently described for the chicken CRP1 and tobacco WLIM1 proteins.^2,3 In addition, these two proteins were shown to arrange AF into cables both in vitro and in vivo and thus join the list of actin bundlers.Open in a separate windowFigure 1Domain maps for wild-type WLIM1 (A) and GFP-fused chimeric 3xWLIM1 (B). A. WLIM1 basically comprises a short N-terminal domain (Nt), two LIM domains (LIM1 and LIM2), an interLIM spacer (IL) and a C-terminal domain (Ct). B. 3xWLIM1 consists of three tandem WLIM1 copies. This chimeric protein has been fused in C-terminus to GFP and transiently expressed in tobacco BY2 cells.To identify the peptide domains of WLIM1 responsible for its actin-related properties/activities, we generated domain-deleted and single domain variants and submitted them to a series of in vivo and in vitro assays.⁴ Localization experiments established that both LIM domains are required to efficiently target the actin cytoskeleton in tobacco BY2 cells. High-speed (200,000 g) cosedimentation data confirmed that the actin-binding activity of WLIM1 relies on its LIM domains. Indeed, the deletion of either the first or the second LIM domain respectively resulted in a 5-fold and 10-fold decrease of the protein affinity for AF. Importantly, each single LIM domain was found able to interact with AF in an autonomous manner, although with a reduced affinity compared to the wild-type WLIM1. Low-speed (12,500 g) cosedimentation data and electron microscopy observations revealed that the actin bundling activity of WLIM1 is also triggered by its LIM domains. Surprisingly each single LIM domain was able to bundle AF in an autonomous manner, suggesting that WLIM1 has two discrete actin-bundling sites. However, the bundles induced by the variants containing only one LIM domain, i.e., LIM domain-deleted mutants and single LIM domains, differed from those induced by the full-length WLIM1. They appeared more wavy and loosely packed and formed only at relatively high protein:actin ratios. Together these data suggest that LIM domains are autonomous actin-binding and -bundling modules that function in synergy in wild-type WLIM1 to achieve optimal activities.To further assess the mechanism of cooperation between the LIM domains of plant CRP-related proteins, we generated a chimeric protein composed of three WLIM1 copies in tandem (3 × WLIM1, Fig. 1B), and transiently expressed it as a GFP-fusion in tobacco BY2 cells. We anticipated that such a six LIM domain-containing protein displays an even higher actin-bundling activity. (Fig. 2A) shows the typical actin cytoskeleton pattern in an expanding BY2 cell as visualized using the actin marker GFP-fABD2.⁵ As previously reported by Sheahan et al.,⁵ GFP-fABD2 decorated dense, transversely oriented, cortical networks as well as transvacuolar strands connecting the subcortical-perinuclear region to the cortex. Ectopic expression of WLIM1-GFP (BY2 cells normally do not express the WLIM1 gene) induced moderate but perceptible modifications of the actin cytoskeleton structure (Fig. 2B). Most AF are arranged in bundles thicker than those observed in GFP-fABD2 expressing cells and fine AF arrays are less frequently observed. As expected, this phenotype was significantly enhanced in cells transformed with the 3xWLIM1-GFP protein (Fig. 2C). Indeed, cells were almost devoided of fine AF arrays and exhibited very thick actin cables (Fig. 2C) that, at times (≈30 %), form atypical long looped structures (Fig. 2D). The appearance of such structures may result from the increase of cable stability and thickness induced by the 3xWLIM1-GFP protein, as these parameters are likely to determine, at least partially, the maximal length of actin bundles. Together the present observations support earlier data showing that LIM domains work in concert in LIM proteins to regulate actin bundling in plant cells. Strikingly, vertebrate and plant CRPs invariably contain two LIM domains. The lack, in these organisms, of CRP-related proteins combining more than two LIM domains may be explained by the fact that very thick cables, such as those induced by the artificial 3xWLIM1, may be too stable structures incompatible with the necessary high degree of actin cytoskeleton plasticity. As an exception, a muscle CRP-related protein with five LIM domains (Mlp84B) has been identified in Drosophila.⁶ However, rather than decorating actin filaments in an homogenous manner, this protein has been found to concentrate in a specialized region of the Z-discs where it stabilizes, in concert with D-titin, muscle sarcomeres.⁷Open in a separate windowFigure 2Typical actin cytoskeleton patterns in tobacco BY2 cells that have been transiently transformed, using a particle gun, with GFP-fABD2 (A), WLIM1-GFP (B), and 3xWLIM1-GFP (C and D). For each construct, more than 60 cells were analyzed by confocal microscopy. In the case of 3xWLIM1-GFP, two prevalent patterns have been observed (C and D). Bars = 20 µm.The relatively well conserved spacer length (≈50 amino acids) that separates the two LIM domains in vertebrate CRPs and related plant LIM proteins remains an intriguing feature the importance of which in actin cable organization remains to be established. Using electron microscopy we are currently evaluating the effects of the modification of the interLIM domain length on the structural properties of actin cables.     

Does prey size matter? Novel observations of feeding in the leatherback turtle (Dermochelys coriacea) allow a test of predator–prey size relationships

Optimal foraging models predict that large predators should concentrate on large prey in order to maximize their net gain of energy intake. Here, we show that the largest species of sea turtle, Dermochelys coriacea, does not strictly adhere to this general pattern. Field observations combined with a theoretical model suggest that a 300 kg leatherback turtle would meet its energetic requirements by feeding for 3-4 h a day on 4 g jellyfish, but only if prey were aggregated in high-density patches. Therefore, prey abundance rather than prey size may, in some cases, be the overriding parameter for foraging leatherbacks. This is a classic example where the presence of small prey in the diet of a large marine predator may reflect profitable foraging decisions if the relatively low energy intake per small individual prey is offset by high encounter rates and minimal capture and handling costs. This study provides, to our knowledge, the first quantitative estimates of intake rate for this species.     

Arabidopsis WD repeat domain55 Interacts with DNA damaged binding protein1 and is required for apical patterning in the embryo

CUL4-RING ubiquitin E3 ligases (CRL4s) were recently shown to exert their specificity through the binding of various substrate receptors, which bind the CUL4 interactor DNA damaged binding protein1 (DDB1) through a WDxR motif. In a segregation-based mutagenesis screen, we identified a WDxR motif-containing protein (WDR55) required for male and female gametogenesis and seed development. We demonstrate that WDR55 physically interacts with Arabidopsis thaliana DDB1A in planta, suggesting that WDR55 may be a novel substrate recruiter of CRL4 complexes. Examination of mutants revealed a failure in the fusion of the polar cells in embryo sac development, in addition to embryo and endosperm developmental arrest at various stages ranging from the zygote stage to the globular stage. wdr55-2 embryos suggest a defect in the transition to bilateral symmetry in the apical embryo domain, further supported by aberrant apical embryo localization of DORNROESCHEN, a direct target of the auxin response factor protein monopteros. Moreover, the auxin response pattern, as determined using the synthetic auxin-responsive reporter ProDR5:green fluorescent protein, was shifted in the basal embryo and suspensor but does not support a strong direct link to auxin response. Interestingly, the observed embryo and endosperm phenotype is reminiscent of CUL4 or DDB1A/B loss of function and thus may support a regulatory role of a putative CRL4(WDR55) E3 ligase complex.     

Genomic imbalances are confined to non-proliferating cells in paediatric patients with acute myeloid leukaemia and a normal or incomplete karyotype

Leukaemia is often associated with genetic alterations such as translocations, amplifications and deletions, and recurrent chromosome abnormalities are used as markers of diagnostic and prognostic relevance. However, a proportion of acute myeloid leukaemia (AML) cases have an apparently normal karyotype despite comprehensive cytogenetic analysis. Based on conventional cytogenetic analysis of banded chromosomes, we selected a series of 23 paediatric patients with acute myeloid leukaemia and performed whole genome array comparative genome hybridization (aCGH) using DNA samples derived from the same patients. Imbalances involving large chromosomal regions or entire chromosomes were detected by aCGH in seven of the patients studied. Results were validated by fluorescence in situ hybridization (FISH) to both interphase nuclei and metaphase chromosomes using appropriate bacterial artificial chromosome (BAC) probes. The majority of these copy number alterations (CNAs) were confirmed by FISH and found to localize to the interphase rather than metaphase nuclei. Furthermore, the proliferative states of the cells analyzed by FISH were tested by immunofluorescence using an antibody against the proliferation marker pKi67. Interestingly, these experiments showed that, in the vast majority of cases, the changes appeared to be confined to interphase nuclei in a non-proliferative status.     

Induction of stem cell factor/c-Kit/slug signal transduction in multidrug-resistant malignant mesothelioma cells

Malignant mesothelioma (MM) is strongly resistant to conventional chemotherapy by unclear mechanisms. We and others have previously reported that cytokine- and growth factor-mediated signal transduction is involved in the growth and progression of MM. Here, we identified a pathway that involves stem cell factor (SCF)/c-Kit/Slug in mediating multidrug resistance of MM cells. When we compared gene expression profiles between five MM cells and their multidrug-resistant (MM DX) sublines, we found that MM DX cells expressed both SCF and c-Kit and had higher mRNA levels of Slug. Knockdown of c-Kit or Slug expression with their respective small interfering RNA sensitized MM DX cells to the induction of apoptosis by different chemotherapeutic agents, including doxorubicin, paclitaxel, and vincristine. Transfection of c-Kit in parental MM cells in the presence of SCF up-regulated Slug and increased resistance to the chemotherapeutic agents. Moreover, MM cells expressing Slug showed a similar increased resistance to the chemotherapeutic agents. These results indicate that induction of Slug by autocrine production of SCF and c-Kit activation plays a key role in conferring a broad spectrum chemoresistance on MM cells and reveal a novel signal transduction pathway for pharmacological or genetic intervention of MM patients.     

Induction of 1,N(2)-etheno-2'-deoxyguanosine in DNA exposed to beta-carotene oxidation products

Epidemiological studies testing the effect of β-carotene in humans have found a relative risk for lung cancer in smokers supplemented with β-carotene. We investigated the reactions of retinal and β-apo-8′-carotenal, two β-carotene oxidation products, with 2′-deoxyguanosine to evaluate their DNA damaging potential. A known mutagenic adduct, 1,N²-etheno-2′-deoxyguanosine, was isolated and characterized on the basis of its spectroscopic features. After treatment of calf thymus DNA with β-carotene or β-carotene oxidation products, significantly increased levels of 1,N²-etheno-2′-deoxyguanosine and 8-oxo-7,8-dihydro-2′-deoxyguanosine were quantified in DNA. These lesions are believed to be important in the development of human cancers. The results reported here may contribute toward an understanding of the biological effects of β-carotene oxidation products.