Tissue Transglutaminase Knock-Out Preadipocytes and Beige Cells of Epididymal Fat Origin Possess Decreased Mitochondrial Functions Required for Thermogenesis.

Beige adipocytes with thermogenic function are activated during cold exposure in white adipose tissue through the process of browning. These cells, similar to brown adipocytes, dissipate stored chemical energy in the form of heat with the help of uncoupling protein 1 (UCP1). Recently, we have shown that tissue transglutaminase (TG2) knock-out mice have decreased cold tolerance in parallel with lower utilization of their epididymal adipose tissue and reduced browning. To learn more about the thermogenic function of this fat depot, we isolated preadipocytes from the epididymal adipose tissue of wild-type and TG2 knock-out mice and differentiated them in the beige direction. Although differentiation of TG2 knock-out preadipocytes is phenotypically similar to the wild-type cells, the mitochondria of the knock-out beige cells have multiple impairments including an altered electron transport system generating lower electrochemical potential difference, reduced oxygen consumption, lower UCP1 protein content, and a higher portion of fragmented mitochondria. Most of these differences are present in preadipocytes as well, and the differentiation process cannot overcome the functional disadvantages completely. TG2 knock-out beige adipocytes produce more iodothyronine deiodinase 3 (DIO3) which may inactivate thyroid hormones required for the establishment of optimal mitochondrial function. The TG2 knock-out preadipocytes and beige cells are both hypometabolic as compared with the wild-type controls which may also be explained by the lower expression of solute carrier proteins SLC25A45, SLC25A47, and SLC25A42 which transport acylcarnitine, Co-A, and amino acids into the mitochondrial matrix. As a consequence, the mitochondria in TG2 knock-out beige adipocytes probably cannot reach the energy-producing threshold required for normal thermogenic functions, which may contribute to the decreased cold tolerance of TG2 knock-out mice.

Transglutaminase 2 Has Metabolic and Vascular Regulatory Functions Revealed by In Vivo Activation of Alpha1-Adrenergic Receptor.

The multifunctional tissue transglutaminase has been demonstrated to act as α1-adrenergic receptor-coupled G protein with GTPase activity in several cell types. To explore further the pathophysiological significance of this function we investigated the in vivo effects of the α1-adrenergic receptor agonist phenylephrine comparing responses in wild type and TG2-/- mice. Injection of phenylephrine, but not a beta3-adrenergic agonist (CL-316,243), resulted in the long-term decline of the respiratory exchange ratio and lower lactate concentration in TG2-/- mice indicating they preferred to utilize fatty acids instead of glucose as fuels. Measurement of tail blood pressure revealed that the vasoconstrictive effect of phenylephrine was milder in TG2-/- mice leading to lower levels of lactate dehydrogenase (LDH) isoenzymes in blood. LDH isoenzyme patterns indicated more damage in lung, liver, kidney, skeletal, and cardiac muscle of wild type mice; the latter was confirmed by a higher level of heart-specific CK-MB. Our data suggest that TG2 as an α1-adrenergic receptor-coupled G protein has important regulatory functions in alpha1-adrenergic receptor-mediated metabolic processes and vascular functions.

Browning deficiency and low mobilization of fatty acids in gonadal white adipose tissue leads to decreased cold-tolerance of transglutaminase 2 knock-out mice.

During cold-exposure 'beige' adipocytes with increased mitochondrial content are activated in white adipose tissue (WAT). These cells, similarly to brown adipose tissue (BAT), dissipate stored chemical energy in the form of heat with the help of uncoupling protein 1 (UCP1). We investigated the effect of tissue transglutaminase (TG2) ablation on the function of ATs in mice. Although TG2+/+ and TG2-/- mice had the same amount of WAT and BAT, we found that TG2+/+ animals could tolerate acute cold exposure for 4h, whereas TG2-/- mice only for 3h. Both TG2-/- and TG2+/+ animals used up half of the triacylglycerol content of subcutaneous WAT (SCAT) after 3h treatment; however, TG2-/- mice still possessed markedly whiter and higher amount of gonadal WAT (GONAT) as reflected in the larger size of adipocytes and lower free fatty acid levels in serum. Furthermore, lower expression of 'beige' marker genes such as UCP1, TBX1 and TNFRFS9 was observed after cold exposure in GONAT of TG2-/- mice, paralleled with a lower level of UCP1 protein and a decreased mitochondrial content. The detected changes in gene expression of Resistin and Adiponectin did not provoke glucose intolerance in the investigated TG2-/- mice, and TG2 deletion did not influence adrenaline, noradrenaline, glucagon and insulin production. Our data suggest that TG2 has a tissue-specific role in GONAT function and browning, which becomes apparent under acute cold exposure.

Combined introduction of Bmi-1 and hTERT immortalizes human adipose tissue-derived stromal cells with low risk of transformation.

Adipose tissue-derived stromal cells (ASCs) are increasingly being studied for their usefulness in regenerative medicine. However, limited life span and donor-dependent variation of primary cells such as ASCs present major hurdles to controlled and reproducible experiments. We therefore aimed to establish immortalized ASC cell lines that provide steady supply of homogeneous cells for in vitro work while retain essential features of primary cells. To this end, combinations of human telomerase reverse transcriptase (hTERT), murine Bmi-1, and SV40 large T antigen (SV40T) were introduced by lentiviral transduction into ASCs. The resulting cell lines ASC(hTERT), ASC(Bmi-1), ASC(Bmi-1+hTERT) and ASC(SV40T+hTERT) were tested for transgene expression, telomerase activity, surface immunomarkers, proliferation, osteogenic and adipogenic differentiation, karyotype, tumorigenicity, and cellular senescence. All cell lines have maintained expression of characteristic surface immunomarkers, and none was tumorigenic. However, ASC(Bmi-1) had limited replicative potential, while the rapidly proliferating ASC(SV40T+hTERT) acquired chromosomal aberrations, departed from MSC phenotype, and lost differentiation capacity. ASC(hTERT) and ASC(hTERT+Bmi-1), on the other hand, preserved all essential MSC features and did not senesce after 100 population doublings. Notably, a subpopulation of ASC(hTERT) also acquired aberrant karyotype and showed signs of transformation after long-term culture. In conclusion, hTERT alone was sufficient to extend the life span of human ASC, but ASC(hTERT) are prone to transformation during extensive subculturing. The combination of Bmi-1 and hTERT successfully immortalized human ASCs without significantly perturbing their phenotype or biological behavior.

Phagocytosis of cells dying through autophagy induces inflammasome activation and IL-1ß release in human macrophages.

Phagocytosis of naturally dying cells usually blocks inflammatory reactions in host cells. We have recently observed that clearance of cells dying through autophagy leads to a pro-inflammatory response in human macrophages. Investigating this response further, we found that during engulfment of MCF-7 or 293T cells undergoing autophagic death, but not apoptotic or anoikic ones, caspase-1 was activated and IL-1ß was processed, then secreted in a MyD88-independent manner. Autophagic dying cells were capable of preventing some LPS-induced pro-inflammatory responses, such as TNFα, IL-6 and IL-8 induction, but synergized with LPS for IL-1ß production. Caspase-1 inhibition prevented macrophage IL-1ß release triggered by the dying cells and also other pro-inflammatory cytokines which were not formed in the presence of IL-1 receptor antagonist anakinra either. IL-1ß secretion was also observed using calreticulin knock down or necrostatin treated autophagic MCF-7 cells and it required phagocytosis of the dying cells which led to ATP secretion from macrophages. Blocking K (+) efflux during phagocytosis, the presence of apyrase, adding an antagonist of the P2X7 receptor or silencing the NOD-like receptor protein NALP3 inhibited IL-1ß secretion. These data suggest that during phagocytosis of autophagic dying cells ATP, acting through its receptor, initiates K (+) efflux, inflammasome activation and secretion of IL-1ß, which initiates further pro-inflammatory events. Thus, autophagic death of malignant cells and their clearance may lead to immunogenic response.

Altered sialylation on the cell-surface proteins of dexamethasone-treated human macrophages contributes to augmented uptake of apoptotic neutrophils.

Macrophages eliminate apoptotic granulocytes before their secondary necrosis during resolution of inflammation. A well-known glucocorticoid, the anti-inflammatory dexamethasone augments phagocytosis capacity of macrophages with a so far not fully clarified mechanism. We have found that sialylation of cell-surface proteins on human macrophages is markedly altered by dexamethasone. Compared to non-treated cells, dexamethasone-treated macrophages can bind significantly less Sambucus nigra lectin specific for sialic acids on their surfaces as a result of undersialylation of annexin-II and an HLA-II protein. Non-treated macrophages covered by S. nigra lectin had increased uptake of apoptotic cells; however, the significantly higher phagocytosis capacity of dexamethasone-treated macrophages could not be stimulated further this way. Our results suggest that dexamethasone treatment leads to decreased number of sialic acids on the surfaces of human macrophages promoting recognition and uptake of apoptotic cells.

Mass spectrometric proteome analysis suggests anaerobic shift in metabolism of Dauer larvae of Caenorhabditis elegans.

The Dauer larva is a non-feeding alternative larval stage of some nematodes specialized for long-term survival and dispersal. In this study we compared proteome maps obtained from Dauer larvae with those from the corresponding third larval stage (L3) of the feeding life cycle of C. elegans wild-type strain N2. We demonstrate at the protein level that altered metabolism may participate in longevity determination of Dauers. We detected huge amounts of alcohol dehydrogenase (CE12212) and aldehyde dehydrogenase (CE29809) in Dauer animals, indicating highly active fermentative pathways. Inorganic pyrophosphatase (CE05448) that enables to metabolize pyrophosphate as a high-energy source was over-expressed in Dauers. An interesting differentially expressed protein was phosphatidylethanolamine-binding protein (CE38516) that was found in high abundance in samples from Dauer larvae. Protein synthesis may be lowered in Dauer animals by the reduced expression of splicing factor rsp-3 (CE31089) and methionyl-tRNA synthase (CE34219). We observed significantly lower amounts of the pepsin-like aspartyl protease 1 (CE21681) in non-feeding Dauers, which is in agreement with reduced nutrient digestion. Finally, the hypothetical protein R08E5.2 (CE33294) was present in high abundance in L3 animals.

High-throughput scintillation proximity assay for transglutaminase activity measurement.

Members of the transglutaminase enzyme family are involved in a broad range of biological phenomena, including haemostasis, apoptosis, semen coagulation, skin formation, and wound healing. A new and rapid method for measurement of transglutaminase activity is described in this article. The enzyme links tritium-labeled putrescine to biotinylated oligoglutamine, and the tritiated peptide is bound to a streptavidin-coated microtiter plate permanently covered by a thin layer of scintillant. Only the radioisotope incorporated into the peptide substrate is close enough to the scintillant molecules for photons to be produced. The signal generation depends on the transglutaminase activity, and it can be detected by appropriate light-measuring instrumentation without separation steps. The assay is sensitive, specific, linear at concentrations of tissue transglutaminase between 0.05 and 1.6m U/ml, and suitable for high-throughput measurements.

Arginine methylation provides epigenetic transcription memory for retinoid-induced differentiation in myeloid cells.

Cellular differentiation is governed by changes in gene expression, but at the same time, a cell's identity needs to be maintained through multiple cell divisions during maturation. In myeloid cell lines, retinoids induce gene expression and a well-characterized two-step lineage-specific differentiation. To identify mechanisms that contribute to cellular transcriptional memory, we analyzed the epigenetic changes taking place on regulatory regions of tissue transglutaminase, a gene whose expression is tightly linked to retinoid-induced differentiation. Here we report that the induction of an intermediary or "primed" state of myeloid differentiation is associated with increased H4 arginine 3 and decreased H3 lysine 4 methylation. These modifications occur before transcription and appear to prime the chromatin for subsequent hormone-regulated transcription. Moreover, inhibition of methyltransferase activity, pre-acetylation, or activation of the enzyme PAD4 attenuated retinoid-regulated gene expression, while overexpression of PRMT1, a methyltransferase, enhanced retinoid responsiveness. Taken together, our results suggest that H4 arginine 3 methylation is a bona fide positive epigenetic marker and regulator of transcriptional responsiveness as well as a signal integration mechanism during cell differentiation and, as such, may provide epigenetic memory.

Differential proteome analysis and mass spectrometric characterization of germ line development-related proteins of Caenorhabditis elegans.

Proteome maps and differences of protein patterns of the synchronized larval stage L4 of the temperature-sensitive Caenorhabditis elegans (C. elegans) glp-1 mutant (e2144ts) were investigated after cultivation at 15 degrees C (developing a normal phenotype) or 25 degrees C (developing a mutated phenotype) by two-dimensional gel electrophoresis (2-DE) and matrix-assisted laser desorption/ionization (MALDI)-mass spectrometry. From the 183 identified protein spots six proteins were found differently expressed. The Vit-6 vitellogenin (CE28594), the hypothetical 17.2 protein (CE25224), the hypothetical 17.4 protein (CE16999), and the heat shock protein 16 kDa (CE14249) were more abundant when growing worm cultures at 25 degrees C. By contrast, the nucleoside diphosphate kinase (CE09650) was found increased at 15 degrees C. Most notably, the eukariotic initiation factor 5A-1 (CE00503), highly abundant at 15 degrees C, was not present in cultures grown at 25 degrees C. Its absence at 25 degrees C can not be attributed to lack of the enzymatic machinery that is necessary for hypusinylation. Instead, a direct downstream effect of the lack of functionality of GLP-1 may cause the expression of this protein. The yolk proteins 115 kDa and 88 kDa were attributed by mass spectrometric protein structure analysis as C-terminal and N-terminal fragments of the Vit-6 vitellogin protein (CE28594), respectively. The cleavage site between both derivatives was located between R764 and A768. A conflict in the database sequences at amino acid positions 1622 and 1623 of vitellogenin-6 was solved by mass spectrometric sequence analysis. The combination of 2-DE with mass spectrometry enabled the identification of mutation-associated differences on somatic gonadal cell and germ line cell development-associated proteins.

Amine donor protein substrates for transglutaminase activity in Caenorhabditis elegans.

Transglutaminase dependent cross-linking of proteins has been implicated in a wide range of biological phenomena occurring in both extracellular and intracellular compartments. Clarification of the physiological role of transglutaminases requires identification of substrate molecules. Here we report the detection, purification, and identification by mass spectrometry of proteins, the glutamate dehydrogenase, a protein disulfide isomerase, and aldehyde dehydrogenase as amine donor substrates for the transglutaminase activity of the nematode Caenorhabditis elegans utilizing a novel biotinylated oligoglutamine peptide as a substrate. We also purified and identified streptavidin-binding proteins of the worm.

Mass spectrometric proteome analysis for profiling temperature-dependent changes of protein expression in wild-type Caenorhabditis elegans.

We investigated the effect of cultivation temperatures on the protein expression levels in the fourth larval stage of the postembryonic development of wild-type Caenorhabditis elegans by mass spectrometric proteome analysis. From the 64 protein spots that were investigated, 5 spots were found reproducibly differently expressed when proteome maps derived from animals kept at 15 degrees C and at 25 degrees C, respectively, were compared. Spots of heat shock proteins HSP 70 (CE18679 or CE09682) and HSP 16 (CE14249) were present only in gels from protein extracts when worms were grown at 15 degrees C. Spots of two metabolic enzymes, the isocitrate dehydrogenase (CE10345) and the aspartic proteinase (CE21681) were detected only in cultures grown at the lower temperature as well. A protein with still unknown function (CE05036) was present only in gels from worm samples grown at 25 degrees C. We show for the first time by proteome analyses that cultivation of worms at the lowest temperature of the known physiological range (15 degrees C) already triggers a (weak) stress response in wild-type animals. This work led to the identification of "internal control proteins" in the wild-type strain for further characterization of temperature-sensitive strains using a proteomics approach.

Profiling stage-dependent changes of protein expression in Caenorhabditis elegans by mass spectrometric proteome analysis leads to the identification of stage-specific marker proteins.

Proteome maps obtained by synchronization of the wild-type Caenorhabditis elegans development reflected stage-dependent molecular differences and revealed dynamic cytoskeletal processes during ontogenesis. Distinct protein spots that may function as molecular markers for the corresponding developmental stages were mass spectrometrically identified. The amount of the Cu(2+)- Zn(2+) superoxide dismutase (CE23550) and an aspartyl proteinase (CE21681) was highest in the first larval stage (L1) and decreased during the ontogenesis from the first larval stage to the adult. Tropomyosin III (CE29059) was prominently present in the first and second larval stage (L1/L2). Abundances of actin 1 or 4 (CE12358 or CE13148) and tropomyosin I (CE28782) were particularly high in multiple spots in the third larval stage (L3). Interestingly, the amount of DIM-1 protein (CE27706), reflected by two spots, was the lowest in this stage. A particular splicing factor (CE31089) was detected only in the fourth larval stage (L4), whereas a spot with high abundance representing the cuticle collagen (CE02272) was only found highly expressed in adult animals (A). In addition, a Ca(2+)-binding protein (CE12368) and one protein spot which has not yet been identified, both reached their maximal spot intensities in the adult stage (A). Moreover, the ASP-1, CCT-5, GPD-1, GPD-2, HSP-6, HSP-16.2, IFB-2, LEC-2, LIN-53, LMN-1, MDH-1, NUD-1, RPA-0, RSP-12, SOD-1, TBB-1, TBB-2, TMY-1, UNC-60, and VIT-2 proteins for which mutants are available and two still unidentified protein spots which were present in all developmental stages, have been reproducibly localized in proteome maps of distinct ontogenesis states.

Thioredoxin motif of Caenorhabditis elegans PDI-3 provides Cys and His catalytic residues for transglutaminase activity.

Previous reports have suggested that protein disulfide isomerases (PDIs) have transglutaminase (TGase) activity. The structural basis of this reaction has not been revealed. We demonstrate here that Caenorhabditis elegans PDI-3 can function as a Ca(2+)-dependent TGase in assays based on modification of protein- and peptide-bound glutamine residues. By site-directed mutagenesis the second cysteine residue of the -CysGlyHisCys- motif in the thioredoxin domain of the enzyme protein was found to be the active site of the transamidation reaction and chemical modification of histidine in their motif blocked TGase activity.