Hyperosmotic stress and elevated pCO2 alter monoclonal antibody charge distribution and monosaccharide content

Medium osmolality increases with pCO2 at constant pH. Elevated pCO2 and osmolality inhibit hybridoma growth to similar extents in both serum-containing and serum-free media. The combination of osmolality and elevated pCO2 synergizes to negatively impact cell growth. IgG2a glycosylation by hybridoma cells was evaluated under elevated pCO2 (to 250 mmHg pCO2) and/or osmolality (to 476 mOsm/kg). IgG2a site occupancy did not change significantly under any of the conditions studied, which is consistent with the robust glycosylation of other antibodies produced under various environmental stresses. However, changes were observed in the IgG2a charge distribution. Changes in the isoelectric point (pI) were greater under hyperosmotic stress, increasing by 0.32 and 0.41 pH units at 435 mOsm/kg in serum-containing and serum-free medium, respectively. Hyperosmotic stress also resulted in a concomitant increase in the heterogeneity of the charge distribution. The mean pI in serum-containing medium decreased by 0.16 pH units at 250 mmHg pCO2 when osmolality was controlled at 320 mOsm/kg but increased by 0.20 pH units when the osmolality increased with pCO2 (195 mmHg pCO2-435 mOsm/kg). In serum-free medium, elevated pCO2 did not alter pI, regardless of medium osmolality. In contrast to elevated osmolality at control pCO2, elevated pCO2 did not significantly alter the IgG2a charge heterogeneity under any of the conditions studied. The IgG2a was not sialylated, so sialylation changes were not responsible for changes in the charge distribution. IgG2a galactose content decreased with elevated osmolality, as a result of either elevated NaHCO3 or NaCl. However, when osmolality was controlled at elevated pCO2, the galactose content tended to increase. The mannose content decreased with increasing stress, while the fucose content remained relatively unchanged. It is likely that the observed increases in the pI of murine IgG2a were due to increased organellar pH, which is reflected by increased specific beta-galactosidase activity in the supernatant.     

MMP-12 catalytic domain recognizes and cleaves at multiple sites in human skin collagen type I and type III

Collagens of either soft connective or mineralized tissues are subject to continuous remodeling and turnover. Undesired cleavage can be the result of an imbalance between proteases and their inhibitors. Owing to their superhelical structure, collagens are resistant to many proteases and matrix metalloproteinases (MMPs) are required to initiate further degradation by other enzymes. Several MMPs are known to degrade collagens, but the action of MMP-12 has not yet been studied in detail. In this work, the potential of MMP-12 in recognizing sites in human skin collagen types I and III has been investigated. The catalytic domain of MMP-12 binds to the triple helix and cleaves the typical sites -Gly₇₇₅-Leu₇₇₆- in α-2 type I collagen and -Gly₇₇₅-Ile₇₇₆- in α-1 type I and type III collagens and at multiple other sites in both collagen types. Moreover, it was observed that the region around these typical sites contains comparatively less prolines, of which some have been proven to be only partially hydroxylated. This is of relevance since partial hydroxylation in the vicinity of a potential scissile bond may have a local effect on the conformational thermodynamics with probable consequences on the collagenolysis process. Taken together, the results of the present work confirm that the catalytic domain of MMP-12 alone binds and degrades collagens I and III.     

Influence of Coenzyme Q_{10} on release of pro-inflammatory chemokines in the human monocytic cell line THP-1

Coenzyme Q_{10} (CoQ_{10}) is an obligatory element in the mitochondrial electron transport system and functions as a potent antioxidant of lipid membranes. In-vivo and in-vitro studies indicate an involvement of CoQ_{10} in inflammatory pathways. Here we studied in the human monocytic cell-line THP-1 the influence of CoQ_{10} on LPS-induced secretion of the pro-inflammatory chemokines Macrophage inflammatory protein-1 alpha (MIP-1alpha), Regulated upon activation, normal T cell expressed and secreted (RANTES) and Monocyte chemoattractant protein-1 (MCP-1). In comparison to unstimulated cells, LPS leads to 22-, 3- and 4.5-fold higher levels of MIP-1alpha, RANTES and MCP-1 in the cell culture medium, respectively. Pre-incubation of cells with 10 microM CoQ_{10} resulted in a significant decrease of LPS-induced MIP-1alpha and RANTES secretion to 55.04% (p = 0.02) and 76.84% (p = 0.04), respectively. In conclusion, CoQ_{10} reduces the LPS-induced secretion levels of the pro-inflammatory chemokines MIP-1alpha and RANTES in the human monocytic cell line THP-1. These data suggest that CoQ_{10} possesses anti-inflammatory properties.     

A new type of peroxisomal acyl-coenzyme A synthetase from Arabidopsis thaliana has the catalytic capacity to activate biosynthetic precursors of jasmonic acid

Arabidopsis thaliana contains a large number of genes that encode carboxylic acid-activating enzymes, including nine long-chain fatty acyl-CoA synthetases, four 4-coumarate:CoA ligases (4CL), and 25 4CL-like proteins of unknown biochemical function. Because of their high structural and sequence similarity with bona fide 4CLs and their highly hydrophobic putative substrate-binding pockets, the 4CL-like proteins At4g05160 and At5g63380 were selected for detailed analysis. Following heterologous expression, the purified proteins were subjected to a large scale screen to identify their preferred in vitro substrates. This study uncovered a significant activity of At4g05160 with medium-chain fatty acids, medium-chain fatty acids carrying a phenyl substitution, long-chain fatty acids, as well as the jasmonic acid precursors 12-oxo-phytodienoic acid and 3-oxo-2-(2'-pentenyl)-cyclopentane-1-hexanoic acid. The closest homolog of At4g05160, namely At5g63380, showed high activity with long-chain fatty acids and 12-oxo-phytodienoic acid, the latter representing the most efficiently converted substrate. By using fluorescent-tagged variants, we demonstrated that both 4CL-like proteins are targeted to leaf peroxisomes. Collectively, these data demonstrate that At4g05160 and At5g63380 have the capacity to contribute to jasmonic acid biosynthesis by initiating the beta-oxidative chain shortening of its precursors.     

Micronutrient special issue: Coenzyme Q(10) requirements for DNA damage prevention

Coenzyme Q(10) (CoQ(10)) is an essential component for electron transport in the mitochondrial respiratory chain and serves as cofactor in several biological processes. The reduced form of CoQ(10) (ubiquinol, Q(10)H(2)) is an effective antioxidant in biological membranes. During the last years, particular interest has been grown on molecular effects of CoQ(10) supplementation on mechanisms related to DNA damage prevention. This review describes recent advances in our understanding about the impact of CoQ(10) on genomic stability in cells, animals and humans. With regard to several in vitro and in vivo studies, CoQ(10) provides protective effects on several markers of oxidative DNA damage and genomic stability. In comparison to the number of studies reporting preventive effects of CoQ(10) on oxidative stress biomarkers, CoQ(10) intervention studies in humans with a direct focus on markers of DNA damage are limited. Thus, more well-designed studies in healthy and disease populations with long-term follow up results are needed to substantiate the reported beneficial effects of CoQ(10) on prevention of DNA damage.