Paul J. Birckbichler

The role of transglutaminase in the rat subtotal nephrectomy model of renal fibrosis.

Tissue transglutaminase is a calcium-dependent enzyme that catalyzes the cross-linking of polypeptide chains, including those of extracellular matrix (ECM) proteins, through the formation of epsilon-(gamma-glutamyl) lysine bonds. This crosslinking leads to the formation of protein polymers that are highly resistant to degradation. As a consequence, the enzyme has been implicated in the deposition of ECM protein in fibrotic diseases such as pulmonary fibrosis and atherosclerosis. In this study, we have investigated the involvement of tissue transglutaminase in the development of kidney fibrosis in adult male Wistar rats submitted to subtotal nephrectomy (SNx). Groups of six rats were killed on days 7, 30, 90, and 120 after SNx. As previously described, these rats developed progressive glomerulosclerosis and tubulo-interstitial fibrosis. The tissue level of epsilon-(gamma-glutamyl) lysine cross-link (as determined by exhaustive proteolytic digestion followed by cation exchange chromatography) increased from 3.47+/- 0.94 (mean+/-SEM) in controls to 13.24+/-1.43 nmol/g protein 90 d after SNx, P </= 0.01. Levels of epsilon-(gamma-glutamyl) lysine cross-link correlated well with the renal fibrosis score throughout the 120 observation days (r = 0.78, P </= 0.01). Tissue homogenates showed no significant change in overall transglutaminase activity (14C putrescine incorporation assay) unless adjusted for the loss of viable tubule cells, when an increase from 5.77+/-0.35 to 13.93+/-4.21 U/mg DNA in cytosolic tissue transglutaminase activity was seen. This increase was supported by Western blot analysis, showing a parallel increase in renal tissue transglutaminase content. Immunohistochemistry demonstrated that this large increase in epsilon-(gamma-glutamyl) lysine cross-link and tissue transglutaminase took place predominantly in the cytoplasm of tubular cells, while immunofluorescence also showed low levels of the epsilon-(gamma-glutamyl) lysine cross-link in the extracellular renal interstitial space. The number of cells showing increases in tissue transglutaminase and its cross-link product, epsilon-(gamma-glutamyl) lysine appeared greater than those showing signs of typical apoptosis as determined by in situ end-labeling. This observed association between tissue transglutaminase, epsilon-(gamma-glutamyl) lysine cross-link, and renal tubulointerstitial scarring in rats submitted to SNx suggests that tissue transglutaminase may play an important role in the development of experimental renal fibrosis and the associated loss of tubule integrity.

Enhanced transglutaminase activity associated with macrophage activation: Possible role in Fc-mediated phagocytosis

Abstract Homogenate transglutaminase (TGase)-specific activity of guinea pig peritoneal macrophages was measured under a variety of conditions that stimulate or activate macrophages. Resident peritoneal macrophages had low levels of TGase as compared with oil-elicited inflammatory macrophages, which showed 30- to 100-fold greater enzyme activity. Immunofluorescent staining with specific antibody to purified enzyme showed a corresponding increase in staining intensity in subpopulations of inflammatory macrophages. Stimulation of macrophages with bacterial endotoxin, lymphokine, or Lotus tetragonolobus lectin resulted in increased TGase-specific activity. Cystamine, an inhibitor of the enzyme, reduced TGase activity, reduced lymphokine-mediated migration inhibition, and inhibited Fc-mediated phagocytosis. The substrate inhibitors, methylamine and dansylcadaverine, also inhibited Fc-dependent phagocytosis. These results suggest a possible role for TGase in macrophage activation and in receptor-dependent phagocytosis.

Cellular transglutaminase has affinity for extracellular matrix

SummaryCellular transglutaminase (TGase) was demonstrated as an intracellular enzyme by immunofluorescence in WI-38 cells. Following cell membrane perturbation by Triton X-100 treatment, TGase was bound to the extracellular matrix and was found to coexist with fibronectin as visualized by immunofluorescence microscopy. The binding of TGase to the cell matrix was blocked by anti-fibronectin antibody. Exogenous sources of soluble TGase were transferred to the extracellular matrix of an untreated or methanol fixed cell. The experimental data indicated that “particulate bound” TGase is a consequence of soluble TGase binding to the extracellular matrix following cell rupture.

Catalytic formation of ϵ-(γ-glutamyl)lysine in guinea pig liver transglutaminase

Abstract Incorporation of putrescine into purified guinea pig liver transglutaminase was observed when the enzyme was incubated under catalytic conditions in the absence of the exogenous acceptor substrate casein. Furthermore, in the absence of exogenous substrates, putrescine and casein, the enzyme monomer of 85–90,000 daltons was converted to polymeric material. ϵ(γ-Glutamyl)lysine isopeptide was isolated from polymeric transglutaminase samples following proteolytic digestion. The results were consistent with the formation of an intermolecular isopeptide, ϵ(γ-glutamyl)lysine, between two or more enzyme monomers apparently by an autocatalytic reaction.

ε-(γ-Glutamyl)lysine isopeptide bonds in normal and virus transformed human fibroblasts

Abstract Normal human lung cells (WI-38) possessed 20–40 times more e-(γ-glutamyl)lysine isopeptide bonds than Simian virus transformed counterparts, WI-38 VA13A and WI-38 VA13-2RA. Normal cells arrested in an essentially nonmitotic state had more isopeptide bonds than proliferating cells. Isopeptide content paralleled the transglutaminase activity of these cells. The results suggest that isopeptide crosslinks contribute to a cellular architecture conducive to a nonproliferating state.

Enhanced transglutaminase activity in transformed human lung fibroblast cells after exposure to sodium butyrate

The low level of transglutaminase activity in virus-transformed human embryonic lung fibroblasts (WI-38 VA13A) increased markedly when cells were exposed to sodium butyrate. The effect of sodium butyrate was time- and concentration-dependent and fully reversible. Transformed cells exposed for 5 days to 1 mM sodium butyrate had fewer cells, showed an 8-10 fold higher transglutaminase activity, and stained more abundantly for transglutaminase and pericellular fibronectin than control cells when examined by indirect immunofluorescence. Non-transformed cells (WI-38) showed only a 2-4-fold increase in transglutaminase activity when treated in a similar manner. Studies with metabolic inhibitors revealed the increase in activity was the result of synthesis of new protein. Kinetic studies showed the affinity of putrescine for the enzyme was essentially unchanged but the number of active sites increased 9-fold following exposure to sodium butyrate. Enhanced transglutaminase activity returned to control levels within 7 days after subculture and sodium butyrate removal. These findings suggest that sodium butyrate offers a potential model system to understand better the role of transglutaminase in cells in culture; particularly growth control in transformed cells.

Induction of cellular transglutaminase biosynthesis by sodium butyrate

Cellular transglutaminase activity was induced in simian virus-transformed human embryonic lung fibroblasts (WI-38 VA13A) by sodium butyrate. The level of enzyme activity approached a maximum by 6 days; 9-11-fold higher in the presence of sodium butyrate (1 mM) than in its absence. The observed increases in cellular transglutaminase activity could be entirely accounted for by equivalent increases in the levels of enzyme protein measured by inhibition enzyme-linked immunosorbent assay. Sodium butyrate also increased the rate of enzyme synthesis, but had no effect on the rate of cellular transglutaminase degradation. The increase in the rate of enzyme synthesis was matched by an increased level of translatable transglutaminase mRNA as measured in a cell-free translation system. Our results suggest that sodium butyrate regulates cellular transglutaminase at the pretranslational level.

Hierarchies in the binding of human factor XIII, factor XIIIa, and endothelial cell transglutaminase to human plasma fibrinogen, fibrin, and fibronectin.

The affinities of Factor XIII (FXIII), Factor XIIIa (FXIIla), and cellular transglutaminase (Tg) for fibrinogen (Fgn), fibrin (Fbn), and fibronectin (Fn) were compared using a solid-phase binding assay. Initial rates of binding were as follows: FXIII bound Fbn 3-fold more than Fgn. FXIII did not bind Fn till 20 min. Increasing the ligands concentrations and binding time, resulted in weak binding of FXIII to Fn. FXIIla bound Fbn 2-fold more than Fgn and 28-fold more than Fn. Tg bound Fn ∼ 130-fold more than either Fgn or Fbn. At equilibrium, the extent of binding was determined to be as follows: FXIII bound Fbn 3–15-fold more than Fgn and 8-fold more than Fn. FXIIIa bound Fgn and Fbn equally and 12–25-fold more than Fn. FXIIla bound Fgn or Fbn 2-fold and 25-fold greater than FXIII-Fbn and FXIII-Fgn interactions, respectively. Tg bound about equally to Fgn and Fbn and 10–20-fold less than Fn. The Kds′ for FXIIla binding to Fn, Fgn, and Fbn were 100, 23, and 19 nM, respectively. The Kdfor Tg binding to Fn was 6.5 nM. The binding hierarchies are: [Tg-Fn]>[FXIIIa-Fgn]=[FXIIIa-Fbn]>[FXIII-Fbn]>[FXIIIFgn]=[FXIIIa-Fn]>[Tg-Fbn]=[Tg-Fgn]>[FXIII-Fn]. Such hierarchies could regulate the cross-linkings by FXIIIa and Tg during hemostasis, wound healing, and cell adhesion.

Calmodulin Regulates Nucleotide Hydrolysis Activity of Tissue Transglutaminase

The interaction of calmodulin with purified guinea pig liver transglutaminase was studied. The nucleotide (ATP and GTP) hydrolysis activity of this tissue transglutaminase was transiently increased and then gradually decreased depending on calmodulin concentration. The peak activation was obtained in the presence of a stoichiometric amount of calmodulin. The effect of calmodulin on the classical transglutaminase activity was minimal. Fluorescence spectroscopy demonstrated that the enzyme produced a significant blue shift in the emission peak of dansylated calmodulin. Interestingly, Ca2+ was not required for the interaction between the two proteins. The results described here give an additional regulatory role to calmodulin

Direct estimation of protein of cloned cells in 96-well microtiter plates

A rapid and reproducible method for the direct determination of the amount of material in 96-well microtiter plates is reported. The spectrophotometric method is based on dye-binding followed by extraction with dilute acid. The absorbance is proportional to the amount of protein or the number of nuclei in the well.