Francesco Autuori

Apoptotic hepatocytes become insoluble in detergents and chaotropic agents as a result of transglutaminase action.

Physiological deletion of cells ensues programmed death which involves formation of apoptotic bodies with fragmented DNA. Here we report that apoptotic hepatocytes are insoluble in detergents, urea, guanidine hydrochloride, reducing agents and thereby can be isolated from rat liver following collagenase treatment. They are wrinkled, spherical structures similar to cornified envelopes of epidermis by phase‐contrast microscopy and show irregular, globular morphology by scanning‐electron microscopy. Part of their DNA content is cleaved into nueleosomal and oligonucleosomal fragments. Their insolubility, like that of the cornified envelope, is evoked by ε‐(γ‐glutamyl)lysine and N 1,N 8‐bis(γ‐glutamyl)spermidine protein cross‐linking bonds formed by transglutaminase.

The clearance of apoptotic cells in the liver is mediated by the asialoglycoprotein receptor

Apoptosing cells are actively phagocytosed in parenchymal tissues, thus preventing the inflammatory reaction which could derive from their slow uncontrolled degradation. The molecular mechanisms by which an apoptotic cell is recognized and taken up are largely unknown. We propose that the recognition of apoptotic hepatocytes is mediated by the sugar recognition systems of the liver, particularly the asialoglycoprotein receptor (ASGP‐R). The results presented here demonstrate the participation of ASGP‐R in the removal of apoptotic parenchymal cells, and indicate a new perspective for the understanding of its physiological role.

Tissue transglutaminase is specifically expressed in neonatal rat liver cells undergoing apoptosis upon epidermal growth factor-stimulation.

SummaryWe recently reported that activation of “tissue” transglutaminase (EC 2.3.2.13; tTG) in liver cells undergoing apoptosis determines extensive cross-linking of cellular proteins resulting in the formation of SDS-insoluble shells in the so-called “apoptotic bodies”. In attempt to obtain further insight into the role played by tTG in apoptosis of liver cells, we investigated its expression in primary cultures of neonatal rat liver cells stimulated with epidermal growth factor (EGF). EGF-treatment of neonatal rat liver cells induces first hyperplasia of hepatocytes, followed by involution characterized by a high incidence of apoptosis. The proliferative phase of hepatocytes is paralleled by a 10-fold increase in tTG mRNA level, which is followed, during the phase of involution, by sequential increases in enzyme activity and levels of SDS-insoluble apoptotic bodies. tTG immunostaining at both the light- and electron-microscopic levels shows that the most intensive reaction is present in globular structures showing the typical morphological appearance of mature apoptotic bodies. In early apoptotic stages, tTG protein is localized in the perinuclear region of the cell. Intense immunostaining is also found in the apoptotic bodies present inside phagosomes within the cytoplasm of neighboring cells. This evidence confirms and extends our previous findings, indicating that tTG induction and activation specifically takes place in cells undergoing apoptosis, suggesting a key role for the enzyme in the apoptotic program.

Presence of di- and polyamines covalently bound to protein in rat liver.

Acid hydrolysis of trichloroacetic acid precipitate from rat tissue (liver, kidney and testis) homogenate released significant amounts of acid-insoluble putrescine, spermidine and spermine. Following incubation of liver homogenate with [1,4-14C]putrescine, 1.4% of total radioactivity and 1.0% of labelled diamine were recovered in the acid-insoluble fraction. Exhaustive digestion of acid-precipitable material with proteinases (Pronase, aminopeptidase M, carboxypeptidase A, B and Y) revealed the presence of di- and polyamines and of N1-(gamma-glutamyl)spermidine, N1-(gamma-glutamyl)spermine and N1,N12-bis(gamma-glutamyl)spermine. These derivatives were identified both by chromatographic analysis and by enzymatic digestion with purified gamma-glutamylamine cyclotransferase. The finding of di- and polyamine gamma-glutamyl derivatives in the proteinase-digested acid-insoluble fraction of homogenate may be considered as a proof of the in vivo transglutaminase-catalyzed binding of polyamines to proteins. This evidence suggests that di- and polyamines might have an important role in mammalian tissues through covalent binding to proteins by either one or both the primary amino groups.

Degradation of cells dying by apoptosis leads to accumulation of ε(γ‐glutamyl)lysine isodipeptide in culture fluid and blood

ε(γ‐Glutamyl)lysine isodipeptide, the end‐product of proteolytic digestion of proteins cross‐linked by transglutaminase, was detected in culture fluid of neonatal rat hepatocytes and plasma of adult rats. The concentration of the isodipeptide was significantly increased in both when high rate of apoptosis with phagocytosis of dying hepatocytes was produced either by epidermal growth factor in the culture or by lead nitrate‐induced hyperplasia with subsequent involution in rats. Specific induction of tissue transglutaminase and the consequent formation of highly cross‐linked protein envelopes in apoptotic cells have been previously demonstrated by us in both systems.

Covalent incorporation of polyamines as γ-glutamyl derivatives into CHO cell protein

Abstract The possible role of polyamines in the covalent modification of proteins in CHO cells was investigated by metabolic labeling with [ 3 H]putrescine. A single radiolabeled protein band with an apparent relative molecular mass of 18 000 Da was observed by SDS-polyacrylamide gel electrophoresis. Almost all the radioactivity covalently linked to this protein was recovered as hypusine. The labeling of this protein was increased several-fold when cells were cultured with α-difluoromethylornithine (DFMO) or with this drug plus methylglyoxal bis(guanylhydrazone) (MGBG), as a result of increase in specific radioactivity of the hypusine immediate precursor, spermidine. Also labeled under the latter condition were other cellular proteins. These were aggregates on the top both of the stacking gel and of the running gel, and protein-like materials with relative molecular masses of 36 and 8 kDa. The radioactivity covalently associated with these proteins was recovered after acid hydrolofsis as polyamines. The identification of γ-glutamylputrescine and γ-glutamylspermidines in proteolytic digests of the acid-insoluble fraction of treated cells indicates that polyamines are covalently linked to these cellular protein. Several possible cellular functions of γ-glutamylpolyamine protein components are discussed.

Cycloheximide can rescue heat-shocked L cells from death by blocking stress-induced apoptosis☆

Cultured mouse L cells undergo apoptosis upon 1 h heat shock at 43 and 45 degrees C. Morphologically characteristic apoptotic cells begin to appear soon after the shock. Immunohistochemistry with anti-transglutaminase antibody shows that in most treated cells the enzyme is induced. Its activation results in the formation of highly cross-linked detergent-resistant apoptotic bodies during recovery. Cycloheximide added during hyperthermic stress inhibits the appearance of apoptotic bodies, showing that heat-shock-induced apoptosis is dependent on protein neosynthesis. The analysis of colony-forming ability of heat-shocked L cells shows a survival of 5% at 43 degrees C and less than 0.02% at 45 degrees C. When protein synthesis is inhibited during heat shock the fraction of surviving cells increases to 23% at 43 degrees C and 0.9% at 45 degrees C. This suggest that part of the cells that die upon heat shock are not heavily damaged and would have survived in the presence of a block in protein synthesis.

Induction of apoptosis in thymocytes by prostaglandin E2 in vivo.

In vivo administration in mice of a synthetic analog of prostaglandin E2 (PGE2) caused a selective and dramatic decrease of CD4+CD8+ double-positive, CD3/T-cell-receptor-αb10 cells in the thymus. This loss was corticosteroid-independent and not affected by Cyclosporin A. The disappearance of CD4+CD8+ thymocytes was strictly correlated with the induction of apoptosis inside the thymus as shown by morphological studies and by the induction of intracellular transglutaminase expression. Considering that PGE2 has been found to be produced by different cell populations inside the thymus, these results indicate that PGE2 may act as endogenous signals for apoptosis during T-cell differentiation.

'Tissue' transglutaminase release from apoptotic cells into extracellular matrix during human liver fibrogenesis

Enhanced apoptosis characterizes several pathologies affecting human liver. This study sought to determine whether apoptosis is involved in the formation of fibrotic lesions occurring in hepatic disease. The expression of Bcl‐2 was analysed, and of ‘tissue’ transglutaminase (tTG), a cross‐linking enzyme which recent evidence suggests plays a role in the formation of fibrotic lesions in experimental settings. Regardless of the degree of liver injury, tTG abnormally accumulated in the liver cells adjacent to fibrotic tissue. Many cells showing DNA fragmentation and morphological features of apoptosis were also observed near fibrotic lesions. Bcl‐2 was detected predominantly in infiltrating lymphocytes within the liver tissue. Marked staining for both tTG protein and chromatin was also observed in the acellular fibrotic tissue, which suggested an active release of intracellular macromolecules from the dying cells into the extracellular matrix. This study indicates that fibrogenesis in the liver is associated with the release of tTG from dying cells. By cross‐linking extracellular matrix proteins, this enzyme might play a role in the formation of fibrotic lesions. Copyright

Intracellular localization of superoxide dismutase and its relation to the distribution and mechanism of hydrogen peroxide-producing enzymes

Abstract Superoxide dismutase has been localized exclusively in the soluble fraction of rat liver homogenates. In view of this result, the generation of O2 - by different H2O2-producing enzymes has been examined. It appeared that O2 - is generated only by xanthine oxidase, which is localized in the same compartment as the dismutase. Other enzymes, which are localized in other subcellular fractions, do not produce O2-, but H2O2 directly.