Intracellular distribution of Tankyrases as detected by multicolor immunofluorescence techniques

Poly(ADP-ribose) polymerases are a family of enzymes that catalyze the conversion of NAD+ into ADP-ribose. Among them, Tankyrases have been found to bind to centrosome, mitotic spindle and microsome proteins, in the cytoplasm, and to telomeres in the nucleus, where they play a relevant role in telomere metabolism. However, their precise intracellular localization during interphase has not been so far fully elucidated. We investigated this aspect in situ by double immunofluorescence experiments using antibodies recognizing Tankyrases 1–2 or other proteins residing in specific organelles (Golgi apparatus, mitochondria, lysosomes, endoplasmic reticulum). We used HeLa cells as a model system in vitro, before and after treatment with either actinomycin D or etoposide, to also investigate the possible relocation of Tankyrases during apoptosis. We observed that Tankyrases are distributed both in the nucleus and in the cytoplasm; in this latter compartment, they were found to colocate with the Golgi apparatus but never with the mitochondria; a pool of Tankyrases also colocates with the endoplasmic reticulum and lysosomes. Interestingly, in cells with clear signs of apoptosis, Tankyrases were detectable in the cytoplasmic blebs: this suggests that they are not massively cleaved during apoptosis and persist in the largely heterogeneous apoptotic remnants which are known to contain components of cytoplasmic and nuclear origin

Fluorescence properties of the Na+/H+ exchanger inhibitor HMA (5-(N,N-hexamethylene) amiloride) are modulated by intracellular Ph

HMA (5-(N,N-hexamethylene)amiloride), which belongs to a family of novel amiloride derivatives, is one of the most effective inhibitors of Na+/H+ exchangers, while uneffective against Na+ channels and Na+/Ca2+ exchangers. In this study, we provided evidence that HMA can act as a fluorescent probe. In fact, human retinal ARPE19 cells incubated with HMA show an intense bluish fluorescence in the cytoplasm when observed at microscope under conventional UV-excitation conditions. Interestingly, a prolonged observation under continuous exposure to excitation lightdoes not induce great changes in cells incubated with HMA for times up to about 5 min, while an unexpected rapid increase in fluorescence signal is observed in cells incubated for longer times. The latter phenomenon is particularly evident in the perinuclear region and in discrete spots in the cytoplasm. Since HMA modulates intracellular acidity, the dependence of its fluorescence properties on medium pH and response upon irradiation have been investigated in solution, at pH 5.0 and pH 7.2. The changes in both spectral shape and amplitude emission indicate a marked pH influence on HMA fluorescence properties, making HMA exploitable as a self biomarker of pH alterations in cell studies, in the absence of perturbations induced by the administration of other exogenous dyes

Nuclear binding of cell cycle-related proteins: Cyclin A versus proliferating cell nuclear antigen (PCNA).

We have investigated the cell cycle-dependent nuclear binding of cyclin A and of the proliferating cell nuclear antigen (PCNA) in asynchronously growing human fibroblasts. To this purpose, we have applied flow cytometry immunofluorescence, a powerful technique for elucidating the cell cycle phase during which the nuclear binding occurs. We have observed that, in striking contrast with the distribution of nuclear-bound PCNA which is restricted to S phase, the immunofluorescence signal of the nuclear-bound form of cyclin A is high in the G1 and G2 phases of the cell cycle. These results suggest the involvement of nuclear-bound cyclin A in the G1/S and G2/M phase transitions

Dynamic relocation of nuclear proteins during the execution phase of apoptosis.

In the apoptotic program of controlled cell dismantling, the most characteristic nuclear changes involve chromatin, which condenses and often collapses against the nuclear envelope in the form of crescents. A severe reorganization also occurs in ribonucleoprotein (RNP)-containing structures which are involved in the synthesis and processing of transcripts: already during early apoptosis, the nucleoplasmic RNPs (namely, perichromatin fibrils, perichromatin granules, and interchromatin granules) coalesce in the interchromatin space where they associate with segregated nucleolar components, to ectopically form fibro-granular heterogeneous clusters. This was found to occur in cell systems in vivo and in cultured cell lines, after different apoptogenic stimuli. These RNP aggregates we have called heterogeneous ectopic RNP-derived structures (HERDS) move from the nucleus to the cytoplasm, and may be found in apoptotic bodies, in late apoptosis. Immunolabeling experiments demonstrated that several other proteins which are normally located inside the nucleus also move into the cytoplasm, during apoptosis, independently from HERDS. Apoptotic cells have been suggested to be a powerful source of nuclear auto-antigens, which are produced by the partial proteolytic or nucleolytic cleavage of a wide variety of nuclear substrates. In the presence of defective phagocytosis (or when massive apoptosis overwhelms the clearance capability of the tissue scavenger cells), the disposal of apoptotic cells becomes insufficient and unphagocytosed late apoptotic cells may accumulate in the tissue where they may be engulfed by antigen-presenting cells (such as dendritic cells); an autoimmune response may thus be elicited, by which apoptosis-derived auto-antigens are recognized and presented to the immune system

p21waf1/cip1 protein associates with the detergent-insoluble form of PCNA concomitantly with disassembly of PCNA at nucleotide excision repair sites.

Evidence is presented that after exposure of normal human fibroblasts to UV-C light, nuclear binding of the proliferating cell nuclear antigen (PCNA) required for nucleotide excision repair, was rapidly triggered in the G1 and G2 phases of the cell cycle. Association to repair sites of the detergent-insoluble form of PCNA reached a peak 15-30 min after irradiation, and then decreased to basal levels within 24-48 h. In contrast, the nuclear association of p21 protein showed a slower kinetics, reaching maximal levels between 24 and 48 h but, similarly to PCNA, occurring only in G1 and G2 phases. Although the two proteins are known to be associated as detergent-soluble proteins, it is unknown whether they associate also in the detergent-insoluble form. To address this question, the chromatin-bound form of PCNA was released by using DNAse I. DNA digestion resulted in the almost complete release of PCNA from its binding sites, while only about 60% of nuclear-bound p21 could be solubilized. Immunoprecipitation of PCNA and p21 released by enzymatic digestion showed that p21 was associated with PCNA bound to late DNA repair sites. These results indicate that during nucleotide excision repair, nuclear binding of PCNA precedes that of p21 protein, and suggest that temporal association of p21 with the detergent-insoluble fraction is coincident with the disassembly of PCNA from DNA repair sites