Platelets store laminins 411/421 and 511/521 in compartments distinct from α- or dense granules and secrete these proteins via microvesicles.

BACKGROUND: Blood platelets secrete upon activation of laminins 411/421 and 511/521, large adhesive proteins mainly found in the basement membranes of blood vessels and other tissues. At present, the subcellular localization and secretion mechanisms of platelet laminins are largely unknown. OBJECTIVES: Our aim was to compare the subcellular localization of laminins 411/421 and 511/521 and specific granule markers in platelets. We also elucidated the role of microvesicles and exosomes in laminin release in platelet activation. METHODS: We studied laminin and granule marker protein localization in platelets by using immunofluorescence confocal microscopy and immunoelectron microscopy. Microvesicles and exosomes were separated from material released from platelets on activation by thrombin. The expression of laminins in microvesicles and exosomes was studied by using SDS-PAGE and Western blotting as well as by flow cytometric analysis. The exosomes were immunoprecipitated with magnetic microbeads coated with anti-CD63 antibodies. RESULTS AND CONCLUSIONS: We demonstrate that laminins 411/421 and 511/521 are present in compartments of platelets that do not express α-granule, dense granule, or lysosome marker proteins. Moreover, laminins secreted by activated platelets are mostly found in microvesicles shed from the plasma membrane, while their presence in simultaneously released exosomes is minimum.

Naturally occurring CD4+ CD25+ cells in modulating immune response to administered coagulation factor VIII in factor VIII-deficient mice.

CD4+ CD25+ T regulatory (Treg) cells are critical mediators of peripheral self-tolerance and immune homeostasis. In this study, we characterized the ability of naturally occurring CD4+ CD25+ cells from the wild-type mice to modulate the immune response to administered coagulation factor VIII (FVIII) in FVIII-deficient mice. For the cell therapy, CD4+ CD25+ cells and CD4+ CD25- cells were purified from the spleens of wild-type normal mice and administered to FVIII-deficient mice prior to four injections of recombinant FVIII (rFVIII). The titre of FVIII antibodies and antibodies with inhibitory activity against FVIII was lower in the mice treated with natural CD4+ CD25+ cells or CD4+ CD25- cells compared with the mice treated only with rFVIII. We also demonstrated that CD4+ CD25- cells could differentiate to acquire the Treg phenotype expressing CD25 and FoxP3 if stimulated in vitro. These observations provide evidence that Treg cells can be used for designing cell therapy for controlling the immune response to FVIII.

Activation of p53 by nutlin leads to rapid differentiation of human embryonic stem cells.

p53 Is an important regulator of normal cell response to stress and frequently mutated in human tumours. Here, we studied the effects of activation of p53 and its target gene p21 in human embryonic stem cells. We show that activation of p53 with small-molecule activator nutlin leads to rapid differentiation of stem cells evidenced by changes in cell morphology and adhesion, expression of cell-specific markers for primitive endoderm and trophectoderm lineages and loss of pluripotency markers. p21 is quickly and dose-dependently activated by nutlin. It can also be activated independently from p53 by sodium butyrate, which leads to the differentiation events very similar to the ones induced by p53. During differentiation, the activating phosphorylation site of CDK2 Thr-160 becomes dephosphorylated and cyclins A and E become degraded. The target for CDK2 kinase in p53 molecule, Ser-315, also becomes dephosphorylated. We conclude that the main mechanism responsible for differentiation of human stem cells by p53 is abolition of S-phase entry and subsequent stop of cell cycle in G0/G1 phase accompanied by p21 activation.

CD43 promotes cell growth and helps to evade FAS-mediated apoptosis in non-hematopoietic cancer cells lacking the tumor suppressors p53 or ARF.

CD43 is a highly glycosylated transmembrane protein expressed on the surface of most hematopoietic cells. Expression of CD43 has also been demonstrated in many human tumor tissues, including colon adenomas and carcinomas, but not in normal colon epithelium. The potential contribution of CD43 to tumor development is still not understood. Here, we show that overexpression of CD43 increases cell growth and colony formation in mouse and human cells lacking expression of either p53 or ARF (alternative reading frame) tumor-suppressor proteins. In addition, CD43 overexpression also lowers the detection of the FAS death receptor on the cell surface of human cancer cells, and thereby helps to evade FAS-mediated apoptosis. However, when both p53 and ARF proteins are present, CD43 overexpression activates p53 and suppresses colony formation due to induction of apoptosis. These observations suggest CD43 as a potential contributor to tumor development and the functional ARF-p53 pathway is required for the elimination of cells with aberrant CD43 expression.

In situ hybridisation of chick embryos with p53-specific probe and their immunostaining with anti-p53 antibodies.

Tumor-suppressor protein p53 is an important regulator of cell cycle and apoptosis. On the level of embryo extracts it has been shown earlier that both p53 protein and mRNA are expressed in developing chicken. Here we describe the expression patterns of p53 mRNA and protein in developing chicken embryos (stages 2-12) using in situ hybridisation and immunostaining with p53-specific monoclonal antibody Mab421. p53 mRNA is equally localised all over the embryo in the stages observed. According to electron microscopy data a subfraction of p53 mRNA is bound to dissolving yolk granules expressing acid phosphatase activity characteristic for lysosomes. Protein p53 is synthesised starting from the medium primitive streak stage (stage 3) and reaches its maximum level at the full primitive streak stage. During these stages protein p53 is distributed evenly across the embryos. After gastrulation p53 protein remains visible at higher levels only in certain anlages and areas. In developing nervous system the expression is observable in neuroectoderm, during the closure of the neural tube and in mesenchyme in the area of migrating neural crest cells. In cardiogenesis protein p53 is expressed during formation of tubular heart in the epimyocardium, endocardium and cardiac jelly. p53 protein localises in the neurocoele (obviously connected with cellular debris) and cardiac jelly. Our data support the role of p53 in early development, especially during embryo gastrulation, the development of central nervous system, neural crest and heart. In some cases increased p53 amounts colocalise with the areas of intensive epithelium-mesenchyme transition.

p53 protein accumulation in addition to the transactivation activity is required for p53-dependent cell cycle arrest after treatment of cells with camptothecin.

In this study we characterize the connections between p53-dependent G1 cell cycle arrest, transcriptional activation of the protein and the increase of its intracellular steady-state concentration. Several cell lines expressing wild-type p53 protein were treated with increasing concentrations of DNA-damaging drug camptothecin. Lower doses of the drug caused transcriptional activation of p53, but no accumulation of the protein was detected. Only after a certain threshold dose of camptothecin does the amount of the protein rapidly increase and reach its plateau levels. The threshold dose was different for different cell lines, but the general non-linear profile was similar. Increase of p53 level was accompanied by additional transcriptional activation of some p53 target genes (i.e. waf1), but not the others (mdm2). We demonstrate here that transcriptional activation of p53 after the treatment of camptothecin is not sufficient to cause p53-dependent G1 cell cycle arrest. The latter is observable only after the increase of steady-state level of p53. Low drug concentrations, although accompanied by transcriptional activation of p53, do not cause either p53 protein accumulation nor cell cycle arrest at G1. We propose a model for p53 acting as a part of cellular sensor system detecting the severity of DNA damage.

Tumour associated mutants of p53 can inhibit transcriptional activity of p53 without heterooligomerization.

Tumour suppressor protein p53 is the most frequent target of mutations occurring in different types of human cancers. Most of these are point mutations clustered in certain 'hot spots'. Because p53 is a tetramer in solution, it can form heterooligomers when both wild-type and mutant forms of p53 are expressed in the same cell. Inactivation of wt p53 by heterooligomerization has been proposed as a mechanism for dominant negative effect of mutant protein. In this paper we show that other mechanisms can also be involved in the inhibition of transcriptional activity of wt p53 by mutant proteins. In addition to suppressing the wt p53 activity, mutant proteins are also able to suppress the activity of p53 protein unable to oligomerize. Either N- or C-terminus of mutant p53 are needed for this activity. The suppression of transcriptional activity described is restricted to p53-dependent promoters and no effect is seen with the promoter not containing p53 binding site. Point mutants also inhibit the growth suppressing activity of monomeric p53. Our data allow to propose the existence of a cofactor specifically needed for p53-dependent transcription. Depletion of this cofactor could be an alternative mechanism of inactivation of wt p53 by its point mutants.

p53 protein is a suppressor of papillomavirus DNA amplificational replication.

p53 protein was able to block human and bovine papillomavirus DNA amplificational replication while not interfering with Epstein-Barr virus oriP once-per-cell cycle replication. Oligomerization, intact DNA-binding, replication protein A-binding, and proline-rich domains of the p53 protein were essential for efficient inhibition, while the N-terminal transcriptional activation and C-terminal regulatory domains were dispensable for the suppressor activity of the p53 protein. The inhibition of replication was caused neither by the downregulation of expression of the E1 and E2 proteins nor by cell cycle block or apoptosis. Our data suggest that the intrinsic activity of p53 to suppress amplificational replication of the papillomavirus origin may have an important role in the virus life cycle and in virus-cell interactions.

Oligomerization of p53 is necessary to inhibit its transcriptional transactivation property at high protein concentration.

We have previously shown that transactivation by tumor suppressor protein p53 can be inhibited in vivo at elevated protein concentrations. In this study we characterize the structural requirements of this function. We show that oligomerization domain of p53 is involved in loss of transactivation at high protein concentrations: mutants not able to oligomerize are neither able to suppress transactivation, although these transactivating properties can be untouched.

Protein p53 modulates transcription from a promoter containing its binding site in a concentration-dependent manner.

Tumor suppressor protein p53 binds to DNA in a sequence-specific manner and activates transcription from promoters near its binding site. It is also known to repress promoters lacking the p53-binding site. In this study, we demonstrate that p53 can act as a transcriptional activator or repressor in vivo using the same reporter with the DNA-binding site CON and these effects depend on the amount of p53 expressed. Both in Saos2 and Cos7 cells, lower concentrations of p53 lead to activation and higher concentrations lead to repression of the model promoter containing the consensus p53-binding site CON. The N-terminal part of p53 is necessary for the transcriptional activation. It is not needed, however, for the repression of the same promoter, indicating that different domains of p53 are involved in activation and repression.

A human tumour-derived mutant p53 protein induces a p34cdc2 reversible growth arrest in fission yeast.

We have expressed wild-type and human tumour-derived mutant p53 cDNA genes in the fission yeast Schizosaccharomyces pombe. In the case of one mutant this resulted in a growth arrest of recipient yeast cells. In contrast, wild-type p53 and three other mutant proteins tested did not block outgrowth of colonies. Human and yeast cdc2 acted as functionally equivalent extragenic suppressors of the mutant-induced growth arrest allowing the establishment of viable p53 expressor strains. In cotransformation assays the mutant allele was found to be dominant over wt p53. Our results provide the first evidence of a functional relationship between p53 and p34cdc2 in an in-vivo system and suggest that the wide variety of mutant proteins present in human tumours may fall into functionally distinct subclasses.

Strategies for Working with Families: Guiding families through stressfull events.

Family physicians are in contact with families as they pass through various stages and become aware of marital and family problems. By offering guidance and patient education before problems arise, physicians can avoid trouble and encourage healthy marital and parenting patterns. This article presents the Family Life Cycle framework and discusses the stresses that occur at marriage and at the birth of the first child. Helpful tools can be shared with patients.

p53 interacts with p34cdc2 in mammalian cells: implications for cell cycle control and oncogenesis.

The p53 gene product has been implicated in both human and animal tumorigenesis. p53 complexes with the transforming proteins encoded by several different DNA tumour viruses. We demonstrate that human p53 is phosphorylated by the mammalian p34cdc2 kinase in vitro and coprecipitates with p34cdc2 in vivo. Our observations suggest that phosphorylation of p53 by p34cdc2 kinase may regulate the known activities of p53 in the initiation steps of DNA replication in mammalian cells.

Mouse p53 blocks SV40 DNA replication in vitro and downregulates T antigen DNA helicase activity.

Immunopurified mouse p53 proteins were used to gain experimental access to the mechanisms underlying nonprimate p53 directed suppression of SV40 origin directed DNA replication in vivo. In replication competent HeLa cell extracts containing exogenous T antigen, mouse p53 blocks T antigen dependent DNA synthesis as in vivo. However, in transcription competent HeLa extracts, mouse p53 has no effect either on overall transcription or on the ability of immunopurified T antigen to downregulate SV40 early transcription. We show that although mouse p53 has no significant effect on T antigen encoded activities such as ATPase and DNA binding, helicase activity is somewhat reduced suggesting that the in vivo suppression by mouse p53 of SV40 replication may be due, at least in part, to direct modulation of T antigen function.

The properties of the complex between ribosomal protein L2 and tRNA.

Escherichia coli ribosomal protein L2 interacts with fMet-tRNAfMet and NacPhe-tRNAPhe in solution, protecting their 3'-ends from enzymatic degradation. At the same time L2 enhances the rate of spontaneous hydrolysis of the ester bonds between terminal riboses and amino acyl moieties of these two peptidyl-tRNA analogues. L2 has, however, only a slight effect on the rate of spontaneous deacylation of aminoacyl-tRNAs. We suggest that the role of L2 is in the fixation of the aminoacyl stem of tRNA to the ribosome at its P-site, and speculate that this protein is directly involved in the peptidyl transferase (PT) reaction.

[Stimulation of peptidyltransferase activity of 50S subunits by alcohols]. / Stimuliatsiia peptidiltransferaznoi aktivnosti 50S subchastitsy spirtami.

We have demonstrated that in certain conditions 50S subunits can transfer peptide moiety from peptidyl-tRNA to puromycin in the absence of alcohol. Monovalent cations NH4+ and K+ support this reaction, while Na+ and Li+ are ineffective. Optimal concentration for NH4+ is 1.8 M. Mg2+ ion concentrations above 12 mM are needed as well as an elevated temperature (30 degrees C). Using the alcohol-free puromycin reaction of 50S subunits we show that alcohol activates the peptidyl transferase center, but does not participate in the puromycin reaction. Neither does it change the protein composition of subunits.

[Protein L16 of the Escherichia coli ribosome: possible role in protein biosynthesis]. / Belok L16 ribosomy Escherichia coli: vozmozhnaia rol' v biosinteze belka.

We show that Escherichia coli 50S ribosomal subunits depleted of protein L16 can nevertheless catalyze the transfer of the peptide moiety from fMet-tRNA to puromycin, being, however, unable to use a fragment CACCA-Phe as an acceptor substrate. On the other hand, we found that protein L16 as well as its large fragment (amino acids 10-136) both interact with tRNA in solution (Kd approximately 10(-7) M). Moreover, L16 interacts with CACCA-Phe in solution as well as protects 3' end of tRNA from the enzymatic degradation. We suggest that L16, although not being the peptidyl transferase as such, is involved in the binding of the 3' end cytidines of tRNA into the ribosomal A site.