The Coxsackie and adenovirus receptor binds microtubules and plays a role in cell migration

The Coxsackie and adenovirus receptor (CAR), a cell adhesion molecule of the immunoglobulin superfamily, inhibits cell growth of a variety of tumors. The cytoplasmic domain of CAR has been implicated in decreased invasion and intracerebral growth of human U87 glioma cells. Using affinity binding, we identified tubulin as an interaction partner for the cytoplasmic domain of CAR. The interaction was specific; CAR and tubulin co-immunoprecipitated in cells expressing endogenous CAR and partially co-localized in situ. The binding of CAR to tubulin heterodimers and to microtubules was direct, with dissociation constants of approximately 1 mum for tubulin and approximately 32 nm for in vitro assembled microtubules. Whereas CAR-expressing U87 glioma cells had decreased migration in a chemotactic assay in Boyden chambers as compared with control cells, an effect that depended on the presence of the cytoplasmic domain of CAR, the difference was abrogated at low, non-cytotoxic doses of the taxane paclitaxel, a microtubule-stabilizing agent. These results indicate that CAR may affect cell migration through its interaction with microtubules.     

Means of optimizing light energy conversion in the primary stages of photosynthesis. II. Optimization of the structure of an uniform photosynthetic unit lattice

The possibility of optimization of the structure of a model photosynthetic unit lattice is analysed. The efficiency of the photosynthetic unit operation is evaluated from the time of excitation energy trapping by reaction centers. The calculations assume a F?rster inductive resonance mechanism for energy transfer within light--harvesting antenna and pairwise dipolar interactions. We use the probability matrix method which is adapted to excitation trapping time (but not to excitation jumps number) calculation. It is shown that the specific anisotropy of the distances between antenna molecules (which is in principle possible due to the diskshaped form of chlorophyll molecules) in combination with the optimal spatial arrangement of reaction centers as "well regulated clusters" allows to decrease the time of excitation energy trapping by over an order of magnitude. The requirements for optimization of the structure of a macroscopic photosynthetic unit lattice and the consequences following from them for the in vivo systems are formulated.     

Phagosome fusion vesicles of Paramecium. II. Freeze-fracture evidence for membrane replacement

Phagosome fusion vesicles (PFVs), a new population of relatively large granules in Paramecium caudatum which fuse with the first stage of digestive vacuoles (DV-I) shortly after these vacuoles are released from the cytopharynx (their site of formation), have been studied by using the freeze-fracture technique. Identification of PFVs is possible in the resulting replicas at all sites where they are commonly found in thin sections, at the cytopharynx, bound but not fused with nascent digestive vacuoles and fused with released vacuoles in the cell's posterior end. These PFVs have membranes which do not resemble the membranes of the forming digestive vacuole membrane or the discoidal vesicle membranes from which vacuole membrane is derived. Their smooth E-fracture face with only 50 to 100 intramembrane particles (IMPs) per micrometers 2 and particulate P-face (approximately 2500 IMPs/micrometers) do resemble the second vacuole stage (DV-II) which is characterized by a smaller diameter and acid pH. Evidence is presented for PFV fusion with the DV-I and for membrane replacement, at least in part, as the DV-I becomes a DV-II. Membrane replacement entails first adding PFVs to the DV-I and then removing the original discoidal vesicle-derived membrane as tubules as the vacuole condenses. Implications of the possible role of PFVs in forming intravacuolar symbiotic relationships are also discussed.     

Sulfation of a tyrosine residue in the plasmin-binding domain of alpha 2-antiplasmin

Sulfation of human alpha 2-antiplasmin, the major plasma inhibitor of fibrinolysis, was examined using both protein isolated from human plasma and protein synthesized and biosynthetically labeled with [35S]sulfate by a human hepatoma-derived cell line. Linkage of sulfate to tyrosine was demonstrated by recovery of labeled tyrosine sulfate after base hydrolysis of sulfate-labeled alpha 2-antiplasmin. Analysis by reverse-phase high performance liquid chromatography of peptides released from alpha 2-antiplasmin by cleavage with trypsin or cyanogen bromide indicated that sulfate is linked to a single segment of the protein. A cyanogen bromide peptide corresponding to the sulfate-labeled peptide was prepared from alpha 2-antiplasmin isolated from human plasma. Consistent with the presence of tyrosine sulfate in this peptide, its chromatographic elution was altered by treatment with acid under conditions which release sulfate from a tyrosine residue. No peptide in the total digest of alpha 2-antiplasmin by cyanogen bromide eluted at the position of the peptide following desulfation, suggesting that all of the protein is in a sulfated form. The sequence of the sulfate-containing cyanogen bromide peptide as determined by sequential Edman degradation, amino acid composition, and fast atom-bombardment-mass spectrometry was: Glu-Glu-Asp-Tyr(SO4)-Pro-Gln-Phe-Gly-Ser-Pro-Lys-COOH. This peptide is a segment of the previously identified plasmin-binding domain of alpha 2-antiplasmin.     

Aminopeptidase resistant Arg-Gly-Asp analogs are stable in plasma and inhibit platelet aggregation.

Tetrapeptides containing the sequence Arg-Gly-Asp (RGD) antagonize fibrinogen binding to its platelet receptor (gp IIb/IIIa, integrin alpha IIb beta 3) and inhibit platelet aggregation in vitro. The peptides RGDS and RGDY(Me)-NH2 were rapidly degraded when incubated in human, rat, and dog plasma. HPLC analysis indicated that amino acids were sequentially removed from the peptide N-terminus, and this degradation was prevented by the aminopeptidase inhibitor bestatin. Analogs of RGDY(Me)-NH2 with an acetylated or deleted alpha-amino group were prepared. Both analogs were stable when incubated in plasma, blocked 125I-fibrinogen binding to activated platelets (IC50 = 10-30 microM) and inhibited ADP induced platelet aggregation (IC50 = 10-30 microM). This study concludes that aminopeptidase rapidly degrades RGD peptides in plasma, an important issue for in vivo testing of RGD peptides and analogs. RGD analogs intrinsically stabilized against aminopeptidase are stable in plasma and are important tools for antithrombotic studies involving antagonism of gp IIb/IIIa.     

Axenic Paramecium caudatum. I. Mass culture and structure

To establish and grow Paramecium caudatum in mass axenic culture the culture medium of Soldo, Godoy & van Wagtendonk was modified by substituting phosphatidylethanolamine (PE) for TEM-4T and by a 10-fold increase in folic acid. Population densities of 4000 to 6000 cells/ml and a generation time of 20-26 h are regularly obtained. Optimal growth is obtained with PE-stigmasterol ratios between 40:1 to 400:1. Cells from 1-day-old axenic cultures have many lipid bodies aggregated in clumps (which disappear in 2 to 3 days) as well as foci of rough endoplasmic reticulum bordered by dictyosomes. The latter suggests a very active metabolism. Crystalline sheets found in both food vacuoles and lysosomes presumably play a role in digestion. Axenically grown cells also have abundant Golgi bodies (dictyosomes) and by late log phase become filled with lysosomes.     

An investigation of mitochondrial inner membranes by rapid-freeze deep- etch techniques

Physical fixation by rapid freezing followed by freeze-fracture and deep-etching has provided the means for potentially seeing the three-dimensional arrangement in the native state of particles on mitochondrial inner membranes. We have used these techniques to study the tubular cristae of Paramecium in the hope of determining the arrangement of F1 complexes, their abundance, and location in the membranes. We also sought information regarding other respiratory complexes in these membranes. Our results, supported by stereo pairs, show that F1 complexes are arranged as a double row of particles spaced at 12 nm along each row as a zipper following the full length of the outer curve of the helically shaped tubular cristae. There are an average of 1,500 highly ordered F1 complexes per micrometer squared of 50-nm tubular cristae surface. The F1 complexes definitely lie outside the membranes in their native state. Other particle subsets, also nonrandomly arrayed, were seen. One such population located along the inner helical curve consisted of large 13-nm-wide particles that were spaced at 30 nm center-to-center. Such particles, because of their large size and relative abundance when compared to F1 units, resemble complex I of the respiratory complexes. Any models attempting to understand the coupling of respiratory complexes with F0F1 ATPase in Paramecium must take into account a relatively high degree of order and potential immobility of at least some of these integral membrane complexes.     

Involvement of cystic fibrosis transmembrane conductance regulator in infection-induced edema

Abnormal fluid accumulation in tissues, including the life-threatening cerebral and pulmonary edema, is a severe consequence of bacteria infection. Chlamydia (C.) trachomatis is an obligate intracellular gram-negative human pathogen responsible for a spectrum of diseases, causing tissue fluid accumulation and edema in various organs. However, the underlying mechanism for tissue fluid secretion induced by C. trachomatis and most of other infectious pathogens is not known. Here, we report that in mice C. trachomatis infection models, the expression of cystic fibrosis transmembrane conductance regulator (CFTR), a cAMP activated chloride channel, is up regulated together with increased cytokine release and tissue fluid accumulation that can be reversed by treatment with antibiotic specific for C. trachomatis and CFTR channel blocker. However, C. trachomatis infection cannot induce tissue edema in CFTRtm1Unc mutant mice. Administration of exogenous IL-1beta to mice mimics the C. trachomatis infection-induced CFTR upregulation, enhanced CFTR channel activity and fluid accumulation, further confirming the involvement of CFTR in infection-induced tissue fluid secretion.     

Arginase activity in the frog urinary bladder epithelial cells and its involvement in regulation of nitric oxide production

The activity of arginase converting arginine into ornithine and urea is of particular interest among many factors regulating NO production in the cells. It is known that by competing with NO-synthase for common substrate, arginase can affect the NO synthesis. In the present work, the properties of arginase from the frog Rana temporaria L. urinary bladder epithelial cells possessing the NO-synthase activity were characterized, and possible contribution of arginase to regulation of NO production by epithelial cells was studied. It has been shown that the enzyme had the temperature optimum in the range of 55-60 degrees C, K(m) for arginine 23 mM, and V(max) about 10 nmol urea/mg protein/min, and its activity was effictively inhibited by (S)-(2-boronoethyl)-L-cysteine (BEC), an inhibitor of arginase, at concentrations from 10(-6) to 10(-4) M. The comparison of arginase activity in various frog tissues revealed the following pattern: liver > kidney > brain > urinary bladder (epithelium) > heart > testis. The arginase activity in the isolated urinary bladder epithelial cells was 3 times higher than that in the intact urinary bladder. To evaluate the role of arginase in the regulation of NO production, epithelial cells were cultivated in the media L-15 or 199 containing different amounts of arginine; the concentration of NO2-, the stable NO metabolite, was determined in the culture fluid after 18-20 h of cells incubation. The vast majority of the produced nitrites are associated with the NOS activity, as L-NAME, the NOS-inhibitor, decreased their accumulation by 77.1% in the L-15 medium and by 80% in 199 medium. BEC (10(-4) M) increased the nitrite production by 18.0 % +/- 2.7 in the L-15 medium and by 24.2 +/- 3.5 in the 199 medium (p < 0.05). The obtained data indicate a relatively high arginase activity in the frog urinary bladder epithelium and its involvement in regulation of NO production by epithelial cells.     

The vacuolar-atpase of Paramecium multimicronucleatum: gene structure of the B subunit and the dynamics of the V-ATPase-rich osmoregulatory membranes

Previous studies have shown that the vacuolar-ATPase (V-ATPase) of the contractile vacuole complexes (CVCs) in Paramecium multimicronucleatum is necessary for fluid segregation and osmoregulation. In the current study, immunofluorescence showed that the development of a new CVC begins with the formation of a new pore around which the collecting canals form. The decorated membranes are then deposited around the newly formed collecting canals. Quick-freeze deep-etch techniques reveal that six 10-nm-wide V-ATPase V, sectors, tightly packed into a 20 x 30-nm rectangle, form two rows of these compacted sectors that helically wrap around the cytosolic side of decorated membrane tubules. During new CVC formation, packing of decorated tubules around mature CVCs was temporarily disrupted so that some of these decorated tubules became transformed into decorated vesicles. Freeze-fracturing of these decorated vesicles revealed a highly pitted E-face and a particulate P-face. The V-ATPase was purified for the first time in any ciliated protozoan and shown to contain, as in other cells, the V1 subunits A to E, and four 14-20 kDa polypeptides. The B subunit was cloned and found to be encoded by one gene containing four short introns. This subunit has 510 amino acid residues with a predicted molecular weight of 56.8 kDa, a value similar to B subunits of other organisms. Except for the N- and C-termini, it has a 75% sequence identity with other B subunits, suggesting that the B subunits in Paramecium, like other species, have been conserved and that the entire surface of this subunit may be important in interacting with other subunits.