Actin-severing activity copurifies with phosphofructokinase

Microinjection of muscle 6-phosphofructokinase (PFK; EC 2.7.1.11) into tissue culture cells led to a reversible disintegration of microfilament bundles (stress fibers). The mode of disruption as well as of recovery of stress fibers was very similar to that found previously in experiments performed with the actin-severing protein brevin, an extracellular variant of gelsolin. PFK, like brevin, was also capable of disrupting stress fibers in detergent-extracted cells and in ethanol-fixed cells, in a Ca2+-dependent manner. When compared with heart muscle gelsolin, PFK comigrated with the 85- to 90-kDa band. Antibodies against PFK crossreacted with gelsolin from the same species. These results point to a tight association between polypeptides with similar biochemical and immunological parameters present in both preparations. They suggest hitherto unexpected cellular control mechanisms for both microfilament functions and glycolysis.

Ultrastructural colocalization of tyrosinated and detyrosinated alpha-tubulin in interphase and mitotic cells

Immunofluorescence with specific peptide antibodies has previously established that tyrosinated (Tyr) and detyrosinated (Glu) tubulin, the two species generated by posttranslational modification of the COOH-terminus of alpha-tubulin, are present in distinct, but overlapping, subsets of microtubules in cultured cells (Gundersen, G. G., M. H. Kalnoski, and J. C. Bulinski, 1984, Cell, 38:779-789). Similar results were observed by light microscopic immunogold staining in the two cell types used in this study, CV1 and PtK2 cells: most microtubules were stained with the Tyr antibody, whereas only a few were stained with the Glu antibody. We have examined immunogold-stained preparations by electron microscopy to extend these results. In general, electron microscopic localization confirmed results obtained at the light microscopic level: the majority of the microtubules in CV1 and PtK2 cells were nearly continuously labeled with the Tyr antibody, whereas only a few were heavily labeled with the Glu antibody. However, in contrast to the light microscopic staining, we found that all microtubules of interphase and mitotic CV1 and PtK2 cells contained detectable Tyr and Glu immunoreactivity at the electron microscopic level. No specific localization of either species was observed in microtubules near particular organelles (e.g., mitochondria or intermediate filaments). Quantification of the relative levels of Glu and Tyr immunoreactivity in individual interphase and metaphase microtubules showed that all classes of spindle microtubules (i.e., kinetochore, polar, and astral) contained nearly the same level of Glu immunoreactivity; this level of Glu immunoreactivity was lower than that found in all interphase microtubules. Most interphase microtubules had low levels of Glu immunoreactivity, whereas a few had relatively high levels; the latter corresponded to morphologically sinuous microtubules. Quantification of the relative levels of Tyr and Glu immunoreactivity in segments along individual microtubules suggested that the level of Tyr (or Glu) tubulin in a given microtubule was uniform along its length. Understanding how microtubules with different levels of Tyr and Glu tubulin arise will be important for understanding the role of tyrosination/detyrosination in microtubule function. Additionally, the coexistence of microtubules with different levels of the two species may have important implications for microtubule dynamics in vivo.

A monoclonal antibody specific for snRNPs U1 and U2

A monoclonal antibody (D-5) is described which selectively precipitates snRNPs U1 and U2. The antibody was derived from a mouse immunized with extracts from chick embryonic nuclei. By immunoblotting on either total proteins from purified snRNPs U1-U6, U2-U6 or U1 only, we could demonstrate that the monoclonal antibody cross-reacts with the U1 RNP specific polypeptide A and the U2 RNP specific polypeptide B", thereby establishing that the two snRNP proteins share at least one epitope. D-5 precipitates snRNPs U1 and U2 from a variety of species, including man, chicken, mouse, rat kangaroo and Xenopus laevis. It will thus be a useful tool for studying structure function relationships of the two snRNP species in different cell systems.

Decoration of microtubules by fluorescently labeled microtubule-associated protein 2 (MAP2) does not interfere with their spatial organization and progress through mitosis in living fibroblasts

Microtubule-associated protein 2 (MAP2) derivatized with iodoacetamidotetramethylrhodamine or with iodoacetamidofluorescein binds to microtubules after injection into living interphase cells [Scherson et al, 1984]. The binding of derivatized MAP2 stabilized microtubules in vitro; it was therefore important to check if the binding of MAP2 in vivo perturbed the dynamics and organization of the microtubule network. We have addressed these questions by studying the effect of the injection of derivatized MAP2 on mitosis in PtK 1 cells and on the recovery of the microtubule network from low temperature incubation in interphase cells. We found that the presence of derivatized MAP2 did not change the duration of any mitotic stage and that the injected cell normally completed mitosis. We subsequently showed that the injected MAP2 bound to the microtubules within 5 minutes after injection and remained bound throughout the course of mitosis. The reorganization of the microtubule network upon cooling and rewarming was studied in the cytoplasm of human foreskin fibroblasts (356 cells). During the recovery, the distribution of the fluorescent MAP2 in living cells was identical with the microtubule pattern visualized by immunofluorescence in lysed and fixed cells. In these experiments, the fluorescent MAP2 bound to microtubules can be considered as a nonperturbing reporter of the microtubule network. This result is discussed in terms of the role of MAPs in the dynamics and organization of microtubules in living cells.

Calcium-modulated contractile proteins associated with the eucaryotic centrosome

Affinity-purified antibodies that recognize the 20,000-dalton molecular weight (20 kd) striated flagellar root protein of Tetraselmis striata have been used to identify antigenic homologs in other eucaryotic organisms of diverse evolutionary origins. Among the green algae, Tetraselmis and Chlamydomonas, and their colorless relative, Polytomella, the 20-kd homologs appear associated with basal bodies. This occurs most prominently in the form of flagellar roots of both striated and microtubule subtended types. Among cultured mammalian cells (PtK2 and primary mouse macrophage cell lines), flagellar root protein homologs appear as basal feet, pericentriolar fibrils, and pericentriolar satellites. Mammalian sperm cells also show flagellar root protein homologs associated with their basal bodies. We envisage a functional role for these fibrous calcium-sensitive contractile proteins in altering the orientation of centrioles or basal bodies with their associated MTOCs by responding to topological calcium fluxes.

Preservation of chromosome integrity during micronucleation induced by colchicine in PtK1 cells

Colchicine induces the formation of small nuclei called micronuclei which contain limited parts of the genome. Some of them exhibit a DNA content equivalent to that of a single chromosome. Our purpose was to study the preservation of chromosome integrity during this micronucleation in PtK1 cells. Observation of karyotypes obtained after 3 days of cell cycle restoration revealed that micronucleation did not affect chromosome integrity or the presence of each chromosome pair in the surviving cells. In 'early restoration' cells, all the chromosomes included a centromere and were represented in the karyotype, but at variable rates. Furthermore, flow cytometry analysis of micronucleated cells, intermediate in DNA rate between control PtK1 cells in G1 and those in G2/M phases, led us to consider the possibility of selective replication of some chromosomes during micronucleation. Using antibodies against the kinetochore proteins, we derived the presence of one centromeric region (1-2 spots) in the smallest micronuclei. Therefore, these data (karyotypes, number of chromosomes, DNA content and kinetochore proteins) seem to indicate that micronucleation does not induce chromosome damages or translocations. Micronuclei are a convenient tool for investigation of the role of the different chromosomes in the organization of the interphase nuclei.

Microtubule distribution in cultured cells and intact tissues: improved immunolabeling resolution through the use of reversible embedment cytochemistry

To investigate the detailed distributions of microtubules in cultured cells and intact tissues we developed a reversible embedment method for antibody labeling of sectioned material. Fixed tissues were infiltrated with fully polymerized polymethylmethacrylate dissolved in an organic solvent. Evaporation of the solvent left the tissue embedded in hard plastic. After sectioning by conventional methods, the plastic was extracted and sections were processed for indirect immunofluorescence to label microtubules. Clear images of microtubules were observed in sections of cultured epithelial cells, intact chick intestinal epithelium, and dividing sea urchin eggs. Microtubules in the differentiated epithelium of the chick intestine generally paralleled the long axis of the cells and did not focus on a microtubule-organizing center. Mitotic cells of the intestinal epithelium appeared similar to the mitotic cells of epithelial lines in culture. In sections of dividing sea urchin eggs detailed images of spindle and astral fibers were revealed. Immunoelectron microscopic labeling for tubulin was performed on sections of Pt K1 cells using secondary antibodies adsorbed to 20-nm gold particles. Semi-thick sections viewed by high-voltage electron microscopy showed both the overall distribution of microtubules and their detailed interactions with other cellular organelles. Mitochondria were often aligned along labeled microtubules. Reversible embedment cytochemistry should provide a general method for high resolution labeling of cells and tissues with affinity probes.

Monoclonal antibodies to pseudorabies virus produced by mouse hybridomas

Monoclonal antibodies to pseudorabies viral capsid protein were prepared by fusing Sp2/0-Ag14 myeloma cells with pseudorabies virus (PrV)-primed Balb/c splenocytes. These monoclonal antibodies were specific for PrV. No crossreaction with Herpes Simplex Virus (HSV, type I) or infectious bovine rhinotrachitis virus (IBR) was found. The reaction between these monoclonal antibodies and PrV was demonstrated by immunofluorescent staining technique and enzyme-linked immunoblotting assay. These antibodies could be a useful diagnostic reagent for PrV as well as a good tool for the study of the capsid protein of PrV.

Association of anti-dynein-1 cross-reactive antigen with the mitotic spindle of mammalian cells

Two anti-dynein-1 antibodies were affinity-purified from rabbit antiserum produced by immunization with dynein-1 from sea urchin sperms. One was prepared with dynein-1 as the ligand and the other with the A heavy chains of dynein-1 as the ligand. In Western blots of axonemal proteins, the former antibody reacted with the A heavy chains of dynein-1 as well as with several other smaller polypeptides, whereas the latter bound almost exclusively to the A heavy chains. PtK2 cells stained by indirect immunofluorescence with either of these antidyneins had identical fluorescence patterns. The interphase cell showed rather diffuse and weak fluorescence in its nucleus and perinuclear cytoplasm. Its primary cilium and its centrioles also fluoresced. During prophase and prometaphase, a more intense fluorescence was present in the asters and developing spindle. During metaphase and anaphase the half-spindles fluoresced intensely in a fibrous pattern that corresponded to that of the spindle fibers, showing less intense fluorescence in the anaphase interzone. In telophase and early interphase, the intercellular bridge on each side of the midbody also was stained. These results are evidence that dynein-1, specifically the A heavy chains and/or a related antigen, is densely packed in the mitotic spindle of PtK2 cells.

The characterization of two monoclonal anti-keratin antibodies and their use in the study of epithelial disorders

The present paper describes the production and characterization of two monoclonal antibodies, K20 and K92. Immunohistological staining showed these two antibodies to be specific for keratinizing epithelium. However, whereas K20 stained all layers of the epidermis K92 reacted with only the suprabasal epidermal layers. Immunoblotting studies with preparations of keratins from both the non-cornified (i.e. the basal, spinous and granular layers) and cornified (stratum corneum) layers of epidermis showed that K20 recognized the 46, 48, 50, 55, 56, 56.5, 59, 61, 62, 64, 65, 66 and 67 kd bands, of which the 50 and 46 kd bands appeared to be masked in tissue sections. In contrast, antibody K92 was more restricted in its activity, recognizing only the 55 and 56 kd bands strongly. These antibodies were used in the study of various epithelial disorders and revealed alterations in the epithelial intermediate filament expression in both benign and malignant disease processes.

Procedure for isolating micronuclei from rat kangaroo cultured cells containing individualized chromosomes

Micronuclei are small interphase nuclei containing part of the genome; the DNA content of the smallest micronuclei is equivalent to one chromosome. For analysis by biochemical method and by cytofluorometry of interphase micronuclei containing a single chromosome, several isolation and purification procedures were tested and checked by fluorescent microscopy using the DNA dye Hoechst 33 342 and electron microscopy. Micronucleation of rat kangaroo epithelial cells was induced by colchicine treatment for three days. Micronuclei were isolated in a low ionic strength buffer containing collagenase, with concomitant mechanical shocks. Eighty % of the micronuclei were released after 3 to 7 min, with minimum nuclear breakage. Subsequent filtration through several polycarbonate filters 12, 8 and 5 micron in diameter enabled purification of the smallest micronuclei without aggregates or debris. Micronuclear morphology was well preserved, as shown by electron microscope observations. Therefore, we established the optimal conditions allowing gentle mass isolation of individual micronuclei of cultured PtK1 cells, compatible with flow cytometry analysis.

The effect of harmine on the localization of the nucleolar proteins C23 and B23

In this study we show that harmine treatment (10 mg/l for 2 or 24 h) of PtK2 cells had a marked effect on the localization of the nucleolar phosphoproteins C23 and B23. C23 was localized with silver staining in the fibrillar areas of completely segregated nucleoli. B23 was localized mainly on the periphery of the nucleoli with the aid of immunofluorescence.

Reorganization of plasma membrane-associated 36 000 dalton protein upon drug-induced redistribution of cytokeratin

Epithelial PtK2 cells were used as a model to study the possible redistribution of the major tyrosine protein kinase substrate, p36, upon drug-induced reorganization of the cytokeratin network. Cells were grown on glass coverslips and exposed to cytochalasin D (CD), colcemid or a combination of the two. The cytokeratin type intermediate filaments of the cells were redistributed by treatment of the cells with colchicine and CD. Simultaneous changes in cytokeratin and in p36 antigen were observed by double-label immunofluorescence. In control PtK2 cells, p36 was distributed characteristically at the cortical cytoplasm. Neither colchicine nor CD alone was able to cause a major reorganization of cytokeratin or p36. Their combined effect resulted in formation of blebs containing abundant p36 at the cell surface and at cell-cell junctions. Actin, on the other hand, was reorganized to similar configurations by CD alone. These observations show for the first time a drug-induced redistribution of p36. The results suggest a relationship between membrane-associated p36 and the cytoskeletal fibres that terminate at the plasma membrane.

Effects of tubulozole on the microtubule system of cells in culture and in vivo

Light and electron microscopic investigations on mammalian cells in vitro and in vivo showed that tubulozole-C (R 46 846), the cis-isomer of tubulozole, a new synthetic anticancer drug, interfered with the structure and function of microtubules in both interphase and mitotic cells. The activity of this compound in experimental tumor systems can thus be explained partly by a direct antimitotic effect and partly by the disintegration of the normal subcellular organization of the nondividing cells. At concentrations which affect the microtubule system, tubulozole-C arrested directional migration of transformed cells and malignant invasion in a three-dimensional organ culture system. Investigations in vivo show that malignant L1210 leukemia cells are more susceptible to the antimicrotubular effect of tubulozole-C than are the normal leukocytes of the host. The trans-isomer of tubulozole (tubulozole-T, R 48 265), which has no antitumor activity in vivo, did not affect the microtubule system of cells in vitro or their capacity for directional migration or for malignant invasion.

Intracellular free calcium levels are reduced in mitotic Pt K2 epithelial cells

Using a fluorescence ratio method, we have studied the intracellular free calcium levels in individual quin-2-loaded mitotic cells under the microscope. We have found that intracellular free calcium concentrations in Pt K2 epithelial cells drop by approximately 50% as they pass through mitosis. Calcium levels in interphase cells were 53 +/- 7 nM. During prophase, free cytoplasmic calcium begins to decrease, reaching 28 +/- 3 nM in prometaphase. Calcium levels remain low until the nuclear envelope is re-formed in late telophase, when they increase again to interphase levels. This decrease in overall free calcium in mitosis suggests that the mitotic cell has mechanisms for the general sequestration, and perhaps local release, of calcium ions.

Role of urine in coordinating reproduction in a desert rodent (Dipodomys merriami)

Detection of reproductive status from chemical signals in the urine of a desert rodent was examined. Intact and castrated male and estrous (induced) and nonestrous (ovariectomized) female Dipodomys merriami were tested for their preferences for various combinations of water and urine from intact males, estrous females, castrated males, and nonestrous females. Intact and castrated males were also tested for their responses to urine from females at different stages of the reproductive cycle: proestrus, estrus, and diestrus. Neither intact nor castrated males exhibited a preference for urine from females in any stage of the estrous cycle. Urine from intact males, however, was preferred by both intact males and estrous females. Urine from reproductively active males, rather than from estrous females, seems to contain information for coordinating reproduction in D. merriami.

Effects of amsacrine and other DNA-intercalating drugs on nuclear and nucleolar structure in cultured V79 Chinese hamster cells and PtK2 rat kangaroo cells

Amsacrine [m-AMSA; 4'-(9-acridinylamino)methanesulfon-m-anisidide] is a synthetic intercalating agent with clinical utility in the treatment of acute leukemias and lymphomas. However, as with other intercalators, its mechanism of action is uncertain. We have examined structural changes induced by amsacrine and other intercalators (actinomycin D, Adriamycin, mitoxantrone, 9-aminoacridine) in cultured Chinese hamster (V79-171b) and rat kangaroo kidney epithelial (PtK2) cells, using light- and electron microscopy with simultaneous assessment of cell survival. During chronic exposure at low concentrations, amsacrine causes cell and nuclear enlargement, lobulation of the nucleus, and nucleolar segregation. Nucleolar segregation was also induced by the other four intercalators. The cytotoxic potency of these drugs, as measured by cell survival after 1-hr exposure, was compared with potency of induction of nucleolar segregation. Relative potencies in the two assays varied by more than 10(4)-fold, with actinomycin D the most effective and amsacrine the least effective inducer of nucleolar segregation relative to cytotoxic potency. Thus, although all five intercalators induced nucleolar segregation with high specificity, this lesion does not correlate with cell killing by these drugs. However, interference with nucleolar function (i.e., ribosomal RNA synthesis) may be responsible for the reversible cytostatic effect observed on chronic exposure to some intercalators (actinomycin D, 9-aminoacridine) at low concentrations.

Fibrillarin: a new protein of the nucleolus identified by autoimmune sera

Autoimmune serum from a patient with scleroderma was shown by indirect immunofluorescence to label nucleoli in a variety of cells tested including: rat kangaroo PtK2, Xenopus A6, 3T3, HeLa, and human peripheral blood lymphocytes. Immunoblot analysis of nucleolar proteins with the scleroderma antibody resulted in the labeling of a single protein band of 34 kD molecular weight with a pI of 8.5. Electron microscopic immunocytochemistry demonstrated that the protein recognized by the scleroderma antiserum was localized exclusively in the fibrillar region of the nucleolus which included both dense fibrillar and fibrillar center regions. Therefore, we have named this protein "fibrillarin". Fibrillarin was found on putative chromosomal nucleolar organizer regions (NORs) in metaphase and anaphase, and during telophase fibrillarin was found to be an early marker for the site of formation of the newly forming nucleolus. Double label indirect immunofluorescence and immunoelectron microscopy on normal, actinomycin D-segregated, and DRB-treated nucleoli showed that fibrillarin and nucleolar protein B23 were predominantly localized to the fibrillar and granular regions of the nucleolus, respectively. RNase A and DNase I digestion of cells in situ demonstrated that fibrillarin was partially removed by RNase and completely removed by DNase. These results suggest that fibrillarin is a widely occurring basic nonhistone nucleolar protein whose location and nuclease sensitivity may indicate some structural and/or functional role in the rDNA-containing dense fibrillar and fibrillar center regions of the nucleolus.

Interaction of triethyl lead chloride with microtubules in vitro and in mammalian cells

The effects of triethyl lead chloride (TriEL) on the in vitro assembly and disassembly of microtubules (MTs) from porcine brain were studied by turbidometry at 350 nm and by electron microscopy. TriEL inhibited MT assembly at 50 microM concentration and caused an almost complete disassembly of preformed MTs. The drug depolymerized MTs more effectively than colchicine. Concentrations higher than 50 microM TriEL caused an aberrant assembly process. Fibers about 10 nm width were formed in addition to aggregates of amorphous material. In vivo TriEL also caused MT depolymerization in interphase and mitotic PtK-1 and Ehrlich ascites tumor (EAT) cells as monitored by indirect immuno-fluorescent staining of tubulin and electron microscopy. The extent of MT depolymerization was concentration- and time-dependent. Recovery occurred as early as 5 min after removal of the drug. The fluorescent actin pattern in PtK-1 cells typical of stress fibers and subcortical filaments seemed not to be altered by the presence of TriEL. The vimentin intermediate filament system was, however, rearranged as a juxtanuclear complex after TriEL treatment. Furthermore, TriEL effected the inhibition of cellular growth (100% inhibition at about 10(-5) M). Cytokinesis is prevented to a great extent, resulting in the formation of binucleate cells which can additionally possess some micronuclei.

The kinetochore of mammalian chromosomes: structure and function in normal mitosis and aneuploidy

The kinetochore is a structurally differentiated site on mitotic chromosomes to which spindle microtubules (MTs) are attached. In mammalian cells, the kinetochore is organized into a trilamellar plate and is morphologically distinct from the centromere. Although kinetochores and centromeres are morphologically and biochemically distinct regions, they are functionally linked and necessary for normal chromosome movement and segregation. Recent biochemical and immunocytochemical studies suggest that the kinetochore is composed of several polypeptides, DNA, and possibly RNA. The kinetochore plates are composed of tubulin and two antigens of 17 Kd and 80 Kd, as detected by scleroderma CREST antiserum. Colcemid, a MT inhibitor, also causes reversible rearrangements of kinetochore structure. Mitomycin C binds to heterochromatin and causes the trilamellar plates to become detached from the chromosome. Diethylstilbestrol (DES), a synthetic estrogen, inhibits mitosis in mammalian cells and causes chromosome lagging or malorientation during recovery. Electron microscopy indicates that DES causes disruption of the mitotic spindle, centriole elongation, and unusual chromosome associations due to interkinetochore microtubules. No apparent damage to kinetochores was noted in lagging or maloriented chromosomes.

Effects of the vital DNA probe fluorochrome Hoechst 33342 on PtK cell chromatin

We investigated the effects of DNA labelling by fluorochrome Hoechst 33342, on chromatin distribution and transcription during a short-term non-toxic staining procedure which did not prevent the cell growth. By electron microscope examination we found chromatin condensation and nucleolar fragmentation just after the staining. Both effects appeared to be reversible 24h after staining; 48h afterwards, the morphological pattern was similar to that of control cells. The rate of RNA transcription was reduced at the end of staining, increased at 24h, and was comparable to the control at 48h. We also observed an effect on the cell cycle when the staining pasted 6h. Consequently, 24h after Hoechst vital staining, the effects on chromatin vanished whereas the cells remained fluorescent.

The role of the renin-angiotensin system in blood pressure regulation in normotensive animals and man

The role of the renin-angiotensin system in the control of blood pressure in normal rodents, primates and man has been evaluated using inhibitors which block the system at various stages. Renin plays a major role in the maintenance of blood pressure under volume depletion. In subjects with a normal salt intake, the contribution of the renin-angiotensin system in maintaining blood pressure levels can be evaluated using angiotensin converting enzyme (ACE) inhibitors. The contribution of the renin-angiotensin system can now be evaluated more closely following the development of new substances which block the renin-angiotensinogen reaction. Available data strongly suggest that renin contributes to the maintenance of blood pressure levels in subjects with a normal salt intake, although to a lesser degree than in subjects on a low sodium intake. The renin-angiotensin system plays a role in the regulation of blood pressure levels in normal experimental animals and man--its importance depending on the state of sodium balance.

Tubulin dynamics in cultured mammalian cells

Bovine neurotubulin has been labeled with dichlorotriazinyl-aminofluorescein (DTAF-tubulin) and microinjected into cultured mammalian cells strains PTK1 and BSC. The fibrous, fluorescence patterns that developed in the microinjected cells were almost indistinguishable from the pattern of microtubules seen in the same cells by indirect immunofluorescence. DTAF-tubulin participated in the formation of all visible, microtubule-related structures at all cell cycle stages for at least 48 h after injection. Treatments of injected cells with Nocodazole or Taxol showed that DTAF-tubulin closely mimicked the behavior of endogenous tubulin. The rate at which microtubules incorporated DTAF-tubulin depended on the cell-cycle stage of the injected cell. Mitotic microtubules became fluorescent within seconds while interphase microtubules required minutes. Studies using fluorescence redistribution after photobleaching confirmed this apparent difference in tubulin dynamics between mitotic and interphase cells. The temporal patterns of redistribution included a rapid phase (approximately 3 s) that we attribute to diffusion of free DTAF-tubulin and a second, slower phase that seems to represent the exchange of bleached DTAF-tubulin in microtubules with free, unbleached DTAF-tubulin. Mean half times of redistribution were 18-fold shorter in mitotic cells than they were in interphase cells.