Properties of a nuclear protein marker of human myeloid cell differentiation

The Mr 55,000 nuclear antigen present in the human promyelocytic cell line HL-60 is a basic protein that is extracted from nuclei or chromatin by 0.35 M NaCl. The antigen is confined to the nucleus of the interphase HL-60 cell as judged by immunocytochemical localization but disperses throughout the cell during mitosis. The antigen was not detected in leukemic cell lines with blast cell properties or in cell lines representing other lineages. Additional cell lines (ML-1, ML-2, and U937) with myeloid cell characteristics similar to those of the HL-60 cells, which also differentiate in vitro, express the antigen. The presence of antigen in normal human myeloid cells in peripheral blood and bone marrow is consistent with its proposed role in nuclear events associated with normal human myeloid cell differentiation.     

Subunit Cell Wall of Sulfolobus acidocaldarius

The cell wall of Sulfolobus acidocaldarius has been isolated. Cells were mechanically disrupted with a French press, and the cytoplasmic membrane was removed by extracting cell-envelope fragments with Triton X-100. The Triton-insoluble cell wall material retained the characteristic subunit structure when examined in the electron microscope. Isolated cell wall fragments formed in open sheets that were easily separated from cytoplasmic contamination. Chemical studies showed that the Triton-insoluble cell wall fragments consisted of lipoprotein with small amounts of carbohydrate and hexosamine. The amino acid composition indicated a highly charged hydrophobic cell surface. The presence of diaminopimelic acid with only traces of muramic acid indicates that the cell envelope does not have a rigid peptidoglycan layer. The results of chemical analyses and electron microscopy suggest a wall-membrane interaction stabilizing the cell envelope. The chemical and physical properties of this type of cell envelope would appear to form the basis for a new major division of bacteria with the definitive characteristics of a morphologically distinct subunit cell wall devoid of peptidoglycan.     

Microgametogenesis in Plumbago zeylanica (Plumbaginaceae). 1. Descriptive cytology and three-dimensional organization

The generative cell is initiated as a small, lenticular, unpolarized cell with a cell wall traceable to two origins: the external segment originates as intine, while an inner callose positive cell wall forms de novo. As the lenticular generative cell begins its migration into the pollen cytoplasm, the generative cell becomes polarized both externally and internally, displaying a characteristic shape and patterns of organelle distribution oriented with respect to the vegetative nucleus and independent of pollen aperture location. Separation of the generative cell from the pollen wall begins at the end opposite the vegetative nucleus and results in an elongating protuberance at the opposite end of the generative cell; this becomes associated with a preformed groove located on the surface of the vegetative nucleus. The generative cell subsequently separates from the intine near the vegetative nucleus and moves progressively toward the opposite end of the cell; during this separation, the edge of the wall facing the intine becomes callose-positive and remains so until separating from the intine. The generative cell becomes a free cell within the pollen, which is in physical association with the vegetative nucleus. Generative cell organization and organelle content become increasingly polarized during maturation, with microtubules evident both in the elongating protuberance of the generative cell and in association with organelles. The generative nucleus migrates away from the vegetative nucleus and toward the plastid-rich end of the generative cell, whereas mitochondria are more generally distributed within the cell. Generative cell polarization is made permanent during mitotic division and cytokinesis, i.e., two sperm cells differing in morphology are formed: the larger cell associated with the vegetative nucleus (S_vn) contains a majority of the mitochondria, and the smaller, unassociated sperm cell (S_ua) receives the plastids.     

Cell motility in a new single-cell wound model

Summary  Until now researchers have used a monolayer of cultured cells to investigate cell motility toward an injured cell. However, we suspect that, when using this method, adjacent cells move to the free space due to relief of contact inhibition. The current study was designed to investigate the cell motility nearby an injured cell in varying cell connectivity. A lowpower laser beam was used to damage one cell selectively with the silver coating beads. After injury, we observed the cell motility in three different cell types: (1) those immediately adjacent to the injured cell, 92) those removed from the injured cell by interposition of another cell, and (3) those removed from the injured cell by free space. The cells that are in direct contact with the injured cell moved toward the injured cell within 1.5–3.0 h. Indirectly connected cells and cells with no contact, on the other hand, showed no significant movement toward the injured cell. This suggests that the cell motility toward the cell injury is not only due to relief of contact inhibition but might also be caused by cell-to-cell signaling via cell connection. The current method will provide a tool to create a cell injury without damaging adjacent cells.     

Detection of mycoplasma contamination in cell cultures by a mycoplasma group-specific PCR.

The suitability of a 16S rRNA-based mycoplasma group-specific PCR for the detection of mycoplasma contamination in cell cultures was investigated. A total of 104 cell cultures were tested by using microbiological culture, DNA fluorochrome staining, DNA-rRNA hybridization, and PCR techniques. A comparison of the results obtained with these techniques revealed agreement for 95 cell cultures. Discrepant results, which were interpreted as false negative or false positive on the basis of a comparison with the results obtained with other methods, were observed with nine cell cultures. The microbiological culture technique produced false-negative results for four cell cultures. The hybridization technique produced false-negative results for two cell cultures, and for one of these cell cultures the DNA staining technique also produced a false-negative result. The PCR may have produced false-positive results for one cell culture. Ambiguous results were obtained with the remaining two cell cultures. Furthermore, the presence of contaminating bacteria interfered with the interpretation of the DNA staining results for 16 cell cultures. For the same reason the hybridization signals of nine cell cultures could not be interpreted. Our results demonstrate the drawbacks of each of the detection methods and the suitability of the PCR for the detection of mycoplasmas in cell cultures.     

Comparative study of the transformation of various thymidine kinase-deficient human and animal cell lines with the thymidine kinase gene of the Herpes simplex virus

The comparative study of transformation of four thymidine kinase deficient cell lines (mouse mammary carcinoma cell line FS tk-; rat cell line Rat-2tk-; mouse cell line Ltk-, clone D1; human cell line 143tk-) with the thymidine kinase cloned gene of Herpes simplex virus 1 was undertaken. The differences in efficiency and optimal conditions of transformation were shown for these cell lines. The advantages and disadvantages of the cell systems examined for the use in experiments for transformation and cotransformation of cultured cells with isolated genes are discussed.     

Differential signalling by variant ligands of the T cell receptor and the kinetic model of T cell activation

The structural basis of T cell activation through the T cell receptor is still a major unresolved issue in T cell biology. The wealth of information on the generation and structure of T cell receptor ligands and the biochemistry of signal transduction from this receptor have been useful in the initial approach to explain how T cell activation occurs. More recently, the generation of variant T cell receptor ligands with partial agonist or antagonist properties, the determination of crystal structures for unengaged and engaged T cell receptors, and the kinetics of T cell receptor interactions with peptide:MHC molecule complexes have provided new insights on T cell receptor function. The common theme arising from these experiments is that the T cell receptor is a versatile signalling machine, with an inherent flexibility for ligand recognition that translates in different signalling patterns. Here, I will review the data on differential signalling from the T cell receptor upon recognition of partial agonist and antagonist ligands and how these data impact on a more general kinetic model of T cell receptor-mediated activation.     

Identification of a glycoprotein, gp21, of adult T cell leukemia virus by monoclonal antibody

A mouse hybridoma cell line producing monoclonal antibody, F10, was established from mice hyperimmunized with cells bearing adult T cell leukemia (ATL) virus (ATLV). F10 antibody reacted with an ATLV structural polypeptide ( gp21 ) with a m.w. of 21,000 that was glycosylated on cell surfaces. The gp21 was expressed on cell surfaces of all ATL-associated antigen (ATLA)-positive human cell lines but not on ATLA-negative cell lines nor peripheral blood leukocytes stimulated with mitogens. The gp21 was also detected with anti-ATLA-positive human serum, and the binding of F10 antibody to ATLA-positive cell surfaces was significantly blocked by pretreatment with anti-ATLA-positive human sera. Double immunofluorescence staining with F10 antibody and anti-ATLA-positive human serum caused co-capping on cell surfaces, which suggests that gp21 co-exists with other ATLV antigens expressed on cell surfaces. Immunoprecipitation studies also suggested that the gp21 is a minor component of the ATLV envelope.     

肝癌细胞67kD层粘连蛋白受体N-糖链结构与功能的变化

探讨肝癌细胞与正常肝细胞 6 7kD层粘连蛋白受体 (6 7LR)N 糖链结构与功能的差异 .采用流式细胞术检测SMMC 772 1肝癌细胞和L 0 2正常肝细胞膜表面 6 7LR的表达 ,并分别从这 2株细胞分离纯化到高亲和力的 6 7LR ,利用凝集素结合分析其糖链结构 ,并用肽 N 糖苷酶水解N 糖链 ,观察糖链在与层粘连蛋白结合过程中的作用 .结果发现 ,L 0 2细胞膜表面 6 7LR表达的阳性率为5 5 3% ,而SMMC 772 1细胞为 34.7% ,这两株细胞 6 7LR与伴刀豆素 (ConA)的结合能力无显著差异 ,但SMMC 772 1细胞的 6 7LR与麦胚凝集素的结合能力明显高于L 0 2细胞的 6 7LR ,说明 2株细胞 6 7LR的糖链结构存在显著差异 .当N 糖链被切除后 ,SMMC 772 1细胞的 6 7LR与层粘连蛋白的结合能力明显下降 ,而L 0 2细胞则没有变化 .这些资料表明 ,SMMC 772 1肝癌细胞和L 0 2正常肝细胞与层粘连蛋白结合能力的差别 ,以及两株细胞的 6 7LR与层粘连蛋白结合能力的不同 ,很可能是由于这两株细胞的层粘连蛋白受体的N 糖链结构不同所引起     

Synaptic inputs to the ganglion cells in the tiger salamander retina

The postsynaptic potentials (PSPs) that form the ganglion cell light response were isolated by polarizing the cell membrane with extrinsic currents while stimulating at either the center or surround of the cell's receptive field. The time-course and receptive field properties of the PSPs were correlated with those of the bipolar and amacrine cells. The tiger salamander retina contains four main types of ganglion cell: "on" center, "off" center, "on-off", and a "hybrid" cell that responds transiently to center, but sustainedly, to surround illumination. The results lead to these inferences. The on-ganglion cell receives excitatory synpatic input from the on bipolars and that synapse is "silent" in the dark. The off-ganglion cell receives excitatory synaptic input from the off bipolars with this synapse tonically active in the dark. The on-off and hybrid ganglion cells receive a transient excitatory input with narrow receptive field, not simply correlated with the activity of any presynaptic cell. All cell types receive a broad field transient inhibitory input, which apparently originates in the transient amacrine cells. Thus, most, but not all, ganglion cell responses can be explained in terms of synaptic inputs from bipolar and amacrine cells, integrated at the ganglion cell membrane.     

The nuclear lamins and the nuclear envelope

The cell nucleus is separated from the rest of the cell by the nuclear envelope. The nuclear envelope, nuclear envelope proteins and nuclear lamina organise the structure of the entire nucleus and the chromatin via a myriad of interactions. These interactions are dynamic, change with the change (progress) of the cell cycle, with cell differentiation and with changes in cell physiology.     

Regeneration and maturation of daughter cell walls in the autospore-forming green alga<Emphasis Type="Italic"> Chlorella vulgaris</Emphasis> (Chlorophyta,Trebouxiophyceae)

Cell-wall synthesis in Chlorella vulgaris, an autospore-forming alga, was observed using the cell wall-specific fluorescent dye Fluostain I. The observation suggested two clearly distinguishable stages in cell-wall synthesis: moderate synthesis during the cell-growth process and rapid synthesis at the cell-division stage. We used electron microscopy to examine the structural changes that occurred with growth in the premature daughter cell wall during the cell-growth and cell-division phases. The cell began to synthesize a new daughter cell wall shortly after its release from the autosporangium. A very thin daughter cell wall, with a thickness of about 2 nm, was formed inside the mother cell wall and completely enveloped the outer surface of the plasma membrane of the cell. The daughter cell wall gradually increased in thickness from 2 to 3.8 nm. During the protoplast-division phase in the cell-division stage, the daughter cell wall expanded on the surface of the invaginating plasma membrane of the cleavage furrow, accompanied by active synthesis of the cell wall, which increased in thickness from 3.8 to 6.1 nm. The daughter cell matured into an autospore while completely enclosed by its own thickening (from 6.1 to 17 nm) wall. Finally, the released daughter cell was enclosed by its own cell wall after the mother cell wall burst. The daughter cell with mature wall thickness (17–21 nm) emerged as a small, but complete, autospore.     

Cycling in a crowd: Coordination of plant cell division,growth, and cell fate

The reiterative organogenesis that drives plant growth relies on the constant production of new cells, which remain encased by interconnected cell walls. For these reasons, plant morphogenesis strictly depends on the rate and orientation of both cell division and cell growth. Important progress has been made in recent years in understanding how cell cycle progression and the orientation of cell divisions are coordinated with cell and organ growth and with the acquisition of specialized cell fates. We review basic concepts and players in plant cell cycle and division, and then focus on their links to growth-related cues, such as metabolic state, cell size, cell geometry, and cell mechanics, and on how cell cycle progression and cell division are linked to specific cell fates. The retinoblastoma pathway has emerged as a major player in the coordination of the cell cycle with both growth and cell identity, while microtubule dynamics are central in the coordination of oriented cell divisions. Future challenges include clarifying feedbacks between growth and cell cycle progression, revealing the molecular basis of cell division orientation in response to mechanical and chemical signals, and probing the links between cell fate changes and chromatin dynamics during the cell cycle.

Plant cell cycle and division are linked to specific cell fates and respond to growth-related cues, such as metabolic state, cell size, cell shape, and mechanical stress.     

Mathematical description and analysis of cell cycle kinetics and the application to Ehrlich ascites tumor

The linear and nonlinear aspects of the dynamics of the cell cycle kinetics of cell populations are studied. The dynamics are represented by difference equations. The characteristics of cell population systems are analyzed by applying the model to Ehrlich ascites tumor. The model applied for the simulations of the growth of Ehrlich ascites tumor cells incorporates processes of cell division, cell death, transition of cells to resting states and clearance of dead cells. Comparison of the results obtained with the model and the experimental data suggests that the duration of the mean generation time of the proliferating EAT cells increases with aging of the tumor. An attempt is made to relate the prolongation of cell mean generation time with processes of cell death and dead cell clearance. Studying the transition of cells to the resting states, it becomes apparent that in fact transition of proliferating cells to the resting states occurs somewhere close to the end of the cell cycle and with a rate that varies with the age of the tumor. Time course behavior of the cell age, cell size, and cell DNA distribution with aging of the tumor are obtained. Variations in average size and average DNA contents are determined.     

Real-time Cytotoxicity Assays in Human Whole Blood

A live cell-based whole blood cytotoxicity assay (WCA) that allows access to temporal information of the overall cell cytotoxicity is developed with high-throughput cell positioning technology. The targeted tumor cell populations are first preprogrammed to immobilization into an array format, and labeled with green fluorescent cytosolic dyes. Following the cell array formation, antibody drugs are added in combination with human whole blood. Propidium iodide (PI) is then added to assess cell death. The cell array is analyzed with an automatic imaging system. While cytosolic dye labels the targeted tumor cell populations, PI labels the dead tumor cell populations. Thus, the percentage of target cancer cell killing can be quantified by calculating the number of surviving targeted cells to the number of dead targeted cells. With this method, researchers are able to access time-dependent and dose-dependent cell cytotoxicity information. Remarkably, no hazardous radiochemicals are used. The WCA presented here has been tested with lymphoma, leukemia, and solid tumor cell lines. Therefore, WCA allows researchers to assess drug efficacy in a highly relevant ex vivo condition.     

Analysis of the Cell Cycle and a Method Employing Synchronized Cells for Study of Protein Expression at Various Stages of the Cell Cycle

Study of protein expression during the cell cycle requires preparation of pure fractions of cells at various phases of the cell cycle. This was achieved by the development of methods for cell synchronization. Successful cell synchronization requires knowledge of the duration of all phases of the cell cycle. So, in the present review these interrelated problems are considered together. The first part of this review deals with basic methods employed for analysis of duration of cell cycle phases. The second summarizes data on treatments used for cell synchronization. Methods for calculation of percent of cells at various stages of the cell cycle in fractions of synchronized cells are considered in the third part. The fourth part of this review deals with a method of study of protein expression during the cell cycle by means of immunoblotting of synchronized cell fractions. In the Appendix, basic principles are illustrated with practical examples of analysis of the cell cycle, synchronization, and study of expression of some proteins at various stages of the cell cycle using synchronized XL2 (Xenopus laevis) cells.     

Regulative differentiation as bifurcation of interacting cell population

In multicellular organisms, several cell states coexist. For determining each cell type, cell-cell interactions are often essential, in addition to intracellular gene expression dynamics. Based on dynamical systems theory, we propose a mechanism for cell differentiation with regulation of populations of each cell type by taking simple cell models with gene expression dynamics. By incorporating several interaction kinetics, we found that the cell models with a single intracellular positive-feedback loop exhibit a cell fate switching, with a change in the total number of cells. The number of a given cell type or the population ratio of each cell type is preserved against the change in the total number of cells, depending on the form of cell-cell interaction. The differentiation is a result of bifurcation of cell states via the intercellular interactions, while the population regulation is explained by self-consistent determination of the bifurcation parameter through cell-cell interactions. The relevance of this mechanism to development and differentiation in several multicellular systems is discussed.     

The characteristics of encapsulated whole cell β-galactosidase

We prepared encapsulated whole cell β-galactosidase using E. coli. The cell culture was divided into two steps for the cell accumulation inside the capsule and enzyme production in the cell. Growth and production media were used individually for this purpose. The dry cell weight of the free cell culture was increased 2.8 times by controlling the pH of the growth medium during cultivation. However, the weight of cells accumulated in the capsule reduced 40% with pH control. The dry cell weight increased with lactose concentration of the production medium for both cases of free and capsule cultures. The dry cell weights were 1.5?g/l for free culture and 100?g/l in the capsule when the lactose concentration of the production medium was 10?g/l. The dry cell weight increased about 60% for both cases as the lactose concentration increased from 10 to 50?g/l. The specific activity of whole cell enzyme decreased with lactose concentration from 5 to 1.4?unit/g dry cell for free culture and from 1.1 to 0.65?unit/g dry cell in the capsule. The value of Michaelis constant, K_m, of whole cell enzyme increased 3 times because of the resistance of mass transfer through the capsule membrane. The constants of Michaelis-Menten equation for the whole cell enzyme in the capsule were V_m: 0.0479?mM/min and K_m: 44.86?mM. These constants of the membrane-free cells were V_m: 0.0464?mM/min and K_m: 15.64?mM. To increase the whole cell enzyme activity, we treated encapsulated cells with organic solvents. The activity of encapsulated whole cell enzyme was increased 3.5 times with the treatment of chloroform and ethanol. The activity of the encapsulated whole cell enzymes was reserved after repeating the process 30 times.     

Increased G2 delay in radiation-resistant cells obtained by transformation of primary rat embryo cells with the oncogenes H-ras and v-myc

Cell cycle perturbation after irradiation was studied in five cell lines transfected with oncogenes. Two immortalized, radio-sensitive cell lines with D0s of 1.06 and 1.08 Gy were compared to three radioresistant cell lines with D0s of 1.68-2.17 Gy. The sensitive cell lines were transfected with the v-myc or c-myc oncogenes, the resistant cell lines with the v-myc plus H-ras oncogenes. Exponentially growing populations were exposed to 5, 10, or 15 Gy of orthovoltage radiation. The percentage of cells in each phase of the cell cycle was determined at various times after irradiation using flow cytometry. All cell lines underwent a dose-dependent arrest in G2 phase after irradiation, but the resistant cell lines underwent a significantly longer arrest in G2 phase after irradiation than did the sensitive cell lines. In conjunction with other results from our laboratories, we suggest that this difference in G2 arrest may be the basis for the increased resistance of cells transfected with oncogenes to irradiation.     

Traction in smooth muscle cells varies with cell spreading

Changes in cell shape regulate cell growth, differentiation, and apoptosis. It has been suggested that the regulation of cell function by the cell shape is a result of the tension in the cytoskeleton and the distortion of the cell. Here we explore the association between cell-generated mechanical forces and the cell morphology. We hypothesized that the cell contractile force is associated with the degree of cell spreading, in particular with the cell length. We measured traction fields of single human airway smooth muscle cells plated on a polyacrylamide gel, in which fluorescent microbeads were embedded to serve as markers of gel deformation. The traction exerted by the cells at the cell-substrate interface was determined from the measured deformation of the gel. The traction was measured before and after treatment with the contractile agonist histamine, or the relaxing agonist isoproterenol. The relative increase in traction induced by histamine was negatively correlated with the baseline traction. On the contrary, the relative decrease in traction due to isoproterenol was independent of the baseline traction, but it was associated with cell shape: traction decreased more in elongated than in round cells. Maximum cell width, mean cell width, and projected area of the cell were the parameters most tightly coupled to both baseline and histamine-induced traction in this study. Wide and well-spread cells exerted larger traction than slim cells. These results suggest that cell contractility is controlled by cell spreading.