The role of fractions from Paracoccidioides brasiliensis in the genesis of inflammatory response

The influx of inflammatory cells towards the peritoneal cavity in rats inoculated intraperitoneally with subcellular preparations of the fungus Paracoccidioides brasiliensis was studied. In addition to the dead fungus, also fractions F1 of the cell wall, which mainly consisted of polysaccharides and the lipid extract, induced intense cell migration 4 hr after inoculation, with a greatly increased number of polymorphonuclear leucocytes (PMN). Study of the kinetics of cell influx showed that both fraction F1 and the lipid extract initially induced intense PMN migration between the 4th and 24th hr after inoculation of these agents, followed by migration of mononuclear cells (MN) around the 48th hr. We also observed that migration of these cells increased gradually after inoculation of growing doses of fraction F1. The present data suggest that polysaccharides and lipids isolated from P. brasiliensis may participate in the initial phase of the inflammatory response in paracoccidioidomycosis.     

Inducing cellular dedifferentiation: a potential method for enhancing endogenous regeneration in mammals

Salamanders have the remarkable ability to regenerate lost body parts and injured organs. This regenerative ability requires fully-differentiated cells in the vicinity of the injury to dedifferentiate, proliferate, and then redifferentiate to form the specialized cells that comprise the regenerated structure or organ. The dedifferentiation stage plays a crucial role in the regenerative response and distinguishes the salamander from other vertebrates with more limited regenerative abilities. Recently, several investigators have shown that certain mammalian cell types can be induced to dedifferentiate to progenitor cells when stimulated with the appropriate signals. This discovery opens the possibility that researchers might one day enhance the endogenous regenerative capacity of mammals by inducing cellular dedifferentiation in vivo.     

MITOTIC INDUCTION AND SYNCHRONIZED CELL DIVISION IN OEDOGONIUM CARDIACUM (HASS.) WITTR.

Waves of mitosis are induced in Oedogonium cardiacum grown under a 15 hr light/9 hr dark cycle. Mitosis starts 4 to 5 hr after the start of the dark period. Each mitotic stage has a high initial rate which plateaus at a lower rate for several additional hours. Partial synchronization of mitotic stages results from this induction of cell division. Mitotic divisions last 9 to 10 hr after induction. During the remainder of the 24-hr light/dark cycle, cells are in interphase. Along a filament, several dividing cells tend to be adjacent, with the most advanced stage in the cap cell. Progressively earlier mitotic stages are basal to the dividing cap cell. This pattern of mitotic division differs from the state in nature where only the cap cell usually divides. Chromosomes probably maintain a telophase arrangement during interphase. The suitability and advantages of Oedogonium, a haploid alga with sexual reproduction, as an experimental plant for cytological, developmental, biochemical, and genetic studies is pointed out.     

Caryological behavior during the first phases of dedifferentiation and habituation inNicotiana bigelovii

Summary Hypocotylar tissues ofNicotiana bigelovii var.quadrivalvis seedlings were induced to dedifferentiate and to habituate after a short treatment with 2,4-D or kinetin.Investigation by cytophotometry and chromosome counts on the nuclear cytology of callus induction and development in minimal medium showed, in addition to diploid cells, an high incidence of aneuploid nuclei. Amitotic phenomena have frequently observed during the culture period. The sequence of nuclear events were not influenced by the hormonal composition of the medium.The origin of these aneuploid cells from nuclear fragmentation processes is hypothesized.The results are discussed in comparison with the cytological status of other habituated and tumorous tissues in plant and animal systems.     

Kinetical Analysis of Tumor Cell Death-Inducing Mechanism by Polymorphonuclear Leukocyte-Derived Calprotectin: Involvement of Protein Synthesis and Generation of Reactive Oxygen Species in Target Cells

We have previously shown that calprotectin, the most abundant cytosolic protein existing in polymorphonuclear leukocytes (PMNs), induces apoptotic cell death in various tumor cells, suggesting that calprotectin is an effector molecule against tumor cells in PMNs. To explore the cell death-inducing mechanism of the factor, we examined the involvement of target protein synthesis and generation of reactive oxygen species (ROS) in the reaction. Calprotectin induced cell death in MM46 mouse mammary carcinoma cells after a 14-16 hr lag time. When the factor was removed from the medium up to about 12 hr after culturing, the effect was diminished. The induction of cell death by calprotectin was markedly inhibited by the presence of the RNA synthesis inhibitor actinomycin D or the protein synthesis inhibitor cycloheximide. However, the addition of these inhibitors after 12 hr of culturing was unable to inhibit the reaction. Up to 12 hr of culturing, the net protein synthesis of MM46 cells was augmented by the presence of calprotectin, but thereafter was impaired. The induction of cell death was also inhibited by the antioxidative reagents N-acetyl-l -cysteine (NAC) or propyl gallate. The addition of NAC even 15 hr later significantly attenuated the calprotectin effect. Flow cytometry analysis showed that calprotectin began to increase the ROS content in MM46 cells after 8-12 hr of culturing, and that the increase was abrogated by the antioxidants. Thus, protein synthesis and ROS generation may be essential elements in the early or later phases of the cell death-inducing reaction of calprotectin, respectively.     

In long bacterial cells,the Min system can act off‐center

In many rod‐shaped bacteria, the Min system is well‐known for generating a cell‐pole to cell‐pole standing wave oscillation with a single node at mid‐cell to align cell division. In filamentous E. coli cells, the single‐node standing wave transitions into a multi‐nodal oscillation. These multi‐nodal dynamics have largely been treated simply as an interesting byproduct of artificially elongated cells. However, a recent in vivo study by Muraleedharan et al. shows how multi‐nodal Min dynamics are used to align non‐mid‐cell divisions in the elongated swarmer cells of Vibrio parahaemolyticus. The authors propose a model where the combined actions of cell‐length dependent Min dynamics, in concert with nucleoid occlusion along the cell length and regulation of FtsZ levels ensures Z ring formation and complete chromosome segregation at a single off‐center position. By limiting the number of cell division events to one per cell at an off‐center position, long swarmer cells are preserved within a multiplying population. The findings unveil an elegant mechanism of cell‐division regulation by the Min system that allows long swarmer cells to divide without the need to ‘dedifferentiate’.     

MITOTIC ACTIVITY AT THE SHOOT APEX OF AZOLLA FILICULOIDES

The mosquito fern, Azolla filiculoides Lam., was grown in a growth chamber on a nitrogen-free culture solution at 24 C under the following photoperiod: 16 hr light/8 hr darkness. Shoot tips were fixed every 2 hr for 24 hr to determine the mitotic index for the apical cell, immediate derivatives, and remaining cells to the level of the first leaf or lateral shoot primordium. Mitotic indices were 6.9%, 6.5% and 6.3%, respectively. The colchicine method was employed to determine the cell-cycle durations and duration of mitosis for the same populations of cells. The cell-cycle duration and duration of mitosis of the apical cell were 28.2 hr and 2.8 hr, respectively; for the immediate derivatives, 26.7 hr and 2.5 hr; for the remaining cells, 23.6 hr and 2.1 hr. Conclusions: the apical cell is as mitotically active as its immediate derivatives, and there is no evidence of a quiescent apical cell.     

Induction and synthesis of tubulin during the cell cycle and life cycle of Chlamydomonas reinhardi

Two types of tubulin induction are observed in Chlamydomonas reinhardi. One is elicited by flagellar detachment and the other occurs as a normal event of the vegetative cell cycle. In the former case, a strong and extensive induction of tubulin synthesis occurs following deflagellation of cells in all phases of the life cycle [vegetative, gametic, and (early) zygotic]. Synthesis is initiated in all three cell types within 15 min after deflagellation. In gametic and zygotic cells, tubulin synthesis so induced accounts for 15 to 20% of the total protein synthesis during the 1-hr peak period of tubulin production. The ability to support both tubulin synthesis and flagellar regeneration is lost in zygotes at 1.5 hr after the initiation of zygotic development. This alteration represents one of several dramatic shifts in the programming of protein synthesis that occur during the first 4 hr of zygotic differentiation in C. reinhardi. The second (i.e., cell cycle-dependent) type of induction is observed in synchronously growing vegetative cells at ～1.5–2 hr prior to cytokinesis. Tubulin synthesis, in this case, persists at relatively high levels (～5% of the total protein synthesis) for the next 9 hr, i.e., through the entire period of cell division to a time just before the liberation of fully flagellated daughter cells at hr 20 of the cell cycle. Changes in the programming of protein synthesis, and of tubulin synthesis in particular, are discussed in relation to specific physiological and cytological transitions that occur during the growth and differentiation of C. reinhardi.     

Dedifferentiation of mammalian myotubes induced by msx1

The process of cellular differentiation culminating in terminally differentiated mammalian cells is thought to be irreversible. Here, we present evidence that terminally differentiated murine myotubes can be induced to dedifferentiate. Ectopic expression of msx1 in C2C12 myotubes reduced the nuclear muscle proteins MyoD, myogenin, MRF4, and p21 to undetectable levels in 20%-50% of the myotubes. Approximately 9% of the myotubes cleave to produce either smaller multinucleated myotubes or proliferating, mononucleated cells. Finally, clonal populations of the myotube-derived mononucleated cells can be induced to redifferentiate into cells expressing chondrogenic, adipogenic, myogenic, and osteogenic markers. These results suggest that terminally differentiated mammalian myotubes can dedifferentiate when stimulated with the appropriate signals and that msx1 can contribute to the dedifferentiation process.     

Analysis of Cell Flow and Cell Loss Following X-Irradiation Using Sequential Investigation of the Total Number of Cells In the Various Parts of the Cell Cycle

The cell flow and cell loss of an in vivo growing Ehrlich ascites tumour were calculated by sequential estimation of changes in the total number of cells in the cell cycle compartments. Normal growth was compared with the grossly disturbed cell flow evident after a 5 Gy X-irradiation. The doubling time of normal, exponentially growing cells was 24 hr. the generation time was 21 hr based on double-isotope labelling studies and the potential doubling time was 21 hr. Thus, the growth fraction was 1.0 and the cell loss rate about 0.5%/hr. Following irradiation, a transiently increased relative outflow rate from all cell cycle compartments was found at about 3 and 40 hr, and from S phase at 24 hr after irradiation. Minimum flow rates from all compartments were found up to 20 hr. Cell loss as calculated from the cell flow was compared with non-viable cells determined by Percoll density separation. Increase in cell loss as well as non-viable cells was observed at 24 hr after irradiation at the time of release of the irradiation-induced G₂ blockage. Up to 50 hr, about 70% of the initial total number of cells were lost. the experiments show the applicability and limitations of cell flow and cell loss calculations by sequential analysis of the total number of cells in the various parts of the cell cycle.     

Leishmania amazonensis Infection Induces Changes in the Electrophysiological Properties of Macrophage-like Cells

Whole cell patch-clamp recordings were used to study the electrical properties of the macrophage-like cell line J774.1, after infection with Leishmania amazonensis. Infection induced a significant increase in cell size and membrane capacitance, suggesting that parasite invasion leads to the addition of plasma membrane to the host cell. By 24 hr after infection, the host cell membrane potential was significantly more hyperpolarized than control cells, and this difference remained for the subsequent 72 hr post-infection. The hyperpolarization was paralleled by an increase in the density of inward rectifying K⁺ currents. The shape of the conductance vs. voltage curve, the kinetic properties and the pharmacological profile of these currents were not significantly altered by infection. These results suggest that infection by L. amazonensis causes an increase in the number of functional inward rectifying K⁺ channels, leading to hyperpolarization of the host cell membrane. Received: 19 January 1999/Revised: 20 April 1999     

Morphogenetic factors controlling differentiation and dedifferentiation of epidermal cells in the gynoecium of Catharanthus roseus

To test the morphogenetic role of equilateral stress and physiological confinement in dedifferentiation of epidermal cells, impermeable barriers of goldmetal foil were placed between the postgenitally fusing epidermal surfaces in the gynoecium of Catharanthus roseus (L.) G. Don. Cells contacting the foil barrier were firmly compressed and air spaces were almost eliminated, thus mimicking an internal cellular environment. However, the cells adjacent to the barriers retained epidermal characteristics and did not dedifferentiate. In contrast, epidermal cells that could establish a direct cell-to-cell contact along the margins of the barriers rapidly dedifferentiated as in normal development. The results indicate that neither physical stress on the cell surfaces nor modifications in gradients of gases or volatile products around the cells control the process of epidermal dedifferentiation. The morphogenetic stimulus in this system requires direct cell contact, and may thus consist of a diffusible messenger molecule or some kind of cell surface interaction. Aspects of this cell interaction and of epidermal cell differentiation generally are discussed.     

Alteration in timing of cell differentiation resulting from cell interactions during development of the cellular slime mold, Dictyostelium discoideum

The effect of cell interactions on the timing of cell differentiation of Dictyostelium discoideum was studied by monitoring spore differentiation in chimeric aggregates composed of two cell populations, one of which was cycloheximide resistant.Chimeras were constructed with cells of a rapidly developing strain, FR-1, and cells of a normally developing cycloheximide resistant strain, CR-2. CR-2 cells formed spores 4 to 5 hr prematurely while spore formation by FS-1 cells was delayed by 1 hr. The two cell populations formed spores 3 hr apart from each other. FS-1 spores were localized to the enlarged bases of the fruiting bodies, whereas CR-2 spores were found in the apical structures.Chimeras were also constructed with cells of two normally developing strains, CR-2 and A3, one population of which had been dissociated at 8.5 hr and the other at 19 hr of development. The 19-hr cells formed spores 2 hr late and 8.5-hr cells 2 to 4 hr prematurely. The two cell populations formed spores within 1 hr of each other although they were asynchronous by 10.5 hr at the time of mixing. These chimeras formed normal fruiting bodies. The results indicate that the timing of cell differentiation is altered by the presence of cells developing at a different rate.     

Light-induced synchrony of cell division in the protonema of the fern,Pteris vittata

Summary In protonemata of Pteris vittata grown for 6 days under red light, which brings about a marked depression of mitotic activity, the first division of the cells was synchronously induced by irradiation with blue light, and subsequent cell divisions were also promoted. The peak of the mitotic index reached a maximum of about 70% at 11.5 hrs, and 90% of all protonemata divided between the 11th and 13th hour after exposure to blue light. When the protonemata were continuously irradiated with blue light, synchronism of the next cell division in the apical cells decreased to a mitotic index of about 30%, and further divisions occurred randomly.The synchronization of cell division was found to be a combined effect of red and blue light. Red light maintained the cells in the early G₁ phase of the cell cycle; blue light caused the cells to progress synchronously through the cell cycle, with an average duration of 12 hr. By using ³H-thymidine, the average duration of the G₁, S, G₂ and M phases was determined to be about 3.5, 5, 2.5 and 1 hr, respectively.Synchronous cell division could be induced in older protonemata grown for 6 to 12 days in red light and even in protonemata having two cells. It could be repeated in the same protonema by reexposure to red light for 24 hrs or more before another irradiation with blue light.     

The giant panda (Ailuropoda melanoleuca) somatic nucleus can dedifferentiate in rabbit ooplasm and support early development of the reconstructed egg

The giant panda skeletal muscle cells, uterus epithelial cells and mammary gland cells from an adult individual were cultured and used as nucleus donor for the construction of intenpecies embryos by transferring them into enucleated rabbit eggs. All the three kinds of somatic cells were able to reprogram in rabbit ooplasm and support early embryo development, of which mammary gland cells were proven to be the best, followed by uterus epithelial cells and skeletal muscle cells. The experiments showed that direct injection of mammary gland cell into enucleated rabbit ooplasm, combined within vim development in ligated rabbit oviduct, achieved higher blastocyst development thanin vitro culture after the somatic cell was injected into the perivitelline space and fused with the enucleated egg by electrical stimulation. The chromosome analysis demonstrated that the genetic materials in reconstructed blastocyst cells were the same as that in panda somatic cells. In addition, giant panda mitochondrial DNA (mtDNA) was shown to exist in the intenpecies reconstructed blastocyst. The data suggest that (i) the ability of ooplasm to dedifferentiate somatic cells is not speciesspecific; (ii) there is compatibility between intenpecies somatic nucleus and ooplasm during early development of the reconstructed egg.     

ERYTHROPOIETIN SENSITIVITY OF RAT BONE MARROW CELLS SEPARATED BY VELOCITY SEDIMENTATION

Rat bone marrow cells have been separated on the basis of their sedimentation at unit gravity. The cell population most responsive to erythropoietin in vitro was found to have a sedimentation velocity of about 6.6 mm/hr. In the process of becoming hemoglobin-synthesizing cells, it undergoes cell division and its sedimentation velocity decreases to 3.9 mm/hr and then to 2.1 mm/hr, the sedimentation velocity of mature red blood cells.     

Effects of Ultraviolet Irradiation on the Cell Cycle

Cultured mouse Cloudman melanoma cells, EMT6 breast carcinoma cells, and 3T3 fibroblasts all accumulated in the G2/M phase of the cell cycle when exposed to UVB radiation. The effects of UVB were maximal at 20–30 mJ/cm² for all three cell lines, and could be observed by flow cytometry as early as 12 hr post irradiation. It has been known since the mid-1970s that MSH receptor binding activity is highest on Cloudman melanoma cells when they are in the G2/M phase of their cycle. Here we show that either UVB irradiation or synchronization of Cloudman cells with colchicine results in a stimulation of MSH binding within 24 hr following treatment, a time when both treatments have resulted in accumulation of cells in the G2/M phase of the cycle. Furthermore, the two treatments performed together on the melanoma cells stimulated MSH receptor activity to the same extent as either treatment performed separately, suggesting that each may be influencing MSH receptor activity solely through a G2/M accumulation of cells. Together, these results raise the possibility that an increase in the number of cells in the G2 phase of the cell cycle is a generalized cellular response to injury, such as UV irradiation. However, in the case of pigment cells this response includes a mechanism for increasing melanin formation, i.e., increased MSH receptor activity. Should this be the case, similar G2/M “injury responses” of other cell types might be expected, consistent with their differentiated phenotypes.     

THE EARLY ACTION OF THE FLORAL STIMULUS ON MITOTIC ACTIVITY AND DNA SYNTHESIS IN THE APICAL MERISTEM OF XANTHIUM STRUMARIUM

Vegetative plants of Xanthium strumarium (a short-day species) were induced to flower by exposure to a single 16-hr long night. By cutting off the induced leaf (half-expanded leaf) at various times, it was established that, by 8 hr after the end of the long night, a sufficient amount of floral stimulus had reached the meristem to induce a flowering response. The following sequence of events occurred in both the peripheral and central zones of the apical meristem of induced plants: 1) a rise in the mitotic index beginning at 28 hr after the end of the long night and culminating at 36 and 56 hr; 2) a stimulation of DNA synthesis starting at 32–36 hr and reaching a maximum at 60 hr; 3) an increase in nucleolus diameter starting at 32 hr. The cell population in the meristems of both vegetative and induced plants displayed a similar distribution, with about 80 % of the nuclei with the 2C amount of DNA. The comparison of the kinetic data concerning the mitotic index and DNA synthesis indicated that one of the early effects of the floral stimulus in the peripheral and central zones was the release in mitosis of cells whose nuclei were in the postsynthetic (G₂) phase of the mitotic cycle. In the pith-rib meristem, the following events were recorded: 1) a stimulation of DNA synthesis starting at 20 hr; 2) a rise of the mitotic index beginning at 28 hr; 3) the vacuolation and elongation of cells starting at 48 hr. All these events occurred well before the initiation of bract and flower primordia, which began at 96 and 136 hr, respectively. Neither stimulation of mitotic activity nor flowering occurred in the meristems of plants subjected to a long night interrupted at its midpoint by a 5-min light break. The results are discussed in relation to the early events which are known to occur in the meristems of other photoperiodic species in transition to flowering.     

Inhibitory effects of tunicamycin on cell-cell adhesion and cell reaggregation of the cellular slime mold,Polysphondylium pallidum

To assess the role in cell-cell adhesion of gp64, a putative cell-cell adhesion molecule ofPolysphondylium pallidum, we treated the cells with tunicamycin (TM), a known inhibitor of the synthesis of the N-linked oligosaccharide precursor, and examined TM's effect on cell-cell adhesion. The vegetative growth ofPolysphondylium cells was inhibited with TM in a dose-dependent manner. When cells were treated with TM (2.0 μg/ml) during only the first 4 hr of starvation and further starved for 8 hr without TM, the cells dissociated considerably, although even the growth phase cells ofPolysphondylium normally show EDTA-resistant (Ca²⁺-independent) cell adhesions. In parallel with the above effects, the amounts of intact gp64 decreased considerably in time with the lengths of incubation (0 hr>4 hr >8 hr). When TM-treated cells were washed free of TM, and shaken for a further 12 hr, the cells began to aggregate again, accompanied by an increase of gp64. In conclusion, TM affected cell-cell adhesion ofPolysphondylium cells, but we were not able to distinguish whether the inhibition of cell aggregation was due to defects in glycosylation on glycoproteins and/or due to reduced levels of glycoproteins themselves.