Seasonal changes in the activity of the thyroid gland of the gerbil Meriones unguiculatus]

Positive correlation was observed between the thermostability level of the parental sperm and that of muscles in the progeny of the frog R. temporaria. The data obtained indicate that in animal evolution the thermostability of cells may be monitored by non-thermal factor or factors.     

Effects of plating density and age in culture on growth and cell division of neonatal rat heart primary cultures

Summary The cell-type composition of the initial cell population from protease-dispersed neonatal rat heart tissue has been evaluated using time lapse photography and identification of cell type-specific functions. The effects of two commonly employed plating densities on growth and cell division of the two major cell types were examined. Total protein synthesis rates were not affected by plating density but did change with age in culture. Maximum protein synthesis rates were observed during the period of maximum cell division and cell growth (increase in total cell protein), which was from 24 h in culture to the 4th d in culture. After 6 d in culture, synthesis rates for total proteins remained constant for at least 2 wk. Sizing of cells by Coulter counter analysis indicated that essentially all the cells were increasing in size with age in culture. Measurements of cell numbers and rate of DNA synthesis indicated that the extent of cell division was dependent on plating density. Cells disaggregated from neonatal rat hearts consisted of approximately 75% muslce cells and 25% nonmuscle cells. This composition approximates the cell-type composition of the intact neonatal rat heart. In high density cultures there is little cell division and the relative proportionsof the cell types are preserved with time in culture. In low density cultures, proliferation of nonmuscle cells is a significant process and the composition of the cell population changes drastically during the first 2 to 3 d in culture. These results suggest that the low plating density used by many researchers may limit correlation of data derived from such cultures with the physiological state. It also indicates that plating densities should be given in published accounts for comparisons to be made with results from other laboratories. This work was supported in part by U.S. Public Health Service Grant HL10018 and The Pennsylvania State University Agricultural Experiment Station and was authorized for publication as Paper 5490 in the journal series of the Pennsylvania Agricultural Experiment Station.     

Activity and thermal stability of acid phosphatase in homogenates of Amoeba proteus, acclimated to various temperatures

Activity and thermoresistance of acid phosphatase were determined in supernatant of Amoeba proteus homogenates using 1-naphthyl phosphate (pH 4.0) and p-nitrophenyl phosphate (pH 5.5). Although tartrate-resistant and tartrate-sensitive acid phosphatases hydrolyse both substrates, the former mainly hydrolyses p-nitrophenyl phosphate and the latter 1-naphthyl phosphate. A decrease in the activity of the total and tartrate-sensitive acid phosphatases, when using 1-naphthyl phosphate, and of the total and tartrate-resistant acid phosphatases, when using p-nitrophenyl phosphate, was found in amoebae acclimated to 10 degrees C (10 degrees-amoebae) compared to those acclimated to 25 degrees C (25 degrees-amoebae). Using 1-naphthyl phosphate, the thermoresistance of the total acid phosphatase was lower in 10 degrees-amoebae than in 25 degrees-amoebae, but the thermostability of tartrate-resistant enzyme was the same in both groups of amoebae. Using p-nitrophenyl phosphate, the thermoresistance of the total and tartrate-resistant acid phosphatases was lower (the latter only slightly) in 10 degrees-amoebae than in 25 degrees-amoebae. It is suggested that at least with the use of 1-naphthyl phosphate a decrease in thermostability of the total acid phosphatase may be due to a decrease in thermoresistance of tartrate-sensitive enzyme. The results obtained confirm the author's previous data on the activity and thermostability of electrophoretic forms of acid phosphatase using 2-naphthyl phosphate in 10- and 25 degrees-amoebae (Sopina, 2001). It is the first case of discovering a correlation between changes in primary cell thermoresistance of amoebae cultured at different temperatures and changes in the activity and thermostability of acid phosphatase in their homogenates, with the number of electrophoretic forms of this enzyme and their mobility being permanent.     

The temperature dependence of protein kinase A and C activity in variant mouse neuroblastoma cells differing genetically in their heat resistance]

The ability of the mouse neuroblastoma cell line NTR to proliferate at 40 degrees C correlates with the position of the temperature optimum of protein kinases A and C activities in the region of higher temperatures compared to those for cells of the original line N18AI, and with higher thermostability of protein kinase A after its heating at various elevated temperatures. The found changes in protein kinases A and C in the cells of NTR line mean that the selection of variants, capable of growing at elevated temperatures, is accompanied with conformational protein changes.     

Spindle orientation and epidermal morphogenesis

Asymmetric cell divisions (ACDs) result in two unequal daughter cells and are a hallmark of stem cells. ACDs can be achieved either by asymmetric partitioning of proteins and organelles or by asymmetric cell fate acquisition due to the microenvironment in which the daughters are placed. Increasing evidence suggests that in the mammalian epidermis, both of these processes occur. During embryonic epidermal development, changes occur in the orientation of the mitotic spindle in relation to the underlying basement membrane. These changes are guided by conserved molecular machinery that is operative in lower eukaryotes and dictates asymmetric partitioning of proteins during cell divisions. That said, the shift in spindle alignment also determines whether a division will be parallel or perpendicular to the basement membrane, and this in turn provides a differential microenvironment for the resulting daughter cells. Here, we review how oriented divisions of progenitors contribute to the development and stratification of the epidermis.     

Small angle neutron scattering as sensitive tool to detect ligand-dependent shape changes in a plant lectin with β-trefoil folding and their dependence on the nature of the solvent

The galactoside-specific Viscum album L. agglutinin (VAA) is a potent biohazard akin to ricin and a mitogen for immune and tumor cells. These activities depend on cell surface binding to glycans. It is an open question whether the process of ligand binding alters the lectin's shape. Small angle neutron scattering (SANS) experiments revealed that the carbohydrate ligand lactose induced a decrease of the radius of gyration of dimeric VAA from 54.5 +/- 1 to 49.5 +/- 1 A in water. Apparently, VAA in aqueous solution and at the concentrations tested at 3.6 mg/ml and above adopts a compacted structure as response to ligand binding. In contrast to the behavior in aqueous solution, lactose binding in DMSO resulted in an increase of the lectin's radius of gyration from 49 +/- 1 to 55.5 +/- 1 A. Because shape changes may be reflected in the thermostability of the protein, this parameter was examined by activity assays of protein exposed to 60 degrees C and 70 degrees C and by differential scanning calorimetry (DSC). In line with the lactose-induced conformational alterations revealed by the SANS experiments, lactose presence enhanced the thermostability of VAA in water. Thus, binding of the carbohydrate ligand in solution can entail changes in shape and thermostability in the case of the tested plant lectin.     

The effects of tracheid dimensions on variations in maximum density of Picea glehnii and relationships to climatic factors

An investigation was made of the effects of tracheid dimensions on variations in the maximum density of Picea glehnii Mast., which were associated with climatic changes. Radial cell diameter and the thickness of the tangential cell walls of the last-formed cells in 90 annual rings of nine trees with different annual ring widths were analyzed by image analysis. Correlations between maximum density and tracheid dimensions indicated that changes in maximum density were due mainly to changes in cell wall thickness of the last-formed cells in annual rings and were not due to changes in radial cell diameter. The effects of climatic factors on tracheid dimensions were examined by application of dendroclimatological techniques. A chronology of cell wall thickness that represented common signals among trees was established. Simple correlation and response function analyses of the chronology revealed that cell wall thickness was influenced positively by summer temperature and negatively by precipitation in August, and these responses were similar to those of maximum density. The study demonstrated that variations in maximum density were due to variations in the cell wall thickness of the last-formed cells, which varied depending on the weather in summer. Received: 8 February 1999 / Accepted: 7 October 1999     

On the constancy of cell division rate in the root meristem

This review examines under what circumstances the rate of cell division among cells of the root meristem is known to vary. First, methods are compared that have been used to quantify cell division rate. These can be grouped as being either cytological, in which the rate of accumulation of cells in a particular phase of the cell cycle is determined based on some form of cytological labeling, or kinematic, in which the rate of cell accumulation is determined from the net movement of cells. Then, evidence is reviewed as to whether cell division rates vary between different tissues or cell types, between different positions in the root, or finally between different environments. The evidence is consistent with cells dividing at a constant rate, and well documented examples where cell division rate changes substantially are rare. The constancy of cell division rate contrasts with the number of dividing cells, which varies extensively, and implies that a major point for cell cycle control is governing the exit from the proliferative state at the basal boundary of the meristem.     

链脲佐菌素诱导糖尿病大鼠胰腺外分泌部A、B细胞密度的变化

本文应用A蛋白金银—过氧化物酶抗过氧化物酶(PAGS-PAP)双重染色法,观察了链脲佐菌素(streptozotocin,STZ)诱导的糖尿病大鼠胰腺外分泌部含高血糖素的单个A细胞(单A细胞)及合胰岛素的单个B细胞(单B细胞)密度的变化.在一次大剂量腹腔注射STZ后第5天和第10天,大鼠胰腺外分泌部单A细胞密度较对照组大鼠增加,而单B细胞密度在注射STZ后第5天较对照组大鼠减少,但在第15天与对照组大鼠接近.在第15天,一些单B细胞分布在靠近胰岛的腺泡中,岛周腺泡含单B细胞的胰岛百分率明显高于对照组.由于胰腺外分泌部的单A、单B细胞在分布特征上与中间细胞相似,在糖尿病时其数量变化也与中间细胞一致,因此,本研究所观察到的单A、单B细胞与前人报道的中间细胞有密切关系.上述单A、单B细胞密度的变化提示,在STZ诱导的糖尿病大鼠,胰腺中的B细胞被STZ破坏后,其外分泌部可能有某些细胞通过中间细胞向单A、单B细胞发生了转化或者单A、单B细胞即此转化过程中的中间细胞.     

Effect of temperature and non-temperature selection of male parental gametes on the heat resistance of the ciliated epithelium in frog progeny

Positive correlation was observed between the thermostability level of the parental sperm and that of the ciliary epithelium in the frog Rana temporaria. It is suggested that this correlation is realized by a special mechanism irrespective of the functional profile of the somatic cells.     

Acidic cell elongation drives cell differentiation in the Arabidopsis root

In multicellular systems, the control of cell size is fundamental in regulating the development and growth of the different organs and of the whole organism. In most systems, major changes in cell size can be observed during differentiation processes where cells change their volume to adapt their shape to their final function. How relevant changes in cell volume are in driving the differentiation program is a long‐standing fundamental question in developmental biology. In the Arabidopsis root meristem, characteristic changes in the size of the distal meristematic cells identify cells that initiated the differentiation program. Here, we show that changes in cell size are essential for the initial steps of cell differentiation and that these changes depend on the concomitant activation by the plant hormone cytokinin of the EXPAs proteins and the AHA1 and AHA2 proton pumps. These findings identify a growth module that builds on a synergy between cytokinin‐dependent pH modification and wall remodeling to drive differentiation through the mechanical control of cell walls.     

Thermal proteome profiling in bacteria: probing protein state in vivo

Increasing antibiotic resistance urges for new technologies for studying microbes and antimicrobial mechanism of action. We adapted thermal proteome profiling (TPP) to probe the thermostability of Escherichia coli proteins in vivo. E. coli had a more thermostable proteome than human cells, with protein thermostability depending on subcellular location—forming a high‐to‐low gradient from the cell surface to the cytoplasm. While subunits of protein complexes residing in one compartment melted similarly, protein complexes spanning compartments often had their subunits melting in a location‐wise manner. Monitoring the E. coli meltome and proteome at different growth phases captured changes in metabolism. Cells lacking TolC, a component of multiple efflux pumps, exhibited major physiological changes, including differential thermostability and levels of its interaction partners, signaling cascades, and periplasmic quality control. Finally, we combined in vitro and in vivo TPP to identify targets of known antimicrobial drugs and to map their downstream effects. In conclusion, we demonstrate that TPP can be used in bacteria to probe protein complex architecture, metabolic pathways, and intracellular drug target engagement.     

Correlated motion and oscillation of neighboring cells in vitro

It has long been realized that fibroblastic and epithelial cells establish recognizable patterns in tissue culture. This behavior implies that neighboring cells interact with one another to produce organized populations. Interaction between cells that are separated by many intervening cells is also possible and is demonstrated here using a special configuration of a biosensor referred to as electric cell-substrate impedance sensing (ECIS). Normally the electrical impedance of a single electrode covered with a confluent cell layer is measured, and the morphological changes of the cells are reflected in the impedance. In this case the cells are cultured on two closely spaced electrodes whose impedances are measured independently as a function of time, and communication between the cell populations is revealed as a correlation between these two time series. We also report for the first time another striking manifestation of dynamic cell interaction, where confluent layers of Madin-Darby canine kidney cells (MDCK) on a single electrode are observed to oscillate in synchrony with a period of approximately 2.5 h.     

Correlated Motion and Oscillation of Neighboring Cells in Vitro

It has long been realized that fibroblastic and epithelial cells establish recognizable patterns in tissue culture. This behavior implies that neighboring cells interact with one another to produce organized populations. Interaction between cells that are separated by many intervening cells is also possible and is demonstrated here using a special configuration of a biosensor referred to as electric cell-substrate impedance sensing (ECIS). Normally the electrical impedance of a single electrode covered with a confluent cell layer is measured, and the morphological changes of the cells are reflected in the impedance. In this case the cells are cultured on two closely spaced electrodes whose impedances are measured independently as a function of time, and communication between the cell populations is revealed as a correlation between these two time series. We also report for the first time another striking manifestation of dynamic cell interaction, where confluent layers of Madin-Darby canine kidney cells (MDCK) on a single electrode are observed to oscillate in synchrony with a period of approximately 2.5 h.     

Regulation of cell adhesion using a signal-responsive membrane substrate

We have developed a novel cell culture material that regulates cell adhesion by changes in potassium ion concentration. The material is a polyethylene substrate grafted to a copolymer of the thermoresponsive polymer N-isopropylacrylamide (NIPAM) and benzo-18-crown- 6-acrylamide (BCAm), with a pendant crown ether as sensor. The crown ether recognizes potassium ion concentrations and NIPAM conformational changes lead to changes in the hydrophobicity/hydrophilicity balance of the entire polymer at constant cell culture temperatures. Although cells were successfully cultured on the ion recognition material in normal culture medium at 37 degrees C, the cells could be detached from the material surface by adding potassium ions alone, without proteolytic enzymes, because the surface to which the cells were attached altered its surface characteristics to a more hydrophilic state. Therefore, cell layers with intact cell-to-cell junctions and high activities were successfully recovered. Furthermore, by changing the target sensors, this material will be able to control cell adhesion through various cellular signals.     

Coding of chemosensory information by the nervous system ofDaphnia magna andEnchytraeus albidus under conditions of action of high environmental temperature

Chemical stimuli (glutamate, glycine, cAMP, and AMP) cause slow and pronounced changes in thermostability of the organisms ofDaphnia magna andEnchytraeus albidus, which can be explained by functioning of not adapted or partially adapted chemoreceptive cells. In experiments with action of purines on the thermostability, the presence inE. albidus of two different chemoreceptors, specific accordingly to cAMP and non-cyclic purines, is shown. A complex extremal stimulus—reaction function, with several optimal values of intensity of the chemical stimulus, at its action on theD. magna andE. albidus thermostability, shows that the elements (neurons or their systems) with the extremal input-output function take part in coding the chemosensory information by the nervous system of these animals.     

Cell cycle,cell size and mitochondrial activity of hybridoma cells during batch cultivation

Cell cycle, cell size and rhodamine 123 fluorescence in cell populations of two batch cultures were analysed and quantified with a fluorescence-activated cell sorter (FACS). Two cultures derived from either exponential or stationary phase innocula were investigated in order to demonstrate the dependency of the subsequent cell growth on innoculum condition. The results demonstrated that the level of activity of cells in the innoculum culture could have a significant effect on cellular activity during the initial phase of the inoculated culture, as it advances through its growth cycle. Positive correlation was found between the cell size and mitochondrial activity (as measured by rhodamine 123 uptake) with S and G₂ fractions as the cell progressed through the cell cycle. The enumeration of the fractions of cell cycle phases has helped in prediction of the changes in cell numbers following perturbation of the culture condition.     

The morphological changes in cultured cells caused by Bordetella pertussis adenylate cyclase toxin

Bordetella pertussis is the causative agent for human whooping cough. It was found that Bordetella pertussis infection caused a change in shape from flat to round in L2 cells, which are derived from rat type 2 alveolar cells. This phenomenon was reproduced using the culture supernatant of B. pertussis, and bacterium-free adenylate cyclase toxin (CyaA) was identified as the factor responsible. A purified preparation of wild-type CyaA but not an enzyme-dead mutant caused the cell rounding. It was examined whether CyaA causes similar morphological changes in various cultured cell lines. L2, EBL, HEK293T, MC3T3-E1, NIH 3T3, and Vero cells were rounded by the toxin whereas Caco-2, Eph4, and MDCK cells were not, although all these cells showed a significant elevation of the intracellular cAMP level in response to CyaA treatment, which indicates that there is no quantitative correlation between the rounding phenotype and the intracellular cAMP level. CyaA has been believed to target various immunocompetent cells and support the establishment of the bacterial infection by subverting the host immune responses. The possibility that CyaA may also affect tissue cells such as respiratory epithelial cells and may be involved in the pathogenesis of the bacterial infection is also indicated.     

Comparison of coulter volumes with radiometrically determined intracellular water volumes for cultured cells

Summary During methotrexate-induced differentiation of cultured human choriocarcinoma (BeWo) cells, proliferation is inhibited, morphologic and biochemical changes occur, and giant, often multinucleated, cells form. We have used the increase in cell volume as a marker of the mature syncytiotrophoblastlike phenotype. Uninduced and differentiated BeWo cells are not spherical, and theoretical considerations suggested that deviations in shape could result in significant errors in Coulter volume. To determine if the values obtained by electrical pulse sizing reflected the actual mass of BeWo cells, we have evaluated the relationship between Coulter volumes and intracellular water volumes obtained using a shape-independent estimate for eight cell types. A close correlation (r ²=0.97) was found, indicating that cell volume changes in populations of irregularly shaped cells can be accurately measured using a Coulter instrument. Supported by an operating grant from the National Cancer Institute of Canada. N.S.B. was a recipient of a studentship award from the Alberta Heritage Foundation for Medical Research. C.E.C. is a Senior Research Scientist of the National Cancer Institute of Canada. The McEachern Laboratory is a research facility of the Faculty of Medicine, University of Alberta, and the Cross Cancer Institute, Edmonton, Alberta.     

Chromatin and Arabidopsis root development

During development cells transit through different states as they pass from stem cell to terminally differentiated cell. There is evidence that the transition from one state to another can be accompanied by changes in epigenetic state of genes, which is embodied in chromatin state. Here we give an overview of the changes in chromatin that accompany the regulation of expression and review the evidence for the involvement of such changes during epidermal root development and discuss the roles that these changes play in the differentiation of the cell types involved.