The Modification of Cell Surface with Lipophilic Glycoconjugates and the Interaction of Modified Cells with Natural Killer Cells

An experimental model system involving the modification of carbohydrate composition of the target cell surface with neoglycolipids was developed for studying the role of surface carbohydrates of target cells in the NK-cell-mediated cytotoxicity. The polymeric glycoconjugates of the Glyc–PAA–PEA and Glyc–PAA(Flu)–PEA types (where Glyc was an oligosaccharide residue, PAA poly(acrylamide) polymer, PEA the phosphatidylethanolamine residue, and Flu fluorescein residue) capable of incorporating into the cell membrane were synthesized. The optimum structures of neoglycoconjugates and the conditions for their incorporation into K562 and Raji cell lines, which differ in their sensitivity to the NK-cell-mediated lysis were selected. The mechanism of association of glycoconjugates with the plasma cell membrane and the kinetics of their elimination from the cell surface were investigated using the fluorescent-labeled Glyc–PAA(Flu)–PEA derivatives. The spatial accessibility of the carbohydrate ligands for the interaction with human NK cells was demonstrated. The target cells modified with the Le^x trisaccharide were shown to be more sensitive to the cytotoxic effect of human NK cells than the intact cells.     

Two types of granular cells in the cerebellar cortex

We recorded the activity of two types of granular cells in the rostral folia of the paramedial lobe (the projection region of the front legs) of the cerebellar cortex in cats immobilized by administration of ditiline; these cells differed in their receptive fields, the characteristics of their reaction to single stimulation of somatic nerves, and the character of their background activity. The granular cells of the first type were excited only when the nerves of the front legs were stimulated (reacting with 1–3 impulses with a latent period of 8–20 msec) and were inhibited between 20–50 and 70–180 msec after stimulation of the nerves of any leg. The cells of the second type responded with volleys of 3–6 impulses with a latent period of 20–40 msec to stimulation of the nerves of all four legs. Comparison of the reactions of the granular cells and other neurons of the cerebellar cortex showed that the cells of the first type cause excitation of the Purkinje and Golgi cells and the neurons of the molecular layer. The granular cells of the second type have an excitatory effect on the Golgi cells. The differences in the reactions of the two types of granular cells result from the fact that they are selectively innervated by the mossy fibers of different afferent pathways. Comparison with the data in the literature enables us to surmise that the fibers of the cuneocerebellar tract terminate at granular cells of the first type, while the reticular fibers terminate at cells of the second type.Institute of Problems of Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 1, No. 2, pp. 167–176, September–October, 1969.     

Indigo formation by aromatic hydrocarbon-degrading bacteria

A variety of aromatic hydrocarbon-degrading bacteria expressing different oxygenases were tested for their ability to produce indigo from indole. Styrene-grown cells of Pseudomonas putida S12 and CA-3 expressing styrene mono-oxygenase produced indigo at rates of 4–8 nmol min–1 mg dry wt–1. Toluene-grown cells of P. putida F1 and naphthalene-grown cells of P. putida PpG7 expressing dioxygenases formed indigo at rates of 1.5 and 2.5 nmol min–1 mg dry wt–1, respectively. © Rapid Science Ltd. 1998     

The Significance of Exometabolites in the Formation and Operation of the Soybean–Rhizobium Symbiosis

The effect of various inoculates of the soybean-specific strain of nodule bacteria Bradyrhizobium japonicum 634b (unwashed cells, cells washed from the exopolysaccharide–protein complex, and cells combined with the complex) on the formation and operation of soybean–rhizobium symbiosis. It was shown that addition of the exopolysaccharide–protein complex doubled the ability of the microsymbiont to form nodules, nodule weight, and the nitrogenase activity of the nodules. Bradyrhizobium japonicum 634b cells washed from exometabolites had lower indices of symbiotic activity than their intact counterparts.     

Cell contacts and smooth muscle bundle formation in tissue transplants into the anterior eye chamber

Summary Segments of the taenia coli from guinea-pig were transplanted into the anterior chamber of the eye. Depending on such factors as the total volume of the transplant and the presence or absence of ganglion cells degeneration was either very extensive (90% or more of the total number of muscle cells) or localized (alternating regions of degenerating and normal structure). During days 1–2 muscle cells lost their plasma membranes so that their cytoplasmic contents were dispersed into the intercellular spaces. Many cells produced numerous small processes which were pinched off and dispersed in a similar manner. Following a period of intense mitotic activity (3–8 days) numerous cells with the characteristics of embryonic smooth muscle cells were evident. Within 10–14 days these differentiating cells produced bulbous protrusions and assumed more irregular outlines than at 3–8 days. The protrusions formed close contacts (50–100Å intercellular space) and tight junctions between adjacent muscle cells. Aggregation of muscle cells into bundles was under way between 14–28 days. At approximately 4–6 weeks these developing muscle groups were invaded by nerve fiber bundles. The pattern of the innervation and the form and size of the muscle bundles simulated the normal. These findings are discussed in relation to the possible functions of the intercellular contacts and cellular protrusions which characterise various periods of regeneration.This work was supported by the Australian Research Grants Committee. The transplants were carried out by Dr. T. Malmfors assistant, Miss Ulla Enberg.     

Cooperative forms of granule cell and Purkinje cell activity in the frog cerebellar cortex

Spatial and temporal characteristics of functional relations between granule cells and Purkinje cells were studied by multimicroelectrode recording of activity of two or more neurons and statistical analysis of the results. On the arrival of mono- and polymodal afferent volleys, excited granule cells and Purkinje cells were shown to organize themselves into cooperative groups (elementary ensembles) of neurons measuring 200–300 and 300–400 µ, respectively. Elementary ensembles of these neurons are regarded as components of functional units which process information in the frog cerebellar cortex. Some of the special features connected with the cooperative principle of their organization and activity were investigated.Rostov State University. Institute of Cybernetics, Hanoi. Translated from Neirofiziologiya, Vol. 9, No. 2, pp. 171–176, March–April, 1977.     

Functional characterization of human T cells immortalized by oncogene transfection

We have succeeded in immortalizing human lymphocytes derived from the peripheral blood of a healthy donor and of an atopic patient, and from the lymph node of a cancer patient by oncogene transfection (Alam et al., 1996). All immortalized human lymphocytes were shown to be CD3+ and CD19–, indicating that these immortalized human lymphocytes were all T cells. We established 317, 154 and 692 individual immortalized human T cell lines derived from the healthy donor, the atopic patient and the cancer patient, respectively. The ratios of CD4+ and CD8+ subpopulations within the set containing immortalized T cells derived from the healthy donor were shown to be varied depending on the combinations of transfected oncogenes used. However, CD8+ cells were found to be the dominant subpopulation of immortalized T cells derived from the atopic patient and the cancer patient. These immortalized T cells showed different proliferative responses in the presence of exogenous human IL–2 depending on their origin, and was consistent with the surface expression of the IL–2 receptor. Furthermore, the cytokine secretion patterns of these immortalized T cells stimulated with mitogen were investigated. The results showed that the immortalized T cells from the healthy donor is able to secrete various kinds of cytokines such as IL–2, IL–10, -IFN and GM-CSF. However, immortalized T cells from the cancer patient was shown to only secrete IL–2 and GM-CSF. These results suggest that depending on the origin, the immortalized T cells came from different subsets or from cells in different activated states. Mixed lymphocytes reactions demonstrated that these immortalized T cells are able to proliferate in the presence of allogenic or xenogenic stimulator cells, suggesting that they maintain the ability to recognize specific antigens on the stimulator cells and can proliferate even after the immortalization. Furthermore, immortalized T cells derived from the healthy donor and the cancer patient strongly responded to K562 cells, suggesting that MHC-nonrestricted killer T cells were also immortalized.Abbreviations IL–2R – interleukin 2 receptor; MLR – mixed lymphocyte reaction     

Structural and developmental differences between three types of Na channels in dorsal root ganglion cells of newborn rats

Summary The changes in Na current during development were studied in the dorsal root ganglion (DRG) cells using the whole-cell patch-clamp technique. Cells obtained from rats 1–3 and 5–8 days after birth were cultured and their Na currents were compared. On top of the two types of Na currents reported in these cells (fast-FA current and slow-S current) a new fast current was found (FN). The main characteristics of the three currents are: (i) The voltages of activation are –37, –36, and –23 mV for the FN, FA and S currents, respectively. (ii) The activation and inactivation kinetics of FN and FA currents are about five times faster than those of the S current. (iii) The voltages at which inactivation reaches 50% are –139, –75 and –23 mV for the FN, FA and S currents, respectively.The kinetics and voltage-dependent parameters of the three currents and their density do not change during the first eight days after birth. However, their relative frequency in the cells changes. In the 1–3 day-old rats the precent of cells with S, FA, and mixed S+FN currents is 22, 18, and 60% of the cells, respectively. In the 5–8 day-old, the percent of cells with S, FA, and FN+S is 10, 66 and 22%. The relative increase in the frequency of cells with FA current during development can contribute to the ease of action potential generation compared with cells with FN currents, which are almost completely inactivated under physiological conditions. The predominance of FA cells also results in a significant decrease in the relative frequency of cells with the high-threshold, slow current.Antibodies directed against a part of the S₄ region of internal repeat I of the sodium channel (C ₁ ⁺ , amino acids 210–223, eel channel numbering) were found to shift the voltage dependence of FA current inactivation (but not of FN or S currents) to more negative potentials. The effect was found only when the antibodies were applied externally. The results suggest that FN, FA and S types of Na currents are generated by channels, which are different in the topography of the C ₁ ⁺ region in the membrane.     

An hypothesis for the interpretation of the contractile response of vascular smooth muscle at the cellular level

The long preservation and recovery of functional (contractile) properties in cultured aortic smooth muscle cells, even after replating or deep-frozen storage and the measurement of their responses are now technically settled issues. We could thus study extensively the responses of single cultured cells from rat thoracic aorta. Responses were elicited by the addition of KCl 40 mmol/L without or with a calcium blocker PN 200-100 (10^–6 mol/L); angiostein II (10^–11–10^–6 mol/L) without or with antagonist (losartan 10^–5 mol/L); or serotonin (10^–9–10^–4 mol/L) without or with antagonist (naftidrofuryl 10^–5 mol/L). Results thus obtained enabled us to propose a new hypothesis for the interpretation of the contractile responses of an elastic vascular smooth muscle. The different maximal effects of different agonists result mainly from the different proportions of cells they can mobilize; the agonist concentration-contraction relationship is mainly due to the increase of the proportion of cells involved up to a maximal value typical of the agonist used. An antagonist primarily reduce the proportion of cells an agonist can mobilize. Some of the consequences of this hypothesis are briefly outlined.     

The effect of light on the number of chloroplast nucleoids in daughter cells of the algaScenedesmus quadricauda

Summary Synchronous cultures of the green algaScenedesmus quadricauda (Turp.) Bréb. grown at mean irradiances 25Wm^–2, 75Wm^–2, and 130Wm^–2 PhAR were exposed to different illumination regimes (ratio of light to dark interval varied from 2:22 to 24:0 hours). The populations of daughter cells released under these conditions differed markedly in their progress in the cell cycle. The cells from these populations were stained with DAPI and the shape, localization and number of chloroplast nucleoids were examined. The nucleoids were of spherical shape, divided asynchronously having dumbbell shape during fission. In the chloroplast, nucleoids were located symmetrically about the transverse axis of the cells. The mean number of nucleoids varied from two in the least developed daughter cells to 16 in the daughter cells of the highest developmental stage. The progress of these cells and thus also the number of nucleoids were proportional to the portion of the light energy amount which these daughter cells shared from the total light energy amount obtained by their mother cells.Abbreviations DAPI 4, 6-diamidino-2-diphenylindole - PhAR photosynthetically active radiation (400–700 nm)     

Unit responses in the anterior zone of the suprasylvian gyrus to peripheral stimuli of different modalities

Unit responses in the anterior zone of the suprasylvian gyrus to visual, electrodermal, and acoustic stimulation were investigated in experiments on unanesthetized cats immobilized with tubocurarine. Electrical activity was recorded from 131 units, 121 of which were spontaneously active. In 65.5% of cells responses consisted of a short or long increase or a decrease in intensity of spike activity. Most cells (58.2%) were monosensory. Responses to visual stimulation were given by 72% of neurons, to electrodermal by 61.6%, and to acoustic by 9.3%. The corresponding latent periods were 20–40, 20–30, and 15–20 msec. Responses of the same neurons to different peripheral stimuli were uniform or they differed in their dynamics. Intracellular recording gave responses in the form of EPSPs (amplitude 4–5 mV, duration 60–80 msec) or, rarely, IPSPs (amplitude 2–3 mV, duration 160–200 msec). The functional organization of the associative cortex and mechanisms of analysis of incoming afferent information are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 4, No. 4, pp. 368–374, July–August, 1972.     

Structural and functional changes in the malpighian tubules of Carausius morosus during dehydration and starvation

Summary Carausius morosus starved and deprived of water lose about 30% of their body weight in 4 days, mainly due to water loss. Isolated inferior tubules from starved dehydrated insects secrete urine at 0.041 nl·mm^–1·min^–1 compared with 0.118 nl·mm^–1·min^–1 in those from fed hydrated insects. This difference is due partly to the level of a diuretic (and perhaps also an antidiuretic) hormone in the haemolymph acting directly on the urine-secreting mechanism and partly to changes in the intrinsic capacity of the tubule cells for urine secretion. This latter change is accompanied by structural changes in the tubules. During starvation and dehydration the lumen becomes packed with white granules, the height of the type 1 cells is reduced, their basal infoldings and brush border become shorter and their mitochondrial volume is reduced.     

Immuno-electron-microscopic study of the prolactin cells in the pituitary gland of male Wistar rats during aging

Summary Prolactin cells were identified by means of immunocytochemistry with protein-A gold as a marker on ultrathin sections of the pituitary gland of young (3–4 months), middle-aged (16–19 months), and aged (26–30 months) male Wistar rats. Point-counting volumetry revealed that the prolactin (PRL) cell-volume density in middle-aged rats was significantly increased in comparison to the volume densities in young and aged rats. Within the PRL-cell population, four types of PRL cells were distinguished on the basis of the shape and size of their secretory granules. During aging, dramatic changes occurred in the relative volumes of the four cell types. The volume percentage of cells with round granules (type I, granule diameter 150–250 nm, and type IIA, granule diameter 250–350 nm) increased from ±30% in young rats to ±90% in old rats. The volume percentage of cells with round and polymorphic granules (type IIB; granule diameter 350–400 nm and type III; granule diameter 500–600 nm) decreased from ±70% in young rats to ±7% in old rats. Age-related changes in serum PRL levels were not found. It is concluded that although during the life span of the male Wistar rat considerable changes in PRL-cell volume densities and in the ratios of PRL-cell types occur serum, PRL levels remain more or less constant.     

Analysis of germinal aging in Paramecium caudatum by micronuclear transplantation

The role of the micronucleus in the age-dependent increase in mortality after conjugation in Paramecium has been investigated using micronuclear transplantation. The clone of Paramecium caudatum used for this study had a lifespan of about 750 fissions. In this clone, the fission rate began to decrease about 450 fissions after conjugation. Mortality after selfing conjugation also began to appear at about 450 fissions and gradually increased with clonal age. Cells at about 650 fissions showed 10–70% survival after selfing conjugation but when their micronuclei were transplanted into amicronucleate cells of about 450 fissions, the progeny survival increased to 70–90%. When micronuclei from cells 700–750 fissions old were transplanted into amicronucleate cells of 100–150 fissions, however, increase in progeny survival was very rare. The results indicate that micronuclei in cells up to the age of 650 fissions can function normally if the cytoplasmic environment is young.     

Changes in frequencies of variegated leaves in NMU treated tobacco

Summary Seeds of Nicotiana tabacum were allowed to imbibe water for 1 h and were then treated with 5–20 mM N-nitroso-N-methylurea (NMU) for 1 h. Seedlings were planted out separately and leaves no. 1–6 were scored individually after expansion was complete: frequencies of leaves with mutant sectors and the percentage of leaf area that was mutant were determined for the numbered leaves. Treatment with 5 mM NMU gave few mutant plants but after 10–20 mM NMU 50–98% of plants were mutant. The frequency of mutant leaves increased from leaf no. 1 to leaves no. 3–4; as much as a 5.6-fold increase, from leaf no. 1 to no. 3 was found. There appears to be differential sensitivity to NMU: it is lower in the initial cells for leaf no. 1 than in the initials for leaves no. 3 or 4. Leaves no. 1–4 arise from four different groups of initial cells: mutations appearing in two or more of leaves no. 1–4 must, therefore, arise independently of one another. From mutants found in leaves no. 1–4 it is estimated that the mean number of mutations per seedling was 2.68 after treatment with 20 mM NMU. Mean percentage of leaf surface area occupied by mutant sectors increased from 14% to 29.4% as NMU concentration increased from 10 to 20 mM. It also increased significantly from leaf no. 1 to leaves no. 3–6 after treatment with 15 or 20 mM NMU but not after 10 mM NMU: this suggests that mutagen treatment may affect the formation of mutant homoplasmon cells and their contribution to leaf primordia.     

Classes and mechanisms of calcium waves

The best known calcium waves move at about 5–30 μm/s (at 20°C) and will be called fast waves to distinguish them from slow (contractile) ones which move at 0.1-1 μm/s as well as electrically propagated, ultrafast ones. Fast waves move deep within cells and seem to underlie most calcium signals. Their velocity and hence mechanism has been remarkably conserved among all or almost all eukaryotic cells. In fully active (but not overstimulated) cells of all sorts, their mean speeds lie between about 15–30 μm/s at 20°C. Their amplitudes usually lie between 3–30 μM and their frequencies from one per 10–300 s. They are propagated by a reaction diffusion mechanism governed by the Luther equation in which Ca²⁺ ions are the only diffusing propagators, and calcium induced calcium release, or CICR, the only reaction; although this reaction traverses various channels which are generally modulated by IP₃ or cADPR. However, they may be generally initiated by a second, lumenal mode of CICR which occurs within the ER. Moreover, they are propagated between cells by a variety of mechanisms. Slow intracellular waves, on the other hand, may be mechanically propagated via stretch sensitive calcium channels.     

Providing a microenvironment for the development of human CD34+ hematopoietic cells in SCID mice

In order to develop a convenient small-animal model that can support the differentiation of human bone-marrow-derived CD34+ cells, we transplanted SCID mice with an immortalized human stromal cell line, Lof(11–10). The Lof(11–10) cell line has been characterized to produce human cytokines capable of supporting primitive human hematopoietic cell proliferation in vitro. Intraperitoneal injection of Lof(11–10) cells into irradiated SCID mice by itself resulted in a dose-dependent survival of the mice from lethal irradiation. The radioprotective survival was reflected by an increase in the growth and number of mouse bone-marrow-derived committed hematopoietic progenitors. The Lof(11–10) cells localized to the spleen, but not to the bone marrow of these animals and resulted in detectable levels of circulating human IL-6 in their plasma. Secondary intravenous injections of either human or simian CD34+ cells into the Lof(11–10)-transplanted SCID mice resulted in engraftment of injected cells within the bone marrow of these mice. The utility of this small-animal model that allows the growth and differentiation of human CD34+ cells and its potential use in clinical gene therapy protocols are discussed.     

Protective Role of the Polysaccharide-containing Capsular Components of Azospirillum brasilense

The involvement of the carbohydrate components of the Azospirillum brasilenseSp245 capsules in bacterial protection from the action of extreme factors was investigated. The survival of encapsulated and non-encapsulated azospirilla exposed to elevated (46–48°C) and below-freezing (–20 and –70°C) temperatures, extreme pH values (2 and 10), and to drying was studied. High-molecular-weight carbohydrate-containing complexes (lipopolysaccharide–protein complex and polysaccharide–lipid complex) were isolated from the capsular material of azospirilla. It was shown that the addition of these complexes to the suspension of decapsulated cells before exposing them to extreme factors enhanced their survival rates by 15 to 51%.     

The isolation of immunogenic molecular entities from immunogenic and nonimmunogenic tumor homogenates by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE)

Summary YAC, a Moloney-virus-induced tumor of A-strain mice, is a nonimmunogenic tumor. Mice injected with the inactivated neoplastic cells and challenged with viable tumor cells did not survive longer than mice that received the challenge dose alone. The homogenate of this nonimmunogenic tumor was subjected to sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). After electrophoresis, the gel slices containing isolated molecular entities were injected into various groups of mice. The mice were challenged with low doses of viable tumor cells (10–30 cells) and their survival time was recorded. Small but significant numbers of mice injected with apparent 80–90 K SDS-PAGE-isolated molecular entity rejected the tumor or survived longer than the control groups of mice. Spleen cells from mice injected with 80–90 K molecular entity inhibited the YAC tumor cotransferred with them to naive recipients (Winn assay). Spleen cells from mice injected with monoclonal antibody against nonspecific T-cell helper factor and immunized with 80–90 K SDS-PAGE-isolated molecular entity failed to inhibit the tumor growth in naive recipients, indicating that helper T cells are involved in induction of the antitumor resistance. Nylon-wool-passed splenocytes from mice injected with 80–90 K inhibited tumor growth in some of the recipient mice. Spleen cells from these mice treated with anti-Thy-1 and complement also inhibited the tumor growth in some of the recipients, suggesting that the effector cells were both T and non-T cells. C57BL/6 mice immunized with apparent 20 K SDS-PAGE-isolated molecular entity of RBL5 tumor also induced in vivo resistance to the syngeneic viable RBL5 cells, but not to the syngeneic B16 melanoma cells, indicating the specificity of the protective effect. The practical and theoretical implications of these findings are discussed.     

Transferrin and Transferrin Receptor Function in Brain Barrier Systems

1. Iron (Fe) is an essential component of virtually all types of cells and organisms. In plasma and interstitial fluids, Fe is carried by transferrin. Iron-containing transferrin has a high affinity for the transferrin receptor, which is present on all cells with a requirement for Fe. The degree of expression of transferrin receptors on most types of cells is determined by the level of Fe supply and their rate of proliferation.2. The brain, like other organs, requires Fe for metabolic processes and suffers from disturbed function when a Fe deficiency or excess occurs. Hence, the transport of Fe across brain barrier systems must be regulated. The interaction between transferrin and transferrin receptor appears to serve this function in the blood–brain, blood–CSF, and cellular–plasmalemma barriers. Transferrin is present in blood plasma and brain extracellular fluids, and the transferrin receptor is present on brain capillary endothelial cells, choroid plexus epithelial cells, neurons, and probably also glial cells.3. The rate of Fe transport from plasma to brain is developmentally regulated, peaking in the first few weeks of postnatal life in the rat, after which it decreases rapidly to low values. Two mechanisms for Fe transport across the blood–brain barrier have been proposed. One is that the Fe–transferrin complex is transported intact across the capillary wall by receptor-mediated transcytosis. In the second, Fe transport is the result of receptor-mediated endocytosis of Fe–transferrin by capillary endothelial cells, followed by release of Fe from transferrin within the cell, recycling of transferrin to the blood, and transport of Fe into the brain. Current evidence indicates that although some transcytosis of transferrin does occur, the amount is quantitatively insufficient to account for the rate of Fe transport, and the majority of Fe transport probably occurs by the second of the above mechanisms.4. An additional route of Fe and transferrin transport from the blood to the brain is via the blood–CSF barrier and from the CSF into the brain. Iron-containing transferrin is transported through the blood–CSF barrier by a mechanism that appears to be regulated by developmental stage and iron status. The transfer of transferrin from blood to CSF is higher than that of albumin, which may be due to the presence of transferrin receptors on choroid plexus epithelial cells so that transferrin can be transported across the cells by a receptor-mediated process as well as by nonselective mechanisms.5. Transferrin receptors have been detected in neurons in vivo and in cultured glial cells. Transferrin is present in the brain interstitial fluid, and it is generally assumed that Fe which transverses the blood–brain barrier is rapidly bound by brain transferrin and can then be taken up by receptor-mediated endocytosis in brain cells. The uptake of transferrin-bound Fe by neurons and glial cells is probably regulated by the number of transferrin receptors present on cells, which changes during development and in conditions with an altered iron status.6. This review focuses on the information available on the functions of transferrin and transferrin receptor with respect to Fe transport across the blood–brain and blood–CSF barriers and the cell membranes of neurons and glial cells.