A head signal influences apical migration of interstitial cells in Hydra vulgaris

Although interstitial cells of hydra can migrate either apically or basally along the body column, there is a distinct bias toward apical cell accumulation. This apical bias could be produced by a local vectorial property of the tissue or it may be controlled by a more global property, such as a signal from the apical head region. The migration behavior of BrdU-labeled interstitial cells was examined in several types of grafts to distinguish between these two general types of migration control. Grafting BrdU-labeled midgastric region tissue into a host in either the normal or the reverse orientation had no effect on the apical bias, indicating that a local vectorial cue was probably not guiding cells apically. In grafts with heads or with feet at both ends of the body column, there was no directional bias in migration if the labeled tissue was equidistant from both ends. In the two-headed grafts, if the labeled tissue was closer to one end, there was a bias in the direction of the closer head. The results suggest that a graded signal emanating from the head creates the apical bias and may attract cells via chemotaxis. The apical bias is enhanced in decapitated animals regenerating a head, indicating that the attracting signal is present and is possibly stronger in regenerating heads. The signal for cell migration may be involved in a patterning process underlying head regeneration.     

The influence of tissue polarity on nematocyte migration in Hydra attenuata

Influences underlying the direction of nematocyte migration in hydra were studied. Nematocytes arise by interstitial cell differentiation in the body column, and then up to 80% migrate into the ectodermal epithelial cells of the tentacles. The migration of these cells, which is clearly apically directed, may be due either to a chemotactic attraction into the hypostome and tentacles, or to a property inherent in the tissue of the body column, such as the regeneration polarity. To distinguish between these two possibilities, the rates of accumulation of ³H-proline-labeled desmoneme and stenotele nematocytes in unlabeled heads (hypostome and tentacles) grafted either basally or apically to the labeled body column were compared. Basally grafted heads, if left in place for an appropriate length of time, reversed the regeneration polarity of the tissue. In all experiments the direction of desmoneme migration was correlated with the direction (apical or basal) of the regeneration polarity of the tissue. Further, the kinetics of polarity reversal were modified by varying the grafting procedure or the environmental conditions. In every case the kinetics of reversal of desmoneme migration also paralleled the kinetics of reversal of tissue polarity. The results suggest that the direction of desmoneme migration is influenced by the regeneration polarity of the tissue. Stenotele migration was largely unaffected by tissue polarity, but behaved as though chemotactically attracted to the head.     

Role of interstitial cell migration in generating position-dependent patterns of nerve cell differentiation in Hydra

The role of interstitial cell migration in the formation of newly differentiated nerve cells was examined during head regeneration in Hydra magnipapillata. When distal tissue was removed from the body of a wild-type strain (105), nerve cell differentiation occurred at a rapid rate during the first 48 hr of regeneration, slowing after this point. Rapid nerve cell differentiation was due primarily to migration of interstitial cells, some of which appeared to be nerve cell precursors, into the regenerating head. The migration decreased considerably after the first 48 hr of regeneration. In reg-16, a mutant strain deficient in head regeneration, no migration of interstitial cells and hence no new nerve cell differentiation were observed in the regenerating tip. However, the interstitial cells of reg-16 were observed to migrate into regenerating tissue of strain 105. These observations suggest that the migration of nerve cell precursors plays an important role when the new nerve net is being established during head regeneration.     

Cell migration and chick limb development: chemotactic action of FGF-4 and the AER.

Experiments have been carried out to investigate the role of the apical ectodermal ridge (AER) and FGF-4 on the control of cell migration during limb bud morphogenesis. By coupling DiI cell labeling with ectopic implantation of FGF-4 microcarrier beads we have found that FGF-4 acts as a potent and specific chemoattractive agent for mesenchymal cells of the limb bud. The response to FGF-4 is dose dependent in both the number of cells stimulated to migrate and the distance migrated. The cell migration response to FGF-4 appears to be independent of the known inductive activity of FGF-4 on Shh gene expression. We investigated the role of the AER in controlling cell migration by characterizing the migration pattern of DiI-labeled subapical cells during normal limb outgrowth and following partial AER removal. Subapical cells within 75 micrometer of the AER migrate to make contact with the AER and are found intermingled with nonlabeled cells. Thus, the progress zone is dynamic with cells constantly altering their neighbor relationships during limb outgrowth. AER removal studies show that cell migration is AER dependent and that subapical cells redirect their path of migration toward a functional AER. These studies indicate that the AER has a chemoattractive function and regulates patterns of cell migration during limb outgrowth. Our results suggest that the chemoattractive activity of the AER is mediated in part by the production of FGF-4.     

A new method for the estimation of cell cycle phases.

A method is described, which is applicable to cell renewal systems with an anatomical structure in which all cell locations may be uniquely mapped. Its use is demonstrated on the rat incisor inner enamel epithelium, which forms a one cell thick column in the sagittally sectioned tooth. Cells born in the apical part of the column migrate toward the distal end of the tooth, where they mature. As the cells migrate along the column, they traverse the various cell cycle phases. The present study has been designed to estimate the probability of a cell being in a given phase; all cells touching the basement membrane were numbered, and the number of cells separating any two cells was taken as a measure of distance. Since generally all cells move in one direction (lateral cell migration may occur), it is possible to solve the problem with the aid of functions describing the renewal counting stochastic process in which cell distance serves as an independent variable. The method predicts labelled cell and mitotic rates which agree with those estimated in the usual way. It was then utilized to estimate the fraction of cells in G2.     

A NEW METHOD FOR THE ESTIMATION OF CELL CYCLE PHASES

A method is described, which is applicable to cell renewal systems with an anatomical structure in which all cell locations may be uniquely mapped. Its use is demonstrated on the rat incisor inner enamel epithelium, which forms a one cell thick column in the sagittally sectioned tooth. Cells born in the apical part of the column migrate toward the distal end of the tooth, where they mature. As the cells migrate along the column, they traverse the various cell cycle phases. The present study has been designed to estimate the probability of a cell being in a given phase; all cells touching the basement membrane were numbered, and the number of cells separating any two cells was taken as a measure of distance. Since generally all cells move in one direction (lateral cell migration may occur), it is possible to solve the problem with the aid of functions describing the renewal counting stochastic process in which cell distance serves as an independent variable. The method predicts labelled cell and mitotic rates which agree with those estimated in the usual way. It was then utilized to estimate the fraction of cells in G₂.     

Nanotopography-guided migration of T cells

T cells navigate a wide variety of tissues and organs for immune surveillance and effector functions. Although nanoscale topographical structures of extracellular matrices and stromal/endothelial cell surfaces in local tissues may guide the migration of T cells, there has been little opportunity to study how nanoscale topographical features affect T cell migration. In this study, we systematically investigated mechanisms of nanotopography-guided migration of T cells using nanoscale ridge/groove surfaces. The velocity and directionality of T cells on these nanostructured surfaces were quantitatively assessed with and without confinement, which is a key property of three-dimensional interstitial tissue spaces for leukocyte motility. Depending on the confinement, T cells exhibited different mechanisms for nanotopography-guided migration. Without confinement, actin polymerization-driven leading edge protrusion was guided toward the direction of nanogrooves via integrin-mediated adhesion. In contrast, T cells under confinement appeared to migrate along the direction of nanogrooves purely by mechanical effects, and integrin-mediated adhesion was dispensable. Therefore, surface nanotopography may play a prominent role in generating migratory patterns for T cells. Because the majority of cells in periphery migrate along the topography of extracellular matrices with much lower motility than T cells, nanotopography-guided migration of T cells would be an important strategy to efficiently perform cell-mediated immune responses by increasing chances of encountering other cells within a given amount of time.     

Fast-crawling cell types migrate to avoid the direction of periodic substratum stretching

To investigate the relationship between mechanical stimuli from substrata and related cell functions, one of the most useful techniques is the application of mechanical stimuli via periodic stretching of elastic substrata. In response to this stimulus, Dictyostelium discoideum cells migrate in a direction perpendicular to the stretching direction. The origins of directional migration, higher migration velocity in the direction perpendicular to the stretching direction or the higher probability of a switch of migration direction to perpendicular to the stretching direction, however, remain unknown. In this study, we applied periodic stretching stimuli to neutrophil-like differentiated HL-60 cells, which migrate perpendicular to the direction of stretch. Detailed analysis of the trajectories of HL-60 cells and Dictyostelium cells obtained in a previous study revealed that the higher probability of a switch of migration direction to that perpendicular to the direction of stretching was the main cause of such directional migration. This directional migration appears to be a strategy adopted by fast-crawling cells in which they do not migrate faster in the direction they want to go, but migrate to avoid a direction they do not want to go.     

Interstitial cell migration in Hydra attenuata. I. Quantitative description of cell movements

The interstitial cell system of hydra contains multipotent stem cells which can form at least two classes of differentiated cell types, nerves and nematocytes. The amount of nerve and nematocyte production varies in an axially dependent pattern along the body column. Some interstitial cells can migrate, which makes it conceivable that this observed pattern of differentiation is not the result of regionally specified stem cell commitment, but rather arises by the selective movement of predetermined cells to the correct site prior to expression. To assess this latter possibility quantitative information on the dynamics of interstitial cell migration was obtained. Epithelial hydra were grafted to normal animals in order to measure (1) the number of cells migrating per day, (2) the location of these cells within the host tissue, and (3) the axial directionality of this movement. Tissue properties such as axial position and the density of cells within the interstitial spaces of the host were also tested for their possible influence on migration. Results indicate that there is a considerable traffic of migrating interstitial cells and this movement has many of the characteristics necessary to generate the position-dependent pattern of nerve differentiation.     

Isolation,characterization, and long-term culture of fetal bovine tracheal epithelial cells

Summary Epithelial cells were isolated from fetal bovine trachea by exposing and stripping the mucosal epithelium from the adjacent connective tissue. The tissue was minced and enzymically dissociated in Ca-Mg-free medium containing dispase and dithiothreitol. The stripping procedure and selective trypsinization produced epithelial cell cultures free of fibroblasts. Seeded on plastic, the plating efficiency was 21.5% with a doubling time of 24 h. Dome formation, evidence of occluding junctions and active ion transport characteristic of epithelial cells, was common. Growth of the cells on glass, collagen, and Engelbreth-Holm-Swarm (EHS) substrate demonstrated a striking difference in morphology. Cells grown on EHS presented a more distinctly three-dimensional growth pattern and many more microvilli when compared to cells grown on glass or collagen. The cells retained their epithelioid characteristics through more than 30 passages as shown by the presence of distinct apical and basolateral membranes, tight junctions, and positive keratin staining. This study was supported in part by grants BRSG S07 RR05408-25, Biomedical Research Support Grant Program, Division of Research Resources, by ES 00159, Center Grant, National Institutes of Environmental Health Sciences, by R23-HL37621, New Investigator Award, National Heart, Lung and Blood Institutes, National Institutes of Health, and by the Health Effects Institute, an organization jointly funded by the U.S. Environmental Protection Agency (Assistance Agreement X-8120059) and automotive manufactures. The contents do not necessarily reflect the views of policies of HEI, EPA, or automotive manufacturers.     

Gaussian Curvature Directs Stress Fiber Orientation and Cell Migration

We show that substrates with nonzero Gaussian curvature influence the organization of stress fibers and direct the migration of cells. To study the role of Gaussian curvature, we developed a sphere-with-skirt surface in which a positive Gaussian curvature spherical cap is seamlessly surrounded by a negative Gaussian curvature draping skirt, both with principal radii similar to cell-length scales. We find significant reconfiguration of two subpopulations of stress fibers when fibroblasts are exposed to these curvatures. Apical stress fibers in cells on skirts align in the radial direction and avoid bending by forming chords across the concave gap, whereas basal stress fibers bend along the convex direction. Cell migration is also strongly influenced by the Gaussian curvature. Real-time imaging shows that cells migrating on skirts repolarize to establish a leading edge in the azimuthal direction. Thereafter, they migrate in that direction. This behavior is notably different from migration on planar surfaces, in which cells typically migrate in the same direction as the apical stress fiber orientation. Thus, this platform reveals that nonzero Gaussian curvature not only affects the positioning of cells and alignment of stress fiber subpopulations but also directs migration in a manner fundamentally distinct from that of migration on planar surfaces.     

The band patterns of twelve D 98/AH-2 marker chromosomes and their use for identification of intraspecific cell hybrids

The chromosomal complement of the human cell line D98/AH-2 has been studied by quinacrine mustard and trypsin Giemsa banding techniques. The dispersion of chromosome counts has been shown to be due to non-random variation involving mainly a few particular chromosomes. — Twelve different marker chromosomes could be distinguished and the presumptive derivation of most of their chromosomal material from normal human chromosomes has been determined. Most cells in 6 different hybrid clones derived from fusion of D98/AH-2 cells with skin fibroblasts from a cystinotic patient contained a single copy of each marker chromosome.Supported by: united States Public Health Service Grant HD 04608, National Institute of General Medical Sciences Grant GM 17702 and American Heart Association Grant 71-981.Established Investigator of the American Heart Association.     

Hybridization of somatic cells derived from mouse and Syrian hamster: Evolution of karyotype and enzyme studies

Somatic hybrids of drug-resistant mutant hamster and mouse cell lines have been isolated and propagated in long-term culture and have been studied in respect to karyotype and three enzymes. During the course of propagation the long-surviving hybrid clones show progressive loss of telocentric chromosomes associated in at least one case with loss of mouse enzyme. Hybrid clones showed hybrid molecules for malate dehydrogenase (MDH), lactate dehydrogenase (LDH), and 6-phosphogluconate dehydrogenase (6PGD) made up by recombination of parental subunits.This work was supported by National Institutes of Health Grant HD 00486.     

Fragile (X) expression: Relationship to the cell cycle

Summary The fragile (X) chromosome demonstrable in individuals with one type of X-linked mental retardation is seldom, if ever, seen in more than 50% of cells of affected individuals. We have devised a model to explain this apparent 50% maximum, one essential feature of which is that the fragile (X) will not be seen in cells in their first division in thymidine-depleted media. The validity of our model was tested on lymphoblastoid cell lines from affected males by treating the cells with fluorodeoxyuridine (FUdR) to induce the marker and/or bromodeoxyuridine (BrdU) to determine the cell cycle. We have evidence that the fragile (X) is present in cells in the first and subsequent these observations our model is not valid and the 50% expression of the fragile site at Xq(28) and other unusual properties of this region of the X chromosome remain unexplained.This work was supported by Grant HD 07879 from the National Institutes of Health     

Cellular mechanisms of stimulation of bud production in Hydra by low levels of inorganic lead compounds

Summary Treatment of Hydra with subtoxic levels of inorganic lead compounds (lead nitrate and lead chloride) for periods ranging from 5 min to one hour causes a temporary increase in bud production as compared to untreated control animals. This effect can be inhibited by the addition of large amounts of calcium chloride to the culture medium.The increased rate of budding is preceded by a dramatic increase in the number of nerve cells per animal, which is first observed within six hours after lead treatment. This appears to be the result of an increased rate of mitosis in the undifferentiated interstitial cells and their subsequent differentiation into nerve cells. The total number of cells per animal also increases after exposure to lead compounds, suggesting that lead may act as a general mitotic stimulator of all dividing cell types in Hydra.This investigation was supported by the National Science Foundation, Grant GB-27395     

Extracellular matrix and capillary ingrowth in interspecies chimeric kidneys

The migration of capillaries into mouse embryonic kidneys grafted on quail chorioallantoic membrane (CAM) was analyzed by two monoclonal antibodies against quail endothelial and haematopoietic cells. As shown by immunohistochemistry, the quail chorioallantoic vessels invaded the kidney explant. Initially, the capillaries were detected in the interstitial stroma and, soon thereafter, tightly adjacent to the branches of the ureteric bud. The induced mesenchymal cell condensates, the prospective nephric vesicles, were avascular, but when the early S-shaped body was formed, the capillaries invaded its lower crevice. Finally chimeric glomeruli consisting of mouse podocytes and quail endothelial cells, were formed and, contemporarily, the capillaries ceased to migrate. Within the endothelial-mesangial area of the chimeric glomeruli, all cells expressed the quail-type nuclear structure and were stained by the quail endothelial-specific antibodies. The pattern of migrating capillaries was compared to the distribution of the extracellular matrix (ECM) molecules by double staining with polyclonal antibodies against laminin or fibronectin, and monoclonal quail endothelial-specific antibodies. Initially, the capillaries migrated in a fibronectin-rich matrix, devoid of laminin, but when the epithelial kidney tubules formed, some capillaries attached to the newly formed epithelial basement membrane. At no stage were the capillaries seen to penetrate the epithelial basement membrane. The orderly branching of the ureteric bud, followed by the formation of nephrons and the shift in the ECM, might create pathways for an oriented capillary migration. The fibronectin-rich areas could be a scaffold for the capillary migration, and the attachment to the basement membranes a means for their cessation.     

The cytoarchitecture of gustatory receptors from the rabbit foliate papillae

Summary The apical region of the taste bud, delimited by the stratum disjunctum of the papillary epithelium, is divided into a distal taste pore, a channel, and a proximal chamber. In addition to fuzzy coated microvilli, the chamber contains an amorphous dense material histochemically defined as a neutral mucopolysaccharide.Abounding in the apical cytoplasm of the taste cell is a randomly oriented filamentous component 60–70 Å in diameter extending into each microvillus. Likewise in this area membrane-bounded electron-dense bodies are found whose content is considered to be synthesized by the rough endoplasmic reticulum and subsequently concentrated and packaged by the Golgi complex. These bodies are thought to contain the neutral mucopolysaccharide, which finally reaches the chamber. Other components of the taste cell cytoplasm include vesicles, mitochondria, ribosomes, and nucleus. Two centrioles, each possessing a pair of rootlets, have been observed in the apical cytoplasm. Adjacent taste cells are attached apically by a zonula occludens followed by a zonula adhaerens. The synaptic clefts between taste cells and nerve fibers are acetylcholinesterase positive but are negative for butylcholinesterase and adenosine triophosphatase. A lineage of taste cells is postulated.This work was supported in part by In House Independent Research Grant No. 6.11.30.01, 3A013001A91C; by National Defense Education Act Group IV Fellowship, awarded to the author; and in part by Grant No. GM-0877, awarded to Dr. Everett Anderson, University of Massachusetts, by the National Institutes of Health. I am grateful to Drs. Everett AnderSon, James N. Dumont, Gunter F. Bahr, and Joe L. GRiffin for their expert guidance and support in the preparation of this paper.     

Apical movement during interkinetic nuclear migration is a two-step process

Neural progenitor cells in the pseudostratified neuroepithelium in vertebrates undergo interkinetic nuclear migration, which results in mitotic cells localized to the apical surface. Interphase nuclei are distributed throughout the rest of the epithelium. How mitosis is coordinated with nuclear movement is unknown, and the mechanism by which the nucleus migrates apically is controversial. Using time-lapse confocal microscopy, we show that nuclei migrate apically in G2 phase via microtubules. However, late in G2, centrosomes leave the apical surface after cilia are disassembled, and mitosis initiates away from the apical surface. The mitotic cell then rounds up to the apical surface, which is an actin-dependent process. This behavior is observed in both chicken neural-tube-slice preparations and in mouse cortical slices, and therefore is likely to be a general feature of interkinetic nuclear migration. We propose a new model for interkinetic nuclear migration in which actin and microtubules are used to position the mitotic cell at the apical surface.     

Fibroblast growth factor induces the soft agar growth of two non-transformed celllines

Summary Recent studies have determined that fibroblast growth factor (FGF) potentiates the soft agar growth responses of NRK-49F cells to several combinations of transforming growth factors (TGFs). In the current study, two other non-transformed cell lines, NR-6 and AKR-2B, which do not spontaneously form colonies in soft agar, were examined for their soft agar growth responses to FGF. Both the acidic form and basic form of FGF were found to induce the soft agar growth of these cells. In the case of NR-6 cells, the effects of TGF-β were also examined. TFG-β potentiated the soft agar growth response of NR-6 cells to FGF, but on its own did not induce soft agar growth. Attempts to identify other factors capable of modulating the response of these cells to FGF, led to the finding that both 12-0-tetra-decanoylphorbol-13-acetate and retinoic acid suppress FGF-induced soft agar growth of NR-6 cells and AKRR-2B cells. The finding that FGF induces the soft agar growth of both non-transformed cell lines, together with the findings of others that both forms of FGF are angiogenic, lends further support to the suggestion that FGF plays a significant role in the in vivo growth of some, and possibly many, tumors. This work was supported by grants from the Nebraska Department of Health (86-11R, 87-38), the National Institute of Child Health and Human Development (HD 19837, HD 21568) and the National Cancer Institute (Laboratory Cancer Research Center Support Grant CA 36727). Editor's Statement The last several years have seen extraordinary advances in the understanding of the biochemistry and physiology of heparin-binding growth factors. Among the activities of these peptides that may be of significance for neoplasia and wound healingin vivo is ability to promote anchorage independent growth of some cell types. In this study the interactions among several stimulatory and inhibitory factors are examined in a soft agar growth assay. An appreciation of these interactions is critical in attempts to relatein vitro effects to those in the intact organism.     

Influence of sialic acid on cell surface properties in I-cell disease fibroblasts

Summary Fibroblasts derived from patients with I-cell disease have been shown to accumulate many natural substrates including a three to fourfold increase in sialic acid content compared to that found in normal fibroblasts. This diverse accumulation of storage material is due to a massive deficiency of multiple lysosomal hydrolases as they are preferentially excreted into the culture fluid. There is evidence that the I-cell plasma membrane itself is abnormal with respect to certain transferase activities and in its sensitivity to freezing and Triton X-100. In this study, we have shown that a neuraminidase-sensitive substrate, and perhaps others in I-cell fibroblasts, contribute to an increased electronegativity of the I-cell fibroblast surface and to the cells' sensitivity to freezing. We also found that neuraminidase treatment of I-cell fibroblasts before preservative freezing in liquid nitrogen enables the cells to adapt more easily to subculture upon thawing. This project was supported in part by National Institutes of Health (NIH) BRSG Grant RR-05493, NIH Grant 1-R01-HD-11453-01-A1, National Science Foundation Grant PCM 77-05733, and Maternal and Child Health Service Project 417. Georgirene D. Vladutiu is the recipient of Research Career Development Award 1K04 HD 00312-01A1 from the National Institutes of Health.