Role of the cellular environment in interstitial stem cell proliferation in Hydra

Summary The role of the cellular environment on hydra stem cell proliferation and differentiation was investigated by introduction of interstitial cells into host tissue of defined cellular composition. In epithelial tissue lacking all non-epithelial cells the interstitial cell population did not grow but differentiated into nerve cells and nematocytes. In host tissue with progressively increased numbers of nerve cells growth of the interstitial cell population was positively correlated to the nerve cell density. In agreement with previous observations (Bode et al. 1976), growth of the interstitial cell population was also found to be negatively correlated to the level of interstitial cells present. The strong correlation between the growth of the interstitial cell population and the presence of interstitial cells and nerve cells implies that interstitial cell proliferation is controlled by a feedback signal from interstitial cells and their derivatives. Our results suggest that the cellular environment of interstitial cells provides cues which are instrumental in stem cell decision making. Offprint requests to: T.C.G. Bosch     

On the stochastic interpretation of a pathological cell renewal system,I: Theoretical basis

The population constituted by parenchymal liver cells is normally a static or slowly expanding one. This is in contrast with “renewal systems,” or cell populations which turn over more or less rapidly. In experimental situations tending to produce cirrhosis of the liver the rate of cell renewal is appreciable. The situation then corresponds to the definition of a “renewal system.” A repeating unit of the liver lattice structure is proposed in which liver cells are assumed to be sequestrated by anatomical constraints on cell migration, and the order of magnitude of its population determined. The characteristics of the simple birth-and-death process are reviewed to show how it leads to greater fluctuation than does a pure birth process with equivalent expected net growth. A hypothetical birth-and-death process is proposed for the renewal of the cell population of the liver unit. The rate of cell proliferation is placed at a level comparable to that found in reports of experimental cirrhosis taken from the literature. This example of a birth-and-death process leads to the prediction of appreciable fluctuation in the population of the liver unit. It is suggested that fluctuations of this kind may account for some of the morphological features of cirrhosis and lead to a new definition of “nodular regeneration.”     

Involvement of endothelin receptors in normal and pathological development of neural crest cells

Endothelin receptors (Ednr) are G-protein-coupled receptors with seven membrane-spanning domains and are involved in various physiological processes in adults. We review here the function of these receptors during the development and transformation of the neural crest cell-specific lineage. Neural crest cells (NCC) may be classified according to their location in the body. In particular, there are clear differences between the neural crest cells arising from the cephalic part of the embryo and those arising from the vagal and truncal part. The development of cranial and cardiac NCC requires the endothelin-1/Ednra system to be fully functional whereas the development of more posterior NCC requires full functionality of the endothelin-3/Ednrb system. Mutations have been found in the genes corresponding to these systems in mammals. These mutations principally impair pigmentation and enteric ganglia development. The precise patterns of expression of these receptors and their ligands have been determined in avian and mammalian models. Data obtained in vitro and in vivo have provided insight into the roles of these proteins in cell proliferation, migration, differentiation and transformation.     

Composium of the histiocyte population of the subcutaneous tissue of white rats (according to the results of a morphometric analysis of their ultrastructure)]

Investigations on polymorphism of histiocytes (macrophages) in the rat normal loose connective tissue support the suggestion about a complex composition of these cellular population. Two classes of cells (subpopulations K-1 and K-2) separated by means of multidimension morphometric analysis of ultrastructure are well identified by several morphologic criteria of weighed informativity. The cells of both populations are recognized under conditions of the organism's functional loadings supposed to produce macrophage activation. Quantitative rearrangements in the subpopulations composing the histiocyte population and a number of morphological transformations revealed in them as specific for fasting and degeneration proved a real importance of the classification.     

Spermatogenic columns,somatic cells,and the microenvironment of germinal cells in the testes of asteroids

Sixty-seven specimens of the common North Atlantic asteroid, Asterias vulgaris, were collected at seasonal intervals over a 2-year period and their testes observed with both light and electron microscopy. In the germinal epithelium, a predictable series of interactions between versatile somatic cells and germinal cells is repeated annually in relation to sequential events in spermatogenesis. For example, massive proliferation and differentiation of spermatogenic cells depend on the elaboration of thousands of spermatogenic columns, which are distinct cellular subdivisions of the germinal epithelium. Each fully developed column is composed of at least one somatic cell surrounded by ≈? 400 germinal cells. Such columns form only after intensive spermatogonial mitosis begins in the germinal epithelium. Single annual periods of spermatogenic proliferation and differentiation are initiated from 1 to 3 months out of phase in different individuals and overlap incompletely. Therefore, it is possible to observe testes that are entirely in the proliferative phase, entirely in the differentiative phase, or in both phases simultaneously. Detailed ultrastructural observations and preliminary autoradiographic data demonstrate that columns maintain their height for a variable period of time as germinal cells are generated near their bases, pass along their lengths, and differentiate near their tips; therefore, simultaneous proliferation and differentiation of more than one generation of germinal cells occur in the same column. Finally, formation of primary spermatocytes ceases basally, (terminating proliferation), and remaining columns degrade completely as germinal cells composing them differentiate or are phagocytized (terminating differentiation and spermatogenesis); resulting spermatozoa ultimately accumulate in the expandable lumen. It is proposed that spermatogenic columns provide the structural basis for organization of the microenvironment of small groups of spermatogenic cells (≈? 400 at a time) during proliferation and differentiation. Preliminary evidence from A. vulgaris and other species also suggests that somatic cells are temporally pluripotent and are variously involved in the formation, structure, and activities of columns, in extensive phagocytosis, and probably in contributing intrinsic (e.g., 1-methyl adenine and steroids) and mediating extrinsic (e.g., gamete shedding substance and nutrients) microenvironmental factors influential during spermatogenesis in asteroids. The prodigious spermatogenic capabilities of asteroids apparently depend on the generation of spermatogenic columns, on the progressive interaction of germinal and somatic cells before, during, and after columns form, and on the predictable effects of microenvironmental factors received and interpreted at the structural level of the spermatogenic column.     

Cell dynamics and gene expression control in tissue homeostasis and development

During tissue and organ development and maintenance, the dynamic regulation of cellular proliferation and differentiation allows cells to build highly elaborate structures. The development of the vertebrate retina or the maintenance of adult intestinal crypts, for instance, involves the arrangement of newly created cells with different phenotypes, the proportions of which need to be tightly controlled. While some of the basic principles underlying these processes developing and maintaining these organs are known, much remains to be learnt from how cells encode the necessary information and use it to attain those complex but reproducible arrangements. Here, we review the current knowledge on the principles underlying cell population dynamics during tissue development and homeostasis. In particular, we discuss how stochastic fate assignment, cell division, feedback control and cellular transition states interact during organ and tissue development and maintenance in multicellular organisms. We propose a framework, involving the existence of a transition state in which cells are more susceptible to signals that can affect their gene expression state and influence their cell fate decisions. This framework, which also applies to systems much more amenable to quantitative analysis like differentiating embryonic stem cells, links gene expression programmes with cell population dynamics.     

The diffuse neuroendocrine system. Studies of this newly discovered controlling system in health and disease

Numerous peptides (neuropeptides) have been recently found to be present in both the nervous and endocrine systems composing what is now known as the diffuse neuroendocrine system. Two immunological methods, radioimmunoassay and immunocytochemistry, have been used here in combination to study their distribution and cellular localization. A number of these neuropeptides have recently been found to be abnormal in disease state, thus providing further information as to their role in normal and pathological conditions.     

A simple, flexible, nonfluorescent system for the automated screening of neurite outgrowth

Measurement of neurite outgrowth is a common assay of neurotrophic activity. However, currently available techniques for measuring neurite outgrowth are either time or resource intensive. The authors established a system in which chronic treatment of a subcloned SH-SY5Y cell line with aphidicolin and various concentrations of nerve growth factor (NGF) induced discernable alterations in proliferation and differentiation. Cells were fixed, labeled with a nonfluorescent dye, and evaluated both manually and with an automated analysis system. NGF increased multiple parameters of differentiation, including neurite length, the proportion of cells extending neurites, and branching, as well as promoting cellular survival/proliferation. Interestingly, although NGF treatment increased the total number of branches, it actually decreased the proportion of branches per neurite length. The authors observed no differences in results obtained using the manual and automated systems, but the automated system was orders of magnitude faster. To demonstrate the flexibility of the system, the authors also show that they could measure changes in differentiation induced by a small-molecule Rho kinase inhibitor, as well as by retinoic acid cotreatment with brain-derived neurotrophic factor. In addition to this flexibility, this system does not require specialized equipment or fluorescent antibodies for analysis and therefore provides a less resource-intensive alternative to fluorescence-based systems.     

Increased hemangioblast commitment, not vascular disorganization, is the primary defect in flt-1 knock-out mice.

We previously demonstrated the essential role of the flt-1 gene in regulating the development of the cardiovascular system. While the inactivation of the flt-1 gene leads to a very severe disorganization of the vascular system, the primary defect at the cellular level was unknown. Here we report a surprising finding that it is an increase in the number of endothelial progenitors that leads to the vascular disorganization in flt-1(-/-) mice. At the early primitive streak stage (prior to the formation of blood islands), hemangioblasts are formed much more abundantly in flt-1(-/-) embryos. This increase is primarily due to an alteration in cell fate determination among mesenchymal cells, rather than to increased proliferation, migration or reduced apoptosis of flt-1(-/-) hemangioblasts. We further show that the increased population density of hemangioblasts is responsible for the observed vascular disorganization, based on the following observations: (1) both flt-1(-/-) and flt-1(+/+) endothelial cells formed normal vascular channels in chimaeric embryos; (2) wild-type endothelial cells formed abnormal vascular channels when their population density was significantly increased; and (3) in the absence of wild-type endothelial cells, flt-1(-/-) endothelial cells alone could form normal vascular channels when sufficiently diluted in a developing embryo. These results define the primary defect in flt-1(-/-) embryos at the cellular level and demonstrate the importance of population density of progenitor cells in pattern formation.     

Organotypic Slice Cultures to Study Oligodendrocyte Dynamics and Myelination

NG2 expressing cells (polydendrocytes, oligodendrocyte precursor cells) are the fourth major glial cell population in the central nervous system. During embryonic and postnatal development they actively proliferate and generate myelinating oligodendrocytes. These cells have commonly been studied in primary dissociated cultures, neuron cocultures, and in fixed tissue. Using newly available transgenic mouse lines slice culture systems can be used to investigate proliferation and differentiation of oligodendrocyte lineage cells in both gray and white matter regions of the forebrain and cerebellum. Slice cultures are prepared from early postnatal mice and are kept in culture for up to 1 month. These slices can be imaged multiple times over the culture period to investigate cellular behavior and interactions. This method allows visualization of NG2 cell division and the steps leading to oligodendrocyte differentiation while enabling detailed analysis of region-dependent NG2 cell and oligodendrocyte functional heterogeneity. This is a powerful technique that can be used to investigate the intrinsic and extrinsic signals influencing these cells over time in a cellular environment that closely resembles that found in vivo.     

Evidences on sodium ions compartmentalization in biological systems due to pathological states. A noninvasive NMR study

Noninvasive nuclear magnetic resonance was used to measure the relaxation decay curves of naturally occurring 23Na ions in several biological systems. Experimental results showed an increase of membrane bound population for pathologic samples as compared with control. The bound sodium population was put in evidence using singular value decomposition method. Thus, the singular values that are obtained without any a priori from the fitting the relaxation decay curves are a new parameter in characterizing the cellular state. In the presence of artificial biological membranes, 23Na bound strongly to membranes containing phosphatidylcholine (PC) and phosphatidylserine (PS), but not to membranes consisting of only PC. A large bound population also appeared in the presence of apoptotic epithelial cells, which are known to translocate PS to the cell surface. A role for PS was confirmed by showing that sodium binds to the surface of epithelial cells infected with Chlamydia psittaci, and the amplitude of the bound population increases with a time-course similar to the appearance of PS on the surface of dying cells. Finally, this approach could distinguish between normal perfused liver and liver undergoing ischemia, due most likely to the exposure of surface PS on apoptotic and necrotic cells in the damaged tissue. Taken together, these studies demonstrate that the analysis of 23Na relaxation decay curves could reveal the presence of cells undergoing apoptosis and/or necrosis in living tissues. Noninvasive 23Na NMR measurements could thus be envisioned for controlling the quality of organs before transplantation, for the detection of asymptomatic infections that result in death of the host cell or inflammation of the tissue, and for characterizing the efficiency of novel apoptosis-inducing drugs to treat cancer.     

SV40 Large T Antigen Interferes with Adult Myosin Heavy Chain Expression, but Not with Differentiation of Human Satellite Cells

The growth of muscle fibers during late development as well as in regeneration following muscle injury is the result of the proliferation and differentiation of satellite cells. However, all human cells, including satellite cells, show a limit in their proliferation. In order to define a cellular system with enhanced proliferative capacity, human satellite cells were transfected with a construct containing large T antigen from SV40 under the control of the human vimentin promoter. Vimentin is normally expressed during proliferation, and its expression is down-regulated as differentiation proceeds. In transfected cells, the construct is regulated like the endogenous vimentin gene. The effect of exogenous T antigen expression on both the proliferation and differentiation of human satellite cells was investigated. T antigen expression reduced the doubling time of human satellite cells from 36 to 20 h and increased the final proliferative capacity from 46 to 69 mean population doublings. When differentiation was triggered, although T antigen did not prevent the formation of myotubes, fusion was delayed. A similar delay was observed in the appearance of myogenin protein, one of the HLH regulatory factors, but not in the corresponding mRNA. Finally, T antigen has an effect on adult myosin isoform expression, since both adult slow and fast isoforms were only detected in myotubes negative for T antigen. These results led us to propose a model of the possible interactions between T antigen and muscle-specific factors.     

Evidence for contact stimulation of growth of homologous cells in superinoculated cultures of chick embryo cells

The secondary cultures of chick embryo cells were suspended and transferred to homologous cell cultures. Cell adhesion and proliferation were studied in these superinoculated cultures. It was shown that added cells soon adhered to the underlying cell layer which results in a prompt increase in culture density followed by the activation of DNA synthesis and cell division. Stimulation of cell proliferation involved both cell subpopulations composing the superinoculated culture: cells seeded on the built-up cell layer and cells of the layer. The contact nature of added cell mitogenic action on overlaid cell proliferation was evidenced. The cell system described can be used to investigate the adhesive properties of the cell layer apical surface, the relationship between cell growth rate and culture density, and the contact stimulation of cell proliferation.     

Embryonic stem cell differentiation and the analysis of mammalian development

Molecular and cellular analysis of early mammalian development is compromised by the experimental inaccessibility of the embryo. Pluripotent embryonic stem (ES) cells are derived from and retain many properties of the pluripotent founder population of the embryo, the inner cell mass. Experimental manipulation of these cells and their environment in vitro provides an opportunity for the development of differentiation systems which can be used for analysis of the molecular and cellular basis of embryogenesis. In this review we discuss strengths and weaknesses of the available ES cell differentiation methodologies and their relationship to events in vivo. Exploitation of these systems is providing novel insight into embryonic processes as diverse as cell lineage establishment, cell progression during differentiation, patterning, morphogenesis and the molecular basis for cell properties in the early mammalian embryo.     

Breast cancer, a stem cell disease

Breast cancer is a first magnitude problem of public health worldwide. There is increasing evidence that this cancer is originated in and maintained by a small population of undifferentiated cells with self-renewal properties. This small population generates a more differentiated pool of cells which represents the main mass of the tumor, resembling the hierarchical tissue organization of the normal breast. These cancer stem cells seem to share a similar phenotype with their normal counterparts but they display dysfunctional patterns of proliferation and differentiation, and they no longer respond to normal physiological controls that ensure a balanced cellular turnover. The origin of these cancer stem cells is controversial; it is not well known if they are originated from normal stem cells or from more differentiated progenitors where a de novo stem cell program is activated by the oncogenic insult. Here we review the origin of breast cancer stem cells and their role in the pathogenesis of cancer development, together with their implications in breast cancer progression, treatment and prognosis.     

Persistent oxidative stress in human colorectal carcinoma, but not in adenoma.

Few studies have been conducted focusing on a potential role of reactive oxygen species in tumor cell metabolism. Here we studied human colorectal adenocarcinomas and adenomas to determine whether oxidative stress is imposed on cancer cells in vivo and used specific antibodies against 8-hydroxy-2'-deoxyguanosine (8-OHdG), 4-hydroxy-2-nonenal (HNE)-modified proteins, and 3-nitro-L-tyrosine (3-NT) to determine whether there is an association between oxidative stress and cellular proliferation. Higher levels of oxidative modifications in DNA and proteins were observed in carcinoma cells, but not in adenoma cells, than in the corresponding nontumorous epithelial cells by immunohistochemistry as well as high-performance liquid chromatography (HPLC)-based 8-OHdG determination. The fraction of proliferating cell nuclear antigen-positive cells was proportionally associated in adenocarcinomas with the staining intensities of 8-OHdG and 3-NT. Furthermore, Western blot analysis of the proteins extracted from carcinoma cells revealed several specific proteins modified by HNE or peroxynitrite. Thus we concluded that colorectal carcinoma, but not adenoma cells, are exposed to more oxidative stress than their corresponding nontumorous epithelial cells, regardless of clinical stage and histology, and further that the oxidative stress in carcinoma cells might stimulate cellular proliferation.     

Bovine theca and granulosa cell interactions modulate their growth, morphology, and function

We have developed a culture system in which bovine granulosa and theca cells are allowed to attach to opposite sides of a collagen membrane. We studied the interaction between theca and granulosa cells by investigating the morphology, proliferation, and steroidogenesis of the cells. Granulosa cells cultured alone were flattened and polygonal and formed monolayer sheets. Granulosa cells cocultured with theca cells formed multilayer sheets. The apical surface of each cell appeared convex. Numerous filopodia spread over the cellular surface connecting cells. Theca cells cultured alone were thin, flat, and spindle-shaped. Theca cells cocultured with granulosa cells were also spindle-shaped; however, the apical surface appeared convex. Cocultured cells were more densely packed than theca cells cultured alone. The number of both granulosa and theca cells in the cocultured group increased approximately twofold compared to control cells cultured alone. Progesterone content per 1 x 10(5) granulosa cells in 24-h culture medium of the cocultured group was reduced to 40% of that of the control group. In contrast, androstenedione content per 1 x 10(5) theca cells of the cocultured group increased approximately threefold compared to androstenedione content of control group. These results indicate that communication between these two types of follicular cells results in reciprocal modulation of their proliferation, morphology, and function.     

Relationship between AgNOR proteins, Ki-67 antigen, p53 immunophenotype and differentiation markers in archival breast carcinomas.

The present study investigated (i) the relationship between standardised morphometric AgNOR parameters (argyrophilic nucleolar organiser region-associated proteins) and MIB1 growth fraction, and (ii) their correlation with immunohistochemical p53, sex steroid receptor status and histopathological differentiation grade in serial paraffin sections from 39 breast carcinomas. Ten sections were double-stained for AgNOR/MIB1. AgNOR parameters correlated significantly with MIB1 growth fraction and p53 protein expression. Significant inverse correlation was found between proliferation markers and oestrogen/progesterone receptor status and histopathological grade. AgNOR expression was significantly higher in cycling (MIB1 positive) tumour cells, than in resting (MIB1 negative) ones, however with exceptions. We conclude, that standardised AgNOR parameters correlate with markers of increased malignant potential in breast carcinomas. However, AgNORs seem to reflect proliferation independent cellular and nucleolar activity of tumour cells, as well. We recommend the use of standardised AgNOR analysis for obtaining sound results in routine paraffin sections.