Proliferation controls in a linear growth system: theoretical studies of cell division in the cartilage growth plate

The columnar arrangement of dividing cells in the epiphyseal cartilage plates of growing bones provides a model of a linear proliferation system. One factor which determines the rate of cell production, and hence the rate of growth, is the size of the proliferating population. In this one dimensional system this size is equal to the length of the proliferation zone. Two possible mechanisms for a differentiation control that sets a limit to the length of this zone have been tested in computer simulations. While a diffusion gradient control is consistent with cell kinetic measurements a division limit based on an inheritable growth substance is shown to require further development before the model fits experimental data.Cell division in the columns produces linear clones of cells. If the final length of a bone is set by a limit on the number of divisions that the cartilage stem cells can make, then the number of cells per clone is crucial in determining overall bone growth. The parameters that affect linear clone size have been investigated in computer simulations. Clone size depends largely on the relative division rate of stem cells to proliferation zone cells — but the data on stem cell division rates are generally unreliable.The analysis could be applied to other linear proliferating systems.     

Regulation of breast cancer cell cycle progression by growth factors, steroids and steroid antagonists

The control of human breast cancer cell proliferation in vitro is known to involve complex interactions between steroid hormones, peptide hormones and growth factors. Little is known, however, of the mechanisms by which these factors, alone or in combination, control cell cycle progression and the expression of specific genes involved in cell cycle control. A pre-requisite for such studies is a cellular system in which non-proliferating or slowly proliferating cells can be maintained in a defined environment and stimulated to progress through the cell cycle by addition of hormones and growth factors. Such a system has been developed for T-47D human breast cancer cells: quiescent or slowly proliferating cells maintained in a serum-free medium can be stimulated to increase their rate of cell cycle progression upon a single addition of insulin, IGF-I, EGF, TGF or bFGF. Oestradiol alone was ineffective but caused a significant increase in % S phase cells when added in the presence of insulin. Progestins, in the presence or absence of insulin, had a biphasic effect with an initial increase in cell cycle progression followed by cell cycle arrest. Both antioestrogens and the antiprogestin, RU 486, in the absence of oestrogen or progestin, were potent inhibitors of insulin-induced proliferation. Increases in cell cycle progression were invariably accompanied by acute increases in c-fos and c-myc mRNA levels. Induction of c-myc by oestrogen and 3rogestin was inhibited by antioestrogens and RU 486, respectively. These data illustrate that the culture of breast cancer cells in a serum-free, chemically defined environment provides an excellent model in which to define the role of individual factors involved in breast cancer growth control. The biological data derived from this system provide a basis for identifying and characterizing genes involved in the control of cell cycle progression in human breast cancer.     

Intrinsic and extrinsic control of growth in developing organs

The growth rate and final size of developing organs is controlled by organ-intrinsic mechanisms as well as by hormones and growth factors that originate outside the target organ. Recent work on Drosophila imagined discs and other regenerating systems has led to the conclusion that the intrinsic growth-control mechanism that controls regenerative growth depends on position-specific interactions between cells and their neighbors, and that these interactions also control pattern formation. According to this interpretation, local growth by cell proliferation is stimulated when cells with disparate positional information are confronted as a result of grafting or wound healing. This local growth leads to intercalation of cells with intervening positional values until the positional information discontinuity is eliminated. When all discontinuities have been eliminated from a positional field, growth stops. In this article we consider the possibility that organ growth during normal development may be controlled by an intercalation mechanism similar to that proposed for regenerative growth. Studies of imaginal disc growth are consistent with this suggestion, and in addition they show that the cell interactions thought to control growth are independent of cell lineage. Developing organs of vertebrates also show intrinsic growth-control mechanisms, as demonstrated by the execution of normal growth programs by immature organs that are transplanted to fully grown hosts or to hosts with genetically different growth parameters. Furthermore, these organ-intrinsic mechanisms also appear to be based on position-specific cell interactions, as suggested by the growth stimulation seen after partial extirpation or rearrangement by grafting. In organs of most adult vertebrates, the organ-intrinsic growth-control system seems to be suppressed as shown by the loss of regenerative ability, although it is clearly retained in the limbs, tails and other organs of salamanders. The clearest example of an extrinsic growth regulator is growth hormone, which plays a dominant role along with insulin-like growth factors, thyroid hormone and sex hormones in supporting the growth of bones and other organs in postnatal mammals. These hormones do not appear to regulate prenatal growth, but other hormones and insulin-like growth factors may be important prenatally. The importance of other growth factors in regulating organ growth in vivo remains to be established. It is argued that both intrinsic and extrinsic factors control organ growth, and that there may be important interactions between the two types of control during development.     

Endocrine regulation of the growth plate

Longitudinal bone growth occurs at the growth plate by endochondral ossification. Within the growth plate, chondrocyte proliferation, hypertrophy, and cartilage matrix secretion result in chondrogenesis. The newly formed cartilage is invaded by blood vessels and bone cells that remodel the newly formed cartilage into bone tissue. This process of longitudinal bone growth is governed by a complex network of endocrine signals, including growth hormone, insulin-like growth factor I, glucocorticoid, thyroid hormone, estrogen, androgen, vitamin D, and leptin. Many of these signals regulate growth plate function, both by acting locally on growth plate chondrocytes and also indirectly by modulating other endocrine signals in the network. Some of the local effects of hormones are mediated by changes in paracrine factors that control chondrocyte proliferation and differentiation. Many human skeletal growth disorders are caused by abnormalities in the endocrine regulation of the growth plate. This review provides an overview of the endocrine signals that regulate longitudinal bone growth, their interactions, and the mechanisms by which they affect growth plate chondrogenesis.     

Collagen IX-deficiency seriously compromises growth cartilage development in mice.

For a large part, skeletal development, growth, and repair occur by endochondral ossification which comprises an orderly sequence of consecutive steps of proliferation and late differentiation of chondrocytes. After vascular invasion into hypertrophic cartilage, the tissue is remodelled into bone. At all stages, the process is under tight environmental control exerted by a combination of regulators, including nutritional supply and signalling through growth factors, hormones, and cell-matrix-interactions. Therefore, genetic elimination of collagen IX, a stabilizing component of the periphery of thin cartilage fibrils, is expected to compromise extracellular matrix properties and, hence, the chondrocyte environment required for normal cartilage development and homeostasis. Here, we have shown that growth plate cartilage morphology is markedly disturbed in mice lacking collagen IX. Abnormalities were most prominent in late proliferative, pre-hypertrophic, and hypertrophic zones whereas resting and early proliferative zones were less affected. In central epiphyseal regions of long bones, newborn animals show grossly abnormal areas with strongly reduced cell numbers, irregular distribution of glycosaminoglycans in the extracellular matrix, and a profoundly disturbed columnar arrangement of chondrocytes with an irregular beta1 integrin immunostaining. As a result, all long bones are shorter and broader in newborn Col9a1-/- mice. Remarkably, these abnormalities are attenuated in adult mice, but the number of cells per area still is too low due to reduced cell proliferation.     

Hormone dependence in breast and prostate tumor cell lines

Knowledge about the role of sex hormones in the control of cell proliferation and cell-type specific protein synthesis is mainly collected by using cell culture techniques. The adoption of cell culture models addressed at defining these issues is due to the uncomplicated assessment of reliable proliferation-related parameters. Established cell lines derived from estrogen and androgen sensitive tissues, have been used in proliferation studies for more than thirty years. The data gathered so far can be summarized in three following working hypotheses: the direct and indirect-positive hypotheses and the indirect-negative hypothesis. Further characterization and assessment of the hormone dependence of growth factors and growth inhibitors will allow for the mechanistic understanding of the regulation of cell proliferation by sex hormones.     

Comparative endocrinology-paracrinology-autocrinology of human adult large vessel endothelial and smooth muscle cells

Summary Endothelial and smooth muscle cells were isolated from human adult large blood vessels to compare their proliferative response to hormones and growth factors. Neural extracts and the medium from differentiated hepatoma cells were used as concentrated sources of required hormones and growth factors that supported both cell types. Active hormones and growth factors were identified from the neural extracts and hepatoma medium by substitution or direct isolation and biochemical characterization. Epidermal growth factor, lipoproteins, and heparin-binding growth factors elicited growth-stimulatory effects on both endothelial and smooth muscle cells. Both types of human vascular cells displayed 7600 to 8600 specific heparin-binding growth factor receptors per cell with a similar apparent dissociation constant (Kd) of 200 to 250 pM. Heparin modified the response of both endothelial and smooth muscle cells to heparin-binding growth factors dependent on the type of heparin-binding growth factor and amount of heparinlike material present. In addition, heparin exerted a growth factor-independent inhibition of smooth muscle cell proliferation. Platelet-derived growth factor, insulinlike growth factors, and glucocorticoid specifically supported proliferation of smooth muscle cells with no apparent effect on endothelial cell proliferation. Growth-factorlike proteinase inhibitors had an impact specifically on endothelial cell proliferation. Transforming growth factor beta was a specific inhibitor of endothelial cells, but had a positive effect on smooth muscle cell proliferation. The results provide a framework for differential control of the two vascular cell types at normal and atherosclerotic blood vessel sites by the balance among positive and negative effectors of endocrine, paracrine and autocrine origin. This research was supported by NIH grants CA37589, HL33847, and AM35310 from the National Institutes of Health, Bethesda, MD; grant 1718 from the Council for Tobacco Research; and a grant from RJR/Nabisco, Inc.     

Physiology and pathophysiology of the growth plate

Longitudinal growth of the skeleton is a result of endochondral ossification that occurs at the growth plate. Through a sequential process of cell proliferation, extracellular matrix synthesis, cellular hypertrophy, matrix mineralization, vascular invasion, and eventually apoptosis, the cartilage model is continually replaced by bone as length increases. The regulation of longitudinal growth at the growth plate occurs generally through the intimate interaction of circulating systemic hormones and locally produced peptide growth factors, the net result of which is to trigger changes in gene expression by growth plate chondrocytes. This review highlights recent advances in genetics and cell biology that are illuminating the important regulatory mechanisms governing the structure and biology of the growth plate, and provides selected examples of how studies of human mutations have yielded a wealth of new knowledge regarding the normal biology and pathophysiology of growth plate cartilage.     

The Effect of Dexamethasone and Triiodothyronine on Terminal Differentiation of Primary Bovine Chondrocytes and Chondrogenically Differentiated Mesenchymal Stem Cells

The newly evolved field of regenerative medicine is offering solutions in the treatment of bone or cartilage loss and deficiency. Mesenchymal stem cells, as well as articular chondrocytes, are potential cells for the generation of bone or cartilage. The natural mechanism of bone formation is that of endochondral ossification, regulated, among other factors, through the hormones dexamethasone and triiodothyronine. We investigated the effects of these hormones on articular chondrocytes and chondrogenically differentiated mesenchymal stem cells, hypothesizing that these hormones would induce terminal differentiation, with chondrocytes and differentiated stem cells being similar in their response. Using a 3D-alginate cell culture model, bovine chondrocytes and chondrogenically differentiated stem cells were cultured in presence of triiodothyronine or dexamethasone, and cell proliferation and extracellular matrix production were investigated. Collagen mRNA expression was measured by real-time PCR. Col X mRNA and alkaline phosphatase were monitored as markers of terminal differentiation, a prerequisite of endochondral ossification. The alginate culture system worked well, both for the culture of chondrocytes and for the chondrogenic differentiation of mesenchymal stem cells. Dexamethasone led to an increase in glycosaminoglycan production. Triiodothyronine increased the total collagen production only in chondrocytes, where it also induced signs of terminal differentiation, increasing both collagen X mRNA and alkaline phosphatase activity. Dexamethasone induced terminal differentiation in the differentiated stem cells. The immature articular chondrocytes used in this study seem to be able to undergo terminal differentiation, pointing to their possible role in the onset of degenerative osteoarthritis, as well as their potential for a cell source in bone tissue engineering. When chondrocyte-like cells, after their differentiation, can indeed be moved on towards terminal differentiation, they can be used to generate a model of endochondral ossification, but this limitation must be kept in mind when using them in cartilage tissue engineering application.     

Recent trends in research on differentiation of hematopoietic cells and lymphokines (hemopoietins).

A recent trend in hematological research fields has been to isolate and characterize hematopoietic stem cells/progenitors and their growth factors (hemopoietins) to gain a much better understanding of the nature of the stem cell and the mechanisms regulating its development. It is generally accepted that all the various types of blood cells develop from a single progenitor called a hematopoietic stem cell. Quantitative studies of the function of hemopoietic stem cells began two decades ago with the development of a spleen colony assay, and then, clonal cell culture techniques for committed progenitors were developed with several models for hematopoietic differentiation being proposed. Within the last few years, some hormones have been discovered that are known as hematopoietic growth hormones or hemopoietins, each of which is of protein nature and causes specific classes of blood cells to be made and primed. These hormones also enhance the function of the mature cells, the genes of which have recently been cloned. On the other hand, long-term bone marrow culture has recently permitted detailed investigations of the relationship between hematopoietic cells and the microenvironment in which they are found, e.g. stromal cells, in vitro, relating to the regulation of cell proliferation and differentiation. Further, in hematological fields, other bioactive factors including differentiation-inducing compounds, e. g. bioactive glycosphingolipids, and leukocyte-endothelial cell recognition molecules (adhesion receptors) have been discovered, the molecular mechanism(s) of which have yet to be elucidated. This communication focuses on recent advances in research on soluble hemopoietins and other bioactive factors relating to differentiation-induction and to cell-to-cell recognition.     

Muscle cell culture as a tool in animal growth research

Muscle cell culture techniques have been used for several years in research on muscle growth and development. Several types of culture systems have been devised, including primary cultures from embryonic or postnatal muscle and myogenic cell lines. In addition, serum-free and serum-containing media have been developed to address specific muscle development questions. Many of these questions center around muscle cell differentiation and muscle cell physiology; and, more recently, muscle cell cultures have been used as bioassay tools for examining growth physiology in domestic animals. In our laboratory, skeletal muscle satellite cells have been studied in vitro to evaluate the effect of several protein hormones and growth factors on satellite cell proliferation and differentiation. Of the hormones examined, only the insulin-like growth factors/somatomedins and fibroblast growth factor have been shown to have a stimulatory effect on proliferation that could be physiologically significant. None of the major anterior pituitary hormones interacted directly with satellite cells to stimulate proliferation. With advances in serum-free medium formulations and cell separation techniques, more information can be obtained from experiments with muscle cell cultures. With appropriate design and interpretation, our knowledge of muscle growth in domestic animals will be expanded.     

Induction of proliferation or hypertrophy of chondrocytes in serum-free culture: the role of insulin-like growth factor-I, insulin, or thyroxine

In bone forming cartilage in vivo, cells undergo terminal differentiation, whereas most of the cells in normal articular cartilage do not. Chondrocyte hypertrophy can be induced also in vitro by diffusible signals. We have identified growth factors or hormones acting individually on 17-d chick embryo sternal chondrocytes cultured in agarose gels under strictly serum-free conditions. Insulin-like growth factor I or insulin triggered the first steps of chondrocyte maturation, i.e., cell proliferation and increased matrix deposition while the chondrocytic phenotype was maintained. However, cells did not progress to the hypertrophic stage. Proliferation and stimulated collagen production was preceded by a lag period, indicating that synthesis of other components was required before cells became responsive to insulin-like growth factor I or insulin. Very small amounts of FBS exerted effects similar to those of insulin-like growth factor I or insulin. However, FBS could act directly and elicited hypertrophy when constituting greater than 1% of the culture media. Basic FGF has been claimed to be the most potent chondrocyte mitogen, but had negligible effects under serum-free conditions. The same is true for PDGF, a major serum-mitogen. Under the direction of thyroxine, cells did not proliferate but became typical hypertrophic chondrocytes, extensively synthesizing collagen X and alkaline phosphatase.     

Adrenomedullin--a regulator of bone formation

Bone growth and maintenance are highly regulated processes. Throughout life, bone constantly undergoes remodelling, maintaining a balance between bone formation by osteoblasts and bone resorption by osteoclasts. This balance depends on the coordinated activities of many systemic hormones and locally acting factors in the bone microenvironment. Understanding the mechanisms of action of these factors provides a better appreciation of the cellular and molecular basis of bone remodelling.Adrenomedullin has recently been found to stimulate the proliferation of osteoblasts in vitro, and to increase indices of bone formation when administered either locally or systemically in vivo. Adrenomedullin receptors, as well as adrenomedullin itself, are expressed in primary osteoblasts and in osteoblast-like cell lines. In this paper we discuss the anabolic effect of adrenomedullin in bone, and present new evidence for a possible role of adrenomedullin in the regulation of cartilage cells. We show that adrenomedullin stimulates proliferation of primary chondrocytes in culture and that mRNA for adrenomedullin and for adrenomedullin receptors are expressed in these cells.Studies of structure-activity relationships have demonstrated that osteotropic effects of adrenomedullin can be retained in peptide fragments of the molecule which lack the parent molecule's vasodilatory properties. Thus, these small peptides, or their analogues, are attractive candidates as anabolic therapies for osteoporosis.     

Decrease in cytosolic free Ca2+ and enhanced proteoglycan synthesis induced by cartilage derived growth factors in cultured chondrocytes

Cartilage-derived growth factors, enhance proteoglycan synthesis in cultured chick-embryo chondrocytes, and have almost no effect on cell proliferation. Addition of cartilage derived growth factors to cartilage cells loaded with the fluorescent Ca2+ indicator quin 2, caused a rapid, concentration dependent decrease in cytoplasmic free Ca2+. This decrease persisted also in Ca2+-free medium, indicating that it is not mediated by a decrease in the passive permeability of cell membrane to Ca2+. Addition of the Ca2+ ionophore A23187, with or without cartilage derived factors, caused an increase in cytoplasmic free Ca2+ together with inhibition of proteoglycan synthesis and enhanced cell proliferation. The results may indicate that whereas cell proliferation in chondrocytes is signaled by an increase in cytoplasmic Ca2+ ([Ca2+]in), proteoglycan synthesis is signaled by a decrease in [Ca2+]in. The data lead to suggesting a mechanism for antagonistic regulation of cell proliferation and the expression of the differentiated state.     

Osteoarthritis

Osteoarthritis (OA) is characterized by degeneration of articular cartilage, limited intraarticular inflammation with synovitis, and changes in peri-articular and subchondral bone. Multiple factors are involved in the pathogenesis of OA, including mechanical influences, the effects of aging on cartilage matrix composition and structure, and genetic factors. Since the initial stages of OA involve increased cell proliferation and synthesis of matrix proteins, proteinases, growth factors, cytokines, and other inflammatory mediators by chondrocytes, research has focused on the chondrocyte as the cellular mediator of OA pathogenesis. The other cells and tissues of the joint, including the synovium and subchondral bone, also contribute to pathogenesis. The adult articular chondrocyte, which normally maintains the cartilage with a low turnover of matrix constituents, has limited capacity to regenerate the original cartilage matrix architecture. It may attempt to recapitulate phenotypes of early stages of cartilage development, but the precise zonal variations of the original cartilage cannot be replicated. Current pharmacological interventions that address chronic pain are insufficient, and no proven structure-modifying therapy is available. Cartilage tissue engineering with or without gene therapy is the subject of intense investigation. There are multiple animal models of OA, but there is no single model that faithfully replicates the human disease. This review will focus on questions currently under study that may lead to better understanding of mechanisms of OA pathogenesis and elucidation of effective strategies for therapy, with emphasis on mechanisms that affect the function of chondrocytes and interactions with surrounding tissues.     

Onset of direct 17-beta estradiol effects on proliferation and c-fos expression during oncogenesis of endometrial glandular epithelial cells

In normal endometrial glandular epithelial cells (GEC), 17beta-estradiol (E2) enhances proliferation and c-fos expression only in the presence of growth factors. On the contrary, growth factors are not required for the E2 effects in cancerous cells. Thus, a repression of E2 action could exist in normal cells and be turned off in cancerous cells, allowing a direct estrogen-dependent proliferation. To verify this hypothesis, we established immortalized and transformed cell models, then investigated alterations of E2 effects during oncogenesis. SV40 large T-antigen was used to generate immortalized GEC model (IGEC). After observation of telomerase reactivation, IGEC model was transfected by activated c-Ha-ras to obtain transformed cell lines (TGEC1 and TGEC2). The phenotypic, morphological, and genetic characteristics of these models were determined before studying the E2 effects. In IGEC, the E2 action on proliferation and c-fos expression required the presence of growth factors, as observed in GECs. In TGECs, this action arose in the absence of growth factors. After IGEC transformation, the activation of ras pathway would substitute the priming events required for the release of repression in GEC and IGEC and thus permit direct E2 effects. Our cell models are particularly suitable to investigate alterations of gene regulation by E2 during oncogenesis.     

The regulation of expression of mouse mammary tumor virus DNA by steroid hormones and growth factors

Mouse mammary tumor virus (MMTV) expression is associated with hyperplastic alveolar growth and subsequent development of mammary cancers in the mouse. The expression of this virus is also controlled by factors involved in the normal proliferation and differentiation of the mammary epithelium. During pregnancy when the mammary gland undergoes massive proliferation, MMTV expression is increased. Steroid hormones and growth factors that play an important role in the proliferation of mammary gland cells are responsible for the increased MMTV expression. In sarcomatous transformation of mouse mammary epithelial cells, MMTV expression is repressed. This repression is due to negative control of MMTV expression by transforming growth factor-beta (TGF beta). This growth factor is produced in high amounts when mammary epithelial cells progress into the transformed state. The expression of MMTV is therefore under multiple control by steroid hormones and growth factors.     

Hormonal regulation of root growth: integrating local activities into global behaviour

To date, plant researchers have probed the control of root growth by studying the roles of individual regulatory components or cellular processes. However, recent studies in the Arabidopsis (Arabidopsis thaliana) root have shown that different hormones control organ growth by regulating specific growth processes (cell proliferation, differentiation or expansion) in distinct tissues. We discuss key issues raised by these new insights and hypothesise that novel tissue-to-tissue signals exist to coordinate organ growth. We conclude by describing how multiscale models can help probe the interplay between the different scales at which hormones and their regulatory networks operate in different cells and tissues. Such approaches promise to generate new insights into the mechanisms that control root growth.     

Direct analysis of growth factor requirements for isolated human fetal hepatocytes

Summary Hepatocytes were isolated from human fetal liver in order to analyze the direct effects of growth factors and hormones on human hepatocyte proliferation and function. Mechanical fragmentation and then dissociation of fetal liver tissue with a collagenase/dispase mixture resulted in high yield and viability of hepatocytes. Hepatocytes were selected in arginine-free, ornithine-supplemented medium and defined by morphology, albumin production and ornithine uptake into cellular protein. A screen of over twenty growth factors, hormones, mitogenic agents and crude organ and cell extracts for effect on the stimulation of hepatocyte growth revealed that EGF, insulin, dexamethasone, and factors concentrated in bovine neural extract and hepatoma cell-conditioned medium supported attachment, maintenance and growth of hepatocytes on a collagen-coated substratum. The population of cells selected and defined as differentiated hepatocytes had a proliferative potential of about 4 cumulative population doublings. EGF and insulin synergistically stimulated DNA synthesis in the absence of other hormones and growth factors. Although neural extracts enhanced hepatocyte number, no effect on DNA synthesis of neural extracts or purified heparin-binding growth factors from neural extracts could be demonstrated in the absence or presence of defined hormones, hepatoma-conditioned medium or serum. Hepatoma cell-conditioned medium had the largest impact on both hepatocyte cell number and DNA synthesis under all conditions. Dialyzed serum protein (1 mg/ml) at 10 times higher protein concentration had a similar effect to hepatoma cell-conditioned medium (100 μg/ml). The results suggest that hepatoma cell conditioned medium may be a concentrated and less complicated source than serum for purification and characterization of additional normal hepatocyte growth factors. This work was supported by NIH grant DK35310. Editor’s statement Many investigators have struggled with the special problems associated with culture of differentiated hepatocytes. In this paper attention is given to the specific growth factor requirements for fetal human hepatocytes. The observation that factors from hepatoma conditioned medium or neural extracts enhanced the growth of the cells may indicate that additional growth factors are to be identified that are important in the survival and proliferation of hepatocytes, and may also indicate that the malignant transformation of these cells may involve the production of autocrine growth stimulators.