Simulation of Rhythmic Tree Growth under Constant Conditions

The observed rhythmic growth of trees under relatively uniform environmental conditions has been ascribed by some authors to endogenous factors, by others to slight fluctuations of environmental factors. A model for the simulation of rhythmic growth was developed based on the assumption that endogenous rhythms can result from feedback interaction between two potentially continuous processes, like shoot and root growth, if the slower process is rate limiting for the faster one. Rhythmic growth in trees would be the consequence of feedback mechanisms needed for maintaining a constant shoot: root ratio. Period length of the rhythms depends upon the rates of the growth processes involved. Environmental factors modify period length through affecting growth rates. Growth patterns predicted by the model compare well with growth measurements of tropical trees. The transition from intermittent to continuous growth, as observed under certain conditions, can be simulated by varying a single parameter in the model.     

Simulation of rice biomass accumulation by an extended logistic model including influence of meteorological factors

The biomass (X) of a biological population, described by growth models, depends only on time (t), i.e., X = f(t). Some parameters in these models are frequently taken as constants, but they may vary with growth processes under different ecological conditions. An extended logistic model including changes in the influence of meteorological factors is developed to simulate biomass accumulation processes of rice sown on different dates. The model may be generally described as X = f (p, t), in which p stands for meteorological factors. The model can be used to generalize population growth processes in experiments carried out under different environments. It is shown that the model may account for 96.6% of the variance of rice biomass on the basis of sowing dates, developmental stage, solar radiation and temperature in the Yangtze River valley in China.     

Influence of factors released from sciatic nerve on adult dorsal root ganglion neurons

Previous experiments have shown that medium conditioned (CM) by denervated peripheral nerve contains a process outgrowth promoting factor (s) for cultured adult frog dorsal root ganglion (DRG) neurons. The present experiments further characterize the influences of these factors on DRG neurons. The growth factors increases average process length by threefold, restricts the number of processes extended from four to two while simultaneously altering the morphology of those processes. Neurons with preexisting processes respond to the factors by significantly increasing the length of 35% of these processes. Only the newly elongated portions of preexisting processes have morphology typical of factor-induced processes, while the previously extended portions retain their original morphology. The number of processes of these neurons remains unchanged. Although composed of two population according to size, neurons in both populations are similarly influenced, suggesting that the factors influence neurons of all sensory modalities. To look at other possible influences of the nerve-released factors, a novel simple culture system has been developed in which concentration gradients of these factors can be established and maintained. The front of the outgrowth-promoting influence in these cultures could be followed over time (up to 9 days) as it affected the process length and morphology of neurons at increasing distances (up to 8 mm) from the source of the factors. The trophic factors may play important roles during regeneration in vivo by influencing the cytoskeletal organization in the cell body and growth cones to bring about a stabilization and consolidation of growth cone membrane of only a limited number of processes resulting in increasing the rate of process elongation. The factors may also serve to direct process outgrowth, which can be examined using the new culture system. 1994 John Wiley & Sons, Inc.     

The role of oxidised regenerated cellulose/collagen in chronic wound repair and its potential mechanism of action

Normal wound healing is a carefully controlled balance of destructive processes necessary to remove damaged tissue and repair processes which lead to new tissue formation. Proteases and growth factors play a pivotal role in regulating this balance, and if disrupted in favour of degradation then delayed healing ensues; a trait of chronic wounds. Whilst there are many types of chronic wounds, biochemically they are thought to be similar in that they are characterised by a prolonged inflammatory phase, which results in elevated levels of proteases and diminished growth factor activity. This increase in proteolytic activity and subsequent degradation of growth factors is thought to contribute to the net tissue loss associated with these chronic wounds.

In this study, we describe a new wound treatment, comprising oxidised regenerated cellulose and collagen (ORC/collagen), which can redress this imbalance and modify the chronic wound environment. We demonstrate that ORC/collagen can inactivate potentially harmful factors such as proteases, oxygen free radicals and excess metal ions present in chronic wound fluid, whilst simultaneously protecting positive factors such as growth factors and delivering them back to the wound.

These characteristics suggest a beneficial role for this material in helping to re-balance the chronic wound environment and therefore promote healing.     

Neurotrophic and growth factors of the brain: regulatory specificity and therapeutic potential

Neurotrophic and growth factors are major subgroups of polypeptides that are synthesized naturally and characterized by the following effects: neuronal differentiation, survey of nerve cell functional integrity, protection against degeneration and lesions, which maintain nerve cells alive. Neurotrophic and growth factors increase the resistance of neuronal tissue to the noxious influence such as hypoxia, exitotoxicity, trauma, stress injury, hypoglycemia, etc. Neurotrophic and growth factors are important in the synaptic plastivcity, activity of learning and cognitive proecesses, regulation of depressive and anxiogenic states. Analysis of clinical and experimental data suggested tha main role of neurotrophins and growth factors in the pathogenesis of ischemic and neurodegenerative brain processes. Some factors are considered as specific markers or targets for concrete diseases; but for any other factors the protective function and therapeutically opportunity for treatment of some pathologies have been revealed. There is some evidence for antiapoptic effects of neurotrophic and growth factors as a basic principle for their neuroprotective function.     

Polypeptide growth factors in embryogenesis and tumor growth

Polypeptide growth factors, which belong to different families (epidermal growth factors, insulin-like growth factors, fibroblast growth factors, transforming growth factors-beta, and some others), were characterized regarding their specific role in embryogenesis and tumor growth. Differences and parallels of the functioning of growth factors in these processes have been noted. Potential significance of the described characteristics of growth factors for directed modulation of embryogenesis and tumor growth is discussed.     

Form and function of grass ring patterns in arid grasslands: the role of abiotic controls

Ring-shaped growth patterns commonly occur in resource-limited arid and semi-arid environments. The spatial distribution, geometry, and scale of vegetation growth patterns result from interactions between biotic and abiotic processes, and, in turn, affect the spatial patterns of soil moisture, sediment transport, and nutrient dynamics in aridland ecosystems. Even though grass ring patterns are observed worldwide, a comprehensive understanding of the biotic and abiotic processes that lead to the formation, growth and breakup of these rings is still lacking. Our studies on patterns of infiltration and soil properties of blue grama (Bouteloua gracilis) grass rings in the northern Chihuahuan desert indicate that ring patterns result from the interaction between clonal growth mechanisms and abiotic factors such as hydrological and aeolian processes. These processes result in a negative feedback between sediment deposition and vegetation growth inside the bunch grass, which leads to grass die back at the center of the grass clump. We summarize these interactions in a simple theoretical and conceptual model that integrates key biotic and abiotic processes in ring formation, growth and decline.     

Fatty acid-induced angiogenesis in first trimester placental trophoblast cells: Possible roles of cellular fatty acid-binding proteins

Angiogenesis is involved in the growth of new blood vessels from the existing one. Consequently, angiogenesis plays an indispensable role in tissue growth and repair including early placentation processes. Besides angiogenic growth factors (vascular endothelial growth factor (VEGF), angiopoietin-like 4 (ANGPTL4), placental growth factor (PlGF), platelet derived growth factor (PDGF), fibroblast growth factors (FGF)), dietary fatty acids (c>16) also directly or indirectly modulate angiogenic processes in tumors and other cell systems. Usually n − 3 fatty acids inhibit whereas n − 6 fatty acids stimulate angiogenesis in tumors and other cells. Contrary to this, docosahexaenoic acid, 22:6n − 3 (DHA) and other fatty acids including conjugated linoleic acid stimulate angiogenesis in placental first trimester cells. In addition to the stimulation of expression of major angiogenic factors such as VEGF and ANGPTL4, fatty acids also stimulate expression of intracellular fatty acid-binding proteins (FABPs) FABP-4 and FABP-3 those are known to directly modulate angiogenesis. Emerging data indicate that FABPs may be involved in the angiogenesis process. This paper reviews the fatty acid mediated angiogenesis process and the involvement of their binding proteins in these processes.     

Eclectic mechanisms of heme regulation of hematopoiesis

Regulatory features of heme (ferroprotoporphyrin IX) on hematopoietic growth/differentiation and related processes are reviewed. It is emphasized that expressions of specific erythroid and nonerythroid heme biosynthetic and degradatory enzymes are required, and the regulatory processes whereby this occurs is considered. The specificity of heme, relationship to cellular events such as differentiation, response to growth factors, oncogene and receptor expression, and how heme counteracts toxic effects such as viral growth are all discussed. The significance of heme in the hemopoietic bone marrow microenvironment and growth factor network are considered. Finally, the third pathway for arachidonic acid metabolism via the heme-cytochrome P450 monooxygenase system, in addition to cyclooxygenase and lipoxygenase, by bone marrow adherent cells and its role in cellular differentiation is briefly reviewed.     

Effects of insulin on cellular growth and proliferation

Insulin stimulates the growth and proliferation of a variety of cells in culture. The growth-stimulatory effects of insulin are observed in G_o/G_l arrested cells limited for serum growth factors or essential nutrients, and in cells growing in hormone-supplemented serum-free media. Some, but not all, of the effects of insulin on growth require superphysiological concentrations of insulin. The action of insulin on growth is synergistic with the action of other hormones and growth factors, including FGF, PDGF, PGF_2α and vasopressin. This observation, as well as other observations regarding the temporal sequence of action of growth factors, suggests that different growth factors act on different intracellular biochemical events. Several hypotheses have been proposed to explain the effect of insulin on cellular proliferation, including regulation of essential metabolic processes and interaction of insulin with receptors for insulin-like growth factors. Evidence supporting these various hypotheses is reviewed. In addition to the growth-stimulatory effect of insulin observed in cell culture, a number of clinical examples suggest that insulin is an important growth-regulating hormone during fetal development.     

Effects of neurotrophic factors and cell substrates on the differentiation of a sympathoadrenal progenitor cell line

The detailed spatial organization of cytoskeletal proteins in an immortalized sympathoadrenal precursor cell line, termed MAH, was studied when the cells were grown on cellular substrates and when treated with combinations of recombinant nerve growth factor, ciliary neurotrophic factor and basic fibroblast growth factor. In response to growth factors, MAH cells expressed appropriate distributions of phosphorylated and non-phosphorylated neurofilaments, and dendrite and axon specific microtubule associated proteins. Sequential stages of maturation and axon formation were identified as the MAH cells established neuronal polarity and developed into sympathetic-like neurons. Combinations of the growth factors initiated growth associated protein-43 expression in processes and promoted the MAH cells to acquire sympathetic-like neuron characteristics with long, thin processes that branched and often terminated in elaborate growth cones. When treated with the three trophic factors, 15% of the MAH cells differentiated into sympathetic-like neurons, in contrast to less than 10% when cultured with ciliary neurotrophic factor plus nerve growth factor. An enhanced cholinergic phenotype was evident in the MAH cells when grown with ciliary neurotrophic factor. MAH cells also expressed neuron-specific markers when co-cultured on enriched substrates of smooth muscle, fibroblasts or Schwann cells. The results indicate that this sympathoadrenal cell lineage, carrying the v-myc oncogene, can express appropriate cytoskeletal markers in the process of neuronal differentiation when induced by neurotrophic factors or by specific cellular conditions in vitro.     

Polypeptide Growth Factors in Embryogenesis and Tumor Growth

Polypeptide growth factors belonging to different families (epidermal growth factors, insulin-like growth factors, fibroblast growth factors, transforming growth factors-, and some others), were characterized regarding their specific role in embryogenesis and tumor growth. Differences and parallels in the functioning of growth factors in these processes have been noted. The potential significance of the described characteristics of growth factors for directed modulation of embryogenesis and tumor growth is discussed.     

Extracellular and cell-matrix interaction in pathology

A lot of physiological processes including cell proliferation, cell migration, and differentiation are regulated by intercellular and cell-matrix interaction. The misbalance of intercellular and stroma-epithelial interaction is one of main factor of initiation of different pathological processes. Nonhealing wounds (chronic inflammation) and adenocarcinomas, despite the different external features, have many general inner features: cell proliferation, survival, cell migration, differentiation induced by cocktail of different growth factors and cytokines which promote inflammation and angiogenesis. Various stroma components including extracellular matrix are active participants of wound healing and cancer growth. The changes of pl-integrins distribution and cytokine expression, TGFbeta in particular, influence the development of pathological processes. It is possible to consider these factors as potential pharmacological targets.     

Growth factors which affect bone

The coupled processes of bone resorption and bone formation occur throughout life. New research suggests that some well-characterized growth factors affect bone and that transforming growth factors and tumor-derived growth factors may also influence bone growth and remodeling.     

Differential regulation of tissue transglutaminase in rat hepatoma cell lines McA-RH7777 and McA-RH8994: Relation to growth rate and cell death

Close correlation between tissue transglutaminase (tTG) induction and growth regulation and/or cell death processes has been suggested in many cell lineages. In this study, the regulation of the tTG levels by various growth and differentiation factors and its relation to growth rate and cell death processes were investigated in two rat hepatoma cell lines, McA-RH7777 and McA-RH8994, using a monoclonal antibody against liver tTG. Transforming growth factor-β1 (TGF-β1) and retinoic acid (RA) each increased tTG to the level of 8- to 32-fold above that of control cultures in both cell lines after 72-h treatment. Dexamethasone (DEX) induced a 16- to 32-fold of tTG in McA-RH8994 cells while it did not change the enzyme level in McA-RH7777 cells. Simultaneous addition of DEX and RA increased the tTG level to more than 50-fold in McA-RH7777 cells as well as McA-RH8994 cells. Other factors, such as TGF-α, hepatocyte growth factor, dimethyl sulfoxide, and protein kinase C activator, did not show significant increases of the tTG levels. Although tTG induction by TGF-β1 or DEX appeared to be correlated with their growth suppressive effects, RA increased the tTG level without suppressing the growth rate of hepatoma cells. TGF-β1 was also shown to induce cell death in both cell lines. Our results demonstrate that RA and DEX are capable of modulating the TGF-β1-induced cell death processes independent of the tTG levels. We present evidence here that tTG induction by itself is not the direct cause of growth suppression and cell death in these hepatoma cells.     

Bioactive molecules in milk and their role in health and disease: the role of transforming growth factor-beta

Human breast milk is rich in nutrients, hormones, growth factors and immunoactive molecules, which influence the growth, development and immune status of the newborn infant. Although several of these factors are also present in bovine milk, the greater susceptibility of the formula-fed infant to infection and disease and the development of allergy is often attributed to the reduced level of protective factors in milk formulas. Nevertheless, modifying manufacturing processes may preserve the biological activity of some bioactive molecules in end products. Transforming growth factor (TGF)-beta is one such molecule. TGF-beta is a polypeptide, which has been described in both human and bovine milk. It is implicated in many processes, including epithelial cell growth and differentiation, development, carcinogenesis and immune regulation. The present article discusses the biological activity of TGF-beta2 that has been preserved and activated in a cow's milk-based product. More specifically, it addresses possible mechanisms of action in the intestinal lumen and speculates on how milk products containing naturally occurring TGF-beta2 could be exploited in functional foods for the infant or as therapies for specific intestinal diseases.