This article summarizes research relevant to the possible association between aberrant production of hemopoietins or hemopoietin-activated signals and the neoplastic growth of leukemic cells.

The induction of beta-lactamase in Gram-negative bacteria in vitro has been established. It is possible to distinguish between high and low beta-lactamase inducers in vitro. This differentiation is clinically irrelevant because induction has little effect on the treatment of a bacterial infection with beta-lactam antibiotics. Regardless of the amount of induced beta-lactamase, the kill kinetics are usually not affected. In mutated cells, the regulatory mechanism is destroyed by inactivation of the relevant genes with respect to their regulatory function, particularly by inactivation of the amp D gene. These mutants overproduce the beta-lactamase constitutively, which results in an enzyme level that significantly exceeds the induced level. The induction process is probably not the cause of clinical failures associated with the use of beta-lactam antibiotics. It is concluded that the selection of resistant mutants with constitutive overproduction of beta-lactamase is the reason for most of these treatment failures.

C1q, the collagen-like and Fc-recognizing component of the complement system, is mainly synthesized in macrophages and epithelial cells. Inhibitors of collagen biosynthesis, known to inhibit the post-translational hydroxylation of proline and lysine residues, were as effective in macrophages as inhibitors of C1q synthesis and secretion as has been described for collagen. This indicates that post-translational processing of C1q is dependent upon its collagen portions and triple helical formation within the cells. The macrophage-derived C1q is immuno- and physicochemically identical with serum C1q indicating that macrophages have to be considered as a major source for serum C1q. This was recently confirmed by Northern blot analysis using a cDNA probe for the B-chain of murine C1q. In contrast, an extremely weak signal was found in kidney, lung, gut, muscle and liver RNA. Besides the 11 S C1q molecule macrophages also synthesize a low molecular weight (LMW) form of C1q. The biological function of this 4 S LMW-C1q is still unclear. Macrophage-derived and secreted C1q is reinserted into the macrophage membrane. It is unlikely that the membranous form of C1q is bound via C1q-receptors into the membrane of macrophages since the B-chain of membrane-associated C1q is structurally different to that of fluid-phase C1q. The demonstration of a distinct membrane form of C1q supports earlier functional studies which implicated C1q as a membrane-associated molecule with receptor functions for those molecules which also interact with fluid-phase C1q, such as polyanions, the Fc portions of immune complexes, and bacteria (LPS and outer membrane proteins, OMP).

Many chemicals produce their biological effects by binding to specific 'receptor' macromolecules on or within the cell. Much current research in pharmacology and toxicology is aimed at the molecular mechanisms by which such ligand-receptor interactions elicit cellular responses. Studies of the mechanism by which TCDD (dioxin) activates CYP1A1 gene transcription demonstrate the usefulness of applying recombinant DNA and gene transfer methods to analyse these fundamental problems. In this article, James Whitlock summarizes the evidence that the Ah receptor functions as a ligand-dependent transcription factor during the induction of aryl hydrocarbon hydroxylase activity by TCDD.

Biosynthesis of C1r and C1s subcomponents has been studied using monocytes and macrophages, hepatocytes and hepatoma cell lines or fibroblasts. Both proteins have been detected in supernatants and cell lysates as proenzymic monocatenar molecules. C1r and C1s were secreted by stimulated monocytes and by Hep G2 cells, according to a 1:1 stoichiometry. Monocyte C1s secretion was enhanced by lymphokines, such as alpha- or gamma-interferon or by placental soluble factors. Expression of both proteins was coordinately modulated by a newly purified 14 kDa lymphokine at a pretranslational level. Data from in vitro RNA translation are discussed.

C1-inhibitor (C1-inh) is synthesised and secreted by at least four cell types: hepatocytes, mononuclear phagocytes, fibroblasts and umbilical vein endothelial cells. The production of this protein by monocytes/macrophages and Hep G2 cells has been studied in great detail. Environmental factors alter C1-inh synthesis by these cells. A number of agents which inhibit monocyte C1-inh production (such as histamine, PGE2 C5a des arg and serum treated immune complexes) bind to membrane receptors, activate adenylate cyclase, elevate intracellular cAMP and activate cAMP-dependent protein kinase. Elevation of monocyte cAMP levels is associated with decreased C1-inh secretion by these cells and reduced C1-inh mRNA levels. These changes can be seen within 8 hours of exposure. Stimulation of monocyte C1-inh synthesis occurs after the addition of agents which induce the formation of sodium ion and calcium ion channels, activate the phosphatidyl inositol cycle and activate protein kinase C (immune-complexes, carbamylcholine and phenylephrine). Agents which act directly on protein kinase C (phorbol myristate acetate) also stimulate C1-inh synthesis. Amongst the most potent stimulators of monocyte and Hep G2 C1-inh synthesis are the interferons (Ifns) Ifn alpha, Ifn beta and Ifn gamma. These are known to bind to specific receptors on cells (Ifn alpha and beta binding to Type I Ifn receptors and Ifn-gamma binding to type II Ifn receptors). At least two mechanisms by which Ifn receptor-ligand interaction elicit their effects exist. These are: 1) binding of an activated receptor transducer/regulatory component to specific DNA sequences on Ifn sensitive genes; 2) the activation of protein kinase C and binding of its regulatory components to specific DNA sequences. Ifn alpha, beta and gamma cause a dose related increase in monocyte and Hep G2 cell C1-inh mRNA abundance and protein synthesis. Ifn-gamma is the most potent of the interferons on monocyte C1-inh synthesis. Ifn alpha and beta being less effective but equipotent. These cytokines elicit their maximum effect on monocyte C1-inh synthesis after 1-2 hours treatment. This rapid stimulation of monocyte C1-inh synthesis suggests that this increases the transcription of the C1-inh gene. After removal of Ifns from monocytes the elevated C1-inh mRNA levels subside towards control levels of expression in Ifn alpha and beta-treated cells but remain elevated in Ifn-gamma-treated monocytes. This binding suggests that Ifn-gamma alters the stability of C1-inh mRNA.(ABSTRACT TRUNCATED AT 400 WORDS)

A major goal in multistep carcinogenesis research is the integration of recent findings obtained by sophisticated molecular-genetic and cytogenetic analysis of cancer into the more descriptive concepts of experimental pathology. It is proposed that the creation of a promotable cell in carcinogenic initiation requires a response modification to extracellular or intercellular signals. Different types of response modification can be distinguished: changes in the receptors for growth and differentiation factors and their cytoplasmic and nuclear signal transduction pathways; increased resistance of initiated cells to cytotoxic agents; alterations in junctional cell-to-cell communications. The challenge of a response-modified cell to an appropriate promoter results in its selection and clonal expansion, usually to a benign tumor. In addition, for malignancy, chromosomal changes are required that affect cellular functions that can play a role early or late in tumorigenesis. These concepts are illustrated with examples from oncogene research and oxidant promotion.

There is considerable evidence that malignant transformation need not eliminate the potential for a cell to express its developmental capabilities. This review explores the process whereby polar compounds, hexamethylene bisacetamide (HMBA) in particular, induce murine erythroid leukemoid cells (MELC) to express the differentiated erythroid phenotype, including hemoglobin production and cessation of cell division. This is a multi-step process which, although the mechanisms of action of HMBA are not yet fully understood, is amenable to experimental definition and analysis. Early effects, including changes in protein kinase C activity, in ion transport, and in expression of certain nuclear proto-oncogenes, have been examined in relation to the onset of terminal cell differentiation. This experimental experience has formed the context for initiating preliminary clinical studies designed to examine the pharmacology of HMBA and to explore its potential for modifying the natural history of cancer.

Human papillomaviruses (HPVs) are known as etiologic agents of various diseases in regions of the human epithelium. Specific type HPV16 is most frequently found in association with human squamous cell carcinoma. To examine biological activity of HPV type 16 in human cells, primary foreskin epidermal cells and dermal fibroblasts were transfected by recombinant viral DNA containing neo gene with Ca2+-phosphate precipitation. Epidermal cells were maintained in 0.5% Chelex-treated fetal calf serum, low calcium medium supplemented with bovine pituitary extracts and hormone mix. Fibroblasts were cultured in DMEM plus 10% fetal calf serum. The transfected cells were then selected with G418-resistant phenotype. These cells were propagated to maintain in culture and subsequently became stable lines carrying HPV16 genomes, while mock transfected control cells died off at approximately 40-50 population doublings (PD) in a parallel experiment. We have established two independently immortalized human epidermal cell lines (PHK16-I and II) which harbor different copies of HPV16 genome and express HPV16 specific mRNA. Although younger populations of PHK16 lines were fairly sensitive to high Ca2+-level to be differentiating keratinocytes, progressive changes of the cellular phenotype were demonstrated in terms of changes in Ca2+-response and anchorage independent growth during over 300 PD. Altered Ca2+-regulation of growth and differentiation appeared to be common reliable phenotype associated with stable transformation of skin epidermal cells. In contrast, none of the HPV16-transfected fibroblast line immortalized but simply showed extended life span up to 100 PD in average. The result suggested that this biological activity of HPV16 could be reflected in HPV-tropism related to epithelial transformation. We then studied correlations between HPV16 gene expression and the regulation of growth and differentiation of PHK lines during the progressive transformation. Northern blot analysis of RNA from cells in earlier passages demonstrated that down-regulation of HPV16 E6/E7 transcription was associated with keratinocyte differentiation induced by added 1.0mM calcium. The p97 promoter for HPV 16 early genes covering E6/E7 was specifically responsible for this Ca2+-regulation. The eventual loss of Ca2+-regulation could be implicated in a process of progressive transformation of HPV16-epidermal cell system.

Avidin is a host acute defense protein induced by progestins and by inflammation caused by injurious factors such as microbes, viruses, toxic factors or tissue trauma. In the reproductive tract of egg-laying vertebrates avidin has evolved into a progestin-dependent secretory protein involved in anti-microbial action through its biotin avidity. For "progestin-dependent avidin" production, cellular differentiation by estrogen is necessary. In contrast, the expression of "progestin-independent or inflammation-induced avidin" does not require differentiation. Many cell types such as macrophages, heterophils and fibroblasts can produce avidin after non-specific cellular injuries. The wide distribution of avidin in avian, reptilian and amphibian species could be explained on the basis of its vital functions such as antimicrobial or antifungal, metabolic and immunomodulatory actions. The ontogeny of the progestin-dependent avidin synthesis is a complex event involving oviductal differentiation by steroid hormones leading to a specific gene expression. The first phase in oviductal differentiation by estrogens is characterized by a new chromatin organization and by an infiltration of progesterone receptor (PR)-containing mesenchymal cells into the subepithelial mucosa leading to epithelial cell differentiation ("mesenchymal and epithelial cell interaction"). The second phase in the differentiation of progestin-induced response is dependent on the presence of PR in the secretory cells. Two kinds of PR expression occur in the oviduct. The first is a "constitutive PR" and is found in the epithelial, submucosal and peritoneal cells of the immature chick oviduct without steroid treatment, and the second is an "inducible PR" found especially in the mucosal mesenchymal and smooth muscle cells. Avidin production requires PR in the target cells, but not all PR-containing cells can produce avidin. Therefore, in addition to PR, other transcription factors are needed to define the target cell specificity of the response to progestins. Earlier biochemical studies suggested that cytosolic and/or nuclear unoccupied PR was complexed as an 8 S form with the heat shock protein 90 (hsp90). Our immunohistochemical results, however, indicate that PR in vivo is not bound to hsp90, which is located entirely in the cytoplasm, whereas PR is an entirely nuclear protein in both ligand-occupied and unoccupied forms. Therefore, we assume that PR is a monomeric (4S) or homodimeric (5S) (chromatin?) protein associated to DNA. Ligand binding to PR appears to lead to a conformational change, dimer formation, tighter binding to PRE (progesterone responsive element) and to transcription factors, phosphorylation and proteolysis of PR as well as a chromatin change.(ABSTRACT TRUNCATED AT 400 WORDS)

IVIgG preparations are now widely applied for immune modulatory treatment in various forms of autoimmune and immune complex diseases. Several controlled studies clearly demonstrated the clinical efficacy of this type of treatment; the underlying pathophysiological mechanisms, however, have yet to be elucidated. Among the mechanisms suggested to play a role in this context is the interaction of gamma globulin with Fc gamma receptors (Fc gamma R) expressed in the membrane of immunocompetent cells. Our studies concentrated on these aspects and focused on possible functional consequences of IgG-Fc gamma R interaction. By using the peripheral blood monocyte as a model system for an Fc gamma R-bearing cell, we confirmed previous reports by showing differences in Fc gamma R binding and Fc gamma R modulation induced by IgG in its various forms (monomeric IgG, Polymeric IgG, immune complexes). As biological consequences of Fc gamma R modulation, changes in effector and accessory function of these cells were observed. The results presented in this brief review emphasize especially the difference between ligand-oriented Fc gamma R diffusion (induced by surface-bound IgG) and true long-term down-modulation of Fc gamma R (mediated by fluid-phase IgG polymers) and show that only the down-modulation of Fc gamma R correlated with impaired functions of the affected cell.