Wounding acts as a tumor promoter in chickens inoculated with avian sarcoma virus 17

Origins of injection-site sarcomas in cats: the possible role of chronic inflammation-a review

The etiology of feline injection-site sarcomas remains obscure. Sarcomas and other tumors are known to be associated with viral infections in humans and other animals, including cats. However, the available evidence suggests that this is not the case with feline injection-site sarcomas. These tumors have more in common with sarcomas noted in experimental studies with laboratory animals where foreign materials such as glass, plastics, and metal are the causal agent. Tumors arising with these agents are associated with chronic inflammation at the injection or implantation sites. Similar tumors have been observed, albeit infrequently, at microchip implantation sites, and these also are associated with chronic inflammation. It is suggested that injection-site sarcomas in cats may arise at the administration site as a result of chronic inflammation, possibly provoked by adjuvant materials, with subsequent DNA damage, cellular transformation, and clonal expansion. However, more fundamental research is required to elucidate the mechanisms involved.

Dynamic characterization of the molecular events during in vitro epidermal wound healing

The aim of this study was to characterize some of the molecular events stimulated in vitro in response to injury within a confluent culture of normal epidermal keratinocytes as a model to understand the mechanisms of wound healing. To this end, an original device was developed specifically designed to perform calibrated injuries of great lengths within mono-stratified or pluri-stratified keratinocyte cultures. The experiments performed in this study validate this device as an appropriate tool for studying epidermal wound healing; this is because it performs mechanical injuries that stimulate the expression of multiple healing markers also known to be upregulated during wound healing in vivo (growth factors, cytokines, proteinases, extracellular matrix proteins). Using this device, it was demonstrated in human keratinocytes: mechanical injuries (i) immediately stimulate the tyrosine phosphorylation of numerous cellular proteins; (ii) induce molecular cascades leading to the activation of p21ras, mitogen-activated protein kinases, extracellular signal-regulated kinases 1/2, c-Jun NH2 terminal kinase, and p38 mitogen-activated protein kinase; and (iii) increase the phosphorylation of their respective substrates, c-jun and activator transcription factor 1. Wounding of these cells also results in increases in the DNA binding activities of several jun/fos activator protein-1 transcription factor complexes. It is important to note that the development of an appropriate wounding system was essential for performing this study, as use of a classical wounding procedure did not enable the detection of the biologic parameters reported above. In conclusion, these data indicate that using the appropriate system, it is possible to identify the signaling pathways activated in normal human keratinocyte cells after injury. In this study, it was shown that the mitogen-activated protein kinase pathways and activator protein-1 are stimulated in response to physical injury, and may be involved in regulating the expression of healing markers.

Cats differ from mink and ferrets in their response to commercial vaccines: a histologic comparison of early vaccine reactions

Early histologic changes in lesions at vaccine sites were compared in cats, mink, and ferrets. Twenty-four 4-month-old cats, 20 4-month-old mink, and 20 12-month-old ferrets were vaccinated with three rabies virus vaccines, two feline leukemia virus vaccines, alum adjuvant, and saline. Injection sites were excised at selected time points up to 21 days postvaccination. Histologic examination of the tissue revealed significant differences among the cats, mink, and ferrets in the local response to the commercial vaccines. When compared with ferrets and mink, cats had more lymphocytes in response to all three rabies vaccines. Production of fibroblasts, collagen, and macrophages differed among the three killed aluminum-adjuvanted vaccines in cats but did not differ significantly in mink or ferrets. Cats produced fewer binucleate cells than did mink or ferrets in response to the two adjuvanted leukemia virus vaccines. Differences seen in early tissue response of cats to commercial vaccines may be related to the increased predisposition of cats to vaccine-associated sarcomas.

Jun, the oncoprotein

Cellular Jun (c-Jun) and viral Jun (v-Jun) can induce oncogenic transformation. For this activity, c-Jun requires an upstream signal, delivered by the Jun N-terminal kinase (JNK). v-Jun does not interact with JNK; it is autonomous and constitutively active. v-Jun and c-Jun address overlapping but not identical sets of genes. Whether all genes essential for transformation reside within the overlap of the v-Jun and c-Jun target spectra remains to be determined. The search for transformation-relevant targets of Jun is moving into a new stage with the application of DNA microarrays technology. Genetic screens and functional tests remain a necessity for the identification of genes that control the oncogenic phenotype.

Wound reepithelialization activates a growth factor-responsive enhancer in migrating keratinocytes

Wound reepithelialization and keratinocyte migration require strictly ordered gene expression, which is assumed to be initiated by locally released mitogens and exposure of the cells to different matrix components. The mechanisms triggering gene expression specifically during reepithelialization are poorly understood. The far upstream AP-1-driven, FGF-inducible response element (FiRE) of the syndecan-1 gene was activated during cutaneous wound healing in transgenic mice. FiRE was induced selectively in migrating but not in proliferating keratinocytes at the wound edge. The activation was initiated at the start of the cell migration, was persistent throughout the merging and stratification phases, and was terminated after completion of reepithelialization. Although FiRE has been found within the gene of syndecan-1, the proximal promoter of syndecan-1 was not required for activation of FiRE in the migrating keratinocytes. The wounding induced activation was inhibited by blocking cell surface growth factor receptors with suramin. However, the activation of FiRE in resting skin required simultaneous growth factor- and stress-induced signals, but could also be elicited by the phosphatase inhibitor, okadaic acid. The activation by both wounding and chemical stimuli was blocked by inhibiting extracellular regulated kinase and p38 MAP kinases, suggesting the involvement of at least two parallel signal transduction pathways in wounding induced gene activation. As FiRE shows specificity for migrating keratinocytes only, it can be a useful tool for future wound healing studies and for targeting genes to injured tissues.

Autocrine interleukin-1 receptor antagonist can support malignant growth of glioblastoma by blocking growth-inhibiting autocrine loop of interleukin-1

In situ hybridization (ISH) of human glioblastoma tissue sections revealed expression of interleukin-1 (IL-1)alpha and/or beta and IL-1 receptor types I and II (IL-1R I and II) in the majority of cases evaluable. To understand the function of IL-1-family members in human glioblastomas, we have studied 6 glioblastoma cell lines. RT-PCR, ISH, ELISA and 125I-IL-1-binding assays revealed expression of IL-1 and high-affinity receptors for human (h)IL-1 in all but 1 cell line. Using a colony growth assay in semi-solid media for testing serial plating efficacy (PE, number of colonies per number of cells seeded in %), only the IL-1R-negative cell line was not influenced by recombinant human (rh)IL-1alpha or -beta, whereas IL-1 down-regulated the self-renewal of clonogenic cells of the other glioblastomas. Tritiated thymidine uptake was down-regulated by rhIL-1 in all cell lines studied. Cell viability remained unchanged by rhIL-1. Wherever growth modulation by rhIL-1 was detected, it could be reversed by either soluble IL-1R I or II or by rhIL-1 receptor antagonist (ra). IL-1ra not only was able to reverse rhIL-1-induced growth modulation but alone could modulate glioblastoma growth in comparison with control in cell lines producing IL-1. Our results show the presence of public autocrine loops for IL-1 leading to growth inhibition in some glioblastomas. To understand these loops, we have studied expression and function of IL-1ra in glioblastomas. ISH of human glioblastoma tissue sections revealed expression of hIL-1ra in all 8 cases evaluable. In 4 of 6 cell lines, IL-1ra was found in the supernatant under constitutive conditions, the IL-1R-negative line being among the 2 non-producers. The other non-producing cell line, HTB 17, showed expression of hIL-1R II. Most interestingly, a neutralizing antibody against IL-1ra down-regulated growth of IL-1- and IL-1ra-producing glioblastoma cells to approx. 30% of the controls. Thus, public autocrine loops for IL-1 in human glioblastomas exist and result in growth inhibition. An autocrine production of IL-1-antagonizing molecules such as IL-1ra by these tumors can counteract this IL-1 function and represent a basic escape mechanism supporting malignant growth in some glioblastomas.

Cellular aging is a critical determinant of primary cell resistance to v-src transformation

Primary cell cultures are in general resistant to the transforming effect of a single oncogene, a finding considered consistent with the multistage theory of carcinogenesis. In the present studies, we examined whether cellular age, differentiation stage, and/or tissue origin of primary cells plays a role in determining their response to v-src transformation. To study the role of cellular age, rat mammary fibroblasts were isolated from a 50-day-old female rat and infected with a recombinant retrovirus carrying a v-src gene after 2, 7, 14, 21, and 28 days of continuous growth. To determine whether cellular differentiation is important, fibroblasts were isolated from embryos at 12 and 16 days of gestation, from newborns, and from a 30-day-old rat and similarly infected. Finally, the role of primary-cell histogenesis was assessed by infecting primary cultures of fibroblasts isolated from the mammary gland, dermis, and lungs of a mature rat. When compared to 3Y1 cells, all preparations of primary cultures exhibited considerable resistance to v-src transformation. However, whereas primary cells isolated from different tissues responded similarly to the transforming effect of the oncogene, major differences were observed when cells were transduced at different stages of their in vitro life span. v-src was capable of inducing formation of foci and growth in soft agar in early-passage cells but failed to do so in primary cultures infected after 14 days of continuous passaging. Similarly, both the number of foci and the number of colonies in soft agar decreased with tissue donor age. The differential response of young and senescing cells could not be explained by mutations in v-src provirus, by differences in functional v-src expression, or by growth stimulation or suppression via paracrine mechanisms. Furthermore, v-src cooperated with an immortalizing gene, like simian virus 40 large T, polyomavirus large T, E6 and E7 of human papillomavirus, or an activated p53 mutant, to induce anchorage-independent growth of primary cultures but failed to do so with cytoplasmic transforming genes, like v-abl, v-ras, or v-raf, which did not confer indefinite division potential. These studies indicate that cellular aging is a critical determinant of primary-cell resistance to v-src transformation. It is suggested that v-src requires a nuclear auxiliary function for transformation which is present in early-passage cells, particularly when these cells are derived from embryonic tissue, but is lost as cells approach replicative senescence. This auxiliary function is provided by nuclear oncogenes but not cytoplasmic transforming genes.

Induction of collagenase and stromelysin gene expression by mechanical injury in a vascular smooth muscle-derived cell line

We describe a novel system for studying the production of matrix metalloproteinases types I and III (collagenase and stromelysin) by a vascular smooth muscle cell line (Rb-1 cells) in response to mechanical injury. Highly confluent Rb-1 cells are disrupted by passing a plastic comb around the plate to clear a series of circumferential paths, which are bordered by two ridges of displaced cells. Over the next 24 hours, cells migrate into the cleared areas. Northern blot analysis demonstrates the accumulation of mRNAs for collagenase and stromelysin during this process, although they are undetectable prior to injury. Cotreatment with all-trans-retinoic acid (10(-6) M) markedly decreases the level of mRNAs induced by injury, whereas dexamethasone (10(-7) M) causes only a slight reduction. In situ hybridization studies for stromelysin mRNA and immunohistochemical staining for collagenase protein on plates of injured cells showed the highest levels of stromelysin mRNA in cells in the ridges left by the injury; lower levels were observed in some cells migrating into the clear region. The same pattern of expression was observed when cells were stained with antiserum to collagenase protein. Nuclear run-on assays demonstrated increases in transcription of stromelysin and collagenase genes following injury. Transient transfection of cells with a vector containing the luciferase gene driven by a wild-type promoter comprising 1.8 kb of the 5'-flanking region of the rabbit collagenase gene showed increased activity associated with injury. We conclude that: (1) mechanical injury is associated with induction of mRNAs for the metalloproteinases collagenase and stromelysin, (2) retinoic acid effectively antagonizes this responses, and (3) the increase in steady-state mRNA levels is, at least in part, transcriptionally mediated. Thus our data suggest a role for mechanical forces in initiating the changes in gene expression in vascular smooth muscle cells following arterial injury in vivo.