The calcium signal for BALB/MK keratinocyte terminal differentiation counteracts epidermal growth factor (EGF) very early in the EGF-induced proliferative pathway

The suppressor of cytokine signaling-3 is upregulated in impaired skin repair: implications for keratinocyte proliferation

In this study, we determined regulation and function of the suppressor of cytokine signaling (SOCS)-3 in acute and impaired murine skin repair. Upon skin injury, SOCS-3 was induced and expressed during the inflammatory phase of repair. SOCS-3 protein expression was localized in a subset of non-proliferating keratinocytes within the developing wound margin epithelia. Growth factors (EGF, transforming growth factor-alpha), nitric oxide (NO), and pro-inflammatory cytokines were inducers of SOCS-3 mRNA and protein expression in cultured human (HaCaT) and primary murine keratinocytes. Stable overexpression of SOCS-3 in HaCaT keratinocytes interfered with cytokine-induced signal transducers and activators of transcription-3 phosphorylation and inhibited serum-stimulated proliferation of the cells. Moreover, overexpression of SOCS-3 led to final differentiation of keratinocytes, which was comparable to the Ca(2+)-induced differentiation process in the cells. Finally, we determined SOCS-3 expression in two models of impaired skin repair: NO-deficient and diabetic wound healing. In line with observations from normal repair and SOCS-3 overexpression experiments, reduced keratinocyte proliferation within atrophied neo-epithelia in both models of impaired healing was associated with a marked increase in SOCS-3-expressing wound keratinocytes. In summary, this study suggests a potential novel function of SOCS-3 in regulating keratinocyte proliferation and differentiation in vitro and during skin repair in vivo.

Phorbol ester-induced G1 arrest in BALB/MK-2 mouse keratinocytes is mediated by delta and eta isoforms of protein kinase C

We investigated the possible negative regulation of the cell cycle by protein kinase C (PKC) isoforms in synchronously grown BALB/MK-2 mouse keratinocytes, in which PKC isoforms were overexpressed by using the adenovirus vector Ax. Cells at the G1/S boundary of the cell cycle were the most sensitive to the inhibitory effect of 12-O-tetradecanoylphorbol-13-acetate (TPA), a PKC agonist, resulting in G1 arrest. TPA-induced inhibition of DNA synthesis was augmented by overexpression of the eta and delta isoforms, but rescued by the dominant-negative and antisense eta isoforms. In contrast, the alpha and zeta isoforms showed no effect on DNA synthesis with or without TPA treatment. Immunoblotting indicated cell cycle-dependent expression of the eta isoform, being highest in cells at the G1/S boundary. The present study provides evidence that the eta and delta isoforms of PKC are involved in negative regulation of cell cycle at the G1/S boundary in mouse keratinocytes.

Transcription factor regulation of epidermal keratinocyte gene expression

The epidermis is a tissue that undergoes a very complex and tightly controlled differentiation program. The elaboration of this program is generally flawless, resulting in the production of an effective protective barrier for the organism. Many of the genes expressed during keratinocyte differentiation are expressed in a coordinate manner; this suggests that common regulatory models may emerge. The simplest model envisions a 'common regulatory element' that is possessed by all genes that are regulated together (e.g., involucrin and transglutaminase type 1). Studies to date, however, have not identified any such elements and, if anything, the available studies suggest that appropriate expression of each gene is achieved using sometime subtly and sometime grossly different mechanisms. Recent studies indicate that a variety of transcription factors (AP1, AP2, POU domain. Sp1, STAT factors) are expressed in the epidermis and, in many cases, multiple members of several families are present (e.g., AP1 and POU domain factors). The simultaneous expression of multiple members of a single transcription factor family provides numerous opportunities for complex regulation. Some studies suggest that specific members of these families interact with specific keratinocyte genes. The best studied of these families in epidermis is the AP1 family of factors. All of the known AP1 factors are expressed in epidermis [52] and each is expressed in a specific spatial pattern that suggests the potential to regulate multiple genes. It will be important to determine the role of each of these members in regulating keratinocyte gene expression. Finally, information is beginning to emerge regarding signal transduction in keratinocytes. Some of the early events in signal transduction have been identified (e.g., PLC and PKC activation, etc.) and some of the molecular targets of these pathways (e.g., AP1 transcription factors) are beginning to be identified. Eventually we can expect to elucidation of all of the steps between the interaction of the stimulating agent with its receptor and the activation of target gene expression.

Cell kinetic characterization of the epidermal growth factor dependent BALB/MK line using flow cytometric analysis of DNA content and iododeoxyuridine incorporation

Epidermal hyperproliferation (psoriasis, wound repair) is the result of quiescent (G0) keratinocytes being recruited into the cell cycle. A detailed characterization of the cell cycle kinetic parameters of the mouse keratinocyte line (Balb/MK) has been carried out with the aid of bivariate iododeoxyuridine (IdUrd) and DNA analysis using flow cytometry, in order to establish whether it might provide a useful model for the study of the biochemical events controlling recruitment into the cell cycle. Balb/MK keratinocytes were cultured using low Ca2+ Dulbecco's modified Eagle's medium/F 12 in the presence of 10% dialysed fetal bovine serum and 4 ng/ml epidermal growth factor (EGF). IdUrd labelling followed by flow cytometric analysis of trypsinized cells showed that about 95% of the population were actively cycling, with a cell cycle time of around 14h and no significant contact inhibition. Omission of serum and EGF followed by IdUrd pulse-labelling indicated that the cells progressively withdrew from the cycle and, after 16h, less than 10% incorporated IdUrd. Subsequent restimulation with serum resulted in a synchronized cohort of cells being recruited. Entry into the S phase of the cell cycle (IdUrd incorporation) started at 8 h and was maximal between 12 h and 16h after stimulation. Restimulation with EGF alone reached a growth fraction of 87% after 24 h continuous labelling compared with 97% using serum together with EGF. Epidermal growth factor already showed a significant stimulation at 10 pg/ml compared with the controls. There is a broad plateau centred on 5 ng/ml, followed by a slight decline above this level. We conclude that the use of a cell line with defined cell cycle kinetic parameters which can be switched between the quiescent and cycling states in a fully defined medium will provide an ideal model for biochemical studies of the relevant signal transduction pathways in keratinocytes.

2,3,7,8-Tetrachlorodibenzo-P-dioxin induced alterations in protein phosphorylation in guinea pig adipose tissue

An in situ (explant tissue culture) model has been developed to study the effect of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), hormones, and growth factors either alone or in combination. In our model system, the effect of TCDD on protein phosphorylation was greatly affected by the presence or the absence of externally added D-glucose. In the presence of a physiologically relevant level of glucose (13.3 mM), TCDD clearly stimulated protein phosphorylation as in the case of in vivo data. However, in the absence of D-glucose, TCDD clearly inhibited protein phosphorylation. On the other hand, TCDD reduced the glucose uptake activity in isolated adipose tissue either in the presence or absence of D-glucose (13.3 mM). Therefore, the TCDD-induced reduction of glucose transport does not appear to be related directly to the simultaneous rise in protein phosphorylation. For comparison, several agents which are known to affect protein phosphorylation were tested. These hormonal agents generally affected the TCDD-untreated adipose tissues in the manner expected from their known actions, indicating that this in situ model is an adequate system to study their independent actions. The TCDD-treated adipose tissue samples showed only mild or insignificant response to these hormonal stimuli. In terms of the changes in the pattern of protein phosphorylation activities, the action of TCDD appeared to resemble that of EGF and T3. Since under in situ conditions no agents such as EGF or T3 can be expected to be present, the observed TCDD-induced changes are suggestive of the basic intracellular changes in cellular activities. The types of TCDD-induced protein kinases appear to be protein tyrosine kinases and protein kinase C.

Regulation of epidermal growth factor receptor expression in normal and transformed keratinocytes

Transformed keratinocytes (SCC-4, SCC-15, SCC-12F2, SVK14) or normal keratinocytes which differ in their differentiation programme were used to study the regulation of EGF-receptor expression. The capacity of the cells to differentiate was modulated by changing the extracellular calcium concentration. We were able to demonstrate that EGF-receptor expression in normal and transformed keratinocytes depends upon the cell type and one or more levels of regulatory control. At the DNA level, EGF-receptor gene amplification occurred in poorly differentiating cells. At the mRNA level, cells showing EGF-receptor gene amplification expressed elevated mRNA and protein levels when cultured under low Ca2+ conditions. Cells not exhibiting EGF-receptor gene amplification showed equal mRNA expression, regardless the Ca2+ concentration in the culture medium. At the protein level, EGF-receptor protein was decreased in cells exhibiting EGF-receptor gene amplification when extracellular Ca2+ was increased (to 1.6 mM) to stimulate differentiation, the decrease in protein being comparable to mRNA expression. Cells not exhibiting EGF-receptor gene amplification showed equal protein expression, regardless of the Ca2+ concentration in the culture medium. Under the same conditions, SV40 transformed keratinocytes showed equal mRNA but elevated protein expression in cells grown under low Ca2+ conditions. At the membrane level, normal keratinocytes and SCC-17F2 cells showed elevated numbers of cell surface exposed EGF-receptors in cells grown under low Ca2+ conditions, but equal mRNA and protein expression.(ABSTRACT TRUNCATED AT 250 WORDS)

Epidermal growth factor (EGF) expression in the congenital polycystic mouse kidney

The mechanisms responsible for renal cyst formation in congenital polycystic kidney disease remain unknown, although abnormalities of cellular metabolism, basement membrane components, and growth factors have been suggested. In the present study, we examined a potential role for epidermal growth factor (EGF) in cyst formation in a mouse model. We measured growth factor activity and concentration in renal cyst fluid, urine, and serum obtained from mice with congenital polycystic kidney disease (cpk). In affected mice, both growth factor activity of urine and the urinary EGF concentration were much lower than unaffected littermate controls even when corrected for creatinine concentration. Although the growth factor activity was much lower in affected mice, there were significant differences in the regional distribution of EGF in animals with cysts. Both growth factor activity and EGF concentration were greater in cyst fluid when compared to urine. Growth factor activity in cysts was completely inhibited by anti-EGF antibody using BALB/MK epithelial keratinocytes as targets. The expression of EGF mRNA in kidneys from affected mice was markedly decreased when compared to littermate controls. These results suggest that decreased EGF production and local differences in EGF concentration may contribute to cyst formation.

Extracellular ATP shows synergistic enhancement of DNA synthesis when combined with agents that are active in wound healing or as neurotransmitters

The polypeptides PDGF, TGF alpha, and EGF have previously been shown by others to stimulate proliferation of fibroblasts and keratinocytes in the process of wound healing. Here we demonstrate that extracellular ATP, ADP or AMPPNP caused synergistic enhancement of DNA synthesis in 3T6 mouse fibroblasts and BALB/MK keratinocytes when combined with any of the above polypeptides. TGF beta showed synergistic stimulation with ATP in fibroblasts but it inhibited keratinocytes. ATP acted as a mitogen for NIE-115 neuroblastoma cultures. In 3T6 cells, ATP stimulated thymidine incorporation in combination with carbachol or norepinephrine. The effect of carbachol was sensitive to atropine. We suggest that extracellular ATP and ADP may play a physiological role in wound healing and as a mitogenic neurotransmitter in the nervous system.

Differential effects of Ca2+ on proliferation of stomach, colonic, and pancreatic cancer cell lines in vitro

Calcium intake inhibits growth of colon cancer in vivo, the mechanisms of which are not fully elucidated. The objective of this study was to determine whether Ca2+ directly affects the growth of colon cancer cells in vitro and to compare the effects of Ca2+ on the growth of several gastroenteropancreatic cancer cells, including mouse colon cancer (MC-26), human colon cancer (LoVo and WIDR), human gastric cancer (AGS and SII), and human pancreatic cancer (PANC-1 and MIA) cells. All tumor cell lines tested grew in medium containing low concentration (approx 0.16 mM) of Ca2+. Higher concentrations of Ca2+ significantly inhibited the growth of all three colon cancer cell lines tested but had no significant effect on proliferation of the stomach and pancreatic cancer cell lines. Growth of AGS cells, in the presence of 0.1 or 0.5 mM EGTA (resulting in the loss of the extracellular Ca2+) was similar to that observed in the absence of EGTA, indicating that AGS cells were relatively insensitive to loss of extracellular Ca2+. In the presence of TMB-8, an inhibitor of intracellular Ca2+ release, the growth of colonic cancer cell lines was inhibited in a dose-dependent manner, indicating that a minimum basal level of intracellular Ca2+ was required for continued proliferation of colon cancer cells. The stomach cancer cell lines (AGS) was once again less sensitive to the effects of TMB-8 than were the colon cancer cells, indicating an inherent difference in Ca2+ requirements and sensitivity to Ca2+ for growth of different gastroenteropancreatic cancer cells in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)

Uncoupling of the calcium-induced terminal differentiation and the activation of membrane-associated transglutaminase in murine keratinocytes by type-beta transforming growth factor

Calcium is an important regulator of terminal differentiation of cultured epidermal cells. In order to investigate the relationship between the termination of proliferative activity and the process of keratinization, we studied the time course of events induced by a sudden increase of extracellular calcium (calcium-switch) in cultures of established murine skin keratinocytes (BALB/c MK-1). These cells displayed density-dependent growth arrest without undergoing terminal differentiation in the presence of serum- and mitogen-free medium with a calcium concentration less than 0.10 mM. The calcium-switch alone was sufficient to induce a dose-dependent burst of DNA synthesis, which was followed by a state in which the cells became progressively refractory to mitogenic stimulation with epidermal growth factor. Treatment of cultures with type beta transforming growth factor during the first 6- to 10 h following the calcium-switch completely eliminated the initial burst of DNA synthesis as well as the terminal differentiation in response to calcium. On the other hand, the calcium-switch also caused the induction of a four- to fivefold increase of the activity of the membrane-associated form of transglutaminase that is required for keratinization, which was not affected by the presence of type beta transforming growth factor. These observations suggest that type beta transforming growth factor regulates the calcium-induced terminal cell division independently of the induction of phenotypic markers of keratinization, such as transglutaminase.