Biochemical localization of the transformation-sensitive 52 kDa (p52) protein to the substratum contact regions of cultured rat fibroblasts. Butyrate induction, characterization, and quantification of p52 in v-ras transformed cells

SERPINE1: Role in Cholangiocarcinoma Progression and a Therapeutic Target in the Desmoplastic Microenvironment

A heterogenous population of inflammatory elements, other immune and nonimmune cells and cancer-associated fibroblasts (CAFs) are evident in solid malignancies where they coexist with the growing tumor mass. In highly desmoplastic malignancies, CAFs are the prominent mesenchymal cell type in the tumor microenvironment (TME), where their presence and abundance signal a poor prognosis. CAFs play a major role in the progression of various cancers by remodeling the supporting stroma into a dense, fibrotic matrix while secreting factors that promote the maintenance of cancer stem-like characteristics, tumor cell survival, aggressive growth and metastasis and reduced sensitivity to chemotherapeutics. Tumors with high stromal fibrotic signatures are more likely to be associated with drug resistance and eventual relapse. Identifying the molecular underpinnings for such multidirectional crosstalk among the various normal and neoplastic cell types in the TME may provide new targets and novel opportunities for therapeutic intervention. This review highlights recent concepts regarding the complexity of CAF biology in cholangiocarcinoma, a highly desmoplastic cancer. The discussion focuses on CAF heterogeneity, functionality in drug resistance, contributions to a progressively fibrotic tumor stroma, the involved signaling pathways and the participating genes.

PAI-1 Expression Is Required for HDACi-Induced Proliferative Arrest in ras-Transformed Renal Epithelial Cells

Malignant transformation of mammalian cells with ras family oncogenes results in dramatic changes in cellular architecture and growth traits. The generation of flat revertants of v-K-ras-transformed renal cells by exposure to the histone deacetylase inhibitor sodium butyrate (NaB) was previously found to be dependent on transcriptional activation of the PAI-1 (SERPINE1) gene (encoding the type-1 inhibitor of urokinase and tissue-type plasminogen activators). NaB-initiated PAI-1 expression preceded induced cell spreading and entry into G(1) arrest. To assess the relevance of PAI-1 induction to growth arrest in this cell system more critically, two complementary approaches were used. The addition of a stable, long half-life, recombinant PAI-1 mutant to PAI-1-deficient v-K-ras-/c-Ha-ras-transformants or to PAI-1 functionally null, NaB-resistant, 4HH cells (engineered by antisense knockdown of PAI-1 mRNA transcripts) resulted in marked cytostasis in the absence of NaB. The transfection of ras-transformed cells with the Rc/CMVPAI expression construct, moreover, significantly elevated constitutive PAI-1 synthesis (10- to 20-fold) with a concomitant reduction in proliferative rate. These data suggest that high-level PAI-1 expression suppresses growth of chronic ras-oncogene transformed cells and is likely a major cytostatic effector of NaB exposure.

PAI-1 expression is required for epithelial cell migration in two distinct phases of in vitro wound repair

Several proteases and their specific inhibitors modulate the interdependent processes of cell migration and matrix proteolysis as part of the global program of trauma repair. Expression of plasminogen activator inhibitor type-1 (PAI-1), a serine protease inhibitor (SERPIN) important in the control of barrier proteolysis and cell-to-matrix adhesion, for example, is spatially-temporally regulated following epithelial denudation injury in vitro as well as in vivo. PAI-1 mRNA/protein synthesis was induced early after epidermal monolayer scraping and restricted to keratinocytes comprising the motile cohort closely recapitulating, thereby, similar events during cutaneous healing. The time course of PAI-1 promoter-driven PAI-1-GFP fusion "reporter" expression in wound-juxtaposed cells approximated that of the endogenous PAI-1 gene confirming the location-specificity of gene regulation in this model. ERK activation was evident within 5 min after injury and particularly prominent in cells residing at the scrape-edge (suggesting a possible role in PAI-1 induction and/or the motile response) as was myosin light chain (MLC) phosphorylation. Indeed, MEK blockade with PD98059 or U0126 attenuated keratinocyte migration (by > or =60%), as did transient transfection of a dominant-negative ERK1 construct (40% decrease in monolayer repair), and completely inhibited PAI-1 transcript expression. Anti-sense down-regulation of PAI-1 synthesis (by 80-85%), or addition of PAI-1 neutralizing antibodies also inhibited injury site closure over a 24 h period establishing that PAI-1 was required for efficient long-term planar motility in this system. PAI-1 anti-sense transfection or actinomycin D transcriptional blockade, in contrast, did not affect the initial migratory response suggesting that residual PAI-1 protein levels (at least in transfectant cells and actinomycin D-treated cultures) may be sufficient to support early cell movement. Pharmacologic inhibition of keratinocyte MEK signaling effectively ablated scrape-induced PAI-1 mRNA expression but failed to attenuate wound-associated increases in cellular PAI-1 protein levels soon after monolayer injury. Collectively, these data suggest that basal PAI-1 transcripts may be mobilized for initial PAI-1 synthesis and, perhaps, the early motile response while maintenance of the normal rate of migration requires the prolonged PAI-1 expression that typically accompanies the repair response. To assess this possibility, scrape site closure studies were designed using keratinocytes isolated from PAI-1-/- mice. PAI-1-/- keratinocytes, in fact, had a significant wound healing defect evident even within the first 6 h following monolayer denudation injury. Addition of active PAI-1 protein to PAI-/- keratinocytes rescued the migratory phenotype that that approximating wild-type cells. These findings validate use of the present keratinocyte model to investigate injury-related controls on PAI-1 gene regulation and, collectively, implicate participation of PAI-1 in two distinct phases of epidermal wound repair.

Growth state-dependent binding of USF-1 to a proximal promoter E box element in the rat plasminogen activator inhibitor type 1 gene

Induced PAI-1 gene expression in renal epithelial (NRK-52E, clone EC-1) cells occurs as part of the immediate-early response to serum. PAI-1 transcripts are maximally expressed early in G(1) (within 4 h of serum addition to quiescent EC-1 cells) and then subsequently decline to basal levels prior to entry into DNA synthetic phase. Comparative analysis of PAI-1 mRNA abundance and de novo-synthesized thiolated RNA in quiescent cells, as well as at 4 h (early G(1)) and 20 h (late G(2)) postserum addition, in conjunction with RNA decay measurements indicated that PAI-1 gene regulation upon growth activation was predominantly transcriptional. An E box motif (CACGTG), important in the induced expression of some growth state-dependent genes, mapped to nucleotides -160 to -165 upstream of the transcription start site in the PAI-1 proximal promoter. Mobility-shift assessments, using a 18-bp deoxyoligonucleotide construct containing the E box within the context of PAI-1-specific flanking sequences, confirmed binding of EC-1 nuclear protein(s) to this probe and, specifically, to the E box hexanucleotide site. The specificity of this protein-probe interaction was verified by competition analyses with double-stranded DNA constructs that included E box deoxyoligonucleotides with non-PAI-1 flanking bases, mutant E box sequences incapable of binding NRK nuclear proteins, and unrelated (i.e., AP-1) target motifs. Extract immunodepletion and supershift/complex-blocking experiments identified one PAI-1 E box-binding protein to be upstream stimulatory factor-1 (USF-1), a member of the HLH family of transcription factors. Mutation of the CACGTG site to TCCGTG in an 18-bp PAI-1 probe inhibited the formation of USF-1-containing complexes confirming that an intact E box motif at -160 to -165 bp in the PAI-1 promoter and, in particular, the CA residues at -165 and -164 are essential for USF-1 binding. Incorporation of this 2 bp change into a reporter construct containing 764 bp of the proximal PAI-1 "promoter" ligated to a CAT gene effectively reduced (by 74%) CAT activity in cycling cells. An intact E box motif at nucleotides -160 to -165 in the PAI-1 promoter, thus, is an important functional element in the regulation of PAI-1 transcriptional activity in renal cells.

Differential regulation of PAI-1 gene expression in human fibroblasts predisposed to a fibrotic phenotype

Synthesis of the major negative physiologic regulator of plasmin activation [plasminogen activator inhibitor type-1 (PAI-1)] is elevated during progressive cellular senescence, in premature aging disorders (e.g., Werner's syndrome), and in conditions associated with tissue fibrosis and excessive fibrin accumulation (e.g., sclerosis, keloid formation). Dermal fibroblasts derived from Werner's patients as well as from keloid lesions markedly overexpress PAI-1 mRNA transcripts compared to normal skin fibroblasts. Such cell type-related differences in steady-state PAI-1 mRNA content, and variances in the relative abundance of the 3.0- compared to the 2.2-kb PAI-1 mRNA species, served to discriminate normal from Werner's and keloid fibroblasts. This disparity in PAI-1 mRNA levels paralleled transcriptional activities of the PAI-1 gene; de novo synthesis of PAI-1 protein among the three cell types, moreover, closely approximated the respective differences in total PAI-1 mRNA content. Despite the markedly elevated levels of PAI-1 mRNA and protein evident in newly confluent keloid fibroblasts, these cells effectively suppressed PAI-1 synthesis (as did normal dermal fibroblasts) upon culture in serum-free medium. Werner's syndrome skin fibroblasts, in contrast, continued to maintain high-level PAI-1 expression even after 3 days of growth arrest. Adhesion-mediated attenuation of serum-stimulated PAI-1 expression, a characteristic of normal cells involving sequences which mapped to the distal 5' flanking region of the PAI-1 gene, was retained in keloid but not Werner's fibroblasts. Collectively, these data suggest that (1) specific controls on PAI-1 gene expression are fundamentally different between these two clinically significant high PAI-1-synthesizing cell types and (2) the localized keloid may define the emergence of a distinct profibrotic dermal fibroblastoid phenotype in genetically predisposed individuals.

Induced PAI-1 mRNA expression and targeted protein accumulation are early G1 events in serum-stimulated rat kidney cells

Expression of plasminogen activator inhibitor type-1 (PAI-1), a member of the SERPIN gene family that functions to regulate the plasmin-based pericellular proteolytic cascade, is growth state-regulated in normal rat kidney (NRK) cells (Ryan and Higgins, 1990, J. Cell. Physiol., 155:376-384; Ryan et al., 1996, Biochem. J., 314:1041-1046). Comparative analysis of arrest states induced in NRK cells upon exposure to serum-deficient (0.5% FBS) or serum-free culture conditions served to define the kinetics of PAI-1 gene expression and fate of de novo-synthesized PAI-1 protein. While cells rendered quiescent in serum-free or serum-deficient media were equivalent with regard to the time course of PAI-1 mRNA induction, the level of expressed transcripts (27-fold vs. 12-fold) and accumulated saponin fraction PAI-1 protein (12-fold vs. 6-fold) were consistently greater in cells recruited into exponential growth phase from a serum-free as compared to a serum-deficient arrest condition. Relative PAI-1 mRNA abundance increased within 1-2 hr post-serum addition, was maximal at 4 hr, and declined rapidly thereafter; this time course of expression coupled with placement of entry into DNA synthetic phase at approximately 12 hr after stimulation indicates that PAI-1 induction is an early-to-mid G1 phase event. Induced PAI-1 protein was evident immunocytochemically within 2 hr of serum stimulation as a peripheral "rim" of accumulated protein restricted to the cellular ventral surface at the plane of the substrate. No PAI-1 was detected between individual cells suggesting that this protein may be targeted directly to the undersurface region. By 6 hr post-stimulation, the rim of PAI-1 deposition increased in intensity and broadened to occupy approximately 30 to 50% of the total undersurface area. Double-label immunocytochemistry indicated that accumulated PAI-1 was deposited in close proximity to, but not actually within, vinculin-containing focal contact structures. Potential functionality of induced PAI-1 expression to either the initiation or maintenance of the serum-stimulated phenotype was assessed using antibodies to PAI-1. The IgG fractions of two different antisera which neutralize the ability of PAI-1 to complex with and thereby inhibit the catalytic activity of urokinase plasminogen activator significantly reduced (by 25-35%) the incidence of cells displaying the serum-stimulated phenotype; antibodies that bind PAI-1 but do not block PAI-1 inhibitory activity were without effect. In view of the vagaries of antibody accessibility and in situ neutralizing activity (particularly in a region as structurally complex as the focal contact), these data may actually underestimate the importance of PAI-1 in maintaining the activated phenotype.

P52PAI-1 gene expression in butyrate-induced flat revertants of v-ras-transformed rat kidney cells: mechanism of induction and involvement in the morphological response

Sodium n-butyrate-induced flat reversion in v-K-ras oncogene-transformed rat kidney (KNRK) cells is associated with transcriptional activation of the p52PAI-1 gene (which encodes the type-1 inhibitor of plasminogen activator). Butyrate-initiated expression of p52PAI-1 mRNA and protein correlated with induced cell spreading and preceded development of cell-to-substrate focal adhesions. Such undersurface matrix contact structures, which are absent from parental KNRK cells, require proximal PAI-1 deposition for their stabilization. Stimulated p52PAI-1 expression by flat revertants (approximating 25-fold that of control cells) and the accompanying cytoarchitectural reorganization appeared to be programmed responses to butyrate as both events required de novo RNA and protein synthesis, metabolic characteristics consistent with a secondary pathway of gene regulation. To assess the relevance of p52PAI-1 induction to the process of flat reversion more critically, a molecular genetic approach was designed to maintain high-level constitutive p52PAI-1 synthesis in the absence of butyrate. KNRK cells transfected with a Rc/CMVPAI plasmid construct, in which expression of a p52PAI-1 cDNA insert was driven by enhancer-promoter sequences from the immediate-early gene of human cytomegalovirus, formed colonies comprised of flat-revertant-like cells with a greater frequency than did cells transfected with the Rc/CMV vector alone (24.8% and 1.7% respectively). Comparative analysis of randomly selected Rc/ CMVPAI clones indicated that a 10-fold increase in immunoreactive p52PAI-1 protein, relative to Rc/CMV isolates, correlated with generation of the flat phenotype. These data suggest that induced p52PAI-1 expression probably functions in the development of morphological revertants in the KNRK cell system.

Induced PAI-1 mRNA expression and targeted protein accumulation are early G1 events in serum-stimulated rat kidney cells

Expression of plasminogen activator inhibitor type-1 (PAI-1), a member of the SERPIN gene family that functions to regulate the plasmin-based pericellular proteolytic cascade, is growth state-regulated in normal rat kidney (NRK) cells (Ryan and Higgins, 1990, J. Cell. Physiol., 155:376-384; Ryan et al., 1996, Biochem. J., 314:1041-1046). Comparative analysis of arrest states induced in NRK cells upon exposure to serum-deficient (0.5% FBS) or serum-free culture conditions served to define the kinetics of PAI-1 gene expression and fate of de novo-synthesized PAI-1 protein. While cells rendered quiescent in serum-free or serum-deficient media were equivalent with regard to the time course of PAI-1 mRNA induction, the level of expressed transcripts (27-fold vs. 12-fold) and accumulated saponin fraction PAI-1 protein (12-fold vs. 6-fold) were consistently greater in cells recruited into exponential growth phase from a serum-free as compared to a serum-deficient arrest condition. Relative PAI-1 mRNA abundance increased within 1-2 hr post-serum addition, was maximal at 4 hr, and declined rapidly thereafter; this time course of expression coupled with placement of entry into DNA synthetic phase at approximately 12 hr after stimulation indicates that PAI-1 induction is an early-to-mid G1 phase event. Induced PAI-1 protein was evident immunocytochemically within 2 hr of serum stimulation as a peripheral "rim" of accumulated protein restricted to the cellular ventral surface at the plane of the substrate. No PAI-1 was detected between individual cells suggesting that this protein may be targeted directly to the undersurface region. By 6 hr post-stimulation, the rim of PAI-1 deposition increased in intensity and broadened to occupy approximately 30 to 50% of the total undersurface area. Double-label immunocytochemistry indicated that accumulated PAI-1 was deposited in close proximity to, but not actually within, vinculin-containing focal contact structures. Potential functionality of induced PAI-1 expression to either the initiation or maintenance of the serum-stimulated phenotype was assessed using antibodies to PAI-1. The IgG fractions of two different antisera which neutralize the ability of PAI-1 to complex with and thereby inhibit the catalytic activity of urokinase plasminogen activator significantly reduced (by 25-35%) the incidence of cells displaying the serum-stimulated phenotype; antibodies that bind PAI-1 but do not block PAI-1 inhibitory activity were without effect. In view of the vagaries of antibody accessibility and in situ neutralizing activity (particularly in a region as structurally complex as the focal contact), these data may actually underestimate the importance of PAI-1 in maintaining the activated phenotype.

Differential growth state-dependent regulation of plasminogen activator inhibitor type-1 expression in senescent IMR-90 human diploid fibroblasts

The type-1 inhibitor of plasminogen activator (PAI-1) regulates pericellular proteolytic activity functioning, thereby to control matrix integrity, cell growth, and morphology. Subconfluent late-passage IMR-90 human fibroblasts and normal rat kidney (NRK) cells, both at the stage of replicative senescence accumulated 15- to 30-fold more undersurface PAI-1 protein compared to early-passage, actively-proliferating, cultures. Senescence-associated elevations in PAI-1 expression by IMR-90 cells reflected corresponding 11-fold increases in the 3.0- and 2.2-kb PAI-1 mRNA species. The 2.2-kb transcript exhibited a greater age-dependent increase (7.2-fold) compared to the 3.0-kb mRNA (3.7-fold). Since PAI-1 expression is coupled to growth activation in serum-deprived cultures (Ryan and Higgins, 1993, J. Cell. Physiol., 155:376-384), it was important to determine if PAI-1 gene regulation was altered as a function of cellular aging. In contrast to early-passage cultures, senescent IMR-90 fibroblasts did not down-regulate either PAI-1 protein expression or steady-state levels of PAI-1 mRNA transcripts upon serum-deprivation. Late-passage human fibroblasts at their proliferative end-stage, thus, appear to regulate PAI-1 mRNA levels through different mechanisms than do young, actively-proliferating, cells. PAI-1 overexpression during in vitro cellular aging, therefore, may contribute to the acquisition of specific senescence-associated phenotypic traits (e.g., enlarged cell morphology; increased adhesivity) by altering the pericellular proteolytic balance influencing, in turn, the formation or stability of cell-to-substrate attachment complexes.

Cell-shape-dependent modulation of p52(PAI-1) gene expression involves a secondary response pathway

Expression of the rat p52(PAI-1) gene is positively regulated by agents that influence cellular microfilament organization and/or cell-to-substrate adhesion [e.g. cytochalasin D (CD) and sodium n-butyrate (NaB)] [Higgins, Chaudhari and Ryan (1991) Biochem. J. 273, 651-658; Higgins, Ryan and Providence (1994) J. Cell. Physiol. 159, 187-195]. As shape-responsive genes may be subject to inducer-specific controls, the biochemical mechanisms underlying the shape-dependent pathway of p52(PAI-1) gene regulation were examined in v-ras-transformed rat kidney (KNRK) cells. NaB and/or CD effectively stimulated p52(PAI-1) run-off transcription and augmented de novo p52(PAI-1) mRNA and protein synthesis in KNRK cells; induction at both the mRNA and protein levels was inhibited by actinomycin D. Pretreatment with cycloheximide (CX) markedly attenuated NaB- and/or CD-stimulated p52(PAI-1) expression. CX alone, however, induced low levels of p52(PAI-1) mRNA; increased p52(PAI-1) protein synthesis was evident after release of KNRK cells from CX blockade. Such CX-mediated induction was also sensitive to actinomycin D. Full stimulation of p52(PAI-1) expression in KNRK cells in response to the shape modulators NaB and/or CD involves transcriptional activation of the p52(PAI-1) gene, requires de novo RNA synthesis and occurs through a secondary-response (i.e. protein-synthesis-dependent) pathway.

Induced expression of p52(PAI-1) in normal rat kidney cells by the microfilament-disrupting agent cytochalasin D

In established normal rat kidney (NRK) cells, synthesis of the 52 kDa type-1 inhibitor of plasminogen activator [p52(PAI-1)] is stimulated by the cell shape-modulating fungal metabolite cytochalasin D (CD). Induction paralleled the time course of morphologic change and reflected relatively specific increases in saponin-resistant p52(PAI-1) protein accumulation (approximating ten- to thirty-fold over control) and mRNA abundance (seven- to nine-fold). Augmented p52 (PAI-1) mRNA levels closely correlated with increases in 43 kDa p52(PAI-1) core protein biosynthesis. Sensitivity to tunicamycin indicated that N-linked post-translational modifications to this 43 kDa core species generated the full complement of 50 kDa (intermediate) and 52 kDa (mature) p52(PAI-1) glycosylated isoforms. CD-induced p52(PAI-1) expression occurred efficiently in quiescent NRK cells maintained under serum-free conditions as well as in fully serum-supplemented actively growing cultures. While 8-bromo-cAMP reduced both constitutive and transforming growth factor-beta-induced p52(PAI-1) synthesis by > 50%, no such inhibition was evident in short-term (4 h) CD-stimulated cultures. Long-term (24 h) exposure of NRK/CD cells to 8-bromo-cAMP did result in an approximately 34% reduction in stimulated p52(PAI-1) expression, however, levels expressed by NRK/CD+cAMP populations remained markedly elevated relative to control values. These data suggest the existence of a cell shape-dependent aspect of p52(PAI-1) expression control distinct from both the constitutive and growth factor-mediated pathways of gene regulation.

Abnormal rectal cell proliferation and p52/p35 protein expression in patients with ulcerative colitis

We evaluated the presence of cell proliferation and antigenic abnormalities in rectal biopsies from 37 patients affected by ulcerative colitis and 15 controls. The study was carried out by thymidine labeling and immunochemistry, using antibodies against specific cytoskeletal-associated proteins (p52, p35, alpha-actinin). Among ulcerative colitis patients, 24 had an immunofluorescence pattern similar to that of controls, while 13 showed an abnormal distribution of one or more proteins (p52 alone or p52 and either p35 or alpha-actinin) within the rectal crypts. Patients showed a shift of the proliferative compartment towards the top of the rectal crypts compared with controls. This finding was more evident in patients with p52 or p35 abnormalities. Proliferative and antigenic defects were not related either to age or the duration of colitis. These phenotypic changes might be a biomarker of increased risk of colon cancer in ulcerative colitis.

Growth state-regulated expression of p52(PAI-1) in normal rat kidney cells

In normal rat kidney (NRK) cells, synthesis of the 52-kDa substrate-associated type 1 inhibitor of plasminogen activator [p52(PAI-1)] is linked to alterations in cell shape and substrate adhesion. Subconfluent NRK cells accumulated significantly more ventral undersurface-associated p52(PAI-1) compared to newly confluent or 1-to 2-day postconfluent cultures, suggesting that p52(PAI-1) expression was also growth state-modulated. Since cytoarchitectural constraints function in cell growth control, changes in p52(PAI-1) synthesis were assessed with respect to defined morphologic events that accompany growth activation of cultured NRK cells. Stimulation of low population density, quiescent NRK cells with 20% serum-containing medium resulted in a rapid increase in matrix p52(PAI-1) protein content (6- and 26-fold after 1 and 5 hr, respectively). Growth activation in response to serum reflected activations in p52(PAI-1) cytoplasmic mRNA abundance, which peaked at 2 hr (125-fold increase) and subsequently declined (100-fold increase) at 5 hr poststimulation. Morphologic analysis indicated that quiescent NRK cells were devoid of transcytoplasmic actin filaments and focal contact-associated vinculin. A marked increase in the fraction of cells that elaborated transcytoplasmic microfilaments and vinculin-containing focal adhesions was evident within 5 min of serum addition. Such cytoarchitectural restructuring preceded p52(PAI-1) induction. Morphologic reorganization and p52(PAI-1) induction occurred prior to progression of cells through the S-phase, indicating they are early events associated with serum stimulation in the NRK cell system. The relevance of p52(PAI-1) induction during this growth state transition is not clear but may influence the established cytoarchitectural changes observed prior to p52(PAI-1) induction by regulating pericellular proteolysis and, thereby, cell-to-substrate adhesion.

Pleotrophic action of interferon gamma in human orbital fibroblasts

Analysis of the two-dimensional electrophoretic patterns of total radiolabeled cellular proteins derived from human orbital fibroblast cultures revealed that interferon gamma (100 U/ml) elicited significant quantitative changes in 42% of 86 randomly-selected proteins relative to untreated cultures. The most substantial up-regulation involved a protein with pI/mw map coordinates of 5.9/54,000 and a heterogenous 5 isoform protein cluster (pIs = 6.1-5.6) of approximately 47- to 50-kDa. These proteins were identified as the previously described 54-kDa protein inducible in interferon gamma-sensitive cell types and type-1 plasminogen activator inhibitor (PAI-1), respectively. Definition of PAI-1 as an interferon gamma-responsive protein in orbital fibroblasts was confirmed by immunoprecipitation using PAI-1-specific antibodies. Induction of PAI-1 and the 54-kDa protein in orbital fibroblasts, moreover, was relatively specific for interferon gamma since interferon alpha failed to initiate a similar inductive response. The synthesis of a 170 kDa protein, tentatively identified as a collagen, was decreased by approximately 80%. Analysis of the labeled proteins secreted into the culture medium revealed that interferon gamma increased the medium content of fibronectin and decreased the secretion of collagen. It would appear from these data that the inflammatory cytokine can exert regulatory effects on the synthesis of many specific proteins in orbital fibroblasts.

Cell-shape-associated transcriptional activation of the p52(PAI-1) gene in rat kidney cells

The microfilament-disrupting agent cytochalasin D (CD) increased (by 10-22-fold) the synthesis de novo and extracellular matrix deposition of plasminogen-activator inhibitor type-1 [p52(PAI-1)] in normal rat kidney (NRK) cells. Transition from a flat to a round phenotype occurred concomitantly with, and may actually precede, p52(PAI-1) induction; both the morphological and p52(PAI-1) responses were dose-dependent. Augmented synthesis became evident between 4 and 5 h of treatment of NRK cells with 100 microM-CD, correlating with a transition from 25 to more than 60% rounded cells. CD-associated increases in p52(PAI-1) mRNA abundance and protein biosynthesis were maximal between 6 and 8 h of continuous CD exposure, declined by 50% thereafter, but remained elevated (by at least 6-21-fold respectively over control values) for 24 h. Changes in p52(PAI-1) mRNA abundance at this 24 h point reflected an approx. 5-fold increase in p52(PAI-1)-gene transcription. These data confirm previous suggestions, based on actinomycin D-sensitivity of the inductive response [Higgins & Ryan (1992) Biochem. J. 284, 433-439], that CD-mediated increases in p52(PAI-1) expression are at least partly due to transcription-level events. Since CD also augments specific cellular responses to growth factors or cytokines, the potential effectiveness of this inducer was evaluated both in the presence and absence of serum growth factors using quiescent NRK cells [a growth state in which p52(PAI-1) is not expressed] as a model system. Induction of p52(PAI-1) synthesis and matrix deposition in CD-stimulated quiescent NRK cells was as efficient under growth-factor-deficient conditions as when CD was added simultaneously with serum. CD alone is thus a complete inducer of p52(PAI-1) expression in NRK cells, an observation that supports the contention that cell shape is an important regulatory element in p52(PAI-1)-gene control.

Cell shape changes during transition of basal keratinocytes to mature enucleate-cornified envelopes: modulation of terminal differentiation by fibronectin

Normal human keratinocytes (NHK) in submerged culture were used to assess mechanisms associated with in vitro exposure to known stimulators (sodium butyrate; NaB) and inhibitors (fibronectin; FN) of NHK maturation. A multiparameter approach was used to define cell types generated under a range of growth conditions. Differentiation induced in response to NaB occurred through a series of morphologically distinct phenotypes and culminated in the formation of enucleate-cornified envelopes. Two-dimensional electrophoresis provided a limited database to evaluate global changes in cellular protein composition as a function of induced differentiation. Proteins were identified that characterized predominantly basal cell cultures, NaB-treated cells, and fully differentiated NHKs. Growth of NHKs on FN suppressed both spontaneous and NaB-directed maturation and inhibited maximal expression of protein changes associated with the differentiated state. Thus, the composition of the extracellular matrix can modulate (at both the morphologic and protein levels) the response of basal NHKs to a potent differentiation-inducing agent. Abrogation of NHK maturation by FN was not due to adverse effects on cellular metabolism, abortive differentiation, or altered timing of induced differentiation. FN appears to exert its suppressive effect by either maintaining an early stem cell phenotype which is poorly competent for terminal maturation or attenuating an as yet unknown aspect of the NaB-initiated differentiation cascade.

Identification of the 52 kDa cytoskeletal-like protein of cytochalasin D-stimulated normal rat kidney (NRK/CD) cells as substrate-associated glycoprotein p52 [plasminogen-activator inhibitor type-1 (PAI-1)]. Expression of p52 (PAI-1) in NRK/CD cells is regulated at the level of mRNA abundance

Cell shape profoundly affects cellular metabolic activity, protein and nucleic acid synthesis, and cytoskeletal organization. To examine the influence of cell shape on protein expression, normal rat kidney (NRK) cells were exposed to the microfilament-disrupting drug cytochalasin D (CD), labelled with [35S]methionine, and newly synthesized cellular and cytoskeletal proteins examined by two-dimensional gel electrophoresis. CD produced dramatic changes in cell shape (from a flat to round phenotype) with concomitant 3-7-fold increases in the cellular content and cytoskeletal deposition of the microfilament-associated proteins actin, alpha-actinin, and tropomyosin isoform 1. Augmented actin protein content in NRK/CD cells was paralleled by a corresponding increase in actin mRNA abundance and was inhibited by prior addition of actinomycin D. A detergent-insoluble protein of 52 kDa was also detected at high levels in the cytoskeletal fraction of NRK/CD cells. Two-dimensional electrophoretic mapping of total cellular and cytoskeletal proteins revealed this 52 kDa protein to be the previously described glycoprotein p52 [Higgins & Ryan (1989) Biochem. J. 257, 173-182]. By using electrophoretic and immunochemical criteria, p52 was identified as plasminogen-activator inhibitor type-1 (PAI-1). Like actin, CD-induced p52(PAI-1) synthesis, cellular content, and partitioning to the detergent-insoluble cytoskeletal compartment reflected a corresponding increase in p52(PAI-1) mRNA. Such induction was similarly inhibited by actinomycin D. p52(PAI-1) expression in the NRK-cell system is thus responsive to CD-mediated shape changes and requires ongoing RNA synthesis for its induction. Differential extraction of detached cell bodies and the substrate-adherent 'remnant' fraction of NRK/CD cultures, furthermore, indicated that p52(PAI-1) was not an intrinsic internal cytoskeletal element but, rather, selectively localized to the extracellular residue. p52(PAI-1) retained its detergent-insoluble characteristics even in this isolated 'remnant' fraction, where it was also the predominant protein species resolved.

p52(PAI-1) and actin expression in butyrate-induced flat revertants of v-ras-transformed rat kidney cells

Flat revertants of v-ras-transformed (KNRK) rat kidney cells, which express elevated levels of p21ras protein, were generated to high efficiencies with sodium butyrate (NaB). Overall protein synthesis in revertants was not different from parental cells, although changes were evident in expression and distribution of specific microfilament-associated cytoskeletal proteins. Quantitative two-dimensional electrophoresis revealed revertant-associated 3-4-fold increases in cytoskeletal deposition of the microfilament-associated proteins gelsolin and vinculin correlating with microfilament reorganization and focal-contact formation respectively. Similar increases in actin content were evident at both the total-cellular- and cytoskeletal-associated-protein levels. In contrast, intermediate-filament family elements (vimentin, lamins) remained unaltered. The only unique protein resolved in flat revertants was p52, a 52 kDa extracellular-matrix-associated protein previously identified as plasminogen-activator inhibitor type 1 (PAI-1). p52(PAI-1) expression was induced early during generation of the revertant phenotype and preceded development of focal-contact structures. NaB-induced p52(PAI-1) synthesis and generation of early morphological reversion in KNRK cells required ongoing RNA synthesis, since exposure to actinomycin D before addition of NaB inhibited both events. p52(PAI-1) induction by NaB was regulated at the level of mRNA abundance; in contrast, actin mRNA levels were the same in parental and revertant cells, suggesting that the increased actin content which typified the revertant phenotype was due to augmented actin microfilament stability.

Cell-shape regulation and matrix protein p52 content in phenotypic variants of ras-transformed rat kidney fibroblasts. Functional analysis and biochemical comparison of p52 with proteins implicated in cell-shape determination

The 52 kDa transformation-sensitive protein p52 was previously identified as a major substrate-associated component of normal rat kidney (NRK) fibroblasts [Higgins & Ryan (1989) Biochem. J. 257, 173-182]. p52 selectively localized to cellular fractions enriched in substrate focal-contact sites and associated ventral undersurface elements. Rapid attachment/spreading of NRK cells on to prepared p52 matrices and inhibition of fibroblast spreading by antibodies to p52 indicated that this protein participates in shape determination or cell-to-substrate adhesion. NRK cells transformed with Kirsten murine sarcoma virus (KiMSV), with a temperature-sensitive mutant (ts-371 KiMSV) and maintained at the permissive temperature, or with the cloned EJrasval.12 oncogene, exhibited down-regulated accumulation of p52 in the ventral undersurface region. Immunochemical, lectin-affinity and electrophoretic analyses indicated that p52 shares considerable sequence similarity with plasminogen-activator inhibitor type-1, which is consistent with its subcellular localization and likely morphoregulatory activity. The marked down-regulation of p52 expression seen in four different ras-mediated transformation systems, its induction prior to butyrate-induced morphological reorganization in KiMSV-transformed cells, and the morphological consequences of exogenously added p52 or p52 antibodies on NRK fibroblasts suggest that this protein probably functions in cell-shape regulation. Abrogation of p52 matrix accumulation typically seen in ras transformants may contribute, therefore, to the aberrant cytoarchitecture characteristic of malignant fibroblasts.

TGF-alpha and TGF-beta expression during sodium-N-butyrate-induced differentiation of human keratinocytes: evidence for subpopulation-specific up-regulation of TGF-beta mRNA in suprabasal cells

Sodium-N-butyrate (NaB) induces terminal differentiation and cornified envelope formation in cultured human keratinocytes. In the present study we explored the question of whether NaB-induced maturation could be mediated through changes in TGF-alpha and TGF-beta expression in normal keratinocytes. NaB induced a four-fold increase in TGF-beta mRNA transcript levels. This increase in TGF-beta mRNA abundance occurred only within the nonbasal keratinocyte subpopulation which maximally responds to NaB treatment by progression to cornified envelopes. Basal keratinocytes, which are relatively refractive to cornified envelope formation, did not show any increase in TGF-beta mRNA abundance after NaB treatment. By comparison, TGF-alpha mRNA transcript and extracellular TGF-alpha protein levels were unaffected by NaB treatment. A 50% decrease in EGF receptor binding was observed in NaB-treated keratinocyte cultures, rendering the cells less responsive to proliferation induction.

Epidermal cell-shape regulation and subpopulation kinetics during butyrate-induced terminal maturation of normal and SV40-transformed human keratinocytes: epithelial models of differentiation therapy

Recent data indicate that malignant human epidermal cells may be appropriate targets for sodium butyrate (NaB)-mediated differentiation therapy. The response of pre- and post-crisis populations of SV40-transformed human keratinocytes (SVKs) to this differentiation-inducing agent was assessed, therefore, within the framework of NaB-directed normal human keratinocyte (NHK) maturation. NaB augmented cornified envelope (CE) production in NHK and pre-crisis SVK cultures; the time-course and efficiency of induced maturation were similar in the 2 cell systems. In NHKs, the percentage of amplifying ("B" substate) cells decreased with time in NaB correlating with increases in both "C" stage keratinocytes and CEs. The latter formed over one or 2 layers of nucleated basal-like cells. Inductions were accompanied by immediate cell cycle blocks (in both the G1 and G2/M phases), reorganization within the actin cytoskeleton, and transient early increases in cellular actin content. Increased NHK and pre-crisis SVK cytoskeletal-associated actin reached a maximum approximately 48 hr after NaB addition and preceded development of CEs. The CE precursors, thus, probably reside in the "B" substate. Post-crisis SVKs, in contrast, were refractive to NaB-induced terminal maturation or cell-cycle perturbation, failed to initiate actin filament rearrangements, and retained a basal cell-like phenotype. Stable transformation of human SVKs in post-crisis phase, therefore, appears to be associated with loss of maturation "competence" within the "B" keratinocyte subpopulation.

Effects of 1,25-dihydroxyvitamin D3 and its analogs on butyrate-induced differentiation of HT-29 human colonic carcinoma cells and on the reversal of the differentiated phenotype

1,25-Dihydroxyvitamin D3 (1,25-(OH)2D3) greatly enhances sodium butyrate (NaB)-induced enterocyte differentiation of HT-29 human colonic carcinoma cells while 1,25-(OH)2D3 alone induces growth restriction without associated differentiation. In the present study, the efficacies of various analogs of 1,25-(OH)2D3 to enhance NaB-induced HT-29 differentiation and to prolong the reversal of the differentiated phenotype under NaB-free growth conditions were subsequently examined. Extent of HT-29 differentiation was assessed by measurement of alkaline phosphatase (AP) activity, appearance of mucin-producing cells, changes in morphological characteristics, and expression of differentiation-associated cytokeratin proteins. Among active analogs of 1,25-(OH)2D3, 26,26,26,27,27,27-hexafluoro-1,25-(OH)2D3 (F6-1,25-(OH)2D3), 24,24-difluoro-24-homo-1,25-(OH)2D3, and 26,27-dimethyl-1,25-(OH)2D3 were 100-, 10-, and 5-fold, respectively, more effective than 1,25-(OH)2D3 in enhancing NaB-induced mucin production. Combined use of NaB and F6-1,25-(OH)2D3 (10(-9) M) also induced HT-29 cells to form highly differentiated goblet-like enterocytes, and increased both cellular AP enzymatic activity and tissue-type cytokeratin content. This differentiated state was qualitatively more advanced than that achieved by a combination of NaB and 10(-7) M 1,25-(OH)2D3. NaB-mediated HT-29 differentiation (in short-term inductions) was found to be reversible following a return to NaB-free medium. HT-29 cells differentiated by combined use of NaB and 1,25-(OH)2D3 or its analogs exhibited a significant prolonged reversal time relative to cells differentiated with NaB alone. The most prominent effect was achieved using cells differentiated with NaB and 10(-9) M F6-1,25-(OH)2D3 which exhibited a 7-fold prolonged reversal time over colonocytes differentiated by NaB alone. Our data suggest that a combined use of NaB and 1,25-(OH)2D3 or its derivatives may provide a convenient in vitro model system to probe molecular events associated with steroid-target tissue interactions in a differentiating cell system as commonly occurs in vivo. Such an analysis might lend itself to design of a rational combination differentiation-based therapy for the clinical management of colon cancer.

The substrate-associated protein p45 of porcine endothelial cells: multiple isoforms, cytoskeletal-like properties and induction by hyperoxic stress

1. Cultured mesenchymal cells respond to hyperoxic (hyper-O2) stress with increased cell flattening/substrate adhesion and overall 47-69% reductions in total matrix-associated (i.e. saponin-resistant [SAP fraction]) protein. 2. Electrophoretic analysis revealed a selective hyper-O2-related 2.7- to 4-fold increase in SAP and cytoskeletal fraction deposition of the protein p45 beginning early (within 12 hr) after initial exposure of porcine endothelial cells to hyper-O2 and increasing over a 48 hr period. 3. p45 consisted of 8 distinct isoforms differing only in pI; hyper-O2-augmented matrix deposition of 3. p45 consisted of 8 distinct isoforms differing only in pI; hyper-02-augmented matrix deposition of p45 involved all 8 isoforms with the more basic subtypes exhibiting slightly greater net increases. 4. Both the specificity and time course of p45 induction, relative to the onset of hyper-O2 cytoarchitectural remodeling, indicate that p45 up-regulation constitutes an early aspect of the hyper-O2 adaptive response.

Cytochalasin D-mediated hyperinduction of the substrate-associated 52-kilodalton protein p52 in rat kidney fibroblasts

Regulation of certain differentiated and housekeeping functions in cultured mammalian cells is significantly influenced by cell shape. The shape-modulating agent cytochalasin D (CD) was used, therefore, to elucidate potential cytoarchitectural influences affecting synthesis of a major 52 kDa secreted/substrate-associated protein (p52) of normal rat kidney (NRK) fibroblasts. Biosynthetic labeling experiments indicated that treatment of NRK cells with CD increased, by 10-18-fold, the medium content of an Mr 52,000 protein. Two-dimensional gel electrophoresis and peptide fragment mapping confirmed that the 52 kDa protein produced in abundance as a consequence of CD treatment was identical to p52 constitutively expressed by NRK cells. A lower mw protein (p50; Mr 50,000) was also resolved which, based on pl microheterogeneity, protease fragmentation profile, and sensitivity to tunicamycin, could be identified as a less-glycosylated form of p52. p50 and p52 were both detected in the matrix and medium compartments of NRK and NRK/CD cells. The matrix p52 content of CD-induced and uninduced cells, however, was significantly greater (by 200-500-fold) than the corresponding medium levels. This differential compartmentalization, the time course of p52 accumulation in the matrix of NRK/CD cells compared to its appearance in the medium, and the kinetics of p52 pulse-chase from the matrix collectively indicated that the matrix is the initial site of p52 deposition. Low levels of CD (1 microM) produced extensive disruptions of cellular microfilaments but did not result in an overall cell shape change nor a hyperinduction of p52. Morphologic rounding (seen in 10-100 microM CD) coincided with augmented p52 production. Transition from a flat to a round phenotype in NRK cells, or at least the generation of sufficient microfilament fragmentation to compromise cell-substrate adhesivity, appears to be an essential aspect of CD-mediated p52 hyperinduction.

Cytoarchitecture of ras oncogene-expressing tumor cells: butyrate modulation of substrate adhesion, cytoskeletal actin content and subcellular microfilament distribution

1. The subcellular distribution of particular cytoskeletal (CSK) and cell-substrate adhesive elements was assessed during the morphologic response of cultured tumor cells to the shape modulating agent sodium butyrate (NaB). 2. NaB induced marked increases in cellular and CSK actin content and in the matrix-associated proteins fibronectin and p52. 3. Subcellular fractionation indicated disproportionate increases in the actin content of the substrate-attached cellular residue (SAM fraction) which contains the majority of cell-substrate adhesive elements. 4. Augmented cell spreading and substrate attachment characteristic of NaB-treated cells is likely due to increased elaboration of cell-to-substrate adhesive structures and reflected in an enhanced deposition of actin into the CSK and SAM compartments.