Gold nanoparticles cellular toxicity and recovery: effect of size, concentration and exposure time.

Gold nanoparticles (AuNPs) are used in many applications; however, their interactions with cells and potential health risk(s) are not fully known. In this manuscript, we describe the interactions of AuNPs with human dermal fibroblasts and show that they can penetrate the plasma membrane and accumulate in large vacuoles. We also demonstrate that the uptake of the AuNPs is a function of time, their size and concentration. Specifically, we demonstrate that 45 nm AuNPs penetrate cells via clathrin-mediated endocytosis, while the smaller 13 nm enter mostly via phagocytosis. Furthermore, we provide evidence of cytoskeleton filament disruption as a result of AuNPs exposure and reconstitution during recovery (following AuNP removal), despite no changes in actin or beta-tubulin protein levels. In contrast, the expression of the extracellular matrix (ECM) proteins, collagen and fibronectin, was diminished in the cells exposed to AuNPs. We also examined the proliferation rates of cells exposed to AuNPs and show that its diminution is a function of apoptosis and speculate that apoptosis results from the number of vacuoles present in the cells, which is probably the main factor that disrupts the cytoskeleton causing cell area contraction and decreases in motility. Lastly, we also present data that indicates that AuNPs' damage to cells is not permanent and that the cells can completely recover as a function of AuNPs' size, concentration and exposure time. Taken together, our data suggest that AuNPs exert detrimental effects on cell function that could reverse following AuNPs removal.

Perturbation of transforming growth factor (TGF)-beta1 association with latent TGF-beta binding protein yields inflammation and tumors.

Transforming growth factor-beta (TGF-beta) activity is controlled at many levels including the conversion of the latent secreted form to its active state. TGF-beta is often released as part of an inactive tripartite complex consisting of TGF-beta, the TGF-beta propeptide, and a molecule of latent TGF-beta binding protein (LTBP). The interaction of TGF-beta and its cleaved propeptide renders the growth factor latent, and the liberation of TGF-beta from this state is crucial for signaling. To examine the contribution of LTBP to TGF-beta function, we generated mice in which the cysteines that link the propeptide to LTBP were mutated to serines, thereby blocking covalent association. Tgfb1(C33S/C33S) mice had multiorgan inflammation, lack of skin Langerhans cells (LC), and a shortened lifespan, consistent with decreased TGF-beta1 levels. However, the inflammatory response and decreased lifespan were not as severe as observed with Tgfb1(-/-) animals. Tgfb1(C33S/C33S) mice exhibited decreased levels of active TGF-beta1, decreased TGF-beta signaling, and tumors of the stomach, rectum, and anus. These data suggest that the association of LTBP with the latent TGF-beta complex is important for proper TGF-beta1 function and that Tgfb1(C33S/C33S) mice are hypomorphs for active TGF-beta1. Moreover, although mechanisms exist to activate latent TGF-beta1 in the absence of LTBP, these mechanisms are not as efficient as those that use the latent complex containing LTBP.

The presence of B-type natriuretic peptide in burns and the responsiveness of fibroblasts to BNP: proof of principle.

BACKGROUND: B-type natriuretic peptide (BNP) released from cardiac myocytes plays an important role in cardiac homeostasis through cyclic guanosine monophosphate (cGMP) activation. BNP also reduces cardiac remodeling and fibrosis. The antifibrotic effects of BNP are mediated in part by blocking the effects of transforming growth factor beta, a profibrotic cytokine that plays a significant role in cutaneous wound healing. It is unclear if BNP plays any role in cutaneous wound healing. OBJECTIVES: To investigate if BNP levels would be elevated in thermally injured human skin and if human-derived fibroblasts would respond to BNP exposure by increasing levels of cGMP. METHODS: This was an in vitro analysis of human skin. Skin samples and cells were collected from patients with and without thermal injury. The authors stained three skin samples from normal skin (taken at the time of elective cosmetic surgery) with antibodies to BNP and compared these with three tissue samples obtained from burned human skin taken during tangential excision of deep burns. Normal human-derived fibroblasts and keratinocytes were exposed in triplicate to BNP in vitro, and cGMP accumulation was evaluated. Levels of cGMP were quantified and compared with analysis of variance. RESULTS: BNP was present in all specimens of thermally injured skin (especially around collagen, epithelial cells, and endothelial cells) but not in any uninjured skin samples (p = 0.05, single-tailed Fisher's exact test). In vitro grown fibroblasts showed significant increases of cGMP levels with increasing levels of BNP exposure (mean [+/-SD]: 0.6 [+/-0.3], 1.2 [+/-0.2], 4.6 [+/-0.1], and 5.0 [+/-0.9] pmol/mL with BNP concentrations of 0, 10, 500, and 1,000 nmol/L, respectively; p < 0.001). The effect of BNP on keratinocytes was minimal and below the level of quantification. CONCLUSIONS: These findings demonstrate proof of principle that human fibroblasts are responsive to the effects of BNP in vitro and that BNP is present in injured skin, suggesting that BNP may play a role in cutaneous wound healing.

Absence of integrin-mediated TGFbeta1 activation in vivo recapitulates the phenotype of TGFbeta1-null mice.

The multifunctional cytokine transforming growth factor (TGF) beta1 is secreted in a latent complex with its processed propeptide (latency-associated peptide [LAP]). TGFbeta1 must be functionally released from this complex before it can engage TGFbeta receptors. One mechanism of latent TGFbeta1 activation involves interaction of the integrins alpha v beta6 and alpha v beta8 with an RGD sequence in LAP; other putative latent TGFbeta1 activators include thrombospondin-1, oxidants, and various proteases. To assess the contribution of RGD-binding integrins to TGFbeta1 activation in vivo, we created a mutation in Tgfb1 encoding a nonfunctional variant of the RGD sequence (RGE). Mice with this mutation (Tgfb1(RGE/RGE)) display the major features of Tgfb1(-/-) mice (vasculogenesis defects, multiorgan inflammation, and lack of Langerhans cells) despite production of normal levels of latent TGFbeta1. These findings indicate that RGD-binding integrins are requisite latent TGFbeta1 activators during development and in the immune system.

TSP50 encodes a testis-specific protease and is negatively regulated by p53.

Earlier studies suggested that TSP50 is a testis-specific gene that encodes a protein, which is homologous to serine proteases but differs in that threonine replaces serine in its catalytic triad. Most importantly, it was abnormally reactivated in many breast cancer biopsies tested. While further investigating its biochemical and cell biological natures, we found that TSP50 exhibited enzyme activity and was located in the endoplasmic reticulum and cytosol membrane. During our studies to elucidate the regulatory mechanisms related to its differential expression, we discovered a putative p53-binding site and several Sp1-binding sites in the TSP50 promoter, which led us to test if it was regulated by the p53 gene. We found that the p53 transgene negatively regulated the TSP50 promoter in diverse types of cell lines. This result was consistent with other observations: (a) p53 overexpression reduced endogenous TSP50 expression; and (b) breast cancer cell lines containing mutated p53, such as MCF7/Adr, or normal p53, such as MCF7, produced high or low levels of TSP50 transcripts, which was consistent with the fact that TSP50 promoter activity was much higher in MCF7/Adr than that in MCF7 cells. We also found that the quantity of Sp1 transcription factor was lower in MCF7/Adr than in MCF7 cells, which suggested that another mechanism (i.e., transcription factor modulation) was also involved in TSP50 differential expression.

Isoform-specific activation of latent transforming growth factor beta (LTGF-beta) by reactive oxygen species.

The three mammalian transforming growth factor beta (TGF-beta) isoforms are each secreted in a latent complex in which TGF-beta homodimers are non-covalently associated with homodimers of their respective pro-peptide called the latency-associated peptide (LAP). Release of TGF-beta from its LAP, called activation, is required for binding of TGF-beta to cellular receptors, making extracellular activation a critical regulatory point for TGF-beta bioavailability. Our previous work demonstrated that latent TGF-beta1 (LTGF-beta1) is efficiently activated by ionizing radiation in vivo and by reactive oxygen species (ROS) generated by Fenton chemistry in vitro. In the current study, we determined the specific ROS and protein target that render LTGF-beta1 redox sensitive. First, we compared LTGF-beta1, LTGF-beta2 and LTGF-beta3 to determine the generality of this mechanism of activation and found that redox-mediated activation is restricted to the LTGF-beta1 isoform. Next, we used scavengers to determine that ROS activation was a function of OH(.) availability, confirming oxidation as the primary mechanism. To identify which partner of the LTGF-beta1 complex was functionally modified, each was exposed to ROS and tested for the ability to form a latent complex. Exposure of TGF-beta1 did not alter its ability to associate with LAP, but exposing LAP-beta1 to ROS prohibited this phenomenon, while treatment of ROS-exposed LAP-beta1 with a mild reducing agent restored its ability to neutralize TGF-beta1 activity. Taken together, these results suggest that ROS-induced oxidation in LAP-beta1 triggers a conformational change that releases TGF-beta1. Using site-specific mutation, we identified a methionine residue at amino acid position 253 unique to LAP-beta1 as critical to ROS-mediated activation. We propose that LTGF-beta1 contains a redox switch centered at methionine 253, which allows LTGF-beta1 to act uniquely as an extracellular sensor of oxidative stress in tissues.

Epigenetic regulation of WTH3 in primary and cultured drug-resistant breast cancer cells.

Previous studies showed that the WTH3 gene functioned as a negative regulator during multidrug resistance (MDR) development in vitro. To understand whether this gene is also involved in clinical drug resistance, hypermethylation at its promoter region observed in cultured MDR MCF7/AdrR cells was examined in primary drug-resistant breast cancer epithelial cells isolated from effusions of breast cancer patients. The results showed that this event also occurred in drug-resistant breast cancer epithelial cells and a newly induced drug-resistant cell line, MCF7/inR. Interestingly, we found that a CpG (CpG 23) that was close to the TATA-like box was constantly methylated in the WTH3 promoter of drug-resistant breast cancer epithelial and cultured MDR cells. Mutagenic study suggested that this CpG site had a functional effect on promoter activity. We also discovered that MCF7/AdrR cells treated with trichostatin A, a histone deacetylase inhibitor, exhibited higher WTH3, but lower MDR1, expression. A reverse correlation between WTH3 and MDR1 gene expression was also observed in MCF7/AdrR, and its non-MDR parental cell line, MCF7/WT. This result indicated that both DNA methylation and histone deacetylase could act in concert to inhibit WTH3 and consequently stimulate MDR1 expression. This hypothesis was supported by data obtained from introducing the WTH3 transgene into MDR cell lines, which reduced endogenous MDR1 expression. Therefore, our studies suggested that the behavior of WTH3 in primary drug-resistant breast cancer epithelial cells was similar to that in a model system where epigenetic regulation of the WTH3 gene was linked to the MDR phenotype.

Methods for measuring TGF-b using antibodies, cells, and mice.

The transforming growth factor (TGF)-betas are essential in pre- and postnatal development, differentiation and morphogenesis of higher organisms. Quantitation of the levels of TGF-beta synthesis, secretion, and activation are crucial for grasping the mechanisms that control these events and ultimately control TGF-beta action. Rather than presenting a single method, we describe several methods for measuring active TGF-beta in different experimental situations. This is possible as a result of advances in transgenic mice technology that allow in vivo TGF-beta measurements in addition to the more established in vitro approaches.

WTH3, which encodes a small G protein, is differentially regulated in multidrug-resistant and sensitive MCF7 cells.

The WTH3 gene's biological characteristics and relationship to multidrug resistance (MDR) were investigated further. Results showed that WTH3 was mainly located in the cytosol and capable of binding to GTP. In addition, WTH3's promoter function was significantly attenuated in MDR (MFC7/AdrR) relative to non-MDR (MCF7/WT) cells. Advanced analyses indicated that two mechanisms could be involved in WTH3's down-regulation: DNA methylation and trans-element modulations. It was found that the 5' end portion of a CpG island in WTH3's promoter was hypermethylated in MCF7/AdrR but not MCF7/WT cells, which could have a negative effect on the WTH3 promoter. This idea was supported by the observation that a 45-bp sequence (DMR45) in this differentially methylated region positively influenced promoter activity. We also discovered that different nuclear proteins in MCF7/AdrR and MCF7/WT cells bound to methylated or nonmethylated DMR45. Moreover, a sequence containing a unique repeat that was also a positive cis-element for the promoter was attached by different transcription factors depending on whether they were prepared from MCF7/AdrR or MCF7/WT cells. These molecular changes, apparently induced by drug treatment, resulted in WTH3's down regulation in MDR cells. Therefore, present studies support previous observations that WTH3, as a negative regulator, participates in MDR development in MCF7/AdrR cells.

Lung alveolar septation defects in Ltbp-3-null mice.

Latent transforming growth factor (TGF)-beta binding proteins (LTBPs) modulate the secretion and activation of latent TGF-beta. To explore LTBP function in vivo, we created an Ltbp-3(-/-) mouse that has developmental emphysema with decreased septation in terminal alveoli. Differences in distal airspace enlargement were obvious at day 6 after birth. Secondary septation was inhibited, so by days 21 to 28 the mean linear intercept was approximately twofold greater in mutant versus control lungs. There were no differences in lung collagen and elastin, visualized by immunohistochemistry, or in myofibroblast numbers, determined by alpha-smooth muscle actin-positive cells, between mutant or wild-type lungs as the animals aged, other than differences associated with altered lung structure in mutant animals. However, from day 10 there was twice the number of alveolar type II cells in mutant alveoli compared to controls. At days 6 and 10, a transient enhancement in cell proliferation in the mutant lungs was observed by both 5-bromo-2'-deoxy-uridine and proliferating cell nuclear antigen labeling, accompanied by enhanced numbers of terminal dUTP nick-end labeling-positive cells at days 4, 6, and 10. Finally, there was a transient decrease in TGF-beta signaling at days 4 to 6 in Ltbp-3(-/-) lungs. These results indicate that in the absence of Ltbp-3, a temporary decrease in TGF-beta signaling in the lungs at days 4 to 6 alters cell proliferation, correlating with inhibition of septation and developmental emphysema.

Expression of truncated latent TGF-beta-binding protein modulates TGF-beta signaling.

Transforming growth factor-beta is released from most cells as an inactive complex consisting of transforming growth factor-beta, the transforming growth factor-beta propeptide and the latent transforming growth factor-beta-binding protein. We studied the role of latent transforming growth factor-beta-binding protein in modulating transforming growth factor-beta availability by generating transgenic mice that express a truncated form of latent transforming growth factor-beta-binding protein-1 that binds to transforming growth factor-beta but is missing the known N- and C-terminal matrix-binding sequences. As transforming growth factor-beta is an inhibitor of keratinocyte proliferation and is involved in the control of hair cycling, we over-expressed the mutated form of latent transforming growth factor-beta-binding protein under the control of the keratin 14-promoter. Transgenic animals displayed a hair phenotype due to a reduction in keratinocyte proliferation, an abbreviated growth phase and an early initiation of the involution (catagen) phase of the hair cycle. This phenotype appears to result from excess active transforming growth factor-beta, as enhanced numbers of pSmad2/3-positive nuclei are observed in transgenic animal skin. These data suggest that the truncated form of latent transforming growth factor-beta-binding protein-1 competes with wild-type latent transforming growth factor-beta-binding protein for binding to latent transforming growth factor-beta, resulting in latent transforming growth factor-beta complexes that fail to be targeted correctly in the extracellular matrix. The mis-localization of the transforming growth factor-beta results in inappropriate activation and premature initiation of catagen, thereby illustrating the significance of latent transforming growth factor-beta-binding protein interaction with transforming growth factor-beta in the targeting and activation of latent transforming growth factor-beta in addition to previously reported effects on small latent complex secretion.