N-acylsphingosine amidohydrolase 1 promotes melanoma growth and metastasis by suppressing peroxisome biogenesis-induced ROS production.

OBJECTIVE: Metabolic deregulation is a key hallmark of cancer cells and has been shown to drive cancer growth and metastasis. However, not all metabolic drivers of melanoma are known. Based on our finding that N-acylsphingosine amidohydrolase 1 (ASAH1) is overexpressed in melanoma, the objective of these studies was to establish its role in melanoma tumor growth and metastasis, understand its mechanism of action, and evaluate ASAH1 targeting for melanoma therapy. METHODS: We used publicly available melanoma datasets and patient-derived samples of melanoma and normal skin tissue and analyzed them for ASAH1 mRNA expression and ASAH1 protein expression using immunohistochemistry. ASAH1 was knocked down using short-hairpin RNAs in multiple melanoma cell lines that were tested in a series of cell culture-based assays and mouse-based melanoma xenograft assays to monitor the effect of ASAH1 knockdown on melanoma tumor growth and metastasis. An unbiased metabolomics analysis was performed to identify the mechanism of ASAH1 action. Based on the metabolomics findings, the role of peroxisome-mediated reactive oxygen species (ROS) production was explored in regard to mediating the effect of ASAH1. The ASAH1 inhibitor was used alone or in combination with a BRAFV600E inhibitor to evaluate the therapeutic value of ASAH1 targeting for melanoma therapy. RESULTS: We determined that ASAH1 was overexpressed in a large percentage of melanoma cells and regulated by transcription factor E2F1 in a mitogen-activated protein (MAP) kinase pathway-dependent manner. ASAH1 expression was necessary to maintain melanoma tumor growth and metastatic attributes in cell cultures and mouse models of melanoma tumor growth and metastasis. To identify the mechanism by which ASAH1 facilitates melanoma tumor growth and metastasis, we performed a large-scale and unbiased metabolomics analysis of melanoma cells expressing ASAH1 short-hairpin RNAs (shRNAs). We found that ASAH1 inhibition increased peroxisome biogenesis through ceramide-mediated PPARγ activation. ASAH1 loss increased ceramide and peroxisome-derived ROS, which in turn inhibited melanoma growth. Pharmacological inhibition of ASAH1 also attenuated melanoma growth and enhanced the effectiveness of BRAF kinase inhibitor in the cell cultures and mice. CONCLUSIONS: Collectively, these results demonstrate that ASAH1 is a druggable driver of melanoma tumor growth and metastasis that functions by suppressing peroxisome biogenesis, thereby inhibiting peroxisome-derived ROS production. These studies also highlight the therapeutic utility of ASAH1 inhibitors for melanoma therapy.

Loss of thymidine kinase 1 inhibits lung cancer growth and metastatic attributes by reducing GDF15 expression.

Metabolic alterations that are critical for cancer cell growth and metastasis are one of the key hallmarks of cancer. Here, we show that thymidine kinase 1 (TK1) is significantly overexpressed in tumor samples from lung adenocarcinoma (LUAD) patients relative to normal controls, and this TK1 overexpression is associated with significantly reduced overall survival and cancer recurrence. Genetic knockdown of TK1 with short hairpin RNAs (shRNAs) inhibits both the growth and metastatic attributes of LUAD cells in culture and in mice. We further show that transcriptional overexpression of TK1 in LUAD cells is driven, in part, by MAP kinase pathway in a transcription factor MAZ dependent manner. Using targeted and gene expression profiling-based approaches, we then show that loss of TK1 in LUAD cells results in reduced Rho GTPase activity and reduced expression of growth and differentiation factor 15 (GDF15). Furthermore, ectopic expression of GDF15 can partially rescue TK1 knockdown-induced LUAD growth and metastasis inhibition, confirming its important role as a downstream mediator of TK1 function in LUAD. Collectively, our findings demonstrate that TK1 facilitates LUAD tumor and metastatic growth and represents a target for LUAD therapy.

Calcium Phosphate-Mediated Transfection of Eukaryotic Cells with Plasmid DNAs.

This protocol describes a calcium phosphate-mediated transfection method for use with plasmid DNAs and adherent cells. At the end of the protocol is an alternative method for high-efficiency generation of stable transfectants.

Calcium Phosphate-Mediated Transfection of Cells with High-Molecular-Weight Genomic DNA.

This protocol describes a calcium phosphate-mediated transfection method for use with high-molecular-weight genomic DNAs.

Calcium Phosphate-Mediated Transfection of Adherent Cells or Cells Growing in Suspension: Variations on the Basic Method.

This protocol describes two variations of the calcium phosphate-mediated transfection method. The first can be used with all types of adherent cells, but is particularly useful for polarized epithelial cells, which do not efficiently take up material by endocytosis through the apical plasma membrane. To improve transfection efficiency, adherent cells are trypsinized and collected by centrifugation. The cells are resuspended in the calcium phosphate-DNA coprecipitate and then plated again on tissue culture dishes. Most lines of cells grown in suspension are resistant to calcium phosphate-mediated transfection methods; however, a few cell lines grown as suspension cultures (e.g., HeLa cells) can be transfected using the second modified calcium phosphate procedure described here.

Transfection of Mammalian Cells with Calcium Phosphate-DNA Coprecipitates.

Biochemical methods of transfection, including calcium phosphate-mediated and diethylaminoethyl (DEAE)-dextran-mediated transfection, have been used for many years to deliver nucleic acids into cultured cells. Here, we briefly review the use of calcium phosphate-DNA coprecipitates for transfection.

Introducing Genes into Cultured Mammalian Cells.

Strategies for the delivery of genes into eukaryotic cells fall into three categories: transfection by biochemical methods, transfection by physical methods, and virus-mediated transduction. This introduction deals with the first two categories.

DNA Transfection by Electroporation.

Electroporation, which uses pulsed electrical fields, can be used to introduce DNA into a variety of animal cells, plant cells, and bacteria. Electroporation works well with cell lines that are refractory to other transfection techniques, such as lipofection and calcium phosphate-DNA coprecipitation. But, as with other transfection methods, the optimal conditions for electroporating DNA into untested cell lines must be determined empirically. Several different electroporation instruments are available commercially, and manufacturers supply detailed protocols for their use with specific cell types and guidelines for optimization with others. This method describes the conditions for electroporating mammalian cell lines using the Gene Pulser Xcell Electroporation System (Bio-Rad).

Electroporation.

Electroporation is a process in which brief electrical pulses create transient pores in the plasma membrane that allow nucleic acids to enter the cellular cytoplasm. Here, we provide information on the history, mechanism, and optimization of electroporation. We also describe nucleofection, an improvement of the electroporation technology that permits the introduction of nucleic acids directly into the nucleus.

DNA Transfection Mediated by Cationic Lipid Reagents.

Liposomal transfection reagents vary in their ability to transfect cell lines efficiently. Some are generalists, whereas others are best used with specific cell types. The nonliposomal FuGENE 6 and the cationic liposomal Lipofectamine 2000 are examples of reagents that can successfully transfect most adherent and suspension cell types (including several primary and hard-to-transfect cell types) with negligible toxicity and a minimal number of manipulations. Importantly, both reagents can be used to transfect cells in the presence of serum, minimizing the number of manipulations during the transfection procedure. We also provide an alternative protocol that uses the cationic lipid reagents Lipofectin and Transfectam.

Histochemical Staining of Cell Monolayers for ß-Galactosidase.

There are several methods for assaying the success of transient transfections. If a plasmid expressing Escherichia coli ß-galactosidase was used, then this histochemical staining procedure is simple to perform and yields dependable results. The following method was designed for cells growing in 60-mm culture dishes.

Lipofection.

In the past, cloned DNA was introduced into cultured eukaryotic cells chiefly by biochemical methods using either calcium phosphate or diethylaminoethyl (DEAE)-dextran. Lipid reagents are now preferred because of the high efficiency of transfection that can be obtained and because of the ability of this class of reagents to mediate transfection of all types of nucleic acids into a wide range of cell types.

Dot Blot Analysis for Measuring Global N6-Methyladenosine Modification of RNA.

Posttranscriptional modification of mRNAs plays an important role in establishing the functional diversity of the proteome. The m6A modification is found in many species of RNA, including tRNA, mRNA, rRNA, and long noncoding RNAs. The physiological role of m6A modification of RNA is not fully explored and is a topic of current research. It is predicted that the major effect of m6A modification of mRNAs is on its stability and/or translation. The global changes in m6A levels in total RNA or particular species of RNAs can be measured by dot blot analysis using m6A specific antibodies or using mass spectrometry following chromatographic separation. The dot blot method for detection of global m6A changes is a relatively straightforward method to quantitate m6A modification but suffers from low sensitivity when the fraction of m6A-modified RNA is small in analyzed samples. Here, we describe a modified dot blot method that is sensitive and quantitative for detecting m6A-modified RNA by adding an immunoprecipitation step to enrich for m6A-modified RNA.

Optical Transfection.

Strategies for the delivery of genes into eukaryotic cells fall into three categories: transfection by biochemical methods, transfection by physical methods, and virus-mediated transduction. "Optical transfection"-a physical transfection method-exploits the ability of light to create small transient pores in the plasma membrane of mammalian cells.

Selective Agents for Stable Transfection.

A stable cell line is generated when transfected DNA undergoes integration into a chromosome by nonhomologous recombination. Cells that stably express selectable (e.g., antibiotic-resistant) markers are also likely to have incorporated other DNA sequences. This phenomenon, in which physically unlinked genes are assembled into a single integrated array and expressed in the same transfected cell, is known as "cotransfection." Resistance to antibiotics has proven to be effective in selecting cotransfectants and, in some cases, as a driver for gene amplification.

Heparan Sulfate and Heparan Sulfate Proteoglycans in Cancer Initiation and Progression.

Heparan sulfate (HS) are complex unbranched carbohydrate chains that are heavily modified by sulfate and exist either conjugated to proteins or as free, unconjugated chains. Proteins with covalently bound Heparan sulfate chains are termed Heparan Sulfate Proteoglycans (HSPGs). Both HS and HSPGs bind to various growth factors and act as co-receptors for different cell surface receptors. They also modulate the dynamics and kinetics of various ligand-receptor interactions, which in turn can influence the duration and potency of the signaling. HS and HSPGs have also been shown to exert a structural role as a component of the extracellular matrix, thereby altering processes such as cell adhesion, immune cell infiltration and angiogenesis. Previous studies have shown that HS are deregulated in a variety of solid tumors and hematological malignancies and regulate key aspects of cancer initiation and progression. HS deregulation in cancer can occur as a result of changes in the level of HSPGs or due to changes in the levels of HS biosynthesis and remodeling enzymes. Here, we describe the major cell-autonomous (proliferation, apoptosis/senescence and differentiation) and cell-non-autonomous (angiogenesis, immune evasion, and matrix remodeling) roles of HS and HSPGs in cancer. Finally, we discuss therapeutic opportunities for targeting deregulated HS biosynthesis and HSPGs as a strategy for cancer treatment.

Transfection Mediated by DEAE-Dextran.

Here, we describe two variations on the classical DEAE-dextran transfection procedure. The first involves a brief exposure of cells to a high concentration of DEAE-dextran and yields higher transfection frequencies but elevated cellular toxicity. The second involves a longer exposure of cells to a lower concentration of DEAE-dextran, which produces lower transfection frequencies but increased cell survival.

DEAE-Dextran Transfection.

Biochemical methods of transfection, including calcium phosphate-mediated and diethylaminoethyl (DEAE)-dextran-mediated transfection, have been used for many years to deliver nucleic acids into cultured eukaryotic cells. Here, we briefly review the use of DEAE-dextran in transfection.

Analysis of Cell Viability by the alamarBlue Assay.

This protocol describes viability measurements for cell cultures in a 96-well tissue culture plate using alamarBlue (resazurin). The assay can be modified to accommodate larger plates; however, for a preliminary analysis of transfection reagents and parameters of the transfection protocol on cell viability, a 96-well plate format is the most cost effective.

Analysis of Cell Viability by the Lactate Dehydrogenase Assay.

A common method for determining cytotoxicity is based on measuring the activity of cytoplasmic enzymes released by damaged cells. Lactate dehydrogenase (LDH) is a stable cytoplasmic enzyme that is found in all cells. LDH is rapidly released into the cell culture supernatant when the plasma membrane is damaged, a key feature of cells undergoing apoptosis, necrosis, and other forms of cellular damage. LDH activity can be easily quantified by using the NADH produced during the conversion of lactate to pyruvate to reduce a second compound in a coupled reaction into a product with properties that are easily quantitated. This protocol measures the reduction of a yellow tetrazolium salt, INT, by NADH into a red, water-soluble formazan-class dye by absorbance at 492 nm. The amount of formazan is directly proportional to the amount of LDH in the culture, which is, in turn, directly proportional to the number of dead or damaged cells.