Kannan Krishnamurthy

Selective apoptosis of pluripotent mouse and human stem cells by novel ceramide analogues prevents teratoma formation and enriches for neural precursors in ES cell–derived neural transplants

The formation of stem cell–derived tumors (teratomas) is observed when engrafting undifferentiated embryonic stem (ES) cells, embryoid body–derived cells (EBCs), or mammalian embryos and is a significant obstacle to stem cell therapy. We show that in tumors formed after engraftment of EBCs into mouse brain, expression of the pluripotency marker Oct-4 colocalized with that of prostate apoptosis response-4 (PAR-4), a protein mediating ceramide-induced apoptosis during neural differentiation of ES cells. We tested the ability of the novel ceramide analogue N-oleoyl serinol (S18) to eliminate mouse and human Oct-4(+)/PAR-4(+) cells and to increase the proportion of nestin(+) neuroprogenitors in EBC-derived cell cultures and grafts. S18-treated EBCs persisted in the hippocampal area and showed neuronal lineage differentiation as indicated by the expression of β-tubulin III. However, untreated cells formed numerous teratomas that contained derivatives of endoderm, mesoderm, and ectoderm. Our results show for the first time that ceramide-induced apoptosis eliminates residual, pluripotent EBCs, prevents teratoma formation, and enriches the EBCs for cells that undergo neural differentiation after transplantation.

Development and characterization of a novel anti-ceramide antibody

Ceramide is emerging as a key sphingolipid that regulates a variety of cellular processes. To facilitate the study of ceramide localization and its interaction with cellular proteins, we have developed a novel antibody against ceramide. Our results indicate that the antibody (rabbit IgG) specifically recognizes ceramide in lipid overlay assays and detects ceramide species with different fatty acid chain lengths that include C2, C8, C16, C18, C20, and C24. The new antibody was compared with the commercially available anti-ceramide antibody (mouse IgM) in immunocytochemistry experiments to study the localization of ceramide. Although both antibodies stain the same regions on the cell membrane, the rabbit IgG reveals the distribution of ceramide in compartments that are not well identified with the commercially available antibody. In addition to staining of ceramide in protrusions of the plasma membrane, the rabbit IgG also detects ceramide in the Golgi apparatus. Pharmacological depletion or increase of ceramide levels results in a corresponding change in staining intensity, confirming the specificity of the antibody. These results indicate that the rabbit IgG is a suitable antibody to determine the localization of ceramide and its interaction with proteins by immunocytochemistry.

Lipids isolated from bone induce the migration of human breast cancer cells

Bone is the most common site to which breast cancer cells metastasize. We found that osteoblast-like MG63 cells and human bone tissue contain the bile acid salt sodium deoxycholate (DC). MG63 cells take up and accumulate DC from the medium, suggesting that the bone-derived DC originates from serum. DC released from MG63 cells or bone tissue promotes cell survival and induces the migration of metastatic human breast cancer MDA-MB-231 cells. The bile acid receptor farnesoid X receptor (FXR) antagonist Z-guggulsterone prevents the migration of these cells and induces apoptosis. DC increases the gene expression of FXR and induces its translocation to the nucleus of MDA-MB-231 cells. Nuclear translocation of FXR is concurrent with the increase of urokinase-type plasminogen activator (uPA) and the formation of F-actin, two factors critical for the migration of breast cancer cells. Our results suggest a novel mechanism by which DC-induced increase of uPA and binding to the uPA receptor of the same breast cancer cell self-propel its migration and metastasis to the bone.

Regulation of primary cilia formation by ceramide

The primary cilium is an important sensory organelle, the regulation of which is not fully understood. We found that in polarized Madin-Darby Canine Kidney cells, the sphingolipid ceramide is specifically distributed to a cis-Golgi compartment at the base of the primary cilium. This compartment immunostained for the centrosome marker &ggr;-tubulin, the Rho type GTPase cell division cycle 42 (Cdc42), and atypical protein kinase C&zgr;/&lgr; (aPKC), a kinase activated by ceramide and associated with a polarity protein complex consisting of partitioning defective (Par)6 and Cdc42. Inhibition of ceramide biosynthesis with Fumonisin B1 prevented codistribution of aPKC and Cdc42 in the centrosomal/pericentriolar compartment and severely impaired ciliogenesis. Cilium formation and codistribution of aPKC and Cdc42 were restored by incubation with N-acetyl or N-palmitoyl sphingosine (C2 or C16 ceramide), or the ceramide analog N-oleoyl serinol (S18). Cilium formation was also restored by the glycogen synthase kinase-3&bgr; (GSK-3&bgr;) inhibitor indirubin-3-monoxime, suggesting that regulation of ciliogenesis depends on the inhibition of GSK-3&bgr; by ceramide-activated aPKC. Consistently, inhibition of aPKC with a pseudosubstrate inhibitor prevented restoration of ciliogenesis by C2 ceramide or S18. Our data show for the first time that ceramide is required for primary cilium formation.—Wang, G., K. Krishnamurthy, and E. Bieberich. Regulation of primary cilia formation by ceramide.

Ceramide Regulates Atypical PKCζ/λ-mediated Cell Polarity in Primitive Ectoderm Cells A NOVEL FUNCTION OF SPHINGOLIPIDS IN MORPHOGENESIS

In mammals, the primitive ectoderm is an epithelium of polarized cells that differentiates into all embryonic tissues. Our study shows that in primitive ectoderm cells, the sphingolipid ceramide was elevated and co-distributed with the small GTPase Cdc42 and cortical F-actin at the apicolateral cell membrane. Pharmacological or RNA interference-mediated inhibition of ceramide biosynthesis enhanced apoptosis and impaired primitive ectoderm formation in embryoid bodies differentiated from mouse embryonic stem cells. Primitive ectoderm formation was restored by incubation with ceramide or a ceramide analog. Ceramide depletion prevented plasma membrane translocation of PKCζ/λ, its interaction with Cdc42, and phosphorylation of GSK-3β, a substrate of PKCζ/λ. Recombinant PKCζ formed a complex with the polarity protein Par6 and Cdc42 when bound to ceramide containing lipid vesicles. Our data suggest a novel mechanism by which a ceramide-induced, apicolateral polarity complex with PKCζ/λ regulates primitive ectoderm cell polarity and morphogenesis.

The Carboxyl-terminal Domain of Atypical Protein Kinase Cζ Binds to Ceramide and Regulates Junction Formation in Epithelial Cells

Atypical protein kinase Cs (PKCs) (aPKCζ and λ/ι) have emerged as important binding partners for ceramide, a membrane-resident cell signaling lipid that is involved in the regulation of apoptosis as well as cell polarity. Using ceramide overlay assays with proteolytic fragments of PKCζ and vesicle binding assays with ectopically expressed protein, we show that a protein fragment comprising the carboxyl-terminal 20-kDa sequence of PKCζ (C20ζ, amino acids 405–592) bound to C16:0 ceramide. This sequence is not identical to the C1 domain (amino acids 131–180), which has been suggested to serve as a potential ceramide binding domain. Using immunocytochemistry, we found that a C20ζ protein fragment ectopically expressed in two epithelial cell types (neural progenitors and Madin-Darby canine kidney cells) co-distributed with ceramide. Stable expression of C20ζ-EGFP in Madin-Darby canine kidney cells disrupted the formation of adherens and tight junctions and impaired the epithelium integrity by reducing transepithelial electrical resistance. Disruption of cell adhesion and loss of transepithelial electrical resistance was prevented by incubation with C16:0 ceramide. Our results show, for the first time, that there is a novel ceramide binding domain (C20ζ) in the carboxyl terminus of aPKC. Our results also show that the interaction of ceramide with this binding domain is essential for cell-to-cell contacts in epithelia. Therefore, ceramide interaction with the C20ζ binding domain is a potential mechanism by which ceramide and aPKC regulate the formation of junctional complexes in epithelial cells.

Deoxycholate promotes survival of breast cancer cells by reducing the level of pro-apoptotic ceramide

IntroductionAt physiologic concentration in serum, the bile acid sodium deoxycholate (DC) induces survival and migration of breast cancer cells. Here we provide evidence of a novel mechanism by which DC reduces apoptosis that is induced by the sphingolipid ceramide in breast cancer cells.MethodsMurine mammacarcinoma 4T1 cells were used in vitro to determine apoptosis and alteration of sphingolipid metabolism by DC, and in vivo to quantify the effect of DC on metastasis.ResultsWe found that DC increased the number of intestinal metastases generated from 4T1 cell tumors grafted into the fat pad. The metastatic nodes contained slowly dividing cancer cells in immediate vicinity of newly formed blood vessels. These cells were positive for CD44, a marker that has been suggested to be expressed on breast cancer stem cells. In culture, a subpopulation (3 ± 1%) of slowly dividing, CD44+ cells gave rise to rapidly dividing, CD44- cells. DC promoted survival of CD44+ cells, which was concurrent with reduced levels of activated caspase 3 and ceramide, a sphingolipid inducing apoptosis in 4T1 cells. Z-guggulsterone, an antagonist of the farnesoid-X-receptor, obliterated this anti-apoptotic effect, indicating that DC increased cell survival via farnesoid-X-receptor. DC also increased the gene expression of the vascular endothelial growth factor receptor 2 (Flk-1), suggesting that DC enhanced the initial growth of secondary tumors adjacent to blood vessels. The Flk-1 antagonist SU5416 obliterated the reduction of ceramide and apoptosis by DC, indicating that enhanced cell survival is due to Flk-1-induced reduction in ceramide.ConclusionsOur findings show, for the first time, that DC is a natural tumor promoter by elevating Flk-1 and decreasing ceramide-mediated apoptosis of breast cancer progenitor cells. Reducing the level or effect of serum DC and elevating ceramide in breast cancer progenitor cells by treatment with Z-guggulsterone and/or vascular endothelial growth factor receptor 2/Flk-1 antagonists may thus be a promising strategy to reduce breast cancer metastasis.

Regulation of neural progenitor cell motility by ceramide and potential implications for mouse brain development.

We provide evidence that the sphingolipid ceramide, in addition to its pro‐apoptotic function, regulates neural progenitor (NP) motility in vitro and brain development in vivo. Ceramide (N‐palmitoyl d‐erythro sphingosine and N‐oleoyl d‐erythro sphingosine) and the ceramide analog N‐oleoyl serinol (S18) stimulate migration of NPs in scratch (wounding) migration assays. Sphingolipid depletion by inhibition of de novo ceramide biosynthesis, or ceramide inactivation using an anti‐ceramide antibody, obliterates NP motility, which is restored by ceramide or S18. These results suggest that ceramide is crucial for NP motility. Wounding of the NP monolayer activates neutral sphingomyelinase indicating that ceramide is generated from sphingomyelin. In membrane processes, ceramide is co‐distributed with its binding partner atypical protein kinase C ζ/λ (aPKC), and Cdc42, α/β‐tubulin, and β‐catenin, three proteins involved in aPKC‐dependent regulation of cell polarity and motility. Sphingolipid depletion by myriocin prevents membrane translocation of aPKC and Cdc42, which is restored by ceramide or S18. These results suggest that ceramide‐mediated membrane association of aPKC/Cdc42 is important for NP motility. In vivo, sphingolipid depletion leads to ectopic localization of mitotic or post‐mitotic neural cells in the embryonic brain, while S18 restores the normal brain organization. In summary, our study provides novel evidence that ceramide is critical for NP motility and polarity in vitro and in vivo.

Tumor necrosis factor‐α up‐regulates glucuronosyltransferase gene expression in human brain endothelial cells and promotes T‐cell adhesion

Stimulation of human brain microvascular endothelial cells (SV‐HCECs) with tumor necrosis factor‐α (TNF‐α) up‐regulates sulfoglucuronosyl paragloboside (SGPG) synthesis in a dose‐ and time‐dependent manner. After TNF‐α exposure at a concentration of 50 ng/ml for 24 hr, we observed a seven‐ to tenfold elevation of SGPG concentration. Interleukin‐1β (IL‐1β) at a concentration of 10 ng/ml and the combined doses of TNF‐α and IL‐1β were less effective than TNF‐α alone. TNF‐α also stimulated T‐cell (Jurkat) adhesion with SV‐HCECs via SGPG‐L‐selectin recognition: this was determined by double‐label immunofluorescent staining with SGPG and L‐selectin antibodies. The number of T cells bound to SV‐HCECs after different cytokine stimulations was proportional to the SGPG concentration, and the cell attachment was inhibited by anti‐SGPG and anti‐L‐selectin antibodies, respectively. Our data unequivocally establish that inflammatory cytokines, particularly TNF‐α, stimulate the glucuronosyltransferse, GlcAT‐P, and GlcAT‐S, gene expression in brain endothelial cells and promote T‐cell adhesion via SGPG‐L‐selectin recognition, a preliminary step for onset of neuroinflammation.