Involvement of cortactin and phosphotyrosine proteins in cell–cell contact formation in cultured bovine corneal endothelial cells

Phosphotyrosine proteins involvement, particularly cortactin, was studied in cell–cell contacts of cultured bovine corneal endothelial (BCE) cells. These proteins, including α-catenin, vinculin and cortactin, are localized at cell–cell contacts separate from the cortical actin ring. Approximately 50% of cortactin isoforms p80 and p85 were associated with the Triton-insoluble fraction while phosphotyrosine proteins were in the soluble fraction. Disruption of cell–cell contacts by EDTA treatment was associated with a decrease in cortactin isoforms p80 (26%) and p85 (57%). Cortactin isoform p85 was phosphorylated at Y⁴⁶⁶, expressed in reattaching cells and associated with the Triton-soluble fraction, whereas cortactin isoform p80 was phosphorylated at Y⁴²¹ and associated with the Triton-insoluble fraction. In sub-confluent cultures, pY⁴²¹-cortactin was localized at the leading edge and pY⁴⁶⁶-cortactin at a perinuclear area. In confluent cultures both pY⁴⁶⁶- and pY⁴²¹-cortactin isoforms were localized at the cell–cell contacts. In conclusion, in BCE cells, the most prominent appearance of cortactin was at the cell–cell contacts separate from the cortical actin ring. Isoform p80 was phosphorylated at Y⁴²¹ and associated with the Triton-insoluble fraction and isoform p85 was phosphorylated at Y⁴⁶⁶ and associated with the Triton-insoluble fraction.     

Distinct effect of forskolin and interferon-γ on cell proliferation and regulation of histocompatibility antigen expression in hematopoietic cells

The adenylate cyclase activator, forskolin, was found to induce expression of class I and class II major histocompatibility complex antigens in a B precursor cell line, Reh, as well as in a B lymphoid cell line, Raji. No such effect was, however, observed when the promyelocytic cells line HL-60 was treated with either forskolin or the cAMP analogue 8-bromoadenosine cyclic monophosphate. As expected, all three cell lines showed reduced proliferation upon forskolin treatment. Forskolin induced expression of class I and class II major histocompatibility complex antigens in cell lines not affected by interferon-γ and vice versa, indicating that cAMP is not involved in the regulation of histocompatibility antigens by interferon-γ. We also compared the effect of interferon-γ and 12-O-tetradecanoylphorbol 13-acetate on major histocompatibility complex class I and class II expression, and despite differences in the response on the tested cell lines, we can not at this point exclude the possibility that protein kinase C is involved in the action of interferon-γ.     

The Schaechter-Bentzon-Maaløe experiment and the analysis of cell cycle events in eukaryotic cells

The Schaechter-Bentzon-Maal?e (SBM) experiment, performed more than 40 years ago, provides an important lesson for the analysis of the eukaryotic cell cycle. Before this experiment, temperature shifts had been used to synchronize bacteria and determine the pattern of DNA synthesis during the bacterial division cycle. These experiments indicated that DNA replication occurred during a fraction of the division cycle with gaps before and after DNA synthesis, a pattern similar to the eukaryotic division cycle. The SBM experiment studied DNA replication during the division cycle by labeling an unperturbed culture with a short pulse of tritiated thymidine. All cells were found to be labeled, indicating that unperturbed cells synthesize DNA throughout the division cycle. Thus, the SBM experiment was a control experiment demonstrating that artifacts can be introduced by synchronization methods. The idea of an control experiment under unperturbed conditions is proposed for the analysis of data on cell-cycle-specific gene expression in yeast and mammalian cells.     

Enhanced expression of VEGF-A in β cells increases endothelial cell number but impairs islet morphogenesis and β cell proliferation

There is a reciprocal interaction between pancreatic islet cells and vascular endothelial cells (EC) in which EC-derived signals promote islet cell differentiation and islet development while islet cell-derived angiogenic factors promote EC recruitment and extensive islet vascularization. To examine the role of angiogenic factors in the coordinated development of islets and their associated vessels, we used a "tet-on" inducible system (mice expressing rat insulin promoter-reverse tetracycline activator transgene and a tet-operon-angiogenic factor transgene) to increase the β cell production of vascular endothelial growth factor-A (VEGF-A), angiopoietin-1 (Ang1), or angiopoietin-2 (Ang2) during islet cell differentiation and islet development. In VEGF-A overexpressing embryos, ECs began to accumulate around epithelial tubes residing in the central region of the developing pancreas (associated with endocrine cells) as early as embryonic day 12.5 (E12.5) and increased dramatically by E16.5. While α and β cells formed islet cell clusters in control embryos at E16.5, the increased EC population perturbed endocrine cell differentiation and islet cell clustering in VEGF-A overexpressing embryos. With continued overexpression of VEGF-A, α and β cells became scattered, remained adjacent to ductal structures, and never coalesced into islets, resulting in a reduction in β cell proliferation and β cell mass at postnatal day 1. A similar impact on islet morphology was observed when VEGF-A was overexpressed in β cells during the postnatal period. In contrast, increased expression of Ang1 or Ang2 in β cells in developing or adult islets did not alter islet differentiation, development, or morphology, but altered islet EC ultrastructure. These data indicate that (1) increased EC number does not promote, but actually impairs β cell proliferation and islet formation; (2) the level of VEGF-A production by islet endocrine cells is critical for islet vascularization during development and postnatally; (3) angiopoietin-Tie2 signaling in endothelial cells does not have a crucial role in the development or maintenance of islet vascularization.     

Effects of curvature and cell–cell interaction on cell adhesion in microvessels

It has been found that both circulating blood cells and tumor cells are more easily adherent to curved microvessels than straight ones. This motivated us to investigate numerically the effect of the curvature of the curved vessel on cell adhesion. In this study, the fluid dynamics was carried out by the lattice Boltzmann method (LBM), and the cell dynamics was governed by the Newton’s law of translation and rotation. The adhesive dynamics model involved the effect of receptor-ligand bonds between circulating cells and endothelial cells (ECs). It is found that the curved vessel would increase the simultaneous bond number, and the probability of cell adhesion is increased consequently. The interaction between traveling cells would also affect the cell adhesion significantly. For two-cell case, the simultaneous bond number of the rear cell is increased significantly, and the curvature of microvessel further enhances the probability of cell adhesion.     

Involvements of the ABC protein ABCF2 and α-actinin-4 in regulation of cell volume and anion channels in human epithelial cells

After osmotic swelling, cell volume is regulated by a process called regulatory volume decrease (RVD). Although actin cytoskeletons are known to play a regulatory role in RVD, it is not clear how actin‐binding proteins are involved in the RVD process. In the present study, an involvement of an actin‐binding protein, α‐actinin‐4 (ACTN4), in RVD was examined in human epithelial HEK293T cells. Overexpression of ACTN4 significantly facilitated RVD, whereas siRNA‐mediated downregulation of endogenous ACTN4 suppressed RVD. When the cells were subjected to hypotonic stress, the content of ACTN4 increased in a 100,000 × g pellet, which was sensitive to cytochalasin D pretreatment. Protein overlay assays revealed that ABCF2, a cytosolic member of the ABC transporter superfamily, is a binding partner of ACTN4. The ACTN4‐ABCF2 interaction was markedly enhanced by hypotonic stimulation and required the NH₂‐terminal region of ABCF2. Overexpression of ABCF2 suppressed RVD, whereas downregulation of ABCF2 facilitated RVD. We then tested whether ABCF2 has a suppressive effect on the activity of volume‐sensitive outwardly rectifying anion channel (VSOR), which is known to mediate Cl^? efflux involved in RVD, because another ABC transporter member, CFTR, was shown to suppress VSOR activity. Whole‐cell VSOR currents were largely reduced by overexpression of ABCF2 and markedly enhanced by siRNA‐mediated depletion of ABCF2. Thus, the present study indicates that ACTN4 acts as an enhancer of RVD, whereas ABCF2 acts as a suppressor of VSOR and RVD, and suggests that a swelling‐induced interaction between ACTN4 and ABCF2 prevents ABCF2 from suppressing VSOR activity in the human epithelial cells. J. Cell. Physiol. 227: 3498–3510, 2012. © 2012 Wiley Periodicals, Inc.     

Regional-specific alterations in cell–cell junctions,cytoskeletal networks and myosin-mediated mechanical cues coordinate collectivity of movement of epithelial cells in response to injury

This study investigates how epithelial cells moving together function to coordinate their collective movement to repair a wound. Using a lens ex vivo mock cataract surgery model we show that region-specific reorganization of cell–cell junctions, cytoskeletal networks and myosin function along apical and basal domains of an epithelium mediates the process of collective migration. An apical junctional complex composed of N-cadherin/ZO-1/myosin II linked to a cortical actin cytoskeleton network maintains integrity of the tissue during the healing process. These cells’ basal domains often preceded their apical domains in the direction of movement, where an atypical N-cadherin/ZO-1 junction, linked to an actin stress fiber network rich in phosphomyosin, was prominent in cryptic lamellipodia. These junctions joined the protruding forward-moving lamellipodia to the back end of the cell moving directly in front of it. These were the only junctions detected in cryptic lamellipodia of lens epithelia migrating in response to wounding that could transmit the protrusive forces that drive collective movement. Both integrity of the epithelium and ability to effectively heal the wound was found to depend on myosin mechanical cues.     

Use of cell cycle analysis to characterise growth and interferon-γ production in perfusion culture of CHO cells

The importance of cell cycle analysis in cell culture development has been widely recognised. Whether such analysis is useful in indicating future performance of high cell density culture is uncertain. Using flow cytometric approach to address this question, we utilised the fraction of cells in the S phase to control specific growth rate and productivity in spin filter perfusion cultures and found a significant increase in the accumulated interferon-γ over that obtained from the nutrient-based controlled fed culture. While a general decrease with time exists in both percentage of S phase cells and specific growth rate, a clear oscillatory behaviour of both parameters is found in perfusion cultures. This revised version was published online in July 2006 with corrections to the Cover Date.     

The distribution of calmodulin and Ca^2＋—activated calmodulin in cell cycle of mouse erythroleukemia cells

Cell proliferation is accompanied with changing levels of intracellular calmodulin (CaM) and its activation.Prior data from synchronized cell population could not actually stand for various CaM levels in different phases of cell cycle.Here,based upon quantitative measurement of fluorescence in individual cells,a method was developed to investigate intracellular total CaM and Ca^2 -activated CaM contents. Intensity of CaM immunoflurescence gave total CaM level,and Ca^2 -activated CaM was measured by fluorescence intensity of CaM antagonist trifluoperazine (TFP).In mouse erythroleukemia (MEL) cells,total CaM level increased from G1 through S to G2M,reaching a maximum of 2-fold increase,then reduced to half amount after cell division.Meanwhile,Ca^2 -activated CaM also in creased through the cell cycle(G1,S,G2M).Increasing observed in G1 meant that the entry of cells from G1 into S phase may require CaM accumulation,and,equally or even more important,Ca^2 -dependent activation of CaM.Ca^2 -activated CaM decreased after cell division.The results suggested that CaM gene expression and C^2 -modulated CaM activation act synergistically to accomplish the cell cycle progression.     

Rate of activation and deactivation of K∶Cl cotransport by changes in cell volume in hemoglobin SS,CC and AA red cells

Red blood cells (RBC) of subjects homozygous for hemoglobin A (AA), C (CC) and S (SS) exhibit different cell volumes which might be related to differences in cell volume regulation. We have investigated how rapidly K:Cl cotransport is activated and deactivated to regulate the cell volume in these cells. We measured the time course of net K⁺ efflux after step changes in cell volume and determined two delay times: one for activation by cell swelling and a second for deactivation by cell shrinkage. Cell swelling induced by 220 mOsm media activated K⁺ efflux to high values (10–20 mmol/ liter cell x hr) in CC and SS; normal AA had a threefold lower activity. The delay time for activation was very short in blood with a high percentage of reticulocytes (retics): (SS, 10% retics, 1.7±0.3 min delay, n=8; AA, 10% retics, 4±1.5 min, n=3; CC, 11.6% retics, 4±0.3, n=3) and long in cells with a smaller percentage of reticulocytes: (AA, 1.5% retics, 10±1.4 min, n=8; CC whole blood 6% retics, 10±2.0 min, n=10, P<0.02 vs. SS). The delay times for deactivation by cell shrinking were very short in SS (3.6±0.4 min, n=8, P<0.02) and AA cells with high retics (2.7±1 min, n=3) and normal retics (2.8±1 min, n=3), but 8–15-fold longer in CC cells (29±2.8 min, n=9).Density fractionation of CC cells (n=3) resulted in coenrichment of the top fraction in reticulocytes and in swelling-activated cotransport (fourfold) with short delay time for activation (4±0.3 min) and long delay for deactivation (14±4 min). The delay time for activation, but not for deactivation, increased markedly with increasing cell density. These findings indicate that all CC cells do not promptly shut off cotransport with cell shrinkage and high rates of cellular K⁺ loss persist after return to isotonic conditions.In summary, (i) K:Cl cotransport is not only very active in young cells but it is also very rapidly activated and deactivated in young AA and SS cells by changes in cell volume. (ii) Delay times for cotransport activation markedly increased with RBC age and in mature cells with low cotransport rates, long delay times for activation were observed. (iii) The long delay time for deactivation exhibited even by young CC cells induces a persistent loss of K⁺ after cell shrinkage which may contribute in vivo to the uniformly low cell volume, low K⁺ and water content of CC cells.This research was supported by National Institutes of Health grants Shannon Award HL-35664, HL-42120, Sickle Cell Center grant HL-38655, and a Grant-in-Aid of the New York Branch of the American Heart Association. The technical help of Sandra M. Suzuka, M.S. is gratefully acknowledged.     

Development of Ca²(+) signaling mechanisms and cell motility in presumptive ectodermal cells during amphibian gastrulation

This study investigated the development of Ca2(+) signaling mechanisms and their role in initiating morphogenetic cell movement in the presumptive ectoderm of Japanese newt (Cynops pyrrhogaster) during gastrulation. Histochemical staining using fluorescently labeled ryanodine and dihydropyridine probes revealed that dihydropyridine receptor (L-type Ca2(+) channels) appeared in stage 12b embryos, while ryanodine receptors were expressed in both stage 11 and 12b embryos. Transmission electron microscopy of stage 12b embryos showed abundant peripheral couplings, which are couplings of the endoplasmic reticulum and cell membrane with an approximate 12 nm gap. Caffeine increased the intracellular free Ca2(+) concentration ([Ca2(+)](i)) in presumptive ectodermal cells isolated from both stage 11 and 12b embryos, while (±)-Bay K 8644 ((±)-BayK) increased [Ca2(+)](i) in cells isolated from stage 12b embryos, but not in cells isolated from stage 11 embryos. Dantrolene and nifedipine completely inhibited increases in [Ca2(+)](i) after treatment with caffeine and (±)-BayK, respectively. Caffeine activated the motility of cells isolated from both stage 11 and 12b embryos, but (±)-BayK only activated the motility of cells isolated from stage 12b embryos. These findings suggested that formation of the Ca2(+) -induced Ca2(+) release system in presumptive ectodermal cells during gastrulation plays an important role in the initiation and execution of epibolic extension.     

On the mechanism of UV and γ-ray-induced intrachromosomal recombination in yeast cells synchronized in different stages of the cell cycle

A genetic system selecting for deletion events (DEL recombination) due to intrachromosomal recombination has previously been constructed in the yeastSaccharomyces cerevisiae. Intrachromosomal recombination is inducible by chemical and physical carcinogens. We wanted to understand better the mechanism of induced DEL recombination and to attempt to determine in which phase of the cell cycle DEL recombination is inducible. Yeast cells were arrested at specific phases of the cell cycle, irradiated with UV or γ-rays, and assayed for DEL recombination and interchromosomal recombination. In addition, the contribution of intrachromatid crossing-over to the number of radiation induced DEL recombination events was directly investigated at different phases of the cell cycle. UV irradiation induced DEL recombination preferentially in S phase, while γ-rays induced DEL recombination in every phase of the cell cycle including G1. UV and γ-radiation induced intrachromatid crossing over preferentially in G1, but it accounted at the most for only 14% of the induced DEL recombination events. The possibility is discussed that single-strand annealing or one-sided invasion events, which can occur in G1 and may be induced by a double-strand break intermediate, may be responsible for a large proportion of the induced DEL recombination events.     

Influence of homologous recombinational repair on cell survival and chromosomal aberration induction during the cell cycle in γ-irradiated CHO cells

The repair of DNA double-strand breaks (DSBs) by homologous recombinational repair (HRR) underlies the high radioresistance and low mutability observed in S-phase mammalian cells. To evaluate the contributions of HRR and non-homologous end-joining (NHEJ) to overall DSB repair capacity throughout the cell cycle after γ-irradiation, we compared HRR-deficient RAD51D-knockout 51D1 to CgRAD51D-complemented 51D1 (51D1.3) CHO cells for survival and chromosomal aberrations (CAs). Asynchronous cultures were irradiated with 150 or 300 cGy and separated by cell size using centrifugal elutriation. Cell survival of each synchronous fraction (～20 fractions total from early G1 to late G2/M) was measured by colony formation. 51D1.3 cells were most resistant in S, while 51D1 cells were most resistant in early G1 (with survival and chromosome-type CA levels similar to 51D1.3) and became progressively more sensitive throughout S and G2. Both cell lines experienced significantly reduced survival from late S into G2. Metaphases were collected from every third elutriation fraction at the first post-irradiation mitosis and scored for CAs. 51D1 cells irradiated in S and G2 had ～2-fold higher chromatid-type CAs and a remarkable ～25-fold higher level of complex chromatid-type exchanges compared to 51D1.3 cells. Complex exchanges in 51D1.3 cells were only observed in G2. These results show an essential role for HRR in preventing gross chromosomal rearrangements in proliferating cells and, with our previous report of reduced survival of G2-phase NHEJ-deficient prkdc CHO cells [Hinz et al., DNA Repair 4, 782–792, 2005], imply reduced activity/efficiency of both HRR and NHEJ as cells transition from S to G2.     

CXCR7 mediated Giα independent activation of ERK and Akt promotes cell survival and chemotaxis in T cells

Chemokine receptors CXCR7 and CXCR4 bind to the same ligand stromal cell derived factor-1alpha (SDF-1α/CXCL12). We assessed the downstream signaling pathways mediated by CXCL12-CXCR7 interaction in Jurkat T cells. All experiments were carried out after functionally blocking the CXCR4 receptor. CXCL12, on binding CXCR7, induced phosphorylation of extra cellular regulated protein kinases (ERK 1/2) and Akt. Selective inhibition of each signal demonstrated that phosphorylated ERK 1/2 is essential for chemotaxis and survival of T cells whereas activation of Akt promotes only cell survival. Another interesting finding of this study is that CXCL12-CXCR7 interaction under normal physiological conditions does not activate the p38 pathway. Furthermore, we observed that the CXCL12 signaling via CXCR7 is Giα independent. Our findings suggest that CXCR7 promotes cell survival and does not induce cell death in T cells. The CXCL12 signaling via CXCR7 may be crucial in determining the fate of the activated T cells.     

Distribution of E-cadherin and β-catenin in relation to cell maturation and cell extrusion in rat and mouse small intestines

In the small intestines, cell renewal from stem cells present in the crypts is balanced by cell extrusion from the tips of the villi. The mechanism by which extrusion occurs is unknown. Recent in vitro data suggested that loss of E-cadherin could contribute to cell extrusion and induction of programmed cell death (PCD) in mouse small intestinal epithelium. We have studied if this also occurs in the intact rodent small intestine. Our results confirm that extruded cells are negative for E-cadherin. However, loss of the E-cadherin-interacting protein β-catenin preceded both extrusion and loss of E-cadherin. Thus, all extruded cells as well as all cells in the process of extrusion lacked staining for β-catenin. Moreover, almost 80% of all cells undergoing programmed cell death, as detected by the TUNEL reaction, lacked β-catenin whereas over 70% of such cells were positive for E-cadherin. However, most cells lacking β-catenin did not display signs of PCD as detected by the TUNEL method or by staining for active caspase-3. Therefore, these results suggest that loss of β-catenin precedes the onset of programmed cell death, loss of E-cadherin and extrusion from the villi.     

Down-regulation of Pkd2 by siRNAs suppresses cell–cell adhesion in the mouse melanoma cells

The Pkd2 gene encodes an integral protein (~130 kDa), named polycystin-2 (PC-2). PC-2 is mainly involved in autosomal dominant polycystic kidney disease. Recently, polycystin-1/polycystin-2 complex has been shown to act as an adhesion complex mediating or regulating cell–cell or cell–matrix adhesion, suggesting that PC-2 may play a role in cell–cell/cell–matrix interactions. Here, we knocked down the expression of Pkd2 gene with small interfering RNAs (siRNAs) in the mouse melanoma cells (B16 cells), indicating that the cells transfected with the targeted siRNAs significantly suppressed cell–cell adhesion, but not cell–matrix adhesion, compared to the cells transfected with non-targeted control (NC) siRNA. This study provides the first directly functional evidence that PC-2 mediates cell–cell adhesion. Furthermore, we demonstrated that PC-2 modulated cell–cell adhesion may be, at least partially, associated with E-cadherin. Collectively, these findings for the first time showed that PC-2 may mediate cell–cell adhesion, at least partially, through E-cadherin.     

Different effects on cell proliferation and migration abilities of endothelial cells by LPA₁ and LPA₃ in mammary tumor FM3A cells

Lysophosphatidic acid (LPA) receptors belong to G protein-coupled transmembrane receptors and mediate a variety of cellular responses through the binding of LPA. So far, six types of LPA receptors (LPA receptor-1 (LPA?) to LPA?) have been identified. Recently, it has been demonstrated that each LPA receptor has opposite effects on malignant property of cancer cells. In this study, to evaluate an involvement of LPA receptors on angiogenic process in mammary tumor cells, we generated Lpar1- and Lpar3-expressing (FM3A-a1 and FM3A-a3A9, respectively) cells from FM3A cells, and investigated the effects on cell proliferation and migration abilities of endothelial F-2 cells by those cells. In Vegf-A and Vegf-C genes, FM3A-a1 cells indicated high expression and FM3A-a3A9 cells showed low expression, compared with control cells. When F-2 cells were cultured with a supernatant from FM3A-a1 cells, the cell growth rate and migration ability of F-2 cells was significantly higher than control cells. By contrast, a supernatant from FM3A-a3A9 cells significantly inhibited those abilities of F-2 cells. These results suggest that LPA? and LPA? may play opposite roles on the regulation of endothelial cells in mouse mammary tumor FM3A cells.     

C-terminal region of GADD34 regulates eIF2α dephosphorylation and cell proliferation in CHO-K1 cells

GADD34 is a member of a growth arrest and DNA damage (GADD)-inducible gene family. Here, we established a novel Chinese hamster ovary (CHO)-K1-derived cell line, CHO-K1-G34M, which carries a nonsense mutation (termed the Q525X mutation) in the GADD34 gene. The Q525X mutant protein lacks the C-terminal 66 amino acids required for GADD34 to bind to and activate protein phosphatase 1 (PP1). We investigated the effects of GADD34 with or without the Q525X mutation on the phosphorylation status of PP1 target proteins, including the α subunit of eukaryotic initiation factor 2 (eIF2α) and glycogen synthase kinase 3β (GSK3β). CHO-K1-G34M cells had higher levels of eIF2α phosphorylation compared to the control CHO-K1-normal cells both in the presence and absence of endoplasmic reticulum stress. Overexpression of the wild-type GADD34 protein in CHO-K1-normal cells largely reduced eIF2α phosphorylation, while overexpression of the Q525X mutant did not produce similar reductions. Meanwhile, neither wild type nor Q525X mutation of GADD34 affected the GSK3β phosphorylation status. GADD34 also did not affect the canonical Wnt signaling pathway downstream of GSK3β. Cell proliferation rates were higher, while expression levels of the cyclin-dependent kinase inhibitor p21 were lower in CHO-K1-G34M cells compared to the CHO-K1-normal cells. The GADD34 Q525X mutant had a reduced ability to inhibit cell proliferation and enhance p21 expression of the CHO-K1-normal cells compared to the wild-type GADD34 protein. These results suggest that the GADD34 protein C-terminal plays important roles in regulating not only eIF2α dephosphorylation but also cell proliferation in CHO-K1 cells.     

Synthesis and antitumor activity of (−)-bassianolide in MDA-MB 231 breast cancer cells through cell cycle arrest

The high level of interest in the cyclodepsipeptides family in the natural products stems from their diverse range of biological activities. One of the cyclodepsipeptides, (−)-bassianolide, represents rich pharmacophores with diverse biological activities including potential cytotoxicity to various cancer cells. Efficient total synthesis of (−)-bassianolide was designed and achieved in nine steps, with significant improvements in the overall yield of 46.8% (vs. 7.2% yield in previous synthesis) using Ghosez’s chloroenamine reagent under mild conditions. The cytotoxicity of the (−)-bassianolide was evaluated against five human tumor cells, and the results showed that the (−)-bassianolide displayed significant cytotoxicity against A549, SK-OV-3, HepG2, HCT-15, MCF-7 and MDA-MB 231 cell lines with IC₅₀ values of 7.24, 8.44, 15.39, 6.40, 11.42 and 3.98 μg/mL respectively. Specifically, (−)-bassianolide induced G0/G1 arrest associated with a decrease of cyclin A, D1 and an increase of p53, MDM2, and p21 expression in MDA-MB 231 cells. These results demonstrate that (−)-bassianolide possesses antitumor activities via arresting of the cell cycle and the synthetic approach features an efficient and mild method for the formation of amide bonds through three inter- and intramolecular coupling reactions.