Anoikis evasion in inflammatory breast cancer cells is mediated by Bim-EL sequestration

Inflammatory breast cancer (IBC) is a rare and highly invasive type of breast cancer, and patients diagnosed with IBC often face a very poor prognosis. IBC is characterized by the lack of primary tumor formation and the rapid accumulation of cancerous epithelial cells in the dermal lymphatic vessels. Given that normal epithelial cells require attachment to the extracellular matrix (ECM) for survival, a comprehensive examination of the molecular mechanisms underlying IBC cell survival in the lymphatic vessels is of paramount importance to our understanding of IBC pathogenesis. Here we demonstrate that, in contrast to normal mammary epithelial cells, IBC cells evade ECM-detachment-induced apoptosis (anoikis). ErbB2 and EGFR knockdown in KPL-4 and SUM149 cells, respectively, causes decreased colony growth in soft agar and increased caspase activation following ECM detachment. ERK/MAPK signaling was found to operate downstream of ErbB2 and EGFR to protect cells from anoikis by facilitating the formation of a protein complex containing Bim-EL, LC8, and Beclin-1. This complex forms as a result of Bim-EL phosphorylation on serine 59, and thus Bim-EL cannot localize to the mitochondria and cause anoikis. These results reveal a novel mechanism that could be targeted with innovative therapeutics to induce anoikis in IBC cells.Inflammatory breast cancer (IBC) is a rare and highly invasive type of breast cancer, and patients diagnosed with IBC often face a very poor prognosis. The 5-year survival rate for patients with IBC is <40%, while the 5-year survival rate of all other breast cancers combined is approximately 90%.^{1, 2, 3, 4} This poor prognosis can be attributed to a number of factors, including the propensity for misdiagnosis of the disease due to its unique clinical presentation.^{5, 6, 7} In contrast to most breast cancers, IBC is characterized by the lack of discernible primary tumor formation and the accumulation of cancerous epithelial cells in the dermal lymphatic vessels.⁸ This lodging of IBC cells in the dermal lymphatics manifests as what appears to be inflammation, oftentimes causing clinicians to incorrectly diagnose the malady. Given that IBC cells are inherently aggressive, misdiagnosis is particularly problematic as a correct diagnosis or appropriate treatment is prolonged until more advanced disease is discovered. Thus it is imperative to gain a better understanding of the unique molecular mechanisms underlying IBC pathogenesis so that improved therapies can be designed to specifically eliminate IBC cells in a manner that improves patient outcome.Unfortunately, few treatment options exist that are specifically designed to combat IBC. A review of nearly 400 IBC patients treated at The University of Texas MD Anderson Cancer Center between 1974 and 2005 demonstrated that there has been no significant improvement in prognosis for patients with IBC over the past 30 years.¹ Many recent studies have focused on assessing the efficacy of chemotherapeutic regimens in IBC cells/patients where success had previously been observed only in the treatment of non-IBCs.^{9, 10} Some progress has been made in understanding the mechanisms underlying the invasive nature of IBC. For instance, Akt1 has been identified as a possible chemotherapeutic target that appears to be involved in the aggressive behavior of IBC cells.¹¹ Other studies have identified RhoC, which is overexpressed in 90% of IBC tissue samples, as a potent oncogene contributing to IBC pathogenesis.^{11, 12, 13, 14, 15} More recently, evidence implicating the membrane protein TIG1 and the receptor tyrosine kinase Axl in the oncogenic behavior of IBC cells has been uncovered.¹⁶ However, despite these advances, knowledge of the biological mechanisms underlying IBC pathogenesis remains fairly rudimentary, and additional research dedicated to understanding the unique molecular pathways involved in IBC progression remains essential.Given that IBC cells do not form a palpable primary tumor and instead flourish in suspension in the lymph of the dermal lymphatic vessels, we hypothesized that IBC cells must have an inherent ability to survive in the absence of attachment to the extracellular matrix (ECM). Normal mammary epithelial cells require attachment to the ECM to inhibit anoikis, which is defined as caspase-dependent cell death caused by ECM detachment.¹⁷ It has become clear that tumor progression and metastasis require cancer cells to inhibit anoikis, oftentimes through alterations in intracellular signaling pathways.^{18, 19, 20} Interestingly, previous studies have shown that ErbB2 and EGFR, which are hyperactivated in a substantial percentage of IBC patients,²¹ can effectively antagonize the anoikis program to facilitate anchorage-independent growth.^{22, 23, 24, 25, 26, 27, 28} However, a detailed examination of the molecular mechanisms underlying anoikis inhibition in IBC cells has yet to be completed. In this study, we demonstrate that signaling from EGFR and ErbB2 through ERK/MAPK has a major role in the ability of IBC cells to survive in the absence of ECM attachment. Surprisingly, we have discovered that ERK-mediated anoikis suppression in IBC cells is not due to targeting of the pro-apoptotic protein Bim-EL for degradation that has previously been observed in mammary epithelial cells.^{23, 27} Rather, ERK activation in IBC cells promotes the formation of a protein complex containing Bim-EL, Beclin-1, and LC8, which functions to sequester Bim-EL from the mitochondria and thereby block anoikis. In support of the importance of this signaling pathway in IBC patients, five of the seven IBC patient samples assayed showed discernible Bim-EL staining. Collectively, these data identify a novel mechanism utilized by IBC cells to survive during ECM detachment and reveal a potential target for the development of anoikis-inducing chemotherapeutics targeting IBC cells.     

Direct detection of calmodulin tuning by ryanodine receptor channel targets using a Ca2+-sensitive acrylodan-labeled calmodulin

Calmodulin (CaM) activates the skeletal muscle ryanodine receptor (RyR1) at nanomolar Ca(2+) concentrations but inhibits it at micromolar Ca(2+) concentrations, indicating that binding of Ca(2+) to CaM may provide a molecular switch for modulating RyR1 channel activity. To directly examine the Ca(2+) sensitivity of RyR1-complexed CaM, we used an environment-sensitive acrylodan adduct of CaM. The resulting (ACR)CaM probe displayed high-affinity binding to, and Ca(2+)-dependent regulation of, RyR1 similar to that of unlabeled wild-type (WT) CaM. Upon addition of Ca(2+), (ACR)CaM exhibited a substantial (>50%) decrease in fluorescence (K(Ca) = 2.7 +/- 0.8 microM). A peptide derived from the RyR1 CaM binding domain (RyR1(3614)(-)(43)) caused an even more pronounced Ca(2+)-dependent fluorescence decrease, and a >or=10-fold leftward shift in its K(Ca) (0.2 +/- 0.1 microM). In the presence of intact RyR1 channels in SR vesicles, (ACR)CaM fluorescence spectra were distinct from those in the presence of RyR1(3614)(-)(43), although a Ca(2+)-dependent decrease in fluorescence was still observed. The K(Ca) for (ACR)CaM fluorescence in the presence of SR (0.8 +/- 0.4 microM) was greater than in the presence of RyR1(3614)(-)(43) but was consistent with functional determinations showing the conversion of (ACR)CaM from channel activator (apoCaM) to inhibitor (Ca(2+)CaM) at Ca(2+) concentrations between 0.3 and 1 microM. These results indicate that binding to RyR1 targets evokes significant changes in the CaM structure and Ca(2+) sensitivity (i.e., CaM tuning). However, changes resulting from binding of CaM to the full-length, tetrameric channels are clearly distinct from changes caused by the RyR1-derived peptide. We suggest that the Ca(2+) sensitivity of CaM when in complex with full-length channels may be tuned to respond to physiologically relevant changes in Ca(2+).     

Interactions between human and carp (Cyprimus carpio) low density lipoproteins (LDL) and LDL receptors

1. We have compared the concentration and chemical composition of carp and human plasma lipoproteins and studied their interaction with human fibroblast LDL receptors. 2. The main lipoproteins in carp are of high density (HDL) in contrast to low density lipoproteins (LDL) in human. 3. Carp lipoproteins are devoid of apolipoprotein (apo) E, a major ligand for interaction with LDL receptors in mammals. 4. Carp very low density lipoproteins (VLDL) and LDL but not HDL nor apoA-I cross react with human LDL in their interaction with LDL receptors on human cultured fibroblasts. 5. Carp liver membranes possess high affinity receptors that are saturable and have calcium dependent ligand specificity (apoB and apoE) similar to human LDL receptor. Carp VLDL and LDL but not HDL nor its major apolipoprotein complexed to L-alpha-phosphatidylcholine dimyristoyl (apoA-I-DMPC) competed with the specific binding of human LDL to this receptor.     

SEPTAL PORES IN THE HETEROBASIDIOMYCETIDAE,PUCCINIA GRAMINIS AND P. RECONDITA

The septal pores in uredial mycelium of Puccinia graminis and P. recondita lack the septal swelling and septal pore cap (dolipore-parenthosome configuration) typically associated with the pores of previously investigated Homobasidiomycetidae and the Tremellales among the Heterobasidiomycetidae. The pores in young hyphae of these two species of Puccinia are characterized by the presence of a cytoplasmic matrix which apparently occludes the pore and acts as a plug, thus preventing the migration of organelles from cell to cell. Large vesicles are typically present at the periphery of the pore matrix and the matrix may be very incompletely bounded by a membrane. Nuclei and other cytoplasmic structures migrate from cell to cell through an opening in the septum lateral to the pore. The available evidence indicates that this peripheral gap in the septum results from a breakdown of a portion of an initially complete septum rather than from incomplete septum formation. In addition to the centripetally formed septa, the hyphae of P. graminis and P. recondita are further compartmentalized by shallow infoldings of the lateral wall and limited unilateral septum formation. There is apparent free passage of cellular material between adjacent compartments.     

Cholecystokinin and EGF activate a MAPK cascade by different mechanisms in rat pancreatic acinar cells

The effects of activating the G_qprotein-coupled cholecystokinin (CCK) receptor on differentproteins/signaling molecules in the mitogen-activated protein kinase(MAPK) cascade in pancreatic acinar cells were analyzed and comparedwith the effects of activating the tyrosine kinase-coupled epidermalgrowth factor (EGF) receptor. Both EGF and CCK octapeptide rapidlyincreased the activity of the MAPKs [extracellular signal-regulatedkinase (ERK) 1 and ERK2], reaching a maximum within 2.5 min when 3.9- and 8.5-fold increases, respectively, were observed. The EGF-inducedincrease of MAPK activity was transient, with only a slight elevationafter 30 min, whereas CCK-stimulated MAPK remained at a high level ofactivation to 60 min. The protein kinase C inhibitor GF-109203Xabolished the activation by phorbol ester and inhibited the effect ofCCK by 78% but had no effect on EGF-activated MAPK activity. EGF and CCK activated both forms of MAPK kinase (MEK), with CCK having a muchlarger effect, activating MEK1 by 6-fold and MEK2 by 10-fold, whereasEGF activated both MEKs by only 2-fold. Immunoblotting revealed threedifferent forms of Raf in pancreatic acinar cells. Of the total basalRaf kinase activity, 3.7% was Raf-A, 89.0% was Raf-B, and 7.3% wasc-Raf-1. All three forms of Raf were stimulated to a greater extent byCCK than by EGF, which was especially evident for Raf-A and c-Raf-1.The effect of CCK in activating Rafs was at least partially mimicked bystimulation with the phorbol ester 12-O-tetradecanoylphorbol-13-acetate. EGF significantlyincreased GTP-bound Ras by 183 and 164% at 2.5 and 10 min,respectively; CCK and TPA had no measurable effect. Our study suggeststhat CCK and EGF activate the MAPK cascade by distinct mechanisms in pancreatic acinar cells.

     

Structural studies of human placental dermatan sulfate during development using optical mixing spectroscopy

Optical mixing spectroscopy is a recently developed technique which permits the measurement of diffusion coefficients and molecular weights of macromolecular species when only small amounts of material can be obtained for analyses. In this study, an approxmate empirical relationship between diffusion coefficient and viscosity-average molecular weight was established for highly sulfated mucopolysaccharides. This relationship was then used to deduce the molecular weights of small quantities of highly purified dermatan sulfate extracted from human placenta at the full term (40 weeks) and at earlier stages of development (12–18 weeks). The effect of hyaluronidase digestion on molecular weight was then investigated as a probe for glucuronic acid substitutions in the dermatan sulfate. The molecular weights of dermatan sulfate were similar, 27,000–29,000, in the term and young placenta. Digestion with hyaluronidase produced a 50% reduction in molecular weight in the young placenta versus a 30% reduction in the term placenta, clearly demonstrating significant differences in the nature of glucuronic acid substitution at the two developmental stages studied.