Imiquimod simultaneously induces autophagy and apoptosis in human basal cell carcinoma cells.

BACKGROUND: Imiquimod shows antitumour activity through the stimulation of cell-mediated immunity in vivo. Recent studies have shown that imiquimod promotes apoptosis in melanoma cells and induces autophagy in macrophage cell lines. OBJECTIVES: To evaluate the imiquimod-induced apoptosis, autophagy and their relationship in a basal cell carcinoma (BCC) cell line. METHODS: Cell viability was determined by XTT test. Apoptosis was evaluated by DNA content assay, annexin V/propidium iodide staining assay and terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick-end labelling assay. Autophagy was determined by LC3 immunoblotting, EGFP-LC3 puncta formation and quantification of acidic vesicular organelles with acridine orange staining. The temporal and spatial differences of imiquimod-induced apoptosis and autophagy were examined by immunoblotting and simultaneously monitored by staining the EGFP-LC3 transfected cells with caspase 3 fluorogenic substrate. We inhibited the apoptosis and autophagy by pancaspase inhibitor and siRNA for Beclin 1 or Atg5, respectively, to evaluate the interplay between imiquimod-induced apoptosis and autophagy. RESULTS: We found that imiquimod induces autophagy and apoptosis in BCC cells in a time- and dose-dependent manner. Imiquimod not only induced EGFP-LC3 puncta formation for autophagy, but also simultaneously activated an apoptotic caspase cascade in the same cells. Both apoptosis and autophagy induced by imiquimod cooperate to cause BCC cell death. However, inhibition of imiquimod-induced apoptosis increased the strength of autophagy, and inhibition of imiquimod-induced autophagy further promoted cell apoptosis. CONCLUSIONS: This study not only demonstrates that imiquimod can directly induce autophagy and apoptosis in BCC cells, but also shows the cooperation and coordination between these two processes to induce cell death.

Modulation of the binding affinity of myelopoietins for the interleukin-3 receptor by the granulocyte colony-stimulating factor receptor agonist.

Myelopoietins (MPOs) are a family of recombinant chimeric proteins that are both interleukin-3 (IL-3) receptor and granulocyte colony-stimulating factor (G-CSF) receptor agonists. In this study, MPO molecules containing one of three different IL-3 receptor agonists linked with a common G-CSF receptor agonist have been examined for their IL-3 receptor binding characteristics. Binding to the alpha-subunit of the IL-3 receptor revealed that the affinity of the MPO molecules was 1.7-3.4-fold less potent than those of their individual cognate IL-3 receptor agonists. The affinity decrease was reflected in the MPO chimeras having approximately 2-fold slower dissociation rates and 2.7-5.5-fold slower association rates than the corresponding specific IL-3 receptor agonists alone. The affinity of binding of the MPO molecules to the heteromultimeric alphabeta IL-3 receptor expressed on TF-1 cells was either 3-, 10-, or 42-fold less potent than that of the individual cognate IL-3 receptor agonist. Biophysical data from nuclear magnetic resonance, near-UV circular dichroism, dynamic light scattering, analytical ultracentrifugation, and size exclusion chromatography experiments determined that there were significant tertiary structural differences between the MPO molecules. These structural differences suggested that the IL-3 and G-CSF receptor agonist domains within the MPO chimera may perturb one another to varying degrees. Thus, the differential modulation of affinity observed in IL-3 receptor binding may be a direct result of the magnitude of these interdomain interactions.

Receptor binding kinetics of human IL-3 variants with altered proliferative activity.

The binding kinetics of native IL-3 and a set of truncated IL-3 variants to the alpha subunit of the IL-3 receptor (IL-3Ralpha) were studied using surface plasmon resonance. These variants, with amino acid substitutions at residues, 22, 42, 43, 45, 46, 113, or 116, have previously been identified to have altered capacity to stimulate cell proliferation compared to native IL-3(1-133). In this study, variants E43N and F113Y exhibited >100-fold slower association rates than IL-3(15-125) consistent with residues 43 and 113 being essential for the binding of IL-3 to the IL-3Ralpha. Variants G42A, G42D, Q45V, D46S, K116V, and K116W exhibited increased association rates (up to 15-fold relative to IL-3(15-125)) and decreased dissociation rates (up to 7-fold). The results demonstrate that both the association and dissociation rates for the binding of IL-3 to the IL-3Ralpha are altered by truncation and by amino acid substitution at individual sites. Intracellular signaling studies using K116W and E43N demonstrate that differences in the IL-3alpha binding characteristics are reflected in magnitude and kinetics of STAT5 phosphorylation.

Bivalent binding and signaling characteristics of Leridistim, a novel chimeric dual agonist of interleukin-3 and granulocyte colony-stimulating factor receptors.

Leridistim is a member of a novel family of engineered chimeric cytokines, myelopoietins, that contain agonists of both interleukin-3 (IL-3) receptors (IL-3R) and granulocyte colony-stimulating factor (G-CSF) receptors (G-CSFR). To more clearly understand Leridistim's function at the molecular level, binding to both IL-3R and G-CSFR and subsequent signaling characteristics have been delineated. The affinity of Leridistim for the human G-CSFR was found to be comparable to that of native G-CSF (IC(50) = 0.96 nM and 1.0 nM, respectively). Both Leridistim and G-CSF induced receptor tyrosine phosphorylation to a similar maximal level. Compared with native recombinant human IL-3 (rhIL-3), Leridistim was found to possess higher affinity for the IL-3R alpha chain (IL-3Ralpha) (IC(50) = 85 nM and 162 nM, respectively). However, the increase in Leridistim binding affinity to the functional, high-affinity heterodimeric IL-3Ralphabeta(c) receptor is lower than that observed with rhIL-3 (85 nM and 14 nM vs 162 nM and 3.5 nM, respectively). Leridistim induced tyrosine phosphorylation of beta(c) to a level comparable to native IL-3, and the level of JAK2 tyrosine phosphorylation in cells expressing both IL-3R and G-CSFR was comparable to that observed with IL-3 or G-CSF alone. The ability of Leridistim to interact with IL-3R and G-CSFR simultaneously was demonstrated using surface plasmon resonance analysis. These studies were extended to demonstrate that Leridistim exhibited a higher affinity for the IL-3R on cells that express both the IL-3Ralphabeta(c) and the G-CSFR (IC(50) = 2 nM) compared with cells that contain the IL-3Ralphabeta(c) alone (IC(50) = 14 nM). Leridistim binds to both IL-3R and G-CSFR simultaneously and has been shown to activate both receptors. The bivalent avidity may explain the unique biologic effects and unexpected potency of Leridistim in hematopoietic cells compared with rhIL-3 or G-CSF alone or in combination.

Circular permutation of the granulocyte colony-stimulating factor receptor agonist domain of myelopoietin.

Myelopoietins (MPOs) are a family of engineered dual interleukin-3 (IL-3) and granulocyte colony-stimulating factor (G-CSF) receptor agonists that are superior in comparison to the single agonists in their ability to promote the growth and maturation of hematopoietic cells of the myeloid lineage. A series of MPO molecules were created which incorporated circularly permuted G-CSF (cpG-CSF) sequences with an IL-3 receptor (IL-3R) agonist moiety attached at locations that correspond to the loops that connect the helices of the G-CSF four-helix bundle structure. The cpG-CSF linkage sites (using the original sequence numbering) were residue 39, which is at the beginning of the first loop connecting helices 1 and 2; residue 97, which is in the turn connecting helices 2 and 3; and residues 126, 133, and 142, which are at the beginning, middle, and end, respectively, of the loop connecting helices 3 and 4. The N- and C-terminal helices of each cpG-CSF domain were constrained, either by direct linkage of the termini (L0) or by replacement of the amino-terminal 10-residue segment with a seven-residue linker composed of SGGSGGS (L1). All of the MPO molecules stimulated the proliferation of both IL-3-dependent (EC50 = 13-95 pM) and G-CSF-dependent (EC50 = 35-710 pM) cell lines. MPOs with the IL-3R agonist domain linked to cpG-CSFs in the first (residue 39) or second (residue 133) long overhand loops were found by CD spectroscopy to have helical contents similar to that expected for a protein comprised of two linked four-helix bundles. The MPOs retained the ability to bind to the IL-3R with affinities similar to that of the parental MPO. Using both a cell surface competitive binding assay and surface plasmon resonance detection of binding kinetics, the MPOs were found to bind to the G-CSF receptor with low nanomolar affinities, similar to that of G-CSF(S17). In a study of isolated cpG-CSF domains [Feng, Y., et al. (1999) Biochemistry 38, 4553-4563], domains with the L1 linker had lower G-CSF receptor-mediated proliferative activities and conformational stabilities than those which had the L0 linker. A similar trend was found for the MPOs in which the G-CSFR agonist activity is mostly a property of the cpG-CSF domain. Important exceptions were found in which the linkage to the IL-3R agonist domain either restored (e.g., attachment at residue 142) or further decreased (linkage at residue 39) the G-CSFR-mediated proliferative activity. MPO in which the IL-3R agonist domain is attached to the cpG-CSF(L1)[133/132] domain was shown to be more potent than the coaddition of the IL-3R agonist and G-CSF in stimulating the production of CFU-GM colonies in a human bone marrow-derived CD34+ colony-forming unit assay. Several MPOs also had decreased proinflammatory activity in a leukotriene C4 release assay using N-formyl-Met-Leu-Phe-primed human monocytes. It was found that circular permutation of the G-CSF domain can alter the ratio of G-CSFR:IL-3R agonist activities, demonstrating that it is a useful tool in engineering chimeric proteins with therapeutic potential.

Use of combinatorial mutagenesis to select for multiply substituted human interleukin-3 variants with improved pharmacologic properties.

A combinatorial mutagenesis strategy was used to create a collection of nearly 500 variants of human interleukin 3 (IL-3), each with four to nine amino acid substitutions clustered within four linear, nonoverlapping regions of the polypeptide. The variants were secreted into the periplasm of Escherichia coli and supernatants were assayed for IL-3 receptor-dependent cell proliferation activity. Sixteen percent of the variants, containing "region-restricted" substitutions, retained substantial proliferative activity through two rounds of screening. A subset of these was combined to yield variants with substitutions distributed through approximately half of the polypeptide. With one exception, "half-substituted" variants exhibited proliferative activity within 3.5-fold of native IL-3. A subset of the "half-substituted" variants was combined to yield "fully substituted" IL-3 variants having 27 or more substitutions. The combination of the substitutions resulted in a set of polypeptides, some of which exhibit increased proliferative activity relative to native IL-3. The elevated hematopoietic potency was confirmed in a methylcellulose colony-forming unit assay using freshly isolated human bone marrow cells. A subset of the multiply substituted proteins exhibited only a modest increase in inflammatory mediator (leukotriene C4) release. The molecules also exhibited 40- to 100-fold greater affinity for the alpha subunit of the IL-3 receptor and demonstrated a 10-fold faster association rate with the alpha-receptor subunit. The multiply substituted IL-3 variants described in this study provide a unique collection of molecules from which candidates for clinical evaluation may be defined and selected.

Molecular study on the infantile form of Pompe disease in Chinese in Taiwan.

Glycogen-storage disease type II, Pompe disease, is caused by the deficiency of acid alpha-D-glucosidase in lysosome. Previously we found that acid alpha-D-glucosidase did exist in the skin fibroblasts and there was also no difference of mRNA in quantity and size of Chinese infantile type Pompe disease patients in Taiwan. However, functional assay of the acid alpha-D-glucosidase of these patients showed its enzyme function to be defective. In the present study, first we identified a substitution site in four Chinese infantile patients with Pompe disease which is a cytidine to adenosine (C1935-->A) transversion at 5' end of exon 14 causing substitution of glutamic acid for aspartic acid at position 645 of the acid alpha-D-glucosidase. This substitution was introduced in wild-type cDNA and expressed in COS-1 cells. The Asp-645-->Glu substitution resulted in significant reduction of acid alpha-D-glucosidase activity. Second, according to the screening data in 25 Chinese Pompe disease patients using digestion of RT-PCR amplified specific fragment with Aat II, the restriction fragment length analysis showed that patients presented the 861 bp band and the normal individuals presented the 728 bp and 133 bp polymorphic bands. We found that the frequency of mutant allele is 0.8 in infantile patients with Chinese Pompe disease and 0 in normal individuals. These results therefore indicate that Asp-645-->Glu mutation results in infantile form of Pompe disease as the major cause in Chinese patients in Taiwan.

Differential effects of CTLA-4 substitutions on the binding of human CD80 (B7-1) and CD86 (B7-2).

CTLA-4 expressed on activated T cells binds to CD80 (B7-1) and CD86 (B7-2) molecules present on APC with high avidity and appears to deliver a negative regulatory signal to the T cell. We have investigated the kinetics of CTLA-4 binding to CD80 and CD86, together with the effects of selected CTLA-4 mutations on binding activity. The dissociation constants (Kd) for binding of CTLA-4-Ig to CD80 and CD86 transfectants were 8.1 and 6.7 nM, respectively. Surface plasmon resonance was used to determine kinetic parameters of CTLA-4-Ig binding to CD80-Ig and CD86-Ig fusion proteins and revealed enhanced association (ka) and dissociation (kd) rate constants for CD86-Ig compared with CD80-Ig. Furthermore, CD80-Ig and CD86-Ig fusion molecules demonstrated variable abilities to cross-compete for binding to several modified forms of CTLA-4-Ig. Differential binding of CD80 and CD86 to CTLA-4 was further revealed by analysis of 10 discrete CTLA-4 mutants. Five single amino acid substitutions within the CTLA-4 MYPPPY domain exerted modest effects on CD80 binding, but each of these substitutions completely abrogated CD86 binding. In addition, substitutions just N-terminal of the MYPPPY region, and within the CDR1-like region of CTLA-4, eliminated both CD80 and CD86 binding. Hence, CD80 and CD86 bind with different association/dissociation kinetics to similar, but distinct, sites on CTLA-4.