Despina Kolonias

Multivalent 4-1BB binding aptamers costimulate CD8+ T cells and inhibit tumor growth in mice

4-1BB is a major costimulatory receptor that promotes the survival and expansion of activated T cells. Administration of agonistic anti-4-1BB Abs has been previously shown to enhance tumor immunity in mice. Abs are cell-based products posing significant cost, manufacturing, and regulatory challenges. Aptamers are oligonucleotide-based ligands that exhibit specificity and avidity comparable to, or exceeding, that of Abs. To date, various aptamers have been shown to inhibit the function of their cognate target. Here, we have described the development of an aptamer that binds 4-1BB expressed on the surface of activated mouse T cells and shown that multivalent configurations of the aptamer costimulated T cell activation in vitro and mediated tumor rejection in mice. Because aptamers can be chemically synthesized, manufacturing and the regulatory approval process should be substantially simpler and less costly than for Abs. Agonistic aptamers could therefore represent a superior alternative to Abs for the therapeutic manipulation of the immune system.

Induction of tumour immunity by targeted inhibition of nonsense-mediated mRNA decay

The main reason why tumours are not controlled by the immune system is that, unlike pathogens, they do not express potent tumour rejection antigens (TRAs). Tumour vaccination aims at stimulating a systemic immune response targeted to, mostly weak, antigens expressed in the disseminated tumour lesions. Main challenges in developing effective vaccination protocols are the identification of potent and broadly expressed TRAs and effective adjuvants to stimulate a robust and durable immune response. Here we describe an alternative approach in which the expression of new, and thereby potent, antigens are induced in tumour cells by inhibiting nonsense-mediated messenger RNA decay (NMD). Small interfering RNA (siRNA)-mediated inhibition of NMD in tumour cells led to the expression of new antigenic determinants and their immune-mediated rejection. In subcutaneous and metastatic tumour models, tumour-targeted delivery of NMD factor-specific siRNAs conjugated to oligonucleotide aptamer ligands led to significant inhibition of tumour growth that was superior to that of vaccination with granulocyte–macrophage colony-stimulating factor (GM-CSF)-expressing irradiated tumour cells, and could be further enhanced by co-stimulation. Tumour-targeted NMD inhibition forms the basis of a simple, broadly useful, and clinically feasible approach to enhance the antigenicity of disseminated tumours leading to their immune recognition and rejection. The cell-free chemically synthesized oligonucleotide backbone of aptamer–siRNAs reduces the risk of immunogenicity and enhances the feasibility of generating reagents suitable for clinical use.

Targeting 4-1BB Costimulation to Disseminated Tumor Lesions With Bi-specific Oligonucleotide Aptamers

The paucity of costimulation at the tumor site compromises the ability of tumor-specific T cells to eliminate the tumor. Here, we show that bi-specific oligonucleotide aptamer conjugates can deliver costimulatory ligands to tumor cells in situ and enhance antitumor immunity. In poorly immunogenic subcutaneously implanted tumor and lung metastasis models, systemic delivery of an agonistic 4-1BB aptamer ligand conjugated to a prostate specific membrane antigen (PSMA)-binding tumor-targeting aptamer led to inhibition of tumor growth, was more effective than, and synergized with, vaccination, and exhibited a superior therapeutic index compared to costimulation with 4-1BB antibodies. Tumor inhibition was dependent on homing to PSMA-expressing tumor cells and 4-1BB costimulation. Aptamer targeted costimulation is a broadly applicable and clinically feasible approach to enhance the costimulatory environment of disseminated tumor lesions. This study suggests that potentiating naturally occurring antitumor immunity via tumor-targeted costimulation could be an effective approach to elicit protective immunity to control tumor progression in cancer patients.The paucity of costimulation at the tumor site compromises the ability of tumor-specific T cells to eliminate the tumor. Here, we show that bi-specific oligonucleotide aptamer conjugates can deliver costimulatory ligands to tumor cells in situ and enhance antitumor immunity. In poorly immunogenic subcutaneously implanted tumor and lung metastasis models, systemic delivery of an agonistic 4-1BB aptamer ligand conjugated to a prostate specific membrane antigen (PSMA)-binding tumor-targeting aptamer led to inhibition of tumor growth, was more effective than, and synergized with, vaccination, and exhibited a superior therapeutic index compared to costimulation with 4-1BB antibodies. Tumor inhibition was dependent on homing to PSMA-expressing tumor cells and 4-1BB costimulation. Aptamer targeted costimulation is a broadly applicable and clinically feasible approach to enhance the costimulatory environment of disseminated tumor lesions. This study suggests that potentiating naturally occurring antitumor immunity via tumor-targeted costimulation could be an effective approach to elicit protective immunity to control tumor progression in cancer patients.

CD28 Aptamers as Powerful Immune Response Modulators

CD28 is one of the main costimulatory receptors responsible for the proper activation of T lymphocytes. We have isolated two aptamers that bind to the CD28 receptor. As a monomer, one of them interfered with the binding of CD28 to its ligand (B7), precluding the costimulatory signal, whereas the other one was inactive. However, dimerization of any of the anti-CD28 aptamers was sufficient to provide an artificial costimulatory signal. No antibody has featured a dual function (i.e., the ability to work as agonist and antagonist) to date. Two different agonistic structures were engineered for each anti-CD28 aptamer. One showed remarkably improved costimulatory properties, surpassing the agonistic effect of an anti-CD28 antibody. Moreover, we showed in vivo that the CD28 agonistic aptamer is capable of enhancing the cellular immune response against a lymphoma idiotype and of prolonging survival of mice which receive the aptamer together with an idiotype vaccine. The CD28 aptamers described in this work could be used to modulate the immune response either blocking the interaction with B7 or enhancing vaccine-induced immune responses in cancer immunotherapy.

Regulation of RelB Expression during the Initiation of Dendritic Cell Differentiation

ABSTRACT The transcription factor RelB is required for proper development and function of dendritic cells (DCs), and its expression is upregulated early during differentiation from a variety of progenitors. We explored this mechanism of upregulation in the KG1 cell line model of a DC progenitor and in the differentiation-resistant KG1a subline. RelB expression is relatively higher in untreated KG1a cells but is upregulated only during differentiation of KG1 by an early enhancement of transcriptional elongation, followed by an increase in transcription initiation. Restoration of protein kinase CβII (PKCβII) expression in KG1a cells allows them to differentiate into DCs. We show that PKCβII also downregulated constitutive expression of NF-κB in KG1a-transfected cells and restores the upregulation of RelB during differentiation by increased transcriptional initiation and elongation. The two mechanisms are independent and sensitive to PKC signaling levels. Conversely, RelB upregulation was inhibited in primary human monocytes where PKCβII expression was knocked down by small interfering RNA targeting. Altogether, the data show that RelB expression during DC differentiation is controlled by PKCβII-mediated regulation of transcriptional initiation and elongation.

Induced dendritic cell differentiation of chronic myeloid leukemia blasts is associated with down-regulation of BCR-ABL.

Although differentiation of leukemic blasts to dendritic cells (DC) has promise in vaccine strategies, the mechanisms underlying this differentiation and the differences between leukemia and normal progenitor-derived DC are largely undescribed. In the case of chronic myeloid leukemia (CML), understanding the relationship between the induction of DC differentiation and the expression of the BCR-ABL oncogene has direct relevance to CML biology as well as the development of new therapeutic approaches. We now report that direct activation of protein kinase C (PKC) by the phorbol ester PMA in the BCR-ABL+ CML cell line K562 and primary CML blasts induced nonterminal differentiation into cells with typical DC morphology (cytoplasmic dendrites), characteristic surface markers (MHC class I, MHC class II, CD86, CD40), chemokine and transcription factor expression, and ability to stimulate T cell proliferation (equivalent to normal monocyte-derived DC). PKC-induced differentiation was associated with down-regulation of BCR-ABL mRNA expression, protein levels, and kinase activity. This down-regulation appeared to be signaled through the mitogen-activated protein kinase pathway. Therefore, PKC-driven differentiation of CML blasts into DC-like cells suggests a potentially novel strategy to down-regulate BCR-ABL activity, yet raises the possibility that CML-derived DC vaccines will be less effective in presenting leukemia-specific Ags.

Differentiation of acute and chronic myeloid leukemic blasts into the dendritic cell lineage: analysis of various differentiation-inducing signals.

Purpose: Ex vivo differentiation of myeloid leukemic blasts into dendritic cells (DCs) holds significant promise for use as cellular vaccines, as they may present a constellation of endogenously expressed known and unknown leukemia antigens to the immune system. Although variety of stimuli can drive leukemia→DC differentiation in vitro, these blast-derived DCs typically have aberrant characteristics compared with DCs generated from normal progenitors by the same stimuli. It is not clear whether this is due to underlying leukemogenic mechanisms (e.g., specific oncogenes), genetic defects, stage of maturation arrest, defects in cytokine receptor expression or signal transduction pathways, or whether different stimuli themselves induce qualitatively dissimilar DC differentiation. Methods: To assess what factors may contribute to aberrant leukemic blast→DC differentiation, we have examined how the same leukemic blasts (AML and CML) respond to different DC differentiation signals—including extracellular (the cytokine combination GM-CSF+TNF-α+IL-4) and intracellular (the protein kinase C agonist PMA, the calcium ionophore A23187, and the combination of PMA plus A23187) stimuli. Results: We have found that the same leukemic blasts will develop qualitatively different sets of DC characteristics in response to differing stimuli, although no stimuli consistently induced all of the characteristic DC features. There were no clear differences in the responses relative to specific oncogene expression or stage of maturation arrest (AML vs CML). Signal transduction agonists that bypassed membrane receptors/proximal signaling (in particular, the combination of PMA and A23187) consistently induced the greatest capability to activate T cells. Interestingly, this ability did not clearly correlate with expression of MHC/costimulatory ligands. Conclusions: Our findings suggest that signal transduction may play an important role in the aberrant DC differentiation of leukemic blasts, and demonstrate that direct activation of PKC together with intracellular calcium signaling may be an effective method for generating immunostimulatory leukemia-derived DCs.

Accumulation of simple organic cations correlates with differential cytotoxicity in multidrug-resistant and -sensitive human and rodent cells.

Structure/functional studies previously reported showed that in a series of simple organic cations in which the charge is delocalized, an aromatic ring and a minimal degree of lipophilicity (log P > −1) were required for recognition by murine cells which express P-glycoprotein (p-gp)-mediated multidrug resistance (MDR). In the present report we find that 3H-octylpyridinium, the simple aromatic cation which has been shown to be preferentially toxic to MDR− as compared to MDR+ cells, accumulates 4.7-fold greater in the MDR− cell line. In contrast, we find that 3H-guanidinium which displays no selective toxicity between MDR+ and MDR− cells, shows no significant uptake differences between these two cell types. We also present data which demonstrate that other organic cations which contain aromatic rings, a minimal degree of lipophilicity (log P> −1) and carry a delocalized (Rho 123) or shielded (triphenylmethyl phosphonium) positive charge, also accumulate to a greater degree in MDR− vs MDR+ cells. Additionally, we find that human cells which express p-gp MDR, have similar requirements for recognition of these simple compounds. In fact, the sensitivity profiles of these compounds closely correlate between murine and human cell lines. It was also found that none of the series of simple organic compounds tested showed modulatory activity in MDR+ cells, as assayed by monitoring retention of Rho 123. Thus, the requirements for MDR recognition vs those for MDR modulation are clearly distinguished with these simple structured compounds. In comparison, the calcium channel antagonist, verapamil, and a calcium channel agonist, Bay K 8644, both showed modulatory activity by increasing Rho 123 retention in MDR+ cells, further supporting the interpretation that verapamil’s modulation of MDR is unrelated to its action on calcium flux. Overall, the data presented here add further information for defining the structural requirements of compounds for their recognition by, or modulation of, human cells expressing p-gp-mediated MDR

α-Smooth muscle actin expression in cultured cardiac fibroblasts of newborn rat

SummaryUsing a panel of monoclonal anitbodies to several different cytoskeletal elements in primary cultures derived from newborn rat hearts we report that fibroblasts similar to cardiac-muscle cells expressed theα-actin isoform of smooth muscle cells. However, striated muscleα-actin or desmin antibodies did not stain cardiac fibroblasts but did stain cardiac-muscle cells. Theα-smooth muscle actin distributed as a stress fiber and in a cross-striated pattern in cardiac muscle while fibroblasts showed exclusive stress fiber staining. These results suggest that connective tissue cells during development of the heart contain muscle-specific elements which may relate to the organ-specific contractile function with which they are associated.

Modulation of dendritic cell differentiation and function by YopJ of Yersinia pestis

Yersinia pestis evades immune responses in part by injecting into host immune cells several effector proteins called Yersinia outer proteins (Yops) that impair cellular function. This has been best characterized in the innate effector cells, but much less so for cells involved in adaptive immune responses. Dendritic cells (DC) sit at the crossroads between innate and adaptive immunity, and can function to initiate or inhibit adaptive immune responses. Although Y. pestis can target and inactivate DC, the mechanism responsible for this remains unclear. We have found that injection of Y. pestis YopJ into DC progenitors disrupts key signal transduction pathways and interferes with DC differentiation and subsequent function. YopJ injection prevents up‐regulation of the NF‐κB transcription factor Rel B and inhibits MAPK/ERK activation – both having key roles in DC differentiation. Furthermore, YopJ injection prevents costimulatory ligand up‐regulation, LPS‐induced cytokine expression, and yields differentiated DC with diminished capability to induce T cell proliferation and IFN‐γ induction. By modulating DC function through YopJ‐mediated disruption of signaling pathways during progenitor to DC differentiation, Yersinia may interfere with the adaptive responses necessary to clear the infection as well as establish a tolerant immune environment that leads to chronic infection/carrier state in the surviving host.