- Open Access
Overexpression of CCL-21/Secondary Lymphoid Tissue Chemokine in Human Dendritic Cells Augments Chemotactic Activities for Lymphocytes and Antigen Presenting Cells
Molecular Cancer volume 2, Article number: 35 (2003)
Ex vivo generated dendritic cells (DC) genetically modified to express secondary lymphoid tissue chemokine (CCL-21/SLC) have been shown to stimulate potent antitumor responses in murine models. When injected intratumorally, CCL-21 colocalizes DC and lymphocyte effector cells at the tumor site. This may improve tumor antigen presentation and T cell activation by utilizing the tumor as an in vivo source of antigen for DC. In order to develop DC-based cancer therapies for intratumoral injection that could promote tumor antigen uptake and presentation in situ, we constructed and characterized an adenoviral vector that expresses human CCL-21 (AdCCL-21).
Human monocyte derived DC were cultured in GM-CSF and IL-4 for 6 days. Following AdCCL-21 transduction, CCL-21 protein production was assessed by ELISA on day 8. DC transduced with AdCCL-21 at multiplicities of infection (MOIs) of 50:1 or 100:1 produced up to 210 ± 9 ng/ml and 278 ± 6.5 ng/ml /106 cells/48 hours, respectively. Following transduction, an immature DC phenotype was maintained and an upregulation of the costimulatory molecule, CD86 was noted. In addition, supernatant from AdCCL-21-DC caused significant chemotaxis of peripheral blood lymphocytes and mature DC.
These studies demonstrate that AdCCL-21-DC generate functional levels of CCL-21 without adversely altering DC phenotype. These findings strengthen the rationale for further investigation of AdCCL-21-DC as a DC-based therapy in cancer treatment.
Tumor-associated antigens are expressed by many tumors, including lung cancers, and can be presented to cytotoxic T cells by antigen presenting cells (APCs) resulting in antitumor responses . As a result of limited expression of major histocompatibility complex (MHC) antigen and costimulatory molecules, as well as production of immune inhibitory cytokines, tumor cells are ineffective APCs . Therefore, recruitment of professional APCs to the tumor site may be essential for generating specific anti-tumor immune responses. Dendritic cells (DC) are potent APCs fundamental in the activation of specific immunity . Advancements in the isolation and in vitro propagation of DC have generated interest in their use in cancer therapy. DC have been investigated as adjuvants to cancer immunotherapy to stimulate tumor-specific antigen presentation for promotion of T cell activation and anticancer immunity [4–8].
Strategies employing DC in immunotherapy have included DC pulsed with tumor antigen peptides, apoptotic tumor cells, tumor lysates, or genetic modification of DC with genes encoding tumor antigens or immunomodulatory proteins [8–17]. There is evidence that DC transduced with adenoviral vectors (AdV) have prolonged survival and resistance to spontaneous and Fas-mediated cell death . This could result in the improved delivery of immunotherapy. AdV transduction can also augment the capacity of DC to induce protective antitumor immunity . In addition, enhanced local and systemic anti-tumor effects have been demonstrated when AdV transduced DC expressing cytokine genes have been injected intratumorally [17, 20–23].
The use of ex vivo-propagated DC genetically modified to express chemokines that attract DC and lymphocyte effector cells to sites of tumor may improve tumor antigen presentation and T cell activation by utilizing the tumor as an in vivo source of antigen for dendritic cells. Chemokines are a family of proteins involved in leukocyte chemotaxis and activation, and have been associated with the regulation of angiogenesis [24, 25]. CCL-21 is a CC chemokine expressed by high endothelial venules and in T cell zones of spleen and lymph nodes that strongly attracts T cells and mature DC [26–33]. CCL-21 recruits both Th1 lymphocytes and antigen-stimulated dendritic cells into T cell zones of secondary lymphoid organs, co-localizing the immune response elements and resulting in T cell activation . In plt-/plt- mice with undetectable levels of CCL-21, the homing of T cells and DC to secondary lymphoid organs has been shown to be significantly decreased . In addition to its immunotherapeutic potential, CCL-21 has been found to have potent angiostatic effects , thus adding further support for its use in cancer therapy.
Based on these capacities, CCL-21 could be an important protein for evaluation in cancer immunotherapy. Studies using recombinant CCL-21 in mouse lung cancer models have shown that intratumoral injection of recombinant CCL-21 led to potent antitumor responses with complete tumor eradication in 40% of treated mice . In a spontaneous lung cancer model, recombinant CCL-21 injected into the axillary lymph node region produced a marked reduction in tumor burden with extensive lymphocytic and DC infiltration of the tumors. The CCL-21 injected mice also showed increased survival . Intratumoral injections of murine CCL-21 gene modified DC (murine AdCCL-21-DC) into established murine lung tumors resulted in complete tumor regression and enhanced protective immunity compared to mice treated with control vector transduced DC or DC alone . Similar results have been shown in a murine melanoma model [20, 21]. The anti-tumor efficacy of AdCCL-21-DC implies an important role for DC as a vehicle to deliver CCL-21 to the tumor.
Based on these preclinical results, we constructed and characterized an adenoviral vector expressing human CCL-21 (AdCCL-21) to be utilized for transduction of human monocyte-derived DC (AdCCL-21-DC). We hypothesized that this construct would effectively produce CCL-21 without compromising DC phenotype. In addition, we proposed that human DC transduced with AdCCL-21 would demonstrate enhanced chemokine-dependent biologic activity evidenced by the capacity to attract lymphocytes and APCs. Our results indicate that AdCCL-21-DC generate biologically relevant levels of CCL-21 without negatively altering DC phenotype.
AdCCL-21 gene-modified human DC produce biologically active levels of CCL-21
On day 6 of culture, immature human monocyte-derived DC (at 106 cells/ml) were transduced with AdCCL-21 at various multiplicities of infection (MOIs, 50:1–10,000:1) for 24–192 hours. Transduction was accomplished either by the standard method (2 hours incubation at 37°C), or by the centrifugation method (2000 × g at 37°C for 2 hours) as previously described [38, 39]. CCL-21 protein production was assessed by ELISA, and demonstrated higher concentrations with increasing MOIs. Protein production increased with escalating MOIs, and plateaued at MOIs greater than 100:1. Cell viability significantly decreased at MOIs greater than 500:1 (data not shown). At relatively low MOIs of 50:1 and 100:1, 210 and 278 ng/ml/106 cells/48 hours of CCL-21 protein was produced respectively (Table 1). Moreover, DC transduction by the centrifugation method led to 2.9 fold increase in CCL-21 protein secretion compared to the standard transduction method (Table 1). Time course experiments revealed a plateau of CCL-21 production at 48 hours with sustained protein secretion at high levels (>190 ng/106 cells) up to day 8 after transduction (day 14 of culture) (Figure 1). There were no significant differences noted in CCL-21 protein production when comparing LPS-matured and immature DC (data not shown). For subsequent studies, we assessed DC phenotype and function 48 hours following adenoviral transduction at MOI 50:1 and 100:1 in immature DC.
DC phenotype is maintained after transduction with AdCCL-21
DC, AdCCL-21-DC, and DC transduced with the control adenoviral construct (AdCV) were characterized by flow cytometry at 48 hours after transduction. The expression of DC surface markers was not significantly altered by transduction with AdCCL-21 or AdCV (AdCV-DC). The immature DC phenotype was preserved in AdCV-DC and AdCCL-21-DC without up-regulation of CD83, HLA-DR, or CCR7 (Figure 2). We demonstrated an increase in the expression of CD86 following transduction with either AdCCL-21 or AdCV. The latter is consistent with previous reports [19, 40, 41].
AdCCL-21-DC augments chemotaxis of PBL and mature DC
The migration of peripheral blood lymphocytes (PBL) to AdCCL-21-DC was assessed by a standard transwell chemotaxis assay. Supernatants from AdCCL-21-DC, AdCV-DC, and non-transduced DC (NTDC), as well as recombinant CCL-21 (rCCL-21) were used to demonstrate this integral activity. 2 × 105 freshly isolated PBL, labeled with a fluorescent probe, were allowed to migrate through 3 μm pore inserts of the transwell plate. Total cell migration was determined by measuring optical density (OD). Supernatant from AdCCL-21-DC (producing 20 ng/ml/106 cells) induced enhanced chemotaxis of PBL when compared to AdCV-DC supernatant, non-transduced DC supernatant alone, or control medium (p < 0.002) (10% AB serum) (Figure 3). Furthermore, AdCCL-21-DC promoted chemotaxis of LPS-matured DC (data not shown).
Anti-CCL-21 antibody significantly inhibits the enhanced chemotaxis stimulated by AdCCL-21-DC
We evaluated the contribution of CCL-21 to the enhanced function of AdCCL-21-DC compared to AdCV-DC or NTDC. A pre-titered neutralizing concentration of CCL-21 antibody was added to AdCCL-21-DC supernatant or recombinant CCL-21 and incubated for 30 minutes. The chemokine-dependent activity of AdCCL-21-DC was assessed by measuring the migration of T2 cells to AdCCL-21-DC and NTDC supernatants or rCCL-21 in the presence or absence of anti-CCL-21 antibody. T2 is a T/B hybridoma that lacks HLA class II antigen, but expresses HLA.A2 molecules. These cells are often used as APCs when evaluating specific cytotoxic T lymphocyte responses, and were chosen to evaluate chemotaxis of APCs to AdCCL-21-DC. Our results showed that anti-CCL-21 antibody efficiently blocked the chemotactic activity of recombinant CCL-21 (data not shown). Moreover, the enhanced attraction of T2 cells observed with AdCCL-21-DC supernatant was significantly inhibited by the addition of anti-CCL-21 antibody. (Figure 4). Our data shows a partial reversal of the chemoattractive properties of AdCCL-21-DC using anti-CCL-21 antibody. Other proteins and chemokines with attractant capacities exist in DC supernatants, and these likely account for the incomplete inhibition of cell migration when anti-CCL-21 is added to AdCCL-21-DC. Chemotaxis of AdCCL-21-DC was not inhibited following addition of control antibody.
AdCCL-21 transduction decreases immunosuppressive cytokine production
Previous studies have indicated that that adenoviral vector transduction of DC stimulates enhanced effector cell activity , in part through increased IL-12 production. We investigated the effects of AdCCL-21 and AdCV transduction on DC production of IL-12 and IL-10 after stimulation with IFNγ and LPS or LPS alone, respectively. We found that AdCV-DC and AdCCL-21-DC maintained the capacity to secrete IL-12 with decreased production of IL-10 (Figure 5). Secretion of IL-10 was decreased by 40–49% after AdCCL-21 or AdCV transduction.
The ability of DC to capture, process, and present antigens with subsequent activation of CD4+ and CD8+ T lymphocytes makes them ideal adjuvants in immunotherapy approaches to cancer. In animal models, intratumoral injection of AdV transduced DC expressing cytokine genes has generated enhanced anti-tumor effects compared with NTDC or DC transduced with control vector [17, 20–23]. We have characterized DC following transduction with an adenoviral vector expressing the CCL-21 gene. At the MOIs evaluated, DC maintained their immature phenotype without significantly up-regulating CD83 or CCR7 expression. Our findings that the DC expression of CD86 is increased following adenoviral transduction is consistent with prior reports [19, 40, 41]. These results suggest that DC transduced with adenovirus will have improved costimulatory capacities. In addition, supernatant from AdCCL-21-DC augmented the chemoattraction of peripheral blood lymphocytes and LPS-stimulated DC when compared to migration to supernatants from non-transduced DC or DC transduced with control adenoviral vector. These studies demonstrate that AdCCL-21 transduction of monocyte-derived DC yield cells with enhanced capacity to attract PBL and APCs. Thus, intratumoral administration of gene modified DC to express CCL-21 may prove to be an effective strategy of immunotherapy for achieving tumor antigen presentation utilizing the tumor as an in vivo source of antigen for DC .
CCL-21 recruits both T lymphocytes and antigen-stimulated DC into T cell zones of secondary lymphoid organs. This creates a convergence of the immune response elements to sites of CCL-21 production, resulting in T cell activation and antitumor effects [26, 36]. CCL-21 acts through CCR7, a chemokine receptor belonging to a subfamily of G protein-coupled seven-transmembrane receptors . CCR7 is integral in mediating the homing of DC and naïve and activated T lymphocytes to secondary lymphoid organs. This creates an environment in which co-localization of T cells and mature antigen-loaded DC can occur .
We found that intratumoral injection of murine AdCCL-21-DC was effective in eradicating established tumors and promoting long-term anti-tumor immunity in a murine lung cancer model . We have developed the use of intratumoral administration of DC that have been modified with cytokine genes ex vivo, and this approach achieves tumor antigen presentation by utilizing the tumor as an in vivo source of antigen for DC . In contrast to in vitro immunization with purified peptide antigen, autologous tumor has the capacity to provide the DC administered at the tumor site access to the entire repertoire of available antigens in situ. This may increase the likelihood of a response and reduce the potential for tumor resistance due to phenotypic modulation.
Increased IL-10 at the tumor site has been reported to suppress immune responses [44, 45]. Our finding that transduction of DC with AdCV or AdCCL-21 resulted in decreased IL-10 production while maintaining IL-12 secretion when compared to non-transduced DC, is consistent with an overall immunostimulatory effect of the adenovirus upon transduction of DC . The ability to polarize the immune response to a Th1 phenotype may potentiate the antitumor immune response seen with intratumoral injection of AdCCL-21-DC.
Our investigations have revealed that the transduced DC maintain their immature phenotype. This has important implications for its use as a potential intratumoral therapy in cancer because immature DC are efficient in antigen uptake. Following antigen capture, DC mature and develop improved migration, antigen presentation, and T cell stimulation . Mature DC are potent APCs, expressing high levels of MHC class II, adhesion, and costimulatory molecules on their surface. Surface expression of CCR7 is also enhanced and mature DC thus gain the capacity to respond to CCL-21 [47, 48]. Clinical trials employing mature DC injected by subcutaneous and intranodal routes have suggested that these cells may be effective in eliciting T cell responses [49–51]. Our approach involves the transduction of immature DC with AdCCL-21 to stimulate the migration of mature DC and T lymphocytes to the site of injection. We propose that introducing immature DC to the site of tumor will create the optimal environment for effective antigen uptake, using the tumor as an in vivo source of antigen [17, 23]. CCL-21 expression could then promote movement of mature DC and Th1 lymphocytes to the site of tumor for potential cross-presentation and activation of T cells for potent anti-tumor immune responses.
AdCCL-21-DC may potentiate the induction of anti-tumor immune responses by augmenting antigen presentation and T lymphocyte activation. Thus, in this system the transferred DC expressing CCL-21 may act to enhance the generation of anti-tumor immunity because the tumor can serve as the in vivo source of antigen for DC. Our results demonstrate that AdCCL-21-DC generate biologically functional levels of CCL-21 without impairing DC phenotype. This data, revealing the biological activity of AdCCL-21-DC, paired with our results of intratumoral injection of AdCCL-21-DC in murine lung cancer models , supports further investigation of this approach as a novel genetic immunotherapy for cancer treatment.
Preparation of adenoviral vector expressing human CCL-21
The adenoviral construct (AdCCL-21) is an E1-deleted, replication-deficient adenoviral serotype 5 vector encoding a 491 bp-containing human CCL-21 cDNA (Figure 6). The coding sequence 59–453, was amplified by PCR with the following primers: 5' primer 5'-CTTGCAGCTGCCCACCTCAC (1–20) and 3' primer 5'-TCTCCAGGGCTCCAGGCT-GC-3 (491-472). The CCL-21 gene was amplified and cloned into pAC-CMVpLpA (originally cloned by Dr. R. Gerard, and was acquired from Dr. J. Economou at UCLA, Los Angeles, CA) to generate pAC-CMV-CCL-21pA. pAC-CMV-CCL-21pA was co-transfected with pJM-17 (plasmid containing the E1-deleted Ad-genome, obtained from Dr. J. Economou) into 293 cells (American Type Culture Collection [ATCC] Manassas, VA) to yield recombinant E1-deleted adenovirus (AdCCL-21) following homologous recombination. The control vector (AdCV) did not contain the CCL-21 cDNA insert. Clones of AdCCL-21 and AdCV were obtained by limiting dilution analysis of the ability of the medium to induce a cytopathic effect on fresh 293 cells. Clones were confirmed by CCL-21 specific ELISA. Viral stocks were then obtained by amplification of the 293 cells followed by CsCl purification, dialysis, and storage as a glycerol (10% volume/volume) stock at -80°C. The titer of each viral stock was routinely 1011–1012 plaque forming units by plaque assay on 293 cells. Contamination with wild type recombinant adenovirus was assessed for each viral stock by plaque assay on Hela cells and was consistently negative.
Generation of dendritic cells
The use of leukocyte-enriched buffy coat from healthy donors was approved by the UCLA IRB, and informed consent was obtained from all donors. Peripheral blood mononuclear cells (PBMC) were obtained from leukocyte-enriched buffy coat from healthy donors by centrifugation with Ficoll-Paque™ Plus (Amersham Biosciences, Uppsala, Sweden) and the light density fraction from the 42.5–50% interface was recovered. The cells were resuspended at 2 × 106 cells/ml in RPMI 1640 supplemented with 20 mM HEPES buffer (Cellgro, Mediatech, Herdon, VA), 100 units/ml Penicillin-Streptomycin, and 2 mM glutamine (Invitrogen, Carlsbad, CA). The cells were allowed to adhere to tissue culture flasks for 2 hours at 37°C. After incubation, the non-adherent cells were removed, and adherent cells were washed twice in Dulbecco's PBS without Ca2+ and Mg2+(Cellgro). Cells were then cultured for 6 days in complete RPMI medium with 10% human AB serum (Gemini Bio-Products, Woodlands, CA), recombinant human GM-CSF (75 ng/ml), (Peprotech Inc., Rocky Hill, NY, specific activity ≥ 1 × 107 units/mg) and recombinant human IL-4 (75 ng/ml) (Peprotech Inc., specific activity ≥ 5 × 106 units/mg). Cytokines were added every 2–3 days during culture.
Adenoviral transduction of human DC
Monocyte-derived DC were transduced with human AdCCL-21 or AdCV expression vectors on day 6 of culture either by the standard method of incubation at 37° for 2 hours or by centrifugation method as previously described [38, 39]. Briefly 1.0 × 106 DC, resuspended in 300 μl DPBS (Invitrogen, Carlsbad, CA) containing Ad-CCL-21 or AdCV at various MOIs (from 5:1 to 10,000:1) were incubated at 37°C for 2 hours or centrifuged at 2000 × g at 37°C for two hours (Microfuge Eppendorf 5415R, Fisher Scientific, Pittsburgh, PA). NTDC, AdCCL-21-DC and AdCV-DC were then washed twice, resuspended in complete medium and incubated at 37°C for 24 to 192 hours. The cumulative CCL-21 protein production was measured daily up to 8 days following transduction.
Immunophenotypic analysis and cell viability by flow cytometry
DC, AdCCL-21-DC, and AdCV-DC were characterized by flow cytometry on day 8 of culture. The following panel of monoclonal antibodies was used: HLA-DR-FITC (fluorescein isothiocyanin), CD40-PE (phycoerytrin), CD80-PE, CD86-PE, HLA-DR-FITC (BD Biosciences PharMingen, San Diego, CA), and CD83-FITC (Coulter Immunology, Hialeah, FL). All antibodies were used with appropriate isotype controls (BD Biosciences, La Jolla, CA). Evaluation of CCR7 surface expression was performed by a double step staining method using purified anti-human CCR7 (BD Biosciences PharMingen) followed by biotin-streptavidin staining. Briefly, DC were first labeled with purified mouse anti-human CCR7 monoclonal antibody for 30 minutes at room temperature. Cells were washed twice in FACS buffer (PBS, 2% FBS) and incubated with a biotin-conjugated rat anti-mouse IgM monoclonal antibody (BD PharMingen). After two washes in FACS buffer cells were stained with streptavidin PE (BD PharMingen). Viability of the cells was measured using 7-Amino-Actinomycin-D (7-AAD) (Calbiochem, San Diego, CA). A live gate was set by forward and side scatter and 7-AAD staining. 10,000 cells with high forward scatter and high side scatter were counted. Events were acquired by FACS using a LSR flow cytometer (Becton, Dickenson, and Co. Biosciences Immunocytometry System, San Jose, CA) in the University of California, Los Angeles, Jonsson Comprehensive Cancer Center Flow Cytometry Core Facility. Data analysis was performed by CELLQuest software.
CCL-21 protein concentration from NTDC, AdCCL-21-DC and AdCV-DC supernatant was determined by CCl-21-specific ELISA. Briefly, 96-well Costar (Cambridge, MA) plates were coated overnight with 2 μg/ml of anti-CCL-21 monoclonal antibody (Peprotech Inc., Rocky Hill, NY). After four washes in PBS-0.05% Tween-20, the unbound material was removed and the plate was incubated with a blocking buffer (10% fetal bovine serum, Gemini Bioproducts, Woodlands, CA) in PBS for 30 minutes. After four washes, the plate was incubated with CCL-21 standard or with the sample supernatant for one hour and excess antigen was washed off with PBS/Tween. The plate was then incubated with avidin-conjugated to horseradish-peroxidase for 20 minutes in the dark. After washing to remove all unbound reagents, the plate was incubated with a substrate solution for 20 minutes in the dark. Reactions were stopped by adding 1-M sulfuric acid and the optical density was read at 450 nm in a microplate reader (Molecular Dynamics, Sunnyvale, CA). The sensitivity of the CCl-21 assay was 156 pg/ml.
The biological function of supernatant derived from AdCCL-21-DC, AdCV-DC and NTDC was assessed in a standard chemotaxis assay. We measured the migration of PBL through a 24-well transwell plate fitted with 3 μm polycarbonate membrane inserts. 2 × 105 freshly isolated PBL by Ficoll-Paque density-gradient separation were labeled with 5 μm cell tracker™ green 5-chloromethylfluorescein diacetate (CMFDA, Molecular Probes Inc., Eugene, OR) for 45 minutes, washed and loaded in the upper chamber of the transwell plate in 100 μl serum-free medium. 500 μl of supernatant from 106 AdCCL-21-DC, AdCV-DC and NTDC were added to the lower chamber. 10% AB medium and 100 ng/ml recombinant CCL-21 (R&D Systems, Minneapolis, MN) were used as negative and positive controls, respectively. Cells were incubated for 2 hours at 37°C. The migrated cells were recovered from the lower chamber, centrifuged, and transferred into a 96-well flat-bottomed plate (Costar). Total cell migration was determined by measuring optical density (OD) of migrated cells using Wallac 1420 (Perkin Elmer, Boston, MA) fluorescent plate reader set at excitation/emission wavelengths of 485/530 nm.
Chemotaxis blocking assay
Chemotaxis blocking assays were performed using QCM™ chemotaxis 96-well plates fitted with 3 μm membrane inserts (Chemicon International, Inc., Temecula, CA) according to the manufacturers instructions. Briefly, 2 × 10 5 cells/ml T2 cells (a gift from Dr. J. Economou, David Geffen School of Medicine at UCLA, Los Angeles, CA), were resuspended in serum-free medium and loaded in the upper chamber of a QCM™ apparatus. 150 μl of supernatant derived from AdCCL-21-DC were pre-incubated with neutralizing concentrations of anti-CCL-21 antibody (R&D Systems) or Chrompure goat IgG whole molecule as the control antibody (Jackson Immunoresearch, Westgrove, PA) for 30 minutes at room temperature. Similarly 100–600 ng/ml recombinant CCL-21 was pre-incubated with 4–8 μg/ml anti-CCL-21 or control antibody. The neutralizing concentration of anti-CCL-21 antibody (R&D Systems) used in these studies (4 μg/ml and 8 μg/ml) was based on the ND50 (50% maximum inhibition of cytokine activity when CCL-21 is present at a concentration high enough to elicit maximum response) of goat anti-human CCL-21 as reported by the manufacturer (4 – 8 μg/ml anti-CCL-21 with 500 ng/ml rCCL-21). The pre-incubated samples were then added to the lower chamber of the QCM™ apparatus. In addition, 150 μl of supernatant without antibody from AdCCL-21-DC, 10% AB medium or 100–600 ng/ml recombinant CCL-21 (R & D Systems) were added to the lower chambers as chemotaxis controls. After 2 hours incubation at 37°C migrated cells were recovered from the lower chamber and from the inserts according to the manufacturer's instructions. Cells were lysed and stained with a green fluorescent dye (CyQuant GR dye, Molecular Probes) for 15 minutes at room temperature. Cells were transferred to a 96-well flat-bottomed ELISA microplate (Costar) and fluorescence was read at 480/525 nm using Wallac 1420 fluorescent plate reader (Perkin Elmer).
IL-10 and IL-12p70 ELISA
To induce IL-12 production, (1.0 × 105) AdCCL21-DC, AdCV-DC and control DC were primed with 50 ng/ml γ-IFN (Peprotech Inc.) for 2 hours and then stimulated with 1 μg/ml LPS (Sigma) for 48 hours. To induce IL-10 production, (1.0 × 105) AdCCL21-DC, AdCV-DC and control DC were stimulated with 1 μg/ml LPS for 48 hours. IL-12 p70 and IL-10 concentrations were measured in the supernatant of either unstimulated or stimulated DC by specific ELISA as previously described . For detection of IL-12p70, antibodies and standards were purchased from R&D Systems Inc. For detection of IL-10, antibodies and standards were obtained from BD Biosciences. The sensitivity of the ELISA for IL-12 p70 and IL-10 was < 1 pg/ml.
The unpaired two-tailed Student's t test was used to compare differences in DC and AdCCL-21-DC groups. P-values = 0.05 were considered significant.
Author 1 KR and Author 2 FB contributed equally to this research. KR and FB coordinated and carried out all the experiments. Authors SCY, JL, RB, and RF contributed to the discussion of the article. Author FB together with KR performed the statistical analyses. Authors RS, SS, and SD together with KR and FB conceived of the study, participated in its design, and drafted the manuscript.
All authors read and approved the final manuscript.
- The abbreviations used are:
DC, dendritic cells
secondary lymphoid tissue chemokine
granulocyte macrophage colony-stimulating factor
multiplicity of infection
antigen presenting cell
major histocompatibility complex
peripheral blood lymphocyte
peripheral blood mononuclear cell
fluorescence-activated cell scanner
human leukocyte antigen.
Huang A, Golumbek P, Ahmadzadeh M, Jaffee E, Pardoll D, Levitsky H: Role of bone marrow-derived cells in presenting MHC class I-restricted tumor antigens. Science. 1994, 264: 961-965.
Restifo N, Esquivel F, Kawakami Y, Yewdell J, Mule J, Rosenberg S, Bennink J: Identification of human cancers deficient in antigen processing. J Exp Med. 1993, 177: 265-272.
Banchereau J, Steinman R: Dendritic cells and the control of immunity. Nature. 1998, 392: 245-252. 10.1038/32588
Timmerman J, Levy R: Dendritic cell vaccines for cancer immunotherapy. Annu Rev Med. 1999, 50: 507-529. 10.1146/annurev.med.50.1.507
Mukherji B, Chakraborty N, Yamasaki S, Okino T, Yamase H, Sporn J, Kurtzman S, Ergin M, Ozols J, Meehan J: Induction of antigen-specific cytolytic T cells in situ in human melanoma by immunization with synthetic peptide-pulsed autologous antigen presenting cells. Proc Natl Acad Sci USA. 1995, 92: 8078-8082.
Murphy G, Tjoa B, Simmons S, Ragde H, Rogers M, Elgamal A, Kenny G, Troychak M, Salgaller M, Boynton A: Phase II prostate cancer vaccine trial: report of a study involving 37 patients with disease recurrence following primary treatment. Prostate. 1999, 39: 5459-10.1002/(SICI)1097-0045(19990401)39:1<54::AID-PROS9>3.3.CO;2-L.
Lodge P, Jones L, Bader R, Murphy G, Salgaller M: Dendritic cell-based immunotherapy of prostate cancer: immune monitoring of a phase II clinical trial. Cancer Res. 2000, 60: 829-833.
Nestle F, Alijagic S, Gilliet M, Sun Y, Grabbe S, Dummer R, Burg G, Schadendorf D: Vaccination of melanoma patients with peptide- or tumor lysate-pulsed dendritic cells. Nat Med. 1998, 4: 328-332.
Miller P, Sharma S, Stolina M, Chen K, Zhu L, Paul RW, Dubinett S: Dendritic cells augment granulocyte-macrophage colony-stimulating factor (GM-CSF)/herpes simplex virus thymidine kinase-mediated gene therapy of lung cancer. Cancer Gene Ther. 1998, 5: 380-389.
Sharma S, Miller P, Stolina M, Zhu L, Huang M, Paul R, Dubinett S: Multi-component gene therapy vaccines for lung cancer: effective eradication of established murine tumors in vivo with Interleukin 7 / Herpes Simplex Thymidine Kinase-transduced autologous tumor and ex vivo-activated dendritic cells. Gene Therapy. 1997, 4: 1361-1370. 10.1038/sj.gt.3300531
Mayordomo J, Loftus D, Sakamoto H, De Cesare C, Appasamy P, Lotze M, Storkus W, Appella E, DeLeo A: Therapy of murine tumors with p53 wild-type and mutant sequence peptide-based vaccines. J Exp Med. 1996, 183: 1357-1365.
Henderson R, Nimgaonkar M, Watkins S, Robbins P, Ball E, Finn O: Human dendritic cells genetically engineered to express high levels of the human epithelial tumor antigen mucin (MUC-1). Cancer Res. 1996, 56: 3763-3770.
Ribas A, Butterfield L, McBride W, Jilani S, Bui L, Vollmer C, Lau R, Dissette V, Hu B, Chen A, Glaspy J, Economou J: Genetic immunization for the melanoma antigen MART-1/Melan-A using recombinant adenovirus-transduced murine dendritic cells. Cancer Res. 1997, 57: 2865-2869.
Ribas A, Bui L, Butterfield L, Vollmer C, Jilani S, Dissette V, Glaspy J, McBride W, Economou J: Antitumor protection using murine dendritic cells pulsed with acid-eluted peptides from in vivo grown tumors of different immunogenicities. Anticancer Res. 1999, 19: 1165-1170.
Celluzzi C, Falo L: Cutting edge: Physical interaction between dendritic cells and tumor cells result in an immunogen that induces protective and therapeutic tumor rejection. J Immunol. 1998, 160: 3081-3085.
Cao X, Zhang W, He L, Xie Z, Ma S, Tao Q, Yu Y, Hamada H, Wang J: Lymphotactin gene-modified bone marrow dendritic cells act as more potent adjuvants for peptide delivery to induce specific antitumor immunity. J Immunol. 1998, 161: 6238-6244.
Miller P, Sharma S, Stolina M, Butterfield L, Luo J, Lin Y, Dohadwala M, Batra R, Wu L, Economou J, Dubinett S: Intratumoral administration of adenoviral interleukin 7 gene-modified dendritic cells augments specific antitumor immunity and achieves tumor eradication. Hum Gene Ther. 2000, 11: 53-65. 10.1089/10430340050016157
Lundqvist A, Choudhury A, Nagata T, Andersson T, Quinn G, Fong T, Maitland N, Pettersson S, Paulie S, Pisa P: Recombinant adenovirus vector activates and protects human monocyte-derived dendritic cells from apoptosis. Hum Gene Ther. 2002, 13: 1541-1549. 10.1089/10430340260201635
Miller G, Lahrs S, Pillarisetty V, Shah A, DeMatteo R: Adenovirus infection enhances dendritic cell immunostimulatory properties and induces natural killer and T-cell-mediated tumor protection. Cancer Res. 2002, 62: 5260-5266.
Kirk C, Hartigan-O'Connor D, Nickoloff B, Chamberlain J, Giedlin M, Aukerman L, Mule J: T cell-dependent antitumor immunity mediated by secondary lymphoid tissue chemokine: augmentation of dendritic cell-based immunotherapy. Cancer Res. 2001, 61: 2062-2070.
Kirk C, Hartigan-O'Connor D, Mule J: The Dynamics of the T-Cell Antitumor Response: Chemokine-secreting Dendritic Cells Can Prime Tumor-reactive T Cells Extranodally. Cancer Res. 2001, 61: 8794-8802.
Nishioka Y, Hirao M, Robbins P, Lotze M, Tahara H: Induction of systemic and therapeutic antitumor immunity using intratumoral injection of dendritic cells genetically modified to express interleukin 12. Cancer Res. 1999, 59: 4035-4041.
Riedl K, Baratelli F, Yang S, Luo J, Escuadro B, Batra R, Figlin R, Strieter R, Sharma S, Dubinett S: Characterization of adenoviral CCL21/SLC for intratumoral dendritic cell (DC) based therapies in NSCLC [Abstract 1834]. Proc AACR. 2003, 44: 417-
Rollins B: Chemokines. Blood. 1997, 90: 909-928.
Baggiolini M, Dewald B, Moser B: Human chemokines: an update. Annu Rev Immunol. 1997, 15: 675-705. 10.1146/annurev.immunol.15.1.675
Cyster J: Chemokines and the Homing of Dendritic Cells to the T Cell Areas of Lymphoid Organs. J Exp Med. 1999, 189: 447-450. 10.1084/jem.189.3.447
Ogata M, Zhang Y, Wang Y, Itakura M, Zhang Y, Harada A, Hashimoto S, Matsushima K: Chemotactic Response Toward Chemokines and Its Regulation by Transforming Growth Factor-beta1 of Murine Bone Marrow Hematopoietic Progenitor Cell-Derived Different Subset of Dendritic Cells. Blood. 1999, 93: 3225-3232.
Chan V, Kothakota S, Rohan M, Panganiban-Lustan L, Gardner J, Wachowicz J, Winter M, Williams L: Secondary lymphoid-tissue chemokine (SLC) is chemotactic for mature dendritic cells. Blood. 1999, 93: 3610-3616.
Hedrick J, Zlotnik A: Identification and characterization of a novel beta chemokine containing six conserved cysteines. J Immunol. 1997, 159: 1589-1593.
Hromas R, Kim C, Klemsz M, Krathwohl M, Fife K, Cooper S, Schnizlein-Bick C, Broxmeyer H: Isolation and characterization of Exodus-2, a novel C-C chemokine with a unique 37-amino acid carboxyl-terminal extension. J Immunol. 1997, 159: 2554-2558.
Nagira M, Imai T, Hieshima K, Kusuda J, Ridanpaa M, Takagi S, Nishimura M, Kakizaki M, Nomiyama H, Yoshie O: Molecular cloning of a novel human CC chemokine secondary lymphoid-tissue chemokine that is a potent chemoattractant for lymphocytes and mapped to chromosome 9p13. J Biol Chem. 1997, 272: 19518-19524. 10.1074/jbc.272.31.19518
Tanabe S, Lu Z, Luo Y, Quackenbush E, Berman M, Collins-Racie L, Mi S, Reilly C, Lo D, Jacobs K, Dorf M: Identification of a new mouse beta-chemokine, thymus-derived chemotactic agent 4, with activity on T lymphocytes and mesangial cells. J Immunol. 1997, 159: 5671-5679.
Willimann K, Legler D, Loetscher M, Roos R, Delgado M, Clark-Lewis I, Baggiolini M, Moser B: The chemokine SLC is expressed in T cell areas of lymph nodes and mucosal lymphoid tissues and attracts activated T cells via CCR7. Eur J Immunol. 1998, 28: 2025-2034. 10.1002/(SICI)1521-4141(199806)28:06<2025::AID-IMMU2025>3.0.CO;2-C
Gunn M, Kyuwa S, Tam C, Kakiuchi T, Matsuzawa A, Williams L, Nakano H: Mice lacking expression of secondary lymphoid organ chemokine have defects in lymphocyte homing and dendritic cell localization. J Exp Med. 1999, 189: 451-460. 10.1084/jem.189.3.451
Soto H, Wang W, Strieter R, Copeland N, Gilbert D, Jenkins N, Hedrick J, Zlotnik A: The CC chemokine 6Ckine binds the CXC chemokine receptor CXCR3. Proc Natl Acad Sci U S A. 1998, 95: 8205-8210.
Sharma S, Stolina M, Luo J, Strieter R, Burdick M, Zhu L, Batra R, Dubinett S: Secondary lymphoid tissue chemokine mediates T cell-dependent antitumor responses in vivo. J Immunol. 2000, 164: 4558-4563.
Sharma S, Stolina M, Zhu L, Lin Y, Batra R, Huang M, Strieter R, Dubinett S: Secondary lymphoid organ chemokine reduces pulmonary tumor burden in spontaneous murine bronchoalveolar cell carcinoma. Cancer Res. 2001, 61: 6406-6412.
Nishimura N, Nishioka Y, Shinohara T, Ogawa H, Yamamoto S, Tani K, Sone S: Novel centrifugal method for simple and highly efficient adenovirus-mediated green fluorescence protein gene transduction into human monocyte-derived dendritic cells. J Immunol Methods. 2001, 253: 113-124. 10.1016/S0022-1759(01)00360-X
Nishimura N, Nishioka Y, Shinohara T, Sone S: Enhanced efficiency by centrifugal manipulation of adenovirus-mediated interleukin 12 gene transduction into human monocyte-derived dendritic cells. Hum Gene Ther. 2001, 12: 333-346. 10.1089/10430340150503966
Hirschowitz E, Weaver J, Hidalgo G, Doherty D: Murine dendritic cells infected with adenovirus vectors show signs of activation. Gene Ther. 2000, 7: 1112-1120. 10.1038/sj.gt.3301210
Morelli A, Larregina A, Ganster R, Zahorchak A, Plowey J, Takayama T, Logar A, Robbins P, Falo L, Thomson A: Recombinant adenovirus induces maturation of dendritic cells via an NF-kappaB-dependent pathway. J Virol. 2000, 74: 9617-9628. 10.1128/JVI.74.20.9617-9628.2000
Christopherson K, Campbell J, Hromas R: Transgenic overexpression of the CC chemokine CCL21 disrupts T-cell migration. Blood. 2001, 98: 3562-3568. 10.1182/blood.V98.13.3562
Forster R, Schubel A, Breitfeld D, Kremmer E, Renner-Muller I, Wolf E, Lipp M: CCR7 coordinates the primary immune response by establishing functional microenvironments in secondary lymphoid organs. Cell. 1999, 99: 23-33.
Huang M, Stolina M, Sharma S, Mao J, Zhu L, Miller P, Wollman J, Herschman H, Dubinett S: Non-small cell lung cancer cyclooxygenase-2-dependent regulation of cytokine balance in lymphocytes and macrophages: up-regulation of interleukin 10 and down-regulation of interleukin 12 production. Cancer Res. 1998, 58: 1208-1216.
Bellone G, Turletti A, Artusio E, Mareschi K, Carbone A, Tibaudi D, Robecchi A, Emanuelli G, Rodeck U: Tumor-associated transforming growth factor-beta and interleukin-10 contribute to a systemic Th2 immune phenotype in pancreatic carcinoma patients. Am J Pathol. 1999, 155: 537-547.
Banchereau J, Briere F, Caux C, Davoust J, Lebecque S, Liu Y, Pulendran B, Palucka K: Immunobiology of dendritic cells. Annu Rev Immunol. 2000, 18: 767-811. 10.1146/annurev.immunol.18.1.767
Sallusto F, Schaerli P, Loetscher P, Schaniel C, Lenig D, Mackay C, Qin S, Lanzavecchia A: Rapid and coordinated switch in chemokine receptor expression during dendritic cell maturation. Eur J Immunol. 1998, 28: 2760-2769. 10.1002/(SICI)1521-4141(199809)28:09<2760::AID-IMMU2760>3.0.CO;2-N
Kellermann S, Hudak S, Oldham E, Liu Y, McEvoy L: The CC chemokine receptor-7 ligands 6Ckine and macrophage inflammatory protein-3 beta are potent chemoattractants for in vitro- and in vivo-derived dendritic cells. J Immunol. 1999, 162: 3859-3864.
Rieser C, Ramoner R, Holtl L, Rogatsch H, Papesh C, Stenzl A, Bartsch G, Thurnher M: Mature dendritic cells induce T-helper type-1-dominant immune responses in patients with metastatic renal cell carcinoma. Urol Int. 1999, 63: 151-159. 10.1159/000030438
Schuler-Thurner B, Dieckmann D, Keikavoussi P, Bender A, Maczek C, Jonuleit H, Roder C, Haendle I, Leisgang W, Dunbar R, Cerundolo V, von Den Driesch P, Knop J, Brocker E, Enk A, Kampgen E, Schuler G: Mage-3 and influenza-matrix peptide-specific cytotoxic T cells are inducible in terminal stage HLA-A2.1+ melanoma patients by mature monocyte-derived dendritic cells. J Immunol. 2000, 165: 3492-3496.
Jonuleit H, Giesecke-Tuettenberg A, Tuting T, Thurner-Schuler B, Stuge T, Paragnik L, Kandemir A, Lee P, Schuler G, Knop J, Enk A: A comparison of two types of dendritic cell as adjuvants for the induction of melanoma-specific T-cell responses in humans following intranodal injection. Int J Cancer. 2001, 93: 243-251. 10.1002/ijc.1323
Whittaker D, Bahjat K, Moldawer L, Clare-Salzler M: Autoregulation of human monocyte-derived dendritic cell maturation and IL-12 production by cyclooxygenase-2-mediated prostanoid production. J Immunol. 2000, 165: 4298-4304.
We thank Sandra Tran and Kimberly Atianzar for their assistance in the preparation of this manuscript. Flow cytometry was performed in the UCLA Jonsson Comprehensive Cancer Center and Center for AIDS Research Flow Cytometry Core Facility supported by National Institutes of Health awards CA-16042 and AI-28697, by the Jonsson Cancer Center, the UCLA AIDS Institute and the David Geffen School of Medicine at UCLA.
This work was supported by National Institutes of Health Grant R01 CA78654, CA85686, 1T32HL6699201, The UCLA Lung Cancer SPORE (P50 CA90388), The Research Enhancement Award Program in Cancer Gene Medicine, and the Tobacco-Related Disease Research Program of the University of California.
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Riedl, K., Baratelli, F., Batra, R.K. et al. Overexpression of CCL-21/Secondary Lymphoid Tissue Chemokine in Human Dendritic Cells Augments Chemotactic Activities for Lymphocytes and Antigen Presenting Cells. Mol Cancer 2, 35 (2003) doi:10.1186/1476-4598-2-35
- Dendritic Cell
- Antitumor Immune Response
- Intratumoral Injection
- Immature Dendritic Cell
- Mature Dendritic Cell