Abstract
Dendritic cells (DCs) are the most powerful antigen-presenting cells known to date and play an important role in initiating and amplifying both innate and adaptive immune responses. Extracellular acidosis is an important hallmark of a variety of inflammatory processes and solid tumors. However, few studies have focused on the effect of extracellular acidosis on DCs and their functions. Cellular mechanical properties reflect the relationship between cell structure and function, including cytoskeleton (especially F-actin organization), membrane negative charges, membrane fluidity, and osmotic fragility. The study investigated the effects of extracellular acidosis on the DCs functions from the perspective of cellular migration and mechanical properties. The results showed that migration ability, F-actin contents, and membrane negative charges of DCs were reduced by extracellular acidosis no matter whether LPS stimulated its maturation or not. And these functions could not return to normal after removing acidic microenvironment, which revealed that the function impairment induced by extracellular acidosis might be irreversible. In addition, the proliferation capacity of stimulated allogeneic T cells was impaired by extracellular acidosis. Our results suggest extracellular acidosis may play an immunosuppressive role in DCs-mediated immune process.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
INTRODUCTION
DCs are the most potent antigen-presenting cells that play a crucial role in initiating and amplifying both the innate and adaptive immune responses. Functionally, DCs undergo two stages of differentiation: immature DCs (imDCs) and mature DCs (mDCs). The imDCs reside in non-lymphoid tissues and specifically capture and process foreign antigens. Then, they travel through blood or lymph to secondary lymphoid organs and gradually differentiate to mDCs, physically interacting with naive T cells to initiate immune responses or tolerance [1, 2]. It has been reported that the motility and immune functions of DCs have deteriorated in numerous inflammatory diseases and tumors [3,4,5].
Extracellular acidosis (or acidic microenvironment) is a significant hallmark of various inflammatory processes and solid tumors. The potential of hydrogen (pH) is an important physiological indicator of homeostasis in vivo, which usually ranges from pH 7.2 to 7.4 in the physiological state. However, interstitial acidification is commonly associated with the development of inflammatory reactions against pathogens in peripheral tissues, ranging from pH 5.5 to 7.0 [6,7,8]. Autoimmune processes such as rheumatoid arthritis and asthma are also associated with lower pH in injured tissues compared with normal tissues [9, 10]. In addition, observations made in solid tumors such as breast cancer, malignant melanomas, squamous cell carcinomas, brain tumors, adenocarcinomas, and sarcomas showed that tumor microenvironments reach pH ranging from 5.8 to 7.4 [6]. Importantly, low pH has been shown to favor cancer progression by promoting local tumor invasion and distant metastatic spread [11]. Nowadays, different strategies have been explored to utilize the relative acidity of tumor versus normal tissue in order to enhance the efficacy of antitumor therapy [12, 13].
Although the acidic microenvironment is a common and significant feature in a variety of inflammatory processes and tumors, few studies analyze effect of extracellular acidosis on immune cells, especially DCs. There were only two reports about effects of extracellular acidosis on the functions of murine bone marrow–derived DCs, and the results showed that acidification of the culture medium to pH 6.5 enhanced the endocytosis and expression of cell surface proteins involved in Ag presentation of DCs. This effect appears to be mediated by acid-sensing ion channels, which represent a family of Na+ channel and are activated by extracellular protons [14, 15].
Cellular mechanical properties reflect the relationship between cell structure and function, including cytoskeleton organization, membrane negative charges, membrane fluidity, osmotic fragility, and etc. The motility and mechanical properties of DCs are closely related to the immunological function such as antigen presentation and stimulation of T cells [16,17,18,19]. Hence, the study investigated the effects of extracellular acidosis on the DCs functions from the perspective of cellular motility and mechanical properties. Because imDCs capture and process antigens in peripheral tissues, and considering that many inflammatory processes as well as the growth of multiple tumors lead to the development of the acidic microenvironment in peripheral tissues, we examined the impact of extracellular acidosis on the function of DCs based on the following aspects in the study: (1) effect of extracellular acidosis on imDCs and their maturation process. (2) The functional changes after DCs migrate out of the acidic microenvironment. Our results show that extracellular acidosis reduces the migration, F-actin contents, and membrane negative charges of DCs, but has no effect on its membrane fluidity and osmotic fragility (data not shown). These results help us better understand the immune regulatory function of DCs and provide important information for preventing various inflammations and tumors.
MATERIALS AND METHODS
Animals
The 6–8-week-old C57BL/6 mice were purchased from the Animal Experiment Center of Guizhou Medical University. They were housed under specific pathogen-free conditions and kept at 22 ± 2 °C. Animal care and treatment were performed in accordance with the Animal Care Welfare Committee of Guizhou Medical University.
DCs Cultures and Treatments
The femurs and tibias obtained from euthanized mice were washed twice with phosphate-buffered saline (PBS). Both ends of the bones were cut with sterile scissors, and then, the marrow was flushed out using RPMI 1640 (Gibco, NY, USA) and filtered into a sterile conical tube (Corning, NY, USA). Subsequently, the liquid was centrifuged for 5 min at 1200 rpm, and then, supernatant was removed and resuspended in red blood cell lysis buffer (Solarbio, Beijing, China) 5 min to lyse red blood cells. After washed twice with PBS, the cells were cultured for 7 days in RPMI1640 medium supplemented with 10% fetal bovine serum (Gibco, NY, USA), 20 ng/ml recombinant murine GM-CSF (PeproTech, Rocky Hill, USA), and 10 ng/ml recombinant murine IL-4 (PeproTech, Rocky Hill, USA) to obtain imDCs. The imDCs were induced with 100 ng/ml lipopolysaccharide (LPS; InvivoGen, Toulouse, France) for 24 h to obtain mDCs.
To study the effects of extracellular acidosis on the migration capacity and mechanical properties of imDCs and their maturation processes, the imDCs were divided into four groups added medium with pH 7.3, pH 6.5, pH 7.3 + LPS, and pH 6.5 + LPS. The medium at pH 7.3 was adjusted to pH 6.5 by addition of isotonic HCl. The pH 7.3 and pH 7.3 + LPS groups were used as the control group of pH and pH + LPS group, respectively. The cells from pH 7.3 and pH 6.5 groups were respectively collected at 1 h, 4 h, and 24 h after adding different pH media. The pH 7.3 + LPS and pH 6.5 + LPS group cells were collected only at 24 h after adding different pH and 100 ng/ml LPS media. The collected cells were performed for the experiments on mobility and cellular mechanical properties. To study the functional changes after DCs migrate out of the acidic microenvironment, imDCs were incubated for 4 h at pH 6.5 and then the culture medium was replaced with pH 7.3 or pH 7.3 + LPS. The imDCs were divided into four groups added medium with pH 7.3, pH 6.5 → 7.3, pH 7.3 + LPS, and pH 6.5 → 7.3 + LPS, and the similar method as above was used.
Cell Viability Assay
The Counting Kit-8 (CCK-8, Solarbio, Beijing, China) was used to quantify the cell viability. The cells were incubated in a 96-well plate (1 × 104/well) for 24 h and then incubated with 10 μl of CCK-8 solution for 2 h at room temperature. The absorbance was measured spectrophotometrically at 450 nm.
Motility
Transwell system was used to determine the motility of DCs. The cells were placed in the upper Transwell chamber (Corning, NY, USA) with 8.0-μm pores and the lower compartment filled with RPMI 1640 medium. In the LPS-induced group, the medium of lower compartment was supplemented 100 ng/ml CCL19 (BioLegend, San Diego, USA) as chemokine for mDCs. In the pH group, the chemokine was not used. The cells in the lower compartment were collected and the numbers were counted using a cell counting plate. The ratio of the counted numbers to the initial adding amount represents the migration percentage. Three repeated experiments were performed for standard deviation (SD) analyses.
Confocal Laser Scanning Microscopy Analysis
The cells were immobilized on the coverslips coated with poly-l-lysine (Solarbio, Beijing, China) for 30 min and fixed with 4% paraformaldehyde (Solarbio, Beijing, China). After permeabilization with 0.1% Triton X-100 (Solarbio, Beijing, China), DCs were incubated with PBS containing 1% bovine serum albumin (Solarbio, Beijing, China) for 30 min. Subsequently, the cells were stained with 2 U rhodamine phalloidin (Solarbio, Beijing, China) in the dark for 20 min, followed by staining with 4,6-diamidino-2-phenylindole (Solarbio, Beijing, China) in dark for 5 min. Then, the coverslips were mounted with antifade medium (Solarbio, Beijing, China) on glass slides and the cells were imaged by confocal laser scanning microscopy (FV1000, Olympus, Tokyo, Japan). The 3-dimensional images were reconstructed with the software function of Olympus. The F-actin contents were quantified by measuring the mean fluorescent intensities using the ImageJ software. Three repeated experiments were performed and about six cells from each group were randomly selected for analyses in each experiment.
Electrophoretic Mobility
The collected cells were adjusted to 2 × 106/mL with 9% (w/v) sucrose solution. The electrophoretic mobility (EPM) was examined by a cell electrophoresis meter (WD-9408E, Liuyi Biotechnology, Beijing, China) at 30 °C. Ten cells were randomly selected for each group and three repeated experiments were performed to obtain the means.
Mixed Leukocyte Reaction
The mixed leukocyte reaction (MLR) assay was performed to measure the immune stimulatory capabilities of mDCs. Allogeneic T cells were obtained from the murine spleen through the nylon wool columns (Corning, NY, USA). A total of 2 × 105 T cells were cultured with the same number of DCs incubated at 37 °C with 5% CO2 for 48 h, and then subjected to CCK-8 analysis as described above.
Statistical Analysis
The mean and SD from the three repeated experiments were calculated. Student’s t test was used to compare the two means using Microsoft Excel. Differences were considered to be significant at p < 0.05 and to be highly significant at p < 0.01.
RESULTS
The pH 6.5 Treatment Did Not Affect DCs Viability
The cell viability is closely related to its function. So far, all of the studies on the regulation of DCs function by extracellular acidosis use pH 6.5 as the treatment condition and have achieved remarkable results [13]. In the study, our results showed that the DCs viability was not affected after treated with pH 6.5 (Fig. 1). Therefore, pH 6.5 was selected to study the effect of extracellular acidosis on DCs function in the experiment.
Extracellular Acidosis Reduced the Motility
Excellent motility of DCs is crucial for their performing immune functions, including antigen-uptaking in peripheral tissues and acquiring antigen presentation in lymph nodes [2]. The results showed that the migration capability of DCs was markedly diminished in the acidic microenvironment (Fig. 2a). Tong et al. have reported that exposure to pH 6.5 for 4 h resulted in a significant difference of DCs immune function [14]. Therefore, DCs were incubated at pH 7.3 after exposure to pH 6.5 for 4 h to simulate the process of DCs that migrate out of the acidic microenvironment to the lymph node. Our data revealed that the DCs mobility also was impaired after leaving the acidic microenvironment (Fig. 2b).
Extracellular Acidosis Damaged the F-Actin Structure
The cytoskeleton of eukaryotic cells is a network structure system composed of protein fibers, mainly including microfilaments, microtubules, and intermediate fibers. Microfilaments composed of F-actin mainly control cell plasticity and migration by generated depolymerization and polymerization [20, 21]. Our result showed that the F-actin contents were significantly reduced by extracellular acidosis (Fig. 3).
Effects of Extracellular Acidosis on EPM
The EPM indicates that the negative charges come from the hydrolysis of sialic acid of glycoprotein located on the surface of cell membrane [19]. The results showed that EPM of DCs was apparently reduced by extracellular acidosis (Fig. 4). That is, the amount of negative charges of DCs was decreased by extracellular acidosis.
Extracellular Acidosis Impaired the Ability of Stimulated T Cell Proliferation
The main function of mDCs is their stimulatory capabilities, which is determined by the primary allogeneic mixed leukocyte reaction (MLR) assay using murine spleen T lymphocytes as responder cells. The imDCs were induced maturation by LPS incubated in pH 7.3 for 24 h after exposed to pH 6.5 for 4 h. The imDCs were incubated at pH 7.3 for 4 h, followed by LPS-induced maturation for 24 h as controls. The results showed that pre-treatment with pH 6.5 significantly impaired the immune stimulatory capabilities of mDCs (Fig. 5), suggesting that the stimulatory function may be impaired after DCs leave the acidic microenvironment to lymph nodes.
DISCUSSION
The study investigated the effect of extracellular acidosis on immune function of DCs from the perspective of cellular motility and mechanical properties. Our data show that extracellular acidosis reduces the migration, F-actin contents, and membrane negative charges of DCs, and these functions cannot return to normal after removing the acidic microenvironment, which reveal that the function impairment induced by extracellular acidosis may be irreversible.
DCs migrate to lymph nodes and activate T cells after acquire antigens to induce immune response. In tumor-bearing hosts, the immune function of the body is impaired. A key reason is the downregulation of DCs motility, which makes DCs fail to migrate to the lymph nodes [22]. The development of acidic microenvironment is a prominent characteristic of multiple solid tumors, which has been proven to play a key role in tumorigenesis and progression [11, 23]. Therefore, it is great significance to know the effect of extracellular acidosis on DCs mobility. In our study, DCs migration was impaired by extracellular acidosis, which may be one of the important reasons why DCs fail to migrate to lymph nodes and immune function was impaired in tumor-bearing hosts.
Dynamic organization of actin cytoskeleton is essential to function of DCs, including antigen capture, deformability, and motility, especially F-actin organization [24, 25]. F-Actin is a filamentous polymer composed of multiple globular actin (G-actin) subunits. The dynamics of the intracellular ratio between F-actin and G-actin are vital for actin remodeling [26, 27]. In our experiment, rhodamine phalloidin was used to specifically labeled F-actin, instead of combining it with G-actin. Our results showed that the F-actin contents of DCs were significantly reduced by extracellular acidosis. Interestingly, it was found that the F-actin content significantly decreased within 1 h, indicating that F-actin may be depolymerized once DCs entered the acidic microenvironment. The data also indicated that the re-polymerized of F-actin was suppressed even if DCs left the acidic microenvironment. F-Actin organization of DCs is closely related to its migration ability. These results suggested that extracellular acidosis was likely to affect DCs migration ability by regulating F-actin polymerization. Further investigations about the relationships among acidic microenvironment, DCs migration, and F-actin organization need to be done.
The electrical properties of cell membrane play an important role in cell-cell and extracellular matrix interactions. The cells of eukaryotic organism have negatively charged surfaces in vivo, which is related to their adhesion to neighboring cells or to solid organic or inorganic surfaces [19]. DCs and T cells must overcome the barrier posed by negatively charged glycocalyx components for direct physical contact during the process of antigen presentation [28]. Here, the results showed that the surface negative charge of DCs was significantly reduced by extracellular acidosis. Fewer negative charges on the surface of DCs could increase the adhesion between DCs and T cells, which might lead to an increased contact time. The different contact times between DCs and T cells induce different immune responses and the longer contact time prime immune tolerance [17, 18]. Thus, the interaction of DCs with T cells might be disturbed by extracellular acidosis through the decrement of negative charges on DC surfaces, which may be responsible for the immune dysfunction mediated by DCs in many inflammatory diseases and tumors.
The stimulatory capability of mDCs is their most important function for immune efficacy. The short-term exposure of imDCs to acid conditions followed by longer periods at a neutral pH and gradual differentiation to mDCs probably reflects what occurs in vivo because the migration of DCs from the periphery to lymph nodes usually demands several hours and occurs at a neutral pH environment [29]. Hence, the maturation of imDCs was induced by LPS incubated in pH 7.3 for 24 h after exposed to pH 6.5 for 4 h and then MLR was performed in our study to simulate the process of DCs in vivo. The results showed that the immune stimulatory capabilities of DCs were impaired by extracellular acidosis. In conclusion, extracellular acidosis may play an immunosuppressive role in DCs-mediated immune process from the perspective of cellular motility and mechanical properties.
References
Santos, P.M., and L.H. Butterfield. 2018. Dendritic cell-based cancer vaccines. The Journal of Immunology 200: 443–449.
Eisenbarth, S.C. 2019. Dendritic cell subsets in T cell programming: location dictates function. Nature Reviews Immunology 19: 89–103.
Worbs, T., S.I. Hammerschmidt, and R. Förster. 2017. Dendritic cell migration in health and disease. Nature Reviews Immunology 17: 30–48.
Lee, J.H., S.Y. Choi, N.C. Jung, J.Y. Song, H.G. Seo, H.S. Lee, and D.S. Lim. 2020. The effect of the tumor microenvironment and tumor-derived metabolites on dendritic cell function. Journal of Cancer 11: 769–775.
Qian, C., and X. Cao. 2018. Dendritic cells in the regulation of immunity and inflammation. Seminars in Immunology 35: 3–11.
Erra Díaz, F., E. Dantas, and J. Geffner. 2018. Unravelling the interplay between extracellular acidosis and immune cells. Mediators of Inflammation 2018: 1–11.
De Nadai, T.R., M.N. De Nadai, A.A.S. Albuquerque, M.T. de Carvalho, A.C. Celotto, and P.R. Evora. 2013. Metabolic acidosis treatment as part of a strategy to curb inflammation. International Journal of Inflammation 2013: 1–4.
Torres, I.M., Y.R. Patankar, T.B. Shabaneh, E. Dolben, D.A. Hogan, D.A. Leib, and B.L. Berwin. 2014. Acidosis potentiates the host proinflammatory interleukin-1β response to pseudomonas aeruginosa infection. American Journal of Physiology-Lung Cellular and Molecular Physiology 82: 4689–4697.
Sluka, K.A., L.A. Rasmussen, M.M. Edgar, J.M. O’Donnell, R.Y. Walder, S.J. Kolker, D.L. Boyle, and G.S. Firestern. 2013. Acid-sensing ion channel 3 deficiency increases inflammation but decreases pain behavior in murine arthritis. Arthritis and Rheumatism 65: 1194–1202.
Zhao, J.J., Y. Shimizu, K. Dobashi, T. Kawata, A. Ono, N. Yanagitani, K. Kaira, M. Utsugi, T. Hisada, T. Ishizuka, and M. Mori. 2008. The relationship between oxidative stress and acid stress in adult patients with mild asthma. Journal of Investigational Allergology and Clinical Immunology 18: 41–45.
Estrella, V., T. Chen, M. Lloyd, J. Wojtkowiak, H.H. Cornnell, A. Ibrahim-Hashim, K. Bailey, Y. Balagurunathan, J.M. Rothberg, B.F. Sloane, J. Johnson, R.A. Gatenby, and R.J. Gillies. 2013. Acidity generated by the tumor microenvironment drives local invasion. Cancer Research 73: 1524–1535.
Pilon-Thomas, S., K.N. Kodumudi, A.E. EI-Kenawi, S. Russell, A.M. Weber, K. Luddy, M. Damaghi, J.W. Wojtkowiak, J.J. Mulé, A. Ibrahim-Hashim, and R.J. Gillies. 2016. Neutralization of tumor acidity improves antitumor responses to immunotherapy. Cancer Research 76: 1381–1390.
Huber, V., C. Camisaschi, A. Berzi, S. Ferro, L. Lugini, T. Triulzi, A. Tuccitto, E. Tagliabue, C. Castelli, and L. Rivoltini. 2017. Cancer acidity: an ultimate frontier of tumor immune escape and a novel target of immunomodulation. Seminars in Cancer Biology 43: 74–89.
Tong, J., W.N. Wu, X. Kong, P.F. Wu, L. Tian, W. Du, M. Fang, F. Zheng, J.G. Chen, Z. Tan, and F. Gong. 2011. Acid-sensing ion channels contribute to the effect of acidosis on the function of dendritic cells. The Journal of Immunology 186: 3686–3692.
Vermeulen, M., M. Giordano, A.S. Trevani, C. Sedlik, R. Gamberale, G. Salamone, P. Fernández-Calotti, S. Raiden, J. Sanjurjo, and J.R. Geffner. 2004. Acidosis improves uptake of antigens and MHC class I-restricted presentation by dendritic cells. The Journal of Immunology 172: 3196–3204.
Jiang, Y., Z. Zeng, D. Sun, W. Ka, and Z. Wen. 2005. Adhesion of monocyte-derived dendritic cells to human umbilical vein endothelial cells in flow field decreases upon maturation. Clinical Hemorheology and Microcirculation 32: 261–268.
Mempel, T.R., S.E. Henrickson, and U.H. Von Andrian. 2004. T-cell priming by dendritic cells in lymph nodes occurs in three distinct phases. Nature 427: 154–159.
Stoll, S., J. Delon, T.M. Brotz, and R.N. Germain. 2002. Dynamic imaging of T cell-dendritic cell interactions in lymph nodes. Science 296: 1873–1876.
Zeng, Z., X. Liu, Y. Jiang, G. Wang, J. Zhan, J. Guo, W. Yao, D. Sun, W. Ka, Y. Tang, J. Tang, Z. Wen, and S. Chien. 2006. Biophysical studies on the differentiation of human CD14+ monocytes into dendritic cells. Cell Biochemistry Biophysics 45: 19–30.
Breitsprecher, D., S.A. Koestler, I. Chizhov, M. Nemethova, J. Mueller, B.L. Goode, J.V. Small, K. Rottner, and J. Faix. 2011. Cofilin cooperates with fascin to disassemble filopodial actin filaments. Journal of Cell Science 124: 3305–3318.
Blanchoin, L., R. Boujemaa-Paterski, C. Sykes, and J. Plastino. 2014. Actin dynamics, architecture, and mechanics in cell motility. Physiological Reviews 94: 235–263.
Seyfizadeh, N., R. Muthuswamy, D.A. Mitchell, S. Nierkens, and N. Seyfizadeh. 2016. Migration of dendritic cells to the lymph nodes and its enhancement to drive anti-tumor responses. Critical Reviews in Oncology Hematology 107: 100–110.
Corbet, C., and O. Feron. 2017. Tumour acidosis: from the passenger to the driver’s seat. Nature Reviews Cancer 17: 577–593.
Yoo, J.Y., N.C. Jung, J.H. Lee, S.Y. Choi, H.J. Choi, S.Y. Park, J.S. Jang, S.H. Byun, S.U. Hwang, K.E. Noh, Y. Park, J. Lee, J.Y. Song, H.G. Seo, H.S. Lee, and D.S. Lim. 2019. Pdlim4 is essential for CCR7-JNK-mediated dendritic cell migration and F-actin-related dendritic formation. The FASEB Journal 33: 11035–11044.
Curreli, S., B.S. Wong, O. Latinovic, K. Konstantopoulos, and N.M. Stamatos. 2016. Class 3 semaphorins induce F-actin reorganization in human dendritic cells: role in cell migration. Journal of Leukocyte Biology 100: 1323–1334.
Kim, J.I., J. Park, Y. Ji, K. Jo, S.M. Han, J.H. Sohn, K.C. Shin, J.S. Han, Y.G. Jeon, H. Nahmgoong, K.H. Han, J. Kim, S. Kim, S.S. Choe, and J.B. Kim. 2019. During adipocyte remodeling, lipid droplet configurations regulate insulin sensitivity through F-actin and G-actin reorganization. Molecular and Cellular Biology 39: e00210.
Song, H., J. Zhang, W. He, P. Wang, and F. Wang. 2019. Activation of cofilin increases intestinal permeability via depolymerization of F-actin during hypoxia in vitro. Frontiers in Physiology 10: 1455.
Hu, Z.Q., H. Xue, J.H. Long, Y. Wang, Y. Jia, W. Qiu, J. Zhou, Z.Y. Wen, W.J. Yao, and Z. Zeng. 2016. Biophysical properties and motility of human mature dendritic cells deteriorated by vascular endothelial growth factor through cytoskeleton remodeling. International Journal of Molecular Sciences 17: 1756.
Randolph, G.J., V. Angeli, and M.A. Swartz. 2005. Dendritic-cell trafficking to lymph nodes through lymphatic vessels. Nature Reviews Immunology 5: 617–628.
Funding
This study was funded by the National Natural Science Foundation of China (31960206), the Science and Technology Foundation of Guizhou Province (J-[2020]1Y334), and Health and Wellness Committee Foundation of Guizhou Province (gzwjkj2019-1-078) to Wei Qiu.
Author information
Authors and Affiliations
Corresponding authors
Ethics declarations
Conflict of Interest
The authors declare that they have no conflict of interest.
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Tong, L., Yue, P., Yang, Y. et al. Motility and Mechanical Properties of Dendritic Cells Deteriorated by Extracellular Acidosis. Inflammation 44, 737–745 (2021). https://doi.org/10.1007/s10753-020-01373-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10753-020-01373-z