Lymph node biophysical remodeling is associated with melanoma lymphatic drainage

Rohner, Nathan A.; McClain, Jacob; Tuell, Sara Lydia; Warner, Alex; Smith, B.; Yun, Young-Ho; Mohan, Ayush; Sushnitha, Manuela; Thomas, Susan N.

doi:10.1096/fj.15-274761

Cited by 48 publications

(52 citation statements)

References 86 publications

(114 reference statements)

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“…For example, sentinel, or tumor-draining, lymph nodes are exposed to a high concentration of lymph-transported molecules from the tumor interstitium by virtue of their proximity to growing tumors (Figure 1) (7, 8). Signaling pathways active within the local tumor microenvironment that result in tissue remodeling associated with cancer cell survival (44), invasion (45–47), and immune suppression (5) could therefore operate within tumor-draining lymph nodes.…”

Section: Lymphatic Transport–directed Remodeling Of the Lymph Nodementioning

confidence: 99%

“…Signaling pathways active within the local tumor microenvironment that result in tissue remodeling associated with cancer cell survival (44), invasion (45–47), and immune suppression (5) could therefore operate within tumor-draining lymph nodes. We recently analyzed lymph nodes from B16 melanoma–bearing mice with respect to tumor stage and found that melanoma lymphatic drainage was associated with alterations in lymph node hyaluronic acid and collagen content corresponding with physical adaptations that manifest in tumors (44, 48, 49), including increased intranodal pressures (7, 50, 51) and increased lymph node tissue stiffness and viscoelasticity (7). The potential for these and other remodeling responses to influence critical cellular processes in the lymph node, including cell proliferation, migration, and lymphocyte homing, is discussed below.…”

Section: Lymphatic Transport–directed Remodeling Of the Lymph Nodementioning

confidence: 99%

“…Low–molecular weight hyaluronic acid induces an increase in the proliferation of lymphatic endothelial cells and triggers their migration and organization into tubelike structures (57). Alterations in lymph node hyaluronic acid content, which were previously demonstrated to be associated with melanoma lymphatic drainage (7), therefore have the potential to influence the survival, proliferation, and functionality of lymph node resident cells.…”

Section: Lymphatic Transport–directed Remodeling Of the Lymph Nodementioning

confidence: 99%

“…Indeed, lymph drainage affects more than just tissue edema. For example, lymph drainage facilitates both exogenous and self-antigen transport to lymph nodes to tune humoral response to immunization as well as regulatory T (T reg ) cell function and immune tolerance (4); locally dampens antitumor immunity (5); and directs the remodeling of draining lymph nodes (4, 6, 7), tissues whose microstructure orchestrates the comingling of lymph and lymphocytes to facilitate adaptive immune response. The transport role of the lymphatics is thus intrinsically linked to lymphatic function in immune physiology.…”

Section: Introductionmentioning

confidence: 99%

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Implications of Lymphatic Transport to Lymph Nodes in Immunity and Immunotherapy

Thomas

Rohner

Edwards

2016

Annu. Rev. Biomed. Eng.

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Adaptive immune response consists of many highly regulated, multistep cascades that protect against infection while preserving the health of autologous tissue. The proper initiation, maintenance, and resolution of such responses require the precise coordination of molecular and cellular signaling over multiple time and length scales orchestrated by lymphatic transport. In order to investigate these functions and manipulate them for therapy, a comprehensive understanding of how lymphatics influence immune physiology is needed. This review presents the current mechanistic understanding of the role of the lymphatic vasculature in regulating biomolecule and cellular transport from the interstitium, peripheral tissue immune surveillance, the lymph node stroma and microvasculature, and circulating lymphocyte homing to lymph nodes. This review also discusses the ramifications of lymphatic transport in immunity as well as tolerance and concludes with examples of how lymphatic-mediated targeting of lymph nodes has been exploited for immunotherapy applications.

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Section: Lymphatic Transport–directed Remodeling Of the Lymph Nodementioning

confidence: 99%

Section: Lymphatic Transport–directed Remodeling Of the Lymph Nodementioning

confidence: 99%

Section: Lymphatic Transport–directed Remodeling Of the Lymph Nodementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Implications of Lymphatic Transport to Lymph Nodes in Immunity and Immunotherapy

Thomas

Rohner

Edwards

2016

Annu. Rev. Biomed. Eng.

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“…Furthermore, tumor-draining lymph nodes often display altered immunological microenvironments relative to non-tumor associated lymph nodes, suggesting active regulation of the tumor-draining lymph node microenvironment by the tumor to suppress anti-tumor immunity. We and others have noted lymph node remodeling associated with tumor lymphatic drainage [17,18,83–85], effects that may alter antigen, cytokine, growth factor, or even therapeutic agent accumulation within and distribution throughout tumor-draining lymph nodes to alter their signaling activity [18]. Furthermore, increased frequencies of regulatory T cells [86] and low densities of CD169 + subcapsular sinus macrophages [87] within tumor-draining lymph nodes predicts poor patient outcome in melanoma [86].…”

Section: Opportunities and Potential Strategies For Improving Checmentioning

confidence: 99%

Progress and opportunities for enhancing the delivery and efficacy of checkpoint inhibitors for cancer immunotherapy

Francis

Thomas

2017

Advanced Drug Delivery Reviews

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Despite the advent of immune checkpoint blockade for effective treatment of advanced malignancies, only a minority of patients respond to therapy and significant immune-related adverse events remain to be minimized. Innovations in engineered drug delivery systems and controlled release strategies can improve drug accumulation at and retention within target cells and tissues in order to enhance therapeutic efficacy while simultaneously reducing drug exposure in off target tissues to minimize the potential for treatment-associated toxicities. This review will outline basic principles of the immune physiology of checkpoint signaling, the existing knowledge of dose-efficacy relationships in checkpoint inhibition, the influence of administration route on treatment efficacy, as well as the resulting checkpoint inhibitor antibody biodistribution profiles amongst target versus systemic tissues. It will also highlight recent successes in the application of drug delivery principles and technologies towards augmenting checkpoint blockade therapy in cancer. Delivery strategies that have been developed for other therapeutic and immunotherapy applications with as-of-yet underexplored potential in checkpoint inhibition therapy will also be discussed.

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Award Winner in the Young Investigator Category, 2017 Society for Biomaterials Annual Meeting and Exposition, Minneapolis, MN, April 05—08, 2017: Lymph node stiffness‐mimicking hydrogels regulate human B‐cell lymphoma growth and cell surface receptor expression in a molecular subtype‐specific manner

Apoorva

Tian

Pierpont

et al. 2017

J Biomedical Materials Res

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Diffuse large B-cell lymphoma (DLBCL) is the most common type of non-Hodgkin's lymphoma, with multiple molecular subtypes. The activated B-cell-like DLBCL subtype accounts for roughly one-third of all the cases and has an inferior prognosis. There is a need to develop better class of therapeutics that could target molecular pathways in resistant DLBCLs; however, this requires DLBCLs to be studied in representative tumor microenvironments. The pathogenesis and progression of lymphoma has been mostly studied from the point of view of genetic alterations and intracellular pathway dysregulation. By comparison, the importance of lymphoma microenvironment in which these malignant cells arise and reside has not been studied in as much detail. We have recently elucidated the role of integrin signaling in lymphomas and demonstrated that inhibition of integrin-ligand interactions abrogated the proliferation of malignant cells in vitro and in patient-derived xenograft. Here we demonstrate the role of lymph node tissue stiffness on DLBCL in a B-cell molecular subtype specific manner. We engineered tunable bioartificial hydrogels that mimicked the stiffness of healthy and neoplastic lymph nodes of a transgenic mouse model and primary human lymphoma tumors. Our results demonstrate that molecularly diverse DLBCLs grow differentially in soft and high stiffness microenvironments, which further modulates the integrin and B-cell receptor expression level as well as response to therapeutics. We anticipate that our findings will be broadly useful to study lymphoma biology and discover new class of therapeutics that target B-cell tumors in physical environments. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 105A: 1833-1844, 2017.

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Lymph node biophysical remodeling is associated with melanoma lymphatic drainage

Cited by 48 publications

References 86 publications

Implications of Lymphatic Transport to Lymph Nodes in Immunity and Immunotherapy

Implications of Lymphatic Transport to Lymph Nodes in Immunity and Immunotherapy

Progress and opportunities for enhancing the delivery and efficacy of checkpoint inhibitors for cancer immunotherapy

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