BackgroundThe lack of a reliable scoring system that predicts the development of septic shock and death precludes comparison of disease and/or treatment outcomes in animal models of sepsis. We developed a murine sepsis score (MSS) that evaluates seven clinical variables, and sought to assess its validity and reliability in an experimental mouse model of polymicrobial sepsis.MethodsStool collected from the cecum of C57BL/6 (B6) mice was dissolved in 0.9% normal saline (NS) and filtered, resulting in a fecal solution (FS) which was injected intraperitoneally into B6 mice. Disease severity was monitored by MSS during the experimental timeline. Blood and tissue samples were harvested for the evaluation of inflammatory changes after sepsis induction. The correlation between pro-inflammatory markers and MSS was assessed by the Spearman rank correlation coefficient.ResultsMice injected with FS at a concentration of 90 mg/mL developed polymicrobial sepsis with a 75% mortality rate at 24 hours. The MSS was highly predictive of sepsis progression and mortality, with excellent discriminatory power, high internal consistency (Cronbach alpha coefficient = 0.92), and excellent inter-rater reliability (intra-class coefficient = 0.96). An MSS of 3 had a specificity of 100% for predicting onset of septic shock and death within 24 hours. Hepatic dysfunction and systemic pro-inflammatory responses were confirmed by biochemical and cytokine analyses where the latter correlated well with the MSS. Significant bacterial dissemination was noted in multiple organs. Furthermore, the liver, spleen, and intestine demonstrated histopathological evidence of injury.ConclusionsThe MSS reliably predicts disease progression and mortality in an animal model of polymicrobial sepsis. More importantly, it may be used to assess and compare outcomes among various experimental models of sepsis, and serve as an ethically acceptable alternative to death as an endpoint.
Despite recent therapeutic advances, including the introduction of novel cytostatic drugs and therapeutic antibodies, many cancer patients will experience recurrent or metastatic disease. Current treatment options, particularly for those patients with metastatic breast, prostate, or skin cancers, are complex and have limited curative potential. Recent clinical trials, however, have shown that cell-based therapeutic vaccines may be used to generate broad-based, antitumor immune responses. Dendritic cells (DC) have proved to be the most efficacious cellular component for therapeutic vaccines, serving as both the adjuvant and antigen delivery vehicle. At present it is not possible to noninvasively determine the fate of DC-based vaccines after their administration to human subjects. In this study, we demonstrate that in vitro-generated mouse DC can be readily labeled with superparamagnetic iron oxide nanoparticles, Feridex, without altering cell morphology, or their phenotypic and functional maturation. Feridex-labeling enables the detection of DC in vivo after their migration to draining lymph nodes using a 1.5 T clinical magnetic resonance scanner. In addition, we report a semiquantitative approach for analysis of magnetic resonance images and show that the Feridex-induced signal void volume, and fractional signal loss, correlates with the delivery and migration of small numbers of in vitro-generated DC. These findings, together with ongoing preclinical studies, are key to gaining information critical for improving the efficacy of therapeutic vaccines for the treatment cancer, and potentially, chronic infectious diseases.
Acute (i.e., wasting) pediatric malnutrition consistently elevates blood glucocorticoid levels, but neither the magnitude of the rise in concentration nor its kinetics is clear. Male and female C57BL/6J mice, initially 19 days old, and CBA/J mice, initially 23 days old, consumed a complete purified diet either ad libitum (age-matched control) or in restricted daily quantities (mimicking marasmus), or they consumed a purified isocaloric low-protein diet ad libitum (mimicking incipient kwashiorkor). Serum levels of corticosterone were assessed by double antibody radioimmunoassay after 3, 6, and 14 days (C57BL/6J strain) or after 6 and 14 days in the genetically distant CBA/J strain. Age-matched control groups of both strains exhibited mean corticosterone levels of 5-30 ng/ml, whereas the acutely malnourished groups exhibited mean levels of this hormone that were elevated by more than an order of magnitude as early as 3 days after initiation of weight loss. This outcome was confirmed in a second experiment in which the serum corticosterone level of C57BL/6J weanlings was examined by competitive binding enzyme immunoassay 3 and 14 days after initiation of the dietary protocols. Therefore, deficits of protein and/or energy in weanling murine systems relevant to acute pediatric malnutrition elicit early elevations in blood glucocorticoid levels to a magnitude reminiscent of critical illness and multiple trauma. The key to this novel finding was an exsanguination method that permitted accurate assessment of the blood corticosterone level of the healthy, quiescent mouse. Overall, the results of this investigation provide a new perspective on the glucocorticoids as part of the early hormonal response to acute weanling malnutrition coincident with the shift toward catabolic metabolism and the initiation of depression in cellular immune competence.
Metastasis is present in approximately 30% of patients diagnosed with renal cell carcinoma (RCC) and is associated with a 5-year survival rate of < 15%. Kidney injury molecule 1 (KIM-1), encoded by the HAVCR1 gene, is a proximal tubule cell-surface glycoprotein and a biomarker for early detection of RCC, but its pathophysiological significance in RCC remains unclear. We generated human and murine RCC cell lines either expressing or lacking KIM-1, respectively, and compared their growth and metastatic properties using validated methods. Surprisingly, KIM-1 expression had no effect on cell proliferation or subcutaneous tumour growth in immune deficient (Rag1−/−) Balb/c mice, but inhibited cell invasion and formation of lung metastasis in the same model. Further, we show that the inhibitory effect of KIM-1 on metastases was observed in both immune deficient and immune competent mice. Transcriptomic profiling identified the mRNA for the pro-metastatic GTPase, Rab27b, to be downregulated significantly in KIM-1 expressing human and murine RCC cells. Finally, analysis of The Cancer Genome Atlas (TCGA) data revealed that elevated HAVCR1 mRNA expression in the two most common types of RCC, clear cell and papillary RCC, tumours correlated with significantly improved overall patient survival. Our findings reveal a novel role for KIM-1 in inhibiting metastasis of RCC and suggests that tumour-associated KIM-1 expression may be a favourable prognostic factor.
Renal cell carcinoma (RCC) is the most common and lethal form of kidney cancer. Cancer immune evasion is a major obstacle for effective immunotherapy in RCC. Mechanisms of immune evasion are characterized by three phenotypes: Immune Inflamed; tumor contains infiltrating T cells which are rendered inactive within the tumor microenvironment due to localized inhibition. Immune Desert; tumor is devoid of activate T cells due to defective antigen presentation, and/or T cell activation. Lastly, Immune Excluded; tumor is surrounded by T cells that are unable to penetrate the parenchyma, caused by immunosuppression within the tumor stroma. Kidney Injury Molecule-1 (KIM-1) is a cell-surface glycoprotein aberrantly expressed in >90% of RCC tumors. The purpose of this study was to determine the pathophysiological significance of KIM-1 in RCC pathogenesis. We generated murine RCC cells (Renca) expressing KIM-1 (KIM-1pos) or control vector (KIM-1neg) using lentiviral transduction. We found that KIM-1 expression on RCC cells promoted more rapid tumor growth when injected contralaterally into syngeneic immunocompetent BALB/c mice (KIM-1neg = 263.75mm3, KIM-1pos = 849.72, p = 0.0149 & KIM-1neg = 0.32g, KIM-1pos = 0.58, p = 0.0229), but not in RAG1-/- immunodeficient BALB/c mice suggesting the KIM-1 promotes tumor growth through evasion of the adapt immune system. When analyzing tumor infiltrating lymphocytes (TILs) from both tumor groups, we found a relative scarcity of CD4+ and CD8+ T cells within the KIM-1pos vs. KIM-1neg tumors. To classify the immune evasion phenotype, we analyzed localization of the immune infiltrate using immunofluorescence within KIM-1pos and KIM-1neg RCC tumors. We found significantly fewer CD3+ cells within the KIM-1pos vs. KIM-1neg tumor parenchyma (KIM-1neg = 3625.78%, KIM-1pos = 272.36%, p = 0.0410). Moreover, CD3+ cells of the KIM-1neg tumors were observed in the parenchyma, whereas CD3+ cells of the KIM-1pos tumors were localized to the tumor stroma. In addition, we observed a higher frequency of myeloid derived suppressor cells (MDSCs) within the KIM-1pos vs the KIM-1neg tumor parenchyma (KIM-1neg = 0.05, KIM-1pos = 0.19, p = 0.0266). Transcriptomic profiling of both KIM-1pos and KIM-1neg Renca cells suggests that KIM-1 promotes deposition of extracellular matrix (KIM-1neg = -1.21, KIM-1pos = 1.96-fold change), which may contribute to KIM-1-mediated immune evasion Our data suggests that KIM-1 expression in RCC promotes immune evasion by altering the tumor microenvironment resulting in an Immune Excluded phenotype. Citation Format: Demitra M. Yotis, Bradly Shrum, Marie Sarabusky, Lakshman Gunaratnam. KIM–1 mediatesimmune evasioninrenal cell carcinoma [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 2162.
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