Baseline sLAG-3 levels in Caucasian and African-American breast cancer patients.

BACKGROUND: Worse survival persists for African-Americans (AA) with breast cancer compared to other race/ethnic groups despite recent improvements for all. Unstudied in outcomes disparities to date is soluble LAG-3 (sLAG-3), cleaved from the LAG-3 immune checkpoint receptor which is a proposed target for deactivation in emerging immunotherapies due to its prominent immunosuppressive function in the tumoral microenvironment. A prior study has found that lower sLAG-3 baseline level was associated with poor outcomes. METHODS: In a cross-sectional study of 95 patients with primary breast cancer (n = 58 Caucasian, n = 37 AA), we measured sLAG-3 (ELISA pg/ml) in pre-treatment blood samples using the non-parametric Mann-Whitney u-Test for independent samples, and, calculated Pearson r correlation coefficients of sLAG-3 with circulating cytokines by race. RESULTS: Mean sLAG-3 level was lower in AA compared to Caucasian patients (1377.6 vs 3690.3, P = .002), and in patients with triple-negative breast cancer (TNBC) compared to those with non-TNBC malignancies (P = .02). When patients with TNBC tumors were excluded from analyses, the difference in sLAG-3 level between AA (n = 21) and Caucasian patients (n = 40) substantially remained (1937.4 vs 4182.4, P = .06). Among Caucasian patients, sLAG-3 was correlated with IL-6, IL-8 and IL-10 (r = .69, P < .001; r = .70, P < .001; and, r = .46, P = .01; respectively). For AA patients, sLAG-3 was correlated only with IL-6 (r = .37, P = .03). CONCLUSIONS: We present the first report that African-American breast cancer patients might have comparatively low pre-treatment sLAG-3 levels, independent of TNBC status, along with reduced co-expression with circulating cytokines. The mechanistic and prognostic role of cleaved LAG-3, particularly in disparate outcomes, remains to be elucidated.

Targeting apoptotic pathways for cancer therapy.

Apoptosis is a form of programmed cell death that is mediated by intrinsic and extrinsic pathways. Dysregulation of and resistance to cell death are hallmarks of cancer. For over three decades, the development of therapies to promote treatment of cancer by inducing various cell death modalities, including apoptosis, has been a main goal of clinical oncology. Apoptosis pathways also interact with other signaling mechanisms, such as the p53 signaling pathway and the integrated stress response (ISR) pathway. In addition to agents directly targeting the intrinsic and extrinsic pathway components, anticancer drugs that target the p53 and ISR signaling pathways are actively being developed. In this Review, we discuss selected and promising anticancer therapies in various stages of development, including drug targets, mechanisms, and resistance to related treatments, focusing especially on B cell lymphoma 2 (BCL-2) inhibitors, TRAIL analogues, DR5 antibodies, and strategies that target p53, mutant p53, and the ISR.

Therapeutic targeting of TRAIL death receptors.

The discovery of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) along with its potent and selective antitumor effects initiated a decades-long search for therapeutic strategies to target the TRAIL pathway. First-generation approaches were focused on the development of TRAIL receptor agonists (TRAs), including recombinant human TRAIL (rhTRAIL) and TRAIL receptor-targeted agonistic antibodies. While such TRAIL pathway-targeted therapies showed promise in preclinical data and clinical trials have been conducted, none have advanced to FDA approval. Subsequent second-generation approaches focused on improving upon the specific limitations of first-generation approaches by ameliorating the pharmacokinetic profiles and agonistic abilities of TRAs as well as through combinatorial approaches to circumvent resistance. In this review, we summarize the successes and shortcomings of first- and second-generation TRAIL pathway-based therapies, concluding with an overview of the discovery and clinical introduction of ONC201, a compound with a unique mechanism of action that represents a new generation of TRAIL pathway-based approaches. We discuss preclinical and clinical findings in different tumor types and provide a unique perspective on translational directions of the field.