anti-PD-1 therapy

anti-PD-1 therapy

Overview

Anti-PD-1 therapy refers to cancer immunotherapy that blocks the programmed cell death protein 1 (PD-1) pathway, a major immune checkpoint that normally restrains T-cell activation. By inhibiting PD-1 signaling, these therapies can restore cytotoxic T-lymphocyte function, enhance antitumor immunity, and promote immune-mediated tumor control. In contemporary oncology, anti-PD-1 therapy is widely studied across solid tumors and is often discussed alongside related checkpoint approaches such as anti-PD-L1 and CTLA-4 blockade.

Biologically, anti-PD-1 therapy is most relevant in tumors where immune evasion is driven by T-cell exhaustion, suppressive macrophage states, fibroblast-mediated remodeling, or other features of the tumor microenvironment. Recent research has focused heavily on mechanisms of resistance and on combination strategies designed to improve response, including agents that modulate CD28 signaling, FGFR1-regulated SPP1 signaling, Fap-positive fibroblasts, LILRB2-positive monocytes, salt-inducible kinases, PCSK9, and other immune or metabolic pathways.

Focus of Latest Publications

The recent studies provided here collectively portray anti-PD-1 therapy as both a clinically important immunotherapy and a benchmark for combination strategies designed to overcome resistance. Several reports examined mechanisms that limit response to PD-1 blockade. In hepatocellular carcinoma, multimodal sequencing identified synergistic mechanisms driving resistance to neoadjuvant nivolumab, highlighting the mechanistic basis of resistance to anti-PD-1 therapy. In oral squamous cell carcinoma, FAP expression predicted resistance to anti-PD-1 therapy, and inhibition of FAP enhanced treatment efficacy. In non-small cell lung cancer, single-cell and real-world analyses linked resistance to immunotherapy with specific cellular states, including LILRB2+ monocytes and distinct immunomodulatory gene-expression profiles, while another study associated CBX4 accumulation with nonresponse in patients receiving neoadjuvant anti-PD-1 therapy. Additional work in cervical cancer noted that PD-1 blockade remains the only approved immunotherapy for the disease but often provides limited and short-lived benefit, underscoring the need for better precision combinations.

A major theme across the studies was combination therapy to sensitize tumors to anti-PD-1 treatment. In hepatocellular carcinoma, a binary-amplified cascade hydrogel synergized with anti-PD-1 therapy to reinvigorate cytotoxic T lymphocytes and establish durable immune memory after incomplete microwave ablation, suppressing relapse and metastasis. Another hepatocellular carcinoma study found that targeting FGFR1-regulated SPP1 signaling repolarized immunosuppressive macrophages and sensitized tumors to anti-PD-1 therapy; pharmacological FGFR1 inhibition with BGJ398 enhanced antitumor efficacy in preclinical models. Similarly, blockade of LRG1 reprogrammed the hepatic niche toward an immune-activated state and sensitized tumors to anti-PD-1 therapy. In ovarian cancer, inhibition of salt-inducible kinases extended survival when combined with PD-1 blockade, and another ovarian cancer study reported that PAK inhibition with PD-1 blockade enhanced cytotoxic CD8+ T-cell killing and suppressed invasion. In breast cancer, STAT3-interference-driven nanomodulators showed synergy with αPD-1, inhibiting progression of primary and metastatic tumors.

Several studies used anti-PD-1 therapy as a backbone for engineered delivery systems or immune-activating platforms. A PD-1-targeted IL-15 mutein activated CD8+ and CD4+ T cells in infection and cancer, and outperformed anti-PD-1 plus untargeted IL-15, supporting the value of targeted cytokine delivery. A dual-payload nanotuner designed to weaponize pyroptosis overcame resistance to anti-PD-1 therapy and triggered systemic antitumor immunity. In another preclinical study, tumor-specific delivery of CD28 siRNA via Lyso-PC C-16 modified lipid nanoparticles effectively eradicated resistance to anti-PD-1 therapy by remodeling the tumor microenvironment. Likewise, a strategically activatable PEGylated peptide disrupted small extracellular vesicle-mediated PD-L1 interactions with PD-1 on CD8+ T cells, restoring effector function. AAV-ImmunAct also synergized with anti-PD-1 therapy in humanized mice by enhancing T-cell migration and activation and increasing killing of cancer cell lines and patient-derived organoids.

Other studies explored immune-priming approaches that improved outcomes with PD-1 blockade. In acral melanoma, a phase Ib neoadjuvant trial of oncolytic virus plus PD-1 blockade achieved a 77.8% pathological response rate and 81.5% 2-year relapse-free survival, suggesting meaningful clinical activity. In advanced melanoma, a therapeutic vaccine combined with anti-PD-1 therapy was reported to improve progression-free survival in a phase III study. In microsatellite stable/proficient mismatch repair locally advanced rectal cancer, total neoadjuvant chemotherapy using CapOX plus a PD-1 antibody and IL-2 was evaluated in a prospective phase II study. In hepatocellular carcinoma, intratumoral Lactobacillus johnsonii or NA synergistically inhibited tumor relapse and growth when combined with anti-PD-1 therapy in immunocompetent or humanized mice. In another study, intratumoral virus-like particles containing a TLR9 agonist combined with systemic αPD-1 produced a persistent increase in intratumoral tumor-specific CD8+ T cells and sustained tumor control.

The literature also emphasized biomarker discovery and immune contexture. Predictors of response to anti-PD-1 therapy were investigated in dMMR colorectal cancer using an integrated immune-enhanced multi-omics platform. In NSCLC, pretherapeutic prognostic factors were assessed in advanced disease treated with chemoimmunotherapy or immunotherapy, and PD-1/PD-L1 antibodies were noted to provide significant benefit even in advanced stage IVA/B. In cutaneous T-cell lymphoma, PD-1 checkpoint pathways were identified as part of immune evasion tactics deployed by malignant T cells. In rheumatoid arthritis and spondyloarthritis, PD1+ TIGIT+ CD4+ T cells were described as immune checkpoints relevant to response to anti-TNF therapy, reinforcing the broader immunobiological role of PD-1 beyond cancer.

Some studies also highlighted broader biological consequences and safety considerations. A case report described multiple endocrine adverse reactions and pituitary axis dysfunction induced by PD-1 immunotherapy in an esophageal cancer patient, illustrating immune-related endocrine toxicities associated with PD-1 blockade. Another study reported unexpected effects of anti-PD-1 therapy on the blood-brain barrier, suggesting that PD-1 inhibitors can alter systemic and central nervous system physiology in ways that may influence metastasis and drug delivery. Finally, several reports positioned anti-PD-1 therapy within the evolving landscape of immune checkpoint inhibition, including comparisons with TIGIT-targeted strategies and combinations with other agents such as alirocumab, doxorubicin, afatinib, gefitinib, and checkpoint inhibitor-based regimens in ongoing or preclinical settings.

Key Publications

  • NEWApr PD-1-targeted IL-15 mutein activates CD8+ and CD4+ T cells in infection and cancer. (JCI insight, 2026, PMID 42060360): "Notably, SAR'877 outperformed anti-PD-1 plus untargeted IL-15, highlighting the therapeutic potential of targeted IL-15 delivery."
  • Jun Reversing immunotherapy resistance in cold tumors by weaponizing pyroptosis with a dual-payload nanotuner. (Journal of controlled release : official journal of the Controlled Release Society, 2026, PMID 42314991): "As a result, this nano-pyroptosis inducer overcomes resistance to anti-PD-1 therapy, triggering potent systemic anti-tumor immunity and significantly inhibiting tumor growth."
  • Jun Single-Cell Reveal GALNT7-Dependent Ferroptosis Suppression as a Mechanism of Immunotherapy Resistance in Non-Small Cell Lung Cancer. (Advanced science (Weinheim, Baden-Wurttemberg, Germany), 2026, PMID 42318657): "Moreover, combining GALNT7 depletion with PD-1 blockade achieved synergistic tumor suppression, which is reversed by Ferrostatin-1, indicating ferroptosis-dependent immunostimulation."
  • Jun STAT3 interference-driven nanomodulators reverse lipid metabolism-associated chemoresistance and potentiate metalloimmunotherapy in breast cancer. (Cell reports. Medicine, 2026, PMID 42242229): "Moreover, the synergy with αPD-1 inhibits the progression of both primary and metastatic tumors."
  • Jun Tumor-Specific Delivery of CD28 siRNA via Lyso-PC C-16 Modified Lipid Nanoparticles Overcomes Anti-PD-1 Resistance by Remodeling Tumor Microenvironment. (Advanced science (Weinheim, Baden-Wurttemberg, Germany), 2026, PMID 42261788): "Furthermore, the combined use of LPC-LNP-Cd28 effectively eradicates resistance to anti-PD-1 therapy."
  • Jun Injectable Binary-Amplified Cascade Hydrogels Suppress Post-Incomplete Microwave Ablation Relapse via Integrated Metallo-Metabolic-Immunomodulation. (ACS nano, 2026, PMID 42150126): "Crucially, S/CuCo@HD synergizes with anti-PD-1 therapy to reinvigorate cytotoxic T lymphocytes and establish durable immune memory, effectively suppressing tumor relapse and metastasis post-iMWA, offering an integrated metallo-metabolic-immunomodulation strategy with promising translational potential for comprehensive HCC management."
  • Jun Multimodal sequencing identifies synergistic mechanisms driving resistance to neoadjuvant nivolumab treatment in hepatocellular carcinoma. (Molecular cancer, 2026, PMID 42226281): "...mechanistic basis of resistance to anti-PD-1 therapy in HCC."
  • Jun Long-term survival benefit of neoadjuvant oncolytic virus plus PD-1 blockade in acral melanoma: implications of STING in resistance and potential therapy. (Experimental hematology & oncology, 2026, PMID 42226303): "Our phase Ib neoadjuvant trial demonstrated that oncolytic virus (OV) combined with PD-1 blockade achieved a 77.8% pathological response rate and 81.5% 2-year relapse-free survival in patients with acral melanoma."
  • Jun LILRB2+ monocytes reshape the immune activation landscape in immunotherapy with non-small cell lung cancer: Evidence from real-world cohorts and single-cell analyses. (International journal of biological macromolecules, 2026, PMID 42069195): "LILRB2+ monocytes promoted the activation of CD8+ T cells, further enhanced the anti-tumor efficacy of PD-1 blockade."
  • Jun The global landscape of TIGIT-targeted cancer clinical trials: Trends, geographic shift, and policy implications. (Journal of cancer policy, 2026, PMID 42142605): "TIGIT has emerged as a notable immune checkpoint in tumor immunotherapy following PD-1/L1, though recent Phase III setbacks have tempered early optimism."
Show 27 more publications
  • May FAP+ fibroblasts promote C1QC+ macrophage infiltration via WNT2 signaling to exacerbate T cell exhaustion in oral squamous cell carcinoma. (Cancer letters, 2026, PMID 41831519): "Crucially, FAP expression predicted resistance to anti-PD-1 therapy, and its inhibition enhanced the efficacy of anti-PD-1 treatment in OSCC."
  • May Combating small extracellular vesicle-mediated immunological barriers in the tumor microenvironment via strategically activatable PEGylated peptides. (Signal transduction and targeted therapy, 2026, PMID 42204141): "Mechanistic investigations revealed that the peptide preferentially ruptured small EVs at pH 6.5, effectively preventing EVs' PD-L1 interactions with PD-1 on CD8⁺ T cells and contributing to the restoration of their effector functions."
  • May Multiple endocrine adverse reactions and pituitary axis dysfunction induced by PD-1 immunotherapy in an esophageal cancer patient: Case report. (Medicine, 2026, PMID 42175425): "Immune checkpoint inhibitors, particularly programmed cell death protein 1 (PD-1) blockers, have transformed cancer therapy but can induce immune-related endocrine toxicities."
  • May Inhibition of salt-inducible kinases reprograms T cells and antitumor immunity in ovarian cancer. (Nature immunology, 2026, PMID 42162294): "and combination of PD-1 blockade with SIK inhibition further extended survival."
  • May Multiomic study of cutaneous T-cell lymphoma reveals single-cell clonal evolution in progression and therapy resistance. (Blood, 2026, PMID 41662591): "we highlight mutation of CCR4, phosphoinositide 3-kinase inhibitor signaling, and programmed cell death protein 1 (PD-1) checkpoint pathways as evasion tactics deployed by malignant T cells."
  • May PD1+ TIGIT+ CD4+ T cells predict response to anti-TNF in rheumatoid arthritis and spondyloarthritis. (RMD open, 2026, PMID 42161414): "Programmed cell death protein 1 (PD-1) and T cell immunoreceptor with Ig and ITIM domains (TIGIT) are immune checkpoints expressed on T cells."
  • May CD155 links tumor immunotype to epithelial-directed precision therapy beyond checkpoint inhibition in cervical cancer. (Journal for immunotherapy of cancer, 2026, PMID 42161400): "Despite its viral etiology and immunogenic features, cervical cancer shows limited and often short-lived benefit from programmed cell death protein 1 blockade, currently the only approved immunotherapy for this disease."
  • May Ferroptotic tumor cells reprogram tumor-associated macrophage antigen presentation to enhance the efficacy of immune checkpoint blockade. (Cell reports. Medicine, 2026, PMID 42061406): "This creates a positive feedback loop wherein activated macrophages further promote immune-driven tumor ferroptosis, synergizing with anti-PD-1 (programmed cell death protein 1) therapy across preclinical models."
  • May In vivo CRISPR screens identify CBX4 as an epigenetic regulator for cancer immunotherapy. (The Journal of clinical investigation, 2026, PMID 41915438): "Single-cell RNA-seq and spatial transcriptomics analyses of patients receiving neoadjuvant anti-programmed cell death protein 1 (anti-PD-1) therapy revealed high CBX4 expression in both tumor cells and immunosuppressive tumor-associated macrophage subpopulations, with preferential accumulation in nonresponders."
  • May Discovery of INCB191358: A Potent and Selective DGKα/ζ Dual Inhibitor. (Journal of medicinal chemistry, 2026, PMID 41996127): "enhancing antitumor efficacy in a syngeneic tumor model when combined with PD-1 blockade."
  • May Total neoadjuvant chemotherapy combined with PD‑1 blockade and IL‑2 in MSS/pMMR locally advanced rectal cancer: short-term results of a prospective, single-arm phase II study. (Signal transduction and targeted therapy, 2026, PMID 42071008): "we evaluated the efficacy and safety of total neoadjuvant chemotherapy (TNT) using a CapOX regimen combined with a programmed cell death protein 1 (PD‑1) antibody (sintilimab) and interleukin‑2 (IL‑2) in patients with microsatellite stable (MSS)/defining proficient mismatch repair (pMMR) LARC."
  • May Pretherapeutic prognostic factors for survival under chemoimmunotherapy/immunotherapy of advanced NSCLC patients. (European journal of cancer (Oxford, England : 1990), 2026, PMID 41780180): "Checkpoint inhibitor therapy with PD-1/PD-L1-antibodies has significant benefits in non-small-cell lung cancer treatment even in advanced stage IVA/B."
  • May EGFR and IRE1α pathways are associated with distinct immunomodulatory gene expression profiles in NSCLC cells with acquired resistance to EGFR TKIs. (Archives of biochemistry and biophysics, 2026, PMID 41672191): "These findings suggest a poor prognosis and limited efficacy of anti-PD-1/PD-L1 immunotherapy in NSCLC patients with similar resistance profiles."
  • May Investigating PAK inhibition in combination with PD-1 blockade to enhance cytotoxic CD8+ T cell-mediated killing and suppress invasion of ovarian cancer cells. (British journal of cancer, 2026, PMID 41792510): "One notable method of ovcan survival is through the PD-(L)1 checkpoint pathway, and PD-L1 expression in ovcan is correlated with poor patient outcomes."
  • May Checkpoint Breaches: Unexpected Effects of Anti-PD-1 Therapy on the Blood-Brain Barrier. (Cancer discovery, 2026, PMID 42063318): "PD-1 inhibitors make cytotoxic T lymphocytes secrete a Wnt pathway suppressor to the blood that opens the blood-brain barrier, both allowing circulating tumor cells to enter the brain and a chemotherapeutic to better reach tumor cells in brain metastases."
  • May Domvanalimab combined with zimberelimab as first-line treatment in patients with PD-L1-high, advanced non-small cell lung cancer: Results from the randomized phase 2 ARC-10 study, Part1. (Lung cancer (Amsterdam, Netherlands), 2026, PMID 41830668): "TIGIT and PD-1 trigger distinct but interconnected immunosuppressive pathways."
  • May Targeting NK cell CLEC12B enhances cancer immunotherapy. (Nature immunology, 2026, PMID 41844941): "Furthermore, this nanobody has potent synergistic efficacy when combined with PD-1 blockade."
  • May Intratumoral Virus-Like Particles Containing a TLR9 Agonist Combined with Systemic αPD-1 Activate Tumor-Specific CD8+ T Cells. (Cancer research communications, 2026, PMID 41960903): "The addition of αPD-1 to Vidu led to a persistent increase in intratumoral tumor-specific CD8+ T cells and sustained tumor control."
  • Apr High-fidelity bioassembly of organoids and spheroids using inertial droplet microfluidics for precision oncology and tumor microenvironment modeling. (Microsystems & nanoengineering, 2026, PMID 42031701): "Furthermore, μPDOs generated with OsciSphere support efficient infiltration of autologous PBMCs, enabling quantitative assessment of PD-1 blockade."
  • Apr Predictors of Immune Checkpoint Blockade Response in dMMR Colorectal Cancer Using an Integrated Immune-Enhanced Multi-Omics Platform. (Clinical cancer research : an official journal of the American Association for Cancer Research, 2026, PMID 41995725): "We sought to identify candidate tumor- and immune-related biomarkers associated with clinical outcomes following anti-PD-1 therapy."
  • Apr Intratumoral Lactobacillus johnsonii Enhances Sensitivity to PD-1 Blockade by Inducing CD8+ T-cell Expansion in Hepatocellular Carcinoma. (Cancer research, 2026, PMID 41570324): "Combining L. johnsonii or NA with anti-PD-1 therapy synergistically inhibited tumor relapse and tumor growth in immunocompetent or humanized mice."
  • Apr Dual-Targeting Multivalent Aptamer-Drug Hybrids for Synergistic Cancer Immunotherapy. (Journal of the American Chemical Society, 2026, PMID 41973478): "Notably, Dualo-mvApDHsD/S synergize with PD-1 blockade to achieve durable tumor eradication and long-term protection."
  • Apr Immune modulatory vaccines targeting tumor microenvironment antigens: recent advances in oncology and beyond. (Signal transduction and targeted therapy, 2026, PMID 41963297): "A phase III study in first-line advanced melanoma recently demonstrated that a therapeutic vaccine, when combined with anti-PD-1 therapy, can improve progression-free survival in patients with metastatic disease."
  • Apr Hepatocyte-derived LRG1 primes the liver for metastasis and impairs immunotherapy. (Cellular & molecular immunology, 2026, PMID 41963620): "Importantly, therapeutic blockade of LRG1 not only suppressed liver metastasis but also reprogrammed the hepatic niche toward an immune-activated state, sensitizing tumors to anti-PD-1 therapy."
  • Apr Alirocumab plus cemiplimab in advanced immuno-refractory metastatic non-small cell lung cancer: an ongoing multi-center phase II study. (Future oncology (London, England), 2026, PMID 41940540): "Building on this evidence, we present the scientific rationale and study design of TOP2201, an ongoing single-arm phase II trial evaluating the addition of the PCSK9 inhibitor alirocumab to anti-PD-1 therapy in patients with metastatic NSCLC who have experienced disease progression on prior immune checkpoint inhibitor-based regimens."
  • Apr Targeting FGFR1-regulated SPP1 signaling repolarizes immunosuppressive macrophages and sensitizes Hepatocellular Carcinoma to anti-PD-1 therapy. (Cancer letters, 2026, PMID 41786278): "Importantly, pharmacological inhibition of FGFR1 using BGJ398 synergized with anti-PD-1 therapy, resulting in enhanced antitumor efficacy in preclinical models."
  • Apr Miniature and versatile genome regulation TnpB-ωRNA toolkits facilitate cancer immunotherapy. (Nature communications, 2026, PMID 41917051): "AAV-ImmunAct effectively enhances T cell migration and activation, increases killing of cancer cell lines and patient-derived organoids, and synergizes with anti-PD-1 therapy in humanized mice."