Xenetic Biosciences, Inc. Announces Abstract Acceptance for Presentation at the 2026 ASCO Annual Meeting

On April 22, 2026 Xenetic Biosciences, Inc. (NASDAQ:XBIO) ("Xenetic" or the "Company"), a biopharmaceutical company focused on advancing innovative immuno-oncology technologies addressing difficult to treat cancers, reported that its abstract has been accepted for presentation at the 2026 American Society of Clinical Oncology (ASCO) (Free ASCO Whitepaper) Annual Meeting, taking place May 29 – June 2, 2026, in Chicago, IL.

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The accepted abstract, titled "Targeting cfDNA and NETs with DNase I to augment CAR T cell function and antitumor efficacy," highlights preclinical research supporting Xenetic’s DNase-based therapeutic approach designed to enhance CAR T-cell activity and improve antitumor responses.

Presentation Details:

Session Title: Hematologic Malignancies – Plasma Cell Dyscrasia (Poster Session)

Abstract Title: Targeting cfDNA and NETs with DNase I to augment CAR T cell function and antitumor efficacy

Poster Board: 410

Presentation Date & Time: June 1, 2026, 9:00 AM – 12:00 PM CDT

Presenter: Alexey V. Stepanov, PhD

The poster will be available to conference attendees during the scheduled session. For more information, please visit asco.org.

(Press release, Xenetic Biosciences, APR 22, 2026, View Source [SID1234664693])

CytoDyn Presents New Leronlimab Data in Metastatic Colorectal Cancer at AACR Annual Meeting 2026

On April 22, 2026 CytoDyn Inc. (OTCQB: CYDY) ("CytoDyn" or the "Company"), a clinical-stage oncology company advancing leronlimab, a first-in-class humanized monoclonal antibody targeting the CCR5 receptor with therapeutic potential across multiple indications, including metastatic triple-negative breast cancer ("mTNBC") and colorectal cancer ("mCRC"), reported that new clinical data from its ongoing Phase 2 study in metastatic colorectal cancer (mCRC) were presented at the AACR (Free AACR Whitepaper) Annual Meeting 2026, taking place April 17–22, 2026, at the San Diego Convention Center.

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The presentation highlighted findings supporting CCR5 inhibition with leronlimab as a strategy to modulate the tumor microenvironment, enhance immune engagement, and improve outcomes in metastatic colorectal cancer (mCRC), particularly in combination with standard-of-care therapies.

Metastatic colorectal cancer remains a significant clinical challenge, particularly in patients with refractory disease who have progressed on multiple prior lines of therapy. While standard regimens such as TAS-102 in combination with bevacizumab provide modest benefit, treatment resistance and immune evasion continue to limit durable responses. Results presented at AACR (Free AACR Whitepaper) demonstrate that CCR5 inhibition with leronlimab may enhance anti-tumor activity by modulating the tumor microenvironment and improving immune engagement.

"Preliminary results from our ongoing Phase 2 study suggest that CCR5 inhibition with leronlimab may enhance both biomarker and clinical responses in heavily pretreated mCRC patients," said Pashtoon M. Kasi, M.D., M.S., Medical Director of GI Oncology, City of Hope Orange County, Irvine, California. "Real-time assessment of novel liquid biopsy biomarkers, including circulating tumor cells, circulating tumor DNA, and cancer-associated macrophage-like cells in blood, along with integrated evaluation of tumor tissue and the tumor microenvironment, is providing insights that conventional imaging and traditional assessment methods cannot capture."

Key findings from the ongoing Phase 2 mCRC study include:

Among pre-screened patients with evaluable samples (N=33), CCR5 expression was detected in 100% of cases, supporting its potential as a therapeutic target in mCRC.
Early clinical and biomarker responses were observed, including rapid and substantial reductions in circulating tumor DNA (ctDNA), with median declines of approximately 70% by week 2 across evaluable patients (N=19).
The combination regimen has been well tolerated, with no leronlimab-related dose-limiting toxicities (DLTs) observed, and escalation to 700 mg dosing underway.
The study continues to enroll toward full enrollment, reflecting significant unmet need in previously treated mCRC.
"Building on the translational and clinical data presented earlier in the week in mTNBC, these findings further support CCR5 as a key regulator of the tumor microenvironment across solid tumors," said Jacob P. Lalezari, M.D., Chief Executive Officer of CytoDyn. "The early biomarker and clinical signals observed in our ongoing Phase 2 mCRC study reinforce the potential of leronlimab-based combination approaches to enhance immune engagement and address resistance in heavily pretreated patients."

The poster presentation titled "Preliminary results of a phase 2 study of leronlimab in combination with TAS-102 and bevacizumab in previously treated metastatic colorectal cancer" was presented by Dr. Kasi on April 21, 2026, from 2:00 p.m. – 5:00 p.m. PT (Poster #6466). A copy of the poster will be made available on CytoDyn’s website under the Publications & Posters section.

(Press release, CytoDyn, APR 22, 2026, View Source [SID1234664709])

Anixa Biosciences Announces Presentation of its Ovarian Cancer CAR-T Therapy at the International Society for Cell & Gene Therapy 2026 Annual Meeting

On April 22, 2026 Anixa Biosciences, Inc. ("Anixa" or the "Company") (NASDAQ: ANIX), a biotechnology company focused on the treatment and prevention of cancer, reported that Cheryl Cox, MHA, Operations Director of the Cell Therapies and Gene Expression Engineering Facility at Moffitt Cancer Center, will be presenting at the International Society for Cell & Gene Therapy (ISCT) 2026 Annual Meeting, being held May 6 – 9, 2026, in Dublin, Ireland.

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Ms. Cox’s presentation, titled "Phase 1 clinical trial of autologous T cells genetically engineered with a chimeric receptor to target the follicle-stimulating hormone receptor (FSHR) in recurrent ovarian cancer," will discuss the clinical trial design and objectives, as well as the current status of Anixa’s ongoing Phase 1 clinical trial of lira-cel.

The ISCT 2026 Annual Meeting will bring together thousands of global experts in cell and gene therapy. This event is recognized as the largest conference focused on translating cell and gene therapies from research to clinical practice. The four-day program will feature hundreds of speakers, cutting edge scientific presentations, and interactive sessions covering advances in areas such as gene editing, bioprocessing, and clinical translation, alongside extensive networking opportunities and industry showcases.

About Lira-cel, Anixa’s CAR-T Therapy for Recurrent Ovarian Cancer
Liraltagene autoleucel, or lira-cel, uniquely targets the follicle-stimulating hormone receptor (FSHR), which is selectively expressed on ovarian cells, tumor vasculature, and certain cancer cells, but not in healthy tissue. The ongoing Phase 1 trial (ClinicalTrials.gov NCT05316129) is enrolling adult women with recurrent ovarian cancer who have progressed after at least two prior therapies.

(Press release, Anixa Biosciences, APR 22, 2026, View Source [SID1234664678])

Nurix Therapeutics Announces New Preclinical Data Highlighting Breadth of Targeted Protein Degradation Pipeline at AACR 2026

On April 22, 2026 Nurix Therapeutics, Inc. (Nasdaq: NRIX), a clinical-stage biopharmaceutical company developing targeted protein degradation therapies, reported new preclinical data from multiple oncology programs at the American Association for Cancer Research (AACR) (Free AACR Whitepaper) Annual Meeting 2026.

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The presentations highlight continued progress across Nurix’s oncology pipeline, including programs targeting pan-mutant BRAF, CBL-B and Aurora Kinase A (AURKA), as well as a featured AACR (Free AACR Whitepaper) Advances session presentation highlighting the broader scientific progress and clinical translation of targeted protein degradation. Collectively, these data provide additional mechanistic validation of Nurix’s approach to CBL-B, Aurora kinase A (AURKA) and mutant BRAF to address key limitations of traditional approaches, including resistance, incomplete pathway suppression, and inability to target non-enzymatic protein functions.

"These data, together with our participation in the AACR (Free AACR Whitepaper) Advances session, highlight the growing clinical and scientific validation of targeted protein degradation as a new therapeutic modality," said Arthur T. Sands, M.D., Ph.D., president and chief executive officer. "Across multiple programs, we are seeing consistent evidence that these therapies can drive deeper and more durable biological responses, supporting their potential to deliver meaningful benefit for patients."

AACR Advances Session
Later today, April 22, 2026, Gwenn Hansen, Ph.D., chief scientific officer of Nurix, will present "Designing Effective Degrader Therapeutics: What Early Clinical Experience Has Taught Us" as part of the AACR (Free AACR Whitepaper) Advances session "Induced Proximity Pharmacology: Degraders and Beyond." Dr. Hansen’s remarks will provide a broad perspective on recent advances in targeted protein degradation, including insights from early clinical experience and the evolving potential of induced proximity approaches to expand the druggable target space and improve therapeutic outcomes.

Pan-Mutant BRAF Degrader Program
In a poster presentation titled "NRX-0305, an orally bioavailable, CNS penetrant pan-mutant BRAF degrader demonstrates robust efficacy in intracranial models of melanoma brain metastasis and primary glioma," Nurix reported that NRX-0305 achieves dose-proportional pharmacokinetics across plasma, tumor, and brain, enabling robust degradation of mutant BRAF and downstream pathway inhibition. These properties translate into potent antitumor activity in intracranial glioma and melanoma models while selectively sparing wildtype BRAF and avoiding paradoxical MAPK pathway activation. In a clinically relevant BRAF inhibitor–resistant melanoma brain metastasis patient-derived xenograft (PDX) model, NRX-0305 significantly extended survival versus both vehicle and dabrafenib, delivering a 142% increase in lifespan, compared with approximately 12% for the approved BRAF inhibitor.

Additional data were presented in a poster titled "NRX-0305 is an orally bioavailable, pan-mutant BRAF degrader that exhibits single-agent and combination efficacy with MEKi or anti-EGFR across Class 1/2/3 BRAF-mutant cancers." In preclinical tumor models, NRX-0305 demonstrates broad activity across mutant BRAF classes, including activity across 14 PDX models spanning Class 1 treatment-resistant, Class 2, and Class 3 BRAF mutations. Combination of NRX-0305 with MEK inhibitors or anti-EGFR therapy enhanced tumor regressions in Class 2 and drove complete responses in Class 1 and 3 models. Notably, the complete regressions are achieved at lower MEK inhibitor dose levels, supporting the potential for an improved therapeutic window relative to current treatment approaches.

CBL-B Program
In an oral presentation titled "Discovery and characterization of CBL-B intramolecular glue inhibitors that increase T cell activation and suppress tumor growth," Nurix reported the discovery and characterization of novel intramolecular glue inhibitors targeting CBL-B, an E3 ubiquitin ligase that negatively regulates T, B, and NK cell activation. Using mechanism-agnostic screening assays guided by CBL-B biology, Nurix identified a novel series of intramolecular glue inhibitors that stabilize the closed, inactive conformation of CBL-B, representing a first-in-class mechanism of action. Through structure-guided optimization, this series was advanced to NX-1607, a potent and selective CBL-B inhibitor with sub-nanomolar binding affinity. In preclinical studies, NX-1607 enhanced T cell activation, as evidenced by increased IL-2 and IFN-γ secretion in response to TCR stimulation, and demonstrated single-agent anti-tumor activity across multiple syngeneic tumor models, including colorectal, triple-negative breast cancer, and B cell lymphoma. NX-1607 also synergized with anti-PD-1 therapy to significantly enhance survival across multiple models. Early clinical data demonstrated dose-dependent pharmacokinetics and modulation of the proximal pharmacodynamic biomarker pHS1 in CD8 T cells, providing initial evidence of target engagement in patients.

Aurora Kinase A (AURKA) Degrader Program
In a poster presentation titled "NRX-4972, a selective, oral, Aurora kinase A degrader, demonstrates increased efficacy in an SCLC tumor model, and greater in vitro synergy than an AURKA inhibitor," Nurix reported new data demonstrating that targeted degradation of AURKA enables more complete biological modulation compared to inhibition alone. NRX-4972 exhibits central nervous system penetration and a favorable pharmacokinetic and pharmacodynamic profile, translating into superior antitumor activity in aggressive small cell lung cancer models, particularly with an optimized twice-daily dosing regimen. In the H82 SCLC model, twice-daily administration of NRX-4972 resulted in 60% of mice surviving to the end of the study, whereas none of the mice treated with AURKA inhibitors alisertib or LY3295668 survived. Mechanistically, degradation of AURKA results in downregulation of MYC and enhanced induction of DNA damage, apoptosis, and G2/M arrest. NRX-4972 also demonstrated broader and more potent synergy than an AURKA inhibitor in an in vitro screen of combination agents across triple-negative breast cancer, SCLC, and NSCLC cell lines, further supporting its therapeutic potential.

About NRX-0305
NRX-0305 is a potent, selective, and orally bioavailable central nervous system (CNS)-penetrant pan-mutant BRAF degrader that Nurix is exploring for use in oncology. Nurix has reported preclinical data demonstrating potent anti-tumor activity in multiple cell line-derived and patient-derived xenograft disease models representing Class 1, Class 2, and Class 3 B-RAF mutations. Anti-tumor activity was also observed in the setting of CNS disease and treatment-resistance, suggesting the potential for utility across a broad range of solid tumor types.

About NX-1607
NX-1607 is an investigational first-in-class oral inhibitor of the E3 ligase Casitas B-lineage lymphoma proto-oncogene B (CBL-B) being developed for immuno-oncology indications, including a range of solid tumor types. CBL-B is a cytoplasmic E3 ubiquitin ligase that negatively regulates T cell activation, making it an attractive target for immuno-oncology and offering a novel therapeutic approach to treat solid tumors. Inhibition of CBL-B in preclinical studies reverses T cell exhaustion, alleviates tumor induced immunosuppression, and may also exert direct antitumor effects. Nurix is evaluating NX-1607 in an ongoing Phase 1 trial in adults in a range of oncology indications. This study includes a thorough investigation of both dose and schedule in the Phase 1a portion. Additional information on the NX-1607 clinical trial can be accessed at www.clinicaltrials.gov (NCT05107674).

About NRX-4972
NRX-4972 is a CNS-penetrant, orally bioavailable and highly selective degrader of Aurora A kinase (AURKA). AURKA is an oncogene frequently overexpressed in adult solid tumors, hematologic malignancies, and pediatric cancers. Several AURKA inhibitors are effective in preclinical tumor models, but this activity has failed to translate into clinical efficacy. To address the limitations of inhibitors, Nurix has designed bifunctional targeted protein degraders of AURKA that enable removal of both enzymatic and scaffolding functions.

(Press release, Nurix Therapeutics, APR 22, 2026, View Source [SID1234664694])

SEED Therapeutics Reports Tumor Eradication in a Neuroblastoma In Vivo Model with Clinical-Stage RBM39 Molecular Glue Degrader ST-01156

On April 22, 2026 SEED Therapeutics, Inc. ("SEED"), a clinical-stage biotechnology company pioneering rationally designed molecular glue degraders, reported new data demonstrating potent anticancer activity of its RBM39 degrader program in neuroblastoma, a pediatric cancer with high unmet medical need. SEED’s scientific work also identified potential biomarkers predictive of anticancer response that will be further examined in the clinic, with Phase 1 dose escalation projected to be completed by Q1 2027. The findings are being presented at the 2026 Annual Meeting of the American Association for Cancer Research (AACR) (Free AACR Whitepaper), which convenes more than 22,000 scientists, clinicians, and investors this week in San Diego.

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ST-01156, SEED’s clinical-stage RBM39 molecular glue degrader, is currently being evaluated in a Phase 1 dose escalation study (NCT07197554) at six leading U.S. oncology centers.

Highlights At A Glance

Tumor eradication in a rigorous in vivo model: ST-01156 achieved complete tumor regression in neuroblastoma model using a differentiated dosing regimen — a demanding efficacy benchmark in solid tumor oncology.
Active Phase 1 clinical trial: Dose escalation is underway (NCT07197554) at six leading U.S. oncology centers, with clinical sites in additional geographies in preparation.
Biomarker strategy: MYC overexpression (sensitivity) and CDKN2A/B deletion (resistance) were identified as part of SEED’s biomarker program, potentially enabling precision patient enrollment as the trial advances.
Rare Pediatric and Orphan disease opportunity: Neuroblastoma is a high-unmet-need rare pediatric cancer representing a Rare Pediatric Disease and Orphan Disease designation-eligible indication, with potential for expedited regulatory pathways including Priority Review Voucher eligibility.

Scientific Rationale: Why RBM39 Matters

RBM39 is an RNA-binding protein that governs pre-mRNA splicing — a process cancer cells exploit to fuel uncontrolled growth, evade cell death, and repair DNA damage. By degrading RBM39 entirely, rather than merely inhibiting it, SEED’s approach disrupts multiple oncogenic pathways simultaneously: cell cycle progression, metabolic reprogramming, DNA damage response, and programmed cell death (apoptosis — the process by which damaged or cancerous cells are eliminated by the body). This breadth of effect is a key differentiator from conventional targeted therapies.

Molecular glue degraders achieve this by redirecting the cell’s own quality-control machinery — the ubiquitin-proteasome system — to tag and destroy the target protein. SEED’s proprietary RITE3 platform was designed from inception to identify, validate, and optimize molecular glues with a defined therapeutic window, bringing rational drug design to protein targets previously considered undruggable.

Key Data Highlights — AACR (Free AACR Whitepaper) 2026 Poster #5785

Tumor eradication in an in vivo model: ST-01156 achieved complete tumor regression in a neuroblastoma xenograft model — meaning tumors disappeared entirely — using the same dosing schedule now deployed in the Phase 1 trial. This direct correspondence between preclinical and clinical dosing strengthens confidence in the translational path forward.
Consistent potency across a biologically diverse disease: ST-01156 demonstrated potent anticancer activity across ten neuroblastoma models — six established cell lines and four patient-derived models — with IC50 values (the concentration required to kill half of cancer cells) in the low-to-sub-micromolar range. Neuroblastoma is genetically heterogeneous; this breadth of coverage matters.
A clear mechanism of action: Treatment with ST-01156 induced DNA damage, switched on the tumor-suppressing p53/p21 pathway, and reduced the levels of known cancer-driving proteins cMYC and EZH2 — confirming a coherent, multi-pronged path to programmed cancer cell death (apoptosis).
Biomarker roadmap for precision enrollment: SEED’s translational research identified MYC overexpression as a marker of sensitivity to ST-01156, and CDKN2A/B deletion as a marker of resistance. These biomarkers — identifiable through standard tumor profiling — may provide a practical framework for selecting patients most likely to benefit as the Phase 1 trial progresses toward expansion cohorts.

"ST-01156’s advancement into clinical testing in 2026 marks a pivotal milestone for SEED and for patients with RBM39 dependent cancers, including neuroblastoma — a pediatric cancer with very limited effective treatment options. The identification of MYC and CDKN2A/B status as potential biomarkers is the product of SEED’s focus on identifying the patients who will significantly benefit from ST-01156."

— James Tonra, PhD, President & Chief Scientific Officer, SEED Therapeutics

"The RBM39 data we are presenting at AACR (Free AACR Whitepaper) 2026 reflect what SEED’s RITE3 platform was designed to do — not just degrade a difficult target, but understand which patients are most likely to benefit. Seeing ST-01156 achieve complete tumor regression in a neuroblastoma model, at the same dosing schedule now in the clinic, is deeply gratifying and scientifically meaningful. Our focus at SEED is on ensuring that the molecular insight behind this program translates into real outcomes for patients with very few options."

— Lan Huang, PhD, Co-Founder, SEED Therapeutics

Clinical Development Status

ST-01156 is being evaluated in an ongoing Phase 1 dose escalation study (NCT07197554) designed to establish safety, pharmacokinetics, and target engagement. The study enrolls patients enriched for cancer types with demonstrated RBM39 dependency in preclinical research. The trial is currently active at six leading U.S. oncology centers, with additional clinical sites in preparation. Phase 1 dose escalation is projected to be completed by Q1 2027. The dosing schedule employed is consistent with that used in IND-enabling studies and in the in vivo efficacy program reported at AACR (Free AACR Whitepaper) 2026 — providing a robust translational foundation.

AACR 2026 Poster Presentation Details

Title: RBM39 Degrader Anticancer Activity Against Neuroblastoma; MYC and CDKN2A/B as Potential Response Biomarkers
Poster Number: 5785
Session: Proximity-Induced Drug Discovery 2 (Experimental and Molecular Therapeutics)
Authors: James Finn, Imad Salhab, Haihong Jin, Fei Liu, Dong Liu, Yunkai Zhang, Xing Liu, James Tonra, Lan Huang, Dan Lu

(Press release, Seed Therapeutics, APR 22, 2026, View Source [SID1234664710])