Transferrin Receptor Antibody Research Articles

A Human Brain-Chip for Modeling Brain Pathologies and Screening Blood–Brain Barrier Crossing Therapeutic Strategies

Background/Objectives: The limited translatability of preclinical experimental findings to patients remains an obstacle for successful treatment of brain diseases. Relevant models to elucidate mechanisms behind brain pathogenesis, including cell-specific contributions and cell-cell interactions, and support successful targeting and prediction of drug responses in humans are urgently needed, given the species differences in brain and blood-brain barrier (BBB) functions. Human microphysiological systems (MPS), such as Organ-Chips, are emerging as a promising approach to address these challenges. Here, we examined and advanced a Brain-Chip that recapitulates aspects of the human cortical parenchyma and the BBB in one model. Methods: We utilized human primary astrocytes and pericytes, human induced pluripotent stem cell (hiPSC)-derived cortical neurons, and hiPSC-derived brain microvascular endothelial-like cells and included for the first time on-chip hiPSC-derived microglia. Results: Using Tumor necrosis factor alpha (TNFα) to emulate neuroinflammation, we demonstrate that our model recapitulates in vivo-relevant responses. Importantly, we show microglia-derived responses, highlighting the Brain-Chip’s sensitivity to capture cell-specific contributions in human disease-associated pathology. We then tested BBB crossing of human transferrin receptor antibodies and conjugated adeno-associated viruses. We demonstrate successful in vitro/in vivo correlation in identifying crossing differences, underscoring the model’s capacity as a screening platform for BBB crossing therapeutic strategies and ability to predict in vivo responses. Conclusions: These findings highlight the potential of the Brain-Chip as a reliable and time-efficient model to support therapeutic development and provide mechanistic insights into brain diseases, adding to the growing evidence supporting the value of MPS in translational research and drug discovery.

Modulation of hippocampal protein expression by a brain penetrant biologic TNF-α inhibitor in the 3xTg Alzheimer’s disease mice

BackgroundBiologic TNF-α inhibitors (bTNFIs) can block cerebral TNF-α in Alzheimer’s disease (AD) if these macromolecules can cross the blood–brain barrier (BBB). Thus, a model bTNFI, the extracellular domain of type II TNF-α receptor (TNFR), which can bind to and sequester TNF-α, was fused with a mouse transferrin receptor antibody (TfRMAb) to enable brain delivery via BBB TfR-mediated transcytosis. Previously, we found TfRMAb-TNFR to be protective in a mouse model of amyloidosis (APP/PS1) and tauopathy (PS19), and herein we investigated its effects in mice that combine both amyloidosis and tauopathy (3xTg-AD).MethodsEight-month-old female 3xTg-AD mice were injected intraperitoneally with saline (n = 11) or TfRMAb-TNFR (3 mg/kg; n = 11) three days per week for 12 weeks. Age-matched wild-type (WT) mice (n = 9) were treated similarly with saline. Brains were processed for immunostaining and high-resolution multiplex NanoString GeoMx spatial proteomics.ResultsWe observed regional differences in proteins relevant to Aβ, tau, and neuroinflammation in the hippocampus of 3xTg-AD mice compared with WT mice. From 64 target proteins studied using spatial proteomics, a comparison of the Aβ-plaque bearing vs. plaque-free regions in the 3xTg-AD mice yielded 39 differentially expressed proteins (DEP) largely related to neuroinflammation (39% of DEP) and Aβ and tau pathology combined (31% of DEP). Hippocampal spatial proteomics revealed that the majority of the proteins modulated by TfRMAb-TNFR in the 3xTg-AD mice were relevant to microglial function (⁓ 33%). TfRMAb-TNFR significantly reduced mature Aβ plaques and increased Aβ-associated microglia around larger Aβ deposits in the 3xTg-AD mice. Further, TfRMAb-TNFR increased mature Aβ plaque-associated microglial TREM2 in 3xTg-AD mice.ConclusionOverall, despite the low visual Aβ load in the 11-month-old female 3xTg-AD mice, our results highlight region-specific AD-relevant DEP in the hippocampus of these mice. Chronic TfRMAb-TNFR dosing modulated several DEP involved in AD pathology and showed a largely microglia-centric mechanism of action in the 3xTg-AD mice.

The Impact of Pabinafusp Alfa on the Disease Burden in Hunter's Syndrome: Patient-Reported Outcomes

AbstractSevere mucopolysaccharidosis type II (MPS-II) patients present with progressive mental impairment and reduced life expectancy. While current available treatment cannot cross the blood–brain barrier, the enzyme replacement therapy with pabinafusp alfa (a recombinant iduronate-2-sulfatase fused to an antihuman transferrin receptor antibody) was designed to penetrate it using transferrin receptor-mediated transcytosis. In this cross-sectional retrospective study, we aimed to report the impact of this new therapy using patient-reported outcomes. Data were collected using standardized questionnaire replied by patients or their caregivers (as proxies). Nine patients received intravenous administration of pabinafusp alfa for at least 104 weeks. All patient showed improvements in behavior (mainly aggressiveness), speech, motor ability, muscle strength, facial expression, breathing, and cognitive skills. Gait improvement was also found in 78% of participants. Caregivers also reported improvements in emotion demonstration as ability to smile, establish eye contact, and give hugs. Collectively, our results indicate a positive impact of pabinafusp alfa on quality of life of individuals with MPS-II and their relatives/caregivers. Future studies are warranted to elucidate the mechanisms underlying these beneficial effects.

α-L-iduronidase fused with humanized anti-human transferrin receptor antibody (lepunafusp alfa) for mucopolysaccharidosis type I: A phase 1/2 trial

Mucopolysaccharidosis type I (MPS I) causes systemic accumulation of glycosaminoglycans due to a genetic deficiency of α-L-iduronidase (IDUA), which results in progressive systemic symptoms affecting multiple organs, including the central nervous system (CNS). Because the blood-brain barrier (BBB) prevents enzymes from reaching the brain, enzyme replacement therapy is effective only against the somatic symptoms. Hematopoietic stem cell transplantation can address the CNS symptoms, but the risk of complications limits its applicability. We have developed a novel genetically modified protein consisting of IDUA fused with humanized anti-human transferrin receptor antibody (lepunafusp alfa; JR-171), which has been shown in nonclinical studies to be distributed to major organs, including the brain, bringing about systemic reductions in heparan sulfate (HS) and dermatan sulfate concentrations. Subsequently, a first-in-human study was conducted to evaluate the safety, pharmacokinetics, and exploratory efficacy of JR-171 in 18 patients with MPS I. No notable safety issues were observed. Plasma drug concentration increased dose-dependently and reached its maximum approximately 4 hours after the end of drug administration. Decreased HS in the cerebrospinal fluid suggested successful delivery of JR-171 across the BBB, while suppressed urine and serum concentrations of the substrates indicated its somatic efficacy was comparable to that of laronidase.

Development of a neuroimaging biomarker of the pro‐coagulant state in Alzheimer’s disease: The BioClotAD Project

AbstractBackgroundAlzheimer’s disease (AD) is the most common form of dementia1. Its multifactorial profile includes a strong vascular factor, partially driven by an early haemostatic dysregulation. Accordingly, fibrin, the main protein component of blood clots, is significantly increased in AD‐patients’ brains2. Furthermore, amyloid‐β contributes to this process by interacting with fibrin and producing degradation‐resistant clots3. Consequently, this pro‐thrombotic milieu intensifies hypoperfusion, neurodegeneration and blood‐brain barrier (BBB) disruption4, but it does not affect all patients. Therefore, early detection of these phenomena would be invaluable to identify patients likely to benefit from anticoagulant therapies5. Therefore, the BioClotAD Project aims to develop an imaging biomarker based on a fibrin binding probe (FBP)6 to non‐invasively identify AD’s pro‐coagulant state.MethodBioClotAD involves four partners in three European countries with complementary expertise. To optimize and test FBP we use extensive in vitro, ex vivo and in vivo assays, including AD animal models and human AD samples. Our project is comprised of three blocks: 1) Testing the FBP to in vivo detect the cerebral occlusions by nuclear imaging. 2) Detecting fibrin deposits inside the brain parenchyma with FBP coupled to a transferrin receptor antibody (FBP‐TfR) to facilitate BBB crossing7. FBP‐TfR will be labelled for optical and nuclear imaging. 3) Validating the most promising FBP probes in frozen brain samples of AD patients by autoradiography or fluorescence microscopy.ResultBioClotAD provides feasible neuroimaging strategies to in vivo detect the fibrin cerebral accumulation of AD models and identify the specific regional distribution in the brain. Our project will set the basis for future clinical trials on neuroimaging of the cerebral fibrin accumulation in AD.ConclusionBioClotAD neuroimaging biomarkers will allow the early detection of the pro‐thrombotic state in AD, opening a window of opportunity to delay the disease progression by personalized anticoagulant therapies. Funding: EU Joint Programme – Neurodegenerative Disease Research (JPND)

Modulation of hippocampal protein expression by a brain penetrant biologic TNF‐α inhibitor in the 3xTg Alzheimer’s disease mice

AbstractBackgroundAlzheimer’s disease (AD) is a chronic neuroinflammatory condition and the proinflammatory cytokine, tumor necrosis factor alpha (TNF‐α), is a key mediator of neuroinflammation in AD. Biologic TNF‐α inhibitors (bTNFIs) can block cerebral TNF‐α if these large molecules cross the blood‐brain barrier (BBB). Thus, a model bTNFI, the extracellular domain of type II TNF‐α receptor (TNFR) which can bind to and sequester TNF‐α, has been reengineered to enable brain delivery by fusion with a mouse transferrin receptor antibody (TfRMAb). TfRMAb binds to the BBB TfR to deliver the TNFR into the brain via receptor‐mediated transcytosis. Previously, we found the TfRMAb‐TNFR to be protective in a mouse model of amyloidosis (APP/PS1) and tauopathy (PS19), and the aim of the current study was to investigate its effects in a mouse model that combines both amyloidosis and tauopathy (3xTg‐AD mice).MethodEight‐month‐old female triple transgenic 3xTg‐AD mice were injected intraperitoneally with saline (n = 11) or TfRMAb‐TNFR (3 mg/kg; n = 11) three days per week for 12 weeks. At the end of treatment, brains were processed for hippocampal immunohistochemistry and high‐resolution multiplex NanoString spatial proteomics using the GeoMx protein assays for neuroscience.ResultTfRMAb‐TNFR treatment significantly reduced mature β‐sheet rich Aβ plaques and increased plaque‐associated microglial localization around larger plaques in the 3xTg mice. Further, TfRMAb‐TNFR increased plaque‐associated microglial TREM2 compared with saline‐treated 3xTg mice. From a total of 64 target proteins studied using spatial proteomics (comparing protein expression in the Aβ‐plaque bearing vs. plaque‐free regions), 39 (61%) differentially expressed proteins (DEP) were identified in the 11‐month‐old 3xTg mice, comprising of proteins related to neurodegeneration (10% of DEP), neuroinflammation (41% of DEP), amyloid (21% of DEP) and tau (10% of DEP) pathology, autophagy (10% of DEP) and other pathways (8% of DEP). TfRMAb‐TNFR treatment modulated proteins involved in Aβ clearance and processing, microglial function, RNA processing, and neurodegeneration. Majority of these proteins were relevant to microglial function (∼ 40%).ConclusionThe study highlights that TfRMAb‐TNFR modulates several proteins involved in AD pathology and progression and largely suggests a microglia‐centric mechanism of action of this treatment in the 3xTg mice.

Transferrin Receptor-Targeted Iduronate-2-sulfatase Penetrates the Blood-Retinal Barrier and Improves Retinopathy in Mucopolysaccharidosis II Mice.

Mucopolysaccharidoses (MPSs) make up a group of lysosomal storage diseases characterized by the aberrant accumulation of glycosaminoglycans throughout the body. Patients with MPSs display various signs and symptoms, such as retinopathy, which is also observed in patients with MPS II. Unfortunately, retinal disorders in MPS II are resistant to conventional intravenous enzyme-replacement therapy because the blood-retinal barrier (BRB) impedes drug penetration. In this study, we show that a fusion protein, designated pabinafusp alfa, consisting of an antihuman transferrin receptor antibody and iduronate-2-sulfatase (IDS), crosses the BRB and reaches the retina in a murine model of MPS II. We found that retinal function, as assessed by electroretinography (ERG) in MPS II mice, deteriorated with age. Early intervention with repeated intravenous treatment of pabinafusp alfa decreased heparan sulfate deposition in the retina, optic nerve, and visual cortex, thus preserving or even improving the ERG response in MPS II mice. Histological analysis further revealed that pabinafusp alfa mitigated the loss of the photoreceptor layer observed in diseased mice. In contrast, recombinant nonfused IDS failed to reach the retina and hardly affected the retinal disease. These results support the hypothesis that transferrin receptor-targeted IDS can penetrate the BRB, thereby ameliorating retinal dysfunction in MPS II.

A Perfused In Vitro Human iPSC-Derived Blood–Brain Barrier Faithfully Mimics Transferrin Receptor-Mediated Transcytosis of Therapeutic Antibodies

Delivering biologics to elicit a therapeutic response in the central nervous system (CNS) remains challenging due to the presence of the blood–brain barrier (BBB). Receptor-mediated transcytosis is a strategy to improve brain exposure after systemic drug administration. The availability of a clinically relevant in vitro BBB model is crucial to investigate transcytosis pathways and to predict the penetration of biologics into the CNS. We created a perfused human in vitro BBB model made of induced pluripotent stem cells (iPSC)-derived brain microvascular endothelial cells (BMEC) for studying transferrin receptor-mediated transcytosis. iPSC-derived BMEC were seeded in the top channel of a three-lane microfluidic device (OrganoPlate®). After 2 days in culture, the established cell model exhibited relevant BBB features, including physiological transendothelial electrical resistance in a transwell setting (1500 Ω*cm2), reduced apparent permeability (Papp) to the fluorescence tracer Lucifer yellow (20-fold less than cell-free chips), expression of key BBB markers such as tight junctions proteins, transporters, receptors and functional P-gp efflux pump. Moreover, the model exhibited functional transferrin receptor-mediated uptake and transcytosis. To assess selective transferrin receptor-mediated transcytosis, a mixture of anti-human transferrin receptor (MEM-189) and control (sheep IgG anti-bovine serum albumin) antibodies was perfused in the top channel for 2 h. The Papp of MEM-189 was 11-fold higher than that of the control antibody, demonstrating facilitated receptor-mediated transcytosis. Compared to published work reporting a 2-fold ratio, this result is remarkable and establishes the suitability of our model for exploring receptor-mediated transcytosis and screening of antibodies for putative brain shuttle application.Graphical A perfused in vitro human model made of iPSC-derived BMEC with the chief characteristics (barrier tightness, functionality) of the human BBB can be applied to study transferrin receptor (TfR)-mediated transcytosis of therapeutic antibodies. This may bring critical advances in drug shuttle technology. Graphical abstract generated with biorender.com.

Application of In vitro transcytosis models to brain targeted biologics.

The blood brain barrier (BBB) efficiently limits the penetration of biologics drugs from blood to brain. Establishment of an in vitro BBB model can facilitate screening of central nervous system (CNS) drug candidates and accelerate CNS drug development. Despite many established in vitro models, their application to biologics drug selection has been limited. Here, we report the evaluation of in vitro transcytosis of anti-human transferrin receptor (TfR) antibodies across human, cynomolgus and mouse species. We first evaluated human models including human cerebral microvascular endothelial cell line hCMEC/D3 and human colon epithelial cell line Caco-2 models. hCMEC/D3 model displayed low trans-epithelial electrical resistance (TEER), strong paracellular transport, and similar transcytosis of anti-TfR and control antibodies. In contrast, the Caco-2 model displayed high TEER value and low paracellular transport. Anti-hTfR antibodies demonstrated up to 70-fold better transcytosis compared to control IgG. Transcytosis of anti-hTfR.B1 antibody in Caco-2 model was dose-dependent and saturated at 3 μg/mL. Enhanced transcytosis of anti-hTfR.B1 was also observed in a monkey brain endothelial cell based (MBT) model. Importantly, anti-hTfR.B1 showed relatively high brain radioactivity concentration in a non-human primate positron emission tomography study indicating that the in vitro transcytosis from both Caco-2 and MBT models aligns with in vivo brain exposure. Typically, brain exposure of CNS targeted biologics is evaluated in mice. However, antibodies, such as the anti-human TfR antibodies, do not cross-react with the mouse target. Therefore, validation of a mouse in vitro transcytosis model is needed to better understand the in vitro in vivo correlation. Here, we performed transcytosis of anti-mouse TfR antibodies in mouse brain endothelial cell-based models, bEnd3 and the murine intestinal epithelial cell line mIEC. There is a good correlation between in vitro transcytosis of anti-mTfR antibodies and bispecifics in mIEC model and their mouse brain uptake. These data strengthen our confidence in the predictive power of the in vitro transcytosis models. Both mouse and human in vitro models will serve as important screening assays for brain targeted biologics selection in CNS drug development.

Enzyme replacement with transferrin receptor-targeted α-L-iduronidase rescues brain pathology in mucopolysaccharidosis I mice

Mucopolysaccharidosis I (MPS I), a lysosomal storage disease caused by dysfunction of α-L-iduronidase (IDUA), is characterized by the deposition of dermatan sulfate (DS) and heparan sulfate (HS) throughout the body, which causes several somatic and central nervous symptoms. Although enzyme-replacement therapy (ERT) is currently available to treat MPS I, it does not alleviate central nervous disorders, as it cannot penetrate the blood-brain barrier. Here we evaluate the brain delivery, efficacy, and safety of JR-171, a fusion protein comprising humanized anti-human transferrin receptor antibody Fab and IDUA, using monkeys and MPS I mice. Intravenously administered JR-171 was distributed in major organs, including the brain, and reduced DS and HS concentrations in the central nervous system and peripheral tissues. JR-171 exerted similar effects on peripheral disorders similar to conventional ERT and further reversed brain pathology in MPS I mice. We found that JR-171 improved spatial learning ability, which was seen to deteriorate in the vehicle-treated mice. Further, no safety concerns were noted in repeat-dose toxicity studies in monkeys. This study provides nonclinical evidence that JR-171 might potentially prevent and even improve disease conditions in patients with neuronopathic MPS I without serious safety concerns.

Development of brain-penetrable antibody radioligands for in vivo PET imaging of amyloid-β and tau.

Alzheimer's disease (AD) is characterized by the misfolding and aggregation of two major proteins: amyloid-beta (Aβ) and tau. Antibody-based PET radioligands are desirable due to their high specificity and affinity; however, antibody uptake in the brain is limited by the blood-brain barrier (BBB). Previously, we demonstrated that antibody transport across the BBB can be facilitated through interaction with the transferrin receptor (TfR), and the bispecific antibody-based PET ligands were capable of detecting Aβ aggregates via ex vivo imaging. Since tau accumulation in the brain is more closely correlated with neuronal death and cognition, we report here our strategies to prepare four F-18-labeled specifically engineered bispecific antibody probes for the selective detection of tau and Aβ aggregates to evaluate their feasibility and specificity, particularly for in vivo PET imaging. We first created and evaluated (via both in vitro and ex vivo studies) four specifically engineered bispecific antibodies, by fusion of single-chain variable fragments (scFv) of a TfR antibody with either a full-size IgG antibody of Aβ or tau or with their respective scFv. Using [18F]SFB as the prosthetic group, all four 18F-labeled bispecific antibody probes were then prepared by conjugation of antibody and [18F]SFB in acetonitrile/0.1 M borate buffer solution (final pH ~ 8.5) with an incubation of 20 min at room temperature, followed by purification on a PD MiniTrap G-25 size exclusion gravity column. Based on both in vitro and ex vivo evaluation, the bispecific antibodies displayed much higher brain concentrations than the unmodified antibody, supporting our subsequent F18-radiolabeling. [18F]SFB was produced in high yields in 60 min (decay-corrected radiochemical yield (RCY) 46.7 ± 5.4) with radiochemical purities of >95%, confirmed by analytical high performance liquid chromatography (HPLC) and radio-TLC. Conjugation of [18F]SFB and bispecific antibodies showed a 65%-83% conversion efficiency with radiochemical purities of 95%-99% by radio-TLC. We successfully labeled four novel and specifically engineered bispecific antibodies with [18F]SFB under mild conditions with a high RCY and purities. This study provides strategies to create brain-penetrable F-18 radiolabeled antibody probes for the selective detection of tau and Aβ aggregates in the brain of transgenic AD mice via in vivo PET imaging.

A fusion protein of anti-human transferrin receptor antibody and alfa-L-fucosidase 1 is a prospective candidate for the treatment of the symptoms in CNS and visceral tissues of fucosidosis

A fusion protein of anti-human transferrin receptor antibody and alfa-L-fucosidase 1 is a prospective candidate for the treatment of the symptoms in CNS and visceral tissues of fucosidosis

ImmunoPET imaging of amyloid-beta in a rat model of Alzheimer’s disease with a bispecific, brain-penetrating fusion protein

BackgroundHijacking the transferrin receptor (TfR) is an effective strategy to transport amyloid-beta (Aβ) immuno-positron emission tomography (immunoPET) ligands across the blood–brain barrier (BBB). Such ligands are more sensitive and specific than small-molecule ligands at detecting Aβ pathology in mouse models of Alzheimer’s disease (AD). This study aimed to determine if this strategy would be as sensitive in rats and to assess how TfR affinity affects BBB transport of bispecific immunoPET radioligands.MethodsTwo affinity variants of the rat TfR antibody, OX26, were chemically conjugated to a F(ab′)2 fragment of the anti-Aβ antibody, bapineuzumab (Bapi), to generate two bispecific fusion proteins: OX265-F(ab′)2-Bapi and OX2676-F(ab′)2-Bapi. Pharmacokinetic analyses were performed 4 h and 70 h post-injection of radioiodinated fusion proteins in wild-type (WT) rats. [124I]I-OX265-F(ab′)2-Bapi was administered to TgF344-AD and WT rats for in vivo PET imaging. Ex vivo distribution of injected [124I]I-OX265-F(ab′)2-Bapi and Aβ pathology were assessed.ResultsMore [125I]I-OX265-F(ab′)2-Bapi was taken up into the brain 4 h post-administration than [124I]I-OX2676-F(ab′)2-Bapi. [124I]I-OX265-F(ab′)2-Bapi PET visualized Aβ pathology with significantly higher signals in the TgF344-AD rats than in the WT littermates without Aβ pathology. The PET signals significantly correlated with Aβ levels in AD animals.ConclusionAffinity to TfR affects how efficiently a TfR-targeting bispecific fusion protein will cross the BBB, such that the higher-affinity bispecific fusion protein crossed the BBB more efficiently. Furthermore, bispecific immunoPET imaging of brain Aβ pathology using TfR-mediated transport provides good imaging contrast between TgF344-AD and WT rats, suggesting that this immunoPET strategy has the potential to be translated to higher species.

Selection of single domain anti-transferrin receptor antibodies for blood-brain barrier transcytosis using a neurotensin based assay and histological assessment of target engagement in a mouse model of Alzheimer's related amyloid-beta pathology.

The blood-brain barrier (BBB) presents a major obstacle in developing specific diagnostic imaging agents for many neurological disorders. In this study we aimed to generate single domain anti-mouse transferrin receptor antibodies (anti-mTfR VHHs) to mediate BBB transcytosis as components of novel MRI molecular contrast imaging agents. Anti-mTfR VHHs were produced by immunizing a llama with mTfR, generation of a VHH phage display library, immunopanning, and in vitro characterization of candidates. Site directed mutagenesis was used to generate additional variants. VHH fusions with neurotensin (NT) allowed rapid, hypothermia-based screening for VHH-mediated BBB transcytosis in wild-type mice. One anti-mTfR VHH variant was fused with an anti-amyloid-beta (Aβ) VHH dimer and labeled with fluorescent dye for direct assessment of in vivo target engagement in a mouse model of AD-related Aβ plaque pathology. An anti-mTfR VHH called M1 and variants had binding affinities to mTfR of <1nM to 1.52nM. The affinity of the VHH binding to mTfR correlated with the efficiency of the VHH-NT induced hypothermia effects after intravenous injection of 600 nmol/kg body weight, ranging from undetectable for nonbinding mutants to -6°C for the best mutants. The anti-mTfR VHH variant M1P96H with the strongest hypothermia effect was fused to the anti-Aβ VHH dimer and labeled with Alexa647; the dye-labeled VHH fusion construct still bound both mTfR and Aβ plaques at concentrations as low as 0.22 nM. However, after intravenous injection at 600 nmol/kg body weight into APP/PS1 transgenic mice, there was no detectible labeling of plaques above control levels. Thus, NT-induced hypothermia did not correlate with direct target engagement in cortex, likely because the concentration required for NT-induced hypothermia was lower than the concentration required to produce in situ labeling. These findings reveal an important dissociation between NT-induced hypothermia, presumably mediated by hypothalamus, and direct engagement with Aβ-plaques in cortex. Additional methods to assess anti-mTfR VHH BBB transcytosis will need to be developed for anti-mTfR VHH screening and the development of novel MRI molecular contrast agents.

Efficacy and Safety of a Brain-Penetrant Biologic TNF-α Inhibitor in Aged APP/PS1 Mice.

Tumor necrosis factor alpha (TNF-α) plays a vital role in Alzheimer’s disease (AD) pathology, and TNF-α inhibitors (TNFIs) modulate AD pathology. We fused the TNF-α receptor (TNFR), a biologic TNFI that sequesters TNF-α, to a transferrin receptor antibody (TfRMAb) to deliver the TNFI into the brain across the blood–brain barrier (BBB). TfRMAb-TNFR was protective in 6-month-old transgenic APP/PS1 mice in our previous work. However, the effects and safety following delayed chronic TfRMAb-TNFR treatment are unknown. Herein, we initiated the treatment when the male APP/PS1 mice were 10.7 months old (delayed treatment). Mice were injected intraperitoneally with saline, TfRMAb-TNFR, etanercept (non-BBB-penetrating TNFI), or TfRMAb for ten weeks. Biologic TNFIs did not alter hematology indices or tissue iron homeostasis; however, TfRMAb altered hematology indices, increased splenic iron transporter expression, and increased spleen and liver iron. TfRMAb-TNFR and etanercept reduced brain insoluble-amyloid beta (Aβ) 1-42, soluble-oligomeric Aβ, and microgliosis; however, only TfRMAb-TNFR reduced Aβ peptides, Thioflavin-S-positive Aβ plaques, and insoluble-oligomeric Aβ and increased plaque-associated phagocytic microglia. Accordingly, TfRMAb-TNFR improved spatial reference memory and increased BBB-tight junction protein expression, whereas etanercept did not. Overall, despite delayed treatment, TfRMAb-TNFR resulted in a better therapeutic response than etanercept without any TfRMAb-related hematology- or iron-dysregulation in aged APP/PS1 mice.

Functional validation of the simplified in vitro 3D Co-culture based BBB model

Various methods of generating 2D and 3D in vitro blood-brain barrier (BBB) models have previously been published with the objective of developing therapeutics for brain diseases. In general, published methods including our published method demonstrate that in vivo-like semi-permeable barrier can be generated. To further verify that an in vitro BBB model closely represents BBB, functional validation is required. Here, we functionally validate our in vitro 3D BBB model using rituximab as a representative therapeutic antibody and previously published anti-TfR (transferrin receptor) antibodies as representative BBB-penetrating antibodies. We demonstrate that our BBB model can efficiently block rituximab while allowing receptor-mediated transcytosis (RMT) of anti-TfR antibodies. In addition, we showed that RMT efficacy of anti-TfR antibodies with different binding affinity can be displayed using our BBB model. In conclusion, this demonstrates that our BBB model functionally mimics the BBB as well as having BBB-like physical properties, further establishing our BBB model as a screening tool for discovery and development of therapeutics for brain diseases.

Dose-dependent effects of a brain-penetrating iduronate-2-sulfatase on neurobehavioral impairments in mucopolysaccharidosis II mice

Deposition of heparan sulfate (HS) in the brain of patients with mucopolysaccharidosis II (MPS II) is believed to be the leading cause of neurodegeneration, resulting in several neurological signs and symptoms, including neurocognitive impairment. We recently showed that pabinafusp alfa, a blood-brain-barrier-penetrating fusion protein consisting of iduronate-2-sulfatase and anti-human transferrin receptor antibody, stabilized learning ability by preventing the deposition of HS in the CNS of MPS II mice. We further examined the dose-dependent effect of pabinafusp alfa on neurological function in relation to its HS-reducing efficacy in a mouse model of MPS II. Long-term intravenous treatment with low (0.1 mg/kg), middle (0.5 mg/kg), and high (2.0 mg/kg) doses of the drug dose-dependently decreased HS concentration in the brain and cerebrospinal fluid (CSF). A comparable dose-dependent effect in the prevention of neuronal damage in the CNS, and dose-dependent improvements in neurobehavioral performance tests, such as gait analysis, pole test, Y maze, and Morris water maze, were also observed. Notably, the water maze test performance was inversely correlated with the HS levels in the brain and CSF. This study provides nonclinical evidence substantiating a quantitative dose-dependent relationship between HS reduction in the CNS and neurological improvements in MPS II.

Pharmacological property, mechanism of action and clinical study results of Pabinafusp Alfa (Genetical Recombination) (IZCARGO® I.V. Infusion 10 mg) as the therapeutic for Mucopolysaccharidosis type-II (Hunter syndrome)

Mucopolysaccharidosis type II (MPS II) is an X-linked recessive lysosomal storage disease with the accumulation of glycosaminoglycans in tissues and organs throughout the body caused by dysfunction or loss of iduronate-2-sulfatase (IDS), resulting in somatic and central nervous system (CNS) disorders. Although enzyme replacement therapy (ERT) with recombinant human IDS is the current first-line therapy for MPS II, it is not effective for the CNS because intravenously administered enzyme cannot cross the blood-brain barrier (BBB) and thereby does not reach the brain parenchyma. Pabinafusp alfa, approved in March 2021 in Japan, is a recombinant fusion protein composed of human IDS and humanized anti-human transferrin receptor (hTfR) antibody, utilizing the BBB-penetrating technology "J-Brain Cargo®" established by JCR Pharmaceuticals. Nonclinical studies showed that pabinafusp alfa was distributed in the brain of hTfR knock-in mice and monkeys after intravenous administration, and dose-dependently decreased heparan sulfate (HS) glycosaminoglycan deposited in major organs including the brain of MPS II mice. Pabinafusp alfa also suppressed neurodegeneration in cerebellum and hippocampus, leading to the maintenance of spatial learning ability. Phase II/III clinical study conducted in Japan showed that pabinafusp alfa decreased HS concentration in the cerebrospinal fluid, which serves as an efficacy biomarker for central nervous symptoms, and improved or stabilized the developmental age of the patients. Moreover, pabinafusp alfa exerted comparable effects to current ERT in terms of improvement of somatic manifestations. Therefore, pabinafusp alfa is a promising therapeutic option as a BBB-penetrating enzyme for the treatment of patients with neuronopathic MPS II.

Biologic TNF-\u03b1 inhibitors reduce microgliosis, neuronal loss, and tau phosphorylation in a transgenic mouse model of tauopathy

BackgroundTumor necrosis factor-α (TNF-α) plays a central role in Alzheimer’s disease (AD) pathology, making biologic TNF-α inhibitors (TNFIs), including etanercept, viable therapeutics for AD. The protective effects of biologic TNFIs on AD hallmark pathology (Aβ deposition and tau pathology) have been demonstrated. However, the effects of biologic TNFIs on Aβ-independent tau pathology have not been reported. Existing biologic TNFIs do not cross the blood–brain barrier (BBB), therefore we engineered a BBB-penetrating biologic TNFI by fusing the extracellular domain of the type-II human TNF-α receptor (TNFR) to a transferrin receptor antibody (TfRMAb) that ferries the TNFR into the brain via receptor-mediated transcytosis. The present study aimed to investigate the effects of TfRMAb-TNFR (BBB-penetrating TNFI) and etanercept (non-BBB-penetrating TNFI) in the PS19 transgenic mouse model of tauopathy.MethodsSix-month-old male and female PS19 mice were injected intraperitoneally with saline (n = 12), TfRMAb-TNFR (1.75 mg/kg, n = 10) or etanercept (0.875 mg/kg, equimolar dose of TNFR, n = 10) 3 days/week for 8 weeks. Age-matched littermate wild-type mice served as additional controls. Blood was collected at baseline and 8 weeks for a complete blood count. Locomotion hyperactivity was assessed by the open-field paradigm. Brains were examined for phosphorylated tau lesions (Ser202, Thr205), microgliosis, and neuronal health. The plasma pharmacokinetics were evaluated following a single intraperitoneal injection of 0.875 mg/kg etanercept or 1.75 mg/kg TfRMAb-TNFR or 1.75 mg/kg chronic TfRMAb-TNFR dosing for 4 weeks.ResultsEtanercept significantly reduced phosphorylated tau and microgliosis in the PS19 mouse brains of both sexes, while TfRMAb-TNFR significantly reduced these parameters in the female PS19 mice. Both TfRMAb-TNFR and etanercept treatment improved neuronal health by significantly increasing PSD95 expression and attenuating hippocampal neuron loss in the PS19 mice. The locomotion hyperactivity in the male PS19 mice was suppressed by chronic etanercept treatment. Equimolar dosing resulted in eightfold lower plasma exposure of the TfRMAb-TNFR compared with etanercept. The hematological profiles remained largely stable following chronic biologic TNFI dosing except for a significant increase in platelets with etanercept.ConclusionBoth TfRMAb-TNFR (BBB-penetrating) and non-BBB-penetrating (etanercept) biologic TNFIs showed therapeutic effects in the PS19 mouse model of tauopathy.

P53 and P16 Protein Expression Have Prognostic Value in Mantle Cell Lymphomas in the Lyma Trial in the Lysa Group

Introduction: Mantle Cell Lymphomas (MCL) are rare non-Hodgkin lymphomas with often poor outcome. Currently, definitive criteria predicting time to treatment failure and overall survival are based on clinical factors included the mantle cell lymphoma prognostic index (MIPI) and the proliferation index assessed by Ki67 expression. In order to find other predictive parameters we tested 4 immunohistochemical (IHC) markers usually correlated with a more aggressive behavior in tumors in a large series of MCL samples from patients enrolled in LYMA trial and treated with 4 R-DHAP then Rituximab-BEAM and autograft.Methods: The LYMA trial includes 300 patients for whom we obtained specimen suitable for Tissue Micro Arrays (TMA) for 166 patients. On these formalin fixed paraffin embedded diagnostic TMA, immunohistochemistry was performed using p53, Myc, p16 and transferrin receptor (CD71) antibodies . These markers were scored by quantifying the percentage of cells stained on each TMA spot. IHC results were then compared with clinical data base of the patients and with Ki67 expression. For each variable, different cut-offs were studied on progression free survival (PFS) and overall survival (OS).Results: Patients characteristics of the 166 patients were similar to those of the total population of the LYMA trial: age ≤60y (72%), male sex (78%), stage IV (84%), low MIPI score predominant and classic histological type (81%). In univariate analysis, p53 protein expression with a cut-off >30% increased significantly the risk of poor PFS (HR=3.03 [1.66,5.54], p=0.001) as p16 expression with a cut-off > 10% (HR=2.90 [1.56, 5.40], p=0.003). These 2 markers were was also significant for OS (HR=2.49 [1.25, 4.98], p=0.006) for p53 and (HR=3.32 [1.65, 6.68], p=0.002) for p16. In multivariate analysis, p53 and p16 markers remained significant for PFS ajusted or not for the MIPI whereas for OS if we ajust models on MIPI, only P16 was a significant pronostic factor (p=0.0001). If we combined both markers p53 and p16 we could determine 3 groups of patients: low risk group if p16 is <10% and p53<30%, intermediate risk: when one of the 2 risk markers was over the cut-off determined and high risk group when both p53 and p16 markers were over the cut-off determined. In the intermediate risk and high risk groups, the PFS is worse (p=0.009 and ≤0.001 respectively) and in the high risk group, the OS is very poor (HR=6.12 [2.60,14.41] p<0.001). These findings were independant to the Ki67 expression which was significant for both PFS and OS in uni and multivariate analysis in our series. Myc and CD71 markers were not significant on PFS and OS. A correlation was found between the MCL histological subtype classic or blastoid and p53 and p16 markers: blastoid type was more often observed in MCL cases expressing p53 >30% and p16 >10% (p=0.093 and p=0.034 respectively).Conclusion: In 166 patients treated in the LYMA trial, we found that patients with high p53 expression >30% and high p16 expression >10% had a significant shorter PFS and poor OS. It could be then recommended to incorporate p53 and p16 IHC in routine diagnostic practice. Find new novel therapies for these patients presenting with high risk should be one of the next challenges for MCL. DisclosuresRibrag:Roche: Honoraria; Infinity: Honoraria; MSD: Honoraria; Nanostring: Honoraria; Gilead: Honoraria; BMS: Honoraria; ArgenX: Research Funding; Servier: Consultancy, Honoraria; Epizyme: Honoraria. Thieblemont:Roche: Membership on an entity's Board of Directors or advisory committees, Research Funding; Bayer: Membership on an entity's Board of Directors or advisory committees; Abbvie: Membership on an entity's Board of Directors or advisory committees; Janssen: Membership on an entity's Board of Directors or advisory committees; Celgene: Membership on an entity's Board of Directors or advisory committees.