Transferrin Receptor Monoclonal Antibody Research Articles

The Effects of a Blood-Brain Barrier Penetrating Erythropoietin in a Mouse Model of Tauopathy.

Erythropoietin (EPO), a hematopoietic neurotrophin, is a potential therapeutic for Alzheimer's disease (AD) but has limited blood-brain barrier (BBB) permeability. EPO fused to a chimeric transferrin receptor monoclonal antibody (cTfRMAb) enters the brain via TfR-mediated transcytosis across the BBB. We previously showed that cTfRMAb-EPO is protective in a mouse model of amyloidosis, but its effects on tauopathy are not known. Given that amyloid and tau pathology are characteristics of AD, the effects of cTfRMAb-EPO were studied in a tauopathy mouse model (PS19). Six-month-old PS19 mice were injected intraperitoneally with either saline (PS19-Saline; n = 9) or cTfRMAb-EPO (PS19-cTfRMAb-EPO, 10 mg/kg; n = 10); every two or three days on alternate weeks for 8 weeks. Age-matched, saline-treated, wildtype littermates (WT-Saline; n = 12) were injected using the same protocol. After 8 weeks, locomotion, hyperactivity, and anxiety were assessed via the open-field test, and brains were harvested and sectioned. Cerebral cortex, hippocampus, amygdala, and entorhinal cortex sections were analyzed for phospho-tau (AT8) and microgliosis (Iba1). Hippocampal cellular density (H&E) was also assessed. PS19-Saline mice were hyperactive and less anxious compared to WT-Saline mice, and these behavioral phenotypes were significantly reduced in the PS19-cTfRMAb-EPO mice compared to the PS19-Saline mice. cTfRMAb-EPO significantly reduced AT8 load by ≥50% in all of the brain regions analyzed and microgliosis in the entorhinal cortex and amygdala compared to the PS19-Saline mice. Hippocampal pyramidal and granule cell layer density did not differ significantly between the PS19-cTfRMAb-EPO and PS19-Saline mice. This proof-of-concept study demonstrates the therapeutic effects of the BBB-penetrating cTfRMAb-EPO in PS19 mice.

Basic Research on Therapy of Leukemia with Nanoparticles Drug Delivery System Modified by Transferrin Receptor Monoclonal Antibody

To investigate the therapeutic effect of targeted drug-loaded nanoparticles modified by transferrin receptor monoclonal antibody (TfR mAb) on acute leukemia and its potential anti-tumor mechanism. Nanoparticles drug delivery system, which was composed of poly (lactic-co-glycolic acid), poly-l-lysine, polyethylene glycol, TfR mAb (TfR mAb-PLGA-PLL-PEG)-daunorubicin (DNR), was first synthesized. After drug intervention, the intracellular accumulation in leukemia HL60 cells was observed under a fluorescent microscope and concentration of DNR was determined by flow cytometry (FCM). Meanwhile, cell apoptosis rate was measured by FCM and the expression levels of apoptosis related protein Cleaved-caspase 3 was determined by Western blot. Under an inverted fluorescent microscope, intracellular accumulation of DNR autofluorescence in HL60 cells was observed in both TfR mAb-PLGA-PLL-PEG-DNR group and DNR group. FCM analysis showed that the intracellular concentration of DNR in TfR mAb-PLGA-PLL-PEG-DNR group was higher than that in DNR group（P<0.05）. The apoptotic rate of HL60 cells in TfR mAb-PLGA-PLL-PEG-DNR group was higher than that of DNR group（P<0.05）. Moreover, the expression levels of apoptosis-related protein Cleaved-caspase 3 in TfR mAb-PLGA-PLL-PEG-DNR group was significantly higher than that in DNR group（P<0.05）. TfR mAb-PLGA-PLL-PEG nanoparticle drug delivery system can target chemotherapy drugs to leukemia cells and enhance anticancer ability through apoptotic pathway.

Brain targeting of Baicalin and Salvianolic acid B combination by OX26 functionalized nanostructured lipid carriers.

In order to deliver Salvianolic acid B (Sal B) and Baicalin (BA) to the brain tissue to repair neuron damage and improve cerebral ischemia-reperfusion injury (IRI), in our previous study, a nanostructured lipid carrier (NLC) containing BA and Sal B, and modified by the transferrin receptor monoclonal antibody OX26 (OX26-BA/Sal B-NLC) was constructed. The present study is to evaluate its in vitro release behavior, in vitro and in vivo targeting ability, in vitro pharmacodynamics and brain pharmacokinetics. The results showed that the release mechanism of the formulation was in line with the Weibull model release equation. The in-vitro and in-vivo targeting ability study exhibited that OX26 modified formulations was obviously higher than that of non-modified and solution groups. The results of in vitro preliminary study to investigate the protective effect of OX26-BA/Sal B-NLC on oxygen-glucose deprivation/reperfusion injured cells showed that it could decrease the injury. Furthermore, the results of brain microdialysis study showed that the OX26-modified preparation group could significantly increase the content of BA in the brain. In the solution group and the unmodified group, Sal B can only be detected at few time points, while OX26-modified BA/Sal B-NLC could be detected within 4 h. These results indicating that OX26-modified NLC can promote the brain delivery of Sal B and BA combination.

Magnetic polycarbonate microspheres for tumor-targeted delivery of tumor necrosis factor

Objective: The specific expression of transferrin receptor can represent a diagnostic tool or therapeutic target in solid tumors expressing this antigen. Herein, the human transferrin receptor monoclonal antibody (T9) was investigated as a tumor-targeting group for active targeted-drug delivery systems.Materials and methods: A tumor-targeted conjugate T9-TNF was synthesized by the attachment of both human transferrin receptor monoclonal antibody (T9) as a tumor-targeting group and human tumor necrosis factor-α (TNF) as an anti-cancer drug to two terminated hydroxyl groups of poly(ethylene glycol). Subsequently, a solvent evaporation technique was adopted to produce anti-cancer magnetic polymer microspheres T9-TNF-PC-M containing T9-TNF and Fe3O4 magnetic ultrafine powders (M) using poly(trimethylene carbonate-co-5,5-dimethyl trimethylene carbonate) (PC, P(TMC-co-DTC)) as a polymeric carrier.Results and discussion: These magnetic polycarbonate microspheres possessed a steady TNF release rate in phosphate buffer saline solution, strong magnetic responsiveness and high T9-TNF loading capacity. In vitro cytotoxicity assays demonstrated the microspheres T9-TNF-PC-M and conjugate T9-TNF were strongly inhibitory to the human hepatic carcinoma (Bel-7204) cells. In vivo site-specific therapy in nude mice with human hepatic carcinoma indicated that the microspheres T9-TNF-PC-M and conjugate T9-TNF possessed markedly higher anti-tumor activity against Bel-7204 in mice than that of TNF.Conclusions: These results indicated that the magnetic polycarbonate microspheres were suitable as the potential-targeted treatment for hepatic carcinoma therapeutics.

Targeting Parkinson’s - Tyrosine Hydroxylase and Oxidative Stress as Points of Interventions

Parkinson's disease (PD) is characterized by the progressive loss of the dopaminergic neurons leading to decrease in striatal dopamine (DA) levels. In the present review, our focus was on recent advances in the treatment procedures of PD to achieve an increase in deficient tyrosine hydroxylase (TH) activity and/or expression. Stimulation of residual TH activity by the cofactors, 6R-L-erythro-tetrahydrobiopterin (BPH4) or NADH, or by brain transplant of natural TH-containing cells (fetal substantia nigra) or genetically engineered TH-containing cells, has been tried experimentally and clinically lately. As a promising approach to the gene therapy, intrastriatal expression of DAsynthesizing enzymes through transduction with separate adeno-associated virus (AAV) vectors/ marrow stromal cells (MSCs) or nonviral intravenous administration of rat transferrin receptor monoclonal antibody (TfRmAb)-targeted PEGylated immunoliposomes (PILs) has been found to be effective in animal models. Oxidative stress has been identified as one of the intermediary risk factors that could initiate and/or promote degeneration of DA neurons. TH itself is a prime target of oxidative/nitrosative injury. Certain superoxide dismutase and catalase mimetic prevented nitration of TH in cultured dopaminergic neurons. Therefore, development of therapeutic agents that can prevent formation of or specifically remove nitrating agents without interfering with normal neuronal function may protect protein from inactivation and provide means of limiting neuronal injury in PD. Non-pharmacological approaches such as diet therapy or use of active constituents of plants and phytomedicines have also emerged as a new - area of high interest. New treatment strategies for TH dysfunction rectification, a provision for neuroprotection in PD, seem to be on the horizon with many therapies under investigation.

Transbuccal Delivery of CNS Therapeutic Nanoparticles: Synthesis, Characterization, and In Vitro Permeation Studies

This work utilized polyamidoamine (PAMAM) dendrimer G4.5 as the underlying carrier to construct CNS therapeutic nanoparticles and explored the buccal mucosa as an alternative absorption site for administration of the dendritic nanoparticles. Opioid peptide DPDPE was chosen as a model CNS drug. It was coupled to PAMAM dendrimer G4.5 with polyethylene glycol (PEG) or with PEG and transferrin receptor monoclonal antibody OX26 (i.e., PEG-G4.5-DPDPE and OX26-PEG-G4.5-DPDPE). The therapeutic dendritic nanoparticles labeled with 5-(aminoacetamido) fluorescein (AAF) were studied for transbuccal transport using a vertical Franz diffusion cell system mounted with porcine buccal mucosa. For comparison, AAF-labeled PAMAM dendrimers G3.5 and G4.5, and fluorescein isothiocynate (FITC)-labeled G3.0 and G4.0 were also tested for transbuccal delivery. The permeability of PEG-G4.5 (AAF)-DPDPE and OX26-PEG-G4.5(AAF)-DPDPE were on the order of 10(-7) - 10(-6) cm/s. Coadministration of bile salt sodium glycodeoxycholate (NaGDC) enhanced the permeability of dendritic nanoparticles by multiple folds. Similarly, a multifold increase of permeability of dendritic nanoparticles across the porcine buccal mucosal resulted from the application of mucoadhesive gelatin/PEG semi-interpenetrating network (sIPN). These results indicate that transbuccal delivery is a possible route for administration of CNS therapeutic nanoparticles.

Commentary [Research Highlights

Drug delivery to the central nervous system remains a vexing problem because of the presence of the blood-brain barrier (BBB), whose endothelial cell tight junctions limit the paracellular flux of hydrophilic molecules. One solution may be vector-mediated delivery to the brain. This employs chimeric peptide technology, wherein the drug is conjugated to a molecular carrier of protein nature (e.g. cationized albumin or a transferrin receptor antibody). Transferrin receptor antibodies selectively target BBB endothelium due to the high levels of receptor expressed by these cells, thereby triggering receptor-mediated transport across the BBB via transcytosis. Chitosan, a naturally occurring, abundant, and biocompatible polysaccharide has found widespread pharmaceutical application. In particular, the cationic nature of chitosan facilitates its interaction with negative charges on the brain endothelium, Building on their previous work on brain-deliverable chitosan-polyethylene glycol nanoparticles functionalized with monoclonal anti-transferrin antibody, Karatas and colleagues have now designed caspase-3 inhibitor-loaded chitosan nanospheres conjugated with an anti-mouse transferrin receptor monoclonal antibody that selectively recognizes the transferrin receptor type 1 on the cerebral vasculature. Caspase-3 has been implicated in neuronal cell death in cerebral ischemia, as well as in the pathophysiology of other neurological disorders. When given intravenously, the caspase-3-loaded nanospheres were rapidly transported across the BBB and dose-dependently decreased infarct volume, neurological deficit, and ischemiainduced caspase-3 activity in mice subjected to focal cerebral ischemia/reperfusion. Because significant opening of the BBB starts only 6 h after ischemia/reperfusion, the rapid transfer of nanospheres to the brain was not likely caused by an increased permeability of the BBB. Similarly, nanospheres inhibited physiological caspase-3 activity during development in the neonatal mouse cerebellum on postnatal day 17, after closure of the BBB. These observations convincingly demonstrate that transferrin monoclonal antibody-conjugated chitosan nanospheres are an efficient delivery system for bringing neuroprotective, small peptide drugs into the brain. This opens intriguing new avenues for the treatment of central nervous system disorders in which the administration of therapeutic agents is handicapped by insufficient diffusion across the BBB. Further studies are eagerly awaited to see if this technology will be applicable to polypeptide factors, for example, brain-derived neurotrophic factor and ciliary neurotrophic factor.

A Nanomedicine Transports a Peptide Caspase-3 Inhibitor across the Blood–Brain Barrier and Provides Neuroprotection

Caspases play an important role as mediators of cell death in acute and chronic neurological disorders. Although peptide inhibitors of caspases provide neuroprotection, they have to be administered intracerebroventricularly because they cannot cross the blood-brain barrier (BBB). Herein, we present a nanocarrier system that can transfer chitosan nanospheres loaded with N-benzyloxycarbonyl-Asp(OMe)-Glu(OMe)-Val-Asp(OMe)-fluoromethyl ketone (Z-DEVD-FMK), a relatively specific caspase-3 inhibitor, across BBB. Caspase-3 was chosen as a pharmacological target because of its central role in cell death. Polyethylene glycol-coated nanospheres were conjugated to an anti-mouse transferrin receptor monoclonal antibody (TfRMAb) that selectively recognizes the TfR type 1 on the cerebral vasculature. We demonstrate with intravital microscopy that this nanomedicine is rapidly transported across the BBB without being measurably taken up by liver and spleen. Pre- or post-treatment (2 h) with intravenously injected Z-DEVD-FMK-loaded nanospheres dose dependently decreased the infarct volume, neurological deficit, and ischemia-induced caspase-3 activity in mice subjected to 2 h of MCA occlusion and 24 h of reperfusion, suggesting that they released an amount of peptide sufficient to inhibit caspase activity. Similarly, nanospheres inhibited physiological caspase-3 activity during development in the neonatal mouse cerebellum on postnatal day 17 after closure of the BBB. Neither nanospheres functionalized with TfRMAb but not loaded with Z-DEVD-FMK nor nanospheres lacking TfRMAb but loaded with Z-DEVD-FMK had any effect on either paradigm, suggesting that inhibition of caspase activity and subsequent neuroprotection were due to efficient penetration of the peptide into brain. Thus, chitosan nanospheres open new and exciting opportunities for brain delivery of biologically active peptides that are useful for the treatment of CNS disorders.

Engineering and expression of a chimeric transferrin receptor monoclonal antibody for blood–brain barrier delivery in the mouse

Protein therapeutics may be delivered across the blood-brain barrier (BBB) by genetic fusion to a BBB molecular Trojan horse. The latter is an endogenous peptide or a peptidomimetic monoclonal antibody (MAb) against a BBB receptor, such as the insulin receptor or the transferrin receptor (TfR). Fusion proteins have been engineered with the MAb against the human insulin receptor (HIR). However, the HIRMAb is not active against the rodent insulin receptor, and cannot be used for drug delivery across the mouse BBB. The rat 8D3 MAb against the mouse TfR is active as a drug delivery system in the mouse, and the present studies describe the cloning and sequencing of the variable region of the heavy chain (VH) and light chain (VL) of the rat 8D3 TfRMAb. The VH and VL were fused to the constant region of mouse IgG1 heavy chain and mouse kappa light chain, respectively, to produce a new chimeric TfRMAb. The chimeric TfRMAb was expressed in COS cells following dual transfection with the heavy and light chain expression plasmids, and was purified by protein G affinity chromatography. The affinity of the chimeric TfRMAb for the murine TfR was equal to the 8D3 MAb using a radio-receptor assay and mouse fibroblasts. The chimeric TfRMAb was radio-labeled and injected into mice for a pharmacokinetics study of the clearance of the chimeric TfRMAb. The chimeric TfRMAb was rapidly taken up by mouse brain in vivo at a level comparable to the rat 8D3 MAb. In summary, these studies describe the genetic engineering, expression, and validation of a chimeric TfRMAb with high activity for the mouse TfR, which can be used in future engineering of therapeutic fusion proteins for BBB drug delivery in the mouse.

Transferrin- and transferrin-receptor-antibody-modified nanoparticles enable drug delivery across the blood–brain barrier (BBB)

Human serum albumin (HSA) nanoparticles were manufactured by desolvation. Transferrin or transferrin receptor monoclonal antibodies (OX26 or R17217) were covalently coupled to the HSA nanoparticles using the NHS-PEG-MAL-5000 crosslinker. Loperamide was used as a model drug since it normally does not cross the blood–brain barrier (BBB) and was bound to the nanoparticles by adsorption. Loperamide-loaded HSA nanoparticles with covalently bound transferrin or the OX26 or R17217antibodies induced significant anti-nociceptive effects in the tail-flick test in ICR (CD-1) mice after intravenous injection, demonstrating that transferrin or these antibodies covalently coupled to HSA nanoparticles are able to transport loperamide and possibly other drugs across the BBB. Control loperamide-loaded HSA nanoparticles with IgG2a antibodies yielded only marginal effects.

The p14 Fusion-associated Small Transmembrane (FAST) Protein Effects Membrane Fusion from a Subset of Membrane Microdomains

The p14 Fusion-associated Small Transmembrane (FAST) Protein Effects Membrane Fusion from a Subset of Membrane Microdomains

Imaging Gene Expression in Regional Brain Ischemia in Vivo with a Targeted [111In]-Antisense Radiopharmaceutical

The gene encoding glial fibrillary acidic protein (GFAP) is downregulated 24 hr after reversible brain ischemia, such as with a middle cerebral artery occlusion (MCAO). The in vivo imaging of decreased GFAP gene expression in cerebral ischemia was examined in the present studies using a targeted peptide nucleic acid (PNA), which was labeled with (111)In, and which hybridized to nucleotides 20-37 of the rat GFAP mRNA. The PNA was monobiotinylated, and was attached to a monoclonal antibody (MAb) to the transferrin receptor (TfR) via a biotin-streptavidin linkage. The TfR MAb enables trans-membrane transport of the PNA antisense radiopharmaceutical from blood to the cytosol of brain cells. The decreased GFAP gene expression at 24 hr after a 1-hr reversible MCAO was confirmed by immunocytochemistry. The [(111)In]-labeled PNA - MAb conjugate was administered intravenously to anesthetized rats at 24 hr after the 1-hr reversible MCAO, and the brain uptake of the targeted antisense imaging agent was decreased relative to brain regions outside of the infarct zone. These studies provide evidence that decreased expression of a target gene in brain can be imaged in vivo with a sequence-specific PNA, provided the antisense radiopharmaceutical is delivered across cell membranes with a receptor-specific targeting agent.

Imaging Gene Expression in Regional Brain Ischemia In Vivo with a Targeted [&lt;SUP&gt;111&lt;/SUP&gt;In]-Antisense Radiopharmaceutical

The gene encoding glial fibrillary acidic protein (GFAP) is downregulated 24 hr after reversible brain ischemia, such as with a middle cerebral artery occlusion (MCAO). The in vivo imaging of decreased GFAP gene expression in cerebral ischemia was examined in the present studies using a targeted peptide nucleic acid (PNA), which was labeled with (111)In, and which hybridized to nucleotides 20-37 of the rat GFAP mRNA. The PNA was monobiotinylated, and was attached to a monoclonal antibody (MAb) to the transferrin receptor (TfR) via a biotin-streptavidin linkage. The TfR MAb enables trans-membrane transport of the PNA antisense radiopharmaceutical from blood to the cytosol of brain cells. The decreased GFAP gene expression at 24 hr after a 1-hr reversible MCAO was confirmed by immunocytochemistry. The [(111)In]-labeled PNA - MAb conjugate was administered intravenously to anesthetized rats at 24 hr after the 1-hr reversible MCAO, and the brain uptake of the targeted antisense imaging agent was decreased relative to brain regions outside of the infarct zone. These studies provide evidence that decreased expression of a target gene in brain can be imaged in vivo with a sequence-specific PNA, provided the antisense radiopharmaceutical is delivered across cell membranes with a receptor-specific targeting agent.

Stability of the Disulfide Bond in an Avidin-Biotin Linked Chimeric Peptide During in vivo Transcytosis Through Brain Endothelial Cells

Drug delivery of potential neuropharmaceuticals with poor intrinsic permeability through the blood-brain barrier (BBB), such as peptides, is facilitated by coupling to a vector that undergoes receptor-mediated transcytosis through the endothelial cells of brain microvessels. When cleavable disulfide linkers are used in the synthesis of such "chimeric peptides", it is crucial that the S-S-bridge is stable during transcytosis. Cleavage within endothelial cells could result in sequestration of the drug moiety instead of passage through the BBB. In the present study the metabolically stable opioid peptide [3 H]DALDA ([3 H]Tyr-DArg-Phe-Lys-NH2 ) was used as a model drug. It was monobiotinylated with the cleavable biotin reagent sulfosuccinimidyl 2-(biotinamido)ethyl-1,3'-dithiopropionate (NHS-SS-biotin) to obtain bio-[3 H]DALDA. The biotinylated peptide was then bound to a vector for brain delivery after intravenous injection in rats, a covalent conjugate of streptavidin and the transferrin receptor monoclonal antibody, OX26. Compared to peptide without vector, brain uptake of bio-[3 H]DALDA after was increased 18-fold to reach 0.12% of the injected dose per g tissue. Transcranial microdialysis was performed for 60 min after an intravenous bolus of chimeric peptide, followed by reverse phase HPLC of dialysate. Stability of the chimeric peptide during transport through the BBB into brain extracellular fluid was concluded from the absence of a peptide peak generated by disulfide cleavage.

Transport of transferrin across the blood-thymus barrier in young rats

The interaction of transferrin-peroxidase (Tf-HRP) with the capillary endothelium of the rat thymus was analyzed by diaminobenzidine (DAB) cytochemistry and electron microscopy. The thoracic aortas of young rats were cannulated and the upper bodies perfused with the Tf-HRP conjugate. In the thymus, plasmalemmal vesicles of the endothelium mediated the endocytosis and transport of Tf-HRP. Transcytosis of Tf-HRP appeared to occur by micropinocytosis, without morphological evidence of involvement by endothelial endosomes. DAB reaction product was commonly present in the subendothelial interstitial space and, in addition, was often localized in clathrin coated pits and vesicles in epithelial reticular cells that surround the thymic capillaries. In perfusions done at 4 °C, no binding of Tf-HRP to the lumenal membranes of capillaries was detected. The transport of Tf-HRP across the capillary endothelium in the thymus was not inhibited by competition with excess native transferrin; however, the uptake of Tf-HRP by epithelial reticular cells was completely inhibited by excess transferrin. Transferrin receptors were localized in the thymus by indirect immunocytochemistry using OX-26, a mouse anti-rat transferrin receptor monoclonal antibody. No transferrin receptors were detected on the capillary endothelium but diffuse reaction product was localized on the subjacent epithelial reticular cells. These results indicate that transport of Tf-HRP across the thymus capillary wall is independent of transferrin receptors at the level of the endothelial cells but that subsequent uptake of Tf-HRP by epithelial reticular cells is a transferrin receptor dependent process.

The effects of transferrin receptor antibody, transferrin receptor antibody bound to Pseudomonas exotoxin and transforming growth factor-alpha bound to Pseudomonas exotoxin on human tenon's capsule fibroblast proliferation.

Pharmacological agents which modulate the wound healing process by the inhibition of proliferation of fibroblasts may improve the success of glaucoma filtration surgery. Since cell proliferation is essential to the wound healing process, we targeted the surface receptors that are associated with proliferating cells. We present the effects of three such agents-purified mouse anti-human transferrin receptor monoclonal antibody 42/6 (anti-TfR-42/6), anti-transferrin monoclonal antibody bound to a Pseudomonas exotoxin (anti-TfR-PE40) and transforming growth factor-alpha Pseudomonas exotoxin (TGF-alpha-PE40)--on human fibroblasts from Tenon's capsule. The inhibition of human subconjunctival fibroblast proliferation by anti-TfR-42/6 (with a concentration up to 25 micrograms/ml) and by anti-TfR-PE40 and TGF-alpha-PE40 (both with a concentration range of 5000-0.00001 micrograms/ml) was determined by colorimetric (OD), and cell counting (CC) assays over a 9-day period. Neither anti-TfR-42/6 nor anti-TfR-PE40 had an antiproliferative effect on the fibroblasts. TGF-alpha-PE40 demonstrated an antiproliferative effect in a dose response manner. The mean 50% inhibitory dose (ID50) by OD was 32.91 micrograms/ml, while the ID50 by CC was 27.88 micrograms/ml. EGF was used as a negative control for TGF-alpha-PE40 toxin. The inhibitory effect of the toxin conjugate was completely blocked by the addition of 1000 micrograms/ml of EGF. These in vitro studies show that TGF-alpha-PE40 may be useful in modulating the proliferation of human ocular fibroblasts; they also give some indication of drug dosages for future in vivo testing.

Analysis and isolation of human transferrin receptor using the OKT-9 monoclonal antibody covalently crosslinked to magnetic beads

A method is described for the use of magnetic beads as a solid phase for the immunoprecipitation of labeled proteins. The anti-human transferrin receptor monoclonal antibody OKT-9 has been coupled to sheep anti-mouse IgG1-coated magnetic beads using the crosslinking agent dimethyl pimelimidate. The transferrin receptor is readily detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography following immunoprecipitation from 35S-labeled cell lysates. When compared with precipitations using OKT-9 coupled to protein G Sepharose the magnetic beads result in fewer nonspecific bands. The protocol described is generally applicable to the identification of labeled proteins. In addition, because magnetic beads are amenable to covalent crosslinking procedures they can be used for the purification of proteins from complex mixtures. Covalently crosslinked OKT-9 sheep anti-mouse IgG1-coated magnetic beads have been used to affinity purify unlabeled transferrin receptor from cell lysates giving comparable purity and yield to transferrin Sepharose isolated transferrin receptor. The major advantages offered by magnetic beads compared to conventional affinity matrices are low nonspecific binding and the rapidity with which the purification can be performed.

In situ immunocytochemical staining method for haemopoietic cells grown in vitro

Characterization and enumeration of haemopoietic cells grown in vitro is routinely performed either on unstained cultures or on cultures stained by cytochemical agents. This report describes a novel method for the immunocytochemical analysis of cells grown in plasma clots. The stain is performed in situ by subjecting the whole plasma clot in the culture dish to the staining procedure. The growth of early haemopoietic progenitor cells was monitored in cultures from normal human peripheral blood and proliferating progenitor cells were identified with an anti-human transferrin receptor monoclonal antibody followed by a two-layer immunoperoxidase stain. The number of transferrin receptor positive clusters demonstrable after 5 days of culture was similar to the number of haemopoietic colonies detectable after 12 days of culture.

Insulin stimulates cellular iron uptake and causes the redistribution of intracellular transferrin receptors to the plasma membrane.

Insulin stimulates the accumulation of iron by isolated fat cells by increasing the uptake of diferric transferrin. Analysis of the cell-surface binding of diferric 125I-transferrin indicated that insulin caused a 3-fold increase in the cell surface number of transferrin receptors. This result was confirmed by the demonstration that insulin increases the binding of an anti-rat transferrin receptor monoclonal antibody (OX-26) to the surface of fat cells. The basis of this effect of insulin was examined by investigating the number of transferrin receptors in membrane fractions isolated from disrupted fat cells. Two methods were employed. First the binding isotherm of diferric 125I-transferrin to the isolated membranes was studied. Second, the membranes were solubilized with detergent, and the number of transferrin receptors was measured by immunoblotting using the monoclonal antibody OX-26. It was observed that insulin treatment of intact fat cells resulted in an increase in the number of transferrin receptors located in the isolated plasma membrane fraction of the disrupted fat cells. Furthermore, the increase in the number of plasma membrane transferrin receptors was associated with a concomitant decrease in the transferrin receptor number in a low density microsome fraction previously shown to consist of intracellular membranes. This redistribution of transferrin receptors between cellular membrane fractions in response to insulin is remarkably similar to the regulation by insulin of glucose transporters and type II insulin-like growth factor receptors. We conclude that insulin stimulates fat cell iron uptake by a mechanism that may involve the redistribution of transferrin receptors from an internal membrane compartment (low density microsomes) to the cell surface (plasma membrane).

Inhibition of cell growth by monoclonal anti-transferrin receptor antibodies.

Five anti-murine transferrin receptor monoclonal antibodies have been characterized with respect to immunoglobulin class, effects on binding of transferrin, and effects on AKR1 lymphoma cell growth in vitro. The immunoglobulin M (IgM) antibodies, but not the IgG antibodies, prevent cell growth. We suggest that the profound effects of the IgM antibodies on cell growth are probably due to extensive cross-linking of cell surface receptors. In support of this, we are able to mimic the growth-inhibiting effects of the IgM antibodies by adding antiimmunoglobulin to an IgG antibody. By flow microfluorimetry, we show that an IgG antibody by itself induces up to a 10-fold downward regulation in the cell surface transferrin receptor, which is accompanied by accelerated receptor degradation. A similar downward regulation is seen in mutant cells resistant to growth inhibition by an IgM antibody, when grown in the selecting antibody. Wild-type cells grown in the presence of IgM antibody do not show receptor downward regulation. Inhibitory effects of antibody plus antiimmuoglobulin on mutant cells are also consistent with extensive cross-linking causing inhibition of growth.