Advanced Molecular Dynamics Approaches to Model a Tertiary Complex APRIL/TACI with Long Glycosaminoglycans.

Glycosaminoglycans (GAGs) are linear anionic periodic polysaccharides participating in a number of biologically relevant processes in the extracellular matrix via interactions with their protein targets. Due to their periodicity, conformational flexibility, pseudo-symmetry of the sulfation pattern, and the key role of electrostatics, these molecules are challenging for both experimental and theoretical approaches. In particular, conventional molecular docking applied for GAGs longer than 10-mer experiences severe difficulties. In this work, for the first time, 24- and 48-meric GAGs were docked using all-atomic repulsive-scaling Hamiltonian replica exchange molecular dynamics (RS-REMD), a novel methodology based on replicas with van der Waals radii of interacting molecules being scaled. This approach performed well for proteins complexed with oligomeric GAGs and is independent of their length, which distinguishes it from other molecular docking approaches. We built a model of long GAGs in complex with a proliferation-inducing ligand (APRIL) prebound to its receptors, the B cell maturation antigen and the transmembrane activator and calcium modulator and cyclophilin ligand interactor (TACI). Furthermore, the prediction power of the RS-REMD for this tertiary complex was evaluated. We conclude that the TACI-GAG interaction could be potentially amplified by TACI's binding to APRIL. RS-REMD outperformed Autodock3, the docking program previously proven the best for short GAGs.

Study on the Mechanism of Selective Interaction of BR3 and BCMA with BAFF and APRIL.

BACKGROUND: B-cell activating factor (BAFF) and a proliferation-inducing ligand (APRIL) can activate signaling pathways by binding to specific receptors. BR3 (BAFF receptor) shows a unique selectivity for BAFF ligand, while B-cell maturation antigen (BCMA) exhibits a stronger interaction between APRIL-BCMA rather than BAFF-BCMA interaction. OBJECTIVE: The combined domains were fused with IgG1 Fc to better understand which domain affects the selective interaction of the receptor with BAFF and APRIL. METHODS: Since BR3 and BCMA both contain cysteine-rich repeat domains (CRD) with DxL motif, the binding domains of BR3 and BCMA were segmented into two parts in this study. BR3-1 (CFDLLVRHGVAC) and BCMA-1 (YFDSLLHACIPC) contained the conservative DxL motif, while BR3-2 (GLLRTPRPKPA) and BCMA-2 (QLRCSSNTPPLT) were adjacent to the CRDs yet still joined with BR3-1 and BCMA-1. Affinity between all possible combinations was then tested. RESULTS: The affinity of BR3-1-BCMA-2-Fc and BR3-1-BR3-2-Fc for BAFF was higher than BCMA-1-BR3-2-Fc and BCMA-1-BCMA-2-Fc. Moreover, BR3-1-BCMA-2-Fc and BCMA-1-BCMA- 2-Fc had affinity for APRIL, while BR3-1-BR3-2-Fc and BCMA-1-BR3-2-Fc hardly interacted with APRIL. CONCLUSION: BR3-1 region played a key role for interaction with BAFF, while BCMA-1 region exhibited weaker binding with BAFF. BCMA-2 region having an α-helix might contribute towards selectivity of APRIL-BCMA binding and BR3-2 rigid region had deleterious effects on the APRIL-BR3 interaction. These results provide comprehensive insights of the mechanism of selective interactions, and may promote specific antagonist design in the future.

Structural prediction of antibody-APRIL complexes by computational docking constrained by antigen saturation mutagenesis library data.

IgA nephropathy (IgAN) is the most prevalent cause of primary glomerular disease worldwide, and the cytokine A PRoliferation-Inducing Ligand (APRIL) is emerging as a key player in IgAN pathogenesis and disease progression. For a panel of anti-human APRIL antibodies with known antagonistic activity, we sought to define their structural mode of engagement to understand molecular mechanisms of action and aid rational antibody engineering. Reliable computational prediction of antibody-antigen complexes remains challenging, and experimental methods such as X-ray co-crystallography and cryoEM have considerable technical, resource, and throughput barriers. To overcome these limitations, we implemented an integrated and accessible experimental-computational workflow to more accurately predict structures of antibody-APRIL complexes. Specifically, a yeast surface display library encoding site-saturation mutagenized surface positions of APRIL was screened against a panel of anti-APRIL antibodies to rapidly obtain a comprehensive biochemical profile of mutational impact on binding for each antibody. The experimentally derived mutational profile data were used as quantitative constraints in a computational docking workflow optimized for antibodies, resulting in robust structural models of antibody-antigen complexes. The model results were confirmed by solving the cocrystal structure of one antibody-APRIL complex, which revealed strong agreement with our model. The models were used to rationally select and engineer one antibody for cross-species APRIL binding, which quite often aids further testing in relevant animal models. Collectively, we demonstrate a rapid, integrated computational-experimental approach to robustly predict antibody-antigen structures information, which can aid rational antibody engineering and provide insights into molecular mechanisms of action.

An APRIL-based chimeric antigen receptor for dual targeting of BCMA and TACI in multiple myeloma.

B-cell maturation antigen (BCMA) is a promising therapeutic target for multiple myeloma (MM), but expression is variable, and early reports of BCMA targeting chimeric antigen receptors (CARs) suggest antigen downregulation at relapse. Dual-antigen targeting increases targetable tumor antigens and reduces the risk of antigen-negative disease escape. "A proliferation-inducing ligand" (APRIL) is a natural high-affinity ligand for BCMA and transmembrane activator and calcium-modulator and cyclophilin ligand (TACI). We quantified surface tumor expression of BCMA and TACI on primary MM cells (n = 50). All cases tested expressed BCMA, and 39 (78%) of them also expressed TACI. We engineered a third-generation APRIL-based CAR (ACAR), which killed targets expressing either BCMA or TACI (P < .01 and P < .05, respectively, cf. control, effector-to-target [E:T] ratio 16:1). We confirmed cytolysis at antigen levels similar to those on primary MM, at low E:T ratios (56.2% ± 3.9% killing of MM.1s at 48 h, E:T ratio 1:32; P < .01) and of primary MM cells (72.9% ± 12.2% killing at 3 days, E:T ratio 1:1; P < .05, n = 5). Demonstrating tumor control in the absence of BCMA, we maintained cytolysis of primary tumor expressing both BCMA and TACI in the presence of a BCMA-targeting antibody. Furthermore, using an intramedullary myeloma model, ACAR T cells caused regression of an established tumor within 2 days. Finally, in an in vivo model of tumor escape, there was complete ACAR-mediated tumor clearance of BCMA+TACI- and BCMA-TACI+ cells, and a single-chain variable fragment CAR targeting BCMA alone resulted in outgrowth of a BCMA-negative tumor. These results support the clinical potential of this approach.

Selective Binding BAFF/APRIL by the In and Outside Conservative Region of BCMA.

BACKGROUND: BAFF and APRIL are members of TNF superfamily. They play vital roles in the pathogenesis of autoimmune diseases. BCMA, a receptor, shows higher affinity for APRIL than for BAFF. Previous studies found that ligand binding specificity of BCMA may be determined by sequence outside DxL motif. OBJECTIVE: Investigate the contribution of a segment outside the DxL motif of BCMA for binding with ligands. METHOD: In this study, the conservative region of BCMA was divided into two segments: BCMA1 (NEYFDSLLHACIPC), a segment of the DXL motif and BCMA2 (QLRCSSNTPPLT), a segment outside of the DXL motif. Two peptides corresponding to the two segments were synthesized and their contribution to the ligands binding were detected by competitive ELISA. BCMA1-Fc fusion protein was also constructed, purified and analyzed by indirect and competitive ELISA. RESULTS: BCMA2 had no inhibiting effect on the interaction of BCMA-Fc and BCMA1-Fc with BAFF, but, it inhibited 22.5% and 15.2% of the interaction of BCMA-Fc and BCMA1-Fc with mAPRIL respectively. The binding rates of BCMA1-Fc for BAFF were 91.7%, but 80.6% for mAPRIL, suggesting that BCMA1-Fc without BCMA2, bound BAFF well and less efficiently to mAPRIL. CONCLUSION: These results suggest that BCMA2 outside of the conservative DxL motif of BCMA may play an important role in the binding selectivity to its ligands.

Characterization of Lamprey BAFF-like Gene: Evolutionary Implications.

BAFF (TNF superfamily [TNFSF] 13B/Blys) and APRIL (TNFSF13) are important regulatory factors for lymphocyte activation and survival in mammals. A BAFF/APRIL-like relative called BAFF- and APRIL-like molecule (BALM) has also been identified in cartilaginous and bony fishes, and we report in this study a BAFF-like gene in lampreys. Our phylogenetic analysis of these genes and a related TNFSF12 gene called TNF-like weak inducer of apoptosis (TWEAK) suggest that, whereas an ancestral homolog of BAFF and APRIL was already present in a common ancestor of jawed and jawless vertebrates, TWEAK evolved early on in the jawed vertebrate lineage. Like mammalian BAFF and APRIL, the lamprey BAFF-like gene is expressed in T-like, B-like, and innate immune cells. The predicted protein encoded by this BAFF-like gene in lampreys exhibits higher sequence similarity with mammalian BAFF than APRIL. Correspondingly, we find BAFF orthologs in all of the jawed vertebrate representatives that we examined, although APRIL and/or BALM orthologs are not identifiable in certain jawed vertebrates. For example, BALM is not identifiable in tetrapods, and APRIL is not identifiable in several bony fishes or in birds, the latter of which also lack a TWEAK-like gene. Our analysis further suggests that a hybrid molecule called TWE-PRIL, which is a product of an in-genomic fusion between APRIL and TWEAK genes evolved early in mammalian evolution.

Molecular Characterization of Equine APRIL and its Expression Analysis During the Adipogenic Differentiation of Equine Adipose-Derived Stem Cell In Vitro.

A proliferation inducing ligand (APRIL) is a member of the TNF superfamily. It shares two receptors with B-cell activating factor (BAFF), B-cell maturation antigen (BCMA), and transmembrane activator and CAML interactor (TACI). Herein, the equine APRIL was identified from equine adipose-derived stem cell (ASC), and the protein expression of APRIL and its related molecules were detected during the adipogenic differentiation of equine ASC in vitro. The equine APRIL gene was located on chromosome 11, spans 1852 base pairs (bp). Its open reading frame covers 753 bp, encoding a 250-amino acid protein with the typical TNF structure domain. During the two weeks' adipogenic differentiation of equine ASC, although the protein expression of APRIL and TACI had an insignificant change, that of BCMA increased significantly. Moreover, with the addition of recombinant protein His6-sAPRIL, a reduced differentiation of equine ASC toward adipocyte was detected. These results may provide the basis for investigating the role of APRIL in ASC adipogenic differentiation.

Molecular Cloning, Recombinant Expression, and Funtional Characterization of APRIL (TNFSF13) in Cat (felis catus).

A proliferation-inducing ligand (APRIL) is a critical member of the tumor necrosis factor (TNF) superfamily, which is involved in immune regulation. In the present study, the cDNA of cat APRIL (cAPRIL) was successfully amplified. Sequence analysis showed that the open reading frame (ORF) of cAPRIL contains a putative furin protease cleavage site (R-R-K-R), a conserved putative N-glycosylation site (Asn(124)), and two conservative cysteine residues (Cys(196) and Cys(211)). Real-time quantitative PCR (qPCR) analysis revealed that cAPRIL could be detected in various tissues. The phylogenetic analysis and predicted three dimensional (3D) structure revealed that it is similar to its counterparts. The extracellular soluble domain of the cAPRIL (csAPRIL) fragment was cloned into the expression vector pET43.1a. SDS-PAGE and Western blotting analysis indicated a high-level expression of csAPRIL protein in Escherichia coli BL21 (DE3). MTT assays revealed that purified recombinant csAPRIL protein was able to stimulate proliferation of mouse B-cells. These findings indicate that cAPRIL plays an important role in proliferation of B-cells and provide the basis for investigation on the roles of APRIL in this important domestic species.

Stoichiometry of Heteromeric BAFF and APRIL Cytokines Dictates Their Receptor Binding and Signaling Properties.

The closely related TNF family ligands B cell activation factor (BAFF) and a proliferation-inducing ligand (APRIL) serve in the generation and maintenance of mature B-lymphocytes. Both BAFF and APRIL assemble as homotrimers that bind and activate several receptors that they partially share. However, heteromers of BAFF and APRIL that occur in patients with autoimmune diseases are incompletely characterized. The N and C termini of adjacent BAFF or APRIL monomers are spatially close and can be linked to create single-chain homo- or hetero-ligands of defined stoichiometry. Similar to APRIL, heteromers consisting of one BAFF and two APRILs (BAA) bind to the receptors B cell maturation antigen (BCMA), transmembrane activator and CAML interactor (TACI) but not to the BAFF receptor (BAFFR). Heteromers consisting of one APRIL and two BAFF (ABB) bind to TACI and BCMA and weakly to BAFFR in accordance with the analysis of the receptor interaction sites in the crystallographic structure of ABB. Receptor binding correlated with activity in reporter cell line assays specific for BAFFR, TACI, or BCMA. Single-chain BAFF (BBB) and to a lesser extent single-chain ABB, but not APRIL or single-chain BAA, rescued BAFFR-dependent B cell maturation in BAFF-deficient mice. In conclusion, BAFF-APRIL heteromers of different stoichiometries have distinct receptor-binding properties and activities. Based on the observation that heteromers are less active than BAFF, we speculate that their physiological role might be to down-regulate BAFF activity.

Identification of the sAPRIL binding peptide and its growth inhibition effects in the colorectal cancer cells.

BACKGROUND: A proliferation-inducing ligand (APRIL) is a member of the tumor necrosis factor (TNF) super family. It binds to its specific receptors and is involved in multiple processes during tumorigenesis and tumor cells proliferation. High levels of APRIL expression are closely correlated to the growth, metastasis, and 5-FU drug resistance of colorectal cancer. The aim of this study was to identify a specific APRIL binding peptide (BP) able to block APRIL activity that could be used as a potential treatment for colorectal cancer. METHODS: A phage display library was used to identify peptides that bound selectively to soluble recombinant human APRIL (sAPRIL). The peptides with the highest binding affinity for sAPRIL were identified using ELISA. The effects of sAPRIL-BP on cell proliferation and cell cycle/apoptosis in vitro were evaluated using the CCK-8 assay and flow cytometry, respectively. An in vivo mouse model of colorectal cancer was used to determine the anti-tumor efficacy of the sAPRIL-BP. RESULTS: Three candidate peptides were characterized from eight phage clones with high binding affinity for sAPRIL. The peptide with the highest affinity was selected for further characterization. The identified sAPRIL-BP suppressed tumor cell proliferation and cell cycle progression in LOVO cells in a dose-dependent manner. In vivo in a mouse colorectal challenge model, the sAPRIL-BP reduced the growth of tumor xenografts in nude mice by inhibiting proliferation and inducing apoptosis intratumorally. Moreover, in an in vivo metastasis model, sAPRIL-BP reduced liver metastasis of colorectal cancer cells. CONCLUSIONS: sAPRIL-BP significantly suppressed tumor growth in vitro and in vivo and might be a candidate for treating colorectal cancers that express high levels of APRIL.

In Silico Identification of Novel APRIL Peptide Antagonists and Binding Insights by Molecular Modeling and Immunosorbent Assays.

The "A proliferation inducing ligand" protein (APRIL) is a cytokine over-expressed in many transformed and tumoral cells acting onto two distinct receptors of the Tumoral Necrosis Factor B cell maturation antigen (BCMA) and the transmembrane activator and calcium modulator and cyclophilin ligand interactor (TACI). We herein describe, through a detailed computational approach, the molecular interactions between TACI and its ligands APRIL and another structurally similar protein called B-cell activating factor (BAFF) by means of molecular dynamics. Dynamical analysis suggests R84 and D85 residues from TACI as possible mutation candidates, yielding increased affinity between TACI and APRIL. The association of computational simulations, site directed mutagenesis and peptide design could be a powerful tool, driving to better in vitro experiments. Our results contribute to the elucidation of APRIL signaling and help clarify the effects of blocking interaction between APRIL and its receptors through the use of particular peptides.

Expression and purification of soluble human APRIL in Escherichia coli using ELP-SUMO tag.

APRIL is a member of the tumor necrosis factor (TNF) family of ligands that mediate tumor cells proliferation as well as survival, depending on the cellular context. In this report, we present a novel method to obtain soluble human APRIL in Escherichia coli using the elastin-like polypeptide and SUMO (ELP-SUMO) tags. The fusion protein with ELP-SUMO tag was expressed in a soluble form at 15°C. After purification based on inverse transition cycling (ITC) method, the purified ELP-SUMO-hAPRIL fusion protein was subsequently cleaved by SUMO protease to release mature hAPRIL. Following affinity chromatography, the target protein was re-purified with high purity. Finally, about 4.8mg recombinant hAPRIL was obtained from 1l bacterial culture with no less than 85% purity. The molecular mass (Mr) of the recombinant hAPRIL was confirmed by MALDI-TOF MS as Mr 16,314. The purified hAPRIL exhibits biological activity on Jurkat cells. It is the first report on soluble production of hAPRIL in E. coli using ELP-SUMO tag.

Molecular structure, expression pattern and functional characterisation of APRIL in an aquatic mammal.

The Yangtze finless porpoise (Neophocaena phocaenoides asiaorientalis) is listed on the First Order of Protected Animals in China and was identified as an endangered species by the International Union for Conservation of Nature and Natural Resources (IUCN) in 2011. A proliferation inducing ligand (APRIL), belonging to the tumour necrosis factor (TNF) family, is critical for immune regulation. In this study, we identified a finless porpoise APRIL cDNA (fAPRIL) by RACE (rapid amplification of cDNA ends) strategies, from the Yangtze finless porpoise (fAPRIL). This gene encodes 247 amino acids containing a predicted transmembrane domain and a TNF domain, and phylogenetic analysis of the APRIL sequence indicated that finless porpoises are closely related to Artiodactyla. In vitro, soluble fAPRIL (fsAPRIL) not only promoted the survival/proliferation of the mouse spleen lymphocytes, but also bound specifically to the surface of the B cells. The results of this study contribute to our understanding of the immune mechanisms in the finless porpoise and other aquatic mammals.

Structural analysis of the inhibition of APRIL by TACI and BCMA through molecular dynamics simulations.

APRIL (a proliferation-inducing ligand) is a member of the tumour necrosis factor (TNF) superfamily that binds the receptors (TNFRs) TACI and BCMA. Since it was discovered, a great amount of evidence has been reported about the involvement of APRIL in autoimmune diseases including systemic lupus erythematosus (SLE), rheumatoid arthritis (RA), Sjögren's syndrome (SS) and multiple sclerosis (MS). In addition, an important role of APRIL has been described in different types of tumour cell lines and in a variety of primary tumour tissues where, in contrast with the normal ones, high mRNA levels have been detected. Accordingly, the design of compounds mimicking the inhibition of APRIL by its receptors appears to be a promising way to treat autoimmune and cancer diseases. As a first step to achieve these goals and in order to better understand the key interactions involved in these systems, we report a structural analysis of the inhibition of human and murine APRIL by its human receptors TACI and BCMA obtained by molecular dynamics simulations. Although most of the key interactions can be obtained from the existing experimental information, new described interactions between human APRIL and its receptors can contribute to a better design of APRIL inhibitors.

The design and characterization of receptor-selective APRIL variants.

A proliferation-inducing ligand (APRIL), a member of the TNF ligand superfamily with an important role in humoral immunity, is also implicated in several cancers as a prosurvival factor. APRIL binds two different TNF receptors, B cell maturation antigen (BCMA) and transmembrane activator and cylclophilin ligand interactor (TACI), and also interacts independently with heparan sulfate proteoglycans. Because APRIL shares binding of the TNF receptors with B cell activation factor, separating the precise signaling pathways activated by either ligand in a given context has proven quite difficult. In this study, we have used the protein design algorithm FoldX to successfully generate a BCMA-specific variant of APRIL, APRIL-R206E, and two TACI-selective variants, D132F and D132Y. These APRIL variants show selective activity toward their receptors in several in vitro assays. Moreover, we have used these ligands to show that BCMA and TACI have a distinct role in APRIL-induced B cell stimulation. We conclude that these ligands are useful tools for studying APRIL biology in the context of individual receptor activation.

Gene cloning, expression and functional characterization of a proliferation-inducing ligand (APRIL) from hedgehog (Erinaceus europaeus).

Here we describe the identification of the hedgehog Erinaceus europaeus homologue of a proliferation-inducing ligand (APRIL) of the TNF family (designated heAPRIL). Hedgehog APRIL contains two cysteine residues (Cys(196) and Cys(211)), a furin protease cleavage site and a conserved putative N-glycosylation site (Asn(124)). Real-time quantitative PCR (qPCR) analysis revealed that heAPRIL could be detected in various tissues. MTT assays and flow cytometric analysis revealed that Nus-hesAPRIL and hesAPRIL could promote the survival/proliferation of splenic B cells. Laser scanning confocal microscopy analysis showed GFP-hesAPRIL could successfully bind to the APRIL receptors of lymphocytes.

Effects of APRIL (TNFSF13) polymorphisms and splicing isoforms on the secretion of soluble APRIL.

Functional APRIL (TNFSF13) is a secreted trimer generated by furin protease cleavage. We previously reported the association of APRIL haplotypes formed by two nonsynonymous polymorphisms, Gly67Arg and Asn96Ser, with systemic lupus erythematosus. Here, we tested the hypothesis that polymorphisms and/or alternative splicing may influence the generation of soluble APRIL (sAPRIL). HEK 293T cells were transfected with plasmids containing one of the six combinations of splicing isoforms (α or ß) and haplotypes (susceptible, neutral, or protective). APRIL concentrations were quantitated in the cell lysates and supernatants using an enzyme-linked immunosorbent assay (ELISA). The association between splicing efficiency and polymorphisms was analyzed using quantitative reverse transcription polymerase chain reaction (RT-PCR). The efficiency of cleavage by furin protease was analyzed using western blotting. Although both splicing isoforms were cleaved by furin protease, sAPRIL was not detected in the supernatant of the cells transfected with the ß isoform, regardless of the haplotype. This suggested that, similarly to B-cell activating factor (BAFF), one of the major APRIL splicing isoforms may not be secreted as a functional molecule. Furthermore, the secretion of sAPRIL was decreased in the transfectants expressing the protective haplotype. An association between the polymorphisms and splicing efficiency or furin cleavage efficiency was not detected. In conclusion, these observations suggested that both alternative splicing and polymorphisms may affect the generation of functional sAPRIL.

Expression and characterization of a variant of TACI (CRD2-shortTACIFc) in Pichia pastoris.

TACI is a member of the tumor necrosis factor receptor superfamily and serves as a key regulator of B cell function. The extracellular domain of a typical TNFR contains multiple copies of CRD, which bind in the monomermonomer interfaces of a trimeric ligand. TACI binds to two ligands, APRIL and BAFF, with high affinity and contains two CRD in its extracellular regions, while BCMA and BR3, contain a single or partial CRD for binding the two ligands. However, TACI can be classified as a single CRD receptor because the amino-terminal CRD1 doesn't contribute to ligand binding. To obtain a new variant of TACI possessing higher affinities for binding, we fused a repeat sequence of CRD2 to the N-terminus of the short form of TACI. The new APRIL antagonist peptide, CRD2-shortTACI-Fc, was designed based on the modeling 3-D complex structure of TACI and APRIL. As expected, the purified recombinant CRD2-shortTACI-Fc fusion protein could bind to APRIL in vitro and demonstrated dose-dependent inhibition of APRIL-induced proliferative activity in Raji cells. We found that CRD2-shortTACI-Fc, has a higher affinity for binding to ligands than short-TACI-Fc, which contains a single CRD2.

Aberrant expression of functional BAFF-system receptors by malignant B-cell precursors impacts leukemia cell survival.

Despite exhibiting oncogenic events, patient's leukemia cells are responsive and dependent on signals from their malignant bone marrow (BM) microenvironment, which modulate their survival, cell cycle progression, trafficking and resistance to chemotherapy. Identification of the signaling pathways mediating this leukemia/microenvironment interplay is critical for the development of novel molecular targeted therapies.We observed that primary leukemia B-cell precursors aberrantly express receptors of the BAFF-system, BAFF-R, BCMA, and TACI. These receptors are functional as their ligation triggers activation of NF-κB, MAPK/JNK, and Akt signaling. Leukemia cells express surface BAFF and APRIL ligands, and soluble BAFF is significantly higher in leukemia patients in comparison to age-matched controls. Interestingly, leukemia cells also express surface APRIL, which seems to be encoded by APRIL-δ, a novel isoform that lacks the furin convertase domain. Importantly, we observed BM microenvironmental cells express the ligands BAFF and APRIL, including surface and secreted BAFF by BM endothelial cells. Functional studies showed that signals through BAFF-system receptors impact the survival and basal proliferation of leukemia B-cell precursors, and support the involvement of both homotypic and heterotypic mechanisms.This study shows an unforeseen role for the BAFF-system in the biology of precursor B-cell leukemia, and suggests that the target disruption of BAFF signals may constitute a valid strategy for the treatment of this cancer.

Multiple novel classes of APRIL-specific receptor-blocking peptides isolated by phage display.

A proliferation-inducing ligand (APRIL) is a member of the tumor necrosis factor (TNF) ligand superfamily and has a proliferative effect on both normal and tumor cells. The TNF family receptors (B-cell maturation antigen (BCMA), transmembrane activator and CAML-interactor (TACI), and BAFF receptor-3 (BR3)) for APRIL and the closely related ligand, B-cell activating factor of the TNF family (BAFF), bind these ligands through a highly conserved six residue DXL motif ((F/Y/W)-D-X-L-(V/T)-(R/G)). Panning peptide phage display libraries led to the identification of several novel classes of APRIL-binding peptides, which could be grouped by their common sequence motifs. Interestingly, only one of these ten classes consisted of peptides containing the DXL motif. Nevertheless, all classes of peptides prevented APRIL, but not BAFF, from binding BCMA, their shared receptor. Synthetic peptides based on selected sequences inhibited APRIL binding to BCMA with IC(50) values of 0.49-27 microM. An X-ray crystallographic structure of APRIL bound to one of the phage-derived peptides showed that the peptide, lacking the DXL motif, was nevertheless bound in the DXL pocket on APRIL. Our results demonstrate that even though a focused, highly conserved motif is required for APRIL-receptor interaction, remarkably, many novel and distinct classes of peptides are also capable of binding APRIL at the ligand receptor interface.