Publications

Drug targeting can be achieved by coupling drugs or their carriers to affinity molecules, mostly antibodies (Abs), which recognise specific protein targets. However, most proteins are not expressed in an exclusive configuration but as various isoforms. Hence, selected targeting molecules may fail to target with enough efficiency in clinical trials, which is overlooked. We illustrate this by targeting intercellular adhesion molecule 1 (ICAM-1), a cell-surface protein overexpressed in many pathologies. Most ICAM-1 targeting studies used Ab R6.5, which binds ICAM-1 domain 2 (D2). Yet, literature and our data show that D2 is frequently absent among ICAM-1 isoforms. We thus produced a battery of five new Abs (B4, B6, B11, C12 and G2) and tested their ability to recognise both full-length and -D2 ICAM-1. In solution, all Abs recognised both ICAM-1 forms (from 5.3 x 1011 to 4.2 x 1012 sum intensity/well). Coating them on nanocarriers (NCs) rendered G2 specific against -D2 ICAM-1 (4.2 x 106 NCs/well) while other Abs kept their dual recognition (from 6.4 x 106 to 2.2 x 107 NCs/well). All Abs induced NC intracellular uptake in respective cells (from 42% to 85%) and displayed good cross-species reactivity (from 4.4 x 1011 to 2.6 x 1012 sum intensity/well). These Abs represent valuable tools to target ICAM-1 and illustrate a new targeting paradigm that may improve classical strategies.

JTD Keywords: Adhesion, Antibody-targeted nanocarriers, Cross-species reactivit, Design, Domai, Endothelial delivery, Enlimomab, Icam-1, Icam-1 isoforms, Intercellular adhesion molecule 1, Nanocarriers, Nanoparticles, New recombinant antibodies, Pecam-1, Targeting and intracellular trafficking

Intercellular adhesion molecule-1 (ICAM-1) is a membrane protein whose expression is enhanced at pathological sites, supporting drug delivery using nanocarriers (NCs). Any of its five extracellular domains (D1 to D5) can be targeted, yet most NC studies have used antibody (Ab) R6.5, which targets domain D2. While this provided efficient NC targeting and intracellular transport, literature indicates the absence of D2 in about 50 % of ICAM-1 isoforms expressed in mouse models. In this study, we verified the presence of ICAM-1 isoforms lacking D2 in human cells at both mRNA and protein levels, supporting the need to test Abs targeting other ICAM-1 domains. We developed a new cell model specifically lacking ICAM-1 D2 and compared R6.5 to Abs targeting D1 (Ab 15.2), D3D4 (Ab G-5), and D5 (Ab H-4). Abs G-5 and H-4 showed best targeting results, for which they were coated on model polymeric NCs. Compared to non-specific IgG NCs, both anti-ICAM-1 formulations targeted recombinant cells expressing human ICAM-1 lacking D2 and also primary cells naturally expressing the whole ICAM-1 isoform pattern observed. Both formulations were efficiently internalized by cells and trafficked to lysosomes, as previously observed for ICAM-1-targeting systems. Furthermore, NCs coated with either one of these two Abs showed good cross-species reactivity, being amenable for future pre-clinical testing. Therefore, Abs G-5 or H-4 are good options to provide ICAM-1 targeting without missing ICAM-1 isoforms lacking D2, present in human.

JTD Keywords: Adhesion molecule-1 icam-1, Anti-icam-1 antibody, Antibody-targeted nanocarriers, Design, Different receptor epitopes, Domai, Endothelial delivery, Enlimomab, Icam-1 extracellular domains, Icam-1 isoforms, Identification, Intercellular adhesion molecule 1, Monoclonal-antibodies, Nanoparticles, Targeting and endocytosi, Transport

ASM deficiency in Niemann-Pick disease type A results in aberrant cellular accumulation of sphingomyelin, neuroinflammation, neurodegeneration, and early death. There is no available treatment because enzyme replacement therapy cannot surmount the blood-brain barrier (BBB). Nanocarriers (NCs) targeted across the BBB via transcytosis might help; yet, whether ASM deficiency alters transcytosis remains poorly characterized. We investigated this using model NCs targeted to intracellular adhesion molecule-1 (ICAM-1), transferrin receptor (TfR), or plasmalemma vesicle-associated protein-1 (PV1) in ASM-normal vs. ASM-deficient BBB models. Disease differentially changed the expression of all three targets, with ICAM-1 becoming the highest. Apical binding and uptake of anti-TfR NCs and anti-PV1 NCs were unaffected by disease, while anti-ICAM-1 NCs had increased apical binding and decreased uptake rate, resulting in unchanged intracellular NCs. Additionally, anti-ICAM-1 NCs underwent basolateral reuptake after transcytosis, whose rate was decreased by disease, as for apical uptake. Consequently, disease increased the effective transcytosis rate for anti-ICAM-1 NCs. Increased transcytosis was also observed for anti-PV1 NCs, while anti-TfR NCs remained unaffected. A fraction of each formulation trafficked to endothelial lysosomes. This was decreased in disease for anti-ICAM-1 NCs and anti-PV1 NCs, agreeing with opposite transcytosis changes, while it increased for anti-TfR NCs. Overall, these variations in receptor expression and NC transport resulted in anti-ICAM-1 NCs displaying the highest absolute transcytosis in the disease condition. Furthermore, these results revealed that ASM deficiency can differently alter these processes depending on the particular target, for which this type of study is key to guide the design of therapeutic NCs.© 2023. Controlled Release Society.

JTD Keywords: asm deficiency, blood-brain barrier, delivery, determines, drug, endocytosis, enzymes, icam-1, lysosomal storage disease, mechanisms, nanoparticles, natural-history, niemann-pick disease type a, pv-1, receptor-mediated transcytosis, trafficking, transferrin receptor, Asm deficiency, Blood-brain barrier, Blood–brain barrier, Drug carriers, Drug nanocarriers, Humans, Icam-1, Icam-1-targeted nanocarriers, Intercellular adhesion molecule-1, Lysosomal storage disease, Niemann-pick disease type a, Niemann-pick disease, type a, Niemann-pick diseases, Pv-1, Receptor-mediated transcytosis, Transferrin receptor

Integrins are cell membrane adhesion receptors involved in morphogenesis, immunity, tissue healing, and metastasis. A central, yet unresolved question regarding the function of integrins is how these receptors regulate both their conformation and dynamic nanoscale organization on the membrane to generate adhesion-competent microclusters upon ligand binding. Here we exploit the high spatial (nanometer) accuracy and temporal resolution of single-dye tracking to dissect the relationship between conformational state, lateral mobility, and microclustering of the integrin receptor lymphocyte function-associated antigen 1 (LFA-1) expressed on immune cells. We recently showed that in quiescent monocytes, LFA-1 preorganizes in nanoclusters proximal to nanoscale raft components. We now show that these nanoclusters are primarily mobile on the cell surface with a small (ca. 5%) subset of conformational- active LFA-1 nanoclusters preanchored to the cytoskeleton. Lateral mobility resulted crucial for the formation of microclusters upon ligand binding and for stable adhesion under shear flow. Activation of high-affinity LFA-1 by extracellular Ca 2+ resulted in an eightfold increase on the percentage of immobile nanoclusters and cytoskeleton anchorage. Although having the ability to bind to their ligands, these active nanoclusters failed to support firm adhesion in static and low shear-flow conditions because mobility and clustering capacity were highly compromised. Altogether, our work demonstrates an intricate coupling between conformation and lateral diffusion of LFA-1 and further underscores the crucial role of mobility for the onset of LFA-1 mediated leukocyte adhesion.

JTD Keywords: Cumulative probability distribution, Integrin lymphocyte function-associated antigen 1, Intercellular adhesion molecule, Single molecule detection