A minimally invasive bronchoscopic approach for direct delivery to murine airways and application to models of pulmonary infection.

The laboratory mouse is used extensively for human disease modeling and preclinical therapeutic testing for efficacy, biodistribution, and toxicity. The variety of murine models available, and the ability to create new ones, eclipses all other species, but the size of mice and their organs create challenges for many in vivo studies. For pulmonary research, improved methods to access murine airways and lungs, and track substances administered to them, would be desirable. A nonsurgical endoscopic system with a camera, effectively a bronchoscope, coupled with a cryoimaging fluorescence microscopy technique to view the lungs in 3D, is described here that allows visualization of the procedure, including the anatomical location at which substances are instilled and fluorescence detection of those substances. We have applied it to bacterial infection studies to characterize better and optimize a chronic lung infection murine model in which we instill bacteria-laden agarose beads into the airways and lungs to extend the duration of the infection and inflammation. The use of the endoscope as guidance for placing a catheter into the airways is simple and quick, requiring only momentary sedation, and reduces post-procedural mortality compared with our previous instillation method that includes a trans-tracheal surgery. The endoscopic method improves speed and precision of delivery while reducing the stress on animals and the number of animals generated and used for experiments.

FcRn overexpression in human cancer drives albumin recycling and cell growth; a mechanistic basis for exploitation in targeted albumin-drug designs.

Albumin accumulation in tumours could reflect a role of albumin in transport of endogenous nutrient cargos required for cellular growth and not just a suggested source of amino acids; a role driven by albumin engagement with its cognate cellular recycling neonatal Fc receptor. We investigate the hypothesis that albumin cellular recruitment is increased by higher human FcRn (hFcRn) expression in human cancer tissue that provides the mechanistic basis for exploitation in albumin-based drug designs engineered to optimise this process. Eight out of ten different human cancer tissue types screened for hFcRn expression by immunohistochemistry (310 samples) exhibited significantly higher hFcRn expression compared to healthy tissues. Accelerated tumour growth over 28 days in mice inoculated with hFcRn-expressing HT-29 human colorectal cancer cell xenografts, compared to CRISPR/Cas9 hFcRn-knockout HT-29, suggests a hFcRn-mediated tumour growth effect. Direct correlation between hFcRn expression and albumin recycling supports hFcRn-mediated diversion of albumin from lysosomal degradation. Two-fold increase in accumulation of fluorescent labelled high-binding hFcRn albumin, compared to wild type albumin, in luciferase MDA-MB-231-Luc-D3H2LN breast cancer xenografts was shown. This work identifies overexpression of hFcRn in several human cancer types with mechanistic data suggesting hFcRn-driven albumin recruitment for increased cellular growth that has the potential to be exploited with high hFcRn-binding albumin variants for targeted therapies.

A new class of recombinant human albumin with multiple surface thiols exhibits stable conjugation and enhanced FcRn binding and blood circulation.

Human serum albumin is an endogenous ligand transport protein whose long circulatory half-life is facilitated by engagement with the human cellular recycling neonatal Fc receptor (hFcRn). The single free thiol located at Cys-34 in domain I of albumin has been exploited for monoconjugation of drugs. In this work, we increased the drug-to-albumin ratio potential by engineering recombinant human albumin (rHSA) variants with varying hFcRn affinity to contain three free, conjugation-competent cysteines. Structural analysis was used to identify positions for cysteine introduction to maximize rHSA stability and formation of the conjugated product without affecting hFcRn binding. The thiol rHSA variants exhibited up to 95% monomeric stability over 24 months and retained hFcRn engagement compared with a WT unconjugated control demonstrated by Biolayer Interferometry. The additional cysteines were further introduced into a panel of rHSA variants engineered with different affinities for hFcRn. After conjugation with three Alexa Fluor 680 (AF680) fluorophores, hFcRn binding was similar to that of the original triple-thiol nonconjugated rHSA variants (0.88 and 0.25 µm for WT albumin with or without 3xAF680 respectively, and 0.04 and 0.02 µm for a high hFcRn-binding variant with or without 3xAF680, respectively). We also observed a 1.3-fold increase in the blood circulatory half-life of a high hFcRn-binding triple-thiol variant conjugated with AF680 (t½ = 22.4 h) compared with its WT counterpart (t½ = 17.3 h) in mice. Potential high drug-to-albumin ratios combined with high hFcRn engagement are attractive features of this new class of albumins that offer a paradigm shift for albumin-based drug delivery.

Cellular recycling-driven in vivo half-life extension using recombinant albumin fusions tuned for neonatal Fc receptor (FcRn) engagement.

Recombinant albumin-drug genetic fusions are an effective technology to prolong the serum half-life of therapeutics that has resulted in marketed products. Indirect evidence suggests albumin fusions' long circulation is controlled by engagement with the cellular recycling neonatal Fc receptor (FcRn) in addition to reduced kidney filtration. In this work, we have used a panel of recombinant fusions, engineered with different human FcRn (hFcRn) affinity, including a novel high binding albumin variant (HBII), to directly define and importantly, control the intracellular mechanism as a half-life extension tuning method. mNeonGreen or mCherry fusion to the N-terminal of the recombinant human albumin (rHA) variants null-binder (rHA NB), wild-type (rHA WT), high-binder I (rHA HBI), and high-binder II (rHA HBII) did not generally interfere with hFcRn interaction determined by Biolayer Interferometry. Co-localisation of the albumins with endosomal, but not lysosomal, markers was shown by confocal microscopy for high, but not low, hFcRn binders in a human microvascular endothelial hFcRn overexpressing cell line (HMEC-1 FcRn) suggestive of endosomal compartmentalisation. Furthermore, a cellular recycling assay revealed increased recycling of albumin fusions for the high binding variants (mNeonGreen WT; ~1, mNeonGreen HBI; 5.26-fold higher, and mNeonGreen HBII; 5.77-fold higher) in the hFcRn overexpressing cell line. In vivo experiments demonstrated a direct in vitro recycling/in vivo half-life correlation with a longer circulation for the mCherry fusions engineered with high hFcRn affinity that was highest with the HBII variant of 30.1 h compared to 18.2 h for the mCherry WT. This work gives the first direct evidence for an FcRn-driven endosomal cellular recycling pathway for recombinant albumin fusions that correlates with half-life extension controlled by the affinity to hFcRn; promoting a versatile method to tune the pharmacokinetics of albumin fusion-based therapeutics not met by current technologies.

CXCL13 predicts disease activity in early rheumatoid arthritis and could be an indicator of the therapeutic 'window of opportunity'.

INTRODUCTION: A key phenomenon in rheumatoid arthritis is the formation of lymphoid follicles in the inflamed synovial membrane. C-X-C motif chemokine 13 (CXCL13) is central in this process as it attracts C-X-C chemokine receptor type 5 (CXCR5)-expressing B cells and T follicular helper cells to the follicle. We here examine the role of CXCL13 and its association with disease in patients with treatment-naïve early rheumatoid arthritis. METHODS: Plasma samples from patients in the OPERA trial were examined for CXCL13 at treatment initiation and after 6 months of treatment with either methotrexate plus placebo (DMARD) (n = 37) or methotrexate plus adalimumab (DMARD + ADA) (n = 39). Treatment outcome was evaluated after 1 and 2 years. CXCL13 plasma levels in healthy volunteers (n = 38) were also examined. RESULTS: Baseline CXCL13 plasma levels were increased in early rheumatoid arthritis patients in comparison with healthy volunteers. Also, plasma CXCL13 correlated positively with disease activity parameters; swollen joint count 28 (rho = 0.34) and 40 (rho = 0.39), visual analog score (rho = 0.38) and simplified disease activity index (rho = 0.25) (all P <0.05). CXCL13 levels decreased a significantly twofold more in the DMARD + ADA group than in the DMARD group. Baseline CXCL13 plasma levels in the DMARD group correlated inversely with disease activity parameters; disease activity score in 28 joints, four variables, C-reactive protein based (DAS28CRP) (rho = 0.58, P < 0.05) at 12 months. High baseline CXCL13 was associated with remission (DAS28CRP less than 2.6) after 2 years. CONCLUSIONS: In treatment-naïve early rheumatoid arthritis patients, plasma CXCL13 levels were associated with joint inflammation. Furthermore, patients with high baseline plasma CXCL13 levels had an improved chance of remission after 2 years. We propose that high CXCL13 concentrations indicate recent onset of inflammation that may respond better to early aggressive treatment. Thus, high levels of CXCL13 could reflect the 'the window of opportunity' for optimal treatment effect. TRIAL REGISTRATION: Clinicaltrial.gov NCT00660647. Registered 10 April 2008.