Discovery of novel pyrrole derivatives as potent agonists for the niacin receptor GPR109A.

Novel pyrrole derivatives were discovered as potent agonists of the niacin receptor, GPR109A. During the derivatization, compound 16 was found to be effective both in vitro and in vivo. The compound 16 exhibited a significant reduction of the non-esterified fatty acid in human GPR109A transgenic rats, and the duration of its in vivo efficacy was much longer than niacin.

Generation and Characterization of a Novel Small Biologic Alternative to Proprotein Convertase Subtilisin/Kexin Type 9 (PCSK9) Antibodies, DS-9001a, Albumin Binding Domain-Fused Anticalin Protein.

Since it was recently reported that an antibody for proprotein convertase subtilisin/kexin type 9 (PCSK9) reduces the risk of cardiovascular events in a clinical context, PCSK9 inhibition is thought to be an attractive therapy for dyslipidemia. In the present study, we created a novel small biologic alternative to PCSK9 antibodies called DS-9001a, comprising an albumin binding domain fused to an artificial lipocalin mutein (ABD-fused Anticalin protein), which can be produced by a microbial production system. DS-9001a strongly interfered with PCSK9 binding to low-density-lipoprotein receptor (LDL-R) and PCSK9-mediated degradation of LDL-R. In cynomolgus monkeys, single DS-9001a administration significantly reduced the serum LDL-C level up to 21 days (62.4% reduction at the maximum). Moreover, DS-9001a reduced plasma non-high-density-lipoprotein cholesterol and oxidized LDL levels, and their further reductions were observed when atorvastatin and DS-9001a were administered in combination in human cholesteryl ester transfer protein/ApoB double transgenic mice. Additionally, their reductions on the combination of atorvastatin and DS-9001a were more pronounced than those on the combination of atorvastatin and anacetrapib. Besides its favorable pharmacologic profile, DS-9001a has a lower molecular weight (about 22 kDa), yielding a high stoichiometric drug concentration that might result in a smaller administration volume than that in existing antibody therapy. Since bacterial production systems are viewed as more suited to mass production at low cost, DS-9001a may provide a new therapeutic option to treat patients with dyslipidemia. In addition, considering the growing demand for antibody-like drugs, ABD-fused Anticalin proteins could represent a promising new class of small biologic molecules.

A Novel Three-Dimensional Human Peritubular Microvascular System.

Human kidney peritubular capillaries are particularly susceptible to injury, resulting in dysregulated angiogenesis, capillary rarefaction and regression, and progressive loss of kidney function. However, little is known about the structure and function of human kidney microvasculature. Here, we isolated, purified, and characterized human kidney peritubular microvascular endothelial cells (HKMECs) and reconstituted a three-dimensional human kidney microvasculature in a flow-directed microphysiologic system. By combining epithelial cell depletion and cell culture in media with high concentrations of vascular endothelial growth factor, we obtained HKMECs of high purity in large quantity. Unlike other endothelial cells, isolated HKMECs depended on high vascular endothelial growth factor concentration for survival and growth and exhibited high tubulogenic but low angiogenic potential. Furthermore, HKMECs had a different transcriptional profile. Under flow, HKMECs formed a thin fenestrated endothelium with a functional permeability barrier. In conclusion, this three-dimensional HKMEC-specific microphysiologic system recapitulates human kidney microvascular structure and function and shows phenotypic characteristics different from those of other microvascular endothelial cells.

Maintenance of vascular integrity by pericytes is essential for normal kidney function.

Pericytes are tissue-resident mesenchymal progenitor cells anatomically associated with the vasculature that have been shown to participate in tissue regeneration. Here, we tested the hypothesis that kidney pericytes, derived from FoxD1+ mesodermal progenitors during embryogenesis, are necessary for postnatal kidney homeostasis. Diphtheria toxin delivery to FoxD1Cre::RsDTR transgenic mice resulted in selective ablation of >90% of kidney pericytes but not other cell lineages. Abrupt increases in plasma creatinine, blood urea nitrogen, and albuminuria within 96 h indicated acute kidney injury in pericyte-ablated mice. Loss of pericytes led to a rapid accumulation of neutral lipid vacuoles, swollen mitochondria, and apoptosis in tubular epithelial cells. Pericyte ablation led to endothelial cell swelling, reduced expression of vascular homeostasis markers, and peritubular capillary loss. Despite the observed injury, no signs of the acute inflammatory response were observed. Pathway enrichment analysis of genes expressed in kidney pericytes in vivo identified basement membrane proteins, angiogenic factors, and factors regulating vascular tone as major regulators of vascular function. Using novel microphysiological devices, we recapitulated human kidney peritubular capillaries coated with pericytes and showed that pericytes regulate permeability, basement membrane deposition, and microvascular tone. These findings suggest that through the active support of the microvasculature, pericytes are essential to adult kidney homeostasis.

Hyperactive FOXO1 results in lack of tip stalk identity and deficient microvascular regeneration during kidney injury.

Loss of the microvascular (MV) network results in tissue ischemia, loss of tissue function, and is a hallmark of chronic diseases. The incorporation of a functional vascular network with that of the host remains a challenge to utilizing engineered tissues in clinically relevant therapies. We showed that vascular-bed-specific endothelial cells (ECs) exhibit differing angiogenic capacities, with kidney microvascular endothelial cells (MVECs) being the most deficient, and sought to explore the underlying mechanism. Constitutive activation of the phosphatase PTEN in kidney MVECs resulted in impaired PI3K/AKT activity in response to vascular endothelial growth factor (VEGF). Suppression of PTEN in vivo resulted in microvascular regeneration, but was insufficient to improve tissue function. Promoter analysis of the differentially regulated genes in KMVECs suggests that the transcription factor FOXO1 is highly active and RNAseq analysis revealed that hyperactive FOXO1 inhibits VEGF-Notch-dependent tip-cell formation by direct and indirect inhibition of DLL4 expression in response to VEGF. Inhibition of FOXO1 enhanced angiogenesis in human bio-engineered capillaries, and resulted in microvascular regeneration and improved function in mouse models of injury-repair.

The role of interface framework residues in determining antibody V(H)/V(L) interaction strength and antigen-binding affinity.

While many antibodies with strong antigen-binding affinity have stable variable regions with a strong antibody heavy chain variable region fragment (V(H))/antibody light chain variable region fragment (V(L)) interaction, the anti-lysozyme IgG HyHEL-10 has a fairly strong affinity, yet a very weak V(H)/V(L) interaction strength, in the absence of antigen. To investigate the possible relationship between antigen-binding affinity and V(H)/V(L) interaction strength, a novel phage display system that can switch two display modes was employed. We focused on the two framework region 2 regions of the HyHEL-10 V(H) and V(L), facing each other at the domain interface, and a combinatorial library was made in which each framework region 2 residue was mixed with that of D1.3, which has a far stronger V(H)/V(L) interaction. The phagemid library, encoding V(H) gene 7 and V(L) amber codon gene 9, was used to transform TG-1 (sup+), and the phages displaying functional variable regions were selected. The selected phages were then used to infect a nonsuppressing strain, and the culture supernatant containing V(H)-displaying phages and soluble V(L) fragment was used to evaluate the V(H)/V(L) interaction strength. The results clearly showed the existence of a key framework region 2 residue (H39) that strongly affects V(H)/V(L) interaction strength, and a marked positive correlation between the antigen-binding affinity and the V(H)/V(L) interaction, especially in the presence of a set of particular V(L) residues. The effect of the H39 mutation on the wild-type variable region was also confirmed by a SPR biosensor as a several-fold increase in antigen-binding affinity owing to an increased association rate, while a slight decrease was observed for the single-chain variable region.

Detection of protein tyrosine phosphorylation by open sandwich fluoroimmunoassay.

In the era of proteomics, high-throughput screening of posttranslational modification states of proteins, especially protein phosphorylation, is considered of utmost importance. However, current protein phosphorylation detection methods depend on either the combination of proteolysis and mass spectrometry, or time-consuming immunoassay that requires inevitable washing processes. As a way to rapidly assay protein phosphorylation events, here we propose the use of Open Sandwich immunoassay that detects antigen-dependent stabilization of antibody variable region (Fv). As a model system, the heavy and light chain variable regions (V(H)/V(L)) of anti-phosphotyrosine antibody PY20 were used to evaluate its performance. When V(H)/V(L) interaction was first estimated by phage ELISA, wild-type Fv showed a modest phosphotyrosine (PY)-dependent increase in signal. However, after screening of mutants at an interface residue, one with weak V(H)/V(L) interaction (HQ39R) showed markedly improved (>200%) antigen-dependent signals. Using this mutant, two fusion proteins in which each variable region fragment was tethered to a GFP color variant were made (V(H)-eYFP/V(L)-eCFP) to monitor PY-induced fluorescence resonance energy transfer (FRET) between them. The results showed significant PY- or tyrosine phosphorylated peptide-induced enhancement in FRET in homogeneous solutions, indicating applicability of the method for rapid screening of tyrosine phosphorylation in vitro or in situ and possibly in vivo.

Luminescent and substrate binding activities of firefly luciferase N-terminal domain.

Firefly luciferase catalyzes highly efficient emission of light from the substrates luciferin, Mg-ATP, and oxygen. A number of amino acid residues are identified to be important for the luminescent activity, and almost all the key residues are thought to be located in the N-terminal domain (1-437), except one in the C-terminal domain, Lys529, which is thought to be critical for efficient substrate orientation. Here we show that the purified N-terminal domain still binds to the substrates luciferin and ATP with reduced affinity, and retains luminescent activity of up to 0.03% of the wild-type enzyme (WT), indicating that all the essential residues for the activity are located in the N-terminal domain. Also found is low luminescence enhancement by coenzyme A (CoA), which implies a lower product inhibition than in the WT enzyme. These findings have interesting implications for the light emission reaction mechanism of the enzyme, such as reaction intermediates, product inhibition, and the role of the C-terminal domain.

Importance of a CDR H3 basal residue in V(H)/V(L) interaction of human antibodies.

Although the cooperativity of the V(H) and V(L) domains of an antibody in antigen binding has been extensively studied, the interaction between the V(H) and V(L) domains had not received sufficient attention. To systematically investigate the relationship between the amino acid sequence and V(H)/V(L) interaction strength, we here used a set of anti-bovine serum albumin antibodies having a single human framework for V(H) (V3-23/DP-47 and JH4b) and Vk (O12/O2/DPK9 and Jk1), but with different V(H)/V(L) interaction strengths. By phage display of a V(H) mini-library and analysis of the interaction of amino acids with immobilized V(L) fragments, the residue at H95 (Kabat numbering) at the beginning of seven CDR H3 residues was found to play a key role in determining the V(H)/V(L) interaction. On saturation mutagenesis of H95, Gly showed the strongest interaction, while Asp, Asn, and Glu showed lesser interaction in that order. The generality of the rule was confirmed by the test with urine-derived human L chain instead of a particular V(L). The results demonstrate that H95 plays a central role in deciding the V(H)/V(L) interaction of human Fvs that have most commonly found frameworks.

A general method to select antibody fragments suitable for noncompetitive detection of monovalent antigens.

Previously, immunological detection of a small hapten was only possible in competitive format, which needed a competitor antigen either labeled by a reporter or attached to a carrier protein. Recently, we proposed the open sandwich (OS) immunoassay, a simple immunoassay that can noncompetitively determine monovalent antigen concentration by measuring the antigen-dependent change in a heavy-chain variable region (VH)/light-chain variable region (VL) interaction of an antibody. However, there was a limitation in the assay that the antibody used should have a suitable property such that the VH/VL interaction would become fairly strong along with the addition of antigen. Here, we devised a phage-based "split-Fv system" to rapidly evaluate and select antibody variable region (Fv) fragments that are suitable to OS immunoassay. When three antibodies raised against endocrine disruptor bisphenol A were tested with this system, all were more or less suitable to OS-ELISA. Among them, the best Fv selected was used to construct fusion proteins of VH tethered to an alkaline phosphatase and a tagged VL that can be site-specifically biotinylated to perform direct OS-ELISA. The results showed that the OS-ELISA detects bisphenol A with higher sensitivity than the corresponding competitive assay, also implying that many antibodies to small haptens have suitable properties for OS-ELISA.