Kei Kanie

Novel Small-Caliber Vascular Grafts With Trimeric Peptide for Acceleration of Endothelialization

BACKGROUND Both rapid endothelialization and the prevention of intimal hyperplasia are essential to improve the patency of small-caliber vascular grafts (SCVGs). Using the peptide array based screening system, we identified the peptide CAG (cysteine-alanine-glycine), which has a high affinity for endothelial cells and a low adhesive property for smooth muscle cells (SMCs). In this article, we report an in vivo analysis of novel vascular grafts that were constructed with a biodegradable polymer (poly-ε-caprolactone [PCL]) containing CAG peptide. METHODS The novel SCVG, which measured 0.7 mm in diameter and 7 mm in length, was fabricated using the electrospinning technique. Carotid arterial replacement was performed on Sprague-Dawley rats using SCVGs with (group CAG) or without CAG (group C). Histologic and biochemical assessments were performed at 1, 2, and 6 weeks after implantation. RESULTS The ratio of endothelialization was significantly higher in group CAG compared with group C (CAG versus C, 64.4±20.0% versus 42.1±8.9% at 1 week; p=0.017; 98.2±2.3% versus 72.7±12.9% at 2 weeks; p=0.001; and 97.4±4.6% versus 76.7±5.4% at 6 weeks; p<0.001). Additionally, Western blot analysis showed that the level of endothelial nitric oxide synthase (eNOS) at 1 week in group CAG was significantly higher than that in group C (CAG versus C, 1.20±0.37 versus 0.34±0.16; p=0.013), and that α-smooth muscle actin (ASMA) at 6 weeks in group CAG was significantly lower than that in group C (CAG versus C, 0.89±0.06 versus 1.25±0.22; p=0.04). CONCLUSIONS The graft with CAG promoted rapid endothelialization and the potential for inhibition of intimal hyperplasia.

Collagen type IV‐specific tripeptides for selective adhesion of endothelial and smooth muscle cells

Controlling the balance of endothelial cells (ECs) and smooth muscle cells (SMCs) in blood vessels is critically important to minimize the risk associated with vascular implants. Extracellular matrix (ECM) plays a key role in controlling the cellular balance, suggesting a promising source of cell‐selective peptides. To obtain EC‐ or SMC‐selective peptides, we start by highlighting sequence differences found among ECM molecules as enriched targets for cell‐selective peptides. We explored the EC‐ or SMC‐selective performance of tripeptides that are specifically enriched only in collagen type IV, but not in types I, II, III, and V. Collagen type IV was chosen since it is the major ECM in the basement membrane of blood vessels, which separates ECs and SMCs. Among 114 collagen type IV‐derived tripeptides pre‐screened from in silico analysis, 22 peptides (19%) were found to promote cell‐selective adhesion, as determined by peptide array. One of the best performing EC‐selective peptides (Cys‐Ala‐Gly (CAG)) was mixed into an electrospun fine‐fiber, a vascular graft material, for practical application. Compared to unmodified fiber, the CAG containing fiber surface was found to enhance adhesion of ECs (+190%) while limiting SMCs (−20%). These results are not only consistent with the hypothesis of ECM as a source of cell selective peptides, but also suggest a new genre of EC‐ or SMC‐selective peptides for tissue engineering applications. Collectively, these findings favorably support the screening approach used to discover new peptides for these purposes. Biotechnol. Bioeng. 2012; 109:1808–1816.

Overexpression of prefoldin from the hyperthermophilic archaeum Pyrococcus horikoshii OT3 endowed Escherichia coli with organic solvent tolerance

Prefoldin is a jellyfish-shaped hexameric chaperone that captures a protein-folding intermediate and transfers it to the group II chaperonin for correct folding. In this work, we characterized the organic solvent tolerance of Escherichia coli cells that overexpress prefoldin and group II chaperonin from a hyperthermophilic archeaum, Pyrococcus horikoshii OT3. The colony-forming efficiency of E. coli cells overexpressing prefoldin increased by 1,000-fold and decreased the accumulation of intracellular organic solvent. The effect was impaired by deletions of the region responsible for the chaperone function of prefoldin. Therefore, we concluded that prefoldin endows E. coli cells by preventing accumulation of intracellular organic solvent through its molecular chaperone activity.

Label-Free Morphology-Based Prediction of Multiple Differentiation Potentials of Human Mesenchymal Stem Cells for Early Evaluation of Intact Cells

Precise quantification of cellular potential of stem cells, such as human bone marrow–derived mesenchymal stem cells (hBMSCs), is important for achieving stable and effective outcomes in clinical stem cell therapy. Here, we report a method for image-based prediction of the multiple differentiation potentials of hBMSCs. This method has four major advantages: (1) the cells used for potential prediction are fully intact, and therefore directly usable for clinical applications; (2) predictions of potentials are generated before differentiation cultures are initiated; (3) prediction of multiple potentials can be provided simultaneously for each sample; and (4) predictions of potentials yield quantitative values that correlate strongly with the experimental data. Our results show that the collapse of hBMSC differentiation potentials, triggered by in vitro expansion, can be quantitatively predicted far in advance by predicting multiple potentials, multi-lineage differentiation potentials (osteogenic, adipogenic, and chondrogenic) and population doubling potential using morphological features apparent during the first 4 days of expansion culture. In order to understand how such morphological features can be effective for advance predictions, we measured gene-expression profiles of the same early undifferentiated cells. Both senescence-related genes (p16 and p21) and cytoskeleton-related genes (PTK2, CD146, and CD49) already correlated to the decrease of potentials at this stage. To objectively compare the performance of morphology and gene expression for such early prediction, we tested a range of models using various combinations of features. Such comparison of predictive performances revealed that morphological features performed better overall than gene-expression profiles, balancing the predictive accuracy with the effort required for model construction. This benchmark list of various prediction models not only identifies the best morphological feature conversion method for objective potential prediction, but should also allow clinicians to choose the most practical morphology-based prediction method for their own purposes.

Parametric analysis of colony morphology of non-labelled live human pluripotent stem cells for cell quality control

Given the difficulties inherent in maintaining human pluripotent stem cells (hPSCs) in a healthy state, hPSCs should be routinely characterized using several established standard criteria during expansion for research or therapeutic purposes. hPSC colony morphology is typically considered an important criterion, but it is not evaluated quantitatively. Thus, we designed an unbiased method to evaluate hPSC colony morphology. This method involves a combination of automated non-labelled live-cell imaging and the implementation of morphological colony analysis algorithms with multiple parameters. To validate the utility of the quantitative evaluation method, a parent cell line exhibiting typical embryonic stem cell (ESC)-like morphology and an aberrant hPSC subclone demonstrating unusual colony morphology were used as models. According to statistical colony classification based on morphological parameters, colonies containing readily discernible areas of differentiation constituted a major classification cluster and were distinguishable from typical ESC-like colonies; similar results were obtained via classification based on global gene expression profiles. Thus, the morphological features of hPSC colonies are closely associated with cellular characteristics. Our quantitative evaluation method provides a biological definition of ‘hPSC colony morphology’, permits the non-invasive monitoring of hPSC conditions and is particularly useful for detecting variations in hPSC heterogeneity.

Amino acid sequence preferences to control cell-specific organization of endothelial cells, smooth muscle cells, and fibroblasts

Effective surface modification with biocompatible molecules is known to be effective in reducing the life‐threatening risks related to artificial cardiovascular implants. In recent strategies in regenerative medicine, the enhancement and support of natural repair systems at the site of injury by designed biocompatible molecules have succeeded in rapid and effective injury repair. Therefore, such a strategy could also be effective for rapid endothelialization of cardiovascular implants to lower the risk of thrombosis and stenosis. To achieve this enhancement of the natural repair system, a biomimetic molecule that mimics proper cellular organization at the implant location is required. In spite of the fact that many reported peptides have cell‐attracting properties on material surfaces, there have been few peptides that could control cell‐specific adhesion. For the advanced cardiovascular implants, peptides that can mimic the natural mechanism that controls cell‐specific organization have been strongly anticipated. To obtain such peptides, we hypothesized the cellular bias toward certain varieties of amino acids and examined the cell preference (in terms of adhesion, proliferation, and protein attraction) of varieties and of repeat length on SPOT peptide arrays. To investigate the role of specific peptides in controlling the organization of various cardiovascular‐related cells, we compared endothelial cells (ECs), smooth muscle cells (SMCs), and fibroblasts (FBs). A clear, cell‐specific preference was found for amino acids (longer than 5‐mer) using three types of cells, and the combinational effect of the physicochemical properties of the residues was analyzed to interpret the mechanism. Copyright

Directed evolution of angiotensin II-inhibiting peptides using a microbead display

Angiotensin II (ang II), an octapeptide (DRVYVHPF), can regulate blood pressure by binding specifically to its receptor, AT1. A peptide (VVIVIY) in the first transmembrane of AT1 has been found, via peptide array technology, to have an affinity for ang II. In this study, the peptide P2, which contained the VVIVIY sequence, was mutated and screened using microbead display technology that utilized emulsion PCR and cell-free protein synthesis. After one round of screening, the binding activities of collected mutants were estimated using flow cytometry and a peptide array. Two of these exhibited improved association rate constants to ang II, compared to the P2 peptide.

Drastic change in cell surface hydrophobicity of a new bacterial strain, Pseudomonas sp. TIS1-127, induced by growth temperature and its effects on the toluene-conversion rate

In a previous study, we reported the effectiveness of a bacterial strain showing monolayer adsorption to oil surfaces on microbial conversion at oil-water interfaces. In the present study, we screened wild type strains from our toluene-degrading bacterial library that showed similar properties and succeeded in obtaining five wild type strains that adsorb to oil surfaces as a cell monolayer. We investigated the effects of cultivation conditions on cell surface hydrophobicity of these five strains. The effects of substrate hydrophobicity and the porous carrier were not significant. By contrast, growth temperature greatly affected the cell surface hydrophobicity of all five strains, especially strain TIS1-127, which was phylogenetically identified as Pseudomonas sp. which is closely related to P. mosselii, P. monteilii, and P. plecoglossicida. Pseudomonas sp. TIS1-127 cells grown at 37 degrees C were determined by the kinetic microbial-adhesion-to-hydrocarbon (MATH) test to be fully hydrophilic (lower than 10% of MATH value) while the cells grown at 28 degrees C were highly hydrophobic (over 90% of MATH value). We investigated the effects of growth temperature on toluene conversion by TIS1-127 resting cells in single-phase batch cultivation and in two-liquid-phase partitioning reactors containing an emulsion consisting of 20% silicone oil and 80% cell suspension. In both cases, the cells grown at 28 degrees C showed much higher conversion ability than those grown at 37 degrees C. Toluene conversion followed Michaelis-Menten kinetics and the K(m) values for the cells grown at 28 degrees C were lower than 1/10 those for the cells grown at 37 degrees C.

Effects of the properties of short peptides conjugated with cell-penetrating peptides on their internalization into cells

Peptides, especially intracellular functional peptides that can play a particular role inside a cell, have attracted attention as promising materials to control cell fate. However, hydrophilic materials like peptides are difficult for cells to internalize. Therefore, the screening and design of intracellular functional peptides are more difficult than that of extracellular ones. An effective high-throughput screening system for intracellular functional peptides has not been reported. Here, we demonstrate a novel peptide array system for screening intracellular functional peptides, in which both cell-penetrating peptide (CPP) domain and photo-cleavable linkers are used. By using this screening system, we determined how the cellular uptake properties of CPP-conjugated peptides varied depending on the properties of the conjugated peptides. We found that the internalization ability of CPP-conjugated peptides varied greatly depending on the property of the conjugated peptides, and anionic peptides drastically decreased the uptake ability. We summarized our data in a scatter diagram that plots hydrophobicity versus isoelectric point (pI) of conjugated peptides. These results define a peptide library suitable for screening of intracellular functional peptides. Thus, our system, including the diagram, is a promising tool for searching biological active molecules such as peptide-based drugs.

Visualization of morphological categories of colonies for monitoring of effect on induced pluripotent stem cell culture status

From the recent advances, there are growing expectations toward the mass production of induced pluripotent stem cells (iPSCs) for varieties of applications. For such type of industrial cell manufacturing, the technology which can stabilize the production efficiency is strongly required. Since the present iPSC culture is covered by delicate manual operations, there are still quality differences in produced cells from same culture protocols. To monitor the culture process of iPSCs with the quantified data to evaluate the culture status, we here introduce image-based visualization method of morphological diversity of iPSC colonies. We have set three types of experiments to evaluate the influential factors in iPSC culture technique that may disturb the undifferentiation status of iPSC colonies: (Exp. 1) technical differences in passage skills, (Exp. 2) technical differences in feeder cell preparation, and (Exp. 3) technical differences in maintenance skills (medium exchange frequency with the combination of manual removal of morphologically irregular colonies). By measuring the all existing colonies from real-time microscopic images, the heterogenous change of colony morphologies in the culture vessel was visualized. By such visualization with morphologically categorized Manhattan chart, the difference between technical skills could be compared for evaluating appropriate cell processing.