Byeongmoon Jeong

Enzymatically degradable temperature-sensitive polypeptide as a new in-situ gelling biomaterial

We are reporting a poly (ethylene glycol)-block-poly(alanine-co-phenyl alanine) (PEG-PAF) aqueous solution that undergoes sol-to-gel transition as the temperature increases. The sol-to-gel transition was observed at as low a concentration as 3.0-7.0 wt.%. Micellar aggregation accompanying small conformational changes of the peptide from random coils to beta-sheets is suggested as the sol-to-gel transition mechanism of the PEG-PAF aqueous solution. The PEG-PAF is stable in phosphate buffered saline, however, it degraded in the subcutaneous layer of rats. In vitro study showed that proteolytic enzymes such as cathepsin B, cathepsin C, and elastase that are present in the subcutaneous layer of the mammalian tissue might be responsible for the degradation of the polymer in rats. As a feasibility study of this material, a single shot of an aqueous insulin formulation (13.8 mg insulin/kg) showed a hypoglycemic effect over 18 days in rats. The current functional polypeptide may be very promising as an in-situ gelling system for tissue engineering, cell/stem cell therapy, and drug delivery.

Significance of secondary structure in nanostructure formation and thermosensitivity of polypeptide block copolymers

Well-defined nanostructural control from biological motifs is gaining attention among materials scientists. We are reporting that the β-sheet structure of L-polyalanine plays a critical role in developing a fibrous nanostructure as well as the sol-to-gel transition of amphiphilic poly(ethylene glycol)-L/or DL-polyalanine diblock copolymers. L-isomers underwent transitions from random coils to β-sheets, and to nanofibers as the polymer concentration increased, whereas the DL-isomer remained as a random coil structure without developing any specific nanostructure. At high polymer concentrations, the aqueous polymer solutions underwent a sol-to-gel transition as the temperature increased, a so called reverse thermal gelation. The L-isomer with a preassembled β-sheet secondary structure facilitates the sol-to-gel transition rather than the DL-isomer with a random coil structure. Thus, only the L-isomer showed a sol-to-gel transition in the physiologically important range of 20–40 °C. This report provides fundamental information on the relationship between hierarchical structures of polypeptides and the thermosensitive sol-gel transition of the polypeptide aqueous solution.

Comprehensive Analysis Reveals Dynamic and Evolutionary Plasticity of Rab GTPases and Membrane Traffic in Tetrahymena thermophila

Cellular sophistication is not exclusive to multicellular organisms, and unicellular eukaryotes can resemble differentiated animal cells in their complex network of membrane-bound structures. These comparisons can be illuminated by genome-wide surveys of key gene families. We report a systematic analysis of Rabs in a complex unicellular Ciliate, including gene prediction and phylogenetic clustering, expression profiling based on public data, and Green Fluorescent Protein (GFP) tagging. Rabs are monomeric GTPases that regulate membrane traffic. Because Rabs act as compartment-specific determinants, the number of Rabs in an organism reflects intracellular complexity. The Tetrahymena Rab family is similar in size to that in humans and includes both expansions in conserved Rab clades as well as many divergent Rabs. Importantly, more than 90% of Rabs are expressed concurrently in growing cells, while only a small subset appears specialized for other conditions. By localizing most Rabs in living cells, we could assign the majority to specific compartments. These results validated most phylogenetic assignments, but also indicated that some sequence-conserved Rabs were co-opted for novel functions. Our survey uncovered a rare example of a nuclear Rab and substantiated the existence of a previously unrecognized core Rab clade in eukaryotes. Strikingly, several functionally conserved pathways or structures were found to be associated entirely with divergent Rabs. These pathways may have permitted rapid evolution of the associated Rabs or may have arisen independently in diverse lineages and then converged. Thus, characterizing entire gene families can provide insight into the evolutionary flexibility of fundamental cellular pathways.

Block length affects secondary structure, nanoassembly and thermosensitivity of poly(ethylene glycol)-poly(L-alanine) block copolymers

Poly(ethylene glycol)-conjugated polypeptides have been drawing attention as a biomaterial as well as a pharmaceutical agent. In this paper, we synthesized a series of poly(ethylene glycol)-poly(L-alanine) block copolymers (PEG-L-PA) and investigated the block length effect on (1) the secondary structure of the PA, (2) the nanostructure of the self-assembled amphiphilic PEG-L-PA, and (3) the thermosensitivity of the PEG-L-PA aqueous solution. First, the molecular weight of the L-PA was fixed at 700–760 Daltons and that of the conjugated PEG varied over 1,000, 2,000, and 5,000 Daltons. L-PA with an antiparallel β-sheet structure in water transformed into an α-helical structure, and the self-assembled nanostructure of PEG-L-PA changed from a fibrous structure to a spherical micellar structure as the molecular weight of conjugated PEG increased. Then, when the molecular weight changed from 700 to 1,500 Daltons at a fixed molecular weight of PEG at 2,000, similar transitions involving antiparallel β-sheets changing to α-helices, and fibers to spherical micelles were observed. The polymer aqueous solution underwent a sol-to-gel transition as the temperature increased in a high polymer concentration range of 3–14 wt%. Interestingly, the transition temperature did not follow the simple rule that a more hydrophobic polymer has a lower transition temperature. This paper suggests that the control of PEG molecular weight in PEG-conjugated polypeptide biomaterials is important in that it affects the secondary structure of the polypeptide, the nanoassembled morphology, and the thermosensitivity of the polymer.

3D Culture of Adipose-Tissue-Derived Stem Cells Mainly Leads to Chondrogenesis in Poly(ethylene glycol)-Poly(l-alanine) Diblock Copolymer Thermogel

Poly(ethylene glycol)-b-poly(L-alanine) (PEG-L-PA)s with L-PA molecular weights of 620, 1100, and 2480 Da and a fixed molecular weight of PEG at 5000 Da were synthesized to compare the thermosensitive behavior, and to investigate their potential as a three-dimensional (3D) culture matrix of adipose-tissue-derived stem cells (ADSCs). The sol-to-gel transition temperature and the concentration ranges where the transition was observed decreased as the L-PA molecular weight increased. ADSCs were cultured in the 3D matrixes of in situ formed PEG-L-PA hydrogels, which were produced by increasing the temperature of cell-suspended PEG-L-PA aqueous solutions. The spherical morphology was maintained in the PEG-L-PA hydrogel, while the cells underwent fibroblastic morphological changes in the Matrigel over 14 days of incubation. ADSCs exhibited high expression of type II collagen in the PEG-L-PA thermogel. In addition, they also moderately expressed the biomarker of myogenic differentiation factor 1 as the same mesodermal lineages, as well as the type III β-tubulin as a cross-differentiation biomarker. Similar to the in vitro study, the ADSCs predominantly exhibited chondrogenic biomarkers in the in vivo study. The study demonstrates that the polypeptide thermogel of PEG-L-PA is promising as a 3D culture matrix of ADSCs and as an injectable tissue engineering biomaterial.

Cell therapy for skin wound using fibroblast encapsulated poly(ethylene glycol)-poly(L-alanine) thermogel.

As a new application of a thermogel, a poly(ethylene glycol)-b-poly(L-alanine) (PEG-L-PA) gel encapsulating fibroblasts was investigated for wound healing. The fibroblasts were encapsulated by the temperature sensitive sol-to-gel transition of the polymer aqueous solution. Under the in vitro three-dimensional (3D) cell culture condition, the PEG-L-PA thermogel was comparable with Matrigel for cell proliferation and was significantly better than Matrigel for collagen types I and III formation. After confirming the excellent 3D microenvironment of the PEG-L-PA thermogel for fibroblasts, in vivo wound healing was investigated by injecting the cell-suspended polymer aqueous solution on incisions of rat skin, where the cell-encapsulated gel was formed in situ. Compared with the phosphate buffered saline treated system and the cell-free PEG-L-PA thermogel, the cell-encapsulated PEG-L-PA thermogel not only accelerated the wound closure but also improved epithelialization and the formation of skin appendages such as keratinocyte layer (epidermis), hair follicles, and sebaceous glands. The results demonstrate the potential of thermogels for cell therapy as an injectable tissue-engineering scaffold.

Tonsil-derived Mesenchymal Stem Cells Ameliorate CCl4–induced Liver Fibrosis in Mice via Autophagy Activation

Liver transplantation is the treatment of choice for chronic liver failure, although it is complicated by donor shortage, surgery-related complications, and immunological rejection. Cell transplantation is an alternative, minimally invasive treatment option with potentially fewer complications. We used human palatine tonsil as a novel source of mesenchymal stem cells (T-MSCs) and examined their ability to differentiate into hepatocyte-like cells in vivo and in vitro. Carbon tetrachloride (CCl4) mouse model was used to investigate the ability of T-MSCs to home to the site of liver injury. T-MSCs were only detected in the damaged liver, suggesting that they are disease-responsive. Differentiation of T-MSCs into hepatocyte-like cells was confirmed in vitro as determined by expression of hepatocyte markers. Next, we showed resolution of liver fibrosis by T-MSCs via reduction of TGF-β expression and collagen deposition in the liver. We hypothesized that autophagy activation was a possible mechanism for T-MSC-mediated liver recovery. In this report, we demonstrate for the first time that T-MSCs can differentiate into hepatocyte-like cells and ameliorate liver fibrosis via autophagy activation and down-regulation of TGF-β. These findings suggest that T-MSCs could be used as a novel source for stem cell therapy targeting liver diseases.

Enzymatically degradable thermogelling poly(alanine-co-leucine)-poloxamer-poly(alanine-co-leucine).

In the search for an enzymatically degradable thermogelling system, we are reporting poly(alanine-co-leucine)-poloxamer-poly(alanine-co-leucine) (PAL-PLX-PAL) aqueous solution. As the temperature increased, the polymer aqueous solution underwent sol-to-gel transition at 20-40 °C in a polymer concentration range of 3.0-10.0 wt %. The amphiphilic polymers of PAL-PLX-PAL form micelles in water, where the hydrophobic PALs form a core and the hydrophilic PLXs form a shell of the micelle. FTIR, circular dichroism, and (13)C NMR spectra suggest that the α-helical secondary structure of PAL is preserved; however, the molecular motion of the PLX significantly decreases in the sol-to-gel transition range of 20-50 °C. The polymer was degraded by proteolytic enzymes such as matrix metalloproteinase and elastase, whereas it was quite stable against cathepsin B, cathepsin C, and chymotrypsin or in phosphate-buffered saline (control). The in situ formed gel in the subcutaneous layer of rats showed a duration of ∼ 47 days, and H&E staining study suggests the histocompatibility of the gel in vivo with a marginal inflammation response of capsule formation. A model drug of bovine serum albumin was released over 1 month by the preset-gel injection method. The thermogelling PAL-PLX-PAL can be a promising biocompatible material for minimally invasive injectable drug delivery.

3D Culture of Tonsil-Derived Mesenchymal Stem Cells in Poly(ethylene glycol)-Poly(l-alanine-co-l-phenyl alanine) Thermogel

Poly(ethylene glycol)-poly(L-alanine-co-L-phenyl alanine) (PEG-PAF) aqueous solutions undergo sol-to-gel transition as the temperature increases. The transition is driven by the micelle aggregation involving the partial dehydration of the PEG block and the partial increase in β-sheet content of the PAF block. Tonsil-tissue-derived mesenchymal stem cells (TMSCs), a new stem cell resource, are encapsulated through the sol-to-gel transition of the TMSC-suspended PEG-PAF aqueous solutions. The encapsulated TMSCs are in vitro 3D cultured by using induction media supplemented with adipogenic, osteogenic, or chondrogenic factors, where the TMSCs preferentially undergo chondrogenesis with high expressions of type II collagen and sulfated glycosaminoglycan. As a feasibility study of the PEG-PAF thermogel for injectable tissue engineering, the TMSCs encapsulated in hydrogels are implanted in the subcutaneous layer of mice by injecting the TMSC suspended PEG-PAF aqueous solution. The in vivo studies also prove that TMSCs undergo chondrogenesis with high expression of the chondrogenic biomarkers. This study suggests that the TMSCs can be an excellent resource of MSCs, and the thermogelling PEG-PAF is a promising injectable tissue engineering scaffold, particularly for chondrogenic differentiation of the stem cells.

Reverse thermal gelation of PAF-PLX-PAF block copolymer aqueous solution.

The aqueous solution of poly(L-Ala-co-L-Phe)-poly(propylene glycol)-poly(ethylene glycol)-poly(propylene glycol)-poly(L-Ala-co-L-Phe) block copolymers (PAF-PLX-PAF) in a concentration range of 6.0-10.0 wt % underwent sol-to-gel transition as the temperature increased from 10 to 50 degrees C. Circular dichroism spectra, hydrophobic dye solubilization, dynamic light scattering, and transmission electron microscopy image of the polymer suggest that the polymers form micelles in water, where the hydrophilic (PLX) blocks form a shell and the hydrophobic (PAF) blocks form a core of the micelle. Circular dichroism, FTIR, and (13)C NMR spectra suggest that sol-to-gel transition accompanies partial strengthening of the beta-sheet structure of PAF and a decrease in molecular motion of the PLX. The sol-to-gel transition temperature could be controlled by varying the molecular weight of PAF and PLX blocks, the ratio of Ala to Phe, and the corresponding secondary structure of the polypeptide.