Project description:How DNA damaged is formed, recognized, and repaired in chromatin is an area of intense study. To better understand the structure activity relationships of damaged chromatin, mono and dinucleosomes containing site-specific damage have been prepared and studied. This review will focus on the design, synthesis, and characterization of model systems of damaged chromatin for structural, physical, and enzymatic studies.

Project description:Chemotherapy commonly used in the treatment of advanced bladder cancer is only moderately effective and associated with significant toxicity. There has been no appreciable improvement in overall survival over the last three decades. The goal of this project is to develop and characterize bladder cancer-specific nanometer-scale micelles loaded with the chemotherapeutic drug paclitaxel (PTX) and determine the anti-tumor activity and toxicity. Micelle-building-material telodendrimers were synthesized through the stepwise conjugation of eight cholic acid units at one terminus of polyethylene glycol (PEG) and a bladder cancer-specific targeting peptide named PLZ4 at the other terminus. To synthesize disulfide-crosslinked PLZ4 nanomicelles (DC-PNM), cysteine was introduced between the cholic acid and PEG. DC-PNM-PTX was synthesized through the evaporation method by loading PTX in the core. The loading capacity of PTX in DC-PNM was 25% (W/W). The loading efficiency was over 99%. DC-PNM-PTX was spherical with the median size of 25 nm. The stability of DC-PNM-PTX was determined in a solution containing sodium docecyl sulfate (SDS). It was stable in a SDS solution, but dissolved within 5 min after the addition of glutathione at the physiological intracellular concentration of 10 mM. In vivo targeting and anti-tumor activity were determined in immunodeficient mice carrying patient-derived bladder cancer xenografts (PDXs). After intravenous administration, DC-PNM specifically targeted the bladder cancer PDXs, but very little to the lung cancer xenografts in the same mice (p < 0.001). DC-PNM loaded with PTX overcame cisplatin resistance, and improved the median survival from 55 d with free PTX to 69.5 d (p = 0.03) of mice carrying PDXs. In conclusion, DC-PNM remained stable in the SDS solution, specifically targeted the bladder cancer xenografts in vivo, and improved the anti-cancer efficacy of PTX.

Project description:Enzyme stability is an important issue for protein engineers. Understanding how rigidity in the active site affects protein kinetic stability will provide new insight into enzyme stabilization. In this study, we demonstrated enhanced kinetic stability of Candida antarctica lipase B (CalB) by mutating the structurally flexible residues within the active site. Six residues within 10 ? of the catalytic Ser(105) residue with a high B factor were selected for iterative saturation mutagenesis. After screening 2200 colonies, we obtained the D223G/L278M mutant, which exhibited a 13-fold increase in half-life at 48 °C and a 12 °C higher T50(15), the temperature at which enzyme activity is reduced to 50% after a 15-min heat treatment. Further characterization showed that global unfolding resistance against both thermal and chemical denaturation also improved. Analysis of the crystal structures of wild-type CalB and the D223G/L278M mutant revealed that the latter formed an extra main chain hydrogen bond network with seven structurally coupled residues within the flexible ?10 helix that are primarily involved in forming the active site. Further investigation of the relative B factor profile and molecular dynamics simulation confirmed that the enhanced rigidity decreased fluctuation of the active site residues at high temperature. These results indicate that enhancing the rigidity of the flexible segment within the active site may provide an efficient method for improving enzyme kinetic stability.

Project description:Minicollagens from cnidarian nematocysts are attractive potential building blocks for the creation of strong, lightweight and tough polymeric materials with the potential for dynamic and reconfigurable crosslinking to modulate functionality. In this study, the Hydra magnipapillata minicollagen-1 isoform was recombinantly expressed in bacteria, and a high throughput purification protocol was developed to generate milligram levels of pure protein without column chromatography. The resulting minicollagen-1 preparation demonstrated spectral properties similar to those observed with collagen and polyproline sequences as well as the ability to self-assemble into oriented fibers and bundles. Photo-crosslinking with Ru(II) (bpy)32+ was used to create robust hydrogels that were analyzed by mechanical testing. Interestingly, the minicollagen-1 hydrogels could be dissolved with reducing agents, indicating that ruthenium-mediated photo-crosslinking was able to induce disulfide metathesis to create the hydrogels. Together, this work is an important first step in creating minicollagen-based materials whose properties can be manipulated through static and reconfigurable post-translational modifications.

Project description:We employ stable-isotope labeling and quantitative mass spectrometry to track histone methylation stability. We show that H3 trimethyl K9 and K27 are slow to be established on new histones and slow to disappear from old histones, with half-lives of multiple cell divisions. By contrast, the transcription-associated marks K4me3 and K36me3 turn over far more rapidly, with half-lives of 6.8 h and 57 h, respectively. Inhibition of demethylases increases K9 and K36 methylation, with K9 showing the largest and most robust increase. We interpret different turnover rates in light of genome-wide localization data and transcription-dependent nucleosome rearrangements proximal to the transcription start site.

Project description:The aim of this study was to evaluate the persistence of alkaline hydrogels based on a common (N,N′-methylenebisacrylamide, BIS) and three recently published tetraallyl crosslinkers. Such hydrogels have been shown to be suitable materials for the rehabilitation of cementitious materials. Of the four crosslinkers under investigation, N,N,N′,N′-tetraallylpiperazinium dibromide decomposed quickly in 1 m KOH solution and was not considered further. BIS showed the first signs of a decomposition after several days, while tetraallylammonium bromide and N,N,N′,N′-tetraallyltrimethylene dipiperidine dibromide remained unaffected. In contrast to BIS, which suffers from low solubility in water, the two tetraallyl crosslinkers show unlimited miscibility with diallyldimethylammonium hydroxide solutions. For the study, gels with up to 50 wt % crosslinker were prepared. Of these, gels containing tetraallylammonium bromide always show the highest degrees of swelling, with a peak value of 397 g/g at a content of 2 wt %. Under accelerated ageing at 60 °C for 28 d, gels crosslinked with BIS ultimately turned liquid, while the storage modulus and the degree of swelling of the two tetraallyl-crosslinked gels remained unchanged. This indicates that alkaline gels can be suitable for long application periods, which are common for rehabilitation measures in the construction industry.

Project description:The monomer surface mobility is the single most important parameter that decides the nucleation density and morphology of islands during thin-film growth. During template-assisted surface growth in particular, low surface mobilities can prevent monomers from reaching target sites and this results in a partial to complete loss of nucleation control. Whereas in atomic systems a broad range of surface mobilities can be readily accessed, for colloids, owing to their large size, this window is substantially narrow and therefore imposes severe restrictions in extending template-assisted growth techniques to steer their self-assembly. Here, we circumvented this fundamental limitation by designing templates with spatially varying feature sizes, in this case moiré patterns, which in the presence of short-range depletion attraction presented surface energy gradients for the diffusing colloids. The templates serve a dual purpose: first, directing the particles to target sites by enhancing their surface mean-free paths and second, dictating the size and symmetry of the growing crystallites. Using optical microscopy, we directly followed the nucleation and growth kinetics of colloidal islands on these surfaces at the single-particle level. We demonstrate nucleation control, with high fidelity, in a regime that has remained unaccessed in theoretical, numerical, and experimental studies on atoms and molecules as well. Our findings pave the way for fabricating nontrivial surface architectures composed of complex colloids and nanoparticles as well.

Project description:Use of atomic force microscopy (AFM) has recently led to a better understanding of the molecular mechanisms of the unfolding process by mechanical forces; however, the rational design of novel proteins with specific mechanical strength remains challenging. We have approached this problem from a new perspective that generates linear physical-chemical properties (PCP) motifs from a limited AFM data set. Guided by our linear sequence analysis, we designed and analyzed four new mutants of the titin I1 domain with the goal of increasing the domain's mechanical strength. All four mutants could be cloned and expressed as soluble proteins. AFM data indicate that at least two of the mutants have increased molecular mechanical strength. This observation suggests that the PCP method is useful to graft sequences specific for high mechanical stability to weak proteins to increase their mechanical stability, and represents an additional tool in the design of novel proteins besides steered molecular dynamics calculations, coarse grained simulations, and ?-value analysis of the transition state.

Project description:Background: Chinese hamster ovary (CHO) cells are the most widely used mammalian host for recombinant protein production. The primary production method is to construct stable, high-yielding cell lines to provide high-quality, low-cost products. The key to optimizing recombinant protein production is to modify engineered cell lines to obtain better growth, expression, or product quality characteristics. Site-specific integration technology can build monoclonal cell lines with ideal stability, yield, and epigenetics by integrating transgenes at stable transcriptional hotspots, becoming a potential tool for constructing genetically engineered cell lines. The previous study screened the C12orf35 site of CHO cells and built an engineered cell line expressing a mAb by CRISPR/Cas9. While the mechanism of site-specific integration of transgenes to achieve high-efficiency expression also needs to be further studied. In this study, we used the extracellular domains of CLL1 and CD33 as model proteins to construct engineered cell lines integrating at C12orf35. Then we studied the growth, expression, and passage stability of these cell lines and conducted transcriptomic studies. Method: In this study, the transgenes CLL1 and CD33 were site-specifically integrated into the C12orf35 site of the CHO-S cell by CRISPR/Cas9 technology. To obtain stable and high-yielding cell lines, we screened and identified monoclonal cell lines by 5’/3’ junction PCR, out-out PCR, and Western blot. Then we compared the growth characteristics of CLL1 and CD33 monoclonal cell lines with wild-type CHO-S cell lines to investigate the growth characteristics. We studied the protein yield and affinity of CLL1 and CD33 cell lines through protein purification, BCA quantification, and ELISA. In addition, we assessed the stability of monoclonal cell lines in long-term culture by studying the growth characteristics, protein yield, and protein quality of early (5th-10th passage) and late (about 20th-25th passage) cells. We performed transcriptomic studies on cell lines with different transgenes, including CLL1, CD33, and anti-PD-1 mAb, inserted at C12orf35. We analyzed the differential genes, GO enrichment, and KEGG enrichment of cell lines hoping to explore the reasons for the phenotypic changes of cell lines from the transcriptional level, as well as the high expression mechanism of C12orf35 site-specific integration cell lines. Results:Using the site-specific integration technology mediated by CRISPR/Cas9, we successfully built CLL1 and CD33 monoclonal cell lines integrated at the C12orf35 site. We evaluated the cell growth characteristics and protein expression properties. The results showed that the insertion of different transgenes at the C12orf35 site had no specific effect on the growth state of the cells. The proteins yields were about 120 mg/L and 160 mg/L, respectively. And the EC50 values of CLL1 and CD33 with the corresponding antibodies reached about 0.36 μg/mL and 0.1 μg/mL, respectively. In addition, the above indicators had similar properties between the 5th and 20th generations, indicating that the specific integration at C12orf35 can achieve both high expression of the target protein and production stability. Transcriptomic analysis showed that the integration of transgenes at the C12orf35 site of CHO cells mainly induced genes in the GO term of “Regulation of transcription, DNA-templated” differentially expressed. Further analysis screened that ATF4 and multiple ZFPs family members were significantly up-regulated. ATF4 and ZFPs are related to gene transcription and protein synthesis, which may be the mechanism of the stable and high expression of the cell lines. Besides, differential gene analysis showed that Car4 and CXCL12 were significantly up- and down-regulated in CD33 cells, respectively. And KEGG enrichment showed that Wnt, PI3K/AKT, and JAK/STAT pathways related to cell proliferation and apoptosis were significantly enriched in CD33 cells. These genes and pathways may be related to the growth state of CD33. In summary, this paper studied the growth characteristics, protein expression characteristics, and stability of the C12orf35 site-specific integration of recombinant CHO cell lines. Combined with transcriptomic analysis, this paper explored the stable and high expression mechanism of these cell lines, hoping to provide a theoretical reference for the subsequent construction and optimization of high-expression stable cell lines.

Project description:Disulfide bonds play an important role in protein folding and stability. However, the cross-linking of sites within proteins by cysteine disulfides has significant distance and dihedral angle constraints. Here we report the genetic encoding of noncanonical amino acids containing long side-chain thiols that are readily incorporated into both bacterial and mammalian proteins in good yields and with excellent fidelity. These amino acids can pair with cysteines to afford extended disulfide bonds and allow cross-linking of more distant sites and distinct domains of proteins. To demonstrate this notion, we preformed growth-based selection experiments at nonpermissive temperatures using a library of random ?-lactamase mutants containing these noncanonical amino acids. A mutant enzyme that is cross-linked by one such extended disulfide bond and is stabilized by ?9 °C was identified. This result indicates that an expanded set of building blocks beyond the canonical 20 amino acids can lead to proteins with improved properties by unique mechanisms, distinct from those possible through conventional mutagenesis schemes.