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- All Subjects: Molecular Biology
- All Subjects: Pleiotrophin
- Creators: Wang, Xu
Pleiotrophin (PTN) is a cell-signaling protein in the human body that plays a pivotal role in the development of the central nervous system. It is known to have a high affinity for glycosaminoglycan (GAG), a type of linear polysaccharide. PTN has the ability to bind to a wide range of receptors, including receptor-type protein tyrosine phosphatase ζ (PTPRZ), a protein expressed in embryonic stem cells that regulates signals associated with survival, cell proliferation, and stem cell pluripotency. Several of these receptors are proteoglycans that carry GAGs, and the interaction between PTN and GAG has proven to be crucial to PTN’s functionality. Though PTN performs several important biochemical duties in normal cellular processes, this protein is upregulated in various cancer cell lines, primarily glioblastoma, an aggressive form of cancer that arises in the brain or spinal cord. The high levels of PTN expression in these forms of cancer may correlate to the cancer cells’ metastatic ability in the body. Determining how these PTN-GAG interactions form in cells is imperative for understanding how they may correlate to the development of cancer cell lines such as glioblastoma. However, due to the NMR signal degeneracy among the lysines in PTN, it is currently not possible to distinguish between lysines that have strong interactions with GAG and those that do not. To overcome this, pyrrolysyl-tRNA synthetase-mediated amber codon suppression is used to incorporate a single 15N-labeled lysine, Boc-lysine (Boc-K), at a specific position. This thesis seeks to optimize the systems and conditions needed to achieve amber codon suppression. The Origami B (DE3) strain is commonly used to achieve this, and demonstrates positive expression of PTN. The first aim of this project is to determine whether SHuffle® demonstrates enhanced expression of PTN and, therefore, incorporation of Boc-K. However, upon comparing PTN expression results, it was found that SHuffle® and Origami B(DE3) demonstrated similar levels of PTN expression. This project's second phase is focused on using C321.ΔA (Church) strain to evaluate differences in PTN expression compared to SHuffle® and Origami B(DE3). Expression testing indicated, however, that the expression of PTN in Church strain was inconclusive.
Post Translational Modifications (PTMs) are a series of chemical modifications with the capacity to expand the structural and functional repertoire of proteins. PTMs can regulate protein-protein interaction, localization, protein turn-over, the active state of the protein, and much more. This can dramatically affect cell processes as relevant as gene expression, cell-cell recognition, and cell signaling. Along these lines, this Ph.D. thesis examines the role of two of the most important PTMs: glycosylation and phosphorylation.
In chapters 2, 3 and 4, a 10,000 peptide microarray is used to analyze the glycan variations in a series lipopolysaccharides (LPS) from Gram negative bacteria. This research was the first to demonstrate that using a small subset of random sequence peptides, it was possible to identify a small subset with the capacity to bind to the LPS of bacteria. These peptides bound to LPS not only in the solid surface of the array but also in solution as demonstrated with surface plasmon resonance (SPR), isothermal titration calorimetry (ITC) and flow cytometry. Interestingly, some of the LPS binding peptides also exhibit antimicrobial activity, a property that is also analyzed in this work.
In chapters 5 and 6, the role of protein phosphorylation, another PTM, is analyzed in the context of human cancer. High risk neuroblastoma, a very aggressive pediatric cancer, was studied with emphasis on the phosphorylations of two selected oncoproteins: the transcription factor NMYC and the adaptor protein ShcC. Both proteins were isolated from high risk neuroblastoma cells, and a targeted-directed tandem mass spectrometry (LC-MS/MS) methodology was used to identify the phosphorylation sites in each protein. Using this method dramatically improved the phosphorylation site detection and increased the number of sites detected up to 250% in comparison with previous studies. Several of the novel identified sites were located in functional domain of the proteins and that some of them are homologous to known active sites in other proteins of the same family. The chapter concludes with a computational prediction of the kinases that potentially phosphorylate those sites and a series of assays to show this phosphorylation occurred in vitro.
The molecular structure of caddisfly larval silk from the species Hesperophylax consimilis was characterized using solid-state nuclear magnetic resonance (ss-NMR) and Wide Angle X-ray Diffraction (WAXD) techniques. This insect, which typically dwells in freshwater riverbeds and streams, uses silk fibers as a strong and sticky nanoadhesive material to construct cocoons and cases out available debris. Conformation-sensitive 13C chemical shifts and 31P chemical shift anisotropy (CSA) information strongly support a unique protein motif in which phosphorylated serine- rich repeats (pSX)4 complex with di- and trivalent cations to form rigid nanocrystalline β-sheets. Additionally, it is illustrated through 31P NMR and WAXD data that these nanocrystalline structures can be reversibly formed, and depend entirely on the presence of the stabilizing cations.
Nanofiber silks produced by webspinners (order Embioptera) were also studied herein. This work addresses discrepancies in the literature regarding fiber diameters and tensile properties, revealing that the nanofibers are about 100 nm in diameter, and are stronger (around 500 MPa mean ultimate stress) than previous works suggested. Fourier-transform Infrared Spectroscopy (FT-IR), NMR and WAXD results find that approximately 70% of the highly repetitive glycine- and serine-rich protein core is composed of β-sheet nanocrystalline structures. In addition, FT-IR and Gas-chromatography mass spectroscopy (GC-MS) data revealed a hydrophobic surface coating rich in long-chain lipids. The effect of this surface coating was studied with contact angle techniques; it is shown that the silk sheets are extremely hydrophobic, yet due to the microstructural and nanostructural details of the silk surface, are surprisingly adhesive to water.
tissue growth, development, and repair. First isolated from neuronal tissues, much interest in this protein resides in development of the central nervous system and neuronal regeneration. Owning to its role in growth, development and its ability to promote angiogenesis and metastasis, PTN’s overexpression in cancers such as glioblastoma, has become the focal point of much research. Many of the receptors through which PTN acts contain glycosaminoglycans (GAGs), through which PTN binds. Thus, understanding the atomistic detail of PTN’s architecture and interaction with GAG chains is of significant importance in elucidating its functional role in growth and malignancy of biological tissues, as well as in neural development and progression of other diseases. Herein the first solution state structure of PTN was solved via nuclear magnetic resonance (NMR), with extensive characterization of its ability to bind GAG. Structurally, PTN consists of two -sheet domains connected by a short flexible linker, and flanked by long flexible termini. Broad distribution of positively charged amino acids in the protein’s sequence yields highly basic surfaces on the -sheet domains as well as highly cationic termini. With GAG chains themselves being linear anionic polymers, all interactions between these sugars and PTN are most exclusively driven through the electrostatic interactions between them, with no discernable specificity for GAG types. Moreover, this binding event is coordinated mostly through basic patches located in the C-Terminal domain (CTD). Although the flexible C- terminus has been shown to play a significant role in receptor binding, data here also reveal an adaptability of PTN to maintain high affinity interactions through its structured domains
when termini are removed. Additionally, analysis of binding information revealed for the first time the presence of a secondary GAG binding site within PTN. It is shown that PTN’s CTD constitutes the major binding site, while the N-terminal domain (NTD) contains the much weaker secondary site. Finally, compilation of high-resolution data containing the atomistic detail of PTN’s interaction with GAG provided the information necessary to produce the highest accuracy model to date of the PTN-GAG complex. Taken together, these findings provide means for specific targeting of this mitogenic cytokine in a wide array of biological applications.
Novel approaches for highly multiplexed single cell in situ transcriptomic analysis were developed by our group to enable single-cell comprehensive RNA profiling in their native spatial contexts. Reiterative FISH was demonstrated to be able to detect >100 RNA species in single cell in situ, while more sophisticated approaches, consecutive FISH (C-FISH) and switchable fluorescent oligonucleotide based FISH (SFO-FISH), have the potential for whole transcriptome profiling at the single molecule sensitivity. The introduction of a cleavable fluorescent tyramide even enables sensitive RNA profiling in intact tissues with high throughput. These approaches will have wide applications in studies of systems biology, molecular diagnosis and targeted therapies.