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Browsing by Author "Li, Zhuo"

Now showing 1 - 3 of 3
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    Bio-based composites that mimic the plant cell wall
    Li, Zhuo (Virginia Tech, 2009-04-22)
    Nature creates high performance materials under modest conditions, i.e., neutral pH and ambient temperature and pressure. One of the most significant materials is the plant cell wall. The plant cell wall is a composite of oriented cellulose microfibrils reinforcing a lignin/hemicellulose matrix. In principle, the plant cell wall composite is designed much like a synthetic fiber-reinforced polymer composite. Unlike synthetic composites, the plant cell wall has an excellent combination of high modulus, strength, toughness and low density that originates in the optimal interactions between the biopolymers. Therefore, to produce high performance composites, a unique route may be to mimic a biological system like the plant cell wall. The present work focuses on understanding the thermodynamics of biopolymer assembly to exploit the process in vitro. In our system, we use an already polymerized nanocellulose template and polymerize phenolic monomers on the template using a peroxidase enzyme. In the first part, we have polymerized phenol using horseradish peroxidase (HRP) in the presence of TEMPO-oxidized nanocellulose. Similar to native plant cell wall structures, the polyphenol-nanocellulose composite had intimate mixing of polyphenol and cellulose at the nanoscale with the presence of cellulose promoting a uniquely organized structure. The obtained composite material showed synergy that enhanced the thermal stability, hydrophobicity, and possibly mechanical properties. In the second part, monolignol coniferyl alcohol was polymerized in the presence of nanocellulose by the same procedure. A comparison between the polyphenol composite and poly(coniferyl alcohol) (PCA) composite revealed that the propanyl substitution imparted flexibility to the PCA molecules so that they could bend and form a hollow globule structure to envelope nanocellulose inside. Polyphenol could not do this because of its rigidity.
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    Demonstration of Interactions Among Dif Proteins and the Identification of Kapb as a Regulator of Exopolysaccharide in Myxococcus Xanthus
    Li, Zhuo (Virginia Tech, 2007-05-01)
    Myxococcus xanthus Dif proteins are chemotaxis homologues that regulate exopolysaccharide (EPS) biogenesis. Previous genetic studies suggested that Dif protein might interact with one another as do the chemotaxis proteins in enterics. The interactions among Dif proteins were since investigated with the yeast two-hybrid (Y2H) system. The results indicate that DifC interacts with both DifA and DifE. Using a modified Y2H system, DifC was shown to be able to bring DifA and DifE into a protein complex. Further Y2H experiments demonstrated that the different conserved domains of DifE likely function as their counterparts of CheA-type kinases because the putative P2 domain of DifE interacts with DifD, P5 with DifC and the dimerization domain P3 with itself. Similarly, DifA can interact with itself through its C-terminal region. In addition, DifG was found to interact with the CheY homologue DifD. These findings support the notion that Dif proteins constitute a unique chemotaxis-like signal transduction pathway in M. xanthus. In addition, KapB, a TPR (Tetratricopeptide repeats) protein, was identified as an interacting partner of DifE byY2H library screening. Further analysis demonstrated that the N-terminal half of KapB interacted with the putative P2 domain of DifE. KapB had been previously reported to interact with several Serine/Threonine (Ser/Thr) kinase pathways including the Pkn4-Pfk pathway. This pathway is implicated in glycogen metabolism in M. xanthus by a previous report. In this study, kapB as well as pfkn deletion mutants were found to overproduce EPS. It was also found that the Dif pathway is involved in glycogen metabolism because the glycogen level is altered in dif mutants. These results indicate EPS biogenesis and glycogen metabolism may be coordinately regulated. This coordination of the Dif-regulated EPS production and the Pkn4-regulated glycogen metabolism appears to involve KapB. This is the first example of a TPR protein mediating the interplays of a histidine kinase pathway and a Ser/Thr kinase pathway.
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    The Hsp70-like StkA functions between T4P and Dif signaling proteins as a negative regulator of exopolysaccharide in Myxococcus xanthus
    Moak, Pamela L.; Black, Wesley P.; Wallace, Regina A.; Li, Zhuo; Yang, Zhaomin (PeerJ, 2015-02-03)
    Myxococcus xanthus displays a form of surface motility known as social (S) gliding. It is mediated by the type IV pilus (T4P) and requires the exopolysaccharide (EPS) to function. It is clear that T4P retraction powers S motility. EPS on a neighboring cell or deposited on a gliding surface is proposed to anchor the distal end of a pilus and trigger T4P retraction at its proximal end. Inversely, T4P has been shown to regulate EPS production upstream of the Dif signaling pathway. Here we describe the isolation of two Tn insertions at the stk locus which had been known to play roles in cellular cohesion and formation of cell groups. An insertion in stkA (MXAN_3474) was identified based on its ability to restore EPS to a pilA deletion mutant. The stkA encodes a DnaK or Hsp70 homolog and it is upstream of stkB (MXAN_3475) and stkC (MXAN_3476). A stkB insertion was identified in a separate genetic screen because it eliminated EPS production of an EPS+ parental strain. Our results with in-frame deletions of these three stk genes indicated that the stkA mutant produced increased level of EPS while stkB and stkC mutants produced less EPS relative to the wild type. S motility and developmental aggregation were affected by deletions of stkA and stkB but only minimally by the deletion of stkC. Genetic epistasis indicated that StkA functions downstream of T4P but upstream of the Dif proteins as a negative regulator of EPS production in M. xanthus.