Cell Surface and Membrane Engineering: Emerging Technologies and Applications

Saeui, Christopher T.; Mathew, Mohit P.; Liu, Lingshui; Urias, Esteban; Yarema, Kevin J.

doi:10.3390/jfb6020454

Cited by 26 publications

(18 citation statements)

References 136 publications

(163 reference statements)

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“…B. subtilis DB104, a derivative of strain B. subtilis 168, which only expresses 4% of the extracellular protease activity in comparison to its parental strain, shows an excellent expression and secretion advantage when being used as a cell factory of industrially important extracellular enzymes [26, 27]. Cell envelope engineering has recently been shown to be beneficial to increase yields in industrial processes, such as the production of enzymes, biofuels and chemicals, and this powerful approach is perfectly suitable for novel protein engineering and directed evolution strategies combined high-throughput screening [28, 29]. Inspired by this, cell envelope engineering is employed in this research to alter the properties of cell surface components with the goal of enhancing heterologous protein production in B. subtilis DB104.…”

Section: Discussionmentioning

confidence: 99%

Cell surface engineering of Bacillus subtilis improves production yields of heterologously expressed α-amylases

et al. 2017

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Background Bacillus subtilis is widely used as a cell factory for numerous heterologous proteins of commercial value and medical interest. To explore the possibility of further enhancing the secretion potential of this model bacterium, a library of engineered strains with modified cell surface components was constructed, and the corresponding influences on protein secretion were investigated by analyzing the secretion of α-amylase variants with either low-, neutral- or high- isoelectric points (pI).ResultsRelative to the wild-type strain, the presence of overall anionic membrane phospholipids (phosphatidylglycerol and cardiolipin) increased dramatically in the PssA-, ClsA- and double KO mutants, which resulted in an up to 47% higher secretion of α-amylase. Additionally, we demonstrated that the appropriate net charge of secreted targets (AmyTS-23, AmyBs and AmyBm) was beneficial for secretion efficiency as well.ConclusionsIn B. subtilis, the characteristics of cell membrane phospholipid bilayer and the pIs of heterologous α-amylases appear to be important for their secretion efficiency. These two factors can be engineered to reduce the electrostatic interaction between each other during the secretion process, which finally leads to a better secretion yield of α-amylases.

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Section: Discussionmentioning

confidence: 99%

Cell surface engineering of Bacillus subtilis improves production yields of heterologously expressed α-amylases

et al. 2017

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“…Once the pathogenic cells in samples bind to the antibodies on the biological membrane, calcium flux across the membrane changes due to alteration in membrane structure. The change in calcium flux across the membrane causes change in membrane potential that is detected with high sensitivity [ 80 ].…”

Section: Transducer Technologiesmentioning

confidence: 99%

“… Working principle of Bioelectric Recognition Assay (BERA), a functional principle of an amperometric biosensor. (Reproduced with permission from [ 80 ]). …”

Section: Figurementioning

confidence: 99%

HCV Detection, Discrimination, and Genotyping Technologies

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Song

et al. 2018

Sensors

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According to the World Health Organization (WHO), 71 million people were living with Hepatitis C virus (HCV) infection worldwide in 2015. Each year, about 399,000 HCV-infected people succumb to cirrhosis, hepatocellular carcinoma, and liver failure. Therefore, screening of HCV infection with simple, rapid, but highly sensitive and specific methods can help to curb the global burden on HCV healthcare. Apart from the determination of viral load/viral clearance, the identification of specific HCV genotype is also critical for successful treatment of hepatitis C. This critical review focuses on the technologies used for the detection, discrimination, and genotyping of HCV in clinical samples. This article also focuses on advantages and disadvantages of the reported methods used for HCV detection, quantification, and genotyping.

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“…Synthetic biology and cell surface engineering techniques in vitro and in vivo have resulted in novel tools for the development of membrane biology, 1 offering promising membrane-based devices that may enable new types of artificial tissues, 2 , 3 biosensors, 4 , 5 drug delivery approaches, 6 , 7 3D bio-printing and the study of lipid metabolism. 8 To boost the development of these technologies, there is a growing need to enhance surface engineering techniques of membranes under in vitro and in vivo conditions with particular emphasis on exploiting artificial surface receptors 9 and designing novel biomaterials guided by natural processes, 10 such as self-assembling peptides, proteins and DNA oligonucleotides.…”

Section: Introductionmentioning

confidence: 99%