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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Single-molecule Imaging of the Cell Division Ring in Escherichia coli Using the ALFA-tag / Enmolekyl-mikroskopi av delningsringen i Escherichia coli med användandet av ALFA-taggen

Westlund, Emma January 2023 (has links)
The use of super-resolution (SR) microscopy is an important tool for understanding the inside mechanisms of bacterial cells. However, for SR imaging, the labelling of the proteins of interest is a great challenge as flourescent proteins (FPs) are often too big to be directly fused to the target protein and traditional immunolabelling with antibodies creates too long separation between the fluorophore and the target protein. In an attempt to overcome this hurdle, the Escherichia coli (E. coli) cell division protein FtsZ is in this project fused to a nanotag (NT) that is subsequently labelled with a nanobody (NB). The ALFA-tag, a short amino acid peptide, is chromosomally fused to the target protein, creating a MG1655/FtsZ-ALFA strain where all FtsZ proteins have an ALFA-tag attached. Recognising the ALFA-tag is the NB αALFA (anti-ALFA) which is fused to a FP and expressed from a plasmid. The MG1655/FtsZ-ALFA strain is labelled using standard plasmid transformation which allows for live cell imaging of the division ring in E. coli. Both FPs sfGFP and mEos3.2 are used for labelling which means that the cells can be imaged in epifluorescence microscopy and single-molecule Photo-Activated Localisation Microscopy (PALM), and even single-molecule time lapses of the constricting FtsZ-ring is possible. This system is also applicable to other bacterial proteins. / Superupplösningsmikroskopi (SUM) är ett viktigt redskap för att förstå de inre processerna i en bakteriecell. Att på ett framgångsrikt sätt tagga målproteinerna har dock visat sig vara en utmaning för SUM. Att direkttagga målproteinerna med fluorescerande protein är oftast inte möjligt på grund av de fluorescerande proteinernas storlek och traditionell märkning med antikroppar skapar ett för stort avstånd mellan fluorofor och målprotein. För att överkomma detta problem taggas här celldelningsproteinet FtsZ iEscherichia coli (E. coli) med hjälp av nanotaggar (NT) och nanokroppar (NK). ALFA-taggen, en kort aminosyrapeptid, är kromosomt bunden till FtsZ i cellinjen MG1655/FtsZ-ALFA, så att varje FtsZ protein som produceras har en ALFA-tag bunden till sig. NK αALFA (anti-ALFA) känner igen och binder till ALFA-taggen när de kommer i kontakt. NK är bunden till ett fluorescerande protein och uttryckt från en plasmid vilket gör att MG1655/FtsZ-ALFA kan bli taggad med hjälp av vanlig plasmidtransformation. Denna metod möjliggör mikroskopi av divisionsringen i levande E. coli-celler. Två olika fluorescerande protein används, sfGFP och mEos3.2, vilket innebär att både epifluorensmikroskopi och fotoaktiverad lokaliseringsmikroskopi (PALM) kan användas. Dessutom är även intervallfotografering i enmolekylmikroskopi av divisionsringens konstriktion möjligt. Denna märkningsteknik är vidare applicerbar på andra bakteriella protein.
2

Orthogonality and Codon Preference of the Pyrrolysyl-tRNA Synthetase-tRNAPyl pair in Escherichia coli for the Genetic Code Expansion

Odoi, Keturah 2012 May 1900 (has links)
Systematic studies of basal nonsense suppression, orthogonality of tRNAPyl variants, and cross recognition between codons and tRNA anticodons are reported. E. coli displays detectable basal amber and opal suppression but shows a negligible ochre suppression. Although detectable, basal amber suppression is fully inhibited when a pyrrolysyl-tRNA synthetase (PylRS)-tRNAPyl_CUA pair is genetically encoded. trnaPyl_CUA is aminoacylated by an E. coli aminoacyl-tRNA synthetase at a low level, however, this misaminoacylation is fully inhibited when both PylRS and its substrate are present. Besides that it is fully orthogonal in E. coli and can be coupled with PylRS to genetically incorporate a NAA at an ochre codon, tRNAPyl_UUA is not able to recognize an UAG codon to induce amber suppression. This observation is in direct conflict with the wobble base pair hypothesis and enables using an evolved M. jannaschii tyrosyl-tRNA synthetase-tRNAPyl_UUA pair and the wild type or evolved PylRS-tRNAPyl_UUA pair to genetically incorporate two different NAAs at amber and ochre codons. tRNAPyl_UCA is charged by E. coli tryptophanyl-tRNA synthetase, thus not orthogonal in E. coli. Mutagenic studies of trnaPyl_UCA led to the discovery of its G73U form which shows a higher orthogonality. Mutating trnaPyl_CUA to trnaPyl_UCCU not only leads to the loss of the relative orthogonality of tRNAPyl in E. coli but also abolishes its aminoacylation by PylRS.

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