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1. The crystal structure of bacteriophage λ RexA provides novel insights into the DNA binding properties of Rex-like phage exclusion proteins

Author

Adams, Myfanwy C, primary, Schiltz, Carl J, additional, Sun, Jing, additional, Hosford, Christopher J, additional, Johnson, Virginia M, additional, Pan, Hao, additional, Borbat, Peter P, additional, Freed, Jack H, additional, Thomason, Lynn C, additional, Court, Carolyn, additional, Court, Donald L, additional, and Chappie, Joshua S, additional

Published
2024
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2. tCRISPRi: tunable and reversible, one-step control of gene expression.

Author

Li, Xin-Tian, Jun, Yonggun, Erickstad, Michael J, Brown, Steven D, Parks, Adam, Court, Donald L, and Jun, Suckjoon

Subjects
Arabinose, Bacterial Proteins, Genetic Engineering, Gene Expression, Gene Expression Regulation, Bacterial, Operon, Promoter Regions, Genetic, Gene Knockout Techniques, CRISPR-Cas Systems, Gene Expression Regulation, Bacterial, Promoter Regions, Genetic, Genetics, Biotechnology, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

The ability to control the level of gene expression is a major quest in biology. A widely used approach employs deletion of a nonessential gene of interest (knockout), or multi-step recombineering to move a gene of interest under a repressible promoter (knockdown). However, these genetic methods are laborious, and limited for quantitative study. Here, we report a tunable CRISPR-cas system, "tCRISPRi", for precise and continuous titration of gene expression by more than 30-fold. Our tCRISPRi system employs various previous advancements into a single strain: (1) We constructed a new strain containing a tunable arabinose operon promoter PBAD to quantitatively control the expression of CRISPR-(d)Cas protein over two orders of magnitude in a plasmid-free system. (2) tCRISPRi is reversible, and gene expression is repressed under knockdown conditions. (3) tCRISPRi shows significantly less than 10% leaky expression. (4) Most important from a practical perspective, construction of tCRISPRi to target a new gene requires only one-step of oligo recombineering. Our results show that tCRISPRi, in combination with recombineering, provides a simple and easy-to-implement tool for gene expression control, and is ideally suited for construction of both individual strains and high-throughput tunable knockdown libraries.

Published
2016

5. The crystal structure of bacteriophage lambda RexA provides novel insights into the DNA binding properties of Rex-like phage exclusion proteins

Author

Adams, Myfanwy C, primary, Schiltz, Carl J, additional, Sun, Jing, additional, Hosford, Christopher J, additional, Johnson, Virginia M, additional, Pan, Hao, additional, Borbat, Peter P, additional, Freed, Jack H, additional, Thomason, Lynn C, additional, Court, Carolyn, additional, Court, Donald L, additional, and Chappie, Joshua S, additional

Published
2023
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24. Recombineering in Prokaryotes

Author

Thomason, Lynn C., primary, Myers, Richard S., additional, Oppenheim, Amos, additional, Costantino, Nina, additional, Sawitzke, James A., additional, Datta, Simanti, additional, Bubunenko, Mikhail, additional, and Court, Donald L., additional

Published
2014
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28. Transcription antitermination by translation initiation factor IF1

Author

Phadtare, Sangita, Kazakov, Teymur, Bubunenko, Mikhail, Court, Donald L., Pestova, Tatyana, and Severinov, Konstantin

Subjects
Protein folding -- Research, Escherichia coli -- Genetic aspects, Escherichia coli -- Research, Genetic transcription -- Research, Molecular chaperones -- Research, Genetic translation -- Research, Biological sciences
Abstract

Bacterial translation initiation factor IF1 is an S1 domain protein that belongs to the oligomer binding (OB) fold proteins. Cold shock domain (CSD)-containing proteins such as CspA (the major cold shock protein of Escherichia coil) and its homologues also belong to the OB fold protein family. The striking structural similarity between IF1 and CspA homologues suggests a functional overlap between these proteins. Certain members of the CspA family of cold shock proteins act as nucleic acid chaperones: they melt secondary structures in nucleic acids and act as transcription antiterminators. This activity may help the cell to acclimatize to low temperatures, since cold-induced stabilization of secondary structures in nascent RNA can impede transcription elongation. Here we show that the E. colt translation initiation factor, IF1, also has RNA chaperone activity and acts as a transcription anti-terminator in vivo and in vitro. We further show that the RNA chaperone activity of IF1, although critical for transcription antitermination, is not essential for its role in supporting cell growth, which presumably functions in translation. The results thus indicate that IF1 may participate in transcription regulation and that cross talk and/or functional overlap may exist between the Csp family proteins, known to be involved in transcription regulation at cold shock, and S1 domain proteins, known to function in translation.

Published
2007

29. Essentiality of ribosomal and transcription antitermination proteins analyzed by systematic gene replacement in Escherichia coli

Author

Bubunenko, Mikhail, Baker, Teresa, and Court, Donald L.

Subjects
Escherichia coli -- Genetic aspects, Escherichia coli -- Research, Genetic transcription -- Research, Ribosomal proteins -- Research, Biological sciences
Abstract

We describe here details of the method we used to identify and distinguish essential from nonessential genes on the bacterial Escherichia coli chromosome. Three key features characterize our method: high-efficiency recombination, precise replacement of just the open reading frame of a chromosomal gene, and the presence of naturally occurring duplications within the bacterial genome. We targeted genes encoding functions critical for processes of transcription and translation. Proteins from three complexes were evaluated to determine if they were essential to the cell by deleting their individual genes. The transcription elongation Nus proteins and termination factor Rho, which are involved in rRNA antitermination, the ribosomal proteins of the small 30S ribosome subunit, and minor ribosome-associated proteins were analyzed. It was concluded that four of the five bacterial transcription antitermination proteins are essential, while all four of the minor ribosome-associated proteins examined (RMF, SRA, YfiA, and YhbH), unlike most ribosomal proteins, are dispensable. Interestingly, although most 30S ribosomal proteins were essential, the knockouts of six ribosomal protein genes, rpsF ($6), rpsI ($9), rpsM (S13), rpsO (S15), rpsQ (S17), and rpsT ($20), were viable.

Published
2007

30. Recombineering

Author

Sawitzke, James A., primary, Thomason, Lynn C., additional, Bubunenko, Mikhail, additional, Li, Xintian, additional, Costantino, Nina, additional, and Court, Donald L., additional

Published
2013
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31. Role of an RNase III binding site in transcription termination at [lambda] nutL by HK022 nun protein

Author

Washburn, Robert S., Court, Donald L., and Gottesman, Max E.

Subjects
Bacterial proteins -- Research, DNA binding proteins -- Research, Genetic transcription -- Research, Biological sciences
Abstract

The phage HK022 Nun protein excludes phage k by binding nascent [lambda] [p.sub.L] and [p.sub.R] transcripts at nutL and nutR, respectively, and inducing transcription termination just downstream of these sites. Termination is more efficient at nutL than at nutR. One difference between nutL and nutR is the presence of RNase III processing sites (rIII) located immediately promoter distal to [lambda] nutL. We found that deletion of rIII dramatically reduced Nun transcription arrest in vitro but had little effect on termination in vivo. However, consistent with the in vitro results, overexpression of a transcript carrying nutL and rIII efficiently titrated Nun, allowing [lambda] to grow on a strain that expressed Nun, whereas a transcript carrying only nutL or nutL-rIII with nucleotides 97 to 141 deleted was ineffective. Rnc70, an RNase III mutant that binds but does not cleave rIII, also prevented Nun-mediated [lambda] exclusion. We propose that rIII enhances the on-rate of Nun at nutL, stimulating Nun-mediated arrest in vitro. We have shown that a specific element in rIII, i.e., box C ([G.sub.89]GUGUGUG), strongly enhances arrest on [rIII.sup.+] templates. Nun-rIII interactions do not stimulate Nun termination in vivo, presumably because formation of the Nun-nutL complex is normally not rate-limiting in the cell. In contrast to Nun, N is not occluded by Rnc70 and is not efficiently titrated by a nutL-rIII transcript.

Published
2006

32. Structural Insight into the Mechanism of Double-Stranded RNA Processing by Ribonuclease III

Author

Gan, Jianhua, Tropea, Joseph E., Austin, Brian P., Court, Donald L., Waugh, David S., and Ji, Xinhua

Subjects
Esterases, Ribonuclease, RNA, Biological sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.cell.2005.11.034 Byline: Jianhua Gan (1), Joseph E. Tropea (1), Brian P. Austin (1), Donald L. Court (1), David S. Waugh (1), Xinhua Ji (1) Abstract: Members of the ribonuclease III (RNase III) family are double-stranded RNA (dsRNA) specific endoribonucleases characterized by a signature motif in their active centers and a two-base 3' overhang in their products. While Dicer, which produces small interfering RNAs, is currently the focus of intense interest, the structurally simpler bacterial RNase III serves as a paradigm for the entire family. Here, we present the crystal structure of an RNase III-product complex, the first catalytic complex observed for the family. A 7 residue linker within the protein facilitates induced fit in protein-RNA recognition. A pattern of protein-RNA interactions, defined by four RNA binding motifs in RNase III and three protein-interacting boxes in dsRNA, is responsible for substrate specificity, while conserved amino acid residues and divalent cations are responsible for scissile-bond cleavage. The structure reveals a wealth of information about the mechanism of RNA hydrolysis that can be extrapolated to other RNase III family members. Author Affiliation: (1) Center for Cancer Research, National Cancer Institute, National Institutes of Health, Frederick, MD 21702, USA Article History: Received 17 August 2005; Revised 5 October 2005; Accepted 10 November 2005 Article Note: (miscellaneous) Published: January 26, 2006

Published
2006

33. On the role of Cro in [lambda] prophage induction

Author

Svenningsen, Sine L., Costantino, Nina, Court, Donald L., and Adhya, Sankar

Subjects
Bacterial genetics -- Research, Bacteriophages -- Research, Bacteriophages -- Genetic aspects, Science and technology
Abstract

The lysogenic state of bacteriophage [lambda] is exceptionally stable yet the prophage is readily induced in response to DNA damage. This delicate epigenetic switch is believed to be regulated by two proteins; the lysogenic maintenance promoting protein CI and the early lytic protein Cro. First, we confirm, in the native configuration, the previous observation that the DNA loop mediated by oligomerization of CI bound to two distinct operator regions ([O.sub.L] and OR), increases repression of the early lytic promoters and is important for stable maintenance of lysogeny. Second, we show that the presence of the cro gene might be unimportant for the lysogenic to lytic switch during induction of the [lambda] prophage. We revisit the idea that Cro's primary role in induction is instead to mediate weak repression of the early lytic promoters. CI protein | genetic switch | transcription

Published
2005

34. Quantitative kinetic analysis of the bacteriophage [lambda] genetic network

Author

Kobiler, Oren, Rokney, Assaf, Friedman, NiR, Court, Donald L., Stavans, Joel, and Oppenheim, Amos B.

Subjects
Bacterial genetics -- Research, Bacteriophages -- Research, Bacteriophages -- Genetic aspects, Science and technology
Abstract

The lysis-lysogeny decision of bacteriophage A has been a paradigm for a developmental genetic network, which is composed of interlocked positive and negative feedback loops. This genetic network is capable of responding to environmental signals and to the number of infecting phages. An interplay between CI and Cro functions suggested a bistable switch model for the lysis-lysogeny decision. Here, we present a real-time picture of the execution of lytic and lysogenic pathways with unprecedented temporal resolution. We monitor, in vivo, both the level and function of the CII and Q gene regulators. These activators are cotranscribed yet control opposite developmental pathways. Conditions that favor the lysogenic response show severe delay and down-regulation of Q activity, in both CII-dependent and CII-independent ways. Whereas CII activity correlates with its protein level, Q shows a pronounced threshold before its function is observed. Our quantitative analyses suggest that by regulating CII and CIII, Cro plays a key role in the ability of the [lambda] genetic network to sense the difference between one and more than one phage particles infecting a cell. Thus, our results provide an improved framework to explain the longstanding puzzle of the decision process. gene regulation | lysogeny | lysis | green fluorescent protein

Published
2005

35. Switches in bacteriophage lambda development

Author

Oppenheim, Amos B., Kobiler, Oren, Stavans, Joel, Court, Donald L., and Adhya, Sankar

Subjects
Bacteriophage lambda -- Research, Genetic regulation -- Research, Animal development -- Genetic aspects, Biological sciences
Abstract

A systems biology approach is proposed to the study of genetic regulatory circuits of bacteriophage lambda. The individual components of the genetic regulatory circuits and switches and also the kinetics of their interactions are determined to obtain a realistic picture of this important paradigm for more complex developmental processes.

Published
2005

36. Identification of the Escherichia coli K-12 ybhE gene as pgl, encoding 6-phosphogluconolactonase

Author

Thomason, Lynn C., Court, Donald L., Datta, Atin R., Khanna, Rita, and Rosner, Judah L.

Subjects
Bacteriology -- Research, Escherichia coli -- Research, Escherichia coli -- Genetic aspects, Biological sciences
Abstract

We report identification of the Escherichia coli ybhE gene as the pgl gene that encodes 6-phosphogluconolactonase. A tentative identification was first made based on the known approximate location of the pgl gene and the similarity of the presumptive ybhE-encoded protein sequence to a known Pgl enzyme. To test this notion, the ybhE gene was deleted and replaced with a drug marker. Like previously characterized pgl mutants, the ybhE deletion mutant had a [Blu.sup.-] phenotype (dark-blue staining with iodine due to accumulation of starch after growth on minimal maltose) and demonstrated impaired growth on minimal glucose medium when combined with a pgi mutation. Biochemical assay of crude extracts for 6-phosphogluconolactonase enzymatic activity showed that ybhE encodes this activity. The ybhE gene was transferred from the E. coli chromosome to an expression vector. This ybhE clone complemented both the precise deletion of the ybhE gene and a larger deletion, pgl[Delta]8, for the [Blu.sup.-] phenotype and for phosphogluconolactonase activity, confirming that ybhE is the pgl gene. A newly observed phenotype of pgl strains is a lowered frequency of appearance of [Bgl.sup.+] mutants that can utilize the [beta]-glucoside salicin. This is likely due to poor growth of [Bgl.sup.+] pgl strains on salicin due to the accumulation of 6-phosphogluconolactone.

Published
2004

41. Enhanced levels of [lambda] Red-mediated recombinants in mismatch repair mutants

Author

Costantino, Nina and Court, Donald L.

Subjects
Escherichia coli -- Research, Nucleotides -- Research, Science and technology
Abstract

Homologous recombination can be used to generate recombinants on episomes or directly on the Escherichia coil chromosome with PCR products or synthetic single-stranded DNA (ssDNA) oligonucleotides (oligos). Such recombination is possible because bacteriophage [lambda]-encoded functions, called Red, efficiently recombine linear DNA with homologies as short as 20-70 bases. This technology, termed recombineering, provides ways to modify genes and segments of the chromosome as well as to study homologous recombination mechanisms. The Red Beta function, which binds and anneals ssDNA to complementary ssDNA, is able to recombine 70-base oligos with the chromosome. In E. coil, methyl-directed mismatch repair (MMR) can affect these ssDNA recombination events by eliminating the recombinant allele and restoring the original sequence. In so doing, MMR can reduce the apparent recombination frequency by >100-fold. In the absence of MMR, Red-mediated oligo recombination can incorporate a single base change into the chromosome in an unprecedented 25% of cells surviving electroporation. Our results show that Beta is the only bacteriophage function required for this level of recombination and suggest that Beta directs the ssDNA to the replication fork as it passes the target sequence.

Published
2003

42. Phage HK022 Nun protein represses translation of phage [lambda] N (transcription termination/ translation repression)

Author

Kim, Hyeong C., Zhou, Jian-guang, Wilson, Helen R., Mogilnitskiy, Grigoriy, Court, Donald L., and Gottesman, Max E.

Subjects
Genetic research, Science and technology
Abstract

The N-terminal arginine-rich motif of phage HK022 Nun protein binds to NUT sequences in phage [lambda] nascent transcripts and induces transcription termination. Interactions between the Nun C terminus and RNA polymerase as well as the DNA template are required for termination. We have isolated Nun C-terminal point and deletion mutants that are unable to block transcription. The mutants bind NUT RNA and inhibit translation of the [lambda] N gene. Thus HK022 excludes [lambda] both by terminating transcription on the phage chromosome and by preventing translation of the essential [lambda] N gene. Like N autoregulation, translation repression by Nun requires host RNaselll deficiency (rnc) or a mutation in the RNaselll processing site (rlll) located between NUTL and the beginning of the N coding sequence. Our data support the idea that Nun bound at NUTL causes steric interference with ribosome attachment to the nearby N coding sequence. Two models, Nun acting alone or in complex with host proteins, are discussed.

Published
2003

44. Bex, the Bacillus subtilis homolog of the essential Escherichia coli GTPase era, is required for normal cell division and spore formation

Author

Minkovsky, Natalie, Zarimani, Arash, Chary, Vasant K., Johnstone, Brian H., Powell, Bradford S., Torrance, Pamela D., Court, Donald L., Simons, Robert W., and Piggot, Patrick J.

Subjects
Bacteriology -- Research, Bacillus subtilis -- Physiological aspects, Bacillus subtilis -- Genetic aspects, Escherichia coli -- Physiological aspects, Escherichia coli -- Genetic aspects, Spores (Bacteria) -- Physiological aspects, Cell division -- Analysis, Mutagens -- Growth, Mutagens -- Genetic aspects, Company growth, Biological sciences
Abstract

Research has been conducted on Bex protein which demonstrates similarity to Escherichia coli era mutant. Results indicate that bex mutant cells are elongated and filled with diffuse nucleoid material and that they grow slowly and have impaired spore formation.

Published
2002

46. Genetic engineering using homologous recombination (1)

Author

Court, Donald L., Sawitzke, James A., and Thomason, Lynn C.

Subjects
DNA replication -- Research, Genetic engineering -- Research, Genetics -- Research, Cloning -- Research, Biological sciences, Research
Abstract

Key Words DNA replication forks, strand annealing, in vivo cloning, oligo recombination, recombineering Abstract In the past few years, in vivo technologies have emerged that, due to their efficiency and [...]

Published
2002

49. Overproduction of a Dominant Mutant of the Conserved Era GTPase Inhibits Cell Division in Escherichia coli

Author

Zhou, Xiaomei, primary, Peters, Howard K., additional, Li, Xintian, additional, Costantino, Nina, additional, Kumari, Vandana, additional, Shi, Genbin, additional, Tu, Chao, additional, Cameron, Todd A., additional, Haeusser, Daniel P., additional, Vega, Daniel E., additional, Ji, Xinhua, additional, Margolin, William, additional, and Court, Donald L., additional

Published
2020
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