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| Author | : Morigen Morigen |
| Publisher | : Frontiers Media SA |
| Total Pages | : 193 |
| Release | : 2022-02-10 |
| Genre | : Science |
| ISBN | : 2889743241 |
| Author | : Morigen Morigen |
| Publisher | : Frontiers Media SA |
| Total Pages | : 181 |
| Release | : 2022-10-10 |
| Genre | : Science |
| ISBN | : 2889767671 |
Analogous to the eukaryotic G1, S and M phase of the cell cycle, the bacterial cell cycle can be classified into independent stages. Slowly growing bacterial cells undergo three different stages, B-, C- and D-phase, respectively, while the cell cycle of fast-growing bacteria involves at least two independent cycles: the chromosome replication and the cell division. The oscillation in gene expression regulated by transcription factors, and proteolysis mediated by ClpXP, are closely correlated with progression of the cell cycle. Indeed, it has been shown that DnaA couples DNA replication initiation with the expression of the two oscillating regulators GcrA and CtrA, and the DnaA/GcrA/CtrA regulatory cascade drives the forward progression of the Caulobacter cell cycle. Furthermore, it has been found that: the DnaA oscillation in Eschericha coli and Caulobacter crescentus plays an important role in the cell cycle coordination; RpoS in Coxiella regulates the gene expression involved in the developmental cycle; the SigB and SinR transcription factors control whether cells remain in or leave a biofilm responding to metabolic conditions in Bacillus subtilis; similarly, BolA in most Gram-negative bacteria turns off motility and turns on biofilm development as a transcription factor; CtrA regulates cell division and outer membrane composition of the pathogen Brucella abortus; an essential transcription factor SciP enhances robustness of Caulobacter cell cycle regulation. Interestingly, transcription factors mediated metabolism fluctuations are also related to progression of the cell cycle. It has been shown that: CggR and Cra factors are involved in the flux-signaling metabolite fructose-1,6-bisphosphate; IclR mediates para-hydroxybenzoate catabolism in Streptomyces coelicolor; CceR and AkgR regulate central carbon and energy metabolism in alphaproteobacteria; and these metabolism changes affect cell growth. In line with the argument, AspC-mediated aspartate metabolism coordinates the E. coli cell cycle. However, the molecular mechanisms of maintaining the proper cell cycle progression through coordination of transcription factors mediated gene transcription oscillation, cellular metabolism with the cell cycle are not yet well-established. This Research Topic is intended to cover the spectrum of cell cycle regulatory mechanisms, in particular the coordination of transcription factor mediated gene transcription oscillations, and the cellular metabolisms associated with the cell cycle. We welcome all types of articles including Original Research, Review, and Mini Review. The subject areas of interest include but are not limited to: 1. Cell cycle coordination through gene expression and expression oscillation mediated by transcription factors. 2. Regulation of the cell cycle by proteolysis oscillation. 3. Coordination of the cell cycle with metabolism fluctuation. 4. DNA methylation fluctuation and the cell cycle. 5. Novel transcription factors and gene expression patterns associated with the cell cycle.
| Author | : Bruce Alberts |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2002 |
| Genre | : Cytology |
| ISBN | : 9780815332183 |
| Author | : James A. Hoch |
| Publisher | : Amer Society for Microbiology |
| Total Pages | : 488 |
| Release | : 1995 |
| Genre | : Medical |
| ISBN | : 9781555810894 |
The human enteroviruses, particularly the polio viruses, have had a significant role in the history of medicine and microbiology; and continue to cause clinical problems, as well as provide targets for molecular investigation. This book offers a link between the basic science and clinical medicine.
| Author | : Diane Laure Haakonsen |
| Publisher | : |
| Total Pages | : |
| Release | : 2016 |
| Genre | : |
| ISBN | : |
Bacteria use a variety of mechanisms to control transcription in response to environmental cues or growth conditions. Activation or repression of transcription is often carried out by proteins, called transcription factors, that interact with DNA or RNA polymerase (RNAP) or both, and can change the preference of RNAP for target promoters. Additionally, DNA is tightly compacted and organized inside cells. In bacteria, nucleoid-associated proteins (NAPs) play critical roles in shaping and compacting the chromosome by bending, wrapping and bridging the DNA. The binding of these proteins can also profoundly affect gene expression regulation. In this work, I have characterized two DNA-binding proteins from the bacterium Caulobacter crescentus; one transcription factor, GcrA, and one NAP, CnpA. First, I found that GcrA, an essential cell-cycle regulator in Caulobacter, activates transcription by a new mechanism. Unlike most transcription factors that bind to promoters independently of RNAP, GcrA constitutively associates with RNAP via an interaction with Domain 2 of Y70, the primary sigma factor. I showed that GcrA recognizes a subset of methylation sites and can promote binding of RNAP and increase the rate of open complex formation at promoters harboring such sites. Understanding the mechanism by which GcrA activates transcription enabled the identification of its direct regulon and provided important insights into its essential cell-cycle function. For my second project, I identified a new nucleoid-associated protein (NAP), CnpA, in Caulobacter, via mass-spectrometry analysis of its nucleoid content. I showed that CnpA associates with AT-rich DNA but unlike other NAPs, likely does not repress transcription at these loci. We propose a model in which CnpA impacts global supercoiling levels. In sum, these two projects have contributed to expanding our views of how gene expression and chromosome organization are regulated in bacteria.
| Author | : Ron Milo |
| Publisher | : Garland Science |
| Total Pages | : 400 |
| Release | : 2015-12-07 |
| Genre | : Science |
| ISBN | : 1317230698 |
A Top 25 CHOICE 2016 Title, and recipient of the CHOICE Outstanding Academic Title (OAT) Award. How much energy is released in ATP hydrolysis? How many mRNAs are in a cell? How genetically similar are two random people? What is faster, transcription or translation?Cell Biology by the Numbers explores these questions and dozens of others provid
| Author | : Joseph Locker |
| Publisher | : Garland Science |
| Total Pages | : 502 |
| Release | : 2003-12-16 |
| Genre | : Science |
| ISBN | : 1135323623 |
Transcription factors are important in regulating gene expression, and their analysis is of paramount interest to molecular biologists studying this area. This book looks at the basic machinery of the cell involved in transcription in eukaryotes and factors that control transcription in eukaryotic cells. It examines the regulatory systems that modulate gene expression in all cells,a s well as the more specialized systems that regulate localized gene expression throughout the mammalian organism. Transcription Factors updates classical knowledge with recent advances to provide a full and comprehensive coverage of the field for postgraduates and researchers in molecular biology involved in the study of gene regulation.
| Author | : Leise Riber |
| Publisher | : Frontiers Media SA |
| Total Pages | : 123 |
| Release | : 2021-04-30 |
| Genre | : Science |
| ISBN | : 2889667294 |
| Author | : Peggy J. Farnham |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 149 |
| Release | : 2012-12-06 |
| Genre | : Science |
| ISBN | : 3642799108 |
It is of critical importance to maintain an appropriate balance between proliferation and quiescence or differentiation through out the lifespan of all animals. An important control point in this balance occurs in the G, phase of the cell cycle. On the basis of environmental cues a cell in G, must decide whether to continue through the proliferative cycle and enter S phase (where DNA replication occurs) or to exit from the proliferative cycle into a nonreplicating state. Alterations in the mechanisms that nor mally control this decision can lead to cancer, cell death, or loss of differentiated cellular phenotypes. The identification of the E2F gene family of transcription factors has allowed a more complete understanding of how the cell maintains an appropri ate proliferative state. This volume provides an up-to-date ac count of present reports concerning E2F as well as a framework for future investigations. E2F activity requires heterodimerization of two partners. Either partner can be one of several different transcription factors; E2Fl, E2F2, E2F3, E2F4, or E2F5 can heterodimerize with either DPl or DP2. Cellular promoters whose E2F sites mediate a link between transcription and proliferation drive genes whose products are required for DNA synthesis and genes that encode regulators of cell growth. A detailed analY$is of the role that E2F family members play in transcription from these promoters is presented in the chapter by J. E. SLANSKY and P. J. FARNHAM.
| Author | : Bo Zhou |
| Publisher | : |
| Total Pages | : |
| Release | : 2014 |
| Genre | : |
| ISBN | : |
One of the central aspects of the biological program that guide the development of an organism is embedded in the regulated and sequential expression of genes as development progresses. A large part of this regulation is achieved through the temporal activation and repression of transcriptional initiation by the selective binding of regulatory proteins, such as transcription factors, to promoters during specific stages of development. Thus, being able to globally and precisely identify these processes are important steps in gaining a systems-level insight and understanding of the developmental program. The cell cycle of Caulobacter crescentus, an alpha-proteobacteria that undergoes cell differentiation and asymmetric cell division, has been used extensively as a model organism to study bacterial development. A cyclical and integrated genetic circuit involving five master regulatory proteins, including DnaA, GcrA, CtrA, and SciP, and the DNA methyl-transferase CcrM, whose presence and activities oscillate in space and time, orchestrate the many facets of the Caulobacter cell cycle including DNA replication, DNA methylation, organelle biogenesis, and cytokinesis. This genetic circuit is at the core of the Caulobacter developmental program. While microarrays have shown 19% of mRNAs undergo changes in RNA level during the cell cycle and development, it is unclear exactly which regulatory factors of the core circuit drive the changes in transcription at each specific locus, and how these regulatory factors act combinatorially to effect transcriptional outcomes has not been systematically dissected. In order to achieve these goals and to further define the transcriptional regulatory landscape that guides the cell cycle, a thorough and global analysis of Caulobacter transcription as a function of the cell cycle and developmental progression is needed. In this thesis, I devised a novel protocol combining 5' rapid amplification of cDNA ends (5' RACE) and high-throughput sequencing to globally map the precise locations of transcriptional start sites (TSSs) in the Caulobacter genome, measured their transcription levels at multiple times in the cell cycle, and identified their transcription factor binding sites. Using the TSSs identified and a RNA sequencing dataset, I made a functional annotation of operons and other transcriptional units in the genome. A large number of antisense transcripts were identified, and many of them are within essential cell cycle-regulated genes, including two master regulators, a previous unknown feature of the core cell cycle control circuit. Many critical genes and operons have multiple promoters, and these promoters are often independently regulated. Furthermore, approximately 25% of the cell cycle-regulated promoters are co-regulated by two or more master regulatory proteins of the core genetic circuit. These results revealed surprising transcriptional complexity and uncovered multiple new layers of transcriptional control mediating the bacterial cell cycle and development and represent the first in-depth analysis of TSS control in as a function bacterial cell cycle and developmental progression.
