Your search keyword '"Laub MT"' showing total 6 results

1. Toxic antiphage defense proteins inhibited by intragenic antitoxin proteins.

Author

Zhong A, Jiang X, Hickman AB, Klier K, Teodoro GIC, Dyda F, Laub MT, and Storz G

Subjects

Amino Acids, Dimerization, Endonucleases, Escherichia coli, Antitoxins, Bacteriophages, Blood Group Antigens

Abstract

Recombination-promoting nuclease (Rpn) proteins are broadly distributed across bacterial phyla, yet their functions remain unclear. Here, we report that these proteins are toxin-antitoxin systems, comprised of genes-within-genes, that combat phage infection. We show the small, highly variable Rpn C -terminal domains (Rpn S ), which are translated separately from the full-length proteins (Rpn L ), directly block the activities of the toxic Rpn L . The crystal structure of RpnA S revealed a dimerization interface encompassing α helix that can have four amino acid repeats whose number varies widely among strains of the same species. Consistent with strong selection for the variation, we document that plasmid-encoded RpnP2 L protects Escherichia coli against certain phages. We propose that many more intragenic-encoded proteins that serve regulatory roles remain to be discovered in all organisms.

Published

2023

2. Marginal specificity in protein interactions constrains evolution of a paralogous family.

Author

Ghose DA, Przydzial KE, Mahoney EM, Keating AE, and Laub MT

Subjects

Escherichia coli chemistry, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Signal Transduction, Mutation, Phylogeny, Evolution, Molecular

Abstract

The evolution of novel functions in biology relies heavily on gene duplication and divergence, creating large paralogous protein families. Selective pressure to avoid detrimental cross-talk often results in paralogs that exhibit exquisite specificity for their interaction partners. But how robust or sensitive is this specificity to mutation? Here, using deep mutational scanning, we demonstrate that a paralogous family of bacterial signaling proteins exhibits marginal specificity, such that many individual substitutions give rise to substantial cross-talk between normally insulated pathways. Our results indicate that sequence space is locally crowded despite overall sparseness, and we provide evidence that this crowding has constrained the evolution of bacterial signaling proteins. These findings underscore how evolution selects for "good enough" rather than optimized phenotypes, leading to restrictions on the subsequent evolution of paralogs.

Published

2023

3. Spatial gradient of protein phosphorylation underlies replicative asymmetry in a bacterium.

Author

Chen YE, Tropini C, Jonas K, Tsokos CG, Huang KC, and Laub MT

Subjects

Caulobacter crescentus physiology, Flow Cytometry, Fluorescence Recovery After Photobleaching, Markov Chains, Monte Carlo Method, Phosphorylation, Bacterial Proteins metabolism, Caulobacter crescentus metabolism, DNA Replication physiology, DNA-Binding Proteins metabolism, Models, Biological, Transcription Factors metabolism

Abstract

Spatial asymmetry is crucial to development. One mechanism for generating asymmetry involves the localized synthesis of a key regulatory protein that diffuses away from its source, forming a spatial gradient. Although gradients are prevalent in eukaryotes, at both the tissue and intracellular levels, it is unclear whether gradients of freely diffusible proteins can form within bacterial cells given their small size and the speed of diffusion. Here, we show that the bacterium Caulobacter crescentus generates a gradient of the active, phosphorylated form of the master regulator CtrA, which directly regulates DNA replication. Using a combination of mathematical modeling, single-cell microscopy, and genetic manipulation, we demonstrate that this gradient is produced by the polarly localized phosphorylation and dephosphorylation of CtrA. Our data indicate that cells robustly establish the asymmetric fates of daughter cells before cell division causes physical compartmentalization. More generally, our results demonstrate that uniform protein abundance may belie gradients and other sophisticated spatial patterns of protein activity in bacterial cells.

Published

2011

4. Direct and adaptor-mediated substrate recognition by an essential AAA+ protease.

Author

Chien P, Perchuk BS, Laub MT, Sauer RT, and Baker TA

Subjects

Amino Acid Sequence, Bacterial Proteins metabolism, Caulobacter crescentus enzymology, DNA-Binding Proteins metabolism, Molecular Sequence Data, Substrate Specificity, Transcription Factors metabolism, Endopeptidase Clp metabolism

Abstract

Regulated proteolysis is required to execute many cellular programs. In Caulobacter crescentus, timely degradation of the master regulator CtrA by ClpXP protease is essential for cell-cycle progression and requires the colocalization of CtrA and RcdA. Here, we establish a biochemical framework to understand regulated proteolysis in C. crescentus and show that RcdA is not an adaptor for CtrA degradation. CtrA is rapidly degraded without RcdA and is recognized with an affinity comparable with the best ClpXP substrates. In contrast, SspBalpha, the alpha-proteobacterial homolog of SspB, functions as an adaptor to enhance degradation of specific substrates. Cargo-free SspBalpha is also itself a substrate of ClpXP-mediated proteolysis. Thus, our analysis (i) reveals the consequences of both direct and adaptor-stimulated recognition in mediating substrate specificity in vitro, (ii) reveals a potential regulatory role of controlled adaptor stability, and (iii) suggests that cell-cycle regulation of CtrA stability depends on repression of its intrinsic degradation rather than adaptor-mediated enhancement.

Published

2007

5. Genes directly controlled by CtrA, a master regulator of the Caulobacter cell cycle.

Author

Laub MT, Chen SL, Shapiro L, and McAdams HH

Subjects

Amino Acid Motifs, Binding Sites, Caulobacter physiology, Cell Cycle, Morphogenesis, Regulon, Bacterial Proteins physiology, Caulobacter genetics, DNA-Binding Proteins, Genes, Bacterial, Transcription Factors

Abstract

Studies of the genetic network that controls the Caulobacter cell cycle have identified a response regulator, CtrA, that controls, directly or indirectly, one-quarter of the 553 cell cycle-regulated genes. We have performed in vivo genomic binding site analysis of the CtrA protein to identify which of these genes have regulatory regions bound directly by CtrA. By combining these data with previous global analysis of cell cycle transcription patterns and gene expression profiles of mutant ctrA strains, we have determined that CtrA directly regulates at least 95 genes. The total group of CtrA-regulated genes includes those involved in polar morphogenesis, DNA replication initiation, DNA methylation, cell division, and cell wall metabolism. Also among the genes in this notably large regulon are 14 that encode regulatory proteins, including 10 two-component signal transduction regulatory proteins. Identification of additional regulatory genes activated by CtrA will serve to directly connect new regulatory modules to the network controlling cell cycle progression.

Published

2002

6. Complete genome sequence of Caulobacter crescentus.

Author

Nierman WC, Feldblyum TV, Laub MT, Paulsen IT, Nelson KE, Eisen JA, Heidelberg JF, Alley MR, Ohta N, Maddock JR, Potocka I, Nelson WC, Newton A, Stephens C, Phadke ND, Ely B, DeBoy RT, Dodson RJ, Durkin AS, Gwinn ML, Haft DH, Kolonay JF, Smit J, Craven MB, Khouri H, Shetty J, Berry K, Utterback T, Tran K, Wolf A, Vamathevan J, Ermolaeva M, White O, Salzberg SL, Venter JC, Shapiro L, and Fraser CM

Subjects

Adaptation, Biological genetics, Cell Cycle genetics, DNA Methylation, Dinucleotide Repeats, Molecular Sequence Data, Peptide Hydrolases genetics, Phylogeny, Signal Transduction, Transcription, Genetic, Caulobacter crescentus genetics, Genome, Bacterial

Abstract

The complete genome sequence of Caulobacter crescentus was determined to be 4,016,942 base pairs in a single circular chromosome encoding 3,767 genes. This organism, which grows in a dilute aquatic environment, coordinates the cell division cycle and multiple cell differentiation events. With the annotated genome sequence, a full description of the genetic network that controls bacterial differentiation, cell growth, and cell cycle progression is within reach. Two-component signal transduction proteins are known to play a significant role in cell cycle progression. Genome analysis revealed that the C. crescentus genome encodes a significantly higher number of these signaling proteins (105) than any bacterial genome sequenced thus far. Another regulatory mechanism involved in cell cycle progression is DNA methylation. The occurrence of the recognition sequence for an essential DNA methylating enzyme that is required for cell cycle regulation is severely limited and shows a bias to intergenic regions. The genome contains multiple clusters of genes encoding proteins essential for survival in a nutrient poor habitat. Included are those involved in chemotaxis, outer membrane channel function, degradation of aromatic ring compounds, and the breakdown of plant-derived carbon sources, in addition to many extracytoplasmic function sigma factors, providing the organism with the ability to respond to a wide range of environmental fluctuations. C. crescentus is, to our knowledge, the first free-living alpha-class proteobacterium to be sequenced and will serve as a foundation for exploring the biology of this group of bacteria, which includes the obligate endosymbiont and human pathogen Rickettsia prowazekii, the plant pathogen Agrobacterium tumefaciens, and the bovine and human pathogen Brucella abortus.

Published

2001