Insights from the architecture of the bacterial transcription apparatus

Iyer, Lakshminarayan M.; Aravind, L.

doi:10.1016/j.jsb.2011.12.013

Cited by 48 publications

(83 citation statements)

References 165 publications

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“…Evidence of retrotransposable elements has been reported in another early branch of the Apicomplexa, the gregarines (28), and there is evidence that apicomplexan genomes which lack mobile elements used to contain them (29,30), or contain inactive elements as is the case in the apicomplexan coccidian parasite Eimeria tenella (31). More recently, non-integrase-associated bacterial AP2 proteins with architectures similar to AP2 proteins found in plants and alveolates have been reported (32). These AP2 proteins are also predicted to function as novel, specific transcription factors.…”

Section: Introductionmentioning

confidence: 99%

TheCryptosporidium parvumApiAP2 gene family: insights into the evolution of apicomplexan AP2 regulatory systems

et al. 2014

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We provide the first comprehensive analysis of any transcription factor family in Cryptosporidium, a basal-branching apicomplexan that is the second leading cause of infant diarrhea globally. AP2 domain-containing proteins have evolved to be the major regulatory family in the phylum to the exclusion of canonical regulators. We show that apicomplexan and perkinsid AP2 domains cluster distinctly from other chromalveolate AP2s. Protein-binding specificity assays of C. parvum AP2 domains combined with motif conservation upstream of co-regulated gene clusters allowed the construction of putative AP2 regulons across the in vitro life cycle. Orthologous Apicomplexan AP2 (ApiAP2) expression has been rearranged relative to the malaria parasite P. falciparum, suggesting ApiAP2 network rewiring during evolution. C. hominis orthologs of putative C. parvum ApiAP2 proteins and target genes show greater than average variation. C. parvum AP2 domains display reduced binding diversity relative to P. falciparum, with multiple domains binding the 5′-TGCAT-3′, 5′-CACACA-3′ and G-box motifs (5′-G[T/C]GGGG-3′). Many overrepresented motifs in C. parvum upstream regions are not AP2 binding motifs. We propose that C. parvum is less reliant on ApiAP2 regulators in part because it utilizes E2F/DP1 transcription factors. C. parvum may provide clues to the ancestral state of apicomplexan transcriptional regulation, pre-AP2 domination.

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Section: Introductionmentioning

confidence: 99%

TheCryptosporidium parvumApiAP2 gene family: insights into the evolution of apicomplexan AP2 regulatory systems

et al. 2014

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“…The presence of the G-hydrophobic residue in the smallresidue triad could be observed in the HTH DNAbinding domain , located in the α4/α5 loop (G-349, F-350, S-351); comparable, to the canonical hydrophobic residues in α3 (L-334) and α5 (F-356) (Figure 1-c). DNA binding motifs, from the HTH domain, were organized to facilitate DNAprotein interface binding to α3 residues (recognition helix) and the presence of hydrophobic residues in α1 and α3, stabilizing the domain (Iyer & Aravind 2012). It was also confirmed that these domains presented a tetra-helicoidal conformation, characterized by an additional C-terminal helix .…”

Section: Discussionmentioning

confidence: 80%

Computational analysis of 1,3-propanediol operon transcriptional regulators: Insights into Clostridium sp. glycerol metabolism regulation

2014

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We designed a strategy for the sequencing and bioinformatical characterization of the 1,3-propanediol operon regulator genes from the Colombian Clostridium sp. strain IBUN13A, which is taxonomically related to Clostridium butyricum. Three genes are proposed to be involved in the operon's transcriptional activity, the dhaS and dhaA genes through a two-component system and the third gene named dhaY, which encodes a putative transcriptional regulator similar to the domains of the dhaS/A system. Phylogenetic analyses indicated that the predicted proteins had a modular structure consisting of domains homologous to different signal transduction systems, but had significant differences concerning their conserved residues, pointing to the possibility that they constitute ancestral domains. In accordance with the prediction of functions, we propose a mechanism of regulation of the proteins studied of the 1,3-propanediol operon of the native strain, as a response to the presence of glycerol in the medium, which provides valuable information on the overall regulation of the glycerol metabolism in Clostridium sp.

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“…For DDRPs, the β subunit type DPBB was invaded by a SBHM that became the interaction surface for initiation and elongation factors (Fig. 3) required for use of a DNA template 4 , 6 . In this way, DDRPs evolved from RDRPs, prior to LUCA.…”

Section: The Old Testamentmentioning

confidence: 99%

“…Eubacteria, by contrast, because their gene regulatory networks are focused on the DNA interactome (Fig. 8B) 6 and mostly lack additional dimensions, have much simpler signal transduction mechanisms. The surprising similarities comparing the eukaryotic RNAP II transcription cycle and the eukaryotic cell cycle indicate that these processes are co-evolved 32 .…”

Section: The New Testament Of Eukaryotic Gene Regulatory Networkmentioning

confidence: 99%

The Old and New Testaments of gene regulation

Burton¹

2014

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I relate a story of genesis told from the point of view of multi-subunit RNA polymerases (RNAPs) including an Old Testament (core RNAP motifs in all cellular life) and a New Testament (the RNAP II heptad repeat carboxy terminal domain (CTD) and CTD interactome in eukarya). The Old Testament: at their active site, one class of eukaryotic interfering RNAP and ubiquitous multi-subunit RNAPs each have two-double psi β barrel (DPBB) motifs (a distinct pattern for compact 6-β sheet barrels). Between β sheets 2 and 3 of the β subunit type DPBB of all multi-subunit RNAPs is a sandwich barrel hybrid motif (SBHM) that interacts with conserved initiation and elongation factors required to utilize a DNA template. Analysis of RNAP core protein motifs, therefore, indicates that RNAP evolution can be traced from the RNA-protein world to LUCA (the last universal common ancestor) branching to LECA (the last eukaryotic common ancestor) and to the present day, spanning about 4 billion years. The New Testament: in the eukaryotic lineage, I posit that splitting RNAP functions into RNAPs I, II and III and innovations developed around the CTD heptad repeat of RNAP II and the extensive CTD interactome helps to describe how greater structural, cell cycle, epigenetic and signaling complexity co-evolved in eukaryotes relative to eubacteria and archaea.

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Insights from the architecture of the bacterial transcription apparatus

Cited by 48 publications

References 165 publications

TheCryptosporidium parvumApiAP2 gene family: insights into the evolution of apicomplexan AP2 regulatory systems

TheCryptosporidium parvumApiAP2 gene family: insights into the evolution of apicomplexan AP2 regulatory systems

Computational analysis of 1,3-propanediol operon transcriptional regulators: Insights into Clostridium sp. glycerol metabolism regulation

The Old and New Testaments of gene regulation

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