Holding it together: chromatin in the Archaea

Recently, several advances have been made in the understanding of the form and function of archaeal chromatin. Remarkable parallels can be drawn between the structure and modification of chromatin components in the archaeal and the eukaryotic domains of life. Indeed, it now appears that key components of the hugely complex eukaryotic chromatin regulatory machinery were established before the divergence of the archaeal and eukaryotic lineages.     

Architectural roles of Cren7 in folding crenarchaeal chromatin filament

Archaea have evolved various strategies in chromosomal organization. While histone homologues exist in most archaeal phyla, Cren7 is a chromatin protein conserved in the Crenarchaeota. Here, we show that Cren7 preferentially binds DNA with AT‐rich sequences over that with GC‐rich sequences with a binding size of 6~7 bp. Structural studies of Cren7 in complex with either an 18‐bp or a 20‐bp double‐stranded DNA fragment reveal that Cren7 binds to the minor groove of DNA as monomers in a head‐to‐tail manner. The neighboring Cren7 monomers are located on the opposite sides of the DNA duplex, with each introducing a single‐step sharp kink by intercalation of the hydrophobic side chain of Leu28, bending the DNA into an S‐shape conformation. A structural model for the chromatin fiber folded by Cren7 was established and verified by the analysis of cross‐linked Cren7‐DNA complexes by atomic force microscopy. Our results suggest that Cren7 differs significantly from Sul7, another chromatin protein conserved among Sulfolobus species, in both DNA binding and deformation. These data shed significant light on the strategy of chromosomal DNA organization in crenarchaea.     

Histones and chromatin structure in hyperthermophilic Archaea

Abstract: HMf is a histone from the hyperthermophile Methanothermus fervidus . It is the archetype and most studied member of a family of archaeal histones that have primary sequences and three-dimensional structures in common with the eukaryal nucleosome core histones and that bind and compact DNA molecules into nucleosome-like structures (NLS). HMf preparations are mixtures of two similar, small (∼7.5 kDa) polypeptides designated HMfA and HMfB that in vivo form both homodimers and heterodimers. HMfA synthesis predominates during exponential growth but the relative amount of HMfB increases as M. fervidus cells enter the stationary growth phase. Analyses of homogeneous preparations of recombinant (r) (HMfA)₂ and (rHMfB)₂ have demonstrated that these proteins have different DNA-binding and compaction properties in vitro, consistent with different roles in vivo for the (HMfA)₂, (HMfB)₂ and HMfA · HMfB dimers, and for the NLS that they form, in regulating gene expression and in genome compaction and stability.     

Identification of a mismatch-specific endonuclease in hyperthermophilic Archaea

The common mismatch repair system processed by MutS and MutL and their homologs was identified in Bacteria and Eukarya. However, no evidence of a functional MutS/L homolog has been reported for archaeal organisms, and it is not known whether the mismatch repair system is conserved in Archaea. Here, we describe an endonuclease that cleaves double-stranded DNA containing a mismatched base pair, from the hyperthermophilic archaeon Pyrococcus furiosus. The corresponding gene revealed that the activity originates from PF0012, and we named this enzyme Endonuclease MS (EndoMS) as the mismatch-specific Endonuclease. The sequence similarity suggested that EndoMS is the ortholog of NucS isolated from Pyrococcus abyssi, published previously. Biochemical characterizations of the EndoMS homolog from Thermococcus kodakarensis clearly showed that EndoMS specifically cleaves both strands of double-stranded DNA into 5′-protruding forms, with the mismatched base pair in the central position. EndoMS cleaves G/T, G/G, T/T, T/C and A/G mismatches, with a more preference for G/T, G/G and T/T, but has very little or no effect on C/C, A/C and A/A mismatches. The discovery of this endonuclease suggests the existence of a novel mismatch repair process, initiated by the double-strand break generated by the EndoMS endonuclease, in Archaea and some Bacteria.     

Archaea in metazoan diets: implications for food webs and biogeochemical cycling

Although the importance of trophic linkages, including ‘top-down forcing'', on energy flow and ecosystem productivity is recognized, the influence of metazoan grazing on Archaea and the biogeochemical processes that they mediate is unknown. Here, we test if: (1) Archaea provide a food source sufficient to allow metazoan fauna to complete their life cycle; (2) neutral lipid biomarkers (including crocetane) can be used to identify Archaea consumers; and (3) archaeal aggregates are a dietary source for methane seep metazoans. In the laboratory, we demonstrated that a dorvilleid polychaete, Ophryotrocha labronica, can complete its life cycle on two strains of Euryarchaeota with the same growth rate as when fed bacterial and eukaryotic food. Archaea were therefore confirmed as a digestible and nutritious food source sufficient to sustain metazoan populations. Both strains of Euryarchaeota used as food sources had unique lipids that were not incorporated into O. labronica tissues. At methane seeps, sulfate-reducing bacteria that form aggregations and live syntrophically with anaerobic-methane oxidizing Archaea contain isotopically and structurally unique fatty acids (FAs). These biomarkers were incorporated into tissues of an endolithofaunal dorvilleid polychaete species from Costa Rica (mean bulk δ¹³C=−92±4‰ polar lipids −116‰) documenting consumption of archaeal-bacterial aggregates. FA composition of additional soft-sediment methane seep species from Oregon and California provided evidence that consumption of archaeal-bacterial aggregates is widespread at methane seeps. This work is the first to show that Archaea are consumed by heterotrophic metazoans, a trophic process we coin as ‘archivory''.     

Identification of a gonadotropin-releasing hormone receptor orthologue in Caenorhabditis elegans

Background  

The Caenorhabditis elegans genome is known to code for at least 1149 G protein-coupled receptors (GPCRs), but the GPCR(s) critical to the regulation of reproduction in this nematode are not yet known. This study examined whether GPCRs orthologous to human gonadotropin-releasing hormone receptor (GnRHR) exist in C. elegans.     

Crystal structure of the crenarchaeal conserved chromatin protein Cren7 and double-stranded DNA complex

Cren7 is a crenarchaeal conserved chromatin protein discovered recently. To explore the mechanism of the DNA packaging in Crenarchaeota, the crystal structure of Cren7–GCGATCGC complex has been determined and refined at 1.6 Å resolution. Cren7 kinks the dsDNA sharply similar to Sul7d, another chromatin protein existing only in Sulfolobales, which reveals that the “bending and unwinding” compacting mechanism is conserved in Crenarchaeota. Significant structural differences are revealed by comparing both protein–dsDNA complexes. The kinked sites on the same dsDNA in the complexes with Sul7d and Cren7 show one base pair shift. For Cren7, fewer charged residues in the β‐barrel structural region bind to DNA, and additionally, the flexible loop L_β3β4 is also involved in the binding. Electrophoretic mobility shift assays indicate that loop L_β3β4 is essential for DNA‐binding of Cren7. These differences provide insight into the functional difference of both chromatin proteins, suggesting that Cren7 may be more regulative than Sul7d in the DNA‐binding affinity by the methylation in the flexible loop L_β3β4 in vivo.     

Identification of Protein-Tyrosine Phosphatases in Archaea

Protein-tyrosine dephosphorylation is a major mechanism in cellular regulation. A large number of protein-tyrosine phosphatases is known from Eukarya, and more recently bacterial homologues have also been identified. By employing conserved sequence patterns from both eukaryotic and bacterial protein-tyrosine phosphatases, we have identified three homologous sequences in two of the four complete archaeal genomes. Two hypothetical open reading frames in the genome of Methanococcus jannaschii (MJ0215 and MJECL20) and one in the genome of Pyrococcus horikoshii (PH1732) clearly bear all the conserved residues of this family. No homologues were found in the genomes of Archaeoglobus fulgidus and Methanobacterium thermoautotrophicum. This is the first report of protein-tyrosine phosphatase sequences in Archaea. Received: 29 April 1998 / Accepted: 27 November 1998     

A topological model for chromatin transcription and a role for nucleosome linkers

There is a good deal of evidence that transcribing RNA polymerase may translocate across nucleosomes without their displacement and (or) rearrangement. A topological model for RNA chain elongation on a nucleosome is considered here. A new mechanism of RNA polymerase translocation is suggested in order to avoid the steric hindrances inherent in the model. It is shown that a transcribed nucleoprotein fiber should be interrupted by protein-free DNA stretches (nucleosome linkers) to allow release of nascent RNA. Possible verifications and consequences of the model are discussed.