Geranylgeranylglyceryl Phosphate Synthase Research Articles

Hexamerization and thermostability emerged very early during geranylgeranylglyceryl phosphate synthase evolution.

A large number of archaea live in hyperthermophilic environments. In consequence, their proteins need to adopt to these harsh conditions, including the enzymes that catalyze the synthesis of their membrane ether lipids. The enzyme that catalyzes the formation of the first ether bond in these lipids, geranylgeranylglyceryl phosphate synthase (GGGPS), exists as a hexamer in many hyperthermophilic archaea, and a recent study suggested that hexamerization serves for a fine‐tuning of the flexibility – stability trade‐off under hyperthermophilic conditions. We have recently reconstructed the sequences of ancestral group II GGGPS enzymes and now present a detailed biochemical characterization of nine of these predecessors, which allowed us to trace back the evolution of hexameric GGGPS and to draw conclusions about the properties of extant GGGPS branches that were not accessible to experiments up to now. Almost all ancestral GGGPS proteins formed hexamers, which demonstrates that hexamerization is even more widespread among the GGGPS family than previously assumed. Furthermore, all experimentally studied ancestral proteins showed high thermostability. Our results indicate that the hexameric oligomerization state and thermostability were present very early during the evolution of group II GGGPS, while the fine tuning of the flexibility – stability trade‐off developed very late, independent of the emergence of hexamerization.

Structural studies of geranylgeranylglyceryl phosphate synthase, a prenyltransferase found in thermophilic Euryarchaeota.

Archaea are uniquely adapted to thrive in harsh environments, and one of these adaptations involves the archaeal membrane lipids, which are characterized by their isoprenoid alkyl chains connected via ether linkages to glycerol 1-phosphate. The membrane lipids of the thermophilic and acidophilic euryarchaeota Thermoplasma volcanium are exclusively glycerol dibiphytanyl glycerol tetraethers. The first committed step in the biosynthetic pathway of these archaeal lipids is the formation of the ether linkage between glycerol 1-phosphate and geranylgeranyl diphosphate, and is catalyzed by the enzyme geranylgeranylglyceryl phosphate synthase (GGGPS). The 1.72 Å resolution crystal structure of GGGPS from T. volcanium (TvGGGPS) in complex with glycerol and sulfate is reported here. The crystal structure reveals TvGGGPS to be a dimer, which is consistent with the absence of the aromatic anchor residue in helix α5a that is required for hexamerization in other GGGPS homologs; the hexameric quaternary structure in GGGPS is thought to provide thermostability. A phylogenetic analysis of the Euryarchaeota and a parallel ancestral state reconstruction investigated the relationship between optimal growth temperature and the ancestral sequences. The presence of an aromatic anchor residue is not explained by temperature as an ecological parameter. An examination of the active site of the TvGGGPS dimer revealed that it may be able to accommodate longer isoprenoid substrates, supporting an alternative pathway of isoprenoid membrane-lipid synthesis.

Sequence selection by FitSS4ASR alleviates ancestral sequence reconstruction as exemplified for geranylgeranylglyceryl phosphate synthase.

For evolutionary studies, but also for protein engineering, ancestral sequence reconstruction (ASR) has become an indispensable tool. The first step of every ASR protocol is the preparation of a representative sequence set containing at most a few hundred recent homologs whose composition determines decisively the outcome of a reconstruction. A common approach for sequence selection consists of several rounds of manual recompilation that is driven by embedded phylogenetic analyses of the varied sequence sets. For ASR of a geranylgeranylglyceryl phosphate synthase, we additionally utilized FitSS4ASR, which replaces this time-consuming protocol with an efficient and more rational approach. FitSS4ASR applies orthogonal filters to a set of homologs to eliminate outlier sequences and those bearing only a weak phylogenetic signal. To demonstrate the usefulness of FitSS4ASR, we determined experimentally the oligomerization state of eight predecessors, which is a delicate and taxon-specific property. Corresponding ancestors deduced in a manual approach and by means of FitSS4ASR had the same dimeric or hexameric conformation; this concordance testifies to the efficiency of FitSS4ASR for sequence selection. FitSS4ASR-based results of two other ASR experiments were added to the Supporting Information. Program and documentation are available at https://gitlab.bioinf.ur.de/hek61586/FitSS4ASR.

Hexamerization of Geranylgeranylglyceryl Phosphate Synthase Ensures Structural Integrity and Catalytic Activity at High Temperatures.

The cell membranes of all archaea contain ether lipids, and a number of archaea are hyperthermophilic. Consequently, the enzymes that catalyze the synthesis of membrane ether lipids had to adopt to these rough conditions. Interestingly, the enzyme that establishes the first ether bond in these lipids, the geranylgeranylglyceryl phosphate synthase (GGGPS), forms hexamers in many hyperthermophilic archaea, while also dimeric variants of this enzyme exist in other species. We used Methanothermobacter thermautotrophicus GGGPS (mtGGGPS) as a model to elucidate the benefit of hexamerization. We studied the oligomerization interfaces in detail by introducing disturbing mutations and subsequently compared the stability and activity of generated dimeric and monomeric variants with the wild-type enzyme. Differential scanning calorimetry revealed a biphasic denaturation of mtGGGPS. The temperature of the first transition varies and rises with increasing oligomerization state. This first phase of denaturation leads to catalytic inactivation, but CD spectroscopy indicated only minor changes on the secondary structure level. The residual part of the fold is extremely thermostable and denatures in a second phase at temperatures >120 °C. The analysis of another distant native GGGPS enzyme affirms these observations. Molecular dynamics simulations revealed three structural elements close to the substrate binding sites with elevated flexibility. We assume that hexamerization might stabilize these structures, and kinetic studies support this hypothesis for the binding pocket of the substrate glycerol 1-phosphate. Oligomerization might thus positively affect the thermostability-flexibility trade-off in GGGPS by allowing a higher intrinsic flexibility of the individual protomers.

Biological source and provenance of deep-water derived isoprenoid tetraether lipids along the Portuguese continental margin

There is increasing evidence that nitrifying Thaumarchaeota in the deep ocean waters may contribute to the sedimentary composition of isoprenoid glycerol dialkyl glycerol tetraethers (isoGDGTs), impacting TEX86 paleothermometry. We investigated the potential effect of deep-water dwelling Thaumarchaeota in the warm and saline Mediterranean Outflow Water (MOW) on the distribution of isoGDGTs by analysing suspended particulate matter (SPM) and surface sediments collected along five land-ocean transects along the southern Portuguese continental margin. To this end, we directly compared for the first time the composition of intact polar lipid (IPL)-derived isoGDGTs of SPM with the diversity, abundance, and activity of Thaumarchaeota based on the genetic analysis of the genes coding for the archaeal ammonia monooxygenase (amoA) and the geranylgeranylglyceryl phosphate (GGGP) synthase involved in the isoGDGT biosynthetic pathway. Our results revealed a strong positive relationship between water depth and TEX86H values for both SPM and surface sediments. The increasing TEX86H trends for both core lipid (CL) and IPL-derived fractions were accompanied by increasing fractional abundances of GDGT-2 and crenarchaeol regio-isomer and decreasing fractional abundances of GDGT-1 and GDGT-3 with increasing water depth. Phylogenetic analyses based on the archaeal amoA and the GGGP synthase proteins showed that Thaumarchaeota populations detected at 1m and 50m water depth were different from those detected in 200m and 1000m water depth, which had an increased contribution of so-called ‘deep water’ Thaumarchaeota. The differences in the fractional abundances of isoGDGTs with water depth were compatible with the increasing contribution of ‘deep water’ Thaumarchaeota harboring a different GGGP synthase enzyme which has been suggested to relate to changes in the relative proportion of synthesized isoGDGTs. Accordingly, it appears that the sedimentary distribution of CL isoGDGTs used in TEX86H along the Portuguese margin is primarily influenced by water depth due to the increasing contribution of the deep-water population of Thaumarchaeota residing in the MOW. Our study also reveals that the effect of deep water Thaumarchaeotal communities on sedimentary isoGDGT distributions should be considered globally.

Depth‐related distribution of a key gene of the tetraether lipid biosynthetic pathway in marine Thaumarchaeota

The distribution of isoprenoid glycerol dialkyl glycerol tetraethers (GDGT) lipids synthesized by Thaumarchaeota has been shown to be temperature-dependent in world oceans. Depth-related differences in the ammonia monooxygenase (amoA) of Thaumarchaeota have led to the classification of 'shallow' and 'deep water' clusters, potentially affecting GDGT distributions. Here, we investigate if this classification is also reflected in a key gene of the thaumarchaeotal lipid biosynthetic pathway coding for geranylgeranylglyceryl phosphate (GGGP) synthase. We investigated metagenomic databases, suspended particulate matter and surface sediment of the Arabian Sea oxygen minimum zone. These revealed significant differences in amoA and GGGP synthase between 'shallow' and 'deep water' Thaumarchaeota. Intriguingly, amoA and GGGP synthase sequences of benthic Thaumarchaeota clustered with the 'shallow water' rather than with 'deep water' Thaumarchaeota. This suggests that pressure and temperature are unlikely factors that drive the differentiation, and suggests an important role of ammonia concentration that is higher in benthic and 'shallow water' niches. Analysis of the relative abundance of GDGTs in the Arabian Sea and in globally distributed surface sediments showed differences in GDGT distributions from subsurface to deep waters that may be explained by differences in the GGGP synthase, suggesting a genetic control on GDGT distributions.

A comprehensive analysis of the geranylgeranylglyceryl phosphate synthase enzyme family identifies novel members and reveals mechanisms of substrate specificity and quaternary structure organization

Geranylgeranylglyceryl phosphate synthase (GGGPS) family enzymes catalyse the formation of an ether bond between glycerol-1-phosphate and polyprenyl diphosphates. They are essential for the biosynthesis of archaeal membrane lipids, but also occur in bacterial species, albeit with unknown physiological function. It has been known that there exist two phylogenetic groups (I and II) of GGGPS family enzymes, but a comprehensive study has been missing. We therefore visualized the variability within the family by applying a sequence similarity network, and biochemically characterized 17 representative GGGPS family enzymes regarding their catalytic activities and substrate specificities. Moreover, we present the first crystal structures of group II archaeal and bacterial enzymes. Our analysis revealed that the previously uncharacterized bacterial enzymes from group II have GGGPS activity like the archaeal enzymes and differ from the bacterial group I enzymes that are heptaprenylglyceryl phosphate synthases. The length of the isoprenoid substrate is determined in group II GGGPS enzymes by 'limiter residues' that are different from those in group I enzymes, as shown by site-directed mutagenesis. Most of the group II enzymes form hexamers. We could disrupt these hexamers to stable and catalytically active dimers by mutating a single amino acid that acts as an 'aromatic anchor'.

Dimerization Determines Substrate Specificity of a Bacterial Prenyltransferase

We have identified the native dimer interface of heptaprenylglyceryl phosphate synthase PcrB from the bacterium Bacillus subtilis and analyzed the significance of oligomer formation for stability and catalytic activity. Computational methods predicted two different surface regions of the PcrB protomer that could be responsible for dimer formation. These bona fide interfaces were assessed both in silico and experimentally by the introduction of amino acid substitutions that led to monomerization, and by incorporation of an unnatural amino acid to allow cross-linking of the two protomers. The results showed that, in contrast to previous assumptions, PcrB uses the same interface for dimerization as the homologous geranylgeranylglyceryl phosphate synthase from Archaea. Thermal unfolding demonstrated that the monomeric proteins are only slightly less stable than wild-type PcrB. However, activity assays showed that monomerization limits the length of accepted polyprenyl pyrophosphates to three isoprene units, whereas the native PcrB substrate contains seven isoprene entities. We provide a plausible hypothesis as to how dimerization determines substrate specificity of PcrB.

Functional Assignment of an Enzyme that Catalyzes the Synthesis of an Archaea‐Type Ether Lipid in Bacteria

An archaea-type ether lipid in bacteria: PcrB, the bacterial homologue of the archaea-specific geranylgeranylglyceryl phosphate synthase, produces heptaprenylglyceryl phosphate in bacillales. The product becomes dephosphorylated and acetylated in vivo.

Evidence for a Gram-positive, Eubacterial Root of the Tree of Life

Directed indels, insertions, and deletions within paralogous genes, have the potential to root the tree of life. Here we apply a newly developed rooting algorithm, top-down rooting, to indels found in informational and operational gene sets, introduce new computational tools for indel analyses, and present evidence (P < .01) that the root of the tree of life is not present in its traditional location, between the Eubacteria and the Archaebacteria. Using indels contained in the dihydroorotate dehydrogenase/uroporphyrinogen decarboxylase gene pair and in the ribosomal protein S12/beta prime subunit of the RNA polymerase gene pair, we exclude the root from within the clade consisting of the Firmicutes plus the Archaebacteria and their most recent common ancestor. These results, plus previous directed indel studies excluding the root from the eukaryotes, restrict the root to just four possible sites. One potential root is on the branch leading to the double-membrane prokaryotes, another is on the branch leading to the Actinobacteria, another is within the Actinobacteria, and the fourth is on the branch leading to the Firmicutes-Archaea clade. These results imply (1) that the cenancestral population was not hyperthermophilic, but moderate thermophily cannot be excluded for the root on the branch leading to the Firmicutes-Archaea clade, (2) that the cenancestral population was surrounded by ester lipids and a peptidoglycan layer, and (3) that parts of the mevalonate synthesis pathway were present in the population ancestral to the Bacilli and the Archaebacteria, including geranylgeranylglyceryl phosphate synthase, an enzyme thought to be partially responsible for the unique sn-1 stereochemistry of the archaeal glycerol phosphate backbone.

Purification and characterization of geranylgeranylglyceryl phosphate synthase from a thermoacidophilic archaeon, Thermoplasma acidophilum.

We purified a geranylgeranylglyceryl phosphate (GGGP) synthase from Thermoplasma acidophilum by several steps of chromatography. Based on the proteinase-fragment-mass-pattern analysis of the SDS-PAGE band of the partially purified protein, the DNA sequence encoding the protein was identified from the whole genome sequence database of the species. The gene encoding GGGP synthase in T. acidophilum was cloned after PCR amplification of the gene from the genomic DNA. The recombinant enzyme was expressed in Escherichia coli and purified. A single band with a molecular mass of 27 kDa was obtained by SDS-PAGE analysis. The apparent native molecular mass of the enzyme was about 50 kDa based on gel filtration chromatography, suggesting that the enzyme is active as a homodimer. As the GGGP synthase from Methanobacterium thermoautotrophicum has been reported as a pentamer, the enzymes of the two organisms have different oligomeric structures. Other characteristics, including substrate specificity, are similar for the GGGPs of these organisms.

Geranylgeranylglyceryl phosphate synthase. Characterization of the recombinant enzyme from Methanobacterium thermoautotrophicum.

Geranylgeranylglyceryl diphosphate synthase (GGGP synthase) catalyzes alkylation of (S)-glyceryl phosphate [(S)-GP] by geranylgeranyl diphosphate (GGPP) to produce (S)-geranylgeranylglyceryl phosphate [(S)-GGGP]. This reaction is the first committed step in the biosynthesis of ether-linked membrane lipids in Archaea. The gene encoding GGGP synthase from Methanobacterium thermoautotrophicum was cloned using probes designed from the N-terminal sequence determined from the purified enzyme. The open reading frame, which encoded a protein of 245 amino acids, was inserted into a pET expression vector and expressed in Escherichia coli. The recombinant GGGP synthase was purified to homogeneity. The enzyme is active as a homopentamer, as determined by size exclusion chromatography and equilibrium sedimentation experiments. GGGP synthase has optimal activity at 55 degrees C in pH 8.0 buffer containing 1 mM MgCl(2). V(max) = 4.0 +/- 0.1 micromol min(-1) mg(-1) (k(cat) = 0.34 +/- 0.03 s(-1) for pentameric GGGP synthase assuming all subunits are fully active), K(m)((S)-GP) = 13.5 +/- 1.0 microM, and K(m)(GGPP) = 506 +/- 47 nM. These steady-state catalytic constants were identical to those for enzyme isolated from cell extracts of M. thermoautotrophicum [Chen, A., Zhang, D., and Poulter, C. D. (1993) J. Biol. Chem. 268, 21701-21705]. Alignment of seven putative archaeal GGGP synthase sequences revealed a number of highly conserved residues consisting of five aspartate/glutamates, three serine/threonines, two prolines, and five glycines, including a conserved GGG motif.

(S)-geranylgeranylglyceryl phosphate synthase. Purification and characterization of the first pathway-specific enzyme in archaebacterial membrane lipid biosynthesis.

The first pathway-specific step in the biosynthesis of the core membrane diether lipids in archaebacteria is the alkylation of the primary hydroxyl group in (S)-glyceryl phosphate by geranylgeranyl diphosphate. The reaction is catalyzed by (S)-3-O-geranylgeranylglyceryl phosphate ((S)-GGGP) synthase. The cytosolic enzyme was purified to homogeneity from the moderately thermophilic archaebacterium Methanobacterium thermoautotrophicum by a combination of ammonium sulfate precipitation, four chromatographic steps (DE52, Q-Sepharose, phenyl-Superose, and Protein Pak), and native polyacrylamide gel electrophoresis. SDS-polyacrylamide gel electrophoresis of gel-purified GGGP synthase gave a single band at 29 kDa. The enzyme requires Mg2+ for optimal activity, although prenyltransfer is also seen in buffers containing Mn2+ or Zn2+. A well defined pH optimum occurs between 6.0 and 7.5. Maximal activity is seen at 50-65 degrees C. The Michaelis constants for GGGP synthase are Vmax = 4.1 +/- 0.5 mumol min-1 mg-1, KMGGPP = 4.1 +/- 1.1 microM, and KMGP = 41 +/- 5 microM.

Analysis and Purification of Phosphorylated Isoprenoids by Reversed-Phase HPLC

Procedures were developed for analysis and purification of phosphorylated isoprenoids by reversed-phase HPLC. Dimethylallyl diphosphate (C5), geranyl diphosphate (C10), farnesyl diphosphate (C15), geranylgeranyl diphosphate (C20), and farnesylgeranyl diphosphate (C25) were cleanly separated on a C18 column by gradient elution with acetonitrile and 25 mM NH4HCO3. Reversed-phase HPLC was used to directly analyze extracts for phosphorylated isoprenoids and to follow the progress of enzyme-catalyzed reactions without having to hydrolyze the phosphate esters before analysis. Examples are provided for geranylgeranyl diphosphate synthase, geranylgeranylglyceryl phosphate synthase, and squalene synthase. The separations were run on preparative scales to purify products from the enzymatic reactions for mass spectrometry and to purify synthetic substrates.