THAP9 Transposase Cleaves DNA via Conserved Acidic Residues in an RNaseH-Like Domain

The catalytic domain of most ‘cut and paste’ DNA transposases have the canonical RNase-H fold, which is also shared by other polynucleotidyl transferases such as the retroviral integrases and the RAG1 subunit of V(D)J recombinase. The RNase-H fold is a mixture of beta sheets and alpha helices with three acidic residues (Asp, Asp, Glu/Asp—DDE/D) that are involved in the metal-mediated cleavage and subsequent integration of DNA. Human THAP9 (hTHAP9), homologous to the well-studied Drosophila P-element transposase (DmTNP), is an active DNA transposase that, although domesticated, still retains the catalytic activity to mobilize transposons. In this study we have modeled the structure of hTHAP9 using the recently available cryo-EM structure of DmTNP as a template to identify an RNase-H like fold along with important acidic residues in its catalytic domain. Site-directed mutagenesis of the predicted catalytic residues followed by screening for DNA excision and integration activity has led to the identification of candidate Ds and Es in the RNaseH fold that may be a part of the catalytic triad in hTHAP9. This study has helped widen our knowledge about the catalytic activity of a functionally uncharacterized transposon-derived gene in the human genome.

THAP9 transposase cleaves DNA via conserved acidic residues in an RNaseH-like domain

Background: The catalytic domain of most ‘cut and paste’ DNA transposases have the canonical RNase-H fold which is also shared by other polynucleotidyl transferases like the retroviral integrases and the RAG1 subunit of V(D)J recombinase. The RNase-H fold is a mixture of beta sheets and alpha helices with three acidic residues (Asp, Asp, Glu/Asp - DDE/D) that are involved in the metal-mediated cleavage and subsequent integration of DNA. Human THAP9 (hTHAP9), homologous to the well-studied Drosophila P-element transposase (DmTNP), is an active DNA transposase that, although domesticated, still retains the catalytic activity to mobilize transposons.Results: In this study we have modelled the structure of hTHAP9 using the recently available cryo-EM structure of DmTNP as a template to identify an RNase-H like fold along with important acidic residues in its catalytic domain. Site-directed mutagenesis of the predicted catalytic residues followed by screening for DNA excision and integration activity, has led to the identification of candidate Ds and Es in the RNaseH fold that can be a part of the catalytic triad in hTHAP9.Conclusions: Many DNA transposases execute DNA excision via a catalytic domain, which has a canonical RNase-H fold. Despite the similar nature of the catalytic domain, these transposases exhibit mechanistically different strategies of transposition. We identify a potential RNase-H fold in hTHAP9 with conserved DDE motif required for cutting DNA. Additionally, we have found a residue, which when mutated, leads to an increase in hTHAP9’s transposition activity. Such hyperactive transposase mutants can be exploited as tools in genome engineering and gene therapy. This study has helped widen our knowledge about the catalytic activity of a functionally uncharacterised transposon-derived gene in the human genome.

Basis of specificity for a conserved and promiscuous chromatin remodeling protein

Eukaryotic genomes are organized dynamically through the repositioning of nucleosomes. Isw2 is an enzyme that has been previously defined as a genome-wide, non-specific nucleosome spacing factor. Here, we show that Isw2 instead acts as an obligately targeted nucleosome remodeler in vivo through physical interactions with sequence-specific factors. We demonstrate that Isw2- recruiting factors use small and previously uncharacterized epitopes, which direct Isw2 activity through highly conserved acidic residues in the Isw2 accessory protein Itc1. This interaction orients Isw2 on target nucleosomes, allowing for precise nucleosome positioning at targeted loci. Finally, we show that these critical acidic residues have been lost in the Drosophila lineage, potentially explaining the inconsistently characterized function of Isw2-like proteins. Altogether, these data suggest an 'interacting barrier model' where Isw2 interacts with a sequence-specific factor to accurately and reproducibly position a single, targeted nucleosome to define the precise border of phased chromatin arrays.

A Novel Carboxylesterase Derived from a Compost Metagenome Exhibiting High Stability and Activity towards High Salinity

Halotolerant lipolytic enzymes have gained growing interest, due to potential applications under harsh conditions, such as hypersalinity and presence of organic solvents. In this study, a lipolytic gene, est56, encoding 287 amino acids was identified by functional screening of a compost metagenome. Subsequently, the gene was heterologously expressed, and the recombinant protein (Est56) was purified and characterized. Est56 is a mesophilic (Topt 50 °C) and moderate alkaliphilic (pHopt 8) enzyme, showing high thermostability at 30 and 40 °C. Strikingly, Est56 is halotolerant as it exhibited high activity and stability in the presence of up to 4 M NaCl or KCl. Est56 also displayed enhanced stability against high temperatures (50 and 60 °C) and urea (2, 4, and 6 M) in the presence of NaCl. In addition, the recently reported halotolerant lipolytic enzymes were summarized. Phylogenetic analysis grouped these enzymes into 13 lipolytic protein families. The majority (45%) including Est56 belonged to family IV. To explore the haloadaptation of halotolerant enzymes, the amino acid composition between halotolerant and halophilic enzymes was statistically compared. The most distinctive feature of halophilic from non-halophilic enzymes are the higher content of acidic residues (Asp and Glu), and a lower content of lysine, aliphatic hydrophobic (Leu, Met and Ile) and polar (Asn) residues. The amino acid composition and 3-D structure analysis suggested that the high content of acidic residues (Asp and Glu, 12.2%) and low content of lysine residues (0.7%), as well as the excess of surface-exposed acidic residues might be responsible for the haloadaptation of Est56.

The evolution and mechanism of GPCR proton sensing

Of the 800 G protein-coupled receptors (GPCRs) in humans, only three (GPR4, GPR65, and GPR68) regulate signaling in acidified microenvironments by sensing protons (H+). How these receptors have uniquely obtained this ability is unknown. Here we show these receptors evolved the capability to sense H+ signals by acquiring buried acidic residues. Using our informatics platform pHinder, we identified a triad of buried acidic residues shared by all three receptors, a feature distinct from all other human GPCRs. Phylogenetic analysis shows the triad emerged in GPR65, the immediate ancestor of GPR4 and GPR68. To understand the evolutionary and mechanistic importance of these triad residues, we developed Deep Variant Profiling (DVP), a yeast-based technology that utilizes high-throughput CRISPR to build and profile large libraries of GPCR variants. Using DVP and GPCR assays in HEK293 cells, we assessed the pH-sensing contributions of each triad residue in all three receptors. As predicted by our calculations, most triad mutations had profound effects consistent with direct regulation of receptor pH sensing. Additionally, we found that an allosteric modulator of many class A GPCRs, Na+, synergistically regulated pH sensing by maintaining the pKa values of triad residues within the physiologically relevant pH range. As such, we show that all three receptors function as coincidence detectors of H+ and Na+. Taken together, these findings elucidate the molecular evolution and long-sought mechanism of GPR4, GPR65, and GPR68 pH sensing, and provide pH-insensitive variants that should be valuable for assessing the therapeutic potential and (patho)physiological importance of GPCR pH sensing.

Human transcriptional activation domains require hydrophobic and acidic residues

Transcription factors activate gene expression with separable DNA binding domains and activation domains (Latchman, 2008). High-throughput studies have uncovered rules for how DNA binding domains recognize their cognate DNA motifs, but the design principles of activation domains remain opaque. For over thirty years it has been a mystery why activation domains are acidic and unstructured (Sigler, 1988). Activation domains require hydrophobic motifs to bind coactivators and join transcriptional condensates, but low evolutionary conservation and intrinsic disorder have made it difficult to identify the design principles that govern the sequence to function relationship (Boija et al., 2018; Chong et al., 2018; Cress and Triezenberg, 1991; Dyson and Wright, 2016). Consequently, activation domains cannot be predicted from amino acid sequence (Finn et al., 2016). Here, we resolve the functional roles of acidity and disorder in activation domains and use these insights to build a new predictor. We designed sequence variants in seven acidic activation domains and measured their activities in parallel with a high-throughput assay in human cell culture. Our results support a flexible model in which acidic residues solubilize hydrophobic motifs so that they can interact with coactivators. This model accurately predicts activation domains in the human proteome. We identify three general rules for activation domain function: hydrophobic motifs must be balanced by acidic residues; acidic residues make large contributions to activity when they are adjacent to motifs; and within motifs, the presence of aromatic or leucine residues reflects the structural constraints of coactivator interactions. We anticipate these design principles will aid efforts to predict activations from amino acid sequence and to engineer new domains.

THAP9 transposase cleaves DNA via conserved acidic residues in an RNaseH-like domain

The catalytic domain of most ‘cut and paste’ DNA transposases have the canonical RNase-H fold which is also shared by other polynucleotidyl transferases like retroviral integrases and the RAG1 subunit of V(D)J recombinase. The RNase-H fold is a mixture of beta sheets and alpha helices with three acidic residues (Asp, Asp, Glu/Asp - DDE/D) that are involved in metal-mediated cleavage and subsequent integration of DNA. Human THAP9 (hTHAP9), homologous to the well-studied Drosophila P-element transposase (DmTNP), is an active DNA transposase that, although domesticated, still retains the catalytic activity to mobilize transposons. In this study we have modelled the structure of hTHAP9 using the recently available cryo-EM structure of DmTNP as a template to identify an RNase-H like fold along with important acidic residues in its catalytic domain. Site-directed mutagenesis of the predicted catalytic residues followed by screening for DNA excision and integration activity, led to the identification of candidate Ds and Es in the RNaseH fold that appear to constitute the catalytic triad of hTHAP9.Significance statementMany DNA transposases execute DNA excision via a catalytic domain, which has a canonical RNase-H fold. Despite the similar nature of the catalytic domain, these transposases exhibit mechanistically different strategies of transposition. We identify a potential RNase-H fold in hTHAP9 with a conserved DDE motif required for cutting DNA. Additionally, we have found a residue, which when mutated, leads to an increase in hTHAP9’s transposition activity. Such hyperactive transposase mutants can be exploited as tools in genome engineering and gene therapy. This study has helped widen our knowledge about the catalytic activity of a functionally uncharacterized transposon-derived gene in the human genome.