Éva Hunyadi-Gulyás

Active site closure facilitates juxtaposition of reactant atoms for initiation of catalysis by human dUTPase

Human dUTPase, essential for DNA integrity, is an important survival factor for cancer cells. We determined the crystal structure of the enzyme:α,β‐imino‐dUTP:Mg complex and performed equilibrium binding experiments in solution. Ordering of the C‐terminus upon the active site induces close juxtaposition of the incoming nucleophile attacker water oxygen and the α‐phosphorus of the substrate, decreasing their distance below the van der Waals limit. Complex interactions of the C‐terminus with both substrate and product were observed via a specifically designed tryptophan sensor, suitable for further detailed kinetic and ligand binding studies. Results explain the key functional role of the C‐terminus.

Flexible segments modulate co-folding of dUTPase and nucleocapsid proteins

The homotrimeric fusion protein nucleocapsid (NC)-dUTPase combines domains that participate in RNA/DNA folding, reverse transcription, and DNA repair in Mason-Pfizer monkey betaretrovirus infected cells. The structural organization of the fusion protein remained obscured by the N- and C-terminal flexible segments of dUTPase and the linker region connecting the two domains that are invisible in electron density maps. Small-angle X-ray scattering reveals that upon oligonucleotide binding the NC domains adopt the trimeric symmetry of dUTPase. High-resolution X-ray structures together with molecular modeling indicate that fusion with NC domains dramatically alters the conformation of the flexible C-terminus by perturbing the orientation of a critical β-strand. Consequently, the C-terminal segment is capable of double backing upon the active site of its own monomer and stabilized by non-covalent interactions formed with the N-terminal segment. This co-folding of the dUTPase terminal segments, not observable in other homologous enzymes, is due to the presence of the fused NC domain. Structural and genomic advantages of fusing the NC domain to a shortened dUTPase in betaretroviruses and the possible physiological consequences are envisaged.

Modular Broad-Host-Range Expression Vectors for Single-Protein and Protein Complex Purification

ABSTRACT A set of modular broad-host-range expression vectors with various affinity tags (six-His-tag, FLAG-tag, Strep-tag II, T7-tag) was created. The complete nucleotide sequences of the vectors are known, and these small vectors can be mobilized by conjugation. They are useful in the purification of proteins and protein complexes from gram-negative bacterial species. The plasmids were easily customized for Thiocapsa roseopersicina, Rhodobacter capsulatus, and Methylococcus capsulatus by inserting an appropriate promoter. These examples demonstrate the versatility and flexibility of the vectors. The constructs harbor the T7 promoter for easy overproduction of the desired protein in an appropriate Escherichia coli host. The vectors were useful in purifying different proteins from T. roseopersicina. The FLAG-tag-Strep-tag II combination was utilized for isolation of the HynL-HypC2 protein complex involved in hydrogenase maturation. These tools should be useful for protein purification and for studying protein-protein interactions in a range of bacterial species.

Developmental Regulation of dUTPase in Drosophila melanogaster

dUTPase prevents uracil incorporation into DNA by strict regulation of the cellular dUTP:dTTP ratio. Lack of the enzyme initiates thymineless cell death, prompting studies on enzyme regulation. We investigated expression pattern and localization of Drosophila dUTPase. Similarly to human, two isoforms of the fly enzyme were identified at both mRNA and protein levels. During larval stages, a drastic decrease of dUTPase expression was demonstrated at the protein level. In contrast, dUTPase mRNAs display constitutive character throughout development. A putative nuclear localization signal was identified in one of the two isoforms. However, immunohistochemistry of ovaries and embryos did not show a clear correlation between the presence of this signal and subcellular localization of the protein, suggesting that the latter may be perturbed by additional factors. Results are in agreement with a multilevel regulation of dUTPase in the Drosophila proteome, possibly involving several interacting protein partners of the enzyme. Using independent approaches, the existence of such macromolecular partners was verified.

Altered Functional Protein Networks in the Prefrontal Cortex and Amygdala of Victims of Suicide

Probing molecular brain mechanisms related to increased suicide risk is an important issue in biological psychiatry research. Gene expression studies on post mortem brains indicate extensive changes prior to a successful suicide attempt; however, proteomic studies are scarce. Thus, we performed a DIGE proteomic analysis of post mortem tissue samples from the prefrontal cortex and amygdala of suicide victims to identify protein changes and biomarker candidates of suicide. Among our matched spots we found 46 and 16 significant differences in the prefrontal cortex and amygdala, respectively; by using the industry standard t test and 1.3 fold change as cut off for significance. Because of the risk of false discoveries (FDR) in these data, we also made FDR adjustment by calculating the q-values for all the t tests performed and by using 0.06 and 0.4 as alpha thresholds we reduced the number of significant spots to 27 and 9 respectively. From these we identified 59 proteins in the cortex and 11 proteins in the amygdala. These proteins are related to biological functions and structures such as metabolism, the redox system, the cytoskeleton, synaptic function, and proteolysis. Thirteen of these proteins (CBR1, DPYSL2, EFHD2, FKBP4, GFAP, GLUL, HSPA8, NEFL, NEFM, PGAM1, PRDX6, SELENBP1 and VIM,) have already been suggested to be biomarkers of psychiatric disorders at protein or genome level. We also pointed out 9 proteins that changed in both the amygdala and the cortex, and from these, GFAP, INA, NEFL, NEFM and TUBA1 are interacting cytoskeletal proteins that have a functional connection to glutamate, GABA, and serotonin receptors. Moreover, ACTB, CTSD and GFAP displayed opposite changes in the two examined brain structures that might be a suitable characteristic for brain imaging studies. The opposite changes of ACTB, CTSD and GFAP in the two brain structures were validated by western blot analysis.

Effect of nicotine and polyaromtic hydrocarbons on cerebral endothelial cells

The present study was designed to investigate the effect of nicotine and polyaromatic hydrocarbon compounds on cerebral endothelial cells (CECs). Nicotine treatments from 15 min to 5 h did not cause any changes in the expression and localization of principal junctional proteins. One day of treatment with a relatively high concentration of nicotine induced a decrease in the expression of the tight junction protein ZO‐1, occludin, and the adherens junction protein, cadherin. Treatment with 3 × 10−5 M phenanthrene for 24 h caused a redistribution of occludin from the Triton X‐100 insoluble to the Triton X‐100 soluble fraction. Transendothelial electrical resistance was not significantly affected by 24 h treatments with nicotine, methylanthracene or phenanthrene. However, 24 h nicotine treatment increased transendothelial permeability in CECs exposed to oxidative stress. Both nicotine and phenanthrene were able to regulate the expression of a large number of proteins as revealed by 2D electrophoresis. Our experiments suggest that tobacco smoking may affect the junctional complex of CECs, and that this effect is enhanced by oxidative stress.

Identification of nodule-specific cysteine-rich plant peptides in endosymbiotic bacteria

The symbiosis of Medicago truncatula with Sinorhizobium meliloti or Sinorhizobium medicae soil bacteria results in the formation of root nodules where bacteria inside the plant cells are irreversibly converted to polyploid, nondividing nitrogen‐fixing bacteroids. Bacteroid differentiation is host‐controlled and the plant effectors are symbiosis‐specific secreted plant peptides. In the M. truncatula genome there are more than 600 symbiotic peptide genes including 500 small genes coding for nodule‐specific cysteine‐rich (NCR) peptides. While NCR transcripts represent >5% of the nodule transcriptome, the existence of only eight NCR peptides has been demonstrated so far. The predicted NCRs are secreted peptides targeted to the endosymbionts. Correspondingly, all the eight detected peptides were present in the bacteroids. Here, we report on large‐scale detection of NCR peptides from nodules and from isolated, semipurified endosymbionts at various stages of their differentiation. In total 138 NCRs were detected in the bacteroids; 38 were cationic while the majority was anionic. The presence of early NCRs in nitrogen‐fixing bacteroids indicates their high stability, and their long‐term maintenance suggests persisting biological roles in the bacteroids.

Developmental-stage-specific regulation of the polyubiquitin receptors in Drosophila melanogaster

Recognition of polyubiquitylated substrates by the proteasome is a highly regulated process that requires polyubiquitin receptors. We show here that the concentrations of the proteasomal and extraproteasomal polyubiquitin receptors change in a developmentally regulated fashion. The stoichiometry of the proteasomal p54/Rpn10 polyubiquitin receptor subunit, relative to that of other regulatory particle (RP) subunits falls suddenly at the end of embryogenesis, remains low throughout the larval stages, starts to increase again in the late third instar larvae and remains high in the pupae, adults and embryos. A similar developmentally regulated fluctuation was observed in the concentrations of the Rad23 and Dsk2 extraproteasomal polyubiquitin receptors. Depletion of the polyubiquitin receptors at the end of embryogenesis is due to the emergence of a developmentally regulated selective proteolytic activity. To follow the fate of subunit p54/Rpn10 in vivo, transgenic Drosophila melanogaster lines encoding the N-terminal half (NTH), the C-terminal half (CTH) or the full-length p54/Rpn10 subunit were established in the inducible Gal4-UAS system. The daughterless-Gal4-driven whole-body expression of the full-length subunit or its NTH did not produce any detectable phenotypic changes, and the transgenic products were incorporated into the 26S proteasome. The transgene-encoded CTH was not incorporated into the 26S proteasome, caused third instar larval lethality and was found to be multi-ubiquitylated. This modification, however, did not appear to be a degradation signal because the half-life of the CTH was over 48 hours. Accumulation of the CTH disturbed the developmentally regulated changes in subunit composition of the RP and the emergence of the selective proteolytic activity responsible for the depletion of the polyubiquitin receptors. Build-up of subunit p54/Rpn10 in the RP had already started in 84-hour-old larvae and reached the full complement characteristic of the non-larval developmental stages at the middle of the third instar larval stage, just before these larvae perished. Similar shifts were observed in the concentrations of the Rad23 and Dsk2 polyubiquitin receptors. The postsynthetic modification of CTH might be essential for this developmental regulation, or it might regulate an essential extraproteasomal function(s) of subunit p54/Rpn10 that is disturbed by the expression of an excess of CTH.

Factors that contribute to the complexity of protein digests

Abstract High-throughput proteomics is one of the most dynamically developing research areas. Frequently, the whole protein content of a cell is digested, fractionated and analyzed in a completely automated way, including data analysis. Not only are proteins identified this way, but quantitative studies are also performed, and posttranslational modifications and covalently labeled derivatives are identified. Because the presence of unexpected and/or unconsidered contaminants or covalently modified peptides can lead to data misinterpretation in such an environment, it is mandatory that we attempt to identify, understand and evaluate the factors that can contribute to the complexity of protein digest mixtures.

The Guanine-Quadruplex Structure in the Human c-myc Gene's Promoter Is Converted into B-DNA Form by the Human Poly(ADP-Ribose)Polymerase-1

The important regulatory role of the guanine-quadruplex (GQ) structure, present in the nuclease hypersensitive element (NHE) III1 region of the human c-myc (h c-myc) genes promoter, in the regulation of the transcription of that gene has been documented. Here we present evidences, that the human nuclear poly(ADP-ribose)polymerase-1 (h PARP-1) protein participates in the regulation of the h c-myc gene expression through its interaction with this GQ structure, characterized by binding assays, fluorescence energy transfer (FRET) experiments and by affinity pull-down experiments in vitro, and by chromatin immunoprecipitation (ChIP)-qPCR analysis and h c-myc-promoter-luciferase reporter determinations in vivo. We surmise that h PARP-1 binds to the GQ structure and participates in the conversion of that structure into the transcriptionally more active B-DNA form. The first Zn-finger structure present in h PARP-1 participates in this interaction. PARP-1 might be a new member of the group of proteins participating in the regulation of transcription through their interactions with GQ structures present in the promoters of different genes.