On the mechanism of membrane transport of zinc ions by ZntB

Zinc is essential for all branches of life and is the second most abundant transition metal divalent cation in living organisms after iron. Since metal ions cannot be synthesized, all living organisms rely on membrane proteins to take up metal cations from the environment. However, in many cases an excess of metals is toxic, thus there must be also membrane proteins capable to expel unnecessary ions. To fully understand these processes of metal transport in and out the cell, it is essential to solve structures of the membrane proteins in the presence and absence of their substrates, and to characterize them biochemically to propose and validate their transport mechanism. This thesis contributes in the understanding on the transport of zinc, and several other metal ions, via ZntB and other members of the 2-TM-GxN family, which are present in every kingdom of life

Cation permeability in CorA family of proteins

CorA proteins belong to 2-TM-GxN family of membrane proteins, and play a major role in Mg2+ transport in prokaryotes and eukaryotic mitochondria. The selection of substrate is believed to occur via the signature motif GxN, however there is no consensus how strict this selection within the family. To answer this question, we employed fluorescence-based transport assays on three different family members, namely CorA from bacterium Thermotoga maritima, CorA from the archeon Methanocaldococcus jannaschii and ZntB from bacterium Escherichia coli, reconstituted into proteoliposomes. Our results show that all three proteins readily transport Mg2+, Co2+, Ni2+ and Zn2+, but not Al3+. Despite the similarity in cation specificity, ZntB differs from the CorA proteins, as in the former transport is stimulated by a proton gradient, but in the latter by the membrane potential, confirming the hypothesis that CorA and ZntB proteins diverged to different transport mechanisms within the same protein scaffold

An Overview of the Top Ten Detergents Used for Membrane Protein Crystallization

To study integral membrane proteins, one has to extract them from the membrane—the step that is typically achieved by the application of detergents. In this mini-review, we summarize the top 10 detergents used for the structural analysis of membrane proteins based on the published results. The aim of this study is to provide the reader with an overview of the main properties of available detergents (critical micelle concentration (CMC) value, micelle size, etc.) and provide an idea of what detergents to may merit further study. Furthermore, we briefly discuss alternative solubilization and stabilization agents, such as polymers

Structural and Functional Characterization of NadR from Lactococcus lactis

NadR is a bifunctional enzyme that converts nicotinamide riboside (NR) into nicotinamide mononucleotide (NMN), which is then converted into nicotinamide adenine dinucleotide (NAD). Although a crystal structure of the enzyme from the Gram-negative bacterium Haemophilus influenzae is known, structural understanding of its catalytic mechanism remains unclear. Here, we purified the NadR enzyme from Lactococcus lactis and established an assay to determine the combined activity of this bifunctional enzyme. The conversion of NR into NAD showed hyperbolic dependence on the NR concentration, but sigmoidal dependence on the ATP concentration. The apparent cooperativity for ATP may be explained because both reactions catalyzed by the bifunctional enzyme (phosphorylation of NR and adenylation of NMN) require ATP. The conversion of NMN into NAD followed simple Michaelis-Menten kinetics for NMN, but again with the sigmoidal dependence on the ATP concentration. In this case, the apparent cooperativity is unexpected since only a single ATP is used in the NMN adenylyltransferase catalyzed reaction. To determine the possible structural determinants of such cooperativity, we solved the crystal structure of NadR from L. lactis (NadRLl). Co-crystallization with NAD, NR, NMN, ATP, and AMP-PNP revealed a ‘sink’ for adenine nucleotides in a location between two domains. This sink could be a regulatory site, or it may facilitate the channeling of substrates between the two domains

Structural and biochemical characterization of a novel ZntB (CmaX) transporter protein from Pseudomonas aeruginosa

The 2-TM-GxN family of membrane proteins is widespread in prokaryotes and plays an important role in transport of divalent cations. The canonical signature motif, which is also a selectivity filter, has a composition of Gly-Met-Asn. Some members though deviate from this composition, however no data are available as to whether this has any functional implications. Here we report the functional and structural analysis of CmaX protein from a pathogenic Pseudomonas aeruginosa bacterium, which has a Gly-Ile-Asn signature motif. CmaX readily transports Zn2+, Mg2+, Cd2+, Ni2+ and Co2+ ions, but it does not utilize proton-symport as does ZntB from Escherichia coli. Together with the bioinformatics analysis, our data suggest that deviations from the canonical signature motif do not reveal any changes in substrate selectivity or transport and easily alter in course of evolution

A structural view onto disease-linked mutations in the human neutral amino acid exchanger ASCT1

The ASCT1 transporter of the SLC1 family is largely involved in equilibration of neutral amino acids’ pools across the plasma membrane and plays a prominent role in the transport of both L- and D-isomers of serine, essential for the normal functioning of the central nervous system in mammals. A number of mutations in ASCT1 (E256K, G381R, R457W) have been linked to severe neurodevelopmental disorders, however in the absence of ASCT1 structure it is hard to understand their impact on substrate transport. To ameliorate that we have determined a cryo-EM structure of human ASCT1 at 4.2 Å resolution and performed functional transport assays and molecular dynamics simulations, which revealed that given mutations lead to the diminished transport capability of ASCT1 caused by instability of transporter and impeded transport cycle

The structural basis of proton driven zinc transport by ZntB

Zinc is an essential microelement to sustain all forms of life. However, excess of zinc is toxic, therefore dedicated import, export and storage proteins for tight regulation of the zinc concentration have evolved. In Enterobacteriaceae, several membrane transporters are involved in zinc homeostasis and linked to virulence. ZntB has been proposed to play a role in the export of zinc, but the transport mechanism of ZntB is poorly understood and based only on experimental characterization of its distant homologue CorA magnesium channel. Here, we report the cryo-electron microscopy structure of full-length ZntB from Escherichia coli together with the results of isothermal titration calorimetry, and radio-ligand uptake and fluorescent transport assays on ZntB reconstituted into liposomes. Our results show that ZntB mediates Zn2+ uptake, stimulated by a pH gradient across the membrane, using a transport mechanism that does not resemble the one proposed for homologous CorA channels

Інтенсифікація процесу гранулювання у вихрових апаратах псевдозрідженого шару

Сучасна вітчизняна хімічна промисловість, зокрема галузь виробництва гранульованих продуктів, стає на шлях переходу від застарілого великогабаритного обладнання до малогабаритних модернізованих апаратів, що забезпечують високу питому потужність та збереження матеріальних і енергетичних ресурсів на етапі проектування, монтажу, функціонування та ремонту. Основна мета, що постає перед проектувальниками нового обладнання – підвищення якості готового продукту та зменшення його собівартості. Одним із варіантів вирішення поставленої задачі є створення апарату для проведення процесу гранулювання, що виключає недоліки попереднього обладнання та набуває нових переваг порівняно з ним. З цією метою в лабораторних умовах кафедри «Процеси та обладнання хімічних і нафтопереробних виробництв» Сумського державного університету розроблено вихровий гранулятор псевдозрідженого шару. Роботу експериментального зразка вихрового гранулятора досліджено на експериментальній технологічній лінії виробництва гранульованих продуктів

Structural characterization of cephaeline binding to the eukaryotic ribosome using Cryo-Electron Microscopy

The eukaryotic ribosome is emerging as a promising target against human pathogens, includ- ing amoeba, protozoans, and fungi. Among the eukaryotic-specific families of inhibitors, al- kaloids are known to bind to the eukaryotic ribosome and inhibit translocation. However, these inhibitors have varying medical indications and toxicity to humans. Structural information is available for only two of them, cryptopleurine and emetine. Aim. In our work, we aimed to elucidate the binding mechanism of another alkaloid, cephaeline, to the eukaryotic ribosome. Methods. We used cryogenic electron microscopy and cell-free assays to reveal its mechanism of action. Results. Our results indicate that cephaeline binds to the E-tRNA binding site on the small subunit of the eukaryotic ribosome. Similar to emetine, cephaeline forms a stacking interaction with G889 of 18S rRNA and L132 of the protein uS11. We propose the hypothesis of cephaeline specificity to eukaryotes by comparing the interaction pattern of cephaeline with other inhibitors binding to the E-site of the mRNA tunnel. Conclusions. The high-resolution structure of ribosome-bound cephaeline (2.45 Å) allowed us to precisely determine the in- hibitor’s position in the binding site, which holds potential for the development of the next generation of drugs targeting the mRNA tunnel of the ribosome