Isotopic labeling of mammalian G protein-coupled receptors heterologously expressed in Caenorhabditis elegans

High-resolution structural determination and dynamic characterization of membrane proteins by nuclear magnetic resonance (NMR) require their isotopic labeling. Although a number of labeled eukaryotic membrane proteins have been successfully expressed in bacteria, they lack post-translational modifications and usually need to be refolded from inclusion bodies. This shortcoming of bacterial expression systems is particularly detrimental for the functional expression of G protein-coupled receptors (GPCRs), the largest family of drug targets, due to their inherent instability. In this work, we show that proteins expressed by a eukaryotic organism can be isotopically labeled and produced with a quality and quantity suitable for NMR characterization. Using our previously described expression system in Caenorhabditis elegans, we showed the feasibility of labeling proteins produced by these worms with ¹⁵N,¹³C by providing them with isotopically labeled bacteria. ²H labeling also was achieved by growing C. elegans in the presence of 70% heavy water. Bovine rhodopsin, simultaneously expressed in muscular and neuronal worm tissues, was employed as the “test” GPCR to demonstrate the viability of this approach. Although the worms’ cell cycle was slightly affected by the presence of heavy isotopes, the final protein yield and quality was appropriate for NMR structural characterization.     

Investigating macromolecules inside cultured and injected cells by in-cell NMR spectroscopy

The noninvasive character of NMR spectroscopy, combined with the sensitivity of the chemical shift, makes it ideally suited to investigate the conformation, binding events and dynamics of macromolecules inside living cells. These 'in-cell NMR' experiments involve labeling the macromolecule of interest with a nonradioactive but NMR-active isotope (15N or 13C). Cellular samples are prepared either by selectively overexpressing the protein in suitable cells (e.g., bacterial cells grown on isotopically labeled media), or by injecting isotopically labeled proteins directly into either cells or cell extracts. Here we provide detailed protocols for in-cell NMR experiments in the prokaryotic organism Escherichia coli, as well as eukaryotic cells and extracts employing Xenopus laevis oocytes or egg extracts. In-cell NMR samples with proteins overexpressed in E. coli can be produced within 13-14 h. Preparing Xenopus oocyte samples for in-cell NMR experiments takes 6-14 h depending on the oocyte preparation scheme and the injection method used.     

Zinc-mediated interaction of copper chaperones through their heavy-metal associated domains

BackgroundA copper chaperone CCS is a multi-domain protein that supplies a copper ion to Cu/Zn-superoxide dismutase (SOD1). Among the domains of CCS, the N-terminal domain (CCS^dI) belongs to a heavy metal-associated (HMA) domain, in which a Cys-x-x-Cys (CxxC) motif binds a heavy metal ion. It has hence been expected that the HMA domain in CCS has a role in the metal trafficking; however, the CxxC motif in the domain is dispensable for supplying a copper ion to SOD1, leaving an open question on roles of CCS^dI in CCS.MethodsTo evaluate protein-protein interactions of CCS through CCS^dI, yeast two-hybrid assay, a pull-down assay using recombinant proteins, and the analysis with fluorescence resonance energy transfer were performed.ResultsWe found that CCS specifically interacted with another copper chaperone HAH1, a HMA domain protein, through CCS^dI. The interaction between CCS^dI and HAH1 was not involved in the copper supply from CCS to SOD1 but was mediated by a zinc ion ligated with Cys residues of the CxxC motifs in CCS^dI and HAH1.ConclusionWhile physiological significance of the interaction between copper chaperones awaits further investigation, we propose that CCS^dI would have a role in the metal-mediated interaction with other proteins including heterologous copper chaperones.     

Dictyostelium discoideum as Expression Host: Isotopic Labeling of a Recombinant Glycoprotein for NMR Studies

The advantages of the organism Dictyostelium discoideum as an expression host for recombinant glycoproteins have been exploited for the production of an isotopically labeled cell surface protein for NMR structure studies. Growth medium containing [¹⁵N]NH₄Cl and [¹³C]glycerol was used to generate isotopically labeled Escherichia coli, which was subsequently introduced to D. discoideum cells in simple Mes buffer. A variety of growth conditions were screened to establish minimal amounts of nitrogen and carbon metabolites for a cost-effective protocol. Following single-step purification by anion-exchange chromatography, 8 mg of uniformly ¹³C,¹⁵N-labeled protein secreted by approximately 10¹⁰D. discoideum cells was isolated from 3.3 liters of supernatant. Mass spectrometry showed the recombinant protein of 16 kDa to have incorporated greater than 99.9% isotopic label. The two-dimensional ¹H-¹³C HSQC spectrum confirms ¹³C labeling of both glycan and amino acid residues of the glycoprotein. All heteronuclear NMR spectra showed a good dispersion of cross-peaks essential for high-quality structure determination.     

Yeast-expressed human membrane protein aquaporin-1 yields excellent resolution of solid-state MAS NMR spectra

One of the biggest challenges in solid-state NMR studies of membrane proteins is to obtain a homogeneous natively folded sample giving high spectral resolution sufficient for structural studies. Eukaryotic membrane proteins are especially difficult and expensive targets in this respect. Methylotrophic yeast Pichia pastoris is a reliable producer of eukaryotic membrane proteins for crystallography and a promising economical source of isotopically labeled proteins for NMR. We show that eukaryotic membrane protein human aquaporin 1 can be doubly (¹³C/¹⁵N) isotopically labeled in this system and functionally reconstituted into phospholipids, giving excellent resolution of solid-state magic angle spinning NMR spectra.     

Stable isotope labeling of glycoprotein expressed in silkworms using immunoglobulin G as a test molecule

Silkworms serve as promising bioreactors for the production of recombinant proteins, including glycoproteins and membrane proteins, for structural and functional protein analyses. However, lack of methodology for stable isotope labeling has been a major deterrent to using this expression system for nuclear magnetic resonance (NMR) structural biology. Here we developed a metabolic isotope labeling technique using commercially available silkworm larvae. The fifth instar larvae were infected with baculoviruses for co-expression of recombinant human immunoglobulin G (IgG) as a test molecule, with calnexin as a chaperone. They were subsequently reared on an artificial diet containing ¹⁵N-labeled yeast crude protein extract. We harvested 0.1 mg of IgG from larva with a ¹⁵N-enrichment ratio of approximately 80 %. This allowed us to compare NMR spectral data of the Fc fragment cleaved from the silkworm-produced IgG with those of an authentic Fc glycoprotein derived from mammalian cells. Therefore, we successfully demonstrated that our method enables production of isotopically labeled glycoproteins for NMR studies.     

Enhancing the sensitivity of multidimensional NMR experiments by using triply-compensated π pulses

An improved expression protocol is proposed for amino acid type-specific [¹³C], [¹⁵N]-isotope labeling of proteins in baculovirus-infected (BV) insect cell cultures. This new protocol modifies the methods published by Gossert et al. (J Biomol NMR 51(4):449–456, 2011) and provides efficient incorporation of isotopically labeled amino acids, with similar yields per L versus unlabeled expression in rich media. Gossert et al. identified the presence of unlabeled amino acids in the yeastolate of the growth medium as a major limitation in isotope labeling using BV-infected insect cells. By reducing the amount of yeastolate in the growth medium ten-fold, a significant improvement in labeling efficiency was demonstrated, while maintaining good protein expression yield. We report an alternate approach to improve isotope labeling efficiency using BV-infected insect cells namely by replacing the yeast extracts in the medium with dialyzed yeast extracts to reduce the amount of low molecular weight peptides and amino acids. We report the residual levels of amino acids in various media formulations and the amino acid consumption during fermentation, as determined by NMR. While direct replacement of yeastolate with dialyzed yeastolate delivered moderately lower isotope labeling efficiencies compared to the use of ten-fold diluted undialized yeastolate, we show that the use of dialyzed yeastolate combined with a ten-fold dilution delivered enhanced isotope labeling efficiency and at least a comparable level of protein expression yield, all at a scale which economizes use of these costly reagents.     

NMR resonance assignments for sparsely <Superscript>15</Superscript>N labeled proteins

For larger proteins, and proteins not amenable to expression in bacterial hosts, it is difficult to deduce structures using NMR methods based on uniform ¹³C, ¹⁵N isotopic labeling and observation of just nuclear Overhauser effects (NOEs). In these cases, sparse labeling with selected ¹⁵N enriched amino acids and extraction of a wider variety of backbone-centered structural constraints is providing an alternate approach. A limitation, however, is the absence of resonance assignment strategies that work without uniform ¹⁵N, ¹³C labeling or preparation of numerous samples labeled with pairs of isotopically labeled amino acids. In this paper an approach applicable to a single sample prepared with sparse ¹⁵N labeling in selected amino acids is presented. It relies on correlation of amide proton exchange rates, measured from data on the intact protein and on digested and sequenced peptides. Application is illustrated using the carbohydrate binding protein, Galectin-3. Limitations and future applications are discussed.     

An efficient and cost-effective isotope labeling protocol for proteins expressed in shape Escherichia coli

A cost-effective protocol for uniform ¹⁵N and/or¹³ C isotope labeling of bacterially expressed proteins is presented. Unlike most standard protocols, cells are initially grown in a medium containing nutrients at natural abundance and isotopically labeled nutrients are only supplied at the later stages of growth and during protein expression. This permits the accumulation of a large cell mass without the need to employ expensive isotopically labeled nutrients. The abrupt decrease in oxygen consumption that occurs upon complete exhaustion of essential nutrients is used to precisely time the switch between unlabeled and labeled nutrients. Application of the protocol is demonstrated for wild-type and a mutant of the N-terminal zinc-binding domain of HIV-1 integrase.     

On the use of <Emphasis Type="Italic">Pichia pastoris</Emphasis> for isotopic labeling of human GPCRs for NMR studies

NMR studies of human integral membrane proteins provide unique opportunities to probe structure and dynamics at specific locations and on multiple timescales, often with significant implications for disease mechanism and drug development. Since membrane proteins such as G protein-coupled receptors (GPCRs) are highly dynamic and regulated by ligands or other perturbations, NMR methods are potentially well suited to answer basic functional questions (such as addressing the biophysical basis of ligand efficacy) as well as guiding applications (such as novel ligand design). However, such studies on eukaryotic membrane proteins have often been limited by the inability to incorporate optimal isotopic labels for NMR methods developed for large protein/lipid complexes, including methyl TROSY. We review the different expression systems for production of isotopically labeled membrane proteins and highlight the use of the yeast Pichia pastoris to achieve perdeuteration and ¹³C methyl probe incorporation within isoleucine sidechains. We further illustrate the use of this method for labeling of several biomedically significant GPCRs.     

Isotope labeling strategies for NMR studies of RNA

The known biological functions of RNA have expanded in recent years and now include gene regulation, maintenance of sub-cellular structure, and catalysis, in addition to propagation of genetic information. As for proteins, RNA function is tightly correlated with structure. Unlike proteins, structural information for larger, biologically functional RNAs is relatively limited. NMR signal degeneracy, relaxation problems, and a paucity of long-range ¹H–¹H dipolar contacts have limited the utility of traditional NMR approaches. Selective isotope labeling, including nucleotide-specific and segmental labeling strategies, may provide the best opportunities for obtaining structural information by NMR. Here we review methods that have been developed for preparing and purifying isotopically labeled RNAs, as well as NMR strategies that have been employed for signal assignment and structure determination.     

Bcl-2 small hairpin RNAs enhance radiation-induced apoptosis in A549 cells

Bcl-2, a prominent member of the family of proteins, is responsible for dys-regulation of apoptosis and resistance to chemotherapy and radiotherapy. This study investigated whether small hairpin RNA (shRNA) targeting Bcl-2 could render A549 cells more susceptible to gamma radiation-induced apoptosis. Recombinant Bcl-2 shRNAs expression vector were transfected into A549 cells with Lipofectamine 2000. Transfected cells were screened in 800 mg/ml G418 screening medium, and after stable transfection, silencing was examined. Expression of the Bcl-2 protein was assayed using Western blot in A549 cells. Inhibition of cell growth was assessed by a MTT assay. Apoptosis was determined by morphological observation and flow cytometry. Expression levels of Bcl-2 protein from A549 cells decreased after stable transfection with Bcl-2 shRNAs. No differences in Bcl-2 protein levels between control shRNA group and untreated cells were noted. After stable transfection with Bcl-2 shRNAs the viability of cells was less than after stable transfection with those with control shRNAs and untransfected A549, respectively (P<0.05). Control shRNA had no significant effect on growth of cells. Radiation significantly inhibited the growth of cells stably transfected with Bcl-2 shRNA (P<0.05). No difference in survival between the cells with control shRNA and untransfected cells was noted. Using Giemsa staining, cells stably transfected with Bcl-2 shRNA combined with radiation at 48 h displayed changes of apoptosis. After treatment with radiation apoptotic rates of the A549 cells stably transfected with Bcl-2 shRNA significantly increased (P<0.05), compared with the cells with control shRNA and untransfected cells. shRNAs against the Bcl-2 mRNA increases radiation-induced apoptosis in A549 cells.     

Mammalian production of an isotopically enriched outer domain of the HIV-1 gp120 glycoprotein for NMR spectroscopy

NMR spectroscopic characterization of the structure or the dynamics of proteins generally requires the production of samples isotopically enriched in ¹⁵N, ¹³C, or ²H. The bacterial expression systems currently in use to obtain isotopic enrichment, however, cannot produce a number of eukaryotic proteins, especially those that require post-translational modifications such as N-linked glycosylation for proper folding or activity. Here, we report the use of an adenovirus vector-based mammalian expression system to produce isotopically enriched ¹⁵N or ¹⁵N/¹³C samples of an outer domain variant of the HIV-1 gp120 envelope glycoprotein with 15 sites of N-linked glycosylation. Yields for the ¹⁵N- and ¹⁵N/¹³C-labeled gp120s after affinity chromatography were 45 and 44 mg/l, respectively, with an average of over 80% isotope incorporation. Recognition of the labeled gp120 by cognate antibodies that recognize complex epitopes showed affinities comparable to the unlabeled protein. NMR spectra, including ¹H-¹⁵N and ¹H-¹³C HSQCs, ¹⁵N-edited NOESY-HSQC, and 3D HNCO, were of high quality, with signal-to-noise consistent with an efficient level of isotope incorporation, and with chemical shift dispersion indicative of a well-folded protein. The exceptional protein yields, good isotope incorporation, and ability to obtain well-folded post-translationally modified proteins make this mammalian system attractive for the production of isotopically enriched eukaryotic proteins for NMR spectroscopy.     

Abstracts: Albany 2005, The 14th Conversation

Abstract

We report a cost efficient approach for amino-acid-type selective isotope labeling of proteins expressed in Leishmania tarentolae. The method provides an economically advantageous alternative to recently established protocol for isotopic labeling using expensive synthetic media. The method is based on cultivation of the L. tarentolae expression strain in a cheap complex medium supplemented with labeled amino acid(s). In this protocol, a labeled amino acid is deliberately diluted in the medium of undefined composition, which leads to a low-level isotope enrichment upon protein over-expression. The economic advantage of the protocol is achieved by avoiding large volumes of expensive synthetic medium. Decreased sensitivity of a NMR experiment due to low-level isotope enrichment is compensated by a five- to seven-fold increase of the yield of the recombinant protein in complex medium as compared to that in the synthetic medium. In addition, the decreased sensitivity can be compensated by using a higher magnetic field, cryo-detection system or higher number of transients during the NMR data acquisition. We show that enrichment as low as 5% does not compromise a NMR experiment and makes preparation of the recombinant proteins over- expressed in L. tarentolae economically viable. The method is demonstrated by selective labeling of the ～27 kDa enhanced green fluorescent protein (EGFP) with ¹⁵N-labeled valine.     

Biosynthetic site-specific <Superscript>13</Superscript> C labeling of the light-harvesting 2 protein complex: A model for solid state NMR structure determination of transmembrane proteins

Partly biosynthetic site-directed isotopically ¹³C enriched photosynthetic light-harvesting 2(LH2) complexes have been prepared from Rhodopseudomonas acidophila strain 10050 by using chemically labeled [1,2,3,4–¹³C], [1,4–¹³C] and [2,3–¹³C] succinic acid as a precursor in the growth medium. Two-dimensional proton driven spin diffusion (PDSD) solid state NMR correlation spectroscopy has been used to trace each individual ¹³C isotope from the labeled succinic acid precursor to its destination into the protein and into the embedded major light-absorbing bacteriochlorophyll cofactors. For both the residues of the protein and for the cofactors distinct labeling patterns have been deduced, for protein complexes prepared from [1,4–¹³C]-succinic acid or [2,3–¹³C]-succinic labeled media. All residues, except isoleucine and leucine, have been labeled almost homogeneously by the succinic acid precursor. Carbonyl carbons in the protein backbone were labeled by [1,4–¹³C]-succinic acid, while the C and C carbons of the residues were labeled by [2,3 ¹³C]-succinic acid. Leucine and isoleucine residues were labeled using a uniformly labeled amino acid mixture in the medium. The pattern labeling yields an increase of the resolution and less spectral crowding. The partial labeling technique in combination with conventional solid state NMR methods at ultra high magnetic fields provides an attractive route to resolve chemical shifts for -helical transmembrane protein structures.     

受体酪氨酸激酶Axl对胶质母细胞瘤细胞增殖、凋亡和侵袭的影响

摘要 目的：研究受体酪氨酸激酶Axl在胶质母细胞瘤组织和细胞系U-118MG细胞中的表达情况及其对U-118MG细胞增殖、凋亡、侵袭的影响。方法：收集2015年3月至2018年5月在本院进行手术切除并经病理分型证实的胶质母细胞瘤组织标本（n=30）,另取脑外伤手术中因作内减压而切除的正常脑组织作为对照（n=28）。采用荧光实时定量 (qRT-PCR)检测正常脑组织和胶质母细胞瘤肿瘤组织中Axl mRNA表达水平;采用Western blot检测人小神经胶质HM细胞、U-118MG细胞以及Axl-shRNA转染后U-118MG细胞中Axl蛋白表达水平;采用CCK-8检测Axl-shRNA转染后U-118MG细胞增殖能力;采用流式细胞术检测Axl-shRNA转染后U-118MG细胞凋亡水平;采用Transwell小室实验检测Axl-shRNA转染后U-118MG细胞的侵袭能力。结果：在胶质母细胞瘤组织中Axl mRNA表达水平显著高于正常脑组织（P<0.05）;U-118MG细胞Axl蛋白表达水平显著高于人小神经胶质细胞系HM细胞,差异有统计学意义（P<0.05）;转染Axl-shRNA后,U-118MG细胞中Axl蛋白表达水平显著降低（P<0.05）。与U-118MG细胞和转染control-shRNA细胞相比, 转染Axl-shRNA的U-118MG细胞增殖能力降低（P<0.05）,凋亡水平升高（P<0.05）,侵袭能力降低（P<0.05）。结论：在胶质母细胞瘤组织和U-118MG细胞中,Axl表达水平显著增高,并且Axl表达水平与U-118MG细胞增殖、凋亡及侵袭密切关联。     

Rapid,robotic, small‐scale protein production for NMR screening and structure determination

Three‐dimensional protein structure determination is a costly process due in part to the low success rate within groups of potential targets. Conventional validation methods eliminate the vast majority of proteins from further consideration through a time‐consuming succession of screens for expression, solubility, purification, and folding. False negatives at each stage incur unwarranted reductions in the overall success rate. We developed a semi‐automated protocol for isotopically‐labeled protein production using the Maxwell‐16, a commercially available bench top robot, that allows for single‐step target screening by 2D NMR. In the span of a week, one person can express, purify, and screen 48 different ¹⁵N‐labeled proteins, accelerating the validation process by more than 10‐fold. The yield from a single channel of the Maxwell‐16 is sufficient for acquisition of a high‐quality 2D ¹H‐¹⁵N‐HSQC spectrum using a 3‐mm sample cell and 5‐mm cryogenic NMR probe. Maxwell‐16 screening of a control group of proteins reproduced previous validation results from conventional small‐scale expression screening and large‐scale production approaches currently employed by our structural genomics pipeline. Analysis of 18 new protein constructs identified two potential structure targets that included the second PDZ domain of human Par‐3. To further demonstrate the broad utility of this production strategy, we solved the PDZ2 NMR structure using [U‐¹⁵N,¹³C] protein prepared using the Maxwell‐16. This novel semi‐automated protein production protocol reduces the time and cost associated with NMR structure determination by eliminating unnecessary screening and scale‐up steps.     

Intein-based biosynthetic incorporation of unlabeled protein tags into isotopically labeled proteins for NMR studies

Segmental isotopic labeling of proteins using protein ligation is a recently established in vitro method for incorporating isotopes into one domain or region of a protein to reduce the complexity of NMR spectra, thereby facilitating the NMR analysis of larger proteins. Here we demonstrate that segmental isotopic labeling of proteins can be conveniently achieved in Escherichia coli using intein-based protein ligation. Our method is based on a dual expression system that allows sequential expression of two precursor fragments in media enriched with different isotopes. Using this in vivo approach, unlabeled protein tags can be incorporated into isotopically labeled target proteins to improve protein stability and solubility for study by solution NMR spectroscopy.