Occupancy of a C2-C2 type 'zinc-finger' protein domain by copper. Direct observation by electrospray ionization mass spectrometry

Disruption of zinc (II) binding and dimeric protein structure of the XIAP-RING domain by copper (I) ions

Modulation of metalloprotein structure and function via metal ion substitution may constitute a molecular basis for metal ion toxicity and/or metal-mediated functional control. The X-linked Inhibitor of Apoptosis Protein (XIAP) is a metalloprotein that requires zinc for proper structure and function. In addition to its role as a modulator of apoptosis, XIAP has been implicated in copper homeostasis. Given the similar coordination preferences of copper and zinc, investigation of XIAP structure and function upon interaction with copper is relevant. The Really Interesting New Gene (RING) domain of XIAP is representative of a class of zinc finger proteins that utilize a bi-nuclear zinc-binding motif to maintain proper structure and ubiquitin ligase function. Herein, we report the characterization of copper (I) binding to the Zn₂-RING domain of XIAP. Electronic absorption studies that monitor copper-thiolate interactions demonstrate that the RING domain of XIAP binds 5-6 Cu(I) ions and that copper is thermodynamically preferred relative to zinc. Repetition of the experiments in the presence of the Zn(II)-specific dye Mag-Fura2 shows that Cu(I) addition results in Zn(II) ejection from the protein, even in the presence of glutathione. Loss of dimeric structure of the RING domain, which is a requirement for its ubiquitin ligase activity, upon copper substitution at the zinc-binding sites, was readily observed via size exclusion chromatography. These results provide a molecular basis for the modulation of RING function by copper and add to the growing body of literature that describe the impact of Cu(I) on zinc metalloprotein structure and function.

Cu(I) Disrupts the Structure and Function of the Nonclassical Zinc Finger Protein Tristetraprolin (TTP)

Tristetraprolin (TTP) is a nonclassical zinc finger (ZF) protein that plays a key role in regulating inflammatory response. TTP regulates cytokines at the mRNA level by binding to AU-rich sequences present at the 3'-untranslated region, forming a complex that is then degraded. TTP contains two conserved CCCH domains with the sequence CysX₈CysX₅CysX₃His that are activated to bind RNA when zinc is coordinated. During inflammation, copper levels are elevated, which is associated with increased inflammatory response. A potential target for Cu(I) during inflammation is TTP. To determine whether Cu(I) binds to TTP and how Cu(I) can affect TTP/RNA binding, two TTP constructs were prepared. One construct contained just the first CCCH domain (TTP-1D) and serves as a peptide model for a CCCH domain; the second construct contains both CCCH domains (TTP-2D) and is functional (binds RNA) when Zn(II) is coordinated. Cu(I) binding to TTP-1D was assessed via electronic absorption spectroscopy titrations, and Cu(I) binding to TTP-2D was assessed via both absorption spectroscopy and a spin filter/inductively coupled plasma mass spectrometry (ICP-MS) assay. Cu(I) binds to TTP-1D with a 1:1 stoichiometry and to TTP-2D with a 3:1 stoichiometry. The CD spectrum of Cu(I)-TTP-2D did not exhibit any secondary structure, matching that of apo-TTP-2D, while Zn(II)-TTP-2D exhibited a secondary structure. Measurement of RNA binding via fluorescence anisotropy revealed that Cu(I)-TTP-2D does not bind to the TTP-2D RNA target sequence UUUAUUUAUUU with any measurable affinity, while Zn(II)-TTP-2D binds to this site with nanomolar affinity. Similarly, addition of Cu(I) to the Zn(II)-TTP-2D/RNA complex resulted in inhibition of RNA binding. Together, these data indicate that, while Cu(I) binds to TTP-2D, it does not result in a folded or functional protein and that Cu(I) inhibits Zn(II)-TTP-2D/RNA binding.

Elevated copper impairs hepatic nuclear receptor function in Wilson's disease

Wilson's disease (WD) is an autosomal recessive disorder that results in accumulation of copper in the liver as a consequence of mutations in the gene encoding the copper-transporting P-type ATPase (ATP7B). WD is a chronic liver disorder, and individuals with the disease present with a variety of complications, including steatosis, cholestasis, cirrhosis, and liver failure. Similar to patients with WD, Atp7b⁻/⁻ mice have markedly elevated levels of hepatic copper and liver pathology. Previous studies have demonstrated that replacement of zinc in the DNA-binding domain of the estrogen receptor (ER) with copper disrupts specific binding to DNA response elements. Here, we found decreased binding of the nuclear receptors FXR, RXR, HNF4α, and LRH-1 to promoter response elements and decreased mRNA expression of nuclear receptor target genes in Atp7b⁻/⁻ mice, as well as in adult and pediatric WD patients. Excessive hepatic copper has been described in progressive familial cholestasis (PFIC), and we found that similar to individuals with WD, patients with PFIC2 or PFIC3 who have clinically elevated hepatic copper levels exhibit impaired nuclear receptor activity. Together, these data demonstrate that copper-mediated nuclear receptor dysfunction disrupts liver function in WD and potentially in other disorders associated with increased hepatic copper levels.

Specific labeling of zinc finger proteins using noncanonical amino acids and copper-free click chemistry

Zinc finger proteins (ZFPs) play a key role in transcriptional regulation and serve as invaluable tools for gene modification and genetic engineering. Development of efficient strategies for labeling metalloproteins such as ZFPs is essential for understanding and controlling biological processes. In this work, we engineered ZFPs containing cysteine-histidine (Cys2-His2) motifs by metabolic incorporation of the unnatural amino acid azidohomoalanine (AHA), followed by specific protein labeling via click chemistry. We show that cyclooctyne promoted [3 + 2] dipolar cycloaddition with azides, known as copper-free click chemistry, provides rapid and specific labeling of ZFPs at high yields as determined by mass spectrometry analysis. We observe that the DNA-binding activity of ZFPs labeled by conventional copper-mediated click chemistry was completely abolished, whereas ZFPs labeled by copper-free click chemistry retain their sequence-specific DNA-binding activity under native conditions, as determined by electrophoretic mobility shift assays, protein microarrays, and kinetic binding assays based on Förster resonance energy transfer (FRET). Our work provides a general framework to label metalloproteins such as ZFPs by metabolic incorporation of unnatural amino acids followed by copper-free click chemistry.

A systems approach implicates nuclear receptor targeting in the Atp7b(-/-) mouse model of Wilson's disease

Wilson's disease (WD) is an inherited disorder of copper metabolism characterized by liver disease and/or neurologic and psychiatric pathology. The disease is a result of mutation in ATP7B, which encodes the ATP7B copper transporting ATPase. Loss of copper transport function by ATP7B results in copper accumulation primarily in the liver, but also in other organs including the brain. Studies in the Atp7b(-/-) mouse model of WD revealed specific transcript and metabolic changes that precede development of liver pathology, most notably downregulation of transcripts in the cholesterol biosynthetic pathway. In order to gain insight into the molecular mechanisms of transcriptomic and metabolic changes, we used a systems approach analysing the pre-symptomatic hepatic nuclear proteome and liver metabolites. We found that ligand-activated nuclear receptors FXR/NR1H4 and GR/NR3C1 and nuclear receptor interacting partners are less abundant in Atp7b(-/-) hepatocyte nuclei, while DNA repair machinery and the nucleus-localized glutathione peroxidase, SelH, are more abundant. Analysis of metabolites revealed an increase in polyol sugar alcohols, indicating a change in osmotic potential that precedes hepatocyte swelling observed later in disease. This work is the first application of quantitative Multidimensional Protein Identification Technology (MuDPIT) to a model of WD to investigate protein-level mechanisms of WD pathology. The systems approach using "shotgun" proteomics and metabolomics in the context of previous transcriptomic data reveals molecular-level mechanisms of WD development and facilitates targeted analysis of hepatocellular copper toxicity.

Gold ion-angiotensin peptide interaction by mass spectrometry

Stimulated by the interest in developing gold compounds for treating cancer, gold ion-angiotensin peptide interactions are investigated by mass spectrometry. Under the experimental conditions used, the majority of gold ion-angiotensin peptide complexes contain gold in the oxidation states I and III. Both ESI-MS and MALDI-TOF MS detect singly/multiply charged ions for mononuclear/multinuclear gold-attached peptides, which are represented as [peptide + a Au(I) + b Au(III) + (e - a -3b) H](e+), where a,b ≥ 0 and e is charge. ESI-MS data shows singly/multiply charged ions of Au(I)-peptide and Au(III)-peptide complexes. This study reveals that MALDI-TOF MS mainly detects singly charged Au(I)-peptide complexes, presumably due to the ionization process. The electrons in the MALDI plume seem to efficiently reduce Au(III) to Au(I). MALDI also tends to enhance the higher polymeric forms of gold-peptide complexes regardless of the laser power used. Collision-induced dissociation experiments of the mononuclear and dinuclear gold-attached peptide ions for angiotensin peptides show that the gold ion (a soft acid) binding sites are in the vicinity of Cys (a soft ligand), His (a major anchor of peptide for metal ion chelation), and the basic residue Arg. Data also suggests that the abundance of gold-attached peptides increases with higher gold concentration until saturation, after which an increase in gold ion concentration leads to the aggregation and/or precipitation of gold-bound peptides.

Structural and thermodynamic consequences of the replacement of zinc with environmental metals on estrogen receptor α-DNA interactions

Estrogen receptor α (ERα) acts as a transcription factor by virtue of the ability of its DNA-binding (DB) domain, comprised of a tandem pair of zinc fingers, to recognize the estrogen response element within the promoters of target genes. Herein, using an array of biophysical methods, we probe the structural consequences of the replacement of zinc within the DB domain of ERα with various environmental metals and their effects on the thermodynamics of binding to DNA. Our data reveal that whereas the DB domain reconstituted with divalent ions of zinc, cadmium, mercury, and cobalt binds to DNA with affinities in the nanomolar range, divalent ions of barium, copper, iron, lead, manganese, nickel, and tin are unable to regenerate DB domain with DNA-binding potential, although they can compete with zinc for coordinating the cysteine ligands within the zinc fingers. We also show that the metal-free DB domain is a homodimer in solution and that the binding of various metals only results in subtle secondary and tertiary structural changes, implying that metal coordination may only be essential for binding to DNA. Collectively, our findings provide mechanistic insights into how environmental metals may modulate the physiological function of a key nuclear receptor involved in mediating a plethora of cellular functions central to human health and disease.

Elevated copper remodels hepatic RNA processing machinery in the mouse model of Wilson's disease

Copper is essential to mammalian physiology, and its homeostasis is tightly regulated. In humans, genetic defects in copper excretion result in copper overload and Wilson's disease (WD). Previous studies on the mouse model for WD (Atp7b(-)(/-)) revealed copper accumulation in hepatic nuclei and specific changes in mRNA profile prior to the onset of pathology. To find a molecular link between nuclear copper elevation and changes in hepatic transcriptome, we utilized quantitative ionomic and proteomic approaches. X-ray fluorescence and inductively coupled plasma mass spectrometry analysis indicate that copper in the Atp7b(-/-) nucleus, while highly elevated, does not markedly alter nuclear ion content. Widespread protein oxidation is also not observed, although the glutathione reductase SelH is upregulated, likely to maintain redox balance. We further demonstrate that accumulating copper affects the abundance and/or modification of a distinct subset of nuclear proteins. These proteins populate pathways that are most significantly associated with RNA processing. An alteration in splicing pattern was observed for hnRNP A2/B1, itself the RNA shuttling factor and spliceosome component. Analysis of hnRNP A2/B1 mRNA and protein revealed an increased retention of exon 2 and a selective 2-fold upregulation of a corresponding protein splice variant. Mass spectrometry measurements suggest that the nucleocytoplasmic distribution of RNA binding proteins, including hnRNP A2/B1, is altered in the Atp7b(-/-) liver. We conclude that remodeling of the RNA processing machinery is an important component of cell response to elevated copper that may guide pathology development in the early stages of WD.

Nonspecific protein-carbohydrate complexes produced by nanoelectrospray ionization. Factors influencing their formation and stability

Factors influencing the formation of nonspecific protein-carbohydrate complexes during the nanoelectrospray (nanoES) process have been investigated. Protonated and deprotonated nonspecific complexes of ubiquitin (Ubq) and protonated complexes of carbonic anhydrase (CA) with carbohydrates, ranging in size from mono- to tetrasaccharide, were produced by nanoES and detected with a Fourier transform ion cyclotron resonance mass spectrometer. Both the fraction of protein engaged in nonspecific binding with the carbohydrates and the number of carbohydrates bound to the protein increase with increasing carbohydrate concentration. At a given concentration of protein and carbohydrate, nonspecific binding is favored for small (mono- and disaccharide) or hydrophilic carbohydrates over larger or more hydrophobic molecules, which tend to form gaseous monomer or cluster ions by nanoES. However, the extent of nonspecific binding is insensitive to the structure of the protein, with similar distributions of nonspecific complexes observed for both CA and Ubq. Nonspecific association is also insensitive to the charge state of the complex. A comparable degree of binding is observed for complexes in their protonated and deprotonated forms. Furthermore, the number of bound ligands can exceed significantly the charge state of the complex. Thermal dissociation experiments performed on the gaseous nonspecific complexes reveal that their kinetic stability is sensitive to both the structure of the carbohydrate (i.e., mono- < di- < tri- < tetrasaccharide) and the protein (Ubq < CA) and to the charge state, although no simple relationship between stability and charge state was identified. Taken together, the results of this study suggest that neutral protein-carbohydrate interactions (e.g., hydrogen bonds) contribute significantly and, perhaps, predominantly to the formation and stabilization of the nonspecific complexes. A strategy to minimize the formation of the nonspecific complexes, which is based on the enhancement of gaseous carbohydrate ion formation through the addition of metal salts (e.g., CaCl2) to the nanoES solution, is demonstrated.

Cys redox reactions and metal binding of a Cys2His2 zinc finger

The elucidation of mechanisms by which cysteine (Cys) redox reactions influence metal binding to zinc finger domains is important for understanding the structure and function of zinc fingers. The present studies utilize electrospray ionization mass spectrometry (ESI-MS) to analyze Cys redox reactions and their influence on metal ion binding to a synthetic polypeptide similar in motif to the third zinc finger of the RNA polymerase II transcription factor, Sp1 (Sp1-3). The differential specificity of metal binding events to this zinc finger domain is demonstrated over a range of redox-altering dithiothreitol, hydrogen peroxide, and hydrogen ion concentrations. By analyzing this Cys2His2 zinc finger domain at single Da resolution with ESI-MS, shifts in the natural isotope cluster demonstrate that a Cys thiol and thiolate can contribute to Zn2+ and other metal ion coordination. These experiments provide insight into the basic redox chemistry and metal binding mechanisms of Cys2His2 zinc finger domains.

The metal binding properties of the CCCH motif of the 50S ribosomal protein L36 from Thermus thermophilus

The TthL36 protein of the 50S ribosomal proteins from Thermus thermophilus has been found to contain the rare C(Xaa)2C(Xaa)12C(Xaa)4H (CCCH) sequence motif, a zinc finger binding motif, which for other zinc finger proteins is known to cleave RNA hairpins. In order to investigate the metal-binding properties of this T. thermophilus TthL36 protein, the core 26-mer polypeptide containing this CCCH motif was prepared by solid-phase peptide synthesis methods using Fmoc chemistry, purified by preparative RP-HPLC and characterized by circular dichroism, high-performance capillary zone electrophoresis and electrospray ionization mass spectrometry. Reaction of the acetamidomethyl (Acm)-protected polypeptide with iodine under acidic conditions resulted in the formation of the fully de-protected polypeptide. Of interest, the results demonstrate that the standard Acm-deprotection method with the synthetic TthL36 polypeptide using mercuric acetate in the presence of a large excess of 2-mercaptoethanol resulted in preferential formation of a very stable mercuro-polypeptide complex. The properties of the Acm-deprotected polypeptide in the presence of different metal ions were also investigated by spectroscopic methods. The results confirm that this TthL36 polypeptide containing the CCCH motif binds metal ions with different affinities, namely in the order Co(II)>Hg(II)>Zn(II).

Direct characterisation by electrospray ionisation mass spectroscopy of mercuro-polypeptide complexes after deprotection of acetamidomethyl groups from protected cysteine residues of synthetic polypeptides

In this paper, we describe a rapid procedure to characterise the products generated in the presence of mercuric salts following removal of the acetamidomethyl (Acm)-protecting group from cysteine residues of synthetic polypeptides prepared by solid-phase peptide synthesis (SPPS) methods. In particular, electrospray ionisation mass spectrometry (ESI-MS) procedures have been employed to characterise the mercuro-polypeptide products related to the ribosomal L36 protein isolated from the bacterium Thermus thermophilus. The results demonstrate that very stable mercuro-polypeptide complexes can form under standard conditions of deprotection involving Hg(2+) salts in the presence of a reductant such as beta-mercaptoethanol. Metal ion exchange effects involving other divalent metal ions, such as Co(2+) or Zn(2+), can also be monitored by similar procedures, thus permitting the relative affinity and selectivity for metal ion-polypeptide interactions to be qualitatively assessed. Since the Thermus thermophilus ribosomal L36 protein contains a putative zinc finger binding CCCH motif, these procedures enable the formation of metal-ion complexes of synthetic polypeptides related to this structural motif to be directly examined.

Preferential oxidation of zinc finger 2 in estrogen receptor DNA-binding domain prevents dimerization and, hence, DNA binding

For approximately one-third of estrogen receptor (ER)-positive breast cancer patients, extracted tumor ER is unable to bind to its cognate DNA estrogen response element (ERE), an effect that is partly reversible by the thiol-reducing agent dithiothreitol (DTT). Full-length (67 kDa) ER or its 11 kDa recombinant DNA-binding domain (ER-DBD) is also susceptible to loss of structure and function by the action of oxidants such as diamide and hydrogen peroxide; however, prior DNA binding by ER or ER-DBD protects against this oxidant induced loss of function. The ER-DBD contains two (Cys)(4)-liganded zinc finger motifs that cooperate to stabilize a rigid DNA-binding recognition helix and a flexible helix-supported dimerization loop, respectively. Comparisons between synthetic peptide analogues of each zinc finger and recombinant ER-DBD in the presence of zinc by electrophoretic mobility shift assay, circular dichroism, and mass spectrometry confirm that cooperativity between these zinc fingers is required for both ER-DBD structure (alpha-helicity) and function (dimeric DNA binding). Rapid proteolytic digestion of monomeric, non-DNA-bound ER-DBD followed by HPLC-MS analysis of the resulting peptides demonstrates that zinc inhibits thiol oxidation of the DNA-binding finger, but not the finger supporting the flexible dimerization loop, which remains sensitive to internal disulfide formation. These findings indicate that the loss of ER DNA-binding function in extracts from some primary breast tumors and in ER or ER-DBD exposed to thiol-reacting oxidants results from this asymmetric zinc finger susceptibility to disulfide formation that prevents dimerization. Although ER-DBD contains several strategically located methionine residues, they are less susceptible to oxidation than the thiol groups and, thus, afford no protection against cysteine oxidation and consequent loss of ER DNA-binding function.

Electrospray mass spectrometry studies of non-heme iron-containing proteins

The oligomeric state and the metal atom stoichiometry of a series of non-heme iron-containing, multimeric proteins have been measured using electrospray ionization (ESI) in a time-of-flight (TOF) mass spectrometer. The proteins were obtained both from natural sources and by overexpression of recombinant DNA in Escherichia coli. ESI-TOF mass spectra of the metalloproteins present in nondenaturing solutions exhibit peaks corresponding to the multimeric forms of the holoproteins containing the expected number of metal atoms. Capillary-skimmer dissociation of the holoproteins produces a series of ions, which allows an exact count of the number of metal atoms present in each subunit, and also provides an indication of the oxidation state of the metal atoms. Two recombinant proteins, Phascolopsis gouldii hemerythrin (Pg-Hr) and Desulfovibrio vulgaris rubrerythrin (Dv-Rr), have been examined as well as hemerythrin isolated from Lingula reevii (Lr-Hr). ESI-TOF measurements of the aqueous solution of Pg-Hr at pH 6 yields ions of mass 108,783 Da, in close agreement with the calculated average molecular mass of an intact octameric holoprotein. Capillary-skimmer dissociation of the ions of the holoprotein produces a mass spectrum that contains peaks corresponding to a low m/z monomer and a high m/z heptamer. The masses of the monomer ions produced in this manner are assigned to the aposubunit, [subunit + Fe - 3H]+, and [subunit + 2Fe - 6 H]+. Naturally occurring Lr-Hr is composed of two subunits with average molecular masses measured under denaturing conditions by ESI-TOF to be 13,877.0 Da for the alpha-subunit and 13,517.5 Da for the beta-subunit. Under nondenaturing conditions, a multimeric species with a molecular weight of 110,663 Da is measured by ESI-TOF, corresponding to an alpha 4 beta 4 octamer. Capillary-skimmer dissociation of the alpha 4 beta 4 oligomer produces ions corresponding to both types of monomers (alpha and beta) and the corresponding heptamers (alpha 3 beta 4 and alpha 4 beta 3). In ESI-TOF measurements of recombinant rubrerythrin Dv-Rr using nondenaturing conditions, the principal ion observed corresponds to a homotetramer with an average molecular mass of 86,844 Da. Capillary-skimmer dissociation of the rubrerythrin tetramer leads to formation of a series of peaks corresponding to the subunit of the apoprotein and to subunits containing from one to three specifically bound iron atoms.

On-line HPLC-electrospray ionization mass spectrometry: a pharmacological tool for identifying and studying the stability of Gd3+ complexes used as magnetic resonance imaging contrast agents

The identification of MRI contrast agents (CAg) as gadolinium complexes often used at very low concentrations in Pharmacology was carried out by ESI-MS or HPLC-ESI-MS. Firstly, Omniscan, Dotarem and Magnevist were tested. In these compounds, the Gd3+ ion must be solidly chelated by linear or macrocyclic ligands because of the severe toxicity of the free Gd3+. Spectra were obtained at low voltage, preserving the non-covalent binding integrity of the complexes, and at various higher voltages showing the progressive destruction of the complexes. Secondly, a direct reaction of these drugs with the oxidative human neutrophil production, induced in vitro by Phorbol 12-myristate 13-acetate enhancing the respiratory burst, was investigated. This was done to mimic what happens in the case of inflammatory diseases, or infection, or when people are likely to develop anaphylactoid reactions, as the i.v. injection of CAg causes contact between the complexes and neutrophils in the blood. Analysis by HPLC-ESI-MS coupling did not show any direct reaction between Gd complexes and the chemical compounds in the neutrophil oxidative metabolism, even if uncertainty remains as regards meglumine salt. HPLC-ESI-MS is a good way of visualizing characteristic, Gd isotopic distribution and of following its associations in biological samples.

Zinc binding properties of the DNA binding domain of the 1,25-dihydroxyvitamin D3 receptor

To assess the zinc binding stoichiometry and the structural changes induced upon the binding of zinc to the human vitamin D receptor (VDR), we expressed the DNA binding domain (DBD) of the human VDR in bacteria as a soluble glutathione-S-transferase fusion protein at 20 degrees C, and examined the apo-protein and metal-liganded protein by mass spectrometry, and circular dichroism and nuclear magnetic resonance spectroscopy. Following final preparation with a zinc-free buffer, the VDR DBD bound 2 mol of zinc/mol of protein as measured by inductively coupled plasma-mass spectrometry and electrospray ionization-mass spectrometry. When protein preparation was carried out in a zinc containing buffer and zinc content of the protein was assesed by the same methods, VDR DBD bound 4 mol of zinc/mol of protein. Analysis of the protein using circular dichroism spectroscopy demonstrated that the EDTA-treated protein increased in alpha-helical content from 16 to 27% on the addition of zinc. Equilibrium ultracentrifugal analyses of the VDR DBD indicated that the protein was present in solution as a monomer. Gel mobility shift analyses of the VDR DBD with several vitamin D response elements (VDREs) in the absence of accessory proteins such as retinoic acid receptor, showed that VDR DBD was able to form a protein/VDRE DNA structural complex. In the presence of zinc, proton NMR NOESY spectra showed that the protein possessed elements of secondary structure. The addition of VDRE DNA, but not random DNA, caused changes in the proton NMR spectra of VDRE DNA indicating specific interaction between protein and DNA groups. We conclude that the DBD of the VDR binds zinc and DNA and undergoes conformational changes on binding to the metal and DNA.

Copper-binding motifs in catalysis, transport, detoxification and signaling

Copper is required for many biological processes but is toxic at high cellular concentrations, so levels in the cell must be strictly controlled. Copper-binding motifs have been identified and characterized in many proteins. The way in which copper is coordinated by these motifs is important for the transport and distribution of intracellular copper and for the effective functioning of copper-dependent enzymes.

Studying noncovalent protein complexes by electrospray ionization mass spectrometry

Electrospray ionization mass spectrometry has been used to study protein interactions driven by noncovalent forces. The gentleness of the electrospray ionization process allows intact protein complexes to be directly detected by mass spectrometry. Evidence from the growing body of literature suggests that the ESI-MS observations for these weakly bound systems reflect, to some extent, the nature of the interaction found in the condensed phase. Stoichiometry of the complex can be easily obtained from the resulting mass spectrum because the molecular weight of the complex is directly measured. For the study of protein interactions, ESI-MS is complementary to other biophysical methods, such as NMR and analytical ultracentrifugation. However, mass spectrometry offers advantages in speed and sensitivity. The experimental variables that play a role in the outcome of ESI-MS studies of noncovalently bound complexes are reviewed. Several applications of ESI-MS are discussed, including protein interactions with metal ions and nucleic acids and subunit protein structures (quaternary structure).

The cytoplasmic domain of alphaIIb beta3. A ternary complex of the integrin alpha and beta subunits and a divalent cation

Peptides corresponding to the cytoplasmic tails of the alphaIIb (alphaIIb (985-1008)) and beta3 (beta3 (713-762)) subunits of the integrin receptor alphaIIb beta3 (glycoprotein IIb-IIIa) were synthesized and used to characterize their interaction with cations and with one another. alphaIIb (985-1008) was found to contain a functional cation binding site as assessed by both terbium luminescence and electrospray ionization mass spectroscopy. The binding of Tb3+ to alphaIIb (985-1008) was of high affinity (Kd = 8.8 +/- 5.2 nM), occurred with a 1:1 stoichiometry, and was mediated by its acidic carboxy] terminus (alphaIIb (999-1008), PLEEDDEEGE). The affinity of this site for divalent cations was in the micromolar range, suggesting that this site would be constitutively occupied in the intracellular environment. Incubation of alphaIIb (999-1008) with beta3 (713-762) resulted in the formation of a complex, both in the presence and absence of cations. The interactive site for alphaIIb (999-1008) in beta3 was mapped to beta3 (721-740), and complex formation was associated with a stabilization of secondary structure as assessed by circular dichroism. Both a binary (alphaIIb (985-1008).beta3 (721-740)) and a ternary (Tb3+.alphaIIIb (999-1008).beta3 (721-740)) complex were detected by mass spectroscopy, but the distribution and intensity of the mass/charge peaks were distinct. These difference may reflect the involvement of distinct cation coordination sites and the formation of salt bridges in stabilizing the ternary complex. These data demonstrate the formation of a novel entity composed of the cytoplasmic tails of alphaIIb and beta3 and a cation which may constitute a functional intracellular domain.

Toxic metal-responsive gene transcription

Metals play a dual role in biological systems, serving as essential co-factors for a wide range of biochemical reactions yet these same metals may be extremely toxic to cells. To cope with the stress of increases in environmental metal concentrations, eukaryotic cells have developed sophisticated toxic metal sensing proteins which respond to elevations in metal concentrations. This signal is transmitted to stimulate the cellular transcriptional machinery to activate expression of metal detoxification and homeostasis genes. This review summarizes our current understanding of the biochemical and genetic mechanisms which underlie cellular responses to toxic metals via metalloregulatory transcription factors.

Study of noncovalent enzyme-inhibitor complexes and metal binding stoichiometry of matrilysin by electrospray ionization mass spectrometry

Electrospray ionization mass spectrometry (ESI-MS) was used to study the noncovalent metallo-enzyme-inhibitor complexes of matrilysin (a matrix metalloproteinase of mass 18,720 u) under gentle experimental conditions and to determine the metal ion association stoichiometries in both the free enzyme and the complexes. The metal association stoichiometries of the free matrilysin were found to be highly sensitive to solution pH changes. At pH 2.2 the enzyme existed as metal-free apo-matrilysin and was not capable of binding an inhibitor. At pH 4.5-7.0 the enzyme associated specifically with zinc and calcium cations and became active in inhibitor binding. Although the stoichiometries of the metal cofactors varied (zero to two zinc and/or calcium ions) in the free enzyme dependent on solution pH, the predominant form of the enzyme-inhibitor complexes in the pH range of 4.5-7.0, in contrast, always had the metal association stoichiometry of 2Zn + 2Ca, which was the same stoichiometry the most active free metallo-enzyme had at the optimal pH of 7. At the activity onset pH of 4.5 matrilysin existed mostly as apo-enzyme (but in a conformation different from the denatured one at pH 2.2) and bound to an inhibitor slowly (time constant ∼ 2.5 min) to form the noncovalent metallo-enzyme-inhibitor complex. Of the two inhibitors studied, the one with the higher solution binding constant also produced larger ion signals for the noncovalent complex in the solvent-free gas phase, which pointed to the feasibility of the use of ESI-MS for inhibitor screening studies.

An electrospray ionization mass spectrometry study of copper adducts of protonated ubiquitin

A study of the addition of Cu(II) to a ubiquitin electrospray solution shows that the copper ion in the ubiquitin remains doubly charged and displaces two protons on the protonated protein molecule. This observation indicates a chelating bond between the protein and the Cu(II) species. The addition of Cu(I) also was studied and significant intensity was observed for adducts with up to four Cu(I) species attached, with each Cu(I) bonded to one basic site on the protein.

Identification and analysis of a Saccharomyces cerevisiae copper homeostasis gene encoding a homeodomain protein

Yeast metallothionein, encoded by the CUP1 gene, and its copper-dependent transcriptional activator ACE1 play a key role in mediating copper resistance in Saccharomyces cerevisiae. Using an ethyl methanesulfonate mutant of a yeast strain in which CUP1 and ACE1 were deleted, we isolated a gene, designated CUP9, which permits yeast cells to grow at high concentrations of environmental copper, most notably when lactate is the sole carbon source. Disruption of CUP9, which is located on chromosome XVI, caused a loss of copper resistance in strains which possessed CUP1 and ACE1, as well as in the cup1 ace1 deletion strain. Measurement of intracellular copper levels of the wild-type and cup9-1 mutant demonstrated that total intracellular copper concentrations were unaffected by CUP9. CUP9 mRNA levels were, however, down regulated by copper when yeast cells were grown with glucose but not with lactate or glycerol-ethanol as the sole carbon source. This down regulation was independent of the copper metalloregulatory transcription factor ACE1. The DNA sequence of CUP9 predicts an open reading frame of 306 amino acids in which a 55-amino-acid sequence showed 47% identity with the homeobox domain of the human proto-oncogene PBX1, suggesting that CUP9 is a DNA-binding protein which regulates the expression of important copper homeostatic genes.

Identification and analysis of a Saccharomyces cerevisiae copper homeostasis gene encoding a homeodomain protein

Yeast metallothionein, encoded by the CUP1 gene, and its copper-dependent transcriptional activator ACE1 play a key role in mediating copper resistance in Saccharomyces cerevisiae. Using an ethyl methanesulfonate mutant of a yeast strain in which CUP1 and ACE1 were deleted, we isolated a gene, designated CUP9, which permits yeast cells to grow at high concentrations of environmental copper, most notably when lactate is the sole carbon source. Disruption of CUP9, which is located on chromosome XVI, caused a loss of copper resistance in strains which possessed CUP1 and ACE1, as well as in the cup1 ace1 deletion strain. Measurement of intracellular copper levels of the wild-type and cup9-1 mutant demonstrated that total intracellular copper concentrations were unaffected by CUP9. CUP9 mRNA levels were, however, down regulated by copper when yeast cells were grown with glucose but not with lactate or glycerol-ethanol as the sole carbon source. This down regulation was independent of the copper metalloregulatory transcription factor ACE1. The DNA sequence of CUP9 predicts an open reading frame of 306 amino acids in which a 55-amino-acid sequence showed 47% identity with the homeobox domain of the human proto-oncogene PBX1, suggesting that CUP9 is a DNA-binding protein which regulates the expression of important copper homeostatic genes.

Ligand and cation binding are dual functions of a discrete segment of the integrin beta 3 subunit: cation displacement is involved in ligand binding

The alpha IIb beta 3 integrin binds Arg-Gly-Asp-containing (RGD-containing) ligands in a cation-dependent interaction. A fourteen amino acid sequence, beta 3 (118-131), and an antibody to it, inhibited ligand binding functions of alpha IIb beta 3, and a 1:1 stoichiometric beta 3 (118-131)-RGD complex was detected by mass spectroscopy. Cation binding to beta 3 (118-131) was demonstrated by terbium luminescence and mass spectroscopy. Notably, ligand displaced cation from the beta 3(118-131) peptide and also from purified alpha IIb beta 3. Thus, beta 3 (118-131), a highly conserved region in integrin beta subunits, binds both ligand and cation. Formation of a ternary complex between cation, ligand, and receptor, with subsequent displacement of cation from beta 3 (118-131) and a second site within the receptor, may be central to the mechanism of ligand recognition by integrins.

Analysis, by electrospray ionization mass spectrometry, of several forms of Clostridium pasteurianum rubredoxin

Clostridium pasteurianum rubredoxin and its recombinant counterpart purified from Escherichia coli have been analysed by electrospray ionization m.s. (e.s.i.m.s.). Whereas the N-terminal methionine of the native protein is formylated, the recombinant one has a free N-terminal methionine. E. coli cells also produce a colourless protein from the cloned gene. This protein is absent from C. pasteurianum and was shown to be zinc-substituted rubredoxin. The molecular forms of rubredoxin detected by e.s.i.m.s. depended on the experimental conditions used. Significant conversion into apo-rubredoxin occurred when the proteins were ionized at acidic pH and detected in the positive-ion mode. This conversion was quantitative in the case of Zn-rubredoxin. In contrast, when the proteins were analysed at neutral pH in the negative-ion mode, only the holoproteins, i.e. the species initially present in the solutions, were detected in the spectra. The e.s.i.m.s. experimental conditions set up here may prove useful for the analysis of other acidic metalloproteins with weakly bound metals.

Characterisation of a novel cysteine/histidine-rich metal binding domain from Xenopus nuclear factor XNF7

A 42 amino acid synthetic peptide corresponding to a newly defined cysteine/histidine-rich protein motif called B-box, from the Xenopus protein XNF7 has been characterised. The metal-binding stoichiometry and dissociation constant for zinc were determined by competition with the chromophoric chelator Br2BAPTA, demonstrating that one zinc atom binds per molecule of peptide despite the presence of seven putative metal ligands, and represents the first application of this method to measuring zinc stoichiometry of proteins and/or peptides. Cobalt binding studies indicate that the motif binds zinc more tightly than cobalt, that cysteines are used as ligands and that the cation is co-ordinated tetrahedrally. Circular dichroism and NMR studies both indicate that the B-box peptide is structured only in the presence of zinc, copper and to a lesser extent cobalt.

Mass spectrometry of proteins and peptides in biotechnology

Recent technological developments in the field of mass spectrometry have resulted in enhanced performance in traditional biotechnological applications and are opening up new approaches to a wide range of problems in protein analysis. Developments in the area of interfacing mass spectrometry with high-resolution separation techniques and the observation of non-covalent interactions and protein conformational changes by mass spectrometry represent notable advances in the past year.

Mass spectrometric analysis of proteins

The past year has seen greatly increased acceptance and application of the analytical capabilities of mass spectrometry by the biochemical community. The technique has been used to provide accurate mass determinations of non-covalently bound protein complexes, rapid mapping of molecular weights of altered peptides in protease digests, sequencing by collisional activation in tandem mass spectrometry, characterization of glycosylation and other modifications, and quantitation of peptides used in clinical diagnostics.