A method for parallel microscale protein labeling and precise control over the average degree of labeling (aDoL).

A widely used approach for protein conjugation is through the lysine residues reacting with NHS- or other active esters. However, it is a challenge to precisely control the degree of labeling (DoL) due to the instability of active ester and variability of reaction efficiencies. Here, we provide a protocol for better control of aDoL using existing Copper-free Click Chemistry reagents. It is a two-step reaction with one purification in between. Briefly, proteins of interest were first activated with azide-NHS. After removing unreacted azide-NHS, the protein-N3 is then reacted with a limited amount of complementary click tag. Our studies have shown the click tag will fully react with the protein-N3 after 24 h' incubation, and therefore does not require additional purification steps. As such, the aDoL is equal to the input molar ratio of the click tag and the protein. Furthermore, this approach offers a much simpler and more economical way to perform parallel microscale labeling. Once a protein is pre-activated with N3-NHS, any fluorophore or molecule with the complementary click tag can be attached to the protein by mixing the two ingredients. Quantities of the protein used in the click reaction can be at any desired amount. In one example, we labeled an antibody in parallel with 9 different fluorophores using a total of 0.5 mg of antibody. In another example, we labeled Ab with targeted aDoL value from 2 to 8. In a stability comparison study, we have found the conjugated fluorophore using the suggested click protocol stayed attached to the protein longer than with standard NHS-fluorophore labeling.

Epifluorescent single-molecule counting with Streptavidin-Phycoerythrin conjugates.

Single-molecule methods, specifically single-molecule counting, convey high sensitivity in research applications. However, single-molecule counting experiments require specialized equipment or consumables to perform. We demonstrate the utility of using bright Streptavidin-Phycoerythrin (SA-PE) conjugates and an epifluorescence microscope, for single-molecule counting applications. In this work, we show that we can visualize single-molecules on glass surfaces, perform single-molecule diagnostic assays on magnetic microparticles, and image individual foci on cell surfaces. This approach is simple and effective for researchers interested in single-molecule counting.

Affinity of anti-spike antibodies to three major SARS-CoV-2 variants in recipients of three major vaccines.

Background: Measuring anti-viral antibody affinity in blood plasma or serum is a rational quantitative approach to assess humoral immune response and acquired protection. Three common vaccines against SARS-CoV-2-Comirnaty developed by Pfizer/BioNTech, Spikevax developed by Moderna/NIAID, and Jcovden (previously Janssen COVID-19 Vaccine) developed by Johnson & Johnson/Janssen (J&J)-induce antibodies to a variety of immunogenic epitopes including the epitopes located in the ACE2 receptor-binding domain (RBD) of the spike protein. Blocking RBD with antibodies interferes with the binding of the virus to ACE2 thus protecting against infection. Methods: We perform measurements in the serum of the recipients of Pfizer, Moderna, and J&J vaccines, and we compare the apparent affinities of vaccine-induced antibodies against the RBD of the ancestral SARS-CoV-2 virus and the Delta and Omicron variants. We use our recently published method to determine the apparent affinity of anti-spike protein antibodies directly in human serum. This involves probing antibody-antigen equilibria with a small number of antigen-coated magnetic microparticles and imaging them on a fluorescence microscope. Results: Recipients of two-dose Pfizer and Moderna vaccines, as well as recipients of the single-dose J&J vaccine, develop high-affinity antibodies toward RBD derived from ancestral SARS-CoV-2. Affinities of these antibodies to Delta-RBD are approximately 10 times weaker, and even more drastically reduced (∼1000-fold) toward Omicron-RBD. Conclusions: Vaccine-induced antibodies against ancestral SARS-CoV-2 RBD demonstrate ~10-fold and ~1000-fold weaker affinities toward Delta- and Omicron-RBD, respectively. Our approach offers a direct means for evaluating vaccine-induced adaptive immunity and can be helpful in designing or updating vaccines.

Affinity of anti-spike antibodies in SARS-CoV-2 patient plasma and its effect on COVID-19 antibody assays.

BACKGROUND: Measuring anti-spike protein antibodies in human plasma or serum is commonly used to determine prior exposure to SARS-CoV-2 infection and to assess the anti-viral protection capacity. According to the mass-action law, a lesser concentration of tightly binding antibody can produce the same quantity of antibody-antigen complexes as higher concentrations of lower affinity antibody. Thus, measurements of antibody levels reflect both affinity and concentration. These two fundamental parameters cannot be disentangled in clinical immunoassays, and so produce a bias which depends on the assay format. METHODS: To determine the apparent affinity of anti-spike protein antibodies, a small number of antigen-coated magnetic microparticles were imaged by fluorescence microscopy after probing antigen-antibody equilibria directly in patient plasma. Direct and indirect anti-SARS-CoV-2 immunoassays were used to measure antibody levels in the blood of infected and immunised individuals. FINDINGS: We observed affinity maturation of antibodies in convalescent and vaccinated individuals, showing that higher affinities are achieved much faster by vaccination. We demonstrate that direct and indirect immunoassays for measuring anti-spike protein antibodies depend differently on antibody affinity which, in turn, affects accurate interpretation of the results. INTERPRETATION: Direct immunoassays show substantial antibody affinity dependence. This makes them useful for identifying past SARS-CoV-2 exposure. Indirect immunoassays provide more accurate quantifications of anti-viral antibody levels. FUNDING: The authors are all full-time employees of Abbott Laboratories. Abbott Laboratories provided all operating funds. No external funding sources were used in this study.

Direct single-molecule imaging for diagnostic and blood screening assays.

Every year, over 100 million units of donated blood undergo mandatory screening for HIV, hepatitis B, hepatitis C, and syphilis worldwide. Often, donated blood is also screened for human T cell leukemia-lymphoma virus, Chagas, dengue, Babesia, cytomegalovirus, malaria, and other infections. Several billion diagnostic tests are performed annually around the world to measure more than 400 biomarkers for cardiac, cancer, infectious, and other diseases. Considering such volumes, every improvement in assay performance and/or throughput has a major impact. Here, we show that medically relevant assay sensitivities and specificities can be fundamentally improved by direct single-molecule imaging using regular epifluorescence microscopes. In current microparticle-based assays, an ensemble of bound signal-generating molecules is measured as a whole. By contrast, we acquire intensity profiles to identify and then count individual fluorescent complexes bound to targets on antibody-coated microparticles. This increases the signal-to-noise ratio and provides better discrimination over nonspecific effects. It brings the detection sensitivity down to the attomolar (10-18 M) for model assay systems and to the low femtomolar (10-16 M) for measuring analyte in human plasma. Transitioning from counting single-molecule peaks to averaging pixel intensities at higher analyte concentrations enables a continuous linear response from 10-18 to 10-5 M. Additionally, our assays are insensitive to microparticle number and volume variations during the binding reaction, eliminating the main source of uncertainties in standard assays. Altogether, these features allow for increased assay sensitivity, wide linear detection ranges, shorter incubation times, simpler assay protocols, and minimal reagent consumption.

Direct single-molecule counting for immunoassay applications.

Single-molecule methods offer specificity in studying complex systems and dynamics, but they also offer high sensitivity for basic enumeration. We apply single-molecule TIRF to immunoassays by counting the number of target molecules captured on a streptavidin surface. We demonstrate the utility of using single-molecule counting on eluted detection conjugate, following the capture and sandwich formation portions of the assay having been completed on microparticles. This approach is simple and effective, and creates the opportunity for a universal detection platform that can be used to perform a variety of diagnostic and blood screening assays. We take advantage of the low volume requirements of single-molecule detection and apply a sample reloading approach to concentrate sample onto the detection surface. Due to the high affinity of the streptavidin-biotin reaction, concentration through reloading is both quick and robust. These findings are demonstrated on a model system and in an HIV p24 antigen assay. Single-molecule detection techniques do not need to be complex to exhibit power and flexibility, and so can become valuable in the field of immunoassay diagnostics.

Characterization of Fluorescently Labeled Protein with Electrospray Ionization-MS and Fluorescence Spectroscopy: How Random is Random Labeling?

Solvent exposed lysine residues are abundantly present in many proteins. Their highly reactive ε-amino groups serve as universal targets for coupling with active esters of various extrinsic labels including a vast arsenal of fluorescent probes. Here, we describe fluorescent properties and preferential localization of two frequently used fluorescent labels, AlexaFluor488 (AF488) and Cy3, on the surface of a small highly soluble serum protein neutrophil gelatinase-associated lipocalin (NGAL), which serves as a diagnostic marker for acute kidney failure. Using a standard protocol for labeling with either AF488-SDP or AF488-NHS, we achieved >95% labeling efficiency of the protein as determined by UV-vis absorption and electrospray ionization (ESI)-MS. However, fluorescence intensity of the labeled protein was less than 10% of the expected value. To understand the unusually high quenching of the probe, we identified the sites of AF488 attachments by means of LC-MS/MS combined with trypsin digestion. Surprisingly, we found that the AF488 label is not randomly distributed among accessible lysines but predominantly bound to the residues K125, K126, or K135, which are located in the NGAL calyx and are likely quenched by neighboring tryptophans and tyrosines. In contrast, when NGAL was labeled with Cy3, the probe's fluorescence was almost fully retained. The LC-MS/MS data indicated that Cy3 was predominately bound to another lysine, K31, on the protein surface on the opposite side of the calyx. Our findings suggest that a combination of the inherent properties of the label and the specifics of the protein microenvironment may selectively lead probes to specific lysine residues and thus challenge the common view that protein labeling is a random process.

Rhodamine-Derived Fluorescent Dye with Inherent Blinking Behavior for Super-Resolution Imaging.

Super-resolution microscopy enables imaging of structures smaller than the diffraction limit. Single-molecule localization microscopy methods, such as photoactivation localization microscopy and stochastic optical reconstruction microscopy, reconstruct images by plotting the centroids of fluorescent point sources from a series of frames in which only a few molecules are fluorescing at a time. These approaches require simpler instrumentation than methods that depend on structured illumination and thus are becoming widespread. The functionalized rhodamine derivative reported in this paper spontaneously converts between a bright and dark state due to pH-dependent cyclization. At pH 7, less than 0.5% of the dye molecules are fluorescent at any given time. Blinking occurs on time scales of seconds to minutes and can therefore be used for single-molecule localization microscopy without sample treatment or activation. The dye is bright and straightforward to use, and it is easy to synthesize and functionalize. Thus, it has potential to become a new and powerful addition to the toolset for super-resolution imaging.

The photostability of the commonly used biotin-4-fluorescein probe.

Biotin-4-fluorescein (B4F) is a commonly used fluorescent probe for studying biotin-(strept)avidin interactions. During a characterization study of an anti-biotin antibody, using B4F as the probe, we noticed a discrepancy in the expected and experimentally determined number of biotin binding sites. Analytical testing showed that the biotin moiety in the probe undergoes a photosensitized oxidation to produce a mixture of biotin sulfoxides which has the potential to impact the quantitation of binding sites using this fluorescent probe.

Affinity assisted selection of antibodies for Point of Care TSH immunoassay with limited wash.

BACKGROUND: Molecular binding characteristics of several thyroid stimulating hormone (TSH) antibodies were determined for the TSH antigen, along with its closely related endogenous interfering hormones, follicle stimulating hormone (FSH), luteinizing hormone (LH) and chorionic gonadotropin (CG). METHODS: This data was compared to the same antibodies used in the low wash sandwich ELISA immunoassay system, the Point of Care i-STAT® immunoassay. From this information we developed binding criteria useful in the low wash i-STAT® immunoassay to permit good signal generation from TSH and low cross-reactivity from its interfering hormones. For the TSH Assay we have developed characteristics that enable antibody selection in the i-STAT® immunoassay cartridge. Our antibody screening approach used a dot blot approach as a first screen to select for the most useful antibodies. We then compared a FRET (Förster Resonance Energy Transfer) and electrochemical cartridge approach to determine the appropriate antibody combinations. RESULTS: Both methods generated similar data, but the FRET method was not capable of differentiating the antibody with the best characteristics as a capture antibody or a detection conjugate in a sandwich ELISA assay. Finally, we performed binding characterizations of the antibodies using each of the above mentioned glycoproteins. CONCLUSIONS: We found that we need sub-picomolar detection of TSH, and at least 100 fold or higher values for the cross-reacting species.

Water channel in the binding site of a high affinity anti-methotrexate antibody.

In the present study, we report the structure of the free and drug-bound Fab fragment of a high affinity anti-methotrexate antibody and perform a thermodynamic analysis of the binding process. The anti-methotrexate Fab fragment features a remarkably rigid tunnel-like binding site that extends into a water channel serving as a specialized route to move solvent out and into the site upon ligand binding and dissociation. This new finding in antibody structure-function relationships directly relates to the fast association (1 × 107 M⁻¹ s⁻¹) and slow dissociation (4 × 10⁻5 s⁻¹) rates determined for mAb ADD056, resulting in a very strong binding with a K(D) ~ 3.6 pM at 20 °C. As follows from the X-ray data analysis, the methotrexate-antibody complex is stabilized by an extended network of hydrogen bonds and stacking interactions. The analysis also shows structural involvement of the CDR H3 in formation of the water channel revealing another important role of this hypervariable region. This suggests a new direction in natural affinity maturation and opens a new possibility in antibody engineering. Methotrexate is a widely used therapeutic agent for many malignant diseases and inflammatory disorders. Unfortunately, it may also interfere with central aspects of metabolism and thereby cause inevitable side effects. Therefore, methotrexate therapy requires careful monitoring of drug blood levels, which is traditionally done by immunoassays. An understanding of the structure-function properties of antibodies selected for drug monitoring substantiates the performance and robustness of such tests.

Simplified confocal microscope for counting particles at low concentrations.

We describe a compact scanning confocal fluorescence microscope capable of detecting particles concentrations less than 100 particles∕ml in ~15 min. The system mechanically moves a cuvette containing ~3 ml of sample. A relatively large confocal volume is observed within the cuvette using a 1 mm pinhole in front of a detection PMT. Due to the motion of the sample, particles traverse the confocal volume quickly, and analysis by pattern recognition qualifies spikes in the emission intensity data and counts them as events. We show linearity of detection as a function of concentration and also characterize statistical behavior of the instrument. We calculate a detection sensitivity of the system using 3 µm fluorescent microspheres to be 5 particles/ml. Furthermore, to demonstrate biological application, we performed a dilution series to quantify stained E. coli and yeast cells. We counted E. coli cells at a concentration as low as 30 cells∕ml in 10 min/sample.

Supporting immunoassay design with biophysical tools.

In this article, we demonstrate how the application of biophysical tools facilitates the design of robust immunoassays. The binding characteristics of the reagents used in an immunoassay determine the assay response to the analyte concentrations. We applied several biophysical methods to obtain pertinent equilibrium and kinetic coefficients and used this information in the design of a microparticle-based immunoassay for detection of neutrophil gelatinase-associated lipocalin (NGAL), which is a new diagnostic marker of acute kidney injury (AKI). We characterized the conformational stability of recombinant human NGAL and the solution phase binding properties of six monoclonal antibodies. A preferred antibody pair was selected on the basis of the affinities of the antibodies and their sandwich pairing capabilities. One of the antibodies was coated on magnetic microparticles, and the second antibody was conjugated with a reporter group. The apparent kinetic rates of the immobilized and conjugated antibodies were measured and used to compute the assay calibration plot for the target concentration range of the analyte at specific incubation times. The experimental assay results were found to be in good agreement with the computed data, confirming that applying biophysical tools provides a solid foundation for immunoassay design and optimization.

Studying antibody-antigen interactions with fluorescence fluctuation spectroscopy.

Antibodies are excellent binding proteins that have found numerous applications in biological research, biotechnology, and medicine. Characterization of their ligand binding properties has long been, and continues to be, the focus of many researchers. Antibodies are also perfect test systems which can be used for the evaluation of newly introduced biophysical techniques. Working with many different antibodies, we continuously implement the growing arsenal of methods offered by fluorescence fluctuation spectroscopy (FFS) and apply them for antibody research. In this chapter, we will describe applications of FFS for antibody binding characterization and also provide examples how studying of antibodies helps to develop and enhance the tool set offered by FFS technology. In addition to traditional affinity evaluations, we will describe how resolving molecular populations enables determinations of the binding stoichiometry and provides further information about the system. Even though all our examples include antibodies, the same experimental procedures can also serve well for characterizing various proteins and other ligand binding systems.

Rapid determination of antigenic epitopes in human NGAL using NMR.

The recent remarkable rise in biomedical applications of antibodies and their recombinant constructs has shifted the interest in determination of antigenic epitopes in target proteins from the areas of protein science and molecular immunology to the vast fields of modern biotechnology. In this article, we demonstrated that measuring binding induced changes in two-dimensional NMR spectra enables rapid determination of antibody binding footprints on target protein antigens. Such epitopes recognized by six high-affinity monoclonal murine antibodies (mAbs) against human neutrophil gelatinase-associated lipocalin (NGAL) were determined by measuring chemical shifts or broadening of peaks in (1)H-(15)N-TROSY HSQC and (1)H-(13)C HSQC spectra of isotope-labeled NGAL occurring upon its binding to the antibodies. Locations of the epitopes defined by the NMR studies are in good agreement with the results of antibody binding pairing observed by dual-color fluorescence cross-correlation spectroscopy. In all six cases, the antibodies recognize conformational epitopes in regions of relatively rigid structure on the protein. None of the antibodies interact with the more flexible funnel-like opening of the NGAL calyx. All determined epitope areas in NGAL reflect the dimensions of respective antibody binding surface (paratopes) and contain amino acid residues that provide strong interactions. This NMR-based approach offers comprehensive information on antigenic epitopes and can be applied to numerous protein targets of diagnostic or therapeutic interest.

Using nonfluorescent Förster resonance energy transfer acceptors in protein binding studies.

The purpose of this article is to highlight the versatility of nonfluorescent Förster resonance energy transfer (FRET) acceptors in determination of protein equilibrium dissociation constants and kinetic rates. Using a nonfluorescent acceptor eliminates the necessity to spectrally isolate the donor fluorescence when performing binding titrations covering a broad range of reagent concentrations. Moreover, random distribution of the donor and acceptor chromophores on the surface of proteins increases the probability of FRET occurring on their interaction. Three high-affinity antibodies are presented in this study as characteristic protein systems. Monoclonal antibody (mAb) 106.3 binds brain natriuretic peptide (BNP)5-13(C10A) and full-length BNP1-32 with the dissociation constants 0.26+/-0.01 and 0.05+/-0.02 nM, respectively, which was confirmed by kinetic measurements. For anti-hCG (human chorionic gonadotropin) mAb 8F11, studied at two incorporation ratios (IRs=1.9 and 3.8) of the nonfluorescent FRET acceptor, K(D) values of 0.04+/-0.02 and 0.059(-0.004)(+0.006) nM, respectively, were obtained. Likewise, the binding of goat anti-hamster immunoglobulin G (IgG) antibody was not affected by conjugation and yielded K(D) values of 1.26+/-0.04, 1.25+/-0.05, and 1.14+/-0.04 nM at IRs of 1.7, 4.7, and 8.1, respectively. We conclude that this FRET-based method offers high sensitivity, practical simplicity, and versatility in protein binding studies.

Microheterogeneous monoclonal antibody subspecies with differential hepatitis C virus core antigen binding properties identified by SEC-HPLC.

A monoclonal antibody directed against the core protein of hepatitis C virus was characterized for its utility in a sandwich antigen immunoassay wherein the mAb was used as the conjugate. Analysis of unconjugated and acridinium-conjugated monoclonal IgG using a silica-based HPLC size exclusion column revealed the existence of a single, symmetrical peak. Subsequent analysis of unconjugated IgG using a methacrylate-based HPLC size exclusion column revealed the presence of two species of IgG, but only by using a low ionic strength mobile phase buffer. Independent conjugation and testing of the two species showed significant differential reactivity towards HCV core antigen. Isoelectric focusing gels indicated subtle differences in the subspecies composition. Measurement of target peptide dissociation constants using fluorescence correlation spectroscopy indicated that the two HPLC column fractions exhibited a two-fold difference in Kd in low salt buffer that disappeared in high salt buffer. ESI-MS analysis of the fractionated IgG peaks revealed a reduction sensitive modification of the IgG and F(ab')2 of approximately 674 Da. In addition, both IgG and F(ab')2 contained two major heavy chain subspecies differing by about 1216 Da that was reduction insensitive. These modifications were present in only the one of the two SEC-HPLC peaks. These results suggest that this monoclonal antibody consists of microheterogeneous subspecies that exhibit different antigen binding properties associated with differences in post-translational modification of the heavy chain variable region. The choice of size exclusion column matrix and buffer composition was critical to the identification of these monoclonal IgG subspecies.

Multiprobe spectroscopic investigation of molecular-level behavior within aqueous 1-butyl-3-methylimidazolium tetrafluoroborate.

In this work, an array of molecular-level solvent features--including solute--solvent/solvent--solvent interactions, dipolarity, heterogeneity, dynamics, probe accessibility, and diffusion--were investigated across the entire composition of ambient mixtures containing the ionic liquid 1-butyl-3-methylimidazolium tetrafluoroborate, [bmim][BF4], and pH 7.0 phosphate buffer, based on results assembled for nine different molecular probes utilized in a range of spectroscopic modes. These studies uncovered interesting and unusual solvatochromic probe behavior within this benchmark mixture. Solvatochromic absorbance probes--a water-soluble betaine dye (betaine dye 33), N,N-diethyl-4-nitroaniline, and 4-nitroaniline--were employed to determine ET (a blend of dipolarity/polarizability and hydrogen bond donor contributions) and the Kamlet-Taft indices pi* (dipolarity/polarizability), alpha (hydrogen bond donor acidity), and beta (hydrogen bond acceptor basicity) characterizing the [bmim][BF4] + phosphate buffer system. These parameters each showed a marked deviation from ideality, suggesting selective solvation of the individual probe solutes by [bmim][BF4]. Similar conclusions were derived from the responses of the fluorescent polarity-sensitive probes pyrene and pyrene-1-carboxaldehyde. Importantly, the fluorescent microfluidity probe 1,3-bis(1-pyrenyl)propane senses a microviscosity within the mixture that significantly exceeds expectations derived from simple interpolation of the behavior in the neat solvents. On the basis of results from this probe, a correlation between microviscosity and bulk viscosity was established; pronounced solvent-solvent hydrogen-bonding interactions were implicit in this behavior. The greatest deviation from ideal additive behavior for the probes studied herein was consistently observed to occur in the buffer-rich regime. Nitromethane-based fluorescence quenching of pyrene within the [bmim][BF4] + phosphate buffer system showed unusual compliance with a "sphere-of-action" quenching model, a further manifestation of the microheterogeneity of the system. Fluorescence correlation spectroscopic results for both small (BODIPY FL) and macromolecular (Texas Red-10 kDa dextran conjugate) diffusional probes provide additional evidence in support of microphase segregation inherent to aqueous [bmim] [BF4].

Crystal structure and thermodynamic analysis of diagnostic mAb 106.3 complexed with BNP 5-13 (C10A).

B-type natriuretic peptide (BNP) is a naturally secreted regulatory hormone that influences blood pressure and vascular water retention in human physiology. The plasma BNP concentration is a clinically recognized biomarker for various cardiovascular diseases. Quantitative detection of BNP can be achieved in immunoassays using the high-affinity monoclonal IgG1 antibody 106.3, which binds an epitope spanning residues 5-13 of the mature bioactive peptide. To understand the structural basis of this molecular recognition, we crystallized the Fab fragment complexed with the peptide epitope and determined the three-dimensional structure by X-ray diffraction to 2.1 A resolution. The structure reveals the detailed interactions that five of the complementarity-determining regions make with the partially folded peptide. Thermodynamic measurements using fluorescence spectroscopy suggest that the interaction is enthalpy driven, with an overall change in free energy of binding, DeltaG = -54 kJ/mol, at room temperature. The parameters are interpreted on the basis of the structural information. The kinetics of binding suggest a diffusion-limited mechanism, whereby the peptide easily adopts a bound conformation upon interaction with the antibody. Moreover, comparative analysis with alanine-scanning results of the epitope explains the basis of selectivity for BNP over other related natriuretic peptides.

Applications of dual-color fluorescence cross-correlation spectroscopy in antibody binding studies.

Two-photon dual-color fluorescence cross-correlation spectroscopy (DC-FCCS) was applied to study the binding interactions of monoclonal antibodies (mAbs) and protein antigens. We measured the binding constant of the interaction of a 32-amino acid brain natriuretic peptide (BNP) with a mAbs and demonstrated the utility of DC-FCCS in studies of antibody sandwiches, trimolecular formations, where two different antibodies bind the same antigen simultaneously. We also show the use of DC-FCCS for monitoring competitive displacement of the labeled antibody in antibody-antigen complexes and subsequent determination of the pertinent dissociation rate (off-rate). The off-rate measurements were performed for two mAbs toward tissue inhibitor 1 of metalloproteinases (TIMP-1). From a methodological perspective, selection of the best labeling protocols and careful optimization of the FCCS instrumentation are essential to achieve the highest cross-correlation signal. When working in vitro, it is practical to generate a complete binding curve using the normalized cross-correlation signal and then fit the experimental points to a binding model. DC-FCCS offers the sensitivity and all other advantages of a solution phase fluorescence-based technique. For systems containing proteins of a similar size that interact without substantial changes in the fluorescence intensity, DC-FCCS serves as a preferred means of measuring solution phase binding constants.