Antipeptide Immunocapture with In-Sample Calibration Curve Strategy for Sensitive and Robust LC-MS/MS Bioanalysis of Clinical Protein Biomarkers in Formalin-Fixed Paraffin-Embedded Tumor Tissues.

Despite huge promises, bioanalysis of protein biomarkers in formalin-fixed paraffin-embedded (FFPE) tissues by liquid chromatography-tandem mass spectrometry (LC-MS/MS) for clinical applications is still very challenging. Here, we describe a sensitive and robust LC-MS/MS assay to quantify clinical protein biomarkers in FFPE tumor sections using automated antipeptide antibody immunocapture followed by in-sample calibration curve (ISCC) strategy with multiple isotopologue reaction monitoring (MIRM) technique. ISCC approach with MIRM of stable isotopically labeled (SIL) peptides eliminated the need for authentic matrices for external calibration curves, overcame the matrix effects, and validated the quantification range in each individual sample. Specifically, after deparaffinization, rehydration, antigen retrieval, and homogenization, the protein analytes in FFPE tumor tissues were spiked with a known concentration of one SIL peptide for each analyte, followed by trypsin digestion and antipeptide immunocapture enrichment prior to MIRM-ISCC-based LC-MS/MS analysis. This approach has been successfully used for sensitive quantification of programmed cell death-1 (PD-1) and programmed cell death-ligand 1 (PD-L1) in 15 representative FFPE tumor samples from lung, colorectal, and head and neck cancer patients. Except for one sample, PD-L1 and PD-1 in all samples were quantifiable using this assay with concentrations of 27.85-798.43 (amol/µg protein) for PD-L1 and 16.96-129.89 (amol/µg protein) for PD-1. These results were generally in agreement with the immunohistochemistry (IHC) data but with some exceptions. This approach demonstrated the feasibility to quantify low abundant protein biomarkers in FFPE tissues with improved sensitivity, specificity, and robustness and showed great potential as an orthogonal analytical approach to IHC for clinical applications.

In-Sample Calibration Curve Using Multiple Isotopologue Reaction Monitoring of a Stable Isotopically Labeled Analyte for Instant LC-MS/MS Bioanalysis and Quantitative Proteomics.

A novel methodology of in-sample calibration curves (ISCC) using multiple isotopologue reaction monitoring (MIRM) of multiple naturally occurring isotopologue transitions of a stable isotopically labeled (SIL) analyte for instant liquid chromatography-tandem mass spectrometry (LC-MS/MS) bioanalysis of biomarkers, biotherapeutics, and small-molecule compounds is proposed and demonstrated for the first time. The theoretical isotopic abundances of the SIL analyte in its MIRM channels can be accurately calculated based on the isotopic distributions of its daughter ion and neutral loss. The isotopic abundances in these MIRM channels can also be accurately measured with a triple quadrupole mass spectrometer. By spiking a known amount of a SIL analyte into each study sample, an ISCC can be established based on the relationship between the calculated theoretical isotopic abundances (analyte concentration equivalents) in the selected MIRM channels of the SIL analyte and the measured MS/MS peak areas in the corresponding MIRM channels in each individual study sample. The analyte concentration of each study sample can then be calculated individually with the ISCC instantly without using an external calibration curve. The MIRM-ISCC-LC-MS/MS methodology was evaluated and demonstrated in this work with the examples of quantitation of a protein biomarker in human and monkey serum processed with immunocapture and trypsin digestion; three surrogate peptides in trypsin-digested human colon tissue homogenates; and a small-molecule drug in human and rat plasma extracted with liquid-liquid extraction. The potential applications of the MIRM-ISCC-LC-MS/MS methodology in quantitative proteomics, clinical laboratories, and other areas are also discussed in this paper. Without the need for using external calibration curves, this novel MIRM-ISCC-LC-MS/MS methodology can provide accurate and reliable bioanalysis in many potential applications, especially for cases where authentic matrices for external calibration curves are not available.

Eliminating Preparation of Multisample External Calibration Curves and Dilution of Study Samples Using the Multiple Isotopologue Reaction Monitoring (MIRM) Technique in Quantitative LC-MS/MS Bioanalysis.

Preparation of multisample external calibration curves and dilution of study samples are critical steps in bioanalytical sample processing for quantitative liquid chromatography-tandem mass spectrometry (LC-MS/MS) based bioanalysis of small-molecule compounds, biotherapeutics, and biomarkers, but they can be time-consuming and prone to error. It is highly desired to simplify or eliminate these two steps in order to improve the assay throughput and robustness. While multisample external calibration curve preparation using authentic matrices can be eliminated with a previously reported in-sample calibration curve (ISCC) approach using multiple isotopologue reaction monitoring (MIRM) of a stable isotopically labeled (SIL) analyte, dilution of study samples is still inevitable due to limited LC-MS/MS assay ranges. In this work, a one-sample multipoint external calibration curve and isotope sample dilution, both using MIRM of an analyte, for quantitative LC-MS/MS based bioanalysis are proposed and demonstrated. By spiking a known amount of an analyte into one blank authentic matrix sample, a one-sample multipoint external calibration curve in an authentic matrix can be established on the basis of the relationship between the calculated theoretical isotopic abundances (analyte concentration equivalents) and the MS/MS responses in the corresponding MIRM channels. This one-sample multipoint external calibration curve can be used in the same way as the traditional multisample external calibration curve for quantitative LC-MS/MS-based bioanalysis. As isotopic abundance in each MIRM channel can be calculated and measured accurately, isotope sample dilution can be achieved by simply monitoring one or a few of the MIRM channels of the analyte in addition to the most abundant MIRM channel for study samples. While the most abundant MIRM channel (isotopic abundance of 100%) is used for the quantitation of samples having concentrations within the assay calibration curve range, less abundant MIRM channels (isotopic abundance of IA%) can be used for the quantitation of samples having concentrations beyond the assay upper limit of quantitation (ULOQ), resulting in isotope dilution factors (IDF) of 100%/IA%. The approaches of one-sample multipoint external calibration curve and isotope sample dilution were evaluated and demonstrated in this work with an example of the quantitation of daclatasvir in human plasma extracted with liquid-liquid extraction. Using these approaches together with the MIRM-ISCC methodology, accurate and reliable LC-MS/MS bioanalysis can be achieved without the need of preparation of multisample external calibration curve and dilution of study samples.

Determination of Real Time in Vivo Drug Receptor Occupancy for a Covalent Binding Drug as a Clinical Pharmacodynamic Biomarker by Immunocapture-LC-MS/MS.

We report a novel immunocapture (IC)-LC-MS/MS methodology to directly measure real time in vivo receptor occupancy (RO) for a covalent binding drug in blood lysate. A small molecule quencher was added immediately after sample collection to convert the free receptor to a quencher-bound receptor (QB-R) which was measured with the drug-bound receptor (DB-R) simultaneously by LC-MS/MS after immunocapture enrichment, followed by trypsin digestion. Addition of the quencher is necessary to prevent the free receptor from ex vivo binding with the drug. The real time RO was calculated based on the concentrations of DB-R and the free receptor (which is now QB-R) that were obtained from each sample. This strategy has been successfully applied to the measurement of the RO for Bruton's tyrosine kinase (BTK) in the blood lysate of monkeys after dosing with branebrutinib (BMS-986195), a covalent BTK inhibitor being evaluated to treat rheumatoid arthritis. A custom-made quencher, which is more reactive to BTK than branebrutinib, was added in excess amount to bind with all available free BTK to form quencher-bound BTK (QB-BTK) during blood sample collection. To measure a wide range of % BTK RO, including those of <5% or >95%, the required LLOQ at 0.125 nM for QB-BTK and 0.250 nM for drug-bound BTK (DB-BTK) in blood lysate were successfully achieved by using this IC-LC-MS/MS strategy. This proof-of-concept assay demonstrated its suitability with high throughput for real time in vivo BTK RO measurement as a pharmacodynamic (PD) biomarker for clinical drug development.

Fit-for-purpose protein biomarker assay validation strategies using hybrid immunocapture-liquid chromatography-tandem-mass spectrometry platform: Quantitative analysis of total soluble cluster of differentiation 73.

In recent years, biomarkers have played more extensive roles as indicators of disease progression, safety, and drug efficacy. Targeted quantitative analysis of biomarkers including drug targets have become increasingly important to drive critical decision-making in various drug development stages, as well as to improve the success rates of clinical trials. There are many analytical challenges when developing and validating the bioanalytical methods associated with the measurement of an endogenous protein biomarker, especially when using LC-MS based analysis. Moreover, the current regulatory guidelines for assay development and validation using LC-MS platform mainly focuse on regulated bioanalysis for therapeutic drugs. In this manuscript, we use total soluble CD73 (sCD73) as an example to present a "fit-for-purpose" assay using a hybrid immunocapture-LC-MS/MS assay platform. A non-competing antibody (to the therapeutic drug) was used to isolate and enrich the total sCD73 from biological matrix. The enriched sample was digested after immunocapture and a surrogate peptide was monitored for quantification. The assay showed good accuracy, precision, specificity and sensitivity with the LLOQ of 1.00 ng/mL, and was applied in a clinical study to measure the total sCD73 as a potential pharmacodynamic (PD) marker. Some recommendations and considerations for "fit-for-purpose" validation of this assay, and hybrid LC-MS assays in general, for the quantitative analysis of an endogenous protein biomarkers is also discussed.

Development of a Chemiluminescent ELISA Method for the Detection of Total Anti-Adeno Associated Virus Serotype 9 (AAV9) Antibodies.

Recombinant adeno associated viruses (rAAV) have become an important tool for the delivery of gene therapeutics due to long-standing safety and success in clinical trials. Since humans often become exposed to AAVs and develop anti-AAV antibodies (Abs), a potential impediment to the success of gene therapeutics is neutralization of the viral particle before it has had a chance to bind and enter target cells to release the transgene. Identification of subjects with preexisting Abs having neutralizing potential, and exclusion of such subjects from clinical studies is expected to enhance drug efficacy. In vitro cell-based reporter assays are most often employed to determine the level of neutralizing antibodies in a given population. Such assays measure the ability of the Abs to prevent viral binding and entry into cells by engaging epitopes on the viral capsid involved in host cell receptor binding. In general, cell-based assays are low throughput and labor intensive and may suffer from high variability and low sensitivity issues. In contrast, enzyme-linked immunosorbent assays (ELISAs) are simpler, less variable, and have higher throughput. Demonstrating a correlation between neutralizing Abs assessed by a cell-based assay and total binding Abs measured in an ELISA will enable the use and substitution of the latter for screening and exclusion of subjects. In this work, we describe the development of a highly sensitive, specific, robust, and reproducible chemiluminescent ELISA method for the detection of total anti-AAV9 Abs. Using this method, we analyzed the prevalence of preexisting anti-AAV9 Abs in 100 serum samples from heart disease patients. Analysis of neutralizing Abs in the same samples using an in vitro cell-based assay showed a strong correlation between total anti-AAV9 Abs and neutralizing Abs, indicating the feasibility of using the total Ab ELISA in the future for patient screening and exclusion.

LC-MS/MS bioanalysis of plasma 1, 14-tetradecanedioic acid and 1, 16-hexadecanedioic acid as candidate biomarkers for organic anion-transporting polypeptide mediated drug-drug interactions.

AIM: A robust LC-MS/MS assay was developed to quantify endogenous 1, 14-tetradecanedioic acid (TDA) and 1, 16-hexadecanedioic acid (HDA) in human plasma as potential biomarkers for evaluating drug-drug interactions mediated by the hepatic drug transporters, organic anion-transporting polypeptides. RESULTS: This assay was validated using fit-for-purpose approach over standard curve range of 2.5-1000 nM for TDA and HDA using analyte-free charcoal-stripped human plasma as the surrogate matrix. Chromatographic separation condition was successfully optimized to separate TDA from an interference peak while maintaining both analytes in neutral forms to minimize carryover issue. CONCLUSION: The described assay is currently applied to a clinical study for evaluating TDA/HDA as potential substitute biomarkers for drug-drug interaction studies.

Surface plasmon resonance as a tool for ligand-binding assay reagent characterization in bioanalysis of biotherapeutics.

Ligand-binding assay (LBA) performance depends on quality reagents. Strategic reagent screening and characterization is critical to LBA development, optimization and validation. Application of advanced technologies expedites the reagent screening and assay development process. By evaluating surface plasmon resonance technology that offers high-throughput kinetic information, this article aims to provide perspectives on applying the surface plasmon resonance technology to strategic LBA critical reagent screening and characterization supported by a number of case studies from multiple biotherapeutic programs.

Characterization of labeled reagents in ligand-binding assays by a surface plasmon resonance biosensor.

AIM: Ligand-binding assay (LBA) reagent labeling may change the binding characteristics of the reagent to its target and degrade its performance in LBAs. RESULTS: A surface plasmon resonance (SPR) biosensor was used to evaluate the impact of the biotin labeling process on reagent-binding kinetics and affinity for a specific target. The SPR results demonstrate that the biotin molar challenge ratio affects both association and dissociation rates for the labeled reagent binding to its target. The SPR results also predict the labeled reagent performance in LBAs. CONCLUSION: The methodology used in this study provides an example of using an SPR biosensor as an efficient way to analytically and functionally characterize critical reagents and to understand their performance postmodification in LBAs.

A multiplexed immunocapture liquid chromatography tandem mass spectrometry assay for the simultaneous measurement of myostatin and GDF-11 in rat serum using an automated sample preparation platform.

Myostatin, also known as growth differentiation factor 8 (GDF-8), is a protein acting as a negative regulator in skeletal muscle growth. Inhibition of myostatin by therapeutic agents provides opportunities for current unmet medical needs. In order to better understand drug engagement to aid the drug development, we have developed a hybrid LC-MS/MS method which can differentially measure myostatin and another protein from the same GDF family, GDF-11. Although the two proteins share high homology, the LC-MS/MS assay provided the specificity based on monitoring of unique surrogate peptide generated from enzymatic digestion. An automated sample preparation platform, Agilent AssayMap Bravo, was used for automated immunocapture. Capture antibody that is non-competing with our investigational drug and has similar binding affinity to both myostatin and GDF-11 was used. Therefore, total myostatin and GDF-11 including both free form and drug-bound form were captured and measured. The enriched sample was digested after reduction and alkylation. Two surrogate peptides (IPAMVVDR for myostatin and IPGMVVDR for GDF-11) were monitored and the lower limit of quantitation (LLOQ) was established at 1.0 ng/mL for myostatin and 0.1 ng/mL for GDF-11. The accuracy was demonstrated with recovery for IPAMVVDR between 99.2% and 103.1% and for IPGMVVDR between 90.3% and 114.5%. The developed hybrid assay exhibits sufficient sensitivity, accuracy and specificity to differentiate between the highly structurally similar myostatin and GDF-11. This analytical approach was successfully applied to a rat toxicology study, and was demonstrated to be a powerful tool for biomarker measurement in the present of a therapeutic agent.

Overview on biotherapeutic proteins: impact on bioanalysis.

This article provides an overview of the information and factors relevant to designing bioanalytical strategies in support of in vivo nonclinical and clinical studies of protein therapeutics. The summarized information includes representative types of the therapeutic proteins, their key structural characteristics, the relationship between post-translational modifications and function, issues during purification and formulation, PK of therapeutic proteins and immunogenicity. The effect of each of those on bioanalysis strategy has been pointed out. The impacts of structural variant and 'free'/'bound' forms on PK assessment have been discussed.

Quantitation of a PEGylated protein in monkey serum by UHPLC-HRMS using a surrogate disulfide-containing peptide: A new approach to bioanalysis and in vivo stability evaluation of disulfide-rich protein therapeutics.

To quantify a therapeutic PEGylated protein in monkey serum as well as to monitor its potential in vivo instability and methionine oxidation, a novel ultra high performance liquid chromatography-high resolution mass spectrometric (UHPLC-HRMS) assay was developed using a surrogate disulfide-containing peptide, DCP(SS), and a confirmatory peptide, CP, a disulfide-free peptide. DCP(SS) was obtained by eliminating the step of reduction/alkylation before trypsin digestion. It contains an intact disulfide linkage between two peptide sequences that are essential for drug function but susceptible to potential in vivo cleavages. HRMS-based single ion monitoring (SIM) on a Q Exactive™ mass spectrometer was employed to improve assay specificity and sensitivity for DCP(SS) due to its poor fragmentation and low sensitivity with SRM detection. The assay has been validated for the protein drug in monkey serum using both surrogate peptides with excellent accuracy (within ±4.4%Dev) and precision (within 7.5%CV) with a lower limit of quantitation (LLOQ) at 10 ng mL(-1). The protein concentrations in monkey serum obtained from the DCP(SS)-based assay not only provided important pharmacokinetic parameters, but also confirmed in vivo stability of the peptide regions of interest by comparing drug concentrations with those obtained from the CP-based assay or from a ligand-binding assay (LBA). Furthermore, UHPLC-HRMS allowed simultaneous monitoring of the oxidized forms of both surrogate peptides to evaluate potential ex vivo/in vivo oxidation of one methionine present in each of both surrogate peptides. To the best of our knowledge, this is the first report of using a surrogate disulfide-containing peptide for LC-MS bioanalysis of a therapeutic protein.

Recommendations for validation of LC-MS/MS bioanalytical methods for protein biotherapeutics.

This paper represents the consensus views of a cross-section of companies and organizations from the USA and Canada regarding the validation and application of liquid chromatography tandem mass spectrometry (LC-MS/MS) methods for bioanalysis of protein biotherapeutics in regulated studies. It was prepared under the auspices of the AAPS Bioanalytical Focus Group's Protein LC-MS Bioanalysis Subteam and is intended to serve as a guide to drive harmonization of best practices within the bioanalytical community and provide regulators with an overview of current industry thinking on applying LC-MS/MS technology for protein bioanalysis. For simplicity, the scope was limited to the most common current approach in which the protein is indirectly quantified using LC-MS/MS measurement of one or more of its surrogate peptide(s) produced by proteolytic digestion. Within this context, we considered a range of sample preparation approaches from simple in-matrix protein denaturation and digestion to complex procedures involving affinity capture enrichment. Consideration was given to the method validation experiments normally associated with traditional LC-MS/MS and ligand-binding assays. Our collective experience, thus far, is that LC-MS/MS methods for protein bioanalysis require different development and validation considerations than those used for small molecules. The method development and validation plans need to be tailored to the particular assay format being established, taking into account a number of important factors: the intended use of the assay, the test species or study population, the characteristics of the protein biotherapeutic and its similarity to endogenous proteins, potential interferences, as well as the nature, quality, and availability of reference and internal standard materials.

The integration of ligand binding and LC-MS-based assays into bioanalytical strategies for protein analysis.

Both LBAs and LC-MS-based assays are reviewed and summarized for applications in quantitative protein analysis. A strategy for platform selection is proposed based on several factors that contribute to the complexities of bioanalysis of biologics. Protein types, multiple co-existing forms, post-translational modifications, and affinities to ADA, targets, and endogenous proteins need to be considered when selecting the most appropriate platform. Other factors, such as intended use of data, assay sensitivity, available reagents, and multiple analytes also impact on the choice of bioanalytical platform. At BMS, strategies for the seamless integration of both platforms are being implemented to provide not only PK/PD data of the molecules but also useful information of the amino acid structure and functional relationship of the proteins.

A generic template for automated bioanalytical ligand-binding assays using modular robotic scripts in support of discovery biotherapeutic programs.

BACKGROUND: Sample dilution and reagent pipetting are time-consuming steps in ligand-binding assays (LBAs). Traditional automation-assisted LBAs use assay-specific scripts that require labor-intensive script writing and user training. RESULTS: Five major script modules were developed on Tecan Freedom EVO liquid handling software to facilitate the automated sample preparation and LBA procedure: sample dilution, sample minimum required dilution, standard/QC minimum required dilution, standard/QC/sample addition, and reagent addition. The modular design of automation scripts allowed the users to assemble an automated assay with minimal script modification. The application of the template was demonstrated in three LBAs to support discovery biotherapeutic programs. CONCLUSION: The results demonstrated that the modular scripts provided the flexibility in adapting to various LBA formats and the significant time saving in script writing and scientist training. Data generated by the automated process were comparable to those by manual process while the bioanalytical productivity was significantly improved using the modular robotic scripts.

Rapid development of multiple 'fit-for-purpose' assays on an automatic microfluidic system using a streamlined process in support of early biotherapeutics discovery programs.

BACKGROUND: With a rapid increase in the number of novel biotherapeutic programs in the pipelines, efficient development of ligand-binding assays for PK and PD studies in the early discovery stage has become more important than ever. METHODOLOGY: A four-step process was evaluated to quickly develop multiple 'fit-for-purpose' Gyrolab(®) ligand-binding assays in parallel. It covered the following four steps: reagent labeling, reagent screening, assay optimization; and, assay qualification. RESULTS: Eight assays for two programs were developed and qualified in less than 2 weeks. These assays met the specifications of sufficient sensitivity with LLOQ between 2 and 50 ng/ml, %CV <25% and recoveries between 75 and 125% for QC samples. CONCLUSION: The streamlined four-step process enabled timely development of multiple high-throughput assays in parallel with minimal hands-on time. Consequently, it dramatically increased assay development productivity to support the discovery programs.

Characterization and development of a Luminex(®)-based assay for the detection of human IL-23.

BACKGROUND: IL-23 is a cytokine produced by dendritic cells, T-cells and macrophages that plays a critical regulatory role in the inflammatory and autoimmune responses. We describe the development and preclinical validation of a highly sensitive Luminex(®) assay specific to IL-23 that is suitable for its measurement in support of early-phase clinical trials. RESULTS: Intra-assay precision for the BioSource™ ELISA was under 12.3%, and under 5.2% for the eBioscience(®) ELISA. In comparison, the Luminex assays provided an intra-assay precision under 6.2%. The measured inter-assay precision was less than 15.6% for the BioSource ELISA, under 33% for the eBioscience and less than 10% for the Luminex assays. CONCLUSIONS: The Luminex method described provides a way to measure IL-23 in clinical samples either as a single biomarker or as a panel of biomarkers. The assay should prove useful to scientists and clinicians investigating the biology of IL-23 and to those needing to monitor changes in IL-23 as part of a clinical study.

Electrochemiluminescence in bioanalysis.

The discovery of electrochemiluminescence (ECL) and its development as a means of detection is truly a success story. Although studies describing ECL were published in the early 1960s, most studies using ECL as a means of detection were not widely published until the mid 1990s. Incorporating ECL into assays provides increased sensitivity, several logs of dynamic range and the ability to electronically control the reaction. These characteristics provide advantages over assays that rely on radioisotopic labels, fluorescence and enzymatic activity. There have been many areas of science that have benefited from the use of ECL, including environmental microbiology, virology, neurobiology, molecular biology and immunology. ECL has improved the understanding and treatment of infectious diseases, cancer, neurodegenerative diseases and even sleep apnea disorders. Drug development has also benefited from ECL via improved assessment of pharmacodynamics, pharmacokinetics and determining immune responses against protein-based therapeutics. This review provides an overview of ECL chemistry and principles with a more detailed emphasis on the applications of ECL-based assays in different areas of science and medicine. The primary purpose of this review is to provide an in-depth discussion of the impact that ECL-based analysis has had on microbiology, immunology, virology, neurodegenerative diseases, molecular biology and drug development. Examples of ECL-based bioanalysis in each of these fields are discussed in conjunction with an overview of ECL principles and instrumentation.

Immunoassay-based measurement of clinical biomarkers for monitoring changes in nasal cavity.

BACKGROUND: Many drugs for treatment of allergies, migraine headaches, inflammation, and other indications are administered into the nasal cavity providing access to the immune and central nervous systems. One of the concerns for using this route of administration is potential damage to the nasal epithelium and mucosal regions. We assembled a panel of clinical biomarkers that can be used to monitor changes in the nasal epithelium, mucosa, and olfactory regions in preparation for clinical trials involving drugs administered via intranasal route. These biomarkers included albumin, elastase, IL-6, IL-8, lactoferrin, myeloperoxidase and nerve growth factor. METHODS: Immunoassays were developed and used to measure changes in these biomarkers in nasal lavage samples collected twice daily from 30 assumed-healthy volunteers over a 2-day period. Various statistical methods including analysis of variance (ANOVA), paired t-test and Pearson's product-moment correlation were used to evaluate the data. RESULTS: Although the basal levels of these biomarkers were varied among subjects, the data show that the concentrations of albumin, elastase and IL-8 were significantly higher in samples collected in the morning compared to samples collected later during the day. Pre-washing nasal cavity prior to collecting nasal lavage samples did alter the measurement of elastase and albumin, but did not influence the levels of the other biomarkers. CONCLUSIONS: These data show that this panel of biomarkers can be used to monitor changes in the nasal cavity including those affected by diurnal fluctuations. These results also provide useful baseline values and sources of variability for each biomarker that could be used to help design clinical trials.

Identification of dynein heavy chain 7 as an inner arm component of human cilia that is synthesized but not assembled in a case of primary ciliary dyskinesia.

Although the basic structure of the axoneme has been highly conserved throughout evolution, the varied functions of specialized axonemes require differences in structure and regulation. Cilia lining the respiratory tract propel mucus along airway surfaces, providing a critical function to the defense mechanisms of the pulmonary system, yet little is known of their molecular structure. We have identified and cloned a dynein heavy chain that is a component of the inner dynein arm. Bronchial epithelial cells were obtained from normal donors and from a patient with primary ciliary dyskinesia (PCD) whose cilia demonstrated an absence of inner dynein arms by electron microscopy. Cilia from normal and PCD cells were compared by gel electrophoresis, and mass spectrometry was used to identify DNAH7 as a protein absent in PCD cilia. The full-length DNAH7 cDNA was cloned and shares 68% similarity with an inner arm dynein heavy chain from Drosophila. DNAH7 was induced during ciliated cell differentiation, and immunohistochemistry demonstrated the presence of DNAH7 in normal cilia. In cilia from PCD cells, DNAH7 was undetectable, whereas intracellular DNAH7 was clearly present. These studies identify DNAH7 as an inner arm component of human cilia that is synthesized but not assembled in a case of PCD.