Ultrastructural nasal pathology in children chronically and sequentially exposed to air pollutants

Southwest Metropolitan Mexico City (SWMMC) children are repeatedly exposed to a complex mixture of air pollutants, including ozone, particulate matter, and aldehydes. Nasal biopsies taken from these children exhibit a wide range of histopathologic alterations: marked changes in ciliated and goblet cell populations, basal cell hyperplasia, squamous metaplasia, and mild dysplasias. We studied the ultrastructural features of 15 nasal biopsies obtained from clinically healthy children 4 to 15 yr of age, growing up in SWMMC. The results were compared with nasal biopsies from 11 children growing up in Veracruz and exposed to low pollutant levels. Ultrathin sections of nasal biopsies revealed an unremarkable mucociliary epithelium in control children, whereas SWMMC children showed an epithelium comprised of variable numbers of basal, ciliated, goblet, and squamous metaplastic as well as intermediate cells. Nascent ciliated cells, as evidenced by the presence of migratory kinetosomes, were common, as were ciliary abnormalities, including absent central microtubules, supernumerary central and peripheral tubules, ciliary microtubular discontinuities, and compound cilia. Dyskinesia associated with these abnormal cilia was suggested by the altered orientation of the central microtubules in closely adjacent cilia. A transudate was evident between epithelial cells, suggesting potential deficiencies in epithelial junction integrity. Particulate matter was present in heterolysosomal bodies in epithelial cells and it was also deposited in intercellular spaces. The severe structural alteration of the nasal epithelium together with the prominent acquired ciliary defects are likely the result of chronic airway injury in which ozone, particulate matter, and aldehydes are thought to play a crucial role. The nasal epithelium in SWMMC children is fundamentally disordered, and their mucociliary defense mechanisms are no longer intact. A compromised nasal epithelium has less ability to protect the lower respiratory tract and may potentially leave the distal acinar airways more vulnerable to reactive gases. Impairment of mucociliary clearance has the potential to increase the contact time between deposited mutagenic particulate matter and the epithelial surface, thus increasing the risk for nasal carcinogenesis. Chronic exposures to air pollutants affect the whole respiratory tract; the nasal epithelium is an accessible and valuable sentinel to monitor exposures to toxic or carcinogenic substances.     

Ultrastructure of airway epithelial cell membranes among patients with cystic fibrosis

Alterations in transepithelial ion fluxes are a primary pathophysiologic feature in cystic fibrosis (CF). Chronic respiratory infections and host responses are secondary aggravating pulmonary complications of this disease. In the present study, the application of the freeze-fracture technique to samples of nasal and tracheal epithelium from patients with CF has provided a perspective of large areas of cell membrane for the evaluation of possible structural correlates to the pathophysiology of this disease. A variety of aberrant configurations in stranding pattern and disorganization of the epithelial tight junctional complexes in CF airway epithelium are described. Additionally, examination of ciliary membranes revealed the presence of compound cilia and dysmorphology of ciliary necklace configuration. These features are thought to represent acquired structural lesions possibly derived from chronic infection and/or host responses which may further exacerbate abnormal ion transport properties and decrements of ciliary function that appear to be associated with the airway epithelium of individuals with CF.     

Cystic fibrosis and other respiratory diseases of impaired mucus clearance

Exposed to a diverse array of potentially noxious agents, the respiratory tract is protected by a highly developed innate defense system. Physiologically regulated epithelial ion and water transport coordinated with mucin secretion, beating cilia, and cough results in continuous flow of fluid and mucus over airway surfaces toward the larynx. This cleansing action is the initial and perhaps most quantitatively important innate defense mechanism. Repeated lung infections and eventual respiratory insufficiency characteristic of human cystic fibrosis (CF) and primary ciliary dyskinesia (PCD) illustrate the consequences of impaired mucus clearance. Altered mucus clearance likely contributes to the initiation, progression, and chronicity of other airway diseases characterized by inflammation and mucous secretory cell hyper/metaplasia that afflict millions worldwide, including chronic obstructive pulmonary disease (COPD). This review concisely discusses the pathophysiology of human diseases characterized by genetic defects that impair mucus clearance. It then explores animal models in which components of the mucus clearance system have been disrupted. These models firmly establish the importance of mucus clearance for respiratory health, and will help elucidate disease mechanisms and therapeutic strategies in CF, PCD and COPD.     

Absence of nexin links as a possible cause of primary ciliary dyskinesia

Transmission electron microscopy of nasal cilia was performed in three patients, two of them siblings, with repeated respiratory infections. Number of microtubuli and dynein arms were within normal limits and they had an ordered arrangement except for a disarray of the microtubuli in some areas of the biopsies from two of the patients. In the normal areas radial spokes and sheaths were easily found but nexin links could not be discerned in any of the patients. The orientation of the cilia was partly random. As all patients repeatedly and constantly had very low nasal NO (range 9-15 ppb; normal findings for persons <10 years old are > 50 ppb), the diagnoses were very likely primary ciliary dyskinesia (PCD). Absence of nexin links may be an ultrastructural variant of PCD. Deficiency of these structures might be the cause of the microtubular disarray observed in some areas of the biopsies.     

Mutation of murine adenylate kinase 7 underlies a primary ciliary dyskinesia phenotype

Primary ciliary dyskinesia (PCD) is a genetically and phenotypically heterogeneous disorder, characterized by progressive development of bronchiectasis, inflammation, and features characteristic of chronic obstructive pulmonary disease. We report here that a murine mutation of the evolutionarily conserved adenylate kinase 7 (Ak7) gene results in animals presenting with pathological signs characteristic of PCD, including ultrastructural ciliary defects and decreased ciliary beat frequency in respiratory epithelium. The mutation is associated with hydrocephalus, abnormal spermatogenesis, mucus accumulation in paranasal passages, and a dramatic respiratory pathology upon allergen challenge. Ak7 appears to be a marker for cilia with (9 + 2) microtubular organization. This is suggested by its tissue specificity of expression and also the stringent conservation of Ak7 ortholog structure only in protozoans and metazoans possessing motile (9 + 2) cilia. Collectively, our results indicate an ancestral and crucial role of Ak7 in maintaining ciliary structure and function, and suggest that mutations of the human ortholog may underlie a subset of genetically uncharacterized PCD cases.     

Clinico-pathological evaluation of ciliary dyskinesia: diagnostic role of electron microscopy

From November 1995 to May 2002, the authors studied 59 children with suspected primary ciliary dyskinesia (PCD). Samples of ciliated respiratory epithelium were obtained by nasal brushing from 44 patients and by biopsy of bronchial mucosa from 15 patients. Thirty-four/Fifty-nine samples were suitable to obtain a quali-quantitative evaluation of ultrastructural ciliary abnormalities. Many ciliary and axoneme alterations were described. This study revealed that quantitative and qualitative ultrastructural assessment of respiratory epithelial cilia plays an important role in the differentiation between primary, secondary, and borderline ciliary abnormalities. Early diagnosis of PCD with appropriate clinical follow-up and treatment is important to prevent irreversible lung tissue damage, namely bronchiectasis.     

Ultrastructural abnormalities of cilia in the human respiratory tract

Primary ciliary dyskinesia is thought to be caused by a primary defect of ciliary ultrastructure and function. However, atypical cilia have also been described in humans with and without acquired respiratory tract disease. With few exceptions, these abnormalities have not been quantified. Ciliary ultrastructure was therefore studied in 21 specimens of bronchial mucosa from patients with a variety of respiratory problems and in five specimens of nasal mucosa from asymptomatic nonsmokers. The incidence of microtubular abnormalities and compound cilia was generally less than 10 per cent, and there was no correlation between the incidence of these abnormalities and the presence of lung carcinoma or smoking habits. Transposition of ciliary microtubules and radial spoke defects, specific microtubular abnormalities thought to be pathognomonic for primary ciliary dyskinesia, were observed in a number of specimens, and visualization of dynein arms, particularly inner dynein arms, was extremely difficult. It is concluded that ultrastructural abnormalities of cilia should be carefully quantified in patients with primary ciliary dyskinesia and control subjects before it can be assumed they have pathologic significance.     

Computer-assisted analysis of radial symmetry in human airway epithelial cilia: assessment of congenital ciliary defects in primary ciliary dyskinesia

The ultrastructural analysis of cilia and diagnosis of primary ciliary dyskinesia (PCD) in biopsies of airway epithelium is sometimes confounded by poor sampling, inconsistencies in tissue quality and processing, and other technical problems. Although clinical findings maylead to a presumptive diagnosis, ultrastructural analysis of ciliary axonemes is the standard for confirmation of PCD. The ultrastructural features of the ciliumwhen viewed in crosssection by transmission electron microscopy confer a radial symmetry to the axoneme. Current digital image processing techniques can be applied to such images to reinforce signal, diminish noise, and confirm consistency of position of axonemal structures,a process that can augment ultrastructural analysis for PCD. In this study, computer-assisted digital image processing was used to evaluate cross sections of cilia in airway epithelial biopsies from patients previously diagnosed with PCD as well as in control subjects with normal cilia. These studies supported the original diagnoses and provided some new insights into axonemal organization in PCD. This technique is simple and may be useful in providing a supporting means for confirming or ruling out a diagnosis of PCD in cases that appear equivocal.     

Computer-Assisted Analysis of Radial Symmetry in Human Airway Epithelial Cilia: Assessment of Congenital Ciliary Defects in Primary Ciliary Dyskinesia

The ultrastructural analysis of cilia and diagnosis of primary ciliary dyskinesia (PCD) in biopsies of airway epithelium is sometimes confounded by poor sampling, inconsistencies in tissue quality and processing, and other technical problems. Although clinical findings maylead to a presumptive diagnosis, ultrastructural analysis of ciliary axonemes is the standard for confirmation of PCD. The ultrastructural features of the ciliumwhen viewed in crosssection by transmission electron microscopy confer a radial symmetry to the axoneme. Current digital image processing techniques can be applied to such images to reinforce signal, diminish noise, and confirm consistency of position of axonemal structures,a process that can augment ultrastructural analysis for PCD. In this study, computer-assisted digital image processing was used to evaluate cross sections of cilia in airway epithelial biopsies from patients previously diagnosed with PCD as well as in control subjects with normal cilia. These studies supported the original diagnoses and provided some new insights into axonemal organization in PCD. This technique is simple and may be useful in providing a supporting means for confirming or ruling out a diagnosis of PCD in cases that appear equivocal.     

Ciliary beat pattern is associated with specific ultrastructural defects in primary ciliary dyskinesia

BACKGROUND: The main symptoms of primary ciliary dyskinesia (PCD) are nasal rhinorrhea or blockage and moist-sounding cough. Diagnosis can be difficult and is based on an abnormal ciliary beat frequency, accompanied by specific abnormalities of the ciliary axoneme. It is unknown whether determining ciliary beat pattern related to specific ultrastructural ciliary defects might help in the diagnosis of PCD. OBJECTIVE: We sought to determine ciliary beat pattern and beat frequency (CBF) associated with the 5 common ultrastructural defects responsible for PCD. METHODS: Nasal brushings were performed on 56 children with PCD. Ciliary movement was recorded using digital high-speed video imaging to assess beat frequency and pattern. Electron microscopy was performed. RESULTS: In patients with an isolated outer dynein arm or with an outer and inner dynein arm defect, 55% and 80% of cilia were immotile, respectively. Cilia that moved were only flickering. Mean CBF (+/- 95% CI) was 2.3 Hz (+/- 1.2) and 0.8 Hz(+/- 0.8), respectively. Cilia with an isolated inner dynein arm or a radial spoke defect had similar beat patterns. Cilia appeared stiff, had a reduced amplitude, and failed to bend along their length. Immotile cilia were present in 10% of cilia with an inner dynein arm defect and in 30% of radial spoke defects. Mean CBF was 9.3 Hz (+/- 2.6) and 6.0 Hz (+/- 3.1), respectively. The ciliary transposition defect produced a large circular beat pattern (mean CBF, 10.7 Hz [+/- 1.1]). No cilia were immotile. CONCLUSIONS: Different ultrastructural defects responsible for PCD result in predictable beat patterns. Recognition of these might help in the diagnostic evaluation of patients suspected of having PCD.     

Mutation of serine/threonine protein kinase 36 (STK36) causes primary ciliary dyskinesia with a central pair defect

Primary ciliary dyskinesia (PCD) is a genetic condition of impaired ciliary beating, characterized by chronic infections of the upper and lower airways and progressive lung failure. Defects of the outer dynein arms are the most common cause of PCD. In about half of the affected individuals, PCD occurs with situs inversus (Kartagener syndrome). A minor PCD subgroup including defects of the radial spokes (RS) and central pair (CP) is hallmarked by the absence of laterality defects, subtle beating abnormalities, and unequivocally apparent ultrastructural defects of the ciliary axoneme, making their diagnosis challenging. We identified homozygous loss‐of‐function mutations in STK36 in one PCD‐affected individual with situs solitus. Transmission electron microscopy analysis demonstrates that STK36 is required for cilia orientation in human respiratory epithelial cells, with a probable localization of STK36 between the RS and CP. STK36 screening can now be included for this rare and difficult to diagnose PCD subgroup.     

Expression of nitric oxide synthases in primary ciliary dyskinesia

Nitric oxide is believed to play a central role in nonspecific defense of upper airways. Patients with primary ciliary dyskinesia have very low concentration of nasal nitric oxide, which may contribute to the chronic upper airway diseases encountered by these patients. The mechanisms underlying this drop of nasal nitric oxide in primary ciliary dyskinesia are still unknown. The goal of the present work was to study nitric oxide synthases expression in upper airway tissues from patients with primary ciliary dyskinesia. For this purpose, 5 patients with primary ciliary dyskinesia and 10 nonallergic age-matched patients without primary ciliary dyskinesia undergoing nasal polypectomy were included. Nasal nitric oxide concentration was measured before polypectomy, and nitric oxide synthase expression and function were studied in nasal polyps. The nasal nitric oxide in patients with primary ciliary dyskinesia was lower than that in patients without primary ciliary dyskinesia (13 [9-16] ppb versus 210 [167-254] ppb, P < .0001). Nitric oxide synthase 2 immunostaining was prominent at the apical part of the ciliated epithelial cells and was similar in both groups. Nitric oxide synthase 3 staining was restricted to endothelial cells in both groups. In addition, reduced nicotinamide adenine dinucleotide phosphate (NADPH)-diaphorase activity was superimposable to nitric oxide synthases 2 and 3 immunostaining, suggesting a preserved NADPH-activity of nitric oxide synthase. We therefore conclude that the drop in nasal nitric oxide in patients with primary ciliary dyskinesia is not secondary to the loss of nitric oxide synthase expression.     

Ten-year experience using a plastic, disposable curette for the diagnosis of primary ciliary dyskinesia.

BACKGROUND: Primary ciliary dyskinesia (PCD) results in impaired mucociliary clearance. Patients with this disorder develop chronic sinopulmonary disease with recurrent sinusitis, otitis media, nasal polyposis, pneumonia, and, ultimately, bronchiectasis. Other associated findings of dysfunctional ciliary activity include situs inversus, dextrocardia, and infertility. OBJECTIVE: To describe our 10-year experience using a small, plastic, disposable curette to perform a screening procedure for cilia function and to collect samples for electron microscopy. METHODS: In the past 10 years, we screened infants and children with severe chronic sinusitis and other chronic recurrent upper respiratory tract problems for PCD by using a plastic, disposable curette to collect tissue samples from the nasal mucosa. Samples were placed in sterile saline and examined under light microscopy for the presence of cilia. Failure to note ciliary movement prompted another examination 1 month later. If no functional cilia were noted at the follow-up examination, a specimen was obtained and sent for electron microscopy. RESULTS: We identified 7 patients with PCD; 2 had situs inversus totalis. Average age at diagnosis was 3 years. The most common symptom at presentation was frequent upper respiratory tract infections with severe otitis media (7 patients) and sinusitis (5 patients). Recurrent pneumonia was present in 6 patients. Dynein arm deficiency was the most common electron microscopic diagnosis. CONCLUSIONS: Evaluating children for PCD by using a plastic, disposable curette is a relatively simple procedure that could be used by allergists in practice. Primary ciliary dyskinesia occurs frequently enough that physicians should consider it as part of the differential diagnosis in evaluating children with recurrent, severe sinopulmonary infections.     

Ultrastructural defects of respiratory tract cilia associated with chronic infections

Ultrastructural defects were demonstrated in nasal and bronchial cilia from a 12-year-old boy with repeated upper and lower respiratory tract infections. Numerous abnormalities were found, including single axonemes surrounded by excess cytoplasmic matrix, compound cilia, intracytoplasmic microtubular doublets, and cilia contained within a periciliary sheath. Dynein arms were missing from the majority of the peripheral microtubular doublets. The most striking abnormality, however, was a disorientation of cilia as judged by the increased variation in the orientation of central microtubules. Because of these ultrastructural abnormalities, it is highly likely that ciliary motility was markedly decreased and that defective mucociliary transport was responsible for chronic and repeated upper respiratory tract infections.     

Value of transmission electron microscopy for primary ciliary dyskinesia diagnosis in the era of molecular medicine: Genetic defects with normal and non-diagnostic ciliary ultrastructure

ABSTRACT

Primary ciliary dyskinesia (PCD) is a genetic disorder causing chronic oto-sino-pulmonary disease. No single diagnostic test will detect all PCD cases. Transmission electron microscopy (TEM) of respiratory cilia was previously considered the gold standard diagnostic test for PCD, but 30% of all PCD cases have either normal ciliary ultrastructure or subtle changes which are non-diagnostic. These cases are identified through alternate diagnostic tests, including nasal nitric oxide measurement, high-speed videomicroscopy analysis, immunofluorescent staining of axonemal proteins, and/or mutation analysis of various PCD causing genes. Autosomal recessive mutations in DNAH11 and HYDIN produce normal TEM ciliary ultrastructure, while mutations in genes encoding for radial spoke head proteins result in some cross-sections with non-diagnostic alterations in the central apparatus interspersed with normal ciliary cross-sections. Mutations in nexin link and dynein regulatory complex genes lead to a collection of different ciliary ultrastructures; mutations in CCDC65, CCDC164, and GAS8 produce normal ciliary ultrastructure, while mutations in CCDC39 and CCDC40 cause absent inner dynein arms and microtubule disorganization in some ciliary cross-sections. Mutations in CCNO and MCIDAS cause near complete absence of respiratory cilia due to defects in generation of multiple cellular basal bodies; however, the scant cilia generated may have normal ultrastructure. Lastly, a syndromic form of PCD with retinal degeneration results in normal ciliary ultrastructure through mutations in the RPGR gene. Clinicians must be aware of these genetic causes of PCD resulting in non-diagnostic TEM ciliary ultrastructure and refrain from using TEM of respiratory cilia as a test to rule out PCD.     

Discordant organ laterality in monozygotic twins with primary ciliary dyskinesia

Primary ciliary dyskinesia (PCD) is a genetic disease characterized by abnormal ciliary structure and function, impaired mucociliary clearance, and chronic middle ear, sinus, and lung disease. PCD is associated with situs inversus in ∼50% of the patients. One proposed explanation for this relationship is that normal ciliary function plays a role in normal organ orientation, whereas organ orientation in PCD is a random event because of dysfunctional cilia in early embryonic development. Another hypothesis for the association between PCD and situs inversus is that mutated genes in PCD not only cause defective cilia, but are also linked to the control of organ laterality, such that abnormalities in this molecular pathway result in random left-right asymmetry. We report on a set of monozygotic twin women with PCD. In both patients, deficiency of the inner dynein arms was noted on ciliary ultrastructural analysis, associated with a clinical syndrome of bronchiectasis, chronic sinusitis, and middle ear disease. One of the twins has situs solitus, the other has situs inversus totalis. DNA analysis confirmed that the twins are monozygotic. This is consistent with the hypothesis that situs inversus occurring in patients with primary ciliary dyskinesia is a random but “complete” event in the fetal development of patients with PCD. Am. J. Med. Genet. 82:155–160, 1999. © 1999 Wiley-Liss, Inc.     

Mutations in GAS8, a Gene Encoding a Nexin‐Dynein Regulatory Complex Subunit,Cause Primary Ciliary Dyskinesia with Axonemal Disorganization

Primary ciliary dyskinesia (PCD) is an autosomal recessive disease characterized by chronic respiratory infections of the upper and lower airways, hypofertility, and, in approximately half of the cases, situs inversus. This complex phenotype results from defects in motile cilia and sperm flagella. Among the numerous genes involved in PCD, very few—including CCDC39 and CCDC40—carry mutations that lead to a disorganization of ciliary axonemes with microtubule misalignment. Focusing on this particular phenotype, we identified bi‐allelic loss‐of‐function mutations in GAS8, a gene that encodes a subunit of the nexin‐dynein regulatory complex (N‐DRC) orthologous to DRC4 of the flagellated alga Chlamydomonas reinhardtii. Unlike the majority of PCD patients, individuals with GAS8 mutations have motile cilia, which, as documented by high‐speed videomicroscopy, display a subtle beating pattern defect characterized by slightly reduced bending amplitude. Immunofluorescence studies performed on patients’ respiratory cilia revealed that GAS8 is not required for the proper expression of CCDC39 and CCDC40. Rather, mutations in GAS8 affect the subcellular localization of another N‐DRC subunit called DRC3. Overall, this study, which identifies GAS8 as a PCD gene, unveils the key importance of the corresponding protein in N‐DRC integrity and in the proper alignment of axonemal microtubules in humans.     

Chemotaxis of blood neutrophils from patients with primary ciliary dyskinesia

Primary ciliary dyskinesia is characterized by chronic upper and lower respiratory infections which are caused by the grossly impaired ciliary transport. Since the cilia and neutrophils both utilize microtubular system for their movement, it has been speculated that neutrophil motility such as chemotaxis might be impaired in patients with primary ciliary dyskinesia. Neutrophils were purified from whole blood from 16 patients with primary ciliary dyskinesia and from 15 healthy controls. Chemotactic responses of neutrophils to leukotriene B(4) (LTB(4)), complement 5a (C5a), and formylmethionylleucylphenylalanine (fMLP) were examined using the under agarose method. The chemotactic differentials in response to LTB4, C5a, and fMLP in neutrophils from the patient group were significantly lower than the corresponding values in neutrophils from the control group (p<0.05 for all comparisons). The difference in chemotactic index between the two groups was statistically significant for LTB4 and fMLP (p<0.05 for both comparisons), but not for C5a (p=0.20). Neutrophils from patients with primary ciliary dyskinesia showed a decreased chemotactic response as compared with those from normal subjects. It is concluded that the increased frequency of respiratory tract infection in patients with primary ciliary dyskinesia is possibly due to the defective directional migration of neutrophils, as well as to the defective mucociliary clearance of the airways.     

Clinical and genetic aspects of primary ciliary dyskinesia/Kartagener syndrome

Primary ciliary dyskinesia is a genetically heterogeneous disorder of motile cilia. Most of the disease-causing mutations identified to date involve the heavy (dynein axonemal heavy chain 5) or intermediate (dynein axonemal intermediate chain 1) chain dynein genes in ciliary outer dynein arms, although a few mutations have been noted in other genes. Clinical molecular genetic testing for primary ciliary dyskinesia is available for the most common mutations. The respiratory manifestations of primary ciliary dyskinesia (chronic bronchitis leading to bronchiectasis, chronic rhino-sinusitis, and chronic otitis media) reflect impaired mucociliary clearance owing to defective axonemal structure. Ciliary ultrastructural analysis in most patients (>80%) reveals defective dynein arms, although defects in other axonemal components have also been observed. Approximately 50% of patients with primary ciliary dyskinesia have laterality defects (including situs inversus totalis and, less commonly, heterotaxy, and congenital heart disease), reflecting dysfunction of embryological nodal cilia. Male infertility is common and reflects defects in sperm tail axonemes. Most patients with primary ciliary dyskinesia have a history of neonatal respiratory distress, suggesting that motile cilia play a role in fluid clearance during the transition from a fetal to neonatal lung. Ciliopathies involving sensory cilia, including autosomal dominant or recessive polycystic kidney disease, Bardet-Biedl syndrome, and Alstrom syndrome, may have chronic respiratory symptoms and even bronchiectasis suggesting clinical overlap with primary ciliary dyskinesia.     

Static respiratory cilia associated with mutations in Dnahc11/DNAH11: a mouse model of PCD

Primary ciliary dyskinesia (PCD) is an inherited disorder causing significant upper and lower respiratory tract morbidity and impaired fertility. Half of PCD patients show abnormal situs. Human disease loci have been identified but a mouse model without additional deleterious defects is elusive. The inversus viscerum mouse, mutated at the outer arm dynein heavy chain 11 locus (Dnahc11) is a known model of heterotaxy. We demonstrated immotile tracheal cilia with normal ultrastructure and reduced sperm motility in the Dnahc11(iv) mouse. This is accompanied by gross rhinitis, sinusitis, and otitis media, all indicators of human PCD. Strikingly, age-related progression of the disease is evident. The Dnahc11(iv) mouse is robust, lacks secondary defects, and requires no intervention to precipitate the phenotype. Together these findings show the Dnahc11(iv) mouse to be an excellent model of many aspects of human PCD. Mutation of the homologous human locus has previously been associated with hyperkinetic tracheal cilia in PCD. Two PCD patients with normal ciliary ultrastructure, one with immotile and one with hyperkinetic cilia were found to carry DNAH11 mutations. Three novel DNAH11 mutations were detected indicating that this gene should be investigated in patients with normal ciliary ultrastructure and static, as well as hyperkinetic cilia.