John G. Elliot

Vitamin D deficiency causes deficits in lung function and alters lung structure

RATIONALE The prevalence of vitamin D deficiency is increasing and has been linked to obstructive lung diseases including asthma and chronic obstructive pulmonary disease. Recent studies suggest that vitamin D deficiency is associated with reduced lung function. The relationship between vitamin D deficiency and lung function is confounded by the association between physical activity levels and vitamin D status. Thus, causal data confirming a relationship between vitamin D and lung function are lacking. OBJECTIVES To determine if vitamin D deficiency alters lung structure and function. METHODS A physiologically relevant BALB/c mouse model of vitamin D deficiency was developed by dietary manipulation. Offspring from deficient and replete colonies of mice were studied for somatic growth, lung function, and lung structure at 2 weeks of age. MEASUREMENTS AND MAIN RESULTS Lung volume and function were measured by plethysmography and the forced oscillation technique, respectively. Lung structure was assessed histologically. Vitamin D deficiency did not alter somatic growth but decreased lung volume. There were corresponding deficits in lung function that could not be entirely explained by lung volume. The volume dependence of lung mechanics was altered by deficiency suggesting altered tissue structure. However, the primary histologic difference between groups was lung size rather than an alteration in architecture. CONCLUSIONS Vitamin D deficiency causes deficits in lung function that are primarily explained by differences in lung volume. This study is the first to provide direct mechanistic evidence linking vitamin D deficiency and lung development, which may explain the association between obstructive lung disease and vitamin D status.

Airway Smooth Muscle Hypertrophy and Hyperplasia in Asthma

RATIONALE Increased thickness of the airway smooth muscle (ASM) layer in asthma may result from hyperplasia or hypertrophy of muscle cells or increased extracellular matrix (ECM). OBJECTIVES To relate ASM hypertrophy, ASM hyperplasia, and deposition of ECM to the severity and duration of asthma. METHODS Airways from control subjects (n = 51) and from cases of nonfatal (n = 49) and fatal (n = 55) asthma were examined postmortem. Mean ASM cell volume (V(C)), the number of ASM cells per length of airway (N(L)), and the volume fraction of extracellular matrix (f(ECM)) within the ASM layer were estimated. Comparisons between subject groups were made on the basis of general linear regression models. MEASUREMENTS AND MAIN RESULTS Mean V(C) was increased in the large airways of cases of nonfatal asthma (P = 0.015) and fatal asthma (P < 0.001) compared with control subjects. N(L) was similar in nonfatal cases and control subjects but increased in large (P < 0.001), medium (P < 0.001), and small (P = 0.034) airways of cases of fatal asthma compared with control subjects and with nonfatal cases (large and medium airways, P ≤ 0.003). The f(ECM) was similar in cases of asthma and control subjects. Duration of asthma was associated with a small increase in N(L). CONCLUSIONS Hypertrophy of ASM cells occurs in the large airways in both nonfatal and fatal cases of asthma, but hyperplasia of ASM cells is present in the large and small airways in fatal asthma cases only. Both are associated with an absolute increase in ECM. Duration of asthma has little or no effect on ASM hypertrophy or hyperplasia or f(ECM).

Airway smooth muscle thickness in asthma is related to severity but not duration of asthma

Asthma is characterised by an increased airway smooth muscle (ASM) area (ASMarea) within the airway wall. The present study examined the relationship of factors including severity and duration of asthma to ASMarea. The perimeter of the basement membrane (PBM) and ASMarea were measured on transverse sections of large and small airways from post mortem cases of fatal (n = 107) and nonfatal asthma (n = 37) and from control subjects (n = 69). The thickness of ASM (ASMarea/PBM) was compared between asthma groups using multivariate linear regression. When all airways were considered together, ASMarea/PBM (in millimetres) was increased in nonfatal (median 0.04; interquartile range 0.013–0.051; p = 0.034) and fatal cases of asthma (0.048; 0.025–0.078; p<0.001) compared with controls (0.036; 0.024–0.042). Compared with cases of nonfatal asthma, ASMarea/PBM was greater in cases of fatal asthma in large (p<0.001) and medium (p<0.001), but not small, airways. ASMarea/PBM was not related to duration of asthma, age of onset of asthma, sex or smoking. No effect due to study centre, other than that due to sampling strategy, was found. The thickness of the ASM layer is increased in asthma and is related to the severity of asthma but not its duration.

Time to death, airway wall inflammation and remodelling in fatal asthma

Fatal asthma is characterised pathologically by airway wall remodelling, eosinophil and neutrophil infiltration, accumulation of mucus in the airway lumen and smooth muscle shortening. The durations of fatal attacks of asthma show a clear bimodal distribution. Airway smooth muscle contraction and the accumulation of luminal mucus may contribute to death from asthma and relate to time to death. The current authors have examined these two components in uninflated lung tissue in cases of fatal asthma from the second Victorian asthma mortality study. Based on time from onset of symptoms to death, cases fell into two distinct groups: short course <3 (1.5±0.6 mean±sd) h; and long course >8 (12.3±5.9) h. Short course cases had more muscle shortening, higher levels of salbutamol and higher ratios of neutrophils to eosinophils than long course cases, who tended to have more mucus in the lumen. In conclusion, this study confirms the dichotomy of both time to death and the eosinophil/neutrophil ratio in cases of fatal asthma. It suggests that in short course cases acute airway narrowing is due, predominantly, to bronchoconstriction despite higher blood levels of salbutamol. Mucus accumulation may be more important in long course cases.

Airway narrowing and bronchodilation to deep inspiration in bronchial segments from subjects with and without reported asthma.

The present study presents preliminary findings on how structural/functional abnormalities of the airway wall relate to excessive airway narrowing and reduced bronchodilatory response to deep inspiration (DI) in subjects with a history of asthma. Bronchial segments were acquired from subjects undergoing surgery, mostly to remove pulmonary neoplasms. Subjects reported prior doctor-diagnosed asthma (n = 5) or had no history of asthma (n = 8). In vitro airway narrowing in response to acetylcholine was assessed to determine maximal bronchoconstriction and sensitivity, under static conditions and during simulated tidal and DI maneuvers. Fixed airway segments were sectioned for measurement of airway wall dimensions, particularly the airway smooth muscle (ASM) layer. Airways from subjects with a history of asthma had increased ASM (P = 0.014), greater maximal airway narrowing under static conditions (P = 0.003), but no change in sensitivity. Maximal airway narrowing was positively correlated with the area of the ASM layer (r = 0.58, P = 0.039). In tidally oscillating airways, DI produced bronchodilation in airways from the control group (P = 0.0001) and the group with a history of asthma (P = 0.001). While bronchodilation to DI was reduced with increased airway narrowing (P = 0.02; r = -0.64)), when the level of airway narrowing was matched, there was no difference in magnitude of bronchodilation to DI between groups. Results suggest that greater ASM mass in asthma contributes to exaggerated airway narrowing in vivo. In comparison, the airway wall in asthma may have a normal response to mechanical stretch during DI. We propose that increased maximal airway narrowing and the reduced bronchodilatory response to DI in asthma are independent.

Distribution of airway smooth muscle remodelling in asthma: Relation to airway inflammation

Pathological phenotypes of asthma have been based predominantly on inflammation, rather than airway wall remodelling. Differences in the distribution of airway smooth muscle (ASM) remodelling between large and small airways may affect clinical outcomes in asthma. The aim of this study was to examine the distribution of ASM remodelling and its relation to airway inflammation.

Reduced apoptosis of memory T-cells in the inner airway wall of mild and severe asthma

Effector memory T-cells (CD45RO+) may provide pro-inflammatory signals that contribute to the persistent airway inflammation that is characteristic of asthma, and reduced apoptosis of these cells may prolong their effects. The present authors compared apoptosis of CD45RO+ T-cells in the inner airway wall in nonfatal asthma (n = 7), fatal asthma (n = 7) and control (n = 8) cases. Apoptotic cells were identified using both the terminal deoxynucleotidyl transferase dNTP nick end-labelling (TUNEL) technique and cell morphology. The percentage of CD45RO+ T-cells that were apoptotic was significantly greater in control cases compared with nonfatal and fatal cases of asthma, respectively, in small (42±19, 16±9, 7±6%), medium (40±12, 15±11, 12±8%) and large airways (42±15, 23±18, 18±12%). The reduction in the percentage of apoptotic CD45RO+ cells in the cases of asthma was observed in both blood vessels and the interstitium in large airways. In conclusion, these data suggest that reduced apoptosis may prolong the active life of effector memory T-cells in the airways. It is possible that survival signals may be received before cells migrate into the interstitium of the inner airway wall.

In utero exposure to arsenic alters lung development and genes related to immune and mucociliary function in mice

Background: Exposure to arsenic via drinking water is a global environmental health problem. In utero exposure to arsenic via drinking water increases the risk of lower respiratory tract infections during infancy and mortality from bronchiectasis in early adulthood. Objectives: We aimed to investigate how arsenic exposure in early life alters lung development and pathways involved in innate immunity. Methods: Pregnant BALB/c, C57BL/6, and C3H/HeARC mice were exposed to 0 (control) or 100 μg/L arsenic via drinking water from gestation day 8 until the birth of their offspring. We measured somatic growth, lung volume, and lung mechanics of mice at 2 weeks of age. We used fixed lungs for structural analysis and collected lung tissue for gene expression analysis by microarray. Results: The response to arsenic was genetically determined, and C57BL/6 mice were the most susceptible. Arsenic-exposed C57BL/6 mice were smaller in size, had smaller lungs, and had impaired lung mechanics compared with controls. Exposure to arsenic in utero up-regulated the expression of genes in the lung involved in mucus production (Clca3, Muc5b, Scgb3a1), innate immunity (Reg3γ, Tff2, Dynlrb2, Lplunc1), and lung morphogenesis (Sox2). Arsenic exposure also induced mucous cell metaplasia and increased expression of CLCA3 protein in the large airways. Conclusions: Alterations in somatic growth, lung development, and the expression of genes involved in mucociliary clearance and innate immunity in the lung are potential mechanisms through which early life arsenic exposure impacts respiratory health.

Time to death and mast cell degranulation in fatal asthma

Background and objective:  Attacks of fatal asthma have been shown to be either of short duration or long duration and associated with differing degrees of smooth muscle contraction, luminal mucus deposition and ratios of eosinophils to neutrophils in the airway wall. We hypothesized that this bimodal distribution might be related to airway mast cell degranulation.

Airway remodelling in COPD: It's not asthma!

COPD is defined as airflow limitation that is not reversed by treatment. In asthma, airflow limitation is not only reversible, but also inducible. This is called ‘airway hyperresponsiveness’ (AHR) and is associated with thickening of the airway wall, predominantly the layer of airway smooth muscle, due to more cells, bigger cells and more extracellular matrix (ECM) in proportion to the increase in smooth muscle. AHR is also observed in COPD if the changes in airflow are expressed as a percent of the baseline lung function. However, the absolute change in baseline lung function that can be induced in COPD is actually less than that seen in normal subjects, suggesting that the airways in COPD are resistant not only to opening, but also to closing. This observation agrees with physiological measures showing increased airway wall stiffness in COPD. Like asthma, airway wall thickness is increased in COPD, including the layer of smooth muscle. Unlike asthma, however, fixed airflow obstruction appears to be characterized by a disproportionate increase in the ECM within the smooth muscle layer. In this review, we summarize the studies of airway matrix deposition in COPD and put forward the proposal that the airway remodelling in COPD is different from that in asthma and call for a systematic analysis of airway matrix deposition in COPD.