Roger A. Renne

Proliferative and Nonproliferative Lesions of the Rat and Mouse Respiratory Tract

The INHAND Project (International Harmonization of Nomenclature and Diagnostic Criteria for Lesions in Rats and Mice) is a joint initiative of the Societies of Toxicologic Pathology from Europe (ESTP), Great Britain (BSTP), Japan (JSTP) and North America (STP) to develop an internationally-accepted nomenclature for proliferative and non-proliferative lesions in laboratory animals. The purpose of this publication is to provide a standardized nomenclature for classifying microscopic lesions observed in the respiratory tract of laboratory rats and mice, with color photomicrographs illustrating examples of some lesions. The standardized nomenclature presented in this document is also available electronically on the inter-net (http://www.goreni.org/). Sources of material included histopathology databases from government, academia, and industrial laboratories throughout the world. Content includes spontaneous developmental and aging lesions as well as lesions induced by exposure to test materials. A widely accepted and utilized international harmonization of nomenclature for respiratory tract lesions in laboratory animals will decrease confusion among regulatory and scientific research organizations in different countries and provide a common language to increase and enrich international exchanges of information among toxicologists and pathologists.

Gene Expression Profiling in Lung Tissues from Mice Exposed to Cigarette Smoke, Lipopolysaccharide, or Smoke Plus Lipopolysaccharide by Inhalation

The purpose of this study was to investigate whether coexposure to lipopolysacchride (LPS) will heighten the inflammatory response and other pulmonary lesions in mice exposed to cigarette smoke, and thus to evaluate the potential use of this LPS-compromised mouse model as a model for chronic obstructive pulmonary disease (COPD) investigation. AKR/J male mice were exposed to HEPA-filtered air (sham control group), cigarette smoke (smoke group), LPS (LPS group), or smoke plus LPS (smoke–LPS group) by nose-only inhalation. Lungs were collected at the end of the 3-wk exposure and processed for microarray analysis. Clustering and network analysis showed decreased heat-shock response and chaperone activity, increased immune and inflammatory response, and increased mitosis in all three exposed groups. Two networks/function modules were exclusively found in the smoke–LPS group, that is, the downregulated muscle development/muscle contraction process and the upregulated reactive oxygen species production process. Notably, the number of genes and function modules/networks associated with inflammation was reduced in the smoke–LPS group compared to the LPS group. The most upregulated gene in the smoke group, MMP12, is a matrix metalloproteinase that preferentially degrades elastin and has been implicated in COPD development. NOXO1, which was upregulated in all three treatment groups, positively regulates the expression of a subunit of NADPH oxidase (NOX1), a major source of reactive oxygen species, and may play an important role in the pathogenesis of COPD. Serum amyloid A1, which is an acute-phase systemic inflammation marker and can be induced by LPS exposure, was significantly upregulated in the LPS and smoke–LPS groups. MARCO, a scavenger receptor expressed in macrophages that may play a significant role in LPS-induced inflammatory response, was upregulated in the LPS group and the smoke–LPS group, but not in the smoke group. In conclusion, gene expression profiling identified genes and function modules that may be related to COPD pathogenesis and may be useful as biomarkers to monitor COPD progression. In addition, an LPS-compromised mouse model showed potential as a useful tool for studying cigarette smoke-associated COPD.

Histologic Methods and Interspecies Variations in the Laryngeal Histology of F344/N Rats and B6C3F1 Mice

The relatively high incidence and variety of lesions induced in the upper respiratory tract of rodents by inhalation of xenobiotics has resulted in considerable attention given to the microscopic anatomy of this area. Specific areas of the rodent laryngeal mucosa appear to be more sensitive to inhaled materials and more likely to contain cellular changes in response to injury. These include the epithelium covering the base of the epiglottis, ventral pouch, and the medial surfaces of the vocal processes of the arytenoid cartilages. There are few good landmarks for trimming rodent larynges to get consistent and accurate sections through these target areas. We have obtained consistently reproducible results by cutting transversely through the easily palpable cricothyroid notch and embedding the entire larynx anterior to this in paraffin with the cut surface against the face of the block. Multiple sections are cut from the caudal larynx toward the epiglottis, unstained sections examined microscopically for orientation, and sections from target areas selected for staining and histopathologic examination. Routine use of these methods for preparation and microscopic examination of sections of the larynx has revealed some variations in normal laryngeal anatomy between Fischer 344 (F344/N) rats and B6C3F1 mice.

2-Week and 13-Week Inhalation Studies of Aerosolized Glycerol in Rats

AbstractThe potential toxicity of aerosolized glycerol was studied by 2-wk and 13-wk nose-only inhalation exposures in Sprague-Dawley-derived (Cr1:CD) rats. In the first study, 10 ratslsedgroup received 10 nose-only exposures of 6 h/day for 2 wk over a 14-day period to mean aerosol concentrations of 0, 7.00 ± 0.08, 1.93 ± 0.123, or 3.91 ± 0.458 mg glycerol/l of filtered room air: Animals were observed for signs of toxicity twice daily, were weighed at 2– to 3-day intervals, and diet consumption was recorded at weekly intervals. All rats underwent complete necropsy, and designated tissues were weighed and examined histopathologically Blood was collected and analyzed for specific hematological and clinical chemistry parameters. The results of this study showed that rats exposed to 6-h nose-only inhalation for 70 days at all three concentrations of glycerol exhibited minimal to mild squamous metaplasia of the epithelium lining the base of the epiglottis. In a second study, 75 ratslsedgroup were exposed 6 h/d...

Effects of Flavoring and Casing Ingredients on the Toxicity of Mainstream Cigarette Smoke in Rats

A series of in vitro and in vivo studies evaluated the potential effects of tobacco flavoring and casing ingredients. Study 1 utilized as a reference control cigarette a typical commercial tobacco blend without flavoring ingredients, and a test cigarette containing a mixture of 165 low-use flavoring ingredients. Study 2 utilized the same reference control cigarette as used in study 1 and a test cigarette containing eight high-use ingredients. The in vitro Ames Salmonella typhimurium assay did not show any increase in mutagenicity of smoke condensate from test cigarettes designed for studies 1 and 2 as compared to the reference. Sprague-Dawley rats were exposed by nose-only inhalation for 1 h/day, 5 days/wk for 13 wk to smoke from the test or reference cigarettes already described, or to air only, and necropsied after 13 wk of exposure or following 13 wk of recovery from smoke exposure. Exposure to smoke from reference or test cigarettes in both studies induced increases in blood carboxyhemoglobin ((COHb)) and plasma nicotine, decreases in minute volume, differences in body or organ weights compared to air controls, and a concentration-related hyperplasia, squamous metaplasia, and inflammation in the respiratory tract. All these effects were greatly decreased or absent following the recovery period. Comparison of rats exposed to similar concentrations of test and reference cigarette smoke indicated no difference at any concentration. In summary, the results did not indicate any consistent differences in toxicologic effects between smoke from cigarettes containing the flavoring or casing ingredients and reference cigarettes.

Inhalation Toxicity Studies of Cobalt Sulfate in F344/N Rats and B6C3F1 Mice

Groups of 10 F344/N rats and B6C3F1 mice of each sex were exposed to cobalt sulfate heptahydrate aerosols of 0, 0.3, 1.0, 3.0, 10, or 30 mg/m3, 6 hr per day, 5 days per week, for 13 weeks. All rats and female mice and all but 2/10 male mice exposed at the top concentration survived to the end of the studies. Polycythemia was observed in exposed rats but not in mice. Sperm motility was decreased in mice exposed at 3 mg/m3 (the lowest concentration evaluated) and at higher concentrations, and increased numbers of abnormal sperm and decreased testis and epididymal weights occurred in mice exposed to 30 mg/m3. Cobalt content in the urine of rats increased with increasing atmospheric cobalt exposure. Primary histopathologic effects were limited to the respiratory tract. Lesions in rats and mice included degeneration of the olfactory epithelium, squamous metaplasia of the respiratory epithelium, and inflammation in the nose; inflammation, necrosis, squamous metaplasia, ulcers (rats), and inflammatory polyps (rats) of the larynx; metaplasia of the trachea (mice); and fibrosis, histiocytic infiltrates, bronchiolar epithelial regeneration, and epithelial hyperplasia in the alveoli of the lung. The most sensitive tissue was the larynx, with squamous metaplasia observed in rats and mice at the lowest exposure concentration of 0.3 mg/m3. Thus, a no-observed-adverse-effect level was not reached in these studies.

Upper Respiratory Tract Lesions in Inhalation Toxicology

This paper describes some important differences in normal histology of the upper respiratory tract of laboratory animals. It also provides examples of lesions observed or reported in the upper respiratory tract of laboratory animals, predominantly rodents, exposed via inhalation. The anatomy and physiology of upper respiratory tract tissues play a major role in the response to an insult, given that different epithelial types vary in susceptibility to injury and toxicant exposure concentrations throughout the airway vary due to airflow dynamics. Although dogs and nonhuman primates are utilized for inhalation toxicology studies, less information is available regarding sites of upper respiratory injury and types of responses in these species. Awareness of interspecies differences in normal histology and zones of transition from squamous to respiratory to olfactory epithelium in different areas of the upper respiratory tract is critical to detection and description of lesions. Repeated inhalation of chemicals, drugs, or environmental contaminants induces a wide range of responses, depending on the physical properties of the toxicant and concentration and duration of exposure. Accurate and consistent fixation, trimming, and microtomy of tissue sections using anatomic landmarks are critical steps in providing the pathologist the tools needed to compare the morphology of upper respiratory tract tissues from exposed and control animals and detect and interpret subtle differences.

Pulmonary Inflammation in Mice Exposed to Mainstream Cigarette Smoke

Male C57Bl/6 (C57) and ICR mice were exposed by nose-only inhalation to mainstream cigarette smoke (MS) from 2R4F reference cigarettes, at concentrations of 75, 250, and 600 μ g of total particulate matter (TPM) per liter, for up to 6 mo. Respiratory-tract tissue (nose, larynx, and lung), blood, and bronchoalveolar lavage fluid (BALF) samples were collected and analyzed at several time points. Blood samples were analyzed for biomarkers of exposure (COHb and nicotine). BALF was analyzed for biomarkers of cell injury, inflammation, oxidative stress, enzyme activity, and cytokines. Blood COHb and plasma nicotine concentrations increased in a dose-dependent manner, confirming smoke exposure. Mild emphysema was observed following 28 wk of exposure. Macrophage accumulation and inflammatory infiltrates were observed around the alveolar ducts and adjacent vasculature. There was a ∼ 13% increase in mean linear intercept (Lm) only in ICR mice exposed to 600 μ g/L TPM. There were no significant changes in biomarkers of oxidative stress secondary to smoke exposures; however, 8-isoprostane significantly increased following the 13-wk post-inhalation period. BALF macrophage and neutrophil counts were rapidly and consistently elevated, while lymphocyte counts gradually increased over time. MS-induced inflammatory responses observed in this study are comparable to changes reported in chronic smokers, supporting the role of chronic inflammation in the pathogenesis of emphysema. However, mild emphysema in minimal numbers of mice suggests that MS exposure concentration and/or duration in the current study were not sufficient to induce a definitive emphysema phenotype.

3-week inhalation exposure to cigarette smoke and/or lipopolysaccharide in AKR/J mice.

AKR/J mice were exposed to cigarette smoke (CS) and/or lipopolysaccharide (LPS) via inhalation for 3 wk and pulmonary responses were evaluated. The objective was to explore the feasibility of coexposing LPS with cigarette smoke under a subacute exposure, as a surrogate for viral or bacterial insults, that would mimic the pathogenesis of infection-related chronic obstructive pulmonary disease (COPD) exacerbations. The study was the first step in an effort to develop a rodent COPD model in which morphologic lesions of COPD develop in a shorter period of exposure and more closely simulate human COPD. Mice were exposed 6 h/day, 5 days/wk for 3 wk to one of the following: (1) sham control: filtered air; (2) CS: 250 μg/L wet total particulate matter (WTPM) for 5 h/day followed by 1 h/day air; (3) LPS: 0.5 μg/L LPS (055:B5 Escherichia coli; 3,000,000 EU/mg) for the last 1 h/day 2 day/wk (following 5 h/day of filtered air); and (4) CS/LPS: CS 5 h/day followed by air or LPS (2 days/wk) for 1 h/day. After the last exposure, animals were necropsied and subjected to bronchoalveolar lavage (BAL) or histopathology. The BAL neutrophil counts were highest in the LPS group, while macrophage counts were higher in the CS/LPS group than other exposed groups. The LPS group displayed the greatest increases in BAL cytokines, while KC (keratinocyte-derived chemokine) and TARC (thymus and activation-regulated chemokine) were highest in the CS group. The CS/LPS group had generally lower cytokine levels relative to the LPS or CS groups, except for the levels of RANTES and G-CSF (granulocyte-colony stimulating factor) comparable to the LPS group. At microscopic examination of lung sections, celluar inflammatory infiltrates were most notable in the CS/LPS group, which had a diffuse, predominantly macrophage infiltrate with fewer neutrophils. The LPS group had predominantly neutrophils in the pulmonary infiltrate and the CS group had a predominantly macrophage inifiltrate in alveolar ducts and adjacent alveoli. Apoptotic labeling of lung cells was highest with the CS/LPS group. In summary, the CS/LPS group displayed greater cellular infiltration and apoptotic responses in the lung with an indication of immunosuppressive effects (lower BAL cytokines) than the CS or LPS group, suggesting that the CS/LPS model shows promise to be further explored as an animal model for studying pathogenesis of COPD exacerbations. A longer term study with interim assessments is needed to confirm that the subacute responses observed in the CS/LPS group will result in greater severity of COPD-related pulmonary lesions following prolonged exposures.

Types and Patterns of Response in the Larynx Following Inhalation

The laryngeal mucosa responds to insult similarly to other epithelial tissues but the response depends on location within the larynx since important anatomic differences exist, even within rodent species. Although dogs and nonhuman primates are also utilized for inhalation toxicology studies, little published information is available regarding sites of injury from inhaled toxicants in these species. Accurate and consistent fixation, trimming, and microtomy of laryngeal sections allow the pathologist to compare the morphology of laryngeal mucosa from exposed and control animals and detect and interpret subtle differences resulting from inhalation exposure. There are anatomic landmarks that are keys to providing consistent sections through important areas of the laryngeal mucosa. Repeated inhalation of toxic concentrations of chemicals, drugs, or environmental contaminants induces a wide range of responses, depending on the physical properties and concentration of the toxic substance and duration of exposure. Responses include edema, acute to chronic inflammation, fibrosis, mucosal ulceration, degeneration, and necrosis. Attempts at repair include regeneration, hyperplasia, squamous metaplasia, hyperkeratosis, and neoplasia. Awareness of normal histology and zones of transition from squamous to respiratory epithelium in different areas of the larynx in different species is critical to avoid confusing normal epithelium with metaplasia or hyperplasia. Microscopic examination of laryngeal mucosa from animals exposed via inhalation and necropsied following a recovery period provides the opportunity to determine the degree of regression or progression of exposure-induced laryngeal lesions.