The pathogenesis of Malassezia yeasts

The genus Malassezia includes twelve species of yeast, many of which have been mainly associated with human and canine diseases. Malassezia pachydermatis colonizes the skin and mucosal sites of healthy dogs and cats. Despite being part of the normal cutaneous microflora, Malassezia spp. yeast may become pathogenic under certain circumstances. This article reviews the factors related to both host and yeast which affect the pathogenical or commensal phenotypes of Malassezia yeasts.     

In vitro modulation of human keratinocyte pro- and anti-inflammatory cytokine production by the capsule of Malassezia species

Malassezia spp. are commensal, cutaneous fungi that are implicated in seborrhoeic dermatitis. We hypothesize that the lipid-rich capsule of Malassezia spp. masks the organism from host detection, and depletion of this layer elicits an inflammatory response. To test this, preparations of capsulated or acapsular [10% (v/v) Triton X-100 treated], viable and nonviable, exponential or stationary phase Malassezia furfur, Malassezia globosa, Malassezia obtusa, Malassezia restricta, Malassezia slooffiae and Malassezia sympodialis, were incubated with normal human keratinocytes. Proinflammatory (IL-6, IL-8, IL-1alpha and tumour necrosis factor-alpha) and anti-inflammatory cytokine (IL-10) release and intracellular IL-10 concentrations were quantified using enzyme-linked immunosorbent assays. Capsulated Malassezia yeasts stimulated limited or no production of inflammatory cytokines, and increased intracellular IL-10 (P < 0.05). Removal of the capsule of many Malassezia preparations caused a significantly increased production of IL-6, IL-8 and IL-1alpha, and a decrease in intracellular IL-10. Notably, acapsular viable, stationary phase M. globosa caused a 66-fold increase in IL-8 production (P < 0.001) and acapsular nonviable, stationary phase M. furfur caused a 38-fold increase in IL-6 production (P < 0.001) and a 12-fold decrease in intracellular IL-10 (P < 0.001). These results support the hypothesis that the lipid layer of Malassezia spp. modulates cytokine production by keratinocytes. This has implications in the pathogenesis of seborrhoeic dermatitis.     

马拉色菌相关人群及正常人群耳耵聍中马拉色菌带菌情况的调查

目的调查马拉色菌相关人群及正常人群耳耵聍中马拉色菌带菌情况。方法用结晶紫染色法对96例被调查人群耳耵聍进行马拉色菌检测,同时作培养,并以标准株作对照,用生理生化方法将耵聍中分离到的79株马拉色菌进行分类。结果马拉色菌相关人群耳耵聍中马拉色菌的直接检出率为91．84％（45／49）,培养阳性率为81．63％（40／49）,其中厚皮马拉色菌8株（16．33％）,合轴马拉色菌10株（20．41％）,糠秕马拉色菌22株（44．90％）。正常人群耳耵聍马拉色菌直接检出率为89．36％（42／47）,培养阳性率为78．72％（37／47）,其中厚皮马拉色菌5株（10．64％）,合轴马拉色菌8株（17．02％）,糠秕马拉色菌23株（48．93％）,斯洛菲马拉色菌1株（2．13％）。结论马拉色菌为正常人群及马拉色菌相关人群外耳道正常菌群,两组人群中马拉色菌的分离率和菌种分布无显著性差异。     

Onychomycosis due to Malassezia.

The records of fifty patients presenting Malassezia spp. associated onychomycosis were compiled from two different mycology laboratories from Medellín, Colombia. Malassezia spp. was isolated by culture as the only etiological agent in 32% of the cases and associated to a yeast of the genus Candida in 30% of the cases. In 22% of the cases although Malassezia spp. was observed by direct examination, it was no isolated but others species were obtained. No etiological agent was isolated by culture in 16% of the cases. We found evidence of the Malassezia spp.- Candida relationship in 48% of the cases by either direct examination or by culture isolation. The level of detection of Malassezia spp. by culture isolation was of 62% as compared to the direct examination. Results showed similar patterns of distribution of epidemilogical factors for both entities: onychomycosis by Candida albicans and onychomycosis by Malassezia spp.     

Occurrence of Malassezia species in healthy and dermatologically diseased dogs

The presence of Malassezia spp. yeasts was investigated in dermatological specimens of 224 dogs, 164 dermatologically diseased and 60 normal dogs. Subjects included in the study were of different breed, age, sex and habitat. Malassezia spp. positive cultures were obtained in 142 (63.4%) specimens: 67.6% from dermatologically diseased subjects and 51.6% from healthy dogs. Malassezia pachydermatis, either as a pure culture or in association with lipid-dependent species, was identified in 138 (97%) specimens. Malassezia furfur was identified in 69 (48.6%) specimens and was associated with other Malassezia species in 68 dogs, as a pure culture in one subject: at the best of our knowledge, this species was identified before as the sole species from canine dermatitis. Malassezia sympodialis was identified in 11 (7.7%) specimens, always in association with other species: it was never isolated from kennel dogs. Statistical analysis of data showed a very significant difference (P < 0.01) in the prevalence of isolation of Malassezia spp. between animals with and without dermatological signs, and in the distribution of cultural burden between diseased and healthy dogs. A statistically significant difference (P<0.05) was also detected in the group of animals between 1- and 5-years of age. No significant difference was found between male and female dogs.     

Taxonomy of Malassezia furfur: state of the art

Malassezia furfur is a lipophilic yeast considered as a normal component of the human skin flora. Apart from pityriasis versicolor, M. furfur has been linked to several skin diseases such as seborrheic dermatitis, folliculitis or atopic dermatitis. Moreover, these yeasts have been reported as agent of invasive human diseases including pneumonia, catheter-associated sepsis and peritonitis. The existence of morphological, serological, metabolical, biochemical and karyotipical differences has been described among isolates of these yeasts. These observations gave arguments for a possible intraspecific division, and this hypothesis has been confirmed by the existence of six species within the formerly called M. furfur (lipid-dependent Malassezia strains): M. furfur, Malassezia sympodialis, Malassezia globosa, Malassezia obtusa, Malassezia restricta and Malassezia slooffiae.     

Epidemiology and variability of Malassezia spp

A short review on Malassezia spp., completed with our experience, is made. The main epidemiological characteristics with particular regard to the diffusion in several animal species, the characteristics of skin colonization (in particular of the dog) and the distribution of the different Malassezia spp. in some hosts are discussed. Lastly the main phenotypic and genotypic characteristics, referred to M. pachydermatis especially, were described, showing their high variability and differentiation.     

Evaluation of angiogenesis in normal and lichen planus skin by CD34 protein immunohistochemistry: preliminary findings

Angiogenesis is a critical component of both neoplastic and chronic inflammatory disorders, but whether angiogenesis also occurs in inflammatory skin diseases (such as lichen planus) has yet to be established. This study tests the hypothesis that the development of cutaneous lichen planus is associated with alterations of dermal vascularization (microvessel density, MVD). Thirty cases of cutaneous lichen planus and 40 cases of normal skin were studied. Dermal microvessels were immunostained for CD34 and counted in 10 areas with the highest numbers of microvessels; the mean value represented the final MVD. Compared with normal skin, dermal microvessel density was increased in cutaneous lichen planus [mean, 2.50 (SEM, 0.09) versus 1.39 (SEM, 0.12)]. The microvessel number was higher in the dermal inflammatory infiltrate (intralichenoid infiltrate) and at dermoepidermal junction (below Max-Josef space) compared with adventitial dermis [mean, 2.50 (SEM, 0.09) versus 1.6 (SEM, 0.10)]. The higher MVD values in cutaneous lichen planus suggest a possible link between angiogenesis, and development of these cutaneous lesions. These results provide a morphological evidence of potent angiogenic activity in cutaneous lichen planus, indicating that the local microvasculature may undergo an intense process of inflammation-dependent angiogenesis.     

Skin diseases associated with Malassezia species in humans. Clinical features and diagnostic criteria

Malassezia yeasts not only cause the well known pityriasis versicolor and folliculitis, but also play an important role in other skin diseases, including seborrheic dermatitis and atopic dermatitis. The presence of Malassezia yeasts may be confirmed by direct microscopic examination and cultures of skin scrapings. In pityriasis versicolor the direct microscopic examination is the rapidest and surest test for confirming the clinical diagnosis. The preparation will show a cluster of globose budding spores with thick or double wall and short hyphae. For detecting Malassezia in the other diseases the cultures is preferable. Culture is useful both for confirming the clinical diagnosis and for epidemiological investigations. The identification of the Malassezia species is not easy. The microscopic observation of the colony direct towards the identification of Malassezia species, but it is not enough to identify the colonies definitely. Several biochemical tests are necessary for a precise identification, such as catalase reaction, growth on media without lipid sources, ability to utilize hydrophilic emulsifiers as sole lipid source, esculin test, tryptophan test.     

正常人耵聍中马拉色菌菌种构成研究

目的研究正常人耵聍中马拉色菌菌种构成及同一宿主耵聍中菌种是否一致。方法采集45名健康志愿者双侧耵聍,0.1%曲拉通X-100溶解稀释后接种于含菜籽油培养基,生化及形态学方法鉴定到种,同时提取菌种DNA,用真菌通用引物ITS1/ITS4做PCR扩增并测序鉴定。结果有44例(97.78%)双侧耵聍中均培养出马拉色菌(共分离出88株菌),菌种构成:糠粃马拉色菌29株(32.95%)、斯洛菲马拉色菌23株(26.14%)、合轴马拉色菌18株(20.45%)、球形马拉色菌11株(12.50%)、限制性马拉色菌7株(7.95%)。44例(88株菌)中双侧耵聍菌种相同者有38例(76株菌)(一致率86.36%)。结论正常人耵聍中马拉色菌菌种分布较广,主要菌种为糠秕马拉色菌。同一宿主双侧耵聍中马拉色菌菌种具有一定的一致性。     

Concordance between phenotypical features and PCR-REA for the identification of Malassezia spp

The genus Malassezia has been recently revised and nowadays includes 11 species that cannot always be differentiated from each other by physiological and morphological tests. This study was aimed to evaluate the correlation between a molecular method and conventional phenotypic features in the identification of Malassezia spp. To achieve this aim, 92 Argentinean clinical strains isolated between 2001 and 2005 were analyzed along with three reference strains (Malassezia furfur CBS 7019, Malassezia sympodialis CBS 7222 and Malassezia slooffiae CBS 7956). By using PCR and restriction enzyme analysis with three different DNA endonucleases (PCR-REA), the molecular method consistently identified all three reference strains and all 92 clinical isolates as follows: 63 M. sympodialis, 18 M. furfur, 10 Malassezia globosa and one Malassezia obtusa. Phenotypic studies undentified 85 clinical isolates and two of the reference strains (total agreement > 91%). In particular for M. sympodialis, M. furfur and M. globosa, the species more frequently involved in human pathology, the agreement ranged between 84 and 96%. This result suggests that phenotypic studies are suitable for the presumptive identification of important Malassezia species in the clinical medical mycology laboratories where molecular methodologies are not available.     

Phenotypic switching in fungi

Over the past three decades new fungal diseases have emerged that now constitute a major threat, especially for patients with chronic diseases and/or underlying immune deficiencies. Despite the epidemiologic data, the emergence of stable drug-resistant or hypervirulent fungal strains in human disease has not been demonstrated as seen in emerging viral and bacterial infections. Fungi are eukaryotic microbes that capitalize on a sophisticated built-in ability to generate phenotypic variability. This successful strategy allows them to undergo rapid adaptation in response to environmental challenges, such as individual body locations that may exhibit drastic differences in temperature and pH. Rapid microevolution can also confer drug resistance and protect them from the host’s immune response. This review explores phenotypic switching in pathogenic fungi, including Candida spp and Cryptococcus spp, and how phenotypic switching contributes to the pathogenesis of fungal diseases.     

Quantitative analysis of cutaneous malassezia in atopic dermatitis patients using real-time PCR

We quantified the cutaneous Malassezia in patients with atopic dermatitis using a real-time PCR assay. Seven to 12 times more Malassezia colonized the head and neck compared to the trunk or limbs, and the species M. globosa and M. restricta accounted for approximately 80% of all Malassezia colonization at any body site.     

Histopathological diagnosis of mycoses

Infectious diseases emerge as a cause of pathology in our patients. Among the possible etiologies, mycoses have shown a considerable increase in the two last decades. In general, the clinical features of fungal diseases are not very distinctive. The morphology and the clinical aspects of the fungi serve as a protocol for their correct identification. Clinicians, microbiologists and pathologists are essential for the diagnosis. The pathologist using a simple and fast methodology can diagnose some types of mycosis, but they do not only identify the causal agent, but also the kind of injury that produces, the inflammatory response and the affected organ or organs. Moreover, they can classify the mycosis as superficial, cutaneous, subcutaneous, deep and systemic depending on the location. The present review paper describes study guidelines for the pathologist faced with a fungal infection and new technical advances that are established in pathology laboratories for a more precise identification of the mycoses.     

Inhalation of environmental stressors & chronic inflammation: autoimmunity and neurodegeneration

Human life expectancy and welfare has decreased because of the increase in environmental stressors in the air. An environmental stressor is a natural or human-made component present in our environment that upon reaching an organic system produces a coordinated response. This response usually involves a modification of the metabolism and physiology of the system. Inhaled environmental stressors damage the airways and lung parenchyma, producing irritation, recruitment of inflammatory cells, and oxidative modification of biomolecules. Oxidatively modified biomolecules, their degradation products, and adducts with other biomolecules can reach the systemic circulation, and when found in higher concentrations than normal they are considered to be biomarkers of systemic oxidative stress and inflammation. We classify them as metabolic stressors because they are not inert compounds; indeed, they amplify the inflammatory response by inducing inflammation in the lung and other organs. Thus the lung is not only the target for environmental stressors, but it is also the source of a number of metabolic stressors that can induce and worsen pre-existing chronic inflammation. Metabolic stressors produced in the lung have a number of effects in tissues other than the lung, such as the brain, and they can also abrogate the mechanisms of immunotolerance. In this review, we discuss recent published evidence that suggests that inflammation in the lung is an important connection between air pollution and chronic inflammatory diseases such as autoimmunity and neurodegeneration, and we highlight the critical role of metabolic stressors produced in the lung. The understanding of this relationship between inhaled environmental pollutants and systemic inflammation will help us to: (1) understand the molecular mechanism of environment-associated diseases, and (2) find new biomarkers that will help us prevent the exposure of susceptible individuals and/or design novel therapies.     

Crystal structure of the major Malassezia sympodialis allergen Mala s 1 reveals a beta-propeller fold: a novel fold among allergens

Atopic eczema (AE) is a chronic inflammatory disease in which genetic predisposition and environmental factors such as microorganisms contribute to the symptoms. The yeast Malassezia Sympodialis, part of the normal human cutaneous flora, can act as an allergen eliciting specific IgE and T-cell reactivity in patients with AE. The major M. sympodialis allergen Mala s 1 is localized mainly in the yeast cell wall and exposed on the cell surface. Interestingly, Mala s 1 does not exhibit any significant sequence homology to known proteins. Here we present the crystal structure of Mala s 1 determined by single-wavelength anomalous dispersion techniques using selenomethionine-substituted Mala s 1. Mala s 1 folds into a 6-fold beta-propeller, a novel fold among allergens. The putative active site of Mala s 1 overlaps structurally to putative active sites in potential homologues, Q4P4P8 and Tri 14, from the plant parasites Ustilago maydis and Gibberella zeae, respectively. This resemblance suggests that Mala s 1 and the parasite proteins may have similar functions. In addition, we show that Mala s 1 binds to the phosphoinositides (PI) PI(3)P, PI(4)P, and PI(5)P, lipids possibly playing a role in the localization of Mala s 1 to the cell surface. The crystal structure of Mala s 1 will provide insights into the role of this major allergen in the host-microbe interactions and induction of an allergic response in AE.     

Cytokines, growth factors, and plastic surgery.

Numerous inflammatory cytokines and growth factors have been identified and are known to be essential for normal wound healing and host defense, and many have been implicated in disease states treated by plastic surgeons. Cytokines and growth factors are members of a large functional group of polypeptide regulatory molecules secreted by different cell lines. These peptides exert their influence through autocrine and paracrine fashions within sites of injury and repair. Although cytokines and growth factors are crucial in initiating, sustaining, and regulating the postinjury response, these same molecules have been implicated in impaired wound healing, abnormal scarring, and chronic cutaneous diseases. Therapeutic manipulation of inflammatory mediators in normal and impaired wounds has been performed, with mixed clinical results, but evolving strategies such as gene therapy, as well as further characterization of the cellular-mechanism cytokines and growth-factor triggers, will further add to our therapeutic options. This article discusses the current understanding of important cytokines and growth factors involved in the normal injury response and then addresses pathological states associated with an inappropriate expression of these mediators. Finally, a summary of various cytokine and growth factor-directed strategies being used in impaired wound healing states is presented.     

Outbreak of sarcoptic mange and malasseziasis in rabbits (Oryctolagus cuniculus)

An outbreak of combined Sarcoptes and Malassezia spp. infection was diagnosed in a rabbitry. About 20 (4%) of 500 rabbits were affected. Two 6- to 8-month-old female Holland Lops rabbits were submitted to the Tifton Diagnostic & Investigational Laboratory at The University of Georgia for complete necropsy. Gross lesions consisted of marked multifocal areas of alopecia, crusting, and dermatitis around the eye and on ears, nose, lips, neck, abdomen, feet, and external genitalia. Histologic examination of the skin revealed epidermal acanthosis with marked parakeratotic hyperkeratosis and cross sections of embedded mites consistent with Sarcoptes sp. and budding yeasts consistent with Malassezia sp. To the best of the author's knowledge, this is the first case report of combined Sarcoptes and Malassezia spp. infection in rabbits.