The ALS (agglutinin-like sequence) gene family of Candida albicans encodes eight cell-surface glycoproteins, some of which are involved in adherence to host surfaces. A mutational analysis of each ALS gene is currently being performed to deduce the functions of the encoded proteins and to better understand the role of these proteins in C. albicans biology and pathogenesis. This paper describes construction of an als3/als3 mutant and comparison of its phenotype to an als1/als1 strain. Efforts to disrupt ALS3 indicated that the gene could be deleted in two transformation steps, suggesting that the gene is encoded by a single locus and that the ALS3-like locus, ALS8, does not exist. Strains lacking ALS3 or ALS1 did not exhibit a defect in germ tube formation when grown in RPMI 1640 medium, but the als1/als1 mutant formed significantly fewer germ tubes in Lee medium. Analysis of ALS3 and ALS1 promoter activity using green fluorescent protein (GFP) reporter strains and flow cytometry showed that when cells are placed into medium that promotes germ tube formation, ALS1 is transcribed prior to ALS3. Comparison of the mutant strains in adhesion assays showed that the als3/als3 strain was defective in adhesion to both human umbilical vein endothelial cells (HUVEC) and buccal epithelial cells (BEC), but not to fibronectin-coated plastic plates. In contrast, the als1/als1 strain showed decreased adherence to HUVEC, but adherence to BEC and fibronectin were the same as wild-type controls. Inoculation of the buccal reconstituted human epithelium (RHE) model of oral candidiasis with the mutant strains showed nearly a total lack of adhesion and epithelial destruction by the als3/als3 mutant while the als1/als1 strain showed only a slightly reduced degree of epithelial destruction compared to the wild-type control. Adhesion data presented here suggest that, in the assays performed, loss of Als3p affects C. albicans adhesion more than loss of Als1p.Collectively, these results demonstrate functional similarities and differences between Als1p and Als3p, and suggest the potential for more complex interrelationships between the ALS genes and their encoded proteins.
CPFs are generally small and single, occur most often on valvular surfaces, and may be mobile, resulting in embolization. Because of the potential for embolic events, symptomatic patients, patients undergoing cardiac surgery for other lesions, and those with highly mobile and large CPFs should be considered for surgical excision.
Microarrays were used to identify changes in gene expression associated with Candida albicans biofilm development. Two biofilm substrates (denture and catheter), and two C. albicans strains for each substrate, were tested to remove model-and strain-dependent variability from the overall dataset. Three biofilm developmental phases were examined: early (6 h), intermediate (12 h), and mature (48 h). Planktonic specimens were collected at the same time points. Data analysis focused primarily on gene expression changes over the time-course of biofilm development. Glycolytic and non-glycolytic carbohydrate assimilation, amino acid metabolism, and intracellular transport mechanisms were important during the early phase of biofilm formation. These early events increase intracellular pools of pyruvate, pentoses and amino acids, which prepare the biofilm for the large biomass increase that begins around 12 h of development. This developmental stage demands energy and utilizes specific transporters for amino acids, sugars, ions, oligopeptides and lactate/pyruvate. At mature phase (48 h), few genes were differentially expressed compared with the 12 h time point, suggesting a relative lack of initiation of new metabolic activity. Data analysis to assess biofilm model-specific gene expression showed more dynamic changes in the denture model than in the catheter model. Data analysis to identify gene expression changes that are associated with each strain/substrate combination identified the same types of genes that were identified in the analysis of the entire dataset. Collectively, these data suggest that genes belonging to different, but interconnected, functional categories regulate the morphology and phenotype of C. albicans biofilm. INTRODUCTIONMicro-organisms attach to surfaces in many natural, industrial and medical environments and can develop into biofilms. Biofilms are a functional association of microbial cells that are enveloped within extracellular polymer matrices and associated with surfaces (Costerton et al., 1987;Donlan, 2002;Donlan & Costerton, 2002). Phenotypically, biofilm cells are different from planktonic (free-floating) cells (Costerton et al., 1995), with one of the most important manifestations of these differences being the significantly decreased susceptibility of microbial biofilms to antimicrobial agents (Rupp, 2005;Schwank et al., 1998;Stewart et al., 2004;Wilson, 1996). Although bacterial biofilms have been the focus of many studies, detailed investigations into the biology and pathogenesis of fungal biofilms have only recently been initiated (reviewed by Douglas, 2003;Ghannoum & O'Toole, 2004). Candida albicans is the most common fungal pathogen associated with colonization and biofilm formation on the surfaces of indwelling medical devices (IMDs) such as dentures and intravenous catheters (Kojic & Darouiche, 2004). Biofilm formation by C. albicans can promote superficial or systemic disease. For example, denture stomatitis, a superficial candidiasis, occurs in 65 % of denture-wearing Abbrevi...
An RT-PCR assay was developed to analyse expression patterns of genes in the Candida albicans ALS (agglutinin-like sequence) family. Inoculation of a reconstituted human buccal epithelium (RHE) model of mucocutaneous candidiasis with strain SC5314 showed destruction of the epithelial layer by C. albicans and also formation of an upper fungal layer that had characteristics similar to a biofilm. RT-PCR analysis of total RNA samples extracted from C. albicans-inoculated buccal RHE showed that ALS1, ALS2, ALS3, ALS4, ALS5 and ALS9 were consistently detected over time as destruction of the RHE progressed. Detection of transcripts from ALS7, and particularly from ALS6, was more sporadic, but not associated with a strictly temporal pattern. The expression pattern of ALS genes in C. albicans cultures used to inoculate the RHE was similar to that observed in the RHE model, suggesting that contact of C. albicans with buccal RHE does little to alter ALS gene expression. RT-PCR analysis of RNA samples extracted from model denture and catheter biofilms showed similar gene expression patterns to the buccal RHE specimens. Results from the RT-PCR analysis of biofilm RNA specimens were consistent between various C. albicans strains during biofilm development and were comparable to gene expression patterns in planktonic cells. The RT-PCR assay described here will be useful for analysis of human clinical specimens and samples from other disease models. The method will provide further insight into the role of ALS genes and their encoded proteins in the diverse interactions between C. albicans and its host.
Soluble guanylate cyclase as an alternative target for bronchodilator therapy in asthma
Asthma is defined by airway inflammation and hyperresponsiveness, and contributes to morbidity and mortality worldwide. Although bronchodilation is a cornerstone of treatment, current bronchodilators become ineffective with worsening asthma severity. We investigated an alternative pathway that involves activating the airway smooth muscle enzyme, soluble guanylate cyclase (sGC). Activating sGC by its natural stimulant nitric oxide (NO), or by pharmacologic sGC agonists BAY 41-2272 and BAY 60-2770, triggered bronchodilation in normal human lung slices and in mouse airways. Both BAY 41-2272 and BAY 60-2770 reversed airway hyperresponsiveness in mice with allergic asthma and restored normal lung function. The sGC from mouse asthmatic lungs displayed three hallmarks of oxidative damage that render it NO-insensitive, and identical changes to sGC occurred in human lung slices or in human airway smooth muscle cells when given chronic NO exposure to mimic the high NO in asthmatic lung. Our findings show how allergic inflammation in asthma may impede NO-based bronchodilation, and reveal that pharmacologic sGC agonists can achieve bronchodilation despite this loss.A sthma is an inflammatory disease that causes airway hyperreactivity (AHR) and bronchoconstriction, which impedes daily life activities and, when severe, can cause death. It is the most common chronic disease of childhood, accounts for one in three emergency department visits daily, and asthma diagnoses are increasing worldwide (1). The leading treatment for relief and acute care is bronchodilation, which relies heavily on the β-adrenergic receptor-cAMP pathway. Nearly 70% of patients, however, develop resistance or tachyphylaxis to the existing β-agonist therapy (2), underscoring a need for new bronchodilators that can act through a different pharmacologic principle.The nitric oxide-soluble guanylate cyclase-cGMP pathway (NO-sGC-cGMP) is the primary signal transduction pathway for relaxing vascular smooth muscle (3). In contrast, a role for the NO-sGC-cGMP pathway in relaxing airway smooth muscle is less clear (4, 5), and bronchodilation was instead suggested to depend on glutathione nitrosothiol levels in the lung (6, 7). However, recent studies have shown that inflammation can desensitize sGC toward its natural activator, NO (8), and new drugs have become available that directly activate sGC, independent of NO (9). These developments encouraged us to re-examine the NO-sGC-cGMP pathway regarding its role in bronchodilation, its becoming damaged in inflammatory asthma, and its potential for alternative bronchodilator development under this circumstance. ResultsThe NO-sGC-cGMP Pathway Bronchodilates Human Lung. We first tested if stimulating the NO-sGC-cGMP pathway would dilate preconstricted small airways in human precision-cut lung slices (PCLS) obtained from healthy donor lungs (Fig. 1A and Table S1). Graded doses of the slow-release NO donor DETA/NO [3,3-Bis(aminoethyl)-1-hydroxy-2-oxo-1-triazene] produced bronchodilation in human PCLS similar to what was ...
Candida albicans strain SC5314 contains two ALS3 alleles, which differ in sequence with respect to the number of copies of the 108 bp tandem repeat sequence within the central domain of the coding region. One allele (ALS3(12)) has 12 tandem repeat copies while the other (ALS3(9)) has 9 copies. Wild-type C. albicans (ALS3(12)/ALS3(9)) and those containing various ALS3 alleles (ALS3(12)/als3D(9), als3D(12)/ALS3(9) and als3D(12)/als3D(9)) were assayed for adhesion to monolayers of cultured vascular endothelial and pharyngeal epithelial cells. These assays showed obvious adhesive function for the larger Als3p protein, compared to a minor contribution to adhesion from the smaller protein. These functional differences in strain SC5314 prompted examination of ALS3 allelic diversity across the five major genetic clades of C. albicans. This analysis focused on the number of copies of the tandem repeat sequence within the central domain of the coding region and showed a range of alleles encoding from 6 to 19 tandem repeat copies. Clades differed with respect to prevalent ALS3 alleles and allele distribution, but were similar for the mean number of tandem repeat copies per ALS3 allele. Analysis of allelic pairing showed clade differences and the tendency for C. albicans strains to encode one longer and one shorter ALS3 allele. The allelic variability observed for ALS3 and its functional consequences observed in strain SC5314 highlight the importance of understanding ALS allelic diversity in order to draw accurate conclusions about Als protein function.
Haploinsufficiency of utrophin gene worsens skeletal muscle inflammation and fibrosis in mdx mice
To address whether mdx mice with haploinsufficiency of utrophin (mdx/utrn+/-) develop more severe skeletal muscle inflammation and fibrosis than mdx mice, to represent a better model for Duchenne muscular dystrophy (DMD), we performed qualitative and quantitative analysis of skeletal muscle inflammation and fibrosis in mdx and mdx/utrn+/- littermates. Inflammation was significantly worse in mdx/utrn+/- quadriceps at age 3 and 6 months and in mdx/utrn+/- diaphragm at age 3 but not 6 months. Fibrosis was more severe in mdx/utrn+/- diaphragm at 6 months, and at this age, mild fibrosis was noted in quadriceps of mdx/utrn+/- but not mdx mice. The findings indicate that utrophin compensates, although insufficiently, for the effects of dystrophin loss with regard to inflammation and fibrosis of both quadriceps and diaphragm muscles in mdx mice. With more severe muscle dystrophy than mdx mice and a longer life span than utrophin-dystrophin-deficient (dko) mice, mdx/utrn+/- mice provide a better mouse model for testing potential therapies for muscle inflammation and fibrosis associated with DMD.
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