New reports of pathogen spectrum associated with bulb rot and their interactions during the development of rot in tulip.

Bulb rot, a highly damaging disease of tulip plants, has hindered their profitable cultivation worldwide. This rot occurs in both field and storage conditions posing significant challenges. While this disease has been attributed to a range of pathogens, previous investigations have solely examined it within the framework of a single-pathogen disease model. Our study took a different approach and identified four pathogens associated with the disease: Fusarium solani, Penicillium chrysogenum, Botrytis tulipae, and Aspergillus niger. The primary objective of our research was to examine the impact of co-infections on the overall virulence dynamics of these pathogens. Through co-inoculation experiments on potato dextrose agar, we delineated three primary interaction patterns: antibiosis, deadlock, and merging. In vitro trials involving individual pathogen inoculations on tulip bulbs revealed that B. tulipae,was the most virulent and induced complete bulb decay. Nonetheless, when these pathogens were simultaneously introduced in various combinations, outcomes ranged from partial bulb decay to elongated rotting periods. This indicated a notable degree of antagonistic behaviour among the pathogens. While synergistic interactions were evident in a few combinations, antagonism overwhelmingly prevailed. The complex interplay of these pathogens during co-infection led to a noticeable change in the overall severity of the disease. This underscores the significance of pathogen-pathogen interactions in the realm of plant pathology, opening new insights for understanding and managing tulip bulb rot.

Proteome analysis of the penicillin producer Penicillium chrysogenum: characterization of protein changes during the industrial strain improvement.

Proteomics is a powerful tool to understand the molecular mechanisms causing the production of high penicillin titers by industrial strains of the filamentous fungus Penicillium chrysogenum as the result of strain improvement programs. Penicillin biosynthesis is an excellent model system for many other bioactive microbial metabolites. The recent publication of the P. chrysogenum genome has established the basis to understand the molecular processes underlying penicillin overproduction. We report here the proteome reference map of P. chrysogenum Wisconsin 54-1255 (the genome project reference strain) together with an in-depth study of the changes produced in three different strains of this filamentous fungus during industrial strain improvement. Two-dimensional gel electrophoresis, peptide mass fingerprinting, and tandem mass spectrometry were used for protein identification. Around 1000 spots were visualized by "blue silver" colloidal Coomassie staining in a non-linear pI range from 3 to 10 with high resolution, which allowed the identification of 950 proteins (549 different proteins and isoforms). Comparison among the cytosolic proteomes of the wild-type NRRL 1951, Wisconsin 54-1255 (an improved, moderate penicillin producer), and AS-P-78 (a penicillin high producer) strains indicated that global metabolic reorganizations occurred during the strain improvement program. The main changes observed in the high producer strains were increases of cysteine biosynthesis (a penicillin precursor), enzymes of the pentose phosphate pathway, and stress response proteins together with a reduction in virulence and in the biosynthesis of other secondary metabolites different from penicillin (pigments and isoflavonoids). In the wild-type strain, we identified enzymes to utilize cellulose, sorbitol, and other carbon sources that have been lost in the high penicillin producer strains. Changes in the levels of a few specific proteins correlated well with the improved penicillin biosynthesis in the high producer strains. These results provide useful information to improve the production of many other bioactive secondary metabolites.

Molds, mycotoxins, and sick building syndrome.

The following is a review of some of the work we have done since 2004 regarding the importance of molds and their mycotoxins in the phenomenon of sick building syndrome (SBS). In these studies we showed that the macrocyclic trichothecene mycotoxins (MTM) of Stachybotrys chartarum (SC) are easily dissociated from the surface of the organism as it grows and could therefore be consequently spread in buildings as the fungus experiences additional water events. We then showed that SC and Penicillium chrysogenum (PC) colonies remain viable long after a water source has been removed, and the MTM produced by SC remain toxic over extended periods of time. We next showed that PC when inhaled, can release in vivo, a protease allergen that can cause a significant allergic inflammatory reaction in the lungs of mice. We then showed, in a laboratory study, that the MTM of SC can become airborne attached to spores or SC particulates smaller than spores. Following that study, we next showed that the same phenomenon actually occurred in SC infested buildings where people were complaining of health problems potentially associated with SBS. Finally, we were able to demonstrate the presence of MTM in the sera of individuals who had been exposed to SC in indoor environments. This last study was done with enough mold exposed individuals to allow for the statistical significance of SC exposure to be evaluated.

Increased neurotrophin production in a Penicillium chrysogenum-induced allergic asthma model in mice.

Neurotrophins, including nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), and neurotrophin (NT)-3, have been implicated in the pathogenesis of many features and symptoms of asthma. The role of neurotrophins in fungal allergic asthma, however, is unknown. Repeated pulmonary challenge with Penicillium chrysogenum extract (PCE) induces dose-dependent allergic asthma-like responses in mice. The aim of this study was to investigate whether neurotrophins are involved in the PCE-induced allergic airway response in mice. Mice were exposed to 10, 20, 50, or 70 microg PCE by involuntary aspiration 4 times over 1 mo. Bronchial alveolar lavage fluid (BALF) was collected immediately before and after the final exposure. The levels of NGF, NT-3, and NT-4 were determined by enzyme-linked immunosorbent assay (ELISA). The lungs were fixed and processed for immunohistochemical examination of NGF production. PCE-exposed mice had dose-dependent increases in NGF, NT-3, and NT-4 in both BALF and sera. Exposures to PCE produced elevation in positive immunohistochemical staining for NGF in the airway epithelium and smooth muscle cells, in addition to infiltrated cells such as mononuclear cells, eosinophils, and macrophages. Taken together, this is the first study to link fungal allergic asthma in an experimental model with enhanced production of neurotrophins in the airways, and suggests that neurotrophins may play a role in the etiology of mold-induced asthma in humans.

Intestinal invasion and disseminated disease associated with Penicillium chrysogenum.

BACKGROUND: Penicillium sp., other than P. marneffei, is an unusual cause of invasive disease. These organisms are often identified in immunosuppressed patients, either due to human immunodeficiency virus or from immunosuppressant medications post-transplantation. They are a rarely identified cause of infection in immunocompetent hosts. CASE PRESENTATION: A 51 year old African-American female presented with an acute abdomen and underwent an exploratory laparotomy which revealed an incarcerated peristomal hernia. Her postoperative course was complicated by severe sepsis syndrome with respiratory failure, hypotension, leukocytosis, and DIC. On postoperative day 9 she was found to have an anastamotic breakdown. Pathology from the second surgery showed transmural ischemic necrosis with angioinvasion of a fungal organism. Fungal blood cultures were positive for Penicillium chrysogenum and the patient completed a 6 week course of amphotericin B lipid complex, followed by an extended course oral intraconazole. She was discharged to a nursing home without evidence of recurrent infection. DISCUSSION: Penicillium chrysogenum is a rare cause of infection in immunocompetent patients. Diagnosis can be difficult, but Penicillium sp. grows rapidly on routine fungal cultures. Prognosis remains very poor, but aggressive treatment is essential, including surgical debridement and the removal of foci of infection along with the use of amphotericin B. The clinical utility of newer antifungal agents remains to be determined.

Culturability and toxicity of sick building syndrome-related fungi over time.

Two experiments were conducted regarding the culturability and toxicity of fungi located on building materials over time and the efficacy of seven laboratory techniques in recovering culturable fungi from sample swabs. In the first experiment, eight sections of drywall were inoculated with Stachybotrys chartarum and stored at 25 +/- 5 degrees Celsius and 20-60% relative humidity (RH) for up to two years. Another eight sections of ceiling tile were stored at 100% RH for 1 year. Six sections of ceiling tile and 15 swabs were also inoculated with Penicillium chrysogenum and S. chartarum respectively and stored under the same conditions for 8 months and 3.3 years. All materials were tested for culturability at the end of the storage period. S. chartarum-inoculated samples were also tested for toxicity. In the second experiment (replicated twice), S. chartarum and Chaetomium globosum were inoculated onto 84 swabs each. Storage was up to 266 days at 25 +/- 5 degrees Celsius and 20-60% RH. Seven techniques were compared regarding the recovery of culturable fungi from the swabs over different time points. Results for Experiment 1 showed that all samples were culturable after the storage period and that the S. chartarum-inoculated drywall samples were toxic. In Experiment 2, all techniques showed high rates of recovery. These data show that despite being without a water source, these organisms can be culturable and toxic after long periods of time under conditions similar to human-occupied dwellings and that a number of preparation techniques are suitable for the recovery of these fungi from inoculated swabs.

Characterization of exposure to low levels of viable Penicillium chrysogenum conidia and allergic sensitization induced by a protease allergen extract from viable P. Chrysogenum conidia in mice.

BACKGROUND: Previous evidence by our laboratory has shown that mice inoculated with viable Penicillium Chrysogenum conidia or spores at levels comparable to those found in contaminated buildings induced spore antigen-specific allergic responses. We proposed that mice exposed to low levels of viable P. Chrysogenum conidia would not develop allergic symptoms. We also hypothesized that the symptoms induced by high numbers of conidia were the result of sensitization to allergens released by the conidia. METHODS: C57BL/6 and BALB/c mice were exposed to 1 x 10(2) viable P. Chrysogenum conidia by intranasal instillation weekly for a period of 11 weeks. C57BL/6 mice were also sensitized to a viable P. Chrysogenum conidia protease extract by intraperitoneal injections for a period of 6 weeks followed by intranasal challenge with protease extract, viable, or nonviable P. Chrysogenum conidia for 2 weeks. RESULTS: C57BL/6 mice inoculated with low numbers of conidia developed no significant lung inflammation or increased serum immunoglobulins. Mice sensitized to the protease extract and challenged with both protease extract and viable conidia produced significant increases in serum IgE and IgG1. Mice sensitized to and challenged with the protease extract developed significant eosinophilia and mucus hyperproduction as determined by bronchoalveolar lavage and histopathological examination of lung tissue. CONCLUSIONS: Mice did not develop allergic symptoms in response to challenge with low levels of P. Chrysogenum conidia. Protease allergens from viable conidia induced specific allergic responses in mice, indicating the importance of P. Chrysogenum conidia in allergic sensitization to the organism.

Microbial exposure and mold-specific serum IgG levels among children with respiratory symptoms in 2 school buildings.

In this study, the authors determined the association between serum mold-specific immunoglobulin G (IgG) levels in primary school children (N = 181) with asthma, wheezing, or cough symptoms and exposure to indoor mold in 2 schools, with and without mold damage. Microbial exposure was determined with environmental sampling. Serum IgG antibody concentrations against 24 microbial strains were determined with enzyme-linked immunosorbent assay. Children's microbe-specific IgG levels were often higher in the reference school. There was an association between elevated serum IgG antibody levels to Penicillium notatum and moisture damage in the school. In addition, moisture damage both in school and at home was associated with Penicillium notatum and Eurotium amstelodami IgG levels. These observations comported with microbial findings in the index school. No other positive associations between IgG antibodies and microbial findings for the school buildings were observed. IgG levels in sera of school children did not provide a specific means for assessing the microbial exposure associated with moisture and microbial problems in the school buildings. Thus, IgG analysis cannot be readily suggested as a routine method for the evaluation of these exposures.

Necrotizing pneumonia caused by Penicillium chrysogenum.

We report a case of necrotizing pneumonia due to Penicillium chrysogenum in a 57-year-old woman operated on for lung cancer. The residual right lower pulmonary lobe was infiltrated by Penicillium chrysogenum. The patient underwent a second pulmonary right lobectomy and was successfully treated with oral itraconazole. To our knowledge, this is the first case of pneumonia due to P. chrysogenum.

[PBV5 virus induction in Penicillium chrysogenum mycelium]. / Induktsiia virusa PBV5 v mitselii Penicillium chrysogenum

The effect of some physical (increased temperature, UV light) and chemical (N-nitrosomethylbiuret, proflavin, acridine orange) factors on the virus titer in 2 strains of Penicillium chrysogenum was studied. Thermoinactivation of the virus and its induction under the effect of UV light and proflavin were shown. Slight induction was observed with N-nitrosomethylbiuret and acridin orange. It was supposed that induction of the virus in the mycelium of Penicillium chrysogenum was spontaneous.