Production and analysis of citrinin in corn.

A convenient method for the production and analysis of citrinin in corn is described. Up to 2.964 g of citrinin can be produced by Penicillium citrinum per kg of corn by harvesting on day 21 or later. The analysis method has a lower detection limit of 0.25 ppm. Heating citrinin-contaminated corn destroys citrinin but may produce another toxin instead.     

Production of Citrinin by Penicillium viridicatum on Country-Cured Ham

Seven strains of Penicillium viridicatum isolated from country-cured ham produced citrinin in potato dextrose broth and on country-cured ham. None of the strains produced detectable amounts of citrinin at 10 C. The optimal temperature range for citrinin production was 25 to 30 C.     

Comparison of growth characteristics and roquefortin C production of<Emphasis Type="Italic">Penicillium roqueforti</Emphasis> from blue-veined cheese

The properties of 21 isolates ofPenicillium roqueforti from just as many commercial blue-veined cheeses, purchased from the Argentinean market (domestic and imported products) were comparatively examined. Isolates were investigated for their ability to grow at different temperatures, pH values and concentration of NaCl, as well as for their proteolytic and lipolytic activities, respectively. The potential of these strains to produce roquefortin in vitro, and the actual levels of roquefortin in 10 of these cheeses were analysed by TLC. All strains showed similar growth properties in aspects of salt concentration and pH-value of the medium, and all grew well at 10 °C. Only four strains showed proteolytic activity on casein agar, while all strains were lipolytic on trybutirin agar. After incubation at 25 °C for 16 days, all strains produced roquefortin in Yeast Extract Sucrose (25.6–426.7 μg/g) and in reconstituted (10%) sterile skim milk (26.9–488 μg/g). Roquefortin at >0.1 μg/g was also found in 9 out of 10 analysed samples of blue-veined cheeses (8 from Argentine, 1 from Spain), with a maximum value 3.6 μg/g. During the ripening process of blueveined cheese, production of roquefortin seems to be unavoidable. Care should be taken to select strains with low toxin production characteristics, to minimize potential health risks. Roquefortin C production byP. roqueforti in vitro was not correlated with roquefortin C levels found in cheese. Financial support: Research grants from the National University of Quilmes, Argentina     

Chemical characterisation of cheese associated fungi

Recent work in our laboratory has demonstrated that the most common contaminating fungi on different types of cheese are;Penicillium commune, P. nalgiovense, P. solitum, P. discolor, P. roqueforti, P. crustosum, P. nordicum andAspergillus versicolor. On blue cheese a new speciesP. caseifulvum has been discovered as a surface contaminant. A large number of known and unknown metabolites have been described from the above mentioned cheese associated fungi from both synthetic media and real samples. Based on chemotaxonomy our laboratory has discovered thatP. roqueforti should be divided into three species:P. roqueforti (from cheese),P. carneum (from meat) andP. paneum (from bread). SimilarlyP. verrucosum should be divided intoP. verrucosum (from cereals) andP. nordicum (from cheese and meat products). Both species produce ochratoxins, however, only the former species produce citrinin.     

Some technological properties of Penicillium roqueforti strains isolated from a home-made blue cheese

Nine strains of Penicillium roqueforti isolated from a traditional Spanish blue cheese (Valdeón cheese) along with two commercial strains were investigated for their ability to grow at different concentrations of salt and at different temperatures as well as for their proteolytic and lipolytic activities. Low concentrations of salt (1-3%) were stimulating for all the strains, with 1% salt being the concentration with the highest stimulating effect in nearly all. The rate of growth at 10°C was 2-3 times lower than at 25°C, the optimum temperature for the species. None of the strains, including the commercial cultures, showed proteolytic activity on casein agar, while all of them were lipolytic on tributyrin agar.     

Production of lipase free of citrinin by Penicillium citrinum

Lipase (Glycerol ester hydrolase E.G. 3.1.1.3) from a Brazilian strain of Penicillium citrinum free of the mycotoxin citrinin has been investigated. Citrinin production was inhibited by using culture medium containing olive oil, soybean oil and corn oil as carbon sources. Potassium concentration and pH play an important role in citrinin production. Potassium concentration lower than 30 mM and pH below 4.5 inhibited the mycotoxin production. P. citrinum produced lipase free of extraneous proteins and citrinin when cultured using, as nitrogen source, ammonium sulphate (lipase activity of 7.88 U/mg) and yeast extract (lipase activity of 4.95 U/mg) with olive oil as carbon source. This data is relevant to the larger scale production of lipases for food technology applications, from Penicillium citrinum.     

The capacity of Enterobacteriaceae species to produce biogenic amines in cheese

The amino acid decarboxylating activity and production of biogenic amines by 104 cheese-associated Enterobacteriaceae species (58 Enterobacter, 18 Serratia, eight Escherichia, seven Hafnia, six Arizona, four Citrobacter and three Klebsiella) were investigated. All strains could decarboxylate at least two amino acids in M?ller's broth and in Niven's medium, and the decarboxylase activity was strain specific. In a laboratory medium containing all free amino acids, all strains could produce more than 100 ppm cadaverine, putrescine was produced by 96% of strains. Tyramine and histamine were produced in the lowest concentrations. A positive correlation existed between cadaverine concentration and Enterobacteriaceae counts in cheese, that may have caused the increase in decarboxylase content. This study suggests that it is possible to limit the presence of cadaverine in cheese, thereby controlling the Enterobacteriaceae counts, a sign of contamination during cheese making and/or storage.     

Bleu cheese flavor production by submerged fermentation with on-line monitoring by gas chromatography

Eight cultures ofPenicillium roqueforti and related species were compared in shake-flask cultures on the basis of aroma.P. decumbens IFO 7091 was chosen as having the aroma closest to real Bleu cheese, and was used for fermentation studies. Gas chromatography was employed to obtain a continuous record of 2-pentanone concentration in the fermentor. Methyl ketones are characteristic of Bleu cheese flavor, and a subjective correlation was observed between the aroma of the fermentor off-gas and the 2-pentanone concentration measured. Cell growth and milk fat utilization increased consistently with increasing agitation and aeration, but 2-pentanone production did not correlate with growth and was maximum at intermediate values of agitation and aeration. The maximum 2-pentanone concentration, 100 ppm, was approximately ten times the concentration in Bleu cheese on a dry solids basis. Production of Bleu cheese flavor by submerged fermentation offers the opportunity for a new commercial value-added product from butterfat.Mention of brand or firm names does not constitute an endorsement by the US Department of Agriculture over others of a similar nature not mentioned     

Independent domestication events in the blue‐cheese fungus Penicillium roqueforti

Domestication provides an excellent framework for studying adaptive divergence. Using population genomics and phenotypic assays, we reconstructed the domestication history of the blue cheese mould Penicillium roqueforti. We showed that this fungus was domesticated twice independently. The population used in Roquefort originated from an old domestication event associated with weak bottlenecks and exhibited traits beneficial for pre‐industrial cheese production (slower growth in cheese and greater spore production on bread, the traditional multiplication medium). The other cheese population originated more recently from the selection of a single clonal lineage, was associated with all types of blue cheese worldwide except Roquefort, and displayed phenotypes more suited for industrial cheese production (high lipolytic activity, efficient cheese cavity colonization ability and salt tolerance). We detected genomic regions affected by recent positive selection and putative horizontal gene transfers. This study sheds light on the processes of rapid adaptation and raises questions about genetic resource conservation.     

Biogenic amine-forming microbial communities in cheese

The aim of this study was to screen two cheese starter cultures and cheese-borne microbial communities with the potential to produce biogenic amines in cheese during ripening. Bacteria of the genera Enterococcus and Lactobacillus and coliform bacteria were isolated from Dutch-type semi-hard cheese at the beginning of the ripening period. Statistically significant counts of bacterial isolates were screened for the presence of specific DNA sequences coding for tyrosine decarboxylase (tyrDC) and histidine decarboxylase (hDC) enzymes. The PCR analysis of DNA from 14 Enterococcus and 3 Lactobacillus isolates confirmed the presence of the targetted DNA sequences. Simultaneously, 13 tyrDC- and 3 hDC-positive isolates were grown in decarboxylase screening medium and this was followed by HPLC analysis of the produced tyramine and histamine. Conventional and molecular taxonomic analyses of the above-mentioned isolates identified the following species: Enterococcus durans (7 strains), Enterococcus faecalis (3 strains), Enterococcus faecium (1 strain), Enterococcus casseliflavus (3 strains), Lactobacillus curvatus (1 strain), Lactobacillus lactis (1 strain) and Lactobacillus helveticus (1 strain). All of the above Enterococcus and two of the Lactobacillus strains originated from contaminating microbial communities. The L. helveticus strain, which was tyrosine decarboxylase-positive and exhibited tyramine production, originated from starter culture 1 used for cheese production. Comparison of partial tyrDC sequences of positive Enterococcus isolates revealed 89% sequence similarity, and that of hDC-positive Lactobacillus isolates revealed 99% sequence similarity.     

Antigenic characterization of Penicillium camemberti and related common cheese contaminants

Twenty-four isolates of Penicillium (including a green-spored mutant from a French Brie cheese, Penicillium camemberti) with a proposed relationship to the white cheese mold P. camemberti were investigated by immunological procedures. These penicillia, which are representative of species that have caused considerable taxonomic confusion, had common micromorphology (terverticillate penicilli with rough and smooth stipes and smooth ellipsoidal to subglobose [(3 to 5) X 2 1/2 to 4 1/2 microns] conidia); growth rates; good growth on creatine sucrose agar, cheese, and other products with a high amount of protein and lipid as a primary habitat; production (with the exception of Penicillium solitum) of cyclopiazonic acid; and the ability to grow at low temperatures and water activities. The isolates that were investigated proved to be strictly antigenically related. Absorbed antiserum of the green-spored mutant of P. camemberti showed a specific precipitin band when tested by immunodiffusion either with its homologous reference antigen or with the exoantigens obtained from different isolates. The precipitin band was not present in any P. camemberti starter culture but in many unwanted cheese contaminants. The precipitin band can be used in the purity control of P. camemberti starter culture spore preparations. Analysis of the exoantigens of all the cultures by reversed phase high-performance liquid chromatography allowed us to subdivide these penicillia into nine groups below the species level. The results indicate that P. commune Thom is the wild-type ancestor of P. camemberti.     

Toxigenic fungi isolated from roquefort cheese

To evaluate the potential for mycotoxin production by fungi contaminating blue-veined cheese, as well as by the ripening fungus,Penicillium roqueforti, the fungal flora of six of local and imported brands was determined. A total of 19 fungi were isolated from the six brands tested. Fourteen of the isolates were toxic to chicken embryos. The toxigenic fungi produced the following mycotoxins:Aspergillus fumigatus, kojic acid;A. versicolor, sterigmatocystin;Penicillium roqueforti, penicillic acid and unidentified toxic metabolites.     

Antigenic characterization of Penicillium camemberti and related common cheese contaminants.

Twenty-four isolates of Penicillium (including a green-spored mutant from a French Brie cheese, Penicillium camemberti) with a proposed relationship to the white cheese mold P. camemberti were investigated by immunological procedures. These penicillia, which are representative of species that have caused considerable taxonomic confusion, had common micromorphology (terverticillate penicilli with rough and smooth stipes and smooth ellipsoidal to subglobose [(3 to 5) X 2 1/2 to 4 1/2 microns] conidia); growth rates; good growth on creatine sucrose agar, cheese, and other products with a high amount of protein and lipid as a primary habitat; production (with the exception of Penicillium solitum) of cyclopiazonic acid; and the ability to grow at low temperatures and water activities. The isolates that were investigated proved to be strictly antigenically related. Absorbed antiserum of the green-spored mutant of P. camemberti showed a specific precipitin band when tested by immunodiffusion either with its homologous reference antigen or with the exoantigens obtained from different isolates. The precipitin band was not present in any P. camemberti starter culture but in many unwanted cheese contaminants. The precipitin band can be used in the purity control of P. camemberti starter culture spore preparations. Analysis of the exoantigens of all the cultures by reversed phase high-performance liquid chromatography allowed us to subdivide these penicillia into nine groups below the species level. The results indicate that P. commune Thom is the wild-type ancestor of P. camemberti.     

Toxins of molds from decaying tomato fruit.

Among 27 mold isolates from decaying tomatoes, culture filtrates or ethyl acetate extracts of 8 isolates grown in yeast extract-sucrose medium were markedly toxic (mortality, greater than 50%) to brine shrimp larvae. The toxicity of six of these isolates could be attributed to the presence of citrinin, tenuazonic acid, or T-2 toxin. Ethyl acetate extracts of five Alternaria isolates and one Fusarium isolate were mutagenic for Salmonella typhimurium strains. In ripe tomatoes inoculated with toxin-producing isolates and incubated at 25 degrees C, one Alternaria alternata isolate produced tenuazonic acid in seven of seven tomatoes at levels of up to 106 micrograms/g and alternariol methyl ether in one of the seven tomatoes at 0.8 microgram/g. Another A. alternata isolate produced tenuazonic acid or alternariol methyl ether at much lower levels in only three of seven tomatoes. Patulin and citrinin were produced by a Penicillium expansum isolate at levels of up to 8.4 and 0.76 microgram/g, respectively. In tomatoes incubated at 15 degrees C, a Fusarium sulphureum isolate produced T-2 toxin, HT-2 toxin, and neosolaniol at levels of up to 37.5, 37.8 and 5.6 micrograms/g, respectively. If these mycotoxins are thermostable, they may occur at detectable levels in tomato products whenever partially moldy tomatoes are used as raw material.     

Natural occurrence of the mycotoxin viomellein in barley and the associated quinone-producing penicillia.

In a batch of barley associated with field cases of mycotoxic porcine nephropathy and containing ochratoxin A and citrinin, the mycoflora were isolated by parallel incubation at 10 and 25 degrees C. Subsequently, the isolated cultures were checked for production of nephrotoxins (xanthomegnin, viomellein, ochratoxin, and citrinin). The nephrotoxin producers, all isolated by incubation at 10 degrees C, were comprised of one culture of Penicillium viridicatum, five cultures of Penicillium cyclopium, and one culture of Penicillium crustosum, all producing xanthomegnin and viomellein. One culture of P. cyclopium produced citrinin. Viomellein was detected in the barley at a concentration of approximately 1 mg/kg. The method of analysis for xanthomegnin and viomellein included extraction with chloroform, partitioning in hexane-acetone, and thin-layer chromatographic separation and identification. The identity of the xanthomegnin and viomellein produced by the isolated fungi and of viomellein detected in the barley was supported by infrared spectroscopy. This is the first report of viomellein as a natural contaminant of foodstuffs.     

Inhibition of Listeria monocytogenes in cottage cheese manufactured with a lacticin 3147-producing starter culture

The efficacy of using a lacticin 3147-producing starter as a protective culture to improve the safety of cottage cheese was investigated. This involved the manufacture of cottage cheese using Lactococcus lactis DPC4268 (control) and L. lactis DPC4275, a bacteriocin-producing transconjugant strain derived from DPC4268. A number of Listeria monocytogenes strains, including a number of industrial isolates, were assayed for their sensitivity to lacticin 3147. These strains varied considerably with respect to their sensitivity to the bacteriocin. One of the more tolerant strains, Scott A, was used in the cottage cheese study; the cheese was subsequently inoculated with approximately 10(4) L. monocytogenes Scott A g-1. The bacteriocin concentration in the curd was measured at 2560 AU ml-1, and bacteriocin activity could be detected throughout the 1 week storage period. In cottage cheese samples held at 4 degrees C, there was at least a 99.9% reduction in the numbers of L. monocytogenes Scott A in the bacteriocin-containing cheese within 5 d, whereas in the control cheeses, numbers remained essentially unchanged. At higher storage temperatures, the kill rate was more rapid. These results demonstrate the effectiveness of lacticin 3147 as an inhibitor of L. monocytogenes in a food system where post-manufacture contamination by this organism could be problematic.     

Toxins of molds from decaying tomato fruit.

Among 27 mold isolates from decaying tomatoes, culture filtrates or ethyl acetate extracts of 8 isolates grown in yeast extract-sucrose medium were markedly toxic (mortality, greater than 50%) to brine shrimp larvae. The toxicity of six of these isolates could be attributed to the presence of citrinin, tenuazonic acid, or T-2 toxin. Ethyl acetate extracts of five Alternaria isolates and one Fusarium isolate were mutagenic for Salmonella typhimurium strains. In ripe tomatoes inoculated with toxin-producing isolates and incubated at 25 degrees C, one Alternaria alternata isolate produced tenuazonic acid in seven of seven tomatoes at levels of up to 106 micrograms/g and alternariol methyl ether in one of the seven tomatoes at 0.8 microgram/g. Another A. alternata isolate produced tenuazonic acid or alternariol methyl ether at much lower levels in only three of seven tomatoes. Patulin and citrinin were produced by a Penicillium expansum isolate at levels of up to 8.4 and 0.76 microgram/g, respectively. In tomatoes incubated at 15 degrees C, a Fusarium sulphureum isolate produced T-2 toxin, HT-2 toxin, and neosolaniol at levels of up to 37.5, 37.8 and 5.6 micrograms/g, respectively. If these mycotoxins are thermostable, they may occur at detectable levels in tomato products whenever partially moldy tomatoes are used as raw material.