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Aspergillus niger

January 01, 1970

Aspergillus niger is a mold classified within the Nigri section of the Aspergillus genus.[1] The Aspergillus genus consists of common molds found throughout the environment within soil and water, on vegetation, in fecal matter, on decomposing matter, and suspended in the air.[2] Species within this genus often grow quickly and can sporulate within a few days of germination.[2] A combination of characteristics unique to A. niger makes the microbe invaluable to the production of many acids, proteins and bioactive compounds. Characteristics including extensive metabolic diversity, high production yield, secretion capability, and the ability to conduct post-translational modifications are responsible for A. niger's robust production of secondary metabolites.[3] A. niger's capability to withstand extremely acidic conditions makes it especially important to the industrial production of citric acid.[1][4]

Aspergillus niger
Photomicrograph showing the conidial head (conidiophore) of Aspergillus niger
Details of the head by scanning electron microscopy
Scientific classification
Domain: Eukaryota
Kingdom: Fungi
Division: Ascomycota
Class: Eurotiomycetes
Order: Eurotiales
Family: Aspergillaceae
Genus: Aspergillus
Species:
A. niger
Binomial name
Aspergillus niger
Synonyms

Aspergillus niger var. niger
Aspergillopsis nigra (Tiegh.) Speg.
Rhopalocystis nigra (Tiegh.) Grove
Sterigmatocystis nigra (Tiegh.) Sacc. (1877)

A. niger causes a disease known as "black mold" on certain fruits and vegetables such as grapes, apricots, onions, and peanuts, and is a common contaminant of food. It is ubiquitous in soil and is commonly found in indoor environments, where its black colonies can be confused with those of Stachybotrys (species of which have also been called "black mold").[5] A. niger is classified as Generally Recognized as Safe (GRAS) by the US Food and Drug Administration for use in food production,[6] although the microbe is capable of producing toxins that affect human health.[7]

Taxonomy edit

Aspergillus niger is included in Aspergillus subgenus Circumdati, section Nigri. The section Nigri includes 15 related black-spored species that may be confused with A. niger, including A. tubingensis, A. foetidus, A. carbonarius, and A. awamori.[8][9] In 2004, a number of morphologically similar species were described by Samson et al.[9]

In 2007, the strain of ATCC 16404 Aspergillus niger was reclassified as Aspergillus brasiliensis (refer to publication by Varga et al.[10]). This required an update to the U.S. Pharmacopoeia and the European Pharmacopoeia, which commonly use this strain throughout the pharmaceutical industry.[citation needed]

Cultivation edit

 
A. niger growing on potato dextrose agar

A. niger is a strict aerobe; therefore, it requires oxygen to grow.[11] The fungus can grow in a range of environmental conditions; it can grow at temperatures ranging from 6 to 47 °C.[12] As a mesophile,[13] its optimal temperature range is 35-37 °C.[11] It can tolerate pH ranging from 1.5 to 9.8.[12] A. niger is xerophilic, meaning it can grow and reproduce in environments with very little water. It can also grow in humid conditions even tolerating environments with 90-100% relative humidity.[13] The fungus is most commonly grown on potato dextrose agar (PDA), but it can grow on many different types of growth media including Czapek-Dox agar, lignocellulose agar, and several others. [citation needed]

Genome edit

Aspergillus niger has a genome consisting of roughly 34 megabases (Mb) organized into eight chromosomes.[14] The DNA contains 10,785 genes which are transcribed and translated into 10,593 proteins.[14]

Genomic information
NCBI genome ID429
Ploidyhaploid
Genome size34 Mb
Number of chromosomes8

Two strains of A. niger have been sequenced. Strain CBS 513.88 produces enzymes used in industrial applications while strain ATCC 1015 is the wildtype strain of ATCC 11414 used to produce industrial citric acid (CA).[15][16][17] The A. niger ATCC 1015 genome was sequenced by the Joint Genome Institute in a collaboration with other institutions.[18] Completed sequences have been used to uncover orthologous genes and pathways involved in fungal metabolism, specifically the catabolism of monosaccharides.[19] The ability of A. niger to change its metabolism depending on the carbon sources and other nutrients present in its environment has enabled the microorganism to survive and be found in almost all ecosystems. Further research is being done to study these mechanisms for all fungi using the complete sequenced genome of A. niger.[19]

Industrial uses edit

There are two ways in which Aspergillus niger can be grown for industrial purposes: solid state fermentation (SSF) and submerged fermentation (SmF).[20] SSF uses a solid substrate with nutrients and minimal moisture to grow microorganisms. Nutrients such as nitrogen and carbon come from agricultural byproducts such as wheat bran, sugar pulp, rice husks, and corn flour.[21] SSF gives better yield of microbe products and is more cost effective than SmF due to using agricultural byproducts.[22] SSF is predominantly used over SmF.[22] In SmF, microbes are grown in a liquid medium inside large aseptic fermentation vessels.[21][22] These vessels are expensive pieces of equipment that provide more water for growth and allow for tight control of environmental factors, such as temperature and pH, that affects microbial growth.[22]

Aspergillus niger is cultured to facilitate the industrial production of many substances.[23] Various strains of A. niger are used in the industrial preparation of citric acid (E330) and gluconic acid (E574); therefore, they have been deemed acceptable for daily intake by the World Health Organization.[24] A. niger fermentation is "generally recognized as safe" (GRAS) by the United States Food and Drug Administration under the Federal Food, Drug, and Cosmetic Act.[25] A. niger is also being considered as a potential new source of natural food grade pigments.[26]

The production of citric acid (CA) is achieved by growing strains of A. niger in a nutrient rich medium that includes high concentrations of sugar and mineral salts and an acidic pH of 2.5-3.5.[27] Many microorganisms produce CA, but Aspergillus niger produces more than 1 million metric tons of CA annually via a fungal fermentation process.[28] CA is in high demand for applications such as the control of microorganism growth, food and beverage flavor enhancement, acidity manipulation, pharmaceuticals, etc.[29]

A. niger produces many useful enzymes for the catabolism of biopolymers in order to obtain nutrients from its environment.[30] The production of specific enzymes can be increased for industrial purposes.[31][30] For example, A. niger glucoamylase (P69328) is used in the production of high-fructose corn syrup and pectinases (GH28) are used in cider and wine clarification. Alpha-galactosidase (GH27), an enzyme that breaks down certain complex sugars, is a component of Beano and several other products that decrease flatulence.[32] Another use for A. niger within the biotechnology industry is in the production of magnetic isotope-containing variants of biological macromolecules for NMR analysis.[33] Aspergillus niger is also cultured for the extraction of the enzyme, glucose oxidase (P13006), used in the design of glucose biosensors, due to its high affinity for β-D-glucose.[34][35]

In the food industry, A. niger is also cultured to isolate the enzyme fructosyltransferase to produce fructooligosaccharides (FOS).[36] FOS are used to manufacture low-calorie and functional foods due to FOS characteristic ability to slow growth of pathogenic microorganisms in the intestines.[36][37] These foods have prebiotic fiber among other health promoting properties. A. niger is not the only organism to produce the enzyme fructosyltransferase, but it has been found to produce the enzyme at rates conducive to industrial production.[36][37] A specific use of A. niger within the food industry is its capability to produce enzymes like carbohydrase and cellulase, which are commonly used in the seafood industry for removing the bellies of clams during processing and removing the tough external skin of shrimp from their edible internal tissue.[38]

Aspergillus niger can grow in gold-mining solutions containing cyano-metal complexes with gold, silver, copper, iron, and zinc. The fungus also plays a role in the solubilization of heavy-metal sulfides.[39] A. niger has also been shown to remediate acid mine drainage through biosorption of copper and manganese.[40]

Toxicity edit

A. niger produces a wide variety of secondary metabolites,[7] some of which are mycotoxins called ochratoxins,[41] such as ochratoxin A.[5][42] Contamination by filamentous fungi, such as A. niger, occurs frequently in grapes and grape based products resulting in contamination by ochratoxin A (OTA). OTA, a clinically relevant mycotoxin, can accumulate in human tissue and cause a variety of serious health conditions.[43] Potential consequences of OTA poisoning include kidney damage, kidney failure and cancer but the United States Food and Drug Administration (FDA) has not set maximum permissible levels of OTA in food unlike the EU that set maximum permissible levels in a variety of food products.[44]

Pathogenicity edit

 
A. niger growing on onion

Plant pathogen edit

Aspergillus niger can cause black mold infections in certain legumes, fruits, and vegetables such as peanuts, grapes, and onions, leading to the fungus being a common food contaminant. This filamentous ascomycete has a tolerance to changes in pH, humidity, and heat, thriving in a temperature range from 15 to 53 °C (59 to 127 °F).[45] These characteristics make infections of A. niger a common cause of post-harvest decay in fruits and vegetables, which can lead to significant economic loss in the food industry.[46] A. niger infection in plants can cause a reduction in seed germination, seedling emergence, root elongation, and shoot elongation, causing the plant to perish before maturation.[46] Specifically, Aspergillus niger causes sooty mold on onions and ornamental plants.[citation needed]

Human pathogen edit

A. niger is pathogenic. Aspergillosis is a fungal infection caused by spores of indoor and outdoor Aspergillus mold species.[47] Due to the ubiquitous nature of A. niger, its spores are commonly inhaled by humans from their surrounding environment.[48] Aspergillosis infection customarily occurs in people with compromised immune systems or pre-existing lung conditions like asthma and cystic fibrosis.[47] Types of aspergillosis include allergic bronchopulmonary aspergillosis (ABPA), allergic aspergillus sinusitis, azole-resistant aspergillus fumigatus, cutaneous (skin) aspergillosis, and chronic pulmonary aspergillosis.[47] Out of the approximated 180 species of aspergillus molds, roughly 40 species have been found to cause health concern in immunocompromised humans.[47] Aspergillosis is particularly frequent among horticultural workers who often inhale peat dust, which can be rich in Aspergillus niger spores. The fungus has also been found in ancient Egyptian mummies and can be inhaled when they are disturbed.[49] Otomycosis, which is a superficial fungal infection of the ear canal, is another disorder that can be caused by overgrowth of Aspergillus molds like A. niger.[50] Otomycosis caused by A. niger is frequently associated with mechanical damage of the ear canal's external skin barrier and often presents itself in patients living in tropical climates.[50][42] A. niger is rarely reported to cause pneumonia compared to other Aspergillus species, such as Aspergillus flavus, Aspergillus fumigatus, and Aspergillus terreus.[51]

Gallery edit

See also edit

References edit

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External links edit

  • Aspergillosis information, Centers for Disease Control and Prevention, US Department of Health and Human Services
  • A. niger ATCC 1015 genome
  • Aspergillus website (Manchester University, UK)

January 01, 1970
aspergillus, niger, mold, classified, within, nigri, section, aspergillus, genus, aspergillus, genus, consists, common, molds, found, throughout, environment, within, soil, water, vegetation, fecal, matter, decomposing, matter, suspended, species, within, this. Aspergillus niger is a mold classified within the Nigri section of the Aspergillus genus 1 The Aspergillus genus consists of common molds found throughout the environment within soil and water on vegetation in fecal matter on decomposing matter and suspended in the air 2 Species within this genus often grow quickly and can sporulate within a few days of germination 2 A combination of characteristics unique to A niger makes the microbe invaluable to the production of many acids proteins and bioactive compounds Characteristics including extensive metabolic diversity high production yield secretion capability and the ability to conduct post translational modifications are responsible for A niger s robust production of secondary metabolites 3 A niger s capability to withstand extremely acidic conditions makes it especially important to the industrial production of citric acid 1 4 Aspergillus niger Photomicrograph showing the conidial head conidiophore of Aspergillus niger Details of the head by scanning electron microscopy Scientific classification Domain Eukaryota Kingdom Fungi Division Ascomycota Class Eurotiomycetes Order Eurotiales Family Aspergillaceae Genus Aspergillus Species A niger Binomial name Aspergillus nigervan Tieghem 1867 Synonyms Aspergillus niger var niger Aspergillopsis nigra Tiegh Speg Rhopalocystis nigra Tiegh Grove Sterigmatocystis nigra Tiegh Sacc 1877 A niger causes a disease known as black mold on certain fruits and vegetables such as grapes apricots onions and peanuts and is a common contaminant of food It is ubiquitous in soil and is commonly found in indoor environments where its black colonies can be confused with those of Stachybotrys species of which have also been called black mold 5 A niger is classified as Generally Recognized as Safe GRAS by the US Food and Drug Administration for use in food production 6 although the microbe is capable of producing toxins that affect human health 7 Contents 1 Taxonomy 2 Cultivation 3 Genome 4 Industrial uses 5 Toxicity 6 Pathogenicity 6 1 Plant pathogen 6 2 Human pathogen 7 Gallery 8 See also 9 References 10 External linksTaxonomy editAspergillus niger is included in Aspergillus subgenus Circumdati section Nigri The section Nigri includes 15 related black spored species that may be confused with A niger including A tubingensis A foetidus A carbonarius and A awamori 8 9 In 2004 a number of morphologically similar species were described by Samson et al 9 In 2007 the strain of ATCC 16404 Aspergillus niger was reclassified as Aspergillus brasiliensis refer to publication by Varga et al 10 This required an update to the U S Pharmacopoeia and the European Pharmacopoeia which commonly use this strain throughout the pharmaceutical industry citation needed Cultivation edit nbsp A niger growing on potato dextrose agar A niger is a strict aerobe therefore it requires oxygen to grow 11 The fungus can grow in a range of environmental conditions it can grow at temperatures ranging from 6 to 47 C 12 As a mesophile 13 its optimal temperature range is 35 37 C 11 It can tolerate pH ranging from 1 5 to 9 8 12 A niger is xerophilic meaning it can grow and reproduce in environments with very little water It can also grow in humid conditions even tolerating environments with 90 100 relative humidity 13 The fungus is most commonly grown on potato dextrose agar PDA but it can grow on many different types of growth media including Czapek Dox agar lignocellulose agar and several others citation needed Genome editAspergillus niger has a genome consisting of roughly 34 megabases Mb organized into eight chromosomes 14 The DNA contains 10 785 genes which are transcribed and translated into 10 593 proteins 14 Genomic informationNCBI genome ID429PloidyhaploidGenome size34 MbNumber of chromosomes8 Two strains of A niger have been sequenced Strain CBS 513 88 produces enzymes used in industrial applications while strain ATCC 1015 is the wildtype strain of ATCC 11414 used to produce industrial citric acid CA 15 16 17 The A niger ATCC 1015 genome was sequenced by the Joint Genome Institute in a collaboration with other institutions 18 Completed sequences have been used to uncover orthologous genes and pathways involved in fungal metabolism specifically the catabolism of monosaccharides 19 The ability of A niger to change its metabolism depending on the carbon sources and other nutrients present in its environment has enabled the microorganism to survive and be found in almost all ecosystems Further research is being done to study these mechanisms for all fungi using the complete sequenced genome of A niger 19 Industrial uses editThere are two ways in which Aspergillus niger can be grown for industrial purposes solid state fermentation SSF and submerged fermentation SmF 20 SSF uses a solid substrate with nutrients and minimal moisture to grow microorganisms Nutrients such as nitrogen and carbon come from agricultural byproducts such as wheat bran sugar pulp rice husks and corn flour 21 SSF gives better yield of microbe products and is more cost effective than SmF due to using agricultural byproducts 22 SSF is predominantly used over SmF 22 In SmF microbes are grown in a liquid medium inside large aseptic fermentation vessels 21 22 These vessels are expensive pieces of equipment that provide more water for growth and allow for tight control of environmental factors such as temperature and pH that affects microbial growth 22 Aspergillus niger is cultured to facilitate the industrial production of many substances 23 Various strains of A niger are used in the industrial preparation of citric acid E330 and gluconic acid E574 therefore they have been deemed acceptable for daily intake by the World Health Organization 24 A niger fermentation is generally recognized as safe GRAS by the United States Food and Drug Administration under the Federal Food Drug and Cosmetic Act 25 A niger is also being considered as a potential new source of natural food grade pigments 26 The production of citric acid CA is achieved by growing strains of A niger in a nutrient rich medium that includes high concentrations of sugar and mineral salts and an acidic pH of 2 5 3 5 27 Many microorganisms produce CA but Aspergillus niger produces more than 1 million metric tons of CA annually via a fungal fermentation process 28 CA is in high demand for applications such as the control of microorganism growth food and beverage flavor enhancement acidity manipulation pharmaceuticals etc 29 A niger produces many useful enzymes for the catabolism of biopolymers in order to obtain nutrients from its environment 30 The production of specific enzymes can be increased for industrial purposes 31 30 For example A niger glucoamylase P69328 is used in the production of high fructose corn syrup and pectinases GH28 are used in cider and wine clarification Alpha galactosidase GH27 an enzyme that breaks down certain complex sugars is a component of Beano and several other products that decrease flatulence 32 Another use for A niger within the biotechnology industry is in the production of magnetic isotope containing variants of biological macromolecules for NMR analysis 33 Aspergillus niger is also cultured for the extraction of the enzyme glucose oxidase P13006 used in the design of glucose biosensors due to its high affinity for b D glucose 34 35 In the food industry A niger is also cultured to isolate the enzyme fructosyltransferase to produce fructooligosaccharides FOS 36 FOS are used to manufacture low calorie and functional foods due to FOS characteristic ability to slow growth of pathogenic microorganisms in the intestines 36 37 These foods have prebiotic fiber among other health promoting properties A niger is not the only organism to produce the enzyme fructosyltransferase but it has been found to produce the enzyme at rates conducive to industrial production 36 37 A specific use of A niger within the food industry is its capability to produce enzymes like carbohydrase and cellulase which are commonly used in the seafood industry for removing the bellies of clams during processing and removing the tough external skin of shrimp from their edible internal tissue 38 Aspergillus niger can grow in gold mining solutions containing cyano metal complexes with gold silver copper iron and zinc The fungus also plays a role in the solubilization of heavy metal sulfides 39 A niger has also been shown to remediate acid mine drainage through biosorption of copper and manganese 40 Toxicity editA niger produces a wide variety of secondary metabolites 7 some of which are mycotoxins called ochratoxins 41 such as ochratoxin A 5 42 Contamination by filamentous fungi such as A niger occurs frequently in grapes and grape based products resulting in contamination by ochratoxin A OTA OTA a clinically relevant mycotoxin can accumulate in human tissue and cause a variety of serious health conditions 43 Potential consequences of OTA poisoning include kidney damage kidney failure and cancer but the United States Food and Drug Administration FDA has not set maximum permissible levels of OTA in food unlike the EU that set maximum permissible levels in a variety of food products 44 Pathogenicity edit nbsp A niger growing on onion Plant pathogen edit Aspergillus niger can cause black mold infections in certain legumes fruits and vegetables such as peanuts grapes and onions leading to the fungus being a common food contaminant This filamentous ascomycete has a tolerance to changes in pH humidity and heat thriving in a temperature range from 15 to 53 C 59 to 127 F 45 These characteristics make infections of A niger a common cause of post harvest decay in fruits and vegetables which can lead to significant economic loss in the food industry 46 A niger infection in plants can cause a reduction in seed germination seedling emergence root elongation and shoot elongation causing the plant to perish before maturation 46 Specifically Aspergillus niger causes sooty mold on onions and ornamental plants citation needed Human pathogen edit A niger is pathogenic Aspergillosis is a fungal infection caused by spores of indoor and outdoor Aspergillus mold species 47 Due to the ubiquitous nature of A niger its spores are commonly inhaled by humans from their surrounding environment 48 Aspergillosis infection customarily occurs in people with compromised immune systems or pre existing lung conditions like asthma and cystic fibrosis 47 Types of aspergillosis include allergic bronchopulmonary aspergillosis ABPA allergic aspergillus sinusitis azole resistant aspergillus fumigatus cutaneous skin aspergillosis and chronic pulmonary aspergillosis 47 Out of the approximated 180 species of aspergillus molds roughly 40 species have been found to cause health concern in immunocompromised humans 47 Aspergillosis is particularly frequent among horticultural workers who often inhale peat dust which can be rich in Aspergillus niger spores The fungus has also been found in ancient Egyptian mummies and can be inhaled when they are disturbed 49 Otomycosis which is a superficial fungal infection of the ear canal is another disorder that can be caused by overgrowth of Aspergillus molds like A niger 50 Otomycosis caused by A niger is frequently associated with mechanical damage of the ear canal s external skin barrier and often presents itself in patients living in tropical climates 50 42 A niger is rarely reported to cause pneumonia compared to other Aspergillus species such as Aspergillus flavus Aspergillus fumigatus and Aspergillus terreus 51 Gallery edit nbsp A niger growing in a Petri dishSee also editContamination controlReferences edit a b Ellena V Seekles SJ Vignolle GA Ram AF Steiger MG September 2021 Genome sequencing of the neotype strain CBS 554 65 reveals the MAT1 2 locus of Aspergillus niger BMC Genomics 22 1 679 doi 10 1186 s12864 021 07990 8 PMC 8454179 PMID 34548025 a b Curtis L 2020 Aspergillus Salem Press Encyclopedia of Health Salem Press retrieved 2022 10 18 Kurt T Marba Ardebol AM Turan Z Neubauer P Junne S Meyer V August 2018 Rocking Aspergillus morphology controlled cultivation of Aspergillus niger in a wave mixed bioreactor for the production of secondary metabolites Microbial Cell Factories 17 1 128 doi 10 1186 s12934 018 0975 y PMC 6102829 PMID 30129427 S2CID 52053640 Behera BC November 2020 Citric acid from Aspergillus niger a comprehensive overview Critical Reviews in Microbiology 46 6 727 749 doi 10 1080 1040841X 2020 1828815 PMID 33044884 S2CID 222319687 a b Samson RA Houbraken J Summerbell RC Flannigan B Miller JD 2001 Common and important species of fungi and actinomycetes in indoor environments Microorganisms in Home and Indoor Work Environments CRC pp 287 292 ISBN 978 0415268004 Singh Nikita Gaur Smriti 2021 Dai Xiaofeng Sharma Minaxi Chen Jieyin eds GRAS Fungi A New Horizon in Safer Food Product Fungi in Sustainable Food Production Fungal Biology Cham Springer International Publishing pp 27 37 doi 10 1007 978 3 030 64406 2 3 ISBN 978 3 030 64406 2 S2CID 234175577 retrieved 2022 11 16 a b Frisvad JC Moller LL Larsen TO Kumar R Arnau J November 2018 Safety of the fungal workhorses of industrial biotechnology update on the mycotoxin and secondary metabolite potential of Aspergillus niger Aspergillus oryzae and Trichoderma reesei Applied Microbiology and Biotechnology 102 22 9481 9515 doi 10 1007 s00253 018 9354 1 PMC 6208954 PMID 30293194 Klich MA 2002 Identification of common Aspergillus species Utrecht The Netherlands Centraalbureau voor Schimmelcultures ISBN 978 90 70351 46 5 a b Samson RA Houbraken JA Kuijpers AF Frank JM Frisvad JC 2004 New ochratoxin A or sclerotium producing species in Aspergillus section Nigri PDF Studies in Mycology 50 45 6 Varga J Kocsube S Toth B Frisvad JC Perrone G Susca A et al August 2007 Aspergillus brasiliensis sp nov a biseriate black Aspergillus species with world wide distribution International Journal of Systematic and Evolutionary Microbiology 57 Pt 8 1925 1932 doi 10 1099 ijs 0 65021 0 PMID 17684283 a b Costa CP Goncalves Silva D Rudnitskaya A Almeida A Rocha SM June 2016 Shedding light on Aspergillus niger volatile exometabolome Scientific Reports 6 1 27441 Bibcode 2016NatSR 627441C doi 10 1038 srep27441 PMC 4893740 PMID 27264696 a b Semova N Storms R John T Gaudet P Ulycznyj P Min XJ et al February 2006 Generation annotation and analysis of an extensive Aspergillus niger EST collection BMC Microbiology 6 1 7 doi 10 1186 1471 2180 6 7 PMC 1434744 PMID 16457709 a b Aspergillus niger INSPQ in Spanish Retrieved 2022 11 17 a b Aspergillus niger ID 429 Genome NCBI www ncbi nlm nih gov Retrieved 2022 10 18 Home Aspergillus niger NRRL3 mycocosm jgi doe gov Retrieved 2022 10 18 Andersen MR Salazar MP Schaap PJ van de Vondervoort PJ Culley D Thykaer J et al June 2011 Comparative genomics of citric acid producing Aspergillus niger ATCC 1015 versus enzyme producing CBS 513 88 Genome Research 21 6 885 897 doi 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journal a CS1 maint DOI inactive as of January 2024 link a b Pandey A Selvakumar P Soccol CR Nigam P 1999 Solid state fermentation for the production of industrial enzymes Current Science 77 1 149 162 ISSN 0011 3891 JSTOR 24102923 a b c d Doriya K Jose N Gowda M Kumar DS 2016 Solid State Fermentation vs Submerged Fermentation for the Production of l Asparaginase Advances in Food and Nutrition Research 78 115 135 doi 10 1016 bs afnr 2016 05 003 ISBN 9780128038475 PMID 27452168 Cairns TC Nai C Meyer V 2018 How a fungus shapes biotechnology 100 years of Aspergillus niger research Fungal Biology and Biotechnology 5 13 doi 10 1186 s40694 018 0054 5 PMC 5966904 PMID 29850025 Max B Salgado JM Rodriguez N Cortes S Converti A Dominguez JM October 2010 Biotechnological production of citric acid Brazilian Journal of Microbiology 41 4 862 875 doi 10 1590 S1517 83822010000400005 PMC 3769771 PMID 24031566 Inventory of GRAS Notices Summary of all GRAS Notices US FDA CFSAN 2008 10 22 Archived from the original on 11 October 2008 Retrieved 2008 10 31 Toma MA Nazir KH Mahmud MM Mishra P Ali MK Kabir A et al June 2021 Isolation and Identification of Natural Colorant Producing Soil Borne Aspergillus niger from Bangladesh and Extraction of the Pigment Foods 10 6 1280 doi 10 3390 foods10061280 PMC 8227025 PMID 34205202 Papagianni M 2007 05 01 Advances in citric acid fermentation by Aspergillus niger biochemical aspects membrane transport and modeling Biotechnology Advances 25 3 244 263 doi 10 1016 j biotechadv 2007 01 002 PMID 17337335 Baker SE September 2006 Aspergillus niger genomics past present and into the future Medical Mycology 44 1 S17 S21 doi 10 1080 13693780600921037 PMID 17050415 S2CID 50631 Sackett D 2014 Citric Acid Occurrence Biochemistry Applications and Processing Nova Science Publishers Inc p 119 ISBN 978 1 63117 237 3 a b Pel HJ de Winde JH Archer DB Dyer PS Hofmann G Schaap PJ et al February 2007 Genome sequencing and analysis of the versatile cell factory Aspergillus 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P Rossi M D Auria S December 2005 Glucose biosensors as models for the development of advanced protein based biosensors Molecular BioSystems 1 5 6 354 362 doi 10 1039 b513385h PMID 16881003 Ghoshdastider U Wu R Trzaskowski B Mlynarczyk K Miszta P Gurusaran M Viswanathan S Renugopalakrishnan V Filipek S 2015 Nano Encapsulation of Glucose Oxidase Dimer by Graphene RSC Advances 5 18 13570 78 doi 10 1039 C4RA16852F S2CID 55816037 a b c Mao S Liu Y Yang J Ma X Zeng F Zhang Z et al July 2019 Cloning expression and characterization of a novel fructosyltransferase from Aspergillus niger and its application in the synthesis of fructooligosaccharides RSC Advances 9 41 23856 23863 Bibcode 2019RSCAd 923856M doi 10 1039 C9RA02520K PMC 9069702 PMID 35530578 a b Guo W Yang H Qiang S Fan Y Shen W Chen X 2016 07 01 Overproduction purification and property analysis of an extracellular recombinant fructosyltransferase European Food Research and Technology 242 7 1159 1168 doi 10 1007 s00217 015 2620 x ISSN 1438 2385 S2CID 86927574 CFR Code of Federal Regulations Title 21 www accessdata fda gov Retrieved 2022 11 16 Singh H 2006 Mycoremediation Fungal Bioremediation John Wiley amp Sons p 509 ISBN 978 0470050583 Soleimanifar H Doulati AF Marandi R 2012 06 01 Bio Remediation of Acid Mine Drainage in the Sarcheshmeh Porphyry Copper Mine by Fungi Batch and Fixed Bed Process International Journal of Mining and Geo Engineering 46 1 87 103 doi 10 22059 ijmge 2012 51321 ISSN 2345 6930 Abarca ML Bragulat MR Castella G Cabanes FJ July 1994 Ochratoxin A production by strains of Aspergillus niger var niger Applied and Environmental Microbiology 60 7 2650 2652 Bibcode 1994ApEnM 60 2650A doi 10 1128 AEM 60 7 2650 2652 1994 PMC 201698 PMID 8074536 a b Schuster E Dunn Coleman N Frisvad JC Van Dijck PW August 2002 On the safety of Aspergillus niger a review Applied Microbiology and Biotechnology 59 4 5 426 435 doi 10 1007 s00253 002 1032 6 PMID 12172605 S2CID 26113037 Freire L Guerreiro TM Pia AK Lima EO Oliveira DN Melo CF et al October 2018 A quantitative study on growth variability and production of ochratoxin A and its derivatives by A carbonarius and A niger in grape based medium Scientific Reports 8 1 14573 Bibcode 2018NatSR 814573F doi 10 1038 s41598 018 32907 z PMC 6167359 PMID 30275502 Raduly Zsolt Szabo Laszlo Madar Anett Pocsi Istvan Csernoch Laszlo 2020 Toxicological and Medical Aspects of Aspergillus Derived Mycotoxins Entering the Feed and Food Chain Frontiers in Microbiology 10 2908 doi 10 3389 fmicb 2019 02908 ISSN 1664 302X PMC 6962185 PMID 31998250 Dania VO Fajemisin AO Azuh VO 2021 12 14 Morphological and molecular characterization of Aspergillus niger causing postharvest rot of white yam Dioscorea rotundata Poir Archives of Phytopathology and Plant Protection 54 19 20 2356 2374 doi 10 1080 03235408 2021 1983365 ISSN 0323 5408 S2CID 244606795 a b Tawfik E Alqurashi M Aloufi S Alyamani A Baz L Fayad E January 2022 Characterization of Mutant Aspergillus niger and the Impact on Certain Plants Sustainability 14 3 1936 doi 10 3390 su14031936 a b c d Aspergillosis Types of Fungal Diseases Fungal Diseases CDC www cdc gov 2021 05 10 Retrieved 2022 10 26 Information for Healthcare Professionals Aspergillosis Types of Fungal Diseases Fungal Diseases CDC www cdc gov 2022 07 11 Retrieved 2022 10 26 Handwerk Brian May 6 2005 Egypt s King Tut Curse Caused by Tomb Toxins National Geographic a b Javidnia J Ghotbi Z Ghojoghi A Solhjoo K Alshahni MM Jeddi SA et al June 2022 Otomycosis in the South of Iran with a High Prevalence of Tympanic Membrane Perforation A Hospital Based Study Mycopathologia 187 2 3 225 233 doi 10 1007 s11046 022 00626 9 PMID 35347533 S2CID 247776123 Person AK Chudgar SM Norton BL Tong BC Stout JE July 2010 Aspergillus niger an unusual cause of invasive pulmonary aspergillosis Journal of Medical Microbiology 59 Pt 7 834 838 doi 10 1099 jmm 0 018309 0 PMC 3052473 PMID 20299503 External links editAspergillosis information Centers for Disease Control and Prevention US Department of Health and Human Services A niger ATCC 1015 genome Aspergillus website Manchester University UK Retrieved from https en wikipedia org w index php title Aspergillus niger amp oldid 1220437600, wikipedia, wiki, book, books, library,

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