Abstract
Free full text
Three New Records of Mortierella Species Isolated from Crop Field Soil in Korea
Abstract
Three new fungal species of the genus Mortierella, Mortierella zychae, Mortierella ambigua, and Mortierella indohii, have been reported in Korea. The fungi were encountered during a study on the fungal community of soil samples collected from different locations in Korea. The species were identified based on molecular and morphological analyses. This study presents detailed descriptions of the morphological observations and molecular phylogenetic analysis of these three fungi. All three species were found to be sensitive to triphenyltetrazolium chloride staining. M. zychae demonstrated the highest intensity of mycelial staining, indicating that this species has the highest potential to produce arachidonic acid of the three species. The staining results indicated that the newly recorded species could potentially be useful for arachidonic acid production.
Members of the genus Mortierella of the order Mortierellales within the family Mortierellaceae are filamentous fungi commonly found in soil. The genus contains a large number (nearly 100) of validated species that can be found on almost any substrate and are often encountered in soils as saprophytes [1]. Mortierella polycephala was the first species of the genus described by Coemans [2]. Major members of the genus include Mortierella alliacea, Mortierella alpina, M. polycephala, Mortierella elongata, Mortierella spinosa, Mortierella gamsii, Mortierella isabellina, Mortierella humilis, and Mortierella reticulata.
Many filamentous fungi belonging to the genus Mortierella are promising candidates for use as producers of arachidonic acid and other polyunsaturated fatty acids (PUFAs) [3,4]. PUFAs, particularly linoleic acid (18:2, n-6), α-linolenic acid (18:3, n-3), and arachidonic acid (20:4, n-6), are essential fatty acids vital for various mammalian biological functions [5].
Three new species belonging to Mortierella were isolated from soils collected in Gangwon-do, Chungcheongbuk-do, and Gyeonggi-do during a study of the fungal community in crop field soils. This study represents the first report of these species in Korea. The aim of this study was to compare the morphological and phylogenetic characteristics of the new species with previously described Mortierella spp. We also investigated the potential of the newly recorded species to produce arachidonic acid.
MATERIALS AND METHODS
Soil sampling and isolation of fungi
Soil samples were collected in 2014 from agricultural fields at various locations in Gangwon-do (36°54'06.10" N, 127°28'08.20" E), Chungcheongbuk-do (36°46'04.61" N, 127°30'00.52" E), and Gyeonggi-do (37°25'45.60" N, 127°08°14.15° W), Korea. Each soil sample was collected from a depth of approximately from 0~15 cm after removing the surface litter, sealed in a sterile soil sampling polythene bag, air dried, and stored in a plastic bag at 4 until use. The fungi were isolated using the conventional dilution technique [6] and cultured on potato dextrose agar (PDA; Difco Laboratories, Detroit, MI, USA) supplemented with 100 µg/L chloramphenicol (a bacteriostatic agent) for 5~7 days at 28 until fungal colony growth was observed. The pure cultures were maintained on the PDA slants at 4 for future use.
Morphological characterization
Morphological characteristics of isolates KNU14-5, KNU14-14, and KNU14-17 were observed on PDA, malt extract agar (MEA; 30 g/L malt extract, 5 g/L mycological peptone, and 15 g/L agar), and MEA with 0.1% triphenyltetrazolium chloride (TTC) after inoculation in 9-cm petri dishes and incubation at 28 for 5 days. Photomicrographs were taken with an HK 3.1 CMOS digital camera (KOPTIC Korea Optics, Seoul, Korea) attached to an Olympus BX50F-3 microscope (Olympus Optical Co. Ltd., Tokyo, Japan) and a 1450VP scanning electron microscope (Leo Electron Microscopy Ltd., Cambridge, UK).
Genomic DNA extraction, sequencing, and data analysis
Total genomic DNA was extracted from isolates KNU14-5, KNU14-14, and KNU14-17 using the DNeasy Plant Mini Kit (Qiagen, Hilden, Germany) following the manufacturer's instructions. The internal transcribed spacer regions (ITS1 and ITS2), including the 5.8S were amplified with the primers ITS1 and ITS4 [7]. Polymerase chain reaction (PCR) for amplifying the large subunit (LSU) 28S rDNA was done using the standard primers LR0R and LR5 [8]. The amplified PCR products were purified using the QIAquick PCR purification Kit (Qiagen, Valencia, CA, USA) following the manufacturer's instructions. The PCR products were sequenced with the ABI Prism 3730 DNA analyzer (Applied Biosystems, Foster City, CA, USA). The sequences were compared with reference ITS and LSU rDNA sequences of Genbank at National Center for Biotechnology Information (NCBI) using the basic local alignment search tool [9]. The nucleotide sequences were deposited in GenBank and assigned accession numbers KP966613, KP966612, and KP055598 for isolates KNU14-5, KNU14-14, and KNU14-17, respectively. The sequences of closely related strains were aligned using the MultAlin program. Phylogenetic relationships were analyzed using molecular evolutionary genetic analysis (MEGA 6) software [10]. The neighbor-joining tree was constructed using the Kimura 2-parameter substitution model [11]. The phylogeny of the tree was inferred using the maximum-likelihood heuristic search option with the nearest-neighbor interchange. Bootstrap analysis was performed with 1,000 replications to determine the support for each clade.
Qualitative analysis of arachidonic acid production
Arachidonic acid production of the isolates was assessed by TTC staining. Fresh mycelia were harvested by suction filtration and staining was performed according to the procedure described by Zhu et al.[12] with a slight modification; 1mL of 0.6% TTC solution in 0.5M phosphate buffer (pH 7.8) was added to 0.1 g of fresh mycelia in a cap tube and incubated in the dark for 1 hr at 28. Mycelia were then rinsed twice with sterile water and homogenized by grinding with a mortar pestle. The red triphenylformazan (TF) formed in mycelia was extracted three times with 2 mL of ethyl acetate at room temperature using fresh solvent for each extraction. The degree of staining was quantified by measuring the absorbance of TF in the ethyl acetate solvent at a wavelength of 485 nm.
RESULTS AND DISCUSSION
Molecular phylogeny of the isolate KNU14-5
KNU14-5 was isolated from crop field soil in Gangwon-do, Korea in July 2014. ITS rDNA and 28S rDNA sequences were compared to determine the phylogenetic relationship between the isolate KNU14-5 and previously described Mortierella species. The isolate was most closely related to M. zychae CBS316.52 and formed a monophyletic group with bootstrap value of 96% (Fig. 1). The phylogenetic analysis showed that the isolate is M. zychae. A synonym for this species is Mortierella brachyrhiza, E. Wolf (1954). This is a common species found especially in soil as saprophytes, but this is the first report of the isolation of M. zychae in Korea.
Morphological characterization of the isolate KNU14-5
Photomicrographs of morphological structures of the isolate KNU14-5 are shown in Fig. 2. Colonies grew moderately fast on PDA, attaining a diameter of 76~79mm in 5 days at 28. The front side of the colony was whitish and often dark whitish at the center. The reverse side of the colony was yellowish white and narrowly zonate. Extensive aerial mycelium production occurred at the center of the colony and numerous irregular bead-like hyphal swellings were formed. The colonies were also fast-growing on MEA, reaching a diameter of 77~80 mm in 5 days at 28. These colonies were a pale, whitish color and broadly zonate, producing a concentric pattern. Sporulation was abundant and the mycelium had a garlic-like odor. The sporangiophores were hyaline, erect, and simple. They were 190~1,000 µm long and tapered towards the apex. They were 8~12 µm wide at the base and 2~4 µm at the apex, bearing terminal sporangia. The sporangia were spherical, 15~35 µm in diameter, wrinkled, and non-columellate. The sporangiospores were hyaline, ellipsoidal, single-celled, and 6~10 µm × 4~6 µm in size. The chlamydospores were globose, catenulate, clustered, and 15~19 µm in diameter.
Conclusions regarding the isolate KNU14-5
On the basis of the aforementioned taxonomical properties, the isolate was concluded to be a fungus belonging to the genus Mortierella[13,16] and the species zychae[2,15]. Typical swollen hyphae and oil droplets containing hyphae are characteristic features of M. zychae and M. alpina, respectively. These fungi also contain ellipsoidal sporangiospores [16]. These characteristic structures were also observed in our study, clearly demonstrating that the KNU14-5 isolate is M. zychae.
Molecular phylogeny of the isolate KNU14-14
KNU14-14 was isolated from crop field soil in Chungcheongbuk-do, Korea in July 2014. ITS rDNA and 28S rDNA sequences were compared to determine the phylogenetic relationship between the isolate KNU14-14 and previously described Mortierella species. The isolate was most closely related to M. ambigua CBS 373.96 and formed a monophyletic group with bootstrap value of 100% (Fig. 1). This species is commonly found in soil as saprophytes, but this is the first report of the isolation of M. ambigua in Korea.
Morphological characterization of the isolate KNU14-14
Photomicrographs of the morphological structures of the isolate KNU14-14 are shown in Fig. 3. Colonies grew moderately fast on PDA, reaching a diameter of 64~68 mm in 5 days at 28. The front and reverse sides of the colony were milky white in color, cottony, and non-lobed. Aerial mycelium formed irregular bead-like hyphal swellings and sporulation was scanty. Colonies also grew fast on MEA, reaching a diameter of 65~73 mm in 5 days at 28. The colonies were a dirty whitish color, broadly zonate producing a concentric pattern, and lobed at the margin. Sporulation was abundant. The sporangiophores were hyaline, erect, and simple. They were 25~450 µm long, tapered towards the apex. They were 7~25 µm wide at the base and 2~5 µm wide at the apex, bearing single terminal sporangia. The main sporangiophore frequently formed vesicles without sporangia. The sporangia were spherical, 3~35 µm in diameter, wrinkled, and non-columellate. The sporangiospores were globose to sub-globose, singlecelled, and 2.5~5.5 µm in diameter. The chlamydospores were brown, globose, thick-walled, and 19~30 µm in diameter.
Conclusions regarding the isolate KNU14-14
The isolate KNU14-14 was assumed to belong to the genus Mortierella based on the morphologies of its sporangiophores and sporangia and its gross colony appearance. The isolate reasonably fits the description of M. ambigua, which was originally isolated from garden soil [17]. The isolate KNU14-14 from crop field soil only slightly differs from the original description in its sizes of sporangiophores, sporangia, and sporangiospores. It has been reported that the asexual fruiting habit of Mortierella species may change and that one or more stages may not appear depending upon the culture conditions [18,19,20]. Thus, it can be concluded that no other described Mortierella species matches the studied isolate.
Molecular phylogeny of the isolate KNU14-17
KNU14-17 was isolated from crop field soil in Gyeonggi-do, Korea in July 2014. ITS rDNA and 28S rDNA sequences were compared to determine the phylogenetic relationship between the isolate KNU14-17 and previously described Mortierella species. The isolate was most closely related to the type strain CBS 720.71 of M. indohii and formed a monophyletic group with bootstrap value of 92% (Fig. 1). This is a common species found in soil, but this is the first report of its occurrence in Korea.
Morphological characterization of the isolate KNU14-17
Photomicrographs of morphological structures of the isolate KNU14-7 are shown in Fig. 4. Colonies grew fast on PDA, reaching a diameter of 70~73 mm in 5 days at 28. The colonies were snow-white in color and broadly zonate with scanty aerial mycelium. The colonies also grew rapidly on MEA, reaching a diameter of 75~79mm in 5 days at 28. The reverse side of the colony was yellowish white. The front side of the colony was snow-white in color and narrowly zonate. The surface of the colony appeared mealy because of the large number of stylospores. Sporulation was abundant. Sporangiophores were absent. Stylosporebearing stalks were erect, delicate, unbranched, and sometimes swelled at the tip. The stalks were 50~160 µm long and 1.5~2.5 µm wide. The stylospores were almost spherical, 12~18 µm in diameter, thick-walled, and covered with delicate spines.
Conclusions regarding the isolate KNU14-17
The isolate KNU14-17 is M. indohii based on its gross colony appearance and stylospores. The stylospores of the isolate KNU14-17 most closely resemble those of M. polycephala, which are commonly both aerial and submerged. The stylospores of this isolate differ from those of M. polycephala in that they are more perfectly globose and slightly larger. The isolate reasonably fits Chien's (1974) diagnosis [20] of M. indohii, which was originally isolated from the dung of ground hog in Memorial Park, Athens, Georgia. Stylospores are the major characteristics of M. indohii, a species with a close phylogenetic relationship to Mortierella polygonia and Mortierella hypsicladia[16]. Thus, our findings are in accordance with the findings of Wagner et al.[16].
Arachidonic acid production of isolates KNU14-5, KNU14-14, and KNU14-17
The isolates KNU14-5, KNU14-14, and KNU14-17 were stained with TTC to evaluate their arachidonic acid production potential. The results are presented in Table 1 and Fig. 5. The degree of staining was the highest in M. zychae(KNU14-5), with a staining value of 2.012, followed by that in M. ambigua(KNU14-14) and M. indohii(KNU14-17) with staining values of 1.728 and 0.812, respectively. TTC reduction is commonly used as a biochemical marker for the viability of plant cells and tissues and as a measurement of bacterial respiratory activity [21,22]. It is generally thought that TTC is reduced by dehydrogenases and absorbed by living cells [22] where it reacts with hydrogen atoms released by the dehydrogenase enzymes during cellular respiration [23]. There is a positive correlation (r= 0.982) between the degree of TTC staining and arachidonic acid content in mycelia lipids and fungi that did not produce arachidonic acid could not be stained [10,24]. The results of TTC staining (Table 1) clearly revealed that the three newly recorded Mortierellaspecies, especially M. zychae(KNU14-5) and M. ambigua(KNU14-14), could be potential producers of arachidonic acid. However, further studies on the yield of arachidonic acid by the present isolates under different culture conditions are needed.
Table 1
Mean values are given of triplicate samples (± SE). Values with the different alphabetic superscripts are significantly different at p≤ 0.05 levels according to Duncan's multiple range test.
ACKNOWLEDGEMENTS
This work was supported by a grant (NIBR2014-01205) from the National Institute of Biological Resources (NIBR), funded by the Ministry of Environment (MOE) of the Republic of Korea for projects on the survey and discovery of indigenous Korean fungal species.
References
Articles from Mycobiology are provided here courtesy of Korean Society of Mycology
Full text links
Read article at publisher's site: https://doi.org/10.5941/myco.2015.43.3.203
Read article for free, from open access legal sources, via Unpaywall: https://www.tandfonline.com/doi/pdf/10.5941/MYCO.2015.43.3.203?needAccess=true&role=button
Citations & impact
Impact metrics
Citations of article over time
Alternative metrics
Article citations
Diversity of soil fungi from sacred groves of Kerala, India revealed by comparative metagenomics analysis using illumina sequencing.
3 Biotech, 14(3):79, 16 Feb 2024
Cited by: 0 articles | PMID: 38371901
Microecological Shifts in the Rhizosphere of Perennial Large Trees and Seedlings in Continuous Cropping of Poplar.
Microorganisms, 12(1):58, 28 Dec 2023
Cited by: 0 articles | PMID: 38257884 | PMCID: PMC10820384
Do the Reclaimed Fungal Communities Succeed Toward the Original Structure in Eco-Fragile Regions of Coal Mining Disturbances? A Case Study in North China Loess-Aeolian Sand Area.
Front Microbiol, 13:770715, 01 Apr 2022
Cited by: 0 articles | PMID: 35432266 | PMCID: PMC9010878
Agricultural management and plant selection interactively affect rhizosphere microbial community structure and nitrogen cycling.
Microbiome, 7(1):146, 07 Nov 2019
Cited by: 64 articles | PMID: 31699148 | PMCID: PMC6839119
Synthesis of Indoleacetic Acid, Gibberellic Acid and ACC-Deaminase by Mortierella Strains Promote Winter Wheat Seedlings Growth under Different Conditions.
Int J Mol Sci, 19(10):E3218, 18 Oct 2018
Cited by: 27 articles | PMID: 30340353 | PMCID: PMC6214141
Other citations
Data
Data behind the article
This data has been text mined from the article, or deposited into data resources.
BioStudies: supplemental material and supporting data
Nucleotide Sequences (3)
- (1 citation) ENA - KP966612
- (1 citation) ENA - KP966613
- (1 citation) ENA - KP055598
Similar Articles
To arrive at the top five similar articles we use a word-weighted algorithm to compare words from the Title and Abstract of each citation.
Production of arachidonic acid and dihomo-gamma-linolenic acid from glycerol by oil-producing filamentous fungi, Mortierella in the ARS culture collection.
J Ind Microbiol Biotechnol, 35(6):501-506, 15 Jan 2008
Cited by: 9 articles | PMID: 18196303
First Report of Mortierella alpina (Mortierellaceae, Zygomycota) Isolated from Crop Field Soil in Korea.
Mycobiology, 42(4):401-404, 31 Dec 2014
Cited by: 6 articles | PMID: 25606014 | PMCID: PMC4298846
Isolating Mortierella alpina strains of high yield of arachidonic acid.
Lett Appl Microbiol, 39(4):332-335, 01 Jan 2004
Cited by: 11 articles | PMID: 15355534
[Progress in production of arachidonic acid by Mortierella alpina and genetic modification].
Sheng Wu Gong Cheng Xue Bao, 26(9):1232-1238, 01 Sep 2010
Cited by: 0 articles | PMID: 21141113
Review
Research advances on arachidonic acid production by fermentation and genetic modification of Mortierella alpina.
World J Microbiol Biotechnol, 37(1):4, 04 Jan 2021
Cited by: 4 articles | PMID: 33392832
Review