Your search keyword '"Sharon Yu Ling Lau"' showing total 14 results

1. Sphagnum capillifolium holobiont from a subarctic palsa bog aggravates the potential of nitrous oxide emissions

Author

Yanxia Nie, Sharon Yu Ling Lau, Xiangping Tan, Xiankai Lu, Suping Liu, Teemu Tahvanainen, Reika Isoda, Qing Ye, and Yasuyuki Hashidoko

Subjects

Sphagnum moss, bacteria, N2O emitters, N2O-related genes, pH, permafrost peat, Plant culture, SB1-1110

Abstract

Melting permafrost mounds in subarctic palsa mires are thawing under climate warming and have become a substantial source of N2O emissions. However, mechanistic insights into the permafrost thaw-induced N2O emissions in these unique habitats remain elusive. We demonstrated that N2O emission potential in palsa bogs was driven by the bacterial residents of two dominant Sphagnum mosses especially of Sphagnum capillifolium (SC) in the subarctic palsa bog, which responded to endogenous and exogenous Sphagnum factors such as secondary metabolites, nitrogen and carbon sources, temperature, and pH. SC's high N2O emission activity was linked with two classes of distinctive hyperactive N2O emitters, including Pseudomonas sp. and Enterobacteriaceae bacteria, whose hyperactive N2O emitting capability was characterized to be dominantly pH-responsive. As the nosZ gene-harboring emitter, Pseudomonas sp. SC-H2 reached a high level of N2O emissions that increased significantly with increasing pH. For emitters lacking the nosZ gene, an Enterobacteriaceae bacterium SC-L1 was more adaptive to natural acidic conditions, and N2O emissions also increased with pH. Our study revealed previously unknown hyperactive N2O emitters in Sphagnum capillifolium found in melting palsa mound environments, and provided novel insights into SC-associated N2O emissions.

Published

2022

2. Linking prokaryotic community composition to carbon biogeochemical cycling across a tropical peat dome in Sarawak, Malaysia

Author

Simon Peter Dom, Makoto Ikenaga, Sharon Yu Ling Lau, Son Radu, Frazer Midot, Mui Lan Yap, Mei-Yee Chin, Mei Lieng Lo, Mui Sie Jee, Nagamitsu Maie, and Lulie Melling

Subjects

Medicine, Science

Abstract

Abstract Tropical peat swamp forest is a global store of carbon in a water-saturated, anoxic and acidic environment. This ecosystem holds diverse prokaryotic communities that play a major role in nutrient cycling. A study was conducted in which a total of 24 peat soil samples were collected in three forest types in a tropical peat dome in Sarawak, Malaysia namely, Mixed Peat Swamp (MPS), Alan Batu (ABt), and Alan Bunga (ABg) forests to profile the soil prokaryotic communities through meta 16S amplicon analysis using Illumina Miseq. Results showed these ecosystems were dominated by anaerobes and fermenters such as Acidobacteria, Proteobacteria, Actinobacteria and Firmicutes that cover 80–90% of the total prokaryotic abundance. Overall, the microbial community composition was different amongst forest types and depths. Additionally, this study highlighted the prokaryotic communities’ composition in MPS was driven by higher humification level and lower pH whereas in ABt and ABg, the less acidic condition and higher organic matter content were the main factors. It was also observed that prokaryotic diversity and abundance were higher in the more oligotrophic ABt and ABg forest despite the constantly waterlogged condition. In MPS, the methanotroph Methylovirgula ligni was found to be the major species in this forest type that utilize methane (CH4), which could potentially be the contributing factor to the low CH4 gas emissions. Aquitalea magnusonii and Paraburkholderia oxyphila, which can degrade aromatic compounds, were the major species in ABt and ABg forests respectively. This information can be advantageous for future study in understanding the underlying mechanisms of environmental-driven alterations in soil microbial communities and its potential implications on biogeochemical processes in relation to peatland management.

Published

2021

3. Genetic Diversity and Demographic History of Ganoderma boninense in Oil Palm Plantations of Sarawak, Malaysia Inferred from ITS Regions

Author

Frazer Midot, Sharon Yu Ling Lau, Wei Chee Wong, Hun Jiat Tung, Mui Lan Yap, Mei Lieng Lo, Mui Sie Jee, Simon Peter Dom, and Lulie Melling

Subjects

ganoderma boninense, oil palm, basal stem rot, phylogenetic, phylogeographic relationship, its, Biology (General), QH301-705.5

Abstract

Ganoderma boninense causes basal stem rot (BSR) and is responsible for substantial economic losses to Southeast Asia’s palm oil industry. Sarawak, a major producer in Malaysia, is also affected by this disease. Emergence of BSR in oil palm planted on peat throughout Sarawak is alarming as the soil type was previously regarded as non-conducive. Phylogenetic analysis indicated a single species, G. boninense as the cause of BSR in Sarawak. Information on evolutionary and demographic history for G. boninense in Sarawak inferred through informative genes is lacking. Hence, a haplotype study on single nucleotide polymorphisms in internal transcribed spacers (SNPs-ITS) of G. boninense was carried out. Sequence variations were analysed for population structure, phylogenetic and phylogeographic relationships. The internal transcribed spacers (ITS) region of 117 isolates from four populations in eight locations across Sarawak coastal areas revealed seven haplotypes. A major haplotype, designated GbHap1 (81.2%), was found throughout all sampling locations. Single nucleotide polymorphisms were observed mainly in the ITS1 region. The genetic structure was not detected, and genetic distance did not correlate with geographical distance. Haplotype network analysis suggested evidence of recent demographic expansion. Low genetic differences among populations also suggested that these isolates belong to a single G. boninense founder population adapting to oil palm as the host.

Published

2019

4. Comparison of Ganoderma boninense Isolate’s Aggressiveness Using Infected Oil Palm Seedlings

Author

Mei Lieng Lo, Tu Anh Vu Thanh, Frazer Midot, Sharon Yu Ling Lau, Wei Chee Wong, Hun Jiat Tung, Mui Sie Jee, Mei-Yee Chin, and Lulie Melling

Subjects

General Medicine, Applied Microbiology and Biotechnology, Microbiology

Abstract

Basal stem rot incidence caused by a white-rot fungus, Ganoderma boninense, is the major disease of oil palm in Southeast Asia. The rate of disease transmission and host damage are affected by variations in pathogen aggressiveness. Several other studies have used the disease severity index (DSI) to determine G. boninense aggressiveness levels while verifying disease using a culture-based method, which might not provide accurate results or be feasible in all cases. To differentiate G. boninense aggressiveness, we employed the DSI and vegetative growth measurement of infected oil palm seedlings. Disease confirmation was performed through scanning electron microscopy and molecular identification of fungal DNA from both infected tissue and fungi isolated from Ganoderma selective medium. Two-month-old oil palm seedlings were artificially inoculated with G. boninense isolates (2, 4A, 5A, 5B, and 7A) sampled from Miri (Lambir) and Mukah (Sungai Meris and Sungai Liuk), Sarawak. The isolates were categorized into three groups: highly aggressive (4A and 5B), moderately aggressive (5A and 7A), and less aggressive (2). Isolate 5B was identified as the most aggressive, and it was the only one to result in seedling mortality. Out of the five vegetative growth parameters measured, only the bole size between treatments was not affected. The integration of both conventional and molecular approaches in disease confirmation allows for precise detection.

Published

2023

5. Application of ammonium sulfate affects greenhouse gases and microbial diversity of an oil palm plantation on tropical peat

Author

Sharon Yu Ling Lau, Frazer Midot, Simon Peter Dom, Mei Lieng Lo, Mei-Yee Chin, Mui Sie Jee, Mui Lan Yap, Auldry Chaddy, and Lulie Melling

Subjects

Soil Science, Agronomy and Crop Science

Published

2022

6. Root exclusion method for separating soil respiration components: Review and methodological considerations

Author

Mei-Yee CHIN, Sharon Yu Ling LAU, Frazer MIDOT, Mui Sie JEE, Mei Lieng LO, Faustina SANGOK, and Lulie MELLING

Subjects

Soil Science

Published

2023

7. Linking prokaryotic community composition to carbon biogeochemical cycling across a tropical peat dome in Sarawak, Malaysia

Author

Makoto Ikenaga, Lulie Melling, Mei Lieng Lo, Nagamitsu Maie, Son Radu, Simon Peter Dom, Mui Lan Yap, Sharon Yu Ling Lau, Frazer Midot, Mei-Yee Chin, and Mui Sie Jee

Subjects

0301 basic medicine, DNA, Bacterial, Nutrient cycle, Biogeochemical cycle, Peat, Firmicutes, Science, 030106 microbiology, Forests, Swamp, Article, Actinobacteria, Carbon Cycle, Trees, Microbial ecology, 03 medical and health sciences, Soil, Tropical peat, Beijerinckiaceae, RNA, Ribosomal, 16S, Phylogeny, Soil Microbiology, geography, Multidisciplinary, geography.geographical_feature_category, biology, Ecology, Burkholderiaceae, Microbiota, Malaysia, Betaproteobacteria, Carbon Dioxide, biology.organism_classification, Carbon, Acidobacteria, 030104 developmental biology, Wetlands, Environmental science, Medicine, Metagenomics, Methane

Abstract

Tropical peat swamp forest is a global store of carbon in a water-saturated, anoxic and acidic environment. This ecosystem holds diverse prokaryotic communities that play a major role in nutrient cycling. A study was conducted in which a total of 24 peat soil samples were collected in three forest types in a tropical peat dome in Sarawak, Malaysia namely, Mixed Peat Swamp (MPS), Alan Batu (ABt), and Alan Bunga (ABg) forests to profile the soil prokaryotic communities through meta 16S amplicon analysis using Illumina Miseq. Results showed these ecosystems were dominated by anaerobes and fermenters such as Acidobacteria, Proteobacteria, Actinobacteria and Firmicutes that cover 80–90% of the total prokaryotic abundance. Overall, the microbial community composition was different amongst forest types and depths. Additionally, this study highlighted the prokaryotic communities’ composition in MPS was driven by higher humification level and lower pH whereas in ABt and ABg, the less acidic condition and higher organic matter content were the main factors. It was also observed that prokaryotic diversity and abundance were higher in the more oligotrophic ABt and ABg forest despite the constantly waterlogged condition. In MPS, the methanotroph Methylovirgula ligni was found to be the major species in this forest type that utilize methane (CH4), which could potentially be the contributing factor to the low CH4 gas emissions. Aquitalea magnusonii and Paraburkholderia oxyphila, which can degrade aromatic compounds, were the major species in ABt and ABg forests respectively. This information can be advantageous for future study in understanding the underlying mechanisms of environmental-driven alterations in soil microbial communities and its potential implications on biogeochemical processes in relation to peatland management.

Published

2021

8. Microenvironmental Interplay Predominated by Beneficial Aspergillus Abates Fungal Pathogen Incidence in Paddy Environment

Author

Liu Yufei, Haruna Matsumoto, Hua Fang, Bartosz Nitkiewicz, Yang Hu, Mengcen Wang, Xiaoyan Fan, Sharon Yu Ling Lau, Yue Wang, Hongda Fang, and Qiangwei Wang

Subjects

Aspergillus, Appressorium, Fungal protein, Magnaporthe, biology, food and beverages, General Chemistry, Fungus, 010501 environmental sciences, biology.organism_classification, 01 natural sciences, Microbiology, Environmental Chemistry, Bioassay, Phyllosphere, Mycelium, 0105 earth and related environmental sciences

Abstract

Rice fungal pathogens, responsible for severe rice yield loss and biotoxin contamination, cause increasing concerns on environmental safety and public health. In the paddy environment, we observed that the asymptomatic rice phyllosphere microenvironment was dominated by an indigenous fungus, Aspergillus cvjetkovicii, which positively correlated with alleviated incidence of Magnaporthe oryzae, one of the most aggressive plant pathogens. Through the comparative metabolic profiling for the rice phyllosphere microenvironment, two metabolites were assigned as exclusively enriched metabolic markers in the asymptomatic phyllosphere and increased remarkably in a population-dependent manner with A. cvjetkovicii. These two metabolites evidenced to be produced by A. cvjetkovicii in either a phyllosphere microenvironment or artificial media were purified and identified as 2(3H)-benzofuranone and azulene, respectively, by gas chromatography coupled to triple quadrupole mass spectrometry and nuclear magnetic resonance analyses. Combining with bioassay analysis in vivo and in vitro, we found that 2(3H)-benzofuranone and azulene exerted dissimilar actions at the stage of infection-related development of M. oryzae. A. cvjetkovicii produced 2(3H)-benzofuranone at the early stage to suppress MoPer1 gene expression, leading to inhibited mycelial growth, while azulene produced lately was involved in blocking of appressorium formation by downregulation of MgRac1. More profoundly, the microenvironmental interplay dominated by A. cvjetkovicii significantly blocked M. oryzae epidemics in the paddy environment from 54.7 to 68.5% (p < 0.05). Our study first demonstrated implication of the microenvironmental interplay dominated by indigenous and beneficial fungus to ecological balance and safety of the paddy environment.

Published

2019

9. Emericella nidulans (4DP5), Cladosporium herbarum (7DF12) and Bacillus subtilis improve the nutritional value of palm kernel cake (PKC) through solid-state fermentation (SSF).

Author

Sharon Yu Ling Lau, Halim, Mardani Abdul, Douglas Telajan, Elaine Remi Anak, and Vui Ling Wong, Clemente Michael

Subjects

CLADOSPORIUM, SOLID-state fermentation, AMINO acids, ANIMAL feeds, AFLATOXINS

Abstract

Aims: Palm kernel cake (PKC) is a high-protein, high-energy food that is widely utilized in the animal feed business. However, the high fibre and limited amino acid content of untreated PKC were the main issues for it to be used as animal feed, particularly in non-ruminants. To improve the quality of PKC, this study combined the use of solid-state fermentation (SSF) and consortia of fungi and bacteria to treat the PKC. Methodology and results: Two fungi, Emericella nidulans (4DP5) and Cladosporium herbarum (7DF12) and three strains of bacteria, Bacillus subtilis, which were active mannanase producers, were used in different combinations to reduce the hemicellulose content and improve the crude protein content of PKC in a lab-scale solid-state fermentation. PKC inoculated separately with five types of mixed culture treatments were allowed to ferment. The fermentation conditions were 20% inoculum (w/v), 85-92% humidity, pH 7.0 and PKC particle size 0.8 mm. PKC treatments with two fungi, E. nidulans (4DP5) and C. herbarum (7DF12), as well as a fungus-bacterium combination, E. nidulans (4DP5) and B. subtilis, outperformed the other three treatments. The crude protein levels were increased by 3.34% and 1.86%, respectively, due to these treatments. Furthermore, the level of aflatoxins produced increased marginally but remained within the permissible limits. Conclusion, significance and impact of study: The treated PKC has more sugar and crude protein and less than 20 parts per billion (ppb) of aflatoxin, making it appropriate for animal consumption. The SSF technique of combining fungi and Bacilli enhanced the nutritional and market value of PKC substantially, which can be upscaled. [ABSTRACT FROM AUTHOR]

Published

2022

10. Microenvironmental Interplay Predominated by Beneficial

Author

Xiaoyan, Fan, Haruna, Matsumoto, Yue, Wang, Yang, Hu, Yufei, Liu, Hongda, Fang, Bartosz, Nitkiewicz, Sharon Yu Ling, Lau, Qiangwei, Wang, Hua, Fang, and Mengcen, Wang

Subjects

Fungal Proteins, Magnaporthe, Aspergillus, Incidence, Oryza, Gas Chromatography-Mass Spectrometry, Temefos, Plant Diseases

Abstract

Rice fungal pathogens, responsible for severe rice yield loss and biotoxin contamination, cause increasing concerns on environmental safety and public health. In the paddy environment, we observed that the asymptomatic rice phyllosphere microenvironment was dominated by an indigenous fungus

Published

2019

11. Effects of Some Hill Reaction-Inhibiting Herbicides on Nitrous Oxide Emission from Nitrogen-Input Farming Soil

Author

Yasuyuki Hashidoko, Li Li, Yuta Takatsu, and Sharon Yu Ling Lau

Subjects

inorganic chemicals, denitrification inhibition, Denitrification, chemistry.chemical_element, Andisol farmland soil, Diquat, lcsh:Technology, lcsh:Chemistry, 03 medical and health sciences, chemistry.chemical_compound, Denitrifying bacteria, Bromacil, General Materials Science, Instrumentation, lcsh:QH301-705.5, 030304 developmental biology, Fluid Flow and Transfer Processes, 0303 health sciences, 030306 microbiology, lcsh:T, Process Chemistry and Technology, General Engineering, Hill reaction, Andisol, equipment and supplies, Nitrogen, lcsh:QC1-999, electron-transport inhibiting herbicide, Computer Science Applications, chemistry, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Environmental chemistry, N2O emission suppression, Nitrification, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics, Hill reaction inhibitors

Abstract

Nitrous oxide (N2O) emission-suppressing activity of some electron-transport inhibitors of the Hill reaction system was investigated. The Hill reaction inhibitors&mdash, paraquat, isouron, bromacil, diquat, and simazine&mdash, all of which have been or are currently being used as herbicides in farming activity are expected to inhibit the electron-transporting pathways of nitrate respiration in denitrifying bacteria. Using N2O-emitting soil bed (5.0 g of fresh weight) from a continuously manured Andisol corn farmland in Hokkaido, Japan, which was autoclaved and further supplemented with an active N2O-emitter, Pseudomonas sp. 5CFM15-6D, and 1 mL of 100 mM NH4NO3 or (NH4)2SO4 solution as the sole nitrogen source (final concentration, 0.2 mM) in a 30 mL gas-chromatography vial, the effects of the five herbicides on N2O emission were examined. Paraquat and isouron (each at 50 &micro, M) showed a statistically significant suppression of N2O emission in both the nitrification and the denitrification processes after a 7-day-incubation, whereas diquat at the same concentration accelerated N2O emission in the presence of NO3&minus, These results suggest that paraquat and isouron inhibited both the nitrification and the denitrification processes for N2O generation, or its upstream stages, whereas diquat specifically inhibited N2O reductase, an enzyme that catalyzes the reduction of N2O to N2 gas. Incomplete denitrifiers are the key players in the potent emission of N2O from Andisol corn farmland soil because of the missing nosZ gene. The electron relay system-inhibiting herbicides&mdash, paraquat and isouron&mdash, possibly contribute to the prevention of denitrification-induced nitrogen loss from the farming soil.

Published

2019

12. Genetic Diversity and Demographic History of Ganoderma boninense in Oil Palm Plantations of Sarawak, Malaysia Inferred from ITS Regions

Author

Mei Lieng Lo, Mui Lan Yap, Lulie Melling, Wei Chee Wong, Simon Peter Dom, Hun Jiat Tung, Sharon Yu Ling Lau, Mui Sie Jee, and Frazer Midot

Subjects

0106 biological sciences, 0301 basic medicine, Microbiology (medical), ganoderma boninense, Demographic history, Zoology, macromolecular substances, basal stem rot, Biology, complex mixtures, oil palm, 01 natural sciences, Microbiology, Article, 03 medical and health sciences, Virology, parasitic diseases, Genetic variation, its, lcsh:QH301-705.5, Genetic diversity, Phylogenetic tree, Haplotype, technology, industry, and agriculture, food and beverages, 030104 developmental biology, lcsh:Biology (General), Genetic distance, Genetic marker, Genetic structure, phylogeographic relationship, phylogenetic, Ganoderma boninense, 010606 plant biology & botany

Abstract

Ganoderma boninense causes basal stem rot (BSR) and is responsible for substantial economic losses to Southeast Asia&rsquo, s palm oil industry. Sarawak, a major producer in Malaysia, is also affected by this disease. Emergence of BSR in oil palm planted on peat throughout Sarawak is alarming as the soil type was previously regarded as non-conducive. Phylogenetic analysis indicated a single species, G. boninense as the cause of BSR in Sarawak. Information on evolutionary and demographic history for G. boninense in Sarawak inferred through informative genes is lacking. Hence, a haplotype study on single nucleotide polymorphisms in internal transcribed spacers (SNPs-ITS) of G. boninense was carried out. Sequence variations were analysed for population structure, phylogenetic and phylogeographic relationships. The internal transcribed spacers (ITS) region of 117 isolates from four populations in eight locations across Sarawak coastal areas revealed seven haplotypes. A major haplotype, designated GbHap1 (81.2%), was found throughout all sampling locations. Single nucleotide polymorphisms were observed mainly in the ITS1 region. The genetic structure was not detected, and genetic distance did not correlate with geographical distance. Haplotype network analysis suggested evidence of recent demographic expansion. Low genetic differences among populations also suggested that these isolates belong to a single G. boninense founder population adapting to oil palm as the host.

Published

2019

13. Correction: Corrigendum: Indole-3-Acetic Acid Produced by Burkholderia heleia Acts as a Phenylacetic Acid Antagonist to Disrupt Tropolone Biosynthesis in Burkholderia plantarii

Author

Mengcen Wang, Seiji Tachibana, Yuta Murai, Li Li, Sharon Yu Ling Lau, Mengchao Cao, Guonian Zhu, Makoto Hashimoto, and Yasuyuki Hashidoko

Subjects

Multidisciplinary, Indoleacetic Acids, Burkholderia, food and beverages, Corrigenda, Tropolone, Article, Phenylacetates

Abstract

Burkholderia heleia PAK1-2 is a potent biocontrol agent isolated from rice rhizosphere, as it prevents bacterial rice seedling blight disease caused by Burkholderia plantarii. Here, we isolated a non-antibacterial metabolite from the culture fluid of B. heleia PAK1-2 that was able to suppress B. plantarii virulence and subsequently identified as indole-3-acetic acid (IAA). IAA suppressed the production of tropolone in B. plantarii in a dose-dependent manner without any antibacterial and quorum quenching activity, suggesting that IAA inhibited steps of tropolone biosynthesis. Consistent with this, supplementing cultures of B. plantarii with either L-[ring-(2)H5]phenylalanine or [ring-(2)H2~5]phenylacetic acid revealed that phenylacetic acid (PAA), which is the dominant metabolite during the early growth stage, is a direct precursor of tropolone. Exposure of B. plantarii to IAA suppressed production of both PAA and tropolone. These data particularly showed that IAA produced by B. heleia PAK1-2 disrupts tropolone production during bioconversion of PAA to tropolone via the ring-rearrangement on the phenyl group of the precursor to attenuate the virulence of B. plantarii. B. heleia PAK1-2 is thus likely a microbial community coordinating bacterium in rhizosphere ecosystems, which never eliminates phytopathogens but only represses production of phytotoxins or bacteriocidal substances.

Published

2016

14. Indole-3-Acetic Acid Produced by Burkholderia heleia Acts as a Phenylacetic Acid Antagonist to Disrupt Tropolone Biosynthesis in Burkholderia plantarii

Author

Seiji Tachibana, Sharon Yu Ling Lau, Yuta Murai, Mengchao Cao, Guonian Zhu, Makoto Hashimoto, Li Li, Yasuyuki Hashidoko, and Mengcen Wang

Subjects

0301 basic medicine, Multidisciplinary, Metabolite, 030106 microbiology, Phenylalanine, Phenylacetic acid, Biology, biology.organism_classification, Tropolone, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Biochemistry, Biosynthesis, Indole-3-acetic acid, Bacteria, Burkholderia plantarii

Abstract

Burkholderia heleia PAK1-2 is a potent biocontrol agent isolated from rice rhizosphere, as it prevents bacterial rice seedling blight disease caused by Burkholderia plantarii. Here, we isolated a non-antibacterial metabolite from the culture fluid of B. heleia PAK1-2 that was able to suppress B. plantarii virulence and subsequently identified as indole-3-acetic acid (IAA). IAA suppressed the production of tropolone in B. plantarii in a dose-dependent manner without any antibacterial and quorum quenching activity, suggesting that IAA inhibited steps of tropolone biosynthesis. Consistent with this, supplementing cultures of B. plantarii with either L-[ring-2H5]phenylalanine or [ring-2H2~5]phenylacetic acid revealed that phenylacetic acid (PAA), which is the dominant metabolite during the early growth stage, is a direct precursor of tropolone. Exposure of B. plantarii to IAA suppressed production of both PAA and tropolone. These data particularly showed that IAA produced by B. heleia PAK1-2 disrupts tropolone production during bioconversion of PAA to tropolone via the ring-rearrangement on the phenyl group of the precursor to attenuate the virulence of B. plantarii. B. heleia PAK1-2 is thus likely a microbial community coordinating bacterium in rhizosphere ecosystems, which never eliminates phytopathogens but only represses production of phytotoxins or bacteriocidal substances.

Published

2016