Your search keyword '"Ren, Xipeng"' showing total 12 results

1. Enhancing soil health and carbon sequestration through phytogenic treatment: insights into microbial functional pathways in pasture dieback affected soil

Author

Ren, Xipeng, Whitton, Maria M., Trotter, Tieneke, Ashwath, Nanjappa, Stanley, Dragana, and Bajagai, Yadav S.

Published

2024

2. Humate application alters microbiota–mineral interactions and assists in pasture dieback recovery

Author

Whitton, Maria M., Ren, Xipeng, Yu, Sung J., Irving, Andrew D., Trotter, Tieneke, Bajagai, Yadav S., and Stanley, Dragana

Published

2023

3. Ileum transcriptional response to prolonged supplementation with phytogenic product containing menthol, carvacrol and carvone

Author

Bajagai, Yadav S., Petranyi, Friedrich, Horyanto, Darwin, Batacan, Romeo, Jr., Lobo, Edina, Ren, Xipeng, Whitton, Maria M., Yu, Sung J., Kayal, Advait, and Stanley, Dragana

Published

2022

4. Phytogenic supplement containing menthol, carvacrol and carvone ameliorates gut microbiota and production performance of commercial layers

Author

Bajagai, Yadav S., Petranyi, Friedrich, J. Yu, Sung, Lobo, Edina, Batacan, Jr., Romeo, Kayal, Advait, Horyanto, Darwin, Ren, Xipeng, M. Whitton, Maria, and Stanley, Dragana

Published

2022

5. Unveiling Microbial Dynamics and Gene Expression in Legume–Buffel Grass Coculture Systems for Sustainable Agriculture.

Author

Ren, Xipeng, Yu, Sung J., Brewer, Philip B., Ashwath, Nanjappa, Bajagai, Yadav S., Stanley, Dragana, and Trotter, Tieneke

Subjects

*SUSTAINABLE agriculture, *ATMOSPHERIC nitrogen, *MICROBIAL diversity, *SOIL productivity, *GENE expression, *NITROGEN fixation

Abstract

Legumes enhance pasture health and soil productivity by fixing atmospheric nitrogen and boosting soil microbiota. We investigated the effects of tropical pasture legumes, including butterfly pea (Clitoria ternatea), seca stylo (Stylosanthes scabra), desmanthus (Desmanthus virgatus), lablab (Lablab purpureus), and Wynn cassia (Chamaecrista rotundifolia), on the soil microbial community and buffel grass (Cenchrus ciliaris) gene expression. Additionally, we explored the impact of a phytogenic bioactive product (PHY) in the coculture system. A pot trial using soil enriched with cow paunch compost included four treatments: monoculture of buffel grass and five legume species with and without PHY supplementation and coculture of buffel grass with each legume species with and without PHY supplementation. Actinobacteriota and Firmicutes were the dominant bacterial phyla. Regardless of PHY application, the coculture of buffel grass with legumes positively influenced microbial composition and diversity. Transcriptomic analysis revealed significant gene expression changes in buffel grass shoots and roots, with each legume uniquely affecting nitrogen metabolism. Lablab and Wynn cassia exhibited similarities in modulating metabolic processes, butterfly pea contributed to mycotoxin detoxification, and desmanthus balanced cell death and growth. Seca stylo enhanced root cell growth and regeneration. These findings offer insights for optimizing legume–grass coculture systems, enhancing soil activity and promoting sustainable agriculture. [ABSTRACT FROM AUTHOR]

Published

2024

6. Transcriptomic Insights: Phytogenic Modulation of Buffel Grass (Cenchrus ciliaris) Seedling Emergence.

Author

Ren, Xipeng, Trotter, Tieneke, Ashwath, Nanjappa, Stanley, Dragana, Bajagai, Yadav S., and Brewer, Philip B.

Subjects

PENTOSE phosphate pathway, TRANSCRIPTOMES, ENERGY metabolism, TRICARBOXYLIC acids, GENE expression, HEMODILUTION, GERMINATION

Abstract

This study explores the impact of a novel phytogenic product containing citric acid, carvacrol, and cinnamaldehyde on buffel grass (Cenchrus ciliaris) seedling emergence. A dilution series of the phytogenic solution revealed a concentration range that promoted seedling emergence, with an optimal concentration of 0.5%. Transcriptomic analysis using RNA-seq was performed to investigate gene expression changes in seedlings under the influence of the phytogenic product. The results revealed that the phytogenic treatment significantly altered the gene expression, with a prevalent boost in transcriptional activity compared to the control. Functional analysis indicated the positive alteration of key metabolic pathways, including the tricarboxylic acid (TCA) cycle, glycolysis, and pentose phosphate pathways. Moreover, pathways related to amino acids, nucleotide biosynthesis, heme biosynthesis, and formyltetrahydrofolate biosynthesis showed substantial modulation. The study provides valuable insights into the molecular mechanisms underlying the phytogenic product's effects on grass seedling establishment and highlights its ability to promote energy metabolism and essential biosynthetic pathways for plant growth. [ABSTRACT FROM AUTHOR]

Published

2024

7. Application of Phytogenic Liquid Supplementation in Soil Microbiome Restoration in Queensland Pasture Dieback.

Author

Ren, Xipeng, Whitton, Maria M., Yu, Sung J., Trotter, Tieneke, Bajagai, Yadav S., and Stanley, Dragana

Subjects

SOIL restoration, DIEBACK, PASTURES, AGRICULTURE, BEEF industry, PLANT productivity, SOIL microbial ecology, RHIZOSPHERE, GRASSLAND soils

Abstract

Pasture production is vital in cattle farming as it provides animals with food and nutrients. Australia, as a significant global beef producer, has been experiencing pasture dieback, a syndrome of deteriorating grassland that results in the loss of grass and the expansion of weeds. Despite two decades of research and many remediation attempts, there has yet to be a breakthrough in understanding the causes or mechanisms involved. Suggested causes of this phenomenon include soil and plant microbial pathogens, insect infestation, extreme heat stress, radiation, and others. Plants produce a range of phytomolecules with antifungal, antibacterial, antiviral, growth-promoting, and immunostimulant effects to protect themselves from a range of environmental stresses. These products are currently used more in human and veterinary health than in agronomy. In this study, we applied a phytogenic product containing citric acid, carvacrol, and cinnamaldehyde, to investigate its ability to alleviate pasture dieback. The phytogenic liquid-based solution was sprayed twice, one week apart, at 5.4 L per hectare. The soil microbial community was investigated longitudinally to determine long-term effects, and pasture productivity and plant morphometric improvements were explored. The phytogenic liquid significantly improved post-drought recovery of alpha diversity and altered temporal and spatial change in the community. The phytogenic liquid reduced biomarker genera associated with poor and polluted soils and significantly promoted plant and soil beneficial bacteria associated with plant rhizosphere and a range of soil benefits. Phytogenic liquid application produced plant morphology improvements and a consistent enhancement of pasture productivity extending beyond 18 months post-application. Our data show that phytogenic products used in the livestock market as an alternative to antibiotics may also have a beneficial role in agriculture, especially in the light of climate change-related soil maintenance and remediation. [ABSTRACT FROM AUTHOR]

Published

2023

8. Remediation of Pasture Dieback Using Plant Growth Promotant.

Author

Whitton, Maria M., Ren, Xipeng, Yu, Sung J., Trotter, Tieneke, Stanley, Dragana, and Bajagai, Yadav S.

Subjects

*PLANT growth, *DIEBACK, *PASTURES, *ANIMAL feeds, *SOIL remediation, *HEAVY-metal tolerant plants, *GRASSES

Abstract

Pasture dieback is a syndrome of unknown cause affecting grasses in Australia, creating significant economic losses to farmers by reducing available livestock feed and paddock carrying capacity. RC3 is a commercial plant growth stimulant tri-sodium salt of trimercapto-S-triazine (TMT) and potassium humate as active ingredients. TMT is commonly used for soil and wastewater remediation by capturing and binding heavy metals, while potassium humate is an organic compound used as a plant growth promoter. We investigated the ability of RC3 to restore soil health and productivity under pasture dieback conditions. RC3 was applied on pasture dieback affected paddock replicate plots once, at a rate of 4 mL/m2, and soil core samples were taken weekly to analyse microbial communities. Plants were collected regularly to measure dry matter and plant morphometrics. Twenty weeks after a single application, dry matter increased in RC3 plots by 900 kg/ha compared to control plots, and at week 48, eleven months after the single application, RC3 plots showed a trend of more grass and dicot species than the control. Morphometric measures suggest minor improvements in dicotyledon plants. Alpha diversity did not change with the application of RC3. Temporal correlation analysis shows that RC3 steadily reduced the presence of genera predominant in poor soils and with extreme environmental conditions over time and prevented the decline of beneficial genera, such as Marmoricola, Actinomadura, Dactylosporangium, and mle1-7. [ABSTRACT FROM AUTHOR]

Published

2022

9. Sea Minerals Reduce Dysbiosis, Improve Pasture Productivity and Plant Morphometrics in Pasture Dieback Affected Soils.

Author

Whitton, Maria M., Ren, Xipeng, Yu, Sung J., Irving, Andrew D., Trotter, Tieneke, Bajagai, Yadav S., and Stanley, Dragana

Abstract

Pasture dieback (PD) is a grassland deteriorating syndrome resulting in grass loss and weed expansion in Australian pastures, with current estimates indicating that over four million hectares are affected. PD creates financial losses to the industry by reducing animal carrying capacity and producing poor-quality feed, resulting in diminished productivity. After more than a decade since PD first appeared in Australia, the causes and effective treatments are still unknown. Suggested causes include soil microbiota dysbiosis, pathogens, insects, climate change and overuse of chemical fertilisers. Sea minerals have been suggested as capable of improving plants' yield, quality, taste, and nutritional value, but were never brought into conventional practice as an alternative to chemical fertilisers. Here, we investigated the capacity of sea minerals to improve grass health and yield of PD-affected soil. The replicate plots were treated with water or with 4 mL/m2 of commercially available sea mineral product to investigate the soil chemistry profile, plant morphometrics, pasture productivity, soil microbiota profile, and microbiota-nutrient interactions. Sea mineral application significantly increased total dry matter 20 weeks after a single application, translating to an additional 967 kg/ha; this benefit was still present at 498 kg/ha eleven months post a single application. Sea mineral application improved soil microbiota by boosting beneficial taxa while reducing genera associated with arid and toxic soils. Additionally, sea mineral application increased the number of grassroots up to eleven months post a single application. Our data suggest the benefits of sea mineral application to damaged, unproductive or exhausted soils could be further explored as a natural, affordable, and non-toxic alternative to chemical fertilisers. [ABSTRACT FROM AUTHOR]

Published

2022

10. The role of microbiota in animal health and productivity: misinterpretations and limitations.

Author

Bajagai, Yadav S., Trotter, Mark, Williams, Thomas M., Costa, Diogo F. A., Whitton, Maria M., Ren, Xipeng, Wilson, Cara S., and Stanley, Dragana

Abstract

The rise of sequencing technology brought about a surge of new methodologies that offered a new and deeper level of understanding of the role of the microbiome in the health and performance of livestock. This started a chain reaction in technology evolution, and a decade later, we have developed a new appreciation of a healthy gut and the role of early colonisation and nutrition in developing the microbiome, and its subsequent impact on animal productivity. An abundance of new products flooded the livestock supplement market with the promise of improving the health of intestinal microbiota. However, the impact of these products and any potential gains they might provide have not always been quantified or validated. Further to this, the potential interactions with the microbial community naturally occurring in the feed-base have not commonly been considered. We have recently shown that animal feed carries a complex microbial community that can have various impacts, including negating farm biosecurity measures. The ruminant animal provides an even greater level of complexity where physiological drivers act to maintain ruminal homeostasis. Despite many advances, numerous knowledge gaps remain, and the methodologies are not without their challenges with almost constant evolution in analysing and interpreting data. In this paper, we will discuss the benefits, challenges and shortfalls of microbiome science, its interfaces with multi-omics research and the strategies of its contribution to animal production science. With advances in sequencing technology, research of microbial communities has become more accessible and affordable. In livestock research, the roles of microbiota are associated with animal performance and welfare. Although universally accepted, amplicon-sequencing methodology has several issues that need to be considered in data interpretation. Here we review the main shortfalls, benefits and uses of the methodology in livestock research. [ABSTRACT FROM AUTHOR]

Published

2022

11. Improving the Tribological Properties of Spark-Anodized Titanium by Magnetron Sputtered Diamond-Like Carbon.

Author

Chen, Zhaoxiang, Ren, Xipeng, Ren, Limei, Wang, Tengchao, Qi, Xiaowen, and Yang, Yulin

Subjects

TRIBOLOGY, TITANIUM, ANODIC oxidation of metals

Abstract

Spark-anodization of titanium can produce adherent and wear-resistant TiO2 film on the surface, but the spark-anodized titanium has lots of surface micro-pores, resulting in an unstable and high friction coefficient against many counterparts. In this study, the diamond-like carbon (DLC) was introduced into the micro-pores of spark-anodized titanium by the magnetron sputtering technique and a TiO2/DLC composite coating was fabricated. The microstructure and tribological properties of TiO2/DLC composite coating were investigated and compared with the anodic TiO2 mono-film and DLC mono-film. Results show that the DLC deposition significantly decreased the surface roughness and porosity of spark-anodized titanium. The fabricated TiO2/DLC composite coating exhibited a more stable and much lower friction coefficient than anodic TiO2 mono-film. Although the friction coefficient of the composite coating and the DLC mono-film was similar under both light load and heavy load conditions, the wear life of the composite coating was about 43% longer than that of DLC mono-film under heavy load condition. The wear rate of titanium with protective composite coating was much lower than that of titanium with DLC mono-film. The superior low friction coefficient and wear rate of the TiO2/DLC composite coating make it a good candidate as protective coating on titanium alloys. [ABSTRACT FROM AUTHOR]

Published

2018

12. Functional Materials Based on Active Carbon and Titanium Dioxide in Fog Seal.

Author

He, Chuan, Xiao, Qingyi, Gong, Fangyuan, Yang, Yun, and Ren, Xipeng

Subjects

TITANIUM dioxide, CARBON dioxide, NITROGEN oxides, SKID resistance, ASPHALT concrete, COMPOSITE materials

Abstract

Due to its ability to degrade nitrogen oxides under ultraviolet, titanium dioxide has been applied in asphalt concrete to degrade automobile exhaust in recent years. To highlight the protection of road traffic environmental quality and mitigate automobile exhaust on human health, this study proposes combining titanium dioxide and active carbon into Sand-fog seal to form a pavement coating material with a photocatalytic function. It uses active carbon to reinforce the material's function, and the coupling agent for modification makes it well dispersed in the Sand-fog seal. The indoor experiments were carried out at 30 °C and relative humidity of 30%. It tested the composite material's degradation efficiency on nitrogen dioxide in relation to component proportions, coupling agents, and dosages. The study concluded that the optimal photocatalytic efficiency could be achieved when the ratio of active carbon to titanium dioxide is 0.6. After being modified by the titanate coupling agent and through Scanning Electron Microscope tests, it can be seen that materials can be well dispersed into the Sand-fog seal. When the composite material accounts for 10% of the fog seal, it can achieve the optimal photocatalytic efficiency of about 23.9%. The British pendulum tests show it has good skid resistance performance. Half a kilometer of concrete roadway was sprayed with the material coating in Tianjin, China. The photocatalytic experimental road degrades nitrogen oxides better than the original road. The method is feasible for practical implementation. [ABSTRACT FROM AUTHOR]

Published

2020