Your search keyword '"Richardson, Alan E."' showing total 17 results

1. Manipulating exudate composition from root apices shapes the microbiome throughout the root system.

Author

Akitomo Kawasaki, Dennis, Paul G., Forstner, Christian, Raghavendra, Anil K. H., Mathesius, Ulrike, Richardson, Alan E., Delhaize, Emmanuel, Gilliham, Matthew, Watt, Michelle, and Ryan, Peter R.

Published

2021

2. Soil microbial communities influencing organic phosphorus mineralization in a coastal dune chronosequence in New Zealand.

Author

Gaiero, Jonathan R, Tosi, Micaela, Bent, Elizabeth, Boitt, Gustavo, Khosla, Kamini, Turner, Benjamin L, Richardson, Alan E, Condron, Leo M, and Dunfield, Kari E

Subjects

FUNGAL communities, SOIL microbial ecology, MICROBIAL communities, SOCIAL influence, SOIL composition, ACID phosphatase, ACID soils, SOILS

Abstract

The Haast chronosequence in New Zealand is an ∼6500-year dune formation series, characterized by rapid podzol development, phosphorus (P) depletion and a decline in aboveground biomass. We examined bacterial and fungal community composition within mineral soil fractions using amplicon-based high-throughput sequencing (Illumina MiSeq). We targeted bacterial non-specific acid (class A, phoN / phoC) and alkaline (phoD) phosphomonoesterase genes and quantified specific genes and transcripts using real-time PCR. Soil bacterial diversity was greatest after 4000 years of ecosystem development and associated with an increased richness of phylotypes and a significant decline in previously dominant taxa (Firmicutes and Proteobacteria). Soil fungal communities transitioned from predominantly Basidiomycota to Ascomycota along the chronosequence and were most diverse in 290- to 392-year-old soils, coinciding with maximum tree basal area and organic P accumulation. The Bacteria:Fungi ratio decreased amid a competitive and interconnected soil community as determined by network analysis. Overall, soil microbial communities were associated with soil changes and declining P throughout pedogenesis and ecosystem succession. We identified an increased dependence on organic P mineralization, as found by the profiled acid phosphatase genes, soil acid phosphatase activity and function inference from predicted metagenomes (PICRUSt2). [ABSTRACT FROM AUTHOR]

Published

2021

3. Earthworm-induced shifts in microbial diversity in soils with rare versus established invasive earthworm populations.

Author

de Menezes, Alexandre B., Prendergast-Miller, Miranda T., Macdonald, Lynne M., Toscas, Peter, Baker, Geoff, Farrell, Mark, Wark, Tim, Richardson, Alan E., and Thrall, Peter H.

Subjects

EARTHWORMS, SOIL microbial ecology, APORRECTODEA, BACTERIAL communities, HUMUS

Abstract

European earthworms have colonised many parts of Australia, although their impact on soil microbial communities remains largely uncharacterised. An experiment was conducted to contrast the responses to Aporrectodea trapezoides introduction between soils from sites with established (Talmo, 64 A. trapezoides m-2) and rare (Glenrock, 0.6 A. trapezoides m-2) A. trapezoides populations. Our hypothesis was that earthworm introduction would lead to similar changes in bacterial communities in both soils. The effects of earthworm introduction (earthworm activity and cadaver decomposition) did not lead to a convergence of bacterial community composition between the two soils. However, in both soils, the Firmicutes decreased in abundance and a common set of bacteria responded positively to earthworms. The increase in the abundance of Flavobacterium, Chitinophagaceae, Rhodocyclaceae and Sphingobacteriales were consistent with previous studies. Evidence for possible soil resistance to earthworms was observed, with lower earthworm survival in Glenrock microcosms coinciding with A. trapezoides rarity in this site, lower soil organic matter and clay content and differences in the diversity and abundance of potential earthworm mutualist bacteria. These results suggest that while the impacts of earthworms vary between different soils, the consistent response of some bacteria may aid in predicting the impacts of earthworms on soil ecosystems. [ABSTRACT FROM AUTHOR]

Published

2018

4. Plant roots: understanding structure and function in an ocean of complexity.

Author

Ryan, Peter R., Delhaize, Emmanuel, Watt, Michelle, and Richardson, Alan E.

Subjects

RHIZOSPHERE, SOIL microbiology, WATER supply, PLANT nutrients, ABIOTIC stress, PLANT growth

Abstract

* Background The structure and function of plant roots and their interactions with soil are exciting scientific frontiers that will ultimately reveal much about our natural systems, global water and mineral and carbon cycles, and help secure food supplies into the future. This Special Issue presents a collection of papers that address topics at the forefront of our understanding of root biology. * Scope These papers investigate how roots cope with drought, nutrient deficiencies, toxicities and soil compaction as well as the interactions that roots have with soil microorganisms. Roots of model plant species, annual crops and perennial species are studied in short-term experiments through to multi-year trials. Spatial scales range from the gene up to farming systems and nutrient cycling. The diverse, integrated approaches described by these studies encompass root genetics as applied to soil management, as well as documenting the signalling processes occurring between roots and shoots and between roots and soil. * Conclusions This Special Issue on roots presents invited reviews and research papers covering a span of topics ranging from fundamental aspects of anatomy, growth and water uptake to roots in crop and pasture systems. Understanding root structure and function and adaptation to the abiotic and biotic stresses encountered in field conditions is important for sustainable agricultural production and better management of natural systems. [ABSTRACT FROM AUTHOR]

Published

2016

5. Rhizosheaths on wheat grown in acid soils: phosphorus acquisition efficiency and genetic control.

Author

James, Richard A., Weligama, Chandrakumara, Verbyla, Klara, Ryan, Peter R., Rebetzke, Gregory J., Rattey, Allan, Richardson, Alan E., and Delhaize, Emmanuel

Subjects

WHEAT quality, ROOT formation, RHIZOSPHERE microbiology, COMPOSITION of wheat, ROOT hairs (Botany), ACID soils

Abstract

Rhizosheaths comprise soil bound to roots, and in wheat (Triticum aestivum L.) rhizosheath size correlates with root hair length. The aims of this study were to determine the effect that a large rhizosheath has on the phosphorus (P) acquisition by wheat and to investigate the genetic control of rhizosheath size in wheat grown on acid soil. Near-isogenic wheat lines differing in rhizosheath size were evaluated on two acid soils. The soils were fertilized with mineral nutrients and included treatments with either low or high P. The same soils were treated with CaCO3 to raise the pH and detoxify Al3+. Genotypic differences in rhizosheath size were apparent only when soil pH was low and Al3+ was present. On acid soils, a large rhizosheath increased shoot biomass compared with a small rhizosheath regardless of P supply. At low P supply, increased shoot biomass could be attributed to a greater uptake of soil P, but at high P supply the increased biomass was due to some other factor. Generation means analysis indicated that rhizosheath size on acid soil was controlled by multiple, additive loci. Subsequently, a quantitative trait loci (QTL) analysis of an F6 population of recombinant inbred lines identified five major loci contributing to the phenotype together accounting for over 60% of the total genetic variance. One locus on chromosome 1D accounted for 34% of the genotypic variation. Genetic control of rhizosheath size appears to be relatively simple and markers based on the QTL provide valuable tools for marker assisted breeding. [ABSTRACT FROM AUTHOR]

Published

2016

6. Effect of nitrogen and waterlogging on denitrifier gene abundance, community structure and activity in the rhizosphere of wheat.

Author

Hamonts, Kelly, Clough, Tim J., Stewart, Alison, Clinton, Peter W., Richardson, Alan E., Wakelin, Steven A., O'Callaghan, Maureen, and Condron, Leo M.

Subjects

RHIZOSPHERE, WATERLOGGING (Soils), NITROGEN in soils, HYPOXEMIA, POLYMERASE chain reaction, PLANT health, PLOIDY, PLANTS

Abstract

Microbial denitrification plays a key role in determining the availability of soil nitrogen ( N) to plants. However, factors influencing the structure and function of denitrifier communities in the rhizosphere remain unclear. Waterlogging can result in root anoxia and increased denitrification, leading to significant N loss from soil and potential nitrous oxide ( N2O) emissions. This study investigated denitrifier gene abundance, community structure and activity in the rhizosphere of wheat in response to anoxia and N limitation. Denitrifier community structure in the rhizosphere differed from that in bulk soil, and denitrifier gene copy numbers ( nirS, nirK, nosZ) and potential denitrification activity were greater in the rhizosphere. Anoxia and N limitation, and in particular a combination of both, reduced the magnitude of this effect on gene abundance (in particular nirS) and activity, with N limitation having greater impact than waterlogging in rhizosphere soil, in contrast to bulk soil where the impact of waterlogging was greater. Increased N supply to anoxic plants improved plant health and increased rhizosphere soil p H, which resulted in enhanced reduction of N2O. Both anoxia and N limitation significantly influenced the structure and function of denitrifier communities in the rhizosphere, with reduced root-derived carbon postulated to play an important role. [ABSTRACT FROM AUTHOR]

Published

2013

7. Transposon-Mediated Alteration of TaMATE1B Expression in Wheat Confers Constitutive Citrate Efflux from Root Apices.

Author

Tovkach, Andriy, Ryan, Peter R., Richardson, Alan E., Lewis, David C., Rathjen, Tina M., Ramesh, Sunita, Tyerman, Stephen D., and Delhaize, Emmanuel

Subjects

WHEAT genetics, SHOOT apexes, SINGLE nucleotide polymorphisms, GREEN fluorescent protein, RICE genetics

Abstract

The TaMATE1B gene (for multidrug and toxic compound extrusion) from wheat (Triticum aestivum) was isolated and shown to encode a citrate transporter that is located on the plasma membrane. TaMATE1B expression in roots was induced by iron deficiency but not by phosphorus deficiency or aluminum treatment. The coding region of TaMATE1B was identical in a genotype showing citrate efflux from root apices (cv Carazinho) to one that lacked citrate efflux (cv Egret). However, sequence upstream of the coding region differed between these two genotypes in two ways. The first difference was a single-nucleotide polymorphism located approximately 2 kb upstream from the start codon in cv Egret. The second difference was an 11.1-kb transposon-like element located 25 bp upstream of the start codon in cv Carazinho that was absent from cv Egret. The influence of these polymorphisms on TaMATE1B expression was investigated using fusions to green fluorescent protein expressed in transgenic lines of rice (Oryza sativa). Fluorescence measurements in roots of rice indicated that 1.5- and 2.3-kb regions upstream of TaMATE1B in cv Carazinho (which incorporated 3' regions of the transposon-like element) generated 20-fold greater expression in the apical 1 mm of root compared with the native promoter in cv Egret. By contrast, fluorescence in more mature tissues was similar in both cultivars. The presence of the single-nucleotide polymorphism alone consistently generated 2-fold greater fluorescence than the cv Egret promoter. We conclude that the transposon-like element in cv Carazinho extends TaMATE1B expression to the root apex, where it confers citrate efflux and enhanced aluminum tolerance. [ABSTRACT FROM AUTHOR]

Published

2013

8. Phytate addition to soil induces changes in the abundance and expression of Bacillus ß-propeller phytase genes in the rhizosphere.

Author

Jorquera, Milko A., Saavedra, Nicolás, Maruyama, Fumito, Richardson, Alan E., Crowley, David E., Catrilaf, Rosa, Henriquez, Evelyn J., and Mora, María

Subjects

PHYTIC acid, GENE expression, BACILLUS (Bacteria), POLYMERASE chain reaction, SOIL microbiology, RHIZOSPHERE microbiology, PHYSIOLOGIC strain, MICROORGANISMS

Abstract

Phytate-mineralizing rhizobacteria ( PMR) perform an essential function for the mineralization of organic phosphorus but little is known about their ecology in soils and rhizosphere. In this study, PCR-based methods were developed for detection and quantification of the Bacillus β-propeller phytase ( BPP) gene. Experiments were conducted to monitor the presence and persistence of a phytate-mineralizing strain, Bacillus sp. MQH19, after inoculation of soil microcosms and within the rhizosphere. The occurrence of the BPP gene in natural pasture soils from Chilean Andisols was also examined. The results showed that the Bacillus BPP gene was readily detected in sterile and nonsterile microcosms, and that the quantitative PCR (q PCR) methods could be used to monitor changes in the abundance of the BPP gene over time. Our results also show that the addition of phytate to nonsterile soils induced the expression of the BPP gene in the rhizosphere of ryegrass and the BPP gene was detected in all pasture soils sampled. This study shows that phytate addition soils induced changes in the abundance and expression of Bacillus BPP to genes in the rhizosphere and demonstrates that Bacillus BPP gene is cosmopolitan in pasture soils from Chilean Andisols. [ABSTRACT FROM AUTHOR]

Published

2013

9. Methanotrophic communities in Australian woodland soils of varying salinity.

Author

Bissett, Andrew, Abell, Guy C. J., Bodrossy, Levente, Richardson, Alan E., and Thrall, Peter H.

Subjects

METHANOTROPHS, BIOTIC communities, FORESTS & forestry, FOREST soils, SALINITY, ANTHROPOGENIC soils

Abstract

Despite their large areas and potential importance as methane sinks, the role of methane-oxidizing bacteria ( MOB) in native woodland soils is poorly understood. These environments are increasingly being altered by anthropogenic disturbances, which potentially alter ecosystem service provision. Dryland salinity is one such disturbance and is becoming increasingly prevalent in Australian soils. We used microarrays and analysis of soil physicochemical variables to investigate the methane-oxidizing communities of several Australian natural woodland soils affected to varying degrees by dryland salinity. Soils varied in terms of salinity, gravitational water content, NO3-N, SO4-S and Mg, all of which explained to a significant degree MOB community composition. Analysis of the relative abundance and diversity of the MOB communities also revealed significant differences between soils of different salinities. Type II and type Ib methanotrophs dominated the soils and differences in methanotroph communities existed between salinity groups. The low salinity soils possessed less diverse MOB communities, including most conspicuously, the low numbers or absence of type II Methylocystis phylotypes. The differences in MOB communities suggest niche separation of MOB across varying salinities, as has been observed in the closely related ammonia-oxidizing bacteria, and that anthropogenic disturbance, such as dryland salinity, has the potential to alter MOB community and therefore the methane uptake rates in soils in which disturbance occurs. [ABSTRACT FROM AUTHOR]

Published

2012

10. The influence of sampling strategies and spatial variation on the detected soil bacterial communities under three different land-use types.

Author

Osborne, Catherine A., Zwart, Alexander B., Broadhurst, Linda M., Young, Andrew G., and Richardson, Alan E.

Subjects

SOIL sampling, SPATIAL variation, SOIL microbiology, BIOTIC communities, LAND use, EUCALYPTUS, SOIL chemistry, HYDROGEN-ion concentration

Abstract

To determine the influence of pooling strategies on detected soil bacterial communities, we sampled 45 soil cores each from a eucalypt woodland, a sown pasture and a revegetated site in an Australian landscape. We assessed the spatial variation within each land-use plot, including the influence of sampling distance, soil chemical characteristics and, where appropriate, proximity to trees on the soil bacterial community, by generating terminal restriction fragment length polymorphism profiles of the bacterial 16S rRNA genes. The soil bacterial community under the revegetated site was more similar to the original woodland than the pasture, and this result was found regardless of the soil- or the DNA-pooling strategy used. Analyzing as few as eight cores per plot was sufficient to detect significant differences between the bacterial communities under the different plots to be distinguished. Soil pH was found to be most strongly associated with soil bacterial community composition within the plots and there was no association found with proximity to trees. This study has investigated sampling strategies for further research into the transitions of soil microbial communities with land-use change across broader temporal and spatial scales. [ABSTRACT FROM AUTHOR]

Published

2011

11. Effects of selected root exudate components on soil bacterial communities.

Author

Shi, Shengjing, Richardson, Alan E., O'Callaghan, Maureen, DeAngelis, Kristen M., Jones, Eirian E., Stewart, Alison, Firestone, Mary K., and Condron, Leo M.

Subjects

*PLANT exudates, *PLANT roots, *SOIL microbiology, *PLANT-microbe relationships, *BACTERIA classification, *POLYMERASE chain reaction, *DEHYDROGENASES, *SOIL enzymology

Abstract

Low-molecular-weight organic compounds in root exudates play a key role in plant-microorganism interactions by influencing the structure and function of soil microbial communities. Model exudate solutions, based on organic acids (OAs) (quinic, lactic, maleic acids) and sugars (glucose, sucrose, fructose), previously identified in the rhizosphere of Pinus radiata, were applied to soil microcosms. Root exudate compound solutions stimulated soil dehydrogenase activity and the addition of OAs increased soil pH. The structure of active bacterial communities, based on reverse-transcribed 16S rRNA gene PCR, was assessed by denaturing gradient gel electrophoresis and PhyloChip microarrays. Bacterial taxon richness was greater in all treatments than that in control soil, with a wide range of taxa (88-1043) responding positively to exudate solutions and fewer (<24) responding negatively. OAs caused significantly greater increases than sugars in the detectable richness of the soil bacterial community and larger shifts of dominant taxa. The greater response of bacteria to OAs may be due to the higher amounts of added carbon, solubilization of soil organic matter or shifts in soil pH. Our results indicate that OAs play a significant role in shaping soil bacterial communities and this may therefore have a significant impact on plant growth. [ABSTRACT FROM AUTHOR]

Published

2011

12. Soil Microorganisms Mediating Phosphorus Availability.

Author

Richardson, Alan E. and Simpson, Richard J.

Subjects

*MICROORGANISMS, *PHOSPHORUS in soils, *EFFECT of phosphorus on plants, *RHIZOSPHERE, *SOIL microbiology, *IMAGING systems, *PLANT-soil relationships

Abstract

The article summarizes evidence on the role of free-living nonsymbiotic microorganisms in increasing the availability of phosphorus (P) to plants. It cites issues that block an understanding of microbially mediated P dynamics in the rhizosphere and discusses the opportunities for enhancing P mobilization. It suggests that molecular-based techniques combined with high-resolution image analysis offers possibilities in investigating microbial communities in the rhizosphere and that soil microorganisms has a role in the cycling of P in soil-plant systems.

Published

2011

13. HvALMT1 from barley is involved in the transport of organic anions.

Author

Gruber, Benjamin D., Ryan, Peter R., Richardson, Alan E., Tyerman, Stephen D., Ramesh, Sunita, Hebb, Diane M., Howitt, Susan M., and Delhaize, Emmanuel

Subjects

ANIONS, PLANT species, PLANT roots, PLANT cells & tissues, BARLEY, PLANT chromosomes, GREEN fluorescent protein

Abstract

Members of the ALMT gene family contribute to the Al3+ resistance of several plant species by facilitating malate efflux from root cells. The first member of this family to be cloned and characterized, TaALMT1, is responsible for most of the natural variation of Al3+ resistance in wheat. The current study describes the isolation and characterization of HvALMT1, the barley gene with the greatest sequence similarity to TaALMT1. HvALMT1 is located on chromosome 2H which has not been associated with Al3+ resistance in barley. The relatively low levels of HvALMT1 expression detected in root and shoot tissues were independent of external aluminium or phosphorus supply. Transgenic barley plants transformed with the HvALMT1 promoter fused to the green fluorescent protein (GFP) indicated that expression of HvALMT1 was relatively high in stomatal guard cells and in root tissues containing expanding cells. GFP fused to the C-terminus of the full HvALMT1 protein localized to the plasma membrane and motile vesicles within the cytoplasm. HvALMT1 conferred both inward and outward currents when expressed in Xenopus laevis oocytes that were bathed in a range of anions including malate. Both malate uptake and efflux were confirmed in oocyte assays using [14C]malate as a radiotracer. It is suggested that HvALMT1 functions as an anion channel to facilitate organic anion transport in stomatal function and expanding cells. [ABSTRACT FROM PUBLISHER]

Published

2010

14. Extracellular release of a heterologous phytase from roots of transgenic plants: does manipulation of rhizosphere biochemistry impact microbial community structure?

Author

George, Timothy S., Richardson, Alan E., Li, Sumei S., Gregory, Peter J., and Daniell, Tim J.

Subjects

*PHYTASES, *PLANT roots, *TRANSGENIC plants, *RHIZOSPHERE, *BIOCHEMISTRY

Abstract

To maintain the sustainability of agriculture, it is imperative that the reliance of crops on inorganic phosphorus (P) fertilizers is reduced. One approach is to improve the ability of crop plants to acquire P from organic sources. Transgenic plants that produce microbial phytases have been suggested as a possible means to achieve this goal. However, neither the impact of heterologous expression of phytase on the ecology of microorganisms in the rhizosphere nor the impact of rhizosphere microorganisms on the efficacy of phytases in the rhizosphere of transgenic plants has been tested. In this paper, we demonstrate that the presence of rhizosphere microorganisms reduced the dependence of plants on extracellular secretion of phytase from roots when grown in a P-deficient soil. Despite this, the expression of phytase in transgenic plants had little or no impact on the microbial community structure as compared with control plant lines, whereas soil treatments, such as the addition of inorganic P, had large effects. The results demonstrate that soil microorganisms are explicitly involved in the availability of P to plants and that the microbial community in the rhizosphere appears to be resistant to the impacts of single-gene changes in plants designed to alter rhizosphere biochemistry and nutrient cycling. [ABSTRACT FROM AUTHOR]

Published

2009

15. Promoter Analysis of the Barley Pht1;1 Phosphate Transporter Gene Identifies Regions Controlling Root Expression and Responsiveness to Phosphate Deprivation.

Author

Schünmann, Petra H.D., Richardson, Alan E., Vickers, Claudia E., and Delhaize, Emmanuel

Subjects

*PLANT genetics, *BARLEY, *PROMOTERS (Genetics), *GENE expression in plants, *PLANT roots, *PHOSPHATES

Abstract

Previous studies have shown that the promoter from the barley (Hordeum vulgare) phosphate transporter gene, HυPht1;1, activates high levels of expression in rice (Oryza sativa) roots and that the expression level was induced by up to 4-fold in response to phosphorus (P) deprivation. To identify promoter regions controlling gene regulation specificities, successive promoter truncations were made and attached to reporter genes. Promoters of between 856 and 1,400 nucleotides activated gene expression in a number of cell types but with maximal expression in trichoblast (root hair) cells. For shorter promoters the trichoblast specificity was lost, but in other tissues the distribution pattern was unchanged. The low P induction response was unaffected by promoter length. Domain exchange experiments subsequently identified that the region between -856 and -547 nucleotides (relative to the translational start) is required for epidermal cell expression. A second region located between 0 and -195 nucleotides controls root-tip expression. The HυPht1;1 promoter contains one PHO-like motif and three motifs similar to the dicot P1BS element. Analysis of promoters from which the PHO-like element was eliminated (by truncation) showed no change in the gene induction response to P deficiency. In contrast, mutation of the P1BS elements eliminated any induction of gene expression in response to low P. An internal HυPht1;1 promoter fragment, incorporating a single P1BS element, had an increased response to P deprivation in comparison with the unmodified promoter (containing three elements). Together these findings further our understanding of the regulation of the HυPht1;1 gene and provide direct evidence for a functional role of the P1BS element in the expression of P-regulated genes. [ABSTRACT FROM AUTHOR]

Published

2004

16. Prognostic factors in the rehabilitation of patients with spinal problems.

Author

Richardson, Alan E. and Tupper, Annemarie D.

Abstract

One hundred patients undergoing intensive rehabilitation for painful spinal lesions were studied. They were divided into three groups in relation to result, these being ‘good’, ‘moderate’ or ‘poor’. Seventy-eight per cent were regarded as ‘good’ or ‘moderate’. The ‘poor’ group showed significantly raised neuroticism scores measured by the Middlesex Hospital Questionnaire, particularly sub-scores for ‘depression’ and ‘somatic concomitants of anxiety’ in women and ‘free floating anxiety’, ‘depression’ and ‘obsessionality’ in men. Other factors associated with poor outcome were long history, multiple operations and a nonspecific diagnosis of ‘low back pain’. It is suggested that this group can be identified early and might benefit from a combined physical rehabilitation and psychotherapy programme. A controlled study to test this is planned. [ABSTRACT FROM PUBLISHER]

Published

1975

17. HEAD INJURIES.

Author

RICHARDSON, ALAN E.

Published

1965