Your search keyword '"Baker, Robyn"' showing total 30 results

1. Genetic and behavioral adaptation of Candida parapsilosis to the microbiome of hospitalized infants revealed by in situ genomics, transcriptomics, and proteomics.

Author

West, Patrick T, West, Patrick T, Peters, Samantha L, Olm, Matthew R, Yu, Feiqiao B, Gause, Haley, Lou, Yue Clare, Firek, Brian A, Baker, Robyn, Johnson, Alexander D, Morowitz, Michael J, Hettich, Robert L, Banfield, Jillian F, West, Patrick T, West, Patrick T, Peters, Samantha L, Olm, Matthew R, Yu, Feiqiao B, Gause, Haley, Lou, Yue Clare, Firek, Brian A, Baker, Robyn, Johnson, Alexander D, Morowitz, Michael J, Hettich, Robert L, and Banfield, Jillian F

Abstract

BackgroundCandida parapsilosis is a common cause of invasive candidiasis, especially in newborn infants, and infections have been increasing over the past two decades. C. parapsilosis has been primarily studied in pure culture, leaving gaps in understanding of its function in a microbiome context.ResultsHere, we compare five unique C. parapsilosis genomes assembled from premature infant fecal samples, three of which are newly reconstructed, and analyze their genome structure, population diversity, and in situ activity relative to reference strains in pure culture. All five genomes contain hotspots of single nucleotide variants, some of which are shared by strains from multiple hospitals. A subset of environmental and hospital-derived genomes share variants within these hotspots suggesting derivation of that region from a common ancestor. Four of the newly reconstructed C. parapsilosis genomes have 4 to 16 copies of the gene RTA3, which encodes a lipid translocase and is implicated in antifungal resistance, potentially indicating adaptation to hospital antifungal use. Time course metatranscriptomics and metaproteomics on fecal samples from a premature infant with a C. parapsilosis blood infection revealed highly variable in situ expression patterns that are distinct from those of similar strains in pure cultures. For example, biofilm formation genes were relatively less expressed in situ, whereas genes linked to oxygen utilization were more highly expressed, indicative of growth in a relatively aerobic environment. In gut microbiome samples, C. parapsilosis co-existed with Enterococcus faecalis that shifted in relative abundance over time, accompanied by changes in bacterial and fungal gene expression and proteome composition.ConclusionsThe results reveal potentially medically relevant differences in Candida function in gut vs. laboratory environments, and constrain evolutionary processes that could contribute to hospital strain persistence and transfer into prematur

Published

2021

2. Infant gut strain persistence is associated with maternal origin, phylogeny, and traits including surface adhesion and iron acquisition.

Author

Lou, Yue Clare, Lou, Yue Clare, Olm, Matthew R, Diamond, Spencer, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Lou, Yue Clare, Lou, Yue Clare, Olm, Matthew R, Diamond, Spencer, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Gut microbiome succession affects infant development. However, it remains unclear what factors promote persistence of initial bacterial colonizers in the developing gut. Here, we perform strain-resolved analyses to compare gut colonization of preterm and full-term infants throughout the first year of life and evaluate associations between strain persistence and strain origin as well as genetic potential. Analysis of fecal metagenomes collected from 13 full-term and 9 preterm infants reveals that infants' initially distinct microbiomes converge by age 1 year. Approximately 11% of early colonizers, primarily Bacteroides and Bifidobacterium, persist during the first year of life, and those are more prevalent in full-term, compared with preterm infants. Examination of 17 mother-infant pairs reveals maternal gut strains are significantly more likely to persist in the infant gut than other strains. Enrichment in genes for surface adhesion, iron acquisition, and carbohydrate degradation may explain persistence of some strains through the first year of life.

Published

2021

3. Infant gut strain persistence is associated with maternal origin, phylogeny, and traits including surface adhesion and iron acquisition.

Author

Lou, Yue Clare, Lou, Yue Clare, Olm, Matthew R, Diamond, Spencer, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Lou, Yue Clare, Lou, Yue Clare, Olm, Matthew R, Diamond, Spencer, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Gut microbiome succession affects infant development. However, it remains unclear what factors promote persistence of initial bacterial colonizers in the developing gut. Here, we perform strain-resolved analyses to compare gut colonization of preterm and full-term infants throughout the first year of life and evaluate associations between strain persistence and strain origin as well as genetic potential. Analysis of fecal metagenomes collected from 13 full-term and 9 preterm infants reveals that infants' initially distinct microbiomes converge by age 1 year. Approximately 11% of early colonizers, primarily Bacteroides and Bifidobacterium, persist during the first year of life, and those are more prevalent in full-term, compared with preterm infants. Examination of 17 mother-infant pairs reveals maternal gut strains are significantly more likely to persist in the infant gut than other strains. Enrichment in genes for surface adhesion, iron acquisition, and carbohydrate degradation may explain persistence of some strains through the first year of life.

Published

2021

4. Genetic and behavioral adaptation of Candida parapsilosis to the microbiome of hospitalized infants revealed by in situ genomics, transcriptomics, and proteomics.

Author

West, Patrick T, West, Patrick T, Peters, Samantha L, Olm, Matthew R, Yu, Feiqiao B, Gause, Haley, Lou, Yue Clare, Firek, Brian A, Baker, Robyn, Johnson, Alexander D, Morowitz, Michael J, Hettich, Robert L, Banfield, Jillian F, West, Patrick T, West, Patrick T, Peters, Samantha L, Olm, Matthew R, Yu, Feiqiao B, Gause, Haley, Lou, Yue Clare, Firek, Brian A, Baker, Robyn, Johnson, Alexander D, Morowitz, Michael J, Hettich, Robert L, and Banfield, Jillian F

Abstract

BackgroundCandida parapsilosis is a common cause of invasive candidiasis, especially in newborn infants, and infections have been increasing over the past two decades. C. parapsilosis has been primarily studied in pure culture, leaving gaps in understanding of its function in a microbiome context.ResultsHere, we compare five unique C. parapsilosis genomes assembled from premature infant fecal samples, three of which are newly reconstructed, and analyze their genome structure, population diversity, and in situ activity relative to reference strains in pure culture. All five genomes contain hotspots of single nucleotide variants, some of which are shared by strains from multiple hospitals. A subset of environmental and hospital-derived genomes share variants within these hotspots suggesting derivation of that region from a common ancestor. Four of the newly reconstructed C. parapsilosis genomes have 4 to 16 copies of the gene RTA3, which encodes a lipid translocase and is implicated in antifungal resistance, potentially indicating adaptation to hospital antifungal use. Time course metatranscriptomics and metaproteomics on fecal samples from a premature infant with a C. parapsilosis blood infection revealed highly variable in situ expression patterns that are distinct from those of similar strains in pure cultures. For example, biofilm formation genes were relatively less expressed in situ, whereas genes linked to oxygen utilization were more highly expressed, indicative of growth in a relatively aerobic environment. In gut microbiome samples, C. parapsilosis co-existed with Enterococcus faecalis that shifted in relative abundance over time, accompanied by changes in bacterial and fungal gene expression and proteome composition.ConclusionsThe results reveal potentially medically relevant differences in Candida function in gut vs. laboratory environments, and constrain evolutionary processes that could contribute to hospital strain persistence and transfer into prematur

Published

2021

5. Infant gut strain persistence is associated with maternal origin, phylogeny, and traits including surface adhesion and iron acquisition.

Author

Lou, Yue Clare, Lou, Yue Clare, Olm, Matthew R, Diamond, Spencer, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Lou, Yue Clare, Lou, Yue Clare, Olm, Matthew R, Diamond, Spencer, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Gut microbiome succession affects infant development. However, it remains unclear what factors promote persistence of initial bacterial colonizers in the developing gut. Here, we perform strain-resolved analyses to compare gut colonization of preterm and full-term infants throughout the first year of life and evaluate associations between strain persistence and strain origin as well as genetic potential. Analysis of fecal metagenomes collected from 13 full-term and 9 preterm infants reveals that infants' initially distinct microbiomes converge by age 1 year. Approximately 11% of early colonizers, primarily Bacteroides and Bifidobacterium, persist during the first year of life, and those are more prevalent in full-term, compared with preterm infants. Examination of 17 mother-infant pairs reveals maternal gut strains are significantly more likely to persist in the infant gut than other strains. Enrichment in genes for surface adhesion, iron acquisition, and carbohydrate degradation may explain persistence of some strains through the first year of life.

Published

2021

6. Combined analysis of microbial metagenomic and metatranscriptomic sequencing data to assess in situ physiological conditions in the premature infant gut.

Author

Sher, Yonatan, Sher, Yonatan, Olm, Matthew R, Raveh-Sadka, Tali, Brown, Christopher T, Sher, Ruth, Firek, Brian, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Sher, Yonatan, Sher, Yonatan, Olm, Matthew R, Raveh-Sadka, Tali, Brown, Christopher T, Sher, Ruth, Firek, Brian, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Microbes alter their transcriptomic profiles in response to the environment. The physiological conditions experienced by a microbial community can thus be inferred using meta-transcriptomic sequencing by comparing transcription levels of specifically chosen genes. However, this analysis requires accurate reference genomes to identify the specific genes from which RNA reads originate. In addition, such an analysis should avoid biases in transcript counts related to differences in organism abundance. In this study we describe an approach to address these difficulties. Sample-specific meta-genomic assembled genomes (MAGs) were used as reference genomes to accurately identify the origin of RNA reads, and transcript ratios of genes with opposite transcription responses were compared to eliminate biases related to differences in organismal abundance, an approach hereafter named the "diametric ratio" method. We used this approach to probe the environmental conditions experienced by Escherichia spp. in the gut of 4 premature infants, 2 of whom developed necrotizing enterocolitis (NEC), a severe inflammatory intestinal disease. We analyzed twenty fecal samples taken from four premature infants (4-6 time points from each infant), and found significantly higher diametric ratios of genes associated with low oxygen levels in samples of infants later diagnosed with NEC than in samples without NEC. We also show this method can be used for examining other physiological conditions, such as exposure to nitric oxide and osmotic pressure. These study results should be treated with caution, due to the presence of confounding factors that might also distinguish between NEC and control infants. Nevertheless, together with benchmarking analyses, we show here that the diametric ratio approach can be applied for evaluating the physiological conditions experienced by microbes in situ. Results from similar studies can be further applied for designing diagnostic methods to detect NEC in its ear

Published

2020

7. Combined analysis of microbial metagenomic and metatranscriptomic sequencing data to assess in situ physiological conditions in the premature infant gut.

Author

Sher, Yonatan, Zoetendal, Erwin G1, Sher, Yonatan, Olm, Matthew R, Raveh-Sadka, Tali, Brown, Christopher T, Sher, Ruth, Firek, Brian, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Sher, Yonatan, Zoetendal, Erwin G1, Sher, Yonatan, Olm, Matthew R, Raveh-Sadka, Tali, Brown, Christopher T, Sher, Ruth, Firek, Brian, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Microbes alter their transcriptomic profiles in response to the environment. The physiological conditions experienced by a microbial community can thus be inferred using meta-transcriptomic sequencing by comparing transcription levels of specifically chosen genes. However, this analysis requires accurate reference genomes to identify the specific genes from which RNA reads originate. In addition, such an analysis should avoid biases in transcript counts related to differences in organism abundance. In this study we describe an approach to address these difficulties. Sample-specific meta-genomic assembled genomes (MAGs) were used as reference genomes to accurately identify the origin of RNA reads, and transcript ratios of genes with opposite transcription responses were compared to eliminate biases related to differences in organismal abundance, an approach hereafter named the "diametric ratio" method. We used this approach to probe the environmental conditions experienced by Escherichia spp. in the gut of 4 premature infants, 2 of whom developed necrotizing enterocolitis (NEC), a severe inflammatory intestinal disease. We analyzed twenty fecal samples taken from four premature infants (4-6 time points from each infant), and found significantly higher diametric ratios of genes associated with low oxygen levels in samples of infants later diagnosed with NEC than in samples without NEC. We also show this method can be used for examining other physiological conditions, such as exposure to nitric oxide and osmotic pressure. These study results should be treated with caution, due to the presence of confounding factors that might also distinguish between NEC and control infants. Nevertheless, together with benchmarking analyses, we show here that the diametric ratio approach can be applied for evaluating the physiological conditions experienced by microbes in situ. Results from similar studies can be further applied for designing diagnostic methods to detect NEC in its ear

Published

2020

8. Genome-resolved metagenomics of eukaryotic populations during early colonization of premature infants and in hospital rooms.

Author

Olm, Matthew R, Olm, Matthew R, West, Patrick T, Brooks, Brandon, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Olm, Matthew R, Olm, Matthew R, West, Patrick T, Brooks, Brandon, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

BackgroundFungal infections are a significant cause of mortality and morbidity in hospitalized preterm infants, yet little is known about eukaryotic colonization of infants and of the neonatal intensive care unit as a possible source of colonizing strains. This is partly because microbiome studies often utilize bacterial 16S rRNA marker gene sequencing, a technique that is blind to eukaryotic organisms. Knowledge gaps exist regarding the phylogeny and microdiversity of eukaryotes that colonize hospitalized infants, as well as potential reservoirs of eukaryotes in the hospital room built environment.ResultsGenome-resolved analysis of 1174 time-series fecal metagenomes from 161 premature infants revealed fungal colonization of 10 infants. Relative abundance levels reached as high as 97% and were significantly higher in the first weeks of life (p = 0.004). When fungal colonization occurred, multiple species were present more often than expected by random chance (p = 0.008). Twenty-four metagenomic samples were analyzed from hospital rooms of six different infants. Compared to floor and surface samples, hospital sinks hosted diverse and highly variable communities containing genomically novel species, including from Diptera (fly) and Rhabditida (worm) for which genomes were assembled. With the exception of Diptera and two other organisms, zygosity of the newly assembled diploid eukaryote genomes was low. Interestingly, Malassezia and Candida species were present in both room and infant gut samples.ConclusionsIncreased levels of fungal co-colonization may reflect synergistic interactions or differences in infant susceptibility to fungal colonization. Discovery of eukaryotic organisms that have not been sequenced previously highlights the benefit of genome-resolved analyses, and low zygosity of assembled genomes could reflect inbreeding or strong selection imposed by room conditions.

Published

2019

9. Necrotizing enterocolitis is preceded by increased gut bacterial replication, Klebsiella, and fimbriae-encoding bacteria.

Author

Olm, Matthew R, Olm, Matthew R, Bhattacharya, Nicholas, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Song, Yun S, Morowitz, Michael J, Banfield, Jillian F, Olm, Matthew R, Olm, Matthew R, Bhattacharya, Nicholas, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Song, Yun S, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Necrotizing enterocolitis (NEC) is a devastating intestinal disease that occurs primarily in premature infants. We performed genome-resolved metagenomic analysis of 1163 fecal samples from premature infants to identify microbial features predictive of NEC. Features considered include genes, bacterial strain types, eukaryotes, bacteriophages, plasmids, and growth rates. A machine learning classifier found that samples collected before NEC diagnosis harbored significantly more Klebsiella, bacteria encoding fimbriae, and bacteria encoding secondary metabolite gene clusters related to quorum sensing and bacteriocin production. Notably, replication rates of all bacteria, especially Enterobacteriaceae, were significantly higher 2 days before NEC diagnosis. The findings uncover biomarkers that could lead to early detection of NEC and targets for microbiome-based therapeutics.

Published

2019

10. Genome-resolved metagenomics of eukaryotic populations during early colonization of premature infants and in hospital rooms.

Author

Olm, Matthew R, Olm, Matthew R, West, Patrick T, Brooks, Brandon, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Olm, Matthew R, Olm, Matthew R, West, Patrick T, Brooks, Brandon, Firek, Brian A, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

BackgroundFungal infections are a significant cause of mortality and morbidity in hospitalized preterm infants, yet little is known about eukaryotic colonization of infants and of the neonatal intensive care unit as a possible source of colonizing strains. This is partly because microbiome studies often utilize bacterial 16S rRNA marker gene sequencing, a technique that is blind to eukaryotic organisms. Knowledge gaps exist regarding the phylogeny and microdiversity of eukaryotes that colonize hospitalized infants, as well as potential reservoirs of eukaryotes in the hospital room built environment.ResultsGenome-resolved analysis of 1174 time-series fecal metagenomes from 161 premature infants revealed fungal colonization of 10 infants. Relative abundance levels reached as high as 97% and were significantly higher in the first weeks of life (p = 0.004). When fungal colonization occurred, multiple species were present more often than expected by random chance (p = 0.008). Twenty-four metagenomic samples were analyzed from hospital rooms of six different infants. Compared to floor and surface samples, hospital sinks hosted diverse and highly variable communities containing genomically novel species, including from Diptera (fly) and Rhabditida (worm) for which genomes were assembled. With the exception of Diptera and two other organisms, zygosity of the newly assembled diploid eukaryote genomes was low. Interestingly, Malassezia and Candida species were present in both room and infant gut samples.ConclusionsIncreased levels of fungal co-colonization may reflect synergistic interactions or differences in infant susceptibility to fungal colonization. Discovery of eukaryotic organisms that have not been sequenced previously highlights the benefit of genome-resolved analyses, and low zygosity of assembled genomes could reflect inbreeding or strong selection imposed by room conditions.

Published

2019

11. Necrotizing enterocolitis is preceded by increased gut bacterial replication, Klebsiella, and fimbriae-encoding bacteria.

Author

Olm, Matthew R, Olm, Matthew R, Bhattacharya, Nicholas, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Song, Yun S, Morowitz, Michael J, Banfield, Jillian F, Olm, Matthew R, Olm, Matthew R, Bhattacharya, Nicholas, Crits-Christoph, Alexander, Firek, Brian A, Baker, Robyn, Song, Yun S, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Necrotizing enterocolitis (NEC) is a devastating intestinal disease that occurs primarily in premature infants. We performed genome-resolved metagenomic analysis of 1163 fecal samples from premature infants to identify microbial features predictive of NEC. Features considered include genes, bacterial strain types, eukaryotes, bacteriophages, plasmids, and growth rates. A machine learning classifier found that samples collected before NEC diagnosis harbored significantly more Klebsiella, bacteria encoding fimbriae, and bacteria encoding secondary metabolite gene clusters related to quorum sensing and bacteriocin production. Notably, replication rates of all bacteria, especially Enterobacteriaceae, were significantly higher 2 days before NEC diagnosis. The findings uncover biomarkers that could lead to early detection of NEC and targets for microbiome-based therapeutics.

Published

2019

12. Hospitalized Premature Infants Are Colonized by Related Bacterial Strains with Distinct Proteomic Profiles.

Author

Brown, Christopher T, Brown, Christopher T, Xiong, Weili, Olm, Matthew R, Thomas, Brian C, Baker, Robyn, Firek, Brian, Morowitz, Michael J, Hettich, Robert L, Banfield, Jillian F, Brown, Christopher T, Brown, Christopher T, Xiong, Weili, Olm, Matthew R, Thomas, Brian C, Baker, Robyn, Firek, Brian, Morowitz, Michael J, Hettich, Robert L, and Banfield, Jillian F

Abstract

During the first weeks of life, microbial colonization of the gut impacts human immune system maturation and other developmental processes. In premature infants, aberrant colonization has been implicated in the onset of necrotizing enterocolitis (NEC), a life-threatening intestinal disease. To study the premature infant gut colonization process, genome-resolved metagenomics was conducted on 343 fecal samples collected during the first 3 months of life from 35 premature infants housed in a neonatal intensive care unit, 14 of whom developed NEC, and metaproteomic measurements were made on 87 samples. Microbial community composition and proteomic profiles remained relatively stable on the time scale of a week, but the proteome was more variable. Although genetically similar organisms colonized many infants, most infants were colonized by distinct strains with metabolic profiles that could be distinguished using metaproteomics. Microbiome composition correlated with infant, antibiotics administration, and NEC diagnosis. Communities were found to cluster into seven primary types, and community type switched within infants, sometimes multiple times. Interestingly, some communities sampled from the same infant at subsequent time points clustered with those of other infants. In some cases, switches preceded onset of NEC; however, no species or community type could account for NEC across the majority of infants. In addition to a correlation of protein abundances with organism replication rates, we found that organism proteomes correlated with overall community composition. Thus, this genome-resolved proteomics study demonstrated that the contributions of individual organisms to microbiome development depend on microbial community context.IMPORTANCE Humans are colonized by microbes at birth, a process that is important to health and development. However, much remains to be known about the fine-scale microbial dynamics that occur during the colonization period. We conducted a

Published

2018

13. The developing premature infant gut microbiome is a major factor shaping the microbiome of neonatal intensive care unit rooms.

Author

Brooks, Brandon, Brooks, Brandon, Olm, Matthew R, Firek, Brian A, Baker, Robyn, Geller-McGrath, David, Reimer, Sophia R, Soenjoyo, Karina R, Yip, Jennifer S, Dahan, Dylan, Thomas, Brian C, Morowitz, Michael J, Banfield, Jillian F, Brooks, Brandon, Brooks, Brandon, Olm, Matthew R, Firek, Brian A, Baker, Robyn, Geller-McGrath, David, Reimer, Sophia R, Soenjoyo, Karina R, Yip, Jennifer S, Dahan, Dylan, Thomas, Brian C, Morowitz, Michael J, and Banfield, Jillian F

Abstract

BackgroundThe neonatal intensive care unit (NICU) contains a unique cohort of patients with underdeveloped immune systems and nascent microbiome communities. Patients often spend several months in the same room, and it has been previously shown that the gut microbiomes of these infants often resemble the microbes found in the NICU. Little is known, however, about the identity, persistence, and absolute abundance of NICU room-associated bacteria over long stretches of time. Here, we couple droplet digital PCR (ddPCR), 16S rRNA gene surveys, and recently published metagenomics data from infant gut samples to infer the extent to which the NICU microbiome is shaped by its room occupants.ResultsOver 2832 swabs, wipes, and air samples were collected from 16 private-style NICU rooms housing very low birth weight (< 1500 g), premature (< 31 weeks' gestation) infants. For each infant, room samples were collected daily, Monday through Friday, for 1 month. The first samples from the first infant and the last samples from the last infant were collected 383 days apart. Twenty-two NICU locations spanning room surfaces, hands, electronics, sink basins, and air were collected. Results point to an incredibly simple room community where 5-10 taxa, mostly skin-associated, account for over 50% of the amplicon reads. Biomass estimates reveal four to five orders of magnitude difference between the least to the most dense microbial communities, air, and sink basins, respectively. Biomass trends from bioaerosol samples and petri dish dust collectors suggest occupancy to be a main driver of suspended biological particles within the NICU. Using a machine learning algorithm to classify the origin of room samples, we show that each room has a unique microbial fingerprint. Several important taxa driving this model were dominant gut colonizers of infants housed within each room.ConclusionsDespite regular cleaning of hospital surfaces, bacterial biomass was detectable at varying densities.

Published

2018

14. Hospitalized Premature Infants Are Colonized by Related Bacterial Strains with Distinct Proteomic Profiles.

Author

Brown, Christopher T, Gilmore, Michael S1, Brown, Christopher T, Xiong, Weili, Olm, Matthew R, Thomas, Brian C, Baker, Robyn, Firek, Brian, Morowitz, Michael J, Hettich, Robert L, Banfield, Jillian F, Brown, Christopher T, Gilmore, Michael S1, Brown, Christopher T, Xiong, Weili, Olm, Matthew R, Thomas, Brian C, Baker, Robyn, Firek, Brian, Morowitz, Michael J, Hettich, Robert L, and Banfield, Jillian F

Abstract

During the first weeks of life, microbial colonization of the gut impacts human immune system maturation and other developmental processes. In premature infants, aberrant colonization has been implicated in the onset of necrotizing enterocolitis (NEC), a life-threatening intestinal disease. To study the premature infant gut colonization process, genome-resolved metagenomics was conducted on 343 fecal samples collected during the first 3 months of life from 35 premature infants housed in a neonatal intensive care unit, 14 of whom developed NEC, and metaproteomic measurements were made on 87 samples. Microbial community composition and proteomic profiles remained relatively stable on the time scale of a week, but the proteome was more variable. Although genetically similar organisms colonized many infants, most infants were colonized by distinct strains with metabolic profiles that could be distinguished using metaproteomics. Microbiome composition correlated with infant, antibiotics administration, and NEC diagnosis. Communities were found to cluster into seven primary types, and community type switched within infants, sometimes multiple times. Interestingly, some communities sampled from the same infant at subsequent time points clustered with those of other infants. In some cases, switches preceded onset of NEC; however, no species or community type could account for NEC across the majority of infants. In addition to a correlation of protein abundances with organism replication rates, we found that organism proteomes correlated with overall community composition. Thus, this genome-resolved proteomics study demonstrated that the contributions of individual organisms to microbiome development depend on microbial community context.IMPORTANCE Humans are colonized by microbes at birth, a process that is important to health and development. However, much remains to be known about the fine-scale microbial dynamics that occur during the colonization period. We conduct

Published

2018

15. The developing premature infant gut microbiome is a major factor shaping the microbiome of neonatal intensive care unit rooms.

Author

Brooks, Brandon, Brooks, Brandon, Olm, Matthew R, Firek, Brian A, Baker, Robyn, Geller-McGrath, David, Reimer, Sophia R, Soenjoyo, Karina R, Yip, Jennifer S, Dahan, Dylan, Thomas, Brian C, Morowitz, Michael J, Banfield, Jillian F, Brooks, Brandon, Brooks, Brandon, Olm, Matthew R, Firek, Brian A, Baker, Robyn, Geller-McGrath, David, Reimer, Sophia R, Soenjoyo, Karina R, Yip, Jennifer S, Dahan, Dylan, Thomas, Brian C, Morowitz, Michael J, and Banfield, Jillian F

Abstract

BackgroundThe neonatal intensive care unit (NICU) contains a unique cohort of patients with underdeveloped immune systems and nascent microbiome communities. Patients often spend several months in the same room, and it has been previously shown that the gut microbiomes of these infants often resemble the microbes found in the NICU. Little is known, however, about the identity, persistence, and absolute abundance of NICU room-associated bacteria over long stretches of time. Here, we couple droplet digital PCR (ddPCR), 16S rRNA gene surveys, and recently published metagenomics data from infant gut samples to infer the extent to which the NICU microbiome is shaped by its room occupants.ResultsOver 2832 swabs, wipes, and air samples were collected from 16 private-style NICU rooms housing very low birth weight (< 1500 g), premature (< 31 weeks' gestation) infants. For each infant, room samples were collected daily, Monday through Friday, for 1 month. The first samples from the first infant and the last samples from the last infant were collected 383 days apart. Twenty-two NICU locations spanning room surfaces, hands, electronics, sink basins, and air were collected. Results point to an incredibly simple room community where 5-10 taxa, mostly skin-associated, account for over 50% of the amplicon reads. Biomass estimates reveal four to five orders of magnitude difference between the least to the most dense microbial communities, air, and sink basins, respectively. Biomass trends from bioaerosol samples and petri dish dust collectors suggest occupancy to be a main driver of suspended biological particles within the NICU. Using a machine learning algorithm to classify the origin of room samples, we show that each room has a unique microbial fingerprint. Several important taxa driving this model were dominant gut colonizers of infants housed within each room.ConclusionsDespite regular cleaning of hospital surfaces, bacterial biomass was detectable at

Published

2018

16. Strain-resolved analysis of hospital rooms and infants reveals overlap between the human and room microbiome.

Author

Brooks, Brandon, Brooks, Brandon, Olm, Matthew R, Firek, Brian A, Baker, Robyn, Thomas, Brian C, Morowitz, Michael J, Banfield, Jillian F, Brooks, Brandon, Brooks, Brandon, Olm, Matthew R, Firek, Brian A, Baker, Robyn, Thomas, Brian C, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Preterm infants exhibit different microbiome colonization patterns relative to full-term infants, and it is speculated that the hospital room environment may contribute to infant microbiome development. Here, we present a genome-resolved metagenomic study of microbial genotypes from the gastrointestinal tracts of infants and from the neonatal intensive care unit (NICU) room environment. Some strains detected in hospitalized infants also occur in sinks and on surfaces, and belong to species such as Staphylococcus epidermidis, Enterococcus faecalis, Pseudomonas aeruginosa, and Klebsiella pneumoniae, which are frequently implicated in nosocomial infection and preterm infant gut colonization. Of the 15 K. pneumoniae strains detected in the study, four were detected in both infant gut and room samples. Time series experiments showed that nearly all strains associated with infant gut colonization can be detected in the room after, and often before, detection in the gut. Thus, we conclude that a component of premature infant gut colonization is the cycle of microbial exchange between the room and the occupant.

Published

2017

17. Identical bacterial populations colonize premature infant gut, skin, and oral microbiomes and exhibit different in situ growth rates.

Author

Olm, Matthew R, Olm, Matthew R, Brown, Christopher T, Brooks, Brandon, Firek, Brian, Baker, Robyn, Burstein, David, Soenjoyo, Karina, Thomas, Brian C, Morowitz, Michael, Banfield, Jillian F, Olm, Matthew R, Olm, Matthew R, Brown, Christopher T, Brooks, Brandon, Firek, Brian, Baker, Robyn, Burstein, David, Soenjoyo, Karina, Thomas, Brian C, Morowitz, Michael, and Banfield, Jillian F

Abstract

The initial microbiome impacts the health and future development of premature infants. Methodological limitations have led to gaps in our understanding of the habitat range and subpopulation complexity of founding strains, as well as how different body sites support microbial growth. Here, we used metagenomics to reconstruct genomes of strains that colonized the skin, mouth, and gut of two hospitalized premature infants during the first month of life. Seven bacterial populations, considered to be identical given whole-genome average nucleotide identity of >99.9%, colonized multiple body sites, yet none were shared between infants. Gut-associated Citrobacter koseri genomes harbored 47 polymorphic sites that we used to define 10 subpopulations, one of which appeared in the gut after 1 wk but did not spread to other body sites. Differential genome coverage was used to measure bacterial population replication rates in situ. In all cases where the same bacterial population was detected in multiple body sites, replication rates were faster in mouth and skin compared to the gut. The ability of identical strains to colonize multiple body sites underscores the habit flexibility of initial colonists, whereas differences in microbial replication rates between body sites suggest differences in host control and/or resource availability. Population genomic analyses revealed microdiversity within bacterial populations, implying initial inoculation by multiple individual cells with distinct genotypes. Overall, however, the overlap of strains across body sites implies that the premature infant microbiome can exhibit very low microbial diversity.

Published

2017

18. Identical bacterial populations colonize premature infant gut, skin, and oral microbiomes and exhibit different in situ growth rates.

Author

Olm, Matthew R, Olm, Matthew R, Brown, Christopher T, Brooks, Brandon, Firek, Brian, Baker, Robyn, Burstein, David, Soenjoyo, Karina, Thomas, Brian C, Morowitz, Michael, Banfield, Jillian F, Olm, Matthew R, Olm, Matthew R, Brown, Christopher T, Brooks, Brandon, Firek, Brian, Baker, Robyn, Burstein, David, Soenjoyo, Karina, Thomas, Brian C, Morowitz, Michael, and Banfield, Jillian F

Abstract

The initial microbiome impacts the health and future development of premature infants. Methodological limitations have led to gaps in our understanding of the habitat range and subpopulation complexity of founding strains, as well as how different body sites support microbial growth. Here, we used metagenomics to reconstruct genomes of strains that colonized the skin, mouth, and gut of two hospitalized premature infants during the first month of life. Seven bacterial populations, considered to be identical given whole-genome average nucleotide identity of >99.9%, colonized multiple body sites, yet none were shared between infants. Gut-associated Citrobacter koseri genomes harbored 47 polymorphic sites that we used to define 10 subpopulations, one of which appeared in the gut after 1 wk but did not spread to other body sites. Differential genome coverage was used to measure bacterial population replication rates in situ. In all cases where the same bacterial population was detected in multiple body sites, replication rates were faster in mouth and skin compared to the gut. The ability of identical strains to colonize multiple body sites underscores the habit flexibility of initial colonists, whereas differences in microbial replication rates between body sites suggest differences in host control and/or resource availability. Population genomic analyses revealed microdiversity within bacterial populations, implying initial inoculation by multiple individual cells with distinct genotypes. Overall, however, the overlap of strains across body sites implies that the premature infant microbiome can exhibit very low microbial diversity.

Published

2017

19. Strain-resolved analysis of hospital rooms and infants reveals overlap between the human and room microbiome.

Author

Brooks, Brandon, Brooks, Brandon, Olm, Matthew R, Firek, Brian A, Baker, Robyn, Thomas, Brian C, Morowitz, Michael J, Banfield, Jillian F, Brooks, Brandon, Brooks, Brandon, Olm, Matthew R, Firek, Brian A, Baker, Robyn, Thomas, Brian C, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Preterm infants exhibit different microbiome colonization patterns relative to full-term infants, and it is speculated that the hospital room environment may contribute to infant microbiome development. Here, we present a genome-resolved metagenomic study of microbial genotypes from the gastrointestinal tracts of infants and from the neonatal intensive care unit (NICU) room environment. Some strains detected in hospitalized infants also occur in sinks and on surfaces, and belong to species such as Staphylococcus epidermidis, Enterococcus faecalis, Pseudomonas aeruginosa, and Klebsiella pneumoniae, which are frequently implicated in nosocomial infection and preterm infant gut colonization. Of the 15 K. pneumoniae strains detected in the study, four were detected in both infant gut and room samples. Time series experiments showed that nearly all strains associated with infant gut colonization can be detected in the room after, and often before, detection in the gut. Thus, we conclude that a component of premature infant gut colonization is the cycle of microbial exchange between the room and the occupant.

Published

2017

20. Evidence for persistent and shared bacterial strains against a background of largely unique gut colonization in hospitalized premature infants.

Author

Raveh-Sadka, Tali, Raveh-Sadka, Tali, Firek, Brian, Sharon, Itai, Baker, Robyn, Brown, Christopher T, Thomas, Brian C, Morowitz, Michael J, Banfield, Jillian F, Raveh-Sadka, Tali, Raveh-Sadka, Tali, Firek, Brian, Sharon, Itai, Baker, Robyn, Brown, Christopher T, Thomas, Brian C, Morowitz, Michael J, and Banfield, Jillian F

Abstract

The potentially critical stage of initial gut colonization in premature infants occurs in the hospital environment, where infants are exposed to a variety of hospital-associated bacteria. Because few studies of microbial communities are strain-resolved, we know little about the extent to which specific strains persist in the hospital environment and disperse among infants. To study this, we compared 304 near-complete genomes reconstructed from fecal samples of 21 infants hospitalized in the same intensive care unit in two cohorts, over 3 years apart. The genomes represent 159 distinct bacterial strains, only 14 of which occurred in multiple infants. Enterococcus faecalis and Staphylococcus epidermidis, common infant gut colonists, exhibit diversity comparable to that of reference strains, inline with introduction of strains from infant-specific sources rather than a hospital strain pool. Unlike other infants, a pair of sibling infants shared multiple strains, even after extensive antibiotic administration, suggesting overlapping strain-sources and/or genetic selection drive microbiota similarities. Interestingly, however, five strains were detected in infants hospitalized three years apart. Three of these were also detected in multiple infants in the same year. This finding of a few widely dispersed and persistent bacterial colonizers despite overall low potential for strain dispersal among infants has implications for understanding and directing healthy colonization.

Published

2016

21. Evidence for persistent and shared bacterial strains against a background of largely unique gut colonization in hospitalized premature infants.

Author

Raveh-Sadka, Tali, Raveh-Sadka, Tali, Firek, Brian, Sharon, Itai, Baker, Robyn, Brown, Christopher T, Thomas, Brian C, Morowitz, Michael J, Banfield, Jillian F, Raveh-Sadka, Tali, Raveh-Sadka, Tali, Firek, Brian, Sharon, Itai, Baker, Robyn, Brown, Christopher T, Thomas, Brian C, Morowitz, Michael J, and Banfield, Jillian F

Abstract

The potentially critical stage of initial gut colonization in premature infants occurs in the hospital environment, where infants are exposed to a variety of hospital-associated bacteria. Because few studies of microbial communities are strain-resolved, we know little about the extent to which specific strains persist in the hospital environment and disperse among infants. To study this, we compared 304 near-complete genomes reconstructed from fecal samples of 21 infants hospitalized in the same intensive care unit in two cohorts, over 3 years apart. The genomes represent 159 distinct bacterial strains, only 14 of which occurred in multiple infants. Enterococcus faecalis and Staphylococcus epidermidis, common infant gut colonists, exhibit diversity comparable to that of reference strains, inline with introduction of strains from infant-specific sources rather than a hospital strain pool. Unlike other infants, a pair of sibling infants shared multiple strains, even after extensive antibiotic administration, suggesting overlapping strain-sources and/or genetic selection drive microbiota similarities. Interestingly, however, five strains were detected in infants hospitalized three years apart. Three of these were also detected in multiple infants in the same year. This finding of a few widely dispersed and persistent bacterial colonizers despite overall low potential for strain dispersal among infants has implications for understanding and directing healthy colonization.

Published

2016

22. Gut bacteria are rarely shared by co-hospitalized premature infants, regardless of necrotizing enterocolitis development.

Author

Raveh-Sadka, Tali, Raveh-Sadka, Tali, Thomas, Brian C, Singh, Andrea, Firek, Brian, Brooks, Brandon, Castelle, Cindy J, Sharon, Itai, Baker, Robyn, Good, Misty, Morowitz, Michael J, Banfield, Jillian F, Raveh-Sadka, Tali, Raveh-Sadka, Tali, Thomas, Brian C, Singh, Andrea, Firek, Brian, Brooks, Brandon, Castelle, Cindy J, Sharon, Itai, Baker, Robyn, Good, Misty, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Premature infants are highly vulnerable to aberrant gastrointestinal tract colonization, a process that may lead to diseases like necrotizing enterocolitis. Thus, spread of potential pathogens among hospitalized infants is of great concern. Here, we reconstructed hundreds of high-quality genomes of microorganisms that colonized co-hospitalized premature infants, assessed their metabolic potential, and tracked them over time to evaluate bacterial strain dispersal among infants. We compared microbial communities in infants who did and did not develop necrotizing enterocolitis. Surprisingly, while potentially pathogenic bacteria of the same species colonized many infants, our genome-resolved analysis revealed that strains colonizing each baby were typically distinct. In particular, no strain was common to all infants who developed necrotizing enterocolitis. The paucity of shared gut colonizers suggests the existence of significant barriers to the spread of bacteria among infants. Importantly, we demonstrate that strain-resolved comprehensive community analysis can be accomplished on potentially medically relevant time scales.

Published

2015

23. Gut bacteria are rarely shared by co-hospitalized premature infants, regardless of necrotizing enterocolitis development.

Author

Raveh-Sadka, Tali, Raveh-Sadka, Tali, Thomas, Brian C, Singh, Andrea, Firek, Brian, Brooks, Brandon, Castelle, Cindy J, Sharon, Itai, Baker, Robyn, Good, Misty, Morowitz, Michael J, Banfield, Jillian F, Raveh-Sadka, Tali, Raveh-Sadka, Tali, Thomas, Brian C, Singh, Andrea, Firek, Brian, Brooks, Brandon, Castelle, Cindy J, Sharon, Itai, Baker, Robyn, Good, Misty, Morowitz, Michael J, and Banfield, Jillian F

Abstract

Premature infants are highly vulnerable to aberrant gastrointestinal tract colonization, a process that may lead to diseases like necrotizing enterocolitis. Thus, spread of potential pathogens among hospitalized infants is of great concern. Here, we reconstructed hundreds of high-quality genomes of microorganisms that colonized co-hospitalized premature infants, assessed their metabolic potential, and tracked them over time to evaluate bacterial strain dispersal among infants. We compared microbial communities in infants who did and did not develop necrotizing enterocolitis. Surprisingly, while potentially pathogenic bacteria of the same species colonized many infants, our genome-resolved analysis revealed that strains colonizing each baby were typically distinct. In particular, no strain was common to all infants who developed necrotizing enterocolitis. The paucity of shared gut colonizers suggests the existence of significant barriers to the spread of bacteria among infants. Importantly, we demonstrate that strain-resolved comprehensive community analysis can be accomplished on potentially medically relevant time scales.

Published

2015

24. Microbes in the neonatal intensive care unit resemble those found in the gut of premature infants.

Author

Brooks, Brandon, Brooks, Brandon, Firek, Brian A, Miller, Christopher S, Sharon, Itai, Thomas, Brian C, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Brooks, Brandon, Brooks, Brandon, Firek, Brian A, Miller, Christopher S, Sharon, Itai, Thomas, Brian C, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

BackgroundThe source inoculum of gastrointestinal tract (GIT) microbes is largely influenced by delivery mode in full-term infants, but these influences may be decoupled in very low birth weight (VLBW, <1,500 g) neonates via conventional broad-spectrum antibiotic treatment. We hypothesize the built environment (BE), specifically room surfaces frequently touched by humans, is a predominant source of colonizing microbes in the gut of premature VLBW infants. Here, we present the first matched fecal-BE time series analysis of two preterm VLBW neonates housed in a neonatal intensive care unit (NICU) over the first month of life.ResultsFresh fecal samples were collected every 3 days and metagenomes sequenced on an Illumina HiSeq2000 device. For each fecal sample, approximately 33 swabs were collected from each NICU room from 6 specified areas: sink, feeding and intubation tubing, hands of healthcare providers and parents, general surfaces, and nurse station electronics (keyboard, mouse, and cell phone). Swabs were processed using a recently developed 'expectation maximization iterative reconstruction of genes from the environment' (EMIRGE) amplicon pipeline in which full-length 16S rRNA amplicons were sheared and sequenced using an Illumina platform, and short reads reassembled into full-length genes. Over 24,000 full-length 16S rRNA sequences were produced, generating an average of approximately 12,000 operational taxonomic units (OTUs) (clustered at 97% nucleotide identity) per room-infant pair. Dominant gut taxa, including Staphylococcus epidermidis, Klebsiella pneumoniae, Bacteroides fragilis, and Escherichia coli, were widely distributed throughout the room environment with many gut colonizers detected in more than half of samples. Reconstructed genomes from infant gut colonizers revealed a suite of genes that confer resistance to antibiotics (for example, tetracycline, fluoroquinolone, and aminoglycoside) and sterilizing agents, which likely offer a competitive a

Published

2014

25. Microbes in the neonatal intensive care unit resemble those found in the gut of premature infants.

Author

Brooks, Brandon, Brooks, Brandon, Firek, Brian A, Miller, Christopher S, Sharon, Itai, Thomas, Brian C, Baker, Robyn, Morowitz, Michael J, Banfield, Jillian F, Brooks, Brandon, Brooks, Brandon, Firek, Brian A, Miller, Christopher S, Sharon, Itai, Thomas, Brian C, Baker, Robyn, Morowitz, Michael J, and Banfield, Jillian F

Abstract

BackgroundThe source inoculum of gastrointestinal tract (GIT) microbes is largely influenced by delivery mode in full-term infants, but these influences may be decoupled in very low birth weight (VLBW, <1,500 g) neonates via conventional broad-spectrum antibiotic treatment. We hypothesize the built environment (BE), specifically room surfaces frequently touched by humans, is a predominant source of colonizing microbes in the gut of premature VLBW infants. Here, we present the first matched fecal-BE time series analysis of two preterm VLBW neonates housed in a neonatal intensive care unit (NICU) over the first month of life.ResultsFresh fecal samples were collected every 3 days and metagenomes sequenced on an Illumina HiSeq2000 device. For each fecal sample, approximately 33 swabs were collected from each NICU room from 6 specified areas: sink, feeding and intubation tubing, hands of healthcare providers and parents, general surfaces, and nurse station electronics (keyboard, mouse, and cell phone). Swabs were processed using a recently developed 'expectation maximization iterative reconstruction of genes from the environment' (EMIRGE) amplicon pipeline in which full-length 16S rRNA amplicons were sheared and sequenced using an Illumina platform, and short reads reassembled into full-length genes. Over 24,000 full-length 16S rRNA sequences were produced, generating an average of approximately 12,000 operational taxonomic units (OTUs) (clustered at 97% nucleotide identity) per room-infant pair. Dominant gut taxa, including Staphylococcus epidermidis, Klebsiella pneumoniae, Bacteroides fragilis, and Escherichia coli, were widely distributed throughout the room environment with many gut colonizers detected in more than half of samples. Reconstructed genomes from infant gut colonizers revealed a suite of genes that confer resistance to antibiotics (for example, tetracycline, fluoroquinolone, and aminoglycoside) and sterilizing agents, which likely offer a competitive a

Published

2014

26. Co-operative learning as a method for reducing bullying

Author

Jones, Elizabeth, Baker, Robyn, Jones, Elizabeth, and Baker, Robyn

Abstract

Evidence from international research suggests that bullying increases as students make the transition to intermediate school. Bullying interventions frequently focus on individual change with little attention paid to the context that supports the behaviour. This pre-experimental case study examined bullying from a contextual perspective. A cooperative learning program was implemented in a Year 7 and Year 8 composite class to investigate if such a program could reduce bullying and increase positive peer interactions among the students. Qualitative and quantitative data were collected using a questionnaire, sociogram, interviews and observations. The results of the study are equivocal because while the questionnaire results and the results from a component of the sociogram indicated increased bullying behaviours, the observations and interviews indicated a decrease in the behaviour. Also, clearer evidence of increased peer interactions came from the interviews and observations than from the sociogram. The implications of this study relate more to the implementation of co-operative learning than to its impact on bullying behaviour. Effective dissemination of co-operative learning requires: fidelity to the methodology, peer support over time, frequent practice, recognition of resistance and a school climate that both supports and fosters its implementation. A list of indicators for effective implementation of co-operative learning is provided in this study.

Published

2004

27. Co-operative learning as a method for reducing bullying

Author

Jones, Elizabeth, Baker, Robyn, Jones, Elizabeth, and Baker, Robyn

Abstract

Evidence from international research suggests that bullying increases as students make the transition to intermediate school. Bullying interventions frequently focus on individual change with little attention paid to the context that supports the behaviour. This pre-experimental case study examined bullying from a contextual perspective. A cooperative learning program was implemented in a Year 7 and Year 8 composite class to investigate if such a program could reduce bullying and increase positive peer interactions among the students. Qualitative and quantitative data were collected using a questionnaire, sociogram, interviews and observations. The results of the study are equivocal because while the questionnaire results and the results from a component of the sociogram indicated increased bullying behaviours, the observations and interviews indicated a decrease in the behaviour. Also, clearer evidence of increased peer interactions came from the interviews and observations than from the sociogram. The implications of this study relate more to the implementation of co-operative learning than to its impact on bullying behaviour. Effective dissemination of co-operative learning requires: fidelity to the methodology, peer support over time, frequent practice, recognition of resistance and a school climate that both supports and fosters its implementation. A list of indicators for effective implementation of co-operative learning is provided in this study.

Published

2004

28. Co-operative learning as a method for reducing bullying

Author

Jones, Elizabeth, Baker, Robyn, Jones, Elizabeth, and Baker, Robyn

Abstract

Evidence from international research suggests that bullying increases as students make the transition to intermediate school. Bullying interventions frequently focus on individual change with little attention paid to the context that supports the behaviour. This pre-experimental case study examined bullying from a contextual perspective. A cooperative learning program was implemented in a Year 7 and Year 8 composite class to investigate if such a program could reduce bullying and increase positive peer interactions among the students. Qualitative and quantitative data were collected using a questionnaire, sociogram, interviews and observations. The results of the study are equivocal because while the questionnaire results and the results from a component of the sociogram indicated increased bullying behaviours, the observations and interviews indicated a decrease in the behaviour. Also, clearer evidence of increased peer interactions came from the interviews and observations than from the sociogram. The implications of this study relate more to the implementation of co-operative learning than to its impact on bullying behaviour. Effective dissemination of co-operative learning requires: fidelity to the methodology, peer support over time, frequent practice, recognition of resistance and a school climate that both supports and fosters its implementation. A list of indicators for effective implementation of co-operative learning is provided in this study.

Published

2004

29. Co-operative learning as a method for reducing bullying

Author

Jones, Elizabeth, Baker, Robyn, Jones, Elizabeth, and Baker, Robyn

Abstract

Evidence from international research suggests that bullying increases as students make the transition to intermediate school. Bullying interventions frequently focus on individual change with little attention paid to the context that supports the behaviour. This pre-experimental case study examined bullying from a contextual perspective. A cooperative learning program was implemented in a Year 7 and Year 8 composite class to investigate if such a program could reduce bullying and increase positive peer interactions among the students. Qualitative and quantitative data were collected using a questionnaire, sociogram, interviews and observations. The results of the study are equivocal because while the questionnaire results and the results from a component of the sociogram indicated increased bullying behaviours, the observations and interviews indicated a decrease in the behaviour. Also, clearer evidence of increased peer interactions came from the interviews and observations than from the sociogram. The implications of this study relate more to the implementation of co-operative learning than to its impact on bullying behaviour. Effective dissemination of co-operative learning requires: fidelity to the methodology, peer support over time, frequent practice, recognition of resistance and a school climate that both supports and fosters its implementation. A list of indicators for effective implementation of co-operative learning is provided in this study.

Published

2004

30. Co-operative learning as a method for reducing bullying

Author

Jones, Elizabeth, Baker, Robyn, Jones, Elizabeth, and Baker, Robyn

Abstract

Evidence from international research suggests that bullying increases as students make the transition to intermediate school. Bullying interventions frequently focus on individual change with little attention paid to the context that supports the behaviour. This pre-experimental case study examined bullying from a contextual perspective. A cooperative learning program was implemented in a Year 7 and Year 8 composite class to investigate if such a program could reduce bullying and increase positive peer interactions among the students. Qualitative and quantitative data were collected using a questionnaire, sociogram, interviews and observations. The results of the study are equivocal because while the questionnaire results and the results from a component of the sociogram indicated increased bullying behaviours, the observations and interviews indicated a decrease in the behaviour. Also, clearer evidence of increased peer interactions came from the interviews and observations than from the sociogram. The implications of this study relate more to the implementation of co-operative learning than to its impact on bullying behaviour. Effective dissemination of co-operative learning requires: fidelity to the methodology, peer support over time, frequent practice, recognition of resistance and a school climate that both supports and fosters its implementation. A list of indicators for effective implementation of co-operative learning is provided in this study.

Published

2004