Your search keyword '"Azad, Meghan B."' showing total 12 results

1. Divergent maturational patterns of the infant bacterial and fungal gut microbiome in the first year of life are associated with inter-kingdom community dynamics and infant nutrition

Author

Mercer, Emily M., Ramay, Hena R., Moossavi, Shirin, Laforest-Lapointe, Isabelle, Reyna, Myrtha E., Becker, Allan B., Simons, Elinor, Mandhane, Piush J., Turvey, Stuart E., Moraes, Theo J., Sears, Malcolm R., Subbarao, Padmaja, Azad, Meghan B., and Arrieta, Marie-Claire

Published

2024

2. Delayed gut microbiota maturation in the first year of life is a hallmark of pediatric allergic disease.

Author

Hoskinson, Courtney, Dai, Darlene L. Y., Del Bel, Kate L., Becker, Allan B., Moraes, Theo J., Mandhane, Piushkumar J., Finlay, B. Brett, Simons, Elinor, Kozyrskyj, Anita L., Azad, Meghan B., Subbarao, Padmaja, Petersen, Charisse, and Turvey, Stuart E.

Subjects

ALLERGIES, GUT microbiome, METAGENOMICS, ALLERGIC rhinitis, ATOPIC dermatitis, FOOD allergy, MICROBIAL genes

Abstract

Allergic diseases affect millions of people worldwide. An increase in their prevalence has been associated with alterations in the gut microbiome, i.e., the microorganisms and their genes within the gastrointestinal tract. Maturation of the infant immune system and gut microbiota occur in parallel; thus, the conformation of the microbiome may determine if tolerant immune programming arises within the infant. Here we show, using deeply phenotyped participants in the CHILD birth cohort (n = 1115), that there are early-life influences and microbiome features which are uniformly associated with four distinct allergic diagnoses at 5 years: atopic dermatitis (AD, n = 367), asthma (As, n = 165), food allergy (FA, n = 136), and allergic rhinitis (AR, n = 187). In a subset with shotgun metagenomic and metabolomic profiling (n = 589), we discover that impaired 1-year microbiota maturation may be universal to pediatric allergies (AD p = 0.000014; As p = 0.0073; FA p = 0.00083; and AR p = 0.0021). Extending this, we find a core set of functional and metabolic imbalances characterized by compromised mucous integrity, elevated oxidative activity, decreased secondary fermentation, and elevated trace amines, to be a significant mediator between microbiota maturation at age 1 year and allergic diagnoses at age 5 years (βindirect = −2.28; p = 0.0020). Microbiota maturation thus provides a focal point to identify deviations from normative development to predict and prevent allergic disease. Here, using participants in the CHILD birth cohort, the authors reveal that impaired 1-year microbiota maturation may be universal to 5-year pediatric allergies, mediated by functional and metabolic imbalances of compromised mucous integrity, elevated oxidative activity, decreased fermentation, and elevated trace amines. [ABSTRACT FROM AUTHOR]

Published

2023

3. The human gutmicrobiome and health inequities.

Author

Amato, Katherine R., Arrieta, Marie-Claire, Azad, Meghan B., Bailey, Michael T., Broussard, Josiane L., Bruggeling, Carlijn E., Claud, Erika C., Costello, Elizabeth K., Davenport, Emily R., Dutilh, Bas E., Ewald, Holly A. Swain, Ewald, Paul, Hanlon, Erin C., Julion, Wrenetha, Keshavarzian, Ali, Maurice, Corinne F., Miller, Gregory E., Preidis, Geoffrey A., Segurel, Laure, and Singer, Burton

Subjects

HEALTH equity, GUT microbiome, HEALTH policy, POPULATION health, GENDER

Abstract

Individuals who are minoritized as a result of race, sexual identity, gender, or socioeconomic status experience a higher prevalence of many diseases. Understanding the biological processes that cause and maintain these socially driven health inequities is essential for addressing them. The gut microbiome is strongly shaped by host environments and affects host metabolic, immune, and neuroendocrine functions, making it an important pathway by which differences in experiences caused by social, political, and economic forces could contribute to health inequities. Nevertheless, few studies have directly integrated the gut microbiome into investigations of health inequities. Here, we argue that accounting for host-gut microbe interactions will improve understanding and management of health inequities, and that health policy must begin to consider the microbiome as an important pathway linking environments to population health. [ABSTRACT FROM AUTHOR]

Published

2021

4. Decreasing antibiotic use, the gut microbiota, and asthma incidence in children: evidence from population-based and prospective cohort studies.

Author

Patrick, David M, Sbihi, Hind, Dai, Darlene L Y, Al Mamun, Abdullah, Rasali, Drona, Rose, Caren, Marra, Fawziah, Boutin, Rozlyn C T, Petersen, Charisse, Stiemsma, Leah T, Winsor, Geoffrey L, Brinkman, Fiona S L, Kozyrskyj, Anita L, Azad, Meghan B, Becker, Allan B, Mandhane, Piush J, Moraes, Theo J, Sears, Malcolm R, Subbarao, Padmaja, and Finlay, B Brett

Subjects

ASTHMA in children, GUT microbiome, STRUCTURAL equation modeling, WHEEZE, COHORT analysis, INFANT development

Abstract

Childhood asthma incidence is decreasing in some parts of Europe and North America. Antibiotic use in infancy has been associated with increased asthma risk. In the present study, we tested the hypothesis that decreases in asthma incidence are linked to reduced antibiotic prescribing and mediated by changes in the gut bacterial community. This study comprised population-based and prospective cohort analyses. At the population level, we used administrative data from British Columbia, Canada (population 4·7 million), on annual rates of antibiotic prescriptions and asthma diagnoses, to assess the association between antibiotic prescribing (at age <1 year) and asthma incidence (at age 1–4 years). At the individual level, 2644 children from the Canadian Healthy Infant Longitudinal Development (CHILD) prospective birth cohort were examined for the association of systemic antibiotic use (at age <1 year) with the diagnosis of asthma (at age 5 years). In the same cohort, we did a mechanistic investigation of 917 children with available 16S rRNA gene sequencing data from faecal samples (at age ≤1 year), to assess how composition of the gut microbiota relates to antibiotic exposure and asthma incidence. At the population level between 2000 and 2014, asthma incidence in children (aged 1–4 years) showed an absolute decrease of 7·1 new diagnoses per 1000 children, from 27·3 (26·8–28·3) per 1000 children to 20·2 (19·5–20·8) per 1000 children (a relative decrease of 26·0%). Reduction in incidence over the study period was associated with decreasing antibiotic use in infancy (age <1 year), from 1253·8 prescriptions (95% CI 1219·3–1288·9) per 1000 infants to 489·1 (467·6–511·2) per 1000 infants (Spearman's r =0·81; p<0·0001). Asthma incidence increased by 24% with each 10% increase in antibiotic prescribing (adjusted incidence rate ratio 1·24 [95% CI 1·20–1·28]; p<0·0001). In the CHILD cohort, after excluding children who received antibiotics for respiratory symptoms, asthma diagnosis in childhood was associated with infant antibiotic use (adjusted odds ratio [aOR] 2·15 [95% CI 1·37–3·39]; p=0·0009), with a significant dose–response; 114 (5·2%) of 2182 children unexposed to antibiotics had asthma by age 5 years, compared with 23 (8·1%) of 284 exposed to one course, five (10·2%) of 49 exposed to two courses, and six (17·6%) of 34 exposed to three or more courses (aOR 1·44 [1·16–1·79]; p=0·0008). Increasing α-diversity of the gut microbiota, defined as an IQR increase (25th to 75th percentile) in the Chao1 index, at age 1 year was associated with a 32% reduced risk of asthma at age 5 years (aOR for IQR increase 0·68 [0·46–0·99]; p=0·046). In a structural equation model, we found the gut microbiota at age 1 year, characterised by α-diversity, β-diversity, and amplicon sequence variants modified by antibiotic exposure, to be a significant mediator between outpatient antibiotic exposure in the first year of life and asthma diagnosis at age 5 years (β=0·08; p=0·027). Our findings suggest that the reduction in the incidence of paediatric asthma observed in recent years might be an unexpected benefit of prudent antibiotic use during infancy, acting via preservation of the gut microbial community. British Columbia Ministry of Health, Pharmaceutical Services Branch; Canadian Institutes of Health Research; Allergy, Genes and Environment (AllerGen) Network of Centres of Excellence; Genome Canada; and Genome British Columbia. [ABSTRACT FROM AUTHOR]

Published

2020

5. Mining the infant gut microbiota for therapeutic targets against atopic disease.

Author

Boutin, Rozlyn C. T., Sbihi, Hind, Dsouza, Melissa, Malhotra, Raunaq, Petersen, Charisse, Dai, Darlene, Sears, Malcolm R., Moraes, Theo J., Becker, Allan B., Azad, Meghan B., Mandhane, Piush J., Subbarao, Padmaja, Finlay, B. Brett, and Turvey, Stuart E.

Subjects

WHEEZE, ATOPY, GUT microbiome, ETIOLOGY of diseases, DISEASES, INFANTS, FOOD allergy

Abstract

Keywords: atopic dermatitis; atopy; food sensitization; live biotherapeutic product; microbiota EN atopic dermatitis atopy food sensitization live biotherapeutic product microbiota 1 4 4 07/29/20 20200801 NES 200801 Abbreviations LBP live biotherapeutic product rDNA ribosomal deoxyribonucleic acid SCFA short-chain fatty acid Forty percent of the world's population is sensitized to at least one environmental allergen, and atopic diseases such as asthma, atopic dermatitis, and food allergy are among the most frequent health challenges faced by children today. Specifically, increased bacterial diversity (as quantified by the Shannon -diversity index) was associated with protection against allergic sensitization (atopy), wheeze, AW, FS, and AD (Figure 1A and Figure E4). [Extracted from the article]

Published

2020

6. Maternal psychological distress before birth influences gut immunity in mid‐infancy.

Author

Kang, Liane J., Vu, Khanh N., Koleva, Petya T., Field, Catherine J., Chow, Angela, Azad, Meghan B., Becker, Allan B., Mandhane, Piushkumar J., Moraes, Theo J., Sears, Malcolm R., Lefebvre, Diana L., Turvey, Stuart E., Subbarao, Padmaja, Lou, Wendy Y. W., Scott, James A., and Kozyrskyj, Anita L.

Subjects

PSYCHOLOGICAL distress, CHILDBIRTH, MOTHER-infant relationship, GUT microbiome, INFANT development, PRENATAL depression, CO-sleeping

Abstract

Background: Maternal pre‐postnatal psychosocial distress increases the risk for childhood allergic disease. This may occur through a host immunity pathway that involves intestinal secretory immunoglobulin A (sIgA). Experimental animal models show changes in the gut microbiome and immunity of offspring when exposed to direct or prenatal maternal stress, but little is known in humans. Objective: We determined the association between maternal depression and stress symptom trajectories and infant fecal sIgA concentrations. Methods: 1043 term infants from the Canadian Healthy Infant Longitudinal Development (CHILD) birth cohort were studied. Trajectories of maternal perceived stress and depression were based on scored scales administered in pregnancy and postpartum. sIgA was quantified in infant stool (mean age 3.7 months) with Immundiagnostik ELISA. Linear regression and logistic regression were employed to test associations. Results: Very low fecal sIgA concentrations were more common in infants of mothers in the antepartum and persistent depression trajectories (6% and 2% of women, respectively). Independent of breastfeeding status at fecal sampling, infant antibiotic exposure or other covariates, the antepartum depressive symptom trajectory was associated with reduced mean infant sIgA concentrations (β=−0.07, P <.01) and a two fold risk for lowest quartile concentrations (OR, 1.86; 95% CI: 1.02, 3.40). This lowering of sIgA yielded a large effect size in older infants (4‐8 months)—breastfed and not. No associations were seen with postpartum depressive symptoms (7% of women) or with any of the perceived stress trajectories. Conclusion and clinical relevance: Despite improved mood postpartum and independent of breastfeeding status, mothers experiencing antepartum depressive symptoms delivered offspring who exhibited lower fecal sIgA concentrations especially in later infancy. The implications of lowered sIgA concentrations in infant stool are altered microbe‐sIgA interactions, greater risk for C difficile colonization and atopic disease in later years. [ABSTRACT FROM AUTHOR]

Published

2020

7. Clostridioides difficile Colonization Is Differentially Associated With Gut Microbiome Profiles by Infant Feeding Modality at 3–4 Months of Age.

Author

Drall, Kelsea M., Tun, Hein M., Morales-Lizcano, Nadia P., Konya, Theodore B., Guttman, David S., Field, Catherine J., Mandal, Rupasri, Wishart, David S., Becker, Allan B., Azad, Meghan B., Lefebvre, Diana L., Mandhane, Piush J., Moraes, Theo J., Sears, Malcolm R., Turvey, Stuart E., Subbarao, Padmaja, Scott, James A., and Kozyrskyj, Anita L.

Subjects

GUT microbiome, INFANTS, COLONIZATION, MICROBIAL metabolites, DISEASE susceptibility

Abstract

Colonization with Clostridioides difficile occurs in up to half of infants under the age of 3 months, is strongly influenced by feeding modality and is largely asymptomatic. In spite of this, C. difficile 's presence has been associated with susceptibility to chronic disease later in childhood, perhaps by promoting or benefiting from changes in infant gut microbiome development, including colonization with pathogenic bacteria and disrupted production of microbial bioactive metabolites and proteins. In this study, the microbiomes of 1554 infants from the CHILD Cohort Study were described according to C. difficile colonization status and feeding mode at 3–4 months of age. C. difficile colonization was associated with a different gut microbiome profile in exclusively breastfed (EBF) vs. exclusively formula fed (EFF) infants. EBF infants colonized with C. difficile had an increased relative abundance of Firmicutes and Proteobacteria, decreased relative abundance of Bifidobacteriaceae, greater microbiota alpha-diversity, greater detectable fecal short chain fatty acids (SCFA), and lower detectable fecal secretory Immunoglobulin A (sIgA) than those not colonized. Similar but less pronounced differences were seen among partially breastfed infants (PBF) but EFF infants did not possess these differences in the gut microbiome according to colonization status. Thus, breastfed infants colonized with C. difficile appear to possess a gut microbiome that differs from non-colonized infants and resembles that of EFF infants, but the driving force and direction of this association remains unknown. Understanding these compositional differences as drivers of C. difficile colonization may be important to ensure future childhood health. [ABSTRACT FROM AUTHOR]

Published

2019

8. Infant gut microbiota and the hygiene hypothesis of allergic disease: impact of household pets and siblings on microbiota composition and diversity.

Author

Azad, Meghan B., Konya, Theodore, Maughan, Heather, Guttman, David S., Field, Catherine J., Sears, Malcolm R., Becker, Allan B., Scott, James A., and Kozyrskyj, Anita L.

Subjects

*ALLERGIES, *SIBLINGS, *PETS, *DISEASES

Abstract

Background: Multiple studies have demonstrated that early-life exposure to pets or siblings affords protection against allergic disease; these associations are commonly attributed to the "hygiene hypothesis". Recently, low diversity of the infant gut microbiota has also been linked to allergic disease. In this study, we characterize the infant gut microbiota in relation to pets and siblings. Methods: The study population comprised a small sub-sample of 24 healthy, full term infants from the Canadian Healthy Infant Longitudinal Development (CHILD) birth cohort. Mothers reported on household pets and siblings. Fecal samples were collected at 4 months of age, and microbiota composition was characterized by high-throughput signature gene sequencing. Results: Microbiota richness and diversity tended to be increased in infants living with pets, whereas these measures were decreased in infants with older siblings. Infants living with pets exhibited under-representation of Bifidobacteriaceae and over-representation of Peptostreptococcaceae; infants with older siblings exhibited under-representation of Peptostreptococcaceae. Conclusions: This study provides new evidence that exposure to pets and siblings may influence the early development of the gut microbiota, with potential implications for allergic disease. These two traditionally protective "hygiene hypothesis" factors appear to differentially impact gut microbiota composition and diversity, calling into question the clinical significance of these measures. Further research is required to confirm and expand these findings. [ABSTRACT FROM AUTHOR]

Published

2013

9. Gut microbiota of healthy Canadian infants: profiles by mode of delivery and infant diet at 4 months.

Author

Azad, Meghan B., Konya, Theodore, Maughan, Heather, Guttman, David S., Field, Catherine J., Chari, Radha S., Sears, Malcolm R., Becker, Allan B., Scott, James A., and Kozyrskyj, Anita L.

Subjects

*GUT microbiome, *INFANT diseases, *DELIVERY (Obstetrics), *INFANT nutrition, *BREASTFEEDING, *BACTERIAL growth

Abstract

Background: The gut microbiota is essential to human health throughout life, yet the acquisition and development of this microbial community during infancy remains poorly understood. Meanwhile, there is increasing concern over rising rates of cesarean delivery and insufficient exclusive breastfeeding of infants in developed countries. In this article, we characterize the gut microbiota of healthy Canadian infants and describe the influence of cesarean delivery and formula feeding. Methods: We included a subset of 24 term infants from the Canadian Healthy Infant Long itudinal Development (CHILD) birth cohort. Mode of delivery was obtained from medical records, and mothers were asked to report on infant diet and medication use. Fecal samples were collected at 4 months of age, and we characterized the microbiota composition using high-throughput DNA sequencing. Results: We observed high variability in the profiles of fecal microbiota among the in - fants. The profiles were generally dominated by Actinobacteria (mainly the genus Bifidobacterium) and Firmicutes (with diverse representation from numerous genera). Compared with breastfed infants, formula-fed infants had increased richness of species, with overrepresentation of Clostridium difficile. Escherichia- Shigella and Bacteroides species were underrepresented in infants born by cesarean delivery. Infants born by elective cesarean delivery had particularly low bacterial richness and diversity. Interpretation: These findings advance our understanding of the gut microbiota in healthy infants. They also provide new evidence for the effects of delivery mode and infant diet as determinants of this essential microbial community in early life. [ABSTRACT FROM AUTHOR]

Published

2013

10. Perinatal Programming of Asthma: The Role of Gut Microbiota.

Author

Azad, Meghan B. and Kozyrskyj, Anita L.

Subjects

*ASTHMA in children, *NEONATAL diseases, *CARDIOVASCULAR diseases, *GUT microbiome, *EPIGENETICS

Abstract

Perinatal programming, a dominant theory for the origins of cardiovascular disease, proposes that environmental stimuli influence developmental pathways during critical periods of prenatal and postnatal development, inducing permanent changes in metabolism. In this paper, we present evidence for the perinatal programming of asthma via the intestinal microbiome. While epigenetic mechanisms continue to provide new explanations for the programming hypothesis of asthma development, it is increasingly apparent that the intestinal microbiota plays an independent and potentially interactive role. Commensal gut bacteria are essential to immune system development, and exposures disrupting the infant gut microbiota have been linked to asthma. This paper summarizes the recent findings that implicate caesarean delivery, breastfeeding, perinatal stress, probiotics, and antibiotics as modifiers of infant gut microbiota in the development of asthma. [ABSTRACT FROM AUTHOR]

Published

2012

11. Bacterial–fungal interactions in the neonatal gut influence asthma outcomes later in life.

Author

Boutin, Rozlyn C. T., Petersen, Charisse, Woodward, Sarah E., Serapio-Palacios, Antonio, Bozorgmehr, Tahereh, Loo, Rachelle, Chalanuchpong, Alina, Cirstea, Mihai, Lo, Bernard, Huus, Kelsey E., Barcik, Weronika, Azad, Meghan B., Becker, Allan B., Mandhane, Piush J., Moraes, Theo J., Sears, Malcolm R., Subbarao, Padmaja, McNagny, Kelly M., Turvey, Stuart E., and Finlay, B. Brett

Subjects

*ASTHMA, *SHORT-chain fatty acids, *ASTHMA in children, *LABORATORY mice, *GUT microbiome

Abstract

Bacterial members of the infant gut microbiota and bacterial-derived short-chain fatty acids (SCFAs) have been shown to be protective against childhood asthma, but a role for the fungal microbiota in asthma etiology remains poorly defined. We recently reported an association between overgrowth of the yeast Pichia kudriavzevii in the gut microbiota of Ecuadorian infants and increased asthma risk. In the present study, we replicated these findings in Canadian infants and investigated a causal association between early life gut fungal dysbiosis and later allergic airway disease (AAD). In a mouse model, we demonstrate that overgrowth of P. kudriavzevii within the neonatal gut exacerbates features of type-2 and -17 inflammation during AAD later in life. We further show that P. kudriavzevii growth and adherence to gut epithelial cells are altered by SCFAs. Collectively, our results underscore the potential for leveraging inter-kingdom interactions when designing putative microbiota-based asthma therapeutics. [ABSTRACT FROM AUTHOR]

Published

2021

12. Natural environments in the urban context and gut microbiota in infants.

Author

Nielsen, Charlene C., Gascon, Mireia, Osornio-Vargas, Alvaro R., Shier, Catherine, Guttman, David S., Becker, Allan B., Azad, Meghan B., Sears, Malcolm R., Lefebvre, Diana L., Moraes, Theo J., Turvey, Stuart E., Subbarao, Padmaja, Takaro, Tim K., Brook, Jeffrey R., Scott, James A., Mandhane, Piush J., Tun, Hein M., and Kozyrskyj, Anita L.

Subjects

*GUT microbiome, *URBAN ecology, *HUMAN microbiota, *PROXIMITY spaces, *MICROBIAL diversity, *PREMATURE infants, *INFANTS

Abstract

• Proximity to natural urban environments – their vegetation, soil or water – may be beneficial for early life microbiota. • Tested influence of a natural environment within 500 m of a home residence on infant gut microbiota at age 4 months. • Proximity to a natural environment plus pet ownership reduced microbial diversity of infants not breastfed. • Notable changes in gut microbial composition included enrichment of Proteobacteria that are commonly found in vegetation. The biodiversity hypothesis that contact with natural environments (e.g. native vegetation) and biodiversity, through the influence of environmental microbes, may be beneficial for human commensal microbiota has been insufficiently tested. We aimed to study the association between living near natural environments in the urban context, and gut microbiota diversity and composition in young infants. Based on data linkage between the unique Urban Primary Land and Vegetation Inventory (uPLVI) for the city of Edmonton and 355 infants in the CHILD Cohort Study, infant exposure to natural environments (any and specific types, yes/no) was determined within 500 m and 1000 m of their home residence. Gut microbiota composition and diversity at age 4 months was assessed in infant fecal samples. Adjusted for covariates, we observed a reduced odds of high microbial alpha-diversity in the gut of infants exposed to any natural environment within 500 m [Shannon index aOR (95%CI) = 0.63 (0.40, 0.98) and Simpson index = 0.63 (0.41, 0.98)]. In stratified analyses, these associations remained only among infants not breastfed or living with household pets. When doubly stratifying by these variables, the reduced likelihood of high alpha-diversity was present only among infants who were not breastfed and lived with household pets [9% of the study population, Shannon index = 0.07 (0.01, 0.49) and Simpson index = 0.11 (0.02, 0.66)]. Differences in beta-diversity was also seen (p = 0.04) with proximity to a nature space in not breastfed and pets-exposed infants. No associations were observed among infants who were fully formula-fed but without pets at home. When families and their pets had close access to a natural environment, Verrucomicrobiales colonization was reduced in the gut microbiota of formula-fed infants, the abundance of Clostridiales was depleted, whereas the abundance of Enterobacteriales was enriched. Our double-stratified results indicate that proximity to a natural environment plus pet ownership has the capacity to alter the gut microbiota of formula-fed infants. Further research is needed to replicate and better interpret these results, as well as to understand their health consequences. [ABSTRACT FROM AUTHOR]

Published

2020