Yasmine Belkaid

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Yasmine Belkaid
2017-03-31 - Yasmine-Belkaid - 1340.jpg
Belkaid in 2017
Born1968 (age 5556)
Algiers, Algeria
NationalityAlgerian, French, American.
Alma mater University of Sciences and Technology Houari Boumediene
University of Paris-Sud
Pasteur Institute
Known for Microbiome
AwardsSanofi-Pasteur Award
Scientific career
Fields Immunology, Microbiology
Institutions National Institute of Allergy and Infectious Diseases
University of Pennsylvania

'Yasmine Belkaid; born August 1968) is an immunologist, currently President of the Institut Pasteur. She has Algerian citizenship by her father and French citizenship by her mother, and she also holds US citizenship.

Contents

She is best known for her work studying host-microbe interactions in tissues and immune regulation to microbes. Belkaid currently serves as the director of the NIAID Microbiome program. [1] On 29 March 2023, she was appointed as President of the Pasteur Institute for a six-year term, starting from January 2024. [2]

Early life and education

Belkaid was born and raised in Algiers, Algeria. Her father was Algerian politician Aboubakr Belkaid, who was assassinated on September 28, 1995, during the Black Decade. [3] She received her bachelor's and master's degrees in biochemistry from the University of Sciences and Technology Houari Boumediene [lower-alpha 1] as well as a Master of Advanced Studies from University of Paris-Sud. She earned her doctorate in immunology from the Pasteur Institute in 1996, where she studied innate immune responses to Leishmania infection.

Career

Academia

Following graduate school, she moved to the United States for a postdoctoral fellowship at NIAID's Laboratory of Parasitic Diseases. In 2002, she joined the faculty of the Division of Molecular Immunology in Cincinnati Children's Hospital Medical Center before returning to NIAID in 2005 as Head of the Mucosal Immunology Unit in the Laboratory of Parasitic Diseases. In 2008, she became adjunct Professor of Pathology and Laboratory Medicine at the University of Pennsylvania. [4]

Research

Belkaid's research focuses on untangling the mechanisms underlying host-microbe interactions in the gastrointestinal tract and on the skin, which are natural barrier sites between the host's inner workings and their external environment. [5] This also includes the role microbiota play in promoting immunity against infection against other harmful pathogens. [6] [5] Her group has contributed to the scientific understanding of how the host immune system can distinguish good microbes from the bad. [7] [8]

Belkaid's research also led to the discovery of certain skin microbes that play an important role in immune defense. [8] They carried out this experiment using mice that had no naturally-occurring microbes in their skin or gut so they could colonize those mice with only one strain of "good" bacteria. They then infected the colonized and bacteria-free mice with a parasite and found that those without the "good" bacteria were unable to fight back against the parasite, while those with the bacteria mounted an effective immune response. [8] Her team has also found that beneficial bacteria living on the surface of the skin can also accelerate wound healing in mice. [9] Belkaid's group also studies what happens when there are imbalances in our microbiome. Belkaid's research has advanced scientific understanding of how shifts in microbiota can contribute to disease, particularly chronic inflammatory diseases like Crohn's disease and Psoriasis. [10] [11] [12] [13] [14]

Awards and honors

Notes

  1. During her studies, Belkaid worked at the Pasteur Institute of Algeria, where she was responsible for improving diagnostic methods for leishmaniasis.

Related Research Articles

<span class="mw-page-title-main">Human microbiome</span> Microorganisms in or on human skin and biofluids

The human microbiome is the aggregate of all microbiota that reside on or within human tissues and biofluids along with the corresponding anatomical sites in which they reside, including the gastrointestinal tract, skin, mammary glands, seminal fluid, uterus, ovarian follicles, lung, saliva, oral mucosa, conjunctiva, and the biliary tract. Types of human microbiota include bacteria, archaea, fungi, protists, and viruses. Though micro-animals can also live on the human body, they are typically excluded from this definition. In the context of genomics, the term human microbiome is sometimes used to refer to the collective genomes of resident microorganisms; however, the term human metagenome has the same meaning.

<span class="mw-page-title-main">Bacillota</span> Phylum of bacteria

Bacillota is a phylum of bacteria, most of which have gram-positive cell wall structure. The renaming of phyla such as Firmicutes in 2021 remains controversial among microbiologists, many of whom continue to use the earlier names of long standing in the literature.

Gnotobiosis refers to an engineered state of an organism in which all forms of life in or on it, including its microbiota, have been identified. The term gnotobiotic organism, or gnotobiote, can refer to a model organism that is colonized with a specific community of known microorganisms or that contains no microorganisms (germ-free) often for experimental purposes. The study of gnotobiosis and the generation of various types of gnotobiotic model organisms as tools for studying interactions between host organisms and microorganisms is referred to as gnotobiology.

<span class="mw-page-title-main">Gut microbiota</span> Community of microorganisms in the gut

Gut microbiota, gut microbiome, or gut flora are the microorganisms, including bacteria, archaea, fungi, and viruses, that live in the digestive tracts of animals. The gastrointestinal metagenome is the aggregate of all the genomes of the gut microbiota. The gut is the main location of the human microbiome. The gut microbiota has broad impacts, including effects on colonization, resistance to pathogens, maintaining the intestinal epithelium, metabolizing dietary and pharmaceutical compounds, controlling immune function, and even behavior through the gut–brain axis.

<span class="mw-page-title-main">Martin J. Blaser</span> American academic

Martin J. Blaser is an American physician who is the director of the Center for Advanced Biotechnology and Medicine at Rutgers (NJ) Biomedical and Health Sciences and the Henry Rutgers Chair of the Human Microbiome and Professor of Medicine and Pathology and Laboratory Medicine at the Rutgers Robert Wood Johnson Medical School in New Jersey.

<span class="mw-page-title-main">Germ-free animal</span> Multi-cellular organisms that have no microorganisms living in or on them

Germ-free organisms are multi-cellular organisms that have no microorganisms living in or on them. Such organisms are raised using various methods to control their exposure to viral, bacterial or parasitic agents. When known microbiota are introduced to a germ-free organism, it usually is referred to as a gnotobiotic organism, however technically speaking, germ-free organisms are also gnotobiotic because the status of their microbial community is known. Due to lacking a microbiome, many germ-free organisms exhibit health deficits such as defects in the immune system and difficulties with energy acquisition. Typically germ-free organisms are used in the study of a microbiome where careful control of outside contaminants is required.

Dysbiosis is characterized by a disruption to the microbiome resulting in an imbalance in the microbiota, changes in their functional composition and metabolic activities, or a shift in their local distribution. For example, a part of the human microbiota such as the skin flora, gut flora, or vaginal flora, can become deranged, with normally dominating species underrepresented and normally outcompeted or contained species increasing to fill the void. Similar to the human gut microbiome, diverse microbes colonize the plant rhizosphere, and dysbiosis in the rhizosphere, can negatively impact plant health. Dysbiosis is most commonly reported as a condition in the gastrointestinal tract or plant rhizosphere.

<span class="mw-page-title-main">Skin flora</span> Microbiota that reside on the skin

Skin flora, also called skin microbiota, refers to microbiota that reside on the skin, typically human skin.

<span class="mw-page-title-main">Microbial symbiosis and immunity</span>

Long-term close-knit interactions between symbiotic microbes and their host can alter host immune system responses to other microorganisms, including pathogens, and are required to maintain proper homeostasis. The immune system is a host defense system consisting of anatomical physical barriers as well as physiological and cellular responses, which protect the host against harmful microorganisms while limiting host responses to harmless symbionts. Humans are home to 1013 to 1014 bacteria, roughly equivalent to the number of human cells, and while these bacteria can be pathogenic to their host most of them are mutually beneficial to both the host and bacteria.

<span class="mw-page-title-main">Microbiota</span> Community of microorganisms

Microbiota are the range of microorganisms that may be commensal, mutualistic, or pathogenic found in and on all multicellular organisms, including plants. Microbiota include bacteria, archaea, protists, fungi, and viruses, and have been found to be crucial for immunologic, hormonal, and metabolic homeostasis of their host.

Colonization resistance is the mechanism whereby the intestinal microbiota protects itself against incursion by new and often harmful microorganisms.

Skin immunity is a property of skin that allows it to resist infections from pathogens. In addition to providing a passive physical barrier against infection, the skin also contains elements of the innate and adaptive immune systems which allows it to actively fight infections. Hence the skin provides defense in depth against infection.

<span class="mw-page-title-main">Microbiome</span> Microbial community assemblage and activity

A microbiome is the community of microorganisms that can usually be found living together in any given habitat. It was defined more precisely in 1988 by Whipps et al. as "a characteristic microbial community occupying a reasonably well-defined habitat which has distinct physio-chemical properties. The term thus not only refers to the microorganisms involved but also encompasses their theatre of activity". In 2020, an international panel of experts published the outcome of their discussions on the definition of the microbiome. They proposed a definition of the microbiome based on a revival of the "compact, clear, and comprehensive description of the term" as originally provided by Whipps et al., but supplemented with two explanatory paragraphs. The first explanatory paragraph pronounces the dynamic character of the microbiome, and the second explanatory paragraph clearly separates the term microbiota from the term microbiome.

The microbiota are the sum of all symbiotic microorganisms living on or in an organism. The fruit fly Drosophila melanogaster is a model organism and known as one of the most investigated organisms worldwide. The microbiota in flies is less complex than that found in humans. It still has an influence on the fitness of the fly, and it affects different life-history characteristics such as lifespan, resistance against pathogens (immunity) and metabolic processes (digestion). Considering the comprehensive toolkit available for research in Drosophila, analysis of its microbiome could enhance our understanding of similar processes in other types of host-microbiota interactions, including those involving humans. Microbiota plays key roles in the intestinal immune and metabolic responses via their fermentation product, acetate.

The Human Microbiome Project (HMP), completed in 2012, laid the foundation for further investigation into the role the microbiome plays in overall health and disease. One area of particular interest is the role which delivery mode plays in the development of the infant/neonate microbiome and what potential implications this may have long term. It has been found that infants born via vaginal delivery have microbiomes closely mirroring that of the mother's vaginal microbiome, whereas those born via cesarean section tend to resemble that of the mother's skin. One notable study from 2010 illustrated an abundance of Lactobacillus and other typical vaginal genera in stool samples of infants born via vaginal delivery and an abundance of Staphylococcus and Corynebacterium, commonly found on the skin surfaces, in stool samples of infants born via cesarean section. From these discoveries came the concept of vaginal seeding, also known as microbirthing, which is a procedure whereby vaginal fluids are applied to a new-born child delivered by caesarean section. The idea of vaginal seeding was explored in 2015 after Maria Gloria Dominguez-Bello discovered that birth by caesarean section significantly altered the newborn child's microbiome compared to that of natural birth. The purpose of the technique is to recreate the natural transfer of bacteria that the baby gets during a vaginal birth. It involves placing swabs in the mother's vagina, and then wiping them onto the baby's face, mouth, eyes and skin. Due to the long-drawn nature of studying the impact of vaginal seeding, there are a limited number of studies available that support or refute its use. The evidence suggests that applying microbes from the mother's vaginal canal to the baby after cesarean section may aid in the partial restoration of the infant's natural gut microbiome with an increased likelihood of pathogenic infection to the child via vertical transmission.

<span class="mw-page-title-main">Uterine microbiome</span>

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  22. Robert-Koch-Preis 2021
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