Microbiome

The microbiome is the ecological community of commensal, symbiotic and pathogenic microorganisms that live on the skin and genitals and in the nose, ears, mouth and gut. Dysbiosis or an imbalance in this community may play a role in the pathophysiology of chronic fatigue syndrome.

Gut flora
The gut microbiome is a complex community of trillions of microorganisms residing in the intestines.

99% of bacteria in the gut are anaerobes

Chronic fatigue syndrome
A growing body of evidence suggests that an altered microbiome; mucosal barrier dysfunction ; the translocation or crossing of bacteria from the gut into the bloodstream; and subsequent immune response may pay a role in the pathophysiology of chronic fatigue syndrome.

Immune response
A study of 128 ME/CFS patients found significantly increased IgA response to lipopolysaccharides from the cell walls of commensal bacteria. Increased IgA response was associated with increased serum IL-1, TNFα, neopterin and elastase. The study concluded that increased translocation of commensal bacteria may be responsible for the disease activity in some ME/CFS patients.

Dysbiosis
There is strong evidence that dysbiosis or an imbalance in the microbial ecology of the gut plays a role in the symptoms of ME/CFS. ME/CFS patients have higher levels of D-lactic acid bacteria, decreased levels of Bifidobacteria, and may suffer from small intestinal bacterial overgrowth (SIBO) at higher rates.

Exercise
A small study of ten CFS patients found significant changes in the composition of the microbiome and increased bacterial translocation (movement from the intestine into the bloodstream following exercise). In the blood, the study found increased Clostridium fifteen minutes after exercise and increased Bacilli 48 hours later.

Sleep
In a very small study, CFS patients treated with erythromycin who had clinical response (i.e., reduced streptococcus) had improved sleep. Higher lactobacillus was associated with poorer mood.

Gender
A study of 274 ME/CFS patients found sex-specific interactions between Firmicutes (Clostridium, Streptococcus, Lactobacillus and Enterococcus) and ME/CFS symptoms (including neurological, immune and mood symptoms) and symptoms in spite of similar overall composition across sexes.

Diet
The food we eat has a considerable effect on the composition of the intestinal microbiota

Viral infection
Viral infection can cause shifts in the gut microbiome.

In mice, the influenza virus leads to injury of both the lungs (the primary site of infection) and the intestinal tract, even when there is no evidence of viral replication in the gut, and causes decreases Lactobacillus and Lactococcus species and increases in Enterobacteriaceae

Pregnancy
Gut microbiota change dramatically from the first trimester to the third trimester of pregnancy. During the first trimester, there is an overrepresentation of 18 bacterial groups, mainly Faecalibacterium, a butyrate producer that has been shown to improve symptoms of inflammatory bowel disease.

During the third trimester, populations of pro-inflammatory bacteria species such as proteobacteria and actinobacteria increase and there is a reduction in diversity. Populations of Faecalibacterium decrease. Overall bacterial load increases over the course of pregnancy.

Nervous system
The intestinal microbiota play a major role in the gut-brain axis with consequences for both neurological development and host behavior.

Stress
There is growing evidence that the microbiome plays an important role in the stress response. Animals raised in a germ-free environment show an exaggerated HPA response to psychological stress which normalizes when Bifidobacterium infantis is introduced. Escherichia coli can activate the HPA.

Stress also increases intestinal permeability.

Planned studies
British patient charity Invest in ME is raising funds for a gut microbiome study at the University of East Anglia in the United Kingdom led by professor Simon Carding.

Funds have been raised by patients (originally led by the late Vanessa Li) for Ian Lipkin and Mady Hornig of Columbia University in the United States to perform a study looking at the gut microbiome in ME/CFS patients, the Microbe Discovery Project.

Notable studies

 * 2016, Support for the Microgenderome: Associations in a Human Clinical Population (Amy Wallis, Henry Butt, Michelle Ball, Donald Lewis, Dorothy Bruck)
 * 2015, Sleep quality and the treatment of intestinal microbiota imbalance in Chronic Fatigue Syndrome: A pilot study (Jackson ML, Henry Butt, Ball M, Lewis DP, Bruck D)
 * 2015, Changes in Gut and Plasma Microbiome following Exercise Challenge in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS) (Shukla SK, Cook D, Meyer J, Vernon SD, Le T, Clevidence D, Robertson CE, Schrodi SJ, Yale S, Frank DN)
 * 2013, High-throughput 16S rRNA gene sequencing reveals alterations of intestinal microbiota in myalgic encephalomyelitis/chronic fatigue syndrome patients (Frémont M, Coomans D, Massart S, Kenny de Meirleir)
 * 2012, Increased IgA responses to the LPS of commensal bacteria is associated with inflammation and activation of cell-mediated immunity in chronic fatigue syndrome (Michael Maes, Frank Twisk, Kubera M, Ringel K, Leunis JC, Geffard M)
 * 2012, The GI Microbiome and its Role in Chronic Fatigue Syndrome: A Summary of Bacteriotherapy (Thomas J. Borody, Anna Nowak, Sarah Finalayson)
 * 2010, Gut inflammation in chronic fatigue syndrome (Lakhan SE, Kirchgessner A)
 * 2009, Increased d-lactic Acid intestinal bacteria in patients with chronic fatigue syndrome (Sheedy JR, Wettenhall RE, Scanlon D, Gooley PR, Lewis DP, McGregor N, Stapleton DI, Henry Butt, Kenny de Meirleir)

Commercial testers

 * uBiome

Academic projects

 * American Gut
 * British Gut Project

Learn more

 * Wikipedia - Microbiota
 * CFS Remission (Ken Lassesen's blogs about experimental ME/CFS microbiome and probiotic treatments)
 * 2016, Gender Gut Wars: Australian ME/CFS Study Suggests Different Gut Treatment Protocols Needed For Men and Women