http://ghostprof.org/wp-json/oembed/1.0/embed?url=http://ghostprof.org/teaching/past-courses/modernist-novel_2014_01/schedule/ One of medicine’s greatest innovations in the 20th century was the development of antibiotics. It’s a treatment that has transformed our ability to combat disease. And yet medicine in the 21st century is undertaking a re-evaluation of bacteria and concluding that, far from being uniformly bad for us, many of these organisms are actually essential for our health.
http://summeronwinterlane.com/longline-vest-for-spring/?cf_action=sync_comments Nowhere is this more apparent than in the human gut, where the microbiome – the collection of bacteria living in the gastrointestinal tract – plays a complex and critical role in the health of its host. The microbiome interacts with and influences organ systems throughout the body, including, as recent research is revealing, the brain. This discovery has led to a surge of interest in potential gut-based treatments for neuropsychiatric disorders and a new class of studies investigating how the gut and its microbiome affect both healthy and diseased brains.
click here The microbiome consists of a startlingly massive number of organisms – there are anywhere from 10 to 100 times more bacteria in the gut than cells in the human body. This prokaryotic horde encompasses many different sorts of bacteria. Researchers have identified Firmicutes and Bacteroides as the two most common phyla but are still in the process of fully characterizing the microbiome’s diversity. The Human Microbiome Project, coordinated by the NIH, seeks to create a comprehensive database of the bacteria residing throughout the gastrointestinal tract and to catalogue their properties.
The lives of the bacteria in our gut are intimately entwined with our immune, endocrine, and nervous systems. The relationship goes both ways: the microbiome influences the function of these systems, and they in turn alter the activity and composition of the bacterial community. Despite this complexity, we are beginning to gain insight into how gut bacteria interface with the rest of the body and, in particular, how they affect the brain.
The microbiome-immune system link is established early on. Over the first year of life, bacteria populate the gut (which is largely sterile at birth), and the developing immune system learns which bacteria to consider normal residents of the body and which to attack as invaders. This early learning sets the stage for later immune responses to fluctuations in the microbiome’s composition. When a normally scarce strain becomes too abundant or a pathogenic species joins the community of gut bacteria, the resulting inflammatory response can have wide-reaching effects as immune molecules circulate in the bloodstream. Depression has been linked with elevated levels of such molecules in some individuals, suggesting that treatments that alter the composition of the microbiome could alleviate symptoms of this disorder.
Such an intervention could potentially be achieved using either prebiotics – substances that promote the growth of beneficial bacteria – or probiotics – live cultures of these bacteria. It is even possible that the microbiome could be manipulated via dietary changes. In one experiment, researchers transplanted the human microbiome into germ-free mice (animals that have no gut bacteria) in order to study it in a controlled setting. They found that, simply by changing the carbohydrate and fat content of the mice’s food, they could alter basic cellular functions and gene expression in the microbiome.
Depression is not the only psychiatric disorder in which the microbiome may play a role. Research in rodents, as well as a few preliminary studies in humans, indicate that the state of our resident microbes is tied to our anxiety levels. Germ-free mice, for example, appear to be less anxious than normal mice on behavioural tests of anxiety, whereas mice infected with pathogenic bacteria behave more anxiously. Interestingly, there seems to be a window during development when the presence of a microbiome leads to normal levels of anxiety in adulthood: germ-free mice that were exposed to microbiome bacteria at 3 weeks of age subsequently behaved like normal mice, whereas those exposed at 10 weeks of age continued to be less anxious than normal animals. Like the data on microbiome-immune interactions, these findings highlight the critical role gut bacteria play early in life.
This research also reveals the complexity of the relationship between the microbiome and psychological state. Although the general trend is that fewer bacteria mean lower anxiety levels, it is not just the number but the identity of the bacterial species that determine how gut dynamics interact with mental state. For example, adding beneficial bacteria through probiotic treatment may reduce elevated anxiety levels caused by inflammation and infection. A key factor in this relationship is stress – and the way the body responds to it. Researchers have demonstrated that the presence or absence of microbes in young mice affects the sensitivity of the hypothalamic-pituitary-adrenal (HPA) axis – a key pathway in the body’s stress response system. The activity of the microbiome during development thus sways how we respond to future stressors and how much anxiety they cause us.
How do the bacteria in our gut wield such influence over our brains and bodies? The mechanisms of microbiome-host interactions appear to be as numerous and varied as the interactions themselves. Gut microbes help break down food into its component parts, so the molecular building blocks available in the body depend in part on which bacteria are present to extract them. This can influence brain function by, for example, affecting the availability of molecules needed to make neurotransmitters. Amazingly, some gut bacteria can alter neurotransmitter levels directly by converting glutamate – an excitatory transmitter – into GABA – an inhibitory brain chemical. And gut microbes, along with neighboring intestinal cells, communicate with a branch of the nervous system called the enteric nervous system (ENS) whose neurons surround the entire gastrointestinal tract. This part of the nervous system is so sophisticated that many refer to it as the body’s second brain.
The study of microbiome-gut-brain interactions is still young, yet it is already spurring the development of new branches of medical research. At this rate, it is poised to become one of the most fascinating stories in neuroscience.