A gut microbiota-targeted dietary intervention for amelioration of chronic inflammation

志云文献翻译1. What is the significance of studying microbiota in the gut?The gut microbiota plays an important role in the host's health and disease. It is involved in metabolism, immune system development, and protection against pathogens. Therefore, studying the gut microbiota is critical for understanding these processes and developing new therapies.In addition, imbalances in the gut microbiota have been linked to various diseases, such as inflammatory bowel disease, obesity, and diabetes. By studying the gut microbiota, researchers can better understand these conditions and potentially develop new treatments.Furthermore, recently it has been discovered that gut microbiota is related to mental disorders such as autism,Alzheimer's disease and Parkinson's disease, which provides a new insight into the etiology of these disorders.2. What are the limitations of traditional culture-based methods for analyzing gut microbiota?Culture-based methods are limited in their ability to analyze gut microbiota because only a small portion of the gut microbiota can be cultured in a laboratory. Many gut microbes are difficult or impossible to culture using traditional methods, making it challenging to study their function and importance.In addition, culture-based methods can also introduce bias, such as favoring certain types of microorganisms over others. This can lead to an incomplete understanding of the gut microbiota and its functions.3. What are some of the advantages of using high-throughput sequencing to study gut microbiota?High-throughput sequencing allows for the analysis of large amounts of genetic data from microbial communities, providing a more comprehensive view of gut microbiota than traditional culture-based methods. This approach can identify a wide range of microbial species and detect low-abundance microbes that may have gone undetected using other methods.Furthermore, high-throughput sequencing can provide information on the functional properties of microbial communities, such as the metabolic pathways they use to break down food, their interactions with the host immune system, antimicrobial resistance, and pathogenicity.Moreover, the use of high-throughput sequencing in the analysis of gut microbiota has facilitated the development of personalized medicine, where interventions can be tailored to the individual based on their unique gut microbiota profile.4. How does diet affect gut microbiota, and what are some dietary interventions that can improve gut health?Diet plays a significant role in shaping gut microbiota. For example, a diet high in fat and sugar has been shown to alter the composition and function of the gut microbiota, potentially leading to obesity and insulin resistance. In contrast, a diet rich in fiber from fruits, vegetables, and whole grains promotes the growth of beneficial gut microbes.Several dietary interventions have been shown to improve gut health, such as increasing the consumption of non-digestible carbohydrates, such as fiber and resistant starches, and consuming probiotics and prebiotics. Additionally, certain nutrients, such as polyphenols found in plant-based foods and omega-3 fatty acids found in fish, have been shown to have positive effects on gut health.5. How can knowledge of gut microbiota be applied in medicine?Understanding gut microbiota has important implications for medicine, including the development of new therapies forvarious diseases. For example, fecal microbiota transplantation (FMT) has been shown to be effective in treating recurrent Clostridium difficile infection, and probiotics have been used to treat irritable bowel syndrome and inflammatory bowel disease.In addition, interventions aimed at modulating gut microbiota, such as dietary changes, prebiotics and probiotics, and antibiotics, are being investigated for their potential in treating a wide range of conditions, such as obesity, diabetes, and depression.Finally, knowledge of gut microbiota can also be used to develop personalized medicine, where interventions can be tailored to the individual based on their unique gut microbiota profile. This approach has the potential to revolutionize the way medical treatments are developed and prescribed.。

Gut Microbiota ImbalanceThe human large intestine is the main site of microbial colonization where the host is assumed to have co-evolved to allow beneficial interactions with certain members of the intestinal bacteria1. In this ecological niche, bacteria live in close proximity to the epithelial cells that cover the surfaces of the gastrointestinal tract (GIT). Many of these colonic bacteria are able to attach to the mucus layer of the luminal side of the GIT forming colonies. In this way the mucus layer is exposed to commensal bacteria and can tolerate its colonization through a highly developed system that can detect bacterial antigens and that allows the host to distinguish between its resident microbiota and unwelcome allochthonous bacteria such as pathogens2. Remarkably, autochthonous components of the gut microbiota are carrying at the cell surfaces lipoproteins (for Gram positive bacteria) or lipopolysaccharides (for Gram negative bacteria) that act as recognition sites by the host cells.The composition of the colonic microbiota, which consists of autochthonous and allochthonous microorganisms, originates from and depends on a number of factors, including host characteristics such as genotype and immune function, d iet and microbial interactions within the colonic microbiota in the form of cooperation and competition3. As a consequence, the autochthonous human colonic microbiota consists of highly adapted species belonging in only four dominant phyla, but with great diversity between individuals at species/strain level4. On the other hand, the allochthonous colonic microbiota consists of microorganisms originating from ingested food and other environmental factors as well as bacteria from other body parts, resulting in a composition that is less stable and differs greatly over time. Consequently, physiological alterations in the gut and general living conditions such as stress, illness, antibiotic treatment or changes in diet can impair the overall colonic microbiota composition allowing pathogenic or detrimental organisms to become established, hence affecting the health and well being of the host5.The human gut microbiota possesses many metabolic capabilities, which are lacking in the host and thus can be considered as indispensable for human life6. The gut microbiota influences a wide range of physiological features of the host by directing intestinal epithelial cell proliferation and differentiation, pH, and the development of immune system7. Another physiological function of the colonic microbiota is the provision of a barrier against pathogens that contributes to antibacterial defences byproducing antibacterial peptides8. Moreover, the gut microbiota is capable of modulating the intestinal epithelium of the host. In model systems involving human cell lines it has been noted that an appropriate balance of the microbiota induces mucin gene expression, that acts as a barrier and at the same time provides nutrients, like saccharides, for bacterial growth thereby promoting intestinal colonization of the adhering autochthonous bacteria, which helps reduce the chances of host invasion by pathogens9.Due to all the above-mentioned properties of the microbiota, there is a strong incentive for the host to control the shaping of the microbiota through the action of its immune system10. In fact, it has been demonstrated that an imbalance of the intestinal microbiota can lead to local and/or systemic disease state11. The interaction between the gut microbiota and host may therefore allow different kinds of relationships, such as commensalism, mutualism, symbiosis and pathogenicity.ReferencePalmer C, Bik EM, Digiulio DB, Relman DA, Brown PO (2007) Development of the Human Infant Intestinal Microbiota. PLoSBiol5:e177Ley RE, Peterson DA, Gordon JI (2006) Ecological and evolutionary forces shaping microbial diversity in the human intestine. Cell 124:837–848Xu J (2006) Microbial ecology in the age of genomics and metagenomics: concepts, tools, and recent advances. MolEcol 15:1713–1731Ventura M, Canchaya C, Tauch A, Chandra G, Fitzgerald GF, Chater KF, van Sinderen D (2007) Genomics of Actinobacteria: tracing the evolutionary history of an ancient phylum. MicrobiolMolBiol Rev 71:495–548Macpherson AJ, Harris NL. Interactions between commensal intestinal bacteria and the immune system. Nat Rev Immunol 4:478–485, 2004.Savage DC (2001) Microbial biota of the human intestine: a tribute to some pioneering scientists. Curr Issues IntestMicrobiol 2:1–15Backhed F, Ley RE, Sonnenburg JL, Peterson DA, Gordon JI (2005) Host-bacterial mutualism in the human intestine. Science 307:1915–1920Lievin-Le Moal V, Servin AL (2006) The front line of enteric host defense against unwelcome intrusion of harmful microorganisms: mucins, antimicrobial peptides, and microbiota. ClinMicrobiol Rev 19:315–337Destoumieux-Garzon D, Peduzzi J, Rebuffat S (2002) Focus on modified microcins: structural features and mechanisms of action. Biochimie 84:511–519Ley RE, Backhed F, Turnbaugh P, Lozupone CA, Knight RD, Gordon JI (2005) Obesity alters gut microbial ecology. Proc Natl AcadSci U S A 102:11070–11075Ley RE, Turnbaugh PJ, Klein S, Gordon JI (2006) Microbial ecology: human gut microbes associated with obesity. Nature 444:1022–1023。

食物成分对肠道菌群结构的影响孙长豹;刘志静;刘飞;杜鹏;侯俊财【摘要】The gut microbiota is an important"microbial organ"of the human body and plays an important role in digestion and absorption,nutrition metabolism,immune function activation,intestinal barrier and regulation of body behavior.The interaction between the gut microbiota and the human body is affected by many factors such as genotype,diet,living environment,life habit,delivery mode,antibiotics and so on.Diet is the most likely to control or change factor. Food ingredients contains the substrate of gut microbiota metabolism, and which affects the structure and function of gut microbiota in a variety of ways.The long-term,relatively fixed diet makes gut microbiota stable, and the gut microbiota changes as the diet changes. The variability of gut microbiota reveals the possibility of dietary interventions for the adjustment of gut microbiota and disease treatment. This paper reviewed the impact of diet habit, food ingredients and its metabolites on the gut microbiota,aiming to provide further understanding of how diet modulates the composition and metabolism of the gut microbiota and new ideas to regulate them through diet.%肠道菌群是人体重要的"微生物器官",在食物消化吸收、营养代谢、免疫功能激活、肠道屏障和机体行为调控等方面起着至关重要的作用.肠道菌群与人体之间的相互作用关系受到宿主基因型、饮食、生活环境、生活习惯、分娩方式、抗生素等因素的影响,其中饮食因素是最容易控制或改变的因素.食物成分中含有肠道菌群代谢所需的底物,并通过多种方式影响肠道菌群的结构和功能.长期相对固定的饮食结构使肠道菌群趋于稳定,当饮食结构改变时,肠道菌群也会发生相应的变化.肠道菌群结构的可变性揭示了饮食干预手段应用于肠道菌群结构平衡的调节和疾病治疗的可能性.就饮食结构、食物成分及其代谢物对肠道菌群结构的影响进行综述,旨在为未来研究饮食干预调节肠道菌群,预防疾病提供参考和新的思路.【期刊名称】《食品研究与开发》【年(卷),期】2018(039)009【总页数】5页(P178-182)【关键词】饮食;肠道菌群;碳水化合物;蛋白质;脂肪【作者】孙长豹;刘志静;刘飞;杜鹏;侯俊财【作者单位】东北农业大学乳品科学教育部重点实验室,食品学院,黑龙江哈尔滨150030;东北农业大学乳品科学教育部重点实验室,食品学院,黑龙江哈尔滨150030;东北农业大学乳品科学教育部重点实验室,食品学院,黑龙江哈尔滨150030;东北农业大学乳品科学教育部重点实验室,食品学院,黑龙江哈尔滨150030;东北农业大学乳品科学教育部重点实验室,食品学院,黑龙江哈尔滨150030【正文语种】中文人体肠道内栖息着约1014个、1 000多种不同的细菌，其总基因组数目大约是人体总基因组数目的150倍[1]。

Gut Microbiota and Neurodegenerative Disorders The gut microbiota is a complex ecosystem of microorganisms that reside in the gastrointestinal tract. The microbiota plays a critical role in maintaining the health of the host organism, including regulating immune function, metabolism, and the central nervous system. Recent research has found that disruptions in the gut microbiota may be linked to the development of neurodegenerative disorders, such as Parkinson's disease and Alzheimer's disease.One perspective on the relationship between gut microbiota and neurodegenerative disorders is that the microbiota may play a role in the development and progression of these diseases. Studies have found that individuals with Parkinson's disease and Alzheimer's disease have different gut microbiota compositions compared to healthy individuals. Additionally, animal studies have shown that altering the gut microbiota can affect the development of neurodegenerative diseases. For example, mice that were given antibiotics to disrupt their gut microbiota showed increased levels of amyloid-beta protein, a hallmark of Alzheimer's disease.Another perspective is that neurodegenerative disorders may disrupt the gut microbiota, leading to further health complications. For example, individuals with Parkinson's disease often experience gastrointestinal symptoms, such as constipation and inflammation, which may alter the gut microbiota. Additionally, studies have found that individuals with Alzheimer's disease have increased intestinal permeability, which may allow harmful bacteria to enter the bloodstream and cause further inflammation.A third perspective is that the gut microbiota may provide a potential target for treatment or prevention of neurodegenerative disorders. Studies have found that probiotics and prebiotics, which can alter the gut microbiota, may have beneficial effects on cognitive function and brain health. Additionally, fecal microbiota transplantation, a procedure in which fecal matter from a healthy donor is transplanted into the gut of an individual with a disrupted microbiota, has shown promise in treating gastrointestinal symptoms in individuals with Parkinson's disease.However, there are also limitations to the current research on gut microbiota and neurodegenerative disorders. Many studies have been conducted on animal models, and it is unclear how well these findings translate to humans. Additionally, the mechanisms by which the gut microbiota may contribute to neurodegenerative diseases are not yet fully understood, and more research is needed to elucidate these mechanisms.Overall, the relationship between gut microbiota and neurodegenerative disorders is a complex and multifaceted one. While there is evidence to suggest that disruptions in the microbiota may be linked to the development and progression of these diseases, more research is needed to fully understand the mechanisms involved and to develop effective treatments and prevention strategies.。

The worldwide epidemic of obesity and related metabolic diseases is spreading rap-idly and has become a serious problem not only for individual health but also for fami-lies and society in general1–6(BOX 1). Excessive fat accumulation and insulin resistance are the two main pathological phenotypes of obesity, which is also associated with a low-grade systemic and chronic inflammatory condition7. Obesity can increase the risk of a wide array of chronic diseases, such as dia-betes and cardiovascular disease. The rapid increase in obesity over the past few decades cannot be effectively explained by changes in human genetics2,8. Instead, a high-caloric diet and sedentary lifestyle seem to be among the primary driving forces; however, the pathological molecular processes that link a poor diet to obesity are still poorly defined9. Furthermore, the key mediators that are essential checkpoints for the development of obesity and so could potentially be targeted for prevention and therapy are also largely unknown. A paradigm shift in our view of the structure and function of the human body is needed to effectively manage the ongoing epidemic of obesity.In recent years, there has been a growing appreciation for the fact that, as humans, we are in fact supraorganisms composed of both human and microbial cells10, and as such we carry two sets of genes, those encoded inour own genome and those encoded in ourmicrobiota (FIG. 1). The total complementof the former is ~23,000 genes11, whereasthe latter, called the microbiome, comprises~3 million genes12,13. Thus, as supraorgan-isms, we genetically inherit only ~1% of ourgenes from our parents, and the remaining~99% is mainly acquired from the immedi-ate environment when we are born, and inparticular from our mother’s birth canal andbreast milk14–23. Importantly, all the genes inour body, whether human or microbiomeencoded, have the potential to have an impacton our health24,25.The gut is the most densely colonizedmicrobial community in the human bodyand is also one of the most diverse26,27. Thegut functions as a chemostat, a continuousculture system for microorganisms (mostlybacteria) in which fresh nutrients enter thesystem and cultured microorganisms leaveat a relatively constant rate28. Approximately1.5 kg of bacteria are resident in our gut25,and 50% of our faecal matter biomass isbacterial cells. To maintain such a highpopulation density, these bacteria need alot of nutrients, which can come from foodsources such as dietary fibres (which areotherwise indigestible to humans)29,30, mucinand cells sloughed from the gut29,31, as well asdrugs and other xenobiotic compounds thatenter the gut32,33. Host digestive physiology,including the pH of the gut and the pres-ence of bile acids34,35, and components of theinnate immune response, such as defensinsand immunoglobulin A, impose a selectivepressure to determine the membership ofthe gut microbiota — that is, which strainscan colonize the gut — from early life36 .However, the population level that a residentstrain can reach and maintain is a result ofthe equilibrium between the ability of thatstrain to take advantage of the availablenutrients for reproduction and its ability towithstand the forces removing it from thegut37. Diet has been shown to be the majorforce in shaping the composition of the gutmicrobiota38–40.Metabolites produced by gut bacteriacan enter the bloodstream by absorption,enterohepatic circulation or impaired gutbarrier function41. Indeed, up to one-thirdof the small molecules in human bloodcan be derived from gut bacteria42,43. Somemicrobiota-derived metabolites can have apositive impact on the host, including thosewith anti-inflammatory activity44, antioxi-dant activity45 and pain relief activity46, aswell as those acting as vitamins47 or energysources48 and those that regulate gut barrierfunction49. For example, butyrate, whichis produced by bacterial fermentation ofdietary fibres, can serve as an energy sourcefor colonocytes and can increase satiety50,51.This compound is also effective in alleviat-ing inflammation, reducing carcinogenesis,mitigating oxidative stress and improvinggut barrier function49,52. By contrast, othermicrobiota-derived metabolites are toxicto their host, including cytotoxins53, geno-toxins54 and immunotoxins55. For example,lipopolysaccharide (LPS), an endotoxinreleased by Gram-negative bacteria, canprovoke an inflammatory response and thusaggravate inflammation-related chronicconditions such as adiposity and insulinresistance52,55,56.As most of the incidence of obesity isattributed to diet, recent efforts to combatobesity and related metabolic diseases havefocused on whether the gut microbiota hasa role as a mediator that can predisposethe host to diet-induced obesity and, if so,O P I N I O NThe gut microbiota and obesity:from correlation to causalityLiping ZhaoAbstract | The gut microbiota has been linked with chronic diseases such as obesityin humans. However, the demonstration of causality between constituents of themicrobiota and specific diseases remains an important challenge in the field. In thisOpinion article, using Koch’s postulates as a conceptual framework, I explore thechain of causation from alterations in the gut microbiota, particularly of the endo-toxin-producing members, to the development of obesity in both rodents andhumans. I then propose a strategy for identifying the causative agents of obesity inthe human microbiota through a combination of microbiome-wide associationstudies, mechanistic analysis of host responses and the reproduction of diseasesin gnotobiotic animals.PERSPECTIVES NATURE REVIEWS |MICROBIOLOGY VOLUME 11 | SEPTEMBER 2013 |639how we can identify the key obesity-related microorganisms in the gut. Since their estab-lishment more than 100 years ago, Koch’s postulates have been modified for the identification of causative agents not only for infectious diseases but also for non-infectious diseases57. In this Opinion article, using Koch’s postulates as the conceptual framework (BOX 2), I synthesize the evidence that demonstrates a causative role for the gut microbiota, particularly the endotoxin-producing members, in the development of obesity in both rodent models and humans.I then propose a top-down strategy25 for identifying further members of the micro-biota with a causative role in human obesity and related metabolic diseases.The whole microbiota as a ‘pathogen’If the whole gut microbiota has a causative role — that is, functions as a pathogen-like entity (BOX 2) — in the onset and progression of obesity and its sequelae, experimental manipulation of the microbiota (for example, removing or adding it back to animal hosts, or transferring it between lean and obese individuals) should change host obesity-related phenotypes, in particular adiposity and insulin resistance57. Conventionalization of germ-free mice. Carrying out such microbiota manipulation studies in humans is difficult, if not impos-sible, for both technical and ethical reasons. However, it has been possible to develop and maintain germ-free mouse lines, from whichall microorganisms have been removed58–61.The gut microbiota from conventional micecan then be transplanted into the germ-freemice (a process known as conventionaliza-tion) to assess how the recipients respondand in particular whether there are changesin obesity-related phenotypes, such aslipometabolism and inflammation.Using such an approach, the seminalpaper that indicated a putative causativerole for the gut microbiota in obesity39found that conventionalization of previouslylean and insulin-sensitive germ-free miceincreased their adiposity by 60% whilealso increasing their insulin resistance,despite the mice having a reduced foodintake. It was later shown that conventionali-zation of germ-free mice with the microbiotafrom obese mice led to substantially higheradiposity than conventionalization with themicrobiota from lean mice62,63. Althoughthese transplantation studies did not reportfully developed obesity in the recipientmice, they suggest that the gut microbiotahas the capacity to induce fat accumulationin the host.Another approach used to test the roleof the gut microbiota in the development ofobesity has been to investigate how germ-free animals respond to a high-caloric diet.The first study to use such an approachreported that germ-free mice are resistantto obesity induced by a high-fat, high-sugar ‘western’ diet, suggesting that the gutmicrobiota has a central role in the devel-opment of obesity in mice64. Indeed, evenafter 8 weeks on this diet, germ-free miceremained almost as lean as the control micefed on normal chow65,66. However, anotherreport showed that germ-free mice fed adifferent high-fat diet developed obesityafter 8 weeks, whereas mice fed the westerndiet did not67. In another recent study witha similar non-western high-fat diet, germ-free animals significantly increased theirbody weight in the first 8 weeks but thenstarted to lose weight, and after a further8 weeks their body weight was no differ-ent from the controls fed on normal chow,suggesting that if germ-free mice are kepton this high-fat diet for long enough, theyeventually became lean, despite a significantweight gain in the first few weeks56. Takentogether, these studies demonstrate that thewhole gut microbiota is an essential com-ponent in the development of diet-inducedobesity in mice, highlighting a potentialcausative role for the gut microbiota inhuman obesity.Creating pseudo-germ-free mice using anti-biotics. In many studies, pseudo-germ-freeanimals are created by removing most ofthe gut microbiota through treatment withcocktails of broad-spectrum antibiotics, suchas combinations containing cefadroxil, oxy-tetracycline and erythromycin68; neomycinsulphate and streptomycin69; ampicillin andneomycin70,71; and vancomycin, neomycinsulphate, metronidazole and ampicillin72–74.The ampicillin–neomycin cocktail eliminates~90% of the total gut bacteria71. Althoughindividual antibiotics can selectively sup-press particular bacterial populations, thecocktail containing vancomycin, neomycinsulphate, metronidazole and ampicillin cannon-preferentially deplete all bacteria thatare detectable with microbiological culturingtechniques72.Pseudo-germ-free animals provide anadditional approach to investigate the causa-tive role of the whole gut microbiota in thedevelopment of obesity70,71. The ampicillin–neomycin cocktail prevented the develop-ment of obesity in mice fed on a high-fatdiet, indicating that the gut microbiota isessential for this process70. This report ech-oes the previous finding that germ-free miceare resistant to obesity induced by a high-caloric diet64. Intriguingly, both leptin-defi-cient (ob/ob) mice and Toll-like receptor 5(TLR5)-knockout mice developed obesityand insulin resistance induced by hyperpha-gia (intake of excessive food)49,50. However,removal of most of the gut microbiota in P E R S P E C T I V E S640 | SEPTEMBER 2013 | VOLUME 11 /reviews/micro| MicrobiologyHealthTransitionDiseasethese mice using an ampicillin–neomycin cocktail alleviated inflammation, reduced food intake and prevented obesity and insu-lin resistance 70,71. These surprising findings show that the gut microbiota might even have an essential role in genetically induced hyperphagia and metabolic syndrome in mice. This suggests that although the gut microbiota is downstream of a high calorie intake or a genetic mutation, these organ-isms can still serve as an essential ‘check-point’ along the pathological pathway to obesity.Interestingly, a recent study found that subtherapeutic antibiotic therapy which altered the gut microbiota in young mice led to increased adiposity, which might explain the growth-promoting effects of the anti-biotics used as feed additives in agriculture, and also adds another piece of evidence that the gut microbiota has a causal effect in obesity 75.Evidence from human studies. Support for a causative role for the gut microbiota in the development of metabolic syndrome in humans was provided by a recent gut micro-biota transplantation trial 76. Using volunteers who received their own faecal microbiota as controls, the study showed that obese vol-unteers who receive a microbiota from lean donors have significantly improved insulin sensitivity in the serum (although not in the liver) over a 6-week period. This is the first time that the gut microbiota has been shown to have a causative role in the development of insulin resistance in humans.All these experimental manipulations of the gut microbiota have, in some way, followed the essence of Koch’s postulates in showing that the whole gut microbiota can work as a pathogen-like entity.Obesity-associated compositional patterns The question has now become whether we can identify specific members of the gut microbiota that are more relevant than others to the causative role of that microbiota in human obesity. If so, these members of the gut microbiota might serve as new targets for obesity control.Phylum- and class-level compositionalpatterns and obesity. Gordon and colleagues proposed the first obesity-associated compo-sitional pattern of the gut microbiota in their early seminal studies. They observed that the gut microbiotas of obese humans and obese (ob/ob ) mice had a significantly greater ratio of members of the phylum Firmicutes to members of the phylum Bacteroidetes (theF/B ratio) than their lean counterparts 63,77–80. The microbiota from obese individuals also had a lower bacterial diversity than that from lean individuals 62,79. Furthermore, when obese people lost weight using either a low-fat or a low-carbohydrate, calorie-restricted diet, the F/B ratio decreased in association with the percentage reduction in body weight (not caloric intake)78.This phylum-wide compositional pat-tern has also been reported in overweight pregnant women, in infants who became overweight later in childhood, in rats fed a high-fat diet, in genetically obese (fa /fa ) rats and following both diet- and bariatric surgery-induced weight loss 81–85. However, other studies in humans and rodents have reported no difference in the F/B ratio in obese versus lean individuals, no effect of weight loss on the F/B ratio, or even a reverse F/B ratio in obese individuals 38,39,86–91. The reason behind these contradictory obser-vations concerning the F/B ratio and obesity is unclear at present 92.Instead of the whole Firmicutes phylum being associated with obesity, the pres-ence of species from a predominant class within this phylum, Mollicutes (now called Erysipelotrichia), was substantially increased in western diet-fed obese mice, together with a concomitant reduction in other bacterial groups, including organisms from the phylum Bacteroidetes 62. This is the first indication that a diet-induced change in the gut microbiotamight not happen uniformly for each class-level taxon in the same phylum. We might need to go into deeper taxon levels to iden-tify changes in the gut microbiota that are associated with obesity.Species-level changes are more relevant to obesity. Within the class Mollicutes (Erysipelotrichia), the most predominant family in the human gut microbiota is Erysipelotrichaceae; four groups of closely related species-level phylotypes in this family were shown to be differentially responsive to changes in diet and metabolic phenotypes 38. The M1 group was predominant in healthy animals but reduced by one order of magni-tude in insulin-resistant mice, whether the insulin resistance was induced by genetic mutation or a high-fat diet. Perhaps more interestingly, the response to a high-fat diet was not uniform in this family. The M3 group dominated in mice fed on normal chow, whereas the M2 and M4 groups domi-nated in mice fed on a high-fat diet. Thus, closely related species-level phylotypes can respond to dietary changes in different ways, making it important to be careful when con-sidering patterns at higher-order taxonomic levels 38.Using longitudinal study designs to focus on species-level changes in the gut microbiota might also help us to identify members asso-ciated with obesity. The blooming of species from the class Mollicutes (Erysipelotrichia) inFigure 1 | Human health is influenced by interactions among the gut microbiota, the host and the environment. Humans are supraorganisms consisting of both human cells and microbial cells, particularly the gut microbiota. The gut microbiota interacts with host genetics and the environment (mainly diet) to influence the health of the human host. On the one hand, the gut microbiota releases toxins, such as lipopolysaccharides, and beneficial metabolites, such as vitamins and short-chain fatty acids, to damage or nourish humans, respectively. On the other hand, human genetics also imposes selective pressures on the gut microbiota through innate immunity or nutrient availability. The diet and particular drugs have a greater potential to shape the structure and function of the gut microbiota than host genetics, thus influencing the health state of the supraorganism.P E R S P E C T I V E SNATURE REVIEWS | MICROBIOLOGYVOLUME 11 | SEPTEMBER 2013 | 641diet-induced obese mice has been proposed to increase the energy harvest for the host, as demonstrated by the enrichment of genes involved in polysaccharide utilization inthe genome of a human-derived microbiota member in this class62. However, in a study on the structural resilience of the gut microbiota to high-fat feeding, a member of this class became predominant only after the mice had become obese, indicating that the blooming of some members in this class might be a consequence, rather than a cause, of obesity in the mice studies38.Several recent studies identified some key species-level phylotypes that are associated with obesity phenotypes in rodents39,71,93,94. For example, in one study, protective bacteria such as Bifidobacterium spp. were eliminated, whereas a species-level phylotype in the sul-phate-reducing family Desulfovibrionaceae was significantly enriched by 6 months of high-fat feeding38. Accumulating evidence indicates that LPS produced by Gram-negative opportunistic pathogens has an important role in the onset and progression of obesity in both rodents and humans, so below I focus on the potentially causative role of endotoxin producers in obesity.LPS-producing bacteria and obesityLPS is the major component of the outer membrane of Gram-negative bacteria and is an endotoxin that causes inflammation after entering the circulation95. The lipid A portion of LPS contains the endotoxin activity, but can have different levels of pro-inflammatory activity owing to variations in the detailed lipid A structure; LPS frommembers of the families Enterobacteriaceaeand Desulfovibrionaceae, in the phylumProteobacteria, exhibits an endotoxin activ-ity that is 1,000-fold that of LPS from thefamily Bacteroideaceae, in the phylumBacteroidetes (members of this phylum are themost numerous LPS producers in the gut)96.Obesity induced by purified LPS in mice.The aetiological role of gut-bacterial LPSin obesity was first well-characterized inmice55,70. Mice that were obese owing to ahigh-fat diet exhibited 2–3 times higherlevels of plasma LPS than non-obese mice(a threshold that is 10–50 times lower thanlevels observed during septicaemia or infec-tions) and also displayed low-grade systemicinflammation. Furthermore, injection ofEscherichia coli LPS subcutaneously for4 weeks into wild-type mice fed on normalchow led to the development of inflamma-tion, obesity, and fasted glycaemia and insu-linaemia55. Importantly, in CD14-knockoutmice, in which LPS cannot be recognized bythe innate immune system and thus cannotinduce inflammation, there was a delayed oreven complete lack of development of mostfeatures of metabolic diseases induced bya high-fat diet or LPS infusion55. Changesin the gut microbiota owing to antibiotictreatment reduced the LPS concentrationin both the caecal content and plasma,and also led to decreased inflammation,improved glucose intolerance and reducedobesity70. Thus, the low levels of LPS thatare derived from the gut bacteria have beenshown to cause obesity and insulin resist-ance in mice via an inflammation-dependentpathway, a phenomenon termed metabolicendotoxaemia55.Association of LPS-producing bacteriawith obesity. Families in the phylumProteobacteria (members of which arecommonly found in the human gut micro-biota96), such as Enterobacteriaceae andDesulfovibrionaceae, contain many patho-gens that can produce LPS as an endotoxin96.These LPS-producing bacteria are enrichedin obese humans and rodents. For example,Sprague Dawley rats with diet-inducedobesity exhibited higher concentrationsof plasma LPS and higher levels of gutEnterobacteriaceae members than rats thatremained lean on the same diet97. In obeseadolescent humans on an energy-restricteddiet (30–40%) and a physical exercise pro-gramme (with an energy expenditure of3,762–11,286 kJ per week) for 3 months,faecal Enterobacteriaceae members weresignificantly decreased in those individualswho showed remarkable weight loss(4–7 kg)98.In another study, Desulfovibrionaceaespecies were enriched in mice with highfat diet-induced obesity and insulin resist-ance compared with levels in lean mice fedon normal chow38. A cohort of 123 obesehuman volunteers (with a baseline bodymass index of ≥30 kg per m2) was placedon an intervention diet based on wholegrains, traditional Chinese medicinal foodsand prebiotics (the WTP diet) for 9 weeks.Improvement was observed in the levels ofinflammation, obesity and insulin resist-ance, and was associated with reducedlevels of proteobacteria, particularly thosefrom the families Enterobacteriaceae andDesulfovibrionaceae, in the gut (S. Xiao,N. Fei, X. Pang, L. Wang, B. Zhang, M. Zhang,X. Zhang, C. Zhang, M. Li, L. Sun, Z. Xue,J. Wang, J. Feng, F. Y an, N. Zhao, J. Liu,W. Long and L.Z., unpublished observations).It was recently reported that live Gram-negative bacteria can translocate from thegut into adipose tissue of high fat diet-fedmice, a phenomenon termed metabolicbacteraemia99. In a retrospective analysis ofblood samples from 3,280 human partici-pants, it was found that both controls andparticipants who developed diabetes shareda core blood microbiota that was mostlycomposed of proteobacteria (85–90%), butthe baseline 16S rRNA gene concentrationin the blood was higher in study participantswho developed diabetes after 9 years than inthose who did not100.P E R S P E C T I V E S642 | SEPTEMBER 2013 | VOLUME 11 /reviews/microTogether, these association studies indi-cate that LPS producers may be directly involved in inflammation-dependent adi-posity and insulin resistance in both rodents and humans.Host response to LPS-producing bacteria with obesity. After LPS in the gut enters the circulation, it is recognized and bound by LPS-binding protein (LBP), an acute-phase protein synthesized in the liver101,102. LBP then delivers LPS to CD14 and TLR4, which triggers the expression and productionof pro-inflammatory cytokines102,103. Pro-inflammatory cytokines, including tumour necrosis factor (TNF), interleukin-1(IL-1) and IL-6, induce serine phosphorylation of insulin receptor substrate 1 (IRS1) in muscle and adipose cells, and subsequently block insulin signalling in the peripheral tissues and induce insulin resistance104. Serum LBP and pro-inflammatory cytokines therefore link the immune response of the host to bloodstream LPS that is produced by bac-teria in the gut105. Epidemiological studies showed that obese individuals had higher plasma concentration of LPS, LBP and pro-inflammatory cytokines than lean individu-als105–108. Furthermore, in clinical studies, weight loss and improvement of insulin resistance were accompanied by a drop in the levels of serum LBP and inflammatory proteins56 (S. Xiao, N. Fei, X. Pang, L. Wang, B. Zhang, M. Zhang, X. Zhang, C. Zhang, M. Li, L. Sun, Z. Xue, J. Wang, J. Feng, F. Y an, N. Zhao, J. Liu, W. Long and L.Z., unpublished observations).In addition to low-grade inflammation, in which LPS might have a direct role, obese ani-mals also have an increased endocanna b inoid (eCB) level in the plasma and adipose tissues (that is, an increased eCB system tone), which is affected by the gut microbiota. The intesti-nal eCB system tone can in turn regulate gut permeability and plasma LPS levels, and LPS might control adipose tissue metabolism by blocking cannabinoid-driven adipogenesis109. LPS may thus have a pleiotropic role in regulating the development of obesity. Reproducing obesity with Enterobacter cloacae. If endotoxin producers have the potential to make a causative contribution to obesity development in humans, they should be isolated from the gut microbiota of obese human subjects and tested in an experimen-tal host to assess whether they do have the capacity to induce obesity. This reproduction of disease phenotypes in experimental hosts with pure isolates is in line with the evidence for causality required by Koch’s postulates.Recently, Enterobacter cloacae str. B29(referred to below as B29), which was iso-lated from the gut of an obese human, wasshown to cause obesity when introducedinto high fat diet-fed germ-free mice56.Enterobacter spp.-related bacteria constituted~35% of the gut microbiota of this individualbefore dietary intervention, but becameundetectable after the volunteer lost 51.4 kgof his 174.8 kg initial weight. In contrastto germ-free mice, which were essentiallyresistant to high fat diet-induced obesityand insulin resistance64, the B29-mono-associated gnotobiotic mice on a high-fatdiet became as obese and as insulin resistantas conventional mice fed with the samediet for the same time period56. B29-mono-associated mice on normal chow remainedlean, indicating that the high-fat diet actedas a cofactor with B29 in inducing obesity.In addition, the B29-mono-associated obesemice also exhibited a higher circulatingantigen load as reflected by serum LBP, andincreased inflammation in the circulation,liver and adipose tissues56. There was noincreased expression of inflammatory genesin the gut, indicating that the observedovergrowth of B29 might not be stimulatedby nitrate being released from the inflam-matory gut tissues and acting as an electronacceptor110. Gut barrier function might notbe affected either, as the expression levelsof genes encoding tight junction proteinswere not reduced in mice with B29-inducedobesity. The requirement for a high-fat dietin order for obesity to develop in B29-mono-associated mice might be due to the fact thatthese mice have an increased level of chylo-microns, which are used to absorb fat fromthe gut but have also been shown to takeLPS into the host111. Importantly, mono-association of a Bifidobacterium sp. straindid not overcome the resistance of germ-freemice to high fat diet-induced obesity, indi-cating that this obesity-inducing capacity isspecific to B29 (REF. 56).Notably, the B29-mono-associated obesemice also showed distorted expression offasting-induced adipose factor (Fiaf; alsoknown as Angptl4)56. When expressed inadipose tissues, liver and the intestine,FIAF can reduce the storage of fatty acidsin adipocytes by inhibiting the activityof a key enzyme called lipoprotein lipase(LPL). In addition to inhibiting fat stor-age, FIAF might also promote fat oxida-tion64,112. Previous work showed that Fiaf isconstitutively expressed in germ-free mice.Conventionalization of germ-free mice witha normal gut microbiota led to an increasein body fat in association with a decreasein Fiaf expression in the ileum, and a 122%increase in LPL activity in epididymal adi-pose tissue112. Furthermore, Fiaf-knockoutgerm-free mice were no longer resistant towestern diet-induced obesity64. Moreover,B29-mono-associated obese mice showedsignificantly reduced expression of Fiaf inthe ileum, whereas expression of the genesfor lipid synthesis in the liver, Acc1 (alsoknown as Acaca) and Fasn, was substantiallypromoted, as was also seen in germ-freemice that were conventionalized with thegut microbiota56,64.This is the first experimental demon-stration of a causative role of a specific gutbacterium in human obesity within the refer-ence framework of Koch’s postulates (BOX 2).In my opinion, the required combinationof high-fat diet and E. cloacae str. B29 forthe develop m ent of obesity might be com-parable to a latent infection, in which hostswho carry the pathogen might not developthe disease until the right environmentalconditions arise.Perspectives and future directionsChain of causation. Integration of the cur-rently available evidence from both humansand rodents supports the hypothesis thatlow-grade, systemic and chronic inflamma-tion induced by the gut microbiota can initi-ate and aggravate metabolic diseases suchas obesity and diabetes in humans. TakingE. cloacae str. B29 as an example, when thisendotoxin producer thrives in the gut ofan individual on a high-fat diet, it mightlead to an increased endotoxin load in thebloodstream, an increase in inflammatorycytokines and, eventually, the developmentof insulin resistance and excessive fat accu-mulation via disrupted regulation of hostlipometabolism56.However, many more questions remainto be answered, such as whether endotoxinproduction is the only ‘virulence factor’needed to induce obesity; whether the bac-teria produce a molecule (or molecules) todirectly regulate Fiaf or other host genes;how many other endotoxin-producingbacteria can also thrive in the gut of obesehumans and contribute to the disease;whether a Gram-positive opportunisticpathogen overgrowing in the gut of a patientwith obesity would also contribute to thedisease and, if so, how; and whether we canidentify key functional species that mighthave anti-obesity effects. In this last regard,short-chain fatty acid-producing bacteriamight be good candidates, as they have beenshown to have a role in regulating satiety,alleviating inflammation and protectingP E R S P E C T I V E SNATURE REVIEWS |MICROBIOLOGY VOLUME 11 | SEPTEMBER 2013 |643。

Gut Microbiota and Inflammatory Bowel Diseases Inflammatory bowel disease (IBD) is a chronic condition that affects millions of people worldwide. It is characterized by inflammation of the digestive tract, which can lead to a range of symptoms such as abdominal pain, diarrhea, and weight loss. While the exact cause of IBD is not yet fully understood, research has suggested that the gut microbiota plays a crucial role in the development and progression of the disease.The gut microbiota is a complex ecosystem of microorganisms that reside in the digestive tract. These microorganisms play a vital role in maintaining the health of the gut and the immune system. However, when the balance of the gut microbiota is disrupted, it can lead to chronic inflammation and the development of IBD.One of the key factors that influence the gut microbiota is diet. A diet high in processed foods and low in fiber has been shown to have a negative impact on the gut microbiota, leading to an increase in harmful bacteria and a decrease in beneficial bacteria. This imbalance can trigger inflammation in the gut and contribute to the development of IBD.Another factor that can influence the gut microbiota is the use of antibiotics. Antibiotics are designed to kill bacteria, but they can also disrupt the balance of the gut microbiota, leading to an increase in harmful bacteria and a decrease in beneficial bacteria. This imbalance can contribute to the development of IBD, as well as other conditions such as obesity and type 2 diabetes.While the gut microbiota plays a crucial role in the development and progression of IBD, it is important to note that it is not the only factor involved. Genetics, environmental factors, and lifestyle factors such as smoking and stress can all contribute to the development of IBD.Despite the complexity of IBD, there are steps that individuals can take to support the health of their gut microbiota and reduce their risk of developing the disease. Eating a diet rich in fiber and whole foods, avoiding the unnecessary use of antibiotics, and managing stress levels are all important strategies for maintaining a healthy gut microbiota.In conclusion, the gut microbiota plays a crucial role in the development and progression of inflammatory bowel disease. While the exact cause of IBD is not yet fully understood, research has suggested that a disruption in the balance of the gut microbiota can contribute to the development of the disease. By taking steps to support the health of the gut microbiota, individuals can reduce their risk of developing IBD and improve their overall health and well-being.。

Gut Microbiota and Gastrointestinal Cancers Gut microbiota, the microorganisms that reside in our digestive tract, have been the subject of extensive research over the past few decades. The gut microbiota plays a crucial role in maintaining our overall health by aiding in digestion, regulating our immune system, and producing essential vitamins and nutrients. However, recent studies have shown that an imbalance in gut microbiota, known as dysbiosis, can lead to various health issues, including gastrointestinal cancers.Gastrointestinal cancers are a group of cancers that affect the digestive system, including the esophagus, stomach, liver, pancreas, colon, and rectum. These cancers are the leading cause of cancer-related deaths worldwide, with approximately 3.2 million cases and 1.7 million deaths reported each year. While there are various risk factors associated with gastrointestinal cancers, such as age, family history, and lifestyle choices, recent research has linked dysbiosis to an increased risk of developing these cancers.The gut microbiota plays a crucial role in maintaining the health of the gastrointestinal tract. It helps to break down food, produce essential nutrients, and regulate the immune system. However, when the balance of the gut microbiota is disrupted, it can lead to inflammation, which can damage the gastrointestinal lining and increase the risk of cancer. Dysbiosis has been linked to various gastrointestinal cancers, including colon cancer, gastric cancer, and pancreatic cancer.Several studies have shown that the composition of the gut microbiota differs between healthy individuals and those with gastrointestinal cancers. For example, individuals with colon cancer have been found to have a lower abundance of beneficial bacteria, such as Bifidobacterium and Lactobacillus, and a higher abundance of harmful bacteria, such as Fusobacterium and Escherichia coli, in their gut microbiota. Similarly, individuals with gastric cancer have been found to have a higher abundance of Helicobacter pylori, a bacteria known to cause inflammation and increase the risk of gastric cancer.While the link between dysbiosis and gastrointestinal cancers is still being studied, researchers have identified several potential mechanisms that may explain this association.For example, dysbiosis can lead to chronic inflammation, which can damage the gastrointestinal lining and increase the risk of cancer. Dysbiosis can also alter the production of short-chain fatty acids, which are essential for maintaining the health of the gastrointestinal tract and regulating the immune system.The potential link between gut microbiota and gastrointestinal cancers has significant implications for the prevention and treatment of these cancers. Researchers are exploring various strategies to restore the balance of the gut microbiota, such as probiotics, prebiotics, and fecal microbiota transplantation. These approaches aim to increase the abundance of beneficial bacteria and decrease the abundance of harmful bacteria in the gut microbiota, potentially reducing the risk of gastrointestinal cancers.In conclusion, the gut microbiota plays a crucial role in maintaining our overall health, including the health of the gastrointestinal tract. Dysbiosis, an imbalance in gut microbiota, has been linked to an increased risk of developing gastrointestinal cancers. While the link between gut microbiota and gastrointestinal cancers is still being studied, researchers are exploring various strategies to restore the balance of the gut microbiota, potentially reducing the risk of these cancers. The potential implications of this research are significant, and further research is needed to fully understand the link between gut microbiota and gastrointestinal cancers.。

DIET-RELATED CHANGES IN GUT MICROBIOTA INFLUENCE GASTROINTESTINAL MOTILITYChange in dietary habits can affect gut microbiota and development of disease.This diagram describes the interaction between diet, gut microbiota and gastrointestinal motility.This project investigates how diet-induced changes in the gut microbiome affect gastrointestinal (GI) motility with a goal of developing gut microbiota-targeted prebiotic therapies. To do this, the team is examining how environmental factors, including diet, can modify the relationship between GI motility and the gut microbiota.It is known that diet may impact motility directly, via changes in the bulk flow of material through the gut, or indirectly, through an impact on the microbiota. Dietary polysaccharides are a major fuel for the distal gut microbial community; thus, gut microbiomes have a large repertoire of carbohydrate-degrading genes. Dietary fermentable polysaccharides can alter microbiota composition, in part, because community members differ in their ability to metabolize them.Additionally, different bacteria produce different fermentation end products when metabolizing a specific carbohydrate. Changes in production of short-chain fatty acids, such as butyrate, can influence diverse aspects of host physiology, including motility.A part of this project is examining the relationship between diet, gut microbiota and GI motility to better understand irritable bowel syndrome (IBS). Patients with IBS oftenreport food sensitivities and avoid several food groups, which seem to worsen their symptoms. The lab seeks to develop better dietary therapies for management of GI motility disorders such as IBS.。

肠道微生物的英语单词The Complex World of Gut Microbiota.The gut microbiota, often referred to as the "microbiome" or the "intestinal flora," refers to the vast community of microorganisms that reside within the human gastrointestinal tract. This intricate ecosystem plays a crucial role in maintaining our overall health and well-being. The gut microbiota is composed of a diverse range of bacteria, fungi, viruses, and other microorganisms that coexist in a delicate balance.The human body is estimated to contain trillions of microbial cells, outnumbering the human cells by a ratio of 10 to 1. The majority of these microbial cells reside in the gastrointestinal tract, particularly in the colon. The gut microbiota performs various vital functions, including digesting food, synthesizing vitamins, and regulating the immune system.Functions of the Gut Microbiota.Digestion and Nutrition: The gut microbiota aids in the breakdown of dietary fiber and other complex carbohydrates, releasing short-chain fatty acids (SCFAs) such as acetate, propionate, and butyrate. These SCFAs serve as a source of energy for the host and have been linked to various health benefits, including improved insulin sensitivity and reduced inflammation.Immune System Regulation: The gut microbiota plays a crucial role in shaping and regulating the immune system. It stimulates the development of immune cells and helps maintain a balanced immune response, protecting against both infectious diseases and autoimmune conditions.Barrier Function: The gut microbiota contributes to maintaining the integrity of the gut barrier, which prevents harmful bacteria and toxins from leaking into the bloodstream. A healthy gut microbiota supports tight junctions between gut cells, ensuring a strong barrier against pathogens.Brain-Gut Axis: The gut microbiota also interacts with the brain through the gut-brain axis, influencing mood, cognition, and behavior. This axis involves a complex communication network between the gastrointestinal tract and the central nervous system, which is believed to play a role in conditions like depression, anxiety, and autism.Importance of Gut Microbiota Balance.Disruptions to the gut microbiota, known as "dysbiosis," can lead to various health issues. Changes in the composition of the microbiota can be triggered by various factors, including diet, antibiotics, stress, and chronic illnesses.Diet: The composition of the gut microbiota is significantly influenced by the diet. A diet rich in fiber and diverse in plant-based foods promotes the growth of beneficial bacteria, while a diet high in processed foods and low in fiber can lead to a decrease in microbial diversity and an increase in harmful bacteria.Antibiotics: The use of antibiotics can have a profound impact on the gut microbiota, killing off both harmful and beneficial bacteria. This can lead to a temporary imbalance in the microbiota, allowing opportunistic pathogens to proliferate.Stress: Chronic stress has been shown to alter the gut microbiota composition, leading to an increase in inflammatory markers and a decrease in beneficial bacteria.Chronic Illnesses: Conditions like inflammatory bowel disease (IBD), irritable bowel syndrome (IBS), and obesity have been linked to alterations in the gut microbiota. These changes can contribute to the development and progression of these diseases.Modulating the Gut Microbiota.Given the crucial role of the gut microbiota in maintaining health, there has been increasing interest in modulating its composition through various strategies.Probiotics: Probiotics are live microorganisms that, when administered in adequate amounts, confer a health benefit on the host. They are commonly found in yogurt, fermented foods, and dietary supplements. Probiotics can help restore balance to the gut microbiota, improving digestive health and immune function.Prebiotics: Prebiotics are dietary fibers that promote the growth and activity of beneficial bacteria in the gut. By providing food for the probiotic bacteria, prebiotics can help support a healthy gut microbiota.Dietary Changes: Incorporating a diet rich in fiber, fruits, vegetables, and whole grains can promote the growth of beneficial bacteria and maintain gut microbiota diversity.Conclusion.The gut microbiota plays a pivotal role in maintaining human health and well-being. Its intricate balance ofmicroorganisms is essential for digestion, immune system regulation, and overall physiological functions. Disruptions to this balance can lead to various health issues, emphasizing the importance of maintaining a healthy gut microbiota through diet, lifestyle choices, and probiotic supplementation. As research in this field continues to evolve, so does our understanding of the crucial role the gut microbiota plays in our lives.。

Gut Microbiota and Metabolic Syndrome Gut microbiota refers to the complex community of microorganisms that residein the human gastrointestinal tract. These microorganisms, including bacteria, viruses, fungi, and archaea, play a crucial role in maintaining human health. One area of research that has gained significant attention in recent years is the relationship between gut microbiota and metabolic syndrome. Metabolic syndrome is a cluster of conditions that occur together, increasing the risk of heart disease, stroke, and type 2 diabetes. These conditions include high blood pressure, high blood sugar levels, excess body fat around the waist, and abnormal cholesterol levels. The exact cause of metabolic syndrome is not fully understood, but researchers believe that both genetic and environmental factors contribute to its development. One perspective on the relationship between gut microbiota and metabolic syndrome is that alterations in the composition and function of the gut microbiota can contribute to the development of metabolic syndrome. Studies have shown that individuals with metabolic syndrome have a different gut microbiota composition compared to healthy individuals. These differences include lower microbial diversity and an overgrowth of certain bacteria, such as Firmicutes and Actinobacteria, and a decrease in beneficial bacteria, such as Bacteroidetes. These imbalances in gut microbiota have been associated with increased inflammation, insulin resistance, and dyslipidemia, all of which are key components of metabolic syndrome. Another perspective is that metabolic syndrome itself can influence the gut microbiota. For example, high-fat diets, which are often associated with metabolic syndrome, can alter the gut microbiota composition. These changes in gut microbiota can further exacerbate the metabolic abnormalities associated with metabolic syndrome. Additionally, metabolic syndrome-related conditions, such as obesity and type 2 diabetes, can also affect the gut microbiota. Obesity has been linked to a decrease in microbial diversity and an increase in the abundance of certain bacteria, such as Firmicutes. Similarly, individuals with type 2 diabetes have been found to have an altered gut microbiota composition, with a decrease in butyrate-producing bacteria. While the exact mechanisms underlying the relationship between gut microbiota and metabolic syndrome are still being explored, several hypotheses have been proposed. Onehypothesis suggests that gut microbiota can influence host metabolism by producing metabolites, such as short-chain fatty acids (SCFAs). SCFAs are produced by the fermentation of dietary fiber by gut bacteria and have been shown to have beneficial effects on energy metabolism, insulin sensitivity, and inflammation. Another hypothesis proposes that gut microbiota can modulate the gut barrier function and intestinal permeability, leading to the translocation of bacterial components into the bloodstream. This can trigger an immune response and promote inflammation, which is a key feature of metabolic syndrome. The implications of the relationship between gut microbiota and metabolic syndrome are significant. Understanding the role of gut microbiota in metabolic syndrome may lead to the development of novel therapeutic strategies. For example, interventions aimed at modulating the gut microbiota, such as probiotics or prebiotics, could potentially be used to prevent or treat metabolic syndrome. However, more research is needed to fully understand the complex interactions between gut microbiota and metabolic syndrome and to determine the effectiveness of such interventions. In conclusion, the relationship between gut microbiota and metabolic syndrome is a complex and evolving field of research. Alterations in gut microbiota composition and function have been observed in individuals with metabolic syndrome, and these changes may contribute to the development and progression of metabolic abnormalities. Conversely, metabolic syndrome-related conditions, such as obesity and type 2 diabetes, can also influence the gut microbiota. Further research is needed to elucidate the mechanisms underlying this relationship and to explore potential therapeutic interventions. Overall, the study of gut microbiota and metabolic syndrome holds promise for improving our understanding and management of this prevalent and serious health condition.。

关于开派对吃什么的英语对话作文Sure, here's a sample English dialogue essay about what to eat at a party:Paragraph 1:"Hey, we're planning a party this weekend. What should we serve?"Paragraph 2:"I was thinking finger foods would be great. They're easy to eat and don't require much setup."Paragraph 3:"Good idea! Mini pizzas, sliders, and chicken wings could be a hit. They're popular and cater to different tastes."Paragraph 4:"Definitely. And we can't forget about the dessert. Maybe some cupcakes or a chocolate fountain?"Paragraph 5:"A chocolate fountain sounds fancy! But let's not forget about those with dietary restrictions. Maybe some fruitplatters or gluten-free options?"Paragraph 6:"Absolutely, inclusivity is key. We should also consider vegetarian dishes like veggie skewers or a big salad bar."Paragraph 7:"Great point. And let's not forget drinks. A variety of sodas, juices, and maybe a signature cocktail?"Paragraph 8:"Perfect. I'll start making a list. This is going to be one delicious party!"This dialogue covers a variety of food options suitable for a party, ensuring to consider different dietary needs and preferences.。

这种节食有效果吗英语作文标题，Can This Diet Plan Really Work? An Analysis。

In recent years, there has been a surge in popularity of various diet plans promising rapid weight loss and improved health. Among these, one particular diet plan has gained significant attention, both online and offline. In this essay, we will delve into the effectiveness of this diet plan, examining its potential benefits and drawbacks based on the most downloaded reference materials available online.The diet plan in question revolves around the concept of intermittent fasting, a dietary approach that alternates between periods of eating and fasting. Proponents of this diet claim that it can lead to weight loss, improved metabolic health, and various other health benefits.One of the key features of this diet plan is its flexibility. There are several methods of intermittentfasting, including the 16/8 method, where individuals fast for 16 hours and eat within an 8-hour window, and the 5:2 method, which involves eating normally for five days a week and restricting calorie intake on the other two days. This flexibility makes it appealing to many individuals who may find traditional calorie-restricted diets difficult to sustain.Moreover, numerous studies have suggested that intermittent fasting can indeed lead to weight loss and improvements in various health markers. For example, a study published in the New England Journal of Medicine found that intermittent fasting resulted in significant reductions in body weight, body fat percentage, and insulin resistance in obese adults. These findings lend credibility to the claims made by proponents of this diet plan.However, it is essential to acknowledge the potential drawbacks and limitations of intermittent fasting. One concern is that it may lead to nutrient deficiencies if not followed properly. Since individuals are restricting their calorie intake during fasting periods, they may not consumean adequate amount of essential nutrients, vitamins, and minerals. This could potentially lead to nutritional imbalances and negatively impact overall health.Furthermore, intermittent fasting may not be suitable for everyone. Individuals with certain medical conditions, such as diabetes or eating disorders, may need to approach intermittent fasting with caution or avoid it altogether. Additionally, some people may find it challenging to adhere to the fasting schedule, especially during social occasions or when faced with stressors that trigger emotional eating.Another point to consider is the sustainability of intermittent fasting as a long-term dietary strategy. While it may yield rapid results in the short term, the sustainability of intermittent fasting over an extended period remains uncertain. Long-term adherence to any diet plan requires consistency and lifestyle changes, which may be challenging for some individuals.In conclusion, the effectiveness of the intermittent fasting diet plan depends on various factors, includingindividual preferences, medical history, and lifestyle factors. While it has shown promise in promoting weightloss and improving metabolic health, it is not without its limitations and potential drawbacks. As with any dietary approach, it is essential to consult with a healthcare professional before embarking on an intermittent fasting regimen to ensure that it is safe and suitable for your individual needs.This essay provides a comprehensive analysis of the effectiveness of the diet plan in question, drawing on the most downloaded reference materials available online. By considering both the potential benefits and drawbacks, readers can make informed decisions about whetherintermittent fasting is the right dietary approach for them.。

Gut Microbiota Dysbiosis and Disease Gut microbiota dysbiosis is a condition that occurs when there is an imbalance in the composition of the gut microbiome. The gut microbiome is a complex ecosystem of microorganisms that reside in the gastrointestinal tract and play a crucial role in maintaining the overall health of the human body. Dysbiosis of the gut microbiome has been linked to a wide range of diseases and health conditions, including obesity, diabetes, inflammatory bowel disease, and even mental health disorders. In this essay, I will explore the relationship between gut microbiota dysbiosis and disease from multiple perspectives.From a scientific perspective, the gut microbiome is a complex and dynamic ecosystem that is influenced by a wide range of factors, including diet, genetics, and environmental factors. Dysbiosis of the gut microbiome occurs when there is a disruption in the balance of the microbial community, leading to an overgrowth of harmful bacteria and a decrease in beneficial bacteria. This imbalance can lead to a wide range of health problems, including inflammation, immune dysfunction, and metabolic disorders.One of the most well-established links between gut microbiota dysbiosis and disease is with obesity and metabolic disorders. Studies have shown that obese individuals have a different composition of gut microbiota compared to lean individuals, with a higher ratio of Firmicutes to Bacteroidetes. This dysbiosis has been linked to increased inflammation, insulin resistance, and metabolic dysfunction, all of which contribute to the development of obesity and related diseases such as type 2 diabetes.Inflammatory bowel disease (IBD) is another condition that has been linked to gut microbiota dysbiosis. IBD is a chronic inflammatory disorder of the gastrointestinal tract that includes Crohn's disease and ulcerative colitis. Studies have shown that individuals with IBD have a different composition of gut microbiota compared to healthy individuals, with a decrease in beneficial bacteria such as Bifidobacterium and an increase in harmful bacteria such as Escherichia coli. This dysbiosis can lead to increased inflammation and immune dysfunction, contributing to the development and progression of IBD.Mental health is another area where gut microbiota dysbiosis has been implicated. The gut-brain axis is a bidirectional communication pathway between the gut and the brain, and emerging evidence suggests that the gut microbiome plays a crucial role in this communication. Dysbiosis of the gut microbiome has been linked to a wide range of mental health disorders, including depression, anxiety, and autism spectrum disorders. While the exact mechanisms underlying this relationship are not yet fully understood, it is thought that the gut microbiome may influence brain function and behavior through the production of neurotransmitters and other signaling molecules.From a public health perspective, gut microbiota dysbiosis represents a significant health challenge. The prevalence of diseases linked to dysbiosis, such as obesity, diabetes, and IBD, is increasing globally, and there is a growing need for effective interventions to prevent and treat these conditions. One approach that has gained increasing attention in recent years is the use of probiotics and prebiotics to modulate the gut microbiome and promote a healthy microbial community. While the evidence for the effectiveness of these interventions is still limited, there is growing interest in their potential to improve gut health and prevent disease.In conclusion, gut microbiota dysbiosis is a complex and multifaceted condition that has been linked to a wide range of diseases and health conditions. From a scientific perspective, there is a growing understanding of the mechanisms underlying this relationship, and emerging evidence suggests that interventions targeting the gut microbiome may hold promise for preventing and treating these conditions. From a public health perspective, there is a need for increased awareness of the importance of gut health and the potential impact of dysbiosis on overall health and well-being. As research in this area continues to evolve, it is likely that we will gain a deeper understanding of the role of the gut microbiome in health and disease, and new interventions will emerge to help promote a healthy gut microbiome and prevent the development of chronic diseases.。

Microbial Ecology of the Gut The microbial ecology of the gut is a fascinating and complex topic that has gained increasing attention in recent years. The gut microbiome, which consists of trillions of microorganisms living in our intestines, plays a crucial role in maintaining our overall health and well-being. These microbes help us digest food, produce essential nutrients, regulate our immune system, and even influence our mood and behavior. One of the key perspectives to consider when discussing the gut microbiome is its diversity. The gut is home to a wide variety of bacteria, viruses, fungi, and other microorganisms, each playing a unique role in maintaining our health. The diversity of the gut microbiome is influenced by factors such as diet, genetics, and environment. A healthy gut microbiome is characterized by a balanced and diverse community of microorganisms, while an imbalance, known as dysbiosis, can lead to various health problems. Another important perspective to consider is the dynamic nature of the gut microbiome. The composition of the gut microbiome can change rapidly in response to various factors, such as diet, antibiotics, and stress. These changes can have profound effects on our health, leading to conditions such as obesity, inflammatory bowel disease, and even mental health disorders. Understanding the dynamics of the gut microbiome is crucial for developing strategies to maintain a healthy microbial community. The interaction between the gut microbiome and the immune system is also a critical aspect of microbial ecology. The gut is home to a large portion of our immune system, which helps to protect us from harmful pathogens. The gut microbiome plays a key role in training and regulating the immune system, helping to distinguish between harmful and beneficial microorganisms. Disruptions in this delicate balance can lead to chronic inflammation and autoimmune diseases. In addition to its role in digestion and immune function, the gut microbiome also plays a crucial role in mental health. The gut-brain axis is a bidirectional communication system between the gut and the brain, involving the nervous system, immune system, and endocrine system. The gut microbiome produces neurotransmitters and other signaling molecules that can influence our mood, behavior, and cognitive function. Imbalances in the gut microbiome have been linked to conditions such as depression, anxiety, and autism. The study of the gut microbiome has importantimplications for personalized medicine and healthcare. By understanding the unique composition of an individual's gut microbiome, healthcare providers can tailor treatments and interventions to promote optimal health. For example, probiotics, prebiotics, and dietary changes can be used to modulate the gut microbiome and improve health outcomes. Advances in technology, such as metagenomics and metabolomics, have made it easier to study the gut microbiome and its role in health and disease. In conclusion, the microbial ecology of the gut is a complex and dynamic system that plays a crucial role in maintaining our overall health and well-being. By considering the perspectives of diversity, dynamics, immune interactions, mental health, and personalized medicine, we can gain a deeper understanding of the importance of the gut microbiome. Continued research in this field is essential for developing new therapies and interventions to promote a healthy gut microbiome and improve health outcomes for individuals.。

漫滴州演漏市慢寨学校Unit 2 The Olympic Games单元检测卷（时间50分钟；满分100分）I 语言知识及应用 (共两节，满分45分)第一节完形填空 (共20小题；每小题1.5分，满分30分)阅读下面短文，掌握其大意，然后从1～20各题所给的A、B、C和D项中，选出最佳选项，并在答题卡上将该项涂黑。

【贵州省遵义航天高级中学高三第四次模拟】完形填空（共20小题；每小题1.5分，满分30分）Billy, a hard – working student, is fourteen years old and in the ninth grade. He has a part –time job that 41 him up every morning at five o’clock, when most people are still 42 asleep. He is a newspaper boy.Each morning, Billy leaves the house at 5:15 to go to the 43 where the newspapers always are. The newspapers were 44 to the corner by truck at midnight. He always takes a wagon to 45 them.In the winter it is still dark 46 he gets up every day, but during the rest of the yearit is 47 . Billy must send the newspapers to the houses of people on his 48 in all kinds of weather. He tries to put each paper on the porch (门廊) where it will be 49 from wind and rain or snow. Sometimes his customers give him tips, 50 him very excited.Billy earns about $ 70 per month through hard 51 , and he is saving some of the money to go to 52 where he has always been longing to go. Besides that, he 53 the rest of the earnings on records and clothes. Once a month, he has to collect the 54 at night since many of the people work during the day. That is when he is 55 so that he is full of excitement. Luckily, he gets 56 supported by his family. Sometimes, when Billy is sick, his brother offers to deliverthe newspapers for him. Once, his father was too 57 to help him.Billy has seventy customers now, but he doesn’t feel 58 about the number.He dreams that he will get 59 customers as possible some day. 60 , he might win a prize for being an outstanding newspaper boy. He wants to win a trip to Europe, but he will be happy if he wins a new bicycle.41．A．wakes B．takes C．gets D．picks 42．A．sound B．falling C．fall D．soundly43．A．corner B．street C．room D．department44．A．given B．addressed C．handed D．delivered45．A．carry B．bring C．send D．load 46．A．at which B．while C．that D．when 47．A．short B．black C．light D．long 48．A．road B．way C．route D．path 49．A．protected B．stopped C．kept D．prevented50．A．making B．letting C．leading D．causing 51. A．attempt B．job C．workD．struggle52．A．abroad B．company C．collegeD．hospital53. A．costs B．spends C．pays D．uses 54．A．paper B．money C．newspapersD．records55．A．depressed B．energetic C．fulfilled D．moved56．A．very B．great C．greatly D．a lot of 57．A．likely B．reluctant C．tired D．willing 58．A．satisfying B．pleasant C．contented D．happy 59．A．many more B．as much C．as many D．much more60．A．If that B．If so C．Besides D．What’s more42. A 考查副词短语。

2021-2021学年第一学期高三英语(yīnɡ yǔ)晚练〔三〕试卷第二局部阅读理解〔一共两节，满分是40分〕第一节，阅读短文〔一共15小题；满分是30分〕AVisitors worry that London is an expensive city but there really are so many free things to do here. The following ideas should get you started.All of London's major museums are free, but most offer some special exhibitions for a fee. My favorite is the Museum of London where you can learn the history of London from Roman times to today. And I love the Geffrye Museum which shows English domestic interiors and helps bring to life what it was really like to live in London.I regularly hear people tell me the Queen Mary's Rose Gardens in Regent's Park is their favorite spot in London, and who am I to argue? I would also recommend St. James's Park as it offers one of the best views of Buckingham Palace. Hyde Park is enormous and Kensington Gardens nearby includes the ever popular Diana Memorial Playground and the Peter Pan Statue.No visit to London is complete without seeing this military tradition. The Queen's Guard in London changes in the Forecourt inside the gates of Buckingham Palace at 11.30am every day in the summer and every other day in the winter. Get there early and view the spectacle from outside the front gates.Trafalgar Square is one of Britain's greatest visitor attractions and was designed by John Nash in the 1820s and constructed in the 1830s. This iconic square has many sights to see including Nelson's Column and the National Gallery. It is both a tourist attraction and the main focus for politicaldemonstrations. Every December, Norway donates a marvelous Christmas tree, to thank Britain for liberation from the Nazis.21. Where can visitors find the Peter Pan Statue?A. in Regent's Park.B. in St. James's Park.C. in Hyde Park.D. in Kensington Gardens.22. Which of the following descriptions is True ?A. In the Geffrye Museum visitors can learn the history of London fromRoman times to today.B. The Queen Mary's Rose Gardens is in Buckingham Palace.C. There is the Queen's Guard change inside the gates of BuckinghamPalace at 11.30 am every day all year around.D. Trafalgar Square is both a tourist attraction and a place for political demonstrations.23. The writer wrote the passage to ________.A pare some free places in London.B . advertise some free places in London.C. recommend some free places in London.D. expose some free places in London.BMen who wear pink shirts to work earn more and are easier to get a higher position than those who prefer traditional shirt colors, such as white and blue, according to a recent survey. Researchers also found that men who wore pink were more likely to get praise from female co-workers and were more confident in the office.A classical pink shirt wearer earns £1,000 more a ye ar than those who choose other colors, researchers surveyed among 1,500 male office workers. Men who wear pink are also twice as likely to have the Master’s degree as those who prefer white shirts, with one in ten pink shirt wearers having a PHD.Stephanie Thiers-Ratcliffe, International Marketing Manager for Cotton USA, who took charge of the study, said, “You can tell a lot about someone by the color he wears. Pink is a color that more and more men have been embracing recently, and it is encouraging that they are not afraid to experiment with that bright color. They spend most of their days at work and their own confidence needs to remain smart. It is good for company standards, but that doesn’t mean that they have to wear boring clothes.〞 Pink shirt wearers on the other hand are more likely to have a low-carbon (低碳的) life for half of them prefer to choose public means of transportation to go to work.The report also found men who preferred green shirts were the most likely to be late for work, while white shirt fans were the most punctual (准时(zhǔn shí)的).24. According to the survey, pink shirt men ____.A. usually graduate from famous universities or collegesB. prefer to go to work by car with their co-workersC. earn more money than those in other colorsD. are better at pleasing their bosses in the office25. We can learn from the passage that ____.A. the color a man wears can influence his personalityB. the color a man wears can show a lot about himC. pink is the best of all the colors a man likesD. wearing pink can makea man become happy26. According to the passage, who is the least likely to be late for work?A. Jack who often wears pink shirts.B. Mike who often wears green shirts.C. Tom who often wears white shirts.D. Alan who often wears blue shirts.27. If you want to get a higher place in your company, you’d better wear ____.A. purpleB. pinkC. greenD. whiteCWelcome to your future life!You get up in the morning and look into the mirror. Your face is firm and young-looking. In 2035, medical technology is better than ever. Many people your age could live to be 150,so at 40, you’re not old at all. And your parents just had an anti-aging(抗衰老的) treatment. Now, all three of you look the same age !You say to your shirt , “Turn red.〞 It changes from blue to red. In 2035, “smart clothes〞 contain particles(粒子(lìzǐ)) much smaller than the cells in your body. The particles can be programmed to change clothes’color or pattern.You walk into the kitchen . You pick up the milk ,but a voice says , “ You shouldn't drink that!〞Your fridge has read the chip (芯片) that contains information about the milk , and it knows the milk is old . In 2035, every article of food in the grocery store has such a chip .It’s time to go to work . In 2035, cars drive themselves. Just tell your“smart car〞where to go. On the way , you can call a friend using your jacket sleeve . Such “smart technology〞 is all around you.So will all these things come true? “For new technology to succeed,〞says scientist Andrew Zolli , “it has to be so much better that it replaces what we have already.〞 The Internet is one example --- what will be the next?28.We can learn from the text that in the future__________.A.people will never get oldB. everyone will look the sameC. red will be the most popular colorD. clothes will be able to change their pattern29. What can be inferred from Paragraph 4?A. Milk will be harmful to health.B. More drinks will be available for sale.C. Milk in the grocery store will stay fresh much longer.D. Food in the grocery store will carry electronic information.30. Which of the following is mentioned in the text?A. Fridges will know what people need.B. Jacket sleeves can be used as a guide.C. Cars will be able to drive automatically.D. Nothing can replace the Internet.31.What is the text mainly about?A. Future technology in everyday life.B. Food and clothing in 2035.C. Medical treatments of the future.D. The reason for the success of new technology.DBEIJING - A research team led by Chinese scientists have discovered dietary modulation of gut microbiota〔膳食(shànshí)干预肠道菌群〕can relieve both genetic and simple obesity in children.The findings of the team, led by Zhao Liping with Shanghai Jiaotong University, Yin Aihua with the Guangdong province children's hospital, and Tang Huiru with Chinese Academy of Sciences, have been published on EBioMedicine, a renowned medical journal co-sponsored by Cell and The Lancet in July.The team identified bacterial genomes specifically for producing obesity-related metabolites〔代谢物〕, and said an improved gut microbiota can significantly help to treat genetic obesity such as Prader-Willi Syndrome (PWS).Beginning in childhood, PWS affected kids develop an insatiable appetite, leading to chronic overeating and obesity.The scientists used a diet therapy with beneficial gut bacteria on trial patients and found considerable diminished appetite, weight loss and improved health conditions on the patients.The paper concluded dysbiosis 〔失调〕of gut microbiota is highly related with both genetic and simple obesity in children, implicating dietary modulation of gut microbiota a potentially effective treatment method.32. Which of the following factors contributes to child obesity ?A. dietary modulation of gut microbiotaB. beneficial gutbacteriaC. an improved gut microbiotaD. dysbiosis of gut microbiota33. Which can replace the underlined word “diminished〞？A. unsatisfiedB. increasedC. decreasedD. good34. Where is the passage extracted?A. Medicine book B Science book C . Doctor’s instructions D News report35. Which might be the best title for the passage?A. Chinese scientists discover treatment to child obesity.B .The reasons for genetic obesity in children has been found.C. Obesity-related research has been done by Chinese scientists.D. An effective treatment to obesity has been found.第二节〔一共5小题；每一小(yī xiǎo)题2分，满分是10分〕根据短文内容,从短文后的选项里面选出能填入空白处的最正确选项。

Gut Microbiota and Food Allergies Oh, the gut! It's not just about butterflies and hunger pangs, it's a bustling metropolis of microbes that play a symphony with our health. And when it comes to food allergies, the gut microbiota might be holding the conductor's baton. It's a bit like a delicate dance, you see, with our gut bacteria influencing how our immune system reacts to different foods. Imagine this: a baby's born, its gut a blank canvas. As they grow, their gut becomes populated with trillions of bacteria – some good, some bad, and a whole lot of in-between. These bacteria aren't just freeloaders; they help digest food, produce vitamins, and even educate our immune system. It's like a microbial school, teaching our bodies who to befriend and who to fight. Now, in some kids, this education system goes a bit haywire, mistaking harmless food proteins as invaders. The immune system goes on high alert,launching an attack that manifests as an allergic reaction. Scientists are still piecing together the puzzle, but it seems the gut microbiota plays a crucial rolein this drama. Studies have shown differences in the gut bacterial composition of children with food allergies compared to those without. It's like having two different orchestras playing; one creates a harmonious melody of tolerance, the other a chaotic symphony of allergic reactions. But here's the exciting part –we might be able to influence the music! Research suggests that diet can shape the gut microbiota, potentially paving the way for allergy prevention and even treatment. Probiotics, prebiotics, and even dietary changes could help cultivate a more tolerant gut environment. It's like fine-tuning the orchestra, ensuring each instrument plays its part in creating a harmonious melody of health. Of course, the story's not that simple. Food allergies are complex, with genetics and environmental factors also playing a role. But understanding the gut microbiota's influence is like discovering a new musical score – it opens doors to exciting possibilities. So, next time you think about your gut, remember it's not just about digestion, it's about a complex ecosystem that could hold the key to unlocking the mysteries of food allergies. It's a story of science, the human body, and the microscopic world within us, all playing their part in the grand symphony of life. And who knows, maybe one day, we'll be able to rewrite the score and create a world where food allergies are just a distant memory.。