We have summarized recent studies on the alteration of the composition of the microbiota in the development of NAFLD through the gut–liver axis (Table 1). For example, NAFLD is commonly induced by nutritional imbalance, which results from dietary disorder-induced overnutrition and malnutrition. Moreover, comprehensive examination of the NAFLD etiology induced by overnutrition and obesity showed that an alteration of the gut microbiota has emerged as a crucial element in promoting the occurrence of NAFLD (6). The levels of alanine aminotransferase (ALT), aspartate aminotransferase (AST), and triglycerides (TG) were significantly elevated by a high-fat diet (HFD) in C57BL/6 mice with NAFLD (26). Consequently, HFD decreased the special operational taxonomic units (OTUs) and Shannon diversity index of the microbiota, which suggested that HFD caused an imbalance in the homeostasis of the gut microbial community. HFD remarkably enhanced the abundance of Firmicutes and reduced the abundance of Bacteroidetes. Moreover, participants with obesity exhibited a significantly higher ratio of Firmicutes to Bacteroidetes (27). In another study, Li et al. (28) found that the high-fat high-cholesterol (HFHC) group upregulated the abundance of Firmicutes and Verrucomicrobiota and downregulated the abundance of Bacteroidetes, Actinobacteria, and Proteobacteria. However, a gradual decrease in the abundance of Firmicutes, Verrucomicrobiota, and Actinobacteriota and a gradual increase in the abundance of Bacteroidetes were identified during the progression of NAFLD from non-alcoholic steatohepatitis (NASH) to NASH with fibrosis. In fact, the levels of TG and total cholesterol (TC) in the liver were strongly correlated with the abundance of Firmicutes and Bacteroidetes in HFD-induced NAFLD mice. Moreover, the alteration of serum lipid levels was also related to imbalanced bacterial microbiota, including Erysipelotrichaceae, Coriobacteriaceae, Enterorhabdus, Lachnoclostridium, and Alistipes in C57BL/6J mice fed with HFD. Furthermore, the gut microbiome profile differs according to the severity of NAFLD. A previous cross-sectional analysis that included NAFLD-cirrhosis, NAFLD without advanced-fibrosis, and non-NAFLD controls investigated alterations in the composition of the microbiota (29). The β-diversity of the gut microbiota was lower among patients with NAFLD without advanced fibrosis than among participants of the healthy control group, whereas it was higher among patients with NAFLD-cirrhosis than in patients with NAFLD without advanced-fibrosis. Consequently, a decrease in gut microbiota diversity was identified in proportion to NAFLD severity. Furthermore, Streptococcus abundance increased in patients with both NAFLD-cirrhosis and NAFLD without advanced fibrosis; Megasphaera abundance only increased in participants with NAFLD-cirrhosis. However, Bacillus and Lactococcus abundance increased in patients with NAFLD without advanced fibrosis and in healthy participants. Meantime, the abundance of Enterobacteriaceae, Streptococcus, and Gallibacterium was enhanced in patients with NAFLD-cirrhosis, while Faecalibacterium prausnitzii, Catenibacterium, Rikenellaceae, Mogibacterium, and Peptostreptococcaceae were only identified in healthy participants. The composition of the gut microbiome also significantly differed with different severities of HS (4). The abundance of Bacteroidetes, Proteobacteria, Lentisphaerae, and Firmicutes was largely decreased in patients with mild steatosis. In contrast, the abundance of Firmicutes and Bacteroidetes was significantly increased in patients with moderate steatosis. The abundance of Actinobacteria, Bacteroidetes, Lentisphaerae, Firmicutes, and Proteobacteria was also notably decreased in patients with severe steatosis. The abundance of the Firmicutes bacterium CAG 95 was also significantly decreased in patients with both severe and moderate steatosis. Similar to previous studies, some species of the phylum Firmicutes, including Ruminococcus bromii, Dorea longicatena, and Roseburia sp. CAG 182, could regulate AST, ALT, and uric acid levels.

Sex hormones and sex chromosomes are the two major factors driving sex-based characterization of the differences in the microbiome between the male and female sexes (30). A previous study revealed that sex-specific microbiomes may play an essential role in the incidence of NAFLD and obesity (31). For instance, the genus Holdemanella and family Erysipelotrichaceae were negatively related to the android fat ratio in females, whereas a positive relationship was identified in males. Meanwhile, the family Ruminococcaceae was positively related to the gynoid fat ratio only in females. Male and female sexes have different microbiome species associated with fat distribution, and sometimes, the same family and genus of microbiomes have different associations with fat distribution in the two sexes (32). Postmenopausal females with estrogen deficiency display a higher risk for NAFLD progression to fibrosis owing to the alteration of gut microflora (30). Male patients with NAFLD showed a decreasing trend in microbial α-diversity, an increasing trend in the abundance of genera Dialister, Streptococcus, and Bifidobacterium species, and a decreasing trend in the abundance of the genera Phascolarctobacterium, Mogibacteriaceae, Rikenellaceae, and Peptococcaceae. In contrast, female patients with NAFLD had an increasing trend in microbial α-diversity and the abundance of these taxa and showed an opposite trend (33). As previously described, Dialister is a genus of Firmicutes that increases in abundance in patients with liver cirrhosis (3). The genus Phascolarctobacterium showed association with control of the body weight of patients with NAFLD (34). RF39 elicits a potential health benefit in controlling BMI, blood TG, and frailty among older adults (35). The specific changes in microbiota induced by different maternal diets were also notable. For example, the abundance of Firmicutes and Tenericutes was increased and that of Bacteroidetes, Verrucomicrobia, and Cyanobacteria was decreased among male mouse offspring due to HFD. Female mouse offspring had a higher abundance of Firmicutes, Saccharibacteria, and Deferribacteres and lower Bacteroidetes and Verrucomicrobia in the HFD group than in the control group (36). However, the mechanism underlying the alteration of microbiota induced by differences in sex remains poorly explored.

Non-alcoholic fatty liver disease is one of the main factors contributing to HCC (37). The prevalence of NAFLD-HCC has increased more than that of hepatitis, and the frequency of liver transplantations is rapidly growing worldwide. The gut microbiome is a crucial factor that promotes the occurrence of NAFLD and NAFLD-HCC (3, 38, 39). NAFLD-HCC is characterized by an increased abundance of Proteobacteria compared to that in healthy individuals. An increase in Enterobacteriaceae and decrease in Oscillospiraceae and Erysipelotrichaceae abundances were identified in patients with NAFLD-HCC. However, the microbiome signature differed between patients with NAFLD-cirrhosis and NAFLD-HCC. An increase in Eubacteriaceae abundance was observed in NAFLD-cirrhosis group, which was not found in either NAFLD-HCC or the non-NAFLD control groups. Furthermore, an elevated abundance of Coriobacteriaceae and a lower abundance of Muribaculaceae, Odoribacteraceae, and Prevotellaceae were also detected in those with NAFLD-cirrhosis (3, 39). Moreover, supplementation of the diet with cholesterol spontaneously promoted the occurrence of NAFLD-HCC, followed by dysbiosis of the gut microbiota. This report confirmed that an increase in Helicobacter ganmanii and a decrease in Bacteroides play an essential role in NAFLD-HCC onset. In contrast, the imbalanced gut microbiota regulates cholesterol levels in NAFLD-HCC. For example, some bacteria such as Mucispirillum schaedleri, Desulfovibrio, Anaerotruncus, and Clostridium celatum were positively correlated with cholesterol levels. However, Bifidobacterium, Bacteroides acidifaciens, Bacteroides uniformis, Akkermansia muciniphila, and Lactobacillus were negatively correlated with serum and liver cholesterol levels. Similar results were also observed in cases of hypercholesterolemia; Bifidobacterium and Bacteroides negatively regulate the levels of TC and low-density lipoprotein (LDL) cholesterol in the serum (38).

Notably, the abundance of bacterial species is closely associated with host gene expression in NAFLD. First, Barnesiella, Oscillibacter sp. CAG 241, and Roseburia related to HS could regulate the expression of inflammatory genes. For example, Campylobacter concisus and Porphyromonas endodontalis negatively regulated the expression of CXCL9 and LIF-R, respectively, and Veillonella atypica positively regulated the expression of CD244. Based on these data, we can infer that these inflammation-related proteins are responsible for enhancing antigen presentation to lymphocytes, which break the liver immune tolerance and stimulate both cellular and humoral immune responses in NAFLD (4, 39). In addition, some species of bacteria, including Bacteroides caecimuris, Bacteroides xylanisolvens, and Clostridium bolteae, were able to regulate the levels of IL-10+ Tregs and CD8+ T-cells in patients with NAFLD-HCC, suggesting that these bacteria participate in the modulation of adaptive immunity (39). Second, members of the predominant bacterial phyla, Firmicutes and Bacteroidetes, also influence the lipid metabolism pathway in the liver by regulating the related genes. Firmicutes positively regulate the expression of Mogat1 and CD36 in the liver. In contrast, Bacteroidetes negatively regulate the expression of Cidea, CD36, Acnat2, Mogat1, and GPAT3. In addition, Erysipelotrichaceae positively regulated the expression of Cidea, CD36, Acnat2, Mogat1, and GPAT3. Previous studies have suggested that Cidea, CD36, and GPAT3 are involved in the lipid metabolism pathway that drives the occurrence of HS (26). Third, F. prausnitzii can also regulate genes related to other pathways, such as IRS-1/2, IL-6, SOCS3, LEPR, and steroid response element binding protein-α (SREBP-α), to prevent the development of NAFLD (40). In addition, F. prausnitzii regulates the immune response by mediating the expression of PRKCZ, STAT3, and IRS2. Another bacterium, Ruminococcus spp., has also been found to regulate the expression of AKR1B10, which is related to apoptosis (41). The abundance of Ruminococcus spp. is also positively related to JUN and JUNB, which attenuates the pathogenesis of NASH (42).

N,N,N-trimethyl-5-aminovaleric acid (TMAVA) is a novel metabolite identified in patients with HS which is useful for characterizing the different severities of HS (43). Zhao et al. (43) found that plasma trimethyl lysine (TML) is a precursor of TMAVA. Enterococcus faecalis and Pseudomonas aeruginosa can promote TML metabolism into TMAVA (44). Interestingly, increased levels of TML were observed in patients with steatosis. In another clinical trial (4), the plasma level of TMAVA was positively dependent on the abundance of Bacteroides stercoris, B. uniformis, and Parabacteroides distasonis and negatively dependent on the abundance of Prevotella copri. However, TMAVA was significantly decreased by the combined metabolic activators (CMAs). In contrast, TMAVA can bind and inhibit the expression of γ-butyrobetaine hydroxylase (BBOX) to decrease carnitine synthesis (45). Thus, TMAVA participates in energy production and conversion and the metabolism and transport of carbohydrates and lipids in the liver. Therefore, TMAVA can be considered a potential metabolite signature for the prediction of NAFLD.

Short-chain fatty acids are a primary type of bacterial metabolite produced by bacterial fermentation of otherwise indigestible fibers in the colon (46). Many previous studies have illustrated the role of aberrant levels of SCFAs in NAFLD progression (39, 40, 47–50). SCFAs can disrupt the functioning of the intestinal barrier impairing the translocation of LPS and increasing the level of liver endotoxemia to promote the pathogenesis of NAFLD (50). Butyrate and propionate are the main components of SCFAs, which can decrease gut inflammation and improve gut barrier integrity to limit LPS translocation (51). Liu et al. (50) confirmed that butyrate was significantly reduced in female patients with NAFLD and in ovariectomized (OVX) mice. Butyrate was also positively correlated with Tregs and effector IL-10 and negatively correlated with cytotoxic CD8 T-cells in participants with NAFLD-HCC (39). Indeed, previous studies have indicated that gut microbiota directly regulates T-cell immunity through SCFAs (52, 53). Moreover, supplementation of a high fiber diet increases the levels of SCFAs, especially butyrate, to promote hepatocyte proliferation (49, 54). Butyrate, nicotinate, and 2-oxoglutarate positively regulate hepatic oxidative phosphorylation and negatively regulate TG content through oxidative metabolism. The intermediates of SCFAs, oxaloacetate and acetylphosphate, were also increased in patients with NAFLD-HCC (39).

Short-chain fatty acids are closely related to specific bacterial species. For example, F. prausnitzii can produce SCFAs to induce apoptosis by regulating mitochondrial death, reactive oxygen species (ROS), and the caspase pathway during the progression of NAFLD to NASH (55). SCFA levels were also positively dependent on Peptococcus and Romboutsia and negatively dependent on Ruminiclostridiun-6 and Muribaculum (40). SCFAs and these bacteria were found to positively regulate the levels of TC, leptin, and body weight in female participants. In addition, Olivibacter, Clostridium, and Dysgonomonas may be related to levels of other SCFAs, such as acetate and propionate (56).

In addition to SCFAs, BA can also regulate inflammation due to HS by agonizing or antagonizing their cognate receptors (38, 51, 57). Primary BAs, such as taurocholic acid (TCA), tauroursodeoxycholic acid (TUDCA), glycocholic acid (GCA), and taurochenodeoxycholic acid (TCDCA), were aberrantly elevated in patients with NASH and mice fed a HFHC diet. Indeed, it had been confirmed that TCA, GCA, TCDCA, and TUDCA are critical metabolites that affect the accumulation of hepatic lipids and inflammation. Xiang et al. (38) reported that an increase in the abundance of M. schaedleri, Roseburia, and H. ganmanii possibly elevated TUDCA, TCDCA, TCA, and GCA levels, whereas decreased abundance of A. muciniphila due to HFHC diet elevated TCDCA and TUDCA levels. Increased abundance of Anaerotruncus due to a HFHC diet depleted the level of indolepropionic acid (IPA) (57). In addition, other bacteria such as Roseburia intestinalis, P. distasonis, Bacteroides vulgatus, and B. uniformis are also involved in the secondary BA metabolism pathway (4). In participants with NAFLD, primary BA levels were negatively related to the abundance of R. bromii, a species beneficial to human health. In addition, the enrichment of Bilophila wadsworthia lead to BA dysmetabolism, inflammation, and intestinal barrier dysfunction in the host, inducing higher glucose dysmetabolism and HS (58). Thus, Bifidobacterium and Bacteroides, the predominant bacteria of the gut microbiota, also participate in BA metabolism in NAFLD induced by HFHC feed (38). These species could prevent the transformation of taurine- and glycine-conjugated BAs into their unconjugated free forms (59). Collectively, previous findings suggest that treatment strategy exploration for NAFLD may be realized by reversing impaired BA metabolism, thereby preventing the development of NAFLD-HCC.

Fatty acid (FA), which may be produced as a result of metabolism by Firmicutes bacterium CAG 95 and Firmicutes bacterium CAG 110, is also involved in the development of NAFLD (4). The expression of crucial hepatic genes, including SREBP1, PPAR-γ, FAS, and CHREB, is involved in FA synthesis in HFD-fed mice and patients with estrogen reduction (56). Lipid accumulation in the liver is partly responsible for the uptake of circulating FA and decreases in the rate of FA oxidation and secretion (60). Indeed, butyrate can reverse PPAR-α activation to enhance FA β-oxidation, inhibit lipid synthesis, and deplete the level of nuclear factor-kappa B (61, 62), which was also observed in NAFLD-OVX mice (50).

In addition, 3-(4-hydroxyphenyl) lactate is a newly defined amino acid involved in tyrosine metabolism in NAFLD (63). Interestingly, circulating 3-(4-hydroxyphenyl) lactate may be generated by Escherichia coli, which also produces hydroxyphenyllactate in vitro (64). Moreover, members of Firmicutes, Bacteroidetes, and Proteobacteria phyla can also produce 3-(4-hydroxyphenyllactacte and phenyllactate) in NAFLD. Furthermore, many other dysfunctional metabolites are related to bacterial abundance. For example, carnosine, nicotinate, methylamine, trimethylamine, and arabinose were associated with the abundance of Bacteroides in HFD-induced NAFLD. Olivibacter, Clostridium, and Dysgonomonas have been correlated with acetate and propionate (56).