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ORIGINAL RESEARCH article

Front. Immunol., 07 May 2024
Sec. Microbial Immunology
This article is part of the Research Topic Role of Gut Microbiota in Diabetes Mellitus and Tumor Immunity: Volume II View all 5 articles

The causal relationship between gut microbiota and lymphoma: a two-sample Mendelian randomization study

Biyun Li&#x;Biyun Li1†Yahui Han&#x;Yahui Han2†Zhiyu FuZhiyu Fu1Yujie ChaiYujie Chai1Xifeng GuoXifeng Guo1Shurui DuShurui Du1Chi LiChi Li1Dao Wang*Dao Wang1*
  • 1Department of Pediatric Hematology Oncology, The First Affiliated Hospital of Zhengzhou University, Zhengzhou, Henan, China
  • 2Department of Pediatric Surgery, The First Affiliated Hospital of Zhengzhou University, Zhengzhou, Henan, China

Background: Previous studies have indicated a potential link between the gut microbiota and lymphoma. However, the exact causal interplay between the two remains an area of ambiguity.

Methods: We performed a two-sample Mendelian randomization (MR) analysis to elucidate the causal relationship between gut microbiota and five types of lymphoma. The research drew upon microbiome data from a research project of 14,306 participants and lymphoma data encompassing 324,650 cases. Single-nucleotide polymorphisms were meticulously chosen as instrumental variables according to multiple stringent criteria. Five MR methodologies, including the inverse variance weighted approach, were utilized to assess the direct causal impact between the microbial exposures and lymphoma outcomes. Moreover, sensitivity analyses were carried out to robustly scrutinize and validate the potential presence of heterogeneity and pleiotropy, thereby ensuring the reliability and accuracy.

Results: We discerned 38 potential causal associations linking genetic predispositions within the gut microbiome to the development of lymphoma. A few of the more significant results are as follows: Genus Coprobacter (OR = 0.619, 95% CI 0.438–0.873, P = 0.006) demonstrated a potentially protective effect against Hodgkin’s lymphoma (HL). Genus Alistipes (OR = 0.473, 95% CI 0.278–0.807, P = 0.006) was a protective factor for diffuse large B-cell lymphoma. Genus Ruminococcaceae (OR = 0.541, 95% CI 0.341–0.857, P = 0.009) exhibited suggestive protective effects against follicular lymphoma. Genus LachnospiraceaeUCG001 (OR = 0.354, 95% CI 0.198–0.631, P = 0.0004) showed protective properties against T/NK cell lymphoma. The Q test indicated an absence of heterogeneity, and the MR-Egger test did not show significant horizontal polytropy. Furthermore, the leave-one-out analysis failed to identify any SNP that exerted a substantial influence on the overall results.

Conclusion: Our study elucidates a definitive causal link between gut microbiota and lymphoma development, pinpointing specific microbial taxa with potential causative roles in lymphomagenesis, as well as identifying probiotic candidates that may impact disease progression, which provide new ideas for possible therapeutic approaches to lymphoma and clues to the pathogenesis of lymphoma.

1 Introduction

Lymphoma constitutes a category of neoplastic disorders originating from the lymphohematopoietic system. It can be classified into two categories—Hodgkin’s lymphoma (HL) and non-Hodgkin’s lymphoma (NHL)—based on the morphological characteristics of the tumor cells (1). In Western countries, lymphomas account for approximately 4% of newly diagnosed malignancies, ranking them as the fifth most prevalent type of cancer (2, 3). As per international cancer data trends, the incidence of lymphoma has been continuously rising (4, 5). The cause of lymphoma is not entirely clear, although previous studies have suggested a possible link to factors such as smoking (6), alcohol consumption (7), obesity (8), viral infections (9, 10), ionizing radiation exposure (11), chemical exposure (12), autoimmune diseases, or immune dysfunction (13). Moreover, there is mounting evidence that the gut microbiota significantly affect lymphoma pathogenesis, treatment response, and prognosis (14).

The various microorganisms and their ecology in the human gastrointestinal tract constitute the complex gut microbiota (15). Previous research have shown that the gut microbiota appears to influence human pathophysiological phenomena, encompassing immunity modulation, metabolic regulation, and inflammatory response mechanisms (16, 17). The perturbation of gut microbiota, commonly referred to dysbiosis, is increasingly considered as a potential precursor, facilitator, or even an instigating factor for a multitude of malignancies (18). Gut microbiota dysbiosis has been consistently noted across numerous lymphoma investigations, thereby giving rise to the conceptual framework known as the “microbiota–gut–lymphoma axis” (19)—for instance, gastric mucosa-associated lymphoid tissue (MALT) lymphoma in the stomach is strongly associated with infection with Helicobacter pylori (20). SE Yoon and colleagues found that patients diagnosed with diffuse large B-cell lymphoma (DLBCL) exhibit significantly reduced α-diversity compared to healthy subjects, coupled with a marked elevation in the abundance of Enterobacteriaceae family bacteria relative to those seen in healthy controls (21). The gut microbiome has also emerged as a promising diagnostic biomarker. A study conducted by Z Shi and colleagues identified the role of gut microbiota that was illuminated in terms of its utility for diagnosing natural killer/T-cell (NK/T cell) lymphoma (22). In addition, the gut microbiome might play a regulatory role in modulating the effectiveness of immunotherapy for lymphoma. A research found that administering broad-spectrum antibiotics prior to CD19-targeted chimeric antigen receptor T-cell (CAR-T) treatment resulted in unfavorable outcomes (23). In the context of hematopoietic stem cell transplantation (HSCT) among lymphoma patients, research had revealed a correlation between the proliferation of Lactobacillus species with the exacerbation or worsening of graft-versus-host disease (GVHD) (24). Previous studies have indicated that the gut microbiota plays a regulatory role in the effectiveness of cancer immunotherapies, and there is an opportunity for targeted microbiota to enhance anti-cancer efficacy while reducing toxicity in microbial therapies, which is crucial for developing personalized cancer treatment strategies (25).

The majority of the aforementioned studies have adopted a case–control design, which inherently carries limitations in establishing a definitive causal relationship between the exposure and the outcome under investigation. Furthermore, compared with traditional observational studies, the link is less susceptible to potential confounding factors, including environmental factors, dietary habits, and lifestyle. Nevertheless, establishing causal connections would improve our understanding of the gut microbiota’s role in lymphoma pathogenesis and have the potential to guide tailored microbiota-based interventions against various forms of lymphoma in clinical settings.

Mendelian randomization (MR) is an increasingly adopted natural randomization method that utilizes genetic variation as instrumental variables (IVs) (26). It follows Mendelian randomization second law, which identifies genetic variations at conception and follows a pattern akin to random allocation, and is widely used in studies of causality in disease etiology (27). In addition, compared with traditional observational studies, MR effectively reduces biases arising from confounding factors or reverse causality, ensuring greater reliability and validity of experimental findings (28). Recently, MR analyses have been implemented to explore causal links between the gut microbiota and various types of cancers (29). This study employs MR to analyze the potential causal effects of gut microbiota composition on lymphoma given the uncertainty of the causal relationship between the two. The aim is to establish a robust theoretical framework that can facilitate further investigation to the development of lymphoma.

2 Materials and methods

2.1 Data sources

Gut microbe-related genome-wide association studies (GWAS) data were meticulously retrieved from the esteemed MiBioGen Global Consortium, an expansive multi-ethnic study that orchestrates a grand-scale GWAS. The data was derived from an aggregate of 18,340 participant, including cohorts from Germany, Canada, Denmark, Israel, and The Netherlands among others (30). We eliminated 15 bacterial taxa lacking clear taxonomic identification along with one duplicative bacterial taxon entry (31). A set of 195 bacterial taxa stood out as the core elements underpinning the exposure variables in our subsequent MR analyses.

The malignant lymphoma GWAS databases were conveniently accessible via the FinnGen project’s online portal. Among these, the GWAS dataset pertaining to HL comprised 846 cases juxtaposed against an impressive backdrop of 324,650 controls. Similarly, the GWAS data linked with NHL featured an extensive array of subtypes: follicular lymphoma (FL) incorporating 1,181 cases, DLBCL with 1,050 cases, mature T/NK-cell lymphomas documented with 363 cases, and a collective category for other and unspecified NHL types accounting for 1,171 cases.

All the aforementioned GWAS datasets hold the virtue of being publicly accessible and can be effortlessly downloaded from the OPEN GWAS web platform. For clarity and reference, the specific dataset details employed in our Mendelian randomization (MR) analysis have been systematically presented in Table 1.

Table 1
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Table 1 Data information.

2.2 Selection of instrumental variables

This study capitalizes on single-nucleotide polymorphisms (SNPs) as IVs in its analytical framework. For these IVs to be rigorously employed within MR analyses, they must satisfy three basic conditions as described below:

(1) Relevance: Acknowledging that the limitation in the number of SNPs within the gut microbiome reached the genome-wide threshold of statistical significance (P < 5 × 10-8), we adopted a p-value <1 × 10-5 in selecting SNPs associated with risk factors to obtain comprehensive and reliable results (32). To ensure the independence of IVs, we employed a linkage disequilibrium (LD) threshold where r² was set to be less than 0.001, coupled with clumping distances exceeding 10,000 kb. This strategy is designed to filter out genetic variants with a weaker capacity to elucidate exposure, which might potentially influence the results. Utilizing established methods, we used the equation R2 = 2 × eaf × (1 − eaf) × beta2 to calculate the proportion of exposed variation attributable to each SNP. In addition, the F-statistic between each SNP and gut microbiota was calculated using the equation F = R2 × (N − 2)/(1 − R2) (33, 34). In doing so, SNPs with F <10 were discarded, considering them as weak instruments. This multi-level filtering process serves to ensure a strong and meaningful association between the retained SNPs and the gut microbiota under investigation.

(2) Independence: To investigate the potential associations between each SNP and confounders, we used the online Phenoscanner platform (available at http://www.phenoscanner.medschl.cam.ac.uk). We excluded SNPs with confounding factors associated with lymphoma (e.g., smoking, alcohol, body mass index, virus infections, immune abnormalities, chemical exposure, and ionizing radiation exposure). The Mendelian Randomization Pleiotropy Residual Sum and Outlier (MR-PRESSO) analysis serves as a powerful tool adept at detecting and differentiating outliers and SNPs exhibiting pleiotropic effects. In this analytical pipeline, the MR-PRESSO test calculates individual SNP and global test, respectively. The p-values for individual SNPs are sorted in ascending order and eliminated one by one. Afterward, a new MR-PRESSO global test is performed on the residual SNPs to reassess the overall horizontal multidirectionality. This recursive process continued until the global test returned a non-significant p-value (p > 0.05) (35).

(3) Exclusivity: To validate the unidirectional nature of the causal pathway, the MR-Steiger method was used to rigorously measure the directional estimates of causality (36). SNPs with incorrect direction were excluded.

2.3 MR analyses

We conducted MR analyses between gut microbiota and lymphoma. If a single independent variable (IV) representing a specific gut microbiological profile was associated with a lymphoma subtype, we used the Wald’s ratio test (37). When dealing with features characterized by multiple IVs, we applied a suite of five widely recognized MR methodologies: the inverse variance weighted (IVW) test (38), the MR-Egger regression (39), the weighted median estimator (WME) (40), simple mode, and weighted mode (41).

The IVW approach is a meta-analytic tool that integrates the Wald ratio estimates derived from each SNP analysis by summing their estimates with inverse variance weighting (42). The MR-Egger regression was grounded on the no-error-of-measurement (NOME) assumption, using an intercept term to examine the presence of potential pleiotropic effects (39). Moreover, the WME and weighted mode approaches allow for the flexible estimation of causality, even though half of the IVs may be void. Relative to the MR-Egger approach, these two methods help to improve the precision of the study results (43). Simultaneously, we conducted supplementary analyses using both weighted mode and simple mode techniques to bolster the reliability of the primary IVW method results (44).

In summary, the IVW model assumes the central role as the principal analytical strategy when there is no heterogeneity and horizontal pleiotropy. However, when heterogeneity becomes evident, findings derived from the WME approach are deliberated upon. Should there be indications of horizontal pleiotropy, the MR-Egger regression supersedes as the main method of analysis. The association between gut microbial composition and lymphoma risk was quantified using odds ratios (OR) and their corresponding 95% confidence intervals (CI), where p <0.05 was considered statistically significant. Moreover, in ensuring robustness against false positives due to multiple testing, we stringently applied the Bonferroni correction to establish statistically adjusted significance thresholds at each taxonomic stratum. These levels were respectively set at phylum level (α = 0.05/9), class level (α = 0.05/15), order level (α = 0.05/20), family level (α = 0.05/32), and genus level (α = 0.05/119). Statistically significant P-values from MR analyses were interpreted as prima facie or suggestive evidence of a causal association if they were above the adjusted threshold.

2.4 Sensitivity analysis

We conducted pleiotropy analyses, leave-one-out (LOO) analysis, and heterogeneity tests to evaluate and mitigate the effects of uncertainty in the models. Horizontal pleiotropy—a phenomenon where a genetic variant influences multiple traits beyond the primary outcome—was rigorously measured using the MR-Egger approach. Notably, the presence of horizontal pleiotropy was suggested if MR-Egger analysis revealed a statistically significant intercept. Importantly, MR-Egger methodology permits the accommodation of pleiotropic genetic variants while still enabling the estimation of unbiased causal effects even when directional pleiotropy or substantial heterogeneity exists (45). Cochran’s Q test quantifies the degree of inconsistency between the chosen SNPs and, if the result is statistically significant, indicates model heterogeneity (46). Based on this finding, we tend to use random effects IVW for analyses where there is significant heterogeneity. A fixed-effects model was adopted instead (47). Additionally, we performed a LOO analysis, which is used to check whether individual SNPs disproportionately affect the overall estimate. This is done by systematically removing each SNP in succession and then reapplying the MR method to the residual data to examine the robustness of the estimated causal effects and ensure the stability of our findings (48).

2.5 Data visualization and statistical software

We plotted forest plots of the overall causal estimates based on the results of the IVW method as well as scatter plots and LOO forest plots for each causal relationship to illustrate the collective contribution of these SNPs. All statistical analyses were executed using the R software packages “TwoSampleMR” (49) and “MR-PRESSO” (35), which ensured a robust and comprehensive assessment of the data.

3 Results

3.1 Selection of IVs

Figure 1 was constructed to visually reflect the relationship between SNPs (IVs), risk factor (gut microbiota), and outcome (lymphoma). First, SNPs significantly associated with the gut microbiota were selected. We conducted a thorough screening using the PhenoScanner to exclude SNPs that may be associated with lymphoma risk-related confounders (Supplementary Table S1). Subsequently, we ascertained the calculated F-statistics >10 for all IVs (Supplementary Table S2), and the results of MR-PRESSO suggested that there was no significant pleiotropy in this study (Table 2). Additionally, through the application of MR-Steiger analysis, we confirmed that none of the SNPs exhibited reversed causality (Supplementary Table S3). After a rigorous screening of IVs, the remaining 2,548 eligible SNPs were included in the subsequent analyses. The IVs after harmonization are listed in Supplementary Table S4.

Figure 1
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Figure 1 Workflow of MR design. HL, Hodgkin’s lymphoma; NHL, non-Hodgkin’s lymphoma; DLBCL, diffuse large B-cell lymphoma; FL, follicular lymphoma; MR, mendelian randomization; SNPs, single-nucleotide polymorphisms; IVW, inverse-variance weighted; WME, weighted median estimator; MR-PRESSO, Mendelian randomization pleiotropy residual sum and outlier; LD, linkage disequilibrium.

Table 2
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Table 2 Sensitivity analysis of the causal association between gut microbiota and lymphoma.

3.2 MR analysis results

The MR analysis using IVW identified 35 gut microbiota genera linked to lymphoma risk (Figure 2; Supplementary Table S5). Scatter plots corresponding to each causal relationship are provided in Supplementary Figure S1 for further illustration.

Figure 2
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Figure 2 MR results and its forest plot. (A) Causal effects for gut microbiota on HL; (B) Causal effects for gut microbiota on DLBLC; (C) Causal effects for gut microbiota on FL; (D) Causal effects for gut microbiota on T/NK cell lymphoma; (E) Causal effects for gut microbiota on other and unspecified types of NH. HL, Hodgkin’s lymphoma; NHL, non-Hodgkin’s lymphoma; DLBCL, diffuse large B-cell lymphoma; FL, follicular lymphoma; OR, odds radio; 95% CI, 95% confidence interval; IVW, inverse-variance weighted.

In this study, 10 genetically inferred gut microbiota taxa were found to exhibit significant associations with HL. Notably, family Bifidobacteriaceae (OR = 1.898, 95% CI 1.086–3.317, P = 0.024), order Bifidobacteriaceae (OR = 1.898, 95% CI 1.086–3.317, P = 0.024), genus Oscillospira (OR = 1.764, 95% CI 1.033–3.011, P = 0.038), and genus Gordonibacter (OR = 1.307, 95% CI 1.001–1.706, P = 0.049) showed suggestive evidence of increasing the risk of HL development. On the contrary, phylum Tenericutes (OR = 0.584, 95% CI 0.360–0.946, P = 0.029), class Mollicutes (OR = 0.584, 95% CI 0.360–0.946, P = 0.029), genus CandidatusSoleaferrea (OR = 0.615, 95% CI 0.422–0.895, P = 0.011), genus Coprobacter (OR = 0.619, 95% CI 0.438–0.873, P = 0.006), genus Intestinimonas (OR = 0.629, 95% CI 0.429–0.923, P = 0.018), and genus Eggerthella (OR = 0.651, 95% CI 0.456–0.928, P = 0.0176) demonstrated a potentially protective role against HL incidence.

For DLBCL, MR analyses using the IVW method showed causal relationships with five bacterial taxa. Genus Bilophila (OR = 1.777, 95% CI 1.053–3.000, P = 0.031), family Desulfovibrionaceae (OR = 1.579, 95% CI 1.003–2.487, P = 0.049), and genus Coprobacter (OR = 1.367, 95% CI 1.003–1.863, P = 0.048) displayed a statistically suggestive association with elevated risks of DLBCL. On the contrary, genus RuminococcaceaeUCG011 (OR = 0.749, 95% CI 0.574–0.978, P = 0.034) and genus Alistipes (OR = 0.473, 95% CI 0.278–0.807, P = 0.006) showed a negatively correlated relationship with the risk of developing DLBCL.

For FL, MR analyses using the IVW method showed causal relationships with 10 bacterial taxa. Two of those were positively correlated with an elevated risk of FL, class Actinobacteria (OR = 1.520, 95% CI 1.021–2.262, P = 0.039) and genus Catenibacterium (OR = 1.448, 95% CI 1.011–2.076, P = 0.044). On the contrary, family Pasteurellaceae (OR = 0.747, 95% CI 0.565–0.988, P = 0.041), order Pasteurellales (OR = 0.747, 95% CI 0.565–0.988, P = 0.041), genus Alistipes (OR = 0.565, 95% CI 0.321–0.996, P = 0.0484), genus Haemophilus (OR = 0.703, 95% CI 0.502–0.983, P = 0.040), genus Slackia (OR = 0.529, 95% CI 0.296–0.947, P = 0.032), family Peptostreptococcaceae (OR = 0.669, 95% CI 0.463–0.966, P = 0.032), family Rhodospirillaceae (OR = 0.725, 95% CI 0.541–0.970, P = 0.031), and genus Ruminococcaceae (OR = 0.541, 95% CI 0.341–0.857, P = 0.009) showed suggestive protective effects against FL.

Utilizing the IVW approach, a collective of eight bacterial taxa within the gut microbiome were identified to exhibit a statistically significant negative correlation with the onset and progression of T/NK cell lymphoma. They were genus Ruminococcus1 (OR = 0.443, 95% CI 0.198–0.992, P = 0.048), genus ChristensenellaceaeR.7group (OR = 0.359, 95% CI 0.134–0.960, P = 0.041), family Lactobacillaceae (OR = 0.523, 95% CI 0.300–0.917, P = 0.022), genus Lactobacillus (OR = 0.501, 95% CI 0.286–0.880, P = 0.016), genus RuminococcaceaeUCG014 (OR = 0.412, 95% CI 0.205–0.829, P = 0.013), order Methanobacteriales (OR = 0.574, 95% CI 0.371–0.887, P = 0.012), class Methanobacteria (OR = 0.574, 95% CI 0.371–0.887, P = 0.012), and genus LachnospiraceaeUCG001 (OR = 0.354, 95% CI 0.198–0.631, P = 0.0004).

Regarding other and unspecified types of NHL, the application of the IVW method in MR analyses revealed significant causal linkages with a select group of five bacterial taxa. Genus Sutterella (OR = 1.600, 95% CI 1.001–2.545, P = 0.0497), order Clostridiales (OR = 1.663, 95% CI 1.047–2.643, P = 0.031), and family Defluviitaleaceae (OR = 1.527, 95% CI 1.076–2.168, P = 0.018) revealed a trend towards heightened risk. On the contrary, order Bacillales (OR = 0.755, 95% CI 0.590–0.966, P = 0.025) and genus Slackia (OR = 0.642, 95% CI 0.424–0.974, P = 0.0373) displayed a protective effect.

However, despite the statistical significance described above, these observed associations did not meet the strict thresholds imposed by the Bonferroni correction and therefore lost statistical significance after adjustment.

3.3 Sensitivity analysis results

We conducted several rigorous sensitivity analyses and found no factors that significantly affected the robustness of the findings, with the detailed outcomes summarized in Table 2. The LOO test found no outliers, suggesting stable results (Supplementary Figure S2). As mentioned above, the results of MR-Egger suggested that no significant horizontal pleiotropy was found in this study (Supplementary Table S6). Sagittarius conclusions were obtained in the MR-PRESSO test (Supplementary Table S7). Furthermore, no significant heterogeneity was obtained from the Cochran’s Q statistic (Supplementary Table S8).

4 Discussion

Contemporary scientific inquiries have illuminated its intricate participation in the onset and advancement of numerous malignancies, such as pancreatic, breast, and hepatocellular carcinomas, where approximately 13% of worldwide cancer cases bear an imprint of microbial influence (14, 50). Of particular interest lies the burgeoning connection between the gut microbiome and lymphoma—a field witnessing considerable exploration. To our knowledge, our investigation stands as one of the pioneering endeavors to methodically appraise the causative link between the gut microbiota and the multifarious forms of lymphoma. Through MR study, harnessing the power of a large-scale GWAS dataset, we strive to bridge a critical knowledge gap within this burgeoning research landscape.

Our MR study identified a total of 35 species of intestinal flora as potentially associated with five subtypes of lymphoma, thus substantiating the critical involvement of specific gut microbiota in the etiology and progression of various lymphoma forms. Unlike traditional observational studies, which often struggle with confounding factors such as diet, age, and gender as well as economic level (51), our MR approach effectively mitigates these influences, thereby enhancing the credibility of the derived conclusions.

Traditional observational research have consistently highlighted correlations between the two—for instance, in a study focusing on adolescent and young adult Hodgkin’s lymphoma (AYAHL) patients, it was evidenced that individuals diagnosed with AYAHL manifested a notably diminished presence of rare gut microbes along with a conspicuously reduced relative abundance of Actinobacteria when juxtaposed with their unaffected counterparts (52). Similar findings have been reported in cutaneous T-cell lymphoma (CTCL), where patients typically exhibit a state of gut dysbiosis compared to healthy subjects, a disparity that intensifies as the disease progresses to advanced stages (53). Another study discovered that the intestinal flora of DLBLC patients had a notably increased proportion of Aspergillus/Hypobacterium, coupled with a decreased representation of butyrate-generating bacterial strains, including Clostridium, Eubacterium, Ruminococcus, and Roseburia, compared with that of healthy controls (54). However, it is uncertain whether these, in microbial diversity, act as a risk factor for lymphoma, are caused by the lymphoma itself, or result from the therapeutic interventions that patients receive. Moreover, there is also an association between lymphoma treatment and gut microbes—for instance, in a study of chimeric antigen receptor T cells (CAR-T) and their effectiveness in treating lymphoma found when comparing patient populations experiencing complete versus partial remission states, significant temporal disparities were observed in both the biodiversity and relative abundance of key bacterial species, such as Prevotella, Collinsella, Bifidobacterium, and Sutterella (55). Cyclophosphamide, a frequently employed chemotherapeutic agent in lymphoma treatment regimens, has been shown to exert a transformative influence on the intestinal microbiome composition of murine models. It notably facilitates the translocation of specific gram-positive bacterial species to secondary lymphoid tissues, concurrently promoting Th17 cells and memory Th1 immune responses and thus contributing to its anti-tumor efficacy (56).

The current research seek to unravel the complex molecular pathways through which gut bacteria influence the progression of lymphoma. Gut microbiota can either activate or detoxify mutagens, which can promote or prevent DNA damage and cancer (5759)—for example, H. pylori increases oxidative stress and can function as an immunogenic stimulus, stimulating persistent immune cell multiplication, which, in turn, leads to lymphoma (60). In addition, gut microbiota have been shown to exert profound influences on the immune response, which can affect lymphocytes. Segmented filamentous bacteria can lead to alterations in T cell activity, often resulting in augmented secretion of cytokines including IFN-γ and IL-10 (61). In murine models, certain bacteria belonging to the Clostridiales clusters have been demonstrated to exert a direct influence on T regulatory cell differentiation (62). Bacterioides fragilis induces an immune response in Th17 cells, leading to lymphomas (63). In addition, the gut microbiome has systemic effects—for example, Polysaccharide A, a constituent derived from Bifidobacterium fragilis, has been shown to stimulate an augmentation in the circulating population of systemic T helper cells (64). Moreover, metabolites produced by the gut microbiome hold a critical position in the lymphoma advancement. The genera Slackia and Lachnospiraceae abundantly synthesize butyrate via several intricate metabolic routes. Empirical evidence suggests that butyrate-producing Eubacterium inhibit lymphoma development by attenuating the TNF-activated TLR4/MyD88/NF-κB signaling cascade (65). The above-mentioned genera were also suggested to reduce the risk of lymphoma in our study.

Probiotics constitute a collection of beneficial microorganisms that provide health benefits to the gut through various mechanisms. They achieve this by rectifying intestinal dysbiosis, fostering assimilation, strengthening the mucosal lining, and dampening inflammatory processes (66). Research has shown that Lactobacillus is a common probiotic, which inhibits the progression of colorectal cancer by secreting small molecules such as indole-3-lactic acid, downregulating microRNA (miRNA)-155 and upregulating miRNA-26b and miRNA-18a (67, 68). Meanwhile, Lactobacillus can produce conjugated linolenic acid in the intestine and secrete extracellular polysaccharides to promote tumor cell apoptosis (69). Some lactobacilli can also improve the content of short-chain fatty acids in intestines, prompting the proliferation of more probiotics and reducing cellular carcinogenesis (70). This finding aligns with our observations suggesting that family Lactobacillaceae may reduce the risk of T/NK cell lymphoma. In animal experiments, Lactobacillus johnsonii-deficient mice suffering from ataxia–telangiectasia had a higher incidence of lymphoma in a mouse model whose genotoxicity was reduced by a short-term oral administration of Lactobacillus (71). Better treatment outcomes and prognosis in DLBCL patients significantly enriched with Lactobacillus fermentum have also been observed in clinical trials. Combined with our findings, we can further investigate the protective mechanism of Lactobacillus against lymphoma. This may lead to the development of Lactobacillus-enriched drugs or genetically engineered supplements to prevent lymphoma.

Family Bifidobacteriaceae and order Bifidobacteriaceae belong to the phylum Actinobacteria, which constitute a substantial component of the human gastrointestinal flora (72). Some studies have found health-promoting and anti-tumor effects (73). A study discovered that certain strains of Bifidobacterium bifidum in mice reduced tumor load by triggering an anti-tumor host immune response in conjunction with PD-1 blockade or oxaliplatin treatment (74). Bifidobacteria limit the formation of free radicals by binding iron within the colon, which can consequently diminish the risk of colorectal carcinogenesis (75). A study in adolescents found that Bifidobacterium bifidum coordinated fibroblasts to inhibit colorectal tumorigenesis through the Wnt signaling pathway (76). However, no studies have investigated whether they may have an impact on lymphoma. Our study revealed that family Bifidobacteriaceae and order Bifidobacteriaceae are causally associated with HL disease and may increase the risk of HL. This finding is the first report, which also provides new ideas to further explore the immune mechanism between Bifidobacteria and lymphoma in the future.

Genus Alistipes represents a relatively novel group within the bacterial domain, and our study found it to be a protective factor in DLBCL and FL. In previous studies, it has been conceptualized as a “double-edged sword”. Research have claimed that Alistipes has a pathogenic effect on colorectal cancer through the IL-6/STAT3 pathway and has been linked to depression (77). Although a pathogenic role for Alistipes has been observed in colorectal cancer, recent studies suggest that it may also have a positive impact on cancer immunotherapy by altering the tumor microenvironment—for example, in patients responding well to nabulizumab for non-small cell lung cancer, there was an increased abundance of Alistipes (78). Nevertheless, there is currently no explicit evidence in the existing literature that directly implicates a relationship between Alistipes and the development of lymphoma. The immune mechanism between Alistipes and lymphoma can be further explored in the future, providing ideas for microbial-assisted therapy.

Genus Coprobacter is an important member of the phylum Trichoderma and the principal sources of butyric acid production. Butyrate acts as an energy-producing substance in the colon, stabilizes hypoxia-inducible factor to sustain the characteristic anaerobic milieu within the gut environment, and regulates Claudin-1 and synaptopodin expression to maintain gut barrier integrity. Additionally, it limits the production of inflammation-associated cytokines as well as inhibits oncogenic signaling cascades, including TGF-β and Akt/ERK signaling (79). Genus Coprobacter may help to suppress the immune response and alleviate the intensity of allergy, in addition to being associated with depression and language development in young children (80, 81). In our study, genus Coprobacter can potentially augment the susceptibility to DLBCL while demonstrating a protective effect against HL; this conclusion this still needs further studies. Butyrate has also been found to enhance cancer treatment efficacy by modulating intracellular calcium, and the role of these butyrate-producing intestinal flora in the development and treatment of lymphomas remains to be further investigated (82).

This MR study benefits from utilizing a vast amount of data from multiple published GWAS summaries and controlling for partial confounding and reverse causality. In addition, the study focuses on GWAS data for gut microbiota and lymphoma confined in European populations, reducing potential biases arising from genetic and environmental heterogeneity across different ethnic backgrounds.

Nevertheless, our study had several limitations. Firstly, it is important to take care when generalizing the study results to other ethnic populations, as the bulk of patients in the combined GWAS dataset comes from European populations. This may introduce biases into the estimations and compromise the universal applicability of the conclusions. Secondly, the impact of gut microbiota appears to exhibit heterogeneity across different pathological subtypes of lymphoma, requiring further investigation into the precise biological mechanisms that underlie the connection between the gut microbiome and the diverse pathological manifestations of lymphoma. Thirdly, gut microbiome GWAS is still in its infancy and the count of relevant loci is comparatively modest relative to lymphoma, and some bacteria may not be adequately characterized at the genus or species level. As the GWAS continues to expand and incorporate larger sample sizes, along with the use of advanced shotgun metagenomic sequencing techniques, there is a promising prospect that more definitive and nuanced features will emerge with greater clarity (83). Fourthly, after implementing the stringent Bonferroni correction to the MR analysis results, the associations in the current study were not statistically significant. Therefore, the findings should only be regarded as suggestive evidence of a potential association. In addition, there are fewer in vivo or in vitro studies of specific flora associated with lymphoma, which cannot permit adequate comparison and discussion. Subsequent research endeavors can capitalize on these preliminary insights to determine a more definitive link between gut microbiota composition and the etiology of lymphoma. Consequently, conclusions drawn from our current work should be considered provisional rather than conclusive, highlighting the need for further corroboration.

5 Conclusion

We assessed the causal link between gut microbiota and lymphoma through MR analysis of public GWAS data, identifying specific bacteria that might contribute to lymphoma risk and potential protective taxa. Our study provides new ideas for possible therapeutic approaches to lymphoma and clues to the pathogenesis of lymphoma.

Data availability statement

The datasets presented in this study can be found in online repositories. The original contributions presented in the study are included in the article/Supplementary Material. Further inquiries can be directed to the corresponding author.

Ethics statement

Ethical approval was not required for the study involving humans in accordance with the local legislation and institutional requirements. Written informed consent to participate in this study was not required from the participants or the participants’ legal guardians/next of kin in accordance with the national legislation and the institutional requirements.

Author contributions

BL: Writing – original draft, Writing – review & editing, Data curation, Software. YH: Data curation, Software, Writing – original draft, Writing – review & editing. ZF: Data curation, Writing – original draft. YC: Data curation, Writing – original draft. XG: Data curation, Writing – original draft. SD: Data curation, Writing – original draft. CL: Data curation, Writing – original draft. DW: Writing – review & editing.

Funding

The author(s) declare that no financial support was received for the research, authorship, and/or publication of this article.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Supplementary material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fimmu.2024.1397485/full#supplementary-material

Supplementary Table S1 | SNPs with confounding factors.

Supplementary Table S2 | Calculated F-statistics for all IVs.

Supplementary Table S3 | MR-Steiger analysis results for all SNPs.

Supplementary Table S4 | The IVs after harmonization.

Supplementary Table S5 | The results of MR analysis.

Supplementary Table S6 | The results of MR-Egger.

Supplementary Table S7 | The results of MR-PRESSO text.

Supplementary Table S8 | The results of the Cochran’s Q statistic.

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Keywords: gut microbiota, Mendelian randomization, Hodgkin lymphoma, non-Hodgkin lymphoma, causal effect

Citation: Li B, Han Y, Fu Z, Chai Y, Guo X, Du S, Li C and Wang D (2024) The causal relationship between gut microbiota and lymphoma: a two-sample Mendelian randomization study. Front. Immunol. 15:1397485. doi: 10.3389/fimmu.2024.1397485

Received: 07 March 2024; Accepted: 15 April 2024;
Published: 07 May 2024.

Edited by:

Leming Sun, Northwestern Polytechnical University, China

Reviewed by:

Debora Decote-Ricardo, Federal Rural University of Rio de Janeiro, Brazil
Parvaneh Esmaeilnejad-Ahranjani, Institut Jožef Stefan (IJS), Slovenia

Copyright © 2024 Li, Han, Fu, Chai, Guo, Du, Li and Wang. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Dao Wang, deai315@163.com

These authors share first authorship

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.