Although prior work has shown that the disruption or absence of the microbiome can influence bone, interpreting conflicting findings among studies is challenging because many prior studies use young animals of different ages (less than 12 weeks of age) or low‐resolution imaging techniques (mouse DXA). Comparing bone phenotypes in such young animals is not recommended because bone is changing rapidly during growth. 29 Additionally, none of the previous studies have examined the effect of alterations in the gut microbiota on bone mechanical performance. In the present study, we tested the hypothesis that alterations in the gut microbiota can have an effect on whole‐bone biomechanical performance. Specifically, we determined changes in bone structure and strength associated with alterations in the gut microbiota caused by (1) genotypic alterations (the TLR5KO mouse) and (2) chronic treatment with antibiotics that target the gut microbiota.

Genetic models are another tool for studying the effects of the microbiome on animal physiology. The Toll‐like receptor 5–deficient mouse (TLR5KO) is a congenic mouse strain that has been used to study the effects of the gut microbiome on animal physiology and disease. Toll‐like receptor 5 (TLR5) is the innate immune receptor for flagellin and does not have an endogenous ligand. 26 Hence, phenotypic traits of the TLR5KO mouse are primarily due to alterations in host‐microbe interactions. 27 Failure of the TLR5KO mouse to respond to flagellin is associated with changes in the gut microbiome that lead to increases in intestinal and systemic inflammation and a metabolic syndrome–like phenotype characterized by mild obesity, insulin resistance, increased blood pressure, and increased blood glucose. 27 , 28 The metabolic syndrome–like phenotype of the TLR5KO mouse does not develop in mice raised in a germ‐free environment and can be transferred to wild‐type (WT) mice through transplantation of the gut microbiota, demonstrating that the phenotype depends on the gut flora. 28

The effects of the microbiome on bone structure and density have been studied in mice using two standard tools for manipulating the microbiome: germ‐free animals and oral antibiotic treatments. 18 , 19 The changes in bone after these manipulations of the gut flora differ considerably among studies. Germ‐free mice (raised in the absence of live microbes) have been reported to display reduced bone mass 20 as well as increased bone mass 21 compared to mice raised in conventional environments. Alterations in the gut microbiota through treatment with oral antibiotics have been reported to affect bone density in mice, but the findings have been mixed, possibly due to differences in animal age, sex, antibiotic used, dosing schedule, and mouse genotype. 22 - 25

The gut microbiome is initially obtained at birth 11 and subsequently shaped by factors such as environment 12 and diet. 13 , 14 Exposure to the gut microbiome is necessary for the proper education and development of the innate and adaptive immune systems. 15 Dendritic cells, macrophages, granulocytes, T and B cells, and intestinal epithelial cells directly interact with the gut microbiome. 15 Toll‐like receptors are one set of receptors on immune cells that recognize the components of the gut microbiome and facilitate communication between the gut microbiome and the immune system. 16 Alterations in the gut microbiota or improper communication between the immune system and gut microbiota can lead to chronic immune responses and disease. 17

The microbes that inhabit the gastrointestinal tract are known collectively as the gut microbiota. Alterations in the gut microbiota are associated with a number of conditions that cause bone loss or increase fracture risk including malnutrition, 1 , 2 inflammatory bowel disease, 3 - 5 obesity, 6 , 7 and metabolic disease. 8 - 10 The gut microbiota, therefore, have the potential to influence bone and contribute to differences in fracture risk among patient populations.

To determine if genotype or treatment influenced whole‐bone strength in ways that were not explained by cross‐sectional geometry, we performed an analysis of covariance (ANCOVA), implemented with a generalized linear model (GLM) using as the covariate with genotype and treatment as fixed effects. Statistical tests were conducted using JMP Pro (v.9, 2013; SAS Institute Inc., Cary, NC, USA).

Measures of bone were adjusted for body mass (unadjusted values are provided in Supporting Table 1). 29 Homogenous variance was tested using Levene's test and normality tested using the Shapiro‐Wilk test. If parametric assumptions were met, a one‐way ANOVA followed by post hoc Holm correction for multiple comparisons was performed to test for differences between groups. If parametric assumptions were violated, either data was submitted to a log transform to achieve homogenous variance and normality or a nonparametric ranked Dunn's test followed by post hoc Bonferroni adjustment for multiple comparisons was used.

Splenocytes were harvested from the spleen of three mice from each group immediately after euthanasia as described. 43 , 44 The splenocytes were subsequently stained by incubation in 50 μL of FACS containing antibodies (1:500 dilution) for 1 hour. For analyzing B cells, Anti ‐ CD20 antibody conjugated to Phycoerythrin ( PE ) (BD Pharmingen, San Jose, CA, USA) was used and for T cells Anti ‐ CD3 antibody conjugated to PE (BD Pharmingen) was used. The stained cells were rinsed twice with FACS buffer and resuspended in 50 μL FACS buffer to be analyzed by BD Accuri C6 flow cytometer (BD Biosciences, San Jose, CA, USA). The flow cytometer results were analyzed using FlowJo software (FlowJo LLC, Ashland, OR, USA). Gut microbiota interact with and can be regulated by B‐cell and T‐cell populations. 15 , 45 Therefore, we examined the relative percentages of B and T cells in spleens of these mice.

Raw 16S rRNA gene sequences generated were demultiplexed using the open source software pipeline Quantitative Insights Into Microbial Ecology (QIIME, version 1.7.0‐dev; http://qiime.org/ ). 39 Sequences were filtered for quality using established guidelines. 40 Taxonomy was assigned using UCLUST ( http://drive5.com/usearch/manual/uclust_algo.html ) consensus taxonomy assigner, against the Greengenes reference database. 41 Low‐abundance clusters were filtered, and chimeric sequences were removed using USEARCH ( http://drive5.com/usearch/ ). 42 Additionally, we generated a species‐level operational taxonomic unit (OTU) table using the MiSeq Reporter Metagenomics Workflow (Illumina, San Diego, CA, USA). The MiSeq Reporter classification is based on the Greengenes database ( http://greengenes.lbl.gov/ ), and the output of this workflow is a classification of reads at multiple taxonomic levels: kingdom, phylum, class, order, family, genus, and species.

Amplification of the 16S rRNA gene, library construction, and bioinformatics were executed according to described methods. 35 Briefly, for amplification of the V4 hypervariable region of the bacterial/archaeal 16S rRNA gene, primers 515F and 806R were used. 38 The 5′‐barcoded amplicons were generated in triplicate using 12 to 300 ng of template DNA, 2 X EconoTaq Plus Green Master Mix (Lucigen, Middleton, WI, USA) and 10 μM of each primer. Replicate amplicons were pooled and purified using the Gel PCR DNA Fragment Extraction kit (IBI Scientific, Peosta, IA, USA) and visualized by electrophoresis through 1.2% (wt/vol) agarose gel stained with 0.5 mg/mL ethidium bromide. Blank controls in which no DNA was added to the reaction were performed. Purified amplicon DNA was quantified using fluorimetry (Quant‐iT PicoGreen; Life Technologies Corporation, Carlsbad, CA, USA).

The total bacterial load of fecal samples was determined using quantitative PCR (qPCR) as described. 35 The total bacterial load was defined as the total number of 16S rRNA gene copies. Briefly, quantification of the 16S rRNA target DNA was achieved by using the forward: 5′‐TGG AGC ATG TGG TTT AAT TCG A‐3′, and reverse: 5′‐TGC GGG ACT TAA CCC AAC A‐3′) 36 , 37 Unibac primers, and 10‐fold serial dilutions ranging from 1 × 10 0 to 1 × 10 7 plasmid copies of a plasmid DNA standard which was cloned in house. 35 Plasmid standards and feces samples were run in duplicates. The average of the cycle threshold value was used for calculation of the total bacterial load.

Gut microbiota analysis was performed on six samples per group. Isolation of DNA from feces was performed by using PowerSoil DNA Isolation Kit (MO BIO Laboratory Inc., Carlsbad, CA, USA) according to the manufacturer's instructions. DNA concentration and purity were then evaluated using a NanoDrop ND‐1000 spectrophotometer (NanoDrop Technologies, Rockland, DE, USA) at wavelengths of 230 nm, 260 nm, and 280 nm.

Images of the tibias were collected using μCT with 6‐µm voxels (µCT35; Scanco Medical AG, Brüttisellen, Switzerland; 55 kVp, 145 µA, 600‐ms integration time). The trabecular bone microarchitecture of the proximal tibial metaphysis was examined in a region extending from the growth plate to 10% of total bone length. Measurements included bone volume fraction (BV/TV), trabecular thickness (Tb.Th), trabecular separation (Tb.Sp), and cortical tissue mineral density (Ct.TMD). A global threshold for each group was used to segment mineralized tissue from surrounding nonmineralized tissue. A randomized subset ( n = 8) was selected for analysis of trabecular bone morphology for the TLR5KO mice.

where M is peak bending moment, is bone tissue material strength, I is the moment of inertia, and c is the distance from the neutral axis to bone surface. The term incorporates all geometrical properties that can influence peak bending moment. Differences in peak bending moment that are not explained by are caused by alterations in tissue material properties. Because of irregularities in force versus displacement data associated with motion, some specimens were excluded from the biomechanical analysis (4 WT, 1 WT ΔMicrobiota, and 3 TLR5KO).

Femurs were thawed to room temperature and maintained hydrated during mechanical testing. Right femora were loaded to failure in three‐point bending in the anterior‐posterior direction at a rate of 0.1 mm/s using a span length of 6 mm between outer loading pins (858 Mini Bionix; MTS, Eden Prairie, MN, USA). Force and displacement were measured using a 10‐pound load cell (SSM‐100; Transducer Techniques, Temecula, CA, USA) and a linear variable differential transducer at a 100‐Hz sampling rate. Bending stiffness was calculated as the slope of the linear portion of the force‐displacement curve. 29 Peak bending moment was calculated as one‐half the peak load multiplied by one‐half the span length. 29 The peak bending moment is related to bone tissue material properties and bone midshaft geometry by the following equation 34 :

The right femurs were harvested, wrapped in PBS‐soaked gauze, and stored at –20°C prior to analysis. Femur length was measured from the greater trochanter to the lateral condyle using digital calipers. Images of the femoral diaphyseal cross‐section were obtained by μCT with a voxel size of 25 µm (eXplore CT 120, GE, Fairfield, CT, USA; 80 kVp, 32 µA, 100 ms integration time). Images were processed using a Gaussian filter to remove noise and a global threshold for each group was used to segment mineralized tissue from surrounding nonmineralized tissue. Femoral cross‐sectional geometry was determined using a volume of interest extending 2.5% of total bone length and centered midway between the greater trochanter and lateral condyle (BoneJ, version 1.3.3; http://bonej.org/ ). 33 Measurements included total area, cortical cross‐sectional area, cortical thickness, marrow area, and moment of inertia about the medial‐lateral axis.

Animal procedures were approved by Cornell University's Institutional Animal Care and Use Committee. Mice from the C57BL/6J inbred strain and the B6.129S1‐Tlr5tm1Flv/J (TLR5KO) congenic strain were acquired from the Jackson Laboratory (Bar Harbor, ME, USA) and each were bred separately in conventional housing in our animal facility. C57BL/6J is the recommended control strain for TLR5KO. 28 , 30 Animals were housed in plastic cages filled with 1/4‐inch corn cob bedding (The Andersons Lab Bedding Producets, Maumee, OH, USA), fed with standard laboratory chow (Teklad LM‐485 Mouse/Rat Sterilizable Diet; Harlan Teklad Research Diets, Madison, WI, USA) and water ad libitum , and provided a cardboard refuge environmental enrichment hut (Ketchum Manufacturing, Brockville, ON, Canada). Male mice were divided into four groups: two groups treated to disrupt the gut microbiota (C57BL/6J: n = 7, TLR5KO: n = 8) and two untreated groups (C57BL/6J: n = 12, TLR5KO: n = 16). Mice with disrupted microbiota are referred to as “ΔMicrobiota.” Mice were housed in cages with other animals from the same genetic background/treatment group. Treated groups received broad‐spectrum antibiotics (1.0 g/L ampicillin, 0.5 g/L neomycin) in their drinking water from weaning at 4 weeks old until skeletal maturity (16 weeks old). 28 Chronic antibiotics used in this manner causes consistent disruptions to the gut microbiota over a prolonged time period. 31 Ampicillin and neomycin have poor bioavailability, thereby limiting extraintestinal effects of treatment. 28 , 32 Additionally, neomycin and ampicillin have never been associated with impaired bone growth. Animals were euthanized at 16 weeks of age. Femurs, tibias, epididymal fat pads, and spleen were collected immediately after euthanasia. Fecal pellets were collected 1 day prior to euthanasia to allow analysis of the microbiota.

Disruption of the gut microbiota with antibiotics did not alter total bacterial load, but had dramatic effects on gut microbiota composition and bacterial diversity, and immune cell count. ( A ) The relative composition of bacterial phyla shifted from a Bacteroidetes‐dominated phyla in untreated mice to one dominated by Proteobacteria in ΔMicrobiota mice ( n = 6/group). ( B ) Proteobacteria is enriched in ΔMicrobiota mice, especially in TLR5KO ΔMicrobiota mice (Bonferroni correction). ( C ) Bacteroidetes dominates gut microbiota composition in untreated WT and TLR5KO. ( D ) Total bacterial load was unaffected by antibiotic treatment. ( E ) Bacterial diversity was dramatically reduced in ΔMicrobiota mice. ( F ) The percentage of splenic CD20+ B cells was reduced in ΔMicrobiota mice and untreated TLR5KO mice ( n = 3/group). ( G ) The percentage of splenic CD3+ T cells in the spleen was reduced in ΔMicrobiota mice and untreated TLR5KO mice ( n = 3/group). Solid‐colored lines on dot‐plots represent mean. * p < 0.05 after adjusting for multiple comparisons.

Although the total bacterial load did not differ among the four groups (Fig. 3 D ), profound changes in the gut microbiota were observed. The gut microbiota composition at the phyla level differed among groups (Fig. 3 A ). The gut microbiota in WT and TLR5KO mice was dominated by the Bacteroidetes phylum (Fig. 3 A , C ). The gut microbiota in ΔMicrobiota mice was dominated by the Proteobacteria phylum (Fig. 3 A , B ). Proteobacteria abundance was greater in TLR5KO ΔMicrobiota mice compared to WT ΔMicrobiota mice ( p < 0.05, Fig. 3 B ). The diversity of the gut microbiota, as measured by the Shannon diversity index, was reduced in groups with a disrupted gut microbiota (TLR5KO: 4.8 ± 0.5; TLR5KO ΔMicrobiota: 1.7 ± 0.2; WT: 4.7 ± 0.4; and WT ΔMicrobiota: 2.5 ± 0.3) ( p < 0.05, Fig. 3 E ). Compared to untreated animals from the same genetic background, reductions in gut microbiota diversity in TLR5KO ΔMicrobiota mice were greater than those in WT ΔMicrobiota mice ( p < 0.05, Fig. 3 E ). One sample from the WT ΔMicrobiota mice was determined to be an outlier and was removed (Fig. 3 E ).

Sequences from feces microbiome assays were filtered for size, quality, and for the presence of chimeras, and the total post–quality control number of sequences used in this study was 2,465,448. The average coverage was 102,727 ± 32,103 (mean ± SD) reads per sample. No differences in the mean number of reads for each group were observed (WT: 112,309 ± 11,935; WT ΔMicrobiota: 88,325 ± 18,501; TLR5KO: 101,706 ± 39,625; and TLR5KO ΔMicrobiota: 108,568 ± 47,800) ( p = 0.612).

Cancellous bone volume fraction in the proximal tibia did not differ among groups (Fig. 1 F ). No differences in tibial cortical bone tissue mineral density were observed between untreated WT and TLR5KO mice. Disruption of the gut microbiota was associated with reductions in cortical bone tissue mineral density in both strains of mice ( p < 0.05, Fig. 1 F ). The thickness of the growth plate in the proximal tibia did not differ among groups (Table 1 ).

Disruption of the gut microbiota was associated with reduced peak bending moment. Disruption of the gut microbiota in WT mice resulted in an average peak bending moment 9% less than in untreated WT mice ( p < 0.05, Fig. 2 B ). Disruption of the gut microbiota in TLR5KO mice led to a peak bending moment 22% less than in untreated TLR5KO mice ( p < 0.05, Fig. 2 B ). After accounting for differences in cross‐sectional geometry, peak bending moment in mice with a disrupted microbiota was less than that in untreated mice (ANCOVA, effect of ΔMicrobiota, p < 0.0001, Fig. 2 C ). The effect of disruption of the gut microbiota on bone tissue material properties appeared to differ between WT and TLR5KO mice (ANCOVA, ΔMicrobiota × genotype, p = 0.09, Fig. 2 C ). Disruption of the gut microbiota in both WT and TLR5KO mice showed a trend suggesting reduced whole‐bone femoral bending stiffness ( p < 0.15, Fig. 2 D , Table 1 ). Disruption of the gut microbiota was not associated with differences in post‐yield displacement (Table 1 ).

Disruption of the gut microbiota resulted in differences in geometry in TLR5KO mice and in WT mice. Disruption of the gut microbiota in WT mice resulted in increased marrow area, decreased cortical area, and decreased cortical thickness compared to untreated WT mice ( p < 0.05, Table 1 ). Disruption of the gut microbiota did not result in changes in total area, moment of inertia, or femoral length in WT mice (Fig. 1 C , D ; Fig. 2 A ; Table 1 ). Disruption of the gut microbiota in TLR5KO mice resulted in decreased total area, marrow area, cortical area, cortical thickness, and moment of inertia as compared to untreated TLR5KO mice ( p < 0.05, Fig. 1 D , Fig. 2 A , Table 1 ). Disruption of the gut microbiota did not influence femoral length in TLR5KO mice (Fig. 1 C , Table 1 ). Femoral length was 2.6% smaller in TLR5KO ΔMicrobiota mice compared to WT ΔMicrobiota mice ( p < 0.05, Fig. 1 C , Table 1 ).

The peak bending moment in untreated TLR5KO mice was similar to that in WT mice (Fig. 2 C ), but the moment of inertia in TLR5KO mice was larger than in WT mice. Whole‐bone strength in TLR5KO mice was less than that in WT mice after accounting for differences in cross‐sectional femoral geometry (ANCOVA, effect of genotype, p < 0.0001, Fig. 2 C ). No differences in post‐yield displacement (Table 1 ) or bending stiffness (Fig. 2 D ) were observed between WT and TLR5KO mice.

Whole‐bone bending strength in mice with altered microbiota was less than would be expected from differences in cross‐sectional geometry. ( A ) The moment of inertia was larger in TLR5KO mice. ( B ) Whole‐bone bending strength (peak bending moment) was less in ΔMicrobiota mice than in untreated animals. The peak bending moment in TLR5KO mice did not differ from that of WT mice. ( C ) Whole‐bone bending strength in TLR5KO mice was less than in WT mice after accounting for I/c (difference between solid red and blue lines). Bending strength in ΔMicrobiota mice was less than that in untreated animals (difference between dotted and solid lines indicates results of ANCOVA). ( D ). Disruption of the gut microbiota in both WT and TLR5KO mice showed a trend suggesting reduced whole‐bone femoral bending stiffness. Solid‐colored lines on dot‐plots represent mean. Measures in A , B , and D are adjusted for body mass. * p < 0.05.

TLR5KO mice had greater body and fat pad mass. Disruption of the gut microbiota in TLR5KO mice prevented the development of increased body and fat pad mass. Disruption of the gut microbiota in WT mice had no effect on ( A ) body mass or ( B ) epididymal fat pad mass. ( C ) TLR5KO mice femur length was less than WT in both untreated and treated groups. ( D ) Total area was increased in untreated TLR5KO mice compared to untreated WT mice. Disruption of gut microbiota led to a reduced total area in TLR5KO ΔMicrobiota mice. ( E ) Disruption of the gut microbiota in both genotypes was associated with a reduced tibial metaphysis cortical TMD. ( F ) No differences in tibial metaphysis BV/TV were observed between any groups. Solid‐colored lines on dot‐plots represent mean. Measures in C , D , E , and F are adjusted for body mass. * p < 0.05. HA = hydroxyapatite.

The TLR5KO mice showed a mild obesity phenotype with an average body mass 10.4% greater than WT ( p < 0.05; Fig. 1 A ) and an average epididymal fat pad mass 52.0% greater than WT ( p < 0.05; Fig. 1 B ). Body mass and fat pad mass in TLR5KO mice with disrupted microbiota and WT mice with disrupted microbiota were similar, as shown in prior work. 28 No differences in colon histological scoring were observed among groups. One TLR5KO mouse had elevated colon histological scores suggesting mild colitis, but did not display gross differences in bone morphology or body mass and was not excluded from the study. 30

Discussion

Here we report the effects of an altered gut microbiota on bone mechanical properties in WT and TLR5KO mice. Disruption of the gut microbiota through long‐term exposure to antibiotics led to reductions in whole‐bone bending strength that exceeded what could be explained by the associated changes in cross‐sectional geometry, suggesting impairment of bone tissue material properties. Small differences in whole‐bone bending strength were observed between WT and TLR5KO mice after accounting for differences in bone morphology.

Together, the differences in whole‐bone strength, cross‐sectional geometry, and tissue mineral density suggest that alterations in the gut microbiota changed the mechanical properties of the bone tissue itself. Whole‐bone strength in bending is determined by both cross‐sectional geometry and tissue material properties. In bending, the ratio is the geometric measure that describes the entire effect of cross‐sectional geometry on bending strength and is directly proportional to the maximum load an object can sustain in bending. Consistent with this relationship, the ratio was the single best predictor of whole‐bone strength, accounting for 71% of the variation in peak bending moment across groups. However, differences in the regression lines (Fig. 2C) indicated that the ratio did not completely explain differences in strength among the four groups, a situation that implies alteration in bone tissue mechanical properties. Tissue mineral density (TMD) is a material property that can influence bone strength.46 TMD in the tibial metaphysis of mice with a disrupted microbiota was less than that of untreated mice. Although we did not measure TMD at the femoral midshaft directly, our findings in the tibia suggest that TMD may partially explain the reductions in femoral bone strength. Other factors such as collagen quality and noncollagenous proteins may also explain the reductions in femoral bone strength.

TLR5KO mice had larger total area than WT mice, but similar marrow area and cortical area. Increased total area without differences in marrow or cortical area at skeletal maturity has been associated with more rapid periosteal expansion during growth.29 The increased periosteal expansion in TLR5KO mice may be a mechanism employed by the skeleton to maintain whole‐bone strength despite impaired bone tissue material properties.47

Disruption of the gut microbiota resulted in decreased cortical bone at the femoral diaphysis in both WT mice and TLR5KO mice. Disruption of the gut microbiota in WT mice was not associated with alterations in total area, but was associated with decreased cortical area and cortical thickness. Disruption of the gut microbiota in TLR5KO mice prevented the more rapid periosteal expansion that occurred in untreated TLR5KO mice, and resulted in smaller cortical area, marrow area, and cortical thickness. Though marrow area was smaller in TLR5KO ΔMicrobiota mice, marrow area was larger than would be expected from the associated changes in total area. Decreased cortical area and cortical thickness is often attributed to decreased accumulation of bone mass during growth.29

Treatment with antibiotics had a larger effect on bone morphology and whole‐bone strength in TLR5KO mice than in WT mice. This observation has many potential explanations. First, disruption of the gut microbiota prevented the development of the mild obesity phenotype in TLR5KO mice. Obesity is associated with differences in bone morphology and mechanical performance.48 The bones in treated TLR5KO mice, therefore, not only have the effect of an impaired microbiota, but also reduced adiposity. Second, disruption of the gut microbiota in TLR5KO mice had a larger effect on the relative abundance of Proteobacteria and microbial diversity (the Shannon diversity index) than in WT mice, which could help explain the larger effect on the bone phenotype. Third, the immune system and immune responses are impaired in TLR5KO mice, leading to altered gene expression and activity by the gut microbiota.27

The composition of gut microbiota in untreated and treated mice was consistent with prior work. The total bacterial load in fecal samples did not differ between antibiotic treated and untreated groups, consistent with previous reports that oral antibiotic treatment can cause a large initial reduction in a bacterial population which recovers over time to a newly stabilized population.23, 49, 50 The dominant phylum in untreated mice was Bacteroidetes, consistent with reports that Bacteroidetes are the predominant phylum throughout a healthy mouse's lifespan.51 Disruption of the gut microbiota by chronic antibiotic treatment led to a gut microbiota population enriched by the phylum Proteobacteria (a minor component of the untreated mouse gut microbiota). The high relative abundance of Proteobacteria observed in mice with a disrupted microbiota at 16 weeks of age was similar to the immature and unstable gut microbiota typical of newborn mice.45 As a mouse matures, its immune system begins to regulate gut microbiota composition via B cell production of IgA antibodies that target Proteobacteria.45 The antibiotic treatment in the current study may have prevented the shift from Proteobacteria to Bacteroidetes that normally occurs in mice after weaning. Furthermore, the reduced splenic B cell count in mice with a disrupted microbiota is also consistent with the increased presence of Proteobacteria. The prevalence of members of the Proteobacteria phylum has been associated with increased incidence of microbial dysbiosis, metabolic disease, and inflammation, all factors known to influence host physiology and the immune system.16, 52

To understand the mechanisms linking changes in the microbiota to impaired bone tissue material properties it is useful to consider the three primary mechanisms through which the microbiome can influence organs distant from the gut: regulation of the immune system, regulation of nutrient absorption, and translocation of bacterial products across the epithelial barrier.53

We consider the effects of the microbiota on the immune system to be a likely explanation for the differences in bone tissue material properties in the current study. Disruption of the gut microbiota with antibiotics reduced CD20+ B and CD3+ T cell populations and was correlated with reduced whole‐bone strength. Similarly, untreated TLR5KO mice also had reduced CD20+ B and CD3+ T cell populations. B and T cell populations have the potential to cause profound changes in bone remodeling and bone turnover.54-58 However, it is not yet clear how alterations in B and T cell populations would lead to changes in bone tissue material properties.

Although we cannot ignore the possibility that alterations in nutritional absorption influenced our findings, we consider this explanation unlikely for several reasons: First, body mass and fat pad mass in the mice were all similar or greater than that in untreated WT animals, suggesting an acceptable caloric intake. Second, trabecular bone volume fraction was not different among the groups, and femoral length only had small differences. Trabecular bone volume fraction and whole‐bone length are typically severely reduced in situations of nutritional deficiency.20, 59 Trabecular bone is extremely responsive to impaired nutrition; animals submitted to short‐term severe calcium and vitamin D deficiencies showed reductions in trabecular bone volume fraction of 24% to 58%,60, 61 yet we did not observe reductions in trabecular bone volume fraction. Third, the reduction in peak bending moment seen in mice with a disrupted microbiota is not fully explained by changes in bone geometry or bone mass, whereas in animal models of reduced dietary calcium and vitamin D, reductions in whole‐bone strength are usually well described by changes in bone geometry, mass, and tissue mineral density.60, 61 Last, examination of colon histology did not indicate intestinal inflammation in any of our groups, suggesting that treatment with antibiotics to disrupt the gut microbiota did not lead to increased gut inflammation which can impair nutritional absorption.62, 63 Animal models with extensive intestinal inflammation commonly develop reduced body mass and dramatic trabecular bone loss, which, again, was not present in any of our treatment groups.64, 65

Translocation of bacterial products (or even live bacteria) across the gut endothelial barrier is another potential mechanism for gut microbiota to influence bone. Microbial products such as lipopolysaccharide and flagellin are capable of traveling through the bloodstream to distant organs and causing localized inflammation.66 Translocation of bacteria across the endothelial barrier is one of the mechanisms that explains the TLR5KO metabolic syndrome phenotype, so translocation may be involved in the observed differences in bone.27 Although bone cells can respond to lipopolysaccharide and flagellin,53 how such a response would lead to changes in bone tissue mechanical properties is not clear.

A number of strengths of the current study are worth noting. First, the study is unique in examining the effect of alterations in the gut microbiome on whole‐bone mechanical performance. Previous studies in which the microbiota was modified focused solely on bone structure or bone mass and did not examine mechanical performance. Second, the current study examined the effects of prolonged disruption of the gut microbiota during growth on the bone phenotype achieved at skeletal maturity. Most of the prior studies of bone in mice under conditions of altered gut microbiota examined bone from young, rapidly growing animals (7 to 9 weeks of age),53 and did not evaluate the bone phenotype at skeletally maturity. Differences in bone phenotype in growing animals sometimes indicate differences in growth rate and do not always imply changes in bone phenotype at skeletal maturity.29, 67, 68 Because we only looked at skeletally mature mice, we could not assess differences in bone growth and acquisition, although differences in cross‐sectional geometry such as total area suggest differences in rates of periosteal expansion see Discussion above. Third, the current study provided both a detailed analysis of bone along with a full analysis of the constituents of the gut microbiome as determined using 16S rRNA sequencing and therefore provides differences in phyla, bacterial diversity, and total bacterial load along with a detailed bone morphological and biomechanical analysis. We are aware of only one prior study that provides both a detailed analysis of bone morphology and a detailed analysis of the microbiome.69

Despite the novelty of the current study, some limitations must be considered when interpreting the results. The contents of the gut microbiota are dynamic and robust to external stimuli; short‐term treatments (∼1 to 2 weeks) with antibiotics generate a transient change in the gut microbiota that mostly returns to baseline when treatment is suspended.49 To examine a condition of sustained alterations in the gut microbiota during growth we treated mice with chronic antibiotics from the age of weaning until skeletal maturity. Although chronic antibiotic treatment is rarely applied to humans throughout growth and development, less drastic changes in the human gut microbiota do occur for prolonged periods of time as a result of diet or metabolic status.49 The study is further limited by not directly performing a compositional assessment of bone tissue. Direct measures of bone tissue material properties can help explain the mechanical phenotypes but more direct assays of mouse bone tissue mechanical properties than those performed here have additional limitations, especially in determination of tissue strength (see Supporting Information in Jepsen and colleagues29). The current study does not include assessment of bone turnover. Recent findings, however, suggest that the relationship between the microbiota and bone remodeling is complex and dynamic. For example, mice treated with an antibiotic cocktail of ampicillin, vancomycin, metronidazole, and neomycin show changes to serum turnover markers after 1 week of treatment, but no detectable differences from untreated animals after 1 month of treatment.22 Understanding the effects of manipulation of the microbiome on bone remodeling would therefore require examination at many points during growth/treatment. Last, the current study uses the C57BL/6J as a control strain for the TLR5KO strain, despite the TLR5KO mice containing minor remnants of B6.129S1 genetics. However, the TLR5KO congenic strain is backcrossed for 11 generations to the C57BL/6J background to ensure the two strains are over 99.9% genetically identical, thus limiting potential effects of B6.129S1 genetics.

Despite the limitations of our study, our observations regarding changes in bone tissue mechanical properties suggest a new explanation for a long‐standing clinical question. Fracture risk in some patient populations is much greater than expected from bone mineral density, a situation commonly attributed to impaired “bone quality.”70 Although the term bone quality encompasses many different characteristics of bone,71 impaired bone tissue mechanical properties are a well‐recognized component. Changes in bone tissue mechanical properties are often cited as a contributor to fracture risk that exceeds what is explained by BMD in patients with obesity, diabetes, and inflammatory bowel disease—three chronic clinical conditions that are also associated with drastic changes in the gut microbiome. Our findings in mice suggest an intriguing possibility that alterations in gut microbiota may contribute to alterations in clinical fracture risk by regulating bone tissue mechanical properties, although further studies are required to confirm this hypothesis.