The composition of the gut microbiome differs among community dwelling older people with good and poor appetite

Appetite is the collection of sensations that drive consumption of food.1 Loss of appetite, or anorexia, is a common occurrence in older people, estimated to affect 27% of those aged over 65 years in the community,2 rising to 41% in acute care.3 This has important consequences, most notably as a major component in the development of sarcopenia,4 a progressive skeletal muscle disorder involving the accelerated loss of muscle mass and function.5

Loss of appetite in older individuals can often be attributed to medical conditions, such as chronic obstructive pulmonary disease, heart or renal failure, and medication including opiates and certain antimicrobials among others.1 However, it is also due to multiple underlying determinants as part of the ageing process in the anorexia of ageing.1, 6 This includes well‐recognized alterations in mechanical and neuroendocrine functioning of the gut.4, 7 An integral component of gut neuroendocrine activity is the interaction with resident gut microbiota (bacteria, archaea, viruses, and eukaryotic microbes). For example, microbial metabolites, including short‐chain fatty acids (SCFAs), branched chain amino acids, and peptidoglycans, are critical to enterocyte function, including interacting with enteroendocrine cells in the gut wall to affect signalling.8, 9, 10 The composition of the gut microbiome is known to change with age and health status.11 Notably, alterations in its composition have been associated with frailty, anabolic resistance, and skeletal muscle function.12, 13 For example, a randomized controlled trial of a prebiotic, which modulates the gut microbiota, in older adults, reported improvements in two of Fried's frailty criteria14 (exhaustion and grip strength) and a reduction in a frailty index for those given the prebiotic vs. those given the placebo.15, 16 Research has found that frailty is negatively associated with the diversity of the gut microbiota.12, 17 This has led researchers to propose that composition and diversity of the gut microbiome may be considered a biomarker and possible influencer of healthy ageing.18

Despite a shared association with major health burdens in the older population, including sarcopenia, the relationship between the gut microbiome and appetite loss in older people is currently unexplored. The primary objective of this study was therefore to explore if there was a difference in the composition of the gut microbiota between community dwelling people aged 65 years and older reporting good or poor appetite. We used a case–control matching strategy with known microbiota correlates to reduce variance due to confounding and technical factors. Secondarily, in a subgroup of cases and controls, we explored differences in muscle mass and muscle strength as markers of sarcopenia between the two groups.

In the present study, we explored differences in the composition of the gut microbiome between cases with poor appetite and controls with a good appetite, in a community dwelling sample of mainly female members of the TwinsUK cohort aged 65 and older. Cases were matched to controls on variables known to associate with and likely influence microbiota composition including diet, frailty, socio‐economic status, and antibiotic use; this approach reduces microbiota variance attributable to other factors and balances the study design. Our findings demonstrate that there are marked differences in microbiota composition between cases with poor appetite and controls with good appetite. To our knowledge, this is the first description of an association between poor appetite and variability in the composition of the gut microbiota in community dwelling older individuals. Secondly, in this study, we sought to determine if there was a difference in markers of sarcopenia between those with good or poor appetite. We demonstrated that those with poor appetite had reduced muscle strength measured by increased chair stand time, when compared with controls with good appetite.

Anorexia drives sarcopenia via the development of undernutrition and loss of muscle mass.4, 34, 35 However, sarcopenia independent of overall weight loss has been observed in community dwelling older people with anorexia,36 and anorexia predicts muscle strength independent of muscle mass in older people post‐hospital discharge.37 Our analysis is consistent with these findings as we identified that individuals with reduced muscle strength had poor appetite compared with those with normal strength. This difference was significant despite the small sample size. There was no difference in muscle mass between cases and controls in our analysis. Of note, the most recent EWGSOP2 guidelines recommend using muscle strength as more meaningful marker of sarcopenia than mass.5 Muscle mass varies depending on the method used to measure it, overidentifies those who are slim as having sarcopenia, and can underidentify sarcopenia in those who have large mass, which includes fat, known as sarcopenic obesity.5

The gut microbiota plays an integral role in absorption and metabolism of components in an individual's diet, affecting their biochemical profile,38 and so impacting on both quantitative and qualitative nutritional health. We observe a clear difference in microbiota composition between cases and controls; including the suggestion of a reduction in Lachnospira in cases. Lachnospira have been associated with exercise training‐induced improvements in muscle strength, and some species of the genus are a notable butyrate producing bacteria (a SCFA). Higher levels of butyrate have been suggested as the mechanism linking dietary fibre intake with higher percentage of whole body lean mass and physical functioning in older adult men.39, 40 Importantly, SCFAs produced by Lachnospiraceae have also been associated with reduction in inflammatory bowel disease via interactions inducing regulatory T cells with anti‐inflammatory functions.41Lachnospira abundance is associated with vegetable‐rich/high‐fibre diets (particularly vegetarian and vegan diets).42, 43, 44 Alterations in dietary pattern are seen in older people with poor appetite, including reduction in fresh vegetables.45, 46 Appetite change with dietary alteration may therefore predispose to qualitative malnutrition, with reductions in specific macronutrients or micronutrients affecting muscle health and contributing to the onset of sarcopenia.36 Our findings may add to this theory with recognition that those with poor appetite have an altered microbiota composition and reduction in Lachnospira, which is associated with vegetable rich diets. However, in our study, cases and controls were matched on dietary similarity via a healthy eating index, which includes a vegetable intake domain. This highlights the complexity of host–microbiota interaction, with possible alternate mechanisms impacting upon Lachnospira abundance beyond dietary intake alone.18 Conversely, it may also reflect a limitation of using self‐report mechanisms for capturing dietary data.47

We also observed microbiota species richness and diversity were reduced in cases compared with controls. Although differences in species (or alpha) diversity should be interpreted with caution,48 in general lower relative species, diversity is thought to be broadly associated with ill‐health. The ELDERMET study reported significantly lower diversity of gut microbiota composition between those in a care‐home setting vs. matched community dwellers.17 Furthermore, age‐associated alterations in intestinal microbiota composition are implicated in age‐related decline of immune system function and low grade chronic inflammation (immunosenecence and inflammaging), along with anabolic resistance to dietary protein in the elderly.13, 49

While shifts in microbiota composition could simply still be reflective of the overall reduced health, and/or reduced fibre intake in cases compared with controls, the fact that we found striking difference in microbiota with appetite after carefully matching on health status and diet would certainly suggest further investigation of a potentially causal relationship. The observed changes in the gut microbiota in our analysis were from samples pre‐dating the appetite assessment by up to 8 years. This raises the possibility that disturbed host–microbiota functioning is implicated in appetite loss. Indeed, the modification of gut hormone secretion by bacteria, including glucagon‐like peptide‐1 (GLP‐1), peptide YY, leptin and ghrelin, suggests the mechanism could be via disruptive bacterial signals in these key neuroendocrine interactions.50 Particularly, alterations in circulating levels of GLP‐1, peptide YY, and Ghrelin have been observed in older individuals.4, 7, 51 On the other hand, changes to appetite in older individuals may be influencing dietary consumption, further impacting on the observed differences in overall community composition and microbial abundances in the microbiome. Certainly, gut microbiota diversity has previously been associated with both healthy27 and a varied diet.52 Therefore, there may be a potentially cyclical relationship between microbiome alterations and the development of ill‐health over time, with loss of appetite leading to altered gut microbiota, leading to disturbed microbiota–host interaction, leading to loss of appetite and so on (Figure2). Stepwise acceleration in the trajectory to worse health outcomes may occur given insults such as acute illness (Figure2)—certainly, poor appetite during hospital stay is associated with increased mortality in the 6 months post‐hospital discharge.3

This study was in a predominantly female cohort, so further analysis is needed representative of both genders. As appetite data were not collected at the same time as faecal sample, it is unclear whether appetite was also poor at the time of faecal collection, or whether gut dysbiosis may be a pre‐cursor to subsequent poor appetite. However, daily calorific intake (measured concurrently to microbiome sample) was matched between cases and controls and there was no difference between the two groups (FigureS1). The data on muscle strength and mass were collected at a prior time‐point, so it is again unclear whether appetite was also poor at this point, or prior to it, as previous studies suggest.

Another limitation to this study was the potential risk of healthy responder bias to the online appetite questionnaire. However, this was mitigated by the case–control analysis, which included matching for frailty. The use of self‐reported questionnaires to derive measures of frailty and diet is a limitation, as well as the lack of detailed information on medications other than antibiotic use, which may affect the gut microbiota (such as proton pump inhibitor or laxative use). While self‐report approaches enable the study of larger populations, future targeted studies should consider measures of objective frailty and monitor daily dietary consumption. The microbiota analysis utilized 16S rRNA metabarcoding rather than full metagenomic analysis, which would give a more comprehensive view of microbiota profile.

To our knowledge, this is the first demonstration of a difference in composition of the gut microbiome between older individuals with good and poor appetite. Individuals with a poor appetite had reduced species richness and diversity, in particular reduction of Lachnospira. Furthermore, demonstrated in subanalysis was a reduction in muscle strength for individuals with a poor appetite, compared with those with a good appetite.

Further research is needed to determine causality and its direction via longitudinal analysis of those with appetite change, associated alterations of gut microbiota composition and sarcopenia. These studies will require robust collection methods on confounders, which influence the gut microbiota including diet, medication, and frailty status. Furthermore, a more detailed analysis of the composition of the microbiota, including the Lachnospira genus as identified in this analysis, in relation to sarcopenia diagnosis and treatment responsiveness. This would inform intervention strategies with the potential to target the gut microbiota in order to manage anorexia of ageing and prevent onset or progression of sarcopenia.

N.J.C., R.B., M.N.L., H.C.R. and C.S. performed the conceptualization and methodology; R.B. and P.M.W obtained the software used; R.B. conducted the final analysis; N.J.C., M.N.L., P.M.W., and R.B. carried out the data Curation; N.J.C. and R.B. were responsible for the writing—original draft preparation; N.J.C., R.B., M.N.L., H.C.R., and C.S. did the writing—review & editing; C.S. and H.C.R. made the supervision in this study.

N.J.C and H.C.R receive support from the National Institute of Health Research (NIHR) Southampton Biomedical Research Centre. H.C.R receives support from the NIHR Applied Research Collaboration (ARC) Wessex. M.N.L is funded by an NIHR Doctoral Fellowship (RE160685). TwinsUK is funded by the Wellcome Trust (WT081878MA), Medical Research Council, European Union, the NIHR‐funded BioResource, Clinical Research Facility and Biomedical Research Centre based at Guy's and St Thomas' NHS Foundation Trust in partnership with King's College London. This work was also supported by the Chronic Disease Research Foundation. The views expressed are those of the authors and not necessarily those of the NHS, the NIHR or the Department of Health and Social Care.

Natalie Cox, Ruth Bowyer, Mary Ni Lochlainn, Philippa Wells, Helen Roberts, and Claire Steves declare that they have no conflict of interest.

The authors of this paper wish to express our sincere appreciation and gratitude to all of the hard working support staff at TwinsUK and the study participants of the cohort for donating their samples and time and make what we do possible. We thank Dr Julia K. Goodrich, Dr Ruth E. Ley, and the Cornell technical team for generating the microbial sequence data. The authors of this manuscript certify that they comply with the ethical guidelines for authorship and publishing in the Journal of Cachexia, Sarcopenia, and Muscle.53 The study was performed in accordance with the ethical standards laid down in the 1964 Declaration of Helsinki and its later amendments. Favourable ethical opinion was granted by the formerly known St Thomas' Hospital Research Ethics Committee (REC). Following restructure and merging of REC, subsequent amendments were approved by the NRES Committee London—Westminster (TwinsUK, REC ref: EC04/015, 1 November 2011); use of microbiota samples was granted NRES Committee London—Westminster (The Flora Twin Study, REC ref.: 12/LO/0227, 1 November 2011).

Cox N. J., Bowyer R. C. E., Ni Lochlainn M., Wells P. M., Roberts H. C., and Steves C. J. (2021) The composition of the gut microbiome differs among community dwelling older people with good and poor appetite, Journal of Cachexia, Sarcopenia and Muscle, 12, 368–377, 10.1002/jcsm.12683