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Understanding the role of smoking and chronic excess alcohol consumption on reduced caloric intake and the development of sarcopenia

Published online by Cambridge University Press:  24 May 2021

Konstantinos Prokopidis
Affiliation:
Department of Metabolism, Digestion and Reproduction, Faculty of Medicine, Imperial College London, White City, London, UK
Oliver C. Witard*
Affiliation:
Centre for Human and Applied Physiological Sciences, School of Basic and Medical Biosciences, Faculty of Life Sciences and Medicine, King’s College London, London, UK
*
*Corresponding author: Oliver C. Witard; email: [email protected]
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Abstract

This narrative review provides mechanistic insight into the biological link between smoking and/or chronic excess alcohol consumption, and increased risk of developing sarcopenia. Although the combination of excessive alcohol consumption and smoking is often associated with ectopic adipose deposition, this review is focused on the context of a reduced caloric intake (leading to energy deficit) that also may ensue due to either lifestyle habit. Smoking is a primary cause of periodontitis and chronic obstructive pulmonary disease that both induce swallowing difficulties, inhibit taste and mastication, and are associated with increased risk of muscle atrophy and mitochondrial dysfunction. Smoking may contribute to physical inactivity, energy deficit via reduced caloric intake, and increased systemic inflammation, all of which are factors known to suppress muscle protein synthesis rates. Moreover, chronic excess alcohol consumption may result in gut microbiota dysbiosis and autophagy-induced hyperammonemia, initiating the up-regulation of muscle protein breakdown and down-regulation of muscle protein synthesis via activation of myostatin, AMPK and REDD1, and deactivation of IGF-1. Future research is warranted to explore the link between oral healthcare management and personalised nutrition counselling in light of potential detrimental consequences of chronic smoking on musculoskeletal health outcomes in older adults. Experimental studies should investigate the impact of smoking and chronic excess alcohol consumption on the gut–brain axis, and explore biomarkers of smoking-induced oral disease progression. The implementation of behavioural change interventions and health policies regarding smoking and alcohol intake habits may mitigate the clinical and financial burden of sarcopenia on the healthcare system.

Type
Review Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Smoking and chronic excessive alcohol consumption are lifestyle choices that represent major risk factors for comorbidities in older adults, including heart (fatty liver) disease, cirrhosis, alcoholic hepatitis, chronic obstructive pulmonary disease (COPD), and various forms of cancer(Reference Verplaetse and McKee1). According to latest statistics, 28 % and 14 % of adult men and women in the UK, respectively, consume more than the recommended 14 units of alcohol per week, with 38 % between the ages of 55 and 64 years(2). Moreover, 14·4 % of adults are classified as smokers and, combined with excessive alcohol consumption, this demographic accounts for >800 000 of hospital admissions per year(3). Importantly, a higher prevalence of excessive alcohol consumption has been reported in smokers than non-smokers, thus imposing a double burden on public health(Reference Verplaetse and McKee1).

The worldwide population over the age of 65 years is rapidly increasing, with figures projected to exceed 2·1 billion by 2050. Age-related morbidities involving the musculoskeletal system are increasingly common, and include type 2 diabetes, cancer cachexia and osteoporosis. These morbidities may be perpetuated by sarcopenia, which describes the age-related decline in skeletal muscle mass and function, and which serves as a precursor for a decrease in independence, frailty and overall mortality during older age(Reference Cruz-Jentoft, Bahat and Bauer4). Sarcopenia may begin as early as the fifth decade of life. It is estimated that more than 50 million people worldwide are sarcopenic, and this figure is expected to rise to 200 million by 2050(5). This trajectory clearly presents an alarming clinical and financial challenge to the healthcare sector(5). To this end, there is considerable interest in understanding effective lifestyle interventions to promote musculoskeletal health in our ageing population(Reference Witard, Mcglory and Hamilton6); however, the impact of smoking and/or chronic excessive alcohol consumption on the development of sarcopenia has received relatively limited attention.

The potential link between chronic excessive alcohol consumption and/or systemic smoking and sarcopenia risk is clearly multi-factorial, context-specific and not fully understood. Systemic tobacco smoking and alcohol consumption may contribute to ectopic fat accumulation in skeletal muscle(Reference Stuart, Hons and Ko7) and the development of non-alcoholic fatty liver disease, often manifesting in a state of obesity. Accordingly, skeletal muscle fat infiltration (myosteatosis) may increase lipotoxicity and the subsequent release of excess reactive oxygen species (ROS) and low-grade inflammation (i.e. increased interleukin-6 (IL-6) and tumour necrosis factor (TNF)-α secretion), leading to a disruption in glucose homeostasis(Reference Dewidar, Kahl and Pa8). Myosteatosis also may interfere with energy metabolism by contributing to skeletal muscle insulin resistance and gut microbiota dysbiosis via intramuscular fat deposition(Reference Altajar and Baffy9). Moreover, in terms of muscle protein metabolism, systemic inflammation and oxidative stress are associated with muscle fibre atrophy via the impaired stimulation of muscle protein synthesis (MPS) and accelerated rates of muscle protein breakdown (MPB)(Reference Balage, Averous and Rémond10). In addition, and perhaps paradoxically to the increased risk of ectopic adipose deposition when smoking and excess alcohol intake is combined, both lifestyle choices may indirectly lead to a reduced caloric intake, undernutrition and an energy deficit(Reference Ross, Wilson and Banks11), all of which exhibit detrimental implications for muscle protein metabolism and have the potential to increase risk of sarcopenia(Reference Carbone, McClung and Pasiakos12). Thus, given that smoking and chronic excess alcohol consumption are lifestyle choices that continue over many years or decades, understanding the impact of both lifestyle habits on muscle protein metabolism is important for maintaining musculoskeletal health across the lifespan.

Multiple physiological mechanisms are understood to underpin sarcopenia, including hypogonadism, altered oral and gastrointestinal health, increased pro-inflammatory cytokines, motor unit impairments and skeletal muscle insulin resistance leading to mitochondrial dysfunction(Reference Cruz-Jentoft, Bahat and Bauer4). In addition, muscle anabolic resistance, which describes the age-related impairment in the stimulation of MPS in response to anabolic stimuli (i.e. amino acid provision and exercise/physical activity), alongside the age-related suppression of appetite and reduced energy expenditure(Reference Cruz-Jentoft, Bahat and Bauer4) all contribute to sarcopenia risk. A key factor that contributes to the development of any catabolic condition is a chronic state of energy deficit(Reference Carbone, McClung and Pasiakos12). Dietary guidelines for the management of sarcopenia typically target specific macronutrient intakes to support the remodelling of skeletal muscle proteins(Reference Rom, Kaisari and Aizenbud13), alongside the emerging roles of dietary fibre(Reference Frampton, Murphy and Frost14), omega-3 fatty acids(Reference Mcglory, Gorissen and Kamal15) and specific individual amino acids (i.e. leucine)(Reference Mitchell, Wilkinson and Phillips16) in regulating muscle protein metabolism(Reference Trumbo, Schlicker and Yates17). More recent interest has focused on the impact of lifestyle factors on sarcopenia risk, with studies measuring changes in muscle protein metabolism in response to physical inactivity(Reference Oikawa, Holloway and Phillips18Reference Howlett, Trivedi and Troop20), muscle disuse/immobilisation(Reference Breen, Stokes and Churchward-Venne21,Reference English and Paddon-Jones22) and low protein consumption(Reference Bauer, Biolo and Cederholm23) in older adults. Given the high prevalence rates of smoking and chronic alcohol intake patterns in middle/older adult populations, understanding the metabolic impact of these lifestyle habits (both individually and when combined) on muscle protein metabolism offers an important consideration to combat risk of sarcopenia. While we acknowledge that smoking and chronic excess alcohol consumption are often associated with ectopic adipose deposition(Reference Kato, Li and Ota24,Reference Steiner and Lang25) , the primary aim of this narrative review is to critically evaluate the mechanistic link between smoking and chronic excess alcohol consumption and sarcopenia risk in the specific context of a reduced caloric intake (leading to energy deficit) that also may ensue due to either lifestyle habit. We highlight the direct and indirect biological pathways that underpin the link between smoking and/or chronic excessive alcohol consumption and muscle protein metabolism in this population.

Smoking, undernutrition and sarcopenia

At the metabolic level, a key contributor of skeletal muscle catabolism leading to muscle atrophy is a chronic period of negative energy balance(Reference Carbone, McClung and Pasiakos12). This metabolic state predisposes a catabolic environment with the loss of both fat and lean tissue mass(Reference Beaudart, Sanchez-Rodriguez and Locquet26Reference Sousa-Santos, Afonso and Borges28). A negative energy balance has been shown to suppress the activation of insulin-like growth factor 1 (IGF-1) and the mechanistic target of rapamycin complex 1 (mTORC1) cascade, leading to impaired rates of MPS and increased transcription of muscle atrophy-related genes, including myostatin and ubiquitin–proteasome system (UPS) that up-regulate MPB(Reference Carbone, McClung and Pasiakos12). The stimulation of MPS is an energetically expensive process, and thus, maintenance of muscle mass during an energy deficit is metabolically challenging(Reference Carbone, McClung and Pasiakos12). Previous studies have revealed associations between smoking and lower body mass index (BMI). Moreover, pre-clinical weight loss studies have demonstrated reductions in BMI to be associated with increased smoking duration(Reference Audrain-Mcgovern and Benowitz29Reference MacKay, Gray and Pell32). Hence, a clinical link appears to exist between smoking status, undernutrition and subsequent risk of sarcopenia.

The causal mechanisms that underpin the impact of smoking on appetite, energy balance and muscle protein metabolism are detailed in Fig. 1. The anorexic effects of smoking primarily relate to the nicotine content of cigarettes(Reference Jo, Talmage and Role33). Previous studies demonstrate that food intake is modulated by β2-, β3-, β4-, α3-, α4-, α5-, α6- and α7-nicotinic acetylcholine receptor (nAChR) subtypes(Reference Gotti, Zoli and Clementi34Reference Sanjakdar, Maldoon and Marks38), which act primarily in the arcuate nucleus of the ventral hypothalamus and are responsible for the control of feeding patterns and energy expenditure(Reference Sainsbury and Zhang39,Reference Mineur, Abizaid and Rao40) . A change in energy balance with smoking occurs via neurons and appetite-related hormones in the central and peripheral nervous system that are stimulated by nAChR receptor subtypes. Specifically, nicotine administration stimulates pro-opiomelanocortin and cocaine- and amphetamine-regulated transcript(Reference Martínez De Morentin, Whittle and Fernø41,Reference Chen, Hansen and Jones42) , but down-regulates feeding-promoting neuropeptide Y and Agouti-related protein(Reference Fornari, Pedrazzi and Lippi43,Reference Hussain, Al-Daghri and Al-Attas44) . In addition, decreased food cravings during smoking are associated with lower acetylated ghrelin and enhanced leptin levels as regulatory hormones of energy balance(Reference Kroemer, Wuttig, Bidlingmaier, Zimmermann and Smolka45Reference Wittekind, Kratzsch and Mergl49). Ghrelin receptors are expressed in the nucleus accumbens and the ventral tegmental area leading to dopamine release, which exhibits reward properties(Reference Han, Frasnelli and Zeighami50,5Reference Verplaetse and McKee1). It follows that nAChR receptors decrease the food rewarding properties associated with activation of mesolimbic dopamine neurons, leading to a decreased appetite of sweet and calorically dense foods(52–5Reference Stuart, Hons and Ko7). Although dopamine receptors are stimulated via nicotine administration, studies have demonstrated a reduced nicotine-induced reward in obese individuals, suggesting a greater potential of appetite-suppressive effects on food palatability in leaner individuals(5Reference Dewidar, Kahl and Pa8,5Reference Altajar and Baffy9). Given the addictive properties of nicotine and difficulties associated with long-term smoking abstinence, smoking has the potential to facilitate a chronic period of energy deficit(Reference al’Absi, Lemieux and Hodges60). Therefore, a reduced appetite due to smoking may lead to a negative energy balance, corresponding to a muscle catabolic response and an increased risk of muscle atrophy.

Fig. 1. Proposed mechanisms underpinning the impact of smoking and nicotine administration on appetite and undernutrition. CART, cocaine- and amphetamine-regulated transcript; IGF-1, insulin-like growth factor 1; MPB, muscle protein breakdown; MPS, muscle protein synthesis; mTORC1, mammalian target of rapamycin complex 1; nAChRs, nicotinic acetylcholine receptors; NPY, neuropeptide Y; POMC, pro-opiomelanocortin; UPS, ubiquitin-proteasome system. Solid arrows denote a direct impact; broken arrows denote an indirect impact; indicates increase; indicates decrease.

Smoking also has been associated with a decrease in Bifidobacterium levels and short-chain fatty acids in the gut microbiota, suggesting that smoking may modify microbial composition(Reference Tomoda, Kubo and Asahara61). Bifidobacterium and short-chain fatty acids are considered beneficial for metabolic health by improving microbiome diversity, insulin sensitivity and the expression of pro-inflammatory cytokines, which are essential for optimal skeletal muscle function(Reference Frampton, Murphy and Frost14,Reference Chambers, Byrne and Morrison62Reference Le Chatelier, Nielsen and Qin65) . Accordingly, the interactions between nicotine administration and the gut–brain axis are important in regulating appetite, given that smoking may suppress energy intake and contribute to an energy deficit and subsequent skeletal muscle loss. Also noteworthy is the notion that the gut–brain axis is a complex mechanism that is regulated by multiple factors such as genetics, psychological, social and environmental state, nicotine metabolism, and the gut microbiota. This observation indicates a complex and multifaceted relationship between smoking and suppressed food consumption(Reference Hu, Yang and Li66,Reference Nakajima, Fukami and Yamanaka67) . Moving forward, future human studies are warranted to investigate the relationship between smoking and gastrointestinal hormone regulation to quantify the impact of smoking on muscle protein metabolism and the regulation of muscle mass with advancing age.

Smoking, oral health and muscle loss

The deterioration of oral health and consequential dental implications are restrictive for food choice and mastication, leading to reduced dietary intakes from meat, fruits and vegetables. These commonly consumed food sources are major sources of high-quality protein, vitamins, minerals and dietary fibre(Reference Brennan, Spencer and Roberts-Thomson68Reference Stenman, Ahlqwist and Björkelund72). Smoking is associated with poor oral health, which may lead to decreased oral function (e.g. swallowing problems, loss of taste) and compromised food intake, both of which may contribute to an increased incidence of sarcopenia and frailty(Reference Bakri, Tsakos and Masood73Reference Murakami, Hirano and Watanabe77). Smoking also may contribute to periodontitis, which manifests as a progressive deterioration of the teeth periodontium leading to chewing difficulties(Reference Lertpimonchai, Rattanasiri and Arj-Ong Vallibhakara78). In vivo human studies indicate the relationship between poor oral health and periodontitis(Reference Lertpimonchai, Rattanasiri and Arj-Ong Vallibhakara78,Reference Hirotomi, Yoshihara and Yano79) may lead to increases in mitochondrially derived ROS(Reference Bullon, David and Luis80) and lipopolysaccharide (LPS) levels caused by Porphyromonas gingivalis bacterial infection(Reference Wang and Ohura81,Reference Bullon, Cordero and Quiles82) and has been associated with a substantive decline in handgrip strength(Reference Hamalainen, Rantanen and Keskinen83). Accordingly, the cumulative response of periodontitis may be exacerbated with age, enhancing the development of sarcopenia through malnutrition, increased oxidative stress and inflammatory cytokine activation involved in the impaired stimulation of MPS(Reference Barreiro, Peinado and Galdiz84Reference Takahashi, Maeda and Wakabayashi90). In summary, oral health complications associated with smoking may indirectly accelerate the incidence of sarcopenia, highlighting the necessity to maintain oral hygiene during chronic periods of smoking(Reference Azzolino, Passarelli and De Angelis91). Moving forward, a multidisciplinary approach, including dental professionals, dietitians, nutritionists and geriatricians, may provide optimal oral health care management (i.e. prosthodontic rehabilitation) and personalised dietary counselling, combined with follow-up treatments(Reference Azzolino, Passarelli and De Angelis91,Reference Zenthofer, Rammelsberg and Cabrera92) . Longitudinal studies are required to characterise biomarkers of the progression of periodontitis and understand the risk factors associated with this condition(Reference Tonetti, Bottenberg and Conrads93).

Smoking, chronic obstructive pulmonary disease and muscle wasting

Smoking is considered the primary cause of COPD, which is characterised by restricted airflow and pulmonary complications(Reference Roca, Vargas and Cano94). The prevalence of COPD is associated with an increased risk of sarcopenia via systemic inflammation, lower BMI, osteoporosis, cachexia and skeletal muscle weakness(Reference Andrianopoulos, Wouters and Pinto-Plata95Reference Van Den Borst, Koster and Yu100). Interestingly, COPD may result in limited exercise capacity through enhanced muscle fatigue and may exacerbate lean mass and bone mineral density losses with advancing age(Reference Byun, Cho and Chang101Reference Eliason, Abdel-Halim and Arvidsson103). Accordingly, previous studies have reported a decline in quadriceps muscle mass and isokinetic muscle function in COPD patients compared with healthy age-matched controls(Reference Clark, Cochrane and Mackay104Reference Crul, Testelmans and Spruit107). This observation is consistent with previous research that observed reductions in type I and IIA muscle fibres, impaired mitochondrial function and skeletal muscle oxidative capacity in COPD patients, leading to age-related decrements of muscle mass and strength(Reference Agustí, Sauleda and Miralles108Reference Krüger, Dischereit and Seimetz111). However, it is worth noting that smoking per se may not be the causal factor in muscle fibre atrophy and instead may serve to contribute to muscle disuse and its subsequent consequences(Reference Degens and Alway112).

Studies also suggest an association between COPD and hypogonadism, which may be attributed to physical inactivity, weight reduction and systemic inflammation(Reference Karadag, Ozcan and Karul113,Reference Laghi, Langbein and Antonescu-Turcu114) . The gradual weight loss that is experienced in COPD patients may lead to an increased catabolic response of respiratory muscles and elevated levels of inflammatory cytokines, which exacerbates changes in body composition(Reference Lainscak, von Haehling and Doehner115Reference Puente-Maestu, Pérez-Parra and Godoy117). Although COPD is a potential contributor of sarcopenia, tobacco smoking may independently lead to impaired rates of MPS, increased oxidative stress, myostatin expression and cytokine production in skeletal muscle(Reference Madani, Alack and Richter118Reference Zhang, Liu and Shi120). Consistent with this notion, a series of studies demonstrate an up-regulation of the UPS of MPB, as reflected by increased gene expression of skeletal muscle growth inhibitors such as muscle atrophy F-Box (MAFbx/atrogin-1), muscle RING finger-1 (MuRF1) and myostatin through the deactivation of the Akt pathway in smokers versus non-smokers(Reference Petersen, Magkos and Atherton119,Reference Doucet, Russell and Léger121,Reference Foletta, White and Larsen122) . Accordingly, it has been proposed that increased oxidative stress from aldehydes, carbon monoxide, ROS and reactive nitrogen species circulate to the skeletal muscle and activate the p38 and ERK mitogen-activated protein kinase (MAPK), and the nuclear factor κB (NF-κB) signalling pathway(Reference Degens, Gayan-Ramirez and Van Hees123Reference Talhout, Opperhuizen and van Amsterdam125). This overexpression of MAPK may up-regulate the muscle-specific E3 ubiquitin ligases and lead to a greater inflammatory response and up-regulation of MPB in smokers, thus accelerating risk of sarcopenia(Reference Degens126Reference Rom, Kaisari and Aizenbud128).

Chronic alcohol consumption and skeletal muscle dysfunction

Akin to tobacco smoking, evidence exists that excessive alcohol consumption exacerbates sarcopenia risk via direct and indirect mechanisms related to impaired skeletal muscle protein metabolism(Reference Preedy, Adachi and Ueno129Reference Pruznak, Nystrom and Lang131), as depicted in Fig. 2.

Fig. 2. Indirect and direct mechanisms that may underpin the decline in muscle mass and function with smoking and excessive alcohol consumption. 4E-BP1, eukaryotic translation initiation factor 4E-binding protein 1; AMPK, AMP-activated protein kinase; IGF-1, insulin-like growth factor 1; IL-1, interleukin 1; IL-6, interleukin 6; IL-10, interleukin 10; MPB, muscle protein breakdown; MPS, muscle protein synthesis; mTOR, mammalian target of rapamycin; REDD1, regulated in development and DNA damage responses 1; S6K1, ribosomal protein S6 kinase 1; TNF-α, tumour necrosis factor-alpha; UPS, ubiquitin proteasome system. Solid arrows denote a direct impact; broken arrows denote an indirect impact; indicates increase; indicates decrease.

The association between excessive alcohol consumption and gut microbiota dysbiosis is supported by studies that reveal hepatic and intestinal inflammation in humans(Reference Capurso and Lahner132Reference Mutlu, Gillevet and Rangwala135). In particular, reduced Bacteroidetes and Lactobacillus, and increased Proteobacteria, Fusobacteria and Bacilli species are common in chronic alcoholics versus healthy patients(Reference Chen, Yang and Lu133,Reference Mutlu, Gillevet and Rangwala135) . Conversely, positive outcomes in the microbiome also have been highlighted by moderate red wine consumption, potentially due to its polyphenol content and prebiotic benefits(Reference Queipo-Ortuno, Boto-Ordonez and Murri136,Reference Bjørkhaug, Aanes and Neupane137) . Alcohol-induced microbial dysbiosis has the potential to cause or progress liver diseases and facilitate further disruptions in liver metabolism(Reference Frazier, DiBaise and McClain138Reference Schnabl and Brenner140). Hepatic damage that results from altered microbial composition, increased intestinal permeability and circulating endotoxins (e.g. LPS) may progressively lead to subsequent systemic inflammation and insulin resistance, which are common in sarcopenic populations(Reference Ghosh, Lertwattanarak and De Jesus Garduño141Reference Norman, Pirlich and Schulzke145). Increased circulating LPS levels may lead to greater pro-inflammatory cytokine secretion, inducing muscle atrophy and mitochondrial dysfunction, which is prevalent in muscle-wasting conditions(Reference Marzetti, Lorenzi and Landi146). It follows that skeletal muscle dysfunction may be mediated by a combination of cellular senescence, the up-regulation of UPS, unfolding of MPB regulators, and FoXO1/3 signalling pathways(Reference Milan, Romanello and Pescatore147).

It has been proposed that a variety of catabolic mechanisms are impacted by chronic exposure to ethanol and contribute to skeletal muscle atrophy(Reference Buchmann, Spira and König148). Increased ethanol intake (>40 g/d; 7–14 drinks per week in women–men, respectively) may cause impaired ureagenesis and hepatocyte injury, stimulating high ammonia concentrations(Reference Aagaard, Thøgersen and Grøfte149Reference Jayasekara and English155). This observation may result in hyperammonemia, which dysregulates skeletal muscle proteostasis(Reference Hong-Brown, Frost and Lang156Reference Steiner and Lang158). The increase in skeletal muscle ammonia uptake is suggested to up-regulate autophagy and impair MPS, thus increasing sarcopenia risk(Reference Fernandez-Solà, Preedy and Lang159,Reference Thapaliya, Runkana and McMullen160) . Using a rodent model, excess administration of ethanol suppressed protein synthesis rates at the whole-body (−41 %) and skeletal muscle (−75 %) level(Reference Tiernan and Ward161), and resulted in the up-regulation of muscle-specific E3 ligases, atrogin-1 and MuRF1, leading to muscle proteolysis(Reference Vary, Frost and Lang162). Furthermore, alcohol consumption following concurrent exercise may impair cellular homeostasis and trigger intramyocellular apoptosis, and subsequently inhibit post-exercise rates of MPS(Reference Smiles, Parr and Coffey163). Similarly, there is evidence that alcohol consumption inhibits MPS and up-regulates UPS and AMP-activated protein kinase (AMPK) phosphorylation during exercise recovery(Reference Barnes, Mündel and Stannard164Reference Vancampfort, Hallgren and Vandael168) and following muscle injury and immobilisation(Reference Dekeyser, Clary and Otis169,Reference Vargas and Lang170) . Accordingly, alcohol consumption may inhibit muscle adaptations to resistance training in population groups (i.e. athletes) that aim to enhance muscle mass and function. Importantly, these observations also likely apply to older adult binge drinkers, who are consequently at greater risk of sarcopenia than social drinkers(Reference Il, Ha and Lee130,Reference Silveira, De Souza and Silva171) . Moreover, the inhibitory effect of systemic inflammation on rates of MPS may be additive when excessive alcohol consumption and smoking are combined. Although human trials are lacking to evaluate the direct effect of combined tobacco and ethanol intake on skeletal muscle protein metabolism, oral flora modifications from aldehydes (i.e. acetaldehyde) via both smoking and alcohol exposure may enhance hyperammonemia and autophagy, and the expression of muscle myostatin, MAFbx and down-regulatory mechanisms of MPS(Reference Petersen, Magkos and Atherton119,Reference Husain, Scott and Reddy172) . Future work also is necessary to compare the combined impact of excess alcohol consumption and electronic cigarettes (i.e. vaping) or conventional cigarette smoking on muscle protein metabolism and musculoskeletal health outcomes in older adults.

Multiple studies have investigated the impact of chronic alcohol consumption on skeletal muscle metabolism using rodent models, and have observed reduced basal rates of MPS(Reference Korzick, Sharda and Pruznak173Reference Lang, Pruznak and Deshpande175). Both in vivo (Reference Hong-Brown, Frost and Lang156,Reference Hong-Brown, Brown and Navaratnarajah176) and in vitro (Reference Lang, Pruznak and Deshpande175,Reference Lang, Pruznak and Nystrom177,Reference Lang, Frost and Deshpande178) studies have demonstrated that alcohol consumption impairs the muscle protein synthetic machinery via decreased activation of mTORC1, ribosomal protein S6 kinase 1 (S6K1) and eukaryotic translation initiation factor 4E-binding protein 1 (4E-BP1). This down-regulation of mTORC-1 signalling with chronic alcohol consumption may be initiated via increased AMPK, REDD1 (regulated in development and DNA damage responses 1) and myostatin activation(Reference Steiner and Lang158,Reference Lang, Frost and Svanberg179) , as well as decreased plasma and muscle insulin-like growth factor I (IGF-I), which is known to activate the mTORC1 signalling pathway(Reference Lang, Pruznak and Deshpande175,Reference Nguyen, Le and Tong180) . In summary, there is accumulating evidence that inhibiting mTORC1-related mechanisms with an increase in habitual alcohol intake attenuates MPS. However, follow-up pre-clinical human trials are warranted to definitively determine the impact of chronic excess alcohol consumption on skeletal muscle protein metabolism and subsequent onset of sarcopenia.

Conclusions

Accumulating evidence suggests that health implications of smoking and chronic excessive alcohol consumption extend to the musculoskeletal system, as mediated by the down-regulation of metabolic pathways that regulate muscle protein metabolism and subsequent increased risk of sarcopenia. Chronic use of tobacco products may contribute to undernutrition through oral health and dopamine receptor dysfunction and, combined with systemic inflammation, may impair basal rates of MPS. Similarly, excessive alcohol consumption is linked to the impaired stimulation of MPS, primarily due to contraindications that occur upstream in the mTORC1 signalling pathway that are driven by the expression of pro-inflammatory cytokines. Both smoking and chronic alcohol consumption also lead to metabolic damage through underlying conditions such as periodontitis, COPD and liver diseases, which may act synergistically to inhibit skeletal muscle function. Given that chronic smoking and alcohol consumption is common in Western society, these lifestyle habits have the potential to accelerate age-related muscle atrophy and sarcopenia.

Author contributions

K.P. conceived and wrote the initial draft of the manuscript; O.C.W. reviewed and revised the manuscript.

This review received no external funding.

There are no conflicts of interest.

References

Verplaetse, TL & McKee, SA (2017) An overview of alcohol and tobacco/nicotine interactions in the human laboratory. Am J Drug Alcohol Abuse 43, 186196.CrossRefGoogle ScholarPubMed
NHS (2019) Statistics on alcohol, England – 2019. https://digital.nhs.uk/data-and-information/publications/statistical/statistics-on-alcohol/2019 (accessed October 2020).Google Scholar
Cruz-Jentoft, AJ, Bahat, G, Bauer, J, et al. (2019) Sarcopenia: revised European consensus on definition and diagnosis. Age Ageing 48, 1631.CrossRefGoogle ScholarPubMed
Cruz-Jentoft, AJ, Baeyens, JP, Bauer, JM, et al. (2010) Sarcopenia: European consensus on definition and diagnosis. Age and Ageing 39, 412423.CrossRefGoogle ScholarPubMed
Witard, OC, Mcglory, C, Hamilton, DL, et al. (2016) Growing older with health and vitality: a nexus of physical activity, exercise and nutrition. Biogerontology 17, 529546.CrossRefGoogle ScholarPubMed
Stuart, CE, Hons, B, Ko, J, et al. (2020) Implications of tobacco smoking and alcohol consumption on ectopic fat deposition in individuals after pancreatitis. Pancreas 49, 924934.CrossRefGoogle ScholarPubMed
Dewidar, B, Kahl, S, Pa, K, et al. (2020) Metabolic liver disease in diabetes – from mechanisms to clinical trials. Metabolism 111S, 154299.CrossRefGoogle ScholarPubMed
Altajar, S & Baffy, G (2020) Skeletal muscle dysfunction in the development and progression of nonalcoholic fatty liver disease. J Clin Transl Hepatol 8, 414423.CrossRefGoogle ScholarPubMed
Balage, M, Averous, J, Rémond, D, et al. (2010) Presence of low-grade inflammation impaired postprandial stimulation of muscle protein synthesis in old rats. J Nutr Biochem 21, 325331.CrossRefGoogle ScholarPubMed
Ross, LJ, Wilson, M, Banks, M, et al. (2012) Prevalence of malnutrition and nutritional risk factors in patients undergoing alcohol and drug treatment. Nutrition 28, 738743.CrossRefGoogle ScholarPubMed
Carbone, JW, McClung, JP, Pasiakos, SM, et al. (2012) Skeletal muscle responses to negative energy balance: effects of dietary protein. Adv Nutr 3, 119126.CrossRefGoogle ScholarPubMed
Rom, O, Kaisari, S, Aizenbud, D, et al. (2012) Lifestyle and sarcopenia – etiology, prevention and treatment. Rambam Maimonides Med J 3, e0024.CrossRefGoogle Scholar
Frampton, J, Murphy, KG, Frost, G, et al. (2020) Short-chain fatty acids as potential regulators of skeletal muscle metabolism and function. Nat Metab 2, 840848.CrossRefGoogle ScholarPubMed
Mcglory, C, Gorissen, SHM, Kamal, M, et al. (2019) Omega-3 fatty acid supplementation attenuates skeletal muscle disuse atrophy during two weeks of unilateral leg immobilization in healthy young women. FASEB J 33, 45864597.CrossRefGoogle ScholarPubMed
Mitchell, WK, Wilkinson, DJ, Phillips, BE, et al. (2016) Human skeletal muscle protein metabolism responses to amino acid nutrition. Adv Nutr An Int Rev J 7, 828S838S.CrossRefGoogle ScholarPubMed
Trumbo, P, Schlicker, S, Yates, AA, et al. (2002) Dietary reference intakes for energy, carbohydrate, fiber, fat, fatty acids, cholesterol, protein and amino acids. J Am Diet Assoc 102, 16211630.CrossRefGoogle Scholar
Oikawa, SY, Holloway, TM, Phillips, SM, et al. (2019) The impact of step reduction on muscle health in aging: protein and exercise as countermeasures. Front Nutr 6, 111.CrossRefGoogle ScholarPubMed
De Mello, RGB, Dalla Corte, RR, Gioscia, J, et al. (2019) Effects of physical exercise programs on sarcopenia management, dynapenia, and physical performance in the elderly: a systematic review of randomized clinical trials. J Aging Res 2019, 1959486.CrossRefGoogle ScholarPubMed
Howlett, N, Trivedi, D, Troop, NA, et al. (2019) Are physical activity interventions for healthy inactive adults effective in promoting behavior change and maintenance, and which behavior change techniques are effective? A systematic review and meta-analysis. Transl Behav Med 9, 147157.CrossRefGoogle ScholarPubMed
Breen, L, Stokes, KA, Churchward-Venne, TA, et al. (2013) Two weeks of reduced activity decreases leg lean mass and induces “anabolic resistance” of myofibrillar protein synthesis in healthy elderly. J Clin Endocrinol Metab 98, 26042612.CrossRefGoogle ScholarPubMed
English, KL & Paddon-Jones, D (2010) Protecting muscle mass and function in older adults during bed rest. Curr Opin Clin Nutr Metab Care 13, 3439.Google ScholarPubMed
Bauer, J, Biolo, G, Cederholm, T, et al. (2013) Evidence-based recommendations for optimal dietary protein intake in older people: a position paper from the PROT-AGE study group. J Am Med Dir Assoc 14, 542559.CrossRefGoogle ScholarPubMed
Kato, A, Li, Y, Ota, A, et al. (2019) Smoking results in accumulation of ectopic fat in the liver. Diabetes, Metab Syndr Obes Targets Ther 12, 10751080.CrossRefGoogle ScholarPubMed
Steiner, JL & Lang, CH (2017) Alcohol, adipose tissue and lipid dysregulation. Biomolecules 7, 16.CrossRefGoogle ScholarPubMed
Beaudart, C, Sanchez-Rodriguez, D, Locquet, M, et al. (2019) Malnutrition as a strong predictor of the onset of sarcopenia. Nutrients 11, 113.CrossRefGoogle ScholarPubMed
Hunter, GR, Singh, H, Carter, SJ, et al. (2019) Sarcopenia and its implications for metabolic health. J Obes 2019, 110.CrossRefGoogle ScholarPubMed
Sousa-Santos, AR, Afonso, C, Borges, N, et al. (2019) Factors associated with sarcopenia and undernutrition in older adults. Nutr Diet 76, 604612.CrossRefGoogle ScholarPubMed
Audrain-Mcgovern, J & Benowitz, NL (2011) Cigarette smoking, nicotine, and body weight. Clin Pharmacol Ther 90, 164168.CrossRefGoogle ScholarPubMed
Blauw, LL, Boon, MR, Rosendaal, FR, et al. (2015) Smoking is associated with increased resting energy expenditure in the general population: the NEO study. Metabolism 64, 15481555.CrossRefGoogle ScholarPubMed
Chiolero, A, Faeh, D, Paccaud, F, et al. (2008) Consequences of smoking for body weight, body fat distribution, and insulin resistance. Am J Clin Nutr 87, 801809.CrossRefGoogle ScholarPubMed
MacKay, DF, Gray, L, Pell, JP, et al. (2013) Impact of smoking and smoking cessation on overweight and obesity: Scotland-wide, cross-sectional study on 40,036 participants. BMC Public Health 13, 348.CrossRefGoogle ScholarPubMed
Jo, YH, Talmage, DA, Role, LW, et al. (2002) Nicotinic receptor-mediated effects on appetite and food intake. J Neurobiol 53, 618632.CrossRefGoogle ScholarPubMed
Gotti, C, Zoli, M, Clementi, F, et al. (2006) Brain nicotinic acetylcholine receptors: native subtypes and their relevance. Trends Pharmacol Sci 27, 482491.CrossRefGoogle ScholarPubMed
Dani, JA & Bertrand, D (2007) Nicotinic acetylcholine receptors and nicotinic cholinergic mechanisms of the central nervous system. Annu Rev Pharmacol Toxicol 47, 699729.CrossRefGoogle ScholarPubMed
McFadden, KL, Cornier, M-A, Tregellas, JR, et al. (2014) The role of alpha-7 nicotinic receptors in food intake behaviors. Front Psychol 5, 553.CrossRefGoogle ScholarPubMed
Picciotto, MR & Mineur, YS (2014) Molecules and circuits involved in nicotine addiction: the many faces of smoking. Neuropharmacology 76, 545553.CrossRefGoogle ScholarPubMed
Sanjakdar, SS, Maldoon, PP, Marks, MJ, et al. (2015) Differential roles of α6β2∗ and α4β2∗ neuronal nicotinic receptors in nicotine- and cocaine-conditioned reward in mice. Neuropsychopharmacology 40, 350360.CrossRefGoogle ScholarPubMed
Sainsbury, A & Zhang, L (2010) Role of the arcuate nucleus of the hypothalamus in regulation of body weight during energy deficit. Mol Cell Endocrinol 316, 109119.CrossRefGoogle ScholarPubMed
Mineur, YS, Abizaid, A, Rao, Y, et al. (2011) Nicotine decreases food intake through activation of POMC neurons. Science 332, 13301332.CrossRefGoogle ScholarPubMed
Martínez De Morentin, PB, Whittle, AJ, Fernø, J, et al. (2012) Nicotine induces negative energy balance through hypothalamic AMP-activated protein kinase. Diabetes 61, 807817.CrossRefGoogle ScholarPubMed
Chen, H, Hansen, MJ, Jones, JE, et al. (2006) Cigarette smoke exposure reprograms the hypothalamic neuropeptide Y axis to promote weight loss. Am J Respir Crit Care Med 173, 12481254.CrossRefGoogle ScholarPubMed
Fornari, A, Pedrazzi, P, Lippi, G, et al. (2007) Nicotine withdrawal increases body weight, neuropeptide Y and Agouti-related protein expression in the hypothalamus and decreases uncoupling protein-3 expression in the brown adipose tissue in high-fat fed mice. Neurosci Lett 411, 7276.CrossRefGoogle ScholarPubMed
Hussain, T, Al-Daghri, NM, Al-Attas, OS, et al. (2012) Plasma neuropeptide Y levels relate cigarette smoking and smoking cessation to body weight regulation. Regul Pept 176, 2227.CrossRefGoogle ScholarPubMed
Kroemer, NB, Wuttig, F, Bidlingmaier, M, Zimmermann, US, Smolka, MN et al. (2015) Nicotine enhances modulation of food-cue reactivity by leptin and ghrelin in the ventromedial prefrontal cortex. Addict Biol 20, 832–344.CrossRefGoogle ScholarPubMed
Kokkinos, A, Tentolouris, N, Kyriakaki, E, et al. (2007) Differentiation in the short- and long-term effects of smoking on plasma total ghrelin concentrations between male nonsmokers and habitual smokers. Metabolism 56, 523527.CrossRefGoogle Scholar
Koopmann, A, Bez, J, Lemenager, T, et al. (2015) Effects of cigarette smoking on plasma concentration of the appetite-regulating peptide ghrelin. Ann Nutr Metab 66, 155161.CrossRefGoogle ScholarPubMed
Li, MD & Kane, JK (2003) Effect of nicotine on the expression of leptin and forebrain leptin receptors in the rat. Brain Res 991, 222231.CrossRefGoogle ScholarPubMed
Wittekind, DA, Kratzsch, J, Mergl, R, et al. (2019) Higher fasting ghrelin serum levels in active smokers than in former and never-smokers. World J Biol Psychiatry 21, 748756.CrossRefGoogle ScholarPubMed
Han, JE, Frasnelli, J, Zeighami, Y, et al. (2018) Ghrelin enhances food odor conditioning in healthy humans: an fMRI study. Cell Rep 25, 26432652.CrossRefGoogle Scholar
Jerlhag, E & Engel, JA (2011) Ghrelin receptor antagonism attenuates nicotine-induced locomotor stimulation, accumbal dopamine release and conditioned place preference in mice. Drug Alcohol Depend 117, 126131.CrossRefGoogle ScholarPubMed
Kenny, PJ & Markou, A (2006) Nicotine self-administration acutely activates brain reward systems and induces a long-lasting increase in reward sensitivity. Neuropsychopharmacology 31, 12031211.CrossRefGoogle ScholarPubMed
Jerlhag, E, Egecioglu, E, Dickson, SL, et al. (2008) Alpha-conotoxin MII-sensitive nicotinic acetylcholine receptors are involved in mediating the ghrelin-induced locomotor stimulation and dopamine overflow in nucleus accumbens. Eur Neuropsychopharmacol 18, 508518.CrossRefGoogle ScholarPubMed
Blum, K, Liu, Y, Shriner, R, et al. (2012) Reward circuitry dopaminergic activation regulates food and drug craving behavior. Curr Pharm Des 17, 11581167.CrossRefGoogle Scholar
Zoli, M & Picciotto, MR (2012) Nicotinic regulation of energy homeostasis. Nicotine Tob Res 14, 12701290.CrossRefGoogle ScholarPubMed
Criscitelli, K & Avena, NM (2016) The neurobiological and behavioral overlaps of nicotine and food addiction. Prev Med (Baltim) 92, 8289.CrossRefGoogle ScholarPubMed
Stojakovic, A, Espinosa, EP, Farhad, OT, et al. (2017) Effects of nicotine on homeostatic and hedonic components of food intake. J Endocrinol 235, R13R31.CrossRefGoogle ScholarPubMed
Blendy, JA, Strasser, A, Walters, CL, et al. (2005) Reduced nicotine reward in obesity: cross-comparison in human and mouse. Psychopharmacology (Berl) 180, 306315.CrossRefGoogle ScholarPubMed
Rupprecht, LE, Donny, EC, Sveda, AF, et al. (2015) Obese smokers as a potential subpopulation of risk in tobacco reduction policy. Yale J Biol Med 88, 289294.Google ScholarPubMed
al’Absi, M, Lemieux, A, Hodges, JS, et al. (2019) Circulating orexin changes during withdrawal are associated with nicotine craving and risk for smoking relapse. Addict Biol 24, 743753.Google ScholarPubMed
Tomoda, K, Kubo, K, Asahara, T, et al. (2011) Cigarette smoke decreases organic acids levels and population of bifidobacterium in the caecum of rats. J Toxicol Sci 36, 261266.Google ScholarPubMed
Chambers, ES, Byrne, CS, Morrison, DJ, et al. (2019) Dietary supplementation with inulin-propionate ester or inulin improves insulin sensitivity in adults with overweight and obesity with distinct effects on the gut microbiota, plasma metabolome and systemic inflammatory responses: a randomised cross-over t. Gut 68, 14301438.CrossRefGoogle ScholarPubMed
Delzenne, NM, Knudsen, C, Beaumont, M, et al. (2019) Contribution of the gut microbiota to the regulation of host metabolism and energy balance: a focus on the gut-liver axis. Proc Nutr Soc 78, 319328.CrossRefGoogle Scholar
Hiippala, K, Jouhten, H, Ronkainen, A, et al. (2018) The potential of gut commensals in reinforcing intestinal barrier function and alleviating inflammation. Nutrients 10, 988.CrossRefGoogle ScholarPubMed
Le Chatelier, E, Nielsen, T, Qin, J, et al. (2013) Richness of human gut microbiome correlates with metabolic markers. Nature 500, 541546.CrossRefGoogle ScholarPubMed
Hu, T, Yang, Z, Li, MD, et al. (2018) Pharmacological effects and regulatory mechanisms of tobacco smoking effects on food intake and weight control. J Neuroimmune Pharmacol 13, 453466.Google ScholarPubMed
Nakajima, M, Fukami, T, Yamanaka, H, et al. (2006) Comprehensive evaluation of variability in nicotine metabolism and CYP2A6 polymorphic alleles in four ethnic populations. Clin Pharmacol Ther 80, 282297.CrossRefGoogle ScholarPubMed
Brennan, DS, Spencer, AJ, Roberts-Thomson, KF, et al. (2008) Tooth loss, chewing ability and quality of life. Qual Life Res 17, 227235.Google ScholarPubMed
Hung, HC, Colditz, G, Joshipura, KJ, et al. (2005) The association between tooth loss and the self-reported intake of selected CVD-related nutrients and foods among US women. Community Dent Oral Epidemiol 33, 167173.CrossRefGoogle ScholarPubMed
Gil-Montoya, JA, de Mello, ALF, Barrios, R, et al. (2015) Oral health in the elderly patient and its impact on general well-being: a nonsystematic review. Clin Interv Aging 10, 461467.CrossRefGoogle ScholarPubMed
Golpasand Hagh, L, Zakavi, F, Ansarifar, S, et al. (2013) Association of dental caries and salivary sIgA with tobacco smoking. Aust Dent J 58, 219223.Google ScholarPubMed
Stenman, U, Ahlqwist, M, Björkelund, C, et al. (2012) Oral health-related quality of life – associations with oral health and conditions in Swedish 70-year-old individuals. Gerodontology 29, 17.CrossRefGoogle ScholarPubMed
Bakri, NN, Tsakos, G, Masood, M, et al. (2018) Smoking status and oral health-related quality of life among adults in the United Kingdom. Br Dent J 225, 153158.CrossRefGoogle ScholarPubMed
Steffl, M, Bohannon, RW, Petr, M, et al. (2015) Relation between cigarette smoking and sarcopenia: meta-analysis. Physiol Res 64, 419426.CrossRefGoogle ScholarPubMed
Tanaka, T, Takahashi, K, Hirano, H, et al. (2018) Oral frailty is a risk factor for physical frailty and mortality in community-dwelling elderly. J Gerontol Ser A Biol Sci Med Sci 73, 16611667.CrossRefGoogle ScholarPubMed
Zhu, Y & Hollis, JH (2014) Tooth loss and its association with dietary intake and diet quality in American adults. J Dent 42, 14281435.Google ScholarPubMed
Murakami, M, Hirano, H, Watanabe, Y, et al. (2015) Relationship between chewing ability and sarcopenia in Japanese community-dwelling older adults. Geriatr Gerontol Int 15, 10071012.CrossRefGoogle ScholarPubMed
Lertpimonchai, A, Rattanasiri, S, Arj-Ong Vallibhakara, S, et al. (2017) The association between oral hygiene and periodontitis: a systematic review and meta-analysis. Int Dent J 67, 332343.CrossRefGoogle ScholarPubMed
Hirotomi, T, Yoshihara, A, Yano, M, et al. (2002) Longitudinal study on periodontal conditions in healthy elderly people in Japan. Community Dent Oral Epidemiol 30, 409417.CrossRefGoogle ScholarPubMed
Bullon, P, David, M, Luis, J, et al. (2011) Mitochondrial dysfunction promoted by Porphyromonas gingivalis lipopolysaccharide as a possible link between cardiovascular disease and periodontitis. Free Radic Biol Med 50, 13361343.CrossRefGoogle ScholarPubMed
Wang, PL & Ohura, K (2002) Porphyromonas gingivalis lipopolysaccharide signaling in gingival fibroblasts-CD14 and toll-like receptors. Crit Rev Oral Biol Med 13, 132142.CrossRefGoogle ScholarPubMed
Bullon, P, Cordero, MD, Quiles, JL, et al. (2012) Autophagy in periodontitis patients and gingival fibroblasts: unraveling the link between chronic diseases and inflammation. BMC Med 10, 122.CrossRefGoogle ScholarPubMed
Hamalainen, P, Rantanen, T, Keskinen, M, et al. (2004) Oral health status and change in handgrip strength over a 5-year period in 80-year-old people. Gerodontology 21, 155160.CrossRefGoogle Scholar
Barreiro, E, Peinado, VI, Galdiz, JB, et al. (2010) Cigarette smoke-induced oxidative stress: a role in chronic obstructive pulmonary disease skeletal muscle dysfunction. Am J Respir Crit Care Med 182, 477488.CrossRefGoogle ScholarPubMed
Borges, I, Machado Moreira, EA, Filho, DW, et al. (2007) Proinflammatory and oxidative stress markers in patients with periodontal disease. Mediators Inflamm 2007, 15.CrossRefGoogle ScholarPubMed
Castreján-Pérez, RC, Borges-Yá˜ez, SA, Gutiérrez-Robledo, LM, et al. (2012) Oral health conditions and frailty in Mexican community-dwelling elderly: a cross sectional analysis. BMC Public Health 12, 773.CrossRefGoogle Scholar
D’Aiuto, F, Nibali, L, Parkar, M, et al. (2010) Oxidative stress, systemic inflammation, and severe periodontitis. J Dent Res 89, 12411246.CrossRefGoogle Scholar
Lamster, IB, Asadourian, L, Del Carmen, T, et al. (2000) The aging mouth: differentiating normal aging from disease. Periodontol 72, 96107.CrossRefGoogle Scholar
Neves, CDC, Lacerda, ACR, Lage, VKS, et al. (2016) Oxidative stress and skeletal muscle dysfunction are present in healthy smokers. Braz J Med Biol Res 49, 17.CrossRefGoogle ScholarPubMed
Takahashi, M, Maeda, K, Wakabayashi, H, et al. (2018) Prevalence of sarcopenia and association with oral health-related quality of life and oral health status in older dental clinic outpatients. Geriatr Gerontol Int 18, 915921.CrossRefGoogle ScholarPubMed
Azzolino, D, Passarelli, PC, De Angelis, P, et al. (2019) Poor oral health as a determinant of malnutrition and sarcopenia. Nutrients 11, 117.CrossRefGoogle ScholarPubMed
Zenthofer, A, Rammelsberg, P, Cabrera, T, et al. (2015) Prosthetic rehabilitation of edentulism prevents malnutrition in nursing home residents. Int J Prosthodont 28, 198200.CrossRefGoogle Scholar
Tonetti, MS, Bottenberg, P, Conrads, G, et al. (2017) Dental caries and periodontal diseases in the ageing population: call to action to protect and enhance oral health and well-being as an essential component of healthy ageing – consensus report of group 4 of the joint EFP/ORCA workshop on the boundaries between caries and periodontal diseases. J Clin Periodontol 44, S135S144.Google ScholarPubMed
Roca, J, Vargas, C, Cano, I, et al. (2014) Chronic obstructive pulmonary disease heterogeneity: challenges for health risk assessment, stratification and management. J Transl Med 12, 111.CrossRefGoogle ScholarPubMed
Andrianopoulos, V, Wouters, EFM, Pinto-Plata, VM, et al. (2015) Prognostic value of variables derived from the six-minute walk test in patients with COPD: results from the ECLIPSE study. Respir Med 109, 11381146.Google ScholarPubMed
Barbar, MPF, Carpagnan, GE, Spanevellol, A, et al. (2007) Inflammation, oxidative stress and systemic effects in mild chronic obstructive disease. Int J Immunopathol Pharmacol 20, 753763.Google Scholar
Franco, CB, Paz-Filho, G, Gomes, PE, et al. (2009) Chronic obstructive pulmonary disease is associated with osteoporosis and low levels of vitamin D. Osteoporos Int 20, 18811887.CrossRefGoogle ScholarPubMed
Gan, WQ, Man, SFP, Senthilselvan, A, et al. (2004) Association between chronic obstructive pulmonary disease and systemic inflammation: a systematic review and a meta-analysis. Thorax 59, 574580.CrossRefGoogle ScholarPubMed
Jagoe, RT & Engelen, MPKJ (2003) Muscle wasting and changes in muscle protein metabolism in chronic obstructive pulmonary disease. Eur Respir J 22, 5263.CrossRefGoogle Scholar
Van Den Borst, B, Koster, A, Yu, B, et al. (2011) Is age-related decline in lean mass and physical function accelerated by obstructive lung disease or smoking? Thorax 66, 961969.CrossRefGoogle ScholarPubMed
Byun, MK, Cho, EN, Chang, J, et al. (2017) Sarcopenia correlates with systemic inflammation in COPD. Int J COPD 12, 669675.CrossRefGoogle ScholarPubMed
Munhoz da Rocha Lemos Costa, T, Costa, FM, Jonasson, TH, et al. (2018) Borba VZC. Body composition and sarcopenia in patients with chronic obstructive pulmonary disease. Endocrine 60, 95102.Google ScholarPubMed
Eliason, G, Abdel-Halim, S, Arvidsson, B, et al. (2009) Physical performance and muscular characteristics in different stages of COPD. Scand J Med Sci Sport 19, 865870.CrossRefGoogle ScholarPubMed
Clark, CJ, Cochrane, LM, Mackay, E, et al. (2000) Erratum: skeletal muscle strength and endurance in patients with mild COPD and the effects of weight training. Eur Respir J 15, 816.CrossRefGoogle Scholar
Allaire, J, Maltais, F, Leblanc, P, et al. (2002) Lipofuscin accumulation in the vastus lateralis muscle in patients with chronic obstructive pulmonary disease. Muscle Nerve 25, 383389.CrossRefGoogle ScholarPubMed
Allaire, J, Maltais, F, Doyon, JF, et al. (2004) Peripheral muscle endurance and the oxidative profile of the quadriceps in patients with COPD. Thorax 59, 673678.CrossRefGoogle ScholarPubMed
Crul, T, Testelmans, D, Spruit, MA, et al. (2010) Gene expression profiling in vastus lateralis muscle during an acute exacerbation of COPD. Cell Physiol Biochem 25, 491500.CrossRefGoogle ScholarPubMed
Agustí, AGN, Sauleda, J, Miralles, C, et al. (2002) Skeletal muscle apoptosis and weight loss in chronic obstructive pulmonary disease. Am J Respir Crit Care Med 166, 485489.CrossRefGoogle ScholarPubMed
Gosker, HR, van Mameren, H, van Dijk, PJ, et al. (2002) Skeletal muscle fibre-type shifting and metabolic profile in patients with chronic obstructive pulmonary disease. Eur Respir J 19, 617625.CrossRefGoogle ScholarPubMed
Meyer, A, Zoll, J, Charles, AL, et al. (2013) Skeletal muscle mitochondrial dysfunction during chronic obstructive pulmonary disease: central actor and therapeutic target. Exp Physiol 98, 10631078.CrossRefGoogle ScholarPubMed
Krüger, K, Dischereit, G, Seimetz, M, et al. (2015) Time course of cigarette smoke-induced changes of systemic inflammation and muscle structure. Am J Physiol Lung Cell Mol Physiol 309, L119L128.CrossRefGoogle ScholarPubMed
Degens, H & Alway, SE (2006) Control of muscle size during disuse, disease, and aging. Int J Sports Med 27, 9499.CrossRefGoogle Scholar
Karadag, F, Ozcan, H, Karul, AB, et al. (2009) Sex hormone alterations and systemic inflammation in chronic obstructive pulmonary disease. Int J Clin Pract 63, 275281.CrossRefGoogle ScholarPubMed
Laghi, F, Langbein, WE, Antonescu-Turcu, A, et al. (2005) Respiratory and skeletal muscles in hypogonadal men with chronic obstructive pulmonary disease. Am J Respir Crit Care Med 171, 598605.CrossRefGoogle ScholarPubMed
Lainscak, M, von Haehling, S, Doehner, W, et al. (2011) Body mass index and prognosis in patients hospitalized with acute exacerbation of chronic obstructive pulmonary disease. J Cachexia Sarcopenia Muscle 2, 8186.CrossRefGoogle ScholarPubMed
Makarevich, AE & Lemiasheuskaya, S (2015) Dynamics of body composition in male patients during chronic obstructive pulmonary disease (COPD) development. Pneumonol Alergol Pol 83, 424430.Google ScholarPubMed
Puente-Maestu, L, Pérez-Parra, J, Godoy, R, et al. (2009) Abnormal mitochondrial function in locomotor and respiratory muscles of COPD patients. Eur Respir J 33, 10451052.CrossRefGoogle ScholarPubMed
Madani, A, Alack, K, Richter, MJ, et al. (2018) Immune-regulating effects of exercise on cigarette smoke-induced inflammation. J Inflamm Res 11, 155167.Google ScholarPubMed
Petersen, AMW, Magkos, F, Atherton, P, et al. (2007) Smoking impairs muscle protein synthesis and increases the expression of myostatin and MAFbx in muscle. Am J Physiol Endocrinol Metab 293, 843849.CrossRefGoogle ScholarPubMed
Zhang, J, Liu, Y, Shi, J, et al. (2002) Side-stream cigarette smoke induces dose-response in systemic inflammatory cytokine production and oxidative stress. Exp Biol Med 227, 823829.CrossRefGoogle ScholarPubMed
Doucet, M, Russell, AP, Léger, B, et al. (2007) Muscle atrophy and hypertrophy signaling in patients with chronic obstructive pulmonary disease. Am J Respir Crit Care Med 176, 261269.CrossRefGoogle ScholarPubMed
Foletta, VC, White, LJ, Larsen, AE, et al. (2011) The role and regulation of MAFbx/atrogin-1 and MuRFl in skeletal muscle atrophy. Pflugers Arch Eur J Physiol 461, 325335.Google Scholar
Degens, H, Gayan-Ramirez, G, Van Hees, HWH, et al. (2015) Smoking-induced skeletal muscle dysfunction: from evidence to mechanisms. Am J Respir Crit Care Med 191, 620625.CrossRefGoogle ScholarPubMed
Krüger, K, Seimetz, M, Ringseis, R, et al. (2018) Exercise training reverses inflammation and muscle wasting after tobacco smoke exposure. Am J Physiol Regul Integr Comp Physiol 314, R366R376.Google ScholarPubMed
Talhout, R, Opperhuizen, A, van Amsterdam, JGC, et al. (2007) Role of acetaldehyde in tobacco smoke addiction. Eur Neuropsychopharmacol 17, 627636.CrossRefGoogle ScholarPubMed
Degens, H (2010) The role of systemic inflammation in age-related muscle weakness and wasting: review. Scand J Med Sci Sport 20, 2838.CrossRefGoogle Scholar
Liu, Q, Xu, WG, Luo, Y, et al. (2011) Cigarette smoke-induced skeletal muscle atrophy is associated with up-regulation of USP-19 via p38 and ERK MAPKs. J Cell Biochem 112, 23072316.CrossRefGoogle ScholarPubMed
Rom, O, Kaisari, S, Aizenbud, D, et al. (2012) Sarcopenia and smoking: a possible cellular model of cigarette smoke effects on muscle protein breakdown. Ann N Y Acad Sci 1259, 4753.CrossRefGoogle ScholarPubMed
Preedy, VR, Adachi, J, Ueno, Y, et al. (2001) Alcoholic skeletal muscle myopathy: definitions, features, contribution of neuropathy, impact and diagnosis. Eur J Neurol 8, 677687.CrossRefGoogle ScholarPubMed
Il, Yoo J, Ha, YC, Lee, YK, et al. (2017) High prevalence of sarcopenia among binge drinking elderly women: a nationwide population-based study. BMC Geriatr 17, 114.Google Scholar
Pruznak, AM, Nystrom, J, Lang, CH, et al. (2013) Direct central nervous system effect of alcohol alters synthesis and degradation of skeletal muscle protein. Alcohol Alcohol 48, 138145.CrossRefGoogle ScholarPubMed
Capurso, G & Lahner, E (2017) The interaction between smoking, alcohol and the gut microbiome. Best Pract Res Clin Gastroenterol 31, 579588.CrossRefGoogle ScholarPubMed
Chen, Y, Yang, F, Lu, H, et al. (2011) Characterization of fecal microbial communities in patients with liver cirrhosis. Hepatology 54, 562572.CrossRefGoogle ScholarPubMed
Leclercq, S, Matamoros, S, Cani, PD, et al. (2014) Intestinal permeability, gut-bacterial dysbiosis, and behavioral markers of alcohol-dependence severity. Proc Natl Acad Sci U S A 111, E4485E4493.CrossRefGoogle ScholarPubMed
Mutlu, EA, Gillevet, PM, Rangwala, H, et al. (2012) Colonic microbiome is altered in alcoholism. Am J Physiol Gastrointest Liver Physiol 302, G966G978.CrossRefGoogle ScholarPubMed
Queipo-Ortuno, MI, Boto-Ordonez, M, Murri, M, et al. (2012) Influence of red wine polyphenols and ethanol on the gut microbiota. Am J Clin Nut 95, 13231334.CrossRefGoogle ScholarPubMed
Bjørkhaug, ST, Aanes, H, Neupane, SP, et al. (2019) Characterization of gut microbiota composition and functions in patients with chronic alcohol overconsumption. Gut Microbes 10, 663675.CrossRefGoogle ScholarPubMed
Frazier, TH, DiBaise, JK, McClain, CJ, et al. (2011) Gut microbiota, intestinal permeability, obesity-induced inflammation, and liver injury. J Parenter Enter Nutr 35, 14S20S.CrossRefGoogle ScholarPubMed
Meroni, M, Longo, M, Dongiovanni, P, et al. (2019) Alcohol or gut microbiota: who is the guilty? Int J Mol Sci 20, 122.CrossRefGoogle ScholarPubMed
Schnabl, B & Brenner, DA (2014) Interactions between the intestinal microbiome and liver diseases. Gastroenterology 146, 15131524.CrossRefGoogle ScholarPubMed
Ghosh, S, Lertwattanarak, R, De Jesus Garduño, J, et al. (2015) Elevated muscle TLR4 expression and metabolic Endotoxemia in human aging. J Gerontol Ser A Biol Sci Med Sci 70, 232246.CrossRefGoogle ScholarPubMed
Hartmann, P, Seebauer, CT, Schnabl, B, et al. (2015) Alcoholic liver disease: the gut microbiome and liver cross talk. Alcohol Clin Exp Res 39, 763775.CrossRefGoogle ScholarPubMed
Kakiyama, G, Pandak, WM, Gillevet, PM, et al. (2013) Modulation of the fecal bile acid profile by gut microbiota in cirrhosis. J Hepatol 58, 949955.CrossRefGoogle ScholarPubMed
Liang, H, Hussey, SE, Sanchez-Avila, A, et al. (2013) Effect of lipopolysaccharide on inflammation and insulin action in human muscle. PLoS One 8, 815.Google ScholarPubMed
Norman, K, Pirlich, M, Schulzke, JD, et al. (2012) Increased intestinal permeability in malnourished patients with liver cirrhosis. Eur J Clin Nutr 66, 11161119.CrossRefGoogle ScholarPubMed
Marzetti, E, Lorenzi, M, Landi, F, et al. (2017) Altered mitochondrial quality control signaling in muscle of old gastric cancer patients with cachexia. Exp Gerontol 87, 9299.CrossRefGoogle ScholarPubMed
Milan, G, Romanello, V, Pescatore, F, et al. (2015) Regulation of autophagy and the ubiquitin-proteasome system by the FoxO transcriptional network during muscle atrophy. Nat Commun 6, 114.CrossRefGoogle ScholarPubMed
Buchmann, N, Spira, D, König, M, et al. (2019) Problematic drinking in the old and its association with muscle mass and muscle function in type II diabetes. Sci Rep 9, 18.CrossRefGoogle ScholarPubMed
Aagaard, NK, Thøgersen, T, Grøfte, T, et al. (2004) Alcohol acutely down-regulates urea synthesis in normal men. Alcohol Clin Exp Res 28, 697701.CrossRefGoogle ScholarPubMed
Dasarathy, S, Mookerjee, RP, Rackayova, V, et al. (2017) Ammonia toxicity: from head to toe? Metab Brain Dis 32, 529538.CrossRefGoogle ScholarPubMed
Glavind, E, Aagaard, NK, Grønbæk, H, et al. (2017) Time course of compromised urea synthesis in patients with alcoholic hepatitis. J Hepatol 66, S81.CrossRefGoogle Scholar
McDaniel, J, Davuluri, G, Hill, EA, et al. (2016) Hyperammonemia results in reduced muscle function independent of muscle mass. Am J Physiol Gastrointest Liver Physiol 310, G163G170.CrossRefGoogle ScholarPubMed
Qiu, J, Tsien, C, Thapalaya, S, et al. (2012) Hyperammonemia-mediated autophagy in skeletal muscle contributes to sarcopenia of cirrhosis. Am J Physiol Endocrinol Metab 303, E983E993.CrossRefGoogle Scholar
Stern, RA & Mozdziak, PE (2019) Differential ammonia metabolism and toxicity between avian and mammalian species, and effect of ammonia on skeletal muscle: a comparative review. J Anim Physiol Anim Nutr (Berl) 103, 774785.CrossRefGoogle ScholarPubMed
Jayasekara, H, English, DR, et al. (2014) Alcohol consumption over time and risk of death: a systematic review and meta-analysis. Am J Epidemiol 179, 10491059.CrossRefGoogle ScholarPubMed
Hong-Brown, LQ, Frost, RA, Lang, CH, et al. (2001) Alcohol impairs protein synthesis and degradation in cultured skeletal muscle cells. Alcohol Clin Exp Res 25, 13731382.CrossRefGoogle ScholarPubMed
Kant, S, Davuluri, G, Alchirazi, KA, et al. (2019) Ethanol sensitizes skeletal muscle to ammonia-induced molecular perturbations. J Biol Chem 294, 72317244.CrossRefGoogle ScholarPubMed
Steiner, JL & Lang, CH (2015) Dysregulation of skeletal muscle protein metabolism by alcohol. Am J Physiol Endocrinol Metab 308, E699E712.CrossRefGoogle Scholar
Fernandez-Solà, J, Preedy, VR, Lang, CH, et al. (2007) Molecular and cellular events in alcohol-induced muscle disease. Alcohol Clin Exp Res 31, 19531962.CrossRefGoogle ScholarPubMed
Thapaliya, S, Runkana, A, McMullen, MR, et al. (2014) Alcohol-induced autophagy contributes to loss in skeletal muscle mass. Autophagy 10, 677690.CrossRefGoogle Scholar
Tiernan, JM & Ward, LC (1986) Acute effects of ethanol on protein synthesis in the rat. Alcohol Alcohol 21, 171179.Google ScholarPubMed
Vary, TC, Frost, RA, Lang, CH, et al. (2008) Acute alcohol intoxication increases atrogin-1 and MuRF1 mRNA without increasing proteolysis in skeletal muscle. Am J Physiol Integr Comp Physiol 294, 17771789.CrossRefGoogle ScholarPubMed
Smiles, WJ, Parr, EB, Coffey, VG, et al. (2016) Protein coingestion with alcohol following strenuous exercise attenuates alcohol-induced intramyocellular apoptosis and inhibition of autophagy. Am J Physiol Endocrinol Metab 311, E836E849.CrossRefGoogle ScholarPubMed
Barnes, MJ, Mündel, T, Stannard, SR, et al. (2010) Post-exercise alcohol ingestion exacerbates eccentric-exercise induced losses in performance. Eur J Appl Physiol 108, 10091014.CrossRefGoogle Scholar
Vingren, JL, Hill, DW, Buddhadev, H, et al. (2013) Postresistance exercise ethanol ingestion and acute testosterone bioavailability. Med Sci Sports Exerc 45, 18251832.CrossRefGoogle ScholarPubMed
Parr, EB, Camera, DM, Areta, JL, et al. (2014) Alcohol ingestion impairs maximal post-exercise rates of myofibrillar protein synthesis following a single bout of concurrent training. PLoS One 9, 19.CrossRefGoogle ScholarPubMed
Lakićević, N (2019) The effects of alcohol consumption on recovery following resistance exercise: a systematic review. J Funct Morphol Kinesiol 4, 41.CrossRefGoogle Scholar
Vancampfort, D, Hallgren, M, Vandael, H, et al. (2020) Functional exercise capacity in inpatients with alcohol use disorder versus healthy controls: a pilot study. Alcohol 82, 4752.CrossRefGoogle ScholarPubMed
Dekeyser, GJ, Clary, CR, Otis, JS, et al. (2013) Chronic alcohol ingestion delays skeletal muscle regeneration following injury. Regen Med Res 1, 2.CrossRefGoogle ScholarPubMed
Vargas, R & Lang, CH (2008) Alcohol accelerates loss of muscle and impairs recovery of muscle mass resulting from disuse atrophy. Alcohol Clin Exp Res 32, 128137.Google ScholarPubMed
Silveira, EA, De Souza, JD, Silva, A, et al. (2020) What are the factors associated with sarcopenia-related variables in adult women with severe obesity? Arch Public Heal 78, 71.CrossRefGoogle ScholarPubMed
Husain, K, Scott, BR, Reddy, SK, et al. (2001) Chronic ethanol and nicotine interaction on rat tissue antioxidant defense system. Alcohol 25, 8997.CrossRefGoogle ScholarPubMed
Korzick, DH, Sharda, DR, Pruznak, AM, et al. (2013) Aging accentuates alcohol-induced decrease in protein synthesis in gastrocnemius. Am J Physiol Regul Integr Comp Physiol 304, R887R898.Google ScholarPubMed
Lang, CH, Frost, RA, Vary, TC, et al. (2007) Skeletal muscle protein synthesis and degradation exhibit sexual dimorphism after chronic alcohol consumption but not acute intoxication. Am J Physiol Endocrinol Metab 292, 14971507.CrossRefGoogle Scholar
Lang, CH, Pruznak, AM, Deshpande, N, et al. (2004) Alcohol intoxication impairs phosphorylation of S6K1 and S6 in skeletal muscle independently of ethanol metabolism. Alcohol Clin Exp Res 28, 17581767.CrossRefGoogle ScholarPubMed
Hong-Brown, LQ, Brown, CR, Navaratnarajah, M, et al. (2013) Activation of AMPK/TSC2/PLD by alcohol regulates mTORC1 and mTORC2 assembly in C2C12 myocytes. Alcohol Clin Exp Res 37, 18491861.CrossRefGoogle ScholarPubMed
Lang, CH, Pruznak, AM, Nystrom, GJ, et al. (2009) Alcohol-induced decrease in muscle protein synthesis associated with increased binding of mTOR and raptor: comparable effects in young and mature rats. Nutr Metab 6, 117.CrossRefGoogle Scholar
Lang, CH, Frost, RA, Deshpande, N, et al. (2003) Alcohol impairs leucine-mediated phosphorylation of 4E-BP1, S6K1, eIF4G, and mTOR in skeletal muscle. Am J Physiol Endocrinol Metab 285, 12051215.CrossRefGoogle ScholarPubMed
Lang, CH, Frost, RA, Svanberg, E, et al. (2004) IGF-I/IGFBP-3 ameliorates alterations in protein synthesis, eIF4E availability, and myostatin in alcohol-fed rats. Am J Physiol Endocrinol Metab 286, 916926.Google ScholarPubMed
Nguyen, VA, Le, T, Tong, M, et al. (2012) Impaired insulin/IGF signaling in experimental alcohol-related myopathy. Nutrients 4, 10581075.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Proposed mechanisms underpinning the impact of smoking and nicotine administration on appetite and undernutrition. CART, cocaine- and amphetamine-regulated transcript; IGF-1, insulin-like growth factor 1; MPB, muscle protein breakdown; MPS, muscle protein synthesis; mTORC1, mammalian target of rapamycin complex 1; nAChRs, nicotinic acetylcholine receptors; NPY, neuropeptide Y; POMC, pro-opiomelanocortin; UPS, ubiquitin-proteasome system. Solid arrows denote a direct impact; broken arrows denote an indirect impact; indicates increase; indicates decrease.

Figure 1

Fig. 2. Indirect and direct mechanisms that may underpin the decline in muscle mass and function with smoking and excessive alcohol consumption. 4E-BP1, eukaryotic translation initiation factor 4E-binding protein 1; AMPK, AMP-activated protein kinase; IGF-1, insulin-like growth factor 1; IL-1, interleukin 1; IL-6, interleukin 6; IL-10, interleukin 10; MPB, muscle protein breakdown; MPS, muscle protein synthesis; mTOR, mammalian target of rapamycin; REDD1, regulated in development and DNA damage responses 1; S6K1, ribosomal protein S6 kinase 1; TNF-α, tumour necrosis factor-alpha; UPS, ubiquitin proteasome system. Solid arrows denote a direct impact; broken arrows denote an indirect impact; indicates increase; indicates decrease.