Intervention involving tomato or tomato-based product supplementation

Some studies have been conducted in healthy participants. Most studies reported a reduction of pro-inflammatory marker plasma levels (Table 2). Indeed, tomato juice consumption for 2 weeks (daily dose of lycopene: 20·6 mg) decreased plasma CRP level^{(Reference Jacob, Periago and Bohm46)} and MCP1 concentration decreased in twelve healthy participants consuming a vegetable soup constituted mainly of tomato (500 ml/d for 14 d)^{(Reference Sanchez-Moreno, Cano and de Ancos47)}, but did not modulate TNFα and IL1β or TNFα, IL6 and IL1β, respectively. Tomato juice consumption (280 ml/d, containing 32·5 mg lycopene) for 8 weeks also reduced MCP1 concentration and increased adiponectin concentration in young females (n = 30)^{(Reference Li, Chang and Huang48)}. Recently, the consumption of sofrito (Mediterranean tomato-based sauce; 240 g/70 kg body weight) in twenty-two healthy males was associated with a decrease in plasma TNFα and CRP concentration (no modification regarding IL6 concentration), 24 h after consumption^{(Reference Hurtado-Barroso, Martínez-Huélamo and Rinaldi de Alvarenga49)}. However, one study reported no impact on plasma concentrations of ICAM and CRP in 103 healthy participants submitted to a tomato-rich diet (300 g/d for 1 month)^{(Reference Blum, Monir and Khazim50)}, while another one depicted negative result (i.e. increase of plasma TNFα and lack of modulation of IL4, after 330 ml/d tomato juice supplementation for 2 weeks in 22 healthy males)^{(Reference Watzl, Bub and Briviba51)}.

Table 2. Clinical trials that studied the effect of supplementation with tomato or tomato-derived products on inflammation biomarkers

↘, decrease of the measured parameter ; ↗, increase of the measured parameter; NA, data not available.

The anti-inflammatory effect of tomato-based products has been investigated during post-prandial metabolic inflammation. In this particular context, consumption of tomato products reduced IL6 plasma level in healthy females and males (n = 25) during the post-prandial phase^{(Reference Burton-Freeman, Talbot and Park52)}. Similarly, different types of tomato-rich diets (raw tomatoes, tomato sauce or tomato sauce with olive oil) were evaluated regarding post-prandial plasma inflammatory response in healthy participants (n = 40). Such regimens led to a decrease in MCP1 concentration and to an increase in IL10 concentration (anti-inflammatory interleukin) following consumption of the three diets, a decrease in IL18 concentration following tomato sauce consumption and a reduction of IL6 and VCAM concentration following consumption of tomato sauce plus olive oil^{(Reference Valderas-Martinez, Chiva-Blanch and Casas53)}.

In heathy participants with overweight, a cocktail of dietary anti-inflammatory products, including tomato extracts, increased plasma adiponectin concentration (known to display anti-inflammatory activity^{(Reference Ruhl and Landrier54)}) but did not modify CRP levels^{(Reference Bakker, van Erk and Pellis55)}.

Several studies have also been conducted in patients with metabolic disorders (obesity, type-2 diabetes or metabolic syndrome). One study conducted in patients with type-2 diabetes (n = 15) did not report reduction of CRP, ICAM or VCAM plasma concentrations after tomato juice supplementation for 4 weeks (300 ml/d) compared with placebo^{(Reference Upritchard, Sutherland and Mann56)}. Conversely, 20 d of supplementation with 330 ml/d of tomato juice for significantly decreased plasma IL8 and TNFα concentrations in participants with overweight and IL6 levels in participants with obesity^{(Reference Ghavipour, Saedisomeolia and Djalali57)}. Patients with metabolic syndrome who consumed tomato juice four times a week for a duration of 2 months experienced a comparable decrease in their plasma concentrations of IL6 and TNFα^{(Reference Tsitsimpikou, Tsarouhas and Kioukia-Fougia58)}. In a population of twenty-seven participants at high cardiovascular risk, a supplementation for 4 weeks with 200 ml or 400 ml of tomato juice resulted in a decrease of ICAM1 and VCAM1 concentrations, without modification of CRP or IL8^{(Reference Colmán-Martínez, Martínez-Huélamo and Valderas-Martínez59)}. Finally, in fifty-two obese children with fatty liver, the assignment to tomato sauce for 60 d increased adiponectin plasma concentration and decreased leptin plasma concentration^{(Reference Negri, Trinchese and Carbone60)}.

Altogether, these studies provide arguments in favour of a limitation of metabolic inflammation under tomato-based product supplementation, especially in participants with metabolic inflammation at baseline of the study. In agreement, a recent meta-analysis found a reduction in IL6 levels after tomato supplementation (standardised mean difference −0·25; p = 0·03)^{(Reference Cheng, Koutsidis and Lodge61)}. Nevertheless, we have to keep in mind that such results have been obtained following the consumption of tomato sauces or juices, which include several other ingredients (vegetable extracts, olive oil, oregano, basil extracts, etc.). Thus, the anti-inflammatory effect depicted in these studies may not be entirely attributed to tomato-derived products. Indeed, the presence of many other phytochemical-rich extracts could be involved in the anti-inflammatory response. In addition, if the anti-inflammatory effect has been characterised at the systemic level in these trials, it is not clear if such response is only due to circulating immune cells or may be related to other cells, tissues or organs. To our knowledge, no data are available regarding the specific role of tomato on the inflammation process in human organ or tissue; however, the fact that adiponectin and leptin plasma concentrations were modulated in some studies suggests that adipose tissue inflammatory status may be directly or indirectly impacted by tomato supplementation.

Another important issue relies on the identification of bioactive compounds mediating the tomato and tomato-derived product anti-inflammatory effects. We cannot exclude that the anti-inflammatory effect is mainly due to a cocktail effect of phytochemicals (including carotenoids, phenolic compounds, vitamins, etc.). Nevertheless, lycopene is classically considered as the major bioactive compound of tomato. Even if the correlations between the anti-inflammatory effects highlighted in clinical trials and plasma lycopene concentrations are sometimes conflicting^{(Reference Hurtado-Barroso, Martínez-Huélamo and Rinaldi de Alvarenga49,Reference Colmán-Martínez, Martínez-Huélamo and Valderas-Martínez59)} , the specific effect of lycopene is traditionally suggested, based on its anti-inflammatory and antioxidant activity shown in in vitro and in animal studies.

Intervention studies involving lycopene supplementation

Lycopene supplementation for 1 week (Lyc-O-Mato; 80 mg/d lycopene) did not reduce post-prandial inflammation markers (CRP, ICAM or VCAM) in young healthy participants (n = 27)^{(Reference Denniss, Haffner and Kroetsch62)} (Table 3). Among participants with obesity (n = 16), lycopene supplementation (4 weeks, Lyc-O-Mato, 30 mg/d) did not bring about any changes in the plasma levels of inflammatory markers (TNFα, IL6, CRP)^{(Reference Markovits, Ben Amotz and Levy63)}. Similarly, no impact of 1-month lycopene supplementation (7 mg/d) was reported regarding CRP of patients with hypertension^{(Reference Petyaev, Dovgalevsky and Klochkov64)}. In smoking (n = 12) and non-smoking (n = 15) participants, 2 weeks of supplementation (Lyc-O-Mato, 14·64 mg of lycopene/d) had no effect on circulating TNFα and IL2 levels compared with placebo^{(Reference Briviba, Kulling and Moseneder65)}. The consumption of 7 mg/d lycopene for 2 months in patients with CVD and healthy participants (n = 36 in each group) did not modulate CRP^{(Reference Gajendragadkar, Hubsch and Maki-Petaja66)}. In 224 middle-aged participants with moderate overweight, 12 weeks of supplementation with 10 mg/d lycopene or tomato-rich diet did not modify CRP, IL6 and ICAM plasma concentrations^{(Reference Thies, Masson and Rudd23)}. In patients with coronary vascular disease, 7 mg/d lycopene provided by microencapsulated lycopene for 30 d did not modify CRP plasma concentrations but reduced non-classical inflammatory parameters such as Chlamydia pneumonia IgG and oxidative stress as revealed by oxidised LDL^{(Reference Petyaev, Dovgalevsky and Klochkov67)}.

Table 3. Clinical trials that assessed the effect of supplementation with lycopene on blood biomarkers of inflammation

↘, decrease of the measured parameter ; ↗, increase of the measured parameter.

In contrast, a study indicated that in overweight middle-aged population (n = 54), consuming a lycopene-rich diet (providing 224–350 mg lycopene/week) for 12 weeks resulted in a substantial 36% decrease in SAA concentration within the HDL₃ fraction. In the same study group, a 12-week lycopene supplementation regimen (using capsules, 70 mg/week) led to a reduction in SAA levels in both the plasma and HDL₃ fraction^{(Reference McEneny, Wade and Young68)}. Similar results, that is, a decrease of serum and HDL₃ under lycopene or high tomato diet has been recently published in a larger panel of volunteers (n = 225; 40–65 years and BMI between 18·5 and 35 kg/m²)^{(Reference McEneny, Henry and Woodside69)}. In healthy men (n = 126), the intake of lycopene (6 or 15 mg/d for 8 weeks) resulted in decreased plasma concentrations of ICAM and VCAM in both groups. Furthermore, the group receiving a daily dosage of 15 mg also showed a reduction in CRP levels as well^{(Reference Kim, Paik and Kim70)}. Among twenty-six healthy volunteers, the administration of Lyco-O-Mato, containing 5·7 mg of lycopene for a period of 26 d led to a 34·4% reduction in TNFα production from whole blood following an in vitro lipopolysaccharide (LPS) challenge^{(Reference Riso, Visioli and Grande71)}.

Altogether, these intervention studies using lycopene mostly failed to demonstrate a beneficial anti-inflammatory impact at the systemic level. As previously evoked, we cannot exclude that lycopene supplementation could reduce organ or tissue inflammatory status, but to our knowledge, no data are presently available. Nevertheless, current data are not in favour of an anti-inflammatory effect of pure lycopene in human, whereas observational studies clearly support such assumption. It is noteworthy that, in observational studies, plasma lycopene level is a good marker of tomato and tomato-derived product consumption. Thus, the association between high lycopene and low inflammatory status is more in favour of an effect of tomato and derived product consumption on inflammation, via a combination of phytochemicals, rather than solely a direct effect of lycopene.

Effect on inflammation in obesity and associated comorbidities context

The anti-inflammatory effects of the consumption of tomato-based products, especially tomato powder, or lycopene have been extensively studied in the context of obesity and its associated comorbidities (Table 4). Most studies were based on diet-induced obesity (DIO), using different types of regimens, supplemented or not with lycopene or tomato powder.

Table 4. Animal trials that assessed the effect of supplementation with lycopene and/or tomato products on biomarkers of inflammation

↘, decrease of the measured parameter; ↗, increase of the measured parameter.

The high fat/high cholesterol (HF/HChol) diet has been regularly used in DIO animal models. It is reported that lycopene, isolated from algae or tomato, significantly reduced the liver steatosis and blunted atherosclerotic depot in the aorta inflammation in rats (decreased ceruloplasmine, CRP, myeloperoxidase, decreased PBMC 15-lipoxygenase and cyclo-oxygenase activities)^{(Reference Renju, Kurup and Saritha Kumari72)}. This study points out that lycopene from algae gave more favourable results than lycopene isolated from tomatoes, implying a potential synergistic effect with other compounds of algae. A reduction of inflammatory status (TNFα, IL1β, ICAM and p65) in kidneys and heart of male rats fed a high-cholesterol diet supplemented with lycopene (50 mg/kg body weight (BW)/d) was also reported^{(Reference Albrahim73)}. Nevertheless, other studies using HF/HChol diet did not observe local and/or systemic anti-inflammatory effects following tomato product/lycopene consumption in rats^{(Reference Bernal, Martin-Pozuelo and Lozano74,Reference Martin-Pozuelo, Navarro-Gonzalez and Gonzalez-Barrio75)} . It is noteworthy that, in these studies, the HF/HChol diet does not induce any pro-inflammatory response (at the plasma and liver level), making the demonstration of a lycopene-mediated anti-inflammatory effect unlikely. A similar observation was made in HF/HChol-fed mice supplemented for 12 weeks with 9% or 17% of dried tomato peel ^{(Reference Zidani, Benakmoum and Ammouche76)}, where the dose–response effect was not obvious and only insulin sensitivity was restored.

Others model of DIO, mixing high-fat diet plus sucrose and supplemented or not with lycopene, have been used in rats. Under these conditions, lycopene supplementation reduced insulin resistance-related parameters (plasma insulin, glycaemia) and blunted inflammation at the systemic level (decreased plasma concentrations of leptin, resistin and IL6 but not TNFα), in the adipose tissue (decreased mRNA expression of Leptin, Resistin, Mcp1 and Il6 but not Tnfa)^{(Reference Luvizotto Rde, Nascimento and Imaizumi77)} and in the brain^{(Reference Yin, Ma and Hong78)}. Pierine et al. investigated in DIO rats (rats were already obese at the beginning of the supplementation), the impact of a supplementation with lycopene. Although no modulation of plasma TNFα level was observed, in kidney its production decreased^{(Reference Pierine, Navarro and Minatel79)}, suggesting a beneficial impact on kidney oxidative stress and inflammation associated with obesity.

Several studies have been implemented in DIO models. For example, Bahcecioglu et al. supplemented rats with 2 and 4 mg/kg BW/d of lycopene for 6 weeks and observed an improvement of insulin sensitivity, liver steatosis and inflammation with the lower dose of lycopene (2 mg/kg BW/d)^{(Reference Bahcecioglu, Kuzu and Metin80)}. The dose of 4 mg/kg BW/d of lycopene led to a lower reduction of those parameters, supporting the idea of an optimal dosage of lycopene to blunt metabolic disorders. Similar hepatic limitation of inflammation (TNFα and IL1β) was observed in male rats subjected to HF diet and supplemented with lycopene at 25 or 50 mg/kg BW/d)^{(Reference Albrahim and Alonazi81)}. In female rats, 10 weeks of lycopene supplementation with 20 or 40 mg/kg BW/d reduced proinflammatory markers (Il1b, p65 and Il6 mRNA) in the heart of obese rats and induced the expression of Il10 ^{(Reference Ugwor, Ugbaja and James82)}. Similar reduction of inflammation (TNFα, MCP1 and IL6) in the heart of obese male rats with cardiac dysfunction was observed after a supplementation of 10 weeks with tomato oleoresin (equivalent to 10 mg/kg BW/d)^{(Reference Ferron, Francisqueti-Ferron and Silva83)}. In DIO mice, Singh et al. in a very elegant study showed the anti-inflammatory effects of lycopene (10 mg/kg of diet) but also the limitation of adiposity, hyperinsulinaemia and insulin resistance. Authors also reported a limitation of liver inflammation and steatosis (with decreased concentrations of IL6, TNFα, NF-κB and TLR4)^{(Reference Singh, Khare and Zhu84)} and a reduction of plasma inflammatory markers (TNFα, IL1β) in lycopene-supplemented group^{(Reference Singh, Khare and Zhu84)}. Similarly, we reported that supplementation for 12 weeks with lycopene but also tomato powder (providing the same amount of lycopene) reduced hepatic steatosis, reduced inflammation and improved hepatic lipid metabolism in a DIO mouse model^{(Reference Fenni, Hammou and Astier85)}. The hepatic anti-inflammatory effect of lycopene supplementation has been further confirmed^{(Reference Wang, Zou and Suo86,Reference Ni, Zhuge and Nagashimada87)} . In this last study, authors demonstrate that the effects of lycopene are associated with a reduction of Kupffer and T cells (both helper and cytotoxic), a reduction of pro-inflammatory cytokine expression (Il6, Tnfa, Il1β) and a reduction of NF-κB, JNK and p38 signalling pathway activation (Fig. 1)^{(Reference Ni, Zhuge and Nagashimada87)}. In addition, the hepatic anti-inflammatory effect of tomato powder was confirmed in Bco1^−/−/Bco2^−/− mice, possibly through a Sirt1/AMPK pathway-dependent mechanism^{(Reference Li, Liu and Fu88)}.

Fig. 1. Transcription factors activated or inhibited by lycopene or metabolites, leading to anti-inflammatory effects in different organs or cell types. NF-kB, nuclear factor kappa B; JNK, c-Jun N-terminal kinase; NRF2, nuclear factor (erythroid-derived 2)-like 2; PI3K, phosphatidylinositol-3-kinase; ERK, extracellular signal-regulated kinase; RAR, retinoic acid receptor; PPARγ, peroxisome proliferator-activated receptor γ; Sirt1, Sirtuin 1.

The study by Singh et al. mentioned earlier also presents a novel finding, suggesting that lycopene may influence gut microbiota and dysbiosis associated with obesity, as indicated by changes in caecal bacterial abundance and the production of short-chain fatty acids^{(Reference Singh, Khare and Zhu84)}. Therefore, the potential attenuation of dysbiosis and the preservation of gut and colon epithelial integrity, both linked to obesity and insulin resistance, might contribute to the broader systemic anti-inflammatory effects of lycopene. Such observation of an impact of lycopene on intestinal permeability has been further confirmed^{(Reference Wang, Suo and Zhang89)}, as well as the effect of tomato powder on microbial richness^{(Reference Li, Liu and Fu88)}.

Effect on adipose tissue inflammatory status

Adipose tissue and liver constitute the main lycopene storage tissues, and respectively contain 60% and 30% of the total lycopene body stores^{(Reference Böhm, Lietz and Olmedilla-Alonso17,Reference Landrier, Marcotorchino and Tourniaire26,Reference Chung, Ferreira and Epstein90,Reference Moran, Erdman and Clinton91)} . In the liver, lycopene uptake may be mediated via chylomicron-remnant receptors (LDL-receptor (LDLR), LDL-receptor related protein 1 (LRP1) and heparan sulphate proteoglycans (HSPGs))^{(Reference Dallinga-Thie, Franssen and Mooij92)}. In adipose tissue and adipocytes, the lycopene uptake is mediated by cluster of differentiation 36 (CD36)^{(Reference Moussa, Gouranton and Gleize93)} and seems to be independent of its physico-chemical properties^{(Reference Sy, Gleize and Dangles94)}. Lycopene is then stored in lipid droplets and membranes of adipocytes^{(Reference Gouranton, Yazidi and Cardinault95)}.

The effect of lycopene and tomato powder supplementation was evaluated on adipose tissue inflammation. A down-regulation of genes encoding pro-inflammatory markers, including cytokines, adipokines, acute phase proteins, chemokines and metalloproteinases (Mmp3 and Mmp9) and an up-regulation of genes encoding anti-inflammatory proteins were reported^{(Reference Fenni, Hammou and Astier85)}. Some of these regulations were confirmed at the protein level (IL6, TNFα, MCP1, CCL5). We also observed that the phosphorylation levels of p65 and IκB were reduced under lycopene and tomato powder supplementation. Similar anti-inflammatory response under lycopene effect in adipose tissue was observed in other studies^{(Reference Wang, Suo and Zhang89,Reference Chen, Ni and Nagata96)} . In addition, Chen et al. reported a reduction of M1 macrophages (pro-inflammatory macrophages) together with an increase of M2 macrophages (anti-inflammatory macrophages), and a decrease of p38 phosphorylation^{(Reference Chen, Ni and Nagata96)}, whereas Wang et al. reported an induction of autophagy in adipose tissue^{(Reference Wang, Suo and Zhang89)}. Altogether, these data suggest that the anti-inflammatory effect of lycopene and tomato powder on adipose tissue rely on their ability to inhibit NF-κB, p38 and JNK signalling and/or to restore autophagy in adipose tissue. Nevertheless, we cannot exclude that this anti-inflammatory effect was strictly due to the reduced adiposity.

Since apo-10′-lycopenoids were proposed to be major BCO2-mediated metabolites of lycopene^{(Reference Harrison and Kopec97)}, the effect of apo-10′-lycopenoic acid on liver steatosis was studied in the Ob/Ob mouse model^{(Reference Chung, Koo and Lian98)}. Apo-10′-lycopenoic acid supplementation diminished liver steatosis via a SIRT1-dependent mechanism leading to the inhibition of NF-κB inflammatory signalling^{(Reference Schug and Li99)}. The effect of apo-10′-lycopenoic acid was also reported in a high-fat diet mouse model, where this molecule blunted pro-inflammatory response in the liver through the modulation of SIRT1 activity^{(Reference Ip, Hu and Liu100)}. The study on the efficacy of lycopene compared with apo-10′-lycopenoic acid in reducing liver steatosis and inflammation in DIO Bco2^−/− mice has been documented. Ip et al. observed that these two compounds operated through distinct mechanisms, with apo-10′-lycopenoic acid influencing SIRT1 activity and expression in the liver, whereas lycopene exerted its effects at the mesenteric fat level by modulating the actions of PPARα and PPARγ^{(Reference Ip, Liu and Lichtenstein101)}.

The anti-inflammatory effect of apo-10′-lycopenoic acid has been investigated in adipose tissue^{(Reference Gouranton, Aydemir and Reynaud102)}. We reported that apo-10′-lycopenoic acid transactivated RAR in vivo ^{(Reference Gouranton, Aydemir and Reynaud102)}. Such activation of RAR has been associated to a decrease of inflammatory markers in adipose tissue, via a NF-κB deactivation^{(Reference Karkeni, Bonnet and Astier103)}, suggesting that putative metabolites of lycopene may also display efficiency regarding inflammatory process in adipose tissue.

Altogether, data generated in animal model support the anti-inflammatory effect. It is somehow important to keep in mind that some studies (especially those with lycopenoids) have been conducted with huge amount of lycopene or tomato-derived products, which sometimes makes the physiological relevance questionable. It is noteworthy that the dose of 10 mg of lycopene per kilogram of animal body weight could be of physiological interest in animal studies. Such dose is equivalent to 0·81 mg/kg body weight in human (taking classical conversion factor used to translate doses from mice to human). Thus, for a 70 kg human, it represents 56 mg lycopene per day. Based on a mean lycopene content in tomato paste approximately 1500 mg/kg^{(Reference Rao, Ray and Rao16)}, it represents approximatively 300 g of tomato paste to obtain 56 mg of lycopene. Such quantity corresponds to doses classically used in human intervention studies (Table 2) and can thus be considered as relevant for human health.