Dietary supplementation with gamma-linolenic, linoleic and oleic acids decreases PPAR-gamma expression and helps the tetracycline derivative to reduce NOD2 expression in patients with acne vulgaris

Prati, Clarissa; Pilar, Emily Ferreira Salles; Cartel, Andre; Pitoni, João Bayma Galvão; Vasconcellos, Cidia; Costa, Adilson da

doi:10.1016/j.abd.2020.11.016

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Research Letter • An. Bras. Dermatol. 97 (02) • 2022 • https://doi.org/10.1016/j.abd.2020.11.016 copy

Dietary supplementation with gamma-linolenic, linoleic and oleic acids decreases PPAR-gamma expression and helps the tetracycline derivative to reduce NOD2 expression in patients with acne vulgaris^☆ ☆ Study conducted at the Instituto de Assistência Médica ao Servidor Público Estadual, São Paulo, SP, Brazil; Pontifícia Universidade Católica de Campinas, Campinas, São Paulo, SP, Brazil; and Hospital de Clínicas de Porto Alegreda Universidade Fedral do Rio Grande do Sul, Porto Alegre, RS, Brazil.

Authorship SCIMAGO INSTITUTIONS RANKINGS

Dear Editor,

Acne vulgaris (AV) is an immunoinflammatory dermatosis of the sebaceous glands (SG), inter-adnexal epithelium (IE) and hair follicles (HF); it shows lipid synthesis and cytokine expression by microorganism-cell interaction. In AV, toll-like receptors type 2 (TLR2) and 4 (TLR4), nucleotide oligomerization domain-like, type 1 (NOD1) and 2 (NOD2) and peroxisome proliferator-activated receptor gamma (PPARG) regulate the SG expression, cell differentiation and macronutrient metabolism.¹1 Dreno B, GollnickHP, Kang S et al. Understanding innate immunity and inflammation in acne: implications for management. J Eur Acad Dermatol Venereol. 2015;29:3-11. Dietary fatty acids (FAs) seem to influence AV through the imbalance of omega-3 and -6 FAs.²2 Zouboulis CC, Saborowski A, Boschnakow A. Zileuton, an oral 5- lipoxygenase inhibitor, directly reduces sebum production. Dermatology. 2005;210:36-8. Our hypothesis is that supplementation with gamma linolenic (GLA), linoleic (AL) and oleic (OA) acids, with or without lymecycline (LM), interferes with the expression of TLR1, TLR2, NOD1, NOD2, and PPARG in AV.

The present research was an open, prospective, randomized, non-placebo-controlled study, approved by the Research Ethics Committee of Pontifícia Universidade Católica de Campinas (PUC-Campinas; protocol n.387/09) and Faculdade de Medicina da Universidade de São Paulo (FMUSP; 229/10), at the Dermatology Service at PUC-Campinas; FMUSP Department of Dermatology; Experimental Pathology Laboratory of Universidade Federal do Rio Grande do Sul (UFRGS); and the Postgraduate Program in Health Sciences at Instituto de Assistência Médica ao Servidor Público Estadual (IAMSPE) in São Paulo, resulting in the Doctorate theses of the first and last authors. Financial support was provided by Fundo de Apoio da Sociedade Brasileira de Dermatologia (Funaderm) and a donation of LM (Tetralysal®, 300 mg) and GLA/LA/OA (Tiliv L, 1000 mg; 480 mg/day, 1200 mg/day and 510 mg/day, respectively, of GLA/LA/OA) by Galderma Brasil Ltda., São Paulo, SP, Brazil, and Arese Pharma Ltda., Valinhos, SP, Brazil, respectively.

Forty-five male patients with papulopustular or cystic acne, aged between 13 and 38 years, read, understood, signed the free and Informed Consent Form and were randomized into three therapeutic groups (1:1:1) for 90 days: Group 1, LM 300 mg/day; Group 2, GLA/LA/OA 1000 mg/day; or Group 3, Group 1+Group 2. Papules, pustules and cysts were counted at Visits 1, Day 0 (D0); 2, D30; 3, D60; and 4, D90. A biopsy of the papulopustular lesion was performed on D0 and D90 for immunohistochemical analysis of TLR1, TLR2, NOD1, NOD2, and PPARG, evaluated by three pathologists using the following grading score: non-existent (0), weak (1), medium (2) and strong (3).

The means obtained before and after treatment were compared between groups and lesions. Quantitative variables were described by mean and standard deviation, comparing those with a symmetrical distribution by analysis of variance (ANOVA), followed by Tukey’s posthoc; intergroup evaluation was carried out with the Kruskal-Wallis test for non-parametric data; and intragroup evaluation with Wilcoxon test. Descriptive statistics were used, with standard deviation, minimum, maximum , and median values, with a significance level of 5% (p < 0.05) using the statistical package IBM SPSS version 20.

Of the 45 subjects, 36 (80%) completed the study: 11 from Group 1; 13 from Group 2; and 12 from Group 3. There was no statistical difference between the groups (p = 0.626). The ratio of subjects with papulopustular and cystic acne was similar for Groups 1, 2 and 3, and there were no differences regarding phototypes (p = 0.548) and time of disease evolution (p = 0.959; Table 1).

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Table 1
Characteristics of subjects with AV included in the study.

A significant decrease was observed in the number of comedones and cysts throughout the study (p < 0.001), with no difference between the groups and no alterations in comedones and cysts. The pustules decreased significantly (p < 0.001), with no effect of time, difference between the groups (p = 0.049; Table 2). However, the papules and total AV lesions varied between the study groups (p = 0.049 and p = 0.011; group*Visit interaction; Table 2). There was a decrease in comedones and pustules in all groups and visits when compared to D0, except between D60 and D90 (p = 0.966). For the cysts, there was a decrease, except from D30 on (Table 3).

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Table 2
Descriptive statistics of lesions according to group and time of treatment.

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Table 3
Multiple comparisons of numbers of lesions at the visits for the treatment groups.

On immunohistochemistry, there was no difference between the groups and analyzed histopathological sites on D0. On D90, there was a NOD2 difference in the IE between the Groups (Group 1 with higher values than Groups 2 and 3). The median of NOD2 in the IE was two in the three groups, with a maximum value in Group 1 surpassing the others, indicating a somewhat higher distribution of values in Group 1. In the intragroup comparisons, there was a decrease in PPARG in SG in Group 2 (p = 0.016) and a significant increase in NOD2 in HF in Group 1 (p = 0.011; Table 4).

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Table 4
Comparative table between and within groups for the assessment by the score.

The reduction of inflammatory lesions in the Groups with LM undergoing treatment (Groups 1 and 3) was predicted, as it is one of the tetracyclines of choice in the management of inflammatory AV, with high skin penetration.³3 Gollnick HP, Bettoli V, Lambert J, et al. A consensus-based practical and daily guide for the treatment of acne patients. J Eur Acad Dermatol Venereol. 2016;30:1480-90.,⁴4 Dreno B, Betolli V, Ochsendorf F, et al. European recommendations on the use or oral antibiotics for acne. Eur J Dermatol. 2004;12:391-99.

Costa et al., in 2007, pointed out a clinical non-response with the use of GLA/LA/OA supplementation, compared to placebo, in AV, but a possible improvement in the SG size, seen in pre-and post-treatment biopsies.⁵5 Costa A, Alchorne MMA, Michalany NS, Lima HC. Acne vulgar: estudo piloto de avaliação do uso oral de ácidos graxos essenciais por meio de análises clínica, digital e histopatológica. An Bras Dermatol. 2007;82:129-34. The present study, however, indicated a possible usefulness of GLA/LA/OA for comedones and cysts, confirming Rustin's remote assumptions.⁶6 Rustin MHA. Dermatology. Postgrad Med J. 1990;66:894-905.

NODs are activated by bacterial muramyl peptidoglycans, combined or not with TLRs. Thus, the result observed in NOD2 may have come from the control of microorganism-mediated inflammation, as the overexpression of NOD2 reduces clonal proliferation.⁷7 Grime CL, Arivananda D de Z, Melnyk JE, O'Shea EK. The innate immune protein Nod2 binds directly to MDP, a bacterial cell wall fragment. J Am Chem Soc. 2012;134:13535-37.,⁸8 Velloso FJ, Sogayar MC, Correa RG. Expression and in vitro assessment of tumorigenicity for NOD1 and NOD2 receptors in breast cancer cell lines. BMC Res Notes. 2018;11:222.

PPARG acts on sebocyte modulation. Its GLA/LA/OA-induced SG reduction may be the cause of the increase in lauric, myristic, and palmitic acids under equal therapy, suggesting the same role in NOD2-lowering effects in the IE.⁹9 Costa A, Siqueira AT, Duarte OCP et al. Evaluation of the quantitative and qualitative alterations in the fatty acid contents of the sebum of patients with inflammatory acne during treatment with systemic lymecycline and/or oral fatty acid supplementation. Dermatol Res Pract. 2013;2013:120475.

GLA/LA/OA were used In Groups 2 and 3. Therefore, we suggest that their administration causes PPARG reduction in sebocytes in Group 2 and NOD2 in the IE of both Groups 2 and 3, reinforcing the hypothesis of beneficial supplementation with GLA/LA/OA for comedonal and cystic AV.⁵5 Costa A, Alchorne MMA, Michalany NS, Lima HC. Acne vulgar: estudo piloto de avaliação do uso oral de ácidos graxos essenciais por meio de análises clínica, digital e histopatológica. An Bras Dermatol. 2007;82:129-34.

6 Rustin MHA. Dermatology. Postgrad Med J. 1990;66:894-905.-⁷7 Grime CL, Arivananda D de Z, Melnyk JE, O'Shea EK. The innate immune protein Nod2 binds directly to MDP, a bacterial cell wall fragment. J Am Chem Soc. 2012;134:13535-37. Therefore, FAs with great bactericidal potential could reduce the concentrations of Cutibacterium acnes and, thus, the expression of bacterium-activated receptors. Interestingly, isolated LM increased NOD2 labeling in HF, requiring further elucidative studies. As PPARG and NOD2 are inversely related to papules in Group 3, perhaps they can be recruited in the early stages of the dermatosis.

Therefore, it is concluded that daily administration of LM and/or GLA/LA/OA interferes with the pro-inflammatory markers in AV, and supplementation with GLA/LA/OA could be an adjuvant in the treatment of AV.

Financial support

This publication was made possible with the support from Fundo de Apoio à Dermatologia (Funaderm) da Sociedade Brasileira de Dermatologia, Galderma Brasil Ltda., São Paulo, SP, Brazil, and Arese Pharma Ltda., Valinhos, SP, Brazil.

References

¹
Dreno B, GollnickHP, Kang S et al. Understanding innate immunity and inflammation in acne: implications for management. J Eur Acad Dermatol Venereol. 2015;29:3-11.
²
Zouboulis CC, Saborowski A, Boschnakow A. Zileuton, an oral 5- lipoxygenase inhibitor, directly reduces sebum production. Dermatology. 2005;210:36-8.
³
Gollnick HP, Bettoli V, Lambert J, et al. A consensus-based practical and daily guide for the treatment of acne patients. J Eur Acad Dermatol Venereol. 2016;30:1480-90.
⁴
Dreno B, Betolli V, Ochsendorf F, et al. European recommendations on the use or oral antibiotics for acne. Eur J Dermatol. 2004;12:391-99.
⁵
Costa A, Alchorne MMA, Michalany NS, Lima HC. Acne vulgar: estudo piloto de avaliação do uso oral de ácidos graxos essenciais por meio de análises clínica, digital e histopatológica. An Bras Dermatol. 2007;82:129-34.
⁶
Rustin MHA. Dermatology. Postgrad Med J. 1990;66:894-905.
⁷
Grime CL, Arivananda D de Z, Melnyk JE, O'Shea EK. The innate immune protein Nod2 binds directly to MDP, a bacterial cell wall fragment. J Am Chem Soc. 2012;134:13535-37.
⁸
Velloso FJ, Sogayar MC, Correa RG. Expression and in vitro assessment of tumorigenicity for NOD1 and NOD2 receptors in breast cancer cell lines. BMC Res Notes. 2018;11:222.
⁹
Costa A, Siqueira AT, Duarte OCP et al. Evaluation of the quantitative and qualitative alterations in the fatty acid contents of the sebum of patients with inflammatory acne during treatment with systemic lymecycline and/or oral fatty acid supplementation. Dermatol Res Pract. 2013;2013:120475.

Publication Dates

Publication in this collection
22 Apr 2022
Date of issue
2022

History

Received
08 Sept 2020
Accepted
14 Nov 2020

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Variables	Groups of treatment			p-value
	Group 1 (n = 11)	Group 2 (n = 13)	Group 3 (n = 12)
Age (years)				0.626
Mean(SD)	17.5 (3.9)	17.7 (4.7)	19.6 (6.2)
Median (Min-Max)	17 (13 - 28)	16.5 (16 - 31)	17 (15 - 38)
AV degree				0.327
Papulopustular	9 (81.8)	11 (84.6)	10 (83.3)
Cysts	2 (18.2)	2 (15.4)	2 (16.7)
Phototype				0.548
II	3 (27.2)	3 (23.1)	3 (25)
III	4 (36.4)	2 (15.4)	3 (25)
IV	4 (36.4)	8 (61.5)	6 (50.0)
Time of disease (years)				0.959
Mean (SD)	5.3 (2.8)	5.6 (3.6)	6.4 (4.4)
Median (Min-Max)	4.5 (2 - 12)	4.5 (2 - 15)	5.0 (3 - 18)

Visit	Number of lesions	Group 1	Group 2	Group 3	p-value
D0	Comedones				0.328
	Mean (SD)	18.4 (5.7)	23.2 (10.7)	25.5 (13.0)
	Median (Min-Max)	18.5 (12 - 29)	23.0 (5 - 38)	27.0 (5 - 46)
	Papules				0.162
	Mean (SD)	11.3 (4.9)	13.6 (4.6)	14.3 (7.3)
	Median (Min-Max)	9.5 (6 - 22)	12.0 (8 - 25)	12.0 (6 - 35)
	Pustules				0.290
	Mean (SD)	7.3 (4.9)	10.1 (5.4)	9.4 (6.5)
	Median (Min-Max)	8 (2 - 18)	9 (3 - 22)	8 (2 - 26)
	Cysts				0.496
	Mean (SD)	1.0 (2.0)	0.4 (0.9)	2.9 (5.5)
	Median (Min-Max)	0 (0 - 6)	0 (0 - 3)	0 (0 - 16)
	Any lesion				0.156
	Mean (SD)	38.0 (14.5)	47.2 (16.4)	52.1 (23.0)
	Median (Min-Max)	38 (20 - 71)	41.5 (24 - 83)	49 (18 - 99)
D30	Comedones				0.175
	Mean (SD)	14.8 (4.6)	18.9 (8.7)	20.3 (9.1)
	Median (Min-Max)	14 (8 - 22)	18 (4 - 32)	22 (3 - 33)
	Papules				0.156
	Mean (SD)	7.3 (4.2)	9.5 (3.4)	8.1 (5.3)
	Median (Min-Max)	7 (2 - 16)	9 (4 - 16)	7 (3 - 24)
	Pustules				0.374
	Mean (SD)	3.8 (3.5)	5.6 (3.0)	5.4 (4.4)
	Median (Min-Max)	3 (0 - 10)	5.5 (1 - 11)	4 (0 - 15)
	Cysts				0.160
	Mean (SD)	0.3 (0.9)	0.0 (0.0)	1.5 (3.5)
	Median (Min-Max)	0 (0 - 3)	0 (0 - 0)	0 (0 - 12)
	Any lesion				0.142
	Mean (SD)	26.1 (10.3)	33.9 (14.0)	35.4 (15.3)
	Median (Min-Max)	26.5 (10 - 49)	31.5 (12 - 57)	36 (12 - 67)
D60	Comedones				0.296
	Mean (SD)	12.8 (4.0)	17.5 (9.0)	15.6 (6.6)
	Median (Min-Max)	13 (8 - 20)	16 (4 - 33)	16 (3 - 26)
	Papules				0.009
	Mean (SD)	5.1 (2.5)	8.9 (3.7)	5.1 (3.9)
	Median (Min-Max)	5 (1 - 10)	8.5 (3 - 15)	5 (0 - 16)
	Pustules				0.022
	Mean (SD)	2.6 (1.9)	5.6 (3.2)	2.4 (2.9)
	Median (Min-Max)	3.5 (0 - 5)	5 (1 - 12)	1 (0 - 8)
	Cysts				0.149
	Mean (SD)	0.0 (0.0)	0.0 (0.0)	0.6 (1.7)
	Median (Min-Max)	0 (0 - 0)	0 (0 - 0)	0 (0 - 6)
	Any lesion				0.060
	Mean (SD)	20.4 (6.7)	31.9 (12.9)	23.8 (10.6)
	Median (Min-Max)	22.5 (9 - 27)	32.5 (13 - 55)	25.5 (7 - 43)
D90	Comedones				0.19
	Mean (SD)	11.8 (3.8)	16.7 (8.0)	13.4 (6.3)
	Median (Min-Max)	12 (6 - 20)	14 (5 - 30)	12 (3 - 25)
	Papules				0.003
	Mean (SD)	4.5 (2.7)	8.4 (4.2)	3.8 (2.3)
	Median (Min-Max)	3.5 (1 - 10)	9 (3 - 18)	3 (0 - 8)
	Pustules				0.003
	Mean (SD)	2.2 (2.6)	6.2 (4.1)	1.6 (1.7)
	Median (Min-Max)	1.5 (0 - 9)	7 (1 - 13)	1 (0 - 4)
	Cysts				<0.001
	Mean (SD)	0.0 (0.0)	0.0 (0.0)	0.6 (1.7)
	Median (Min-Max)	0 (0 - 0)	0 (0 - 0)	0 (0 - 6)
	Any lesion				0.006
	Mean (SD)	18.4 (6.5)	31.4 (11.6)	18.8 (9.0)
	Median (Min-Max)	18.5 (8 - 27)	36 (11 - 48)	18.5 (6 - 32)

Lesion	Comparison	Estimated mean difference	Standard Error	p-value
Comedones	D0 vs. D30	4.450	0.674	<0.001
	D0 vs. D60	7.175	1.095	<0.001
	D0 vs. D90	8.500	1.232	<0.001
	D30 vs. D60	2.725	0.556	<0.001
	D30 vs. D90	4.050	0.748	<0.001
	D60 vs. D90	1.325	0.368	0.005
Pustules	D0 vs. D30	4.000	0.473	<0.001
	D0 vs. D60	5.425	0.669	<0.001
	D0 vs. D90	5.625	0.916	<0.001
	D30 vs. D60	1.425	0.434	0.012
	D30 vs. D90	1.625	0.702	0.113
	D60 vs. D90	0.200	0.429	0.966
Cysts	D0 vs. D30	0.850	0.224	0.001
	D0 vs. D60	1.225	0.301	<0.001
	D0 vs. D90	1.450	0.352	<0.001
	D30 vs. D60	0.375	0.224	0.341
	D30 vs. D90	0.600	0.301	0.197
	D60 vs. D90	0.225	0.224	0.747

	Group 1 (n = 11)			Group 2 (n = 13)			Group 3 (n = 12)
	D0	D90	P^c c Wilcoxon test.	D0	D90	P^c c Wilcoxon test.	D0	D90	P^c c Wilcoxon test.	PD0^d d Kruskal Wallis test.	PD90^d d Kruskal Wallis test.
Epithelium
PPARG	2 (0-3)	2 (0-3)	0.603	2 (0-3)	1 (0-3)	0.088	3 (0-3)	1 (0-3)	0.184	0.340	0.482
NOD1	3 (2-3)	3 (2-3)	0.317	3 (2-3)	3 (1-3)	0.480	3 (1-3)	3 (1-3)	0.180	0.797	0.177
NOD2	2 (1-3)	2 (2-3)^a a,b Different letters represent statistically different distributions.	0.063	2 (0-3)	2 (1-2)^b a,b Different letters represent statistically different distributions.	0.102	1.5 (0-3)	2 (1-2)^b c Wilcoxon test.	0.999	0.500	0.001^d d Kruskal Wallis test.
TRL2	2 (0-3)	2 (1-3)	0.317	1 (1-3)	2 (0-3)	0.480	1 (1-3)	1 (0-3)	0.739	0.370	0.794
TRL4	1 (0-3)	1 (0-2)	0.999	1 (0-3)	1 (0-3)	0.627	1 (0-3)	1 (0-3)	0.720	0.404	0.503
Gland
PPARG	2 (1-3)	2 (1-3)	0.180	2 (2-3)	2 (0-3)	0.016^c c Wilcoxon test.	2 (1-3)	2 (1-3)	0.132	0.146	0.091
NOD1	2 (1-3)	2 (1-3)	0.366	2 (1-3)	2 (0-3)	0.589	2 (1-3)	2 (2-3)	0.096	0.696	0.197
NOD2	2 (0-3)	2 (1-3)	0.107	2 (0-3)	2 (1-3)	0.317	1 (1-2)	2 (1-3)	0.107	0.331	0.560
TRL2	1 (0-3)	1 (0-2)	0.084	0 (0-3)	1 (0-2)	0.480	1 (0-2)	1 (0-3)	0.271	0.083	0.777
TRL4	0 (0-2)	0 (0-2)	0.999	0 (0-2)	0 (0-2)	0.890	0 (0-3)	1 (0-3)	0.546	0.440	0.067
Follicle
PPARG	0 (0-3)	1 (0-2)	0.739	1 (0-3)	0 (0-3)	0.429	1 (0-2)	1 (0-3)	0.454	0.941	0.299
NOD1	3 (1-3)	3 (1-3)	0.705	2 (0-3)	2 (0-3)	0.874	2 (0-3)	2 (1-3)	0.386	0.405	0.499
NOD2	1 (0-2)	2 (0-3)	0.011^c c Wilcoxon test.	1 (0-2)	1 (0-2)	0.705	0.5 (0-1)	1 (0-2)	0.084	0.082	0.092
TRL2	1 (0-3)	1 (0-2)	0.236	0 (0-3)	1 (0-2)	0.999	1 (0-1)	1 (0-2)	0.206	0.388	0.449
TRL4	0 (0-2)	1 (0-2)	0.480	0 (0-2)	0 (0-3)	0.726	0.5 (0-3)	1 (0-2)	0.850	0.565	0.304

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[1] Financial support

This publication was made possible with the support from Fundo de Apoio à Dermatologia (Funaderm) da Sociedade Brasileira de Dermatologia, Galderma Brasil Ltda., São Paulo, SP, Brazil, and Arese Pharma Ltda., Valinhos, SP, Brazil.