Modulation of soluble receptor for advanced glycation end-products (RAGE) isoforms and their ligands in healthy aging

Francesco Scavello; Filippo Zeni; Calogero C. Tedesco; Emanuela Mensà; Fabrizio Veglia; Antonio Domenico Procopio; Anna Rita Bonfigli; Fabiola Olivieri; Angela Raucci

doi:10.18632/aging.101860

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Research Paper Volume 11, Issue 6 pp 1648—1663

Modulation of soluble receptor for advanced glycation end-products (RAGE) isoforms and their ligands in healthy aging

Francesco Scavello^1, , Filippo Zeni^1, , Calogero C. Tedesco^2, , Emanuela Mensà^3, , Fabrizio Veglia^2, , Antonio Domenico Procopio^3,4, , Anna Rita Bonfigli^5, , Fabiola Olivieri^3,4, , Angela Raucci^1, ,

¹ Unit of Experimental Cardio-Oncology and Cardiovascular Aging, Centro Cardiologico Monzino-IRCCS, Milan, Italy
² Unit of Biostatistics, Centro Cardiologico Monzino-IRCCS, Milan, Italy
³ Department of Clinical and Molecular Sciences, DISCLIMO, Università Politecnica delle Marche, Ancona, Italy
⁴ Center of Clinical Pathology and Innovative Therapy, IRCCS INRCA, Ancona, Italy
⁵ Scientific Direction, IRCCS INRCA, Ancona, Italy

* Equal contribution

Received: November 23, 2018 Accepted: March 6, 2019 Published: March 23, 2019

https://doi.org/10.18632/aging.101860
How to Cite

Copyright: © 2019 Scavello et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Abstract

The receptor for advanced glycation end-products (RAGE) recognizes several ligands involved in inflammatory diseases. Two circulating soluble isoforms exist: esRAGE derived from alternative splicing and cRAGE generated by the membrane-bound RAGE (FL-RAGE) proteolysis. Together, esRAGE and cRAGE constitute sRAGE and function as decoy receptors preventing FL-RAGE/ligands binding.

We determined serum concentration of both, esRAGE and cRAGE, and their ligands AGEs, HMGB1 and S100A8/A9 in a healthy population of 169 subjects aged 20-90 years. cRAGE showed a negative (r=-0.375, P<0.0001) while AGEs (r=0.160, P=0.0384) and S100A8/A9 (r=0.207, P=0.0091) a positive correlation with age. esRAGE did not change during aging and inversely correlated with Hemoglobin, ALT, insulin, HOMA index, Waist-Hip ratio (W/H), Waist Circumference (WC) and positively with AGEs. cRAGE exhibited also an inverse correlation with WC, W/H, PAI-1, HMGB1, AGEs and S100A8/A9. Age, W/H, HMGB1, S100A8/A9 and AGEs are independent predictors of cRAGE, whereas W/H and AGEs associate with esRAGE. Treatment of cells with glycated albumin reduced cRAGE production and upregulated FL-RAGE.

These results indicate that in a healthy population cRAGE is a biomarker of aging while esRAGE represents a more reliable marker of obesity and insulin resistance. Hence, sRAGE isoforms levels could be differentially associated with age-related diseases risk factors.

Introduction

The receptor for advanced glycation end-products (RAGE) belongs to the family of pattern recognition receptor (PRR) that recognizes several ligands, such as advanced glycation end-products (AGE), some S100/calgranulins, amyloid-beta peptide, High Mobility Group Box 1 protein (HMGB1) and extracellular matrix proteins [1,2].

Structurally, the membrane-bound full-length form of RAGE (FL-RAGE) is composed by three extracellular Ig-like domains, a single transmembrane helix and a short intracellular domain [1]. Binding of RAGE to its ligands activates several pathways including MAPKs and NF-κB, thus modulating all steps of the inflammatory process, such as cell migration, adhesion and proinflammatory molecules production [3–7]. In physiological conditions, RAGE is predominantly expressed in the lung compared to other tissues [8–11]; however, the rise of its levels is induced by ligands accumulation at the injured sites and is associated with the onset and progression of several chronic inflammatory diseases [12–15].

The RAGE primary transcript undergoes alternative splicing producing both species- and tissues-specific coding and non-coding variants [16–19]. In human, the variant hRAGE, encoding for FL-RAGE, is the most abundant RAGE isoform [19,20]. The variant hRAGE_v1 encodes for the secreted esRAGE, which is characterized by a unique C-terminal 9 amino acids sequence, and represents the main if not the only detectable circulating soluble protein generated by alternative splicing, since all the other soluble variants are predicted to be targeted to nonsense-mediated decay (NMD) without producing the corresponding protein products [20–22]. A soluble receptor, denominated cleaved RAGE (cRAGE), can also derive from the proteolysis of FL-RAGE ectodomain by the proteases ADAM10 and MMPs [23–26]. Both, esRAGE and cRAGE, are collectively named sRAGE and, in most of the cases, function as endogenous protective decoy receptors binding ligands with affinity similar to FL-RAGE and preventing activation of its signaling [8,14,24,27,28].

Cross-sectional studies on human population have suggested circulating sRAGE as potential biomarker of several pathologies although with conflicting data regarding diabetes and cardiovascular diseases [29–32]. Decreased levels of circulating sRAGE or esRAGE have been reported in patients with hypertension [33], metabolic syndrome (MS) [34], in the early phase of type 2 diabetes [35,36] and obesity suggesting sRAGE as an early predictor of cardiovascular risk. Interestingly, sRAGE levels seems to be related to body composition. Lower total sRAGE levels associate with increased body mass index (BMI), waist circumference (WC) and fat mass [37,38]. Recently, Prakash et al. showed that levels of sRAGE decline with age and inversely associate with BMI and fat free mass (FFM) in an apparently healthy population [39]. Healthy centenarians have a significant higher plasma sRAGE amount than healthy young subject [40]. These findings put forward that sRAGE could be a marker of healthy aging and longevity. Nevertheless, none of these studies quantified specifically esRAGE or cRAGE levels. It is possible that aging influences differently the mechanisms of sRAGE isoforms generation; therefore, determining simultaneously circulating esRAGE and cRAGE could be useful to discriminate their specific contribution to sRAGE decline and association to age-related disease risk factors.

In the present study, we simultaneously determined both sRAGE isoforms, esRAGE and cRAGE, and some of their ligands such as AGEs, HMGB1 and S100A8/A9 in a cohort of healthy subjects ranging from 20- to 90- years, with the aim to disentangle their age-related trends.

Results

Population features

Table 1 shows features of 169 healthy subjects aged 20-90 yrs stratified into three age groups according to World Health Organization (WHO [41,42];): young (≤45 yrs), middle age (46-64 yrs) and elderly-old (≥65 yrs). Young subjects (21.3%) were less represented than middle age (42.6%) and older (36.1%) individuals. The elderly-old cohort was taking more medications than the middle age and younger cohorts (73.8% vs 37.5% and 22.2%, respectively). Anthropometric measurements such as WC and W/H, lipid (Triglycerides, Cholesterol, LDL), liver (AST) and iron (Transferrin) metabolism, glycometabolic indicators (Glucose, HbA1c), Azotemia, inflammation markers (CRP, IL6), number of hypertensive subjects and medications (Antihypertensive, Antiplatelet, Gastro protectant, Micronutrients, Lipid-lowering) increased, while number of white blood cells (WBC) decreased across the age groups (Table 1). Correlation analysis between variables are reported in Supplementary Table 1.

Table 1. Biochemical, metabolic and anthropometric variables and medication therapy of healthy subjects divided in three age groups.

Variables

≤45 yrs

46-64 yrs

≥65 yrs

P trend

Sex (n/% male)

17/46

35/48

24/39

0.3803

BMI (Kg/m²)

25.31 ± 4.30

27.17 ± 4.31

27.05 ± 3.31

0.0700

WC (cm)

84.89 ± 12.93

91.10 ± 11.32

93.95 ± 8.65

0.0002

H (cm)

99.71 ± 9.87

103.22 ± 8.66

103.39 ± 7.84

0.0700

W/H

0.85 ± 0.09

0.88 ± 0.08

0.91 ± 0.06

0.0006

WBC (10³/uL)

6.89 ± 1.57

6.38 ± 1.70

6.18 ± 1.63

0.0495

RBC (10⁶/uL)

4.85 ± 0.45

4.62 ± 0.40

4.67 ± 0.39

0.0900

Triglycerides (mg/dL)

73.00 (53.00-118.0)

83.50 (55.00-112.50)

97.00 (80.00-142.00)

0.0600

Cholesterol (mg/dL)

197.31 ± 35.69

215.94 ± 40.89

218.51 ± 41.89

0.0215

HDL (mg/dL)

54.28 ± 12.93

59.92 ± 15.36

56.33 ± 15.33

0.7500

LDL (mg/dL)

113.49 ± 30.79

127.25 ± 37.60

132.31 ± 33.35

0.0152

ApoAI (mg/dL)

171.51 ± 31.16

181.18 ± 34.89

175.33 ± 31.70

0.7800

ApoB (mg/dL)

100.26 ± 38.96

104.89 ± 29.03

107.16 ± 32.87

0.3300

Insulin (uiU/mL)

4.97 (3.85-7.00)

4.56 (3.18-6.16)

5.34 (3.60-7.15)

0.9000

Glucose (mg/dL)

89.64 ± 8.54

96.11 ± 10.70

94.16 ± 9.46

0.0900

HOMA Index

1.06 (0.89-1.52)

1.02 (0.74-1.51)

1.15 (0.78-1.75)

0.6000

HGB (g/dL)

14.17 ± 1.15

14.23 ± 1.20

13.93 ± 1.09

0.2400

HbA1c (%)

5.45 ± 0.36

5.77 ± 0.43

5.75 ± 0.41

0.0027

GGT (U/L)

44.00 ± 14.98

45.21 ± 16.93

49.44 ± 13.57

0.0700

AST (U/L)

19.00 (16.00-24.00)

19.00 (15.00-22.50)

23.00 (19.50-27.00)

0.0019

ALT (U/L)

35.00 (30.00-41.00)

37.00 (32.00-41.50)

35.00 (32.00-42.00)

0.5700

Transferrin (mg/dL)

287.11 ± 39.56

247.49 ± 39.89

248.79 ± 45.46

0.0003

Ferritin (ng/mL)

41.6 (16.3-100.70)

99.50 (54.10-155.70)

69.80 (44.00-131.10)

0.1200

Azotemia (mg/dL)

31.00 (27.00-37.00)

37.00 (33.00-43.50)

39.00 (34.00-48.00)

<0.0001

Creatinine (mg/dL)

0.81 ± 0.20

0.83 ± 0.18

0.88 ± 0.25

0.1000

PAI-1 (ng/mL)

17.62 (12.39-24.33)

17.26 (13.25-25.66)

19.61 (13.36-30.05)

0.0900

CRP (mg/L)

1.23 (0.63-2.22)

1.26 (0.66-3.17)

2.17 (1.15-5.33)

0.0307

IL6 (pg/mL)

1.16 (0.82-1.64)

1.37 (0.97-2.38)

2.39 (1.71-3.52)

<0.0001

Smoking (n/%)

10/27

19/26

9/14

0.1018

Hypertension (n/%)

4/10

15/20

34/55

<0.0001

Antihypertensive (n/%)

2/5.6

14/19.4

32/52.5

<0.0001

Antiplatelet (n/%)

0/0

3/4.2

8/13.1

0.0070

Gastro protectant (n/%)

1/2.8

4/5.6

8/13.1

0.0490

Micronutrients (n/%)

0/0

5/8.2

0.0090

CNS depressants (n/%)

2/5.6

3/4.2

8/13.1

0.1000

Thyroid therapy (n/%)

0/0

2/2.8

3/4.9

0.2000

Lipid-lowering (n/%)

0/0

4/5.6

10/16.4

0.0030

Variables with Gaussian distribution are expressed as mean ± SD; variables with skewed distribution as median and interquartile range. In bold statistically significant P trend value. BMI=body mass index; WC=Waist Circumference; H=Hip; W/H=Waist/Hip ratio; WBC=White blood cells, RBC=Red blood cells; HDL=High Density Lipoprotein; LDL=Low Density Lipoprotein; ApoAI=Apolipoprotein AI; ApoB=Apolipoprotein B; HGB=Hemoglobin; HbA1c=glycated hemoglobin; GGT=Gamma Glutamyl transferase; AST=Aspartate transaminase; ALT=Alanine transferase; PAI‐1=Plasminogen activator inhibitor‐1; CRP= C-reactive Protein; IL6=Interleukin 6; CNS=Central Nervous System.

cRAGE but not esRAGE decreases with aging

In order to determine the influence of age on circulating RAGE isoforms, we measured total sRAGE, esRAGE and cRAGE in the serum subjects of our cohort. Total sRAGE and cRAGE levels displayed a progressive decrease across the age groups with a significant difference between the young and middle age or elderly-old groups (Fig. 1A). sRAGE and cRAGE variations showed a significant inverse correlation during aging that is stronger for cRAGE (Fig. 1B). In contrast, levels of esRAGE remained almost constant among the groups and showed no correlation with age (Fig. 1). Distributions of all RAGE isoforms were not different between subjects affected and not affected by hypertension, therefore, hypertensive individuals were not removed from the studied population (log_sRAGE P=0.695; log_esRAGE P=0.658; log_cRAGE P=0.159).

Figure 1. Circulating cRAGE but not esRAGE decreases with aging in healthy subjects. cRAGE values were derived by subtracting esRAGE values from the total sRAGE. (A) Bars represent serum levels of total sRAGE, cRAGE and esRAGE in three age groups of a healthy population, young (≤45 yrs; n=35-37), middle age (46-64 yrs; n=66-72) and elderly-old (≥65 yrs; n=59-60). Data are in the original units. Values are expressed as median and interquartile range. **P < 0.01; ***P < 0.0001; Kruskal-Wallis with Dunn’s multiple comparison test. (B) Scatter plots showing correlation between age and sRAGE, cRAGE or esRAGE. Variables showed a skew-ness distribution and were log-transformed. r=Pearson’s coefficient. P<0.05 was considered statistically significant; n=159-169.

Interactions age*gender revealed non-significant difference with aging in all RAGE isoforms between males and females (sRAGE P= 0.398; esRAGE P=0.380; cRAGE P=0.919). However, sRAGE and cRAGE but not esRAGE, declined differently with gender, in particular females showed a progressive reduction across the age groups, while males evidenced a significant drop already in the middle-age subjects compared to the young ones that remaining unaltered in the elderly-old group (Fig. 2). As consequence, both sRAGE and cRAGE levels of the middle-age females were significantly higher in respect to males (Fig.2).

The effect of age on circulating RAGE isoforms in male and female. cRAGE values were derived by subtracting esRAGE values from the total sRAGE. Bars represent serum levels of total sRAGE, cRAGE and esRAGE in the male and female of three age groups of a healthy population, young (≤45 yrs; male n=17, female n=18-19), middle age (46-64 yrs; male n=34-35, female n=32-37) and elderly-old (≥65 yrs; male n=23, female n=36-37). Values are expressed as median and interquartile range. *P

Figure 2. The effect of age on circulating RAGE isoforms in male and female. cRAGE values were derived by subtracting esRAGE values from the total sRAGE. Bars represent serum levels of total sRAGE, cRAGE and esRAGE in the male and female of three age groups of a healthy population, young (≤45 yrs; male n=17, female n=18-19), middle age (46-64 yrs; male n=34-35, female n=32-37) and elderly-old (≥65 yrs; male n=23, female n=36-37). Values are expressed as median and interquartile range. *P < 0.05; **P < 0.01; ***P < 0.0001; Kruskal-Wallis with Dunn’s for multiple comparison test between age groups of the same gender; Mann Whitney test between male and female of the same age group.

Thus, our data indicate that among RAGE isoforms, only cRAGE effectively decrease with age and the differences of sRAGE levels associated to aging are influenced by cRAGE variations.

AGEs and S100A8/A9 but not HMGB1 increase with aging

To assess RAGE ligands variations with age, we measured HMGB1, AGEs and S100A8/A9 in our population. HMGB1 did not vary with age (Fig. 3). Both AGEs and S100A8/A9 showed a tendency to increase across the age groups (Fig. 3A) and their levels exhibited a significant positive correlation with age, S100A8/A9 showing the highest correlation coefficient value (Fig. 3B).

The effect of age on circulating levels of RAGE ligands: AGEs, S100A8/A9 and HMGB1. (A) Bars represent serum levels of indicated RAGE ligands in three age groups of a healthy population, young (≤45 yrs; n=36), middle age (46-64 yrs; n=65-71) and elderly-old (≥65 yrs; n=57-61). Data are in the original units. Values are expressed as median and interquartile range. Kruskal-Wallis with Dunn’s multiple comparison test. (B) Scatter plots showing correlation between age and HMGB1, AGEs or S100A8/A9. Variables showed a skew-ness distribution and were log-transformed. r=Pearson’s coefficient. P

Figure 3. The effect of age on circulating levels of RAGE ligands: AGEs, S100A8/A9 and HMGB1. (A) Bars represent serum levels of indicated RAGE ligands in three age groups of a healthy population, young (≤45 yrs; n=36), middle age (46-64 yrs; n=65-71) and elderly-old (≥65 yrs; n=57-61). Data are in the original units. Values are expressed as median and interquartile range. Kruskal-Wallis with Dunn’s multiple comparison test. (B) Scatter plots showing correlation between age and HMGB1, AGEs or S100A8/A9. Variables showed a skew-ness distribution and were log-transformed. r=Pearson’s coefficient. P < 0.05 was considered statistically significant; n=159-169.

Distributions of RAGE ligands were not different between subjects affected and not affected by hypertension, therefore, hypertensive individuals were not removed from the studied population (log_HMGB1 P=0.786; log_S100A8/9 P=0.927; log_AGEs P= 0.993).

Determinants of serum levels of RAGE isoforms

In order to assess whether in addition to age RAGE isoforms were associated with other variables of our population, we performed a univariate correlation analysis. We found that sRAGE inversely correlates with WC, W/H, insulin and HOMA index, Cholesterol, Ferritin, PAI-1, AGEs, S100A8/A8 and HMGB1; esRAGE inversely correlates with WC, W/H, HGB, insulin and HOMA index, ALT and ferritin, while positively with AGEs; cRAGE inversely correlates with WC, W/H ratio, PAI-1, HMGB1, AGEs, S100A8/A9 and antihypertensive drugs (Table 2). As expected, both esRAGE and cRAGE had high positive correlation with sRAGE (Table 2).

Table 2. Univariate correlation analysis between RAGE isoforms and population variables.

	log sRAGE			log esRAGE		log cRAGE
	r	P		r	P	r	P
Sex (n/% male)	-0.118		0.1276	-0.137	0.0856	-0.025	0.7543
BMI (Kg/m²)	-0.089		0.2514	-0.147	0.0654	-0.027	0.7417
WC (cm)	-0.262		0.0006	-0.247	0.0018	-0.168	0.0351
H (cm)	-0.020		0.8007	-0.058	0.4710	0.023	0.7791
W/H	-0.347		<0.0001	-0.290	0.0002	-0.256	0.0012
WBC (10³/uL)	-0.026		0.7421	-0.044	0.5864	0.033	0.6792
RBC (10⁶/uL)	-0.063		0.4138	-0.149	0.0613	0.012	0.8823
log Triglycerides (mg/dL)	0.007		0.9243	-0.025	0.7586	-0.035	0.6614
Cholesterol (mg/dL)	0.157		0.0419	0.113	0.1584	0.033	0.6827
HDL (mg/dL)	0.115		0.1364	0.105	0.1890	0.062	0.4377
LDL (mg/dL)	-0.034		0.6581	-0.105	0.1898	-0.062	0.4374
ApoAI (mg/dL)	-0.070		0.3689	-0.009	0.9098	-0.065	0.4175
ApoB (mg/dL)	-0.007		0.9270	-0.070	0.3861	-0.018	0.8245
log Insulin (uiU/mL)	-0.175		0.0236	-0.192	0.0155	-0.060	0.4509
Glucose (mg/dL)	-0.019		0.8093	-0.026	0.7420	-0.006	0.9437
log HOMA Index	-0.170		0.0276	-0.190	0.0166	-0.056	0.4832
HGB (g/dL)	-0.089		0.2490	-0.175	0.0282	0.017	0.8307
HbA1c (%)	-0.004		0.9568	-0.042	0.6031	0.028	0.7268
GGT (U/L)	-0.080		0.3033	-0.081	0.3152	-0.108	0.1776
log AST (U/L)	-0.044		0.5698	-0.080	0.3181	-0.083	0.3014
log ALT (U/L)	-0.060		0.4421	-0.211	0.0079	0.075	0.3487
Transferrin (mg/dL)	-0.030		0.7013	-0.112	0.1625	0.001	0.9890
log Ferritin (ng/mL)	-0.201		0.0093	-0.212	0.0076	-0.044	0.5876
log Azotemia (mg/dL)	-0.100		0.1979	0.011	0.8919	-0.138	0.0843
Creatinine (mg/dL)	0.071		0.3635	0.037	0.6443	0.014	0.8654
log PAI-1 (ng/mL)	-0.205		0.0078	-0.128	0.1090	-0.183	0.0213
log CRP (mg/L)	-0.113		0.1477	-0.108	0.1791	-0.137	0.0899
log IL6 (pg/mL)	-0.114		0.1473	-0.081	0.3236	-0.077	0.3450
log HMGB1 (ng/mL)	-0.271		0.0005	-0.003	0.9672	-0.290	0.0002
log S100A8/A9 (ng/mL)	-0.265		0.0008	-0.123	0.1242	-0.223	0.0049
log AGEs (μg/mL)	-0.184		0.0172	0.204	0.0103	-0.374	<0.0001
log sRAGE (pg/mL)	-		-	0.600	0.0001	0.720	<0.0001
Smoking (n/%)	0.087		0.2642	0.109	0.1723	0.065	0.4187
Ipertension (n/%)	-0.040		0.6047	0.036	0.6502	-0.124	0.1202
Antihypertensive (n/%)	-0.011		0.8867	0.124	0.1201	-0.159	0.0465
Antiplatelet (n/%)	-0.125		0.1077	-0.060	0.4551	-0.116	0.1453
Gastro protectant (n/%)	-0.012		0.8806	0.047	0.5608	-0.067	0.4058
Micronutrients (n/%)	-0.014		0.8562	0.120	0.1315	-0.111	0.1646
CNS depressants (n/%)	0.028		0.7206	0.121	0.1306	-0.144	0.0720
Thyroid therapy (n/%)	-0.050		0.5181	-0.059	0.4601	-0.075	0.3508
Lipid-lowering (n/%)	-0.039		0.6190	0.004	0.9636	-0.066	0.4101
Variables with Gaussian distribution are expressed as mean ± SD; variables with skewed distribution as median and interquartile range. In bold statistically significant P trend value. r= Pearson correlation coefficient. n=158-169. BMI=body mass index; WC=Waist Circumference; H=Hip; W/H=Waist/Hip ratio; WBC=White blood cells, RBC=Red blood cells; HDL=High Density Lipoprotein; LDL=Low Density Lipoprotein; ApoAI=Apolipoprotein AI; ApoB=Apolipoprotein B; HGB=Hemoglobin; HbA1c=glycated hemoglobin; GGT=Gamma Glutamyl transferase; AST=Aspartate transaminase; ALT=Alanine transferase; PAI‐1=Plasminogen activator inhibitor‐1; CRP=C-reactive Protein; IL6=Interleukin 6; HMGB1=High Mobility Group Box 1; S100A8/A9=Calgranulin A/Calgranulin B; AGEs=Advanced glycation end-products; sRAGE=soluble Receptor for advanced glycation end-products; CNS=Central Nervous System.

To identify the determinants for RAGE isoforms changes in our cohort, we executed a multivariate analysis taking in consideration traditional risk factors, RAGE ligands and anti-hypertensive drugs. sRAGE negatively associated with age, W/H and HMGB1, and positively with Triglycerides; esRAGE inversely associated with W/H and positively with AGEs; cRAGE inversely associated with age, W/H, ferritin, S100A8/A9, HMGB1 and AGEs (Table 3). S100A8/A9 was excluded as a variable from the analysis since its strong correlation with HMGB1 generates instability in the estimates of the multivariable model parameters. However, S100A8/A9 associated with sRAGE (β=-0.2003, SE=0.0927, P=0.0326) and cRAGE (β=-0.6551, SE=0.2730, P=0.0178) but not with esRAGE (β=-0.0514, SE=0.0852, P=0.5473) when it replaced HMGB1 in the same multivariable model.

Table 3. Multivariable analysis between RAGE isoforms and population variables.

	log sRAGE				log esRAGE			log cRAGE
Variable	β	SE	P	β		SE	P		β	SE	P
Age (yrs)	-0.0062	0.0019	0.0014	-0.0017		0.0018	0.3719		-0.0148	0.0043	0.0008
Sex (n/%)	-0.0395	0.0576	0.4945	-0.0361		0.0546	0.5097		0.0490	0.1282	0.7030
BMI (Kg/m²)	0.0003	0.0061	0.9623	-0.0040		0.0057	0.4896		0.0075	0.0134	0.5781
W/H	-1.0193	0.3778	0.0079	-0.9193		0.3643	0.0128		-1.8048	0.8557	0.0368
log Triglycerides (mg/dL)	0.2954	0.1127	0.0097	0.2008		0.1034	0.0543		0.2307	0.2429	0.3440
HDL (mg/dL)	0.0001	0.0019	0.9803	0.0001		0.0017	0.9671		-0.0003	0.0040	0.9321
LDL (mg/dL)	-0.0001	0.0006	0.9142	-0.0002		0.0006	0.6989		-0.0011	0.0014	0.4464
log Insulin (uiU/mL)	-0.1818	0.0977	0.0651	-0.1788		0.0915	0.0529		0.0223	0.2150	0.9174
Glucose (mg/dL)	0.0016	0.0023	0.4920	0.0002		0.0021	0.9083		0.0046	0.0050	0.3586
log Ferritin (ng/mL)	0.0204	0.0626	0.7451	-0.0641		0.0579	0.2700		0.2980	0.1359	0.0301
log CRP (mg/L)	0.0102	0.0476	0.8307	-0.0088		0.0436	0.8403		-0.0483	0.1024	0.6384
log IL6 (pg/mL)	0.0053	0.0825	0.9490	-0.0366		0.0763	0.6325		0.3081	0.1792	0.0879
log HMGB1 (ng/mL)	-0.0641	0.0294	0.0306	0.0110		0.0271	0.6843		-0.1865	0.0636	0.0040
log AGEs (μg/mL)	-0.0588	0.0881	0.5059	0.3219		0.0832	0.0002		-0.6662	0.1954	0.0009
Antihypertensive (n/%)	0.0667	0.0536	0.2160	0.0821		0.0506	0.1072		-0.0010	0.1189	0.9934
In bold statistically significant P value. n=158-169. BMI=body mass index; W/H=Waist/Hip ratio; HDL=High Density Lipoprotein; LDL=Low Density Lipoprotein; CRP=C-reactive Protein; IL6=Interleukin 6; HMGB1=High Mobility Group Box 1; AGEs=Advanced glycation end-products.

Thus, in a general population, among sRAGE isoforms, age is a significant determinant only for cRAGE while W/H ratio is a determinant for both isoforms. cRAGE mainly correlated with inflammation markers while esRAGE with obesity-related and insulin resistance markers.

AGEs enhance cellular amount of FL-RAGE and reduce cRAGE levels

Then, we ought to determine whether RAGE ligands affect cRAGE production and FL-RAGE expression in vitro. We generated R3/1 cells, which do not express detectable amount of any endogenous RAGE isoforms, stably expressing FL-RAGE (R3/1/FL-RAGE) or the empty vector (R3/1-pLXSN) (Fig. 4A [2];). FL-RAGE proteolysis is constitutive [24] and indeed, R3/1/FL-RAGE, but not R3/1-pLXSN cells, released in the supernatant a robust amount of cRAGE (Fig. 4B). Since in our cohort AGEs showed the strongest association with cRAGE (Tables 2, 3), we stimulated R3/1/FL-RAGE cells with glycated human albumin (Gly-HA) or control human albumin (HA) and found that the basal production of cRAGE was progressively reduced by increasing concentration of Gly-HA but not by corresponding concentrations of HA (Fig. 4C). Then, we checked expression of FL-RAGE in cell lysates and found that Gly-HA but not HA induced a slight but significant upregulation of FL-RAGE levels.

Effect of glycated albumin on FL-RAGE proteolysis in vitro. (A) Expression of FL-RAGE in R3/1-pLXSN (pLXSN) or R3/1-FL-RAGE (FL-RAGE) was determined using 20 µg of protein lysate with a specific antibody raised against the extracellular domain of RAGE. GAPDH detection was used as normalizer. (B) Quantification of cRAGE in the supernatant of R3/1-pLXSN (pLXSN) or R3/1-FL-RAGE (FL-RAGE) cells 6 h after medium changing by means of ELISA assay. Data are expressed as mean ± SD. ***, P≤0.0001. Unpaired t test ; n=4. (C) Quantification of cRAGE in the supernatant of R3/1-FL-RAGE cells treated or not (--) with indicated concentrations of control human albumin (HA) or glycated human albumin (Gly-HA) for 6 h by means of ELISA assay. Data are expressed as mean ± SD. **, P≤0.01. One-way ANOVA with Bonferroni post-hoc test; n = 4. (D) Representative Western blot (left panel) and corresponding quantification (right panel) of FL-RAGE expression using 5 μg protein lysates of R3/1-FL-RAGE cells treated or not (--) with 500 μg/mL HA or Gly-HA for 6 h. GAPDH detection was used as normalizer. Data are expressed as mean ± SD. *, P≤0.05. One-way ANOVA with Bonferroni post-hoc test; n=4; a.u., arbitrary units.

Figure 4. Effect of glycated albumin on FL-RAGE proteolysis in vitro. (A) Expression of FL-RAGE in R3/1-pLXSN (pLXSN) or R3/1-FL-RAGE (FL-RAGE) was determined using 20 µg of protein lysate with a specific antibody raised against the extracellular domain of RAGE. GAPDH detection was used as normalizer. (B) Quantification of cRAGE in the supernatant of R3/1-pLXSN (pLXSN) or R3/1-FL-RAGE (FL-RAGE) cells 6 h after medium changing by means of ELISA assay. Data are expressed as mean ± SD. ***, P≤0.0001. Unpaired t test ; n=4. (C) Quantification of cRAGE in the supernatant of R3/1-FL-RAGE cells treated or not (--) with indicated concentrations of control human albumin (HA) or glycated human albumin (Gly-HA) for 6 h by means of ELISA assay. Data are expressed as mean ± SD. **, P≤0.01. One-way ANOVA with Bonferroni post-hoc test; n = 4. (D) Representative Western blot (left panel) and corresponding quantification (right panel) of FL-RAGE expression using 5 μg protein lysates of R3/1-FL-RAGE cells treated or not (--) with 500 μg/mL HA or Gly-HA for 6 h. GAPDH detection was used as normalizer. Data are expressed as mean ± SD. *, P≤0.05. One-way ANOVA with Bonferroni post-hoc test; n=4; a.u., arbitrary units.

Thus, these data confirm that AGEs are able to inhibit directly FL-RAGE shedding leading to both membrane-bound FL-RAGE increase and soluble cRAGE reduction.

Discussion

In the present study, we analysed for the first time the circulating levels of different isoforms of soluble RAGE, i.e. cRAGE and esRAGE, in a cohort of healthy subjects aged 20-90 years-old, to investigate their age-related trends. We show that esRAGE, deriving from alternative splicing [22], does not vary during aging and eventually represents the predominant circulating sRAGE isoform in the elderly-old subjects (Fig. 1B). On the other hand, cRAGE, generated by proteolytic cleavage of FL-RAGE by ADAM10 and/or MMPs [24,26], is the most abundant circulating sRAGE in the young group and significantly decreases with advancing age dropping to very low if any levels in the elderly-old cohort (Fig. 1C). Therefore, the age-related decline of sRAGE in the blood is due to cRAGE changes (Fig.1). No significant gender differences were observed for both isoforms during aging, except for a significant higher concentration of sRAGE in the middle-age group of females compared to males ascribable to cRAGE variations (Fig. 3). Our data extend previously published data showing that in a general population sRAGE levels is slightly but significantly higher in middle-age women compared to men [38,39]. The reason for this is currently unknown, but estrogen levels may be involved [43,44].

Modulation of RAGE isoforms expression in different organs and tissues during healthy aging has not been reported. In physiological conditions, RAGE is predominately expressed in alveolar type I cells of the lung and barely detectable in other cell types [8,10,11,45]. Indeed, human pulmonary lysates presents three RAGE variants (FL-RAGE, cRAGE and esRAGE) and cRAGE is the most abundant one, indicating a continuous and massive shedding of FL-RAGE, while esRAGE levels are low [24,46]. Therefore, it is plausible that the lung contributes as the major source of circulating cRAGE, whose decrease may depend on loss of airway epithelium and/or to a lower expression or activity of ADAM10 or MMPs with aging. Nevertheless, we cannot exclude that inhibition of FL-RAGE proteolysis on other tissues may contribute to age-mediated circulating cRAGE changes. Additional studies in human and experimental models are necessary to clarify this issue.

Importantly, in addition to cRAGE decline, the inhibition of FL-RAGE proteolysis also leads to an increase of its own expression [8]. Notably, our study also reveals that serum levels of RAGE ligands such as AGEs and S100A8/A9 significantly increase with age in healthy subjects (Fig. 3), and HMGB1, AGEs and S100A8/A9 inversely correlate and are independent predictors of cRAGE (Table 2-3). Interestingly, AGEs show the strongest association with cRAGE (Table 2-3), and we demonstrated that these ligands can regulate directly FL-RAGE/cRAGE ratio, since in vitro stimulation of alveolar-like cells with glycated albumin reduces the constitutive production of cRAGE and enhances FL-RAGE protein expression (Fig 4). Notably, we also reported that in our population circulating AGEs are positive independent predictors of esRAGE (Table 3) indicating a possible feedback mechanism to counterbalance cRAGE downregulation.

It is well established that, the binding of FL-RAGE with ligands drives a cascade of signaling that converges at nuclear factor-κB (NF-κB) promoting the secretion of pro-inflammatory molecules, recruitment of inflammatory cells to damaged tissue and cell adhesion [3–7,47]. Therefore, the incremental FL-RAGE/ligands axis activation during aging could contribute to the chronic, systemic and low-grade inflammatory condition, named “inflammaging”, typical of elderly, and to the development of age-related diseases, such as diabetes, atherosclerosis and cancer [48]. In these contexts, AGEs have been extensively shown to play a pivotal role [49].

Additionally, since both isoforms of sRAGE can act as a decoy receptor suppressing FL-RAGE/ligands pro-inflammatory and chemotactic activity [8,14,24,27], the progressive decrease of cRAGE with aging could further free RAGE ligands to fuel the inflammatory signals favoring the onset of age-related pathologies. Accordingly, in our cohort, cRAGE inversely correlates with the inflammatory marker PAI-1 (Table 2), known to increase in age-associated clinical conditions including cardiovascular diseases, type 2 diabetes (T2DM), obesity and inflammation [50] and shows also an almost significant inverse correlation with CRP (Table 2).

Experimental animal models suggest a protective role of sRAGE against inflammation associated with obesity and T2DM [14,28]. Several clinical studies have also reported significant negative correlation of sRAGE or esRAGE with BMI, WC, W/H and other obesity indices in a general population, obese and pre-diabetic subjects [36–39,51–53]. Much less is known about cRAGE variations in these pathological contexts. Our data expand previous published reports demonstrating that in a healthy population, W/H negatively associates with and is an independent predictor of both RAGE isoforms (Table 2-3); interestingly, we also found that esRAGE inversely correlates with insulin, HOMA index and ALT and sRAGE correlations with these insulin resistance-related markers depend exclusively on esRAGE variations (Table 2).

How W/H influences cRAGE and esRAGE generation is not known. Recent evidences describe that weight loss by dietary interventions increases esRAGE [52,54] but not cRAGE levels [54] indicating that only the mechanism governing esRAGE production is directly affected by fat deposition changes and is reversible. Likely, the influence of W/H on cRAGE levels is an indirect consequence of body composition changes, such as weight gain and accumulation of abdominal fat, occurring during aging [55]. Accordingly, increased visceral fat mass is a significant contributor of low-grade systemic inflammation and in our cohort cRAGE inversely correlates with PAI-1 (Table 2) which is largely produced by abdominal adipose tissue [56,57].

A limitation of this study is the small number of enrolled subjects and the cross-sectional design. Furthermore, several polymorphisms of RAGE gene (AGER) have been identified, including the SNP Gly82Ser that has been associated to decreased sRAGE serum concentrations [58] and lung function [59]. We did not analysed the influence of this genotype on cRAGE and esRAGE levels in our population. Another limitation is the ELISA assay used for AGEs quantification that does not distinguishes between multiple AGEs species.

In conclusion, our finding indicates that in a healthy population, among sRAGE variants, esRAGE represents a more consistent marker of metabolic perturbations associated to insulin resistance and obesity, while cRAGE is a trustworthy biomarker of physiological aging and inflammation. Hence, both RAGE isoforms may be associated with different age-related diseases and their risk factors and could be innovative parameters for the estimation of “biological age”. Further studies are needed to confirm this hypothesis.

Materials and Methods

Study population

Participants were recruited from the Italian National Research Center on Aging (INRCA), Ancona. All subjects gave their written informed consent to participate in the study, which was approved by INRCA’s Ethics Committee. Serum of roughly 169 healthy subjects aged 20-90 years (yrs) (M=75, F=94) was tested for sRAGE (n=169), esRAGE (n=161), cRAGE (n=161), HMGB1 (n=164), S100A8/A9 (n=158), AGEs (n=168) and IL6 (n=164) along with other variables (Table 1). The health status of subjects was assessed using standardized questionnaires, laboratory assays and physical examination. Subjects were considered healthy if at the time of blood collection they did not have any major acute and/or chronic age-related disease such as AMI, CHF, Alzheimer’s disease (AD), T2DM or cancer. Subjects with a Cumulative Illness Rating Scale (CIRS) > 2, which indicates a comorbid state, were excluded [60]. All the studied subjects consumed a Mediterranean diet.

Subjects were defined as hypertensive when they were under active treatment or when their systolic blood pressure was >140 mmHg and/or their diastolic blood pressure was >90 mmHg, on three different occasions. Body mass index (BMI) was determined as body weight in Kg over height in m². Waist circumference (WC) is measured at the midpoint between the lower margin of the last palpable ribs and the top of the iliac crest using a measuring tape. Hip circumference (H) is measured around the widest portion of the buttocks. For both measurements, the individual is standing and wearing little clothing. The measurements are taken at the end of a normal respiration. W/H is calculated as waist measurement divided by hip measurement.

Laboratory assays

Overnight fasting venous blood samples of all subjects were collected from 8:00 to 10:00 a.m in EDTA and citrate tubes. White blood cell, monocyte and platelet counts were performed by standard automated procedures (Sysmex XE-2100, Kobe, Japan). Blood concentrations of glycosylated hemoglobin (HbA1c) were measured by a G8 HPLC analyzer (TOSOH BIOSCIENCE, USA). An immunoenzymatic method was used for PAI-1 antigen (Biopool, Sweden). Total and HDL cholesterol, fasting insulin, fibrinogen, and apolipoprotein AI and B (ApoAI and ApoB), triglycerides, creatinine, and fasting glucose were measured using commercially available kits on an automated clinical chemistry COBAS analyzer (Roche-Hitachi, Basel, Switzerland). Highly sensitive C-reactive protein (hsCRP) was determined by the particle-enhanced immunoturbidimetric assay (CRP High Sensitive, Roche-Hitachi) on a COBAS analyzer. HOMA index was calculated as Glucose (mg/100 ml)* Insulin (uIU/ml)/405.

RAGE isoforms and ligands measurements

Whole human peripheral blood was collected in a tube without anticoagulants. Once collected, the blood was left to clot undisturbed at room temperature for 15–30 minutes. The clot was removed by centrifuging at 2000 g for 10 minutes in a refrigerated (4°C) centrifuge. The resulting supernatant was immediately transferred into a clean polypropylene tubes, aliquoted and stored at -80°C. ELISA kits were used to test serum levels of S100A8/A9 (EKMRP8/14 Bühlmann Laboratories Ag, Switzerland), HMGB1 (ST51011, IBL International-Tecan, Switzerland), AGEs (STA-518 Cell Biolabs, INC. San Diego, CA) and IL6 (HS600B, R&D Systems Inc., MN, USA) following manufacturer’s instruction. Total human sRAGE was determined by a commercial ELISA (DY1145, Human RAGE DuoSet ELISA, R&D Systems Inc.) and included the detection of both cRAGE and esRAGE variants. Serum esRAGE concentration was detected by an ELISA kit with a specific antibody raised against the unique C-terminal 9 amino acids (332-347) sequence (K1009-1, B-bridge International, CA, USA). Serum cRAGE was determined by subtracting esRAGE from sRAGE as already described [36,54]. cRAGE values equal to zero were imposed to be identical to the lowest determined value.

Cell culture

Rat alveolar type I-like R3/1 cells and derived clones were grown in Dulbecco modified Eagle medium (DMEM) supplemented with 10% FBS and 1% penicillin/streptomycin. To generate R3/1-pLXSN or R3/1-FL-RAGE clones, R3/1 cells were infected with retrovirus carrying p-LXSNneo or p-LXSN-neo-FL-RAGE retrovectors. Clones were selected with 500 mg/ml G418 ([2]; Invitrogen, Carlsbad, California, USA).

Assessment of FL-RAGE expression and cRAGE production

Two thousand R3/1-pLXSN or R3/1-FL-RAGE clones were seeded on 6 well-plate (Costar, Kennebunk, ME, USA) and treated with indicated concentration of human glycated Albumin (HGA; #A8301, Sigma Aldrich, Saint Louis, Missouri, USA) or not-glycated human Albumin (HA; #A7736, Sigma Aldrich) as control in DMEM supplemented with 0.1% FBS for 6 hours. Supernatant of cells was tested for cRAGE concentration by a commercial ELISA (DY1145, Human RAGE DuoSet ELISA, R&D Systems Inc., MN, USA). Cells were harvested in RIPA buffer in the presence of proteases inhibitors (P8849, Sigma-Aldrich), incubated in ice for 30 min and centrifuged at 12000g for 15 minutes at 4°C. Protein extracts were separated by SDS-PAGE and transferred to Amersham Hybond ECL Nitrocellulose membranes (GE Healthcare, Little Chalfont, United Kingdom). Membranes were incubated with a goat anti-human RAGE (1 µg/ml; cat. AF1145; R&D Systems Minneapolis, MN, USA) or an antibody against GAPDH (0.2 µg/mL, sc-25778, Santa Cruz Biotechnology) as a loading control. Proteins were visualized by an enhanced chemiluminescence (ECL) detection system (cat. RPN2106, GE Healthcare) and acquired with a ChemiDoc™ MP Imaging System (Biorad, Hercules, CA, USA). Protein bands were quantified by densitometry analysis using ImageJ.

Statistical analysis

Qualitative variables were reported as frequencies and percentages. Quantitative variables were reported as mean plus standard deviation (continuous variables normally distributed) or median and interquartile range (continuous variables skewed distributed). Skewed distributed variables were transformed in logarithm to the base 10: Triglycerides, Insulin, HOMA Index, AST, ALT, Ferritin, Azotemia, PAI-1, CRP, IL6, HMGB1, S100A8/A9, AGEs, sRAGE, esRAGE and cRAGE. Population features changes were classified according to age into three classes, young (≤45 yrs), middle age (46-64 yrs) and elderly-old (≥65 yrs) and linear trends across categories were evaluated. T-test was used to compare means between two groups. Non-parametric ANOVA Kruskal-Wallis with Dunn’s multiple comparisons test between different age classes by gender or Mann Whitney test between male and female of the same age class were applied. The crude relation between RAGE isoforms and the other variables were assessed by Pearson correlation coefficient for continuous variables and by Spearman rank correlation for dichotomous variables. The independent effect of each variable on RAGE isoforms from the other variables were evaluated by multivariable linear regression analysis. Statistical interactions age*gender were also computed to evaluate different effect of age on RAGE isoforms by gender. In vitro experiments were performed at least four times. The Shapiro-Wilk test was used to assess the normality of distribution of investigated parameters. Differences between two groups or more than two groups were conducted with unpaired Student's t-test or one-way analysis of variance (ANOVA) with Bonferroni post-hoc test, respectively, and values were presented as mean ± SD. The analyses were performed using SAS9.4 program or GraphPad Prism software version 7 (GraphPad Software, Inc, La Jolla, CA, USA). A value of p <0.05 was considered statistically significant.

Supplementary Materials

Supplementary Table 1

Acknowledgments

We thank Drs. Stefano Genovese, Gualtiero I. Colombo and Marco E. Bianchi for helpful discussion.

Conflicts of Interest

None.

Funding

This work was supported by funding from Fondazione Cariplo (Research on Ageing diseases 2015) and Centro Cardiologico Monzino-IRCCS (Ricerca Corrente 2016-2019) to Angela Raucci. Francesco Scavello was supported by a Fellowship of Fondazione IEO-Monzino 2017-2018.

References

1. Fritz G. RAGE: a single receptor fits multiple ligands. Trends Biochem Sci. 2011; 36:625–32. https://doi.org/10.1016/j.tibs.2011.08.008 [PubMed]
2. Sessa L, Gatti E, Zeni F, Antonelli A, Catucci A, Koch M, Pompilio G, Fritz G, Raucci A, Bianchi ME. The receptor for advanced glycation end-products (RAGE) is only present in mammals, and belongs to a family of cell adhesion molecules (CAMs). PLoS One. 2014; 9:e86903. https://doi.org/10.1371/journal.pone.0086903 [PubMed]
3. Frommhold D, Kamphues A, Hepper I, Pruenster M, Lukic IK, Socher I, Zablotskaya V, Buschmann K, Lange-Sperandio B, Schymeinsky J, Ryschich E, Poeschl J, Kupatt C, et al. RAGE and ICAM-1 cooperate in mediating leukocyte recruitment during acute inflammation in vivo. Blood. 2010; 116:841–49. https://doi.org/10.1182/blood-2009-09-244293 [PubMed]
4. Orlova VV, Choi EY, Xie C, Chavakis E, Bierhaus A, Ihanus E, Ballantyne CM, Gahmberg CG, Bianchi ME, Nawroth PP, Chavakis T. A novel pathway of HMGB1-mediated inflammatory cell recruitment that requires Mac-1-integrin. EMBO J. 2007; 26:1129–39. https://doi.org/10.1038/sj.emboj.7601552 [PubMed]
5. Penzo M, Molteni R, Suda T, Samaniego S, Raucci A, Habiel DM, Miller F, Jiang HP, Li J, Pardi R, Palumbo R, Olivotto E, Kew RR, et al. Inhibitor of NF-kappa B kinases alpha and beta are both essential for high mobility group box 1-mediated chemotaxis [corrected]. J Immunol. 2010; 184:4497–509. https://doi.org/10.4049/jimmunol.0903131 [PubMed]
6. Volz HC, Laohachewin D, Seidel C, Lasitschka F, Keilbach K, Wienbrandt AR, Andrassy J, Bierhaus A, Kaya Z, Katus HA, Andrassy M. S100A8/A9 aggravates post-ischemic heart failure through activation of RAGE-dependent NF-κB signaling. Basic Res Cardiol. 2012; 107:250. https://doi.org/10.1007/s00395-012-0250-z [PubMed]
7. Volz HC, Seidel C, Laohachewin D, Kaya Z, Müller OJ, Pleger ST, Lasitschka F, Bianchi ME, Remppis A, Bierhaus A, Katus HA, Andrassy M. HMGB1: the missing link between diabetes mellitus and heart failure. Basic Res Cardiol. 2010; 105:805–20. https://doi.org/10.1007/s00395-010-0114-3 [PubMed]
8. Antonelli A, Di Maggio S, Rejman J, Sanvito F, Rossi A, Catucci A, Gorzanelli A, Bragonzi A, Bianchi ME, Raucci A. The shedding-derived soluble receptor for advanced glycation endproducts sustains inflammation during acute Pseudomonas aeruginosa lung infection. Biochim Biophys Acta Gen Subj. 2017; 1861:354–64. https://doi.org/10.1016/j.bbagen.2016.11.040 [PubMed]
9. Dimmeler S, Nicotera P. MicroRNAs in age-related diseases. EMBO Mol Med. 2013; 5:180–90. https://doi.org/10.1002/emmm.201201986 [PubMed]
10. Queisser MA, Kouri FM, Königshoff M, Wygrecka M, Schubert U, Eickelberg O, Preissner KT. Loss of RAGE in pulmonary fibrosis: molecular relations to functional changes in pulmonary cell types. Am J Respir Cell Mol Biol. 2008; 39:337–45. https://doi.org/10.1165/rcmb.2007-0244OC [PubMed]
11. Shirasawa M, Fujiwara N, Hirabayashi S, Ohno H, Iida J, Makita K, Hata Y. Receptor for advanced glycation end-products is a marker of type I lung alveolar cells. Genes Cells. 2004; 9:165–74. https://doi.org/10.1111/j.1356-9597.2004.00712.x [PubMed]
12. Herold K, Moser B, Chen Y, Zeng S, Yan SF, Ramasamy R, Emond J, Clynes R, Schmidt AM. Receptor for advanced glycation end products (RAGE) in a dash to the rescue: inflammatory signals gone awry in the primal response to stress. J Leukoc Biol. 2007; 82:204–12. https://doi.org/10.1189/jlb.1206751 [PubMed]
13. Mahajan N, Dhawan V. Receptor for advanced glycation end products (RAGE) in vascular and inflammatory diseases. Int J Cardiol. 2013; 168:1788–94. https://doi.org/10.1016/j.ijcard.2013.05.013 [PubMed]
14. Song F, Hurtado del Pozo C, Rosario R, Zou YS, Ananthakrishnan R, Xu X, Patel PR, Benoit VM, Yan SF, Li H, Friedman RA, Kim JK, Ramasamy R, et al. RAGE regulates the metabolic and inflammatory response to high-fat feeding in mice. Diabetes. 2014; 63:1948–65. https://doi.org/10.2337/db13-1636 [PubMed]
15. Soro-Paavonen A, Watson AM, Li J, Paavonen K, Koitka A, Calkin AC, Barit D, Coughlan MT, Drew BG, Lancaster GI, Thomas M, Forbes JM, Nawroth PP, et al. Receptor for advanced glycation end products (RAGE) deficiency attenuates the development of atherosclerosis in diabetes. Diabetes. 2008; 57:2461–69. https://doi.org/10.2337/db07-1808 [PubMed]
16. Di Maggio S, Gatti E, Liu J, Bertolotti M, Fritz G, Bianchi ME, Raucci A. The mouse-specific splice variant mRAGE_v4 encodes a membrane-bound RAGE that is resistant to shedding and does not contribute to the production of soluble RAGE. PLoS One. 2016; 11:e0153832. https://doi.org/10.1371/journal.pone.0153832 [PubMed]
17. Hudson BI, Kalea AZ, Del Mar Arriero M, Harja E, Boulanger E, D’Agati V, Schmidt AM. Interaction of the RAGE cytoplasmic domain with diaphanous-1 is required for ligand-stimulated cellular migration through activation of Rac1 and Cdc42. J Biol Chem. 2008; 283:34457–68. https://doi.org/10.1074/jbc.M801465200 [PubMed]
18. Kalea AZ, Reiniger N, Yang H, Arriero M, Schmidt AM, Hudson BI. Alternative splicing of the murine receptor for advanced glycation end-products (RAGE) gene. FASEB J. 2009; 23:1766–74. https://doi.org/10.1096/fj.08-117739 [PubMed]
19. López-Díez R, Rastrojo A, Villate O, Aguado B. Complex tissue-specific patterns and distribution of multiple RAGE splice variants in different mammals. Genome Biol Evol. 2013; 5:2420–35. https://doi.org/10.1093/gbe/evt188 [PubMed]
20. Hudson BI, Carter AM, Harja E, Kalea AZ, Arriero M, Yang H, Grant PJ, Schmidt AM. Identification, classification, and expression of RAGE gene splice variants. FASEB J. 2008; 22:1572–80. https://doi.org/10.1096/fj.07-9909com [PubMed]
21. Kalea AZ, Schmidt AM, Hudson BI. Alternative splicing of RAGE: roles in biology and disease. Front Biosci (Landmark Ed). 2011; 16:2756–70. https://doi.org/10.2741/3884 [PubMed]
22. Yonekura H, Yamamoto Y, Sakurai S, Petrova RG, Abedin MJ, Li H, Yasui K, Takeuchi M, Makita Z, Takasawa S, Okamoto H, Watanabe T, Yamamoto H. Novel splice variants of the receptor for advanced glycation end-products expressed in human vascular endothelial cells and pericytes, and their putative roles in diabetes-induced vascular injury. Biochem J. 2003; 370:1097–109. https://doi.org/10.1042/bj20021371 [PubMed]
23. Galichet A, Weibel M, Heizmann CW. Calcium-regulated intramembrane proteolysis of the RAGE receptor. Biochem Biophys Res Commun. 2008; 370:1–5. https://doi.org/10.1016/j.bbrc.2008.02.163 [PubMed]
24. Raucci A, Cugusi S, Antonelli A, Barabino SM, Monti L, Bierhaus A, Reiss K, Saftig P, Bianchi ME. A soluble form of the receptor for advanced glycation endproducts (RAGE) is produced by proteolytic cleavage of the membrane-bound form by the sheddase a disintegrin and metalloprotease 10 (ADAM10). FASEB J. 2008; 22:3716–27. https://doi.org/10.1096/fj.08-109033 [PubMed]
25. Yamakawa N, Uchida T, Matthay MA, Makita K. Proteolytic release of the receptor for advanced glycation end products from in vitro and in situ alveolar epithelial cells. Am J Physiol Lung Cell Mol Physiol. 2011; 300:L516–25. https://doi.org/10.1152/ajplung.00118.2010 [PubMed]
26. Zhang L, Bukulin M, Kojro E, Roth A, Metz VV, Fahrenholz F, Nawroth PP, Bierhaus A, Postina R. Receptor for advanced glycation end products is subjected to protein ectodomain shedding by metalloproteinases. J Biol Chem. 2008; 283:35507–16. https://doi.org/10.1074/jbc.M806948200 [PubMed]
27. Park L, Raman KG, Lee KJ, Lu Y, Ferran LJJr, Chow WS, Stern D, Schmidt AM. Suppression of accelerated diabetic atherosclerosis by the soluble receptor for advanced glycation endproducts. Nat Med. 1998; 4:1025–31. https://doi.org/10.1038/2012 [PubMed]
28. Sourris KC, Morley AL, Koitka A, Samuel P, Coughlan MT, Penfold SA, Thomas MC, Bierhaus A, Nawroth PP, Yamamoto H, Allen TJ, Walther T, Hussain T, et al. Receptor for AGEs (RAGE) blockade may exert its renoprotective effects in patients with diabetic nephropathy via induction of the angiotensin II type 2 (AT2) receptor. Diabetologia. 2010; 53:2442–51. https://doi.org/10.1007/s00125-010-1837-2 [PubMed]
29. Colhoun HM, Betteridge DJ, Durrington P, Hitman G, Neil A, Livingstone S, Charlton-Menys V, Bao W, Demicco DA, Preston GM, Deshmukh H, Tan K, Fuller JH. Total soluble and endogenous secretory receptor for advanced glycation end products as predictive biomarkers of coronary heart disease risk in patients with type 2 diabetes: an analysis from the CARDS trial. Diabetes. 2011; 60:2379–85. https://doi.org/10.2337/db11-0291 [PubMed]
30. Falcone C, Emanuele E, D’Angelo A, Buzzi MP, Belvito C, Cuccia M, Geroldi D. Plasma levels of soluble receptor for advanced glycation end products and coronary artery disease in nondiabetic men. Arterioscler Thromb Vasc Biol. 2005; 25:1032–37. https://doi.org/10.1161/01.ATV.0000160342.20342.00 [PubMed]
31. Fujisawa K, Katakami N, Kaneto H, Naka T, Takahara M, Sakamoto F, Irie Y, Miyashita K, Kubo F, Yasuda T, Matsuoka TA, Shimomura I. Circulating soluble RAGE as a predictive biomarker of cardiovascular event risk in patients with type 2 diabetes. Atherosclerosis. 2013; 227:425–28. https://doi.org/10.1016/j.atherosclerosis.2013.01.016 [PubMed]
32. Reichert S, Triebert U, Santos AN, Hofmann B, Schaller HG, Schlitt A, Schulz S. Soluble form of receptor for advanced glycation end products and incidence of new cardiovascular events among patients with cardiovascular disease. Atherosclerosis. 2017; 266:234–39. https://doi.org/10.1016/j.atherosclerosis.2017.08.015 [PubMed]
33. Liu Q, Chen HB, Luo M, Zheng H. Serum soluble RAGE level inversely correlates with left ventricular hypertrophy in essential hypertension patients. Genet Mol Res. 2016; 15. https://doi.org/10.4238/gmr.15028414 [PubMed]
34. Momma H, Niu K, Kobayashi Y, Huang C, Chujo M, Otomo A, Tadaura H, Miyata T, Nagatomi R. Lower serum endogenous secretory receptor for advanced glycation end product level as a risk factor of metabolic syndrome among Japanese adult men: a 2-year longitudinal study. J Clin Endocrinol Metab. 2014; 99:587–93. https://doi.org/10.1210/jc.2013-2936 [PubMed]
35. Di Pino A, Mangiafico S, Urbano F, Scicali R, Scandura S, D’Agate V, Piro S, Tamburino C, Purrello F, Rabuazzo AM. HbA1c identifies subjects with prediabetes and subclinical left ventricular diastolic dysfunction. J Clin Endocrinol Metab. 2017; 102:3756–64. https://doi.org/10.1210/jc.2017-00954 [PubMed]
36. Miranda ER, Somal VS, Mey JT, Blackburn BK, Wang E, Farabi S, Karstoft K, Fealy CE, Kashyap S, Kirwan JP, Quinn L, Solomon TP, Haus JM. Circulating soluble RAGE isoforms are attenuated in obese, impaired-glucose-tolerant individuals and are associated with the development of type 2 diabetes. Am J Physiol Endocrinol Metab. 2017; 313:E631–40. https://doi.org/10.1152/ajpendo.00146.2017 [PubMed]
37. Dozio E, Briganti S, Delnevo A, Vianello E, Ermetici F, Secchi F, Sardanelli F, Morricone L, Malavazos AE, Corsi Romanelli MM. Relationship between soluble receptor for advanced glycation end products (sRAGE), body composition and fat distribution in healthy women. Eur J Nutr. 2017; 56:2557–64. https://doi.org/10.1007/s00394-016-1291-0 [PubMed]
38. Norata GD, Garlaschelli K, Grigore L, Tibolla G, Raselli S, Redaelli L, Buccianti G, Catapano AL. Circulating soluble receptor for advanced glycation end products is inversely associated with body mass index and waist/hip ratio in the general population. Nutr Metab Cardiovasc Dis. 2009; 19:129–34. https://doi.org/10.1016/j.numecd.2008.03.004 [PubMed]
39. Prakash J, Pichchadze G, Trofimov S, Livshits G. Age and genetic determinants of variation of circulating levels of the receptor for advanced glycation end products (RAGE) in the general human population. Mech Ageing Dev. 2015; 145:18–25. https://doi.org/10.1016/j.mad.2015.01.001 [PubMed]
40. Geroldi D, Falcone C, Minoretti P, Emanuele E, Arra M, D’Angelo A. High levels of soluble receptor for advanced glycation end products may be a marker of extreme longevity in humans. J Am Geriatr Soc. 2006; 54:1149–50. https://doi.org/10.1111/j.1532-5415.2006.00776.x [PubMed]
41. Definition of an older or elderly person. 2016. http://www.who.int/healthinfo/survey/ageingdefnolder/en/.
42. Olivieri F, Bonafè M, Spazzafumo L, Gobbi M, Prattichizzo F, Recchioni R, Marcheselli F, La Sala L, Galeazzi R, Rippo MR, Fulgenzi G, Angelini S, Lazzarini R, et al. Age- and glycemia-related miR-126-3p levels in plasma and endothelial cells. Aging (Albany NY). 2014; 6:771–87. https://doi.org/10.18632/aging.100693 [PubMed]
43. Mukherjee TK, Reynolds PR, Hoidal JR. Differential effect of estrogen receptor alpha and beta agonists on the receptor for advanced glycation end product expression in human microvascular endothelial cells. Biochim Biophys Acta. 2005; 1745:300–09. https://doi.org/10.1016/j.bbamcr.2005.03.012 [PubMed]
44. Mukhopadhyay S, Mukherjee TK. Bridging advanced glycation end product, receptor for advanced glycation end product and nitric oxide with hormonal replacement/estrogen therapy in healthy versus diabetic postmenopausal women: a perspective. Biochim Biophys Acta. 2005; 1745:145–55. https://doi.org/10.1016/j.bbamcr.2005.03.010 [PubMed]
45. Demling N, Ehrhardt C, Kasper M, Laue M, Knels L, Rieber EP. Promotion of cell adherence and spreading: a novel function of RAGE, the highly selective differentiation marker of human alveolar epithelial type I cells. Cell Tissue Res. 2006; 323:475–88. https://doi.org/10.1007/s00441-005-0069-0 [PubMed]
46. Ohlmeier S, Mazur W, Salmenkivi K, Myllärniemi M, Bergmann U, Kinnula VL. Proteomic studies on receptor for advanced glycation end product variants in idiopathic pulmonary fibrosis and chronic obstructive pulmonary disease. Proteomics Clin Appl. 2010; 4:97–105. https://doi.org/10.1002/prca.200900128 [PubMed]
47. Kislinger T, Fu C, Huber B, Qu W, Taguchi A, Du Yan S, Hofmann M, Yan SF, Pischetsrieder M, Stern D, Schmidt AM. N(epsilon)-(carboxymethyl)lysine adducts of proteins are ligands for receptor for advanced glycation end products that activate cell signaling pathways and modulate gene expression. J Biol Chem. 1999; 274:31740–49. https://doi.org/10.1074/jbc.274.44.31740 [PubMed]
48. Franceschi C, Campisi J. Chronic inflammation (inflammaging) and its potential contribution to age-associated diseases. J Gerontol A Biol Sci Med Sci. 2014 (Suppl 1); 69:S4–9. https://doi.org/10.1093/gerona/glu057 [PubMed]
49. Reynaert NL, Gopal P, Rutten EP, Wouters EF, Schalkwijk CG. Advanced glycation end products and their receptor in age-related, non-communicable chronic inflammatory diseases; Overview of clinical evidence and potential contributions to disease. Int J Biochem Cell Biol. 2016; 81:403–18. https://doi.org/10.1016/j.biocel.2016.06.016 [PubMed]
50. Eren M, Boe AE, Klyachko EA, Vaughan DE. Role of plasminogen activator inhibitor-1 in senescence and aging. Semin Thromb Hemost. 2014; 40:645–51. https://doi.org/10.1055/s-0034-1387883 [PubMed]
51. Catalán V, Gómez-Ambrosi J, Rodríguez A, Ramírez B, Rotellar F, Valentí V, Silva C, Gil MJ, Fernández-Real JM, Salvador J, Frühbeck G. Increased levels of calprotectin in obesity are related to macrophage content: impact on inflammation and effect of weight loss. Mol Med. 2011; 17:1157–67. https://doi.org/10.2119/molmed.2011.00144 [PubMed]
52. Vazzana N, Guagnano MT, Cuccurullo C, Ferrante E, Lattanzio S, Liani R, Romano M, Davì G. Endogenous secretory RAGE in obese women: association with platelet activation and oxidative stress. J Clin Endocrinol Metab. 2012; 97:E1726–30. https://doi.org/10.1210/jc.2012-1473 [PubMed]
53. Zaki M, Kamal S, Kholousi S, El-Bassyouni HT, Yousef W, Reyad H, Mohamed R, Basha WA. Serum soluble receptor of advanced glycation end products and risk of metabolic syndrome in Egyptian obese women. EXCLI J. 2017; 16:973–80. [PubMed]
54. Miranda ER, Fuller KN, Perkins RK, Kroeger CM, Trepanowski JF, Varady KA, Haus JM. Endogenous secretory RAGE increases with improvements in body composition and is associated with markers of adipocyte health. Nutr Metab Cardiovasc Dis. 2018; 28:1155–65. https://doi.org/10.1016/j.numecd.2018.07.009 [PubMed]
55. St-Onge MP, Gallagher D. Body composition changes with aging: the cause or the result of alterations in metabolic rate and macronutrient oxidation? Nutrition. 2010; 26:152–55. https://doi.org/10.1016/j.nut.2009.07.004 [PubMed]
56. Barnard SA, Pieters M, De Lange Z. The contribution of different adipose tissue depots to plasma plasminogen activator inhibitor-1 (PAI-1) levels. Blood Rev. 2016; 30:421–29. https://doi.org/10.1016/j.blre.2016.05.002 [PubMed]
57. Yamamoto K, Takeshita K, Saito H. Plasminogen activator inhibitor-1 in aging. Semin Thromb Hemost. 2014; 40:652–59. https://doi.org/10.1055/s-0034-1384635 [PubMed]
58. Gaens KH, Ferreira I, van der Kallen CJ, van Greevenbroek MM, Blaak EE, Feskens EJ, Dekker JM, Nijpels G, Heine RJ, ’t Hart LM, de Groot PG, Stehouwer CD, Schalkwijk CG. Association of polymorphism in the receptor for advanced glycation end products (RAGE) gene with circulating RAGE levels. J Clin Endocrinol Metab. 2009; 94:5174–80. https://doi.org/10.1210/jc.2009-1067 [PubMed]
59. Miller S, Henry AP, Hodge E, Kheirallah AK, Billington CK, Rimington TL, Bhaker SK, Obeidat M, Melén E, Merid SK, Swan C, Gowland C, Nelson CP, et al. The Ser82 RAGE variant affects lung function and serum RAGE in smokers and sRAGE production in vitro. PLoS One. 2016; 11:e0164041. https://doi.org/10.1371/journal.pone.0164041 [PubMed]
60. Mistry R, Gokhman I, Bastani R, Gould R, Jimenez E, Maxwell A, McDermott C, Rosansky J, Van Stone W, Jarvik L, and UPBEAT Collaborative Group. Measuring medical burden using CIRS in older veterans enrolled in UPBEAT, a psychogeriatric treatment program: a pilot study. J Gerontol A Biol Sci Med Sci. 2004; 59:1068–75. https://doi.org/10.1093/gerona/59.10.M1068 [PubMed]

Featured Nobel Articles

Research Paper Volume 11, Issue 6 pp 1648—1663

Modulation of soluble receptor for advanced glycation end-products (RAGE) isoforms and their ligands in healthy aging

Francesco Scavello^1, , Filippo Zeni^1, , Calogero C. Tedesco^2, , Emanuela Mensà^3, , Fabrizio Veglia^2, , Antonio Domenico Procopio^3,4, , Anna Rita Bonfigli^5, , Fabiola Olivieri^3,4, , Angela Raucci^1, ,

Received: November 23, 2018 Accepted: March 6, 2019 Published: March 23, 2019

Abstract

Introduction

Results

Population features

Table 1. Biochemical, metabolic and anthropometric variables and medication therapy of healthy subjects divided in three age groups.

cRAGE but not esRAGE decreases with aging

AGEs and S100A8/A9 but not HMGB1 increase with aging

Determinants of serum levels of RAGE isoforms

Table 2. Univariate correlation analysis between RAGE isoforms and population variables.

Table 3. Multivariable analysis between RAGE isoforms and population variables.

AGEs enhance cellular amount of FL-RAGE and reduce cRAGE levels

Discussion

Materials and Methods

Study population

Laboratory assays

RAGE isoforms and ligands measurements

Cell culture

Assessment of FL-RAGE expression and cRAGE production

Statistical analysis

Supplementary Materials

Supplementary Table 1

Acknowledgments

Conflicts of Interest

Funding

References

Corresponding Author

Keywords

Paper Sections

Featured Nobel Articles

Research Paper Volume 11, Issue 6 pp 1648—1663

Modulation of soluble receptor for advanced glycation end-products (RAGE) isoforms and their ligands in healthy aging

Francesco Scavello1, , Filippo Zeni1, , Calogero C. Tedesco2, , Emanuela Mensà3, , Fabrizio Veglia2, , Antonio Domenico Procopio3,4, , Anna Rita Bonfigli5, , Fabiola Olivieri3,4, , Angela Raucci1, ,

Received: November 23, 2018 Accepted: March 6, 2019 Published: March 23, 2019

Cite this Article

How to cite

Copy or Download citation:

Abstract

Introduction

Results

Population features

Table 1. Biochemical, metabolic and anthropometric variables and medication therapy of healthy subjects divided in three age groups.

cRAGE but not esRAGE decreases with aging

AGEs and S100A8/A9 but not HMGB1 increase with aging

Determinants of serum levels of RAGE isoforms

Table 2. Univariate correlation analysis between RAGE isoforms and population variables.

Table 3. Multivariable analysis between RAGE isoforms and population variables.

AGEs enhance cellular amount of FL-RAGE and reduce cRAGE levels

Discussion

Materials and Methods

Study population

Laboratory assays

RAGE isoforms and ligands measurements

Cell culture

Assessment of FL-RAGE expression and cRAGE production

Statistical analysis

Supplementary Materials

Supplementary Table 1

Acknowledgments

Conflicts of Interest

Funding

References

Corresponding Author

Keywords

Paper Sections

Francesco Scavello^1, , Filippo Zeni^1, , Calogero C. Tedesco^2, , Emanuela Mensà^3, , Fabrizio Veglia^2, , Antonio Domenico Procopio^3,4, , Anna Rita Bonfigli^5, , Fabiola Olivieri^3,4, , Angela Raucci^1, ,