The central function of adipose tissue and adipocytes is to control lipid metabolism.¹ In conditions of excess nutrients, the adipocyte store energy in the form of lipids, whereas in the post-prandial period or during starvation, it supplies lipids to other tissues through lipolysis.² In response to energy overconsumption, the adipose tissue is expanded through an increase in the number and/or size of adipocytes.³ Adipose tissue expansion also affects the cellular composition and function of the stromal vascular fraction cells of the adipose tissue. This includes macrophage infiltration and low-grade adipose tissue inflammation,⁴ which has been shown to contribute to obesity-related metabolic comorbidities.⁴

Research during the last 3 decades has described many additional specific functions of adipose tissue. Adipose tissue is currently defined as an endocrine organ with secretion of signaling molecules, so-called adipokines, from adipocytes.^5,6 Many of these adipokines play key roles in the regulation of energy homeostasis and contribute to obesity-related metabolic disorders.⁷

In addition to the regular white adipose tissue, humans also have smaller amounts of brown adipose tissue.⁸ The key feature of brown adipose tissue is the generation of heat via the uncoupling of the respiratory chain⁸. Clearly, also brown adipose tissue expresses a set of unique genes which are related to its unique function, and uncoupling protein 1 (UCP1) is the clearest example of this.⁸

The specific functions of the adipocytes and adipose tissue are mediated by proteins that, in many cases, are specifically expressed in the adipocytes. Hence, adipose tissue and adipocytes have distinct expression profiles, and some genes are uniquely expressed by adipocytes. Adipose tissue dysfunction has been linked to several obesity-related comorbidities, and adipocyte-specific genes have been shown to play a part also in these comorbidities.^5,6

Analysis of mRNA expression levels has been used to gain insights into the function of genes, and the development of techniques such as microarrays has enabled screening-based approaches to find genes of relevance for many different functions in the human body and different pathological conditions. Microarray-based methods have previously been used to search for genes with a tissue/cell type-specific expression pattern.⁹ This methodology is based on the comparison of expression profiles from multiple human tissues and cell types. Our group has used this methodology for the identification of several novel adipocyte/adipose tissue-specific genes, including CIDEA, CIDEC, NQO1, TNMD, SAA1 and ITIH5.^10–15 The rationale behind this approach is that genes that are exclusively expressed in a specific tissue most likely have important functions in that tissue. Dysregulation of genes with key functions in adipose tissue may be linked to obesity-related metabolic dysfunction. RNA sequencing (RNAseq) has now emerged as an advantageous tool for expression profiling, compared to microarrays, since it is not limited by the probe composition of the microarray.¹⁶ RNAseq data from multiple human tissues and cell types can potentially also be used in searches for novel adipose tissue-specific genes.

This study hypothesized that adipose tissue express several unique genes that play key roles in adipose tissue function and that dysregulation of such genes may be linked to obesity-related metabolic dysfunction. This study aimed to use an RNAseq dataset with multiple human tissues to search for novel adipose tissue-specific genes and to characterize the expression pattern of such genes.

Tissue distribution of gene expression was analyzed in a publicly available RNAseq dataset, downloaded from the GTEx portal (Version 7, https://www.gtexportal.org/home/datasets). The RNAseq dataset contains 53 tissues and cell types, and data for each tissue/cell type originate from analysis of 5 to 564 samples, but the replicates of each sample were combined into a mean expression profile for each tissue or cell type. The dataset contains expression profiles from both subcutaneous and omental adipose tissue. Gene expression levels were calculated as transcripts per kilobase million (TPM). To identify genes specifically expressed in subcutaneous adipose tissue, genes that had an expression level (TPM) that was at least 10 standard deviations (SD) higher than the mean TPM of all the other tissues and at least 5-fold higher TPM than the tissue with the second-highest TPM (second tissue) were selected. In these analyses, expression profiles for omental adipose tissue and mammary tissue were excluded due to the high degree of similarities to subcutaneous adipose.

A second publicly available RNAseq dataset (HPA RNA-seq normal tissues, https://www.ncbi.nlm.nih.gov/gene/80704) was also analysed since this dataset contained tissues not included in the first dataset.¹⁷ This dataset contains samples from 95 human individuals representing 27 different tissues (2–7 samples analyses per tissue), and gene expression levels were calculated as reads per kilobase million (RPKM).

Two groups of patients were used to investigate adipose tissue depot differences in gene expression. In the first group, paired subcutaneous and omental adipose tissue biopsies were obtained from 5 healthy lean women (Body mass index [BMI] 23.0 ± 1.2 Kg/m²) undergoing elective surgery (liposuction and elective gynecological procedures) at the University Hospital Coventry and Warwickshire.¹³ Smokers and subjects with recent weight change, hormone replacement, and malignant diseases were excluded. In the second group, paired subcutaneous and omental adipose tissue was obtained from 27 subjects without diabetes (17 females, 10 males, BMI 37.8 ± 13.3 Kg/m²) undergoing kidney donation at the Sahlgrenska University Hospital, or bariatric surgery at the Uppsala University Hospital, as previously reported.¹⁸

The SibPair study was designed to study the genetics of obesity and consists of 154 nuclear families with BMI discordant sib-pairs (BMI difference > 10 Kg/m²).¹⁹ In total, 732 subjects were recruited from all over Sweden and examined at the Obesity Unit, the Sahlgrenska University Hospital in Gothenburg. In the current study, subcutaneous adipose tissue needle biopsies were obtained from the parents in the SibPair study (n = 88)²⁰ and were used for the analysis of adipose tissue gene expression. This group was also stratified by BMI into individuals being either of normal weight (BMI 18.5–25 Kg/m²; n = 17) or with obesity (BMI > 30 Kg/m²; n = 32).

Subcutaneous adipose tissue needle biopsies were obtained by needle aspiration of the lower part of the abdomen from a cohort of subjects without diabetes (52 female, 20 male; BMI 26.1 ± 2.9 Kg/m²) at the Uppsala University Hospital. The adipose tissue was used for mRNA extraction (n = 68), and isolation of adipocytes and stromal vascular fraction (n = 4) and expansion of preadipocytes into adipocytes (n = 8). Subjects with type 1 diabetes, endocrine disorders, cancer or other major illnesses were excluded, as so were those having ongoing medication with systemic glucocorticoids, beta-blockers and immune-modulating therapies.

As previously described,¹⁰ 24 persons with obesity (BMI > 30 kg/m²) were treated with a very low-calorie diet (VLCD; 450 kcal/day, Cambridge diet or Modifast) for 16 weeks (wk) at the Sahlgrenska University Hospital in Gothenburg. The VLCD period was followed by a 2 weeks of gradual re-introduction to a normal diet. Abdominal subcutaneous adipose tissue biopsies were obtained before (wk 0), during (wk 8 and 16), and after (wk 18) diet-induced weight loss from 24 subjects (6 women and 18 men), and used for gene expression analysis by DNA microarray. The participants displayed a mean weight loss of 27.7 ± 1.8 kg during the VLCD period (week 16). During wk 17 and 18, the body weight was stabilized.

Biopsies of perirenal adipose tissue were obtained from 55 healthy kidney donors at the Sahlgrenska University Hospital in Gothenburg. The samples were screened for UCP1 gene expression, and samples with high UCP1 expression were classified as containing brown adipose tissue (BAT, n = 10). A matched control group (n = 10) was created from the samples displaying no/low UCP1 expression.²¹

Adipose tissue, obtained by needle aspirations or by surgical biopsies, was snap-frozen and stored at −80°C until analysis. Total RNA was prepared using the RNeasy lipid tissue kit (QIAGEN, Chatsworth, CA), or using the phenol-chloroform extraction method of Chomczynski and Sacchi with further purification with RNeasy clean-up columns.

Microarray analysis of paired subcutaneous and omental adipose tissue samples and adipose tissue samples from the SibPair parents study was performed using U133 plus 2.0 microarray (Affymetrix, Santa Clara, CA). Microarray analysis of adipose tissue from the VLCD study was performed using U133A microarray (Affymetrix), and perirenal adipose tissue was analyzed using Gene 1.0 ST microarrays (Affymetrix). All microarray analysis was performed according to the manufacturer's instructions (Affymetrix), and expression data were analyzed using the Robust Multi-array Average algorithm. SLC19A3 expression was assessed using probe sets 220736_at and 8059538 for U133 microarrays and Gene 1.0 ST microarrays, respectively.

The quantity and quality of the isolated RNA were determined by NanoDrop ND-1000 (NanoDrop Technologies, Inc. Wilmington, New Jersey). cDNA synthesis was performed with High Capacity cDNA Reverse Transcriptase kit (Applied Biosystems, Foster City, CA), according to the manufacturer guidelines. The mRNA expression analyses were performed using the QuantStudio 3 sequence detection system (Applied Biosystems) using a specific Taqman gene expression assay (Applied Biosystems): SLC19A3 (Hs00228858), ADIPOQ (Hs00605917), PLIN1 (Hs00160173), CEBPA (Hs00269972) and PPARG (Hs1115513). All samples were run in duplicate, and the data were analysed using 2^−deltaCt using 18S or GUSB as a reference gene.

Adipocytes and stromal vascular cells were isolated from subcutaneous adipose tissue for preadipocyte differentiation into adipocytes and analyses of SLC19A3 gene and protein expression. The isolation of preadipocytes was performed as previously reported.²² In brief, adipose tissue was digested with collagenase (1.2 mg/ml, from Clostridium histolyticum, Roche, Manheim, Germany) in Hank's medium (5.6 mM glucose, 4% BSA, 150 nM adenosine) for 60 min in a shaking water-bath. Isolated adipocytes were filtered through a 250 μm nylon mesh, and the media under the adipocytes was collected and centrifuged for 3 min at 1200 rpm for isolation of the stromal vascular fraction. The mature adipocytes were washed in Hank's media 6 mmol/L glucose, 4% BSA, 150 nM adenosine, pH 7.4 and separated from the medium through centrifugation in dinonyl phthalate (Tokyo Chemical Industry).

Human isolated preadipocytes: The stromal vascular fraction containing preadipocytes was cultured with preadipocyte medium (Dulbecco's modified Eagle's medium (DMEM)/Ham's F12, Gibco) containing 10% foetal bovine serum (FBS, Thermo Fisher), 100 units/ml penicillin and 100 g/ml streptomycin (Life Technology), 0.04mg/ml gentamycin (Gibco), and 4.125 ng/ml basic fibroblast growth factor (Sigma) at 37°C until 70–80% confluence. Preadipocytes were trypsinized and seeded at a density of 15,000 cells/cm² with preadipocyte media. After cells reached 100% confluence (day 0), differentiation was induced by adding differentiation cocktail (DMEM/Ham's F12, 1% PEST, 100 nM (16,666 µU/ml) human insulin (Actrapid, Novo Nordisk, Bagsvaerd, Denmark), 17 μM pantothenate, 33 μM biotin, 1 μM cortisol, 1 μM rosiglitazone, 250 μM 3-isobutyl-1-methylxanthine (IBMX), 10 μg/ml transferrin human, 2 nM 3, 3, 5-triiodo L-thyronine [all from Sigma]) for 5 days. The differentiation continued with maintenance medium (composition is similar to that of differentiation cocktail except for IBMX) until day 14. The medium was replenished every 3 days.

SGBS cells: Human Simpson-Golabi-Behmel syndrome (SGBS) adipocytes were kindly provided by Professor Martin Wabitsch (Ulm University Medical Centre, Germany). SGBS were expanded in DMEM-F12 containing 33 μM biotin, 17 μM pantothenate, 1% PEST, and 10% non-heat-inactivated FBS until 80% confluence. Adipocyte differentiation was induced for 4 days with differentiation medium: DMEM-F12 with 1% PEST, 100 nM insulin, 17 μM pantothenate, 33 μM biotin, 1 μM dexamethasone, 1 μM rosiglitazone, 250 μM IBMX, 10 μg/ml transferrin, and 2 nM tri-iodothyronine (T3). The differentiation continued with the maintenance medium (the same composition as the differentiation medium except for IBMX, dexamethasone, and rosiglitazone) until day 14.

The cells were used to determine the SLC19A3 gene and protein expression, and the differentiation rate was confirmed by measuring the expression of the adipogenic markers PPARG and CEBPA.

Separated adipocytes or stromal vascular cells were homogenized in lysis buffer (25 mM Tris-HCl; 0.5 mM EGTA; 25 mM NaCl; 1% Nonidet P-40; 1 mM Na3VO4; 10 mM NaF (all from Sigma); 100 nM okadaic acid (Alexis Biochemicals, Lausen, Switzerland), 1X Complete protease inhibitor cocktail (Roche, Indianapolis, IN, USA), pH 7.4) for 30 min at 4°C. The samples were centrifuged at 12,000 g for 15 min and 4°C until complete phase separation. The lysate was collected, and the protein concentration was determined using a BCA protein assay kit (Pierce, Thermo Scientific, Rockford, IL, USA). SDS-PAGE and immunoblotting were performed with standard procedures.²² Membranes were incubated overnight with anti-SLC19A3 (1:1000, 13407-1-AP, Proteintech, Manchester, UK) and thereafter with horseradish peroxidase-conjugated anti-rabbit (Cell Signalling Technologies) secondary antibody. Anti-glyceraldehyde-3-phosphate dehydrogenase (GAPDH, 1:3000, 5174, Cell Signalling) was used as a loading control protein. Protein bands were then visualized using enhanced chemiluminescence with a high-resolution field and quantified with ChemiDocTM MP System (BioRad).

Enrichment analysis was performed using the online David functional annotation tool (version 6.8) using default settings.^23,24 The top 500 genes that positively correlated with SLC19A3 expression in human subcutaneous adipose tissue (SibPair parents, n = 88) were selected, and these 500 genes correspond to 358 unique David IDs. Enrichment analysis was performed with Human Genome U133 plus set as background.

The difference in gene expression in paired subcutaneous and omental adipose tissue biopsies was analyzed using related-samples Wilcoxon signed-rank test. The difference in gene expression in brown adipose tissue and between subjects with differences in BMI was performed using independent sample Mann-Whitney U test or Spearman's rank correlation. Gene and protein expression during adipocyte differentiation and expression during caloric restriction was analyzed by related-samples Friedman's Two-Way Analysis of Variance by rank followed by Wilcoxon signed rank test as post-hoc test. Two-sided p values less than 0.05 were considered statistically significant. Statistical analysis was performed using IBM SPSS statistics 25.

The Regional Ethics Committee in Gothenburg, Uppsala and the South Birmingham Ethics Committee approved these studies. All study subjects received written and oral information about the respective study before giving informed consent.

The RNAseq based search for adipose tissue specific-genes yielded 14 genes that were classified as specifically expressed in subcutaneous adipose tissue using the predefined criteria (Table 1). Classical adipocyte-specific genes such as leptin (LEP), adiponectin (ADIPOQ), Perilipin 1 (PLIN1) and fatty acid binding protein 4 (FABP4) were classified as the top four on the list of genes specifically expressed in subcutaneous adipose tissue (Table 1). Genes previously identified as adipose/adipocyte-specific genes in microarray-based scans, such as CIDEA,¹⁰ CIDEC ¹¹ and TNMD,¹³ were also included on the list. A novel finding from this analysis was that the thiamine transporter 2 (THTR2, encoded by the solute carrier family 19 member 3 [SLC19A3] gene)²⁵ was specifically expressed in adipose tissue and was therefore selected as a focus for further investigation.

TABLE 1 Genes specifically expressed in human subcutaneous adipose tissue

Abbreviation: TPM, transcripts per kilobase million.

^aFold change calculated as the ratio between SAT TPM and TPM of the second tissue. Omental adipose tissue and mammary glands were not included in this analysis.

The complete tissue distribution of SLC19A3 expression in the GTEx dataset is shown in Figure 1A. In this dataset, SLC19A3 was highly expressed in visceral and subcutaneous adipose tissue and in mammary tissue. Similar tissue distribution of SLC19A3 mRNA expression was observed also in an additional RNAseq dataset (Supplemental Figure 1). In this dataset, adipose tissue displayed the highest SLC19A3 expression levels, followed by placenta and duodenum. Higher expression of SLC19A3 in subcutaneous adipose tissue compared with omental adipose tissue was observed in the microarray dataset with paired biopsies from 5 lean women (Figure 1B, p = 0.043). This depot difference in SLC19A3 mRNA expression was verified in an independent dataset with paired biopsies from 27 subjects which were analyzed by real-time PCR (Figure 1C, p < 0.001).

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FIGURE 1. Tissue distribution of SLC19A3 expression. The expression analysis was performed in a panel of human tissues from GTex (A) and in paired subcutaneous and omental adipose tissue biopsies (B, C). Expression analysis was performed by RNA sequencing (A), microarray (B) and real-time PCR (C). Data are presented as mean expression (with SD in B and C). Analysis was performed in 5 and 27 patients, respectively in B and C

SLC19A3 mRNA levels were very low in human preadipocytes but increased during the adipocyte differentiation process (p = 0.0014 for differences among repeated differentiation days), and higher SLC19A3 mRNA levels were observed during all timepoints of differentiation compared with the preadipocytes at day 0 (Figure 2A, p = 0.018 or less for all time points). SLC19A3 protein expression followed the same expression pattern during adipocyte differentiation, but the changes in SLC19A3 protein expression were not statistically significant (Figure 2B). SLC19A3 mRNA levels were also investigated in another model of human adipocyte differentiation (SGBS cells). In line with the human isolated preadipocyte data, SLC19A3 expression was significantly increased after 14 days of adipocyte differentiation (Figure 2D, p = 0.013). Adipocyte differentiation was confirmed in both these models by analysis of PPARG and CEBPA expression (supplement Figure 3 A-D).

SLC19A3 protein levels were also investigated in isolated adipocytes and stromal vascular fraction cells. SLC19A3 protein was detected in both the adipocytes and the stromal vascular fraction cells, but no significant difference in protein levels were observed (Figure 2 E-F).

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FIGURE 2. Expression of SLC19A3 during adipocyte differentiation and in isolated adipocytes. Human preadipocytes were differentiated towards adipocytes for 14 days, and SLC19A3 expression was analyzed by real time PCR (A) and western blot (B and C). Data are presented as mean expression and SD, and the experiment was performed with preadipocytes from 8 and 3 donors, respectively. Differentiation of SGBC cells towards adipocytes and analysis of SLC19A3 expression before and after 14 days of differentiation (D). Western blot analysis of SLC19A3 protein expression in isolated adipocytes and stromal vascular fraction cells (SVC) (E and F)

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FIGURE 3. Subcutaneous adipose tissue expression of SLC19A3 and its relation to BMI. Expression analysis of patients with obesity compared with normal weight controls (A). Correlation analysis of SLC19A3 expression and BMI (B). Expression analysis was performed by microarray (A) and real-time PCR (B). Data are presented as mean expression with SD or as a scatter plot. ns; not significant

SLC19A3 expression was lower in subcutaneous adipose tissue from subjects with obesity compared with subjects of normal weight (p = 0.008, Figure 3A). To verify this finding, real-time PCR analysis of SLC19A3 mRNA expression was performed in subcutaneous adipose tissue from 68 subjects with BMI ranging from 20.2 to 34.5 Kg/m². SLC19A3 expression showed a negative correlation with BMI (Figure 3B, rho = −0.571, p < 0.001). A similar analysis was performed with omental adipose tissue from 27 subjects with BMI ranging from 20.9 to 58.2 Kg/m², but no significant association was found (Supplementary Figure 2 A-B). In addition, mRNA expression analysis of ADIPOQ and PLIN1, two genes known to be downregulated in obesity, were performed. Subcutaneous SLC19A3 mRNA expression was highly correlated to both ADIPOQ and PLIN1 mRNA expression (Supplementary Figure 2 A-B, p < 0.001 for both). However, the correlation pattern was less clear for SLC19A3 mRNA expression in omental adipose tissue (Supplementary Figure 2 A-B).

In a weight-loss study (VLCD study) with 24 participants, subcutaneous adipose tissue SLC19A3 mRNA expression was increased during 16 weeks of energy restriction (p = 0.006 after 16 weeks, Figure 4). However, when regular food was gradually re-introduced during the last two weeks of the intervention (between week 16 and 18), the mRNA expression of SLC19A3 was reduced (p = 0.002) almost to the level as before the intervention.

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FIGURE 4. Subcutaneous adipose tissue expression of SLC19A3 during weight-loss intervention. Adipose tissue gene expression of SLC19A3 from patients with obesity undergoing a 16 weeks diet-induced weight loss (n = 24) treatment using VLCD. After week 16 of VLCD, normal food was gradually introduced for 2 weeks. Data are presented as mean and SD. VLCD, very low caloric diet

To gain insights of the potential function of SLC19A3 in adipose tissue, a gene set enrichment analysis was performed. The top 500 genes with a positive correlation to SLC19A3 expression in the subcutaneous adipose tissue in the SibPair parents cohort (n = 88) were used for enrichment analysis. Terms that were enriched in this analysis were dominated by links to the mitochondrion (Table 2). In addition, significantly enriched terms included lipid metabolism and branched-chain amino acid catabolism (Table 2). Brown adipocytes have a high abundance of mitochondria, and SLC19A3 expression may therefore be linked presence of brown adipocytes and energy metabolism in adipose tissue. However, analysis of SLC19A3 mRNA expression in brown adipocyte containing human perirenal adipose tissue shows that this tissue does not express SLC19A3 mRNA at a higher level compared with perirenal adipose tissue that does not contain brown adipocytes (Figure 5).

TABLE 2 Top 40 enriched terms among top 500 genes positively correlated with SLC19A3 expression in subcutaneous adipose tissue (functional annotation chart)

Abbreviation: NAFLD, non-alcoholic fatty liver disease.

*p-value adjusted according to Benjamini.

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FIGURE 5. SLC19A3 expression in human brown adipose tissue. Human perirenal adipose tissue was analysed for UCP1 expression and stratified into two groups, samples containing (BAT, n = 10) or not containing (WAT, n = 10) brown adipocytes. Data are presented as a mean expression with SD. ns; not significant

This study showed that the thiamine transporter SLC19A3 was specifically expressed in human adipose tissue and that adipose tissue SLC19A3 expression was regulated by obesity, weight-loss and possibly energy intake. Furthermore, an enrichment of genes with mitochondrial function was observed among the genes that correlated with the SLC19A3 adipose tissue expression. Taken together, these results indicate that SLC19A3 plays a role in adipose tissue energy metabolism.

Duodenum has been describes as the main site of thiamin uptake in the body.²⁶ The gene product of SLC19A3 has been suggested to mediate this uptake due to its high expression in duodenum.²⁶ Tissue distribution datasets that contain both adipose tissue and duodenum indicated that the expression levels of SLC19A3 were several-fold higher in adipose tissue compared with the duodenum. This tissue distribution pattern does not speak against a key role for SLC19A3 in intestinal thiamine uptake, but it highlights the very high expression which was observed in adipose tissue.

Thiamine has its main function as a cofactor of the enzyme pyruvate dehydrogenase, an enzyme active in the citric acid cycle.²⁷ Hence, decreased thiamin levels can result in reduced mitochondrial activity, impaired oxidative metabolism, and decreased energy production.²⁷ Skeletal muscle and brown adipose tissue are tissues with high energy demand and an abundance of mitochondria, whereas white adipose tissue has relatively few mitochondria.²⁸ Functional studies²⁷ and the tissue distribution of SLC19A2 indicate that this transporter was responsible for thiamine delivery to the high energy demanding tissues. This was in line with the findings in the current study regarding human brown adipocytes and SLC19A3 expression. Cellular studies have confirmed the thiamine transport capacity of SLC19A3,^29,30 however, the exact function of thiamine and SLC19A3 in adipose tissue needs to be explored in mechanistic studies.

Using a gene identification strategy similar to ours, Ahn et al.³¹ also identified SLC19A3 as an adipose-specific/enhanced protein-coding gene. Using publicly available expression datasets, they identified increased expression of SLC19A3 during adipocyte differentiation and 8-fold higher expression in adipocytes compared with the stromal vascular fraction. The adipocyte differentiation findings are well in line with the findings in the current study. However, the current study indicated that SLC19A3 protein was also expressed in the stromal vascular fraction of adipose tissue. Ahn et al.³¹ also present data from an expression dataset (GSE9624) with omental adipose tissue from prepubertal children, which indicate higher SLC19A3 expression in children with obesity compared with lean children. In addition, they also present data from subcutaneous adipose tissue (expression data set GSE12050), which indicate no difference in SLC19A3 expression between persons with obesity and lean persons. These findings were not in line with the findings in the current study, where lower subcutaneous adipose tissue SLC19A3 expression in persons with obesity was found in two independent populations. The findings from the current study are further strengthened by the results from the weight-loss intervention, where weight-loss and/or reduced energy intake was linked to higher subcutaneous SLC19A3 expression. Despite these findings, the function of SLC19A3 in adipose tissue remains unclear. The link between SLC19A3 expression and the enrichment of genes with mitochondrial functions may be an important guide in future functional experiments aimed at addressing this knowledge gap.

The main limitations of this study are that the majority of the findings are based on analysis of SLC19A3 mRNA and protein expression, and the lack of functional experiments, which could have pinpointed the role of SLC19A3 in adipose tissue. Strengths of this study include that findings have been replicated in independent populations and with different mRNA analyzing technologies.

This study showed that SLC19A3 was highly expressed in adipose tissue and expression characterization of SLC19A3 expression in human adipose tissue and adipocytes was performed. The regulation of SLC19A3 indicate that this gene may play a key metabolic role in adipose tissue but its role in thiamine uptake in adipocytes or other functions in adipocytes needs to be further investigated.

This work was supported by research grants from The Swedish Research Council (2017-01,707), the Swedish state under the agreement between the Swedish government and the county councils, the ALF agreement (ALFGBG-717881 and ALFGBG-717891), the Swedish Diabetes Foundation (2019-417) the Excellence Of Diabetes Research in Sweden (EXODIAB), the Family Ernfors Fund, the Marie Sklodowska Curie Innovative Training Network TREATMENT (H2020-MSCA-ITN-721236); and the Zetterling's Foundation.

Prof. Lena M.S. Carlsson reports receiving consulting fees from Johnson & Johnson Healthcare Systems and grant support, paid to her institution. Dr Taube has a patent and holds stocks in Umecrine AB. Dr K Sjöholm and Dr M Pereira reports grant support, paid to the institutions. The other authors have nothing to disclose.

Maria J. Pereira, Lena M. S. Carlsson and Per-Arne Svensson planned the study. Maria J. Pereira, Johanna C. Andersson-Assarsson, Peter Jacobson, Magdalena Taube, Prasad Kamble, Kajsa Sjöholm and Per-Arne Svensson carried out experiments, performed clinical studies and microarray analysis. All authors were involved in data analysis and writing the paper and had final approval of the submitted and published versions.