Extracellular regulation of LPL activity by angiopoietin-like proteins

Chi, Xun

01 August 2017

Dyslipidemia often accompanies metabolic diseases such as obesity and type II diabetes mellitus and represents a risk factor for cardiovascular disease. Clearance of triglycerides from the plasma is mediated by lipoprotein lipase (LPL), which hydrolyzes the triglycerides in chylomicrons and VLDL, liberating fatty acids for tissue uptake. LPL functions in the capillaries of the heart, adipose tissue, and skeletal muscle where LPL is anchored to the capillary wall by its endothelial cell transporter GPIHBP1. LPL activity is regulated by several factors including three members of the angiopoietin-like (ANGPTL) family–ANGPTL3, ANGPTL4, and ANGPTL8. How these proteins interact with LPL, especially in the physiological context of LPL anchored to endothelial cells by GPIHBP1, has not been well characterized. In my studies of ANGPTL4, I found when LPL is bound to GPIHBP1, it is partially, but not completely, protected from inactivation by ANGPTL4. Inactivation of LPL by ANGPTL4 leads to the dissociation of active LPL dimers into inactive monomers and I found that these monomers have a greatly reduced affinity for GPIHBP1. ANGPTL4 can be cleaved in vivo, separating the N-terminal coiled-coil domain from the C-terminal fibrinogen like-domain. I found the N-terminal domain alone is a much more potent LPL inhibitor than the full-length protein, even though both appear to have similar binding affinities for LPL-GPIHBP1 complexes. When I investigated ANGPTL3, I found ANGPTL3 itself is not a potent inhibitor of LPL at physiological concentrations, and unlike ANGPTL4, cleavage of ANGPTL3 does not improve its ability to inhibit LPL. Instead I found that ANGPTL3 forms a complex with ANGPTL8, a complex that only forms efficiently when the two proteins are co-expressed, and that this complex allows ANGPTL3 to bind and inhibit LPL. My data provide new insights into how ANGPTL proteins regulate LPL activity and the delivery of fat to tissues.

angiopoietin-like protein

chylomicrons

lipid metabolism

LPL

plasma triglycerides

Biochemistry

The effects of prolonged sitting and acute exercise on postprandial plasma triglyceride concentration

Kim, Il-Young, 1973-

31 January 2012

These studies investigated the effect of physical inactivity (prolonged sitting) and physical activity (walking, standing, and moderate intensity exercise) on postprandial plasma triglyceride concentration (PPTG). In the first study, we evaluated the effect of low intensity intermittent walking at ~25% VO₂max (WALK) and energy-matched moderate intensity running at ~65% VO₂max (RUN) on PPTG, compared to a sitting control (SIT). RUN reduced incremental area under the curves for plasma triglyceride concentration (TG AUC[subscript I]), compared to WALK by 17.3% (p = 0.04) and SIT by 27% (p [less than] 0.001). The reduced TG AUC[subscript I] in RUN was accompanied by enhanced whole body insulin sensitivity, compared to WALK and SIT (for both, p [less than] 0.05). Whole body postprandial fat oxidation at rest following a high fat test meal intake was enhanced in RUN by 31% (P [less than] 0.001) and to a lesser extent in WALK by 8.4% (p [less than] 0.005), compared to SIT. In the second study, we evaluated 1) the effect of 2 days of prolonged sitting on PPTG, and 2) the effect of 4 days of SIT on the ability of an acute bout of exercise to reduce PPTG, compared to the same days of active walking and standing with calorically balanced diet (WALK+B). To distinguish the effect of prolonged sitting from the excess calorie effect, we had a sitting condition with calorically balanced diet (SIT+B) in addition to a sitting condition with hypercaloric diet (SIT+H). Following 2 days of respective food and activity control, WALK+B was lower in TG AUC[subscript T] by 21.3% and AUC[subscript I] by 17.4%, compared to SIT+H (for both, p [less than] 0.005). WALK+B was lower than SIT+B for TG AUC[subscript T] by 17.7% (p = 0.165) and AUC[subscript I] by 23.5% (p = 0.145) although statistical significance was not achieved. Remarkably, an acute exercise following 4 days of either SIT+H or SIT+B failed to reduce both TG AUC[subscript T] and AUC[subscript I], compared to SIT+B in HFTT1. The same exercise following 4 days of WALK+B, however, reduced both TG AUC[subscript T] by 29% and TG AUC[subscript I] by 32% in HFTT2, compared to SIT+B in HFTT1 (for both, p [less than] 0.02). Further, both SIT conditions reduced relative whole body fat oxidation in favor of increases in carbohydrate oxidation, compared to WALK+B by more than 40% in both HFTT1 and HFTT2. Taken together, our data suggest that 1) exercise intensity plays an independent role with higher intensity being more effective than lower intensity exercise in reducing PPTG, and 2) prolonged sitting with excess energy intake amplifies PPTG and prolonged sitting impairs the ability of an acute bout of moderate intensity exercise to reduce PPTG. This emphasizes the importance of regular participation in moderate-to-vigorous intensity exercise and reducing sitting time by increasing non-exercise physical activities (i.e., walking and standing) for the favorable postprandial metabolic health from the individual and public health perspectives. / text

Prolonged sitting

Postprandial plasma triglycerides

Substrate oxidation

Insulin sensitivity

Atherosclerosis

Functional Analysis of the TRIB1 Locus in Coronary Artery Disease

Douvris, Adrianna

21 July 2011

The TRIB1 locus (8q24.13) is a novel locus associated with plasma TGs and CAD risk. Trib1 is a regulator of MAPK activity, and has been shown to regulate hepatic lipogenesis and VLDL production in mice. However, the functional relationship between common SNPs at the TRIB1 locus and plasma lipid traits is unknown; TRIB1 has not been identified as an eQTL. This cluster of SNPs falls within an intergenic region 25kb to 50kb downstream of the TRIB1 coding region. By phylogenetic footprinting analysis and DNA genotyping, we identified an evolutionarily conserved region (CNS1) within the risk locus that harbours two common SNPs in tight LD with GWAS risk SNPs and significantly associated with CAD. We investigated the regulatory function of CNS1 by luciferase reporter assays in HepG2 cells and demonstrate that this region has promoter activity. In addition, the rs2001844 risk allele significantly reduces luciferase activity, suggesting that altered expression of the EST-based gene may be associated with plasma TGs. We identified an EST within the risk locus directly downstream of CNS1. We performed 5'/3' RACE using HepG2 RNA, identified multiple variants of this EST-based gene, and confirmed its transcription start site within CNS1. We hypothesize that this EST is a long noncoding RNA due to low abundance, poor conservation, and absence of significant ORF. Over-expression of a short variant implicates its function in the regulation of target gene transcription, although the mechanism of action remains unknown. We conclude that the risk locus at 8q24.13 harbours a novel EST-based gene that may explain the relationship between GWAS SNPs at this locus and plasma lipid traits.

Coronary Artery Disease

Plasma triglycerides

Lipoproteins

Genomics

Genome-wide association studies

Single nucleotide polymorphisms

TRIB1 locus (8q24.13)

Noncoding RNA

Hepatic lipogenesis

Gene transcription

5'/3' RACE

Luciferase reporter assays

Promoter

Intergenic

Functional Analysis of the TRIB1 Locus in Coronary Artery Disease

Douvris, Adrianna

21 July 2011

The TRIB1 locus (8q24.13) is a novel locus associated with plasma TGs and CAD risk. Trib1 is a regulator of MAPK activity, and has been shown to regulate hepatic lipogenesis and VLDL production in mice. However, the functional relationship between common SNPs at the TRIB1 locus and plasma lipid traits is unknown; TRIB1 has not been identified as an eQTL. This cluster of SNPs falls within an intergenic region 25kb to 50kb downstream of the TRIB1 coding region. By phylogenetic footprinting analysis and DNA genotyping, we identified an evolutionarily conserved region (CNS1) within the risk locus that harbours two common SNPs in tight LD with GWAS risk SNPs and significantly associated with CAD. We investigated the regulatory function of CNS1 by luciferase reporter assays in HepG2 cells and demonstrate that this region has promoter activity. In addition, the rs2001844 risk allele significantly reduces luciferase activity, suggesting that altered expression of the EST-based gene may be associated with plasma TGs. We identified an EST within the risk locus directly downstream of CNS1. We performed 5'/3' RACE using HepG2 RNA, identified multiple variants of this EST-based gene, and confirmed its transcription start site within CNS1. We hypothesize that this EST is a long noncoding RNA due to low abundance, poor conservation, and absence of significant ORF. Over-expression of a short variant implicates its function in the regulation of target gene transcription, although the mechanism of action remains unknown. We conclude that the risk locus at 8q24.13 harbours a novel EST-based gene that may explain the relationship between GWAS SNPs at this locus and plasma lipid traits.

Coronary Artery Disease

Plasma triglycerides

Lipoproteins

Genomics

Genome-wide association studies

Single nucleotide polymorphisms

TRIB1 locus (8q24.13)

Noncoding RNA

Hepatic lipogenesis

Gene transcription

5'/3' RACE

Luciferase reporter assays

Promoter

Intergenic

Functional Analysis of the TRIB1 Locus in Coronary Artery Disease

Douvris, Adrianna

21 July 2011

The TRIB1 locus (8q24.13) is a novel locus associated with plasma TGs and CAD risk. Trib1 is a regulator of MAPK activity, and has been shown to regulate hepatic lipogenesis and VLDL production in mice. However, the functional relationship between common SNPs at the TRIB1 locus and plasma lipid traits is unknown; TRIB1 has not been identified as an eQTL. This cluster of SNPs falls within an intergenic region 25kb to 50kb downstream of the TRIB1 coding region. By phylogenetic footprinting analysis and DNA genotyping, we identified an evolutionarily conserved region (CNS1) within the risk locus that harbours two common SNPs in tight LD with GWAS risk SNPs and significantly associated with CAD. We investigated the regulatory function of CNS1 by luciferase reporter assays in HepG2 cells and demonstrate that this region has promoter activity. In addition, the rs2001844 risk allele significantly reduces luciferase activity, suggesting that altered expression of the EST-based gene may be associated with plasma TGs. We identified an EST within the risk locus directly downstream of CNS1. We performed 5'/3' RACE using HepG2 RNA, identified multiple variants of this EST-based gene, and confirmed its transcription start site within CNS1. We hypothesize that this EST is a long noncoding RNA due to low abundance, poor conservation, and absence of significant ORF. Over-expression of a short variant implicates its function in the regulation of target gene transcription, although the mechanism of action remains unknown. We conclude that the risk locus at 8q24.13 harbours a novel EST-based gene that may explain the relationship between GWAS SNPs at this locus and plasma lipid traits.

Coronary Artery Disease

Plasma triglycerides

Lipoproteins

Genomics

Genome-wide association studies

Single nucleotide polymorphisms

TRIB1 locus (8q24.13)

Noncoding RNA

Hepatic lipogenesis

Gene transcription

5'/3' RACE

Luciferase reporter assays

Promoter

Intergenic

Functional Analysis of the TRIB1 Locus in Coronary Artery Disease

Douvris, Adrianna

January 2011

The TRIB1 locus (8q24.13) is a novel locus associated with plasma TGs and CAD risk. Trib1 is a regulator of MAPK activity, and has been shown to regulate hepatic lipogenesis and VLDL production in mice. However, the functional relationship between common SNPs at the TRIB1 locus and plasma lipid traits is unknown; TRIB1 has not been identified as an eQTL. This cluster of SNPs falls within an intergenic region 25kb to 50kb downstream of the TRIB1 coding region. By phylogenetic footprinting analysis and DNA genotyping, we identified an evolutionarily conserved region (CNS1) within the risk locus that harbours two common SNPs in tight LD with GWAS risk SNPs and significantly associated with CAD. We investigated the regulatory function of CNS1 by luciferase reporter assays in HepG2 cells and demonstrate that this region has promoter activity. In addition, the rs2001844 risk allele significantly reduces luciferase activity, suggesting that altered expression of the EST-based gene may be associated with plasma TGs. We identified an EST within the risk locus directly downstream of CNS1. We performed 5'/3' RACE using HepG2 RNA, identified multiple variants of this EST-based gene, and confirmed its transcription start site within CNS1. We hypothesize that this EST is a long noncoding RNA due to low abundance, poor conservation, and absence of significant ORF. Over-expression of a short variant implicates its function in the regulation of target gene transcription, although the mechanism of action remains unknown. We conclude that the risk locus at 8q24.13 harbours a novel EST-based gene that may explain the relationship between GWAS SNPs at this locus and plasma lipid traits.

Coronary Artery Disease

Plasma triglycerides

Lipoproteins

Genomics

Genome-wide association studies

Single nucleotide polymorphisms

TRIB1 locus (8q24.13)

Noncoding RNA

Hepatic lipogenesis

Gene transcription

5'/3' RACE

Luciferase reporter assays

Promoter

Intergenic