Your search keyword '"Stephen G. Young"' showing total 467 results

1. APOA5 deficiency causes hypertriglyceridemia by reducing amounts of lipoprotein lipase in capillaries

Author

Ye Yang, Robert J. Konrad, Michael Ploug, and Stephen G. Young

Subjects

APOA5, lipoprotein lipase, hypertriglyceridemia, ANGPTL3/8, monoclonal antibody, Biochemistry, QD415-436

Abstract

Apolipoprotein AV (APOA5) deficiency causes hypertriglyceridemia in mice and humans. For years, the cause remained a mystery, but the mechanisms have now come into focus. Here, we review progress in defining APOA5’s function in plasma triglyceride metabolism. Biochemical studies revealed that APOA5 binds to the angiopoietin-like protein 3/8 complex (ANGPTL3/8) and suppresses its ability to inhibit the activity of lipoprotein lipase (LPL). Thus, APOA5 deficiency is accompanied by increased ANGPTL3/8 activity and lower levels of LPL activity. APOA5 deficiency also reduces amounts of LPL in capillaries of oxidative tissues (e.g., heart, brown adipose tissue). Cell culture experiments revealed the likely explanation: ANGPTL3/8 detaches LPL from its binding sites on the surface of cells, and that effect is blocked by APOA5. Both the low intracapillary LPL levels and the high plasma triglyceride levels in Apoa5−/− mice are normalized by recombinant APOA5. Carboxyl-terminal sequences in APOA5 are crucial for its function; a mutant APOA5 lacking 40-carboxyl-terminal residues cannot bind to ANGPTL3/8 and lacks the ability to change intracapillary LPL levels or plasma triglyceride levels in Apoa5−/− mice. Also, an antibody against the last 26 amino acids of APOA5 reduces intracapillary LPL levels and increases plasma triglyceride levels in wild-type mice. An inhibitory ANGPTL3/8-specific antibody functions as an APOA5-mimetic reagent, increasing intracapillary LPL levels and lowering plasma triglyceride levels in both Apoa5−/− and wild-type mice. That antibody is a potentially attractive strategy for treating elevated plasma lipid levels in human patients.

Published

2024

2. Quantification of lipoprotein lipase in mouse plasma with a sandwich enzyme-linked immunosorbent assay

Author

Takao Kimura, Kazuya Miyashita, Isamu Fukamachi, Kumiko Fukamachi, Kazumi Ogura, Erina Yokoyama, Katsuhiko Tsunekawa, Takumi Nagasawa, Michael Ploug, Ye Yang, Wenxin Song, Stephen G. Young, Anne P. Beigneux, Katsuyuki Nakajima, and Masami Murakami

Subjects

lipids, triglycerides, transport, vascular biology, LPL, HTGL, Biochemistry, QD415-436

Abstract

To support in vivo and in vitro studies of intravascular triglyceride metabolism in mice, we created rat monoclonal antibodies (mAbs) against mouse LPL. Two mAbs, mAbs 23A1 and 31A5, were used to develop a sandwich ELISA for mouse LPL. The detection of mouse LPL by the ELISA was linear in concentrations ranging from 0.31 ng/ml to 20 ng/ml. The sensitivity of the ELISA made it possible to quantify LPL in serum and in both pre-heparin and post-heparin plasma samples (including in grossly lipemic samples). LPL mass and activity levels in the post-heparin plasma were lower in Gpihbp1−/− mice than in wild-type mice. In both groups of mice, LPL mass and activity levels were positively correlated. Our mAb-based sandwich ELISA for mouse LPL will be useful for any investigator who uses mouse models to study LPL-mediated intravascular lipolysis.

Published

2024

3. Imaging the ANGPTL3/8-mediated regulation of lipoprotein lipase in the heart

Author

Ye Yang, Hyesoo Jung, Robert J. Konrad, Loren G. Fong, and Stephen G. Young

Subjects

Biochemistry, QD415-436

Published

2023

4. Revisiting the truncated lamin A produced by a commonly used strain of Lmna knockout mice

Author

Joonyoung R. Kim, Paul H. Kim, Ashley Presnell, Yiping Tu, and Stephen G. Young

Subjects

Lamins, LMNA deficiency, lmna transcripts, nuclear envelope, nuclear lamina, protein farnesylation, Genetics, QH426-470, Cytology, QH573-671

Abstract

ABSTRACTThe Lmna knockout mouse (Lmna–/–) created by Sullivan and coworkers in 1999 has been widely used to examine lamin A/C function. The knockout allele contains a deletion of Lmna intron 7–exon 11 sequences and was reported to be a null allele. Later, Jahn and coworkers discovered that the mutant allele produces a 54-kDa truncated lamin A and identified, by RT-PCR, a Lmna cDNA containing exon 1–7 + exon 12 sequences. Because exon 12 encodes prelamin A’s CaaX motif, the mutant lamin A is assumed to be farnesylated. In the current study, we found that the truncated lamin A in Lmna–/– mouse embryonic fibroblasts (MEFs) was predominantly nucleoplasmic rather than at the nuclear rim, leading us to hypothesize that it was not farnesylated. Our study revealed that the most abundant Lmna transcripts in Lmna–/– MEFs contain exon 1–7 but not exon 12 sequences. Exon 1–7 + exon 12 transcripts were detectable by PCR but in trace amounts. We suspect that these findings explain the nucleoplasmic distribution of the truncated lamin A in Lmna–/– MEFs, and subsequent cell transduction experiments support this suspicion. A truncated lamin A containing exon 1–7 sequence was nucleoplasmic, whereas a lamin A containing exon 1–7 + exon 12 sequences was located along the nuclear rim. Our study explains the nucleoplasmic targeting of truncated lamin A in Lmna–/– MEFs and adds to our understanding of a commonly used strain of Lmna–/– mice.

Published

2023

5. NanoSIMS imaging of lipid absorption by intestinal enterocytes

Author

Kai Chen, Wenxin Song, Robert Russell, Alessandra Ferrari, Tamim Darwish, Peter Tontonoz, Stephen G. Young, and Haibo Jiang

Subjects

Biochemistry, QD415-436

Published

2022

6. Electrostatic sheathing of lipoprotein lipase is essential for its movement across capillary endothelial cells

Author

Wenxin Song, Anne P. Beigneux, Anne-Marie L. Winther, Kristian K. Kristensen, Anne L. Grønnemose, Ye Yang, Yiping Tu, Priscilla Munguia, Jazmin Morales, Hyesoo Jung, Pieter J. de Jong, Cris J. Jung, Kazuya Miyashita, Takao Kimura, Katsuyuki Nakajima, Masami Murakami, Gabriel Birrane, Haibo Jiang, Peter Tontonoz, Michael Ploug, Loren G. Fong, and Stephen G. Young

Subjects

Metabolism, Medicine

Abstract

GPIHBP1, an endothelial cell (EC) protein, captures lipoprotein lipase (LPL) within the interstitial spaces (where it is secreted by myocytes and adipocytes) and transports it across ECs to its site of action in the capillary lumen. GPIHBP1’s 3-fingered LU domain is required for LPL binding, but the function of its acidic domain (AD) has remained unclear. We created mutant mice lacking the AD and found severe hypertriglyceridemia. As expected, the mutant GPIHBP1 retained the capacity to bind LPL. Unexpectedly, however, most of the GPIHBP1 and LPL in the mutant mice was located on the abluminal surface of ECs (explaining the hypertriglyceridemia). The GPIHBP1-bound LPL was trapped on the abluminal surface of ECs by electrostatic interactions between the large basic patch on the surface of LPL and negatively charged heparan sulfate proteoglycans (HSPGs) on the surface of ECs. GPIHBP1 trafficking across ECs in the mutant mice was normalized by disrupting LPL-HSPG electrostatic interactions with either heparin or an AD peptide. Thus, GPIHBP1’s AD plays a crucial function in plasma triglyceride metabolism; it sheathes LPL’s basic patch on the abluminal surface of ECs, thereby preventing LPL-HSPG interactions and freeing GPIHBP1-LPL complexes to move across ECs to the capillary lumen.

Published

2022

7. Chylomicronemia from GPIHBP1 autoantibodies

Author

Kazuya Miyashita, Jens Lutz, Lisa C. Hudgins, Dana Toib, Ambika P. Ashraf, Wenxin Song, Masami Murakami, Katsuyuki Nakajima, Michael Ploug, Loren G. Fong, Stephen G. Young, and Anne P. Beigneux

Subjects

glycosylphosphatidylinositol-anchored high density lipoprotein binding protein 1, lipoprotein lipase, triglycerides, autoimmune disease, immunoglobulin A, immunoglobulin G4, Biochemistry, QD415-436

Abstract

Some cases of chylomicronemia are caused by autoantibodies against glycosylphosphatidylinositol-anchored HDL binding protein 1 (GPIHBP1), an endothelial cell protein that shuttles LPL to the capillary lumen. GPIHBP1 autoantibodies prevent binding and transport of LPL by GPIHBP1, thereby disrupting the lipolytic processing of triglyceride-rich lipoproteins. Here, we review the “GPIHBP1 autoantibody syndrome” and summarize clinical and laboratory findings in 22 patients. All patients had GPIHBP1 autoantibodies and chylomicronemia, but we did not find a correlation between triglyceride levels and autoantibody levels. Many of the patients had a history of pancreatitis, and most had clinical and/or serological evidence of autoimmune disease. IgA autoantibodies were present in all patients, and IgG4 autoantibodies were present in 19 of 22 patients. Patients with GPIHBP1 autoantibodies had low plasma LPL levels, consistent with impaired delivery of LPL into capillaries. Plasma levels of GPIHBP1, measured with a monoclonal antibody–based ELISA, were very low in 17 patients, reflecting the inability of the ELISA to detect GPIHBP1 in the presence of autoantibodies (immunoassay interference). However, GPIHBP1 levels were very high in five patients, indicating little capacity of their autoantibodies to interfere with the ELISA. Recently, several GPIHBP1 autoantibody syndrome patients were treated successfully with rituximab, resulting in the disappearance of GPIHBP1 autoantibodies and normalization of both plasma triglyceride and LPL levels. The GPIHBP1 autoantibody syndrome should be considered in any patient with newly acquired and unexplained chylomicronemia.

Published

2020

8. The structural basis for monoclonal antibody 5D2 binding to the tryptophan-rich loop of lipoprotein lipase

Author

John G. Luz, Anne P. Beigneux, DeeAnn K. Asamoto, Cuiwen He, Wenxin Song, Christopher M. Allan, Jazmin Morales, Yiping Tu, Adam Kwok, Thomas Cottle, Muthuraman Meiyappan, Loren G. Fong, Judy E. Kim, Michael Ploug, Stephen G. Young, and Gabriel Birrane

Subjects

antibodies, lipid metabolism, protein structure, triglycerides, X-ray crystallography, Biochemistry, QD415-436

Abstract

For three decades, the LPL–specific monoclonal antibody 5D2 has been used to investigate LPL structure/function and intravascular lipolysis. 5D2 has been used to measure LPL levels, block the triglyceride hydrolase activity of LPL, and prevent the propensity of concentrated LPL preparations to form homodimers. Two early studies on the location of the 5D2 epitope reached conflicting conclusions, but the more convincing report suggested that 5D2 binds to a tryptophan (Trp)-rich loop in the carboxyl terminus of LPL. The same loop had been implicated in lipoprotein binding. Using surface plasmon resonance, we showed that 5D2 binds with high affinity to a synthetic LPL peptide containing the Trp-rich loop of human (but not mouse) LPL. We also showed, by both fluorescence and UV resonance Raman spectroscopy, that the Trp-rich loop binds lipids. Finally, we used X-ray crystallography to solve the structure of the Trp-rich peptide bound to a 5D2 Fab fragment. The Trp-rich peptide contains a short α-helix, with two Trps projecting into the antigen recognition site. A proline substitution in the α-helix, found in mouse LPL, is expected to interfere with several hydrogen bonds, explaining why 5D2 cannot bind to mouse LPL.

Published

2020

9. Deficiency in ZMPSTE24 and resulting farnesyl–prelamin A accumulation only modestly affect mouse adipose tissue stores[S]

Author

Patrick J. Heizer, Ye Yang, Yiping Tu, Paul H. Kim, Natalie Y. Chen, Yan Hu, Yuko Yoshinaga, Pieter J. de Jong, Laurent Vergnes, Jazmin E. Morales, Robert L. Li, Nicholas Jackson, Karen Reue, Stephen G. Young, and Loren G. Fong

Subjects

animal models, farnesylation, nuclear lamins, fluorescence microscopy, lipodystrophies, zinc metallopeptidase STE24, Biochemistry, QD415-436

Abstract

Zinc metallopeptidase STE24 (ZMPSTE24) is essential for the conversion of farnesyl–prelamin A to mature lamin A, a key component of the nuclear lamina. In the absence of ZMPSTE24, farnesyl–prelamin A accumulates in the nucleus and exerts toxicity, causing a variety of disease phenotypes. By ∼4 months of age, both male and female Zmpste24−/− mice manifest a near-complete loss of adipose tissue, but it has never been clear whether this phenotype is a direct consequence of farnesyl–prelamin A toxicity in adipocytes. To address this question, we generated a conditional knockout Zmpste24 allele and used it to create adipocyte-specific Zmpste24–knockout mice. To boost farnesyl–prelamin A levels, we bred in the “prelamin A–only” Lmna allele. Gene expression, immunoblotting, and immunohistochemistry experiments revealed that adipose tissue in these mice had decreased Zmpste24 expression along with strikingly increased accumulation of prelamin A. In male mice, Zmpste24 deficiency in adipocytes was accompanied by modest changes in adipose stores (an 11% decrease in body weight, a 23% decrease in body fat mass, and significantly smaller gonadal and inguinal white adipose depots). No changes in adipose stores were detected in female mice, likely because prelamin A expression in adipose tissue is lower in female mice. Zmpste24 deficiency in adipocytes did not alter the number of macrophages in adipose tissue, nor did it alter plasma levels of glucose, triglycerides, or fatty acids. We conclude that ZMPSTE24 deficiency in adipocytes, and the accompanying accumulation of farnesyl–prelamin A, reduces adipose tissue stores, but only modestly and only in male mice.

Published

2020

10. Nuclear membrane ruptures, cell death, and tissue damage in the setting of nuclear lamin deficiencies

Author

Natalie Y. Chen, Paul H. Kim, Loren G. Fong, and Stephen G. Young

Subjects

nuclear membrane rupture, nuclear envelope, nuclear lamina, nuclear lamins, b-type lamins, Genetics, QH426-470, Cytology, QH573-671

Abstract

The nuclear membranes function as a barrier to separate the cell nucleus from the cytoplasm, but this barrier can be compromised by nuclear membrane ruptures, leading to intermixing of nuclear and cytoplasmic contents. Spontaneous nuclear membrane ruptures (i.e., ruptures occurring in the absence of mechanical stress) have been observed in cultured cells, but they are more frequent in the setting of defects or deficiencies in nuclear lamins and when cells are subjected to mechanical stress. Nuclear membrane ruptures in cultured cells have been linked to DNA damage, but the relevance of ruptures to developmental or physiologic processes in vivo has received little attention. Recently, we addressed that issue by examining neuronal migration in the cerebral cortex, a developmental process that subjects the cell nucleus to mechanical stress. In the setting of lamin B1 deficiency, we observed frequent nuclear membrane ruptures in migrating neurons in the developing cerebral cortex and showed that those ruptures are likely the cause of observed DNA damage, neuronal cell death, and profound neuropathology. In this review, we discuss the physiologic relevance of nuclear membrane ruptures, with a focus on migrating neurons in cell culture and in the cerebral cortex of genetically modified mice.

Published

2020

11. Nuclear membrane ruptures underlie the vascular pathology in a mouse model of Hutchinson-Gilford progeria syndrome

Author

Paul H. Kim, Natalie Y. Chen, Patrick J. Heizer, Yiping Tu, Thomas A. Weston, Jared L.-C. Fong, Navjot Kaur Gill, Amy C. Rowat, Stephen G. Young, and Loren G. Fong

Subjects

Vascular biology, Medicine

Abstract

The mutant nuclear lamin protein (progerin) produced in Hutchinson-Gilford progeria syndrome (HGPS) results in loss of arterial smooth muscle cells (SMCs), but the mechanism has been unclear. We found that progerin induces repetitive nuclear membrane (NM) ruptures, DNA damage, and cell death in cultured SMCs. Reducing lamin B1 expression and exposing cells to mechanical stress — to mirror conditions in the aorta — triggered more frequent NM ruptures. Increasing lamin B1 protein levels had the opposite effect, reducing NM ruptures and improving cell survival. Remarkably, raising lamin B1 levels increased nuclear compliance in cells and was able to offset the increased nuclear stiffness caused by progerin. In mice, lamin B1 expression in aortic SMCs is normally very low, and in mice with a targeted HGPS mutation (LmnaG609G), levels of lamin B1 decrease further with age while progerin levels increase. Those observations suggest that NM ruptures might occur in aortic SMCs in vivo. Indeed, studies in LmnaG609G mice identified NM ruptures in aortic SMCs, along with ultrastructural abnormalities in the cell nucleus that preceded SMC loss. Our studies identify NM ruptures in SMCs as likely causes of vascular pathology in HGPS.

Published

2021

12. GPIHBP1 and ANGPTL4 Utilize Protein Disorder to Orchestrate Order in Plasma Triglyceride Metabolism and Regulate Compartmentalization of LPL Activity

Author

Kristian Kølby Kristensen, Katrine Zinck Leth-Espensen, Anni Kumari, Anne Louise Grønnemose, Anne-Marie Lund-Winther, Stephen G. Young, and Michael Ploug

Subjects

GPIHBP1, lipoprotein lipase, intravascular lipolysis, intrinsic disorder, ANGPTL4, LU domain, Biology (General), QH301-705.5

Abstract

Intravascular processing of triglyceride-rich lipoproteins (TRLs) is crucial for delivery of dietary lipids fueling energy metabolism in heart and skeletal muscle and for storage in white adipose tissue. During the last decade, mechanisms underlying focal lipolytic processing of TRLs along the luminal surface of capillaries have been clarified by fresh insights into the functions of lipoprotein lipase (LPL); LPL’s dedicated transporter protein, glycosylphosphatidylinositol-anchored high density lipoprotein–binding protein 1 (GPIHBP1); and its endogenous inhibitors, angiopoietin-like (ANGPTL) proteins 3, 4, and 8. Key discoveries in LPL biology include solving the crystal structure of LPL, showing LPL is catalytically active as a monomer rather than as a homodimer, and that the borderline stability of LPL’s hydrolase domain is crucial for the regulation of LPL activity. Another key discovery was understanding how ANGPTL4 regulates LPL activity. The binding of ANGPTL4 to LPL sequences adjacent to the catalytic cavity triggers cooperative and sequential unfolding of LPL’s hydrolase domain resulting in irreversible collapse of the catalytic cavity and loss of LPL activity. Recent studies have highlighted the importance of the ANGPTL3–ANGPTL8 complex for endocrine regulation of LPL activity in oxidative organs (e.g., heart, skeletal muscle, brown adipose tissue), but the molecular mechanisms have not been fully defined. New insights have also been gained into LPL–GPIHBP1 interactions and how GPIHBP1 moves LPL to its site of action in the capillary lumen. GPIHBP1 is an atypical member of the LU (Ly6/uPAR) domain protein superfamily, containing an intrinsically disordered and highly acidic N-terminal extension and a disulfide bond–rich three-fingered LU domain. Both the disordered acidic domain and the folded LU domain are crucial for the stability and transport of LPL, and for modulating its susceptibility to ANGPTL4-mediated unfolding. This review focuses on recent advances in the biology and biochemistry of crucial proteins for intravascular lipolysis.

Published

2021

13. An upstream enhancer regulates Gpihbp1 expression in a tissue-specific manner[S]

Author

Christopher M. Allan, Patrick J. Heizer, Yiping Tu, Norma P. Sandoval, Rachel S. Jung, Jazmin E. Morales, Eniko Sajti, Ty D. Troutman, Thomas L. Saunders, Darren A. Cusanovich, Anne P. Beigneux, Casey E. Romanoski, Loren G. Fong, and Stephen G. Young

Subjects

chylomicrons, endothelial cells, lipids, lipolysis, fatty acid metabolism, triglycerides, Biochemistry, QD415-436

Abstract

Glycosylphosphatidylinositol-anchored high density lipoprotein–binding protein 1 (GPIHBP1), the protein that shuttles LPL to the capillary lumen, is essential for plasma triglyceride metabolism. When GPIHBP1 is absent, LPL remains stranded within the interstitial spaces and plasma triglyceride hydrolysis is impaired, resulting in severe hypertriglyceridemia. While the functions of GPIHBP1 in intravascular lipolysis are reasonably well understood, no one has yet identified DNA sequences regulating GPIHBP1 expression. In the current studies, we identified an enhancer element located ∼3.6 kb upstream from exon 1 of mouse Gpihbp1. To examine the importance of the enhancer, we used CRISPR/Cas9 genome editing to create mice lacking the enhancer (Gpihbp1 Enh/Enh). Removing the enhancer reduced Gpihbp1 expression by >90% in the liver and by ∼50% in heart and brown adipose tissue. The reduced expression of GPIHBP1 was insufficient to prevent LPL from reaching the capillary lumen, and it did not lead to hypertriglyceridemia–even when mice were fed a high-fat diet. Compound heterozygotes (Gpihbp1 Enh/− mice) displayed further reductions in Gpihbp1 expression and exhibited partial mislocalization of LPL (increased amounts of LPL within the interstitial spaces of the heart), but the plasma triglyceride levels were not perturbed. The enhancer element that we identified represents the first insight into DNA sequences controlling Gpihbp1 expression.

Published

2019

14. ANGPTL4 sensitizes lipoprotein lipase to PCSK3 cleavage by catalyzing its unfolding

Author

Anne-Marie Lund Winther, Anni Kumari, Stephen G. Young, and Michael Ploug

Subjects

Biochemistry, QD415-436

Published

2021

15. ANGPTL4 inactivates lipoprotein lipase by catalyzing the irreversible unfolding of LPL's hydrolase domain

Author

Kristian Kølby Kristensen, Katrine Zinck Leth-Espensen, Stephen G. Young, and Michael Ploug

Subjects

Biochemistry, QD415-436

Published

2020

16. The fatty acids from LPL-mediated processing of triglyceride-rich lipoproteins are taken up rapidly by cardiomyocytes

Author

Haibo Jiang, Cuiwen He, Loren G. Fong, and Stephen G. Young

Subjects

Biochemistry, QD415-436

Published

2020

17. GPIHBP1, a partner protein for lipoprotein lipase, is expressed only in capillary endothelial cells

Author

Xia Meng, Wenwen Zeng, Stephen G. Young, and Loren G. Fong

Subjects

Biochemistry, QD415-436

Published

2020

18. Slc25a17 Gene Trapped Mice: PMP34 Plays a Role in the Peroxisomal Degradation of Phytanic and Pristanic Acid

Author

Paul P. Van Veldhoven, Evelyn de Schryver, Stephen G. Young, An Zwijsen, Marc Fransen, Marc Espeel, Myriam Baes, and Elke Van Ael

Subjects

ATP, beta-oxidation, bile acids, coenzyme A, membrane transport, mitochondrial solute transporter, Biology (General), QH301-705.5

Abstract

Mice lacking PMP34, a peroxisomal membrane transporter encoded by Slc25a17, did not manifest any obvious phenotype on a Swiss Webster genetic background, even with various treatments designed to unmask impaired peroxisomal functioning. Peroxisomal α- and β-oxidation rates in PMP34 deficient fibroblasts or liver slices were not or only modestly affected and in bile, no abnormal bile acid intermediates were detected. Peroxisomal content of cofactors like CoA, ATP, NAD+, thiamine-pyrophosphate and pyridoxal-phosphate, based on direct or indirect data, appeared normal as were tissue plasmalogen and very long chain fatty acid levels. However, upon dietary phytol administration, the knockout mice displayed hepatomegaly, liver inflammation, and an induction of peroxisomal enzymes. This phenotype was partially mediated by PPARα. Hepatic triacylglycerols and cholesterylesters were elevated and both phytanic acid and pristanic acid accumulated in the liver lipids, in females to higher extent than in males. In addition, pristanic acid degradation products were detected, as wells as the CoA-esters of all these branched fatty acids. Hence, PMP34 is important for the degradation of phytanic/pristanic acid and/or export of their metabolites. Whether this is caused by a shortage of peroxisomal CoA affecting the intraperoxisomal formation of pristanoyl-CoA (and perhaps of phytanoyl-CoA), or the SCPx-catalyzed thiolytic cleavage during pristanic acid β-oxidation, could not be proven in this model, but the phytol-derived acyl-CoA profile is compatible with the latter possibility. On the other hand, the normal functioning of other peroxisomal pathways, and especially bile acid formation, seems to exclude severe transport problems or a shortage of CoA, and other cofactors like FAD, NAD(P)+, TPP. Based on our findings, PMP34 deficiency in humans is unlikely to be a life threatening condition but could cause elevated phytanic/pristanic acid levels in older adults.

Published

2020

19. Impaired thermogenesis and sharp increases in plasma triglyceride levels in GPIHBP1-deficient mice during cold exposure

Author

Mikael Larsson, Christopher M. Allan, Patrick J. Heizer, Yiping Tu, Norma P. Sandoval, Rachel S. Jung, Rosemary L. Walzem, Anne P. Beigneux, Stephen G. Young, and Loren G. Fong

Subjects

glycosylphosphatidylinositol-anchored high density lipoprotein–binding protein 1, lipoprotein lipase, triglyceride metabolism, Biochemistry, QD415-436

Abstract

Glycosylphosphatidylinositol-anchored high density lipoprotein–binding protein 1 (GPIHBP1), an endothelial cell protein, binds LPL in the subendothelial spaces and transports it to the capillary lumen. In Gpihbp1−/− mice, LPL remains stranded in the subendothelial spaces, causing hypertriglyceridemia, but how Gpihbp1−/− mice respond to metabolic stress (e.g., cold exposure) has never been studied. In wild-type mice, cold exposure increases LPL-mediated processing of triglyceride-rich lipoproteins (TRLs) in brown adipose tissue (BAT), providing fuel for thermogenesis and leading to lower plasma triglyceride levels. We suspected that defective TRL processing in Gpihbp1−/− mice might impair thermogenesis and blunt the fall in plasma triglyceride levels. Indeed, Gpihbp1−/− mice exhibited cold intolerance, but the effects on plasma triglyceride levels were paradoxical. Rather than falling, the plasma triglyceride levels increased sharply (from ∼4,000 to ∼15,000 mg/dl), likely because fatty acid release by peripheral tissues drives hepatic production of TRLs that cannot be processed. We predicted that the sharp increase in plasma triglyceride levels would not occur in Gpihbp1−/−Angptl4−/− mice, where LPL activity is higher and baseline plasma triglyceride levels are lower. Indeed, the plasma triglyceride levels in Gpihbp1−/−Angptl4−/− mice fell during cold exposure. Metabolic studies revealed increased levels of TRL processing in the BAT of Gpihbp1−/−Angptl4−/− mice.

Published

2018

20. Apolipoprotein C-III inhibits triglyceride hydrolysis by GPIHBP1-bound LPL[S]

Author

Mikael Larsson, Christopher M. Allan, Rachel S. Jung, Patrick J. Heizer, Anne P. Beigneux, Stephen G. Young, and Loren G. Fong

Subjects

glycosylphosphatidylinositol-anchored high density lipoprotein-binding protein 1, lipoprotein lipase, hypertriglyceridemia, Biochemistry, QD415-436

Abstract

ApoC-III is often assumed to retard the intravascular processing of triglyceride-rich lipoproteins (TRLs) by inhibiting LPL, but that view is based largely on studies of free LPL. We now recognize that intravascular LPL is neither free nor loosely bound, but instead is tightly bound to glycosylphosphatidylinositol-anchored HDL-binding protein 1 (GPIHBP1) on endothelial cells. Here, we revisited the effects of apoC-III on LPL, focusing on apoC-IIIʼns capacity to affect the activity of GPIHBP1-bound LPL. We found that TRLs from APOC3 transgenic mice bound normally to GPIHBP1-bound LPL on cultured cells in vitro and to heart capillaries in vivo. However, the triglycerides in apoC-III–enriched TRLs were hydrolyzed more slowly by free LPL, and the inhibitory effect of apoC-III on triglyceride lipolysis was exaggerated when LPL was bound to GPIHBP1 on the surface of agarose beads. Also, recombinant apoC-III reduced triglyceride hydrolysis by free LPL only modestly, but the inhibitory effect was greater when the LPL was bound to GPIHBP1. A mutant apoC-III associated with low plasma triglyceride levels (p.A23T) displayed a reduced capacity to inhibit free and GPIHBP1-bound LPL. Our results show that apoC-III potently inhibits triglyceride hydrolysis when LPL is bound to GPIHBP1.

Published

2017

21. Mutating a conserved cysteine in GPIHBP1 reduces amounts of GPIHBP1 in capillaries and abolishes LPL binding

Author

Christopher M. Allan, Cris J. Jung, Mikael Larsson, Patrick J. Heizer, Yiping Tu, Norma P. Sandoval, Tiffany Ly P. Dang, Rachel S. Jung, Anne P. Beigneux, Pieter J. de Jong, Loren G. Fong, and Stephen G. Young

Subjects

chylomicrons, endothelial cells, lipids/chemistry, lipolysis and fatty acid metabolism, triglycerides, glycosylphosphatidylinositol-anchored HDL binding protein 1, Biochemistry, QD415-436

Abstract

Mutation of conserved cysteines in proteins of the Ly6 family cause human disease—chylomicronemia in the case of glycosylphosphatidylinositol-anchored HDL binding protein 1 (GPIHBP1) and paroxysmal nocturnal hemoglobinuria in the case of CD59. A mutation in a conserved cysteine in CD59 prevented the protein from reaching the surface of blood cells. In contrast, mutation of conserved cysteines in human GPIHBP1 had little effect on GPIHBP1 trafficking to the surface of cultured CHO cells. The latter findings were somewhat surprising and raised questions about whether CHO cell studies accurately model the fate of mutant GPIHBP1 proteins in vivo. To explore this concern, we created mice harboring a GPIHBP1 cysteine mutation (p.C63Y). The p.C63Y mutation abolished the ability of mouse GPIHBP1 to bind LPL, resulting in severe chylomicronemia. The mutant GPIHBP1 was detectable by immunohistochemistry on the surface of endothelial cells, but the level of expression was ∼70% lower than in WT mice. The mutant GPIHBP1 protein in mouse tissues was predominantly monomeric. We conclude that mutation of a conserved cysteine in GPIHBP1 abolishes the ability of GPIHBP1 to bind LPL, resulting in mislocalization of LPL and severe chylomicronemia. The mutation reduced but did not eliminate GPIHBP1 on the surface of endothelial cells in vivo.

Published

2017

22. Lamin B1 is required for mature neuron-specific gene expression during olfactory sensory neuron differentiation

Author

Crystal M. Gigante, Michele Dibattista, Frederick N. Dong, Xiaobin Zheng, Sibiao Yue, Stephen G. Young, Johannes Reisert, Yixian Zheng, and Haiqing Zhao

Subjects

Science

Abstract

Emerging evidence suggests that lamins regulate gene expression during cellular differentiation. Giganteet al. show that lamin B1 is necessary for the upregulation of mature neuron-specific genes during olfactory neuron differentiation, and its deficiency leads to attenuated olfactory neuron response to odour in mice.

Published

2017

23. Monoclonal antibodies that bind to the Ly6 domain of GPIHBP1 abolish the binding of LPL

Author

Xuchen Hu, Mark W. Sleeman, Kazuya Miyashita, MacRae F. Linton, Christopher M. Allan, Cuiwen He, Mikael Larsson, Yiping Tu, Norma P. Sandoval, Rachel S. Jung, Alaleh Mapar, Tetsuo Machida, Masami Murakami, Katsuyuki Nakajima, Michael Ploug, Loren G. Fong, Stephen G. Young, and Anne P. Beigneux

Subjects

chylomicrons, dyslipidemias, endothelial cells, lipoprotein lipase, triglycerides, Biochemistry, QD415-436

Abstract

GPIHBP1, an endothelial cell protein, binds LPL in the interstitial spaces and shuttles it to its site of action inside blood vessels. For years, studies of human GPIHBP1 have been hampered by an absence of useful antibodies. We reasoned that monoclonal antibodies (mAbs) against human GPIHBP1 would be useful for 1) defining the functional relevance of GPIHBP1's Ly6 and acidic domains to the binding of LPL; 2) ascertaining whether human GPIHBP1 is expressed exclusively in capillary endothelial cells; and 3) testing whether GPIHBP1 is detectable in human plasma. Here, we report the development of a panel of human GPIHBP1-specific mAbs. Two mAbs against GPIHBP1's Ly6 domain, RE3 and RG3, abolished LPL binding, whereas an antibody against the acidic domain, RF4, did not. Also, mAbs RE3 and RG3 bound with reduced affinity to a mutant GPIHBP1 containing an Ly6 domain mutation (W109S) that abolishes LPL binding. Immunohistochemistry studies with the GPIHBP1 mAbs revealed that human GPIHBP1 is expressed only in capillary endothelial cells. Finally, we created an ELISA that detects GPIHBP1 in human plasma. That ELISA should make it possible for clinical lipidologists to determine whether plasma GPIHBP1 levels are a useful biomarker of metabolic or vascular disease

Published

2017

24. Mobility of 'HSPG-bound' LPL explains how LPL is able to reach GPIHBP1 on capillaries

Author

Christopher M. Allan, Mikael Larsson, Rachel S. Jung, Michael Ploug, André Bensadoun, Anne P. Beigneux, Loren G. Fong, and Stephen G. Young

Subjects

chylomicrons, endothelial cells, lipids/chemistry, lipolysis and fatty acid metabolism, triglycerides, heparan sulfate proteoglycan, Biochemistry, QD415-436

Abstract

In mice lacking glycosylphosphatidylinositol-anchored high density lipoprotein binding protein 1 (GPIHBP1), the LPL secreted by adipocytes and myocytes remains bound to heparan sulfate proteoglycans (HSPGs) on all cells within tissues. That observation raises a perplexing issue: Why isn't the freshly secreted LPL in wild-type mice captured by the same HSPGs, thereby preventing LPL from reaching GPIHBP1 on capillaries? We hypothesized that LPL–HSPG interactions are transient, allowing the LPL to detach and move to GPIHBP1 on capillaries. Indeed, we found that LPL detaches from HSPGs on cultured cells and moves to: 1) soluble GPIHBP1 in the cell culture medium; 2) GPIHBP1-coated agarose beads; and 3) nearby GPIHBP1-expressing cells. Movement of HSPG-bound LPL to GPIHBP1 did not occur when GPIHBP1 contained a Ly6 domain missense mutation (W109S), but was almost normal when GPIHBP1's acidic domain was mutated. To test the mobility of HSPG-bound LPL in vivo, we injected GPIHBP1-coated agarose beads into the brown adipose tissue of GPIHBP1-deficient mice. LPL moved quickly from HSPGs on adipocytes to GPIHBP1-coated beads, thereby depleting LPL stores on the surface of adipocytes. We conclude that HSPG-bound LPL in the interstitial spaces of tissues is mobile, allowing the LPL to move to GPIHBP1 on endothelial cells.

Published

2017

25. Images in Lipid Research

Author

Stephen G. Young

Subjects

Biochemistry, QD415-436

Published

2020

26. DYT1 Dystonia Patient-Derived Fibroblasts Have Increased Deformability and Susceptibility to Damage by Mechanical Forces

Author

Navjot Kaur Gill, Chau Ly, Paul H. Kim, Cosmo A. Saunders, Loren G. Fong, Stephen G. Young, G. W. Gant Luxton, and Amy C. Rowat

Subjects

torsinA, LINC complex, mechanotype, cell mechanical properties, nuclear envelope, lamins, Biology (General), QH301-705.5

Abstract

DYT1 dystonia is a neurological movement disorder that is caused by a loss-of-function mutation in the DYT1/TOR1A gene, which encodes torsinA, a conserved luminal ATPases-associated with various cellular activities (AAA+) protein. TorsinA is required for the assembly of functional linker of nucleoskeleton and cytoskeleton (LINC) complexes, and consequently the mechanical integration of the nucleus and the cytoskeleton. Despite the potential implications of altered mechanobiology in dystonia pathogenesis, the role of torsinA in regulating cellular mechanical phenotype, or mechanotype, in DYT1 dystonia remains unknown. Here, we define the deformability of mouse fibroblasts lacking functional torsinA as well as human fibroblasts isolated from DYT1 dystonia patients. We find that the deletion of torsinA or the expression of torsinA containing the DYT1 dystonia-causing ΔE302/303 (ΔE) mutation results in more deformable cells. We observe a similar increased deformability of mouse fibroblasts that lack lamina-associated polypeptide 1 (LAP1), which interacts with and stimulates the ATPase activity of torsinA in vitro, as well as with the absence of the LINC complex proteins, Sad1/UNC-84 1 (SUN1) and SUN2, lamin A/C, or lamin B1. Consistent with these findings, we also determine that DYT1 dystonia patient-derived fibroblasts are more compliant than fibroblasts isolated from unafflicted individuals. DYT1 dystonia patient-derived fibroblasts also exhibit increased nuclear strain and decreased viability following mechanical stretch. Taken together, our results establish the foundation for future mechanistic studies of the role of cellular mechanotype and LINC-dependent nuclear-cytoskeletal coupling in regulating cell survival following exposure to mechanical stresses.

Published

2019

27. An LPL–specific monoclonal antibody, 88B8, that abolishes the binding of LPL to GPIHBP1[S]

Author

Christopher M. Allan, Mikael Larsson, Xuchen Hu, Cuiwen He, Rachel S. Jung, Alaleh Mapar, Constance Voss, Kazuya Miyashita, Tetsuo Machida, Masami Murakami, Katsuyuki Nakajima, André Bensadoun, Michael Ploug, Loren G. Fong, Stephen G. Young, and Anne P. Beigneux

Subjects

chylomicrons, endothelial cells, lipids/chemistry, lipolysis and fatty acid metabolism, triglycerides, lipoprotein lipase, Biochemistry, QD415-436

Abstract

LPL contains two principal domains: an amino-terminal catalytic domain (residues 1–297) and a carboxyl-terminal domain (residues 298–448) that is important for binding lipids and binding glycosylphosphatidylinositol-anchored high density lipoprotein binding protein 1 (GPIHBP1) (an endothelial cell protein that shuttles LPL to the capillary lumen). The LPL sequences required for GPIHBP1 binding have not been examined in detail, but one study suggested that sequences near LPL's carboxyl terminus (residues ∼403–438) were crucial. Here, we tested the ability of LPL-specific monoclonal antibodies (mAbs) to block the binding of LPL to GPIHBP1. One antibody, 88B8, abolished LPL binding to GPIHBP1. Consistent with those results, antibody 88B8 could not bind to GPIHBP1-bound LPL on cultured cells. Antibody 88B8 bound poorly to LPL proteins with amino acid substitutions that interfered with GPIHBP1 binding (e.g., C418Y, E421K). However, the sequences near LPL's carboxyl terminus (residues ∼403–438) were not sufficient for 88B8 binding; upstream sequences (residues 298–400) were also required. Additional studies showed that these same sequences are required for LPL binding to GPIHBP1. In conclusion, we identified an LPL mAb that binds to LPL's GPIHBP1-binding domain. The binding of both antibody 88B8 and GPIHBP1 to LPL depends on large segments of LPL's carboxyl-terminal domain.

Published

2016

28. Angiopoietin-like 4 promotes intracellular degradation of lipoprotein lipase in adipocytes

Author

Wieneke Dijk, Anne P. Beigneux, Mikael Larsson, André Bensadoun, Stephen G. Young, and Sander Kersten

Subjects

lipid metabolism, adipose tissue, vascular biology, intracellular processing, Biochemistry, QD415-436

Abstract

LPL hydrolyzes triglycerides in triglyceride-rich lipoproteins along the capillaries of heart, skeletal muscle, and adipose tissue. The activity of LPL is repressed by angiopoietin-like 4 (ANGPTL4) but the underlying mechanisms have not been fully elucidated. Our objective was to study the cellular location and mechanism for LPL inhibition by ANGPTL4. We performed studies in transfected cells, ex vivo studies, and in vivo studies with Angptl4−/− mice. Cotransfection of CHO pgsA-745 cells with ANGPTL4 and LPL reduced intracellular LPL protein levels, suggesting that ANGPTL4 promotes LPL degradation. This conclusion was supported by studies of primary adipocytes and adipose tissue explants from wild-type and Angptl4−/− mice. Absence of ANGPTL4 resulted in accumulation of the mature-glycosylated form of LPL and increased secretion of LPL. Blocking endoplasmic reticulum (ER)-Golgi transport abolished differences in LPL abundance between wild-type and Angptl4−/− adipocytes, suggesting that ANGPTL4 acts upon LPL after LPL processing in the ER. Finally, physiological changes in adipose tissue ANGPTL4 expression during fasting and cold resulted in inverse changes in the amount of mature-glycosylated LPL in wild-type mice, but not Angptl4−/− mice. We conclude that ANGPTL4 promotes loss of intracellular LPL by stimulating LPL degradation after LPL processing in the ER.

Published

2016

29. SREBP-2-deficient and hypomorphic mice reveal roles for SREBP-2 in embryonic development and SREBP-1c expression[S]

Author

Laurent Vergnes, Robert G. Chin, Thomas de Aguiar Vallim, Loren G. Fong, Timothy F. Osborne, Stephen G. Young, and Karen Reue

Subjects

sterol regulatory element-binding protein 2, sterol regulatory element-binding protein 1c, gene regulation, cholesterol synthesis, Biochemistry, QD415-436

Abstract

Cholesterol and fatty acid biosynthesis are regulated by the sterol regulatory element-binding proteins (SREBPs), encoded by Srebf1 and Srebf2. We generated mice that were either deficient or hypomorphic for SREBP-2. SREBP-2 deficiency generally caused death during embryonic development. Analyses of Srebf2−/− embryos revealed a requirement for SREBP-2 in limb development and expression of morphogenic genes. We encountered only one viable Srebf2−/− mouse, which displayed alopecia, attenuated growth, and reduced adipose tissue stores. Hypomorphic SREBP-2 mice (expressing low levels of SREBP-2) survived development, but the female mice exhibited reduced body weight and died between 8 and 12 weeks of age. Male hypomorphic mice were viable but had reduced cholesterol stores in the liver and lower expression of SREBP target genes. Reduced SREBP-2 expression affected SREBP-1 isoforms in a tissue-specific manner. In the liver, reduced SREBP-2 expression nearly abolished Srebf1c transcripts and reduced Srebf1a mRNA levels. In contrast, adipose tissue displayed normal expression of SREBP target genes, likely due to a compensatory increase in Srebf1a expression. Our results establish that SREBP-2 is critical for survival and limb patterning during development. Reduced expression of SREBP-2 from the hypomorphic allele leads to early death in females and reduced cholesterol content in the liver, but not in adipose tissue.

Published

2016

30. High-resolution imaging of dietary lipids in cells and tissues by NanoSIMS analysis[S]

Author

Haibo Jiang, Chris N. Goulbourne, Angelica Tatar, Kirsten Turlo, Daniel Wu, Anne P. Beigneux, Chris R.M. Grovenor, Loren G. Fong, and Stephen G. Young

Subjects

nanoscale secondary ion mass spectrometry imaging, backscattered electron imaging, glycosylphosphatidylinositol-anchored HDL binding protein 1, chylomicrons, triglyceride-rich lipoproteins, Biochemistry, QD415-436

Abstract

Nanoscale secondary ion MS (NanoSIMS) imaging makes it possible to visualize stable isotope-labeled lipids in cells and tissues at 50 nm lateral resolution. Here we report the use of NanoSIMS imaging to visualize lipids in mouse cells and tissues. After administering stable isotope-labeled fatty acids to mice by gavage, NanoSIMS imaging allowed us to visualize neutral lipids in cytosolic lipid droplets in intestinal enterocytes, chylomicrons at the basolateral surface of enterocytes, and lipid droplets in cardiomyocytes and adipocytes. After an injection of stable isotope-enriched triglyceride-rich lipoproteins (TRLs), NanoSIMS imaging documented delivery of lipids to cytosolic lipid droplets in parenchymal cells. Using a combination of backscattered electron (BSE) and NanoSIMS imaging, it was possible to correlate the chemical data provided by NanoSIMS with high-resolution BSE images of cell morphology. This combined imaging approach allowed us to visualize stable isotope-enriched TRLs along the luminal face of heart capillaries and the lipids within heart capillary endothelial cells. We also observed examples of TRLs within the subendothelial spaces of heart capillaries. NanoSIMS imaging provided evidence of defective transport of lipids from the plasma LPs to adipocytes and cardiomyocytes in mice deficient in glycosylphosphatidylinositol-anchored HDL binding protein 1.

Published

2014

31. Evolution and Medical Significance of LU Domain−Containing Proteins

Author

Julie Maja Leth, Katrine Zinck Leth-Espensen, Kristian Kølby Kristensen, Anni Kumari, Anne-Marie Lund Winther, Stephen G. Young, and Michael Ploug

Subjects

uPAR, snake venom α-neurotoxins, GPIHBP1, plesiotypic disulfide bonds, protein evolution, Ly6/uPAR domains, protein module, protein domain, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Proteins containing Ly6/uPAR (LU) domains exhibit very diverse biological functions and have broad taxonomic distributions in eukaryotes. In general, they adopt a characteristic three-fingered folding topology with three long loops projecting from a disulfide-rich globular core. The majority of the members of this protein domain family contain only a single LU domain, which can be secreted, glycolipid anchored, or constitute the extracellular ligand binding domain of type-I membrane proteins. Nonetheless, a few proteins contain multiple LU domains, for example, the urokinase receptor uPAR, C4.4A, and Haldisin. In the current review, we will discuss evolutionary aspects of this protein domain family with special emphasis on variations in their consensus disulfide bond patterns. Furthermore, we will present selected cases where missense mutations in LU domain−containing proteins leads to dysfunctional proteins that are causally linked to genesis of human disease.

Published

2019

32. Assessing mechanisms of GPIHBP1 and lipoprotein lipase movement across endothelial cells[S]

Author

Brandon S.J. Davies, Chris N. Goulbourne, Richard H. Barnes, II, Kirsten A. Turlo, Peter Gin, Sue Vaughan, David J. Vaux, André Bensadoun, Anne P. Beigneux, Loren G. Fong, and Stephen G. Young

Subjects

transcytosis, triglycerides, caveolae, chylomicrons, lipid metabolism, Biochemistry, QD415-436

Abstract

Lipoprotein lipase (LPL) is secreted into the interstitial spaces by adipocytes and myocytes but then must be transported to the capillary lumen by GPIHBP1, a glycosylphosphatidylinositol-anchored protein of capillary endothelial cells. The mechanism by which GPIHBP1 and LPL move across endothelial cells remains unclear. We asked whether the transport of GPIHBP1 and LPL across endothelial cells was uni- or bidirectional. We also asked whether GPIHBP1 and LPL are transported across cells in vesicles and whether this transport process requires caveolin-1. The movement of GPIHBP1 and LPL across cultured endothelial cells was bidirectional. Also, GPIHBP1 moved bidirectionally across capillary endothelial cells in live mice. The transport of LPL across endothelial cells was inhibited by dynasore and genistein, consistent with a vesicular transport process. Also, transmission electron microscopy (EM) and dual-axis EM tomography revealed GPIHBP1 and LPL in invaginations of the plasma membrane and in vesicles. The movement of GPIHBP1 across capillary endothelial cells was efficient in the absence of caveolin-1, and there was no defect in the internalization of LPL by caveolin-1-deficient endothelial cells in culture. Our studies show that GPIHBP1 and LPL move bidirectionally across endothelial cells in vesicles and that transport is efficient even when caveolin-1 is absent.

Published

2012

33. Sphingosine-1-phosphate lyase expression in embryonic and adult murine tissues

Author

Alexander D. Borowsky, Padmavathi Bandhuvula, Ashok Kumar, Yuko Yoshinaga, Mikhail Nefedov, Loren G. Fong, Meng Zhang, Brian Baridon, Lisa Dillard, Pieter de Jong, Stephen G. Young, David B. West, and Julie D. Saba

Subjects

sphingosine phosphate lyase, colon cancer, development, sphingolipid, signal transduction, Biochemistry, QD415-436

Abstract

Sphingosine-1-phosphate (S1P) is a bioactive sphingolipid involved in immunity, inflammation, angiogenesis, and cancer. S1P lyase (SPL) is the essential enzyme responsible for S1P degradation. SPL augments apoptosis and is down-regulated in cancer. SPL generates a S1P chemical gradient that promotes lymphocyte trafficking and as such is being targeted to treat autoimmune diseases. Despite growing interest in SPL as a disease marker, antioncogene, and pharmacological target, no comprehensive characterization of SPL expression in mammalian tissues has been reported. We investigated SPL expression in developing and adult mouse tissues by generating and characterizing a β-galactosidase-SPL reporter mouse combined with immunohistochemistry, immunoblotting, and enzyme assays. SPL was expressed in thymic and splenic stromal cells, splenocytes, Peyer's Patches, colonic lymphoid aggregates, circulating T and B lymphocytes, granulocytes, and monocytes, with lowest expression in thymocytes. SPL was highly expressed within the CNS, including arachnoid lining cells, spinal cord, choroid plexus, trigeminal nerve ganglion, and specific neurons of the olfactory bulb, cerebral cortex, midbrain, hindbrain, and cerebellum. Expression was detected in brown adipose tissue, female gonads, adrenal cortex, bladder epithelium, Harderian and preputial glands, and hair follicles. This unique expression pattern suggests SPL has many undiscovered physiological functions apart from its role in immunity.

Published

2012

34. Inhibitors of protein geranylgeranyltransferase-I lead to prelamin A accumulation in cells by inhibiting ZMPSTE24

Author

Sandy Y. Chang, Sarah E. Hudon-Miller, Shao H. Yang, Hea-Jin Jung, John M. Lee, Emily Farber, Thangaiah Subramanian, Douglas A. Andres, H.Peter Spielmann, Christine A. Hrycyna, Stephen G. Young, and Loren G. Fong

Subjects

protein farnesyltransferase, protein geranylgeranyltransferase, nuclear lamins, lopinavir, prelamin A protease, Biochemistry, QD415-436

Abstract

Protein farnesyltransferase (FTase) inhibitors, generally called “FTIs,” block the farnesylation of prelamin A, inhibiting the biogenesis of mature lamin A and leading to an accumulation of prelamin A within cells. A recent report found that a GGTI, an inhibitor of protein geranylgeranyltransferase-I (GGTase-I), caused an exaggerated accumulation of prelamin A in the presence of low amounts of an FTI. This finding was interpreted as indicating that prelamin A can be alternately prenylated by GGTase-I and that inhibiting both protein prenyltransferases leads to more prelamin A accumulation than blocking FTase alone. Here, we tested an alternative hypothesis—GGTIs are not specific for GGTase-I, and they lead to prelamin A accumulation by inhibiting ZMPSTE24 (a zinc metalloprotease that converts farnesyl–prelamin A to mature lamin A). In our studies, commonly used GGTIs caused prelamin A accumulation in human fibroblasts, but the prelamin A in GGTI-treated cells exhibited a more rapid electrophoretic mobility than prelamin A from FTI-treated cells. The latter finding suggested that the prelamin A in GGTI-treated cells might be farnesylated (which would be consistent with the notion that GGTIs inhibit ZMPSTE24). Indeed, metabolic labeling studies revealed that the prelamin A in GGTI-treated fibroblasts is farnesylated. Moreover, biochemical assays of ZMPSTE24 activity showed that ZMPSTE24 is potently inhibited by a GGTI. Our studies show that GGTIs inhibit ZMPSTE24, leading to an accumulation of farnesyl–prelamin A. Thus, caution is required when interpreting the effects of GGTIs on prelamin A processing.

Published

2012

35. Severe hepatocellular disease in mice lacking one or both CaaX prenyltransferases[S]

Author

Shao H. Yang, Sandy Y. Chang, Yiping Tu, Gregory W. Lawson, Martin O. Bergo, Loren G. Fong, and Stephen G. Young

Subjects

protein farnesyltransferase, protein geranylgeranyltransferase, hyperbilirubinemia, hepatic steatosis, prelamin A, actin stress fibers, Biochemistry, QD415-436

Abstract

Protein farnesyltransferase (FTase) and protein geranylgeranyltransferase-I (GGTase-I) add 15- or 20-carbon lipids, respectively, to proteins that terminate with a CaaX motif. These posttranslational modifications of proteins with lipids promote protein interactions with membrane surfaces in cells, but the in vivo importance of the CaaX prenyltransferases and the protein lipidation reactions they catalyze remain incompletely defined. One study concluded that a deficiency of FTase was inconsequential in adult mice and led to little or no tissue pathology. To assess the physiologic importance of the CaaX prenyltransferases, we used conditional knockout alleles and an albumin–Cre transgene to produce mice lacking FTase, GGTase-I, or both enzymes in hepatocytes. The hepatocyte-specific FTase knockout mice survived but exhibited hepatocellular disease and elevated transaminases. Mice lacking GGTase-I not only had elevated transaminases but also had dilated bile cannaliculi, hyperbilirubinemia, hepatosplenomegaly, and reduced survival. Of note, GGTase-I–deficient hepatocytes had a rounded shape and markedly reduced numbers of actin stress fibers. Hepatocyte-specific FTase/GGTase-I double-knockout mice closely resembled mice lacking GGTase-I alone, but the disease was slightly more severe. Our studies refute the notion that FTase is dispensable and demonstrate that GGTase-I is crucial for the vitality of hepatocytes.

Published

2012

36. GPIHBP1, an endothelial cell transporter for lipoprotein lipase

Author

Stephen G. Young, Brandon S.J. Davies, Constance V. Voss, Peter Gin, Michael M. Weinstein, Peter Tontonoz, Karen Reue, André Bensadoun, Loren G. Fong, and Anne P. Beigneux

Subjects

chylomicrons, endothelial cells, lymphocyte antigen 6 proteins, hypertriglyceridemia, chylomicronemia, Biochemistry, QD415-436

Abstract

Interest in lipolysis and the metabolism of triglyceride-rich lipoproteins was recently reignited by the discovery of severe hypertriglyceridemia (chylomicronemia) in glycosylphosphatidylinositol-anchored high density lipoprotein–binding protein 1 (GPIHBP1)-deficient mice. GPIHBP1 is expressed exclusively in capillary endothelial cells and binds lipoprotein lipase (LPL) avidly. These findings prompted speculation that GPIHBP1 serves as a binding site for LPL in the capillary lumen, creating “a platform for lipolysis.” More recent studies have identified a second and more intriguing role for GPIHBP1—picking up LPL in the subendothelial spaces and transporting it across endothelial cells to the capillary lumen. Here, we review the studies that revealed that GPIHBP1 is the LPL transporter and discuss which amino acid sequences are required for GPIHBP1–LPL interactions. We also discuss the human genetics of LPL transport, focusing on cases of chylomicronemia caused by GPIHBP1 mutations that abolish GPIHBP1’s ability to bind LPL, and LPL mutations that prevent LPL binding to GPIHBP1.

Published

2011

37. Mutation of conserved cysteines in the Ly6 domain of GPIHBP1 in familial chylomicronemia

Author

Gunilla Olivecrona, Ewa Ehrenborg, Henrik Semb, Elena Makoveichuk, Anna Lindberg, Michael R. Hayden, Peter Gin, Brandon S.J. Davies, Michael M. Weinstein, Loren G. Fong, Anne P. Beigneux, Stephen G. Young, Thomas Olivecrona, and Olle Hernell

Subjects

compound heterozygote, lipoprotein lipase, milk lipids, mammary gland, glycosylphosphatidylinositol-anchored high density lipoprotein-binding protein 1, endothelial cells, Biochemistry, QD415-436

Abstract

We investigated a family from northern Sweden in which three of four siblings have congenital chylomicronemia. LPL activity and mass in pre- and postheparin plasma were low, and LPL release into plasma after heparin injection was delayed. LPL activity and mass in adipose tissue biopsies appeared normal. [35S]Methionine incorporation studies on adipose tissue showed that newly synthesized LPL was normal in size and normally glycosylated. Breast milk from the affected female subjects contained normal to elevated LPL mass and activity levels. The milk had a lower than normal milk lipid content, and the fatty acid composition was compatible with the milk lipids being derived from de novo lipogenesis, rather than from the plasma lipoproteins. Given the delayed release of LPL into the plasma after heparin, we suspected that the chylomicronemia might be caused by mutations in GPIHBP1. Indeed, all three affected siblings were compound heterozygotes for missense mutations involving highly conserved cysteines in the Ly6 domain of GPIHBP1 (C65S and C68G). The mutant GPIHBP1 proteins reached the surface of transfected Chinese hamster ovary cells but were defective in their ability to bind LPL (as judged by both cell-based and cell-free LPL binding assays). Thus, the conserved cysteines in the Ly6 domain are crucial for GPIHBP1 function.

Published

2010

38. Assessing the efficacy of protein farnesyltransferase inhibitors in mouse models of progeria

Author

Shao H. Yang, Sandy Y. Chang, Douglas A. Andres, H. Peter Spielmann, Stephen G. Young, and Loren G. Fong

Subjects

protein prenylation, farnesylation, posttranslational modifications, lamin A, aging, protein farnesyltransferase, Biochemistry, QD415-436

Abstract

Hutchinson-Gilford progeria syndrome (HGPS) is caused by the accumulation of a farnesylated form of prelamin A (progerin). Previously, we showed that blocking protein farnesylation with a farnesyltransferase inhibitor (FTI) ameliorates the disease phenotypes in mouse model of HGPS (LmnaHG/+). However, the interpretation of the FTI treatment studies is open to question in light of recent studies showing that mice expressing a nonfarnesylated version of progerin (LmnanHG/+) develop progeria-like disease phenotypes. The fact that LmnanHG/+ mice manifest disease raised the possibility that the beneficial effects of an FTI in LmnaHG/+ mice were not due to the effects of the drug on the farnesylation of progerin, but may have been due to unanticipated secondary effects of the drug on other farnesylated proteins. To address this issue, we compared the ability of an FTI to improve progeria-like disease phenotypes in both LmnaHG/+ and LmnanHG/+ mice. In LmnaHG/+ mice, the FTI reduced disease phenotypes in a highly significant manner, but the drug had no effect in LmnanHG/+ mice. The failure of the FTI to ameliorate disease in LmnanHG/+ mice supports the idea that the beneficial effects of an FTI in LmnaHG/+ mice are due to the effect of drug on the farnesylation of progerin.

Published

2010

39. Increasing the length of progerin's isoprenyl anchor does not worsen bone disease or survival in mice with Hutchinson-Gilford progeria syndrome

Author

Brandon S.J. Davies, Shao H. Yang, Emily Farber, Roger Lee, Suzanne B. Buck, Douglas A. Andres, H. Peter Spielmann, Brian J. Agnew, Fuyuhiko Tamanoi, Loren G. Fong, and Stephen G. Young

Subjects

protein prenylation, progeria, farnesylation, geranylgeranylation, posttranslational modifications, lamin A, Biochemistry, QD415-436

Abstract

Hutchinson-Gilford progeria syndrome (HGPS) is caused by the synthesis of a truncated prelamin A, commonly called progerin, that contains a carboxyl-terminal farnesyl lipid anchor. The farnesyl lipid anchor helps to target progerin to membrane surfaces at the nuclear rim, where it disrupts the integrity of the nuclear lamina and causes misshapen nuclei. Several lines of evidence have suggested that progerin's farnesyl lipid anchor is crucial for the emergence of disease phenotypes. Because a geranylgeranyl lipid is ∼45-fold more potent than a farnesyl lipid in anchoring proteins to lipid membranes, we hypothesized that a geranylgeranylated version of progerin might be more potent in eliciting disease phenotypes. To test this hypothesis, we used gene targeting to create mice expressing geranylgeranylated progerin (LmnaggHG/+). We then compared LmnaggHG/+ mice, side-by-side, with otherwise identical mice expressing farnesylated progerin (LmnaHG/+). Geranylgeranylation of progerin in LmnaggHG/+ cells and farnesylation of progerin in LmnaHG/+ cells was confirmed by metabolic labeling. Contrary to our expectations, LmnaggHG/+ mice survived longer than LmnaHG/+ mice. The LmnaggHG/+ mice also exhibited milder bone disease. The steady-state levels of progerin, relative to lamin C, were lower in LmnaggHG/+ mice than in LmnaHG/+ mice, providing a potential explanation for the milder disease in LmnaggHG/+ mice.

Published

2009

40. Blocking VLDL secretion causes hepatic steatosis but does not affect peripheral lipid stores or insulin sensitivity in mice

Author

Kaori Minehira, Stephen G. Young, Claudio J. Villanueva, Laxman Yetukuri, Matej Oresic, Mark K. Hellerstein, Robert V. Farese, Jr., Jay D. Horton, Frederic Preitner, Bernard Thorens, and Luc Tappy

Subjects

microsomal triglyceride transfer protein, triglyceride-rich lipoprotein, fatty liver, insulin resistance, obesity, de novo lipogenesis, Biochemistry, QD415-436

Abstract

The liver secretes triglyceride-rich VLDLs, and the triglycerides in these particles are taken up by peripheral tissues, mainly heart, skeletal muscle, and adipose tissue. Blocking hepatic VLDL secretion interferes with the delivery of liver-derived triglycerides to peripheral tissues and results in an accumulation of triglycerides in the liver. However, it is unclear how interfering with hepatic triglyceride secretion affects adiposity, muscle triglyceride stores, and insulin sensitivity. To explore these issues, we examined mice that cannot secrete VLDL [due to the absence of microsomal triglyceride transfer protein (Mttp) in the liver]. These mice exhibit markedly reduced levels of apolipoprotein B-100 in the plasma, along with reduced levels of triglycerides in the plasma. Despite the low plasma triglyceride levels, triglyceride levels in skeletal muscle were unaffected. Adiposity and adipose tissue triglyceride synthesis rates were also normal, and body weight curves were unaffected. Even though the blockade of VLDL secretion caused hepatic steatosis accompanied by increased ceramides and diacylglycerols in the liver, the mice exhibited normal glucose tolerance and were sensitive to insulin at the whole-body level, as judged by hyperinsulinemic euglycemic clamp studies. Normal hepatic glucose production and insulin signaling were also maintained in the fatty liver induced by Mttp deletion. Thus, blocking VLDL secretion causes hepatic steatosis without insulin resistance, and there is little effect on muscle triglyceride stores or adiposity.

Published

2008

41. Errata. PCSK9 function and physiology1

Author

Andrew S. Peterson, Loren G. Fong, and Stephen G. Young

Subjects

Biochemistry, QD415-436

Abstract

PCSK9 has exploded onto center stage of plasma cholesterol metabolism, raising hopes for a new strategy to treat hypercholesterolemia. PCSK9 in a plasma protein that triggers increased degradation of the LDL receptor. Gain-of-function mutations in PCSK9 reduce LDL receptor levels in the liver, resulting in high levels of LDL cholesterol in the plasma and increased susceptibility to coronary heart disease. Loss-of-function mutations lead to higher levels of the LDL receptor, lower LDL cholesterol levels, and protection from coronary heart disease. Two papers in this issue of the Journal of Lipid Research exemplify the rapid pace of progress in understanding PCSK9 molecular interactions and physiology. Dr. Shilpa Pandit and coworkers from Merck Research Laboratories describe the functional basis for the hypercholesterolemia associated with gain-of-function missense mutations in PCSK9. Dr. Jay Horton's group at UT Southwestern describe the kinetics and metabolism of PCSK9 and the impact of PCSK9 on LDL receptors in the liver and adrenal gland.

Published

2008

42. PCSK9 function and physiology*1

Author

Andrew S. Peterson, Loren G. Fong, and Stephen G. Young

Subjects

Biochemistry, QD415-436

Published

2008

43. Glycosylation of Asn-76 in mouse GPIHBP1 is critical for its appearance on the cell surface and the binding of chylomicrons and lipoprotein lipase

Author

Anne P. Beigneux, Peter Gin, Brandon S.J. Davies, Michael M. Weinstein, André Bensadoun, Robert O. Ryan, Loren G. Fong, and Stephen G. Young

Subjects

glycosylphosphatidylinositol-anchored HDL binding protein 1, knockout mice, chylomicronemia, hypertriglyceridemia, Biochemistry, QD415-436

Abstract

GPIHBP1 is a glycosylphosphatidylinositol-anchored protein in the lymphocyte antigen 6 (Ly-6) family that recently was identified as a platform for the lipolytic processing of triglyceride-rich lipoproteins. GPIHBP1 binds both LPL and chylomicrons and is expressed on the luminal face of microvascular endothelial cells. Here, we show that mouse GPIHBP1 is N-glycosylated at Asn-76 within the Ly-6 domain. Human GPIHBP1 is also glycosylated. The N-linked glycan could be released from mouse GPIHBP1 with N-glycosidase F, endoglycosidase H, or endoglycosidase F1. The glycan was marginally sensitive to endoglycosidase F2 digestion but resistant to endoglycosidase F3 digestion, suggesting that the glycan on GPIHBP1 is of the oligomannose type. Mutating the N-glycosylation site in mouse GPIHBP1 results in an accumulation of GPIHBP1 in the endoplasmic reticulum and a markedly reduced amount of the protein on the cell surface. Consistent with this finding, cells expressing a nonglycosylated GPIHBP1 lack the ability to bind LPL or chylomicrons. Eliminating the N-glycosylation site in a truncated soluble version of GPIHBP1 causes a modest reduction in the secretion of the protein. These studies demonstrate that N-glycosylation of GPIHBP1 is important for the trafficking of GPIHBP1 to the cell surface.

Published

2008

44. Absence of VLDL secretion does not affect α-tocopherol content in peripheral tissues

Author

Kaori Minehira-Castelli, Scott W. Leonard, Quinn M. Walker, Maret G. Traber, and Stephen G. Young

Subjects

γ-tocopherol, microsomal triglyceride transfer protein, vitamin E, Biochemistry, QD415-436

Abstract

α-Tocopherol is a lipid-soluble antioxidant that helps to prevent oxidative damage to cellular lipids. α-Tocopherol is absorbed by the intestine and is taken up and retained by the liver; it is widely presumed that α-tocopherol is then delivered to peripheral tissues by the secretion of VLDL. To determine whether VLDL secretion is truly important for the delivery of α-tocopherol to peripheral tissues, we examined α-tocopherol metabolism in mice that lack microsomal triglyceride transfer protein (Mttp) expression in the liver and therefore cannot secrete VLDL (MttpΔ/Δ mice). MttpΔ/Δ mice have low plasma lipid levels and increased stores of lipids in the liver. Similarly, α-tocopherol levels in the plasma were lower in MttpΔ/Δ mice than in controls, whereas hepatic α-tocopherol stores were higher. However, α-tocopherol levels in the peripheral tissues of MttpΔ/Δ mice were nearly identical to those of control mice, suggesting that VLDL secretion is not critical for the delivery of α-tocopherol to peripheral tissues. When fed a diet containing deuterated α-tocopherol, MttpΔ/Δ and control mice had similar incorporation of deuterated α-tocopherol into plasma and various peripheral tissues. We conclude that the absence of VLDL secretion has little effect on the stores of α-tocopherol in peripheral tissues, at least in the mouse.

Published

2006

45. Agpat6 deficiency causes subdermal lipodystrophy and resistance to obesity

Author

Laurent Vergnes, Anne P. Beigneux, Ryan Davis, Steven M. Watkins, Stephen G. Young, and Karen Reue

Subjects

acyltransferase, gene-trap, adipose tissue, energy expenditure, 1-acylglycerol-3-phosphate O-acyltransferase, Biochemistry, QD415-436

Abstract

Triglyceride synthesis in most mammalian tissues involves the sequential addition of fatty acids to a glycerol backbone, with unique enzymes required to catalyze each acylation step. Acylation at the sn-2 position requires 1-acylglycerol-3-phosphate O-acyltransferase (AGPAT) activity. To date, seven Agpat genes have been identified based on activity and/or sequence similarity, but their physiological functions have not been well established. We have generated a mouse model deficient in AGPAT6, which is normally expressed at high levels in brown adipose tissue (BAT), white adipose tissue (WAT), and liver. Agpat6-deficient mice exhibit a 25% reduction in body weight and resistance to both diet-induced and genetically induced obesity. The reduced body weight is associated with increased energy expenditure, reduced triglyceride accumulation in BAT and WAT, reduced white adipocyte size, and lack of adipose tissue in the subdermal region. In addition, the fatty acid composition of triacylglycerol, diacylglycerol, and phospholipid is altered, with proportionally greater polyunsaturated fatty acids at the expense of monounsaturated fatty acids. Thus, Agpat6 plays a unique role in determining triglyceride content and composition in adipose tissue and liver that cannot be compensated by other members of the Agpat family.

Published

2006

46. Agpat6—a novel lipid biosynthetic gene required for triacylglycerol production in mammary epithelium

Author

Anne P. Beigneux, Laurent Vergnes, Xin Qiao, Steven Quatela, Ryan Davis, Steven M. Watkins, Rosalind A. Coleman, Rosemary L. Walzem, Mark Philips, Karen Reue, and Stephen G. Young

Subjects

acyltransferase, transacylase, milk fat, Biochemistry, QD415-436

Abstract

In analyzing the sequence tags for mutant mouse embryonic stem (ES) cell lines in BayGenomics (a mouse gene-trapping resource), we identified a novel gene, 1-acylglycerol-3-phosphate O-acyltransferase (Agpat6), with sequence similarities to previously characterized glycerolipid acyltransferases. Agpat6’s closest family member is another novel gene that we have provisionally designated Agpat8. Both Agpat6 and Agpat8 are conserved from plants, nematodes, and flies to mammals. AGPAT6, which is predicted to contain multiple membrane-spanning helices, is found exclusively within the endoplasmic reticulum (ER) in mammalian cells. To gain insights into the in vivo importance of Agpat6, we used the Agpat6 ES cell line from BayGenomics to create Agpat6-deficient (Agpat6−/−) mice. Agpat6−/− mice lacked full-length Agpat6 transcripts, as judged by northern blots. One of the most striking phenotypes of Agpat6−/− mice was a defect in lactation. Pups nursed by Agpat6−/− mothers die perinatally. Normally, Agpat6 is expressed at high levels in the mammary epithelium of breast tissue, but not in the surrounding adipose tissue. Histological studies revealed that the aveoli and ducts of Agpat6−/− lactating mammary glands were underdeveloped, and there was a dramatic decrease in the size and number of lipid droplets within mammary epithelial cells and ducts. Also, the milk from Agpat6−/− mice was markedly depleted in diacylglycerols and triacylglycerols. Thus, we identified a novel glycerolipid acyltransferase of the ER, AGPAT6, which is crucial for the production of milk fat by the mammary gland.

Published

2006

47. Thematic Review Series: Lipid Posttranslational Modifications. Prelamin A, Zmpste24, misshapen cell nuclei, and progeria—new evidence suggesting that protein farnesylation could be important for disease pathogenesis

Author

Stephen G. Young, Loren G. Fong, and Susan Michaelis

Subjects

protein prenylation, laminopathy, aging, Ste24, a-factor, lamin A/C, Biochemistry, QD415-436

Abstract

Prelamin A undergoes multistep processing to yield lamin A, a structural protein of the nuclear lamina. Prelamin A terminates with a CAAX motif, which triggers farnesylation of a C-terminal cysteine (the C of the CAAX motif), endoproteolytic release of the last three amino acids (the AAX), and methylation of the newly exposed farnesylcysteine residue. In addition, prelamin A is cleaved a second time, releasing 15 more residues from the C terminus (including the farnesylcysteine methyl ester), generating mature lamin A. This second cleavage step is carried out by an endoplasmic reticulum membrane protease, ZMPSTE24. Interest in the posttranslational processing of prelamin A has increased with the recognition that certain progeroid syndromes can be caused by mutations that lead to an accumulation of farnesyl-prelamin A. Recently, we showed that a key cellular phenotype of these progeroid disorders, misshapen cell nuclei, can be ameliorated by inhibitors of protein farnesylation, suggesting a potential strategy for treating these diseases.In this article, we review the posttranslational processing of prelamin A, describe several mouse models for progeroid syndromes, explain the mutations underlying several human progeroid syndromes, and summarize recent data showing that misshapen nuclei can be ameliorated by treating cells with protein farnesyltransferase inhibitors.

Published

2005

48. High-level lipoprotein [a] expression in transgenic mice: evidence for oxidized phospholipids in lipoprotein [a] but not in low density lipoproteins

Author

Matthias Schneider, Joseph L. Witztum, Stephen G. Young, Erwin H. Ludwig, Elizabeth R. Miller, Sotirios Tsimikas, Linda K. Curtiss, Santica M. Marcovina, John M. Taylor, Richard M. Lawn, Thomas L. Innerarity, and Robert E. Pitas

Subjects

atherosclerosis, oxidized low density lipoprotein, apolipoprotein [a], cardiovascular, apolipoprotein B-100, Biochemistry, QD415-436

Abstract

Efforts to elucidate the role of lipoprotein [a] (Lp[a]) in atherogenesis have been hampered by the lack of an animal model with high plasma Lp[a] levels. We produced two lines of transgenic mice expressing apolipoprotein [a] (apo[a]) in the liver and crossed them with mice expressing human apolipoprotein B-100 (apoB-100), generating two lines of Lp[a] mice. One had Lp[a] levels of ∼700 mg/dl, well above the 30 mg/dl threshold associated with increased risk of atherosclerosis in humans; the other had levels of ∼35 mg/dl. Most of the LDL in mice with high-level apo[a] expression was covalently bound to apo[a], but most of the LDL in the low-expressing line was free. Using an enzyme-linked sandwich assay with monoclonal antibody EO6, we found high levels of oxidized phospholipids in Lp[a] from high-expressing mice but not in LDL from low-expressing mice or in LDL from human apoB-100 transgenic mice (P < 0.00001), even though all mice had similar plasma levels of human apoB-100.The increase in oxidized lipids specific to Lp[a] in high-level apo[a]-expressing mice suggests a mechanism by which increased circulating levels of Lp[a] could contribute to atherogenesis.

Published

2005

49. Blocking microsomal triglyceride transfer protein interferes with apoB secretion without causing retention or stress in the ER

Author

Wei Liao, To Y. Hui, Stephen G. Young, and Roger A. Davis

Subjects

apolipoprotein B, endoplasmic reticulum, hyperlipidemia, liver, inflammation, unfolded protein response, Biochemistry, QD415-436

Abstract

Microsomal triglyceride transfer protein (MTP) is an intraluminal protein in the endoplasmic reticulum (ER) that is essential for the assembly of apolipoprotein B (apoB)-containing lipoproteins. In this study, we examine how the livers of mice respond to two distinct methods of blocking MTP function: Cre-mediated disruption of the gene for MTP and chemical inhibition of MTP activity. Blocking MTP significantly reduced plasma levels of triglycerides, cholesterol, and apoB-containing lipoproteins in both wild-type C57BL/6 and LDL receptor-deficient mice. While treating LDL receptor-deficient mice with an MTP inhibitor for 7 days lowered plasma lipids to control levels, liver triglyceride levels were increased by only 4-fold. Plasma levels of apoB-100 and apoB-48 fell by >90% and 65%, respectively, but neither apoB isoform accumulated in hepatic microsomes. Surprisingly, loss of MTP expression was associated with a nearly complete absence of apoB-100 in hepatic microsomes. Levels of microsomal luminal chaperone proteins [e.g., protein disulfide isomerase, glucose-regulated protein 78 (GRP78), and GRP94] and cytosolic heat shock proteins (HSPs) (e.g., HSP60, HSC, HSP70, and HSP90) were unaffected by MTP inhibition. These findings show that the liver responds rapidly to inhibition of MTP by degrading apoB and preventing its accumulation in the ER.The rapid degradation of secretion-incompetent apoB in the ER may block the induction of proteins associated with unfolded protein and heat shock responses.

Published

2003

50. Immunochemical evidence that human apoB differs when expressed in rodent versus human cells

Author

Xingyu Wang, Vinita Chauhan, Anh T. Nguyen, Joshua Schultz, Jean Davignon, Stephen G. Young, Jan Borén, Thomas L. Innerarity, Hui Rutai, and Ross W. Milne

Subjects

low density lipoproteins, apolipoprotein B, hybridoma, polymorphism, Biochemistry, QD415-436

Abstract

LDL from human apolipoprotein B-100 (apoB-100) transgenic (HuBTg+/+) mice contains more triglyceride than LDL from normolipidemic subjects. To obtain novel monoclonal antibody (MAb) probes of apoB conformation, we generated hybridomas from HuBTg+/+ that had been immunized with LDL isolated from human plasma. One apoE-specific and four anti-apoB-100-specific hybridomas were identified. Two MAbs, 2E1 and 3D11, recognized an epitope in the amino-terminal 689 residues of apoB in native apoB-containing lipoproteins (LpBs) from human plasma or from the supernatant of human hepatoma HepG2 cells, but did not react with LpB from HuBTg+/+ mice or LpB secreted by human apoB-100-transfected rat McArdle 7777 hepatoma cells. 2E1 reacted weakly and 3D11 reacted strongly with apoB from HuBTg+/+ mice after SDS-PAGE. The lack of expression of the 2E1 and 3D11 epitopes on native LpB from HuBTg+/+ mice did not solely reflect the abnormal lipid composition of murine LpB. Both epitopes were detected in all human plasma samples tested and in all human plasma LpB classes.Therefore, human apoB expressed by rodent hepatocytes or hepatoma cells appears to adopt a different conformation or undergoes different posttranslational modification than apoB expressed in human hepatocytes or hepatoma cells.

Published

2003