Adam B. Francisco

Deficiency of Suppressor Enhancer Lin12 1 Like (SEL1L) in Mice Leads to Systemic Endoplasmic Reticulum Stress and Embryonic Lethality

Stress in the endoplasmic reticulum (ER) plays an important causal role in the pathogenesis of several chronic diseases such as Alzheimer, Parkinson, and diabetes mellitus. Insight into the genetic determinants responsible for ER homeostasis will greatly facilitate the development of therapeutic strategies for the treatment of these debilitating diseases. Suppressor enhancer Lin12 1 like (SEL1L) is an ER membrane protein and was thought to be involved in the quality control of secreted proteins. Here we show that the mice homozygous mutant for SEL1L were embryonic lethal. Electron microscopy studies revealed a severely dilated ER in the fetal liver of mutant embryos, indicative of alteration in ER homeostasis. Consistent with this, several ER stress responsive genes were significantly up-regulated in the mutant embryos. Mouse embryonic fibroblast cells deficient in SEL1L exhibited activated unfolded protein response at the basal state, impaired ER-associated protein degradation, and reduced protein secretion. Furthermore, markedly increased apoptosis was observed in the forebrain and dorsal root ganglions of mutant embryos. Taken together, our results demonstrate an essential role for SEL1L in protein quality control during mouse embryonic development.

Sel1L is indispensable for mammalian endoplasmic reticulum-associated degradation, endoplasmic reticulum homeostasis, and survival

Significance This study provides insights into the physiological role of Sel1L, an adaptor protein for the ubiquitin ligase Hrd1 in endoplasmic reticulum-associated degradation (ERAD). Using both animal and cell models, this study provides unequivocal evidence for an indispensable role of Sel1L in Hrd1 stabilization, mammalian ERAD, endoplasmic reticulum homeostasis, protein translation, and cellular and organismal survival. Moreover, generation of inducible knockout mouse and cell models deficient in both Sel1L and Hrd1 provides an unprecedented opportunity to elucidate the functional importance of this key branch of ERAD in vivo and to identify its physiological substrates. Suppressor/Enhancer of Lin-12-like (Sel1L) is an adaptor protein for the E3 ligase hydroxymethylglutaryl reductase degradation protein 1 (Hrd1) involved in endoplasmic reticulum-associated degradation (ERAD). Sel1L’s physiological importance in mammalian ERAD, however, remains to be established. Here, using the inducible Sel1L knockout mouse and cell models, we show that Sel1L is indispensable for Hrd1 stability, ER homeostasis, and survival. Acute loss of Sel1L leads to premature death in adult mice within 3 wk with profound pancreatic atrophy. Contrary to current belief, our data show that mammalian Sel1L is required for Hrd1 stability and ERAD function both in vitro and in vivo. Sel1L deficiency disturbs ER homeostasis, activates ER stress, attenuates translation, and promotes cell death. Serendipitously, using a biochemical approach coupled with mass spectrometry, we found that Sel1L deficiency causes the aggregation of both small and large ribosomal subunits. Thus, Sel1L is an indispensable component of the mammalian Hrd1 ERAD complex and ER homeostasis, which is essential for protein translation, pancreatic function, and cellular and organismal survival.

The ER-Associated Degradation Adaptor Protein Sel1L Regulates LPL Secretion and Lipid Metabolism

Sel1L is an essential adaptor protein for the E3 ligase Hrd1 in the endoplasmic reticulum (ER)-associated degradation (ERAD), a universal quality-control system in the cell; but its physiological role remains unclear. Here we show that mice with adipocyte-specific Sel1L deficiency are resistant to diet-induced obesity and exhibit postprandial hypertriglyceridemia. Further analyses reveal that Sel1L is indispensable for the secretion of lipoprotein lipase (LPL), independent of its role in Hrd1-mediated ERAD and ER homeostasis. Sel1L physically interacts with and stabilizes the LPL maturation complex consisting of LPL and lipase maturation factor 1 (LMF1). In the absence of Sel1L, LPL is retained in the ER and forms protein aggregates, which are degraded primarily by autophagy. The Sel1L-mediated control of LPL secretion is also seen in other LPL-expressing cell types including cardiac myocytes and macrophages. Thus, our study reports a role of Sel1L in LPL secretion and systemic lipid metabolism.

SEL1L deficiency impairs growth and differentiation of pancreatic epithelial cells

BackgroundThe vertebrate pancreas contains islet, acinar and ductal cells. These cells derive from a transient pool of multipotent pancreatic progenitors during embryonic development. Insight into the genetic determinants regulating pancreatic organogenesis will help the development of cell-based therapies for the treatment of diabetes mellitus. Suppressor enhancer lin12/Notch 1 like (Sel1l) encodes a cytoplasmic protein that is highly expressed in the developing mouse pancreas. However, the morphological and molecular events regulated by Sel1l remain elusive.ResultsWe have characterized the pancreatic phenotype of mice carrying a gene trap mutation in Sel1l. We show that Sel1l expression in the developing pancreas coincides with differentiation of the endocrine and exocrine lineages. Mice homozygous for the gene trap mutation die prenatally and display an impaired pancreatic epithelial morphology and cell differentiation. The pancreatic epithelial cells of Sel1l mutant embryos are confined to the progenitor cell state throughout the secondary transition. Pharmacological inhibition of Notch signaling partially rescues the pancreatic phenotype of Sel1l mutant embryos.ConclusionsTogether, these data suggest that Sel1l is essential for the growth and differentiation of endoderm-derived pancreatic epithelial cells during mouse embryonic development.

Haploid Insufficiency of Suppressor Enhancer Lin12 1-like (SEL1L) Protein Predisposes Mice to High Fat Diet-induced Hyperglycemia

Increasing evidence suggests that endoplasmic reticulum (ER) stress plays an important role in the pathogenesis of type 2 diabetes mellitus. SEL1L is an ER membrane protein that is highly expressed in the pancreatic islet and acinar cells. We have recently reported that a deficiency of SEL1L causes systemic ER stress and leads to embryonic lethality in mice. Here we show that mice with one functional allele of Sel1l (Sel1l+/−) are more susceptible to high fat diet (HFD)-induced hyperglycemia. Sel1l+/− mice have a markedly reduced β-cell mass as a result of decreased β-cell proliferation. Consequently, Sel1l+/− mice are severely glucose-intolerant and exhibit significantly retarded glucose-stimulated insulin secretion. Pancreatic islets from Sel1l+/− mice stimulated with a high concentration of glucose in vitro express significantly higher levels of unfolded protein response genes than those from wild-type control mice. Furthermore, dominant-negative interference of SEL1L function in insulinoma cell lines severely impairs, whereas overexpression of SEL1L efficiently improves protein secretion. Taken together, our results indicate that haploid insufficiency of SEL1L predispose mice to high fat diet-induced hyperglycemia. Our findings highlight a critical and previously unknown function for SEL1L in regulating adult β-cell function and growth.

The full-length isoform of the mouse pleckstrin homology domain-interacting protein (PHIP) is required for postnatal growth.

PHIP was isolated as an insulin receptor substrate 1 (IRS‐1) interacting protein. To date, the physiological roles of PHIP remain unknown. Here we show that mice lacking PHIP1, the full‐length isoform of PHIP, are born at normal size but suffer a 40% growth deficit by weaning. PHIP1 mutant mice develop hypoglycemia and have an average lifespan of 4–5 weeks. PHIP1‐deficient mouse embryonic fibroblasts (MEFs) grow markedly slower than wild‐type MEFs, but exhibit normal AKT phosphorylation and an increased cell proliferation in response to IGF‐1 treatment. Together these results suggest that PHIP1 regulates postnatal growth in an IGF‐1/AKT pathway‐independent manner.

MTCH2 is a conserved regulator of lipid homeostasis.

More than one‐third of U.S. adults have obesity, causing an alarming increase in obesity‐related comorbidities such as type 2 diabetes. The functional role of mitochondrial carrier homolog 2 (MTCH2), a human obesity‐associated gene, in lipid homeostasis was investigated in Caenorhabditis elegans, cell culture, and mice.