Subcellular Localization and Partial Purification of Prelamin a Endoprotease: An Enzyme Which Catalyzes the Conversion of Farnesylated Prelamin a to Mature Lamin A

Kilic, Fusun, Johnson, D A., Sinensky, M.

30 April 1999

The nuclear lamina protein, lamin A is produced by proteolytic cleavage of a 74 kDa precursor protein, prelamin A. The conversion of this precursor to mature lamin A is mediated by a specific endoprotease, prelamin A endoprotease. Subnuclear fractionation indicates that the prelamin A endoprotease is localized at the nuclear membrane. The enzyme appears to be an integral membrane protein, as it can only be removed from the nuclear envelope with detergent. It is effectively solubilized by the detergent n-octyl-beta-D-glucopyranoside and can be partially-purified (approximately 1200-fold) by size exclusion and cation exchange (Mono S) chromatography. Prelamin A endoprotease from HeLa cells was eluted from Mono S with 0.3 M sodium chloride as a single peak of activity. SDS-PAGE analysis of this prelamin A endoprotease preparation shows that it contains one major polypeptide at 65 kDa and smaller amounts of a second 68 kDa polypeptide. Inhibition of the enzyme activity in this preparation by specific serine protease inhibitors is consistent with the enzyme being a serine protease.

acrylic resins

detergents

electrophoresis

polyacrylamide gel

glucosides (metabolism)

hela cells (enzymology)

humans

lamin type a

lamins

nuclear proteins (metabolism)

protein precursors (metabolism)

protein prenylation

subcellular fractions (enzymology)

Biological Sciences

mTOR regulates Aurora A via enhancing protein stability

Fan, Li

11 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Mammalian target of rapamycin (mTOR) is a key regulator of protein synthesis. Dysregulation of mTOR signaling occurs in many human cancers and its inhibition causes arrest at the G1 cell cycle stage. However, mTOR’s impact on mitosis (M-phase) is less clear. Here, suppressing mTOR activity impacted the G2-M transition and reduced levels of M-phase kinase, Aurora A. mTOR inhibitors did not affect Aurora A mRNA levels. However, translational reporter constructs showed that mRNA containing a short, simple 5’-untranslated region (UTR), rather than a complex structure, is more responsive to mTOR inhibition. mTOR inhibitors decreased Aurora A protein amount whereas blocking proteasomal degradation rescues this phenomenon, revealing that mTOR affects Aurora A protein stability. Inhibition of protein phosphatase, PP2A, a known mTOR substrate and Aurora A partner, restored mTOR-mediated Aurora A abundance. Finally, a non-phosphorylatable Aurora A mutant was more sensitive to destruction in the presence of mTOR inhibitor. These data strongly support the notion that mTOR controls Aurora A destruction by inactivating PP2A and elevating the phosphorylation level of Ser51 in the “activation-box” of Aurora A, which dictates its sensitivity to proteasomal degradation. In summary, this study is the first to demonstrate that mTOR signaling regulates Aurora-A protein expression and stability and provides a better understanding of how mTOR regulates mitotic kinase expression and coordinates cell cycle progression. The involvement of mTOR signaling in the regulation of cell migration by its upstream activator, Rheb, was also examined. Knockdown of Rheb was found to promote F-actin reorganization and was associated with Rac1 activation and increased migration of glioma cells. Suppression of Rheb promoted platelet-derived growth factor receptor (PDGFR) expression. Pharmacological inhibition of PDGFR blocked these events. Therefore, Rheb appears to suppress tumor cell migration by inhibiting expression of growth factor receptors that in turn drive Rac1-mediate actin polymerization.

mTOR, Aurora A, protein stability

Proteins -- Stability

Proteins -- Conformation

Proteins -- Research -- Methodology

Cell cycle -- Regulation

Mitosis -- Regulation

Serine proteinases -- Inhibitors

Rho GTPases

Neuroglia

Enzymes -- Regulation

G proteins

Cell division

Proteins -- Metabolism -- Regulation

Proteins -- Synthesis

Rapamycin

Transcription factors -- Research

Cellular signal transduction

Messenger RNA -- Research

Understanding the biological function of phosphatases of regenerating liver, from biochemistry to physiology

Bai, Yunpeng

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Phosphatases of regenerating liver, consisting of PRL-1, PRL-2 and PRL-3, belong to a novel protein tyrosine phosphatases subfamily, whose overexpression promotes cell proliferation, migration and invasion and contributes to tumorigenesis and metastasis. However, although great efforts have been made to uncover the biological function of PRLs, limited knowledge is available on the underlying mechanism of PRLs’ actions, therapeutic value by targeting PRLs, as well as the physiological function of PRLs in vivo. To answer these questions, we first screened a phage display library and identified p115 RhoGAP as a novel PRL-1 binding partner. Mechanistically, we demonstrated that PRL-1 activates RhoA and ERK1/2 by decreasing the association between active RhoA with GAP domain of p115 RhoGAP, and displacing MEKK1 from the SH3 domain of p115 RhoGAP, respectively, leading to enhanced cell proliferation and migration. Secondly, structure-based virtual screening was employed to discover small molecule inhibitors blocking PRL-1 trimer formation which has been suggested to play an important role for PRL-1 mediated oncogenesis. We identified Cmpd-43 as a novel PRL-1 trimer disruptor. Structural study demonstrated the binding mode of PRL-1 with the trimer disruptor. Most importantly, cellular data revealed that Cmpd-43 inhibited PRL-1 induced cell proliferation and migration in breast cancer cell line MDA-MB-231 and lung cancer cell line H1299. Finally, in order to investigate the physiological function of PRLs, we generated mouse knockout models for Prl-1, Prl-2 and Prl-3. Although mice deficient for Prl-1 and Prl-3 were normally developed, Prl-2-null mice displayed growth retardation, impaired male reproductive ability and insufficient hematopoiesis. To further investigate the in vivo function of Prl-1, we generated Prl-1-/-/Prl-2+/- and Prl-1+/-/Prl-2-/- mice. Similar to Prl-2 deficient male mice, Prl-1-/-/Prl-2+/- males also have impaired spermatogenesis and reproductivity. More strikingly, Prl-1+/-/Prl-2-/- mice are completely infertile, suggesting that, in addition to PRL-2, PRL-1 also plays an important role in maintaining normal testis function. In summary, these studies demonstrated for the first time that PRL-1 activates ERK1/2 and RhoA through the novel interaction with p115 RhoGAP, targeting PRL-1 trimer interface is a novel anti-cancer therapeutic treatment and both PRL-1 and PRL-2 contribute to spermatogenesis and male mice reproductivity.

PRL-1

PRL-2

PRL-3

p115 RhoGAP

spermatogenesis

trimerization

Cell proliferation -- Research

Metastasis -- Research

Spermatogenesis -- Genetic aspects

Spermatogenesis in animals -- Regulation

Tumors -- Genetic aspects

Tumors -- Treatment

Oncogenes

Transcription factors

Cell migration

Proteins -- Synthesis

Molecular biology -- Technique

Liver -- Regeneration

Mice as laboratory animals

Proteins -- Metabolism

Lafora Disease: Mechanisms Involved in Pathogenesis

Garyali, Punitee

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Lafora disease is a neurodegenerative disorder caused by mutations in either the EPM2A or the EPM2B gene that encode a glycogen phosphatase, laforin and an E3 ubiquitin ligase, malin, respectively. A hallmark of the disease is accumulation of insoluble, poorly branched, hyperphosphorylated glycogen in brain, muscle and heart. The laforin-malin complex has been proposed to play a role in the regulation of glycogen metabolism and protein degradation/quality control. We evaluated three arms of protein quality control (the autophagolysosomal pathway, the ubiquitin-proteasomal pathway, and ER stress response) in embryonic fibroblasts from Epm2a-/-, Epm2b-/- and Epm2a-/- Epm2b-/- mice. There was an mTOR-dependent impairment in autophagy, decreased proteasomal activity but an uncompromised ER stress response in the knockout cells. These defects may be secondary to the glycogen overaccumulation. The absence of malin, but not laforin, decreased the level of LAMP1, a marker of lysosomes, suggesting a malin function independent of laforin, possibly in lysosomal biogenesis and/or lysosomal glycogen disposal. To understand the physiological role of malin, an unbiased diGly proteomics approach was developed to search for malin substrates. Ubiquitin forms an isopeptide bond with lysine of the protein upon ubiquitination. Proteolysis by trypsin cleaves the C-terminal Arg-Gly-Gly residues in ubiquitin and yields a diGly remnant on the peptides. These diGly peptides were immunoaffinity purified using anti-diGly antibody and then analyzed by mass spectrometry. The mouse skeletal muscle ubiquitylome was studied using diGly proteomics and we identified 244 nonredundant ubiquitination sites in 142 proteins. An approach for differential dimethyl labeling of proteins with diGly immunoaffinity purification was also developed. diGly peptides from skeletal muscle of wild type and Epm2b-/- mice were immunoaffinity purified followed by differential dimethyl labeling and analyzed by mass spectrometry. About 70 proteins were identified that were present in the wild type and absent in the Epm2b-/- muscle tissue. The initial results identified 14 proteins as potential malin substrates, which would need validation in future studies.

Glycogen -- Metabolism

Ubiquitin -- Metabolism

Ligases -- Research

Autophagic vacuoles

Gene targeting

Genetic transcription -- Regulation

Phosphorylation

Proteomics -- Regulation

Glycopeptides

Proteins -- Metabolism

Homeostasis

Mice as laboratory animals