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2. Data from The AMPK-Related Kinases SIK1 and SIK3 Mediate Key Tumor-Suppressive Effects of LKB1 in NSCLC

Author

Reuben J. Shaw, Rebecca Berdeaux, Robert A. Screaton, Maxim N. Shokhirev, April E. Williams, Hector M. Galvez, Amanda Hutchins, T.J. Rymoff, Debbie S. Ross, Liliana I. Vera, Robert U. Svensson, Anwesh Kamireddy, Sonja N. Brun, Lillian J. Eichner, and Pablo E. Hollstein

Abstract

Mutations in the LKB1 (also known as STK11) tumor suppressor are the third most frequent genetic alteration in non–small cell lung cancer (NSCLC). LKB1 encodes a serine/threonine kinase that directly phosphorylates and activates 14 AMPK family kinases (“AMPKRs”). The function of many of the AMPKRs remains obscure, and which are most critical to the tumor-suppressive function of LKB1 remains unknown. Here, we combine CRISPR and genetic analysis of the AMPKR family in NSCLC cell lines and mouse models, revealing a surprising critical role for the SIK subfamily. Conditional genetic loss of Sik1 revealed increased tumor growth in mouse models of Kras-dependent lung cancer, which was further enhanced by loss of the related kinase Sik3. As most known substrates of the SIKs control transcription, gene-expression analysis was performed, revealing upregulation of AP1 and IL6 signaling in common between LKB1- and SIK1/3-deficient tumors. The SIK substrate CRTC2 was required for this effect, as well as for proliferation benefits from SIK loss.Significance:The tumor suppressor LKB1/STK11 encodes a serine/threonine kinase frequently inactivated in NSCLC. LKB1 activates 14 downstream kinases in the AMPK family controlling growth and metabolism, although which kinases are critical for LKB1 tumor-suppressor function has remained an enigma. Here we unexpectedly found that two understudied kinases, SIK1 and SIK3, are critical targets in lung cancer.This article is highlighted in the In This Issue feature, p. 1469

Published
2023

3. A Dual Inhibitor of DYRK1A and GSK3β for β‐Cell Proliferation: Aminopyrazine Derivative GNF4877

Author

Tingting Mo, Yefen Zou, Weijun Shen, Zhihong Huang, Xiaoyue Zhang, Qihui Jin, Jing Li, Shifeng Pan, Michael Di Donato, Loren Jon, Andrew M. Schumacher, George Harb, Shanshan Yan, Anwesh Kamireddy, You-Qing Zhang, Tom Y.-H. Wu, Yong Jia, Xueshi Hao, Yahu A. Liu, Richard Glynne, Bryan Laffitte, Brandon Taylor, Peter McNamara, Qiang Ding, Wenqi Gao, Valentina Molteni, Badry Bursalaya, Lisa Deaton, and Chun Li

Subjects
DYRK1A, medicine.medical_treatment, Protein Serine-Threonine Kinases, Pharmacology, 01 natural sciences, Biochemistry, Mice, Structure-Activity Relationship, In vivo, GSK-3, Insulin-Secreting Cells, Diabetes mellitus, Drug Discovery, Animals, Humans, Medicine, General Pharmacology, Toxicology and Pharmaceutics, Protein Kinase Inhibitors, Cell Proliferation, Glycogen Synthase Kinase 3 beta, Dose-Response Relationship, Drug, Molecular Structure, 010405 organic chemistry, business.industry, Kinase, Cell growth, Insulin, Organic Chemistry, Protein-Tyrosine Kinases, medicine.disease, In vitro, Rats, 0104 chemical sciences, 010404 medicinal & biomolecular chemistry, Molecular Medicine, business
Abstract

Loss of β-cell mass and function can lead to insufficient insulin levels and ultimately to hyperglycemia and diabetes mellitus. The mainstream treatment approach involves regulation of insulin levels; however, approaches intended to increase β-cell mass are less developed. Promoting β-cell proliferation with low-molecular-weight inhibitors of dual-specificity tyrosine-regulated kinase 1A (DYRK1A) offers the potential to treat diabetes with oral therapies by restoring β-cell mass, insulin content and glycemic control. GNF4877, a potent dual inhibitor of DYRK1A and glycogen synthase kinase 3β (GSK3β) was previously reported to induce primary human β-cell proliferation in vitro and in vivo. Herein, we describe the lead optimization that lead to the identification of GNF4877 from an aminopyrazine hit identified in a phenotypic high-throughput screening campaign measuring β-cell proliferation.

Published
2020

4. Selective DYRK1A Inhibitor for the Treatment of Type 1 Diabetes: Discovery of 6-Azaindole Derivative GNF2133

Author

Bo Liu, Sukwon Ha, H. Michael Petrassi, Kate Jacobsen, George Harb, W. Perry Gordon, Bryan Laffitte, Thanh Lam, Qihui Jin, Yong Jia, Janine E. Baaten, Minhua Qiu, Robert Hill, Shelly Meeusen, Shanshan Yan, Badry Bursulaya, Valentina Molteni, Anwesh Kamireddy, Lisa Deaton, Jianfeng Pan, You-Qing Zhang, Loren Jon, Michael DiDonato, Yahu A. Liu, Shifeng Pan, Andrew M. Schumacher, Tingting Mo, Yefen Zou, Xiaoyue Zhang, Weijun Shen, Karyn Colman, Richard Glynne, Xueshi Hao, Peter McNamara, Vân Nguyen-Tran, Zhicheng Wang, Sheryll Espinola, Bao Nguyen, Tom Y.-H. Wu, Jing Li, and Qiang Ding

Subjects
Male, Indoles, DYRK1A, medicine.medical_treatment, Disease, Protein Serine-Threonine Kinases, Pharmacology, 01 natural sciences, Rats, Sprague-Dawley, Mice, 03 medical and health sciences, In vivo, Insulin-Secreting Cells, Diabetes mellitus, Insulin Secretion, Drug Discovery, medicine, Animals, Humans, Hypoglycemic Agents, Rats, Wistar, Cells, Cultured, Cell Proliferation, 030304 developmental biology, Diphtheria toxin, Aza Compounds, 0303 health sciences, Type 1 diabetes, Chemistry, Insulin, Protein-Tyrosine Kinases, medicine.disease, In vitro, Rats, 0104 chemical sciences, Molecular Docking Simulation, 010404 medicinal & biomolecular chemistry, Diabetes Mellitus, Type 1, Molecular Medicine
Abstract

Autoimmune deficiency and destruction in either β-cell mass or function can cause insufficient insulin levels and, as a result, hyperglycemia and diabetes. Thus, promoting β-cell proliferation could be one approach toward diabetes intervention. In this report we describe the discovery of a potent and selective DYRK1A inhibitor GNF2133, which was identified through optimization of a 6-azaindole screening hit. In vitro, GNF2133 is able to proliferate both rodent and human β-cells. In vivo, GNF2133 demonstrated significant dose-dependent glucose disposal capacity and insulin secretion in response to glucose-potentiated arginine-induced insulin secretion (GPAIS) challenge in rat insulin promoter and diphtheria toxin A (RIP-DTA) mice. The work described here provides new avenues to disease altering therapeutic interventions in the treatment of type 1 diabetes (T1D).

Published
2020

5. The AMPK-Related Kinases SIK1 and SIK3 Mediate Key Tumor-Suppressive Effects of LKB1 in NSCLC

Author

Rebecca Berdeaux, Hector M. Galvez, Sonja N. Brun, T.J. Rymoff, Pablo E. Hollstein, Robert U. Svensson, Anwesh Kamireddy, Reuben J. Shaw, Robert A. Screaton, April Williams, Debbie S. Ross, Liliana I. Vera, Maxim N. Shokhirev, Amanda Hutchins, and Lillian J. Eichner

Subjects
0301 basic medicine, Lung Neoplasms, STK11, AMP-Activated Protein Kinases, Protein Serine-Threonine Kinases, Biology, Article, Proto-Oncogene Proteins p21(ras), Mice, 03 medical and health sciences, 0302 clinical medicine, AMP-Activated Protein Kinase Kinases, Downregulation and upregulation, Carcinoma, Non-Small-Cell Lung, Cell Line, Tumor, Animals, Humans, skin and connective tissue diseases, Gene Editing, Kinase, AMPK, Tumor Burden, CRTC2, Gene Expression Regulation, Neoplastic, AP-1 transcription factor, 030104 developmental biology, Oncology, A549 Cells, 030220 oncology & carcinogenesis, Cancer research, Phosphorylation, CRISPR-Cas Systems, Signal transduction, Protein Kinases, Neoplasm Transplantation, Signal Transduction
Abstract

Mutations in the LKB1 (also known as STK11) tumor suppressor are the third most frequent genetic alteration in non–small cell lung cancer (NSCLC). LKB1 encodes a serine/threonine kinase that directly phosphorylates and activates 14 AMPK family kinases (“AMPKRs”). The function of many of the AMPKRs remains obscure, and which are most critical to the tumor-suppressive function of LKB1 remains unknown. Here, we combine CRISPR and genetic analysis of the AMPKR family in NSCLC cell lines and mouse models, revealing a surprising critical role for the SIK subfamily. Conditional genetic loss of Sik1 revealed increased tumor growth in mouse models of Kras-dependent lung cancer, which was further enhanced by loss of the related kinase Sik3. As most known substrates of the SIKs control transcription, gene-expression analysis was performed, revealing upregulation of AP1 and IL6 signaling in common between LKB1- and SIK1/3-deficient tumors. The SIK substrate CRTC2 was required for this effect, as well as for proliferation benefits from SIK loss. Significance: The tumor suppressor LKB1/STK11 encodes a serine/threonine kinase frequently inactivated in NSCLC. LKB1 activates 14 downstream kinases in the AMPK family controlling growth and metabolism, although which kinases are critical for LKB1 tumor-suppressor function has remained an enigma. Here we unexpectedly found that two understudied kinases, SIK1 and SIK3, are critical targets in lung cancer. This article is highlighted in the In This Issue feature, p. 1469

Published
2019

6. AMPK governs lineage specification through Tfeb-dependent regulation of lysosomes

Author

Lillian J. Eichner, Reuben J. Shaw, Maxim N. Shokhirev, Anwesh Kamireddy, Nathan P. Young, Jeanine L. Van Nostrand, and Yelena Dayn

Subjects
0301 basic medicine, Cellular differentiation, Regulator, Embryoid body, AMP-Activated Protein Kinases, Cell fate determination, Biology, Mice, 03 medical and health sciences, Genetics, Animals, Cell Lineage, Wnt Signaling Pathway, Embryonic Stem Cells, Basic Helix-Loop-Helix Leucine Zipper Transcription Factors, Endoderm, Wnt signaling pathway, Gene Expression Regulation, Developmental, AMPK, Cell Differentiation, Embryonic stem cell, Cell biology, 030104 developmental biology, Mutation, TFEB, Lysosomes, Research Paper, Signal Transduction, Developmental Biology
Abstract

Faithful execution of developmental programs relies on the acquisition of unique cell identities from pluripotent progenitors, a process governed by combinatorial inputs from numerous signaling cascades that ultimately dictate lineage-specific transcriptional outputs. Despite growing evidence that metabolism is integrated with many molecular networks, how pathways that control energy homeostasis may affect cell fate decisions is largely unknown. Here, we show that AMP-activated protein kinase (AMPK), a central metabolic regulator, plays critical roles in lineage specification. Although AMPK-deficient embryonic stem cells (ESCs) were normal in the pluripotent state, these cells displayed profound defects upon differentiation, failing to generate chimeric embryos and preferentially adopting an ectodermal fate at the expense of the endoderm during embryoid body (EB) formation. AMPK−/− EBs exhibited reduced levels of Tfeb, a master transcriptional regulator of lysosomes, leading to diminished endolysosomal function. Remarkably, genetic loss of Tfeb also yielded endodermal defects, while AMPK-null ESCs overexpressing this transcription factor normalized their differential potential, revealing an intimate connection between Tfeb/lysosomes and germ layer specification. The compromised endolysosomal system resulting from AMPK or Tfeb inactivation blunted Wnt signaling, while up-regulating this pathway restored expression of endodermal markers. Collectively, these results uncover the AMPK pathway as a novel regulator of cell fate determination during differentiation.

Published
2016

7. Small-Molecule Inducer of β Cell Proliferation Identified by High-Throughput Screening

Author

Richard Glynne, Bryan Laffitte, Peter McNamara, George Harb, Weidong Wang, V. Deshmukh, Matthew S. Tremblay, Charles Y. Cho, You Qing Zhang, Ann E. Herman, Peter G. Schultz, Jonathan G. Swoboda, Janine E. Baaten, Weijun Shen, Tom Y.-H. Wu, Christophe M. Filippi, Jing Li, Qihui Jin, Anwesh Kamireddy, and Xu Wu

Subjects
Cell, Drug Evaluation, Preclinical, IκB kinase, Biochemistry, Catalysis, Cell Line, Islets of Langerhans, Mice, Structure-Activity Relationship, Colloid and Surface Chemistry, medicine, Animals, Humans, Urea, Inducer, Cell Proliferation, Dose-Response Relationship, Drug, Molecular Structure, Kinase, Cell growth, Chemistry, General Chemistry, Small molecule, Molecular biology, High-Throughput Screening Assays, Molecular Weight, medicine.anatomical_structure, Mechanism of action, Cell culture, medicine.symptom
Abstract

The identification of factors that promote β cell proliferation could ultimately move type 1 diabetes treatment away from insulin injection therapy and toward a cure. We have performed high-throughput, cell-based screens using rodent β cell lines to identify molecules that induce proliferation of β cells. Herein we report the discovery and characterization of WS6, a novel small molecule that promotes β cell proliferation in rodent and human primary islets. In the RIP-DTA mouse model of β cell ablation, WS6 normalized blood glucose and induced concomitant increases in β cell proliferation and β cell number. Affinity pulldown and kinase profiling studies implicate Erb3 binding protein-1 and the IκB kinase pathway in the mechanism of action of WS6.

Published
2013

8. Islet Isolation From Human Pancreas With Extended Cold Ischemia Time

Author

David W. Scharp, L.T. Ho, Anwesh Kamireddy, W.M. Kühtreiber, and J.A.W. Yacoub

Subjects
Adult, Male, endocrine system, medicine.medical_specialty, Adenosine, Tissue and Organ Procurement, Allopurinol, Organ Preservation Solutions, Cell Culture Techniques, Cell Separation, Cold Ischemia Time, Islets of Langerhans, Raffinose, Cause of Death, Internal medicine, Insulin Secretion, medicine, Humans, Insulin, Cyclic GMP, Pancreas, Aged, Transplantation, geography, geography.geographical_feature_category, business.industry, Organ Size, Middle Aged, Hypothermia, Islet, Glutathione, Culture Media, Staining, Glucose, Endocrinology, medicine.anatomical_structure, Collagenase, Female, Surgery, medicine.symptom, Digestion, business, medicine.drug
Abstract

The general consensus among transplant centers is that a cold ischemia time (CIT) beyond 8 hours results in reduced yields and quality of human islets. We sought to optimize the isolation process and enzymes for pancreata with extended CIT. We processed 16 extended CIT pancreata (13.2 +/- 0.7 hours). Donors averaged 50.8 +/- 2.6 (standard error of the mean) years old with a body mass index of 28.6 +/- 1.5. Glands were shipped in cold organ preservation solution without oxygenated perfluorocarbon. Isolations were performed under a protocol optimized for digestion with the new cGMP collagenase from Roche. Purification used continuous Euroficoll/University of Wisconsin gradients. Islets were cultured in two types of Prodo cGMP islet culture media and/or in Miami 1A media. Glucose-stimulated insulin secretion assays were performed after 8 to 16 days of culture. Prepurification yield averaged 415 +/- 41 KIEQ postpurification, 359 +/- 29 KIEQ (purification loss 13.5%); and postculture 317 +/- 27 KIEQ (culture loss 11.7%). Our process liberated an average of 4278 IEQ/g of pancreas (97 +/- 5 g). Most islets were recovered in the purest fraction (purity 79.7% +/- 1.9%). Culture loss in our enhanced culture media was 11.7%. After 2 to 3 days in culture, viability was 92% +/- 1%. Islets exhibited compactness and dithizone staining. Glucose-stimulated insulin secretion assays performed after 3 to 23 days in our PIM(R) media resulted in a stimulation index of 6.8 +/- 1.7 (G50 to G350). We concluded that our human islet isolation process permitted the recovery of large numbers of high-quality human islets from extended CIT pancreata and that our cGMP islet culture media was superior to the current standard CMRL-based media.

Published
2010

9. Correction to 'Small-Molecule Inducer of β Cell Proliferation Identified by High-Throughput Screening'

Author

Jing Li, Weidong Wang, Tom Wu, Jonathan G. Swoboda, Bryan A. Laffitte, Peter G. Schultz, Richard Glynne, Christophe M. Filippi, Qihui Jin, Weijun Shen, George Harb, Matthew S. Tremblay, Ann E. Herman, Charles Y. Cho, Eric C. Peters, Xu Wu, Janine E. Baaten, You Qing Zhang, Anwesh Kamireddy, Peter McNamara, and V. Deshmukh

Subjects
Colloid and Surface Chemistry, Chemistry, High-throughput screening, General Chemistry, Computational biology, Biochemistry, Catalysis
Abstract

Page 1672. Eric C. Peters was mistakenly listed in the Acknowledgment of the published Communication rather than in the author list. Eric C. Peters should be included in the author list between Jonathan G. Swoboda and Charles Y. Cho, along with indication (‡) of his affiliation with The Genomics Institute of the Novartis Research Foundation. The first sentence of the Acknowledgment should now read as follows: The authors acknowledge the efforts of John Walker for experimental support.

Published
2013

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