Gene Expression Profiling of Type 2 Diabetes Mellitus by Bioinformatics Analysis

Zhu, Huijing; Zhu, Xin; Liu, Yuhong; Jiang, Fusong; Chen, Miao; Cheng, Lin; Cheng, Xingbo

doi:https://doi.org/10.1155/2020/9602016

Computational and Mathematical Methods in Medicine

On this page

Abstract Introduction Methods Results Discussion Conclusion Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Special Issue

Machine Learning and Network Methods for Biology and Medicine 2020

View this Special Issue

Research Article | Open Access

Volume 2020 | Article ID 9602016 | https://doi.org/10.1155/2020/9602016

Gene Expression Profiling of Type 2 Diabetes Mellitus by Bioinformatics Analysis

Huijing Zhu,^1,2Xin Zhu,²Yuhong Liu,²Fusong Jiang,³Miao Chen,^1,4Lin Cheng,²and Xingbo Cheng¹

Guest Editor: Lei Chen

Received18 Jun 2020

Revised22 Jul 2020

Accepted03 Aug 2020

Published23 Oct 2020

Abstract

Objective. The aim of this study was to identify the candidate genes in type 2 diabetes mellitus (T2DM) and explore their potential mechanisms. Methods. The gene expression profile GSE26168 was downloaded from the Gene Expression Omnibus (GEO) database. The online tool GEO2R was used to obtain differentially expressed genes (DEGs). Gene Ontology (GO) term enrichment analysis and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analysis were performed by using Metascape for annotation, visualization, and comprehensive discovery. The protein-protein interaction (PPI) network of DEGs was constructed by using Cytoscape software to find the candidate genes and key pathways. Results. A total of 981 DEGs were found in T2DM, including 301 upregulated genes and 680 downregulated genes. GO analyses from Metascape revealed that DEGs were significantly enriched in cell differentiation, cell adhesion, intracellular signal transduction, and regulation of protein kinase activity. KEGG pathway analysis revealed that DEGs were mainly enriched in the cAMP signaling pathway, Rap1 signaling pathway, regulation of lipolysis in adipocytes, PI3K-Akt signaling pathway, MAPK signaling pathway, and so on. On the basis of the PPI network of the DEGs, the following 6 candidate genes were identified: PIK3R1, RAC1, GNG3, GNAI1, CDC42, and ITGB1. Conclusion. Our data provide a comprehensive bioinformatics analysis of genes, functions, and pathways, which may be related to the pathogenesis of T2DM.

1. Introduction

Type 2 diabetes mellitus (T2DM), a disease with significant morbidity, disability, and mortality, has affected increasing numbers of people worldwide. The World Health Organization (WHO) projected that diabetes would be the 7th leading cause of death in 2030. In addition, it has been predicted that by 2030, developing countries would account for 77.6% of all diabetic patients [1]. Although diabetes is a chronic disease that often causes various complications, in terms of financial burden, the cost of diabetes is 2-4 times more than that of the average patient in all medical systems [2]. Early detection and diagnosis of diabetes to prevent diabetes-associated complications and to reduce the economic costs on medical care are therefore of significant importance.

T2DM, which is characterized by hyperglycemia in the case of insulin resistance and impaired insulin secretion, is also a multigene heterogeneous disease that is the result of the interaction of genetic and environmental factors [3]. Although genetic factors play an important role in the occurrence and development of T2DM, the elaboration of its exact mechanism depends on the identification of susceptibility genes for T2DM.

At present, most of the gene research on T2DM mainly uses gene chip technology to detect and analyze model animals or clinical patient samples alone. Through this single analysis method, some valuable genes can be screened out for research and analysis. Gene expression analysis based on microarray technology is a powerful and high-throughput research method. Through gene expression profiling, some studies have found that hundreds of differentially expressed genes (DEGs) are involved in multiple molecular functions, biological processes, and signaling pathways [4], which played an important role in the occurrence and development of diseases and could be used as a potential molecular target and diagnostic marker. In the current study, the GSE26168 dataset [5] was downloaded from the Gene Expression Omnibus (GEO) database to identify T2DM-associated DEGs between T2DM and normal samples. Subsequently, GO term enrichment analysis, Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analysis, and PPI network analysis were performed to discover candidate genes as T2DM biomarkers and therapeutic targets worthy of further progress.

2. Methods

2.1. Microarray Data

The dataset GSE26168 based on the GPL6883 platform (Illumina HumanRef-8 v3.0 expression bead chip) was downloaded from GEO. A total of 9 T2DM samples and 8 normal samples were analyzed.

2.2. Identification of DEGs

GEO2R (http://www.ncbi.nlm.nih.gov/geo/geo2r/) is an interactive web tool for comparing two sets of data under the same experimental conditions and can analyze any geo series [6]. GEO2R was applied to explore DEGs between T2DM and normal blood samples. Statistically significant DEGs were defined with , and the value < 0.05 was the cut-off criterion.

2.3. Functional and Pathway Enrichment Analysis of DEGs

GO is a common way to annotate genes, gene products, and sequences as potential biological phenomena, mainly including biological process (BP), cellular component (CC), and molecular function (MF); the Kyoto Encyclopedia of Genes and Genomes (KEGG) is a comprehensive database resource for the biological interpretation of genomic sequences and other high-throughput data. GO and KEGG analyses were performed using the Metascape database to analyze the DEGs at the functional level. A value < 0.01 and were set as the cut-off criterion.

2.4. Integration of the Protein-Protein Interaction (PPI) Network

The PPI network of DEGs was constructed by STRING. A was set as significant. Subsequently, the PPI networks were visualized using Cytoscape software (3.7.1). MCODE was used to screen out the core genes that constitute the stable structure of the PPI network with degree , haircut on, node score , , and maximum . Moreover, the CentiScape plug-in was used to calculate the centrality index and topological properties for the identification of the most important nodes of a network, including undirected, directed, and weighted networks. The key (hub) genes were defined with , while the bottleneck genes were defined with . Then, using Venn diagram analysis, the genes in the intersection of the above three datasets were selected as candidate genes for the diagnosis of T2DM.

3. Results

3.1. Identification of DEGs

Based on the aforementioned threshold ( and ), a total of 981 DEGs including 301 upregulated DEGs and 680 downregulated DEGs were filtered with GEO2R (Figure 1).

3.2. Functional and Pathway Enrichment Analysis

Three GO category results are presented in Figures 2(a)–2(c). As to the biological process (BP), DEGs were significantly enriched in cell morphogenesis involved in differentiation, chemotaxis, and regulation of cell adhesion (Figure 2(a)). For the cell component (CC), DEGs were enriched in the microtubule organizing center, dendrite, and anchored component of the membrane (Figure 2(b)). In terms of the molecular function (MF), DEGs were enriched in protein domain-specific binding, ubiquitin protein ligase binding, and anion transmembrane transporter activity (Figure 2(c)). The KEGG pathway analysis revealed that DEGs were highly associated with the cAMP signaling pathway, Rap1 signaling pathway, and bacterial invasion of epithelial cells (Figure 3).

(a) GO BP analysis

(b) GO CC analysis

(c) GO MF analysis

3.3. PPI Network Construction and Analysis of Modules

The PPI network consisted of 945 nodes and 835 edges after hiding nodes which could not interact with other nodes (Figure 4(a)). Then, we used MCODE to perform kernel analysis of the string network, a total of 9 clusters were generated, and 90 core genes were screened out (Table 1, Figures 4(b)–4(j)). Besides, the topology characteristics of the string network and each node were computed with CentiScape. 12 hub genes and 14 bottleneck genes were obtained (Table 1). Moreover, using Venn diagram analysis, 6 candidate genes in the intersection of the above three datasets were selected for further analysis, including phosphoinositide-3-kinase regulatory subunit 1 (PIK3R1), ras-related C3 botulinum toxin substrate 1 (rho family, small GTP-binding protein Rac1) (RAC1), G protein subunit gamma 3 (GNG3), G protein subunit alpha i1 (GNAI1), cell division cycle 42 (CDC42), and integrin subunit beta 1 (ITGB1) (Figure 5).

(a) DEG PPI network

(b) Module 1

(c) Module 2

(d) Module 3

(e) Module 4

(f) Module 5

(g) Module 6

(h) Module 7

(i) Module 8

(j) Module 9

4. Discussion

In this study, we identified a total of 981 significant DEGs between T2DM and normal samples, including 301 upregulated genes and 680 downregulated genes, and conducted a series of bioinformatics analysis to screen candidate genes and pathways related to T2DM. DEGs were investigated in both GO term enrichment analysis and KEGG pathway analysis for functional annotation. As the outcomes of GO term enrichment analysis, DEGs might play critical roles in T2DM through cell differentiation, cell adhesion, intracellular signal transduction, and regulation of protein kinase activity. Meanwhile, KEGG pathway analysis revealed that DEGs were mainly enriched in the cAMP signaling pathway, Rap1 signaling pathway, regulation of lipolysis in adipocytes, PI3K-Akt signaling pathway, and MAPK signaling pathway. Moreover, by constructing the PPI, 6 candidate genes were identified, which exerted a momentous effect on the T2DM initiation, progression, and intervention strategy from different sides, including PIK3R1, RAC1, GNG3, GNAI1, CDC42, and ITGB1. The regulatory network consisting of microRNAs (miRNAs), long noncoding RNA (lncRNA), and mRNAs has attracted increasing attention to elucidate the mechanism of action in various diseases. In this study, mirDIP and starBase were used to analyze and predict the upstream miRNA interacting with candidate genes and the upstream lncRNA interacting with miRNA. A total of 22 miRNAs and 5 lncRNA were screened, which may play crucial parts in the development of T2DM.

PIK3R1 encodes the p85α regulatory subunit of the phosphatidylinositol-3-kinase (PI3K), which connects firmly with the p110 catalytic subunit, and together, they form the PI3K protein. PI3K plays a key role in insulin signaling by binding to phosphorylated insulin receptor substrates (IRS), producing phosphatidylinositol-4,5-trisphosphate (PIP3), which then activates several downstream targets such as AKT serine-threonine kinase [7]. AKT regulates cell survival, growth, differentiation, glucose transporter type 4 (GLUT-4) trafficking, and glucose utilization [8]. Mouse studies have shown that mice lacking PIK3R1 display enhanced insulin sensitivity and glucose tolerance, due to an improved stoichiometry of the p85α/p110 complex for binding to IRS and enhanced insulin-stimulated Akt activity [9, 10]. The overexpression of p85α weakens signal transmission and causes insulin resistance by disrupting the activity of the p85α/p110 complex and the connection between PI3K and IRS [11, 12], which indicates that p85α subunits play a negative role in PI3K signaling downstream of the insulin receptor. Thus, PIK3R1 is a logical candidate gene involved in the development of T2DM. Regulation of p85α expression in insulin-sensitive tissues may be a new strategy to increase insulin sensitivity and may also become a new target for the treatment of T2DM.

CDC42 and RAC1 are members of the Rho GTPase family, which regulate signaling pathways that control a variety of cellular functions, including cell morphology, migration, endocytosis, and cell cycle progression. Both CDC42 and RAC1 regulate the second phase of glucose-stimulated insulin secretion (GSIS), and the circulation of these proteins between the activated state (GTP-bound) and the inactive state (GDP-bound) is important for insulin secretion [13, 14].

CDC42 plays critical roles in the process of insulin synthesis by regulating granule fusion and cytoskeletal rearrangement [15, 16] and also regulates mobilization and cell membrane exocytosis and endocytosis of insulin granules via activating a series of downstream factors [17–20]. One study showed that upregulation of miR-330-3p reduces the expression of CDC42 and E2F1 in patients with gestational diabetes (GDM), resulting in impaired β-cell proliferation [21]. P21-activated kinase 1 (PAK1) is a downstream factor of CDC42 and an important promoter of cell proliferation. Another study showed an 80% reduction in PAK1 in patients with T2DM [2]. Thus, CDC42 is an important member in the progress of T2DM, and targeted therapy for CDC42 may be one of the effective methods for treating T2DM and related diseases.

RAC1, which can stimulate actin cytoskeleton reorganization [22], is required for insulin-stimulated translocation of glucose transporter 4 (GLUT-4) in muscle cells [23]. RAC1 also can activate PAK [24]. The study indicated that RAC1 and its downstream target protein PAK were reduced in insulin-resistant mice and human skeletal muscle [25]. In addition, RAC1 can activate NADPH oxygenase (NOX), which produces reactive oxygen species (ROS) and activates p38MAPK under high glucose conditions, leading to mitochondrial disorders and islet β-cell apoptosis [26, 27]. This mechanism also plays a crucial role in diabetes-induced vascular injuries, such as diabetic retinopathy [28] and diabetic cardiomyopathy [29]. Thus, RAC1 can be a novel molecular candidate of T2DM and provide new insight to improve therapeutic strategies for T2DM and diabetic complications.

GNG3, a member of signal-transducing molecules, a signal transduction molecule encoding the G protein gamma 3 subunit, plays a variety of roles during signal transduction, from membrane targeting of the α subunit [30] to receptor recognition [31], to activation of effectors [32], and then to effect signaling regulation of various proteins of intensity or duration [33]. The research found that inhibition of G-protein βγ signaling produces the changes in the cytokine mRNA levels, which can benefit the autoimmune diseases [34]. In addition, the mice lacking the G protein γ3 subtype show decreased weight gain, reduced fat intake, and defective Oprm1 signaling [35], when maintained on a high-fat diet. These results suggest that GNG3 may be involved in the pathogenesis of T2DM, and further research on GNG3 may provide new targets for the development of drugs to treat obesity and relevant diseases.

GNAI1, also known as Gi, an adenylate cyclase inhibitor that inhibits the conversion of ATP to cAMP [36], can interact with other proteins. T cell differentiation may change its structure [37]. Studies showed that altered expression of GNAI1 was associated with the progression of inflammation and immune disease [38, 39]. Thus, GNAII may be considered to be a novel biomarker for T2DM.

ITGB1, a member of the integrin family, consists of 18 α and 8 β transmembrane subunits that form at least 24 different heterodimeric receptors allowing cells to adhere to extracellular matrix (ECM) proteins [40]. Integrins play an important role in mediating cell-to-cell and cell-to-ECM adhesion [41], especially between the extracellular environment and platelets, inflammatory cells, and the vasculature [42]. The previous study has confirmed that integrin-mediated adhesion was preferentially mediated by ITGB1. Integrins have been shown to be involved in angiogenesis [43], which is a key pathological characteristic of diabetic microvascular complications and also is essential for homeostasis of adipose tissues. ITGB1 may be a therapeutic target for obesity [44]. Consistently, as a significant membrane gene identified in our study, ITGB1 was expressed differentially between T2DM and normal groups. ITGB1 may play central roles in all DEGs and have a close relationship with the development of obesity, T2DM, and its complications.

5. Conclusion

Our study tried to identify some candidate genes and pathway regulatory network closely related to T2DM by a series of bioinformatics analysis on DEGs between T2DM samples and normal samples. The findings in the current work may help us understand the underlying molecular mechanisms of T2DM. DEGs such as PIK3R1, RAC1, GNG3, GNAI1, CDC42, and ITGB1 have the potential to be used as targets for T2DM diagnosis and treatments. However, the lack of experimental validation is a limitation of this study. In the future, these prediction results obtained through bioinformatics analysis can be verified by further experimental studies such as qRT-PCR and Western blot.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that there is no conflict of interests regarding the publication of this paper.

Acknowledgments

We greatly appreciate the encouragements and supports from Prof. Yongzhi Lun (Department of Laboratory Medicine, School of Pharmacy and Medical Technology, Putian University, China). The study was supported by the Special Fund for Information Development of Shanghai Municipal Commission of Economy and Informatization (grant agreement number 201701014).

References

J. E. Shaw, R. A. Sicree, and P. Z. Zimmet, “Global estimates of the prevalence of diabetes for 2010 and 2030,” Diabetes Research and Clinical Practice, vol. 87, no. 1, pp. 4–14, 2010.
View at: Publisher Site | Google Scholar
J. S. Williams, K. Bishu, C. E. Dismuke, and L. E. Egede, “Sex differences in healthcare expenditures among adults with diabetes: evidence from the medical expenditure panel survey, 2002-2011,” BMC Health Service Research, vol. 17, no. 1, p. 259, 2017.
View at: Publisher Site | Google Scholar
S. Cuschieri, “The genetic side of type 2 diabetes – a review,” Diabetes & Metabolic Syndrome: Clinical Research & Reviews, vol. 13, no. 4, pp. 2503–2506, 2019.
View at: Publisher Site | Google Scholar
M. Nannini, M. A. Pantaleo, A. Maleddu, A. Astolfi, S. Formica, and G. Biasco, “Gene expression profiling in colorectal cancer using microarray technologies: results and perspectives,” Cancer Treatment Reviews, vol. 35, no. 3, pp. 201–209, 2009.
View at: Publisher Site | Google Scholar
D. S. Karolina, A. Armugam, S. Tavintharan et al., “MicroRNA 144 impairs insulin signaling by inhibiting the expression of insulin receptor substrate 1 in type 2 diabetes mellitus,” PLoS One, vol. 6, no. 8, article e22839, 2011.
View at: Publisher Site | Google Scholar
T. Barrett, S. E. Wilhite, P. Ledoux et al., “NCBI GEO: archive for functional genomics data sets—update,” Nucleic Acids Research, vol. 41, no. D1, pp. D991–D995, 2012.
View at: Publisher Site | Google Scholar
C. M. Taniguchi, B. Emanuelli, and C. R. Kahn, “Critical nodes in signalling pathways: insights into insulin action,” Nature Reviews Molecular Cell Biology, vol. 7, no. 2, pp. 85–96, 2006.
View at: Publisher Site | Google Scholar
A. Klippel, C. Reinhard, W. M. Kavanaugh, G. Apell, M. A. Escobedo, and L. T. Williams, “Membrane localization of phosphatidylinositol 3-kinase is sufficient to activate multiple signal-transducing kinase pathways,” Molecular and Cellular Biology, vol. 16, no. 8, pp. 4117–4127, 1996.
View at: Publisher Site | Google Scholar
F. Mauvais-Jarvis, K. Ueki, D. A. Fruman et al., “Reduced expression of the murine p85alpha subunit of phosphoinositide 3-kinase improves insulin signaling and ameliorates diabetes,” Journal of Clinical Investigation, vol. 109, no. 1, pp. 141–149, 2002.
View at: Publisher Site | Google Scholar
K. Ueki, C. M. Yballe, S. M. Brachmann et al., “Increased insulin sensitivity in mice lacking p85 subunit of phosphoinositide 3-kinase,” Proceedings of the National Academy of Sciences of the United States of America, vol. 99, no. 1, pp. 419–424, 2002.
View at: Publisher Site | Google Scholar
F. Giorgino, M. T. Pedrini, L. Matera, and R. J. Smith, “Specific increase in p85α expression in response to dexamethasone is associated with inhibition of insulin-like growth factor-I stimulated phosphatidylinositol 3-kinase activity in cultured muscle cells,” Journal of Biological Chemistry, vol. 272, no. 11, pp. 7455–7463, 1997.
View at: Publisher Site | Google Scholar
L. A. Barbour, J. Shao, L. Qiao et al., “Human placental growth hormone increases expression of the P85 regulatory unit of phosphatidylinositol 3-kinase and triggers severe insulin resistance in skeletal muscle,” Endocrinology, vol. 145, no. 3, pp. 1144–1150, 2004.
View at: Publisher Site | Google Scholar
A. K. Nevins and D. C. Thurmond, “Glucose regulates the cortical actin network through modulation of Cdc42 cycling to stimulate insulin secretion,” American Journal of Physiology-Cell Physiology, vol. 285, no. 3, pp. C698–C710, 2003.
View at: Publisher Site | Google Scholar
Z. Wang and D. C. Thurmond, “Mechanisms of biphasic insulin-granule exocytosis - roles of the cytoskeleton, small GTPases and SNARE proteins,” Journal of Cell Science, vol. 122, no. 7, pp. 893–903, 2009.
View at: Publisher Site | Google Scholar
M. Malacombe, M. Ceridono, V. Calco et al., “Intersectin-1L nucleotide exchange factor regulates secretory granule exocytosis by activating Cdc42,” The EMBO Journal, vol. 25, no. 15, pp. 3494–3503, 2006.
View at: Publisher Site | Google Scholar
Z. Wang, E. Oh, and D. C. Thurmond, “Glucose-stimulated Cdc42 signaling is essential for the second phase of insulin secretion,” Journal of Biological Chemistry, vol. 282, no. 13, pp. 9536–9546, 2007.
View at: Publisher Site | Google Scholar
A. Kowluru, S. E. Seavey, G. Li et al., “Glucose- and GTP-dependent stimulation of the carboxyl methylation of CDC42 in rodent and human pancreatic islets and pure beta cells. Evidence for an essential role of GTP-binding proteins in nutrient-induced insulin secretion,” Journal of Clinical Investigation, vol. 98, no. 2, pp. 540–555, 1996.
View at: Publisher Site | Google Scholar
E. N. Rittmeyer, S. Daniel, S. C. Hsu, and M. A. Osman, “A dual role for IQGAP1 in regulating exocytosis,” Journal of Cell Science, vol. 121, no. 3, pp. 391–403, 2008.
View at: Publisher Site | Google Scholar
V. L. Tokarz, P. E. MacDonald, and A. Klip, “The cell biology of systemic insulin function,” The Journal of Cell Biology, vol. 217, no. 7, pp. 2273–2289, 2018.
View at: Publisher Site | Google Scholar
Q. Y. Huang, X. N. Lai, X. L. Qian et al., “Cdc42: a novel regulator of insulin secretion and diabetes-associated diseases,” International Journal of Molecular Sciences, vol. 20, no. 1, p. 179, 2019.
View at: Publisher Site | Google Scholar
G. Sebastiani, E. Guarino, G. E. Grieco et al., “Circulating microRNA (miRNA) expression profiling in plasma of patients with gestational diabetes mellitus reveals upregulation of miRNA miR-330-3p,” Frontiers in Endocrinology, vol. 8, 2017.
View at: Publisher Site | Google Scholar
N. Tapon and A. Hall, “Rho, Rac and Cdc42 GTPases regulate the organization of the actin cytoskeleton,” Current Opinion in Cell Biology, vol. 9, no. 1, pp. 86–92, 1997.
View at: Publisher Site | Google Scholar
S. Nozaki, S. Ueda, N. Takenaka, T. Kataoka, and T. Satoh, “Role of RalA downstream of Rac1 in insulin-dependent glucose uptake in muscle cells,” Cellular Signalling, vol. 24, no. 11, pp. 2111–2117, 2012.
View at: Publisher Site | Google Scholar
E. Manser, T. Leung, H. Salihuddin, Z. Zhao, and L. Lim, “A brain serine/threonine protein kinase activated by Cdc42 and Rac1,” Nature, vol. 367, no. 6458, pp. 40–46, 1994.
View at: Publisher Site | Google Scholar
L. Sylow, T. E. Jensen, M. Kleinert et al., “Rac1 signaling is required for insulin-stimulated glucose uptake and is dysregulated in insulin-resistant murine and human skeletal muscle,” Diabetes, vol. 62, no. 6, pp. 1865–1875, 2013.
View at: Publisher Site | Google Scholar
V. Sidarala, R. Veluthakal, K. Syeda, C. Vlaar, P. Newsholme, and A. Kowluru, “Phagocyte-like NADPH oxidase (Nox2) promotes activation of p38MAPK in pancreatic β-cells under glucotoxic conditions: evidence for a requisite role of Ras-related C3 botulinum toxin substrate 1 (Rac1),” Biochemical Pharmacology, vol. 95, no. 4, pp. 301–310, 2015.
View at: Publisher Site | Google Scholar
A. Kowluru, “Role of G-proteins in islet function in health and diabetes,” Obesity and Metabolism, vol. 19, pp. 63–75, 2017.
View at: Publisher Site | Google Scholar
R. A. Kowluru, M. Mishra, and B. Kumar, “Diabetic retinopathy and transcriptional regulation of a small molecular weight G-protein, Rac1,” Experimental Eye Research, vol. 147, pp. 72–77, 2016.
View at: Publisher Site | Google Scholar
E. Shen, Y. Li, Y. Li et al., “Rac1 is required for cardiomyocyte apoptosis during hyperglycemia,” Diabetes, vol. 58, no. 10, pp. 2386–2395, 2009.
View at: Publisher Site | Google Scholar
D. S. Evanko, M. M. Thiyagarajan, D. P. Siderovski, and P. B. Wedegaertner, “Gβγ isoforms selectively rescue plasma membrane localization and palmitoylation of mutant Gαs and Gαq,” Journal of Biological Chemistry, vol. 276, no. 26, pp. 23945–23953, 2001.
View at: Publisher Site | Google Scholar
W. K. Lim, C. S. Myung, J. C. Garrison, and R. R. Neubig, “Receptor−G protein γ Specificity: γ11 shows unique potency for A1Adenosine and 5-HT_1A Receptors†,” Biochemistry, vol. 40, no. 35, pp. 10532–10541, 2001.
View at: Publisher Site | Google Scholar
D. E. Clapham and E. J. Neer, “G protein βγ subunits,” Annual Review of Pharmacology and Toxicology, vol. 37, no. 1, pp. 167–203, 1997.
View at: Publisher Site | Google Scholar
D. T. Lodowski, J. A. Pitcher, W. D. Capel, R. J. Lefkowitz, and J. J. Tesmer, “Keeping G proteins at bay: a complex between G protein-coupled receptor kinase 2 and Gbetagamma,” Science, vol. 300, no. 5623, pp. 1256–1262, 2003.
View at: Publisher Site | Google Scholar
T. R. Hynes, E. A. Yost, C. M. Hartle, B. J. Ott, and C. H. Berlot, “Inhibition of G-protein βγ signaling decreases levels of messenger RNAs encoding proinflammatory cytokines in T cell receptor-stimulated CD4+ T helper cells,” Journal of Molecular Signaling, vol. 10, 2015.
View at: Publisher Site | Google Scholar
W. F. Schwindinger, B. M. Borrell, L. C. Waldman, and J. D. Robishaw, “Mice lacking the G protein γ3-subunit show resistance to opioids and diet induced obesity,” American Journal of Physiology-Regulatory, Integrative and Comparative Physiology, vol. 297, no. 5, pp. R1494–R1502, 2009.
View at: Publisher Site | Google Scholar
V. V. Pineda, J. I. Athos, H. Wang et al., “Removal of G(ialpha1) constraints on adenylyl cyclase in the hippocampus enhances LTP and impairs memory formation,” Neuron, vol. 41, no. 1, pp. 153–163, 2004.
View at: Publisher Site | Google Scholar
M. Kanehisa, Y. Sato, M. Kawashima, M. Furumichi, and M. Tanabe, “KEGG as a reference resource for gene and protein annotation,” Nucleic Acids Research, vol. 44, no. D1, pp. D457–D462, 2016.
View at: Publisher Site | Google Scholar
S. Rivetti, M. Lauriola, M. Voltattorni et al., “Gene expression profile of human colon cancer cells treated with cross-reacting material 197, a diphtheria toxin non-toxic mutant,” International Journal of Immunopathology and Pharmacology, vol. 24, no. 3, pp. 639–649, 2011.
View at: Publisher Site | Google Scholar
S. A. Diehl, B. McElvany, R. Noubade et al., “G proteins Gαi1/3 are critical targets for Bordetella pertussis toxin-induced vasoactive amine sensitization,” Infection and Immunity, vol. 82, no. 2, pp. 773–782, 2014.
View at: Publisher Site | Google Scholar
R. O. Hynes, “Integrins,” Cell, vol. 110, no. 6, pp. 673–687, 2002.
View at: Publisher Site | Google Scholar
Y. Takada, X. Ye, and S. Simon, “The integrins,” Genome Biology, vol. 8, no. 5, p. 215, 2017.
View at: Publisher Site | Google Scholar
S. Weng, L. Zemany, K. N. Standley et al., “3 integrin deficiency promotes atherosclerosis and pulmonary inflammation in high-fat-fed, hyperlipidemic mice,” Proceedings of the National Academy of Sciences, vol. 100, no. 11, pp. 6730–6735, 2003.
View at: Publisher Site | Google Scholar
P. C. Brooks, A. M. P. Montgomery, M. Rosenfeld et al., “Integrin alpha v beta 3 antagonists promote tumor regression by inducing apoptosis of angiogenic blood vessels,” Cell, vol. 79, no. 7, pp. 1157–1164, 1994.
View at: Publisher Site | Google Scholar
R. Cheng and J. Ma, “Angiogenesis in diabetes and obesity,” Reviews in Endocrine and Metabolic Disorders, vol. 16, no. 1, pp. 67–75, 2015.
View at: Publisher Site | Google Scholar

Copyright

Copyright © 2020 Huijing Zhu et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

PDF Download Citation

Download other formats

Order printed copies

Views

3435

Downloads

1682

Citations