Genes altered in major depressive disorder
Genes altered in major depressive disorder
Positive relationships between RPS21 and other components at different levels (count: 0)
Positive relationship network of RPS21 in MK4MDD
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Note:
1. The different color of the nodes denotes the level of the nodes.
Genetic/Epigenetic Locus
Protein and Other Molecule
Cell and Molecular Pathway
Neural System
Cognition and Behavior
Symptoms and Signs
Environment
MDD
2. Besides the component related relationships from literature, gene mapped protein and protein mapped gene are also shown in the network.
If the mapped gene or protein is not from literature, square node would be used instead of Circle node.
Accordingly, the relationship is marked with dot line.
2. User can drag the nodes to rearrange the layout of the network. Click the node will enter the report page of the node.
Right-click will show also the menus to link to the report page of the node and remove the node and related edges.
Hover the node will show the level of the node and hover the edge will show the evidence/description of the edge.
3. The network is generated using Cytoscape Web
Negative relationships between RPS21 and MDD (count: 0)
Negative relationships between RPS21 and other components at different levels (count: 0)
Spliced and unspliced viral mRNA in the cytoplasm are transl......
Spliced and unspliced viral mRNA in the cytoplasm are translated by host cell ribosomal translation machinery. At least ten viral proteins are synthesized: HA, NA, PB1, PB2, PA, NP, NS1, NEP/NS2, M1, and M2. Viral mRNA translation is believed to be enhanced by conserved 5'UTR sequences that interact with the ribosomal machinery and at least one cellular RNA-binding protein, G-rich sequence factor 1. The viral NS1 protein and the cellular protein P58. The viral NS1 protein has also been proposed to specifically enhance translation through interaction with host poly. Simultaneously, host cell protein synthesis is downregulated in influenza virus infection through still uncharacterized mechanisms. In most human influenza A strains.More...
Hydrolysis of eIF2-GTP occurs after the Met-tRNAi has recogn......
Hydrolysis of eIF2-GTP occurs after the Met-tRNAi has recognized the AUG. This reaction is catalyzed by eIF5 (or eIF5B) and is thought to cause dissociation of all other initiation factors and allow joining of the large 60S ribosomal subunit. The 60S subunit joins - a reaction catalyzed by eIF5 or eIF5B - resulting in a translation-competent 80S ribosome. Following 60S subunit joining, eIF5B hydrolyzes its GTP and is released from the 80S ribosome, which is now ready to start elongating the polypeptide chain.More...
The mechanism of a peptide bond requires the movement of thr......
The mechanism of a peptide bond requires the movement of three protons. First the deprotonation of the ammonium ion generates a reactive amine, allowing a nucleophilic attack on the carbonyl group. This is followed by the loss of a proton from the reaction intermediate, only to be taken up by the oxygen on the leaving group (from the end of the amino acid chain bound to the tRNA in the P-site). The peptide bond formation results in the net loss of one water molecule, leaving a deacylated-tRNA in the P-site, and a nascent polypeptide chain one amino acid larger in the A-site. For the purpose of illustration, the figures used in the section show one amino acid being added to a peptidyl-tRNA with a growing peptide chain.More...
The 80S ribosome dissociates into free 40S (small) and 60S (......
The 80S ribosome dissociates into free 40S (small) and 60S (large) ribosomal subunits. Each ribosomal subunit is constituted by several individual ribosomal proteins and rRNA.More...
Synthesis of insulin-containing secretory granules can be de......
Synthesis of insulin-containing secretory granules can be described in 6 steps: transcription of preproinsulin genes, translation of preproinsulin mRNA with concomitant removal of the signal peptide, formation of intramolecular disulfide bonds, formation of proinsulin-zinc-calcium complexes, proteolytic cleavage of proinsulin to yield insulin, translocation of the granules across the cytosol to the plasma membrane. Transcription of the human insulin gene INS is activated by 4 important transcription factors: Pdx-1, MafA, Beta2/NeuroD1, and E47. The transcription factors interact with each other at the promoters of the insulin gene and act synergistically to promote transcription. Expression of the transcription factors is upregulated in response to glucose. The preproinsulin mRNA is translated by ribosomes at the rough endoplasmic reticulum (ER) and the preproinsulin enters the secretion pathway by virtue of its signal peptide, which is cleaved during translation to yield proinsulin. Evidence indicates that the preproinsulin mRNA is stabilized by glucose. Within the ER, three intramolecular disulfide bonds form between cysteine residues in the proinsulin. Formation of the bonds is the spontaneous result of the conformation of proinsulin and the oxidizing environment of the ER, which is maintained by Ero1-like alpha The cystine bonded proinsulin then moves via vesicles from the ER to the Golgi Complex. High concentrations of zinc are maintained in the Golgi by zinc transporters ZnT5, ZnT6, and ZnT7 and the proinsulin forms complexes with zinc and calcium. Proinsulin-zinc-calcium complexes bud in vesicles from the trans-Golgi to form immature secretory vesicles (secretory granules) in the cytosol. Within the immature granules the endoproteases Prohormone Convertase 1/3 and Prohormone Convertase 2 cleave at two sites of the proinsulin and Carboxypeptidase E removes a further 4 amino acid residues to yield the cystine-bonded A and B chains of mature insulin and the C peptide, which will also be secreted with the insulin. The insulin-zinc-calcium complexes form insoluble crystals within the granule The insulin-containing secretory granules are then translocated across the cytosol to the inner surface of the plasma membrane. Translocation occurs initially by attachment of the granules to Kinesin-1, which motors along microtubules, and then by attachment to Myosin Va, which motors along the microfilaments of the cortical actin network. A pancreatic beta cell contains about 10000 insulin granules of which about 1000 are docked at the plasma membrane and 50 are readily releasable in immediate response to stimulation by glucose or other secretogogues. Docking is due to interaction between the Exocyst proteins EXOC3 on the granule membrane and EXOC4 on the plasma membrane. Exocytosis is accomplished by interaction between SNARE-type proteins Syntaxin 1A and Syntaxin 4 on the plasma membrane and Synaptobrevin-2/VAMP2 on the granule membrane. Exocytosis is a calcium-dependent process due to interaction of the calcium-binding membrane protein Synaptotagmin V/IX with the SNARE-type proteins.More...
The translation initiation complex forms when the 43S comple......
The translation initiation complex forms when the 43S complex binds the mRNA that is associated with eIF4F, eIF4B and eIF4H. eIF4G in the eIF4F complex can directly contact eIF3 in the 43S complex. eIF1A is necessary for the formation of this complex.More...
Two transcription factors, PDX1 and HNF1A, play key roles in......
Two transcription factors, PDX1 and HNF1A, play key roles in maintaining the gene expression pattern characteristic of mature beta cells in the endocrine pancreas. Targets of these regulatory molecules include genes encoding insulin, the GLUT2 glucose transporter, the liver-.More...
Binding of the methionyl-tRNA initiator to the active eIF2:G......
Binding of the methionyl-tRNA initiator to the active eIF2:GTP complex results in the formation of the ternary complex. Subsequently, this Met-tRNAi:eIF2:GTP (ternary) complex binds to the complex formed by the 40S subunit, eIF3 and eIF1A, to form the 43S complex.More...
Protein metabolism comprises the pathways of translation, po......
Protein metabolism comprises the pathways of translation, post-translational modification and protein folding.More...
The virus particle initially associates with a human host ce......
The virus particle initially associates with a human host cell by binding to sialic acid-containing receptors on the host cell surface. The bound virus is endocytosed by one of four distinct mechanisms. The low endosomal pH sets in motion a number of steps that lead to viral membrane fusion mediated by the viral hemagglutinin (HA) protein, and the eventual release of the uncoated viral ribonucleoprotein complex into the cytosol of the host cell. The ribonucleoprotein complex is transported through the nuclear pore into the nucleus. Once in the nucleus, the incoming negative-sense viral RNA (vRNA) is transcribed into messenger RNA (mRNA) by a primer-dependent mechanism. Replication occurs via a two step process. A full-length complementary RNA (cRNA), a positive-sense copy of the vRNA, is first made and this in turn is used as a template to produce more vRNA. The viral proteins are expressed and processed and eventually assemble with vRNAs at budding sites within the host cell membrane. The viral protein complexes and ribonucleoproteins are assembled into viral particles and bud from the host cell, enveloped in the host cell's membrane. This release contains a framework for the further annotation of the viral life-cycle.More...
Protein synthesis is accomplished through the process of tra......
Protein synthesis is accomplished through the process of translation of an mRNA sequence into a polypeptide chain. This process can be divided into three distinct stages: initiation, elongation and termination. During the initiation phase, the two subunits of the ribosome are brought together to the translation start site on the mRNA where the polypeptide chain is to begin. Extension of the polypeptide chain occurs when a specific aminoacyl-tRNA, as determined by the template mRNA, binds an elongating ribosome. The protein chain is released from the ribosome when any one of three stop codons in the relevant reading frame on the mRNA is reached. Individual reactions at each one of these stages are catalyzed by a number of initiation, elongation and release factors, respectively.More...
The normal development of the pancreas during gestation has ......
The normal development of the pancreas during gestation has been intensively investigated over the past decade especially in the mouse. Studies of genetic defects associated with maturity onset diabetes of the young. During embryogenesis, committed epithelial cells from the early pancreatic buds differentiate into mature endocrine and exocrine cells. It is helpful to schematize this process into four consecutive cellular stages, to begin to describe the complex interplay of signal transduction pathways and transcriptional networks. The annotations here are by no means complete - factors in addition to the ones described here must be active, and even for the ones that are described, only key examples of their regulatory effects and interactions have been annotated. It is also important to realize that in the human, unlike the mouse, cells of the different stages can be present simultaneously in the developing pancreas and the linear representation of these developmental events shown here is an over-simplification of the actual developmental process. The first stage of this process involves the predifferentiated epithelial cells of the two pancreatic anlagen that arise from the definitive endoderm at approximately somite stages 11-15 and undergo budding from somite stages 20-22. This period corresponds to gestational days 8.75-9.5 in the mouse, and 26 in the human. Pancreatic buds subsequently coalesce to form a single primitive gland, while concomitantly a ductal tree lined by highly proliferative epithelial cells is formed. A subset of such epithelial cells is thought to differentiate into either endocrine or acinar exocrine cells. A third cellular stage is defined by the endocrine-committed progenitors that selectively express the basic helix-loop-helix transcription factor NEUROG3. NEUROG3 is known to activate a complex transcriptional network that is essential for the specification of endocrine cells. Many transcription factors that are activated by NEUROG3 are also involved in islet-subtype cellular specification and in subsequent stages of differentiation of endocrine cells. This transient cellular stage thus leads to the generation of all known pancreatic endocrine cells, including insulin-producing beta-cells, and glucagon-producing alpha cells, the final stage of this schematic developmental process. The diagram below summarizes interactions that take place between transcription factors and transcription factor target genes during these cellular stages, and shows cases where there is both functional evidence that a transcription factor is required for the target gene to be expressed, and biochemical evidence that this interaction is direct. We also describe instances where a signaling pathway is known to regulate a transcription factor gene in this process, even if the intervening signaling pathway is not fully understood.More...
Gene Expression covers the process of transcription of mRNA ......
Gene Expression covers the process of transcription of mRNA genes, the processing of pre-mRNA, and its subsequent translation to result in a protein. The expression of non-protein-coding genes is not included in this section yet. However, the transcription of RNAs other than mRNA is described in the section on transcription; in the sections 'RNA Polymerase I Transcription', and 'RNA Polymerase III Transcription'.More...
RPS21 related interactors from protein-protein interaction data in HPRD (count: 2)