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Helmreich E.J.M. — Biochemistry of Cell Signalling
Helmreich E.J.M. — Biochemistry of Cell Signalling



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Íàçâàíèå: Biochemistry of Cell Signalling

Àâòîð: Helmreich E.J.M.

Àííîòàöèÿ:

The Biochemistry of Cell Signalling deals in depth with the principles of cell signalling, concentrating on structure and mechanism. It will serve as a reliable map through the maze of cell signalling pathways and help the reader understand how malfunctions in these pathways can lead to disease. The book is divided into four parts. Part 1 describes the machinery of signal transduction starting with the properties of signals, receptors (including receptor activation), regulators, and the molecules that link receptor and regulator. The design of signalling cascades is explained by describing central signalling pathways: the Ras-regulated MAPK and PI-3 pathways; the Rho/Rac/Cdc 42 pathway controlling chemotaxis and regulating the cytoskeleton; the G protein coupled receptor cascades in response to sensory and hormonal signals; signalling by TGF-ss in morphogenesis; cytokine signalling that controls haemopoiesis. There is also a discussion of the insulin response. As phosphorylation - dephosphorylation is involved in nearly all cellular regulatory processes, Part 1 concludes with a synopsis of its role in signalling. Part 2 describes the implementation of the signalling cascades focusing on the effect on gene transcription. After a brief description of the transcriptional machinery the regulation of transcription by cytokines and growth factors in the control of cell growth and the mechanisms and sites of control are discussed in detail. The regulators discussed include Jun/Fos, NF-AT, SREBPs, and STATs. The next two chapters cover gene regulation by nuclear receptors, including both the steroid hormone receptors and non-steroid nuclear receptors e.g. the retinoic acid receptors RAR and RXR. Part 3 studies the global cellular regulatory programs for the control of cell growth and proliferation. The first chapter concerns the regulation of the cell cycle and the role of the cyclin-dependent kinases, telomerase, Ran, and cell cycle checkpoints. The next topic is the signalling pathways in apoptosis: the TNF-receptor family death receptors, caspases, and the intracellular apoptosis signals and the role of apoptosis in the lifecycle of cells. Part 3 ends with a discussion of the signal pathways involved in the immune response, focusing on the involvement of cell-cell interactions. Part 4 considers loss of regulatory control and its consequences with respect to the molecular basis of cancer. It first describes the cellular regulatory proteins that have oncogenic potential, how they can become oncogenic and cause the transformation of normal cells to cancerous cells. Next is an analysis of the loss of developmental controls, the APC protein, ss-catenin, and the Wnt pathway, that lead to mature terminally differentiated cells reverting to immature embryonic cells. The book ends with a summary of the molecular and cellular causes of cancer and an outlook for novel therapies. Throughout the text, the emphasis is on structure and mechanism and is well illustrated with 200 figures. The Biochemistry of Cell Signalling will be an invaluable companion to all graduate students studying cell signalling.


ßçûê: en

Ðóáðèêà: Áèîëîãèÿ/

Ñòàòóñ ïðåäìåòíîãî óêàçàòåëÿ: Ãîòîâ óêàçàòåëü ñ íîìåðàìè ñòðàíèö

ed2k: ed2k stats

Ãîä èçäàíèÿ: 2001

Êîëè÷åñòâî ñòðàíèö: 357

Äîáàâëåíà â êàòàëîã: 22.12.2005

Îïåðàöèè: Ïîëîæèòü íà ïîëêó | Ñêîïèðîâàòü ññûëêó äëÿ ôîðóìà | Ñêîïèðîâàòü ID
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Ïðåäìåòíûé óêàçàòåëü
PDGF (platelet-derived growth factor), signal transduction mechanisms      9t 11—12
PH domain plate      4 (2p) 31—2 35—36
Phosducin plate      12 (7p) 90—91
Phosphatidylinositol 3-kinase pathway      59—60
Phosphatidylinositol 3-kinase pathway, and insulin action      144 145
Phosphatidylinositol 3-kinase pathway, cytosolic kinase functions      123
Phospholipases, control by G proteins      69 70—72
Phosphoprotein phosphatases calcineurin structure plate      13 (7p)
Phosphoprotein phosphatases, localization and targeting      123—127
Phosphorylation cascades, as multi-enzyme organelles      129—130
Phosphorylation cascades, protein kinases      128—129
Phosphorylation cascades, receptor kinases      123
Phosphorylation dephosphorylation, control of signalling pathways      122—123
Phosphorylation dephosphorylation, glycogen phosphorylase a, structure plate      14 (8p)
Phosphorylation dephosphorylation, phosphorylation cascade organization      123—130
Phosphorylation dephosphorylation, regulation of enzymes and signalling pathways      130—135
Phosphotyrosine phosphatases      37—38 41—43
Phosphotyrosine-binding domain      see “PTB domain”
Platelet-derived growth factor (PDGF), signal transduction mechanisms      9t 11—12
Pleckstrin-homology domain      see “PH domain”
PP1 phosphatase      126 127
Programmed cell death      see “Apoptosis”
Prolactin (PRL) receptor, ligand-dependent dimerization      24—25
Protein glycation      138 139
Protein kinases, localization and targeting      128—130
Protein tyrosine phosphatase (PTP)      41—42
Proteinases, and growth factor processing      5—7
Proteolysis, and apoptosis      236—238 239
Proteolysis, regulation of cyclin-dependent kinases      219—220 222—224
Proteomics      186
Proto-oncogenes, and signalling pathways      271—273
Proto-oncogenes, functions      269—271
Proto-oncogenes, transformation to oncogenes      273—276
PTB domain      31—32 35—36 37
Pyk kinases, in Ras/MAP kinase pathway      58—59
Rac GTPase      64—65
Rac GTPase, and cytoskeleton assembly      65—70
Rac GTPase, control of phospholipases      70—72
Raf kinase, in Ras/MAP kinase pathway      57—58
Ran GTPase, and cytokinesis      228
Rap      1
Rap, and G-protein coupled receptor signalling      84—85
Rap, and Rho/Rac/Cdc42 signalling pathways      72—73
Ras GTPase superfamily      64—65
ras oncogene      273 274
Ras, control of activity      46—49 50 123
Ras/MAP kinase pathway      32 33
Ras/MAP kinase pathway, and G-protein coupled receptor signalling      83—85
Ras/MAP kinase pathway, MAP kinases      60—62
Ras/MAP kinase pathway, MAPKKs      60
Ras/MAP kinase pathway, phosphatidylinositol 3-kinases      59—60
Ras/MAP kinase pathway, Pyk kinases      58—59
Ras/MAP kinase pathway, Raf kinase      57—58
Ras/MAP kinase pathway, role in growth and proliferation      62—63
Ras/MAP kinase pathway, specificity      63—64
Rb gene, and cancer      276—277
Rb protein      277—279
Receptor kinases, phosphorylation      123
Receptor protein tyrosine phosphatase (RPTP)      43
Receptor tyrosine kinases (RTKs), signal transduction mechanisms      8—18
Receptors, ligand-dependent dimerization      24—30
Receptors, plasticity      28—30
Receptors, properties      3—5
Retinoblastoma, Rb      276—279
Retinoic acid receptors (RARs), functions      202—203
Retinoic acid receptors (RARs), regulation      206
Retinoic acid receptors (RARs), structure plate      24 (13p) 204—206 206—207
Retinoid receptors (RXRs), functions      203—204
Retinoid receptors (RXRs), structure plate      24 (13p) 204—206 206—207
Retroviruses, and cancer      270—271 299
Rho GTPase      64—65
Rho GTPase, and cytoskeleton assembly      65—70
Rho GTPase, and G-protein coupled receptor signalling      83—84
Rho GTPase, control of phospholipases      70—72
Rhodopsin, activation      85—88
Rhodopsin, in visual response      90—92
RNA polymerase II transcription factors      see “Transcription factors general”
RNA polymerase II, regulation of      158—161
RNA synthesis, role of MAP kinases      62—63
SAM (sterile $\alpha$-motif)      37 38
SAPKs (stress-activated protein kinases)      60
Scatter factor (SF)      9t 18
Second messenger signalling, and G-protein-coupled receptors      plate 10 (6p) plate 78
Self-tolerance, and apoptosis      263
Serine/threonine phosphatases      124—127
Serine/threonine phosphatases, salcineurin structure plate      13 (7p)
Serotonin (5-HT) receptor      77
SH2 domain plate      2 (1p) 31—32 33—34
SH3 domain plate      3 (2p) 31—2 34—35
Shc adaptor protein      31—32
Sheddases, and growth factor processing      5—7
Signal transduction mechanisms      8—14
SMADs      176
SMADs, and TGF-$/beta$ signalling      102—109
SNARE proteins, and insulin action      141 142
Src tyrosine kinases      38—40
Src-homology 2 domain      see “SH2 domain”
Src-homology 3 domain      see “SH3 domain”
SREBPs (sterol regulatory-element-binding proteins)      175—176
stats      176—178 179
STATs, and embryonic development      116—117
STATs, JAK/STAT signalling pathway      111—116
Steel factor      9t 14
Stem cell factor      9t 14
Sterile $\alpha$-motif (SAM)      37 38
Steroid hormone receptors, and developmental control genes      193—195
Steroid hormone receptors, chaperones and chaperonins      197 198
Steroid hormone receptors, control of signalling      199—200
Steroid hormone receptors, ecdysone receptor      192—193
Steroid hormone receptors, ligand structures      195—196
Steroid hormone receptors, oestrogen receptor and breast cancer      197 199
Steroid hormone receptors, receptor classes      190—192
Steroid hormone receptors, structure plate      24 (13p) 196 201t
Sterol regulatory-element-binding proteins (SREBPs)      175—176
Stress activated transcription factors      179—180
Structure plate      5 (3p)
T cells, activation      250—251
T cells, and antigen presentation plate      28 (15p) 251—252 254
T cells, antigen receptors plate      29 (16p) 255—257
T cells, differentiation      252—254 255t
T cells, selection      252
T cells, signalling pathways      258—259
T cells, survival and death      261—263
Tamoxifen, structure      199
Taste transduction, G protein functions      96—97
TATA box plate      19 (11p) 164
TATA box plate, and initiation of transcription      158—159 160
TATA-box-binding protein (TBP)      164
TATA-box-binding protein (TBP), and initiation of transcription      158—159
TATA-box-binding protein (TBP), structure      plate 19 (l1p) plate plate
Telomerase, and cancer      297—299
Telomerase, and chromosome duplication      225 226
Teratocarcinoma      284—285
TGF-$\alpha$, processing      7
TGF-$\alpha$, signal transduction mechanisms      9t 10
TGF-$\beta$, and morphogenesis      108—109
TGF-$\beta$, growth factor superfamily      102—105
TGF-$\beta$, receptors      102—105
TGF-$\beta$, signalling pathway      105—107
Thyroid hormone receptors      200—202
Thyroid hormone receptors, structure plate      24 (13p)
TNF receptors, and apoptosis      235—236 237
TNF receptors, oligomerization      27—28
TNF-$\alpha$ converting enzyme (TACE)      5—6
TNF-$\alpha$, cross-talk with insulin signalling pathways      148
TNF-$\alpha$, processing      7
TNF-$\beta$, processing      7
Tolerance, of self      263
Transcription factors      179—180
Transcription factors, and cancer      273
Transcription factors, control of      180—185
Transcription factors, CREB      174
Transcription factors, GATA      175
Transcription factors, general plate      20 (11p) plate 158-61 164-5
Transcription factors, Jun/Fos      172—174
Transcription factors, MAD proteins      176
Transcription factors, NF-$\kappa$B      175
Transcription factors, NF-$\kappa$B/p52/DNA complex plate      23 (13p)
Transcription factors, NF-AT plate      23 (13p) 174—175
Transcription factors, NF-AT transcription factor      174—175
Transcription factors, NF-xB      175
Transcription factors, SMAD proteins      176
Transcription factors, SREBPs      175—176
Transcription factors, STAT proteins      176—178 179
Transcription factors, stress activated transcription factors      179—180
Transcription, DNA-binding proteins      plate 15 (9p) plate plate plate plate plate plate 161-4
Transcription, initiation      157—161
Transcription, pre-initiation complex structure      164—165
Transducin      86—87
Transducin, G protein $\alpha\beta\gamma$-holocomplex structure plate      7 (4p)
Transducin, G-$\alpha$ subunit structure plate      6 (4p)
Transforming growth factors      see “TGF-$\alpha$ “TGF-
Tumour necrosis factors      see “TGF-$\alpha$ “TGF-
Tumour-suppressor genes, adenomatous polyposis coli {APC) gene      286—287
Tumour-suppressor genes, p53      279 280—282
Tumour-suppressor genes, Rb gene      276—277
Tyrosine kinases plate      5 (3p) 37—40
Tyrosine kinases plate, and cancer      272
Vascular endothelial growth factor (VEGF), processing      7—8
Vascular endothelial growth factor (VEGF), signal transduction mechanisms      9t 11
Vav adaptor protein      31—32
Visual response, G protein functions plate      12 (7p) 90—92
Vitamin $D_3$, structure      195
Vitamin A receptor      202—203
Wiskott — Aldrich syndrome protein (WASP)      73
Wnt signalling pathway, and cancer      289—290
Zinc finger motif      162
Zinc finger motif, structure plate      16 (9p)
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