回复 1#hualin840518. l' F1 R! w( l
是这个么?[attach]4700[/attach]作者: hualin840518 时间: 2010-3-5 09:15
回复 15#hansey: \% @' a! {7 ^( ^* v
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谢谢! Q/ N& \' c, C B, S8 z
有没有全书的完整版啊 8 O9 B- L- f# G3 ?, ~这只是个书的介绍!作者: ligangcw 时间: 2010-3-5 14:32
哦噢!作者: singtom 时间: 2010-3-7 19:18
可是这个版本(如果是,我就给你下):4 W; F5 v* t8 X. S$ D, O
Table of Contents& @% _, @$ Q7 _$ m0 x5 t; L
6 e/ S' r% G- [2 T: YI. Principles of Developmental Biology % F& R, k$ @. o/ `; B 1 z/ t/ x* \ p& \1. Developmental biology: The anatomical tradition$ X, w" z5 A% U% C/ q
New techniques of mathematical modeling of development* c: U5 |# M* t" E7 I& U
2. Life cycles and the evolution of developmental patterns 9 \$ B7 [' P. \Recent advances in planarian regeneration, F" R4 b7 W) ^9 i
3. Principles of experimental embryology 4 Q* y+ J( Y+ \$ y- _+ ^$ R8 U4. The genetic core of development \4 b" C, O$ c, [! C. z5. The paradigm of differential gene expression/ {, i5 p1 E- |3 M5 A6 G% @- F& B
Histone modifications V, x$ U' N* t2 H! S" x
MicroRNAs - |7 c' j( A8 K. o2 o0 UPioneer transcription factors1 j k" _8 f! A, x
Mammalian cloning and methylation patterns" ?: I) G; v$ h0 |
6. Cell–cell communication in development 4 @+ R( S$ z% a' m; G* XStem cell specification and stem cell niches 6 P: Y% c9 V" D) [0 c& B4 `# FMorphogenetic regulation by cadherins # B L% F" Y6 ^ b" J, MNoncanonical Wnt pathways , z% q& U9 c% e3 I& n8 T0 wDependence receptors and apoptosis / e* }$ B" C8 K! x r/ ^) PCommunity effect and autocrine factors 9 ]# G: b! j, C; ]5 c- w+ T1 z 4 r( o, P& }2 ], D9 C$ G: z0 `II. Early Embryonic Development- o5 W7 e" [1 o' n5 V* r- C5 y
/ U m, g1 j5 m3 C7. Fertilization: Beginning a new organism , j: x+ E0 v& h a5 r" vCortical granule components0 b7 ?* n: b& }7 h* o
New mammalian sperm–egg binding model3 R" G) H, V, g2 d( o, B: w
Mammalian sperm chemotaxis and thermotaxis! i! D) } n. j: v
Mechanisms of sea urchin sperm chemotaxis t9 {. G5 A; B8 J9 ^7 a2 ]0 f) lSea urchin bindin receptor6 c- } l7 S% C- i* X
Oocyte translation inhibitors and their removal# P; \( y8 T$ h4 u9 G; M* P
New hypotheses of sperm activation & o3 I4 q1 l& fMammalian sperm–egg fusion 8 F$ Y( u# h% E5 J/ q" f8. Early development in selected invertebrates" R1 G. b8 I: c1 g7 B, A' c
Wnt and Nodal in sea urchin axis specification , R& _2 e1 z* d4 ?4 a" [Coiling genetics of snail embryos/ h# z- [" _! M) M
Functions of tunicate yellow crescent3 \6 ~# n9 y( D) |; K: w# `
Roles of FGFs in tunicate development+ D8 ?+ S3 p1 N3 p7 \/ f; e
Tunicate heart development 8 u5 s5 o3 M" Q& y9. The genetics of axis specification in Drosophila ) Y8 X0 ?" G4 u7 Q: _3 yFGF signals and Drosophila mesoderm formation # A7 m, C( Z3 z/ _3 {& ~2 ETransport of Nanos and Bicoid messages to opposite ends of the fly oocyte* w6 G" }5 V; F
New model for gap protein stabilization6 G( C, w! F Z: d
10. Early development and axis formation in amphibians8 |, R; H" y, l- e. y. B" J
New models for organizer formation in Xenopus% C" B1 e6 G* Y G& S# F$ E& F; r
New model for mesoderm specification in Xenopus 0 k w* Y* ^9 P9 z& G11. The early development of vertebrates: Fish, birds, and mammals$ Z. Z) u4 p/ @$ R
Maternal effect mutations in zebrafish) h* J" n$ R3 N6 Y+ |& V
Neurulation in zebrafish / O- t! q# m f$ ~* m+ z0 KRetinoic acid in anterior–posterior axis specification in chordates 7 A6 o, x' X1 H# F$ NCiliary movements and left–right axis specification in vertebrates/ v" g( A2 m+ P( _" ]
Role of Cerberus in chick head formation 6 J0 A1 h! T1 h6 ~5 lMesoderm specification and migration in chick gastrulae- r. z0 z) n$ G! I3 |
FGF and cell fate in chick and mammalian epiblasts1 P1 x9 _% N4 N
Induction of pluripotency in mammalian inner cell mass blastomeres % o. g c8 l+ n, [& eHomeotic transformation in mammals due to total Hox paralog knockouts : W0 l- ~" [1 IControversy over blastocyst polarity in mammals ~# m6 d8 y0 R! Z* E) R/ s# \- I1 LFolate receptors and teratogens affecting neurulation 6 @. J% Y2 [" o& E 7 J+ i% U9 _2 F1 oIII. Later Embryonic Development 9 R& i; V* `2 Y: { p! S& n+ r6 }6 a
12. The emergence of the ectoderm: Central nervous system and epidermis I. k( a6 d% cGenes specifying neural fate1 f$ L: ^" L4 c. p
Human-specific genes specifying brain growth# K: Z3 s4 w- u! M
Progressive myelination of the human brain) Z c& B i. W. U. ]
Neural stem cells * y4 E5 o0 I; e: `* W8 K. c1 BEye development and blind cave salamanders, z$ Z3 T5 p2 @
Skin, hair, and pigment stem cells + y% _5 ?: m# m. i! {+ |. g13. Neural crest cells and axonal specificity" y' z1 l, O4 B- t3 W
Neural crest cell specification and migrations/ {/ {, r# ]3 |3 w& O( `
Head vs. trunk neural crest specification & e( e' b A# |Neural crest-endoderm interactions forming facial structures " D) N1 s& E7 z& }5 f" i- c0 NPlacode specification and separation * x- ^, m/ T) G- {3 o2 |Tooth development and evolution 6 X6 y* F0 Z1 _9 F- l* x% S/ ISemaphorins, Robo, and ephrins in neural patterning7 X) r3 E( z& B O# g
14. Paraxial and intermediate mesoderm% i ]! Q2 s0 T: ]
Specification of paraxial and intermediate mesoderm c: Q- {# ~( a: {# x% w
Epithelialization of somites0 W4 R7 L% h6 v
The syndetome—where tendons arise # v* z- o; ^. F. RFGFs, Notch, and Wnt in somite specification and separation! [9 i: C2 a" F$ [. @: p; e
The primaxial and abaxial musculature C+ J4 D. j' M% [% rNew sources of muscle precursor cells ) t0 t0 v) ~2 a/ APathways of skeleton formation , z0 U) F$ O! ^8 x) a' R9 xRegulating ureteric bud branching5 i. z3 g7 I" g' y" t
Wnt and FGF proteins regulating nephron formation 1 ~0 L+ D. V+ ]15. Lateral plate mesoderm and endoderm/ k+ j- `5 L9 @
Cloaca formation . ^ J2 C( }3 u. e2 AHeart cell specification # N# ~3 k$ j9 K- d- B1 o: [Tbx genes, retinoic acid and heart chamber formation 5 Y; ?* {/ m. [/ a' M7 z# y' yHeart valve development * C) R9 \$ ~( N. u IHematopoietic stem cells and their derivatives& d" h+ e/ Q. _/ d, z4 ~1 d3 {" X
Lymphatic development ! G# I9 D# o$ y! b# w" {# n4 fInduction of arteries by neurons( B' t7 Z2 x5 _- j8 a
Placenta as source of blood stem cells8 M- c, Z+ J- c T
Adult blood stem cell niches ( U7 i# J# v0 }( L& Q1 ^3 g. ZEndoderm specificity 6 Q/ C2 L4 V8 \9 W7 DPancreas vs. liver development * A0 D4 G% j: RFate mapping pancreatic cells- v7 _1 w6 |+ z' A9 x g
16. Development of the tetrapod limb: _$ {! o. ^- z; Q4 O8 M5 }0 }" w" v
Hox code of limb development . T# K5 g) M9 ~. z0 ^/ fSpecification of the digits by hedgehog proteins and HoxD genes " w* m# `9 n6 Y' G; mControversy over digit identities in dinosaurs and birds! d9 G' a, K* r' T9 s
Getting limbs from fins 4 u O" s% H' h17. Sex determination5 @( `6 ^1 b, S) F2 t5 \( Q% m7 D
Timing and gene expression in mammalian sex determination9 k# P: X9 R9 ~ A5 @3 k
Brain sex determination pathways in vertebrates and flies/ ~! ?; ?) e4 n6 m1 n, z
Hormone disruptors and sex determination problems W# w7 t) K2 d# `; E9 M8 f) IDosage compensation and sex determination5 R( @$ E# I+ Y) [+ k% L
Temperature-dependent sex determination in turtles : Z2 M% p1 M, K7 V1 v18. Metamorphosis, regeneration, and aging7 H) Z2 J3 W9 r/ c, a* K
Molecular mechanisms of amphibian metamorphosis # F; u2 ^6 d C$ a5 aEcdysone receptors and the response to molting hormone + n) k4 w8 q+ p+ x( g: p/ [+ XCompartment formation in the wing imaginal disc3 y4 D8 Y4 G' @
Why can’t we regenerate our limbs? Z$ r2 V* z6 K' Y* }" J( [- j! P
Neuron- and mesenchyme-dependent stages of limb regeneration 3 d* Z+ V9 m! V8 U2 ?Specification of limb regions by transcription factors during regeneration- d+ K# k' A9 E- \2 f
Mitochondrial control of aging U' Q0 K: W) LInsulin pathway control of aging and possible relation to oxygen radicals " A" G7 S' T/ ^' I“Ageless” animals and environmental control of aging ; L* Y$ S( e* z8 D19. The saga of the germ line ' @/ l+ _8 B) M$ w+ k: MGenetic specification of germ-line cells in Drosophila and vertebrates % n! R/ i" J' u5 |: E9 uComponents of the Drosophila germ plasm 0 s8 F3 b" O6 p g: g# N( lEgg and sperm stem cell niches in Drosophila5 X* v' V4 B* T$ I
Migration of primordial germ cells in mammals, chicks, and flies 4 T- {7 o: h' u( C* PDetermination of meiosis and mitosis in C. elegans 6 L5 T2 T# _' E3 y7 M/ ZRetaining mammalian spermatic stem cells # Z8 q! O3 \$ {1 i# gIV. Ramifications of Developmental Biology( v% i5 T5 E+ M4 Z/ G% k1 i: ^
20. An overview of plant development ' ?& n- `4 L& R, F) C7 g* i* dGamete formation and pollen tube guidance4 t, t$ v! o; S6 P# p) e" o
Maternal effects and embryo development ( V* T4 E+ s \9 ]* j- S3 KRadial and axial patterning 4 `( B9 n/ V7 j0 p& DNew model for auxin specification of polarity 8 w3 y1 u, V- |' }! U" j! j% wRoles of microRNAs in plant development , x5 h5 v& s8 VDorsal–ventral leaf patterning0 ?/ i# }3 J; W- H/ c& t9 x% f
Long-distance RNA transport and flowering- e# C' ^& ^0 U. X
Floral meristem specification & X, i. E& p5 V2 l21. Medical implications of developmental biology8 E' w8 n5 ^* ~. t8 B) \
Mechanisms of alcohol teratogenesis , W6 l w7 U' Q$ r. \3 oEffects of endocrine disruptors on human development e% S; {* |/ |: ANutritional effects of gene methylation and disease susceptibility - Q+ M( i, a! f1 ?- K# X% UCancer as a disease of development! I' i& F; \* E7 _$ U7 k) F) M
Cancer stem cell hypothesis & Q: O, ?6 O% z6 O. @Developmental approaches to cancer therapy @. |9 E1 g: ]0 l8 |1 G( y# U
Stem cell therapeutics ( \7 S9 S5 G1 @: o( wRegenerating human limbs and neurons 5 A4 G0 K7 Q: y9 K22. Environmental regulation of animal development; j& A7 t5 h9 J+ w
Molecular bases for environmental regulation of gene expression 1 i6 q! B, ` v' K B# q, k- f6 _• Importance of symbionts in mammalian gut and immune system / ^' u) d$ i% V/ A; [( o$ qdevelopment" g6 W3 `$ b+ c2 u1 |
Signaling from fetal mammalian lung to initiate labor 6 z, U( T; ?( c6 g* W9 Y6 Q- vThe role of nutrition in the development of the dung beetle # ?& ?/ ?( y% A6 DPredator-induced polyphenism and toxicity testing* M- R4 ^7 T: y( \/ G" C5 q
Genetic assimilation of environmentally induced traits S- P6 c2 i' v; O1 K6 K. n
23. Developmental mechanisms of evolutionary change0 U) J6 p5 [# U7 b; k: _
Developmental modularity and evolution (stickleback studies) V4 k i9 D# dEvolution by heterochrony, heterotopy, heterometry, heterotypy! c( L# u2 \+ K5 j% x
BMPs and Darwin’s finches ' g* ^) x3 G' H# @; m+ \Origin of neural crest cells and the origin of jaws $ |; y) Y& z' e3 O: N4 J1 U7 UThe search for the Urbilaterian ancestor作者: hualin840518 时间: 2010-3-8 08:24
回复 19#singtom 3 A3 }0 I- C% G. N7 ~8 o8 V : u! I$ G! L" c) k: g! K2 V, b / |+ o) c# d/ u A5 |, @. R 目录是对的,可是内容还是第六版的,这个电子书是我制作的,上传在论坛,现在还可以下到!作者: singtom 时间: 2010-3-8 09:08
回复 20#hualin840518 , f7 ]5 l" J# N6 c, U P- P3 i3 j1 R& n# D8 h/ i
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没下载那个目录的,上传的附件我查验过了,是第八版作者: singtom 时间: 2010-3-8 09:21
回复 20#hualin840518' Q, k1 U+ o" ?1 N5 ~; `
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参见图片! v) D0 R' I6 \8 }5 a+ K5 w
[attach]4753[/attach]作者: 细胞海洋 时间: 2010-3-8 10:22
[attach]10588[/attach][attach]10590[/attach][attach]10591[/attach][attach]10597[/attach][attach]10598[/attach]回复 1#hualin840518 `$ Z* P' _' f6 n7 K5 g
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以上是我好不容易才找到的一个版本,说是Eighth版本,请楼主鉴定是不是了。作者: zsutx2005 时间: 2010-7-15 18:26
回复 8#jxjia; |' K" n T- o. y+ X: Q/ b: P
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请问你的版本是比较标准的电子版还是别人从网上复制下来制作的PDF版呢?作者: zsutx2005 时间: 2010-7-15 18:28