| File | Title | Manuscript Id |
|---|
| Chapter Introduction | life11e_ch43_1.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_1_dlap.xml | 57e53d39757a2ea02d000000 |
| key concept 43.1 Fertilization Activates Development
| life11e_ch43_2.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_2_dlap.xml | 57e53d39757a2ea02d000000 |
| The sperm and the egg make different contributions to the zygote
| life11e_ch43_3.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_3_dlap.xml | 57e53d39757a2ea02d000000 |
| Fertilization sets the stage for determination
| life11e_ch43_4.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_4_dlap.xml | 57e53d39757a2ea02d000000 |
| recap | life11e_ch43_5.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_5_dlap.xml | 57e53d39757a2ea02d000000 |
| key concept 43.2 Mitosis Divides Up the Early Embryo
| life11e_ch43_6.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_6_dlap.xml | 57e53d39757a2ea02d000000 |
| Cleavage produces a multicellular embryo
| life11e_ch43_7.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_7_dlap.xml | 57e53d39757a2ea02d000000 |
| Cleavage in mammals is unique
| life11e_ch43_8.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_8_dlap.xml | 57e53d39757a2ea02d000000 |
| The fates of blastomeres depend on the cytoplasm they receive during cleavage
| life11e_ch43_9.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_9_dlap.xml | 57e53d39757a2ea02d000000 |
| Reproductive germ cells are determined early in cleavage
| life11e_ch43_10.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_10_dlap.xml | 57e53d39757a2ea02d000000 |
| recap | life11e_ch43_11.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_11_dlap.xml | 57e53d39757a2ea02d000000 |
| key concept 43.3 Gastrulation Generates Multiple Tissue Layers
| life11e_ch43_12.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_12_dlap.xml | 57e53d39757a2ea02d000000 |
| Invagination at the vegetal pole initiates gastrulation in the sea urchin
| life11e_ch43_13.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_13_dlap.xml | 57e53d39757a2ea02d000000 |
| Frog gastrulation begins at the gray crescent
| life11e_ch43_14.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_14_dlap.xml | 57e53d39757a2ea02d000000 |
| The dorsal lip of the blastopore organizes the formation of the amphibian embryo
| life11e_ch43_15.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_15_dlap.xml | 57e53d39757a2ea02d000000 |
| Transcription factors and growth factors underlie the organizer’s actions
| life11e_ch43_16.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_16_dlap.xml | 57e53d39757a2ea02d000000 |
| Properties of organizer cells change as they migrate from the dorsal lip
| life11e_ch43_17.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_17_dlap.xml | 57e53d39757a2ea02d000000 |
| The amount of yolk influences gastrulation
| life11e_ch43_18.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_18_dlap.xml | 57e53d39757a2ea02d000000 |
| Gastrulation in mammals is similar to avian gastrulation
| life11e_ch43_19.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_19_dlap.xml | 57e53d39757a2ea02d000000 |
| How is bilateral symmetry broken?
| life11e_ch43_20.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_20_dlap.xml | 57e53d39757a2ea02d000000 |
| recap | life11e_ch43_21.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_21_dlap.xml | 57e53d39757a2ea02d000000 |
| key concept 43.4 Organs Develop from the Three Germ Layers
| life11e_ch43_22.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_22_dlap.xml | 57e53d39757a2ea02d000000 |
| The organizer sets the stage for organogenesis
| life11e_ch43_23.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_23_dlap.xml | 57e53d39757a2ea02d000000 |
| Body segmentation is an early feature of vertebrate development
| life11e_ch43_24.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_24_dlap.xml | 57e53d39757a2ea02d000000 |
| Hox genes control differentiation along the anterior–posterior axis
| life11e_ch43_25.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_25_dlap.xml | 57e53d39757a2ea02d000000 |
| recap | life11e_ch43_26.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_26_dlap.xml | 57e53d39757a2ea02d000000 |
| key concept 43.5 Extraembryonic Membranes Nurture Avian and Mammalian Embryos
| life11e_ch43_27.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_27_dlap.xml | 57e53d39757a2ea02d000000 |
| Birds develop four extraembryonic membranes
| life11e_ch43_28.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_28_dlap.xml | 57e53d39757a2ea02d000000 |
| The mammalian placenta forms from extraembryonic membranes
| life11e_ch43_29.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_29_dlap.xml | 57e53d39757a2ea02d000000 |
| Human gestation is divided into trimesters
| life11e_ch43_30.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_30_dlap.xml | 57e53d39757a2ea02d000000 |
| recap | life11e_ch43_31.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_31_dlap.xml | 57e53d39757a2ea02d000000 |
| Investigating Life | life11e_ch43_32.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_32_dlap.xml | 57e53d39757a2ea02d000000 |
| Chapter Summary
| life11e_ch43_33.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_33_dlap.xml | 57e53d39757a2ea02d000000 |
| Apply What You’ve Learned
| life11e_ch43_34.html | 57e53d39757a2ea02d000000 |
| DLAP questions | life11e_ch43_34_dlap.xml | 57e53d39757a2ea02d000000 |