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<Biology> 2007. 9. 12. Development (ch.19,20,21) Sung Su Yea Dept. of Biochemistry College of Medicine, Inje Univ. 19 Differential Gene Expression in Development • The Processes of Development • The Role of Differential Gene Expression in Cell Differentiation • The Roles of Cytoplasmic Segregation and Induction in Cell Determination • The Role of Pattern Formation in Organ Development • The Role of Differential Gene Expression in Establishing Body Segmentation Figure 19.1 Stages of Development 19 The Processes of Development • Development(발달) is a series of progressive changes in shape, form, and function that occur during an organism’s life cycle. • The earliest stage is called the embryonic stage. • Embryos(배) typically acquire food directly or indirectly from a parent. • Embryonic stages precede birth, and development continues until death. • Development consists of growth(생장), differentiation(분화), and morphogenesis(형태형성). 19 The Processes of Development • Growth occurs by cell division and/or expansion. • Repeated mitotic cell divisions increase cell number. • An animal embryo may consist of thousands of cells before it becomes larger. • Differentiation is the process in which cells become specialized structurally and functionally. • When the embryo is small, each cell has the potential to develop in many different ways. • As development proceeds, the possibilities available to individual cells narrow, until each cell’s fate is determined and the cell has differentiated. • Morphogenesis is the shaping of the multicellular body and its organs. • Morphogenesis results from pattern formation, the organization of differentiated tissues into specific structures. • Animal cells can move, which is important during morphogenesis. • Programmed cell death is essential in the orderly development. • Staining early embryo cells can produce fate maps revealing which adult structures derive from which part of the embryo. Figure 19.2 Developmental Potential in Early Frog Embryos 19 The Processes of Development • Moving a section of cells from a region of an early frog embryo to another region causes the cells to differentiate appropriately for the new—not the old—location. • Cells do not generally maintain this developmental plasticity. • Later in development, transplanted tissue from an embryo develops into the original type of tissue, regardless of its new location. At this point the cells are said to be determined. • Determination(결정) is the commitment of a cell to a particular fate and is influenced by the extracellular environment and cell contents acting on the cell’s genome. • Determination is followed by differentiation. 19 The Role of Differential Gene Expression in Cell Differentiation • Differentiation results from differential gene expression. • The fertilized egg is a totipotent cell. That is, it can give rise to all other cell types of the organism. • As development proceeds, cells lose their totipotency and become determined, and then differentiate. • In some cases, differentiation is irreversible. • Red blood cells lose their nuclei as they mature. • Sometimes differentiation is reversible. • In general, differentiation in plant cells can be reversed more easily than differentiation in animal cells. • A carrot root cell can be tricked into forming a whole new plant. • The new plant is called a clone, because it is genetically identical to the original plant. • The ability to generate an entire plant from a single cell is invaluable to biotechnology. 19 The Role of Differential Gene Expression in Cell Differentiation • Nuclear transplant experiments have shown that somatic cells contain the entire genome. • When the nucleus of an unfertilized frog egg is replaced with the nucleus of a somatic cell from an early frog zygote, normal early embryos develop. • These experiments led to two important conclusions: No information is lost in the early stages of embryonic development (a principle known as genomic equivalence(유전체등가성)). The cytoplasmic environment around a nucleus can modify its fate. • In humans, the totipotency of early embryonic cells permits genetic screening and in vitro fertilization: A single cell is removed from an 8-cell human embryo. The cell is tested for harmful genetic conditions. Each remaining cell, being totipotent, can be stimulated to divide and form a normal embryo. 19 The Role of Differential Gene Expression in Cell Differentiation • In 1997, Ian Wilmut and colleagues starved sheep cells of nutrients, which arrested them in the G1 phase. • These cells were fused with enucleated eggs from a different ewe and stimulated to enter the S phase. • The early embryos were transplanted to the womb of a surrogate mother ewe. One lamb, named Dolly, survived to birth. • The ultimate goal of sheep cloning is to develop transgenic (genetically modified) ewes that can produce drugs in their milk. 19 The Role of Differential Gene Expression in Cell Differentiation • Stem cells(줄기세포) are undifferentiated, dividing cells that are found even in adults. • A few examples are those found in bone marrow, skin, and intestine, tissues which need frequent cell replacement. • In the body, stem cells have a limited ability to differentiate, but by manipulating the environment, stem cells can be made to differentiate. • An example of a stem cell differentiation in response to altered environmental signals in mice: Brain stem cells were transplanted to bone marrow, where they became bone marrow stem cells and produced blood cells. The brain stem cells normally differentiate into nerve cells. The reverse experiment resulted in bone marrow cells that differentiated into brain cells. • Stem cells with the greatest totipotency are the cells of early embryos. • Stem cells can be removed from embryos and grown in the lab. They can be induced to differentiate using certain signal molecules. • In the future, manipulation and customizing of embryonic cells in culture may make new disease treatments possible. Figure 19.6 The Potential Use of Embryonic Stem Cells in Medicine (배반포) 19 The Role of Differential Gene Expression in Cell Differentiation • If embryonic stem cells are used to form tissues for a transplantation, genetic differences between the donor and recipient may result in rejection of the transplant. • A procedure called therapeutic cloning has been proposed to address this problem. • This process involves fusing a cell nucleus from the recipient with an enucleated egg cell from a female donor. • These cells can be induced to differentiate into the desired tissue for transplantation without the risk of immune system rejection. • There appears to be genome constancy or equivalence in all somatic cells. 19 The Roles of Cytoplasmic Segregation and Induction in Cell Determination • To understand what determines differential gene expression, myoblasts(근원세포), precursors to muscle cells, have been studied. • MyoD1 is the first gene switched on and it codes for a helix-loop-helix type transcription factor (MyoD1), a DNA-binding protein. • MyoD1 protein binds to the promoters of muscle-specific genes, switching them on. • It also binds to its own promoter, keeping itself in the myoblasts and their descendants. • Chemical signals are involved in cell differentiation. • Two overall mechanisms for producing these signals have been found: Cytoplasmic segregation(세포질분리) occurs when a factor is unequally distributed in the zygote and ends up in some daughter cells but not others. Induction(유도작용) occurs when a factor is produced and secreted by some cells to induce other cells to differentiate. 19 The Roles of Cytoplasmic Segregation and Induction in Cell Determination • Polarity(극성) is an early event in development. • Polarity includes the establishment of the most obvious differentiation, such as anterior–posterior ends and dorsal–ventral surfaces. • When the egg divides, the resulting cells receive unequal amounts of materials that were distributed unevenly in the cytoplasm of the zygote. • These differences in cytoplasmic makeup account for some of the earliest differentiation in embryos. Figure 19.10 Induction during Vulval Development in C. elegans 19 The Role of Pattern Formation in Organ Development • Apoptosis(세포자살) is programmed cell death. • It is caused by the activation of “death” genes. • Of the 1,090 somatic cells produced by C. elegans, 131 cells are programmed to die. • The genes ced-4 and ced-3 appear to control this process. • A third gene, ced-9, codes for an inhibitor of ced-4. Therefore, when cell death is required, ced-3 and ced-4 are active and ced-9 is inactive. • Early human embryos have webs between fingers and toes. • Between day 41 and day 56, the cells of the webbing die, freeing individual fingers and toes. • The enzyme caspase stimulates apoptosis and is homologous to ced-3. • The protein in humans that inhibits apoptosis is bcl-2, which is similar to the protein encoded by the C. elegans gene ced-9. 19 The Role of Pattern Formation in Organ Development • Certain cells in both plants and animals seem to “know” where they are within the organism. This is called positional information. • Positional information usually comes in the form of a signal created by the concentration gradient of a morphogen. • There are two requirements for a signal to be considered a morphogen. It must directly affect target cells. Different concentrations of the signal must cause different effects. • A vertebrate limb develops from a round bud. • The cells that become the bones and muscles of the limb must receive positional information, then organize to shape properly. • A group of cells at the posterior base of the bud makes a morphogen called BMP2, whose gradient determines the anterior–posterior axis of the limb. • Cells that get the highest dose of BMP2 make the thumb, and the smallest dose results in the little finger. 19 The Role of Differential Gene Expression in Establishing Body Segmentation • The adult Drosophila has different types of body segments: The head is composed of several fused segments. There are three different thoracic segments, and eight abdominal segments. The 13 seemingly identical segments of the Drosophila larva correspond to the specialized adult segments. The process of differentiation begins with establishing the polarity of the embryo. • In Drosophila, unequal distribution of morphogens helps establish the basic coordinates. • The morphogen molecules are products of specific maternal effect genes distributed by the mother to the eggs. • The maternal effect genes are transcribed in the ovarian cells that surround the developing egg. • It is their influence that determines the dorsal–ventral and anterior–posterior axes of the embryo. • Two maternal effect genes are bicoid, which controls anterior larval development, and nanos, which controls posterior larval development. Figure 19.14 Bicoid and Nanos Protein Gradients Provide Positional Information 19 The Role of Differential Gene Expression in Establishing Body Segmentation • Segmentation genes influence the number, boundaries, and polarity of the body segments. • Three classes of segmentation genes act one after another: Gap genes organize large areas along the anterior–posterior axis. Pair rule genes divide the embryo into units of two segments each. Segment polarity genes determine the boundaries of anterior-posterior segments. • Finally, homeotic genes are expressed along the length of the body and tell the segments what to become. 19 The Role of Differential Gene Expression in Establishing Body Segmentation • Development is the result of a sequence of changes, each one triggering the next. • The unfertilized egg has stored mRNA that supports protein synthesis during early development. • Cytoplasmic segregation of the stored mRNA provides positional information. • mRNA for Bicoid protein is localized at the end of the egg destined to become the anterior end of the fly. • The Bicoid and Nanos proteins regulate the expression of the gap genes. • Bicoid affects transcription, Nanos affects translation. • High Bicoid at the anterior turns on a gap gene (hunchback), while simultaneously turning off another gap gene (Krüppel). • Nanos at the posterior reduces hunchback. • The gap genes control the expression of pair rule genes. • The pair rule gene products control the segmentation polarity genes. 19 The Role of Differential Gene Expression in Establishing Body Segmentation • The homeotic genes specify the properties of each segment. Mutations in these genes produce changes in segment identity. • One homeotic gene mutant (Antennapedia) causes legs to grow in the place of antennae. Bithorax causes an extra pair of wings to grow. • Antennapedia and bithorax are mutations of adjacent gene clusters. • The genes in these clusters are arranged on the chromosome in the same order as the segments they determine. 19 The Role of Differential Gene Expression in Establishing Body Segmentation • A 180-base-pair DNA sequence that is common to the Antennapedia and bithorax homeotic genes is called the homeobox. • It codes for a 60-amino-acid sequence called the homeodomain, which binds DNA. • The homeodomain has the helix-turn-helix motif. • Each homeodomain recognizes a specific DNA sequence. • Homeotic genes code for transcription factors. 20 Animal Development: From Genes to Organism • Development Begins with Fertilization • Cleavage: Repackaging the Cytoplasm • Gastrulation: Producing the Body Plan • Neurulation: Initiating the Nervous System • Extraembryonic Membranes • Human Development 20 Development Begins with Fertilization • Fertilization is the union of a haploid sperm and egg to form a diploid zygote. • The entry of a sperm into an egg activates the egg metabolically and initiates the rapid series of divisions that produces the multicellular embryo. • In many species, the point of entry of the sperm creates an asymmetry in the radially symmetrical egg. • This asymmetry enables the bilateral body plan to emerge from the radial symmetry of the egg. • Nearly all the cytoplasm of the zygote is from the egg. • The egg cytoplasm is rich in nutrients, ribosomes, mitochondria, and mRNAs. • The sperm’s mitochondria degenerate, so all mitochondria in the zygote come from the egg. • In many species the sperm contributes a centriole(중심립), which becomes the centrosome(중심체) of the zygote. • This produces the mitotic spindles for subsequent cell division. 20 Development Begins with Fertilization • In mammals, certain development genes are active only if they come from a sperm; others are active only if they come from an egg. • This phenomenon is called genomic imprinting(유전체각인). • When cell division occurs, the cytoplasm of the zygote is not distributed equally among the daughter cells. • The uneven distribution of cytoplasmic elements results in signal transduction cascades that orchestrate the three steps of development: determination, differentiation, and morphogenesis. • The dense nutrients accumulate in the vegetal hemisphere, which has no pigment. • The haploid nucleus of the egg is located in the animal hemisphere. The outermost (cortical) cytoplasm of this hemisphere is darkly pigmented. • Specific sperm-binding sites ensure that the sperm always enters the egg at the animal hemisphere. • After fertilization, the cortical cytoplasm rotates toward the site of sperm entry and exposes a less pigmented band opposite the point of sperm entry. This band is called the gray crescent(회색신월환). Figure 20.2 The Gray Crescent 20 Development Begins with Fertilization • Organelles and proteins move from the vegetal hemisphere to the gray crescent. • b-catenin, a transcription factor, and GSK3, a protein kinase are found throughout the cytoplasm, but an inhibitor of GSK-3 is segregated in the vegetal pole. • After sperm entry, the inhibitor moves to the gray crescent and prevents degradation of b-catenin. • The concentration of b-catenin is higher on the dorsal side than on the ventral side of the embryo. • b-catenin is a key player in cell–cell signaling cascade that begins the process of determination. 20 Cleavage: Repackaging the Cytoplasm • Cleavage(난할) is the rapid series of mitotic cell divisions that follows fertilization. • In most animals, there is little cell growth or gene expression. • The embryo becomes a solid ball of small cells called a morula(상실배). • The ball eventually forms a fluid-filled cavity called a blastocoel(포배강), and the embryo is then called a blastula(포배). The individual cells are blastomeres(할구). • The pattern of cleavage is influenced by two factors: the amount of yolk and the formation of mitotic spindles. • Yolk(난황) is the nutrient material stored in an egg. Yolk impedes the formation of a cleavage furrow(난할구). • In embryos with little or no yolk, all daughter cells tend to be of similar size, as in the sea urchin. Figure 20.4 Patterns of Cleavage in Four Model Organisms 20 Cleavage: Repackaging the Cytoplasm • When yolk quantity is larger, asymmetry of cell size is observed. • In the frog egg, the vegetal hemisphere ends up with fewer but larger cells than the animal hemisphere. • Both sea urchins and frogs have complete cleavage(완전난할). • In eggs with a lot of yolk, such as the chicken egg, cleavage is incomplete. The cleavage furrows do not penetrate the yolk. • The embryo forms a disc of cells, called the blastodisc(배반), on top of the yolk. • This type of incomplete cleavage is called discoidal cleavage(반할) and is common in birds, reptiles, and fish. • Another type of incomplete cleavage, called superficial cleavage(표할), occurs in Drosophila and other insects. • The yolk is in the center of insect eggs. In early development, mitosis occurs but not cytokinesis. The nuclei migrate to the periphery of the egg, and the plasma membrane grows inward, partitioning the nuclei into individual cells. • Orientation of the mitotic spindles determine the cleavage planes and arrangements of daughter cells. • If the mitotic spindles form at right angles or parallel to the animal–vegetal axis, a radial cleavage(방사상난할) pattern results. • If the mitotic spindles are at oblique angles to the animal–vegetal axis, the pattern has a twist, and is called spiral cleavage(나선난할). 20 Cleavage: Repackaging the Cytoplasm • In mammals, the first cell division is parallel to the animal–vegetal axis and the second cell division occurs at right angles. This pattern of cleaves is referred to as rotational cleavage(회전난할) and is unique to mammals. • Cleavage in mammals is slow, with divisions occurring 12 to 24 hours apart. • The cell divisions are not synchronous, so the number of cells in the embryo does not follow the regular progression typical of other species. Unlike other animals, gene expression plays a role during mammalian cleavage. • At the 8-cell stage of a mammal embryo, the cells form tight junctions and a compact mass. • At the transition from the 16-cell to 32-cell stage, the cells separate into two masses. • The inner cell mass(세포내괴) develops into the embryo; the outer cells become the trophoblast(영양아층), which becomes part of the placenta. • The trophoblast cells secrete fluid which forms the blastocoel. The embryo is called a blastocyst(배반포). • Fertilization in mammals occurs in the upper oviduct; cleavage occurs as the zygote travels down the oviduct. • When the blastocyst arrives in the uterus, the trophoblast adheres to the uterine wall (the endometrium(자궁내막)), which begins the process of implantation(착상). • Early implantation in the oviduct wall is prevented by the zona pellucida(투명대). • In the uterus, the blastocyst hatches out of the zona pellucida, and implantation can occur. Figure 20.5 The Mammalian Zygote Becomes a Blastocyst 20 Cleavage: Repackaging the Cytoplasm • In all animals, cleavage results in the repackaging of the egg cytoplasm into the cells of the blastula. The cells get different amounts of nutrients and cytoplasmic determinants. • In the next stage, the cells of the blastula begin to move and differentiate. • The cells can be labeled with dyes to determine what tissues and organs develop from each. Fate maps of the blastula are the result. • Blastomeres become determined, or committed to a specific fate, at different times in different animals. • Roundworm and clam blastomeres are already determined at the 8-cell stage. • If one cell is removed, a portion of the embryo fails to develop normally. This is called mosaic development. • Other animals have regulative development. If some cells are lost during cleavage, other cells can compensate. • If blastomeres are separated in an early stage, two embryos can result. • Since the two embryos came from the same zygote, they are monozygotic twins, or genetically identical twins. • Non-identical twins are the result of two separate eggs fertilized by two separate sperm and are not genetically identical. 20 Gastrulation: Producing the Body Plan • Gastrulation(낭배형성) is the process in which a blastula is transformed into an embryo with three tissue layers and body axes. During gastrulation, three germ layers(배엽층) form: The inner germ layer is the endoderm(내배엽) and gives rise to the digestive tract, circulatory tract, and respiratory tract. The outer layer, the ectoderm(외배엽), gives rise to the epidermis and nervous system. The middle layer, the mesoderm(중배엽), contributes to bone, muscle, liver, heart, and blood vessels. • When gastrulation starts, the cells around the vegetal hemisphere flatten. The region invaginates into the blastocoel. • Some cells migrate away from the invaginating region and become primary mesenchyme cells(일차간충직세포). • The invagination becomes the primitive gut or archenteron(원장), and the mesenchyme cells become mesododerm. • Secondary mesenchyme cells break free from the tip of the archenteron. • The secondary mesenchyme cells are attached to the archenteron and send out extensions to the overlying ectoderm. The extensions contract, pulling the archenteron inward. • The region where the archenteron contacts the far side of the sphere becomes the mouth. • The anus forms at the region around the origin of the invagination, called the blastopore(원구). Figure 20.8 Gastrulation in Sea Urchins 20 Gastrulation: Producing the Body Plan • Amphibian gastrulation begins when cells in the gray crescent change shape and bulge inward. These cells are called bottle cells(병세포). • The dorsal lip(원구배순) of the blastopore forms here. Successive sheets of cells move over the lip into the blastocoel in the process of involution(회절). • The first cells form the archenteron. The following cells form the mesoderm. • Cells from the surface animal hemisphere migrate toward the blastopore, a process called epiboly(피포). • Gastrulation is complete when three germ layers have been established. 20 Gastrulation: Producing the Body Plan • Experiments by Spemann and Mangold in the 1920s revealed much about amphibian development. • Spemann constricted salamander embryos with a single human baby hair. • Bisection with a shared gray crescent produced twins, but if just one side received a gray crescent, only that side developed. • Spemann hypothesized that cytoplasmic detrminants in the gray crescent are necessary for gastrulation. 20 Gastrulation: Producing the Body Plan • The next experiments involved transplanting gastrula tissues onto other gastrulas. • In transplants in early gastrulas, the transplanted pieces developed into tissue that were appropriate for the location where they were placed. The fates of the cells had not yet been determined. • If late gastrulas were used, the fates were determined, and transplants did not develop into the same tissue. • Next, they transplanted the dorsal lip of the blastopore onto the belly area of another gastrula. • A second whole embryo developed. • Spemann and Mangold called the dorsal lip the primary embryonic organizer(일차배형성체). 20 Gastrulation: Producing the Body Plan • The role of b-catenin in gastrulation has been verified using molecular biology technology. • When the production of b-catenin is depleted by injection of antisense RNA into the egg, no gastrulation proceeds. • If b-catenin is experimentally overexpressed in another region of the embryo, it can induce a second axis of embryo formation. • The protein b-catenin appears to play critical roles in generating signals that induce primary embryonic organizer activity. 20 Gastrulation: Producing the Body Plan • There are a number of known genes necessary for normal left–right organization of the body. • If one of these genes is knocked out, it can randomize the left–right organization of the internal organs. • The complete details of this mechanism are not fully known. • It appears that a left–right differential distribution of some of the of some of the transcription factors triggers a mechanism that acts very early during gastrulation. • Bird and reptile embryos have modified gastrulation to adapt to huge yolk sizes. • Cleavage forms a blastodisc composed of an epiblast(배반엽상층), which will form the embryo, and a hypoblast(배반엽하층), which gives rise to the extraembryonic membranes. • The blastocoel is the fluid-filled space between the epiblast and the hypoblast. • Gastrulation begins when cells move toward the midline of the epiblast, forming a ridge called the primitive streak(원조). • A primitive groove(원시구) forms along the primitive streak. • The primitive groove becomes the blastopore. Cells migrate through it and become endoderm and mesoderm. • At the forward region of the groove is Hensen’s node(헨센결절), which is equivalent to the dorsal lip of the amphibian blastopore. • Cells that pass over Hensen’s node become determined by the time they reach their destination. Figure 20.13 Gastrulation in Birds 20 Gastrulation: Producing the Body Plan • Mammal eggs have no yolk. • The inner cell mass of the blastocyst splits into an epiblast and hypoblast with a fluid-filled cavity in between. • The embryo forms from the epiblast; the extraembryonic membranes form from the hypoblast. • The epiblast also splits off a layer of cells that form the amnion. The amnion grows around the developing embryo. • Gastrulation is similar to that in birds; a primitive groove forms and cells migrate through it to become endoderm and mesoderm. 20 Neurulation: Initiating the Nervous System • Gastrulation produces an embryo with three germ layers. • Organogenesis(기관형성) occurs next and involves the formation of organs and organ systems. • Neurulation(신경관형성) occurs early in organogenesis and begins the formation of the nervous system in vertebrates. • The first cells to pass over the dorsal lip become the endodermal lining of the digestive tract. • The second group of cells become mesoderm. The dorsal mesoderm closest to the midline (chordomesoderm척삭중배엽) becomes the notochord(척삭). • The notochord is connective tissue and is eventually replaced by the vetebral column. • The chordomesoderm induces the overlying ectoderm to begin forming the nervous system. • Neurulation begins with thickening of the ectoderm above the notochord to form the neural plate(신경판). • Edges of the neural plate thicken to form ridges. Between the ridges a grove forms and deepens. • The ridges fuse, forming a cylinder—the neural tube(신경관). • The anterior end of the neural tube becomes the brain. Figure 20.15 Neurulation in the Frog Embryo 20 Neurulation: Initiating the Nervous System • Body segmentation develops during neurulation. • Blocks of mesoderm called somites(체절) form on both sides of the neural tube. • Somites produce cells that form the vertebrae, ribs, and muscles of the trunk and limbs. They also guide the organization of the peripheral nerves. • When the neural tube closes, cells called neural crest cells(신경능선세 포) break loose; they migrate inward between the epidermis and the somites and under the somites. • The neural crest cells give rise to many structures, including peripheral nerves, which connect to the spinal cord. 20 Neurulation: Initiating the Nervous System • As development progresses, the body segments differentiate. • Differentiation on the anterior– posterior axis is controlled by homeotic genes. • Four families of genes, called homeobox or Hox genes, control differentiation along the body axis in mice. • Each family consists of 10 genes and resides on a different chromosome. • Temporal and spatial expression of these genes follows the same pattern as their linear order on their chromosomes. 20 Extraembryonic Membranes • Extraembryonic membranes(배외막) originate from the germ layers of the embryo and function in nutrition, gas exchange, and waste removal. • In the chicken, the yolk sac(난황주머니) is the first to form, by extension of the endodermal tissue of the hypoblast. • It constricts at the top to create a tube that is continuous with the gut of the embryo. • Yolk is digested by the endodermal cells of the yolk sac, and the nutrients are transported through blood vessels lining the outer surface of the yolk sac. • The allantoic membrane(요막), an outgrowth of the extraembryonic ectoderm, forms the allantois(요막주머니), a sac for storage of metabolic wastes. • Ectoderm and mesoderm combine and extend beyond the embryo to form the amnion(양막) and the chorion(장막). • The amnion surrounds the embryo, forming a cavity. The amnion secretes fluid into the cavity that provides protection for the embryo. • The chorion form a continous membrane just under the eggshell. It limits water loss and functions in gas exchange. Figure 20.18 The Extraembryonic Membranes 20 Extraembryonic Membranes • In mammals, the first extraembryonic membrane to form is the trophoblast. • When the blastocyst hatches from the zona pellucida, the trophoblast cells attach to the uterine wall, This is the beginning of implantation. • The trophoblast becomes part of the uterine wall, and sends out villi to increase surface area and contact with maternal blood. • The hypoblast cells extend to form the chorion. The chorion and other tissues produce the placenta(태반). • The epiblast produces the amnion. Allantoic tissues form the umbilical cord. • Cells from the embryo that are in the amniotic fluid can be sampled and tested for defects. The test is called amniocentesis(양수검사). • Problems such as Down syndrome, cystic fibrosis, and Tay Sachs disease can be detected using this technique. • A newer technique is chorionic villus sampling(융모막융모검사) which makes earlier detection possible. 20 Human Development • The events of human gestation(임신기간) are divided into three trimesters. • The first trimester begins with fertilization. Implantation takes place 6 days later. Then gastrulation takes place, the placenta forms, and tissues and organs begin to form. • The heart first beats at 4 weeks and limbs form at 8 weeks. • The embryo is particularly vulnerable to radiation, drugs, and chemicals during the first trimester. • Hormonal changes can cause major responses in the mother, including morning sickness. • During the second trimester the fetus grows rapidly to about 600g. • Fingers, toes, and facial features become well formed. • Fetal movements are first felt by the mother early in the second trimester. • By the end of the second trimester, the fetus may suck its thumb. • The fetus and the mother continue to grow during the third trimester. • Throughout the third trimester, the fetus remains susceptible to environmental factors such as malnutrition, alcohol consumption, and cigarette smoking. • Kidneys produce urine, the liver stores glycogen, and the brain undergoes cycles of sleep and waking. 20 Human Development • Development does not end at birth. • The organization of the nervous system exhibits a great deal of plasticity in the early years, as patterns of connections between neurons develop. • For example, a child born with misaligned eyes will use mostly one eye. • The connections to the brain from this eye will become stronger, while the connections to the other eye will become weak. • This can be changed if the alignment is corrected within the first three years. • A current area of research into this developmental plasticity in the nervous system examines the role of learning in stimulating the production and differentiation of new neurons in the brain. 21 Development and Evolutionary Change • Introduction • Evolution and Development • Regulatory Genes and Modularity: Modifying Morphology • Plant Development and Evolution • Environmental Influences on Developmental Patterns • Learning: A Modification of Development 21 Environmental Influences on Developmental Patterns • It is now known that the development of many organisms is very sensitive to environmental conditions. • A single genotype may encode a range of phenotypes under different environmental conditions. • Signals from the environment can be divided into two major types: Environmental signals that are accurate predictors of future conditions. It is expected that the developmental processes of organisms respond adaptively to these signals. Environmental signals that are poorly correlated with future conditions. Organisms are unlikely to respond to these signals. • Developing organisms respond to signals such as day length, temperature, and precipitation in such a way that the adults they become are adapted to the predicted conditions. Figure 21.9 Development of Eyespots in Bicyclus anynana Responds to Temperature 21 Environmental Influences on Developmental Patterns • Some organisms need help from another species to complete their development. • For example, house mice raised in microbe-free environments do not have the bacteria that normally colonize their gut. • These gut bacteria induce gene expression in the mouse intestine, which is essential for normal capillary development. • Despite this uncertainty, if the changes have occurred frequently during the evolution of a species, developmental plasticity may allow individuals to respond to them. • The presence or absence of active predators is an example of one of these uncertain environmental signals. • Organisms cannot be expected to have evolved appropriate responses to environmental signals that they have not encountered before. • This is an important problem because human societies have changed the environment in so many ways. • One way humans change the environment is through the release of new chemical compounds. • Understanding how chemicals affect development is important because it may help in the development of less harmful substitutes.