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BIO 127 – D evelopmental Biology Fall 2011. Dr. Tom Landerholm landerholm@csus.edu Humboldt Hall 211E 916-278-6152 Office Hours: Wednesday 1:00-2:00, Thursday 2:00-4:00 (or by appointment). Course Organization. Section I: Developmental Terms and Processes Section II: Early Development
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BIO 127 – Developmental BiologyFall 2011 Dr. Tom Landerholm landerholm@csus.edu Humboldt Hall 211E 916-278-6152 Office Hours: Wednesday 1:00-2:00, Thursday 2:00-4:00 (or by appointment)
Course Organization • Section I: Developmental Terms and Processes • Section II: Early Development • Section III: Development of Organ Systems I • Section IV: Development of Organ Systems II • Section V: Late Development and Other Topics • Labs are designed as extensions of the lectures • Exams will cover both together as a unit
Grades will be based on the result of four exams, 8 laboratory write-ups, the presentation of your poster and participation in the lab as follows: A(-) > 90%, B(+) > 80%, C(+) > 70%, D(+) > 60%, and F < 60% Exam 1 Friday 09/16 100 points Exam 2 Friday 10/07 100 points Exam 3 Friday10/28 100 points Exam 4 Friday 11/18 100 points Exam 5 Wed. 12/14 100 points Lab Write-ups 8 total 200 points Project presentation 12/09 50 points Total Points 750
Bio 127 - Section IDevelopmental Terms and Processes The Big Picture Developmental Anatomy Gilbert 9e – Chapter 1
What are we studying? • The COMPLEX PROCESS: one cell to one hundred trillion cells, over 200 cell phenotypes in humans • The KEY BIOLOGICAL TRANSITION: genetic inheritance to phenotypic expression • The SPECIES COMPARISON: all early animal embryos are similar, the earlier the mutation the bigger the potential change
A VERY COMPLEX PROCESS • Most fields of Biology study the adult • Anatomy, Physiology, Genetics, Molecular Biology • One cell to one hundred trillion cells • very tightly regulated cell division and death • Devo produces 200+ cell types in humans • nearly every one has the same genotype • how do they express different genes so they can change? • Cells, tissues, organs, systems, regulation???
The three embryonic germ layers Just a few of the 200+ cell types......
Fig. 13-6 Sexual Life Cycles Key Haploid (n) Haploid unicellular or multicellular organism Haploid multi- cellular organism (gametophyte) Diploid (2n) Gametes n n Mitosis Mitosis Mitosis Mitosis n n n n n n n n Spores n FERTILIZATION MEIOSIS n Gametes Gametes n MEIOSIS FERTILIZATION Zygote MEIOSIS FERTILIZATION 2n 2n 2n 2n Diploid multicellular organism Zygote Diploid multicellular organism (sporophyte) 2n Mitosis Mitosis Zygote Most fungi and some protists Animals Plants and some algae
THE KEY BIOLOGICAL TRANSITION • Genetic inheritance to phenotypic expression • XX = female adult, XY = male adult (in some organisms) • Globin genes carry mutation for sickle cell • Gigantism can be caused by mutations in a-subunit of G-protein Gs9 • Developmental Biologist wants to know..... • What’s on the X and Y chromosome? • When is it expressed? How does it change sex? • Why are globin genes expressed only in RBC? Why does it persist? • a-subunit of G-protein Gs9 - how does that cause large size?
THE SPECIES COMPARISON • Much is learned from studying organisms that develop the same way, as well as those that do it differently Such as... • All early animal embryos are similar • The earlier a mutation, or other event, occurs, the bigger the potential change
Figure 1.10 Similarities and differences among vertebrate embryos during development
Sometimes the adults are quite different but the embryos give away the closeness of two species
Figure 1.19 Homologies of structure among human arm, seal forelimb, bird wing, and bat wing
Some more key ideas • Developmental Mechanisms of Regeneration • Development’s Role in Evolution • The Impact of the Environment on Developing Organisms
Bio 127 - Section IIntroduction to Developmental Biology Developmental Anatomy Gilbert 9e – Chapter 1
Fertilization embryogenesis Birthing (hatching) post-embryonic development gametogenesis Maturity Fertilization post-embryonic devo and senescence Birthing (hatching) Death
The frog is a classic model organism Frog Post-Embryonic Development is very different from ours
Figure 1.2 Early development of the frog Xenopuslaevis animal EGG = GAMETE vegetal FERTILIZATION CLEAVAGE BLASTULATION The result is a “blastula”
GASTRULATION FORMS THE GERM LAYERS “gastrula” neurulation marks the beginning of organogenesis “neurula” ORGANOGENESIS the tadpole is a “larva”
Figure 1.4 Metamorphosis of the frog POST-EMBRYONIC DEVELOPMENT: METAMORPHOSIS
Fig. 13-5 Egg Haploid gametes The Human Life Cycle Sperm MEIOSIS FERTILIZATION Diploid Zygote • Embryogenesis • Post-Embryonic Development • -Senescence Multicellular adults
1672 1908 ART AND ANATOMY ARE THE BACKBONE OF UNDERSTANDING DEVELOPMENT 1817 1981 The greatest progressive minds of embryology have not looked for hypotheses; they have looked at embryos..... ....Jane Oppenheimer
Drawing is still a very important skill in Developmental Biology but this semester we will employ the digital technologies that are available to us to generate the critical visual communications required to learn DB. - Digital cameras - Image software - Google Images - University websites - Wikipedia - Sac CT
Like all of our sciences, Developmental Biology, had to wade through a time before we knew about cell and molecular biology and digital communications. • No doubt there are other discoveries coming that will change how we view these processes in the future. • We’ll study it in the context of what we know now. (Don’t let that stop you from being amazed by the genius of Aristotle!)
This class is going to teach you a LOT of terminology! Let’s start with some Aristotle classics...... Oviparity = hatched from an egg (birds, amphibians, most reptiles and fish, inverts) Viviparity = born live (placental mammals, some fish and reptiles) Ovoviviparity = born live from eggs hatched in mom (!) (sharks, some reptiles) What is the platypus?
Aristotle Plus Modern Biology... 1. everybody’s born from an egg and 2. cleavage is the first developmental stage after fertilization of that egg, so... meroblastic cleavage = some of the egg cell divides to embryo cells, while some just goes for nutrition holoblastic cleavage = all of the egg cell divides to cells, some embryonic and some extraembryonic
Remember: The Germ Layers formed during gastrulation This is one of the major morphological determinants of taxonomy in Animalia. Of the nine phyla in the kingdom, 7 are triploblastic and 2 are diploblastic.
The Blastopore This is another key taxonomic determinant: 2 phyla of 9 in Animalia form the anus here, the rest form the mouth at the blastopore. deuterostomes v. proteostomes formed during gastrulation
The Notochord Only members of phylum Chordata make a notochord. (of the three sub-phyla, only Vertebrata makes a spine out of it.)
Evolution of pharyngeal arches in the vertebrate head early embryo adult fish This is also a characteristic found only in Chordata. adult reptile human
von Baer’s Laws: 1. The general features of a large group of animals appear earlier in development than do the specialized features of a smaller group. 2. Less general characters develop from the more general, until finally the most specialized appear 3. The embryo of a given species, instead of passing through the adult stages of lower animals, departs more and more from them. 4. Therefore, the early embryo of a higher animal is never like a lower animal, but only like its early embryo.
Keeping Track of Moving Cells in the Embryo • A key difference between embryos and adults is cell movement • Nearly all embryo cells are on the move • Only limited types of cells move in the adult • There are two types of moving cells in the embryo • Epithelial cells adhere to each other, move as a group • Mesenchymal cells live and move as individuals
Tissue Morphogenesis results from..... • Direction and number of cell divisions • Cell shape changes • Cell movement • Cell growth • Cell death • Changes in the composition of the cell membrane or secreted products • Cell differentiation is an obvious omission!
Fate Maps: Mapping the Movements of Cells in the Embryo The idea is to.... • Pick a developmental stage and a group of cells in the embryo that you want to study • Find a way to visually distinguish those cells from all of the rest • Find your cells again during and at the end of the stage and make a map of their fate
Figure 1.11 Fate maps of vertebrates at the early gastrula stage The value of fate mapping is clear from this figure, which shows the common organization of embryos even when the shapes differ.
The process has gotten more sophisticated as our tools have gotten better and better. Direct observation of pigmented cells in the embryo Marking small groups of cells in the early embryo with dyes Replacing embryonic cells of one species with those of another that look different Replacing embryonic cells with those from the same species carrying transgenes
Direct observation of pigmented cells in the embryo (sea urchin larva)
Vital dye staining of amphibian embryos The first experimental fate maps allowed investigators to put color wherever and wherever needed.
Fate mapping using a fluorescent dye Powerful fluorescent dyes allowed investigators to take their fate map studies much later into development of the embryo.
Genetic markers as cell lineage tracers Chick and quail are so similar that they won’t immunologically reject the others’ cells plus quail have very large nucleoli and the cells are easy to distinguish from chick cells.
Figure 1.16 Chick resulting from transplantation of a trunk neural crest region from an embryo of a pigmented strain of chickens into the same region of an embryo of an unpigmented strain Chick and quail can also grow up with each other’s parts! Permanent fate maps!
Fate mapping with transgenic DNA shows that the neural crest is critical in making the bones of the frog jaw Now we can fate map nearly any embryo, at nearly any cell or stage, with molecular tools.
Evolutionary Developmental Biology (EvoDevo)Similarities and Differences Between Embryos Can Define Most Taxonomic and Evolutionary Relationships • This idea pre-dates Darwin • A center pin of “Origin of the Species” • Two things show in the embryo: • Commonalities show common ancestry • Modifications show adaptations to environments • Combined with von Baer: • Evolutionary modifications of related species should come later in development than those of distant species
Homology vs. Analogy • Homologous structures arise from a common ancestral structure • Analogous structures share a common function that has arisen independently in the two (or more) organisms