MASTER COURSE OUTLINEDEPT:BIOL&

Big Bend Community CollegeNO:100

Date: March 2008(Formerly: BIO 101)

COURSE TITLE: Survey of Biology

CIP Code:26.0101CREDITS:5

Intent Code:11Total Contact Hours Per Qtr:66

Program Code:N/ALecture Hours Per Qtr:44

Lab Hours Per Qtr:22

Distribution Designation:Math/Science Lab.Other Hours Per Qtr:

PREPARED BY: Kathleen Duvall

COURSE DESCRIPTION: A study of basic biological principles common to all organisms. This course is intended for non-majors who desire a lab science requirement. Topics of study include: basic chemistry of cells, cell structure and function, membrane transport, cell metabolism and division, genetics and gene function, evolution, and ecology. Related investigations take place in a required two-hour lab period each week. There will be no required dissections in the laboratory.

PREREQUISITE(S): None

TEXT: A recent edition of anon-majors biology text such as Essential Biology with Physiologyby Campbell, Reece, and Simon,2nd Edition, Benjamin Cummings Publishing, 2007.

COURSE GOALS: To provide students with a general knowledge of basic biological principles showing how these principles relate to our natural world. To explore and encourage student interest in current biologically-related social and environmental issues, increasing students’ awareness of at least two viewpoints. To provide lab experiences that promote problem-solving and critical thinking skillsand that reinforce general biology concepts.

COURSE OBJECTIVES: Upon successful completion of the course, the student will be able to:

1.Apply the scientific method to a hypothetical biological problem.

2. Explain the theory of evolution by natural selection and use an appropriate example to illustrate the process.

3.Describe the basic structure and nature of atoms as well as explain ionic, covalent, and hydrogen bonding.

4.Identify and describe the general structure and functions of carbohydrates, lipids, proteins, and nucleic acids.

5. Compare and contrast prokaryotic cells with eukaryotic cells, and also animal cell structure with plant cell structure.

6.Identify, list, and state the structure and function of organelles found within eukaryotic cells.

7.Identify, name, and explain the processes that move substances in and out of cells.

8.Describe how enzymes work and name several enzymes.

9.Generally describe the roles of energy within living systems and explain how ATP is involved.

10. State and then compare and contrast the generalized equations for cellular respiration and photosynthesis.

11. Describe what occurs during glycolysis, Krebs cycle, and electron transport chains; account for CO2 and ATP production.

12.Describe what occurs during the light reactions and the Calvin cycle;state the substance(s) formed and the substance(s) used during each process.

13. List the events that occur during each phase of mitosis and during each phase of meiosis. Compare and contrast the purposes, the events, and the outcomes of mitosis and meiosis.

14.State and give examples of Mendel’s principle of segregation and principle of independent assortment; explain how these principles apply to monohybrid and dihybrid crosses.

15. Use a Punnett square to solve simple genetic problems involving up to two genetic traits at once.

16.Explain the inheritance patterns of incomplete dominance, codominance, and sex-linked inheritance;solve genetic problems involving these inheritance types.

17.Describe the structure of DNA in detail, and compare its structure to that of RNA.

18.Use a sequence of DNA to illustrate what occurs during the processes of replication, transcription, and translation.

COURSE CONTENT OUTLINE:

General Introduction

Organization of Life

Introduction to Evolutionary Theory

The Nature of Science and the Scientific Method

Evolution and Natural Selection

Historical Influences to Evolutionary Theory – Darwin

Evidences of Evolution and the Fossil Record

How Natural Selection Works

Microevolution and Its Mechanisms

General Outcomes of Natural Selection

Macroevolution, Speciation, and Mass Extinction

Taxonomy and Phylogeny

General and Organic Chemistry

Atoms, Elements, Isotopes, and Ions

Using the Periodic Table

Ionic, Covalent, and Hydrogen Bonding

Aqueous Solutions, pH, Acids and Bases

Polymers, Monomers, and Functional Groups

Dehydration Synthesis and Hydrolysis

Carbohydrates and Lipids

Proteins and Nucleic Acids

Cells– Their Structures and Functions

Prokaryotic and Eukaryotic Cells

Organelles of Animal and Plant Cells

Cell Membrane, Cytoskeleton, and Cell Junctions

Energy, Enzymes, and Membrane Transport

Types of Energy

Endergonic and Exergonic Reactions

ATP and Phosphate Transfer

How Enzymes Work and Are Regulated

Diffusion, Osmosis, Facilitated Diffusion, and Active Transport

Endocytosis and Exocytosis

Cell Metabolism

Cellular Respiration

Glycolysis, Krebs Cycle, and Electron Transport Chains

Fermentation

Photosynthesis

Light Reactions and the Calvin Cycle

Effect of Photosynthesis on the Greenhouse Effect

Reproduction, Genetics, and DNA

Sexual and Asexual Reproduction

The Cell Cycle, Mitosis, and Cytokinesis

Meiosis, Crossing Over, and Independent Assortment

Mendel and His Principles

Vocabulary and Tools of Genetics

Monohybrid and Dihybrid Crosses

Dominant Traits, Recessive Traits, and Other Patterns of Inheritance

Gender and Sex-Linked Inheritance

Structure of DNA and RNA

Replication, Transcription, and Translation

Upon completion of the above core material, additional areas of biology may be explored as time permits, including one or more of the following topics:

Gene Regulation and DNA Technology

Ecology of Organisms and Populations

Communities and Ecosystems

Human Impact on the Environment

Diversity of Living Organisms

Animal Structure and Function

Plant Structure and Function

EVALUATION METHODS/GRADING PROCEDURES:

Evaluation will be accomplished by exams, quizzes, assignments, projects, and reports. The overall course grade is based on the following weighted categories. Any slight adjustments to these category percentages will be printed and distributed to students at the beginning of each quarter.

Lecture Exams / 60%
Homework, Projects, In-Class Quizzes,andIn-Class Assignments / 20%
Lab Quizzes, Lab Reports, Lab Mid-Term, and Lab Final / 20%

The final grade will be based on anoverall course percentage according to the approximate schedule below. The instructor may adjust the grade scale slightly as deemed necessary.

100 - 96% 4.0 / 76 - 70% 2.4 - 2.0
95 - 90% 3.9 - 3.5 / 69 - 64% 1.9 - 1.5
89 - 84% 3.4 - 3.0 / 63 - 57% 1.4 - 0.7
83 - 77% 2.9 - 2.5 / 56 - 0% 0.0

Lab is an essential part of this class and is required for credit. Students missing more than two labs or missing the mandatory lab final will not be given credit for this course. All lab exams are practical exams in which students rotate through stations that each contain two questions and usually present a hands-on exhibit. Diagrams, models, 35mm slides, and microscope slides are all commonly used. Lab exam question types include identification, analysis, and prediction of results.

PLANNED TEACHING METHODS/LEARNING STRATEGIES:

X Lecture X Small Group Discussion X Special Project

X LaboratoryX Audiovisual Other (List)

Supervised Clinical Individualized Instruction

Division Chair Approval

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