SRJC Course Outlines

2/22/2018 2:48:35 AMBIO 10 Course Outline as of Summer 2017

Changed Course
CATALOG INFORMATION

Discipline and Nbr:  BIO 10Title:  INTRO PRIN BIOLOGY  
Full Title:  Introduction to Principles of Biology
Last Reviewed:11/26/2012

UnitsCourse Hours per Week Nbr of WeeksCourse Hours Total
Maximum4.00Lecture Scheduled3.0017.5 max.Lecture Scheduled52.50
Minimum4.00Lab Scheduled3.008 min.Lab Scheduled52.50
 Contact DHR0 Contact DHR0
 Contact Total6.00 Contact Total105.00
 
 Non-contact DHR0 Non-contact Total0

 Total Out of Class Hours:  0.00Total Student Learning Hours: 0.00 

Title 5 Category:  AA Degree Applicable
Grading:  Grade or P/NP
Repeatability:  00 - Two Repeats if Grade was D, F, NC, or NP
Also Listed As: 
Formerly: 

Catalog Description:
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Introductory course in biology including: scientific method, ecology, biodiversity, physiology and anatomy, chemistry of life, cell and molecular biology, genetics, and evolution.

Prerequisites/Corequisites:
Completion of MATH 150A or higher; or Qualifying Placement from Math Assessment; AND Course Completion of ENGL 100B or higher or Qualifying Placement from English Assessment. See Student Success & Assessment Services for more information about the assessment process.


Recommended Preparation:

Limits on Enrollment:

Schedule of Classes Information
Description: Untitled document
Introductory course in biology including: scientific method, ecology, biodiversity, physiology and anatomy, chemistry of life, cell and molecular biology, genetics, and evolution.
(Grade or P/NP)

Prerequisites:Completion of MATH 150A or higher; or Qualifying Placement from Math Assessment; AND Course Completion of ENGL 100B or higher or Qualifying Placement from English Assessment. See Student Success & Assessment Services for more information about the assessment process.
Recommended:
Limits on Enrollment:
Transfer Credit:CSU;UC.
Repeatability:00 - Two Repeats if Grade was D, F, NC, or NP

ARTICULATION, MAJOR, and CERTIFICATION INFORMATION

Associate Degree:Effective:Fall 1981
Inactive: 
 Area:C
Natural Sciences
 
CSU GE:Transfer Area Effective:Inactive:
 B2Life ScienceFall 1981
 B3Laboratory Activity  
 
IGETC:Transfer Area Effective:Inactive:
 5BBiological SciencesFall 1981
 5CFulfills Lab Requirement  
 
CSU Transfer:TransferableEffective:Fall 1981Inactive:
 
UC Transfer:TransferableEffective:Fall 1981Inactive:
 
C-ID:

Certificate/Major Applicable: Both Certificate and Major Applicable



COURSE CONTENT

Student Learning Outcomes:
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Upon successful completion of this course students will be able to:
1. Apply the scientific method to investigating and evaluating biological phenomena.
2. Summarize the concept of evolution including the historical development, evidence and mechanisms, and apply these to patterns of biodiversity.
3. Integrate basic principles as they apply to biological systems, such as cellular processes, anatomy, physiology, genetics, ecology, and evolution.
4. Investigate how humans are impacted by ecological processes and relationships and how humans affect these.
5. Perform laboratory techniques, including microscopy, with a high level of expertise without assistance or instruction.

Objectives: Untitled document
Upon completion of this course, student will be able to:
1. Apply the scientific method to biological investigation.
2. Apply laboratory techniques, including proper microscope use, to observing and experimenting with biological phenomena.
3. Describe the role of biotic and/or abiotic factors to structuring biomes, ecosystems, communities, and populations, and how humans interact with these systems.
4. Correlate the structure and function of plant and animal organ systems, organs, tissues and cells.
5. Compare and contrast the cell structure and function of prokaryotic and eukaryotic cells and of plant and animal cells.
6. Explain the relationships between the structure of atoms, molecules, and biological polymers, and their significance to cells, physiology, genetics, and evolution.
7. Integrate knowledge of molecular genetics, inheritance, and cell division (mitosis and meiosis), and apply these to evolutionary biology.
8. Relate the mechanisms of evolution, adaptation, and speciation.
9. Recognize major evolutionary patterns and adaptations in the biodiversity of major taxa (domains, kingdoms, and phyla).
10. Describe the values, themes, methods, and history of biology and relate them to a course of study in the major.

Topics and Scope
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1. Methods and philosophies of science
   A. Steps of the scientific method in laboratory experiments
    B.  Sample size and statistical methods in testing hypotheses
2. Biological Organization: atoms to the biosphere
3. Ecology
   A. Introduction to the biosphere and major world biomes
    B.  Ecosystems: nutrient cycles (water, carbon, nitrogen), energy flow, trophic structure
    C.  Communities: niches, species interactions (resource partitioning, keystone species), co-evolution, succession
    D.  Populations: structure, growth and regulation, human populations
4. Physiology
   A.  Nutrition (autotrophic and heterotrophic), macromolecules, vitamins, and minerals
   B.  Plant structure and function: nutrition, gas exchange, transport, and reproduction
   C.  Comparative animal structure and function:  nutrition and digestion, gas exchange, transport
    D.  Surface to volume ratio
5. Classification and diversity of taxa: domain system, eukaryotic kingdoms and select phyla
   A.  Distinguishing characteristics
    B.  Specialization of structure and function
    C.  Ecology and evolution
6. Chemistry
   A.  Atomic structures and chemical bonding
    B.  Properties of water (polarity and hydrogen bonding, cohesion and adhesion)
    C.  States of matter
    D.  pH
   E.  Macromolecule synthesis, structure and function (carbohydrates, lipids, proteins, nucleic acids)
7. Cell Biology
   A.  Prokaryotic and eukaryotic cell structure and function (organelles, cytoskeleton)
   B.  Endosymbiotic hypothesis
    C.  Cell membrane structure
    D.  Transport: diffusion, osmosis, passive and active transport, endocytosis, and exocytosis
8. Metabolic Pathways
   A.  Enzyme: structure and function
   B.  Enzyme activity: effects of pH and temperature, positive and negative feedback loops
    C.  Photosynthesis light and photopigments
    D.  Photosynthesis (light-dependent and light-independent reactions): substrates, products, and location
   E.  ATP synthesis using chemiosmosis
   F.  Aerobic vs. anaerobic respiration
    G.  Respiration (glycolysis, Krebs cycle, and electron transport chain): substrates, products, and location
9. Cellular Reproduction
   A.  Mitosis
    B.  Meiosis including sources of genetic variation
10. Molecular Genetics
   A.  DNA replication
    B.  Protein synthesis and genetic code
    C.  Mutations and mutagens
    D.  Changes in chromosome number and chromosome structure
11. Transmission Genetics
   A.  Mendelian Genetics
   B.  Post Mendelian Genetics: partial dominance, multiple alleles, polygenic inheritance, autosomal linkage, sex linkage
    C.  Effects of environment on genetic expression
12. Development of Evolutionary Theory
   A.  Pre-Darwinian thought: static world view to Lamarckian evolution
   B.  Darwin and natural selection
    C.  Evidence for evolution
13. Mechanisms of Evolution
    A.  Microevolution: types of selection, gene flow, mutation, and genetic drift
   B.  Macroevolution: biological species, reproductive isolation mechanisms, speciation and adaptive radiation
14. The effect of past and current understanding of biological principles, topics, and methods on the human condition  
15. Biology as a discipline
16. Laboratory Exercises
      Compound and dissecting microscope use
       Scientific method
      Enzyme structure and function
      Properties of water
      Cell types and structures
      Mitosis and meiosis
      Mendelian genetics
      Evolution
      Eukaryotic biodiversity

Assignments:
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1.  Assigned reading from texts and other assigned reading (approximately 25 pages/week).
2.  Lab reports and/or essay assignments (2-4 pages).
3.  Scientific method of analysis and interpretation of data (laboratory excercises) (approximately 1 per week).
4.  Laboratory and/or lecture homework assignments, including genetic problems (approximately 1 per week).
5.  Objective examinations including: multiple choice, short answer and/or essay, lecture exams (4 midterms, 1 final) and short answer laboratory exams (2-3 exams)
6.  Demonstrate basic microscope skills (microscope quiz) (1 per semester).

Methods of Evaluation/Basis of Grade.
Writing: Assessment tools that demonstrate writing skill and/or require students to select, organize and explain ideas in writing.Writing
5 - 10%
Lab reports or essay assignments
Problem solving: Assessment tools, other than exams, that demonstrate competence in computational or non-computational problem solving skills.Problem Solving
2 - 10%
Homework assignments; laboratory exercises; genetics problems
Skill Demonstrations: All skill-based and physical demonstrations used for assessment purposes including skill performance exams.Skill Demonstrations
2 - 5%
Use and care of microscopes
Exams: All forms of formal testing, other than skill performance exams.Exams
65 - 80%
Multiple choice, short answer and/or essay, lecture and lab exams (required)
Other: Includes any assessment tools that do not logically fit into the above categories.Other Category
0 - 10%
Class participation


Representative Textbooks:
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Biology, Concepts and  Connections, edition 7/e.  Campbell, Reece, Taylor, Simon, Dickey. Pearson Benjamin Cummings: 2012.
Concepts of Biology, 2nd edition.  Mader. McGraw-Hill: 2011.
Instructor prepared lab manual

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