EDSC 103: Nature and History of Biology as a Science PDF

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This document is a chapter on the nature and history of biology. It covers topics such as the development of modern biology, major biological discoveries, and the nature of science itself.

Full Transcript

EDSC 103

Chapter 1: Nature and History of Biology as a Science

Lesson #1: Development and Timeline of Modern Biology

Modern Biology studies living organisms and their interactions with each other and their
environments. It encompasses a wide range of fields and disciplines, integrating knowledge
from various scientific areas to understand life at multiple levels, from molecules to ecosystems.

Molecular Biology: molecular mechanisms underlying biological processes
Genetics: heredity, variation, and the role of genes in health and disease
Cell Biology: structure and function of cells and their processes
Evolutionary Biology: origins and changes in species over time
Ecology: interactions between organisms and their environments
Physiology: functions and processes of living organisms and their parts
Developmental Biology: growth and development of organisms
Microbiology: microorganisms and their roles in health, disease, and environmental
processes
Biotechnology: Applies biological knowledge to develop technologies and products

Cell Theory (1830s-1850s): The formulation of cell theory by Matthias Schleiden, Theodor
Schwann, and Rudolf Virchow was pivotal. They established that all living organisms are
composed of cells and that cells are the basic unit of life. This concept laid the groundwork
for many future discoveries in biology.

Theory of Evolution (1859): Charles Darwin’s publication of "On the Origin of Species"
introduced the theory of natural selection, revolutionizing our understanding of how species
evolve and adapt over time. This work provided a unifying framework for understanding
biological diversity and evolution.

Mendelian Genetics (1860s): Gregor Mendel’s experiments with pea plants established the
basic principles of inheritance. Although his work was not widely recognized until the early
20th century, Mendel’s laws of inheritance became fundamental to genetics.

Major Discoveries and Inventions from 17th to 19th Centuries

1667: Robert Hooke
○ The Discovery of the Cell
1674: Antoni van Leeuwenhoek
○ One-lens Simple Microscope
1735: Carolus Linnaeus
○ Taxonomic system
1839: Theodore Schleiden, Matthias Schwann, Rudolf Virchow
 ○ The Cell Theory
1859: Charles Darwin
○ Theory of Evolution by Natural Selection
1866: Gregor Mendel
○ Mendelian Pattern of Inheritance
1866: Louis Pasteur
○ Disproved Spontaneous Generation Theory opening doors to microbiology and
vaccination

Discovery of DNA Structure (1953): James Watson and Francis Crick, with the help of
Rosalind Franklin’s X-ray diffraction images, elucidated the double helix structure of DNA. This
discovery was crucial for understanding how genetic information is stored, replicated, and
transmitted.

Molecular Biology and Biochemistry (1940s-1960s): Advances in molecular biology,
including the understanding of protein synthesis, genetic coding, and enzymology, further
refined the study of biological processes at the molecular level. Techniques like gel
electrophoresis and chromatography became important tools.

Development of Genetic Engineering (1970s-present): The advent of recombinant DNA
technology and gene-editing tools such as CRISPR has allowed for precise manipulation of
genetic material, leading to advances in medicine, agriculture, and biotechnology.

Major Discoveries and Inventions from 20th Century

1908: Wilhelm Weinberg, Godfrey Hardy
○ Allele and Genotype frequencies as indicators of evolution
1910: Thomas Hunt Morgan
○ Chromosomal Theory of Inheritance
1928: Alexander Fleming
○ Penicillin
1944: Oswald Avery, Colin Mcleod, Maclyn McCarthy
○ DNA as the carrier of genetic information
1953: James Watson, Francis Crick
○ DNA exists as a 3D molecule with a double-helix structure
1967: Lynn Margulis
○ Advancement of the Endosymbiotic Theory
1969: Robert Whittaker
○ Five-kingdom Classification System (M, A, F, P, and P)

Lesson #2: Biology and Nature of Science
Nature of Science is a critical component of scientific literacy that enhances students’
understanding of science concepts and enables them to make informed decisions about
scientifically-based personal and societal issues. (nsta.org, 2024)

Nature of Science

Science as a process
○ Scientific ideas are developed through reasoning.
○ Scientific claims are based on testing explanations against observations of the
natural world and rejecting the ones that fail the test.
○ Scientific claims are subject to peer review and replication.
Science has principles
○ Science seeks to explain the natural world and its explanations are tested using
evidence from the natural world.
○ Science assumes that we can learn about the natural world by gathering
evidence through our senses and extensions of our senses.
Characteristics of Science
○ Science corrects itself.
○ Conclusions of science are reliable, though tentative
○ Science is not democratic.
○ Science is non-dogmatic.
○ Science cannot make moral or aesthetic decisions.

Biology as a Science

In simple terms, Biology is a natural science discipline that studies living things. ranging
from the microscopic or submicroscopic view of a cell to ecosystems and the whole living
planet.

As a Science, it consists of knowledge that covers general truths or the operation of general
laws, especially when acquired and tested by the scientific method.

Science (including Biology) using scientific methods attempts to comprehend the nature of
the universe.

Lesson #3: Current and Future Prospects of Biology

Genomics and Transcriptomics (gene sequencing, analysis, and editing)
Proteomics (protein analysis)
Biotechnology (food technology, biofuels)
Synthetic Biology (synthetic organisms, application in medicine and industry)
Computational Biology (Bioinformatics, Predictive Modeling, AI)

Chapter #2: Effective Approaches and Strategies in Teaching Life Science
Approaches and Strategies in Teaching Life Science

Constructivism
○ Personal and societal experiences influence how human beings gather and make
meaning of information.
Context-based Learning
○ Students strengthen their understanding of the concept by connecting it to
real-world situations
Inquiry-based Learning
○ Students use questioning and exploration to gain understanding of real-world
Problem-based Learning
○ Students gain knowledge through specific, complex problem that does not have a
straightforward solution; the focus is on the acquisition of knowledge, not on the
solution
Project-based Learning
○ Students acquire knowledge by designing, developing, and constructing concrete
solutions to a problem; the focus is on the end product
Collaborative Learning
○ Using groups mutually searching for solutions, or meanings, or creating a product

Philosophies of Education

Perennialism
○ Education must pursue universal truths that span across historical periods to
produce well-rounded individuals with some knowledge across the arts and
sciences
○ Usually employs teacher-centered approach, sometimes student-centered
Essentialism
○ Believes that only the core of important skills must be taught to all students.
○ Employs teacher-centered approach
Progressivism
○ It focuses its educational stance towards experiential learning
○ Student-centered
○ It influenced constructivism
Social Reconstructionism
○ Education aims to improve society and be useful for change and social
reforms by leading the students in rational discussion and critical analysis of
contemporary issues.
○ Student-centered

Additional Approaches in Teaching Life Science

Metacognitive Learning
 ○ applying metacognitive (thinking about thinking) strategies to respond to clear
and explicit learning goals
Integrative or Multidisciplinary Learning
○ covers all-inclusive and integrates different disciplines or fields of
knowledge
Technology-supported Instruction
○ use of diverse set of ICT tools in class to communicate, create, disseminate,
store, and manage information

What is the best approach/strategy in teaching contraceptives?

When you unpack the curriculum or plan for your lessons, consider the following:
(1) Background of learners (age, economic status, needs, strengths/weaknesses, etc.)
(2) Resources (facilities, time, human, budget)
(3) School’s PVMO

Chapter #3: Personal Health and Wellness

Lesson #1: Biomechanics of Sports and Exercise