Introduction to Behavioral Neuroscience Lecture 1 PDF

Summary

This lecture introduces the topic of behavioral neuroscience, outlining course information, textbooks, study strategies, and research opportunities. It also provides a summary of molecular biology, including DNA, RNA, and protein synthesis.

Full Transcript

Introduction to Behavioral
Neuroscience
PSY:2701
 Things to know about this course

Go over the syllabus
 Textbook

You can buy a hard copy

Or you can buy the electronic copy via
BryteWave on ICON (this is significantly
cheaper)
 Things to know about this course

1. This course is difficult – it requires WORK and effort

2. You have to know information inside and out,
backwards and forwards

3. Exams based on topics covered in lecture
(Exams will not be based on topics that are in the textbook
but are not touched upon in class)
 How to do well in this course

1. Read the relevant textbook chapters BEFORE class – my
lectures are structured based on the assumption that you
have read the chapters

2. COME to class, listen, take notes

3. Read over chapter AGAIN after class, making sure you
understand all difficult concepts

4. Study and COMMIT information to memory as you go
through course (not just before exam)

5. Office hours, discussion sections
 How to study

1. Massed vs. spaced training

2. Superficial vs. deep processing

3. Memory consolidation – What affects this?
 ICON

ICON will have everything posted on it

Assignments and readings for Discussion sections
are found at bottom of ICON site, under
“Discussion section readings and assignments”
 Research Opportunity

LaLumiere Lab in Department of Psychological and Brain Sciences
looking for Undergraduate Research Assistants
– Research Focuses
Neurobiology of Drug Addiction
Neurobiology of Learning and Memory
– Visit lab website to learn more about our research:
https://lalumiere.lab.uiowa.edu/

Starting Fall 2024
– Sophomores/Juniors with 10 hours/week availability

If interested, email [email protected] with resume/CV.
 Developmental
Psychopathology WE ARE OPEN
Lab FOR
APPLICATIONS!
How to apply…
To complete the online
Are you interested in psychology? application, visit:
Do you enjoy working with children https://uiowa.qualtrics.
com/SE/?SID=SV_6foZ
and families? RkaDKfsPf49
Are you organized and detail OR scan the QR code:
oriented?
Can you commit to at least 2
semesters working in our lab?
Become an
Undergraduate
Research
Assistant in our
Lab!!!
Website:
 Any questions before
getting into Chapter 1?
Chapter 1
How can we study the relationship between brain and
behavior?
Appendix A
 Basics of biology
Proteins are the building blocks of cells
-- they are the “do”ers of your cell

Proteins are made of strings of amino acids

You have all the same DNA in all your cells. So, what makes
a brain cell different from a liver cell from a muscle cell??

It is the distribution, number, and types of proteins in a cell
that determine what the cell is, what the cell does, etc.

How are proteins made?

Genes are codes for proteins
 Molecular biology
How do genes code for proteins?

Genes are parts of your DNA

To make proteins, we go: DNA  RNA  proteins

Let’s talk about DNA and RNA first

DNA and RNA are made up of strings of nucleotides
DNA – two strands connected by “base pairs”

A–T
G–C
C–G
T–A

These are the base pairs
 Molecular biology
It is the SEQUENCE of nucleotides along a stretch of DNA
that is the code for the protein

For example: ACCTGGAGAGAATCCT

The base pairs on the opposite strand would be the
“complementary” bases

What would be the complementary DNA bases for this
code?
TGGACCTCTCTTAGGA

Remember: To make a protein,
DNA (specific gene)  RNA  protein
 Molecular biology
To make RNA copy of a gene, the double-helix of the
DNA opens up

Your cells have machinery that then match up RNA
bases that are floating around with their
complementary DNA bases

Process is called: Transcription = DNA  RNA

(This RNA is also called messenger RNA or mRNA)
 Region of DNA (gene) is opened up

Enzymes link RNA nucleobases together –
form mRNA
 Molecular biology
With RNA, U (uracil) is substituted for T (thymine)

So, if the DNA base is A, the RNA complementary
base is U

Here’s how they DNA RNA
match up:

A U
G C
C G
T A
 Molecular biology
Next step: mRNA  proteins

Process called “translation”

Transcription: DNA  mRNA

Translation: mRNA  proteins
 Molecular biology
How does translation work?

Each trio of RNA nucleotides is called a codon

Each codon encodes ONE of the amino acids

So, every three nucleotides is a code for one amino
acid

Amino acids are linked together  protein
 Summary so far
DNA is the same in every cell, but proteins differ by
the type of cell

Proteins are made up of strings of amino acids.

DNA has four different nucleotides (A, C, G, and T)
whose sequence codes for amino acids

Three nucleotides in a row is a codon and codes for a
single amino acid

DNA is first transcribed (copied over) into mRNA

Then the mRNA is translated into the amino acid
sequence to make the protein
 Techniques of molecular
biology
Different techniques for examining DNA, mRNA, and
proteins

Techniques can do one or more of the following:
1) Whether a molecule is present
2) WHERE a molecule is present
3) HOW MUCH of a molecule is present

Southern blots – identify WHETHER a particular gene
(DNA) is present

Northern blots – identify WHETHER and HOW MUCH a
particular mRNA is present
 Techniques of molecular
biology
For both Northern and Southern blots, you take tissue,
grind it up, and then analyze it

If you want to know WHERE mRNA is expressed, you can do
in situ hybridization

In situ hybridization: Take slice of tissue, expose tissue to
complementary string of RNA

This complementary string (or “probe”) is labeled,
enabling us to visualize the tissue later
Appendix Figure A.4 In Situ Hybridization
 What about proteins?

If you want to know HOW MUCH of a particular protein is
being produced somewhere  Western blot

Take tissue, grind it up, and conduct Western blot technique

How does that work?

Run the ground-up tissue through gel electrophoresis – uses
electric current to separate proteins by size

Then transfer proteins from gel to membrane (this is the
“blotting”)
 What about proteins?

Expose membrane to antibodies
antibodies are made to be specific to the protein of
interest

antibodies – are labelled to enable visualization

Western blot – good for comparing levels of a specific
protein between groups – not so good for localizing where
the protein is expressed

Example: Do a behavioral intervention and then compare
protein level in hippocampus between control group and
experimental group
 More protein stuff

What if you want a better idea of WHERE proteins are
being expressed (like we can do with mRNA and in situ
hybridization)?

Immunocytochemistry

Take tissue sections and expose sections to antibodies

Antibodies are labeled, enabling visualization of WHERE
the proteins are
Box 2.1 Neuroanatomical Methods Provide Ways to Make Sense of the Brain (Part 2)
 Techniques of molecular biology:
Summary
Southern blots – identify DNA/genes in tissue

Northern blots – identify and determine how much mRNA
in tissue

In situ hybridization – localize mRNA in tissue sections –
good for identifying WHERE the mRNA is expressed

Western blots – provides relative quantification of amount
of protein in tissue sample

Immunocytochemistry – show localization of protein
expression
 Techniques of molecular biology:
So, to summarize:
Summary

Southerns, Northerns, & Westerns – grind up tissue – so,
they’re not very specific for WHERE molecules are located
-- can only say based on which tissue is ground up

-- good for identifying (Southerns) and quantifying
(Northerns and Westerns) molecules

In situ hybridization and immunocytochemistry – use tissue
sections – good for WHERE molecules are located
-- NOT so good for saying HOW MUCH of the molecule is
there
 Uses of these molecular
techniques with behavioral
neuroscience

Behavioral intervention  measure mRNA levels/location
or protein levels in a particular structure

E.g. Train a rat to associate a tone with a footshock 
then look to see what kinds of molecular changes occur
as a result of that learning
 Final notes

Potential MC exam question:

Which of the following techniques is good for identifying which cells,
in a tissue section, are expressing a particular mRNA?

A)Northern blot
B)Western blot
C)In situ hybridization
D)Immunocytochemistry
 Final notes

Another potential MC exam question:

Which of the following is the complementary mRNA base sequence
for the DNA nucleobase sequence of A-A-T-C-G-G?

A)U-U-A-G-C-C
B)T-T-A-G-C-C
C)C-C-G-A-T-T
D)T-U-A-C-T-G