Genetics BISC120 PDF

Summary

This document is a collection of diagrams, figures, and text relating to genetics, focusing on meiosis, fertilization, chromosomes and heredity. The document is likely from a university-level biology course.

Full Transcript

Figure 17.04b_3

Figure 17.5

Nuclear
envelope

TRANSCRIPTION

RNA PROCESSING
NUCLEUS

DNA

Pre-mRNA
mRNA

CYTOPLASM
TRANSLATION

Ribosome
Polypeptide

(b) Eukaryotic cell

Figure 17.6

Figure 17.5

Genetics
BISC120

1. Understand how offspring acquire genes
from parents by inheriting chromosomes.

Learning
Objectives

2. Understand how meiosis and fertilization
bridge one generation to the next (life cycle).
3. Understand how meiosis reduces the
number of chromosome sets from diploid to
haploid (overview of stages of meiosis).

Heredity and Genetics
• The transmission of traits from one generation to the next is called
inheritance, or heredity
• Sons and daughters are not identical copies of either parent or of their
siblings
• Along with inherited similarity,
there is variation
• The study of heredity and
inherited variation is called genetics

https://www.illumina.com/

Genes and Chromosomes (review?)
• Genes are passed to the next
generation via reproductive cells
called gametes (sperm and eggs)
• Most DNA is packaged into
chromosomes
– Humans have 46 chromosomes in
the nuclei of their somatic cells
– A gene’s specific position along a
chromosome is called its locus

Figure 13.3

Figure 13.3

Chromosomes and Inheritance
• Although genes are very important,
they make up only a small
percentage of all of the DNA in the
genome.
• Each gene has a specific location on
one of our 23 chromosomes and is
inherited, or passed down, from
generation to generation as a unit.
• We have two copies of each
chromosome and, thus, two copies
of each gene.

Figure 13.3

Broad Picture View of Meiosis and Fertilization

Figure 13.1

1. Understand how offspring acquire genes
from parents by inheriting chromosomes.

Learning
Objectives

2. Understand how meiosis and fertilization
bridge one generation to the next (life cycle).
3. Understand how meiosis reduces the
number of chromosome sets from diploid to
haploid (overview of stages of meiosis).

Life Cycle
• A life cycle is the generation-togeneration sequence of stages
in the reproductive history of an
organism
• The behavior of chromosomes is
related to the human lifecycle
and other types of sexual life
cycles

Figure 13.5

Gamete (n)
• A gamete (sperm or egg) contains a
single set of chromosomes and is
thus a haploid cell (n)
– In humans n=23
• Each set of 23 consists of 22
autosomes and a single sex
chromosome
• In an unfertilized egg (ovum), the sex
chromosome is X
• In a sperm cell, the sex chromosome
may be either X or Y

Figure 13.5

Gamete (n)
• The ovaries and testes produce
haploid (n) gametes by meiosis
– Contains a single set of
chromosomes, in humans n=23
• Each set of 23 consists of 22
autosomes and a single sex
chromosome
• In an unfertilized egg (ovum), the sex
chromosome is X
• In a sperm cell, the sex chromosome
may be either X or Y

Figure 13.5

Zygote (2n)
• Fertilization is the union of
gametes (the sperm and the egg)
• The fertilized egg is called a
zygote (2n = 46) and has one set
of chromosomes from each
parent
• The zygote produces somatic
cells by mitosis and develops
into an adult

Figure 13.5

1. Understand how offspring acquire genes
from parents by inheriting chromosomes.

Learning
Objectives

2. Understand how meiosis and fertilization
bridge one generation to the next (life cycle).
3. Understand how meiosis reduces the
number of chromosome sets from diploid to
haploid (overview of stages of meiosis).

Meiosis
• Meiosis takes place in two
consecutive cell divisions, called
meiosis I and meiosis II
• The two cell divisions result in
four daughter cells, rather than
the two daughter cells in mitosis
• Each daughter cell has only half
as many chromosomes as the
parent cell

Figure 13.7

Meiosis (IPMAT x2)
• Meiosis I separates homologous
chromosomes
– What does this mean?

• Meiosis II separates sister
chromatids
– What does this mean?

Figure 13.7

Meiosis I - Prophase I
• Centrosome movement, spindle
formation, and nuclear envelope
breakdown
• The mitotic spindle is a structure made
of microtubules that controls
chromosome movement
• Assembly of spindle microtubules begins
in the centrosome, a type of microtubuleorganizing center
• Chromosomes condense progressively
throughout prophase I

Figure 13.8

Meiosis I - Prophase I
• In early prophase I, each
chromosome pairs with its
homolog and crossing over
occurs
• Crossing over is the exchange
of genes between two
chromosomes, resulting in nonidentical chromatids that
comprise the genetic material of
gametes.
• X-shaped regions called
chiasmata are sites
of crossovers

Figure 13.

Meiosis I - Metaphase I
• In metaphase I, pairs of homologs line up
at the metaphase plate (an imaginary
plane midway between the spindle’s two
poles), with one chromosome facing each
pole
• Microtubules from one pole are attached to
the kinetochore of one chromosome of
each pair
• Microtubules from the other pole are
attached to the kinetochore of the other
chromosome
Figure 13.8

Meiosis I - Anaphase I
• Breakdown of proteins allow homologous
pairs of chromosomes to separate
• Homologs move toward opposite poles
guided by spindle apparatus.
• Sister chromatid cohesions persists at
the centromere
– Enables each the two chromatids of
each chromosome to move as a unit
towards the same pole.
Figure 13.8

“Pulling” Chromosomes –
At which end to kinetochore microtubules shorten?

Figure 12.9

Meiosis I – Telophase I and Cytokinesis
• In the beginning of telophase I, each half of
the cell has a haploid set of duplicated
chromosomes

• Each chromosome still consists of two
sister chromatids
• Cytokinesis usually occurs simultaneously,
forming two haploid daughter cells
Figure 13.8

Meiosis I Overview

Figure 13.8