Unit I Gen Ed 10 PDF

Summary

This document is a university unit outlining the process of human reproduction, including asexual and sexual reproduction, and the role of hormones. It describes different types of reproduction and associated reproductive processes.

Full Transcript

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UNIT I
Page | 1
INTRODUCTION

Overview
Human reproduction involves creating new individuals through the joining
of male and female reproductive cells. This starts with the fertilization of an egg by
a sperm, forming a zygote. The zygote then goes through various stages of
development, including cell division and differentiation, ultimately becoming an
embryo and then a fetus. This process is controlled by the complex reproductive
systems and hormones in both males and females.
Besides the biological aspects, human reproduction includes important
social, ethical, and cultural elements. Issues such as family planning, access to
reproductive healthcare, and cultural views on reproduction play significant roles.
Advances in reproductive technologies, such as in vitro fertilization (IVF) and genetic
screening, have introduced new opportunities and challenges. Understanding
human reproduction is crucial for improving reproductive health, managing
population growth, and navigating the ethical issues that arise from reproductive
decisions.

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Lesson Proper

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What is Reproduction?

Reproduction is a biological process in which an organism produces offspring that are genetically
similar to itself. This process ensures the continuation of species across generations, playing a crucial role
in life on Earth.

Let's explore reproduction in detail, including its various types and the modes of reproduction
found in plants and animals.

There are two types of reproduction:
1. Asexual Reproduction

Asexual reproduction is a process in which a single parent generates offspring without the need for
gametes (sperm and egg cells). The offspring are genetic replicas of the parent, possessing the same set
of genes and exhibiting no genetic variation. This form of reproduction is commonly seen in plants, fungi,
and certain animals, including bacteria and some invertebrates.

It allows for quick population expansion and does not require a mate, which can be beneficial in stable
environments. However, the absence of genetic diversity
among the offspring can make them more susceptible to
diseases and nutrient deficiencies.

Methods of Asexual Reproduction:
Binary Fission: This is a type of asexual reproduction
frequently found in bacteria and single-celled
organisms, where a single cell splits into two
genetically identical daughter cells.

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An example of binary fission is bacteria like Escherichia
coli. In this process, the bacterial cell divides into two identical
cells, each with a copy of the original genetic material.

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Another example is the amoeba, a single-celled organism
that reproduces by splitting into two new amoeba.

Budding: This reproductive process is found in yeast and some invertebrates, where a new
organism develops as an outgrowth from the body of the parent and eventually detaches to
become a separate individual.

Fragmentation: Common in starfish and certain plants, where a new organism grows from a
fragment of the parent.

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Sporogenesis: In this type of reproduction, a
new organism grows from the spores. These
can be created without fertilization and can
spread through wind and animals. Page | 4

2. Sexual Reproduction

Sexual reproduction is the process of producing offspring through the union of male and
female gametes. This can occur between individuals of different sexes or, in some cases, within a
single organism. Unlike asexual reproduction, which results in offspring genetically identical to
the parent, sexual reproduction generates offspring with diverse genetic traits. This genetic
diversity arises because each gamete carries a unique combination of genes, leading to varied
genetic outcomes in the offspring.

This method of reproduction is generally more complex and time-consuming than asexual
reproduction, involving stages such as gamete production, mating, and fertilization. Despite its
complexity, sexual reproduction promotes genetic variation, which can aid organisms in adapting
to changing environments and enhance their evolutionary success. Many multicellular organisms,
including humans, depend on sexual reproduction for the continuation and advancement of their
species.

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Cell division is a crucial biological process that enables organisms to grow, repair
damaged tissues, and reproduce. In this process, a single parent cell splits into two daughter cells,
each with a complete set of genetic material.
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Primary Types of Cell Division

Mitosis results in the creation of two
daughter cells, each with the same number of
chromosomes as the original parent cell. This
process is vital for growth, tissue repair, and
asexual reproduction. During mitosis, the cell
undergoes a single division where
chromosomes are duplicated, aligned, and
then separated into two identical sets. The
stages of mitosis—prophase, metaphase,
anaphase, and telophase—ensure accurate
replication and distribution of genetic
material to the daughter cells. Mitosis occurs
in somatic cells, which are responsible for
growth, repair, and asexual reproduction.

In contrast, meiosis is a specialized cell division process that produces four daughter cells,
each containing half the chromosome number of the parent cell. This process is critical for sexual
reproduction and involves two sequential divisions: meiosis I and meiosis II. Initially, meiosis
separates homologous chromosomes, followed by the division of sister chromatids. Meiosis also
promotes genetic diversity through mechanisms like crossing over and independent assortment,
which enhance genetic variation in offspring. Meiosis takes place in germ cells, which produce
gametes such as sperm and eggs.

In summary, mitosis generates cells that are genetically identical to the parent cell,
supporting growth and repair, while meiosis produces genetically varied gametes, essential for
reproduction and evolutionary processes.

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Important Terms in Cell Division

Nucleus: The nucleus is a central organelle in cells, housing the DNA
and controlling key cellular functions, including growth, metabolism,
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and reproduction, by regulating gene expression.
Chromatin: Chromatin consists of DNA and associated proteins within
the nucleus. Its primary role is to compact the DNA into a manageable
structure that fits inside the nucleus, while also influencing the
accessibility of genes for transcription.

Chromosomes: Chromosomes are tightly coiled entities made
of DNA and proteins that carry the cell's genetic information.
They become visible during cell division and are essential for
ensuring the precise allocation of genetic material to daughter
cells.
Chromatids: Chromatids are the two identical halves of a
replicated chromosome, joined together at the centromere. In
the process of cell division, these chromatids are divided and
become individual chromosomes in the newly formed daughter
cells.
Centromeres: The centromere is the region on a chromosome
where the two sister chromatids are connected. It serves as the
attachment point for spindle fibers during cell division, helping to ensure the proper separation of
chromatids.

Centrioles: Centrioles are tiny, cylindrical
structures composed of microtubules. They
play a crucial role in organizing the spindle
fibers, which are necessary for the proper
segregation of chromosomes during cell
division.
Centrosome: The centrosome is an
organelle located near the nucleus that acts
as the main organizing center for
microtubules in animal cells. It plays a vital role in assembling the spindle apparatus necessary for cell
division.

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Spindle fibers: Spindle fibers are protein
structures that develop during cell division. They
connect to chromosomes at the centromeres
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and are crucial for separating chromatids,
thereby ensuring that chromosomes are
accurately distributed to each daughter cell.

Cytoplasm: The cytoplasm is the semi-fluid
substance within the cell membrane, excluding the
nucleus. It contains various organelles and is where
many cellular activities, including metabolism and
protein synthesis, take place.

Daughter cells: Daughter cells are the two
new cells produced when a single parent
cell divides. During mitosis, these daughter
cells are genetically identical to each other
and to the original parent cell.

Germ Cells: Germ cells are cells that create
reproductive cells called gametes. Germ cells are
located only in the gonads and are called oogonia in
females and spermatogonia in males. In females, they
are found in the ovaries and in males, in the testes.
During oogenesis, germ cells divide to produce ova, or
eggs, in females.

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Gametes: These are the mature reproductive cells produced from germ cells. Gametes are haploid,
which means they have only one set of chromosomes. In males, the gametes are sperm cells, and in
females, they are egg cells. Gametes combine during fertilization to form a new organism, carrying
genetic information from both parents.
Haploid: Refers to a cell that contains a
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single set of chromosomes, which is half the
number found in diploid cells. In humans,
haploid cells have 23 chromosomes. These cells
are gametes (sperm and egg cells) and are
involved in reproduction.
Diploid: Refers to a cell that contains
two sets of chromosomes, one inherited from
each parent. In humans, diploid cells have 46
chromosomes arranged in 23 pairs. Most cells
in the body are diploid and participate in normal growth and cellular functions.

Mitosis

Cells go through different phases that include growth. DNA replication, cell division, and the production
of two genetically identical daughter cells. This sequence is known as the cell cycle which has two main
phases. Interphase and the mitotic phase, also known as mitosis.

Interphase
Interphase is the longest phase of the cell cycle, accounting for about 90 percent of the
total cycle. During interphase, a cell recovers from the previous division and performs
normal functions. It grows in size by forming more organelles and replicating its DNA
resulting in the duplication of cells chromosomal matter.

Eukaryotic cells that are actively dividing undergo a series of
stages called the cell cycle. This cycle includes two gap
phases (G1 and G2), a synthesis phase (S phase) where the
genetic material is replicated, and a mitotic phase (M phase)
during which mitosis divides the genetic material and the cell
splits into two daughter cells.

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Next, the cell will go through mitosis, which includes the division of the
nucleus and then the division of the cytoplasm called cytokinesis.
Mitosis also has several stages Prophase, Metaphase, Anaphase, and
Telophase which are finally followed by cytokinesis.
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Prophase

During Prophase the chromatin condenses into visible chromosomes and the nuclear membrane
disintegrates. The centrosomes move to the opposite pole of the cell as a spindle fiber form. The spindle
fibers attach to the centromere of the chromosomes.

Metaphase
Metaphase is characterized by the alignment of chromosomes at the
metaphase plane. An imaginary plane in the
middle of the cell. The spindle fibers ensure
each chromosome is properly aligned.

Anaphase
Anaphase begins when a sister chromatid of
each chromosome separates in a pole toward opposite poles of the cells
by the spindle fibers. Once the chromosomes reach the poles, the cell
elongates.

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Telophase

Page | 10

During telophase, the chromosomes decondensed, and new nuclear membranes form around each set.
The spindle fibers are disassembled and the cell prepares for cytokinesis. Cytokinesis, which sometimes
begins during telophase, is the cell cycle's final stage. Cytoplasm divides which forms two genetically
identical daughter cells. After cytokinesis, the two daughter cells enter interphase and the cell cycle begins
again.

Meiosis

Many organisms transfer their genes to offspring through sexual reproduction, which starts with
the fusion of two gametes to create a genetically unique embryo. This embryo develops into an adult,
passing genetic information to its progeny. Gametes are produced via meiosis.
Germline cells are those that undergo meiosis to form gametes. In diploid organisms, these
germline cells contain two copies of each chromosome. Germline cells produce haploid gametes through
meiosis, each with a single set of chromosomes. When these haploid gametes combine, they form a
diploid embryo that will mature into an adult. Meiosis is a critical part of the germline cell life cycle.
Similar to mitosis, germline cells first go through interphase, consisting of the G1, S, and G2
phases. During the S phase, DNA replication occurs, resulting in duplicated chromosomes known as sister
chromatids. These chromatids stay joined until the second division of meiosis.

Meiosis involves two rounds of cell division:
1. Meiosis I: This division results in two unique daughter cells, each with half the chromosome
number of the original germline cell.
2. Meiosis II: This division produces four haploid cells, each containing one copy of each
chromosome. These haploid cells are the gametes that participate in sexual reproduction.

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Meiosis I begins with Prophase I, where DNA condenses into
chromosomes, and duplicated sister chromatids pair up and connect at the
centromere. These pairs undergo synapsis, forming a complex of
homologous chromosomes. During this phase, crossing over
(recombination) occurs, exchanging chromosomal material between
chromatids, which contributes to genetic diversity. The nuclear membrane
breaks down, centrosomes move to opposite poles, and microtubules attach
to chromosomes.

In Metaphase I, paired chromosomes align at the cell's equator randomly,
leading to various combinations of chromosomes.

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During Anaphase I, homologous chromosomes separate and move to
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opposite poles of the cell, while sister chromatids remain attached at their
centromeres.

The final stages, Telophase I and cytokinesis, result in the formation of two
daughter cells.

Meiosis II resembles mitosis. In Prophase II, chromosomes condense
again, the nuclear envelope disintegrates, and spindle fibers form.
Unlike Prophase I, there is no synapsis or crossing over in Prophase II.

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In Metaphase II, chromosomes align at the cell's equator randomly.

During Anaphase II, sister chromatids are separated and pulled to
opposite poles, with microtubules assisting in the process.

Finally, in Telophase II and cytokinesis,
the cell divides into four unique haploid cells.
These gametes can then fuse during fertilization
to form a diploid embryo, which will develop
through numerous mitotic divisions into a new adult.

Mitosis vs. Meiosis: A Comparative Table

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Mitosis and meiosis are two fundamental processes of cell division in eukaryotic organisms. While
both involve the division of a parent cell into daughter cells, they differ significantly in their outcomes and
functions. Here's a table highlighting the key differences between these two processes:

Page | 14
Feature Mitosis Meiosis

Growth, repair, and asexual Sexual reproduction, genetic
Purpose
reproduction diversity

Cell Type Somatic cells (body cells) Germ cells (sex cells)

Number of Divisions One Two

Number of Daughter Cells Two Four

Haploid (n) - half the
Chromosome Number in Diploid (2n) - same as parent
number of chromosomes as
Daughter Cells cell
the parent cell

Genetically different from
Genetic Identity of Genetically identical to the
the parent cell and each
Daughter Cells parent cell
other

Homologous Chromosome
Does not occur Occurs during prophase I
Pairing

Occurs during prophase I,
exchanging genetic material
Crossing Over Does not occur
between homologous
chromosomes

Centromere Splitting Occurs during anaphase Occurs during anaphase II

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Feature Mitosis Meiosis

Occurs during prophase I,
forming tetrads (bivalents) Page | 15
are paired homologous
chromosomes, consisting of
Synapsis Does not occur four chromatids, that form
during prophase I of meiosis
and are key players in the
process of genetic
combination.

Occurs during prophase I,
Tetrad Formation Does not occur consisting of four
chromatids

Chiasmata or chiasma
(singular) are the points
where homologous Present during prophase I
chromosomes physically Absent and metaphase I, indicating
cross over and exchange crossing over
genetic material during
meiosis.

Occurs before meiosis I, but
Interphase Occurs before each division
not before meiosis II

Occurs once before the Occurs once before meiosis
DNA Replication
division I, but not before meiosis II

Duration Relatively shorter Relatively longer

Skin cell division, wound Sperm and egg cell
Examples
healing formation

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Key Takeaways:

Mitosis produces two genetically identical daughter cells, maintaining the chromosome number
of the parent cell. It is essential for growth, repair, and asexual reproduction.

Meiosis produces four genetically diverse daughter cells, each with half the chromosome
Page | 16
number of the parent cell. This process is crucial for sexual reproduction and genetic variation.

Further Exploration:

Explore the specific stages of mitosis and meiosis (prophase, metaphase, anaphase, telophase)
to gain a deeper understanding of the mechanisms involved.

Investigate the role of meiosis in genetic diversity and its implications for evolution.

Research the potential consequences of errors in mitosis and meiosis, such as cancer and
aneuploidy.

What is Genetics?

Genetics is the science that studies genes and how they are inherited from one generation to the
next. Genes are responsible for determining various characteristics, such as why one child may have
blonde hair like their mother while another has brown hair like their father. This field also explores why
certain genetic conditions may appear in families and how sex is determined in offspring.

What are Genes?
Genes are small segments of
DNA (deoxyribonucleic acid) found
within every cell. They are so tiny that
only a powerful microscope can
reveal them. DNA is composed of four
chemicals that pair in different ways
to form codes for genes. Each
individual has around 20,000 genes,
which influence traits like eye color,
body structure, and sex.
DNA (deoxyribonucleic acid)
is composed of four chemical bases that pair in specific ways to form the genetic code. These bases are:
1. Adenine (A)

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2. Thymine (T)
3. Cytosine (C)
4. Guanine (G)
In the structure of DNA, these bases pair in a specific way:
Adenine (A) pairs with Thymine (T)
Page | 17
Cytosine (C) pairs with Guanine (G)
These base pairs form the "rungs" of the DNA double helix,
and the sequence of these base pairs creates the genetic code that
determines the structure and function of genes. The order of these
bases in the DNA sequence is what encodes the instructions for
building proteins and other molecules essential for life.

What are Alleles?
Alleles are different versions or forms of the same gene that exist at the same position, or locus, on a
chromosome. Alleles can vary in sequence and function, leading to different traits or characteristics in an
organism. For example, a gene responsible for eye color might have different alleles that result in blue,
brown, or green eyes.

Dominant and Recessive Alleles:
Dominant Alleles: These
alleles express their traits even
if only one copy is present
(heterozygous). Dominant
alleles are generally denoted
by capital letters(e.g., "B").
Recessive Alleles: These
alleles express their traits only
when two copies are present
(homozygous). They are
represented by lowercase
letters (e.g., "b").

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Homozygous and Heterozygous:
Homozygous: An individual has two
identical alleles for a gene (e.g., BB or bb).
Heterozygous: An individual has two
Page | 18
different alleles for a gene (e.g., Bb).

Genotype and Phenotype
Genotype: The genetic makeup of an organism. For
example, a plant with a genotype "RR" for flower color will
have red flowers, assuming "R" is the dominant allele for
red.
Phenotype: The observable/physical characteristics of an
organism, resulting from the genotype. For instance, a
plant with "RR" or "Rr" will show red flowers, while "rr" will
produce white flowers.

Hormones

Hormones are chemical messengers produced by glands in the endocrine system that travel
through the bloodstream to tissues and organs, regulating various bodily functions. Hormones are
produced by different glands, including the pituitary gland, thyroid gland, adrenal glands, and
reproductive organs (ovaries and testes), among others.

Key Functions of Hormones:
1. Regulation of Growth and Development: Hormones like growth hormone (GH) are crucial for
physical development, including bone growth and muscle development.
2. Metabolism Control: Hormones such as insulin and thyroid hormones regulate how the body uses
and stores energy from food.
3. Mood and Emotional Regulation: Hormones like serotonin (Serotonin is a neurotransmitter,
often referred to as the "feel-good" chemical, that plays a crucial role in mood regulation and
overall mental well-being) and cortisol (Cortisol is a steroid hormone, often called the "stress
hormone," produced by the adrenal glands in response to stress and low blood-glucose
concentration) influence mood, stress response, and emotional well-being. These two hormones
interact in stress response and emotional regulation. Chronic stress and elevated cortisol levels
can reduce serotonin levels, potentially leading to mood disorders such as anxiety and depression.

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4. Homeostasis Maintenance: Hormones help maintain the body’s internal balance, such as
regulating blood pressure, blood sugar levels, and fluid balance.
5. Immune System Regulation: Some hormones, like corticosteroids, help regulate immune
responses and inflammation.
6. Reproductive Functions: Reproductive hormones such as estrogen, progesterone, and
Page | 19
testosterone are essential for sexual development, reproduction, and the menstrual cycle.

Reproductive hormones are chemicals produced by glands in the body that regulate various aspects of
the reproductive system, including development, sexual function, the menstrual cycle, and pregnancy.
Here's an overview of key reproductive hormones, their functions, and where they are produced:
Key Reproductive Hormones:
1. Estrogen is a steroid hormone associated with the female reproductive organs and is responsible
for developing female sexual characteristics. Estrogen or estradiol is the most common form of
estrogen hormone for FDA-approved treatment as hormone replacement therapy (HRT) in
managing symptoms associated with menopause.
o Location: Mainly produced in the ovaries; smaller amounts are made in the adrenal glands
and fat tissue.
o Functions:
▪ Regulates the menstrual cycle and helps prepare the uterus for pregnancy.
▪ Aids in the development of female secondary sexual characteristics (e.g., breasts).
▪ Supports the health of reproductive tissues.
2. Progesterone is an endogenous steroid hormone that is commonly produced by the adrenal
cortex as well as the gonads, which consist of the ovaries and the testes. Progesterone is also
secreted by the ovarian corpus luteum during the first ten weeks of pregnancy, followed by the
placenta in the later phase of pregnancy.
o Location: Primarily produced by the ovaries and the placenta during pregnancy.
o Functions:
▪ Prepares the uterine lining for implantation of a fertilized egg and supports
pregnancy.
▪ Works with estrogen to regulate the menstrual cycle.
3. Testosterone is the primary male hormone regulating sex differentiation, producing male sex
characteristics, spermatogenesis, and fertility. Testosterone's effects are first seen in the fetus.
During the first 6 weeks of development, the reproductive tissues of males and females are
identical.
o Location: Mainly produced in the testes in males and in smaller amounts by the ovaries
and adrenal glands in both sexes.
o Functions:
▪ Drives the development of male secondary sexual characteristics, such as
increased muscle mass and deeper voice.

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▪ Essential for sperm production and male libido.
4. Follicle-Stimulating Hormone (FSH) is a hormone your pituitary
gland makes and releases that plays a role in sexual development
and reproduction. It affects the function of ovaries and testicles.
Despite its name, follicle-stimulating hormone doesn't directly
Page | 20
affect your hair follicles or hair growth.
o Location: Produced by the pituitary gland in the brain.
o Functions:
▪ Promotes the growth and development of ovarian follicles in females.
▪ Stimulates the production of sperm in males.
5. Luteinizing Hormone (LH) is a chemical in your body that triggers
important processes in your reproductive system. LH spurs
ovulation and helps with the hormone production needed to
support pregnancy. Your provider may order a test to check your
LH levels if you have fertility issues or irregular menstruation.
o Location: Also produced by the pituitary gland.
o Functions:
▪ Triggers ovulation and the release of an egg from the ovary in females.
▪ Stimulates testosterone production in males.
6. Gonadotropin-Releasing Hormone (GnRH) plays a crucial role in regulating the reproductive
system. It is released in a pulsatile manner from the hypothalamus, which then controls the
secretion of two key hormones from the pituitary gland: follicle-stimulating hormone (FSH) and
luteinizing hormone (LH). These gonadotropins are essential for managing the functions of the
gonads, including the production of sex hormones and the maturation of gametes, which are the
eggs in females and sperm in males. The precise timing and frequency of GnRH pulses are critical
for proper reproductive function.
o Location: Produced by the hypothalamus in the brain.
o Functions:
▪ Regulates the release of FSH and LH from the pituitary gland, which are critical
for the reproductive cycle.
7. Human Chorionic Gonadotropin (hCG) is a hormone produced primarily
by syncytiotrophoblastic cells of the placenta during pregnancy. The hormone stimulates the
corpus luteum to produce progesterone to maintain the pregnancy. Smaller amounts of hCG are
also produced in the pituitary gland, the liver, and the colon.

o Location: Produced by the placenta during pregnancy.
o Functions:
▪ Helps maintain the corpus luteum, which is crucial for producing progesterone in
early pregnancy.

“Nourishing the mind, nurturing the heart, leading the Future “ Telefax No. (044) 463-0226
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8. Prolactin is a polypeptide hormone responsible for lactation, breast development, and hundreds
of other actions needed to maintain homeostasis. The chemical structure of prolactin is similar to
the structure of growth and placental lactogen hormones.
o Location: Secreted by the pituitary gland.
o Functions:
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▪ Stimulates milk production in women after childbirth.
▪ Involved in reproductive health and regulation.
9. Oxytocin is a natural hormone that manages key aspects of the female and male reproductive
systems, including labor and delivery and lactation, as well as aspects of human behavior. Your
hypothalamus makes oxytocin, but your posterior pituitary gland stores and releases it into your
bloodstream.
o Location: Produced by the hypothalamus and released by the pituitary gland.
o Functions:
▪ Induces uterine contractions during labor.
▪ Facilitates milk release during breastfeeding and plays a role in social bonding.
These hormones are interconnected and work together to regulate the reproductive processes, ensuring
proper reproductive health and function in both males and females.

“Nourishing the mind, nurturing the heart, leading the Future “ Telefax No. (044) 463-0226
[email protected]
www.neust.edu.ph