Preface
Page: i-i (1)
Author: Sanaullah Sajid, Sajjad ur Rahman, Shahid Mahmood, Shayan Bashir and Mudasser Habib
DOI: 10.2174/9789815238037124010001
The Cell and its Molecular Constituents
Page: 1-14 (14)
Author: Samiullah Sajid* and Imran Abdullah
DOI: 10.2174/9789815238037124010003
PDF Price: $15
Abstract
The cell is the basic unit of life and the fundamental building block of all
living organisms. It is a complex and dynamic structure composed of various molecular
constituents. These constituents include the plasma membrane, cytoplasm, organelles,
and genetic material. The plasma membrane is a thin, flexible layer that separates the
cell from its surroundings and regulates the movement of substances into and out of the
cell. The cytoplasm is a gel-like substance that contains various organelles, such as
mitochondria, ribosomes, and the endoplasmic reticulum, which are involved in
multiple cellular functions. The genetic material, composed of DNA and RNA,
contains instructions for synthesizing proteins, the building blocks of life. The cell and
its molecular constituents play vital roles in maintaining the organism’s integrity,
responding to environmental cues, and carrying out essential physiological functions.
Understanding the organization and function of these molecular constituents is crucial
for advancing our knowledge of biology and developing new therapies for various
diseases.
Nucleic Acid Structure
Page: 15-35 (21)
Author: Atta Ur Rahman*
DOI: 10.2174/9789815238037124010004
PDF Price: $15
Abstract
Nucleic acids are essential biomolecules that store and transmit genetic
information in all living organisms. The structure of nucleic acids, specifically DNA
(deoxyribonucleic acid) and RNA (ribonucleic acid), is crucial for their function. The
backbone of nucleic acids is composed of alternating sugar and phosphate groups,
while the nucleotide bases (adenine, guanine, cytosine, thymine and uracil) protrude
from the sugar-phosphate backbone. The bases form specific hydrogen bonds with
complementary bases on the opposite strand, resulting in the double-helical structure of
DNA. RNA is usually single-stranded but can form secondary structures through base
pairing. The three-dimensional structure of nucleic acids is also important for their
function, as it determines the interactions between nucleic acids and other molecules,
such as proteins. Understanding nucleic acid structure is fundamental for many areas of
biology, including genetics, molecular biology and biotechnology.
DNA Replication
Page: 36-48 (13)
Author: Kainat Gul*
DOI: 10.2174/9789815238037124010005
PDF Price: $15
Abstract
DNA replication is the process by which a cell makes identical copies of its
genetic material. This process is essential for transmitting genetic information from one
generation of cells to the next during cell division. DNA replication is a complex
process involving unwinding the double helix, separating the two strands, and
synthesizing new complementary strands. The process is catalyzed by a large complex
of proteins called the replisome, which includes DNA polymerases, helicases, and
other enzymes. The accuracy of DNA replication is critical to the maintenance of
genetic information, and errors in replication can lead to mutations and genetic
diseases. Understanding the molecular mechanisms of DNA replication is fundamental
to many fields of biology, including genetics, biotechnology, and medicine.
Mutation and DNA Repairs
Page: 49-61 (13)
Author: Shumaila Yousaf* and Saba Nasir
DOI: 10.2174/9789815238037124010006
PDF Price: $15
Abstract
Mutations are changes in the DNA sequence that can occur spontaneously or
due to exposure to mutagenic agents such as chemicals, radiation, or viruses. These
changes can have a wide range of effects on the organism, from no effect at all to
causing genetic disorders or cancer. DNA repair mechanisms exist to correct these
mutations, ensuring the integrity of the genetic material. There are several types of
DNA repair mechanisms, including base excision repair, nucleotide excision repair,
and mismatch repair, each designed to correct different types of DNA damage. The
repair mechanisms are highly regulated and involve a complex network of proteins that
detect, remove, and replace damaged DNA. Defects in DNA repair mechanisms can
lead to an accumulation of mutations, increasing the risk of cancer and other diseases.
For example, individuals with inherited mutations in DNA repair genes have a higher
risk of developing certain types of cancer, such as breast and ovarian cancer.
Restriction Enzymes
Page: 62-70 (9)
Author: Zain Ul Abedien*
DOI: 10.2174/9789815238037124010007
PDF Price: $15
Abstract
Restriction enzymes are bacterial enzymes that cleave DNA at specific
recognition sequences, usually consisting of four to eight base pairs. These enzymes
have become invaluable tools in molecular biology, enabling scientists to manipulate
and analyze DNA in various ways. Restriction enzymes are used in various
applications, including gene cloning, DNA fingerprinting, and genome mapping. By
cleaving DNA at specific sites, restriction enzymes can generate DNA fragments with
defined ends, which can then be ligated into vectors for cloning or PCR amplification.
Using restriction enzymes in conjunction with gel electrophoresis allows for the
separation and analysis of DNA fragments based on their size. There are over 3,000
known restriction enzymes, each with its unique recognition sequence. Many of these
enzymes have been isolated from bacteria and are named after the bacterial species
from which they were derived. Some restriction enzymes have also been engineered to
recognize new recognition sequences, expanding their usefulness in molecular biology.
The discovery and development of restriction enzymes have revolutionized molecular
biology, allowing scientists to manipulate and analyze DNA in previously impossible
ways. As our understanding of the molecular mechanisms of these enzymes continues
to grow, they will likely play a critical role in genetics and biotechnology.
Cloning and Expression Vectors
Page: 71-81 (11)
Author: Zain Ul Abedien* and Rai Shafqat Ali
DOI: 10.2174/9789815238037124010008
PDF Price: $15
Abstract
Cloning and expression vectors are essential tools in molecular biology that
enable researchers to manipulate and study genes and proteins. Cloning vectors are
DNA molecules that can carry foreign DNA fragments and introduce them into host
cells. Expression vectors are specialized cloning vectors designed to drive the
expression of foreign genes in a host cell, allowing researchers to produce large
quantities of recombinant proteins. The most commonly used cloning vectors are
plasmids; circular DNA molecules that can replicate independently of the host
chromosome. Plasmids can be engineered to contain various features such as selectable
markers, multiple cloning sites, and regulatory sequences. These features make
plasmids versatile application tools, including gene cloning, mutagenesis, and genetic
engineering. Expression vectors are typically based on plasmids and contain additional
elements that enable the efficient expression of the foreign gene. These elements
include a strong promoter, a ribosome binding site, and a transcription terminator,
which work together to ensure the production of the recombinant protein. The choice of
expression vector depends on the desired protein expression level, the host cell type,
and downstream applications. The use of cloning and expression vectors has
revolutionized the field of molecular biology, enabling the production of recombinant
proteins, genetic engineering of organisms, and gene therapy. However, using these
tools requires careful consideration of potential risks, such as unintended genetic
modifications or the spread of genetically modified organisms.
Recombinant DNA Technology
Page: 82-96 (15)
Author: Farwa Mehmood*
DOI: 10.2174/9789815238037124010009
PDF Price: $15
Abstract
Recombinant DNA technology, also known as genetic engineering, has
revolutionized the field of molecular biology by allowing researchers to manipulate and
transfer DNA sequences between different organisms. This technique involves the use
of restriction enzymes to cut DNA molecules, which can then be spliced together to
create novel sequences. Recombinant DNA technology has numerous applications in
medicine, agriculture, and biotechnology. For example, it has been used to produce
human insulin, growth hormone, and other therapeutic proteins. In agriculture, it has
been used to create crops with improved yield and resistance to pests and diseases.
However, the use of recombinant DNA technology also raises ethical and safety
concerns, and its regulation is subject to the ongoing debate.
DNA Polymorphisms and Genetic Fingerprint
Page: 97-110 (14)
Author: Itrat Fatima Toor*
DOI: 10.2174/9789815238037124010010
PDF Price: $15
Abstract
DNA polymorphisms are variations in the genetic sequence that occur
within a population. These polymorphisms can be used as genetic markers to identify
individuals, determine familial relationships, and study population genetics. Genetic
fingerprinting is a widely used method for identifying individuals based on DNA
polymorphisms. Genetic fingerprinting involves the analysis of DNA polymorphisms
at multiple loci to generate a unique genetic profile for an individual. The most
common types of DNA polymorphisms used for genetic fingerprinting are short
tandem repeats (STRs) and single nucleotide polymorphisms (SNPs). STRs are short,
repeated sequences of DNA that vary in length between individuals. They are highly
polymorphic and generate DNA profiles by analyzing the number of repeats at each
locus. SNP markers, on the other hand, are single nucleotide variations that occur at
specific positions within the genome. They are less polymorphic than STRs, but
genetic mapping and association studies are widely used. Genetic fingerprinting has
many applications, including forensic science, paternity testing, and conservation
biology. However, the use of genetic data also raises ethical concerns regarding privacy
and discrimination.
Application of Molecular Biology in Biotechnology
Page: 111-120 (10)
Author: Hira Asghar*
DOI: 10.2174/9789815238037124010011
PDF Price: $15
Abstract
Molecular biology is the study of molecular interactions and structures that
govern cellular processes. Biotechnology is an interdisciplinary field that utilizes
biological systems to create new products and technologies. The application of
molecular biology in biotechnology has revolutionized the way we understand and
manipulate biological systems. This technology has enabled the development of new
diagnostic tools, therapies, and drugs. The ability to manipulate DNA and RNA
sequences has also allowed the creation of genetically modified organisms with
desirable traits, including crops and animals. In addition, molecular biology has
facilitated the development of gene therapy, where defective genes are replaced or
repaired, and vaccines, where specific antigens are identified and synthesized.
Integrating molecular biology and biotechnology has opened up vast opportunities for
research and innovation in many fields, including medicine, agriculture, and
environmental science. As a result, the application of molecular biology in
biotechnology holds great promise for the future of science and technology.
Application of Molecular Biology in Gene Therapy
Page: 121-131 (11)
Author: Maheen Shafiq*
DOI: 10.2174/9789815238037124010012
PDF Price: $15
Abstract
Gene therapy treats genetic and acquired diseases by introducing functional
genes into cells to replace or correct defective genes. The field of molecular biology
has played a significant role in the development of gene therapy, providing tools and
techniques to manipulate and analyze genes and their expression. One of the main
challenges in gene therapy is the efficient delivery of therapeutic genes to the target
cells. Molecular biology has provided a range of vectors, such as viruses and plasmids,
that can be used to deliver genes to cells and methods to modify these vectors to
improve their efficacy and safety. Molecular biology has also contributed to the
development of gene editing technologies, such as CRISPR-Cas9, which can be used to
correct or modify genes at the genomic level. This approach can potentially treat
genetic disorders by targeting the underlying genetic mutations. In addition, molecular
biology has facilitated the development of methods to regulate gene expressions, such
as gene silencing and RNA interference, which can be used to turn off genes that cause
disease. Despite the progress made in gene therapy, many challenges remain to be
addressed, including ensuring the safety and efficacy of gene therapy approaches.
Continued advancements in molecular biology are critical for developing safe and
effective gene therapies for treating genetic and acquired diseases.
Molecular Biology of Sports
Page: 132-142 (11)
Author: Sanaullah Sajid*
DOI: 10.2174/9789815238037124010013
PDF Price: $15
Abstract
Molecular biology of sports is a rapidly evolving field that investigates the
relationship between genetic and molecular factors and athletic performance. Research
in this area aims to identify genes and molecules influencing physical traits such as
strength, endurance, and speed. By understanding the underlying biology of athletic
performance, scientists can develop new approaches to improve athletic training, injury
prevention, and rehabilitation. The study of molecular biology in sports also provides
insights into the relationship between genetics and lifestyle factors, such as diet and
exercise, that affect overall health and well-being. This abstract will provide an
overview of the current state of research in molecular biology of sports, including
recent advances in genomics, transcriptomics, proteomics, and metabolomics, and how
these techniques are applied to sports science.
Molecular Basis of Cancer
Page: 143-155 (13)
Author: Maliha Sarfraz* and Hayat Ullah
DOI: 10.2174/9789815238037124010014
PDF Price: $15
Abstract
Cancer is a disease that arises from the uncontrolled growth of cells due to
genetic mutations and epigenetic changes. Molecular biology has provided valuable
insights into cancer development and progression mechanisms. Cancer cells have
alterations in the genes that regulate cell growth, division, and death, leading to the
accumulation of mutations that confer a survival advantage. Oncogenes promote cell
growth and division, while tumour suppressor genes inhibit cell proliferation and
induce cell death. Alterations in these genes and changes in DNA methylation and
histone modifications lead to the dysregulation of cell signalling pathways, which
contribute to cancer development. In addition, the tumour microenvironment plays a
critical role in cancer progression by providing growth factors, cytokines, and
extracellular matrix components that promote tumour growth and invasion. Molecular
biology techniques such as DNA sequencing, gene expression profiling, and epigenetic
analysis have facilitated the identification of driver mutations and key molecular
pathways involved in cancer development, leading to targeted therapies that exploit
these vulnerabilities. Understanding the molecular basis of cancer can revolutionize
cancer diagnosis, treatment, and prevention.
Molecular Mechanisms of Diabetes Mellitus
Page: 156-176 (21)
Author: Itrat Fatima Toor*, Munazzah Sajid and Haseeb Ullah Sajid
DOI: 10.2174/9789815238037124010015
PDF Price: $15
Abstract
Diabetes Mellitus (DM) is a complex metabolic disorder characterized by
high blood glucose levels resulting from defects in insulin secretion, insulin action, or
both. The disease affects millions worldwide and is a leading cause of morbidity and
mortality. Molecular mechanisms underlying the pathogenesis of diabetes mellitus are
complex and involve multiple cellular and molecular processes. In this review, we
discuss the current understanding of the molecular mechanisms involved in the
development and progression of diabetes mellitus. Specifically, we focus on the role of
pancreatic beta-cell dysfunction, insulin resistance, and abnormalities in glucose
metabolism, lipids, and proteins. We also examine the contribution of genetic and
environmental factors to developing diabetes mellitus. Additionally, we highlight the
importance of targeting these molecular mechanisms for developing new and effective
therapies for managing diabetes mellitus. A better understanding of the molecular
mechanisms involved in diabetes mellitus can lead to more effective treatments and
better disease management.
Molecular Basis of Obesity
Page: 177-187 (11)
Author: Itrat Fatima Toor*
DOI: 10.2174/9789815238037124010016
PDF Price: $15
Abstract
Based on the classification by the World Organization of Health (WHO), it
considers that a BMI equal to or greater than 30 kg/m2
corresponds to obesity.
Likewise, a BMI value equal to or greater than 25 kg/m2
increases the chances of
developing diseases associated with obesity. It is estimated that heredity in the
variation of the BMI is in the range of 0.4 to 0.7; that is, the probability of inheriting
obesity is very low and is more associated with exogenous factors. Obesity
comorbidities are a risk factor for developing insulin resistance (IR), DM2, CVD,
stroke, osteoarthritis, endometrial, breast, and colon cancer, among other chronic
noncommunicable conditions. In addition, obesity is also linked to various digestive
diseases, including gastroesophageal reflux disease, esophagitis, colorectal polyps, and
non-alcoholic steatohepatitis. Obesity and overweight are associated with 44% of DM2
cases, 23% of ischemic heart disease cases, and 7 to 41% of cancer cases.
Molecular Basis of Hepatitis B
Page: 188-200 (13)
Author: Saima Pervaiz* and Sara Masood Cheema
DOI: 10.2174/9789815238037124010017
PDF Price: $15
Abstract
Hepatitis B virus (HBV) is a serious global health problem affecting
millions worldwide. Chronic HBV infection can lead to liver cirrhosis and
hepatocellular carcinoma, making it a major cause of morbidity and mortality. The
molecular basis of HBV infection and pathogenesis is complex and involves multiple
interactions between the virus and the host immune system. HBV is a partially doublestranded DNA virus replicating through reverse RNA intermediate transcription. The
virus has several proteins, including the envelope protein (HBsAg), core protein
(HBcAg), and polymerase (HBp), that play critical roles in virus entry, replication, and
assembly. The viral genome is organized into four overlapping open reading frames
(ORFs), each encoding a different viral protein. During HBV infection, the virus
initially binds to heparan sulfate proteoglycans on the cell surface, followed by binding
to specific receptors, such as the sodium taurocholate co-transporting polypeptide
(NTCP). The virus then enters the cell through endocytosis, where it is uncoated and
releases the viral DNA into the nucleus. The viral DNA is then transcribed by the host
RNA polymerase II, producing viral mRNAs translated into viral proteins. One key
factor determining the outcome of HBV infection is the host's immune response. The
innate immune response plays an important role in controlling the initial phase of HBV
infection, while the adaptive immune response, particularly the CD8+ T cell response,
is critical for the clearance of the virus. However, in some cases, the immune response
cannot clear the virus, leading to chronic infection. Understanding the molecular basis
of HBV infection and pathogenesis is critical for developing effective treatments and
vaccines. Current treatments for chronic HBV infection include nucleoside/nucleotide
analogs and interferon-based therapies, which can suppress viral replication and reduce
liver damage. However, these treatments are not curative and can have significant side
effects. Vaccination against HBV is highly effective in preventing infection and is
recommended for all individuals at risk of HBV infection.
Molecular Basis of Hepatitis C
Page: 201-211 (11)
Author: Muneeb Ur Rehman and Hafiz Zain Ul Abideen*
DOI: 10.2174/9789815238037124010018
PDF Price: $15
Abstract
Hepatitis C virus (HCV) is a significant cause of chronic liver disease
worldwide. The molecular basis of HCV infection and replication has been extensively
studied, leading to the identification of vital viral proteins and their interactions with
host factors. The HCV genome encodes a single polyprotein cleaved by host and viral
proteases into individual proteins, including the core, envelope glycoproteins (E1 and
E2), p7, NS2, NS3, NS4A, NS4B, NS5A, and NS5B. These viral proteins play critical
roles in virus assembly, entry, replication, and evasion of host immune responses. The
HCV envelope glycoproteins E1 and E2 are responsible for virus attachment and entry
into host cells through interactions with various host receptors, including CD81,
scavenger receptor class B type I (SR-BI), and tight junction proteins. The viral protein
NS3 has multiple functions, including protease and helicase activities, which are
critical for viral RNA replication. NS5A is an essential component of the viral
replication complex and regulates viral RNA replication, virion assembly, and
modulation of host immune responses. NS5B is the RNA-dependent RNA polymerase
responsible for viral RNA synthesis. The molecular mechanisms underlying HCVinduced pathogenesis and the development of chronic infection remain poorly
understood. However, recent studies have shed light on the interactions between HCV
and host factors, including the innate and adaptive immune responses and the roles of
viral proteins in modulating these responses. These insights have led to new antiviral
therapies, including direct-acting antivirals (DAAs) that target viral proteins in RNA
replication.
Molecular Basis of the Human Immunodeficiency Virus
Page: 212-224 (13)
Author: Maliha Sarfraz*, Sanaullah Sajid and Hayat Ullah
DOI: 10.2174/9789815238037124010019
PDF Price: $15
Abstract
Human Immunodeficiency Virus (HIV) is the causative agent of Acquired
Immunodeficiency Syndrome (AIDS), a deadly disease that affects the human immune
system. HIV is a retrovirus that infects T-cells, macrophages, and dendritic cells in the
immune system, leading to their destruction and, ultimately, the onset of AIDS. The
molecular basis of HIV infection involves the interaction of the viral envelope protein
gp120 with the host cell receptor CD4 and a co-receptor such as CCR5 or CXCR4.
This binding triggers a conformational change in gp120 that exposes a fusion peptide,
allowing the viral envelope to fuse with the host cell membrane and release its contents
into the cytoplasm. Once inside the host cell, the viral genome is reverse-transcribed
into DNA, which is then integrated into the host cell genome by the viral integrase
enzyme. This allows the virus to replicate with the host cell and evade the immune
system's surveillance. Despite advances in antiretroviral therapy, HIV continues to pose
a significant global health threat, with over 38 million people living with HIV/AIDS
worldwide. Understanding the molecular mechanisms of HIV infection is critical for
developing effective treatments and vaccines to combat this deadly disease.
Molecular Mechanisms of Human Immunodeficiency Virus Resistance to Antiretroviral
Page: 225-241 (17)
Author: Saima Pervaiz* and Shehryar Awan
DOI: 10.2174/9789815238037124010020
PDF Price: $15
Abstract
Antiretroviral therapy (ART) has transformed the treatment of human
immunodeficiency virus (HIV) infection, improving life expectancy and quality of life
for millions worldwide. However, the emergence of drug-resistant HIV strains poses a
significant challenge to the effectiveness of ART. The molecular mechanisms
underlying HIV resistance to antiretroviral drugs involve multiple genetic changes in
the viral genome that reduce drug susceptibility, often through alterations in the viral
enzymes targeted by the drugs. The primary targets of ART are the viral reverse
transcriptase (RT), protease (PR), and integrase (IN) enzymes, which are essential for
HIV replication. Resistance to nucleoside reverse transcriptase inhibitors (NRTIs)
results from mutations in the viral RT enzyme that reduce drug incorporation into the
viral DNA chain. Non-nucleoside reverse transcriptase inhibitors (NNRTIs) bind to a
hydrophobic pocket near the RT active site, and resistance to these drugs arises from
mutations that alter the binding pocket conformation. Protease inhibitors (PIs) bind to
the viral PR enzyme, and resistance results from mutations that alter the enzyme's
conformation, reducing drug binding affinity. Integrase strand transfer inhibitors
(INSTIs) bind to the viral IN enzyme, and resistance arises from mutations that affect
drug binding or alter the IN active site. The emergence of drug-resistant HIV strains
can also result from poor adherence to ART, leading to the selection of pre-existing
resistant viruses or the development of new resistance mutations. In addition, the
genetic diversity of HIV and the high viral replication and mutation rate contribute to
the rapid evolution and emergence of drug-resistant strains.
Subject Index
Page: 242-248 (7)
Author: Sanaullah Sajid, Sajjad ur Rahman, Shahid Mahmood, Shayan Bashir and Mudasser Habib
DOI: 10.2174/9789815238037124010021
Introduction
Fundamentals of Cellular and Molecular Biology is a comprehensive textbook designed to explain the molecular mechanisms that underpin the functions and structures within living organisms. This resource focuses on improving the reader's understanding and exploration of the cellular and molecular basis of life, emphasizing the latest research findings and technological advancements. The book is structured into 18 chapters that systematically cover topics ranging from the basic structural components of cells to the complex processes of gene expression, protein synthesis, and cell signaling. It offers a detailed examination of DNA replication, repair mechanisms, and the molecular basis of genetic diseases. Additionally, the book explains the application of molecular biology in biotechnology, medicine, and environmental science, as well as advanced topics like cloning, gene therapy, and molecular diagnostics. Key features: - Clear explanations of complex concepts, bridging basic biology concepts with applied scientific fields - Uses real-world examples to illustrate scientific principles - Includes information on the latest research and technological breakthroughs. - Glossaries and references for each chapter - Facilitates learning with diagrams, flowcharts, and tables that summarize critical information, making complex subjects accessible. Fundamentals of Cellular and Molecular Biology is an essential resource for students in life science courses such as biology, biochemistry, biotechnology, and medicine.