Book Volume 2
Chromosome 13
Page: 1-18 (18)
Author: Aishwarya Raja, Ravi Gor, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020003
PDF Price: $30
Abstract
Chromosome 13 represents around 4 percent of the total cellular DNA with
115 million base pairs. It is home to various tumor suppressors and oncogenes, such as
ADP ribosylation factors like GTPase-11 (ARL11), Retinoblastoma-1 (RB1), Ras-related protein Rap-2a (RAP2A), etc. Most of the somatic mutations in this chromosome lead to cancer development. Further, deletion in this chromosome has been
reported to support the cancer of leukemias, lymphomas, etc. In this chapter, we have
tried to list cancer-causing genes and their possible oncogenesis in cancer development.
Chromosome 14
Page: 19-61 (43)
Author: Harini Hariharan, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020004
PDF Price: $30
Abstract
Cancer genetics has focused on several mutational events within a tumor cell
for many years. Recently, the study on cancer genetics has been widened by
concentrating on the importance of intercellular communication and epigenetic events
causing tumor progression and development. The translocation of genetic material
betwixt chromosome 14 and other chromosomes may engender the formation of
various types of tumors. Recent studies emphasize that these chief translocations
between two chromosomes may disrupt the genes crucial for controlling cell growth
and cell division. The translocations involving chromosome-14 and other chromosomes
have been found in tumors including acute myeloid Leukemia, acute lymphoblastic
leukemia, acute bilineal leukemia, follicular lymphoma, small cell lung cancer, non-Hodgkin’s lymphoma, Burkitt lymphoma and multiple myeloma. The tumor suppressor
genes, such as ARID4A, ARID4B, BCL11B, BMP4, CCNB1IP1, CEBPE, DICER1,
DLK1, ESR2, FOXN3, HIF1A, MAX, MEG3, NDRG2 and TTF-1/NKX2-1 under
chromosome 14, play a hypercritical role by enhancing cellular differentiation,
migration, proliferation, metastasis, invasion, cellular growth, and development in
several tumors, including breast cancer, pancreatic tumor, osteosarcoma, lung cancer,
endocrine tumor, T-ALL, cystic nephroma, Hodgkin lymphoma, pleuropulmonary
blastomas, Sertoli Leydig ovarian tumors and rhabdomyosarcoma. Chapter 14
meticulously discusses the importance of each predominant gene under chromosome
14 in mediating tumorigenesis. In cancer genetics, these cardinal genes play a crucial
role by acting as an oncogene or a tumor suppressor in several cancers. Thus, targeting
these tumor-causing genes would provide a breakthrough in cancer biology and
oncology when concerned with future perspectives.
Chromosome 15
Page: 62-106 (45)
Author: Harini Hariharan, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020005
PDF Price: $30
Abstract
The genomic alteration at chromosome 15 has been widely recognized as the
utmost significant and prevalent alteration in several cancers, including non-small-cell
lung cancer, breast cancer, ovarian cancer, prostate cancer, gastrointestinal cancer,
acute lymphoblastic leukemia, colorectal carcinoma, hepatocellular carcinoma,
myeloma, pituitary adenomas, etc. Emerging reports suggest that the abnormalities of
prime genes in chromosome 15 have drastic effects on tumor development and
progression, and can be candidate biomarkers of disease prognosis, disease
progression, and response to treatment. The translocations involving chromosome 15
and other chromosomes have been found in tumors, including mucoepidermoid
carcinomas, mixed-lineage leukemia, colorectal cancer, pancreatic cancer, sarcoma,
lung adenocarcinoma, melanoma, brain cancer, cholangiocarcinoma, spitz tumor,
congenital mesoblastic nephroma, papillary thyroid cancer, pontine glioma tumors, and
acute promyelocytic leukemia. The tumor suppressor genes such as C15orf65, CSK,
CRABP1, DAPK2, FES, GREM1, KNSTRN, NEDD4-1, NTRK3, PML, SPRED1,
TPM1, and TCF12 under chromosome 15 play a crucial role by enhancing cellular
growth, proliferation, migration, invasion, metastasis, cellular differentiation, and
development in various cancer, including colorectal cancer, acute promyelocytic
leukemia, myeloid leukemia, breast cancer, thyroid carcinoma, glioblastoma,
intrahepatic cholangiocarcinoma, chondrosarcoma, cartilaginous cancer, Squamous cell
carcinoma, non- small-cell lung carcinomas, mucosal melanoma, and oral squamous
cell carcinoma. Chapter 15 discusses the significance of each important gene under
chromosome 15 in mediating oncogenesis. The elevated or attenuated expression levels
of these cardinal genes can either act as an oncogene or a tumor suppressor. Thus,
shedding light on these genes would be a game changer in the field of cancer genetics
and theragnostic.
Chromosome 16
Page: 107-178 (72)
Author: Sivasankari Ramadurai, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020006
PDF Price: $30
Abstract
Cancer is a heterogeneous disorder with invasive and metastatic potential. It
is a deadly disorder affecting 1 in 6 people worldwide. Hence, it is important to
eliminate the disease. Genetic alterations remain an underlying cause of cancer, and
several gene mutations were involved in causing different types of cancer. Recently,
researchers have been investigating the role of genetic mutations in causing cancer. For
this reason, the genes associated with chromosome 16 were investigated for their role
in causing cancer. This study revealed 70 genes associated with cancer. Of which, the
cadherin genes (CDH11, CDH13, and CDH1), AXIN-1, ANKRD11, BANP, CYLD,
CBFA2T3, IR8, MVP, MT1F, NQO1 and PYCARD was the tumor suppressor, and the
gene MSLN is the potential oncogene. CBFB and MYH11 are well-known fusion genes
associated with this chromosome. Loss of heterogeneity was noted in the q arm of this
chromosome. The chromosome translocations, t (16;16) (16) (p13q22), t (16;21) (21)
(p11;q22), t (12;16) (q13; p13; p11), t(16;21) (p11;q22) and t(7;16) (q33; p11) led to
the development of acute myeloid leukemia, leukemia, and sarcoma. Several other
genes associated with chromosome 16 responsible for cancer initiation and
proliferation are summarized in this chapter. A novel insight into the genetic
biomarkers and therapeutic targets has been provided to develop potential therapeutic
strategies against cancer.
Chromosome 17
Page: 179-201 (23)
Author: Jayasree Debnath, Kakaraparthi Shradda, Thilaga Thirugnanam, Advait Sohani, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020007
PDF Price: $30
Abstract
Cancer is a disease in which the body's cells divide disorderly and are likely
to spread to other organs. It has always been one of the world's top causes of death. A
growing population, low mortality rate, and lifestyle changes lead to an increase in the
number of cancer cases. It can be caused by genetic or environmental factors or a
combination of both. The risk of cancer increases with age as the body loses its ability
to eliminate the damaged cells. Cancer-causing genes can be inherited or acquired due
to exposure to carcinogens. Cancers are inherited when a mutation occurs in the germ
cells. The carcinogens can alter the DNA of a normal gene (a proto-oncogene)
converting it into a cancerous oncogene. Genes that slow cell division, fix DNA errors,
or undergo programmed cell death (apoptosis) are tumor suppressor genes. Tumor
suppressor genes that don't function properly can cause cells to develop out of control,
leading to cancer. Cancer expresses itself differently in each individual, making it
challenging to identify and treat. Studying the types of genetic mutations, as well as the
genes, proteins, and signaling pathways involved in cancer formation will help better
understand the underlying cause of cancer. Identifying which genes are expressed in
various cancer types will enable scientists to develop novel techniques for curing the
disease. This chapter will explain how different cancer types are linked to specific
genes and their locations on chromosome 17.
Chromosome 18
Page: 202-226 (25)
Author: Sivasankari Ramadurai, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020008
PDF Price: $30
Abstract
Cancer is an abnormal or unusual growth of cells in the body with invasive
and migrating potential. It leads to loss of function, weakens the immune system, and is
the second leading cause of death worldwide. This makes it important to eliminate the
disease. Genetic predisposition imposes a high relative risk for several kinds of cancer.
Inherited genetic mutations are responsible for causing 5 to 10 percent of all cancers.
Scientists have investigated mutations in specific genes with more than 50 hereditary
cancer syndromes. For this, chromosome 18 was explored for its genes associated with
cancer and this study unveiled 30 genes involved in causing cancer. Of these, the genes
DCC, EPB41L3, MBD1 PHLPP1, and RBBP8 were the potential tumor suppressors.
This chromosome consists of the target genes of the transforming growth factor-beta
(TGF-β) signaling pathway. The SMAD family genes (SMAD4, SMAD7, and SMAD2)
are encoded by this chromosome, of which SMAD4 acts as a tumor suppressor.
SERPINB5 and TCF-4 were the potential oncogenes. The enzyme coded by TYMS was
a potential therapeutic target for chemotherapy. Several fusion genes of this
chromosome (SS18-SSX2B, SS18-SSX2, and SS18-SSX4) have been identified to cause
cancer. Therefore, this chapter provides a summary of the genes in chromosome 18 that
are involved in the initiation and proliferation of cancer and provides an insight into the
potential biomarkers and therapeutic targets for clinical application to develop a
cancer-free world.
Chromosome 19
Page: 227-250 (24)
Author: Chandrakumar Subramanian, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020009
PDF Price: $30
Abstract
Gene is considered discrete coding units that contain the information for
individual proteins. These lot of genes were combined and named DNA which is
tightly coiled many times over the histone protein to form Chromosomes. Humans have
got 23pairs of chromosomes, including the sex chromosome. The current study is about
the major genes and their functions that are present in chromosome 19. There are
approximately 1500 genes present in this chromosome, and changes in chromosome 19
are identified in many cancers. Dislocation of the chromosome, a mutation in genes
that are present in a chromosome (rearrangements, deletions, or duplications) of DNA
in the chromosome, epigenetic modification, and lifestyle changes are some of the
chromosomal abnormalities that are responsible for cancer-causing. These changes will
trigger the growth of normal cells and induce cancer cell proliferation, migration,
invasion, angiogenesis, and metastasis. The signaling pathways like PI3K/AKT,
JAK/STAT, NF-κB, and TGF-β are responsible for the various cellular functions with
the result of autocrine, juxtacrine, intracrine, paracrine, or endocrine. When the
dysregulation of these signaling pathways leads to cancer progression and metastasis.
Prostate cancer, breast cancer, gastric cancer, pancreatic cancer, colon cancer, gastric
cancer, lung cancer, leukemia, and cervical cancer are the major cancers that are caused
because of mutation that occurs in chromosome 19.
Chromosome 20
Page: 251-273 (23)
Author: Harini Hariharan, Abhishek Mitra, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020010
PDF Price: $30
Abstract
Over the years, many scientists and doctors have been treating the deadly
disease of cancer but are not able to find a permanent treatment for this disease. Also,
sometimes it becomes very difficult to understand the mechanisms and causes of
cancer as it is a very complex disease that involves many biological processes. Due to
the redundancy in our biological system, cancer progression becomes very easy, thus
making it difficult to cure. To find the root cause of this disease, we should know what
genetic alterations are undergoing, which is causing cancer to progress, and know who
is participating in these alterations, like proteins, signaling pathways, or genes. Cancer
is caused due to various reasons; it can be due to genetics but mostly due to
carcinogens, causing mutations in the genes, thereby making them an oncogene. The
Proto-oncogenes are those genes that usually assist the growth of tumor cells. The
alteration, mutation, or increased copy number of a particular gene may turn into a
proto-oncogene which could end up completely activated or turned on. Many Tumor-causing alterations or mutations related to oncogenes are usually acquired and not
inherited. These tumor-causing mutations often actuate oncogenes via chromosomal
rearrangement, or alterations in the chromosome, which sequestrates one gene after
another, thereby permitting the first gene to prompt the alternative. Search which genes
are involved in different cancer types would help scientists proceed with new methods
for finding a cure for this disease. This article will depict which genes and their
location on which chromosomes, specifically on chromosome 20, are related to
different types of cancer.
Chromosome 21
Page: 274-312 (39)
Author: Thilaga Thirugnanam, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020011
PDF Price: $30
Abstract
The significance of human chromosome 21 is that the trisomy of human
chromosome 21 causes Down syndrome in children. There are about 235 protein-coding genes on chromosome 21. Mutations like translocation in human chromosome
21 cause different conditions such as partial monosomy 21, core binding factor acute
myeloid leukemia, ring chromosome 21, and other types of cancers such as acute
lymphoblastic leukemia. Mutation in the DSCAM gene causes mental retardation and
facial deformities in down syndrome. The human chromosome 21 also comprises the
APP gene, where the expression of the gene causes Alzheimer's disease. The genes that
are involved in causing Down syndrome and Alzheimer's diseases are also involved in
cancer. This chapter discusses 63 genes of human chromosome 21 that are involved in
different types of cancer.
Chromosome 22
Page: 313-333 (21)
Author: Sayooj Madhusoodanan, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020012
PDF Price: $30
Abstract
When the collection of human Chromosome 22 was first suggested in 1999,
it became the most extended, non-stop stretch of DNA ever decoded and assembled.
Chromosome 22 became the first of the 23 human chromosomes to decode due to its
minimal length and affiliation with numerous diseases. Chromosome 22 involves
several genes that contribute to cancer genetics in one way or the other. The
contribution of chromosome 22 in abnormalities is evident through somatic
translocations, germline and somatic, and in certain cases, overexpression of genes.
One famous example is the Philadelphia translocation, particularly in chronic myeloid
leukemia cells. Various gene contributions about types of cancer such as Acute
Myeloid Leukemia, colorectal, lung, breast cancer and many more have been reported
in studies related to chromosome 22. This chapter takes a run-through of important
targeted studies of a gene that facilitates itself as a part of cancer genetics.
Chromosome X
Page: 334-365 (32)
Author: Anusha Mandem, Saurav Panicker, Abhishek Mitra and Satish Ramalingam*
DOI: 10.2174/9789815136500123020013
PDF Price: $30
Abstract
X Chromosome is the sex chromosome that is found in many organisms.
Both males and females, including mammalians, have X Chromosomes. Females have
XX sets of chromosomes, and males have XY sets of chromosomes. X Chromosome
aids in identifying the sex of the organism. The Human X chromosome contains
approximately 1500 genes. These genes may undergo some genetic alterations and
eventually lead to complex diseases. Genetic mutations in some of the genes of the X
chromosome are associated with cancer. Some specific mutations are observed in
human cancer cells. This chapter specifically relayed on X chromosomal genes that are
associated with different types of cancer and gave information on the location of the
gene in the X chromosome. Moreover, the function of the specific gene and
information regarding how many types of cancers were associated with a particular
gene, has also been provided.
Chromosome Y
Page: 366-382 (17)
Author: Sowmiya Sattanathan, Saurav Panicker and Satish Ramalingam*
DOI: 10.2174/9789815136500123020014
PDF Price: $30
Abstract
Sex chromosome constitution vary genetically in both genders, such as XY
in male and XX in female. Even though the chromosomes X and Y advanced from the
autosomal pair of the same ancestor, male-specific genes were harbored by the Y
chromosome. This Y chromosome plays a crucial role in germ cell differentiation, sex
determination in males, and numerous tissue masculinization. Translocations or
deletions of SRY, the sex-determining gene of the Y chromosome, enable sex
development disorders with dysgenic gonads. Gonadal improvement failure outturns
not only in infertility but also in the highest possibilities of GCT (Germ Cell Tumour),
like various kinds of testicular GCT and gonad blastoma. Studies have shown that
selected somatic cancers are closely related to both losses of Y chromosome genes,
ectopic expression, or Y chromosome. These observations remark that genes of the Y
chromosome are associated with male diseases and health more than attic turns out not
only in infertility but also in the highest possibilities of GCT (Germ Cell Tumour) like
various kindspated. Even though only a compact amount of protein-coding genes are
seen in Y chromosomes male-specific region, the effects of those Y chromosomal
genes on human disease are still predominantly unknown. In this part, we can find the
participation of selected genes of the Y chromosome in cancer growth in men.
Subject Index
Page: 383-388 (6)
Author: Satish Ramalingam
DOI: 10.2174/9789815136500123020015
PDF Price: $30
Introduction
Cancer Genes is a comprehensive list of the most critical genes known to contribute to cancer imitation and progression. The book delves into their location on each chromosome, providing valuable insights into the mechanisms of cancer gene dysregulation and genetic mutations which provide cancer cells with an advantage during each stage of tumorigenesis. The reference will familiarize readers with the location of cancer genes and equip them with the necessary information to identify relevant gene expression targets for research aimed at preventing the disease. The book is divided into two volumes focusing on cancer-causing genes found in chromosome pairs 1-12 (volume 1), and chromosomes 13-23 (volume 2). A key features of the book is a detailed reference list for advanced readers. The compilation is therefore a quick and handy reference on cancer causing genes for researchers, medical professionals, and anyone interested in understanding the genetic basis of cancer.