Chapter 2 Introduction To The Human Genome PDF

Summary

This document is an introduction to the human genome, covering the organization, variation, and transmission of genetic material. It also explores chromosome and genome analysis in clinical settings, highlighting its diagnostic and therapeutic applications.

Full Transcript

C H A P T E R 2
Introduction to the
Human Genome

Understanding the organization, variation, and trans-
CHROMOSOME AND GENOME ANALYSIS IN
mission o the human genome is central to appreciating CLINICAL MEDICINE
the role o genetics in medicine, as well as the emerging
principles o genomic and personalized medicine. With Chromosome and genome analysis has become an impor-
the availability o the sequence o the human genome tant diagnostic procedure in clinical medicine. As described
more ully in subsequent chapters, these applications
and a growing awareness o the role o genome varia- include the ollowing:
tion in disease, it is now possible to begin to exploit the Clinical diagnosis. Numerous medical conditions,
impact o that variation on human health on a broad including some that are common, are associated with
scale. The comparison o individual genomes under- changes in chromosome number or structure and
scores the frst major take-home lesson o this book— require chromosome or genome analysis or diagnosis
and genetic counseling (see Chapters 5 and 6).
every individual has his or her own unique constitution Gene identifcation. A major goal o medical genetics
of gene products, produced in response to the combined and genomics today is the identifcation o specifc
inputs of the genome sequence and one’s particular set genes and elucidating their roles in health and disease.
of environmental exposures and experiences. As pointed This topic is reerred to repeatedly but is discussed in
out in the previous chapter, this realization reects what detail in Chapter 10.
Cancer genomics. Genomic and chromosomal changes
Garrod termed chemical individuality over a century in somatic cells are involved in the initiation and pro-
ago and provides a conceptual oundation or the prac- gression o many types o cancer (see Chapter 15).
tice o genomic and personalized medicine. Disease treatment. Evaluation o the integrity, compo-
Advances in genome technology and the resulting sition, and dierentiation state o the genome is criti-
explosion in knowledge and inormation stemming cal or the development o patient-specifc pluripotent
stem cells or therapeutic use (see Chapter 13).
rom the Human Genome Project are thus playing an Prenatal diagnosis. Chromosome and genome analy-
increasingly transormational role in integrating and sis is an essential procedure in prenatal diagnosis (see
applying concepts and discoveries in genetics to the Chapter 17).
practice o medicine.

THE HUMAN GENOME AND THE
CHROMOSOMAL BASIS OF HEREDITY which at this point we consider simply and most broadly
Appreciation o the importance o genetics to medicine as unctional units o genetic inormation, are encoded
requires an understanding o the nature o the heredi- in the DNA o the genome, organized into a number o
tary material, how it is packaged into the human rod-shaped organelles called chromosomes in the
genome, and how it is transmitted rom cell to cell nucleus o each cell. The inuence o genes and genetics
during cell division and rom generation to generation on states o health and disease is proound, and its roots
during reproduction. The human genome consists o large are ound in the inormation encoded in the DNA that
amounts o the chemical deoxyribonucleic acid (DNA) makes up the human genome.
that contains within its structure the genetic inorma- Each species has a characteristic chromosome com-
tion needed to speciy all aspects o embryogenesis, plement (karyotype) in terms o the number, morphol-
development, growth, metabolism, and reproduction— ogy, and content o the chromosomes that make up its
essentially all aspects o what makes a human being a genome. The genes are in linear order along the chro-
unctional organism. Every nucleated cell in the body mosomes, each gene having a precise position or locus.
carries its own copy o the human genome, which con- A gene map is the map o the genomic location o the
tains, depending on how one defnes the term, approxi- genes and is characteristic o each species and the indi-
mately 20,000 to 50,000 genes (see Box later). Genes, viduals within a species.
3
4 THOMPSON & THOMPSON GENETICS IN MEDICINE

The study o chromosomes, their structure, and their inormation; that is, they typically have the same genes
inheritance is called cytogenetics. The science o human in the same order. At any specifc locus, however, the
cytogenetics dates rom 1956, when it was frst estab- homologues either may be identical or may vary slightly
lished that the normal human chromosome number is in sequence; these dierent orms o a gene are called
46. Since that time, much has been learned about human alleles. One member o each pair o chromosomes is
chromosomes, their normal structure and composition, inherited rom the ather, the other rom the mother.
and the identity o the genes that they contain, as well Normally, the members o a pair o autosomes are
as their numerous and varied abnormalities. microscopically indistinguishable rom each other. In
With the exception o cells that develop into gametes emales, the sex chromosomes, the two X chromosomes,
(the germline), all cells that contribute to one’s body are are likewise largely indistinguishable. In males, however,
called somatic cells (soma, body). The genome con- the sex chromosomes dier. One is an X, identical to the
tained in the nucleus o human somatic cells consists o Xs o the emale, inherited by a male rom his mother
46 chromosomes, made up o 24 dierent types and and transmitted to his daughters; the other, the Y chro-
arranged in 23 pairs (Fig. 2-1). O those 23 pairs, 22 are mosome, is inherited rom his ather and transmitted to
alike in males and emales and are called autosomes, his sons. In Chapter 6, as we explore the chromosomal
originally numbered in order o their apparent size rom and genomic basis o disease, we will look at some
the largest to the smallest. The remaining pair comprises exceptions to the simple and almost universal rule that
the two dierent types o sex chromosomes: an X and human emales are XX and human males are XY.
a Y chromosome in males and two X chromosomes in In addition to the nuclear genome, a small but impor-
emales. Central to the concept o the human genome, tant part o the human genome resides in mitochondria
each chromosome carries a dierent subset o genes in the cytoplasm (see Fig. 2-1). The mitochondrial chro-
that are arranged linearly along its DNA. Members mosome, to be described later in this chapter, has a
o a pair o chromosomes (reerred to as homologous number o unusual eatures that distinguish it rom the
chromosomes or homologues) carry matching genetic rest o the human genome.

Somatic cell

Mitochondrial Nuclear chromosomes
chromosomes

CAGGTCTTAGCCATTCGAATCGTACGCTAGCA CAGGTCTTAGCCATTCGAATCGTACGCTAGCA CAGGTCTTAGCCATTCGAATCGTACGCTAGCA CAGGTCTTAGCCATTCGAATCGTACGCTAGCA
ATTCTTATAATCGTACGCTAGCAATTCTTATGGA ATTCTTATAATCGTACGCTAGCAATTCTTATGGA ATTCTTATAATCGTACGCTAGCAATTCTTATGGA ATTCTTATAATCGTACGCTAGCAATTCTTATGGA
AACTGTGAATAGGCTTATAACAGGTCAGGTCT AACTGTGAATAGGCTTATAACAGGTCAGGTCT AACTGTGAATAGGCTTATAACAGGTCAGGTCT AACTGTGAATAGGCTTATAACAGGTCAGGTCT
TAGCCATTCGAATCGTACGCTAGCAATTCTTAT TAGCCATTCGAATCGTACGCTAGCAATTCTTAT TAGCCATTCGAATCGTACGCTAGCAATTCTTAT TAGCCATTCGAATCGTACGCTAGCAATTCTTAT
AATCGTACGCTAGCAATTCTTATGGAAACTGTG AATCGTACGCTAGCAATTCTTATGGAAACTGTG AATCGTACGCTAGCAATTCTTATGGAAACTGTG AATCGTACGCTAGCAATTCTTATGGAAACTGTG
AATAGGCTTATAACAGGTCAGGTCTTAGCCATT AATAGGCTTATAACAGGTCAGGTCTTAGCCATT AATAGGCTTATAACAGGTCAGGTCTTAGCCATT AATAGGCTTATAACAGGTCAGGTCTTAGCCATT
CGAATCGTACGCTAGCAATTCTTATAATCGTAC CGAATCGTACGCTAGCAATTCTTATAATCGTAC CGAATCGTACGCTAGCAATTCTTATAATCGTAC CGAATCGTACGCTAGCAATTCTTATAATCGTAC
GCTAGCAATTCTTATGGAAACTGTGAATAGGCT GCTAGCAATTCTTATGGAAACTGTGAATAGGCT GCTAGCAATTCTTATGGAAACTGTGAATAGGCT GCTAGCAATTCTTATGGAAACTGTGAATAGGCT
TATAACAGGTCAGGTCTTAGCCATTCGAATCGT TATAACAGGTCAGGTCTTAGCCATTCGAATCGT TATAACAGGTCAGGTCTTAGCCATTCGAATCGT TATAACAGGTCAGGTCTTAGCCATTCGAATCGT
ACGCTAGCAATTCTTATAATCGTACGCTAGCAA ACGCTAGCAATTCTTATAATCGTACGCTAGCAA ACGCTAGCAATTCTTATAATCGTACGCTAGCAA ACGCTAGCAATTCTTATAATCGTACGCTAGCAA
TTCTTATGGAAACTGTGAATAGGCTTATAACAG TTCTTATGGAAACTGTGAATAGGCTTATAACAG TTCTTATGGAAACTGTGAATAGGCTTATAACAG TTCTTATGGAAACTGTGAATAGGCTTATAACAG
GTCAGGTCTTAGCCATTCGAATCGTACGCTAGC GTCAGGTCTTAGCCATTCGAATCGTACGCTAGC GTCAGGTCTTAGCCATTCGAATCGTACGCTAGC GTCAGGTCTTAGCCATTCGAATCGTACGCTAGC
AATTCTTATAATCGTACGCTAGCAATTCTTATGG AATTCTTATAATCGTACGCTAGCAATTCTTATGG AATTCTTATAATCGTACGCTAGCAATTCTTATGG AATTCTTATAATCGTACGCTAGCAATTCTTATGG
AAACTGTGAATAGGCTTATAACAGGTCAGGTCT AAACTGTGAATAGGCTTATAACAGGTCAGGTCT AAACTGTGAATAGGCTTATAACAGGTCAGGTCT AAACTGTGAATAGGCTTATAACAGGTCAGGTCT
TAGCCATTCGAATCGTACGCTAGCAATTCTTATA TAGCCATTCGAATCGTACGCTAGCAATTCTTATA TAGCCATTCGAATCGTACGCTAGCAATTCTTATA TAGCCATTCGAATCGTACGCTAGCAATTCTTATA
ATCGTACGCTAGCAATTCTTATGGAAACTGTAA ATCGTACGCTAGCAATTCTTATGGAAACTGTAA ATCGTACGCTAGCAATTCTTATGGAAACTGTAA ATCGTACGCTAGCAATTCTTATGGAAACTGTAA
TAGGCTTATAACAGGTCAGGTCTTAGCCATTCG TAGGCTTATAACAGGTCAGGTCTTAGCCATTCG TAGGCTTATAACAGGTCAGGTCTTAGCCATTCG TAGGCTTATAACAGGTCAGGTCTTAGCCATTCG
AATCGTACGCTAGCAATTCTTATAATCGTACGCT AATCGTACGCTAGCAATTCTTATAATCGTACGCT AATCGTACGCTAGCAATTCTTATAATCGTACGCT AATCGTACGCTAGCAATTCTTATAATCGTACGCT
AGCAATTCTTATGGAAACTGTGAATAGGCTTATA AGCAATTCTTATGGAAACTGTGAATAGGCTTATA AGCAATTCTTATGGAAACTGTGAATAGGCTTATA AGCAATTCTTATGGAAACTGTGAATAGGCTTATA
ACAGGTCAGGTCTTAGCCATTCGAATCGTACG ACAGGTCAGGTCTTAGCCATTCGAATCGTACG ACAGGTCAGGTCTTAGCCATTCGAATCGTACG ACAGGTCAGGTCTTAGCCATTCGAATCGTACG
CTAGCAATTCTTATAATCGTACGCTAGCAATTCT CTAGCAATTCTTATAATCGTACGCTAGCAATTCT CTAGCAATTCTTATAATCGTACGCTAGCAATTCT CTAGCAATTCTTATAATCGTACGCTAGCAATTCT
TATGGAAACTGTGAATAGGCTTATAACAGGTCA TATGGAAACTGTGAATAGGCTTATAACAGGTCA TATGGAAACTGTGAATAGGCTTATAACAGGTCA TATGGAAACTGTGAATAGGCTTATAACAGGTCA
GGTCTTAGCCATTCGAATCGTACGCTAGCAATT GGTCTTAGCCATTCGAATCGTACGCTAGCAATT GGTCTTAGCCATTCGAATCGTACGCTAGCAATT GGTCTTAGCCATTCGAATCGTACGCTAGCAATT
CTTATAATCGTACGCTAGCAATTCTTATGGAAAC CTTATAATCGTACGCTAGCAATTCTTATGGAAAC CTTATAATCGTACGCTAGCAATTCTTATGGAAAC CTTATAATCGTACGCTAGCAATTCTTATGGAAAC
TGTGAATAGGCTTATAACAGGTCAGGTCTTAGC TGTGAATAGGCTTATAACAGGTCAGGTCTTAGC TGTGAATAGGCTTATAACAGGTCAGGTCTTAGC TGTGAATAGGCTTATAACAGGTCAGGTCTTAGC
CATTCGAATCGTACGCTAGCAATTCTTATAATCG CATTCGAATCGTACGCTAGCAATTCTTATAATCG CATTCGAATCGTACGCTAGCAATTCTTATAATCG CATTCGAATCGTACGCTAGCAATTCTTATAATCG...CTAGCAATTCTTATAATCGTACGCTAG
TCTTATGGAAACTGTGAATAGGCTTATAACAGGAG
GTCTTAGCCATTCGAATCGTACGCTAGC...
Human Genome Sequence
Figure 2-1 The human genome, encoded on both nuclear and mitochondrial chromosomes.
See Sources & Acknowledgments.
 CHAPTER 2 — INTRODUCTION TO THE HUMAN GENOME 5

Purines Pyrimidines

NH2 O

C C
N CH3
N C HN C
CH
HC C C CH
N O N
N
H H O
Adenine (A) Thymine (T) _ 5' Base
O P O CH2 O
_
O C C
H H
H H
O NH2 3' C C
OH H
C N C
HN C N CH Phosphate Deoxyribose
CH
C C C CH
H2N N O N
N
H H
Guanine (G) Cytosine (C)

Figure 2-2 The four bases of DNA and the general structure of a nucleotide in DNA. Each o the
our bases bonds with deoxyribose (through the nitrogen shown in magenta) and a phosphate
group to orm the corresponding nucleotides.

GENES IN THE HUMAN GENOME Although the ultimate catalogue o human genes remains
an elusive target, we recognize two general types o gene,
What is a gene? And how many genes do we have? These those whose product is a protein and those whose product
questions are more difcult to answer than it might seem. is a unctional RNA.
The word gene, frst introduced in 1908, has been used The number o protein-coding genes—recognized by
in many dierent contexts since the essential eatures o eatures in the genome that will be discussed in Chapter
heritable “unit characters” were frst outlined by Mendel 3—is estimated to be somewhere between 20,000 and
over 150 years ago. To physicians (and indeed to Mendel 25,000. In this book, we typically use approximately
and other early geneticists), a gene can be defned by its 20,000 as the number, and the reader should rec-
observable impact on an organism and on its statistically ognize that this is both imprecise and perhaps an
determined transmission rom generation to generation. To underestimate.
medical geneticists, a gene is recognized clinically in the In addition, however, it has been clear or several decades
context o an observable variant that leads to a character- that the ultimate product o some genes is not a protein
istic clinical disorder, and today we recognize approximately at all but rather an RNA transcribed rom the DNA
5000 such conditions (see Chapter 7). sequence. There are many dierent types o such RNA
The Human Genome Project provided a more systematic genes (typically called noncoding genes to distinguish
basis or delineating human genes, relying on DNA sequence them rom protein-coding genes), and it is currently esti-
analysis rather than clinical acumen and amily studies mated that there are at least another 20,000 to 25,000
alone; indeed, this was one o the most compelling ratio- noncoding RNA genes around the human genome.
nales or initiating the project in the late 1980s. However, Thus overall—and depending on what one means by the
even with the fnished sequence product in 2003, it was term—the total number o genes in the human genome is o
apparent that our ability to recognize eatures o the the order o approximately 20,000 to 50,000. However, the
sequence that point to the existence or identity o a gene reader will appreciate that this remains a moving target,
was sorely lacking. Interpreting the human genome sequence subject to evolving defnitions, increases in technological
and relating its variation to human biology in both health capabilities and analytical precision, advances in inormat-
and disease is thus an ongoing challenge or biomedical ics and digital medicine, and more complete genome
research. annotation.

DNA Structure: A Brief Review composed o three types o units: a fve-carbon sugar,
Beore the organization o the human genome and its deoxyribose; a nitrogen-containing base; and a phos-
chromosomes is considered in detail, it is necessary to phate group (Fig. 2-2). The bases are o two types,
review the nature o the DNA that makes up the genome. purines and pyrimidines. In DNA, there are two purine
DNA is a polymeric nucleic acid macromolecule bases, adenine (A) and guanine (G), and two pyrimidine
6 THOMPSON & THOMPSON GENETICS IN MEDICINE

A B
_
5' end O Hydrogen 3.4 Å
_ 5' bonds
O P O 3'
O C
Base 1 G
H2C 5'
O
C C
H H
H H
3' C C
C
O H G
34 Å
_
O P O

O
Base 2 T
H2C 5'
O A
C C
H H
H H
3' C C
O H C
_ G
O P O

O 3'
Base 3
H2C 5' 5'
O
C C
H H
H H
3' C C
3' end
OH H 20 Å
Figure 2-3 The structure of DNA. A, A portion o a DNA polynucleotide chain, showing the 3′-5′
phosphodiester bonds that link adjacent nucleotides. B, The double-helix model o DNA, as pro-
posed by Watson and Crick. The horizontal “rungs” represent the paired bases. The helix is said
to be right-handed because the strand going rom lower let to upper right crosses over the opposite
strand. The detailed portion o the fgure illustrates the two complementary strands o DNA,
showing the AT and GC base pairs. Note that the orientation o the two strands is antiparallel.
See Sources & Acknowledgments.

bases, thymine (T) and cytosine (C). Nucleotides, each C. The specifc nature o the genetic inormation encoded
composed o a base, a phosphate, and a sugar moiety, in the human genome lies in the sequence o C’s, A’s,
polymerize into long polynucleotide chains held together G’s, and T’s on the two strands o the double helix along
by 5′-3′ phosphodiester bonds ormed between adjacent each o the chromosomes, both in the nucleus and in
deoxyribose units (Fig. 2-3A). In the human genome, mitochondria (see Fig. 2-1). Because o the complemen-
these polynucleotide chains exist in the orm o a double tary nature o the two strands o DNA, knowledge o
helix (Fig. 2-3B) that can be hundreds o millions o the sequence o nucleotide bases on one strand auto-
nucleotides long in the case o the largest human matically allows one to determine the sequence o bases
chromosomes. on the other strand. The double-stranded structure o
The anatomical structure o DNA carries the chemi- DNA molecules allows them to replicate precisely by
cal inormation that allows the exact transmission o separation o the two strands, ollowed by synthesis o
genetic inormation rom one cell to its daughter cells two new complementary strands, in accordance with
and rom one generation to the next. At the same time, the sequence o the original template strands (Fig. 2-4).
the primary structure o DNA specifes the amino acid Similarly, when necessary, the base complementarity
sequences o the polypeptide chains o proteins, as allows efcient and correct repair o damaged DNA
described in the next chapter. DNA has elegant eatures molecules.
that give it these properties. The native state o DNA,
as elucidated by James Watson and Francis Crick in
1953, is a double helix (see Fig. 2-3B). The helical struc-
Structure of Human Chromosomes
ture resembles a right-handed spiral staircase in which The composition o genes in the human genome, as well
its two polynucleotide chains run in opposite directions, as the determinants o their expression, is specifed in
held together by hydrogen bonds between pairs o bases: the DNA o the 46 human chromosomes in the nucleus
T o one chain paired with A o the other, and G with plus the mitochondrial chromosome. Each human
 CHAPTER 2 — INTRODUCTION TO THE HUMAN GENOME 7

chromosome consists of a single, continuous DNA several classes o specialized proteins. Except during cell
double helix; that is, each chromosome is one long, division, chromatin is distributed throughout the nucleus
double-stranded DNA molecule, and the nuclear genome and is relatively homogeneous in appearance under the
consists, thereore, o 46 linear DNA molecules, totaling microscope. When a cell divides, however, its genome
more than 6 billion nucleotide pairs (see Fig. 2-1). condenses to appear as microscopically visible chromo-
Chromosomes are not naked DNA double helices, somes. Chromosomes are thus visible as discrete struc-
however. Within each cell, the genome is packaged as tures only in dividing cells, although they retain their
chromatin, in which genomic DNA is complexed with integrity between cell divisions.
The DNA molecule o a chromosome exists in chro-
5'
matin as a complex with a amily o basic chromosomal
3'
G C proteins called histones. This undamental unit interacts
G C
C G with a heterogeneous group o nonhistone proteins,
A T which are involved in establishing a proper spatial and
G
A
C
T
unctional environment to ensure normal chromosome
T A
behavior and appropriate gene expression.
G
A
C
T
Five major types o histones play a critical role in the
C
T
G
A
proper packaging o chromatin. Two copies each o the
our core histones H2A, H2B, H3, and H4 constitute an
G
A T
C
octamer, around which a segment o DNA double helix
T A T A
winds, like thread around a spool (Fig. 2-5). Approxi-
C 3' 5' G
G C G C mately 140 base pairs (bp) o DNA are associated with
A A
each histone core, making just under two turns around
T T
T A T A

T A T A the octamer. Ater a short (20- to 60-bp) “spacer”
G C G C
G C G C segment o DNA, the next core DNA complex orms,
and so on, giving chromatin the appearance o beads on
C G C G

A
G
T
C
A
G
T
C
a string. Each complex o DNA with core histones is
A
T
T
A
A
T
T
A
called a nucleosome (see Fig. 2-5), which is the basic
T A T A
structural unit o chromatin, and each o the 46 human
5' 3' 5' 3' chromosomes contains several hundred thousand to
Figure 2-4 Replication o a DNA double helix, resulting in two well over a million nucleosomes. A fth histone, H1,
identical daughter molecules, each composed o one parental appears to bind to DNA at the edge o each nucleosome,
strand and one newly synthesized strand. in the internucleosomal spacer region. The amount o

~30 nm ~10 nm 2 nm

Each loop
Cell in early contains
interphase ~100-200 kb
of DNA

~140 bp
of DNA

Portion of an
interphase Histone
chromosome octamer
Interphase Solenoid Nucleosome fiber Double helix
nucleus ("beads on a string")
Figure 2-5 Hierarchical levels o chromatin packaging in a human chromosome.
8 THOMPSON & THOMPSON GENETICS IN MEDICINE

DNA associated with a core nucleosome, together with mitochondria, although the vast majority o proteins
the spacer region, is approximately 200 bp. within the mitochondria are, in act, the products o
In addition to the major histone types, a number o nuclear genes. Mutations in mitochondrial genes have
specialized histones can substitute or H3 or H2A and been demonstrated in several maternally inherited as
coner specifc characteristics on the genomic DNA at well as sporadic disorders (Case 33) (see Chapters 7
that location. Histones can also be modifed by chemical and 12).
changes, and these modifcations can change the proper-
ties o nucleosomes that contain them. As discussed
urther in Chapter 3, the pattern o major and special-
The Human Genome Sequence
ized histone types and their modifcations can vary rom With a general understanding o the structure and clini-
cell type to cell type and is thought to speciy how DNA cal importance o chromosomes and the genes they
is packaged and how accessible it is to regulatory mol- carry, scientists turned attention to the identifcation o
ecules that determine gene expression or other genome specifc genes and their location in the human genome.
unctions. From this broad eort emerged the Human Genome
During the cell cycle, as we will see later in this Project, an international consortium o hundreds o
chapter, chromosomes pass through orderly stages o laboratories around the world, ormed to determine
condensation and decondensation. However, even when and assemble the sequence o the 3.3 billion base pairs
chromosomes are in their most decondensed state, in a o DNA located among the 24 types o human
stage o the cell cycle called interphase, DNA packaged chromosome.
in chromatin is substantially more condensed than it Over the course o a decade and a hal, powered by
would be as a native, protein-ree, double helix. Further, major developments in DNA-sequencing technology,
the long strings o nucleosomes are themselves com- large sequencing centers collaborated to assemble
pacted into a secondary helical structure, a cylindrical sequences o each chromosome. The genomes actually
“solenoid” fber (rom the Greek solenoeides, pipe- being sequenced came rom several dierent individu-
shaped) that appears to be the undamental unit o als, and the consensus sequence that resulted at the
chromatin organization (see Fig. 2-5). The solenoids are conclusion o the Human Genome Project was reported
themselves packed into loops or domains attached at in 2003 as a “reerence” sequence assembly, to be used
intervals o approximately 100,000 bp (equivalent to as a basis or later comparison with sequences o indi-
100 kilobase pairs [kb], because 1 kb = 1000 bp) to a vidual genomes. This reerence sequence is maintained
protein scaffold within the nucleus. It has been specu- in publicly accessible databases to acilitate scientifc
lated that these loops are the unctional units o the discovery and its translation into useul advances or
genome and that the attachment points o each loop are medicine. Genome sequences are typically presented in
specifed along the chromosomal DNA. As we shall see, a 5′ to 3′ direction on just one o the two strands o the
one level o control o gene expression depends on how double helix, because—owing to the complementary
DNA and genes are packaged into chromosomes and nature o DNA structure described earlier—i one
on their association with chromatin proteins in the knows the sequence o one strand, one can iner the
packaging process. sequence o the other strand (Fig. 2-6).
The enormous amount o genomic DNA packaged
into a chromosome can be appreciated when chromo-
somes are treated to release the DNA rom the underly-
Organization of the Human Genome
ing protein scaold (see Fig. 2-1). When DNA is released Chromosomes are not just a random collection o di-
in this manner, long loops o DNA can be visualized, erent types o genes and other DNA sequences. Regions
and the residual scaolding can be seen to reproduce o the genome with similar characteristics tend to be
the outline o a typical chromosome. clustered together, and the unctional organization o
the genome reects its structural organization and
The Mitochondrial Chromosome sequence. Some chromosome regions, or even whole
As mentioned earlier, a small but important subset o chromosomes, are high in gene content (“gene rich”),
genes encoded in the human genome resides in the cyto- whereas others are low (“gene poor”) (Fig. 2-7). The
plasm in the mitochondria (see Fig. 2-1). Mitochondrial clinical consequences o abnormalities o genome struc-
genes exhibit exclusively maternal inheritance (see ture reect the specifc nature o the genes and sequences
Chapter 7). Human cells can have hundreds to thou- involved. Thus abnormalities o gene-rich chromosomes
sands o mitochondria, each containing a number o or chromosomal regions tend to be much more severe
copies o a small circular molecule, the mitochondrial clinically than similar-sized deects involving gene-poor
chromosome. The mitochondrial DNA molecule is only parts o the genome.
16 kb in length (just a tiny raction o the length o As a result o knowledge gained rom the Human
even the smallest nuclear chromosome) and encodes Genome Project, it is apparent that the organization o
only 37 genes. The products o these genes unction in DNA in the human genome is both more varied and
 CHAPTER 2 — INTRODUCTION TO THE HUMAN GENOME 9

5´... G G A T T T C T A G G T A A C T C A G T C G A... 3´
Double Helix
3´... C C T A A A G A T C C A T T G A G T C A G C T... 5´

Reference... G G AT T T C T A G G T A A C T C A G T C G A...
Sequence

Individual 1... G G A T T T C T A G G T A A C T C A G T C G A...
Individual 2... G G A T T T C C A G G T A A C T C A G T C G A...
Individual 3... G G A T T T C C A G G T A A C T C A G T C G A...
Individual 4... G G A T T T C T A G G T A A C T C A G T A G A...
Individual 5... G G A T - - C T A G G T A A C T C A G T C G A...
Figure 2-6 A portion of the reference human genome sequence. By convention, sequences are
presented rom one strand o DNA only, because the sequence o the complementary strand can
be inerred rom the double-stranded nature o DNA (shown above the reerence sequence). The
sequence o DNA rom a group o individuals is similar but not identical to the reerence, with
single nucleotide changes in some individuals and a small deletion o two bases in another.

1
2000 Gene-rich
chromosomes

Genome Average:
19 ~6.7 genes/Mb
1500
11 2
Number of Genes

17
12 6 3
1000
16 14 7 5
9
X 4
10
20 8
15
500
22
13
21 18
Gene-poor
chromosomes
Y
0
0 50 100 150 200 250
Chromosome Size (Mb)

Figure 2-7 Size and gene content of the 24 human chromosomes. Dotted diagonal line corre-
sponds to the average density o genes in the genome, approximately 6.7 protein-coding genes per
megabase (Mb). Chromosomes that are relatively gene rich are above the diagonal and trend to
the upper let. Chromosomes that are relatively gene poor are below the diagonal and trend to the
lower right. See Sources & Acknowledgments.
10 THOMPSON & THOMPSON GENETICS IN MEDICINE

more complex than was once appreciated. O the bil- The dierent types o such tandem repeats are collec-
lions o base pairs o DNA in any genome, less than tively called satellite DNAs, so named because many o
1.5% actually encodes proteins. Regulatory elements the original tandem repeat amilies could be separated
that inuence or determine patterns o gene expression by biochemical methods rom the bulk o the genome
during development or in tissues were believed to as distinct (“satellite”) ractions o DNA.
account or only approximately 5% o additional Tandem repeat amilies vary with regard to their
sequence, although more recent analyses o chromatin location in the genome and the nature o sequences that
characteristics suggest that a much higher proportion o make up the array. In general, such arrays can stretch
the genome may provide signals that are relevant to several million base pairs or more in length and consti-
genome unctions. Only approximately hal o the total tute up to several percent o the DNA content o an
linear length o the genome consists o so-called single- individual human chromosome. Some tandem repeat
copy or unique DNA, that is, DNA whose linear order sequences are important as tools that are useul in clini-
o specifc nucleotides is represented only once (or at cal cytogenetic analysis (see Chapter 5). Long arrays o
most a ew times) around the entire genome. This repeats based on repetitions (with some variation) o a
concept may appear surprising to some, given that there short sequence such as a pentanucleotide are ound in
are only our dierent nucleotides in DNA. But, con- large genetically inert regions on chromosomes 1, 9, and
sider even a tiny stretch o the genome that is only 10 16 and make up more than hal o the Y chromosome
bases long; with our types o bases, there are over a (see Chapter 6). Other tandem repeat amilies are based
million possible sequences. And, although the order o on somewhat longer basic repeats. For example, the
bases in the genome is not entirely random, any particu- α-satellite amily o DNA is composed o tandem arrays
lar 16-base sequence would be predicted by chance o an approximately 171-bp unit, ound at the centro-
alone to appear only once in any given genome. mere o each human chromosome, which is critical or
The rest o the genome consists o several classes o attachment o chromosomes to microtubules o the
repetitive DNA and includes DNA whose nucleotide spindle apparatus during cell division.
sequence is repeated, either perectly or with some varia- In addition to tandem repeat DNAs, another major
tion, hundreds to millions o times in the genome. class o repetitive DNA in the genome consists o related
Whereas most (but not all) o the estimated 20,000 sequences that are dispersed throughout the genome
protein-coding genes in the genome (see Box earlier in rather than clustered in one or a ew locations. Although
this chapter) are represented in single-copy DNA, many DNA amilies meet this general description, two
sequences in the repetitive DNA raction contribute to in particular warrant discussion because together they
maintaining chromosome structure and are an impor- make up a signifcant proportion o the genome and
tant source o variation between dierent individuals; because they have been implicated in genetic diseases.
some o this variation can predispose to pathological Among the best-studied dispersed repetitive elements
events in the genome, as we will see in Chapters 5 are those belonging to the so-called Alu family. The
and 6. members o this amily are approximately 300 bp in
length and are related to each other although not identi-
Single-Copy DNA Sequences cal in DNA sequence. In total, there are more than a
Although single-copy DNA makes up at least hal o the million Alu amily members in the genome, making up
DNA in the genome, much o its unction remains a at least 10% o human DNA. A second major dispersed
mystery because, as mentioned, sequences actually repetitive DNA amily is called the long interspersed
encoding proteins (i.e., the coding portion o genes) nuclear element (LINE, sometimes called L1) amily.
constitute only a small proportion o all the single-copy LINEs are up to 6 kb in length and are ound in approx-
DNA. Most single-copy DNA is ound in short stretches imately 850,000 copies per genome, accounting or
(several kilobase pairs or less), interspersed with nearly 20% o the genome. Both o these amilies are
members o various repetitive DNA amilies. The orga- plentiul in some regions o the genome but relatively
nization o genes in single-copy DNA is addressed in sparse in others—regions rich in GC content tend to be
depth in Chapter 3. enriched in Alu elements but depleted o LINE sequences,
whereas the opposite is true o more AT-rich regions o
Repetitive DNA Sequences the genome.
Several dierent categories o repetitive DNA are rec-
ognized. A useul distinguishing eature is whether the Repetitive DNA and Disease. Both Alu and LINE
repeated sequences (“repeats”) are clustered in one or a sequences have been implicated as the cause o muta-
ew locations or whether they are interspersed with tions in hereditary disease. At least a ew copies o the
single-copy sequences along the chromosome. Clustered LINE and Alu amilies generate copies o themselves
repeated sequences constitute an estimated 10% to 15% that can integrate elsewhere in the genome, occasionally
o the genome and consist o arrays o various short causing insertional inactivation o a medically impor-
repeats organized in tandem in a head-to-tail ashion. tant gene. The requency o such events causing genetic
 CHAPTER 2 — INTRODUCTION TO THE HUMAN GENOME 11

disease in humans is unknown, but they may account in uture chapters, any and all o these types o variation
or as many as 1 in 500 mutations. In addition, aberrant can inuence biological unction and thus must be
recombination events between dierent LINE repeats or accounted or in any attempt to understand the contri-
Alu repeats can also be a cause o mutation in some bution o genetics to human health.
genetic diseases (see Chapter 12).
An important additional type o repetitive DNA
ound in many dierent locations around the genome
TRANSMISSION OF THE GENOME
includes sequences that are duplicated, oten with The chromosomal basis o heredity lies in the copying
extraordinarily high sequence conservation. Duplica- o the genome and its transmission rom a cell to its
tions involving substantial segments o a chromosome, progeny during typical cell division and rom one gen-
called segmental duplications, can span hundreds o eration to the next during reproduction, when single
kilobase pairs and account or at least 5% o the genome. copies o the genome rom each parent come together
When the duplicated regions contain genes, genomic in a new embryo.
rearrangements involving the duplicated sequences can To achieve these related but distinct orms o genome
result in the deletion o the region (and the genes) inheritance, there are two kinds o cell division, mitosis
between the copies and thus give rise to disease (see and meiosis. Mitosis is ordinary somatic cell division
Chapters 5 and 6). by which the body grows, dierentiates, and eects
tissue regeneration. Mitotic division normally results in
two daughter cells, each with chromosomes and genes
VARIATION IN THE HUMAN GENOME identical to those o the parent cell. There may be dozens
With completion o the reerence human genome or even hundreds o successive mitoses in a lineage o
sequence, much attention has turned to the discovery somatic cells. In contrast, meiosis occurs only in cells o
and cataloguing o variation in sequence among dier- the germline. Meiosis results in the ormation o repro-
ent individuals (including both healthy individuals and ductive cells (gametes), each o which has only 23
those with various diseases) and among dierent popu- chromosomes—one o each kind o autosome and either
lations around the globe. As we will explore in much an X or a Y. Thus, whereas somatic cells have the
more detail in Chapter 4, there are many tens o millions diploid (diploos, double) or the 2n chromosome com-
o common sequence variants that are seen at signifcant plement (i.e., 46 chromosomes), gametes have the
requency in one or more populations; any given indi- haploid (haploos, single) or the n complement (i.e., 23
vidual carries at least 5 million o these sequence vari- chromosomes). Abnormalities o chromosome number
ants. In addition, there are countless very rare variants, or structure, which are usually clinically signifcant, can
many o which probably exist in only a single or a ew arise either in somatic cells or in cells o the germline
individuals. In act, given the number o individuals in by errors in cell division.
our species, essentially each and every base pair in the
human genome is expected to vary in someone some-
where around the globe. It is or this reason that the
The Cell Cycle
original human genome sequence is considered a “reer- A human being begins lie as a ertilized ovum (zygote),
ence” sequence or our species, but one that is actually a diploid cell rom which all the cells o the body (esti-
identical to no individual’s genome. mated to be approximately 100 trillion in number) are
Early estimates were that any two randomly selected derived by a series o dozens or even hundreds o
individuals would have sequences that are 99.9% iden- mitoses. Mitosis is obviously crucial or growth and
tical or, put another way, that an individual genome dierentiation, but it takes up only a small part o the
would carry two different versions (alleles) o the human lie cycle o a cell. The period between two successive
genome sequence at some 3 to 5 million positions, with mitoses is called interphase, the state in which most o
dierent bases (e.g., a T or a G) at the maternally and the lie o a cell is spent.
paternally inherited copies o that particular sequence Immediately ater mitosis, the cell enters a phase,
position (see Fig. 2-6). Although many o these allelic called G1, in which there is no DNA synthesis (Fig. 2-8).
dierences involve simply one nucleotide, much o the Some cells pass through this stage in hours; others spend
variation consists o insertions or deletions o (usually) a long time, days or years, in G1. In act, some cell types,
short sequence stretches, variation in the number o such as neurons and red blood cells, do not divide at all
copies o repeated elements (including genes), or inver- once they are ully dierentiated; rather, they are per-
sions in the order o sequences at a particular position manently arrested in a distinct phase known as G0 (“G
(locus) in the genome (see Chapter 4). zero”). Other cells, such as liver cells, may enter G0 but,
The total amount o the genome involved in such ater organ damage, return to G1 and continue through
variation is now known to be substantially more than the cell cycle.
originally estimated and approaches 0.5% between any The cell cycle is governed by a series o checkpoints
two randomly selected individuals. As will be addressed that determine the timing o each step in mitosis. In
12 THOMPSON & THOMPSON GENETICS IN MEDICINE

integrity is illustrated by a range o clinical conditions
that result rom deects in elements o the telomere or
kinetochore or cell cycle machinery or rom inaccurate
replication o even small portions o the genome (see
Box). Some o these conditions will be presented in
G1 Telomere greater detail in subsequent chapters.
(10-12 hr)
Centromere
M
G2 S
CLINICAL CONSEQUENCES OF ABNORMALITIES
(2-4 hr) (6-8 hr) Telomere AND VARIATION IN CHROMOSOME STRUCTURE
AND MECHANICS

Medically relevant conditions arising rom abnormal
structure or unction o chromosomal elements during
cell division include the ollowing:
Sister chromatids A broad spectrum o congenital abnormalities in chil-
dren with inherited deects in genes encoding key
Figure 2-8 A typical mitotic cell cycle, described in the text. The components o the mitotic spindle checkpoint at the
telomeres, the centromere, and sister chromatids are indicated.
kinetochore
A range o birth defects and developmental disorders
addition, checkpoints monitor and control the accuracy due to anomalous segregation o chromosomes with
o DNA synthesis as well as the assembly and attach- multiple or missing centromeres (see Chapter 6)
A variety o cancers associated with overreplication
ment o an elaborate network o microtubules that (amplifcation) or altered timing o replication o spe-
acilitate chromosome movement. I damage to the cifc regions o the genome in S phase (see Chapter 15)
genome is detected, these mitotic checkpoints halt cell Roberts syndrome o growth retardation, limb short-
cycle progression until repairs are made or, i the damage ening, and microcephaly in children with abnormali-
is excessive, until the cell is instructed to die by pro- ties o a gene required or proper sister chromatid
alignment and cohesion in S phase
grammed cell death (a process called apoptosis). Premature ovarian failure as a major cause o emale
During G1, each cell contains one diploid copy o the inertility due to mutation in a meiosis-specifc gene
genome. As the process o cell division begins, the cell required or correct sister chromatid cohesion
enters S phase, the stage o programmed DNA synthesis, The so-called telomere syndromes, a number o degen-
ultimately leading to the precise replication o each erative disorders presenting rom childhood to adult-
hood in patients with abnormal telomere shortening
chromosome’s DNA. During this stage, each chromo- due to deects in components o telomerase
some, which in G1 has been a single DNA molecule, is And, at the other end o the spectrum, common gene
duplicated and consists o two sister chromatids (see variants that correlate with the number o copies o
Fig. 2-8), each o which contains an identical copy o the repeats at telomeres and with lie expectancy and
the original linear DNA double helix. The two sister longevity
chromatids are held together physically at the centro-
mere, a region o DNA that associates with a number
o specifc proteins to orm the kinetochore. This com-
plex structure serves to attach each chromosome to By the end o S phase, the DNA content o the cell
the microtubules o the mitotic spindle and to govern has doubled, and each cell now contains two copies o
chromosome movement during mitosis. DNA synthesis the diploid genome. Ater S phase, the cell enters a brie
during S phase is not synchronous throughout all chro- stage called G2. Throughout the whole cell cycle, the cell
mosomes or even within a single chromosome; rather, gradually enlarges, eventually doubling its total mass
along each chromosome, it begins at hundreds to beore the next mitosis. G2 is ended by mitosis, which
thousands o sites, called origins of DNA replication. begins when individual chromosomes begin to condense
Individual chromosome segments have their own char- and become visible under the microscope as thin,
acteristic time o replication during the 6- to 8-hour S extended threads, a process that is considered in greater
phase. The ends o each chromosome (or chromatid) are detail in the ollowing section.
marked by telomeres, which consist o specialized repet- The G1, S, and G2 phases together constitute inter-
itive DNA sequences that ensure the integrity o the phase. In typical dividing human cells, the three phases
chromosome during cell division. Correct maintenance take a total o 16 to 24 hours, whereas mitosis lasts only
o the ends o chromosomes requires a special enzyme 1 to 2 hours (see Fig. 2-8). There is great variation,
called telomerase, which ensures that the very ends o however, in the length o the cell cycle, which ranges
each chromosome are replicated. rom a ew hours in rapidly dividing cells, such as those
The essential nature o these structural elements o o the dermis o the skin or the intestinal mucosa, to
chromosomes and their role in ensuring genome months in other cell types.
 CHAPTER 2 — INTRODUCTION TO THE HUMAN GENOME 13

now become independent daughter chromosomes,
Mitosis which move to opposite poles o the cell.
During the mitotic phase o the cell cycle, an elaborate Telophase. Now, the chromosomes begin to decon-
apparatus ensures that each o the two daughter cells dense rom their highly contracted state, and a
receives a complete set o genetic inormation. This nuclear membrane begins to re-orm around each o
result is achieved by a mechanism that distributes one the two daughter nuclei, which resume their inter-
chromatid o each chromosome to each daughter cell phase appearance. To complete the process o cell
(Fig. 2-9). The process o distributing a copy o each division, the cytoplasm cleaves by a process known
chromosome to each daughter cell is called chromosome as cytokinesis.
segregation. The importance o this process or normal There is an important dierence between a cell enter-
cell growth is illustrated by the observation that many ing mitosis and one that has just completed the process.
tumors are invariably characterized by a state o genetic A cell in G2 has a ully replicated genome (i.e., a 4n
imbalance resulting rom mitotic errors in the distribu- complement o DNA), and each chromosome consists
tion o chromosomes to daughter cells. o a pair o sister chromatids. In contrast, ater mitosis,
The process o mitosis is continuous, but fve stages, the chromosomes o each daughter cell have only one
illustrated in Figure 2-9, are distinguished: prophase, copy o the genome. This copy will not be duplicated
prometaphase, metaphase, anaphase, and telophase. until a daughter cell in its turn reaches the S phase o
Prophase. This stage is marked by gradual condensa- the next cell cycle (see Fig. 2-8). The entire process o
tion o the chromosomes, ormation o the mitotic mitosis thus ensures the orderly duplication and distri-
spindle, and ormation o a pair o centrosomes, rom bution o the genome through successive cell divisions.
which microtubules radiate and eventually take up
positions at the poles o the cell.
Prometaphase. Here, the nuclear membrane dis-
The Human Karyotype
solves, allowing the chromosomes to disperse within The condensed chromosomes o a dividing human cell
the cell and to attach, by their kinetochores, to micro- are most readily analyzed at metaphase or prometa-
tubules o the mitotic spindle. phase. At these stages, the chromosomes are visible
Metaphase. At this stage, the chromosomes are maxi- under the microscope as a so-called chromosome spread;
mally condensed and line up at the equatorial plane each chromosome consists o its sister chromatids,
o the cell. although in most chromosome preparations, the two
Anaphase. The chromosomes separate at the centro- chromatids are held together so tightly that they are
mere, and the sister chromatids o each chromosome rarely visible as separate entities.

Cell in G2

Onset of mitosis
S phase Centrosomes
Interphase
Cells in G1

Decondensed
chromatin Prophase

Cytokinesis

Telophase Prometaphase

Anaphase Metaphase

Microtubules Figure 2-9 Mitosis. Only two chromosome
pairs are shown. For details, see text.
14 THOMPSON & THOMPSON GENETICS IN MEDICINE

(“the human karyotype”) and, as a verb, to the process
o preparing such a standard fgure (“to karyotype”).
Unlike the chromosomes seen in stained preparations
under the microscope or in photographs, the chromo-
somes o living cells are uid and dynamic structures.
During mitosis, the chromatin o each interphase chro-
mosome condenses substantially (Fig. 2-12). When
maximally condensed at metaphase, DNA in chromo-
somes is approximately 1/10,000 o its ully extended
state. When chromosomes are prepared to reveal bands
(as in Figs. 2-10 and 2-11), as many as 1000 or more
bands can be recognized in stained preparations o all
the chromosomes. Each cytogenetic band thereore con-
tains as many as 50 or more genes, although the density
o genes in the genome, as mentioned previously, is
variable.

Meiosis
Meiosis, the process by which diploid cells give rise to
Figure 2-10 A chromosome spread prepared from a lymphocyte haploid gametes, involves a type o cell division that is
culture that has been stained by the Giemsa-banding (G-banding) unique to germ cells. In contrast to mitosis, meiosis
technique. The darkly stained nucleus adjacent to the chromo- consists o one round o DNA replication ollowed by
somes is rom a dierent cell in interphase, when chromosomal
material is diuse throughout the nucleus. See Sources & two rounds o chromosome segregation and cell divi-
Acknowledgments. sion (see meiosis I and meiosis II in Fig. 2-13). As out-
lined here and illustrated in Figure 2-14, the overall
As stated earlier, there are 24 dierent types o human sequence o events in male and emale meiosis is the
chromosome, each o which can be distinguished cyto- same; however, the timing o gametogenesis is very di-
logically by a combination o overall length, location o erent in the two sexes, as we will describe more ully
the centromere, and sequence content, the latter reected later in this chapter.
by various staining methods. The centromere is appar- Meiosis I is also known as the reduction division
ent as a primary constriction, a narrowing or pinching-in because it is the division in which the chromosome
o the sister chromatids due to ormation o the kineto- number is reduced by hal through the pairing o homo-
chore. This is a recognizable cytogenetic landmark, logues in prophase and by their segregation to dierent
dividing the chromosome into two arms, a short arm cells at anaphase o meiosis I. Meiosis I is also notable
designated p (or petit) and a long arm designated q. because it is the stage at which genetic recombination
Figure 2-10 shows a prometaphase cell in which the (also called meiotic crossing over) occurs. In this process,
chromosomes have been stained by the Giemsa-staining as shown or one pair o chromosomes in Figure 2-14,
(G-banding) method (also see Chapter 5). Each chromo- homologous segments o DNA are exchanged between
some pair stains in a characteristic pattern o alternating nonsister chromatids o each pair o homologous chro-
light and dark bands (G bands) that correlates roughly mosomes, thus ensuring that none o the gametes pro-
with eatures o the underlying DNA sequence, such as duced by meiosis will be identical to another. The
base composition (i.e., the percentage o base pairs that conceptual and practical consequences o recombina-
are GC or AT) and the distribution o repetitive DNA tion or many aspects o human genetics and genomics
elements. With such banding techniques, all o the chro- are substantial and are outlined in the Box at the end
mosomes can be individually distinguished, and the o this section.
nature o many structural or numerical abnormalities Prophase o meiosis I diers in a number o ways
can be determined, as we examine in greater detail in rom mitotic prophase, with important genetic conse-
Chapters 5 and 6. quences, because homologous chromosomes need to
Although experts can oten analyze metaphase chro- pair and exchange genetic inormation. The most criti-
mosomes directly under the microscope, a common pro- cal early stage is called zygotene, when homologous
cedure is to cut out the chromosomes rom a digital chromosomes begin to align along their entire length.
image or photomicrograph and arrange them in pairs in The process o meiotic pairing—called synapsis—is nor-
a standard classifcation (Fig. 2-11). The completed mally precise, bringing corresponding DNA sequences
picture is called a karyotype. The word karyotype is also into alignment along the length o the entire chromosome
used to reer to the standard chromosome set o an pair. The paired homologues—now called bivalents—
individual (“a normal male karyotype”) or o a species are held together by a ribbon-like proteinaceous structure
 Figure 2-11 A human male karyotype with Giemsa banding (G banding). The chromosomes are
at the prometaphase stage o mitosis and are arranged in a standard classifcation, numbered 1 to
22 in order o length, with the X and Y chromosomes shown separately. See Sources &
Acknowledgments.

Metaphase
Decondensation
as cell returns to
interphase

Interphase
nucleus Decondensed Prophase
chromatin

Condensation as
mitosis begins

Figure 2-12 Cycle o condensation and
decondensation as a chromosome proceeds
through the cell cycle.
16 THOMPSON & THOMPSON GENETICS IN MEDICINE

Chromosome replication
Interphase
Prophase I

Meiosis I

Meiosis I
Meiosis II

Metaphase I

Four haploid gametes
Figure 2-13 A simplifed representation o the essential steps in Anaphase I
meiosis, consisting o one round o DNA replication ollowed by
two rounds o chromosome segregation, meiosis I and meiosis II.

called the synaptonemal complex, which is essential to
the process o recombination. Ater synapsis is com-
plete, meiotic crossing over takes place during pachy-
tene, ater which the synaptonemal complex breaks
down. Interphase
Metaphase I begins, as in mitosis, when the nuclear
membrane disappears. A spindle orms, and the paired
chromosomes align themselves on the equatorial plane
with their centromeres oriented toward dierent poles
(see Fig. 2-14).
Anaphase o meiosis I again diers substantially rom
the corresponding stage o mitosis. Here, it is the two
members o each bivalent that move apart, not the sister
Meiosis II

chromatids (contrast Fig. 2-14 with Fig. 2-9). The
homologous centromeres (with their attached sister

Metaphase II

Figure 2-14 Meiosis and its consequences. A single chromosome
pair and a single crossover are shown, leading to ormation o
our distinct gametes. The chromosomes replicate during inter-
phase and begin to condense as the cell enters prophase o meiosis
I. In meiosis I, the chromosomes synapse and recombine. A cross- Anaphase II
over is visible as the homologues align at metaphase I, with
the centromeres oriented toward opposite poles. In anaphase I,
the exchange o DNA between the homologues is apparent as the
chromosomes are pulled to opposite poles. Ater completion o
meiosis I and cytokinesis, meiosis II proceeds with a mitosis-like
division. The sister kinetochores separate and move to opposite Gametes
poles in anaphase II, yielding our haploid products.
 CHAPTER 2 — INTRODUCTION TO THE HUMAN GENOME 17

chromatids) are drawn to opposite poles o the cell, a Grandpaternal Grandmaternal
process termed disjunction. Thus the chromosome DNA sequences DNA sequences
number is halved, and each cellular product o meiosis
I has the haploid chromosome number. The 23 pairs o
homologous chromosomes assort independently o one
another, and as a result, the original paternal and mater-
nal chromosome sets are sorted into random combina- Paternal
tions. The possible number o combinations o the 23 chromosomes
chromosome pairs that can be present in the gametes is
223 (more than 8 million). Owing to the process o cross-
ing over, however, the variation in the genetic material
that is transmitted rom parent to child is actually much

GENETIC CONSEQUENCES AND MEDICAL RELEVANCE OF
HOMOLOGOUS RECOMBINATION

The take-home lesson o this portion o the chapter is a
simple one: the genetic content of each gamete is unique,
because o random assortment o the parental chromo-
somes to shue the combination o sequence variants
between chromosomes and because o homologous
recombination to shue the combination o sequence
variants within each and every chromosome. This has
signifcant consequences or patterns o genomic varia-
tion among and between dierent populations around the
globe and or diagnosis and counseling o many common
conditions with complex patterns o inheritance (see
Chapters 8 and 10).
The amounts and patterns of meiotic recombination
are determined by sequence variants in specifc genes and
Paternal chromosome Paternal chromosome
at specifc “hot spots” and dier between individuals, inherited by Child 1 inherited by Child 2
between the sexes, between amilies, and between popula-
tions (see Chapter 10). Figure 2-15 The effect of homologous recombination in meiosis.
Because recombination involves the physical inter- In this example, representing the inheritance o sequences on a
twining o the two homologues until the appropriate typical large chromosome, an individual has distinctive homo-
point during meiosis I, it is also critical or ensuring logues, one containing sequences inherited rom his ather (blue)
proper chromosome segregation during meiosis. Failure and one containing homologous sequences rom his mother
to recombine properly can lead to chromosome misseg- (purple). Ater meiosis in spermatogenesis, he transmits a single
regation (nondisjunction) in meiosis I and is a requent complete copy o that chromosome to his two ospring. However,
cause o pregnancy loss and o chromosome abnormali- as a result o crossing over (arrows), the copy he transmits to each
ties like Down syndrome (see Chapters 5 and 6). child consists o alternating segments o the two grandparental
Major ongoing eorts to identify genes and their vari- sequences. Child 1 inherits a copy ater two crossovers, whereas
ants responsible for various medical conditions rely on child 2 inherits a copy with three crossovers.
tracking the inheritance o millions o sequence dier-
ences within amilies or the sharing o variants within
groups o even unrelated individuals aected with a par-
ticular condition. The utility o this approach, which has
uncovered thousands o gene-disease associations to date, greater than this. As a result, each chromatid typically
depends on patterns o homologous recombination in contains segments derived rom each member o the
meiosis (see Chapter 10).
Although homologous recombination is normally
original parental chromosome pair, as illustrated sche-
precise, areas o repetitive DNA in the genome and genes matically in Figure 2-14. For example, at this stage, a
o variable copy number in the population are prone to typical large human chromosome would be composed
occasional unequal crossing over during meiosis, leading o three to fve segments, alternately paternal and
to variations in clinically relevant traits such as drug maternal in origin, as inerred rom DNA sequence vari-
response, to common disorders such as the thalassemias
or autism, or to abnormalities o sexual dierentiation
ants that distinguish the respective parental genomes
(see Chapters 6, 8, and 11). (Fig. 2-15).
Although homologous recombination is a normal and Ater telophase o meiosis I, the two haploid daugh-
essential part o meiosis, it also occurs, albeit more rarely, ter cells enter meiotic interphase. In contrast to mitosis,
in somatic cells. Anomalies in somatic recombination are this interphase is brie, and meiosis II begins. The
one o the causes o genome instability in cancer (see
Chapter 15).
notable point that distinguishes meiotic and mitotic
interphase is that there is no S phase (i.e., no DNA
18 THOMPSON & THOMPSON GENETICS IN MEDICINE

synthesis and duplication o the genome) between the
frst and second meiotic divisions.
Meiosis II is similar to an ordinary mitosis, except
that the chromosome number is 23 instead o 46; the
chromatids o each o the 23 chromosomes separate,
and one chromatid o each chromosome passes to each
daughter cell (see Fig. 2-14). However, as mentioned Testis
earlier, because o crossing over in meiosis I, the chro-
mosomes o the resulting gametes are not identical (see
Fig. 2-15).
Spermatogonium
46,XY

HUMAN GAMETOGENESIS
AND FERTILIZATION
The cells in the germline that undergo meiosis, primary
spermatocytes or primary oocytes, are derived rom the Primary
spermatocyte
zygote by a long series o mitoses beore the onset o 46,XY
meiosis. Male and emale gametes have dierent histo-
ries, marked by dierent patterns o gene expression
that reect their developmental origin as an XY or XX
embryo. The human primordial germ cells are recogniz- Meiosis I
able by the ourth week o development outside the
embryo proper, in the endoderm o the yolk sac. From Secondary
spermatocytes
there, they migrate during the sixth week to the genital
ridges and associate with somatic cells to orm the prim- 23,X 23,Y
itive gonads, which soon dierentiate into testes or
ovaries, depending on the cells’ sex chromosome con-
Meiosis II

stitution (XY or XX), as we examine in greater detail
in Chapter 6. Both spermatogenesis and oogenesis
require meiosis but have important dierences in detail
and timing that may have clinical and genetic conse-
quences or the ospring. Female meiosis is initiated
once, early during etal lie, in a limited number o cells. 23,X 23,X 23,Y 23,Y
In contrast, male meiosis is initiated continuously in Spermatids
many cells rom a dividing cell population throughout
the adult lie o a male.
In the emale, successive stages o meiosis take place
over several decades—in the etal ovary beore the
emale in question is even born, in the oocyte near the
time o ovulation in the sexually mature emale, and
ater ertilization o the egg that can become that
emale’s ospring. Although postertilization stages can
be studied in vitro, access to the earlier stages is limited.
Testicular material or the study o male meiosis is less
difcult to obtain, inasmuch as testicular biopsy is
23,X 23,X 23,Y 23,Y
included in the assessment o many men attending iner-
tility clinics. Much remains to be learned about the
cytogenetic, biochemical, and molecular mechanisms
involved in normal meiosis and about the causes and Figure 2-16 Human spermatogenesis in relation to the two
consequences o meiotic irregularities. meiotic divisions. The sequence o events begins at puberty and
takes approximately 64 days to be completed. The chromosome
number (46 or 23) and the sex chromosome constitution (X or
Spermatogenesis Y) o each cell are shown. See Sources & Acknowledgments.
The stages o spermatogenesis are shown in Figure 2-16.
The seminierous tubules o the testes are lined with
spermatogonia, which develop rom the primordial
 CHAPTER 2 — INTRODUCTION TO THE HUMAN GENOME 19

germ cells by a long series o mitoses and which are in
dierent stages o dierentiation. Sperm (spermatozoa)
are ormed only ater sexual maturity is reached. The
last cell type in the developmental sequence is the Ovary
primary spermatocyte, a diploid germ cell that under-
goes meiosis I to orm two haploid secondary spermato-
cytes. Secondary spermatocytes rapidly enter meiosis II,
each orming two spermatids, which dierentiate
without urther division into sperm. In humans, the
entire process takes approximately 64 days. The enor-
mous number o sperm produced, typically approxi- Primary oocyte
mately 200 million per ejaculate and an estimated 1012 in follicle
in a lietime, requires several hundred successive mitoses.

Meiosis I
As discussed earlier, normal meiosis requires pairing
Suspended in
o homologous chromosomes ollowed by recombina- prophase I
tion. The autosomes and the X chromosomes in emales until sexual
present no unusual difculties in this regard; but what maturity
o the X and Y chromosomes during spermatogenesis?
Although the X and Y chromosomes are dierent and
are not homologues in a strict sense, they do have rela- Secondary oocyte
tively short identical segments at the ends o their
Meiotic spindle
respective short arms (Xp and Yp) and long arms (Xq
and Yq) (see Chapter 6). Pairing and crossing over
1st polar body
occurs in both regions during meiosis I. These homolo-
gous segments are called pseudoautosomal to reect
their autosome-like pairing and recombination behav-
ior, despite being on dierent sex chromosomes. Ovulation
Meiosis II

Oogenesis
Whereas spermatogenesis is initiated only at the time o
puberty, oogenesis begins during a emale’s development
as a etus (Fig. 2-17). The ova develop rom oogonia,
cells in the ovarian cortex that have descended rom the
primordial germ cells by a series o approximately 20
mitoses. Each oogonium is the central cell in a develop-
ing ollicle. By approximately the third month o etal Fertilization
development, the oogonia o the embryo have begun to
develop into primary oocytes, most o which have
already entered prophase o meiosis I. The process o 2nd polar body
oogenesis is not synchronized, and both early and late
stages coexist in the etal ovary. Although there are
several million oocytes at the time o birth, most o these Sperm
degenerate; the others remain arrested in prophase I (see
Fig. 2-14) or decades. Only approximately 400 eventu-
ally mature and are ovulated as part o a woman’s
menstrual cycle.
Ater a woman reaches sexual matur