Human Chromosome

• 1.1 Introduction
  •  1.1.1 Definition of Genetics
  • 1.1.2 What are Genes?
• 1.2 What is Cytogenetics?
  •  1.2.1 The Human Genome
  • 1.2.2 Cell Theory
  •  1.2.3 The Cell and its Types
  • 1.2.4 Cell Cycle
  •  1.2.5 Types of Cell Divisions
•  1.3 Human Chromosome Complement
  • 1.3.1 Morphology of Human Chromosome
  • 1.3.2 Classification of Chromosomes
  • 1.3.3 The Groups of Chromosomes
•  1.4 Methods Used in Chromosome Analysis
  • 1.4.1 Chromosome Preparation
  • 1.4.2 Chromosome Banding Techniques
  •  1.4.3 High Resolution Banding
• 1.5 Karyotype Analysis
  • 1.5.1 Counting the Number
  •  1.5.2 Analysis of the Banding Pattern
  •  1.5.3 Idiogram

1.1 INTRODUCTION

In this block you will learn about an important branch of human genetics known as Human cytogenetics. But before that let me begin with the important elements that will enable you to understand this block’s theme.

1.1.1 Definition of Genetics

Essentially, Genetics is the science of heredity and the study of genes. You might be aware from the newspapers and other media about the rapid expansion of the knowledge in the recent past in the field of genetics. You as an Anthropologist need to understand that genetics will play a central role not only in the new model of medical practice; but also in understanding the variations both normal and abnormal among the diverse ethnic populations spread across World.

1.1.2 What are Genes?

While heredity is understood as the biological similarity of offspring and parents, it is the gene that bears this heredity. Gene is the fundamental, physical and functional unit of the heredity, which carries information from one generation to the next.

The next question is, “Where are these genes?” They are in you. Yes! They are in each of your cell trying to maintain you in all ways, be it your growth, development or disease resistance. They reside tightly packed in what is called as chromosome.

So, chromosomes are thread like structures where a linear end to end arrangement of these genes exists.

1.2 WHAT IS CYTOGENETICS?

Now having examined some elementary terms, let us understand what cytogenetics is. This is the branch of genetics concerned principally with the study of chromosomes. It is the cytological approach to genetics, mainly consisting of microscopic studies of chromosomes. To put in another way the study of chromosomes and cell divisions, is also referred to as cytogenetics. Flemming developed a new staining technique in 1879, using synthesized aniline dyes to identify chromosomes, the structures of the cell nucleus. This allowed observation of mitosis, a term first used by Flemming for cell division, in far greater detail than ever before. He also coined the term chromatin, from the Greek word for color, after noting that his red dye was thoroughly absorbed by structures in the nucleus. He is usually credited as the father of cytogenetics (analysis of human chromosomes for the detection of inheritable diseases).

1.2.1 The Human Genome

The entire complement of genetic material in a chromosome set of a species is known as genome. A unifying theory (known as chromosome theory of inheritance) states that inheritance patterns may be generally explained by assuming that the genes are located in specific sites of chromosomes.

1.2.2 Cell Theory

With the invention of compound microscope around 1600, a whole new world of science to marvel opened up for us. It was between 1655 and 1879 when researchers described the many kinds of cells seen in very thin slices of plant and animal tissues. The darkly staining long threads (chromosomes) were present in every cell. They had a remarkable dance like behaviour during the cell division. It is during this time, that the cell theory was put forth. Cell theory states that the cell is the underlying unit of structure in all the living organisms. They also proposed that new cells come only from pre-existing cells. With this idea, now just imagine a continuous unbroken series of cell divisions, from the point called “you’ backward and backward, continuously to your ancestors, their forefathers and so on. So you would now agree with me, but you are here because of this marvellous unbroken chain of cell divisions running to the remote past. Yes in 4000 million years of earth history, you are lucky enough to be alive because of this continuum!

1.2.3 The Cell and its Types

The dark staining threads as I mentioned, in each cell are called as chromosomes (Greek chroma, “colour”, soma “body”) located in a nucleus. The nucleus is separated from the remaining cell contents, known as cytoplasm by a double membrane wall. Organism with this kind of cell structure is called eukaryotes.

Single celled prokaryotes (bacteria and archaebacteria) lack nuclei and have simpler chromosome. The hereditary material that is faithfully passed on from your ancestor to you resides in the chromosome.

Your body contains about 10 trillion cells. All of them came from just one cell, the fertilised egg. Yet the 10 trillion cells you are made up of are now no longer identical to each other. The skin, bones, muscles, brain, internal organs all are made up of different somatic cells. Yet they are a product of two germ cells that are also called as reproductive cells- the egg in your mother and the sperm in your father that united sexually to produce the new individual called you. Around 200 different types of somatic cells exist; each specialised to perform one or more unique functions.

Inspite of differences in the structure and function of the different cell types there are certain basic structure and functions common to virtually all cells. (Fig.1.3). But remember, that cells have complex organisations and multiple roles. How they develop and carry on their work is taken care by the information packed in their nuclei. The nucleus forms the large central compartment. As I told you earlier the nuclear envelope consists of two membranes that contain many pores, through which materials are exchanged with the surrounding cytoplasm; within the nucleus, are at least one dark staining nucleolus and many finely dispersed chromosomes.

1.2.4 Cell Cycle

Many cell divisions occur before a fertilized egg transforms itself into an individual with trillion cells. Events occurring during cell cycle (Fig 1. 4) indicates whether a cell is dividing or not. The rate of cell cycle differs with the tissue type. For e.g. cells lining the small intestine divide through out the life while nerve cells may not divide at all during the life time. You may define the “Cell Cycle” as a continuous process with two major stages: 1) Interphase (stage with no division of cell), 2) Mitosis (stage with cell division).

Interphase is the time in the cell cycle with great activity like carrying out several biochemical functions concerned with life processes, DNA replication and subcellular structures that are distributed to daughter cells after cell division. Interphase is divided into two gap phase called G1 phase and G2 phase. A cell exists from G1 phase to enter G0 phase also called as “quiscent phase”. A cell in G0 phase maintains its characteristicks and DNA replication or division does not occur at this stage. from here the cell may proceed for division or may lead to “apoptosis” or cell death. In G1 phase, synthesis of proteins, carbohydrates and lipids occur which are required for the daughter cells. The time duration of G1 phase varies from cell to cell.

During the next phase called S phase, cell replicates its entire genome, each chromosome replicates longitudinally held together by the centromere. This phase lasts for 8-10 hours and synthesises protein required for the formation of spindlethe structre that pull the chromosomes to the poles of the cells during anaphase stage of cell division.

G2 phase occurs after the replication of DNA and before the cell enters the mitotic divsion. In this phase cell synthesises more of protein, membranes are formed from the proteins produced in G1 phase and stored in small vesicles that will enclose the daughter cells at later stage.

There are certain check points (group of interacting proteins) that ensure that the events happen in proper sequence. These points are a) DNA damage check pointthat acts during S phase. It inhibits cell cycle from proceeding further till the damage is rectified, b) Apoptosis Check Point- which acts as the mitosis begins. In apoptosis check point, proteins called “survivins” override the signals causing cell death. Thus cells are kept at mitosis., c) Spindle assembly check points- take care of spindle formation to which chromosomes are attached helping their movement towards the poles during cell division.

1.2.5 Types of Cell Divisions

Before going further, let us recollect from our previous biology lessons that cell divisions are of two types. They are Mitosis and Meiosis.

Mitosis

Mitosis is the normal form of cell division. As a person develops from an embryo through fetus and infant to an adult, cell divisions are needed to generate the large number of cells required. Remember that many cells have a limited life span, so there is a continuous requirement to generate new cells in the adult. All these cell divisions occur by Mitosis. Mitosis is the normal process or cell division, from cleavage of the zygote to death of the person. It is estimated that in the life time of a human, there may be something like 1017 mitotic divisionsMeiosis

Meiosis is a specialized form of cell division giving rise to the sperm and egg cells. Primordial germ cells migrate into the embryonic gonad and engage in repeated rounds of mitosis to form oogonia in females and spermatogonia in males. Further growth and differentiation produces primary oocytes in the ovary and produces primary spermatocytes in the testis. These specialized diploid cells can undergo meiosis.

An important point to remember is, that meiosis involves two successive cell divisions first, reduction stage during which chromosome number is halved (i.e it becomes haploid or n) and second, the multiplication stage (also known as equational stage) with mitotic division maintaning the haploid number of chromosomes. Only one round of DNA replication occurs so the products are haploid.

1.3 HUMAN CHROMOSOME COMPLEMENT

Prior to the 1950s, it was believed that each human cell contained 48 chromosomes and that human sex was determined by the number of X chromosomes present at conception. With the help of realise methods for chromosome preparation it was realized that the correct chromosome number in humans is 46 and that maleness is determined by the presence of a Y chromosomes irrespective of the number of X chromosome present in each cell. Further it was also realized that abnormalities of chromosome number and structure could seriously disrupt normal growth and development.

1.3.1 Morphology of Human Chromosome

At the sub-microscopic level chromosomes consist of an extremely elaborate complex, made of supercoils of DNA (Fig. 1.7). So each chromosome contains one molecule of DNA. The DNA molecule is incredibily long and has to fold itself in compact way so as to fit inside a cell which is only one millionth of an inch. Various proteins help in the compression of DNA molecule with out damaging it. A frame work of scaffold proteins guide the DNA molecule to compress. The DNA coils around the proteins known as “Histones” which give beaded appearance. The beaded structures are called “Nucleosomes” which get packed tightly during cell division so that the chromosomes become condensed and are visible as the cell division progresses specially at metaphase and telophase. A chromosome consists about 1/3 of DNA, 1/3 of histone protein, 1/3 of other DNA binding proteins and a small amount of RNA. The chromosome material is referred as “Chromatin” since it takes the color of the dye used while staining.

In a diploid nucleus, the two members of a chromosome pair are called homologous chromosomes or just homologs. Thus in diploids, each gene is present as a gene pair. Although the nucleus in a human cell contains pairs of chromosomes, they are not physically paired, in the sense of being next to each other.

Most of our knowledge of chromosome structure has been gained using microscope. Special stains selectively taken up by the DNA have enabled each individual chromosome to be identified. These are best seen during cell division when the chromosomes are maximally contracted. During this contracted phase the constituent genes can no longer be transcribed. At this point of time, you can see that each chromosome consists of two identical strands known as chromatids, or sister chromatids, which are the result of DNA replication having taken placeduring the S (synthesis) phase of the cell cycle. The point or the primary constriction at which the two sister chromatids are joined is called as the centromere. This is the spot that is responsible for the movement of chromosomes at cell division. Each centromere divides the chromosome into short or petite arm (designated as p) and long arm (designated as q). The tip of each chromosome arm is known as the telomere. Telomeres seal the chromosome tips and their DNA caps have a unique chemical structure that keeps chromosomes from shortening during replication.

But with aging and with certain types of cancer there is a gradual accumulation of changes (mutations) in telomeres. Please remember that for unknown reasons the regions next to telomeres contain a high concentration of genes. Telomeres are known to be highly conserved throughout evolution and in humans they contain many tandem repeats of a sequence TTAGGG Sequence. Morphologically chromosomes are classified according to the position of the centromere.

If this is located centrally, the chromosome is metacentric, if terminal it is acrocentric, and in case the centromere is located in an intermediate position, the chromosome is sub-metacentic.

Besides centromeres, some chromosomes have additional pinched-in sites called secondary constrictions. Acrocentric chromosomes sometimes have stalk like appendages called satellites that form the nucleolus of the resting interface cell and contain multiple repeat copies of genes for ribosomal RNA.

1.3.2 Classification of Chromosomes        

Another parameter that varies among the chromosomes is their over- all length. So three parameters form the basis for classification, length, position of the centromere and the presence or absence of satellites.The early researchers in cytogenetics recognized the 23 chromosomes and divided them into groups.

1.3.3 The Groups of Chromosomes

The groups span from A to G (seven classes) in the alphabetical order based on the overall morphology. In many standard text books you will see that the human mitotic chromosomes* of humans are generally grouped according to the following cytological criteria:

Group A (chromosomes 1-3) Large chromosomes with approximately median centromeres.

Group B (chromosomes 4-5) Large chromosomes with sub median centromeres.

Group C (chromosomes 6-12 and the X chromosome) Medium sized chromosomes with sub median centromeres.

Group D (chromosomes 13-15) Medium sized acrocentric chromosomes. Chromosome 13 has a prominent satellite on the short arm. Chromosome 14 has a small satellite on the short arm.

Group E (chromosomes 16-18) Rather short chromosomes with approximately median (in chromosome 16) or sub median centromeres.

Group F  (chromosomes 19 and 20) Short chromosomes with approximately median centromeres.

Group G  (chromosomes 21, 22 and the Y chromosome) Very short acrocentric chromosomes.

* J.H.Tjio and A . Levan in 1956 demonstrated that the diploid chromosome number for humans is 46.

* M.L.O’Riordin and three colleagues in 1971, reported that all 22 pairs of human autosomes can be identified visually after staining with quinacrine hydrochloride. They demonstrated that the Philadelphia chromosome is an aberrant chromosome 22.

(Philadelphia chromosome was first observed by researchers at the university of Pennsylvania and named after the city where the discovery was made. The chromosome is often found in myeloid leukemia, a disease in which several bone marrow derived cell lineages proliferate uncontrollably. Philadelphia chromosome (Ph1) is generally a reciprocal translocation between human chromosomes 9 and 22 involving break points at 9q34 and 22q11. The translocation generates a fusion gene made up of elements from a gene on chromosome 22 and the majority of a proto-oncogene from chromosome 9).

The regions in the chromosomes where genes are actively expressed stains lightly and these are called as euchromatin regions. On the contrary heterochromatin regions stain darkly and is made up of largely inactive, unexpressed, repetitive DNA.

Sex chromosomes have a critical role in the determination of one’s gender. In humans both males and females have two sex chromosomes. XX in females and XY in males. The most important gene on the Y chromosome is the testis determining factor known as SRY. Other genes on the Y chromosome are important in spermatogenesis. Each of the ovum in the female carries one copy of X chromosome while in male each sperm carries either an X or a Y chromosome.

4 METHODS USED IN CHROMOSOME ANALYSIS

Tijo and Levin were the first group of scientists who in 1956 demonstrated that each human cell contains 46 chromosomes and broke then prevailing belief that it is 48chromosomes.

1.4.1 Chromosome Preparation

Having recollected the features of the two types of cell divisions, let us move to the methods of chromosome analysis. These methods are commonly employed in cytogenetics laboratories to analyze the chromosome constitution of an individual, which is known as karyotype. The word karyotype is also used to describe photomicrograph of an individual’s chromosome arranged in a standard manner.

The entire chromosome complement of an individual organism or cell as seen during mitotic metaphase is used to arrange the karyotype.

Any tissue with living cells having a nucleus that can undergo cell division is suitable for studying human chromosomes. The commonest method is to use circulating lymphocytes from peripheral blood.

Some steps in the chromosome preparation are given below:

• 1) The venous blood sample is added to a small volume of nutrient medium containing phytohemagglutinin, which stimulates T lymphocytes to divide.
• 2) The cells are cultured under sterile conditions in an incubator at 370C for about for 72 hours, at the end of which the culture is terminated.
• 3) At 70 hours i.e. 2 hours prior to the termination of the culture, colchicine is added to each culture which now stops the cell division at metaphase. Colchicine is a chemical that has a special property of preventing formation of the spindle. Once the spindle is not formed, the cell division gets arrested at metaphase. Metaphase is the time when the chromosomes are condensed to a maximum extent and because of this condensation are very clearly visible.
• 4) Hypotonic saline is then added to the cultures, which causes the cells to swell which helps in the lysing or breaking of the cells with ease.
• 5) Then the cell suspensions are dropped on the pre chilled glass slides by holding the pipettes at a distance so that good metaphase spreads are obtained.
• 6) The cells are then fixed and mounted on a slide.
• 7) The slides are further processed for staining.

1.4.2 Chromosome Banding Techniques

Now there is an important step which is called as the staining step. Many different stains and methods are used to identify individual chromosomes, using:

i) G (Giemsa) banding is the most common method used. The chromosomes are treated with Trypsin. Trypsin denatures their protein content; following this, the cells are stained with a DNA-binding dye known as Geimsa. On staining with Geimsa each chromosome takes up a characteristic pattern of light and dark bands. These light and dark bands can be reproduced in the same pattern for each chromosome. In other words the banding pattern is repeatable.

ii) Q (quinacrine) banding: This gives a banding pattern which is similar to the bands, obtained in Giemsa staining. However a ultraviolet fluorescent microscope is required to view these chromosomes.

iii) R (reverse) banding: In this method the chromosomes are denatured by heating and then stained with Giemsa. This gives light and dark bands which are the reverse of those obtained using conventional G banding.

Meaning- there will be a dark band in the region where the Giemsa stain shows up as a light band. Similarly it will be a light band in the corresponding region where the G staining gives a dark band.

iv) C (centromeric heterochromatin) banding: Here the chromosomes are pretreated with acid followed by alkali before G banding; the Centromeres and other heterochromatin regions containing highly repetitive DNA sequences are stained preferentially.

1.4.3 High Resolution Banding

G banding gives approximately 400 to 500 bands per haploid set, enabling us to do a high- quality chromosome analysis. Each band approximately corresponds on an average to 6000 to 8000 kilobases (kb) or 6 – 8 megabases (mb) of DNA (deoxy ribo nuclei acid, which is the ultimate molecule of life – the polymer of which genes are composed). One thousand base pairs in a DNA sequence is equal to one kilobase.

If you want a more detailed banding pattern, which is known as high resolution banding, say with 800 bands can also be obtained. The only condition is that it is technically more skill based and laborious.

Here the cells have to be arrested precisely at even an earlier stage of mitosis called as prophase or prometaphase that results in greater sensitivity to give upto 800 bands per haploid set. The agent used to inhibit cell division is methotrexate or thymidine.

Folic acid or deoxycytidine is added to the culture medium, releasing the cells into mitosis. Colchicine is then added for a specific time interval, leading to a high proportion of cells to remain in prometaphase. They will also be in fully contracted state, giving a more detailed banding pattern.

1.5 KARYOTYPE ANALYSIS

1.5.1 Counting the Number

The most important step in chromosome analysis involves first counting the number of chromosomes present in a particular number of cells. The cells that are counted to know the chromosome number in them are called as the metaphase spreads. One has to first count each metaphase spread and find out how many chromosomes are there in each of the spread.

Generally the total chromosome count is determined in 10 to 15 cells.

But if there is a state of mosaicism (a condition in which the same individual has two or more types of cells with different number of chromosome in one metaphase spread, and another chromosome number in the second spread) then 30 or more metaphase spreads are counted.

Once counting the number of chromosomes in each spread is completed, a little more detailed analysis is done.

1.5.2 Analysis of the Banding Pattern

This is followed by a careful analysis of the banding pattern of each individual chromosome in selected cells. This will be observed on both members of each pair of homologs say the “ 1st chromosome pair”, “ 2nd chromosome pair” and so on. Three to five metaphase spreads, which show high-quality banding, are chosen for this purpose of detailed banding analysis.

1.5.3 Idiogram

The banding pattern of each chromosome is specific and can be shown in a particular style known as idiogram. The chromosome pairs are conventionally presented in a karyotype also called as karyogram with each pair of chromosomes arranged in descending order of their size.

So, having introduced the important steps to you, I will now sum up that, karyotype is the chromosomal complement of a cell, individual, or species. It describes the light microscopic morphology of the component chromosomes, so that their relative lengths, centromere positions and secondary constrictions can be identified. Attention should be paid to heteromorphic sex chromosomes (homologous chromosomes that differ morphologically).

The karyotype is often illustrated with a figure showing the chromosomes placed in order from largest to smallest as I mentioned earlier. This illustration is called as idiogram, which can be constructed by aligning photomicrographs of individual chromosomes, or it may be an inked drawing, summarizing the data from a series of analyses of metaphase chromosome spreads.

Importance of chromosome analysis

Chromosome analysis is important to detect the structural and numerical abnormalities. An extra chromosome can result in a trisomy of that particular chromosome. Sometimes the whole haploid complement can be present resulting in polyploidy instead of the usual diploid complement. Advanced chromosomal techniques like molecular cytogenetics helps to quickly detect the structural abnormalities like deletion of the segment of the chromosome, insertion of anextra bit of chromosome or an inversion of a segment of the chromosome. Sometimes a ring chromosome is found when a break occurs on each arm of a chromosome leaving two ‘sticky’ ends on the central portion that reunite to form a ring.

Sample Questions

• 1) Write in brief about the human chromosome complement.
• 2) What is the basis for the classification of the chromosomes?
• 3) Highlight the seven classes of human chromosomes described in a karyotype.
• 4) What is a telomere?
• 5) What is the importance of chromosome analysis?
• 6) Define Idiogram.
• 7) Write on the various chromosome banding techniques available.
• 8) Differentiate between mitosis and meiosis.
• 9) Write briefly on the morphology of human chromosomes.
• 10) What is cell theory?