“The repetitive DNA found at chromosome’s ends, function to protect the DNA or genes is known as telomere or telomeres of chromosomes.”

Do the telomeres of the human chromosomes have any role in ageing? the answer is “Yes”. In the present article, we will try to describe how it happens.

The DNA of us is situated on chromosomes- a complex network of protein and nucleic acid. The number of chromosomes varies between different organisms. For examples, 23 pairs of chromosomes are present in human.

All nuclear DNA of humans is located on those 46 chromosomes. Also, inherited it to consecutive generations.

Centromere, telomere and arms are three different structure of chromosomes. The centromere is located in the centre. The arms contain all genes and the telomeres are located on the ends of each chromosome.

Interestingly, if the number of chromosome changes, it can cause serious health issue, likewise the structural abnormalities.

In the present article, we will talk about telomeres and its role for us. Furthermore, we will discuss its purpose in ageing and cancer. The content of the article is,

What is a telomere?

In 1939, Muller and McClintock concluded that some specific sequences present at the end of the chromosome prevent chromosome fusion. Those are telomeric sequences.

Telomere : Telos = end, meros = part

As we said, the human chromosome is a complex network of proteins and DNA. Histon proteins like H1, H2A, H2B, H3 and H4 interacts with DNA and arrange it like bead-on-string structure.

Genes are located on the arms of chromosomes. And inherited with it. The telomeres protect genes from damage.

In 1975, Blackburn E, Gall JG discovered telomeres and explained their repetitive nature.

In 1983, McClintock B who discovered the transposons had explained the role of telomere end in chromosome stability.

However, the end replication problem was postulated by Olovnikov A during ‘70.

The enzyme telomerase was discovered and characterised in 2009.

Definition:

The repetitive DNA found at chromosome’s ends, function to protect the DNA is known as telomere or telomeres of chromosomes.

Structure:

The special types of repeated sequences present on the telomeres(AGGGTT) make them unique from other regions of the chromosomes. The overhanging polynucleotide sequence present on telomere is six nucleotide sequence made up of TTAGGG. Also known as Hexa-repeats.

The terminal end of the Hexa-repeat has single-stranded Guanine reach overhang. The six nucleotide sequence present from 2500 to 3000 time on each human chromosome. Notably, it is 15,000 nucleotides long.

The special Kind of TIP (Telomeric interacting proteins) and the Hexa nucleotide repeats of the telomeres provide the structural hierarchy to the telomere.

The 6 basepair repeats are tandem repeats and are conserved since the evolution.

Conclusively the characteristics of the telomere are,

Six nucleotides overhang- TTAGGG

Repetitive DNA sequence

Tandem repeats

Non-coding

Conserved since evolution

The DNA is made up of the long chain of A, T, G and C bases, phosphate backbone and the sugar. Read more on the structure of DNA….click here

Notably, the telomeres are only present in eukaryotes. As the prokaryotic chromosomes are circular, it doesn’t have telomeres.

Function:

The prime function of it is to protect the genetic information of cells.

In addition to this, by capping the ends of chromosomes, it helps chromosomes to fit inside the cell nucleus.

It protects the fusion and deterioration of chromosomes.

It prevents cancer and induces senescence.

It facilitates proper replication. Hence it protects genes from facing end replication problem.

What is the end replication problem?

If genes or coding sequences are located on the ends, It can’t replicate properly. And results in genetic problems.

As we said above, the telomeric sequences are non-coding. Some sequences lose after each round of replications. But it doesn’t cost anything to a cell (because it is just junk!).

The process of replication starts when the single-stranded, short sequences of RNA binds to the single strand of the DNA. This short RNA sequence serves a substrate for DNA polymerase to work. Finally, DNA polymerase binds to the single-stranded DNA-RNA junction and replicate it.

But in the end, the RNA primer is removed and the gap above it remains as well. A similar problem happens at the lagging strand too.

At the lagging strand, each Okazaki fragments are replicated with the help of each dedicated RNA primers, However, the last Okazaki fragment’s RNA primer creates the single-stranded overhang.

The primer of the last Okazaki fragment can’t be made unlike other fragments and hence remains unreplicated. The last RNA primer can not form DNA because no DNA strand is left there. Ultimately, the RNA primer is removed or destroyed and the gap remains unfilled.

Thus after each round of replication, some amount of DNA from the end losses because the single-stranded overhang can’t copy.

Now assume that, if some of the important genes may present at the end of the chromosomes, those genes will skip replication and can’t be inherited.

Further,

The activity of DNA polymerase decreases at the end of the replication. Therefore some amount of DNA can’t be properly copied. Consequently, those sequences are lost or removed.

Telomere shortening:

The process of losing DNA sequences from telomere is referred to as telomere shortening. Scientists believe that it causes cell ageing. After each round of replication, some DNA removed and the cell becomes aged.

Actually, this end replication problem is a reason for eukaryotic mortality. However, Our cell can solve this problem using a special type of enzyme.

All our genetic content must remain intact and unbroken.

The DNA repair pathway of our cell repairs the DNA (which are broken or single-stranded), to prevent the loss of the DNA.

If this DNA repair pathway repairs the DNA of the end of the chromosomes (overhang telomere). The ageing can’t happen.

To skip the DNA repair, the single-stranded overhang forms a loop and becomes double-stranded by creating hydrogen bonds with the adjacent DNA.

This skips DNA repair and induces ageing.

The cell senescence occurred due to the progressive telomere shorting. “Senescence is a process of loss of a cells growth and division power”.

The telomere shortening is very common in somatic cells but not in germ cells!

Note: telomeres can’t shorten in non-dividing tissues.

In germ cells like eggs and sperm, telomere losing prevented. Further, it is can not occur in some pluripotent stem cells as well.

Exceptionally, the pulmonary and heart tissue remains unaffected by telomere shortening. Because those are continuously dividing. In the germ cells, the enzyme called telomerase helps to prevent the telomere shortening.

After each round of replication, telomeres shorten. However, at one critical point, it can’t shorten more, the point is senescence. Here the cell dies and can’t go further cell division. Thus a cell can divide only 50 to 55 times, the limit is known as the “Hayflick limit.”

Telomere prevents unnecessary recombination, DNA repair and degradation. Therefore telomere has a crucial role in preserving information in our genome. Ultimately it determines the lifespan of the cell and organism. It is a kind of biological clock.

Besides the length of our hero (i am talking about “telo”), the shape and structure of it, is also very crucial for normal cell functioning.

The sequences in it are TTAGGG in humans and it’s fixed not changed. Further, The ends formed by the telomeres are not blunt. Actually, it forms a loop by bending and becomes double-stranded.

That’s how it gives an exact shape to ends. Telomere shortening is one of the reasons why we aged.

Telomere and ageing:

Progressive reduction in the function of the cell or tissue causes mortality; is called as an ageing process.

As we age, the functional capability of the cell decreases gradually. The ability of a cell to produce energy, the rate of synthesis of new biomolecules and the rate of replication decreases as well.

“Shorter the telomere, shorter the lifespan of an organism”

As the ageing of an organism depends on the length of the telomere. This means organisms with longer telomeres lives longer (for example human) as compared with short telomere (for example dog and mice).

Nonetheless, telomere shortening is not the only reason for the ageing. So is it possible to increase lifespan by decreasing the rate of telomere shorting?

Well, theoretically, telomerase enzyme can do so. If we increase the expression of the telomerase gene in somatic tissues, we can live longer. Just an assumption!

Practically, it is not possible. Yet, telomerase therapy can do so. However, it can also cause unknown cancer. Or we don’t know what else will happen.

As we know, only telomerase enzyme can prevent telo-shortening, thankfully it is not present in somatic cells.

As we discussed, the abnormal activity of telomerase causes cancer. It also plays a role in preventing cancer as well. I will tell you how!

Too short telomeres can’t copy. Thus, it sends a signal to a cell to repair the DNA. A quickly shortened telomeres treated as broken DNA and get repaired.

Hence, the normal function and activity of cell and cell division are revived. By this mechanism, the chance of cancer decreases.

Telomerase enzyme:

The telomere shortening must be prevented in germ cells by telomerase enzyme.

A type of RNA dependent DNA polymerase- telomerase, prevents telomere shortening in germ cells and pluripotent stem cells.

In humans, two identical telomerase enzymes are required for the proper function of the telomere. Therefore it is also called as a dimeric enzyme.

The short- single-stranded RNA is used as a template for the synthesis of new DNA by reverse transcription activity.

Telomerase is a class of special kind of ribonucleoprotein enzyme that prevents the telomere shortening.

The enzyme consists of TERT and TERC sites. The TERT- telomerase reverse transcriptase helps in reverse transcription of DNA from RNA.

TERC- telomerase RNA component serves as a template for the activity of the telomerase enzyme.

However, the expression of the TERT gene is highly regulated in stem cells and germ cells.

Overall, the telomerase prevents the telomere shorting by adding nucleotides complementary to the overhang.

Telomerase activity can lose due to mutations in TERC or TERT. This will result in either uncontrolled telomere growth or telomere shortening.

The abnormal activity is also associated with chromosome fashion, genomic instability, cancer and DNA breakage, besides ageing.

The telomerase activity depends on the shelterin or telosome. The sheltering is a complex of six telomere maintenance protein composed of TRF1 and TRF2.

The telomeric repeat binding protein 1 (TRF1) work as a negative regulator for the telomere, promotes telomere shortening while the telomeric binding protein 2 helps in telomere end protection by preventing the telomere shortening.

In short, the TRF1 promotes telomere loss while TRF2 prevent telomere loss.

Moreover, other shelterin proteins are RAP1, POT1, TIN2 and TPP1 help in telomere maintenance and regulation.

Now, imagine if telomerase is inactive in germ cells such as sperm or egg, what will happen?

We will answer this question in the last part of this article.

_______________________________________________________________________________

Do you know?

Astragalus membranaceous, a Chinese medicinal plant prevents the telomere shortening. The compound HDTIC enhance the longevity by increasing DNA repair ability and decreasing telomere shortening. Also, the TA- 65 molecule of this plant inhibits DNA damage, elongate telomere by activating telomerase and increasing the life span. This plant has anti ageing properties.

_______________________________________________________________________________

Telomeres and cancer:

As we said above, the hexanucleotide chain is also associated with cancer.

We are talking about the hexanucleotide chain- AATGGG- the telomere.

What is cancer?

It is a process of continuous cell division. That means, in a controlled cell division, after each cell cycle the telomere shortening causes cell death. If telomeres can’t shorten, it causes continuous cell division. Which mean cancer.

So the telomere shortening has a definite role in cancer. In general, a normal cell can divide only 50 to 75 times. After that the cell undergoes apoptosis.

“Apoptosis is a process of cell death.”

In cancer, the dysregulation of p53 and the p16 cell signalling pathway leads to senescence. Results in infinite cell division.

In some cases of cancer, not overexpression of telomere but the much shorter telomere is involved in the occurrence of cancer. A shorter telomere than the normal range damages the DNA.

I mean, the coding DNA sequence which is another reason for cancer. However, this mechanism is less understood.

Some of the telomere shortening inducers are smoking, stress, chemicals, oxidative stress, adverse diet and higher protein consumption.

Intrinsic factors such as epigenetics, genetic makeup and activity of DNA repair pathway also involved in the same.

Smoking can cause DNA damage and increases telomere shortening. Further, lack of physical activity and obesity causes the same.

Uncontrolled telo-shortening an early age cause premature death.

Diet plays a great role in our health. A healthy diet strengthens us and vice versa. Eating more food, especially, protein can shorten telomers. Thus we age faster.

Studies confirmed that less consumption of dietary intact can increase our age by reducing telomere shortening.

Also, some dietary intakes like omega 3 antioxidants reduce the ageing process. Restricted and controlled diet can increase our biological age.

Telomere has a significant role in almost 85% of cancer cases. Telomerase is more active in germ cells and pluripotent cells however the length of the telomere is more shorten in the cancer cells compared to normal cells.

Articles on Agarose gel electrophoresis:

Telomere and other disorders:

Inborn dyskeratosis is the first disorder characterised by the error of telomere activity. However, disturbance in telomere activity is also involved in many other disorders.

Interestingly, telomere shortening is the secondary effect in some of the disease states such as AIDS. AIDS is the acquired immune disease in which telomere shortening observed over a period of time.

Premature ageing and death are occurred by progressive telomere shortening. Further, telomere shortening is involved in cardiovascular disease, diabetes and lung cancer as well.

Conclusion

Telomerase therapy can be one of the anti-ageing options. Even, it can also be used in cancer. However, extensive research required to establish it. Telomere and ageing are co-related with each other. Telomere shortening is a major reason for ageing.

By taking less, balanced and antioxidants rich food, we can increase our biological age.

Now answer to our question: if telomerase is inactive in germ cells such as sperm or egg, what will happen?

The answer is “we will extinct.”

Comment below and share your thoughts on how it’s possible.