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I think you mean 3’ not 5’ , right¿

Hi there, leading-strand synthesis generates a blunt end while lagging-strand synthesis produces a long G-rich 3′ overhang, and suggest that variations in lagging-strand synthesis may regulate the rate of telomere shortening in normal diploid human cells. The article supporting this statement is www.ncbi.nlm.nih.gov/pmc/articles/PMC316649/ If you can specify the mistake you detected, we will gladly take a look at that and amend the problem. Thank you

@@EasyPeasyLearning Could you explain why? I’m a graduate student in mol bio and I have always been taught that the lagging strand is shorter. Which makes complete sense since its 5’ primer is removed at the end of synthesis. My question to you is why do you think the lagging strand and not the leading strand makes a 3’ overhang?

Hi Raphael, you are mixing 2 different concepts. The 1st concept is that the 3' overhang is on the lagging-strand and the second concept is that after replication the telomere overhang lose a part of DNA due to okazaki fragments. Think it this way if the shorter strand start losing its part of DNA then the quality of life will remain for short time only. Telomere overhang have sequence that is not translating the essential proteins, so losing them little bit is not affecting our quality of life until it reaches the crucial part where it stops dividing anymore. Hope that will clear the confusion.

@@EasyPeasyLearning I discussed with my professor who confirmed my points. Many other people also pointed this in the comments. The leading strand is longer. Its overhang is then extended by telomerase to leave more room for polymerase to synthesize the complementary strand

Hi Raphael If you can provide a scientist article or review paper supporting your statement, we will gladly look into it.

Thank you for your comment. I will put correction note on it.

You are welcome 😊 and thanks for the correction 😊 ☺

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Thank you John 😊

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Good media to your take,success for you

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Most welcome

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Glad you liked it!

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I know its really complex but trying my best to make it easy peasy.

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hello i know you asked this question 9 months ago but to answer it, after the primer gets removed, a DNA polymerase with 5’ to 3’ exonuclease activity will replace the primer with DNA versions

@@yintiangiam478only dna polymerase 1 do this 5’--3’ exonuclease avtivity

Thank you

Welcome and continue to share your presentations You have very clear concepts

Hi Paniz! The time span of telomere shortening varies from person to person. It can depend on different factors like atmosphere, food, weather, physical activity etc etc.

Thank you the topic is noted and now is in the queue 😀

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The lagging strand is bigger because it will make up a knot to terminate the process of replication and protect the dna in an intact form (chromosome)

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Hi Eda, think it of this way. New strand always get synthesize from 5' to 3' end. Then which strand can make it without problem ? that is 3' to 5' so it is a leading strand. Furthermore look at the textbook again the confusion will get clear. Here i am giving a reference from 1 site. www.quora.com/Why-does-the-lagging-strand-of-DNA-have-to-be-discontinuous Still the confusion remains there. You can contact me again.

@@EasyPeasyLearning Yes, new strand always synthesize from 5’ to 3’ . My point is the new 3’-5’ strand that synthesized from 5’-3’ parental strand will synthesize as okazaki fragments so we need a new short RNA for every new Okazaki fragment. When it is time to synthesize tip of new 3’-5’ strand the RNA Primase couldn’t synthesize the tip so we lose telomeric G-tail from parental 5’-3’ strand in every division. We use telomerase to prevent that. So the problem should be in the new and 3’-5’ strand.

Hi Eda, here it needs to be corrected. New okazaki fragments appear on lagging strand is not from 3' to 5'. It is also from 5' to 3' on the parental strand that is also from 5' to 3'. That is why they are in pieces and need primer again and again. This is the detailed article on replication www2.csudh.edu/nsturm/CHEMXL153/DNASynthesis.htm

Thanks

Yes you are right it was a mistake in the slide. Thank you for correction

It's a mistake in the video, the correction note is already there

Hi there, leading-strand synthesis generates a blunt end while lagging-strand synthesis produces a long G-rich 3′ overhang, and suggest that variations in lagging-strand synthesis may regulate the rate of telomere shortening in normal diploid human cells. The article supporting this statement is www.ncbi.nlm.nih.gov/pmc/articles/PMC316649/ If you can provide the article claiming that leading strand have overhang, we will gladly want to look upon it and if your statement is true, we will surely amend the video. Thank you

​@@EasyPeasyLearning These are two very concepts. Telomere elongation happens just after DNA replication, so strictly speaking the leading and lagging strands do not appear as shown in the video. the newly synthesized leading strand is in complex with its parental strand, and this duplex consists of equal length strands prior to the involvement of telomorase. The newly synthesized lagging strand is similarly in complex with its parental strand, but here the parental strand is longer than the newly synthesized strand (i.e. there is overhang). Instead of labeling the strands in these duplexes as lagging and leading strands, it's better to follow literature convention and name them either 3' and 5' strand or G-strand and C-strand. Alternatively, the strands in the video could be labeled parental strand and newly synthesized lagging strand, as that is the pairing shown. The parental strand is then of course the longer G-rich strand strand ending in 3'. So the concept that the lagging strand has a longer overhang compared to the leading strand is true, but that refers to the duplex of the lagging strand and its template compared to the leading strand and its template. It does not refer to the overhang between two strands in duplex as presented in the video. This confusion likely resulted from mislabeling these strands as leading and lagging, as discussed before. See this image for a schematic view: www.cell.com/fulltext/S0092-8674(09)00897-6

Thank you very much for providing the information. We will definitely look into it and correct everything accordingly. We appreciate your support and feedback.

Hi there, this article might help you in understanding the concept better www.ncbi.nlm.nih.gov/pmc/articles/PMC7152597/#:~:text=Non%2Dcoding%20RNAs%20critically%20regulate,to%20cellular%20senescence%20and%20aging.

Yes, it was a mistake, we did made a correction note on the video but somehow its not visible all the time.

Hi Psychologie The advent of the clustered regularly interspaced short palindromic repeats/CRISPR-associated (CRISPR/Cas) system has led to a wide array of targeted genetic studies that are already being employed to modify telomeres and telomerase, as well as the genes that affect them. The article supporting this statement is www.ncbi.nlm.nih.gov/pmc/articles/PMC6406488/ Telomeres normally would not get attacked by nucleases present inside our cell due to the knot made by telomere in the end. Lastly the query about histone attachment with telomere, Specific post-translational modifications of histones, including methylation, acetylation, and ubiquitination, have been shown to be necessary for maintaining a chromatin environment that promotes telomere integrity. The article supporting this statement is www.ncbi.nlm.nih.gov/pmc/articles/PMC6407025/

@@EasyPeasyLearning thank you very much! i will look at it. is it also possible to mail you? for asking you some more questions?

@@EasyPeasyLearning hey Easy Peasy, is it possible to ask you something by email?

Hi Psychologie Why don't you ask your questions on our community page. Every subscriber can participate in that and it will be a healthy activity for everyone.

@@EasyPeasyLearning i understand, but is special question. but is oke

Hi Rayan, yes you are right that was a mistake. Thank you for pointing it out

Hi there, the subtitles are added to the video, thank you for your comment.

😃 😃

Lagging strand is longer to make a knot at the end of a chromosome so that the Dnase enzymes can't degrade it if its open. It is also longer then the leading strand so the telomere depletion would not affect the real Gene's present on the chromosome for a certain period of time.

@@EasyPeasyLearning but how can the lagging strand be longer if the last okazaki fragment can not be constructed?

Hi Tony, This article will help you understand it. www.nature.com/scitable/topicpage/telomeres-of-human-chromosomes-21041/ www.intechopen.com/chapters/41797

@@EasyPeasyLearning Your source says the leading strand is longer "Thus, as the replication fork moves along the chromosome, one of the two daughter strands is synthesized continuously. The other daughter strand, known as the lagging strand, is synthesized discontinuously in short fragments known as Okazaki fragments, each of which has its own RNA primer. The RNA primers are subsequently degraded, and the gaps between the Okazaki fragments are then filled in by the DNA repair machinery. A problem arises at the end of the chromosome, however, because the DNA repair machinery is unable to repair the gap left by the terminal RNA primer. Consequently, the new DNA molecule is shorter than the parent DNA molecule by at least the length of one RNA primer. Without a solution to this end-replication problem, chromosomes would progressively shorten over many cell divisions, a process that would bring about catastrophic consequences."