For all of those who don't understand the index thing: - you have your genome DNA which you fragment with restriction enzymes (sticky ends) - you create blunt ends and select for a specific size (too long reads are not possible) with purification beads --> what you get is double stranded DNA with specific length - you add a Adenin and a phosphat group to the end of the fragment so that the phosphat and the A are "complementary" to each other at both ends - now you add the predesigned double stranded index molecules consisting of the two flow cell binding sequences + index 1 and 2 + index read primer 1 and 2. To the index read primers a Thymin and a phosphat group are bound - again "complementary" (so only at ONE end) - because of that your DNA fragment and the index molecules can be ligated (A-T binding) - the index is used to say: the fragments with index ATC e.g. is from E. coli whereas AGT e.g. is from B. subtilis Hope this was not too confusing :D

Thanks, I always wondered how plumbuses are made.

I think the cleaving off of the fluorescent signal and removal of terminator during sequencing by synthesis is a key step that is omitted in the video. It becomes very confusing, then, how the previously added nucleotide's flourescent does not interfere with the newly added nucleotide.

This is so helpful! I was trying to understand what really was going on during the process, which the lecture slides from my lecturer didn't seem to help much. Thanks!

this is one of the best videos for sequencing by synthesis. thanks a lot

Everything is clear except the index 1 read part (3:17), as well as index 2 (3:35). Their purpose was not explained in the video. I read somewhere that unique pairs of index 1&2 allow mixing multiple samples together and sequencing them at the same time. Could you elaborate? I don't understand how that can be accomplished based on this video alone.

In addition, a description providing the video times of each step would be useful. I.e: Paired end joining @ 2:00

is it jus me or is this repetition so heckin confusing to follow .... one thing repeated like 10 times god i hate my degree

Only one word: AMAZING

The loud, repetitive dinging in the background is unfortunately quite distracting.

This video is clear and understandable, I didn't grew up in a English community but I am able to understand the video. This is because i studied before watching the video, i watched the video just to give me a clear picture of what happens inside the MiSeqRUO on the flow and how sequencing is achieved 😂😂

I still do not get it why after sequencing the first strand and before proceeding to adding index 2 primer to generate clusters of the other strand index 1 is added again (3:17) to generate a short read. Reading the comments below has not helped. Is anyone able to explain this again? Is this done to signal to the data acquisition computer: "this is the end of sequencing data for the fragments labelled with index 1"?

The old video is a lot better! It actually explains more, like how the adapters, primers are generated, the Index explanation is a lot better!

woah this is actually so smart

i can only say, WOW what a discovery!!! sometimes i think how we got here? it is absolutely captivating and i feel euphoric being involved that journey

The animation could have mentioned the terminator caps, which are crucial for this technology. Besides that, great explanation.

Dear Illumina group thank you for video, can you please answer my few questions:- 1) at 2:22 and 4:00 reading starts from 5'? 2) is numbers of reads generated per fragment depends on the type of NGS application? 3) If reads are generated from fragments how they are aligned? 4) Do data generated from the read contains sequence of amplicons?

Can someone please explain why sequencing the reverse strand is necessary? We just sequenced the given read by synthesizing from the forward oligo. At 3:20, you have the sequence of the entire read and the index. Is there any new information we gain after 3:20? Thanks!

Next Generation Sequencing is really amazing!

I am now understanding how DNA sequencing works clearly!

Wait a minute…this isn’t a Minecraft speed run

high quality video, exciting to watch

Don't know if they meant to show these details, but the letter ordering in the forward and reverse passes is reversed but not complemented- is this an error? in 2:35 you see the ordering (from top to bottom) of AATTCGCATCG and at 3:56 on the reverse read the order is reversed but not complemented i.e. GCTACGCTTAA- shouldn't it have been complemented i.e. (CG,AT)?

Need some more explanations on index 1 and index 2

I have the same question as Stephen Kim, but most of my question is explained by the comments. However, I still wonder why Index 1 is sequenced separately? Why couldn't it be sequenced together with the read; at 3:11 the read was still incomplete but it already got washed away. Thanks!

How does the actual sequencing work from 2:13? It's not that clear. Does the labelled nucleotide bind and automatically release fluorescence?

Thank you so much! Visualizing the process while reading about this technique is too difficult, an animated illustration is the perfect solution! ❤️

Hello! if I may offer some critique, I actually prefer the original video. The animation might be less fancy, but I found it clearer and more illustrative than this "3D" one.

Data analysis is the real D and A

On 0:43 what are the remaining colors: yellow and blue? Red are incides, green correspond to sequence binding site, and purple ones are complimentary to oligos on a flow cell. But what about yellow and blue?

It's so clear. Thank you for your video.

When sequencing by synthesis (2:35), the animation seems to show that only one of the nucleotide lights up when excited. Why doesn't the fluorophores from all the nucleotides emit light?

Did anyone else get the chills at (2:01) or was that just me?

at 1:26 why the original dna strand removed? is it not same as newly formed? plz reply asap

This explains better than me prof. on class

Amazing video with clear explanation but i have small doubt, here i found that when the reads are cleaved and washed off their respective indices are not ligated to their respective reads, how will this work in demultiplexing??

What is the purpose of the indices in the adaptors mentioned at 0:40?

At 1:52 , since the original starnd is washed away, how is it possible for its complementary strand is folding over to hybridize to the second type of oligo? that strand wont be complementary to the second type of oligo but will have exactly the same sequence with that oligo! I am confused. In some other sources, they mention that once you add the fragment both ends hybridize with thte two oligos and then we have the PCR extension which makes more sense. Anyone can help?

helloo, why do we do the step before bridging ( the replication and detachment of one strand..) thanks !

I wonder what is the physical proximity of the oligos to be able to bend.

Why a read 2 (4:00) is nessesary? How come just read 1 (2:23) is not sufficient?

I'm wondering whether there is a mistake in the narration. Before read 1 it mentions the reverse strands are cleaved off. Isn't read 1 a copy of the forward/coding strand, thus you'd need the reverse/non-coding strand to remain attached? At least my MiSeq read primers were always designed this way.

Can anyone help me Before the first sequencing, how the reverse strand are cleaved and washed off , leaving only forward strand?

Wow ❤ nicely explained 👏

He best at speedrun

Can anyone help me to understand what is an NGS assay? Thank you very much in advance.

Thank you so much, it's so great and clear video

This video is very helpful. Thank you.

In 2:27 we can see, that synthesis goes from purple adapter to blue one, which means, purple must be 5' end. Also in 3:16 the same direction of synthesis occurs. After read product washed off in 3:26, template_X folds over and binds second oligo on the flow cell - that means that if purple adapter on template_X was 5' end, then purple adapter on flow cell in 3:33 must be 3' end. Then how is that possible, that in 3:39 the synthesis goes from 3' end to 5' end? If i missed something, just remind me please... :D but i've watched it few times and can't find it correct. BTW nice video. Actually, in 1:36 synthesis goes from blue oligo on flow cell, so blue oligoes on flow cell must be 5' ends. That means, that in 2:27 synthesis goes from 3' end to 5' end, which shouldn't be possible.

Hi, I have a few questions that need urgent answers: 1/ How flourescent label in the blocking group are removed from the nucleotide? 2/ How to wash away free nucleotide? 3/ Why do we have to sequece 2 strain of DNA? 4/ What is the function of index 1 and 2 in adapter attached to DNA? Thank you.

Thanks to explain NGS😊

Thanks! Why don't we cleave and wash off the reverse strand (p7 adaptor) before bridge amplification, won't it be a waste of nucleotides and energy released from hydrolysis?

does the extension of the primer with a nucleotide also require a polymerase? (2:15)

This is also used for whole genome sequencing correct?

Why are the steps before 2:15 required? Why just don't add fluorescent nucleotides at, say, 1:18 stage?

what does it mean 'the number of cycles determines the length of the read?' at 2:45 .. I thought all fragments are read at the same time.. Please someone help 😣​

I have a question. It seems during the first read all the two types of oligos have been occupied through bridging amplification. Why there are free oligos to be used for bridging during the second read?

The second and third phase is that a primer? I mean, oligos = adaptor = primer right?

If the oligos on the flow cell are only complementary to the adaptors on the forward strand fragments, how do they determine which is the forward strand when the adaptors are ligated? Do they just sequence both strands at the same time and then use known sequences to determine which is the forward strand?

I've heard for some applications generation of the reverse read is not necessary, if this is true what would those applications be?

Thanks for the upload!

Thank you for making this simpler!!!

when could I exert my effort to a company like this?🤯 I'll do my best in college first.✊

Question: Do you do a second read when analyzing "16s rRNA Gene" DNA fragments? Or is this only for full genome analysis?

It is clear for me, thanks

What does Reduced Cycle Amplification means?

Wow Thanks a lot!!!

I have one question... your DNA is sequenced by ilumina miseq is of 5MB size. U have to get 10x coverage . How much data do u need?

Aveces no me gusta mi carrera y otras veo este tipo de cosas y me enamoró más de mi carrera y de la ciencia jajaja ❤️

Since each random fragment has a different sequence, how do the adapters bind to the fragments? Especially if the fragmentation is done using mechanical shearing? I have other such basic questions. Can anyone point me to a source that will introduce me to NGS, please?

Ive pressed the replay button 6 times

1:05 "hybridization is enabled by the first of the two types of oligos on the surface..." Does it mean that at that time only one type of oligo is hybridized though there is ssDNA snippets complementary to the other type of oligo too? And if so what's the principle?

So question about experience, in terms of jobs asking to do things such as experience in PCR, NGS library prep, etc., is experience actually necessary? from being a bit exposed to it and reading it, it just seems as if you just need to follow protocols and instructions in order to do the procedures? Or can anyone elaborate on this?

who else is here because they have an assessment

Why do the nucleotides have to bind sequentially?

I am wondering what the background music in this video is?

How come no polymerase is needed to add the building nucleotides to the cluster?

Hi. What would happen if instead of put 5% of PhiX, I put 60% and the library is the correct amount? Thanks.

How is the read length determined? At 4:10

How do you control the reed's length?

Thankyou this video was very helpful. Just 2 questions for clarification: If the reverse strand is washed away, then when the fluorescence labeled nts bind (to template strand) and emit their light signal, what the computer is reading is actually the reverse or complement of the template sequence? And also how is only the reverse strand washed away, how is it specifically targeted? 2) Given a cluster, since one flow cell lawn is amplified to hold one gene fragment when the computer reads the signal from synthesis, its all of that one gene fragment...In other words the coverage of the fragment is dependent on the number of adapters tethered to the lawn of that flow cell ?

very informative video, thank you :) How would you use NGS to identify Amyotrophic lateral sclerosis (ALS) with focus on RNA binding proteins TDP43, FUS, TAF15? What would be the approach?

Is single cell sequencing the hottest spot in the current sequencing field？

does anybody know if the fluorescent molecule is attached to the nucleotide and before the next nucleotide is added does it has to be removed in order to get a monochromatic signal?

I have a question for this video. can you explain to me how to the ends of template are deprotected and protected?

0:43 what's indices?

Great video Why are two primer mixes necessary? Why is not one primer mix sufficient?

The best lecture vedio

What causes the strand to bend to form the bridge?

This some dank

Does anyone know how only the reverse strands are removed from flow cell?

What is the purpose of the index reads?

This could be applied to cosmetic without surgery if applied concurrent with Active MRI and Lighting treatment and coating optic gel

Yeap, but the question is : how do they "add" adaptaters to each end of the fragments (not knowing their sequence) ? Glue 🤔?

well explained..thanks

Hi @illumina do you allow the showing of your videos in lectures on NGS for educational purposes?

What kind of motifs are added? (0.42). I am not able to understand that. Can someone please write that for me.

Thank you for this :D

anyone know what end is the 3', purple or blue in the video?

very nice, thank you