+Illumina Inc Have to agree with Tiago's comment. I have had multiple professors attempt explanations of this with little success comparatively. Thank you!!

Tiago Bruno Rezende de Castro it takes illumina to explain illumina.

same here but instead of a genomics teacher is a molecular diagnostics teacher haha

Sumanth Neerumalla yeah... "we"

even more incredible where we are today with nanopore.

+rugare maruzani I cannot repeat it

only to the region complementary to flowcell oligo

+Gustavo Loureiro me neither

+Gustavo Loureiro It allows for a copy of your DNA profile to be made, and from this medicines unique to you are possible, rather than as at present, a generalised one size fits all.

Sanger sequencing is still gold XD

@@hezar5166 boomer

@@hezar5166 Good luck trying to sequence a human genome with sanger

If you mean " If 2 fragments get caught in the same spot, so as to generate a mixed cluster instead of a uniform one", the answer is Yes, it can happen. They arrange the concentration of DNA fragments in such way that generally only one molecule will strand to every small spot at the flow cell, and every cluster created from it occupies only a tiny spot. Occasionally a couple of fragments will fall together mixing the signal but that's small exception. Each part of the original DNA molecules is represented many times. A computer deduces the overall sequence from the majority of signals, so a small number of mixed signals doesn't really change anything.

I agree with you.

Pavel Ryzhov you can pool many samples e.g. different microbiomes and reduce costs due to massive parallelization. second sequencing is for verification of first sequ.

Not an expert but I think the index sequencing is used to help define the bounds of the sequence of interest.

My exact confusion too

Each kit come with a certain amount of unique index, let's say 12. You can then prepare up to 12 different samples (or patients), each one getting a unique index that identifies it. The 12 samples are then pooled together in 1 unique container, and everything goes through de sequencing process you just saw there. The computer analysis will then use the index reading datas to sort the reads "per sample" and make up a whole exome or genome for each sample :) Hope it makes sens

i think a sufficiently high concentration of dna polymerase, the knowledge of the rate of nucleotide addition of dna pol and sufficient time should solve your problem.

yess same here... i watched it again n again but can't understand... tomorrow is my presentation on it :(

Do the bases light up one by one ? Is this what is meant by base call?

Statistics :) It's like reading twice the same fragment so that the pc can be more sure about the reading.

from my understanding index 1 is associated with forward sequence, and index 2 is associated with reverse sequence

+Alexander Thomas You don't. And that doesn't happen. There's something called "quality control" after all these. Let me explain: In each cluster, there's the same string with same nucleotides. Let's follow the example from the video. It says that T binds first, and another T after that. But this doesn't always happen at the same time for all the strings in a cluster. For example, when T binds to the second complementary nucleotide, in another string in the same cluster, A binds to the third complementary nucleotide. But when you look at the overall color scheme, you know that T comes the second with high certainty. Sadly, as the sequencing goes, the certainty level drops a lot. And when you come to the, lets say, 100. nucleotide, the certainty drops massively. Paired-end reading can help with dealing with this problem. So, as I said in the beginning, you have to do some quality control after these. Which includes, trimming of low quality base calls, removal of contaminants etc.

Alexander, in short, every base added has a block-cap and a dye. Only one base can be added in each circle. After the reading at the end of each circle, the non-integrated NTs are washed away, then the block and the dye are both cleaved and the circle is repeated. Now the last integrated Nt can receive a new Nt but no longer has a dye. Thus, in each circle only one Nt can be integrated and only the last one can produce light.

I think you helped me understand what they meant about "ambiguous alignments" toward the end of this video.

Each flow cell has the same oligos i think, Strands that fail to have adapters ligated are washed away, and i think they block the 3' adapter by binding with a complementary sequence, I hope I have been a little helpful but i'm not really sure if i'm right.

When sample libraries are prepared, unique indices are attached to each fragment. The libraries are then pooled and then run on the machine. The index reads are used afterwards to identify and separate the sample libraries.

katamari30000 - see my reply to AntiPop4Ever at the top of the comments. The indices are used to differentiate between the paired ends of the sequenced read.

Tom Carnwath Each cluster is composed of a different fragment of DNA. When a fragment binds an oligo in the flowcell lane, it undergoes bridge amplification which stays confined to the vicinity of the original fragment.

Carmen Sandoval Yeah, but how to you guarantee "one fragment per cluster"? If you have 2 or more fragments bind near each other, woudln't the bridge amplification yield a mixed set of DNA (arround that same spot)? I'm missing something here I take it.

+rasmasyean from what I understood, you only separate the sequence after synthesis is complete. Listen starting at minute 4:17. You don't have to 'guarantee ' a specific location of any fragment. You only need the sequence and the computer software will sort the sequences out by identity matching, etc.

+rasmasyean the key phrase in the video that answers your question is "pooled sample libraries."

Nouri Al-Kadhim Let me rephrase the question. OK, each "flash" is from a cluster location of cloned DNA, right? They clone the initial fragment (in each cluster location) into many copies cuz building 1 DNA strand wouldn't make a bright enough flash to be detected by the camera, correct? But in the flowcell, you have to ensure each cluster location has only 1 initial DNA fragment. If you have 2 DNA fragments in one location, it will bridge amplify into dual clones in one spot. Then you can't reliably read flashes from that cluster location. How do you guarantee that there is only 1 initial fragment per cluster. Not 2+.

For example, one flow cells can generate 150M reads, but it's too many for one sample. So samples with different indexes can be pooled together and sequenced. All the reads will be assigned to different samples.

no problem *****

an index for each strand for double strand dna

This is actually for coupling the index to the sample. It is not related to the sequence of the sample but just to identify to which treatment the sequence belongs to

felt

dumbass