Hi Exo-

The modifications look ok and are not that much of a deviation from the protocol. They should be fine.

A couple of other things - the StarScript RT used in ScriptSeq library prep is an AMV....second, the PCR amplification/enrichment step at the end of the procedure adds 58 bases per side to the insert; If the average fragment length of 400 bp refers to the whole library, the insert size would be about 284 bp.

This may not have much effect on library insert size. With TruSeq kit skipping fragmentation increases average size by 50 bp.

This may not increase the fragment size either. Reducing random hexamer amount may increase size more, as library fragment size depend on RNA fragment size and number of locations that is primed and extended by RT.

This should remove smaller fragments but may cause bias in representation of transcripts in library.

If you are looking to increase insert sizes to avoid sequencing through adapters and maximise useful data, other methods such as oligo dT priming using SMART system followed by cDNA fragmentation or Nextera library prep are better options. In this case one point to note is the aim because the data from large insert will not be easily comparable to previous standard RNAseq data with shorter inserts but it is good approach for studying splice variants and other non-counting applications.

This is interesting. Is this something you have done, and if so did you compare complexity, etc. of the resulting libraries? If they were the same it would seem to indicate that cDNA fragment lengths are dictated more by frequency of RT primer binding (or just RT priming maybe) rather than RNA fragment length. So maybe a lower primer concentration could achieve longer cDNAs?

The figure is based on TruSeq user guide and others experience and libraries were not sequenced. Lowering RT primer concentration expected to increase library fragment size in expense of representation or even coverage of transcripts. This will not be a disadvantage if aim is to study other transcripts features than differential expression.