BioMicroCenter:Illumina Sequencing: Difference between revisions

From OpenWetWare
Jump to navigationJump to search
No edit summary
(67 intermediate revisions by 7 users not shown)
Line 1: Line 1:
{{BioMicroCenter}}
{{BioMicroCenter}}


The MIT BioMicro Center has five high-throughput Illumina sequencers, including a HiSeq 2000, two Genome Analyzers, one NextSeq and one MiSeq. We support a wide variety of applications, such as ChIP-Seq, miRNA sequencing and RNA-seq.  Each lane can potentially accomodate dozens of barcoded samples (depending on sequence complexity and desired coverage). [[BioMicroCenter:CoverageCalculations|Read lengths]] vary, depending on users, between 36nt and 325nt per end. <br>
The MIT BioMicro Center has five high-throughput Illumina sequencers including one HiSeq 2000, two NextSeq 500s and two MiSeqs. We support a wide variety of applications, such as ChIP-Seq, miRNA sequencing and RNA-seq.  Each lane can potentially accommodate dozens of barcoded samples (depending on sequence complexity and desired coverage). [[BioMicroCenter:CoverageCalculations|Read lengths]] vary, depending on users, between 20nt and 325nt per end. <br><br>
All questions about Illumina Sequencing can be directed to [[BioMicroCenter:People|Leigh Manley or Michael Gravina.]]
Questions about Illumina Sequencing can be directed to [[BioMicroCenter:People|Noelani Kamelamela]]


==Illumina Massively Parallel Sequencing==
==Illumina Massively Parallel Sequencing==
[[Image:cbot_left.jpg|left]]Illumina sequencing works by binding randomly fragmented DNA to an optical flowcell. Fragments are sequenced by sequentially incorporating and imaging fluorescently labeled nucleotides in a [http://illumina.com/pages.ilmn?ID=203 “Sequencing-By-Synthesis”] reaction. The BioMicro Center uses Illumina's [http://www.illumina.com/truseq/about_truseq/truseq_sequencing_by_synthesis.ilmn TruSeq v3] reagent kits, improving read quality and reducing GC bias at high cluster densities. For an in-depth overview of the Illumina sequencing chemistry, please refer to [http://www.ncbi.nlm.nih.gov/pubmed/19682367 Kirchner et al 2009.]
[[Image:cbot_left.jpg|left]]Illumina sequencing works by binding randomly fragmented and adapted DNA to an optical flowcell. Fragments are sequenced by sequentially incorporating and imaging fluorescently labeled nucleotides in a [http://illumina.com/pages.ilmn?ID=203 “Sequencing-By-Synthesis”] reaction. The BioMicro Center uses Illumina's [http://www.illumina.com/truseq/about_truseq/truseq_sequencing_by_synthesis.ilmn TruSeq v3] reagent kits for HiSeq, v2 chemistry for NextSeq and v2 or v3 chemistry for MiSeq. For an in-depth overview of the Illumina sequencing chemistry, please refer to [http://www.ncbi.nlm.nih.gov/pubmed/19682367 Kirchner et al 2009.]


== Platforms ==
== Platforms ==
=== HiSeq 2000 ===
=== HiSeq 2000 ===
[[Image:hiseq_2000.jpg|right]] The Illumina HiSeq 2000 is the workhorse of BMC's Illumina fleet and is optimized for maximum yield and the lowest price per basepair. Each lane on the HiSeq is typically produces between 160 and 220 million reads passing our quality filter (for high quality libraries). HiSeq flowcells have 8 lanes, one of which is committed to a control sample that is used for base normalization (lane 1).  Read lengths on the HiSeq very between 40 and 100nt per side and nearly all flowcells use barcoding to run multiple samples in each lane. <BR><BR>
[[Image:hiseq_2000.jpg|right]] The Illumina HiSeq 2000 is the workhorse of BMC's Illumina fleet and is optimized for maximum yield and the lowest price per basepair. Each lane on the HiSeq typically produces between 150 and 220 million reads passing our quality filter (for high quality libraries). HiSeq flowcells have 8 lanes, one of which is committed to a control sample that is used for base normalization (Lane 1).  Read lengths on the HiSeq are set around 40 and nearly all flowcells use barcoding to run multiple samples in each lane. <BR><BR>
In order to optimize work flow and keep costs under control, only full flowcells are run. Since all 8 lanes of the flowcell must be run at equal lengths, submissions of single lanes must be grouped with other similar read lengths. This means that some read lengths move through our queue faster then others because more samples of that length are submitted to the BioMicro Center for sequencing. 40nt single end (SE) samples are by far the most common and move through the queue rapidly followed by short paired end (40+40) runs. Many lengths are very unusual (eg. 100nt single end) and should instead be submitted for the NextSeq unless you have a full flowcell. If you have questions about this (or any other aspect of sequencing) please do not hesitate to contact us.<BR>
In order to optimize work flow and keep costs under control, only full flowcells are run. Since all 8 lanes of the flowcell must be run at equal lengths, submissions of single lanes must be grouped with other similar read lengths. This means that some read lengths move through our queue faster then others because more samples of that length are submitted to the BioMicro Center for sequencing. 40nt single end (SE) samples are by far the most common and move through the queue rapidly. Many lengths are very unusual (eg. 100nt single end) and should instead be submitted for the NextSeq unless you have a full flowcell. If you have questions about this (or any other aspect of sequencing) please do not hesitate to contact us.<BR>
<BR>
<BR>
The HiSeq2000 is ideal for:
The HiSeq2000 is ideal for:
* High numbers of multiplexed samples
* De novo sequencing
* SNP detection
* SNP detection
* ChIPseq
* ChIPseq
* Bisulfite sequencing
* Bisulfite sequencing
* RNAseq
* Gene Expression
* Exome sequencing
* Exome sequencing
* smallRNA
''The HiSeq2000 was donated to the BioMicro Center by Drs. Penny Chisholm and Chris Burge and HHMI ''


''The HiSeq2000s were donated to the BioMicro Center by Drs. Penny Chisholm and Chris Burge and HHMI ''
=== MiSeq ===
=== MiSeq ===
[[Image:BMC_miseq.png|right|200px]] The MiSeq is a newer sequencer in the BioMicro Center. Unlike the HiSeq, the MiSeq is optimized for speed. The MiSeq has a single lane that can produce up to 25 million reads passing filter (ideal cases). The MiSeq does *not* have a control lane so having good base balance is critical for runs on this sequencer. Amplicons, such as 16S, can be run on the sequencer but should be constructed to have [[BioMicroCenter:PhasedSequencing|phased sequencing]]. Highly unbalanced libraries, such as RRBS, should not be run on the MiSeq. <BR><BR>
[[Image:BMC_miseq.png|right|200px]] The MiSeq is optimized for speed. The MiSeq has a single lane that can produce up to 25 million reads passing filter (ideal cases, v3 chemistry). The MiSeq does *not* have a control lane so having good base balance is critical for runs on this sequencer. Amplicons, such as 16S, can be run on the sequencer but should be constructed to have complexity in the first several bases. Highly unbalanced libraries, such as RRBS, should not be run on the MiSeq. <BR><BR>
The strength of the MiSeq is its speed and read length. The MiSeq is able to sequence 14nt/hour which allows it to complete a 150+150nt paired end read, from cluster to fastq files, in a little less than a day. This compares to 2-3 weeks of sequencing on the HiSeq. Because the chemistry is on the flowcell for less time, error rates are much lower for the MiSeq then the HiSeq. MiSeq runs are available in 50, 150*, 300, 500 and 600*nt flavors. (*) - v3 kits can reach 25m reads. Other kits can only reach 15m<BR><BR>
The strength of the MiSeq is its speed and read length. The MiSeq is able to sequence 14nt/hour which allows it to complete a 150+150nt paired end read, from cluster to fastq files, in a little less than a day. Because the chemistry is on the flowcell for less time, error rates are much lower for the MiSeq then the HiSeq. MiSeq runs are available in 50, 150*, 300, 500 and 600*nt flavors. (*) - v3 kits can reach 25 M reads. Other kits can only reach 15 M.<BR><BR>
The 50 cycle kit can accommodate up to 60bp read length (single-end or 30+30 paired-end).  The 300 cycle kit can accommodate up to 350bp read length, while the 500 cycle kit can accommodate up to 520bp read length. New kits should push read length even longer, with the Broad Institute having reported 400+400PE runs. <BR><BR>
The 50 cycle kit can accommodate up to 70bp read length (single-end or 30+30 paired-end).  The 300 cycle kit can accommodate up to 350bp read length, while the 500 cycle kit can accommodate up to 520bp read length. Illumina read quality at longer lengths has declined in recent years and reads longer than 250PE have had mixed results. <BR><BR>
The MiSeq is ideal for:
The MiSeq is ideal for:
* Small genome resequencing
* Small genome resequencing
Line 31: Line 31:
* Metagenomics
* Metagenomics
* smRNA
* smRNA
* barcode sequencing
* de novo sequencing.
 


''The MiSeq was donated to the BioMicro Center by Dr. Chris Love. ''
''MiSeqs were donated to the Biomicro Center by Drs. Chris Love, Michael Birnbaum and the Dept. of Biological Engineering. ''


=== NextSeq ===
=== NextSeq500 ===
[[Image:BMC_Next500.png|right|200px]] The NextSeq is the newest sequencer in the BioMicro Center. The NextSeq can be thought of as a MiSeq on steroids. Optimized for speed and yield, the NextSeq has a single lane that can produce up to 500 million reads passing filter (ideal cases). This yeild does come at a slightly lower quality and while most Illumina machines operate well above their specifications, the NextSeq has less margin. The NextSeq also does *not* have a control lane so having good base balance is critical for runs on this sequencer. In addition, The NextSeq chemistry only uses 2 fluor (isntead of 4) which can complicate some experimental designs. Amplicons, such as 16S, have not yet been tested on the sequencer and may fail. Highly unbalanced libraries, such as RRBS, should not be run on the MiSeq. <BR><BR><BR>
[[Image:BMC_Next500.png|right|200px]] The NextSeq is the newest sequencer in the BioMicro Center. The NextSeq can be thought of as a MiSeq on steroids. Optimized for speed and yield, the NextSeq has a single lane that can produce up to 500 million reads passing filter (ideal cases). This yield does come at a slightly lower quality, and while most Illumina machines operate well above their specifications, the NextSeq has less margin. Like the Miseq, the NextSeq does *not* have a control lane, so having good base balance is critical for runs on this sequencer. In addition, NextSeq chemistry only uses 2 fluorophores instead of 4 which can complicate some experimental designs. Amplicons, such as 16S, have not yet been tested on the sequencer and may fail. Highly unbalanced libraries, such as RRBS, have not been run on the NextSeq. <BR><BR>
[[Image:BMC_2dye.jpg|left|200px]]The strength of the NextSeq is its speed and read length coupled with yield. The NextSeq is able to sequence ~10nt/hour which allows it to complete a 150+150nt paired end read, from cluster to fastq files, in two days. Because the chemistry is new, error rates are expected to be higher on the NextSeq than the MiSeq or the HiSeq. NextSeq runs are available in 50, 150, and 300, flavors. Currently, the BMC only stocks High Output flowcells. At this time, we discourage use of the NextSeq for 50nt reads - those are better suited to the HiSeq2000s - and we will prioritize other read lengths before 50nt runs. <BR><BR>
[[Image:BMC_2dye.jpg|left|200px]]The strength of the NextSeq is its speed and read length coupled with yield. The NextSeq is able to sequence ~10nt/hour which allows it to complete a 150+150nt paired end read, from cluster to fastq files, in two days. Kit sizes for Nextseq are 75, 150, and 300 nt. Currently, the BMC only stocks "High Output" flowcells. At this time, we discourage use of the NextSeq for short single end reads - those are better suited to the HiSeq2000s - and we will prioritize other read lengths before 50nt runs. <BR><BR><BR><BR><BR>
<br>
The NextSeq is ideal for:
The NextSeq is ideal for:
* Whole genome sequencing
* Whole genome sequencing
* Splicing analysis in RNAseq
* Splicing analysis in RNAseq
* Metagenomics
* Metagenomics
<br>
'''The Nextseq is NOT ideal for:'''
* low complexity libraries such as PCR amplicons


===Preliminary Data on NextSeq Runs (Dec 2014):===
<LI>75 kit has 91 cycles
 
<LI>150 kit has 166 cycles
[[Image:leigh1.png|left|400px]]
<LI>300 kit has 316 cycles
[[Image:leigh2.png|eight|400px]]


<LI>This is to allow for a 8+8 dual index. However if you want to put the extra reagents toward your sequencing read (such as 42+6+42 for 75 kit), you are welcome to do so.
<BR><BR>
<B>Data on NextSeq Runs (last updated March 2, 2016):</B><BR>
We closely monitor the quality of NextSeq runs. With the newly released v2 chemistry for Nextseq, we see a marked increase in quality (pictured). We aim to get the highest number of reads without sacrificing data quality. If you have a preference for high number of reads (slightly lower data quality) or high data quality (slightly lower number of reads), please let us know so that we can adjust your loading concentration accordingly.
[[Image:160302_nextseq_website.png|left|600px]]
<br><br>
<br><br>
<br><br>
<br><br>
<br><br>
<br><br>
<br><br>
<br><br>
<br><br>
'''Figure: Proportion of reads with zero mismatches at cycle 75, on camera 5, measured by aligning phix spike-in reads to phix genome.'''
<br><br>
''NextSeq500s were donated to the BioMicro Center by Drs. Penny Chisholm, Doug Lauffenburger, Myriam Heiman, Li-Huei Tsai and the Dept. of Biology and the Koch Institute. ''
<br> <br>
<br> <br>


So far we have done 11 runs on the NextSeq. We expect the data quality to increase over time as this is a new product from Illumina and they are still working out kinks in the software. These data show that an increase in loading concentration (correlates to density) and therefore an increase in the number of reads customers get from a run, we must sacrifice some data quality (represented as %Q30).
<!-- commenting GA out 2/2/17 NK === Genome Analyzer IIx ===
 
[[Image:GAIIxcollage.jpg|right|200px]] The Genome Analyzer II (GAII) is the oldest sequencers in the BioMicro Center and remain the most flexible. The newer generations of Illumina sequencers have been designed with increasing focus on clinical applications and have removed some of the "hands on" aspects of the older GAIIs. The GAIIs remain the only sequencers where the actual images of the flowcell can be reprocessed for example. The GAII/IIx can produce 20-40m reads per lane passing filter and typically runs read lengths of 36-150nt per side.<BR><BR>
 
''The NextSeq was donated to the BioMicro Center by Dr. Doug Lauffenburger, Dr. Penny Chisholm, the Dept of Biology and the Koch Institute. ''
 
=== Genome Analyzer IIx ===
[[Image:GAIIxcollage.jpg|right|200px]] The Genome Analyzer II (GAII) are the oldest sequencers in the BioMicro Center and remain the most flexible. The newer generations of Illumina sequencers have been designed with increasing focus on clinical applications and have removed some of the "hands on" aspects of the older GAIIs. The GAIIs remain the only sequencers where the actual images of the flowcell can be reprocessed for example. The GAII/IIx can produce 20-40m reads per lane passing filter and typically runs read lengths of 36-150nt per side.<BR><BR>
With the addition of the MiSeq, we have reworked how we are processing GAII flowcells. We have been able to create [[BioMicroCenter:PartialFlowcells|'''partial flowcells''']] on the GAII by altering recipes. This has allowed us to move from a model like the HiSeq where we need a full flowcell before we run to a model where we can run as soon as the samples pass quality control, more like the MiSeq. However, unlike the MiSeq, we can run multiple lanes at once. Some critical caveats: First, these methods are not supported by Illumina so we cannot offer to replace failed runs. Second, unlike the HiSeq, the PhiX lane is *not* included. You must choose to sequence a lane of PhiX if you want to do control normalization. Finally, this service is completely "a la carte" so the pricing schema is quite different. <BR><BR>
With the addition of the MiSeq, we have reworked how we are processing GAII flowcells. We have been able to create [[BioMicroCenter:PartialFlowcells|'''partial flowcells''']] on the GAII by altering recipes. This has allowed us to move from a model like the HiSeq where we need a full flowcell before we run to a model where we can run as soon as the samples pass quality control, more like the MiSeq. However, unlike the MiSeq, we can run multiple lanes at once. Some critical caveats: First, these methods are not supported by Illumina so we cannot offer to replace failed runs. Second, unlike the HiSeq, the PhiX lane is *not* included. You must choose to sequence a lane of PhiX if you want to do control normalization. Finally, this service is completely "a la carte" so the pricing schema is quite different. <BR><BR>
{| border=1 align="right"
{| border=1 align="right"
Line 89: Line 103:
* Protocol Prototyping
* Protocol Prototyping
* Non-standard assays such as HITS-FLIP
* Non-standard assays such as HITS-FLIP
  This GAII pricing model is an experimental model and is subject to change


''The Genome Analyzer IIs were donated to the BioMicro Center by Drs. Penny Chisholm, Chris Burge, Ernest Fraenkel and the Dept of Biology with contributions from many others ''
''The Genome Analyzer IIs were donated to the BioMicro Center by Drs. Penny Chisholm, Chris Burge, Ernest Fraenkel and the Dept of Biology with contributions from many others ''
 
!width=200| GAII/IIx:  Boris, Natasha, etc 20-40m reads 1 to 8 lanes 24-72 nt/day max read length 80+80 in lane by lane
=== Platform Comparison ===
THE GA IS DEAD LONG LIVE THE GA Jack Daniels is DEAD LONG LIVE JACK DANIELS-->
== Platform Comparison ==


{| border=1  
{| border=1  
  !width=200| SPEC
  !width=200| SPEC
  !width=200| HiSeq2000
  !width=200| HiSeq2000
!width=200| GAII/IIx
  !width=200| MiSeq
  !width=200| MiSeq
  !width=200| NextSeq
  !width=200| NextSeq
  |- align="center"
  |- align="center"
  | '''Machine Names'''
  | '''Machine Names'''
  | SamAdams<BR>JackDaniels
  | SamAdams
  | Ryland<BR>Boris<BR>Preston
  | MiAmore<BR>Tobias<BR>Whitehead
  | MiAmore
  | Lucille<BR>George
| (TBD)
  |- align="center"
  |- align="center"
  | '''# reads / lane'''
  | '''# reads / lane'''
  | 160-220m
  | 150-220m
  | 20-40m
  | 8m-25m
| 12m-25m
  | 200m-500m
  | 300m-500m
  |- align="center"
  |- align="center"
  | ''' # lanes coprocessed '''
  | ''' # lanes coprocessed '''
  | 7+PhiX
  | 7+PhiX
| 1 to 8
  | 1
  | 1
  | 1
  | 1
Line 124: Line 132:
  | ''' nt / day '''
  | ''' nt / day '''
  | 18
  | 18
| 24-72
  | 288
  | 288
  | 150
  | 150
  |- align="center"
  |- align="center"
  | ''' Max Read Length '''
  | ''' Max Read Length '''
  | 100+100
  | 100+100*
  | 80+80 in lane by lane
  | 300+300
| 325+300
  | 150+150
  | 150+150
|}
|}
*Paired End runs are rare and shorter ends are more common, typical runs are 50 Single End
== Additional Information ==
=== Submission guidelines ===
Submission guidelines can be found [[BioMicroCenter:FAQ#HOW_LONG_WILL_IT_TAKE_FOR_MY_HISEQ_SAMPLE_TO_BE_SEQUENCED| on our FAQ.]]


== Additional Information ==
=== Pricing and Priority ===
=== Pricing and Priority ===


Full pricing information is available on [[BioMicroCenter:Pricing|our price list]].<br>
Full pricing information is available on [[BioMicroCenter:Pricing|our price list]].<br>


Priority for Illumina sequencing is given to labs associated with the BioMicro Center [[BioMicroCenter:CoreDeps|Core departments]] on a first-come first-served basis. Users requiring expedited services should contact [[BioMicroCenter:People|Stuart Levine]]. We are able offer our services to other MIT and [[BioMicroCenter:FAQ#NON_MIT_USERS|non-MIT]] users as space allows. A full description of priority and queue time expectations can be found [[BioMicroCenter:FAQ#HOW_LONG_WILL_IT_TAKE_FOR_MY_HISEQ_SAMPLE_TO_BE_SEQUENCED| on our FAQ.]]
Priority for Illumina sequencing is given to labs associated with the BioMicro Center [[BioMicroCenter:CoreDeps|Core departments]] on a first-come first-served basis. We are able offer our services to other MIT and [[BioMicroCenter:FAQ#NON_MIT_USERS|non-MIT]] users as space allows. A full description of priority and queue time expectations can be found [[BioMicroCenter:FAQ#HOW_LONG_WILL_IT_TAKE_FOR_MY_HISEQ_SAMPLE_TO_BE_SEQUENCED| on our FAQ.]]


=== Library Preparation ===
=== Library Preparation ===
Line 190: Line 201:




Custom oligonucleotides should submitted at 100 µM with at least 20 µL provided. At time of submission, please take the time to diagram your primer design for the sequencing technician who can verify its compatibility and help to avoid any unforseen issues.
Custom oligonucleotides should submitted at 100 µM with at least 20 µL provided per each lane of sequencing. At the time of submission, please take the time to diagram your primer design for the sequencing technician who can verify its compatibility and help to avoid any issues.


=== Data Analysis ===
=== Data Analysis ===
Line 205: Line 216:


== MIT Core Collaboration ==
== MIT Core Collaboration ==
Because of the layout of Illumina flowcells, samples must be run in batches of 7 lanes (a pool of multiplexed samples counts as one lane). In order to ensure quick throughput, we have established a collaboration that allows us to move partial flowcells between the various centers at MIT. For users with less then 4 samples, their samples may be moved between the BioMicro Center and the [http://jura.wi.mit.edu/genomecorewiki/index.php/Main_Page Whitehead Institute Center for Genome Technologies]. Samples will be moved only to fill out runs or to expedite processing. The Centers are committed to working together to maintain consistent quality between the different cores, so you should see no difference whether your samples are run in BioMicro or at one of our sister centers. Transfers are only available for members of the MIT community.  
Because of the layout of Illumina HiSeq 2000 flowcells, samples must be run in batches of 7 lanes (a pool of multiplexed samples counts as one lane). In order to ensure quick throughput, we have established a collaboration that allows us to move partial flowcells between the various centers at MIT. For users with less then 4 samples, their samples may be moved between the BioMicro Center and the [http://jura.wi.mit.edu/genomecorewiki/index.php/Main_Page Whitehead Institute Center for Genome Technologies]. Samples will be moved only to fill out runs or to expedite processing. The Centers are committed to working together to maintain consistent quality between the different cores, so you should see no difference whether your samples are run in BioMicro or at one of our sister centers. Transfers are only available for members of the MIT community.  
<BR>
<BR>


Revision as of 08:53, 21 April 2017

HOME -- SEQUENCING -- LIBRARY PREP -- HIGH-THROUGHPUT -- COMPUTING -- OTHER TECHNOLOGY

The MIT BioMicro Center has five high-throughput Illumina sequencers including one HiSeq 2000, two NextSeq 500s and two MiSeqs. We support a wide variety of applications, such as ChIP-Seq, miRNA sequencing and RNA-seq. Each lane can potentially accommodate dozens of barcoded samples (depending on sequence complexity and desired coverage). Read lengths vary, depending on users, between 20nt and 325nt per end.

Questions about Illumina Sequencing can be directed to Noelani Kamelamela

Illumina Massively Parallel Sequencing

Illumina sequencing works by binding randomly fragmented and adapted DNA to an optical flowcell. Fragments are sequenced by sequentially incorporating and imaging fluorescently labeled nucleotides in a “Sequencing-By-Synthesis” reaction. The BioMicro Center uses Illumina's TruSeq v3 reagent kits for HiSeq, v2 chemistry for NextSeq and v2 or v3 chemistry for MiSeq. For an in-depth overview of the Illumina sequencing chemistry, please refer to Kirchner et al 2009.

Platforms

HiSeq 2000

The Illumina HiSeq 2000 is the workhorse of BMC's Illumina fleet and is optimized for maximum yield and the lowest price per basepair. Each lane on the HiSeq typically produces between 150 and 220 million reads passing our quality filter (for high quality libraries). HiSeq flowcells have 8 lanes, one of which is committed to a control sample that is used for base normalization (Lane 1). Read lengths on the HiSeq are set around 40 and nearly all flowcells use barcoding to run multiple samples in each lane.

In order to optimize work flow and keep costs under control, only full flowcells are run. Since all 8 lanes of the flowcell must be run at equal lengths, submissions of single lanes must be grouped with other similar read lengths. This means that some read lengths move through our queue faster then others because more samples of that length are submitted to the BioMicro Center for sequencing. 40nt single end (SE) samples are by far the most common and move through the queue rapidly. Many lengths are very unusual (eg. 100nt single end) and should instead be submitted for the NextSeq unless you have a full flowcell. If you have questions about this (or any other aspect of sequencing) please do not hesitate to contact us.

The HiSeq2000 is ideal for:

  • SNP detection
  • ChIPseq
  • Bisulfite sequencing
  • Gene Expression
  • Exome sequencing
  • smallRNA

The HiSeq2000 was donated to the BioMicro Center by Drs. Penny Chisholm and Chris Burge and HHMI

MiSeq

The MiSeq is optimized for speed. The MiSeq has a single lane that can produce up to 25 million reads passing filter (ideal cases, v3 chemistry). The MiSeq does *not* have a control lane so having good base balance is critical for runs on this sequencer. Amplicons, such as 16S, can be run on the sequencer but should be constructed to have complexity in the first several bases. Highly unbalanced libraries, such as RRBS, should not be run on the MiSeq.

The strength of the MiSeq is its speed and read length. The MiSeq is able to sequence 14nt/hour which allows it to complete a 150+150nt paired end read, from cluster to fastq files, in a little less than a day. Because the chemistry is on the flowcell for less time, error rates are much lower for the MiSeq then the HiSeq. MiSeq runs are available in 50, 150*, 300, 500 and 600*nt flavors. (*) - v3 kits can reach 25 M reads. Other kits can only reach 15 M.

The 50 cycle kit can accommodate up to 70bp read length (single-end or 30+30 paired-end). The 300 cycle kit can accommodate up to 350bp read length, while the 500 cycle kit can accommodate up to 520bp read length. Illumina read quality at longer lengths has declined in recent years and reads longer than 250PE have had mixed results.

The MiSeq is ideal for:

  • Small genome resequencing
  • Targeted resequencing
  • Metagenomics
  • smRNA
  • de novo sequencing.

MiSeqs were donated to the Biomicro Center by Drs. Chris Love, Michael Birnbaum and the Dept. of Biological Engineering.

NextSeq500

The NextSeq is the newest sequencer in the BioMicro Center. The NextSeq can be thought of as a MiSeq on steroids. Optimized for speed and yield, the NextSeq has a single lane that can produce up to 500 million reads passing filter (ideal cases). This yield does come at a slightly lower quality, and while most Illumina machines operate well above their specifications, the NextSeq has less margin. Like the Miseq, the NextSeq does *not* have a control lane, so having good base balance is critical for runs on this sequencer. In addition, NextSeq chemistry only uses 2 fluorophores instead of 4 which can complicate some experimental designs. Amplicons, such as 16S, have not yet been tested on the sequencer and may fail. Highly unbalanced libraries, such as RRBS, have not been run on the NextSeq.

The strength of the NextSeq is its speed and read length coupled with yield. The NextSeq is able to sequence ~10nt/hour which allows it to complete a 150+150nt paired end read, from cluster to fastq files, in two days. Kit sizes for Nextseq are 75, 150, and 300 nt. Currently, the BMC only stocks "High Output" flowcells. At this time, we discourage use of the NextSeq for short single end reads - those are better suited to the HiSeq2000s - and we will prioritize other read lengths before 50nt runs.





The NextSeq is ideal for:

  • Whole genome sequencing
  • Splicing analysis in RNAseq
  • Metagenomics


The Nextseq is NOT ideal for:

  • low complexity libraries such as PCR amplicons
  • 75 kit has 91 cycles
  • 150 kit has 166 cycles
  • 300 kit has 316 cycles
  • This is to allow for a 8+8 dual index. However if you want to put the extra reagents toward your sequencing read (such as 42+6+42 for 75 kit), you are welcome to do so.

    Data on NextSeq Runs (last updated March 2, 2016):
    We closely monitor the quality of NextSeq runs. With the newly released v2 chemistry for Nextseq, we see a marked increase in quality (pictured). We aim to get the highest number of reads without sacrificing data quality. If you have a preference for high number of reads (slightly lower data quality) or high data quality (slightly lower number of reads), please let us know so that we can adjust your loading concentration accordingly.



















    Figure: Proportion of reads with zero mismatches at cycle 75, on camera 5, measured by aligning phix spike-in reads to phix genome.

    NextSeq500s were donated to the BioMicro Center by Drs. Penny Chisholm, Doug Lauffenburger, Myriam Heiman, Li-Huei Tsai and the Dept. of Biology and the Koch Institute.

    Platform Comparison

    SPEC HiSeq2000 MiSeq NextSeq
    Machine Names SamAdams MiAmore
    Tobias
    Whitehead     		Lucille
    George
    # reads / lane 150-220m 8m-25m 200m-500m
    # lanes coprocessed 7+PhiX 1 1
    nt / day 18 288 150
    Max Read Length 100+100* 300+300 150+150
    • Paired End runs are rare and shorter ends are more common, typical runs are 50 Single End

    Additional Information

    Submission guidelines

    Submission guidelines can be found on our FAQ.

    Pricing and Priority

    Full pricing information is available on our price list.

    Priority for Illumina sequencing is given to labs associated with the BioMicro Center Core departments on a first-come first-served basis. We are able offer our services to other MIT and non-MIT users as space allows. A full description of priority and queue time expectations can be found on our FAQ.

    Library Preparation

    Right Illumina sequencing requires the input of libraries with inserts between 10 and 1000bp in length and have specific adapters attached to the 5' and 3' ends. The BioMicro Center accepts custom samples of all types provided the user also submits sequencing primers (though we do not assume responsibility if the samples fail). Samples submitted for Illumina sequencing should be at ~10ng/ul and the user should provide at least 10λ of samples. This is an ideal situation but we do have protocols available to help users with much less concentrated samples. Please submit your sample along with a completed Illumina sequencing form.

    In addition to accepting finished libraries, the Biomicro Center supports a number of different sample preparation methodologies for different applications including RNAseq, ChIPseq and genome sequencing. All samples prepped in the BioMicro Center are barcoded for multiplexing.

    Quality Control

    screenshot from the fastqc package (http://www.bioinformatics.babraham.ac.uk/projects/fastqc/)

    The BioMicro Center undertakes a number of quality assurance methods to ensure that we produce high quality data for you. All samples submitted for Illumina sequencing are checked for size distribution, presence of proper 5' and 3' adapters, and actual concentration using the Agilent Bioanalyzer and qPCR. For more information on library quality can be found on the Sequencing Quality Control page.

    We will skip pre-sequencing QC if the user supplies us with concentration and average fragment length information for each sample submitted. However, different labs often vary substantially in their quantifications and our methods are optimized for our own instruments and operators. We cannot guarantee optimal data output and quality for samples which are quantified outside of the BioMicro Center.

    Additional quality metrics are done during all sequencing runs as part of the standard Illumina process. All samples are spiked with ~0.5% of the bacteriophage ΦX174. The ΦX library is primed off the standard Illumina sequencing primers and is used to both ensure the quality of the reagents used in the run and to measure the background sequencing error rates. ΦX reads will not be detected on non-standard libraries using custom priming.

    Finally, several additional quality metrics are included in the automated analysis pipeline currently under active development in the Center. These include standard metrics of base composition, GC%, library complexity and overrepresented reads that are in the TagCount and Fastqc files. In addition, we now evaluate libraries for contamination from common laboratory species (human, mouse, yeast and E.coli). More information can be found on the Flowcell data guide page.

    Pooling considerations

    When determining how many samples should be combined together in a single lane, the following equations are useful:

    • # of lanes = (genomesize x coverage x #samples) / (#readsperlane x readlength x ends)
    • #samplesperlane = (#readsperlane x readlength x ends) / (genomesize x coverage)

    where,

    • # of lanes is the total number of lanes that are required to achieve the specified coverage given the other variables
    • #samplesperlane is the total number of samples that can be combined into a single lane to achieve the specified coverage given the other variables
    • genomesize is the size, in nt, of the library to be sequenced
    • coverage is the desired multiplicity of coverage for the library
    • #samples is the number of samples needing to be sequenced
    • #readsperlane is the number of reads produced by a lane on the sequencer. (See "Platform Comparison" table above for the typical outputs from each platform.)
    • readlength is the length, in nt, of each separate read of the run
    • ends is the number of insert reads for the run. For single-end, it is 1, and for paired-end, it is 2.

    Custom Primers

    Many non-standard Illumina protocols require custom sequencing primers. The design of these oligos is critical for the success of the experiment and we have observed several experimental failures due to improper oligo design. There are a few critical parameters in oligo design.

    • First, the oligo must only occur once in each sequence. Multiple binding will result in low quality reads.
    • On reverse or index reads, we cannot separate the oligos by lane and so the construct must be compatible with having a cocktail of standard Illumina oligonucleotides in the mix.
    • The Tm of the oligo must match the Tm of the sequencing primer they are designed to replace. Being even a couple degrees below the Tm can result in experimental failure. Any online Tm calculator can be used. The standard Illumina sequences are:
      Forward read: 5'ACACTCTTTCCCTACACGACGCTCTTCCGATCT
      Reverse read: 5'CGGTCTCGGCATTCCTGCTGAACCGCTCTTCCGATCT
      Multiplexing Index Read: 5'GATCGGAAGAGCACACGTCTGAACTCCAGTCAC


    Custom oligonucleotides should submitted at 100 µM with at least 20 µL provided per each lane of sequencing. At the time of submission, please take the time to diagram your primer design for the sequencing technician who can verify its compatibility and help to avoid any issues.

    Data Analysis

    Illumina sequencing at the BioMicro Center includes basic informatic analysis of the data. These steps include:

    • Image analysis to locate clusters
    • Basecalling
    • Demultiplexing of lanes
    • Alignment of sequences to a reference genome
    • Quality control
    • Delivery of the data to a user accessible folder

    All of these steps are run by our automated analysis pipelinecurrently in active development. For users requiring further analysis, we have a staff of |bioinformaticists that can assist you in analyzing your data.

    MIT Core Collaboration

    Because of the layout of Illumina HiSeq 2000 flowcells, samples must be run in batches of 7 lanes (a pool of multiplexed samples counts as one lane). In order to ensure quick throughput, we have established a collaboration that allows us to move partial flowcells between the various centers at MIT. For users with less then 4 samples, their samples may be moved between the BioMicro Center and the Whitehead Institute Center for Genome Technologies. Samples will be moved only to fill out runs or to expedite processing. The Centers are committed to working together to maintain consistent quality between the different cores, so you should see no difference whether your samples are run in BioMicro or at one of our sister centers. Transfers are only available for members of the MIT community.


    OLDE LINKS

    • Retrieved from "https://openwetware.org/mediawiki/index.php?title=BioMicroCenter:Illumina_Sequencing&oldid=985784"