Genome Assemblies and Bac vector library: Difference between pages

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=Echinoderm Genome Assemblies by Species=
<p>On this page you will find information regarding the BAC vector for library preparation, protocols for screening BAC libraries, BAC minipreps and BAC recombineering. </p>


__TOC__


== BAC Vector for Macro-Array Genomic Libraries ==


== '''''Strongylocentrotus purpuratus''''' ==
Frengen E., Weichenhan D., Zhao B., Osoegawa K., van Geel M., de Jong P. J. 1999. A modular, positive selection bacterial artificial chromosome vector with multiple cloning sites. Genomics. 58(3):250-3. [https://www.ncbi.nlm.nih.gov/pubmed/?term=10373322%5BUID%5D&utm_source=gquery&utm_medium=search PUBMED 10373322]
<br>
<p><u>Abstract</u></p>
<p>To construct large-insert libraries for the sequencing, mapping, and functional studies of complex genomes, we have constructed a new modular bacterial artificial chromosome (BAC) vector, pBACe3.6 (GenBank Accession No. U80929). This vector contains multiple cloning sites located within the sacB gene, allowing positive selection for recombinant clones on sucrose-containing medium. A recognition site for the PI-SceI nuclease has also been included, which permits linearization of recombinant DNA irrespective of the characteristics of the insert sequences. An attTn7 sequence present in pBACe3.6 permits retrofitting of BAC clones by Tn7-mediated insertion of desirable sequence elements into the vector portion. The ability to retrofit BAC clones will be useful for functional analysis of genes carried on the cloned inserts. The pBACe3.6 vector has been used for the construction of many genomic libraries currently serving as resources for large-scale mapping and sequencing.</p>


=== '''Assembly_3.1 (Spur_3.1)'''===
<p>NB: pBACe3.6 clones have chloramphenicol antibiotic resistance. Clones should be grown in LB containing 12.5 ug chloramphenicol/ml. Further information on this vector is available from ''CHORI, Children's Hospital Oakland Research Center''</p>
=== '''Assembly 2.6(Spur 2.6)'''===
=== '''Assembly_2.5(Spur_2.5)'''===
=== '''Assembly_2.1(Spur_2.1)'''===
=== '''Assembly_0.5(Spur_0.5)'''===


== '''''Patiria miniata''''' ==
== BAC Library Screening ==


=== '''V2.0 Assembly'''===
<p><u>Materials:</u></p>
<p>Hybridization solution:</p>
<p style="margin-left:10%; margin-right:10%;">• 5x SSPE</p>
<p style="margin-left:10%; margin-right:10%;">• 0.1% NaPPi</p>
<p style="margin-left:10%; margin-right:10%;">• 5% (w/v) SDS</p>
<p>Stripping buffer:</p>
<p style="margin-left:10%; margin-right:10%;">• 0.1x SSC</p>
<p style="margin-left:10%; margin-right:10%;">• 0.1% SDS (w/v)</p>
<p style="margin-left:10%; margin-right:10%;">• 0.2 M Tris-HCl, pH 7.5</p>
<p>DNA Probes:</p>
<p style="margin-left:10%; margin-right:10%;">• See [https://www.agilent.com/cs/library/usermanuals/Public/300385.pdf Agilent Prime-II Random Primer Labeling Kit]</p>
<p style="margin-left:10%; margin-right:10%;">• Sephadex G50</p>
<br>
<p><u>Procedure:</u></p>
<p>'''''Making the probe''''':</p>
<p style="margin-left:10%; margin-right:10%;">1.  25ng DNA template - ensure has no vector seq (included T3 etc site as this will cross react with the BAC backbone seq) </p>
<p style="margin-left:10%; margin-right:10%;">2.  Add appropriate ul of H20 to bring 25 ng DNA to 23 ul total</p>
<p style="margin-left:10%; margin-right:10%;">3.  Add 10 ul of random primers (total is now 35 ul)</p>
<p style="margin-left:10%; margin-right:10%;">4.  Heat denature - boil 5 min</p>
<p style="margin-left:10%; margin-right:10%;">5.  Remove to room temperature</p>
<p style="margin-left:10%; margin-right:10%;">6.  Add 5 ul of 5X of dATP buffer</p>
<p style="margin-left:10%; margin-right:10%;">7.  Add alpha <sup>32</sup>P dATP at 3000 Ci/mmol.</p>
<p style="margin-left:10%; margin-right:10%;">8.  Add 1ul Klenow</p>
<p style="margin-left:10%; margin-right:10%;">9.  Incubate at 37<sup>°</sup>C  for 10 min</p>
<p style="margin-left:10%; margin-right:10%;">10. Add 2 ul of stop mix</p>
<p style="margin-left:10%; margin-right:10%;">11. Take 1 ul probe mix and add to 99 ul 0.2 M EDTA mix</p>
<p style="margin-left:10%; margin-right:10%;">12. Run through Sephadex G50</p>
<p style="margin-left:10%; margin-right:10%;">13. Take 1 ul post spin and add to 99 ul 0.2 M EDTA mix</p>
<p style="margin-left:10%; margin-right:10%;">14. Spot 1 ul of pre and post spin onto Whatman filters</p>
<p style="margin-left:10%; margin-right:10%;">15. Use scintillation counter to measure specific activity</p>
<br>
<p>'''''Screening Filters''''':</p>
<p>'''[CRITICAL]''' If using a filter for the first time, follow the stripping protocol before hybridization (see below)</p>
<p>1. Place the membrane(s) in glass bottles that fit in the Hybaid hybridization oven, using '''nitex sheets to separate the filters'''. A complete set of library filters will fit in one bottle for both hybridization and washing. </p>
<p>2. Prehybridize in a shaking water bath at 65°C (55°C for cross species probes) for 1 hr.</p>
<p>3. Remove HS to minimum amount - so that it just covers the filters Xul probe to the prehybridization solution.</p>
<p>4. Incubate for at least 12 hr at 65°C (55°C for cross species probes).</p><br>
<p>5. Following hybridization, wash the filters by incubating them in 2x SSPE, 0.1% (w/v) SDS at room temperature for 10 min. '''Repeat'''.</p>
<p>6. Replace the solution with 2x SSPE, 0.1% (w/v) SDS. Incubate at 65°C (55°C for cross species probes) for 15 min. '''Repeat'''.</p>
<p>7. Replace the solution with 1x SSPE, 0.1% (w/v) SDS. Incubate at 65°C (55°C for cross species probes) for 10 min. '''Repeat'''. </p>
<p>8. Replace the solution with 0.1x SSPE, 0.1% (w/v) SDS. Incubate at 65°C (55°C for cross species probes) for 10 min. '''Repeat'''. (Use this for high stringency).</p>
<br>
<p>9. Remove filter, wrap in plastic wrap and carry out autoradiography. </p>
<p>10. Plastic wrap should be employed without trapped air for best exposures. From the final wash, pick up the filter by one corner and allow it to drip dry for 10 seconds. Place the filter face up on a piece of plastic wrap still attached to the roll. Fold the attached edge off the filter, then roll the top layer of wrap onto the filter. This expels any trapped air Most importantly, do not allow the filter to dry until it is stripped.</p>
<br>
<p>'''''Stripping filters''''':</p>
<p>Bring 0.5% SDS to a boil.</p>
<p>Pour on the membrane and allow to cool to room temperature.</p>
<p>(If necessary, repeat)</p>
<br>
<p>'''''Storing filters''''':</p>
<p>'''Short-term storage''' (1 or 2 weeks)</p>
<p style="margin-left:10%; margin-right:10%;">a. Wet two sheets of Whatmann paper in EDTA-containing stripping buffer.</p>
<p style="margin-left:10%; margin-right:10%;">b. Place the membrane between the two wet papers.</p>
<p style="margin-left:10%; margin-right:10%;">c. Wrap the papers and the membrane with plastic wrap and keep them in refrigerator until reuse.</p>
<p>'''Long-term storage'''</p>
<p style="margin-left:10%; margin-right:10%;">a. Sandwich between two sheets of plastic wrap.</p>
<p style="margin-left:10%; margin-right:10%;">b. Expose the membrane to X-ray film for at least 12 hr to check whether stripping is done completely. If stripping is done completely, place the membrane between two sheets of dry Whatmann paper and dry it at room temperature for at least 24 hr (until completely dry).</p>
<p style="margin-left:10%; margin-right:10%;">c. If stripping is not complete, repeat steps 1&2 but execute step 2 at the higher temperature.</p>
<br>
<p>'''''Determining microwell plate coordinates from arrayed filters''''':</p>
<p>The high-density filter array is a square arrangement of 48X48 blocks which can be thought of as six sub-fields of 16X24 blocks. Thus each sub-field is equivalent to the wells of a 384-well plate. Each block is a 4X4 array of eight clones spotted in duplicate. That is, the inoculum from each well of each plate has been spotted twice onto the filter in the same 4X4 block. The arrangement has been designed so that the two spots define a unique angle different from all the others within the 4X4 block. The unique angular relationship of the spot pair defines the plate from which that clone was taken. In the accompanying figure, a 4X4 block adjacent to each sub-field indicates the plate number assignments for the blocks in that sub-field. The position of a 4X4 block containing a positive spot pair can be described by the X-Y coordinates of the block in the sub-field (X coordinates are A through P, from bottom to top; Y coordinates are 1 through 24, from right to left). For filters beyond the first one (A) in the set, the plate numbers are increased in increments of 48, thus the plate number for the B filter is the decoded number plus 48; for the C filter, plus 96; etc.</p>
<p>'''EXAMPLE:''' On the accompanying figure there is a positive spot pair circled in white. It lies in the left-middle sub-field at X-Y position I-10. That is I blocks (9) up from the bottom of the sub-field and 10 blocks over from the centerline. Thus the well position with in the plate is I-10. For this sub-field, the angle of the spot pair within the block indicates #31. There fore, the clone is located on plate #31 in well I-10.</p>
<p>'''NOTES:''' Identification of spot coordinates in the case where the background on the filter is very low is aided by pre-marking the filters when they are dry and the colony residue is visible. Dry filters are marked by indentations from a ball point pen. The pen tip is pressed into a filter that is placed on a piece of 3MM paper on a hard surface while observing the operation in oblique lighting. Dots can thus be made at the boundaries of the 6 sub-fields and at the extreme corners of the array.</p>
To aid orientation in the newer filter sets, the A1 well for each plate has been left empty. Thus there are six empty squares that have no bacteria on the filter. After hybridization these squares have lower background and will orient the filter. The squares are 3 sets of 2 across when the label is on the upper right hand edge.</p>


We sought to improve the Patiria miniata genome assembly with additional PacBio sequences. We generated a new PacBio read dataset at the Duke University Sequencing Center using our reference individual DNA. The read dataset contains 2 million reads and 15.8 billion bp. The read N50 is 10.4 Kb. We used PBJelly2 to combine the PacBio reads with the previously assembled contigs. The results were an improvement in contig size and number with only a small reduction in the number of scaffolds (Table). The P. miniata Gene v2.0 set was generated using MAKER2 pipeline from v2.0 genome assembly.
== BAC Miniprep Protocol ==


<p>This protocol uses alkaline lysis and precipitation to isolate BAC DNA to analyze by Pulsed-field Gel Electrophoresis, PFGE, or PCR. BACs purified using this protocol '''cannot''' be injected into fertilized eggs.</p>
<br>
<p><u>Materials:</u></p>
<p>Buffer P1: Stored at 4<sup>o</sup>C. '''Add the RNAseA just prior to use.'''</p>
<p style="margin-left:10%; margin-right:10%;">• 15 mM Tris, pH 8.0</p>
<p style="margin-left:10%; margin-right:10%;">• 10 mM EDTA, pH 8.0</p>
<p style="margin-left:10%; margin-right:10%;">• 100 μg/ml RNase A</p>
<p>Buffer P2: '''Make fresh each use.'''</p>
<p style="margin-left:10%; margin-right:10%;">• 0.2N NaOH</p>
<p style="margin-left:10%; margin-right:10%;">• 1% SDS</p>
<p>Buffer P3: '''Cool on ice prior to use.'''</p>
<p style="margin-left:10%; margin-right:10%;">• 3M KAc pH 5.5</p>
<br>
<p><u>Procedure:</u></p>
<p>1. Inoculate a single bacterial colony into 3 ml LB containing 12.5μg/ml chloramphenicol in a 14 ml culture tube. Grow overnight (< 16 hrs), shaking at 250-300 rpm.</p>
<p style="margin-left:10%; margin-right:10%;">'''Optional''': make bacterial glycerol stock (15%) of BAC.</p>
<p>2. Pellet the bacteria by transferring 1.5 ml of each culture to a 1.7 ml microcentrifuge tube and centrifuge at 6800 g  for 3 min. Discard supernatant.</p>
<p>3. Repeat step 2.</p>
<br>
<p>4. Resuspend each pellet in 250 μl '''P1''' carefully. Be sure to fully resuspend until suspension is creamy with no clumps.</p>
<p>5. Add 250 μl '''P2''' and invert tubes 5 times to mix. The appearance of the suspension should change from very turbid to almost translucent.</p>
<p>6. Add 350 μl cold '''P3''' slowly to each tube and shake gently during addition. A thick white precipitate consisting of E. coli DNA and protein will form. Invert the tube several times to mix the solution thoroughly.</p>
<p>7. Place the tubes on ice for 5 min.</p>
<br>
<p>8. Centrifuge at 18,000 x g for 10 min at room temperature to pellet the white precipitate.</p>
<p>9. Transfer the clear supernatant (~700-800 μl) to a 1.7 ml microcentrifuge tube.</p>
<p>10. Spin again in a microcentrifuge for 5 min at RT to remove the rest of the debris. Transfer the clear supernatant to a fresh tube.</p>
<p>11. Add 0.8 ml '''ice-cold isopropanol'''. Mix well by inverting tubes ~10 times. Place the tube on ice for 30 min, or leave overnight at  4°C.</p>
<br>
<p>12.  Centrifuge at 18,000 x g for 30 min at 4<sup>o</sup>C to pellet BAC DNA.</p>
<p>13. Remove supernatant and add 1ml of '''ice-cold 70% EtOH'''. Invert tubes several times to wash the DNA pellets. Centrifuge at 18,000 x g for 15 min at 4<sup>o</sup>C.</p>
<p>14. Repeat step 13.</p>
<br>
<p>15. Centrifuge at 18,000 x g for 2 min at 4<sup>o</sup>C to remove residual EtOH. Carefully remove all supernatant, taking care not to dislodge the pellet.</p>
<p>16. Briefly air-dry pellet at room temperature.</p>
<p>17. Resuspend pellet in 20-30 μl TE (10 mM Tris; 1 mM EDTA). Gently flick the bottom of the tubes to resuspend DNA. '''Do not vortex or pipet up and down'''.</p>
<br>
<p>For storing use high EDTA TE - i.e. 10mM Tris 10mM EDTA.</p>
<p>To analyze the BACs, use 6 μL of this prep in a ''Not''I digest to run on a PFGE.</p>
<p>For PCR dilute 1 μl of this prep in 24 μl TE.</p>


== BAC Recombineering ==


{| class="wikitable"
<p>More information is available here: [https://pubmed.ncbi.nlm.nih.gov/30948008/?from_term=buckley+k&from_page=2&from_pos=3 Techniques for analyzing gene expression using BAC-based reporter constructs. Buckley KM, Ettensohn CA. Methods Cell Biol. 2019;151:197-218. doi: 10.1016/bs.mcb.2019.01.004. Epub 2019 Feb 23. PMID: 30948008 Review.]</p>
!
<br>
! Pm v1.0
<p><u>Materials</u>:</p>
! Pm v2.0
<p>''Reagents'':</p>
|-
<p>LB with kanamycin (25 μg/mL)</p>
| Scaffold number
<p>LB with chloramphenicol (12.5 μg/mL)</p>
| 60,183
<p>SOC media</p>
| 57,698
<p>10% L-(+)-arabinose</p>
|-
<p>Gel extraction kit</p>
| Scaffold N50
<p>High fidelity DNA polymerase</p>
| 52,6141
<p>DpnI</p>
| 76,341
<p>3 M NaOAc (pH 5.2)</p>
|-
<p>''Cell lines'':</p>
| Contig number
<p>1. Electrocompetent DH10B</p>
| 179,756
<p>2. EL250. A DH10B-derived strain that contains a λ prophage with the recombination genes ''exo'', ''bet'', and ''gam''. These genes are repressed by the temperature-sensitive repressor cI857.</p>
| 131,779
|-
| Contig N50
| 9,466
| 18,676
|}
 
=== '''V1.0 Assembly'''===
<u>What's New</u>
 
Pmin_1.0 is the latest (as of Apr 11, 2012) assembly of the genome of Patiria Miniata. The assembly tools CABOG (Celera Assembler), Newbler, ATLAS-Link, and ATLAS-GapFill were used to assemble a combination of 454 reads (fragment and 2.5kb insert paired ends;~15x coverage) and Illumina reads (300bp insert and 2.5kb insert paired ends;~70x coverage).
 
<u>Introduction</u>
 
This information is for the first release (Pmin_1.0) of the draft genome sequence of the Patiria miniata . This is a draft sequence and may contain errors so users should exercise caution.Typical errors in draft genome sequences include misassemblies of repeated sequences, collapses of repeated regions, and unmerged overlaps(e.g. due to polymorphisms) creating artificial duplications.
 
With a goal of solving the polymorphism issues of the data while maintaining the sequence continuity, The Pmin_1.0 assembly was generated in the following steps:
 
1) 454 reads were assembled by CABOG using settings less strignent than the default (unitigger=bog utgErrorRate=0.03 ovlErrorRate=0.08 cnsErrorRate=0.08 cgwErrorRate=0.14 doExtendClearRanges=0)
 
2) Both contig and degenerate sequences from the previous step were chopped into fake reads with ~11x coverage (500bp long; 460bp overlap; 80bp minimal length) for ctgs and 8x coverage(450bp long; 400bp overlap; 80bp minimal length) for degs. The fake reads were then assembled by Newbler with the option of -large.
 
3) Both 454 and iIlumina pair end reads were mapped to the contigs from the previous step. We used BLAT to map the 454 data and bwa(aln+samse) to map the Illumina data, both with the default options. Based on the mapping locations of the paired ends, contigs were then ordered and oriented into scaffolds using ATLAS-Link.
 
4) ATLAS-GapFill was then used to assemble the reads locally in an attempt to fill the gaps among the contigs within the scaffolds.This final step produced 770.5Mb sequences with contig N50 size of 9.5kb and scaffold N50 size of 50.3kb.
 
<u>Conditions for use</u>
 
These data are made available before scientific publication with the following understanding:
 
- The data may be freely downloaded, used in analyses, and repackaged in databases.
 
- Users are free to use the data in scientific papers analyzing particular genes and regions if the providers of this data (Baylor College of Medicine Human Genome Sequencing Center) are properly acknowledged.
Please cite the BCM-HGSC web site or publications from BCM-HGSC referring to the genome sequence.
 
- The BCM-HGSC plans to publish the assembly and genomic annotation of the dataset, including large-scale identification of regions of evolutionary conservation and other features.
 
- This is in accordance with, and with the understandings in the Fort Lauderdale meeting discussing Community Resource Projects and the resulting NHGRI policy statement (http://www.genome.gov/page.cfm?pageID=10506537).
 
- Any redistribution of the data should carry this notice.
 
== '''''Lytechinus variegatus''''' ==
 
=== '''Assembly LvPtE5C'''===
=== '''Assembly LvMSCB'''===
=== '''Assembly 2.2 (Lvar_2.2)'''===
=== '''Assembly 0.4 (Lvar_0.4)'''===

Revision as of 15:22, 22 April 2020

On this page you will find information regarding the BAC vector for library preparation, protocols for screening BAC libraries, BAC minipreps and BAC recombineering.


BAC Vector for Macro-Array Genomic Libraries

Frengen E., Weichenhan D., Zhao B., Osoegawa K., van Geel M., de Jong P. J. 1999. A modular, positive selection bacterial artificial chromosome vector with multiple cloning sites. Genomics. 58(3):250-3. PUBMED 10373322

Abstract

To construct large-insert libraries for the sequencing, mapping, and functional studies of complex genomes, we have constructed a new modular bacterial artificial chromosome (BAC) vector, pBACe3.6 (GenBank Accession No. U80929). This vector contains multiple cloning sites located within the sacB gene, allowing positive selection for recombinant clones on sucrose-containing medium. A recognition site for the PI-SceI nuclease has also been included, which permits linearization of recombinant DNA irrespective of the characteristics of the insert sequences. An attTn7 sequence present in pBACe3.6 permits retrofitting of BAC clones by Tn7-mediated insertion of desirable sequence elements into the vector portion. The ability to retrofit BAC clones will be useful for functional analysis of genes carried on the cloned inserts. The pBACe3.6 vector has been used for the construction of many genomic libraries currently serving as resources for large-scale mapping and sequencing.

NB: pBACe3.6 clones have chloramphenicol antibiotic resistance. Clones should be grown in LB containing 12.5 ug chloramphenicol/ml. Further information on this vector is available from CHORI, Children's Hospital Oakland Research Center

BAC Library Screening

Materials:

Hybridization solution:

• 5x SSPE

• 0.1% NaPPi

• 5% (w/v) SDS

Stripping buffer:

• 0.1x SSC

• 0.1% SDS (w/v)

• 0.2 M Tris-HCl, pH 7.5

DNA Probes:

• See Agilent Prime-II Random Primer Labeling Kit

• Sephadex G50


Procedure:

Making the probe:

1. 25ng DNA template - ensure has no vector seq (included T3 etc site as this will cross react with the BAC backbone seq)

2. Add appropriate ul of H20 to bring 25 ng DNA to 23 ul total

3. Add 10 ul of random primers (total is now 35 ul)

4. Heat denature - boil 5 min

5. Remove to room temperature

6. Add 5 ul of 5X of dATP buffer

7. Add alpha 32P dATP at 3000 Ci/mmol.

8. Add 1ul Klenow

9. Incubate at 37°C for 10 min

10. Add 2 ul of stop mix

11. Take 1 ul probe mix and add to 99 ul 0.2 M EDTA mix

12. Run through Sephadex G50

13. Take 1 ul post spin and add to 99 ul 0.2 M EDTA mix

14. Spot 1 ul of pre and post spin onto Whatman filters

15. Use scintillation counter to measure specific activity


Screening Filters:

[CRITICAL] If using a filter for the first time, follow the stripping protocol before hybridization (see below)

1. Place the membrane(s) in glass bottles that fit in the Hybaid hybridization oven, using nitex sheets to separate the filters. A complete set of library filters will fit in one bottle for both hybridization and washing.

2. Prehybridize in a shaking water bath at 65°C (55°C for cross species probes) for 1 hr.

3. Remove HS to minimum amount - so that it just covers the filters Xul probe to the prehybridization solution.

4. Incubate for at least 12 hr at 65°C (55°C for cross species probes).


5. Following hybridization, wash the filters by incubating them in 2x SSPE, 0.1% (w/v) SDS at room temperature for 10 min. Repeat.

6. Replace the solution with 2x SSPE, 0.1% (w/v) SDS. Incubate at 65°C (55°C for cross species probes) for 15 min. Repeat.

7. Replace the solution with 1x SSPE, 0.1% (w/v) SDS. Incubate at 65°C (55°C for cross species probes) for 10 min. Repeat.

8. Replace the solution with 0.1x SSPE, 0.1% (w/v) SDS. Incubate at 65°C (55°C for cross species probes) for 10 min. Repeat. (Use this for high stringency).


9. Remove filter, wrap in plastic wrap and carry out autoradiography.

10. Plastic wrap should be employed without trapped air for best exposures. From the final wash, pick up the filter by one corner and allow it to drip dry for 10 seconds. Place the filter face up on a piece of plastic wrap still attached to the roll. Fold the attached edge off the filter, then roll the top layer of wrap onto the filter. This expels any trapped air Most importantly, do not allow the filter to dry until it is stripped.


Stripping filters:

Bring 0.5% SDS to a boil.

Pour on the membrane and allow to cool to room temperature.

(If necessary, repeat)


Storing filters:

Short-term storage (1 or 2 weeks)

a. Wet two sheets of Whatmann paper in EDTA-containing stripping buffer.

b. Place the membrane between the two wet papers.

c. Wrap the papers and the membrane with plastic wrap and keep them in refrigerator until reuse.

Long-term storage

a. Sandwich between two sheets of plastic wrap.

b. Expose the membrane to X-ray film for at least 12 hr to check whether stripping is done completely. If stripping is done completely, place the membrane between two sheets of dry Whatmann paper and dry it at room temperature for at least 24 hr (until completely dry).

c. If stripping is not complete, repeat steps 1&2 but execute step 2 at the higher temperature.


Determining microwell plate coordinates from arrayed filters:

The high-density filter array is a square arrangement of 48X48 blocks which can be thought of as six sub-fields of 16X24 blocks. Thus each sub-field is equivalent to the wells of a 384-well plate. Each block is a 4X4 array of eight clones spotted in duplicate. That is, the inoculum from each well of each plate has been spotted twice onto the filter in the same 4X4 block. The arrangement has been designed so that the two spots define a unique angle different from all the others within the 4X4 block. The unique angular relationship of the spot pair defines the plate from which that clone was taken. In the accompanying figure, a 4X4 block adjacent to each sub-field indicates the plate number assignments for the blocks in that sub-field. The position of a 4X4 block containing a positive spot pair can be described by the X-Y coordinates of the block in the sub-field (X coordinates are A through P, from bottom to top; Y coordinates are 1 through 24, from right to left). For filters beyond the first one (A) in the set, the plate numbers are increased in increments of 48, thus the plate number for the B filter is the decoded number plus 48; for the C filter, plus 96; etc.

EXAMPLE: On the accompanying figure there is a positive spot pair circled in white. It lies in the left-middle sub-field at X-Y position I-10. That is I blocks (9) up from the bottom of the sub-field and 10 blocks over from the centerline. Thus the well position with in the plate is I-10. For this sub-field, the angle of the spot pair within the block indicates #31. There fore, the clone is located on plate #31 in well I-10.

NOTES: Identification of spot coordinates in the case where the background on the filter is very low is aided by pre-marking the filters when they are dry and the colony residue is visible. Dry filters are marked by indentations from a ball point pen. The pen tip is pressed into a filter that is placed on a piece of 3MM paper on a hard surface while observing the operation in oblique lighting. Dots can thus be made at the boundaries of the 6 sub-fields and at the extreme corners of the array.

To aid orientation in the newer filter sets, the A1 well for each plate has been left empty. Thus there are six empty squares that have no bacteria on the filter. After hybridization these squares have lower background and will orient the filter. The squares are 3 sets of 2 across when the label is on the upper right hand edge.

BAC Miniprep Protocol

This protocol uses alkaline lysis and precipitation to isolate BAC DNA to analyze by Pulsed-field Gel Electrophoresis, PFGE, or PCR. BACs purified using this protocol cannot be injected into fertilized eggs.


Materials:

Buffer P1: Stored at 4oC. Add the RNAseA just prior to use.

• 15 mM Tris, pH 8.0

• 10 mM EDTA, pH 8.0

• 100 μg/ml RNase A

Buffer P2: Make fresh each use.

• 0.2N NaOH

• 1% SDS

Buffer P3: Cool on ice prior to use.

• 3M KAc pH 5.5


Procedure:

1. Inoculate a single bacterial colony into 3 ml LB containing 12.5μg/ml chloramphenicol in a 14 ml culture tube. Grow overnight (< 16 hrs), shaking at 250-300 rpm.

Optional: make bacterial glycerol stock (15%) of BAC.

2. Pellet the bacteria by transferring 1.5 ml of each culture to a 1.7 ml microcentrifuge tube and centrifuge at 6800 g for 3 min. Discard supernatant.

3. Repeat step 2.


4. Resuspend each pellet in 250 μl P1 carefully. Be sure to fully resuspend until suspension is creamy with no clumps.

5. Add 250 μl P2 and invert tubes 5 times to mix. The appearance of the suspension should change from very turbid to almost translucent.

6. Add 350 μl cold P3 slowly to each tube and shake gently during addition. A thick white precipitate consisting of E. coli DNA and protein will form. Invert the tube several times to mix the solution thoroughly.

7. Place the tubes on ice for 5 min.


8. Centrifuge at 18,000 x g for 10 min at room temperature to pellet the white precipitate.

9. Transfer the clear supernatant (~700-800 μl) to a 1.7 ml microcentrifuge tube.

10. Spin again in a microcentrifuge for 5 min at RT to remove the rest of the debris. Transfer the clear supernatant to a fresh tube.

11. Add 0.8 ml ice-cold isopropanol. Mix well by inverting tubes ~10 times. Place the tube on ice for 30 min, or leave overnight at 4°C.


12. Centrifuge at 18,000 x g for 30 min at 4oC to pellet BAC DNA.

13. Remove supernatant and add 1ml of ice-cold 70% EtOH. Invert tubes several times to wash the DNA pellets. Centrifuge at 18,000 x g for 15 min at 4oC.

14. Repeat step 13.


15. Centrifuge at 18,000 x g for 2 min at 4oC to remove residual EtOH. Carefully remove all supernatant, taking care not to dislodge the pellet.

16. Briefly air-dry pellet at room temperature.

17. Resuspend pellet in 20-30 μl TE (10 mM Tris; 1 mM EDTA). Gently flick the bottom of the tubes to resuspend DNA. Do not vortex or pipet up and down.


For storing use high EDTA TE - i.e. 10mM Tris 10mM EDTA.

To analyze the BACs, use 6 μL of this prep in a NotI digest to run on a PFGE.

For PCR dilute 1 μl of this prep in 24 μl TE.

BAC Recombineering

More information is available here: Techniques for analyzing gene expression using BAC-based reporter constructs. Buckley KM, Ettensohn CA. Methods Cell Biol. 2019;151:197-218. doi: 10.1016/bs.mcb.2019.01.004. Epub 2019 Feb 23. PMID: 30948008 Review.


Materials:

Reagents:

LB with kanamycin (25 μg/mL)

LB with chloramphenicol (12.5 μg/mL)

SOC media

10% L-(+)-arabinose

Gel extraction kit

High fidelity DNA polymerase

DpnI

3 M NaOAc (pH 5.2)

Cell lines:

1. Electrocompetent DH10B

2. EL250. A DH10B-derived strain that contains a λ prophage with the recombination genes exo, bet, and gam. These genes are repressed by the temperature-sensitive repressor cI857.