Progress for DENG Selection




Over the past two months, I have completed 6 rounds of filterbased selection against Dengue Virus Envelope Protein(DENG) and have performed a binding assay on Rounds 1, 4, 5, and 6. I am currently repeating Round 5. To decrease the size of my posts I am providing links to the images of my cycle course gels. For more information on the target click here.


Round 1 ccPCR Gel: Cycle 15 showed the greatest amplification of DNA without over amplification.


Round 2 ccPCR Gel: Cycle 12 showed the greatest amplification of DNA without over amplification.


Round 3 ccPCR Gel: Cycle 12 showed the greatest amplification without over amplification. Plus and Minus protein showed the same amplification patter. Since this is Round 3 this is not overly concerning. However, if this continues into later rounds, it may indicate a substantial presence of background binders.


Round 4 ccPCR Gel: Cycle 12 showed the greatest amplification without over amplification. Plus protein first showed amplification at Cycle 9. Minus protein first showed amplification at Cycle 12. This suggests that binding species are beginning to dominate the pool.


Round 5 ccPCR Gel: Cycle 9 showed the greatest amplification without over amplification. Plus and Minus protein show almost identical patterns of amplification in Round 5. This unfortunately suggest that the pool is now primarily composed of background binders.


Round 6 ccPCR Gel: Cycle 9 showed the greatest amplification without over amplification. Both Minus Elutions and the Plus DENG Elution showed the same amplification pattern. This unfortunately suggests the continued presence of background binders despite the increase in wash volumes and negative selection.


Round 6B ccPCR Gel: tRNAs and decreased protein concentration were used for this round. Cycle 12 showed the greatest amplification without over amplification. Plus protein amplified later than minus suggesting a strong presence of background binding.


Round 7B ccPCR Gel:Cycle 9 showed the greatest amplification without over amplification. Both Minus Elutions and the Plus DENG Elution showed the same amplification pattern. This unfortunately suggests the continued presence of background binders despite the addition of tRNAs.


Binding Assay R1, R4, R5, R6: A binding assay was performed on Rounds 1, 4, 5, and 6 RNA. The image below shows the results of the assay. This assay shows promising results. The there was a gradual increase in binding of the pool to about 5% by R5, without a substantial presence of background binding, approximately 2%, until Round 6. The binding of the pool seems to level off between Rounds 5 and 6. This combined with the presence of background binding in R6 means that I will go back to R5 and continue through selection. To increase the binding of the pool, I will drop my protein concentration to 100pmol and select for more specific binders. To prevent a rise in background binding, I will use tRNAs to block the nonspecific binding sites of the protein and the filter. After going back to R5, I will carry the pool through two more rounds of selection before performing another binding assay.

A) Shows the developed image of the phosphor plate exposed to the filters containing the radioactive RNA. B) Shows the % binding of the assayed rounds.

Binding Assay R6, R6B, R7B: A binding assay was performed on R6, R6B, and R7B. The percent binding results can be seen below. R6B and R7B are a continuation from R5 with added tRNAs and decreased protein concentration. The increase in background binding suggests that the tRNAs did not effectively block general binding sites. Additionally, the decreased protein concentration most likely favored background binders over protein binders. This assay also raises some concern as to the accuracy of the first assay, since R6 results differ between the two assays.
Shows the % binding of the assayed rounds

IFN-g Second Progress Report (Ashley Dawson)

The abstract and proposal can be found here.

Round One Conditions
Target: IFN-g with 6X His-tag
Beads: Nickel NTA
Pool: N34
Ratio of Pool to Target: 200:200 pmol
Buffer: 1X PBS with MgCl2
Incubation Time/Temp: 30 min at 37C
Wash Volume/Number: 3 washes, 2 volumes

After performing a large scale PCR for round one (see first progress report), the following PAGE purification did not show a band. One microliter of dsDNA from the large scale was run down an agarose gel with 5ul 6X Orange dye+ EtBr, and, as seen in Figure 1, no bands were present.


This implied that the large scale PCR had failed and round one was repeated with the same original conditions.

After repeating bead based selection for round one, another cycle course was performed and cycles six, twelve, fifteen and twenty were run down a 3.8% agarose gel as shown in Figure 2.

As cycle twelve had the best amplification, lsPCR was performed for twelve cycles. The large amounts of overamplification in W0 implies that most of the sequences are weak binders. This could either be attributed to low binding affinity of the target IFN-g or to too much stringency in the washes.


A PAGE was run to purify the round one RNA and the final concentration of RNA was 1911.9 ng/ul after elution and ethanol precipitation. This was more than enough move forward to round two.

Round Two Conditions
Target: IFN-g with 6X His-tag
Beads: Nickel NTA
Pool: N34
Ratio of Pool to Target: 200:200 pmol
Buffer: 1X PBS with MgCl2
Incubation Time/Temp: 25 min at 37C
Wash Volume/Number: 3 washes, 2 volumes


After completing another bead-based selection (with incubation time decreased by five minutes from the previous round) a cycle course PCR was performed on cycles seven, nine, thirteen and twenty. Only the elution was run fown the agarose gel as W0 and W3 were lost in ethanol precipitation. As shown in Figure 3, the elution amplified earlier than in round one implying that more strong binders were carried through the round.


A large scale PCR was run for nine cycles and, after transcription, a PAGE was run. After elution and ethanol precipitation the concentration of RNA was measured as more than 4000 ng/ul. As this was a greater value than the nanodrop's range of accuracy the RNA was diluted in an additional 30ul of 1X PBS SELEX and the new concentration was measured at 1315.5 ng/ul which was enough to move on to round three.

Round Three Conditions

Target: IFN-g with 6X His-tag
Beads: Nickel NTA
Pool: N34
Ratio of Pool to Target: 200:200 pmol
Buffer: 1X PBS with MgCl2
Incubation Time/Temp: 25 min at 37C
Negative Selection: 20 min at 37C
Wash Volume/Number: 3 washes, 2 volumes

In round three a negative selection was performed where an RNA pool binding reaction was incubated on only beads for twenty minutes. The supernantant from this was then incubated with the protein-bound beads. This was done in an effort to reduce the amount of background binders (sequences that bind to the beads or the tube).

After the negative selection, a cycle course was performed and cycles nine, twelve, fifteen and twenty were run down an agarose gel as seen in Figure 4.

The early amplification of W3 suggests that the wash process is not stringent enough as more sequences are still being washed away after two washes. This contradicts the previous data from round one which indicated that the wash proces was too stringent. This could be attributed to the possibility that a large number of the sequences in rounds one and two were binding to the beads or the tubes and when those sequences were removed there was a greater binding area for sequences that bound to the RNA. These sequences most likely included more weak and medium-strength binders than strong ones.

Large scale PCR was performed on cycle twelve and, following transcription, a PAGE was run. Due to bubbles in the gel, the RNA was pulled to the sides and so transcription was repeated and the PAGE run again. No bands showed up the second time either and so round three was restarted with the same original conditions. Another cycle course was performed, as seen in Figure 5, on cycles six, nine, twelve, fifteen and twenty of the elution and W0 only as W3 was lost in ethanol precipitation.

The early amplification was unexpected for the first round with negative selection especially as the previous round thre gel showed amplification at cycle twelve. This could be because of slight changes in the way the sequences stabilized after denaturation or differences in carrying out the protocol. However, a large scale PCR was run for six cycles as that was the optimum number indicated by the gel.


After transcription a PAGE was run and a very small band was shown. After elution and ethanol precipitation the concentration of RNA from the band was 141.8, too low to continue selection. Transcription and PAGE were repeated again and the band was even lighter. In an effort to get a higher yield, two transcriptions were then run and the bands from both combined. This gave a measured concentration of 205.4 ng/ul, still to low to continue. The failed PAGE gels are most likely either caused by something failing in transcription or large scale. If the PAGE fails again this round another test microliter of dsDNA will be run down an agarose gel to determine whether the problem is occurring during large scale.

Round three was restarted 11/29 and, after negative selection, a cycle course was run on W0, W3 and E3 for cycles six, nine, thirteen and sixteen as seen in Figure 6.

This indicates a relatively large amount strong binders as optimal amplification is around ten cycles. W0 amplified very early, as it has before in round three, which implies that the wash process is removing a lot of weak binders. The lack of amplification for W3 is similar to round one, indicating that the wash process removed all of the weak binders in the first two washes. A large scale PCR was run for ten cycles and round three will be continued and the concentration of RNA after PAGE elution will be measured to determine if selection can be continued.



The current progress and results are summarized in Figure 7.

Progress Report 2: Beta-Lactamase Bead Based Selection

The full proposal has been posted on Dropbox, the abstract is here.

Progress, Results, and Discussion

Six rounds of bead based selection (using Streptavidin beads) have been performed with N34 RNA on beta-lactamase (Type IV penicillinase) using 400 pmol RNA each round; 10X HEPES SELEX buffer was used to wash away nonbinding species. The protein/RNA was incubated at 37C for 25 minutes. Protein:RNA ratios and wash volume/number were dependent upon the round number. This information is in Table 1.

Since the last reporting period, four additional rounds have been completed, for a total of six rounds. Gel images from ccPCR give great insight about the selection process. Shown below in Figure 1 is an image of the last wash from each of the six rounds. Despite repeated attempts to decrease nonbinding species in the last wash, these sequences seem to stick to either the target or the beads. Wash number and volume were each increased, in addition to an increase in incubation time between washes. None of these provided any positive results, as amplification occurs at around the same number of cycles each round.

An image of the elution for R1-R6 can be found in Figure 2. Cycles in which optimal amplification occurs are boxed in. These are the number of cycles to be used in lsPCR. Amplification occurs unusually early, especially in R5. This could be cause for concern, as background binders could be present in the elution. However, this cannot be conclusively stated without binding assay data. In spite of this, most of the elution shows up before the washes.

Negative selection was performed in R3, R5, and R6 in order to minimize the sequences that bind the beads. tRNA was used in R6 negative selection so that beta-lactamase-binding sequences are not degraded by possible RNAse activity.

Problems Encountered

Even though numerous measures were implemented to decrease sequences in the last wash, there is still a high concentration of nucleic acid in this wash. This means that some of the nonbinding sequences carried over into the elution. A binding assay will need to be performed in order to truly determine this.

Conclusion and Future Work

Consequently, six rounds of bead based selection have been performed. A summary of this is shown below in Table 1. In order to quantitatively determine the binding affinity of isolated sequences for beta lactamase, a binding assay will be performed. This data will be posted shortly.



mCherry Fluorescent Protein Progress Report Two

See the final report here.

See the abstract, outlining the purpose of this selection,
here. See the first progress report here.

A total of five rounds of selection and a binding assay have been performed since the last progress report. mCherry, a monomeric fluorescent protein, has remained the target. The results for the first six rounds of selection, determined through the binding assay, were dismal – deeming the selection a failure. With such poor results, and discovering that mCherry has minor RNase activity, I determined it best to restart selection, utilizing tRNA to reduce background binding and perhaps limit any lingering RNase activity.

Initial Conditions (beginning at Round
Four):

Target: mCherry
Beads to Use: Nickel-NTA

Pool: N34
Incubation Time and Temperature: 20 minutes at 37 0C
Buffer and pH: PBS SELEX, pH 7.4
RNA:Protein Ratio: 400:200

Wash Volume and Number: 3 washes, 4 volumes

Negative selection was again performed. In an attempt to further reduce background binding, the RNA:protein ratio was reduced from 400:400 to 400:200. A decreased amount of protein would increase competition between the aptamers, hopefully singling out the stronger and/or faster binders.

Cycle course PCR was performed to determine the appropriate number of amplification cycles to be utilized in Large scale PCR (lsPCR). For Round Four, the DNA amplified much earlier than wash three (W3), with essentially no DNA present. As nine cycles appeared under-amplified, and twelve over, eleven cycles of the elution (E1) were determined for utilization in lsPCR. The gel can be seen in Figure 1. The remainder of the round progressed according to the protocol. The concentration of RNA resulting from PAGE and elution was 79.26 uM.

For Round Five, the previous conditions were kept the same, opting to perform a plus and minus selection. Although nothing was changed, the cycle course PCR revealed something seemingly unexpected: W3 + appeared in large amounts. As W3 had been seemingly non-existent in the previous two rounds, this was surprising. One hypothesis could be that the double pool binding reaction utilized, with only 40 uL of beads, contained many bead binders. Thus, when negative selection was performed, and the supernatant removed, perhaps many bead binders still remained, leaving many for the positive (with protein) portion. With essentially half as many beads to bind to, they were transferred into the positive portion of the selection. However, the exact cause of this is unknown. Amplified well, but not over-amplified, nine cycles was determined for utilization in lsPCR. The gel for ccPCR can be seen in Figure 2. The remainder of selection again progressed according to the protocol. The concentration of RNA resulting from PAGE and elution was 77.25 uM.

Round Six of selection returned to the initial conditions of Round Four, but with alterations to incubation times. RNA:protein incubation time was changed to fifteen minutes; incubation time during binding and selection was increased to four minutes, making the time between buffer removal and addition approximately five minutes. These alterations would address binding kinetics. The overall reduction in incubation time would hopefully allow faster binders to predominate; the increase in wash incubation time would potentially allow weak binders to fall off – potentially further isolating more mCherry-specific aptamers.

Cycle course PCR was again performed to determine the appropriate number of amplification cycles to be utilized in lsPCR. For Round Six, the elution amplified before the third wash, but the presence of the third was still disconcerting. In addition, the elution amplified much later than in previous rounds – double the cycles of the Round Five. What caused such a change exactly is unknown. A later amplification could suggest that specific strands were isolated, and the non-specific washed away, but the binding assay performed, following this round, suggested otherwise. The gel for Round Six can be seen in Figure 3. The remainder of this round adhered to the protocol. The concentration of RNA resulting from PAGE and elution was 20.02 uM. The cause of such a low yield is unknown, as the crush-soak elution protocol was executed as normal.

The bead-based binding assay, utilizing Rounds One, Three, Four, and Six, was performed mostly by Holli Duhon. “Hot” Transcription, “Hot” PAGE, and the elution were performed prior to my involvement, which began with ethanol precipitation. One “round” of Katherine Li’s was also utilized.

Ethanol precipitation was performed as normal, taking extra care when working with radioactivity. The samples were resuspended in 50 uL of diH2O. Each round was then read in the spectrophotometer – revealing very low recovery. With such a low yield, a ratio of 50 pmol RNA:50 pmol protein was utilized in the “Hot” Selection. Although I was again not present for this process, Ms. Duhon explained that the procedure was the same as a regular plus and minus protein selection (without negative selection), stopping after the washes and elution. Wash zero, wash one, wash three, and the elution, for RNA exposed to protein (plus) and not exposed to mCherry (minus), were all utilized. The rig utilized was loaded as outlined in Figure 4.

At this time, I do not have a hard copy of the results. However, after seeing the results and talking with Dr. Brad Hall, Holli Duhon, and Katherine Li (also present for the assay), the results were dismal. In addition, Austin Rezigh and Dr. Brad Hall discovered that all the fluorescent proteins, including mCherry, had RNase activity. Although Dr. Hall stated that most of the nucleases should have been removed while washing the immobilized protein with 400 uL of 1X PBS, three times, this is uncertain. Thus, I determined it was best to restart selection from Round One, utilizing tRNA to not only decrease background binding, but also combat any remaining RNase activity. This would hopefully be accomplished as the tRNA would provide competition during protein binding, and also serve as a buffer to nuclease activity. With more tRNA, 8X the amount of RNA (in pmol), there is a higher probability the nucleases would chew up the tRNA, over the N34 RNA pool.

Initial Conditions (Round One plus tRNA):

Target: mCherry
Beads to Use: Nickel-NTA
Pool: N34
Incubation Time and Temperature: 25 minutes at 37 0C
Buffer and pH: PBS SELEX, pH 7.4
RNA:Protein Ratio: 400:400
Wash Volume and Number: 3 washes, 2 volumes

This first round adhered to the protocol. The tRNA, 3200 pmol at 315 uM (about 10.16 uL), was added when the pool binding reaction was added to the protein. Cycle course PCR was performed to determine the appropriate number of amplification cycles to be utilized in large scale PCR. For this first round, Wash Three and the Elution amplified at about the same time. As nine cycles appeared under-amplified, and twelve cycles over-amplified, eleven cycles was determined for utilization in large scale PCR. The gel can be seen in Figure 5. The concentration of RNA resulting from PAGE and elution was 80.84 uM.

To combat non-specific RNA, the RNA:protein ratio was reduced in the second round from 400:400 to 400:200. As stated previously, this again would hopefully provide competition between the RNA, with the faster and/or stronger aptamers binding to the decreased amount of protein. tRNA was again utilized for this round.

Cycle course PCR was again performed as stated. Although E1 amplified before W3, there was still a significant amount of amplification in the third wash. This will be addressed in future rounds. As nine cycles appeared well-amplified, but not over-amplified, it was utilized for large scale PCR. The gel can be seen in Figure 6. The concentration resulting from PAGE and elution was 105.13 uM.

In Round Three, and future rounds, promoting mCherry-specific binding and decreasing background binding will be of the highest priority. Steps will be taken toward this goal in Round Three, as the wash volume will be increased from 200 uL to 400 uL. In addition, negative selection will also be performed.

Aliquots and Buffer Needed

We are out of both glycogen and N34 primer(foward and reverse) aliquots. Also, our new 1X TBE buffer for PAGE gels is running very low.
Cheers,
Austin

Progress Report two for Selection Against Amyloid Precursor Protein (APP)

Original abstract, useful in gaining an overview of the direction of the research, can be found here

Progress, Results and Discussion:
Two rounds of selection were completed using the bead-based selection protocol, using the following conditions
Target: APP
Beads used: Streptavidin
Pool: N34
Selection Buffer/PH: TRIS SELEX, pH 7.3
Ratio: 400 pmol APP: 200 pmol RNA
Incubation Time/Temperature: 20 minutes, at 37 *C
Wash volume/number: 1 volume (100ul), 3 washes.
The major concern for a majority of the experiment, and the main reason behind it falling so behind, was a series of failed transcriptions, using transcription kits N, M and A. After three failed PAGE runs, insufficient lsPCR product remained for another PAGE run, so it was necessary to restart the first round of selection. The cycle course images from both attempts at round one are presented below, in order, from least to most recent.


Figure 1: Cycle course PCR run from the first attempt at Round 1.


Figure 2: Cycle course PCR from the second attempt at Round 1.


As seen from FIGURE 2, the appropriate number of cycles, for the E1 wash, was just above the under amplified 15 cycle well, and so, 16 cycles were chosen. After the lsPCR of this second attempt, the product was run down another agaraose gel, simply to ensure that lsPCR had occurred successfully; as seen in Figure 3, below, there were no problems with the lsPCR.


Figure 3: lsPCR gel run to verify the success of large scale PCR.


Transcription finally worked, using kit B, and yielded a concentration of 404.4 ng/ul, which after all the failure, was quite encouraging. Round two of selection is already underway, and a PAGE should be completed early next week (targeting Monday), hopefully yielding another solid concentration.
Overall, the selection has been fairly hindered by the need to restart an entire round, particularly the first one. I would have liked to have a binding assay by the end of the semester, but seeing as the time constrain is fairly short, this goal will probably need some time input outside of the following week to be realised. I hope that I can at least get through 3 rounds of selection by the time the final report is due.

Lab Party - sign-up to bring food & whatnot

The end of the semester lab party will be held during the regular lecture time & place on Tuesday, November 30th at 4:00 in WAG 214. Please sign-up (add comments) to bring in food or other items.

Food/Desserts:
1. Ashley - something good
2. Travis - chips
3. Holli - pigs in a blanket

Paper items:
1. Stephanie - plates & napkins

Drinks:
1. Kamaxi - cups
2. Emma - some sweet sugary drinks

Other Items/Food:
1. Alec - food

End of semester announcements

A few announcements:

1. Happy Thanksgiving!

2. The Lab party will be held during regular lecture time on Tuesday, November 30th at 4:00 in WAG 214. Please sign-up to bring something. Sign-up on the blog.

3. I'll miss the lab party. :( I've enjoyed working with all of you and getting to know you. Please feel free to stop by sometime & tell me how you're blossoming as a scientist. :)

4. Please take the course evaluation/survey. It's available online and Brad may have his own survey as well.

5. Post your lecture presentations on blackboard.

6. Photo slide show - get your lab photos on the stream's Facebook group so we can create a slideshow.

7. Update your resume on friend.cns.utexas.edu, if you haven't already. Remember, the pool of resumes may be used to find scholarship recipients ... free money.

8. Lab clean-up - please perform 2 hours of work in the lab between December 1-3.

9. Final report guidelines are available on Blackboard. The final report is due on December 3rd, because grades are due on Dec 7th. Brad will accept late reports on Dec 5th, minus 15 points. Submit reports on APS blog to your abstract post (like you did with your proposal).

10. Proposals will be graded & returned soon by email.

11. Please read next week's journal article. The article is posted on the APS blog.

Thank you,
Gwen