Difference between revisions of "Part:BBa K523006"

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From the results, a clear zone and growth of halos around the clone can be observed under iodine solution, which corresponds with the former conclusion that malS can degrade starch. In comparison, 1% amylase solution showed a greater initial starch degradation amount. Yet it’s slope of diameter of clear zone almost levels off in day 3, which suggests that the rate of digestion slows down with time. In contrast, the clones showed a steeper increase in the diameter of clear zone from Day 2 to 3. This can be explained by the continuous production of malS which results in a continuous digestion of starch in the long run.
 
From the results, a clear zone and growth of halos around the clone can be observed under iodine solution, which corresponds with the former conclusion that malS can degrade starch. In comparison, 1% amylase solution showed a greater initial starch degradation amount. Yet it’s slope of diameter of clear zone almost levels off in day 3, which suggests that the rate of digestion slows down with time. In contrast, the clones showed a steeper increase in the diameter of clear zone from Day 2 to 3. This can be explained by the continuous production of malS which results in a continuous digestion of starch in the long run.
  
==VIT_Vellore Characterization: Expression==
+
==VIT_Vellore Characterization: Activity==
  
 
====Methods====
 
====Methods====
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==VIT_Vellore Characterization: Activity==
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==VIT_Vellore Characterization: Expression==
  
 
====Methods====
 
====Methods====
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<p><b><u>Media optimization: pH</b></u></p>
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<p><b><u>Media optimization: pH</u></b></p>
 
<br>
 
<br>
  
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<tr>
 
<tr>
 
<td>3</td>
 
<td>3</td>
<td>0.4352</td>
+
<td>0.4352 </td>
<td>36.342</td>
+
<td>36.342 </td>
 
</tr>
 
</tr>
 
<tr>
 
<tr>
 
<td>4</td>
 
<td>4</td>
<td>0.5796</td>
+
<td>0.5796 </td>
<td>48.375</td>
+
<td>48.375 </td>
 
</tr>
 
</tr>
 
<tr>
 
<tr>
 
<td>5</td>
 
<td>5</td>
<td>0.6756</td>
+
<td>0.6756 </td>
<td>56.375</td>
+
<td>56.375 </td>
 
</tr>
 
</tr>
 
<tr>
 
<tr>
 
<td>6</td>
 
<td>6</td>
<td>0.6532</td>
+
<td>0.6532 </td>
<td>54.508</td>
+
<td>54.508 </td>
 
</tr>
 
</tr>
 
<tr>
 
<tr>
 
<td>7</td>
 
<td>7</td>
<td>0.7717</td>
+
<td>0.7717 </td>
<td>64.383</td>
+
<td>64.383 </td>
 
</tr>
 
</tr>
 
<tr>
 
<tr>
 
<td>8</td>
 
<td>8</td>
<td>0.5344</td>
+
<td>0.5344 </td>
<td>44.608</td>
+
<td>44.608 </td>
 
</tr>
 
</tr>
 
<tr>
 
<tr>
 
<td>9</td>
 
<td>9</td>
<td>0.2971</td>
+
<td>0.2971 </td>
<td>24.333</td>
+
<td>24.333 </td>
 
</tr>
 
</tr>
 
   </table>
 
   </table>

Revision as of 18:11, 21 October 2019

Plac + LacZ + malS

E. coli periplasmic α-amylase gene malS (see [http://www.ncbi.nlm.nih.gov/nuccore/48994873?from=3735520&to=3737550&report=gbwithparts info from GenBank: U00096.2]) under control of lac promoter. LacZα is also present.

Usage and Biology

While an amylase ought to be capable of degrading starch, the product protein is believed to be periplasmic and thus ought to only degrade starch if it leaks from the periplasm in significant quantities (but see below: this does seem to be the case). Its natural function in E. coli presumably involves degrading shorter glucose chains: [http://dx.doi.org/10.1128/JB.00767-08 Lengsfeld et al (2008)] state that "MalS produces preferentially maltohexaose from longer maltodextrins in the periplasm".

Other interesting and useful facts about the MalS protein can be found in [http://dx.doi.org/10.1074/jbc.272.35.22125 Spiess et al (1997)].

The SignalP program predicts that a 17 amino acid localisation signal (at the N terminal) is cleaved off before the protein reaches its mature form.

Iodine assay #1

We (Edinburgh 2011) placed BBa_K523001 under the control of the lac promoter (creating BBa_K523006) and streaked colonies on a starch agar plate. A (poorly characterised) negative control without this construct was also streaked out. The cells were incubated for 3 days.

One colony failed to grow for some reason, but the others did. We flooded the plate with iodine, which turns black in the presence of starch ([http://en.wikipedia.org/wiki/Iodine_test Wikipedia]):

523001-assay-pre2.jpg     523001-assay-post.jpg     523001-assay-post-post2.jpg
Before the assay. Colony 1 failed to grow. Control at top.     Immediately after iodine flooding.     40 minutes after iodine flooding.

We made three observations:

  1. The area under the negative control (top streak) turned black, while the areas under the malS streaks did not.
  2. The iodine gradually evaporated, turning the plate clear again.
  3. After 40 minutes, halos were seen around the two malS streaks.

We can think of two ways to explain observation 1:

  • malS degraded starch, or:
  • the control cells grew slower than the malS cells for some reason, and thus formed a thinner layer; iodine could pass through that layer to turn the starch underneath black, but could not pass through the thicker malS layer.

However, observation 3, the halos, seem to rule out this second explanation, and instead suggest actual diffusion of a starch-degrading enzyme (MalS) into the agar.

Iodine assay #2

The precise nature of the negative control above has been lost in the mists of time (it was JM109 E. coli with an unknown construct in pSB1C3).

We (Edinburgh 2011) repeated the iodine assay with a known control, PlacLacZ-bglX (part BBa_K523014). This part is a good control since it has both Plac-LacZ (like this part) and a periplasmic protein (like this part), and is known to actually work.

(Another control, using only Plac-LacZ, failed to grow because the source cells had been in the cold room too long.)

K523006-starch-2nd-assay-t0.jpg     K523006-starch-2nd-assay-t25.jpg     K523006-starch-2nd-assay-t70.jpg
Control at top. Bottom two streaks are malS.     Same plate, time = 25 minutes.     Same plate, time = 70 minutes. While the iodine has faded from all the bacteria, halos are now visible around the malS streaks but not the control.

DNS assay

We (Edinburgh 2011) made cell extracts using this part and compared them to a negative control (BBa_K523000) in the following way:

Cells were sonicated and fractionated to obtain cell lysate and cell debris. 0.2% starch solution and phosphate buffered saline (PBS) were mixed with cell extract and incubated at 37 C. Every 30 minutes, a sample was taken from the reaction and 3,5-dinitrosalicylic acid (DNS) was added. The sample was heated in boiling water for 10 minutes. Enzyme activity was then halted by addition of potassium tartrate. The sample was cooled to room temperature and OD575 was measured.

If the cell extract is capable of starch degradation, this will cause the liberated glucose to react with the DNS, producing 3-amino,5-nitrosalicylic acid and so increasing the OD575 reading. The data are clearest for the cell lysate, but overall seem to indicate starch degradation:


Left side shows data for 2 experiments (and 2 controls) using cell lysate; right side shows data for cell debris (CD).

Mucoid phenotype

Streaks of E. coli with this part, and grown on starch agar, eventually show a mucoid phenotype so pronounced they were described as "disgusting" by a hardened microbiologist. This phenotype is only visible after several days, and was first spotted on plates that had already been subjected to iodine treatment, so we (Edinburgh 2011) checked plates that were never subjected to iodine. These too show the effect:

K523006-mucoid-2011-09-16.jpg     K523006-mucoid2-2011-09-16.jpg
Starch agar. Mucoid (slimy) phenotype. All colonies are malS.     Same plate, held up to the light. Control failed to grow because it wasn't chloramphenicol resistant. Oops.

Mucoid phenotype "transmission"

We (Edinburgh 2011) wanted to check that a control strain of E. coli without this part doesn't display a mucoid phenotype on starch agar, and so E. coli with the aforementioned Plac-bglX part (BBa_K523014) was streaked out onto a starch agar plate alongside some more malS streaks.

We noticed an interesting fact: whether the control strain showed a mucoid phenotype depended on how close the cells were to the malS streaks. The part of the streak that was close to a malS streak did, while the part that was furthest away did not.

K523006-slime-transmission.jpg
The new starch agar plate. As before, one of the controls (top) failed to grow due to an extended period in the cold room.

This seems to suggest that the MalS protein, or its products, are diffusing through the agar, and causing the nearby cells to show the same mucoid phenotype.

Growth on (minimal) starch agar

The starch agar mentioned above also had other carbon sources present. We tested the ability of K523006 to grow on minimal media but with only starch added as a carbon source. Indeed it could, while normal E. coli displayed weak or no growth:

K523006 on starch.jpg
Growth on M9 minimal media with starch.

Future experiments: Mucoid phenotype on LB agar

A control ought to be run testing whether this part displays the mucoid phenotype on normal agar. On the assumption that this phenotype is related to starch degradation, it should not.

We ([http://2015.igem.org/Team:TecCEM_HS/Parts TecCEM_HS 2015]) ran this experiment to see the phenotype difference between the bacteria that have BBa_K523006 in starch agar and in normal LB agar (no starch). There wasn't any mucoid phenotype to be seen on LB agar in comparison to starch agar, which showed the mucoid phenotype. We can observe that the mucoid phenotype that is shown by E.coli is in fact related to the ability of this part to degrade starch.


K523006 MUCOIDSTARCH.jpg     K523006 LBCAM.jpg
Starch agar after Iodine assay. Mucoid phenotype can be seen.     LB (Cam+) agar, the phenotype is not mucoid. All colonies contain BBa_K523006.

Discussion

There is clear evidence that malS, when expressed from a high copy number plasmid, is capable of at least mild starch degradation.

The mucoid phenotype was unexpected. It is possible that starch degradation has led to a high supply of glucose, leading to extra exopolysaccharide being produced. This might also explain the "transmission" of the phenotype to nearby cells.


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 1841
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BglII site found at 607
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal AgeI site found at 977
    Illegal AgeI site found at 2142
  • 1000
    COMPATIBLE WITH RFC[1000]



IMPROVEMENT REFERENCE: YAU-China 2019

We replaced Plac + LacZ with T7 promoter (BBa_K2999008) to enhance the expression of downstream genes. The new part is: (BBa_K2999007).(Group: iGEM19_YAU-China), Designed by: Xin Ma.

Characterisation by 2019 Hong Kong UCCKE Team

Group: iGEM 2019 Hong Kong UCCKE
Author: Wong Annabelle
Summary: We conducted an assay to compare the catalytic activity on starch of BBa_K23006 clones with 1% amylase solution. Results are recorded in 3 days with the help of iodine solution.

Purpose

Team Edinburgh conducted 2 iodine assays to compare the catalytic activity of BBa_K23006 colonies with a negative control and a known control PlacLacZ-bglX, which proved the ability of malS to degrade starch. Therefore, we undertook the experiment by comparing the catalytic activity of BBa_K23006 on starch with a positive control, 1% amylase solution.

Methods

We transferred a spot of clone of BBa_K23006 and a spot of 1% amylase on opposite sides of the starch agar plate. The cells were incubated for three days at 37℃. Every day, we flooded the plate with iodine, and measured the diameter of clear zone formed by the two samples respectively.
The protocol can be found in our wiki page: https://2019.igem.org/Team:Hong_Kong_UCCKE/Contribution

Results

Day 1 Day 2 Day 3
T--Hong_Kong_UCCKE--charac_2.jpg T--Hong_Kong_UCCKE--charac_3.jpg T--Hong_Kong_UCCKE--charac_1.jpg

1% amylase solution(+ control) added on the top, clone of BBa_K23006 in the bottom

T--Hong_Kong_UCCKE--charac_4.jpg

Graph 1.The diameter of clear zone of α-amylase and 1% amylase

From the results, a clear zone and growth of halos around the clone can be observed under iodine solution, which corresponds with the former conclusion that malS can degrade starch. In comparison, 1% amylase solution showed a greater initial starch degradation amount. Yet it’s slope of diameter of clear zone almost levels off in day 3, which suggests that the rate of digestion slows down with time. In contrast, the clones showed a steeper increase in the diameter of clear zone from Day 2 to 3. This can be explained by the continuous production of malS which results in a continuous digestion of starch in the long run.

VIT_Vellore Characterization: Activity

Methods

After preparing competent cells and transforming them, we let the culture incubate at 37C overnight. The next day, we lysed the cells using ultrasonication, spun it down to remove the debris, and used 0.5ml of the lysate for our experiments. DNS assay enzyme incubation conditions were changed as required.

Results and Interpretation

VIT_Vellore Characterization: Expression

Methods

Cell lysate was obtained and were incubated in various temperature and adjusted the lysate solution pH to the required amounts. To these solutions DNS assay was performed. For more info, look at our characterization page (https://2019.igem.org/Team:VIT_Vellore/Characterization).


Media optimization: pH


pH | O.D. | Activity
3 0.4352 36.342
4 0.5796 48.375
5 0.6756 56.375
6 0.6532 54.508
7 0.7717 64.383
8 0.5344 44.608
9 0.2971 24.333



T--VIT_Vellore--charPh.png


Observations and Inference
As expected, 7 is the optimum pH for amylase production.



Media optimization: Nitrogen source


S.no | Nitrogen Source | Activity
1 Yeast extract 1.633
2 Malt extract 0.908
3 Beef extract 14.492
4 Peptone 1.183



T--VIT_Vellore--charNitrogen.png


Observations and Inference
As we can clearly see, beef extract is the most optimum nitrogen source for amylase expression.




Media optimization: Carbon source



S.no | Carbon Source | Activity
1 Dextrose 0.433
2 Starch 3.591
3 Sucrose 7.483
4 Fructose 4.867



T--VIT_Vellore--charCarbon.png


Observations and Inference
We can thus conclude that Sucrose is the optimum carbon source for amylase expression.




Results and Interpretation