While working with the cyanobacterium Synechococcus elongatus UTEX 2973 we noticed a lack of standardization in the field of Synthetic Biology very quickly. To tackle this huge problem, we decided to focus as one of our main goals on standardization to make scientific results more comparable. Therefore, we worked on standardizing light measurement, cultivating parameters (temperature, CO2, rpm, …) and the cultivation media for cyanobacteria, especially UTEX 2973.

During the theoretical planning of our project we contacted scientists in research and industry that are specialists for cyanobacteria. As a result, Prof. Dr. Annegret Wilde (Institute of Biology, Albert-Ludwigs-University Freiburg) answered our call and was very interested in advising us in regards to our projects. In order to give us an introduction to the handling of cyanobacteria, she invited us to her institute at the University of Freiburg on 5th and 6th June 2019. In a short and focused internship we were able to quickly gain a set of core competencies regarding sterile inoculation, streaking of cyano cultures and further information regarding the cultivation conditions which we applied to our strain.

In addition, we also learned that the measurement of light intensity is an important topic. There is a variety of measuring instruments and different methods for each, which means that information on light intensities should be viewed with caution. For cyanobacteria such as Synechococcus elongatus UTEX 2973 light intensity plays a decisive role, which is why we analysed differences between a variety of instruments and methods to establish a standard for light measurement based on our results. (Light measurement).

In further discussions about our Marburg Collection 2.0 we were recommended to take a very close look at terminators as they oddly enough have an effect on the transcription of upstream genes. As a result, we decided to take a closer look at that and investigated their effects. We thank Professor A. Wilde for her input, her invitation to Freiburg and her recommendations that guided us in our project. (Terminators)

“My major bottleneck is colony picking.” - Davide De Lucrezia, Managing Director of Doulix

The vision of automating colony picking has existed now for many years. Big companies like Tecan, Singer Instruments or Hudson Robotics invented robots those are able to identify and pick colonies. The problem is that they cost a fortune, starting at 50,000€ up to 100,000€ or even more. Although it is highly desired, a low cost solution is still missing for this tedious task. Start-ups like Doulix are currently automating such workflows in their laboratories, but they do not have the funds to finance a state-of-the-art colony picking robot. By now every single step has to be performed manually, draining resources from other departments, which actually should be paid more attention to. “Colony picking is a bottleneck in every of part our workflows” says Davide De Lucrezia, the founder and managing director of Doulix. Doulix focuses on developing innovative technologies for scientists to simplify their work, especially in the field of synthetic biology, and they are currently planning on establishing Opentrons OT-2 in their lab to automate the most part of their workflows.

During an online conference with Davide De Lucrezia, Sota Hirano, and Alessandro Filisetti from Doulix, Davide suggested that turning the OT-2 into a colony picker as a project would be really interesting. To have a fully trained, ready to use package to turn the OT-2 into a colony picker would enhance the workflow at Doulix tremendously. Nevertheless, to suit the user needs as well as to get this job done in the spirit of Opentrons, installing the needed add-ons should be as modular and flexible as possible and designed so that “even a biologist” without technical knowledge or programming would be able to install and use them.

That is where our team came into play. We decided to take this advice to our heart and started to work out what was needed to turn the OT-2 into a fully automated colony picking robot.

One of the first big design questions was whether we wanted to hardcode an image recognition software for the colony detection or if it was a better choice to train a data hungry but - given proper and enough training data - more accurate and scalable artificificial intelligence based colony detection. Kristin Ellis, the director of strategic initiatives at Opentrons referred us to Keoni Gandall from Stanford, a well known tinker of the OT-2 for more unconventional applications. He is building a colony picking system himself, however he chose not to rely on an AI. He recommended us to go with AI he thinks his approach is very prone to changes in parameters. If many different users want to utilize the same system, a flexible software is required that can take environmental changes into account. We decided to opt for maximum flexibility by working with an AI.

Now that we had an idea of the required software we started to design modular hardware to overcome potential problems in a fully automated workflow in the OT-2 (see Colony Picking and Hardware). To illuminate the agar plates in the right way without any distortions we engineered a light table that distributes light equally over the plate.

To give an “eyesight” to the OT-2 we mounted a Raspberry Pi 4 and an ArduCAM on the OT-2 arm. For a better accessibility we created our Graphical User Interface for Directed Engineering (GUIDE). We designed our GUI in a way that will enable every user to train their own AI with their own training data set so that the AI can be optimized for each specific situation. Moreover the GUI will also enable access to users that are not trained in computer/ software engineering.

Now that we gave our robot the ability to see, to think and to communicate with us, nothing stood in the way of our own colony picker. We are now able to turn the OT-2 into a colony picker costing below $300 (LINK TO COLONY PICKING COST REPORT TABLE). Moreover, for companies, teams or groups who do not own an OT-2 yet, we were able to reduce the costs for purchasing a colony picker by 90-95%, compared to the listed market prices for traditional colony pickers.

Finally we contacted Doulix the second time to discuss in more details about our project. They approved it and gave further suggestions such as “live training” so that the AI will continue to learn as it is being used to pick up colonies. Not only will this improve the AI gradually but it will also adapt to the specific needs of each user. This leaves a lot of room to improve the project in the future.

During our visit at the Cyano Conference 2019 in Tübingen we recognized a need for standardization in this community (link expert talk). We asked people to send us their BG-11 recipes and surprisingly received several different versions. The community at the conference is aware of the missing standardization and we received very positive feedback for our efforts. Fixed standards are essential for reproducibility of results, especially the preparation of media and buffers but no one is investing time to set a standard. After the cyano conference we stayed in contact with Nicolas Schmelling, coordinator of the bachelor program at CEPLAS. During his PhD he was working on establishing more standards in the cyano community. He tried to establish protocols and collected different methods and recipes to establish a standard for all.

After he clarified us the importance of comparable media in context of standards, we started to collect different BG11 recipes and compared them in growing experiments. The following graphic represents our results and shows the impact of different recipes for media.
In our experiment we could show that there is a significant difference between the different BG11 recipes despite their relative similarity. During our complete project we were working on the standardization for light intensity, media and different cultivating parameters (Link growth curve and measurement). We made it our destiny to make the first step into the beginning of standardization in the cyano community by providing/establish Synechococcus elongatus with standardized parameters. We were able to find the optimal growing conditions for UTEX 2973 and could show that creating a standard in measurement and methods is really important to have comparable results. With our project we hope that we could set a first step into standardization, so that the future cyano community will have standardized and comparable results.

From September 11th to September 13th we attended the CYANO Conference 2019 in Tuebingen funded by the VAAM (Vereinigung für Allgemeine und Angewandte Mikrobiologie). During the poster sessions we took the chance to present our project and how we revolutionize the upcoming work on phototrophic organisms. Therefore, we gained great feedback from the participants, which showed huge interest in our toolbox specified for cyanobacteria. Our Synthetic Biology approaches encountered the thinking of classical cyanobacterial research which lead to interesting discussions from which we gained a lot of input. Furthermore, the leading experts of cyanobacteria offered talks where we learned how to modify working on Synechococcus elongatus.

We were especially interested in the discussions about methods. We soon realized that the cyanobacterial scene has no standardized protocols for daily laboratory practices and they are also aware of that issue. This started with debates about the media composition of BG-11 media but also concerned issues like standardized evaluation of light conditions. With our project for standardizing growth conditions and providing a part collection we tackle these major issues for scientists studying phototrophic organisms.

Caused by our thrive for standardization as synthetic biologist, we decided to make a small study in the cyano community about standards in handling of cyanobacteria [link standards in cyano community]. Due to the results we know about the importance of our intention and will take the first step for creating a standard for working with cyanobacteria in synthetic biology.

While diving deeper and deeper into the ocean of possibilities that cyanobacteria have to offer we noticed a few inconsistencies in literature.

BG11 media is commonly used in cyanobacterial research, but the exact composition seemed to be different across every second paper we read. Optical densities are more frequently measured at a wavelength of 730nm, though 750nm seems to be the better choice. For Synechococcus elongatus UTEX 2973 the “optimal growth conditions” according to literature are often quite different; some state 38°C and 500µE at a CO2 level of 3% fits best, others prefer 41°C and 1500µE with 5% CO2 concentration. But how are these light intensities measured? With a planar device or a spherical one? We have not seen this being explained in literature.

As all of these things have an incredibly huge impact on various different experiments we saw the need to find a standardized answer to our questions, reaching out to as many experts in this field as we could reach - whether it was industry or research. One of the leading laboratories working with cyanobacteria is the Golden Lab of the UC San Diego. Susan Golden and her husband James W. Golden have both been working with cyanobacteria for quite some time, now with a stronger focus on their use for industrial purposes. We set up a Skype call with them, but sadly Susan Golden was not able to join us on short notice.

During our talk with James W. Golden we laid open our concerns about the cyanobacterial community and he quickly supported our train of thoughts, as he himself noticed a lack of standardization. He assured us that this is a hot topic in this field of research, as many do not seem to care enough about the reproducibility of their data and encouraged us to continue with our efforts.

More accurately, he talked with us about why he thinks there is still no clear decision on whether to measure optical densities at 730nm or 750nm: It might be a technical problem, as many photometers are simply not able to measure wavelengths of 750nm. In contrast, he mentioned that 750nm would be the more optimal way, as it proves to minimize absorbance from pigments in cyanobacterial cells, presenting more accurate data. This confronted us with a conflicting decision: Would it be better to use the more accurate 750nm or 730nm, as the latter would allow more labs all over the world to measure in the same way.

This was one of the key factors that led us to measure the whole spectrum of our cultures for our growth curves, as this would provide a larger dataset, awarding us not just with 730nm and 750nm data, but also the possibility to check if the spectrum shows normal behavior, from which one could conclude how healthy the cultures are.

Another important issue we were able to discuss with Professor Golden is the composition of BG11 media. While working in our own lab we already got the notion that not all BG11 media are prepared in the same way, which is the reason why we kindly asked other researchers - like James Golden - to send us their recipes. In order to compare the various ways the BG11 media can be prepared, we tried those recipes and measured growth curves to find the perfect fit.

It was clear that the growth of our cultures was comparably fast at the beginning no matter what media was used, but one of them stood out: BGM - it enabled faster growth at higher ODs, allowing cultures to reach double the OD of other cultures after the same time.

We are certain that having the same ideal medium throughout different cyano labs is not just elemental for optimal growth, but also vital for comparability, as trying to reproduce the growth conditions of papers can be quite tricky when it is not clear what exact medium was used and how it was prepared.

This problem, as stated before, applies not only to media, but also for the measurement of light intensities. In the beginning we measured the light intensity of our incubators with a planar measurement device - the only one available for us. Talking to James Golden we realized that we should try to get hold of a spherical measurement device, as he assured us that this is the way to generate more accurate data, leading to a more reproducible setup - exactly what we were aiming for.

After acquiring such a device, we again implemented the feedback we got and measured growth curves. One with cultures at 1500µE measured with a spherical device and one with 1500µE measured with a planar device, where the measured intensities were converted to theoretically spherical values with a conversion chart offered to us by Prof. Dr. Annegret Wilde from the University of Freiburg.

These experiments were a huge step in our project, as they heavily influenced the way we cultured our cyanobacteria, not only drastically improving their growth, but also clearly demonstrating how flawed certain measurements can be. We would never have been able to reach the fast doubling times we achieve now without this crucial input and as this will be the case for others too, we made it our mission to keep on stressing the importance of this way of measurement whenever we reach out to the scientific community. Again, thank you very much Prof. Dr. James W. Golden for your invaluable contribution!

“A colony picking module for the OT-2 will be a great help” - Keoni Gandall

We started with the colony picking project back in December 2018. Since from the beginning we know that we have to involve Opentrons in the conversation, because we are working on a colony picking extension module for the OT-2. We contacted Kristin Ellis from Opentrons and this turned out to be the right approach for us, because Kristin is very familiar with the OT-2 community. She has been a big help to us ever since by bridging us with Opentrons’ technical experts or other kinds of resources. At the time Kristin told us that colony picking is a big topic in the OT-2 community and gave us a few contacts, among them: Keoni Gandall.

Keoni Gandall is a bio-hacker who is determined to open source systems in Synthetic Biology. He is an avid user of the OT-2 because of the philosophy that OT-2 embodies: an affordable, and open-source pipetting robot. Colony picking is a big part of a cloning workflow, whose automation involves a lot of cost. There is yet to be an affordable solution for colony picker, and Keoni believes that OT-2 has the potential to fill this gap. When we mentioned our colony picking project to Keoni, it directly resonated with him, and this gave us an extra justification for our project: this is what the community wants and needs. We listened to the community and let it shape our project. Since then we have been keeping in touch with Keoni and exchanging tips and tricks for the OT-2.

When the iGEM year started, we thought about how we could ease the work in the lab using our OT-2. We decided automating the cloning process would be a great idea and soon got into contact with Promega to tell them about our vision. Margarete Schwarz, area manager of southwest germany, and Nans Bodet, a Field Support Scientist (FSS) from the automation department at Promega, were both convinced that the automation of the cloning workflow would be a challenge, but with creativity and some work it would be a major breakthrough and a great tool for everyone with access to an OT-2.

In a skype call both agreed that they would love to see Promegas Wizard® MagneSil® Plasmid Purification System integrated into the workflow, being Promegas very first automated workflow in Opentrons OT-2 and the first protocol for plasmid purification in a large collection of Opentrons protocols. Promega covered our costs in terms of kits we needed for the protocols so we could focus on optimizing the workflow.

We performed the plasmid purification a few times manually, so we would get familiar with the whole workflow and get a feeling where problems in the automated process could arise. We were in regular contact with Nans and he gave great advice on how to automate the shaking process in the OT-2 and that we would need the 8-channel pipette to scale up the number of samples that could be handled with our protocol. For the shaker he told us to get in contact with QInstruments, a company which designs and builds small shakers that are simultaneously capable of heating and cooling the samples. Thanks to recommendations from Nans a member of their support team, Ralf Paetzold, wrote us back and kindly helped us to secure a permanent loan for the BioShake D30-T elm back in June. Through a grant our team won, we were able to purchase the 8-channel pipette arm.

When the shaker arrived, we realized it was a bit bigger than the SPS format for modules in the OT-2 and needed stabilizing support. We designed an adapter for the shaker that is robust enough to withstand the forces that occur during intense shaking (Hardware).

Furthermore, Opentron is currently rolling out a major update from their OT-2 3.9 to 4.0 firmware that included a lot of paradigm change. This changed the way had to define our labware and we ended up defining our shaker module coordinates as a Python dictionary importable via a .json file. After some calibrations with our OT-2 we were trying to finish the protocol; thankfully Opentron customer service was patient with us. They told us how to calibrate the OT-2 directly via the terminal because we had some difficulties.

In late august Margarete Schwarz paid us a visit, curious about how the plasmid purification with Promegas Kit would perform and look like in the OT-2. We were also asked to write a blog post about our thoughts and progress on automating plasmid purification for the Promega Connections Blog.

By the end of this iGEM year we were able to develop a working protocol for the single-channel pipette for up to 6 samples, as well as a protocol for the 8-channel pipette for up to 48 samples.

We are very happy about this fruit bearing interaction, we think both sides profited from this cooperation in a big way.