specialized cell
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2021 ◽  
Author(s):  
Tianchi Chen ◽  
Muhammad Ali Al-Radhawi ◽  
Christopher Voigt ◽  
Eduardo Sontag

A design for genetically-encoded counters is proposed via repressor-based circuits. An N-bit counter reads sequences of input pulses and displays the total number of pulses, modulo 2^N. The design is based on distributed computation, with specialized cell types allocated to specific tasks. This allows scalability and bypasses constraints on the maximal number of circuit genes per cell due to toxicity or failures due to resource limitations. The design starts with a single-bit counter. The N-bit counter is then obtained by interconnecting (using diffusible chemicals) a set of N single-bit counters and connector modules. An optimization framework is used to determine appropriate gate parameters and to compute bounds on admissible pulse widths and relaxation (inter-pulse) times, as well as to guide the construction of novel gates. This work can be viewed as a step toward obtaining circuits that are capable of finite-automaton computation, in analogy to digital central processing units.


2021 ◽  
Author(s):  
Adam Rosenthal ◽  
Ryan McNulty ◽  
Duluxan Sritha ◽  
Shichen Liu ◽  
Sahand Hormoz

Abstract Clonal bacterial populations rely on transcriptional variation to differentiate into specialized cell states that increase the community’s fitness. Such heterogeneous gene expression is implicated in many fundamental microbial processes including sporulation, cell communication, detoxification, substrate utilization, competence, biofilm formation, motility, pathogenicity, and antibiotic resistance1. To identify these specialized cell states and determine the processes by which they develop, we need to study isogenic bacterial populations at the single cell level2,3. Here, we develop a method that uses DNA probes and leverages an existing commercial microfluidic platform (10X Chromium) to conduct bacterial single cell RNA sequencing. We sequenced the transcriptome of over 15,000 individual bacterial cells, detecting on average 365 transcripts mapping to 265 genes per cell in B. subtilis and 329 transcripts mapping to 149 genes per cell in E. coli. Our findings correctly identify known cell states and uncover previously unreported cell states. Interestingly, we find that some metabolic pathways segregate into distinct subpopulations across different bacteria and growth conditions, suggesting that some cellular processes may be more prone to differentiation than others. Our high throughput, highly resolved single cell transcriptomic platform can be broadly used for understanding heterogeneity in microbial populations.


2021 ◽  
Author(s):  
Ryan McNulty ◽  
Duluxan Sritharan ◽  
Shichen Liu ◽  
Sahand Hormoz ◽  
Adam Z. Rosenthal

AbstractClonal bacterial populations rely on transcriptional variation to differentiate into specialized cell states that increase the community’s fitness. Such heterogeneous gene expression is implicated in many fundamental microbial processes including sporulation, cell communication, detoxification, substrate utilization, competence, biofilm formation, motility, pathogenicity, and antibiotic resistance1. To identify these specialized cell states and determine the processes by which they develop, we need to study isogenic bacterial populations at the single cell level2,3. Here, we develop a method that uses DNA probes and leverages an existing commercial microfluidic platform (10X Chromium) to conduct bacterial single cell RNA sequencing. We sequenced the transcriptome of over 15,000 individual bacterial cells, detecting on average 365 transcripts mapping to 265 genes per cell in B. subtilis and 329 transcripts mapping to 149 genes per cell in E. coli. Our findings correctly identify known cell states and uncover previously unreported cell states. Interestingly, we find that some metabolic pathways segregate into distinct subpopulations across different bacteria and growth conditions, suggesting that some cellular processes may be more prone to differentiation than others. Our high throughput, highly resolved single cell transcriptomic platform can be broadly used for understanding heterogeneity in microbial populations.


eLife ◽  
2020 ◽  
Vol 9 ◽  
Author(s):  
Sriram Varahan ◽  
Adhish Walvekar ◽  
Vaibhhav Sinha ◽  
Sandeep Krishna ◽  
Sunil Laxman

2020 ◽  
Vol 18 (5) ◽  
pp. 462-470 ◽  
Author(s):  
Jessica Heatlie ◽  
Vanessa Chang ◽  
Sandra Fitzgerald ◽  
Yohanes Nursalim ◽  
Kate Parker ◽  
...  

2020 ◽  
Vol 16 (7) ◽  
pp. e1008620 ◽  
Author(s):  
Eli J. Cohen ◽  
Daisuke Nakane ◽  
Yoshiki Kabata ◽  
David R. Hendrixson ◽  
Takayuki Nishizaka ◽  
...  

2020 ◽  
Vol 117 (26) ◽  
pp. 15332-15342 ◽  
Author(s):  
Natalie M. Clark ◽  
Adam P. Fisher ◽  
Barbara Berckmans ◽  
Lisa Van den Broeck ◽  
Emily C. Nelson ◽  
...  

Stem cells divide and differentiate to form all of the specialized cell types in a multicellular organism. In theArabidopsisroot, stem cells are maintained in an undifferentiated state by a less mitotically active population of cells called the quiescent center (QC). Determining how the QC regulates the surrounding stem cell initials, or what makes the QC fundamentally different from the actively dividing initials, is important for understanding how stem cell divisions are maintained. Here we gained insight into the differences between the QC and the cortex endodermis initials (CEI) by studying the mobile transcription factor SHORTROOT (SHR) and its binding partner SCARECROW (SCR). We constructed an ordinary differential equation model of SHR and SCR in the QC and CEI which incorporated the stoichiometry of the SHR-SCR complex as well as upstream transcriptional regulation of SHR and SCR. Our model prediction, coupled with experimental validation, showed that high levels of the SHR-SCR complex are associated with more CEI division but less QC division. Furthermore, our model prediction allowed us to propose the putative upstream SHR regulators SEUSS and WUSCHEL-RELATED HOMEOBOX 5 and to experimentally validate their roles in QC and CEI division. In addition, our model established the timing of QC and CEI division and suggests that SHR repression of QC division depends on formation of the SHR homodimer. Thus, our results support that SHR-SCR protein complex stoichiometry and regulation of SHR transcription modulate the division timing of two different specialized cell types in the root stem cell niche.


2020 ◽  
Vol 21 (6) ◽  
pp. 660-670 ◽  
Author(s):  
Domenick E. Kennedy ◽  
Michael K. Okoreeh ◽  
Mark Maienschein-Cline ◽  
Junting Ai ◽  
Margaret Veselits ◽  
...  

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