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1. No Evidence of Copy Number Variation in Acidic Mammalian Chitinase Genes (CHIA) in New World and Old World Monkeys

   https://doi.org/10.1007/s10764-018-0037-7  

   Janiak, Mareike C (January 2018, International journal of primatology)

   Copy number variation may be the most common form of structural genetic variation in the genome. Numerous studies have shown that gene copy number variation can correlate with phenotypic variation, where higher copy numbers correspond to increased expression of the protein and vice versa. Examples include some digestive enzyme genes, where variation in copy numbers and protein expression may be related to dietary differences. Increasing the expression of a digestive enzyme through higher gene copy numbers may thus be a potential mechanism for altering an organism’s digestive capabilities. I investigated copy number variation in genes coding for acidic mammalian chitinase, a chitinolytic digestive enzyme that may be used for the digestion of insect exoskeletons, in nonhuman primates with varying levels of insect consumption. I hypothesized that CHIA copy number correlates positively with level of insectivory, predicting higher copy numbers in more insectivorous primates. I assessed copy number variation with the QuantStudio 3D digital PCR platform, in a comparative sample of Old World and New World primate species (N = 10 species, one or two individuals each). Contrary to my prediction, no evidence of copy number variation was found and all species tested had two gene copies per diploid genome. These findings suggest that if acidic mammalian chitinase expression varies according to insect consumption in primates, it may be up- or downregulated through another mechanism. 

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2. Internal models in control, bioengineering, and neuroscience

   Bin.M.; Huang, J.; Isidori, A.; Marconi, L.; Mischiati, M.; E. D. Sontag, E.D. (October 2021, Annual review of control robotics and autonomous systems)

   Cells respond to biochemical and physical internal as well as external signals. These signals can be broadly classified into two categories: (a) ``actionable'' or ``reference'' inputs that should elicit appropriate biological or physical responses such as gene expression or motility, and (b) ``disturbances'' or ``perturbations'' that should be ignored or actively filtered-out. These disturbances might be exogenous, such as binding of nonspecific ligands, or endogenous, such as variations in enzyme concentrations or gene copy numbers. In this context, the term robustness describes the capability to produce appropriate responses to reference inputs while at the same time being insensitive to disturbances. These two objectives often conflict with each other and require delicate design trade-offs. Indeed, natural biological systems use complicated and still poorly understood control strategies in order to finely balance the goals of responsiveness and robustness. A better understanding of such natural strategies remains an important scientific goal in itself and will play a role in the construction of synthetic circuits for therapeutic and biosensing applications. A prototype problem in robustly responding to inputs is that of ``robust tracking'', defined by the requirement that some designated internal quantity (for example, the level of expression of a reporter protein) should faithfully follow an input signal while being insensitive to an appropriate class of perturbations. Control theory predicts that a certain type of motif, called integral feedback, will help achieve this goal, and this motif is, in fact, a necessary feature of any system that exhibits robust tracking. Indeed, integral feedback has always been a key component of electrical and mechanical control systems, at least since the 18th century when James Watt employed the centrifugal governor to regulate steam engines. Motivated by this knowledge, biological engineers have proposed various designs for biomolecular integral feedback control mechanisms. However, practical and quantitatively predictable implementations have proved challenging, in part due to the difficulty in obtaining accurate models of transcription, translation, and resource competition in living cells, and the stochasticity inherent in cellular reactions. These challenges prevent first-principles rational design and parameter optimization. In this work, we exploit the versatility of an Escherichia coli cell-free transcription-translation (TXTL) to accurately design, model and then build, a synthetic biomolecular integral controller that precisely controls the expression of a target gene. To our knowledge, this is the first design of a functioning gene network that achieves the goal of making gene expression track an externally imposed reference level, achieves this goal even in the presence of disturbances, and whose performance quantitatively agrees with mathematical predictions. 

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3. Dynamic Control of Gene Expression with Riboregulated Switchable Feedback Promoters

   https://doi.org/10.1021/acssynbio.1c00015  

   Glasscock, Cameron J.; Biggs, Bradley W.; Lazar, John T.; Arnold, Jack H.; Burdette, Lisa A.; Valdes, Aliki; Kang, Min-Kyoung; Tullman-Ercek, Danielle; Tyo, Keith E.; Lucks, Julius B. (April 2021, ACS Synthetic Biology)

   null (Ed.)

   One major challenge in synthetic biology is the deleterious impacts of cellular stress caused by expression of heterologous pathways, sensors, and circuits. Feedback control and dynamic regulation are broadly proposed strategies to mitigate this cellular stress by optimizing gene expression levels temporally and in response to biological cues. While a variety of approaches for feedback implementation exist, they are often complex and cannot be easily manipulated. Here, we report a strategy that uses RNA transcriptional regulators to integrate additional layers of control over the output of natural and engineered feedback responsive circuits. Called riboregulated switchable feedback promoters (rSFPs), these gene expression cassettes can be modularly activated using multiple mechanisms, from manual induction to autonomous quorum sensing, allowing control over the timing, magnitude, and autonomy of expression. We develop rSFPs in Escherichia coli to regulate multiple feedback networks and apply them to control the output of two metabolic pathways. We envision that rSFPs will become a valuable tool for flexible and dynamic control of gene expression in metabolic engineering, biological therapeutic production, and many other applications. 

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4. Self-cleaving peptides for expression of multiple genes in Dictyostelium discoideum

   https://doi.org/10.1371/journal.pone.0281211  

   Zhu, Xinwen; Ricci-Tam, Chiara; Hager, Emily R.; Sgro, Allyson E. (March 2023, PLOS ONE)

   Gasset, Maria (Ed.)

   The social amoeba Dictyostelium discoideum is a model for a wide range of biological processes including chemotaxis, cell-cell communication, phagocytosis, and development. Interrogating these processes with modern genetic tools often requires the expression of multiple transgenes. While it is possible to transfect multiple transcriptional units, the use of separate promoters and terminators for each gene leads to large plasmid sizes and possible interference between units. In many eukaryotic systems this challenge has been addressed through polycistronic expression mediated by 2A viral peptides, permitting efficient, co-regulated gene expression. Here, we screen the most commonly used 2A peptides, porcine teschovirus-1 2A (P2A), Thosea asigna virus 2A (T2A), equine rhinitis A virus 2A (E2A), and foot-and-mouth disease virus 2A (F2A), for activity in D. discoideum and find that all the screened 2A sequences are effective. However, combining the coding sequences of two proteins into a single transcript leads to notable strain-dependent decreases in expression level, suggesting additional factors regulate gene expression in D. discoideum that merit further investigation. Our results show that P2A is the optimal sequence for polycistronic expression in D. discoideum , opening up new possibilities for genetic engineering in this model system. 

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5. Enhancing the production of recombinant adeno‐associated virus in synthetic cell lines through systematic characterization

   https://doi.org/10.1002/bit.28562  

   Lu, Min; Lee, Zion; Lin, Yu‐Chieh; Irfanullah, Ibrahim; Cai, Wen; Hu, Wei‐Shou (January 2024, Biotechnology and Bioengineering)

   Abstract Recombinant adeno‐associated virus (rAAV) is among the most commonly used in vivo gene delivery vehicles and has seen a number of successes in clinical application. Current manufacturing processes of rAAV employ multiple plasmid transfection or rely on virus infection and face challenges in scale‐up. A synthetic biology approach was taken to generate stable cell lines with integrated genetic modules, which produced rAAV upon induction albeit at a low productivity. To identify potential factors that restrained the productivity, we systematically characterized virus production kinetics through targeted quantitative proteomics and various physical assays of viral components. We demonstrated that reducing the excessive expression of gene of interest by its conditional expression greatly increased the productivity of these synthetic cell lines. Further enhancement was gained by optimizing induction profiles and alleviating proteasomal degradation of viral capsid protein by the addition of proteasome inhibitors. Altogether, these enhancements brought the productivity close to traditional multiple plasmid transfection. The rAAV produced had comparable full particle contents as those produced by conventional transient plasmid transfection. The present work exemplified the versatility of our synthetic biology‐based viral vector production platform and its potential for plasmid‐ and virus‐free rAAV manufacturing. 

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