Kenric J. Hoegler scite author profile

Hecht

2016

Protein Science

To survive environmental challenges, biological systems rely on proteins that were selected by evolution to function in particular cellular and conditional settings. With the advent of protein design and synthetic biology, it is now possible to construct novel proteins that are not biased by eons of selection in natural hosts. The availability of these sequences prompts us to ask whether natural biological organisms can use na€ ıve-non-biological-proteins to enhance fitness in stressful environments. To address this question, we transformed a library of DNA sequences encoding~1.5 3 10 6 binary patterned de novo proteins into E. coli, and selected for sequences that enable growth in concentrations of copper that would otherwise be toxic. Several novel sequences were discovered, and one of them, called Construct K (ConK), was studied in detail. Cells expressing ConK accumulate approximately 50% less copper than control cells. The function of ConK does not involve an oxidase, nor does it require two of the best characterized copper efflux systems. However, the ability of ConK to rescue cells from toxic concentrations of copper does require an active proton motive force. Further selections for growth in higher concentrations of copper led to the laboratory evolution of variants of ConK with enhanced levels of activity in vivo. These studies demonstrate that novel proteins, unbiased by evolutionary history in the natural world, can enhance the fitness of biological systems.Synopsis: Living systems evolve to adapt to potentially lethal environmental changes. This normally involves repurposing existing genetic information (i.e. sequences that were selected by billions of years of evolution). Here we show that a completely de novo protein, not derived from nature, can enable E. coli cells to grow in otherwise toxic concentrations of copper, demonstrating that living systems also have the capacity to incorporate and protopurpose entirely novel genetic information.

Unevolved De Novo Proteins Have Innate Tendencies to Bind Transition Metals

Wang

Hecht

2019

Life

Life as we know it would not exist without the ability of protein sequences to bind metal ions. Transition metals, in particular, play essential roles in a wide range of structural and catalytic functions. The ubiquitous occurrence of metalloproteins in all organisms leads one to ask whether metal binding is an evolved trait that occurred only rarely in ancestral sequences, or alternatively, whether it is an innate property of amino acid sequences, occurring frequently in unevolved sequence space. To address this question, we studied 52 proteins from a combinatorial library of novel sequences designed to fold into 4-helix bundles. Although these sequences were neither designed nor evolved to bind metals, the majority of them have innate tendencies to bind the transition metals copper, cobalt, and zinc with high nanomolar to low-micromolar affinity.

Artificial Gene Amplification in Escherichia coli Reveals Numerous Determinants for Resistance to Metal Toxicity

Hecht

2018

J Mol Evol

When organisms are subjected to environmental challenges, including growth inhibitors and toxins, evolution often selects for the duplication of endogenous genes, whose overexpression can provide a selective advantage. Such events occur both in natural environments and in clinical settings. Microbial cells—with their large populations and short generation times—frequently evolve resistance to a range of antimicrobials. While microbial resistance to antibiotic drugs is well documented, less attention has been given to the genetic elements responsible for resistance to metal toxicity. To assess which overexpressed genes can endow gram-negative bacteria with resistance to metal toxicity, we transformed a collection of plasmids overexpressing all E. coli open reading frames (ORFs) into naive cells, and selected for survival in toxic concentrations of six transition metals: Cd, Co, Cu, Ni, Ag, Zn. These selections identified 48 hits. In each of these hits, the overexpression of an endogenous E. coli gene provided a selective advantage in the presence of at least one of the toxic metals. Surprisingly, the majority of these cases (28/48) were not previously known to function in metal resistance or homeostasis. These findings highlight the diverse mechanisms that biological systems can deploy to adapt to environments containing toxic concentrations of metals.

Targeting Olfactory Bulb Neurons Using Combined <em>In Vivo</em> Electroporation and Gal4-Based Enhancer Trap Zebrafish Lines

Distel

Köster

et al. 2011

JoVE

In vivo electroporation is a powerful method for delivering DNA expression plasmids, RNAi reagents, and morpholino anti-sense oligonucleotides to specific regions of developing embryos, including those of C. elegans, chick, Xenopus, zebrafish, and mouse 1 . In zebrafish, in vivo electroporation has been shown to have excellent spatial and temporal resolution for the delivery of these reagents [2][3][4][5][6][7] . The temporal resolution of this method is important because it allows for incorporation of these reagents at specific stages in development. Furthermore, because expression from electroporated vectors occurs within 6 hours 7

Targeting the Zebrafish Optic Tectum Using In Vivo Electroporation

Cold Spring Harb Protoc

Horne²

2010

INTRODUCTIONIn vivo electroporation is a method for delivery of plasmids and other oligonucleotide reagents that offers precise temporal control. In zebrafish, in vivo electroporation is particularly well-suited to delivering green fluorescent protein (GFP) expression vectors to the developing central nervous system. This protocol describes a modification of in vivo electroporation that can be used to specifically target the developing optic tectum of zebrafish embryos beginning at 24 h post-fertilization (hpf). The electroporation electrodes required for this approach can be constructed easily from relatively inexpensive materials. Microinjection of plasmid DNA to the midbrain ventricle followed by precise positioning of the electroporation electrodes allows for the targeting of developing neurons in only one hemisphere of the optic tectum. Using this protocol, the optic tectum can be effectively targeted in a high percentage (79%) of expressing embryos. This method can also be used to simultaneously deliver expression vectors and loss-of-function reagents, which can provide precise temporal control of the knockdown of gene function.