Expery Omollo, PhD

Damon Runyon Postdoctoral Fellow · MIT

I am a Biochemist and Systems Biologist studying how bacteria regulate gene expression by coordinating transcription, translation, and mRNA degradation.

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About

I am a Damon Runyon Postdoctoral Fellow in Gene-Wei Li's lab in the Department of Biology at MIT and HHMI. I joined the lab in 2024, where my research focuses on bacterial gene expression. Specifically, I use in vivo assays to monitor transcription, translation, and mRNA decay as they occur simultenously inside cells.

I completed my PhD in Biochemistry at the University of Wisconsin-Madison in 2023 in Robert Landick's lab. During my doctoral work, I used in vitro biochemical assays and cryo-electron microscopy (cryo-EM) to study how elongating RNA polymerase pauses and terminates transcription, and how transcription factors regulate these processes.

I obtained my BS in Biochemistry and Molecular Biology from Michigan State University in 2020. As an undergraduate, I worked with Lisa Lapidus and Lisa Tiemann to study the nucleation and folding kinetics of amyloid-beta monomers, with the goal of understanding early events in amyloid fibril formation in Alzheimer's disease.

Additional details about these projects are provided in the Research section.

Research

Transcription-Translation Coupling

In bacteria, transcription, translation, and mRNA degradation occur simultaneously and are tightly interconnected.

This organization enables rapid regulation of gene expression, but also complicates efforts to understand how individual processes influence one another inside the cell.

My research focuses on measuring these processes directly in living bacterial cells using quantitative in vivo approaches. By examining transcription, translation, and mRNA decay together rather than in isolation, my work seeks to establish general principles for how gene expression is regulated at multiple levels in bacteria.

Regulation of RNA polymerase elongation by NusG

NusG is universally conserved, but its function is not. My work, published in Molecular Cell (2023), examines how the same trancription factor produces opposite outcomes in different bacterial species.

During transcription elongation, RNA polymerase transitions between an active elongating state, and an inactive paused state.

While in elemental paused state, RNA polymerase pausing can be further stabilized by formation of a pause hairpin inside the exit channel.

Our findings showed that NusG shifts the balance between active and paused RNA polymerase depending on the species.

In Mycobacterium tuberculosis, NusG stabilizes a paused RNAP whereas in E. coli, it stabilizes active elongation.

These results provide a blueprint for drug design against Mycobacterium tuberculosis NusG.

Mechanism of intrinsic transcription termination

How does RNA polymerase know when to stop transcription? My work, published in Nature (2023), provides structural snapshots of intrinsic transcription termination across bacterial RNA polymerases.

During transcription elongation, RNA polymerase gets a signal to slow down (pause momentarily) at U7 and U8 of the uracil tract.

This pre-termination pausing allows the nascent RNA to fold onto itself and form secondary structures.

Once RNA polymerase is paused, the exit channel widens to accomodate the nucleating terminator hairpin. This causes RNAP to swivel.

For RNA to be released, the terminator hairpin has to complete forming, which is only possible after the -10 and -9 bases in the upstream DNA bubble rewind. These two processes happen concurrently.

After terminator hairpin completion, RNA is released first and the binary RNAP-DNA complex survives.

This is consistent with biochemical evidence that shows terminated RNAP can remain associated with and slide on DNA after RNA release.

Kinetics of Amyloid-β monomer folding and fibril nucleation

How do disease-associated proteins begin to misfold and aggregate?

Protein misfolding and aggregation underlie many neurodegenerative diseases, yet the earliest steps of these processes are difficult to observe experimentally.

In this project, I studied the folding and nucleation kinetics of amyloid-β, a peptide central to Alzheimer's disease pathology.

Using cysteine-mediated quenching of intrinsic tryptophan autofluorescence, I monitored conformational changes in denatured amyloid-β monomers in real time. This approach enabled quantitative measurements of early folding and nucleation events that precede fibril formation.

Together, this work provided insight into the initial molecular steps that drive amyloid aggregation and established experimental strategies for probing protein folding kinetics at early stages.

Publications

1. Battaglia R.O., Ermis E., Omollo E.O., Li GW. (2026). The definining features of intrinsic transcription terminators. In preparation.
2. Delbeau M.*, Omollo E.O.* et al. (2023). Structural and functional basis of the universal transcription factor NusG pro-pausing activity in Mycobacterium tuberculosis . Molecular Cell. *Equal contribution.
3. You L., Omollo E.O., et al. (2023). Structural basis for intrinsic transcription termination . Nature.
4. Omollo E.O. (2023). Role of NusG, NusA, and nascent RNA structures in regulating transcription elongation and termination . PhD disertation. University of Wisconsin-Madison.

Education

University of Wisconsin–Madison
PhD in Biochemistry
2020 - 2023

Michigan State University
BS in Biochemistry & Molecular Biology/Biotechnology
Graduated with Honors
2016 - 2020

Contact

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