# Investigating Polymer Flipping and Lattice Disruptions in TELSAM-Facilitated Protein Crystallization

**Authors:** Ethan Noakes, MJ Pedroza Romo, Joseph Gonzalez, Alihi Keliiliki, Eli Anderson, James D Moody

PMC · DOI: 10.1063/4.0001141 · 2025-10-27

## TL;DR

This paper investigates how TELSAM polymers disrupt crystal lattices during crystallization and proposes a new device to reduce these disruptions.

## Contribution

A novel device is introduced to reduce polymer flipping and improve crystal quality in TELSAM-mediated crystallization.

## Key findings

- High R-values in structure solution suggest lattice disruptions in TELSAM-mediated crystals.
- Polymer flipping occurs in sequences of three or four normal polymers before flipping.
- A new device was developed to reduce flipping and improve crystal quality.

## Abstract

TELSAM, the sterile alpha motif (SAM) domain of the human translocation ETS leukemia protein (TEL), spontaneously forms 6-fold helical polymers at low pH. Previously, TELSAM was fused to the CMG2 vWA domain via a Threonine–Valine linker to create the 1TEL-TV-vWA construct. This construct was crystallized, mounted in-house, and analyzed using synchrotron X-ray diffraction. Despite successful crystallization, structure solution consistently yielded high R-values. Reciprocal lattice analysis revealed three domains, indicating a break in lattice periodicity. The observed intensity pattern—normal reflections at h-k=3n and streaky reflections at h-k=3n±1—suggests a unit cell shift equivalent to one-third of the P65 unit cell’s h-k length. This aligns with the polymer packing seen in the solved structure, where regular crystals show a repeating pattern of two normal polymers followed by a flipped one. The disrupted lattice shows a shift due to sequences of three or four normal polymers before the next flipped polymer. These flips occur because TELSAM polymers form crystal contacts independent of orientation, a known behavior in TELSAM-mediated crystallization. To address this lattice disruption and improve crystal quality, we have developed a novel device aimed at reducing polymer flipping during crystallization.

## Linked entities

- **Proteins:** ETV6 (ETS variant transcription factor 6)
- **Species:** Homo sapiens (taxon 9606)

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Source: https://tomesphere.com/paper/PMC12585669