#  Publications 

 



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### Submitted

Anjali R. Nelliat, Ibrahim M. Sabbarini, Yuichi Yagita, Kyle Anderson, Ramanujan S. Hegde, Andrew W. Murray, and Vladimir Denic. 2025. “[A Divergent Tubulin-Like Protein Templates Eukaryotic Chaperonin Assembly](/publication/divergent-tubulin-protein-templates-eukaryotic-chaperonin-assembly)”. Science



 

 

Anjali R. Nelliat, Ibrahim M. Sabbarini, Yuichi Yagita, Kyle Anderson, Ramanujan S. Hegde, Andrew W. Murray, and Vladimir Denic. 2025. “[A Divergent Tubulin-Like Protein Templates Eukaryotic Chaperonin Assembly](/publication/divergent-tubulin-protein-templates-eukaryotic-chaperonin-assembly)”. Science



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
 
The CCT chaperonin uses a specific ring topology of eight related subunits to instruct tubulin folding by site-specific interactions. Subunits comprising the negatively-charged hemisphere (Cct2/4/5/7) have the potential to self-assemble but how the...



 

 

 

Piyush Nanda and Andrew W. Murray. 2026. “[Competition Between Mitochondrial and Cytosolic Ribosomes Produces a Bistable Metabolic Switch](/publication/competition-between-mitochondrial-and-cytosolic-ribosomes-produces-bistable-metabolic)”. BioRxiv



 

 

Piyush Nanda and Andrew W. Murray. 2026. “[Competition Between Mitochondrial and Cytosolic Ribosomes Produces a Bistable Metabolic Switch](/publication/competition-between-mitochondrial-and-cytosolic-ribosomes-produces-bistable-metabolic)”. BioRxiv



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://www.biorxiv.org/cgi/content/short/2026.03.30.715437v1)
 
Fast glycolytic growth in the budding yeast, Saccharomyces cerevisiae, produces two epigenetic states: arrestors, which primarily ferment, and recoverers, which respire. Positive feedback in mitochondrial translation produces the two states: mitochondrial...



 

 

- [ descriptionPublisher's Version](https://www.biorxiv.org/cgi/content/short/2026.03.30.715437v1)
 
 

 



### 2025

Gal Lumbroso, Gisela Cairo, Soni Lacefield, and Andrew W Murray. 2025. “[ The B-Type Cyclin Clb4 Prevents Meiosis I Sister Centromere Separation in Budding Yeast](/publication/b-type-cyclin-clb4-prevents-meiosis-i-sister-centromere-separation-budding-yeast)”. G3: Genes Genomes Genetics, jkaf121



 

 

Gal Lumbroso, Gisela Cairo, Soni Lacefield, and Andrew W Murray. 2025. “[ The B-Type Cyclin Clb4 Prevents Meiosis I Sister Centromere Separation in Budding Yeast](/publication/b-type-cyclin-clb4-prevents-meiosis-i-sister-centromere-separation-budding-yeast)”. G3: Genes Genomes Genetics, jkaf121



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://academic.oup.com/g3journal/advance-article/doi/10.1093/g3journal/jkaf121/8153555)
 
In meiosis, one round of DNA replication followed by two rounds of chromosome segregation halves the ploidy of the original cell. Accurate chromosome segregation in meiosis I depends on recombination between homologous chromosomes. Sister centromeres...



 

 

- [ descriptionPublisher's Version](https://academic.oup.com/g3journal/advance-article/doi/10.1093/g3journal/jkaf121/8153555)
 
 

Ibrahim M. Sabbarini, Dvir Reif, Kibum Park, Alexander J. McQuown, Anjali R. Nelliat, Charlotte Trejtnar, Volker Dötsch, Eugene I. Shakhnovich, Andrew W. Murray, and Vladimir Denic. 2025. “[A Ribosome-Associating Chaperone Mediates GTP-Driven Vectorial Folding of Nascent EEF1A](/publication/ribosome-associating-chaperone-mediates-gtp-driven-vectorial-folding-nascent-eef1a)”. Nature Communications, 16



 

 

Ibrahim M. Sabbarini, Dvir Reif, Kibum Park, Alexander J. McQuown, Anjali R. Nelliat, Charlotte Trejtnar, Volker Dötsch, Eugene I. Shakhnovich, Andrew W. Murray, and Vladimir Denic. 2025. “[A Ribosome-Associating Chaperone Mediates GTP-Driven Vectorial Folding of Nascent EEF1A](/publication/ribosome-associating-chaperone-mediates-gtp-driven-vectorial-folding-nascent-eef1a)”. Nature Communications, 16



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublishers Version](https://www.nature.com/articles/s41467-025-56489-3)
 
Eukaryotic translation elongation factor 1A (eEF1A) is a highly abundant, multi-domain GTPase. Post-translational steps essential for eEF1A biogenesis are carried out by bespoke chaperones but co-translational mechanisms tailored to eEF1A folding remain...



 

 

- [ descriptionPublishers Version](https://www.nature.com/articles/s41467-025-56489-3)
 
 

Juliet Barker, Stephen Bell, and Andrew Murray. 2025. “[Cell Integrity Limits Ploidy in Budding Yeast](/publications/cell-integrity-limits-ploidy-budding-yeast)”. G3: Genes Genomes Genetics



 

 

Juliet Barker, Stephen Bell, and Andrew Murray. 2025. “[Cell Integrity Limits Ploidy in Budding Yeast](/publications/cell-integrity-limits-ploidy-budding-yeast)”. G3: Genes Genomes Genetics



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://academic.oup.com/g3journal/advance-article/doi/10.1093/g3journal/jkae286/7953228?utm_source=advanceaccess&utm_campaign=g3journal&utm_medium=email)
 
 Evidence suggests that increases in ploidy have occurred frequently in the evolutionary history of organisms, and can serve adaptive functions to specialized, somatic cells in multicellular organisms (Edgar &amp; Orr-Weaver, 2001; Orr-Weaver, 2015; Van De...



 

 

- [ descriptionPublisher's Version](https://academic.oup.com/g3journal/advance-article/doi/10.1093/g3journal/jkae286/7953228?utm_source=advanceaccess&utm_campaign=g3journal&utm_medium=email)
 
 

 



### 2024

Gal Lumbroso, Gisela Cairo, Soni Lacefield, and Andrew Murray. 2024. “[The B-Type Cyclin Clb4 Prevents Meiosis I Sister Centromere Separation in Budding Yeast](/publications/b-type-cyclin-clb4-prevents-meiosis-i-sister-centromere-separation-budding)”. BioRxiv



 

 

Gal Lumbroso, Gisela Cairo, Soni Lacefield, and Andrew Murray. 2024. “[The B-Type Cyclin Clb4 Prevents Meiosis I Sister Centromere Separation in Budding Yeast](/publications/b-type-cyclin-clb4-prevents-meiosis-i-sister-centromere-separation-budding)”. BioRxiv



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://www.biorxiv.org/content/10.1101/2024.12.18.629243v1)
- [ description10.1101/2024.12.18.629243](/publications/b-type-cyclin-clb4-prevents-meiosis-i-sister-centromere-separation-budding)
 
In meiosis, one round of DNA replication followed by two rounds of chromosome segregation halves the ploidy of the original cell. Accurate chromosome segregation in meiosis I depends on recombination between homologous chromosomes. Sister centromeres...



 

 

- [ descriptionPublisher's Version](https://www.biorxiv.org/content/10.1101/2024.12.18.629243v1)
- [ description10.1101/2024.12.18.629243](/publications/b-type-cyclin-clb4-prevents-meiosis-i-sister-centromere-separation-budding)
 
 

Piyush Nanda, Julien Barrere, Thomas LaBar, and Andrew Murray. 2024. “[A Dynamic Network Model Predicts the Phenotypes of Multicellular Clusters from Cellular Properties](/publications/multicellular-growth-dynamic-network-cells)”. Current Biology



 

 

Piyush Nanda, Julien Barrere, Thomas LaBar, and Andrew Murray. 2024. “[A Dynamic Network Model Predicts the Phenotypes of Multicellular Clusters from Cellular Properties](/publications/multicellular-growth-dynamic-network-cells)”. Current Biology



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://www.sciencedirect.com/science/article/pii/S0960982224006122?dgcid=author)
 
 Cell division without cell separation produces multicellular clusters in budding yeast.

 Two fundamental characteristics of these clusters are their size (the number of cells

 per cluster) and cellular composition: the fractions of cells with different...



 

 

- [ descriptionPublisher's Version](https://www.sciencedirect.com/science/article/pii/S0960982224006122?dgcid=author)
 
 

 



### 2023

Sriram Srikant, Rachelle Gaudet, and Andrew Murray. 2023. “[Extending the Reach of Homology by Using Successive Computational Filters to Find Yeast Pheromone Genes](/publications/extending-reach-homology-using-successive-computational-filters-find-yeast)”. Current Biology, 33, 19, Pp. 4098-4110



 

 

Sriram Srikant, Rachelle Gaudet, and Andrew Murray. 2023. “[Extending the Reach of Homology by Using Successive Computational Filters to Find Yeast Pheromone Genes](/publications/extending-reach-homology-using-successive-computational-filters-find-yeast)”. Current Biology, 33, 19, Pp. 4098-4110



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://www-sciencedirect-com.ezp-prod1.hul.harvard.edu/science/article/pii/S0960982223011181)
 
 The mating of fungi depends on pheromones that mediate communication between two mating types. Most species use short peptides as pheromones, which are either unmodified (e.g., a-factor in *Saccharomyces cerevisiae*) or C-terminally farnesylated (e.g., **a**-f...



 

 

- [ descriptionPublisher's Version](https://www-sciencedirect-com.ezp-prod1.hul.harvard.edu/science/article/pii/S0960982223011181)
 
 

Ibrahim Sabbarini, Dvir Reif, Alexander McQuown, Anjali Nelliat, Jeffrey Prince, Britnie Santiago Membreno, Colin Chih-Chien Wu, Andrew Murray, and Vladimir Denic. 2023. “[Zinc-Finger Protein Zpr1 Is a Bespoke Chaperone Essential for EEF1A Biogenesis](/publications/zinc-finger-protein-zpr1-bespoke-chaperone-essential-eef1a-biogenesis)”. Molecular Cell, 83, 2, Pp. 252-65



 

 

Ibrahim Sabbarini, Dvir Reif, Alexander McQuown, Anjali Nelliat, Jeffrey Prince, Britnie Santiago Membreno, Colin Chih-Chien Wu, Andrew Murray, and Vladimir Denic. 2023. “[Zinc-Finger Protein Zpr1 Is a Bespoke Chaperone Essential for EEF1A Biogenesis](/publications/zinc-finger-protein-zpr1-bespoke-chaperone-essential-eef1a-biogenesis)”. Molecular Cell, 83, 2, Pp. 252-65



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://doi.org/10.1016/j.molcel.2022.12.012)
 
 The conserved regulon of Heat Shock Factor 1 in budding yeast contains chaperones

 for general protein folding as well as Zinc Finger Protein Zpr1, whose essential role in

 archaea and eukaryotes remains unknown. Here, we show that Zpr1 depletion causes

 ac...



 

 

- [ descriptionPublisher's Version](https://doi.org/10.1016/j.molcel.2022.12.012)
 
 

Julien Barrere, Piyush Nanda, and Andrew Murray. 2023. “[Alternating Selection for Dispersal and Multicellularity Favors Regulated Life Cycles](/publications/alternating-selection-dispersal-and-multicellularity-favors-regulated-life)”. Current Biology, 33, 9, Pp. 1809-17



 

 

Julien Barrere, Piyush Nanda, and Andrew Murray. 2023. “[Alternating Selection for Dispersal and Multicellularity Favors Regulated Life Cycles](/publications/alternating-selection-dispersal-and-multicellularity-favors-regulated-life)”. Current Biology, 33, 9, Pp. 1809-17



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://www.cell.com/current-biology/fulltext/S0960-9822(23)00319-6)
 
 The evolution of complex multicellularity opened paths to increased morphological diversity and organizational novelty. This transition involved three processes: cells remained attached to one another to form groups, cells within these groups... 

 

 

- [ descriptionPublisher's Version](https://www.cell.com/current-biology/fulltext/S0960-9822(23)00319-6)
 
 

 



### 2022

Caroline Weisman, Andrew Murray, and Sean Eddy. 2022. “[Mixing Genome Annotation Methods in a Comparative Analysis Inflates the Apparent Number of Lineage-Specific Genes](/publications/mixing-genome-annotation-methods-comparative-analysis-inflates-apparent)”. Current Biology, 32, 12, Pp. 2632-39



 

 

Caroline Weisman, Andrew Murray, and Sean Eddy. 2022. “[Mixing Genome Annotation Methods in a Comparative Analysis Inflates the Apparent Number of Lineage-Specific Genes](/publications/mixing-genome-annotation-methods-comparative-analysis-inflates-apparent)”. Current Biology, 32, 12, Pp. 2632-39



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://www.sciencedirect.com/science/article/pii/S0960982222007217)
 
 Comparisons of genomes of different species are used to identify lineage-specific genes, those genes that appear unique to one species or clade. Lineage-specific genes are often thought to represent genetic novelty that underlies unique adaptations...



 

 

- [ descriptionPublisher's Version](https://www.sciencedirect.com/science/article/pii/S0960982222007217)
 
 

 



### 2021

Marco Fumasoni and Andrew Murray. 2021. “[Ploidy and Recombination Proficiency Shape the Evolutionary Adaptation to Constitutive DNA Replication Stress](/publications/ploidy-and-recombination-proficiency-shape-evolutionary-adaptation)”. PLOS Genetics, 17, 11



 

 

Marco Fumasoni and Andrew Murray. 2021. “[Ploidy and Recombination Proficiency Shape the Evolutionary Adaptation to Constitutive DNA Replication Stress](/publications/ploidy-and-recombination-proficiency-shape-evolutionary-adaptation)”. PLOS Genetics, 17, 11



 

 

 

- add\_circle do\_not\_disturb\_on Abstract
- [ descriptionPublisher's Version](https://journals.plos.org/plosgenetics/article?id=10.1371/journal.pgen.1009875)
 
 In haploid budding yeast, evolutionary adaptation to constitutive DNA replication stress alters three genome maintenance modules: DNA replication, the DNA damage checkpoint, and sister chromatid cohesion. We asked how these trajectories depend on genomic...



 

 

- [ descriptionPublisher's Version](https://journals.plos.org/plosgenetics/article?id=10.1371/journal.pgen.1009875)
 
 

 



 

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##  Books 

**The cell cycle: an introduction (1993)**

In the last decade there has been a revolution in our comprehension of how cells grow and divide. Results from experiments on yeast, embryos, and cultured mammalian cells have unified seemingly disparate viewpoints into a single set of principles for normal cellular reproduction in plants, animals and bacteria. Written by two leading participants in that revolution, *The Cell Cycle* provides the first thorough, authoritative account of the new philosophy of normal cellular reproduction and how it emerged. It is a vivid portrayal of the molecular logic of the cell: how the cell engine induces DNA replication and chromosome replication; how the integrity of genetic information is preserved; and how cell size and environmental signals regulate the cycle of growth and division. By describing important breakthroughs in their historical and experimental context, *The Cell Cycle* traces the development of the new vision of cell biology and shows its relevance to other areas of modern biology. It is the ideal introduction to the current understanding of cell growth and division for advanced undergraduate and graduate level cell biology courses.