Andrew L Paek

Overview

Explore the profile of Andrew L Paek including associated specialties, affiliations and a list of published articles.

Snapshot

Articles 19

Citations 304

Followers 0

Related Specialties

Biology

Cell Biology

Molecular Biology

Top 10 Co-Authors

Ted Weinert

Elizabeth Jose

Lisa Shanks

Curtis A Thorne

Salma Kaochar

Kelvin W Pond

Tongli Zhang

Reeba P Varghese

Hope Jones

Elaheh Alizadeh

Published In

Nat Commun

bioRxiv

Genes Dev

Mol Cell

Cell

Affiliations

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Recent Articles

11.

Drug-induced aneuploidy and polyploidy is a mechanism of disease relapse in MYC/BCL2-addicted diffuse large B-cell lymphoma

Islam S, Paek A, Hammer M, Rangarajan S, Ruijtenbeek R, Cooke L, et al.

Oncotarget . 2018 Dec; 9(89):35875-35890. PMID: 30542505

Key Points: ● MYC mediated upregulation of TPX2, KPNA2 and RanGAP1 dysregulate the spindle assembly checkpoint in drug-induced polyploid cells.● Drug-induced polyploid cells re-enter the cell cycle via multipolar mitosis,...

12.

A dynamical framework for complex fractional killing

Ballweg R, Paek A, Zhang T

Sci Rep . 2017 Aug; 7(1):8002. PMID: 28808338

When chemotherapy drugs are applied to tumor cells with the same or similar genotypes, some cells are killed, while others survive. This fractional killing contributes to drug resistance in cancer....

13.

Cell-to-Cell Variation in p53 Dynamics Leads to Fractional Killing

Paek A, Liu J, Loewer A, Forrester W, Lahav G

Cell . 2016 Apr; 165(3):631-42. PMID: 27062928

Many chemotherapeutic drugs kill only a fraction of cancer cells, limiting their efficacy. We used live-cell imaging to investigate the role of p53 dynamics in fractional killing of colon cancer...

14.

Draft Genome Sequence of the Ale-Fermenting Saccharomyces cerevisiae Strain GSY2239

URen J, Wisecaver J, Paek A, Dunn B, Hurwitz B

Genome Announc . 2015 Jul; 3(4). PMID: 26205854

Saccharomyces cerevisiae strain GSY2239 is derived from an industrial yeast strain used to ferment ale-style beer. We present here the 11.5-Mb draft genome sequence for this organism.

15.

DNA replication: failures and inverted fusions

Carr A, Paek A, Weinert T

Semin Cell Dev Biol . 2011 Oct; 22(8):866-74. PMID: 22020070

DNA replication normally follows the rules passed down from Watson and Crick: the chromosome duplicates as dictated by its antiparallel strands, base-pairing and leading and lagging strand differences. Real-life replication...

16.

Choreography of the 9-1-1 checkpoint complex: DDK puts a check on the checkpoints

Paek A, Weinert T

Mol Cell . 2010 Nov; 40(4):505-6. PMID: 21095580

Checkpoint proteins respond to DNA damage by halting the cell cycle until the damage is repaired. In this issue of Molecular Cell, Furuya et al. (2010) provide evidence that checkpoint...

17.

The role of replication bypass pathways in dicentric chromosome formation in budding yeast

Paek A, Jones H, Kaochar S, Weinert T

Genetics . 2010 Sep; 186(4):1161-73. PMID: 20837992

Gross chromosomal rearrangements (GCRs) are large scale changes to chromosome structure and can lead to human disease. We previously showed in Saccharomyces cerevisiae that nearby inverted repeat sequences (∼20-200 bp...

18.

Genetics. Replication error amplified

Kaochar S, Paek A, Weinert T

Science . 2010 Aug; 329(5994):911-3. PMID: 20724625

No abstract available.

19.

Fusion of nearby inverted repeats by a replication-based mechanism leads to formation of dicentric and acentric chromosomes that cause genome instability in budding yeast

Paek A, Kaochar S, Jones H, Elezaby A, Shanks L, Weinert T

Genes Dev . 2009 Dec; 23(24):2861-75. PMID: 20008936

Large-scale changes (gross chromosomal rearrangements [GCRs]) are common in genomes, and are often associated with pathological disorders. We report here that a specific pair of nearby inverted repeats in budding...