Most cancers exhibit aneuploidy, but its functional significance in tumor development is controversial. Here, we describe ReDACT (
Re
storing
D
isomy in
A
neuploid cells using
C
RISPR
T
argeting), a set of chromosome engineering tools that allow us to eliminate specific aneuploidies from cancer genomes. Using ReDACT, we created a panel of isogenic cells that have or lack common aneuploidies, and we demonstrate that trisomy of chromosome 1q is required for malignant growth in cancers harboring this alteration. Mechanistically, gaining chromosome 1q increases the expression of
MDM4
and suppresses p53 signaling, and we show that
TP53
mutations are mutually-exclusive with 1q aneuploidy in human cancers. Thus, tumor cells can be dependent on specific aneuploidies, raising the possibility that these “aneuploidy addictions” could be targeted as a therapeutic strategy.
Several pathogenic species are capable of heritable and reversible switching between two epigenetic states, "white" and "opaque." In, white cells are essentially sterile, whereas opaque cells are mating-proficient. Here, we interrogate the mechanism by which the white-opaque switch regulates sexual fecundity and identify four genes in the pheromone MAPK pathway that are expressed at significantly higher levels in opaque cells than in white cells. These genes encode the β subunit of the G-protein complex (), the pheromone MAPK scaffold (), and the two terminal MAP kinases (). To define the contribution of each factor to mating, white cells were reverse-engineered to express elevated, opaque-like levels of these factors, either singly or in combination. We show that white cells co-overexpressing, , and undergo mating four orders of magnitude more efficiently than control white cells and at a frequency approaching that of opaque cells. Moreover, engineered white cells recapitulate the transcriptional and morphological responses of opaque cells to pheromone. These results therefore reveal multiple bottlenecks in pheromone MAPK signaling in white cells and that alleviation of these bottlenecks enables efficient mating by these "sterile" cell types. Taken together, our findings establish that differential expression of several MAPK factors underlies the epigenetic control of mating in We also discuss how fitness advantages could have driven the evolution of a toggle switch to regulate sexual reproduction in pathogenic species.
Most cancers exhibit aneuploidy, but its functional significance in tumor development is controversial. Here, we describe ReDACT (Restoring Disomy in Aneuploid cells using CRISPR Targeting), a set of chromosome engineering tools that allow us to eliminate specific aneuploidies from cancer genomes. Using ReDACT, we created a panel of isogenic cells that have or lack common aneuploidies, and we demonstrate that trisomy of chromosome 1q is required for malignant growth in cancers harboring this alteration. Mechanistically, gaining chromosome 1q increases the expression of MDM4 and suppresses TP53 signaling, and we show that TP53 mutations are mutually-exclusive with 1q aneuploidy in human cancers. Thus, specific aneuploidies play essential roles in tumorigenesis, raising the possibility that targeting these "aneuploidy addictions" could represent a novel approach for cancer treatment.
The ability of microbial cells to exist in multiple states is a ubiquitous property that promotes adaptation and survival. This phenomenon has been extensively studied in the opportunistic pathogen Candida albicans, which can transition between multiple phenotypic states in response to environmental signals. C. albicans normally exists as a commensal in the human body, but can also cause debilitating mucosal infections or life-threatening systemic infections. The ability to switch between cellular forms contributes to C. albicans’ capacity to infect different host niches, and strictly regulates the program of sexual mating. We review the unique properties associated with different phenotypic states, as well as how interactions between cells in different states can further augment microbial behavior.
Transcriptional regulation involves both positive and negative regulatory
elements. The Dig1 negative regulators are part of a fungal-specific module that
includes a transcription factor (a Ste12 family member) and a Dig1 family
member. In S. cerevisiae the post-genome-duplication Dig1/Dig2
proteins regulate MAP kinase controlled signaling pathways involved in mating
and filamentous growth. We have identified the single Dig1 ortholog in the
fungal pathogen Candida albicans. Genetic studies and
transcriptional profiling experiments show that this single protein is
implicated in regulation of MAP kinase-controlled processes involved in mating,
filamentous growth and biofilm formation, and also influences cAMP-regulated
processes. This suggests that the multiple cellular roles of the Dig1 protein
are ancestral, and predate the sub-functionalization apparent in S.
cerevisiae after the genome duplication. Intriguingly, even though
loss of Dig1 function in C. albicans enhances filamentous
growth and biofilm formation, colonization of the murine gastrointestinal tract
is reduced in the mutant. The complexity of the processes influenced by Dig1 in
C. albicans, and the observation that Dig1 is one of the
few regulatory proteins that were retained in the duplicated state after the
whole genome duplication event in yeast, emphasizes the important role of these
negative regulators in fungal transcriptional control.
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