Shree Harsha Vijaya Chandra scite author profile

Biallelic mutation of the ADENOMATOUS POLYPOSIS COLI (APC) gene is a hallmark of sporadic colorectal cancer and colorectal, duodenal and desmoid tumours that develop in familial adenomatous polyposis (FAP) patients. The mutations affecting both APC alleles are interdependent, the position of the first APC mutation determining where the second hit will occur. This results in a complex pattern of mutation distribution in the APC sequence that translates into the stabilization of beta-catenin that in turn feeds the affected cells with a permanent mitogenic signal. We describe here a new APC domain, the beta-catenin inhibitory domain (CID) of APC located between the second and third 20 amino acid repeats and therefore present in many truncated APC products found in human tumours. In truncated APC, the CID is absolutely necessary to down-regulate the transcriptional activity and the level of beta-catenin, even when an axin/conductin binding site is present. The activity of the CID is dramatically reduced in several colon cancer cell lines and can be inhibited by shorter truncated APC lacking the CID. The CID is a direct target of the selective pressure acting on APC during tumourigenesis. It explains the interdependence of both APC mutations, not only in colorectal but also in duodenal and desmoid tumours.

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Cutaneous Malassezia: Commensal, Pathogen, or Protector?

Chandra

Ramasamy

Dawson

et al. 2021

Front. Cell. Infect. Microbiol.

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The skin microbial community is a multifunctional ecosystem aiding prevention of infections from transient pathogens, maintenance of host immune homeostasis, and skin health. A better understanding of the complex milieu of microbe-microbe and host-microbe interactions will be required to define the ecosystem’s optimal function and enable rational design of microbiome targeted interventions. Malassezia, a fungal genus currently comprising 18 species and numerous functionally distinct strains, are lipid-dependent basidiomycetous yeasts and integral components of the skin microbiome. The high proportion of Malassezia in the skin microbiome makes understanding their role in healthy and diseased skin crucial to development of functional skin health knowledge and understanding of normal, healthy skin homeostasis. Over the last decade, new tools for Malassezia culture, detection, and genetic manipulation have revealed not only the ubiquity of Malassezia on skin but new pathogenic roles in seborrheic dermatitis, psoriasis, Crohn’s disease, and pancreatic ductal carcinoma. Application of these tools continues to peel back the layers of Malassezia/skin interactions, including clear examples of pathogenicity, commensalism, and potential protective or beneficial activities creating mutualism. Our increased understanding of host- and microbe-specific interactions should lead to identification of key factors that maintain skin in a state of healthy mutualism or, in turn, initiate pathogenic changes. These approaches are leading toward development of new therapeutic targets and treatment options. This review discusses recent developments that have expanded our understanding of Malassezia’s role in the skin microbiome, with a focus on its multiple roles in health and disease as commensal, pathogen, and protector.

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Conservative site-specific and single-copy transgenesis in humanLINE-1elements

Chandra¹,

Makhija²,

Peter³

et al. 2015

Nucleic Acids Res

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Genome engineering of human cells plays an important role in biotechnology and molecular medicine. In particular, insertions of functional multi-transgene cassettes into suitable endogenous sequences will lead to novel applications. Although several tools have been exploited in this context, safety issues such as cytotoxicity, insertional mutagenesis and off-target cleavage together with limitations in cargo size/expression often compromise utility. Phage λ integrase (Int) is a transgenesis tool that mediates conservative site-specific integration of 48 kb DNA into a safe harbor site of the bacterial genome. Here, we show that an Int variant precisely recombines large episomes into a sequence, termed attH4X, found in 1000 human Long INterspersed Elements-1 (LINE-1). We demonstrate single-copy transgenesis through attH4X-targeting in various cell lines including hESCs, with the flexibility of selecting clones according to transgene performance and downstream applications. This is exemplified with pluripotency reporter cassettes and constitutively expressed payloads that remain functional in LINE1-targeted hESCs and differentiated progenies. Furthermore, LINE-1 targeting does not induce DNA damage-response or chromosomal aberrations, and neither global nor localized endogenous gene expression is substantially affected. Hence, this simple transgene addition tool should become particularly useful for applications that require engineering of the human genome with multi-transgenes.

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Directed evolution of λ integrase activity and specificity by genetic derepression

Siau¹,

Chee²,

Makhija

et al. 2015

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Advances in genome engineering are attendant on the development of novel enzyme variants with programed substrate specificities and improved activity. We have devised a novel selection method, wherein the activity of a recombinase deletes the gene encoding an inhibitor of an enzyme conferring a selectable phenotype. By using β-lactamase and the β-lactamase inhibitor protein, the selection couples recombinase activity to Escherichia coli survival in the presence of ampicillin. Using this method, we generated λ integrase variants displaying improved in vitro recombination of a non-cognate substrate present in the human genome. One generalist integrase variant displaying enhanced catalytic activity was further used in a facile, single-step transformation method to introduce transgenes up to 8.5 kb into the unique endogenous attB site of common laboratory E.coli strains.

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Functional Comparison of Human Adenomatous Polyposis Coli (APC) and APC-Like in Targeting Beta-Catenin for Degradation

et al. 2013

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Truncating mutations affect the adenomatous polyposis coli (APC) gene in most cases of colon cancer, resulting in the stabilization of β-catenin and uncontrolled cell proliferation. We show here that colon cancer cell lines express also the paralog APC-like (APCL or APC2). RNA interference revealed that it controls the level and/or the activity of β-catenin, but it is less efficient and binds less well to β-catenin than APC, thereby providing one explanation as to why the gene is not mutated in colon cancer. A further comparison indicates that APCL down-regulates the β-catenin level despite the lack of the 15R region known to be important in APC. To understand this discrepancy, we performed immunoprecipitation experiments that revealed that phosphorylated β-catenin displays a preference for binding to the 15 amino acid repeats (15R) rather than the first 20 amino acid repeat of APC. This suggests that the 15R region constitutes a gate connecting the steps of β-catenin phosphorylation and subsequent ubiquitination/degradation. Using RNA interference and domain swapping experiments, we show that APCL benefits from the 15R of truncated APC to target β-catenin for degradation, in a process likely involving heterodimerization of the two partners. Our data suggest that the functional complementation of APCL by APC constitutes a substantial facet of tumour development, because the truncating mutations of APC in colorectal tumours from familial adenomatous polyposis (FAP) patients are almost always selected for the retention of at least one 15R.

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