Lysine Methyltransferase 2D Regulates Immune Response and Metastasis in Head and Neck Cancer.

BACKGROUND/AIM: The most frequently altered epigenetic modifier in head and neck squamous carcinoma (HNSC) is the histone methyltransferase KMT2D. KMT2D catalyzes methylation of histone H3K4 resulting in open chromatin and the activation of target genes. Tumor-associated macrophages (TAMs) promote cancer growth by causing T lymphocyte exhaustion. C-C motif chemokine ligand 2 (CCL2) is a potent TAM chemotactic factor. In HNSC, TAMs have been associated with unfavorable patient outcomes and metastasis. The aim of this study was to determine the role of KMT2D in HNSC using genetically engineered in vivo models. MATERIALS AND METHODS: KMT2D protein expression was correlated with lymph node metastasis in human HNSC using immunohistochemistry. Genetically engineered KMT2D and CCL2 knockout models of HNSC were created in vivo. HNSC was characterized using qRT-PCR, histopathology, and immunohistochemistry/immunofluorescence microscopy. We also analyzed the effects of KMT2D expression on the proliferation and migration of human HNSC lines. The regulation of the CCL2 gene by KMT2D was characterized using chromatin immunoprecipitation-sequencing assay of transposase accessible chromatin-sequencing, and chromatin conformation capture-sequencing. RESULTS: Human HNSC cases with high KMT2D expression exhibited significantly increased lymph node metastasis. Reduced KMT2D expression in our genetically engineered model correlated with reduced lymph node metastasis, longer latency, and slow tumor growth. CCL2 expression was decreased in KMT2D deficient HNSC, which correlated with a reduced TAM gene expression signature. Genomic experiments demonstrated that KMT2D directly targeted the CCL2 gene. A new genetically engineered in vivo model of CCL2-null HNSC was created, recapitulating the KMT2D deficient phenotype and showing a decreased T lymphocyte exhaustion signature. CONCLUSION: KMT2D regulates CCL2-mediated immune response and metastasis in HNSC.

Paracrine Interaction of Cancer Stem Cell Populations Is Regulated by the Senescence-Associated Secretory Phenotype (SASP).

Dyskeratosis congenita is a telomere DNA damage syndrome characterized by defective telomere maintenance, bone marrow failure, and increased head and neck cancer risk. The Pot1b-/-;Terc+/- mouse exhibits some features of dyskeratosis congenita, but head and neck cancer was not reported in this model. To model the head and neck cancer phenotype, we created unique Pot1b- and p53-null-mutant models which allow genetic lineage tracing of two distinct stem cell populations. Loss of Pot1b expression depleted stem cells via ATR/Chk1/p53 signaling. Tumorigenesis was inhibited in Pot1b-/-;p53+/+ mice due to cellular senescence. Pot1b-/-;p53-/- tumors also exhibited senescence, but proliferated and metastasized with expansion of Lgr6+ stem cells indicative of senescence-associated secretory phenotype. Selective depletion of the small K15+ stem cell fraction resulted in reduction of Lgr6+ cells and inhibition of tumorigenesis via senescence. Gene expression studies revealed that K15+ cancer stem cells regulate Lgr6+ cancer stem cell expansion via chemokine signaling. Genetic ablation of the chemokine receptor Cxcr2 inhibited cancer stem cell expansion and tumorigenesis via senescence. The effects of chemokines were primarily mediated by PI3K signaling, which is a therapeutic target in head and neck cancer. IMPLICATIONS: Paracrine interactions of cancer stem cell populations impact therapeutic options and patient outcomes.

Telomere DNA damage signaling regulates cancer stem cell evolution, epithelial mesenchymal transition, and metastasis.

Chromosome ends are protected by telomeres that prevent DNA damage response and degradation. When telomeres become critically short, the DNA damage response is activated at chromosome ends which induces cellular senescence or apoptosis. Telomeres are protected by the double stranded DNA binding protein TRF2 and maintained by telomerase or a recombination based mechanism known as alternative lengthening of telomeres (ALT). Telomerase is expressed in the basal layer of the epidermis, and stem cells in epidermis have longer telomeres than proliferating populations. Stem cell expansion has been associated with epithelial-mesenchymal transition (EMT) in cancer. EMT is a critical process in cancer progression in which cells acquire spindle morphology, migrate from the primary tumor, and spread to distant anatomic sites. Our previous study demonstrated that loss of TRF2 expression observed in human squamous cell carcinomas expanded metastatic cancer stem cells during mouse skin carcinogenesis. To determine if telomerase inhibition could block the TRF2-null mediated expansion of metastatic clones, we characterized skin carcinogenesis in a conditional TRF2/Terc double null mutant mouse. Loss of TRF2 and Terc expression resulted in telomere DNA damage, severely depleted CD34 + and Lgr6+ cancer stem cells, and induced terminal differentiation of metastatic cancer cells. However a novel cancer stem cell population evolved in primary tumors exhibiting genomic instability, ALT, and EMT. Surprisingly we discovered that metastatic clones evolved prior to histopathologic onset of primary tumors. These results have important implications for understanding the evolution and treatment of metastatic cancer.

Molecular analyses of an unusual translesion DNA polymerase from Methanosarcina acetivorans C2A.

The domain Archaea is composed of several subdomains, and prominent among them are the Crenarchaeota and the Euryarchaeota. Biochemically characterized archaeal family Y DNA polymerases (Pols) or DinB homologs, to date, are all from crenarchaeal organisms, especially the genus Sulfolobus. Here, we demonstrate that archaeal family Y Pols fall into five clusters based on phylogenetic analysis. MacDinB-1, the homolog from the euryarchaeon Methanosarcina acetivorans that is characterized in this study, belongs to cluster II. Therefore, MacDinB-1 is different from the Sulfolobus DinB proteins, which are members of cluster I. In addition to translesion DNA synthesis activity, MacDinB-1 synthesized unusually long products ( approximately 7.2 kb) in the presence of its cognate proliferating cell nuclear antigen (PCNA). The PCNA-interacting site in MacDinB-1 was identified by mutational analysis in a C-terminally located heptapeptide akin to a PIP (PCNA-interacting protein) box. In vitro assays from the present report suggested that MacDinB-1 works in an error-free mode to repair cyclobutane pyrimidine dimers. This study on a euryarchaeal DinB homolog provides important insights into the functional diversity of the family Y Pols, and the availability of a genetic system for this archaeon should allow subsequent elucidation of the physiological significance of this enzyme in M. acetivorans cells.

Biochemical and mutational analyses of a unique clamp loader complex in the archaeon Methanosarcina acetivorans.

Clamp loaders orchestrate the switch from distributive to processive DNA synthesis. Their importance in cellular processes is underscored by their conservation across all forms of life. Here, we describe a new form of clamp loader from the archaeon Methanosarcina acetivorans. Unlike previously described archaeal clamp loaders, which are composed of one small subunit and one large subunit, the M. acetivorans clamp loader comprises two similar small subunits (M. acetivorans replication factor C small subunit (MacRFCS)) and one large subunit (MacRFCL). The relatedness of the archaeal and eukaryotic clamp loaders (which are made up of four similar small subunits and one large subunit) suggests that the M. acetivorans clamp loader may be an intermediate form in the archaeal/eukaryotic sister lineages. The clamp loader complex reconstituted from the three subunits MacRFCS1, MacRFCS2, and MacRFCL stimulated DNA synthesis by a cognate DNA polymerase in the presence of its sliding clamp. We used site-directed mutagenesis in the Walker A and SRC motifs to examine the contribution of each subunit to the function of the M. acetivorans clamp loader. Although mutations in MacRFCL and MacRFCS2 did not impair clamp loading activity, any mutant clamp loader harboring a mutation in MacRFCS1 was devoid of the clamp loading property. Mac-RFCS1 is therefore critical to the clamp loading activity of the M. acetivorans clamp loader. It is our anticipation that the discovery of this unique replication factor C homolog will lead to critical insights into the evolution of more complex clamp loaders from simpler ones as more complex organisms evolved in the archaeal/eukaryotic sister lineages.