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1. Editorial: Germline Development: From Germline Stem Cells to Gametes

   https://doi.org/10.3389/fcell.2020.00650  

   Lee, Myon-Hee; Navarro, Rosa E.; Han, Sung Min (August 2020, Frontiers in Cell and Developmental Biology)
2. Editorial: Germline development: From germline stem cells to gametes, Volume II

   https://doi.org/10.3389/fcell.2023.1193343  

   Lee, Myon Hee; Navarro, Rosa E.; Han, Sung Min (April 2023, Frontiers in Cell and Developmental Biology)
3. C. elegans Germline as Three Distinct Tumor Models

   https://doi.org/10.3390/biology13060425  

   Jones, Mariah; Norman, Mina; Tiet, Alex Minh; Lee, Jiwoo; Lee, Myon Hee (June 2024, Biology)

   Tumor cells display abnormal growth and division, avoiding the natural process of cell death. These cells can be benign (non-cancerous growth) or malignant (cancerous growth). Over the past few decades, numerous in vitro or in vivo tumor models have been employed to understand the molecular mechanisms associated with tumorigenesis in diverse regards. However, our comprehension of how non-tumor cells transform into tumor cells at molecular and cellular levels remains incomplete. The nematode C. elegans has emerged as an excellent model organism for exploring various phenomena, including tumorigenesis. Although C. elegans does not naturally develop cancer, it serves as a valuable platform for identifying oncogenes and the underlying mechanisms within a live organism. In this review, we describe three distinct germline tumor models in C. elegans, highlighting their associated mechanisms and related regulators: (1) ectopic proliferation due to aberrant activation of GLP-1/Notch signaling, (2) meiotic entry failure resulting from the loss of GLD-1/STAR RNA-binding protein, (3) spermatogenic dedifferentiation caused by the loss of PUF-8/PUF RNA-binding protein. Each model requires the mutations of specific genes (glp-1, gld-1, and puf-8) and operates through distinct molecular mechanisms. Despite these differences in the origins of tumorigenesis, the internal regulatory networks within each tumor model display shared features. Given the conservation of many of the regulators implicated in C. elegans tumorigenesis, it is proposed that these unique models hold significant potential for enhancing our comprehension of the broader control mechanisms governing tumorigenesis. 

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4. The germline factor DDX4 contributes to the chemoresistance of small cell lung cancer cells

   https://doi.org/10.1038/s42003-023-04444-7  

   Noyes, Christopher; Kitajima, Shunsuke; Li, Fengkai; Suita, Yusuke; Miriyala, Saradha; Isaac, Shakson; Ahsan, Nagib; Knelson, Erik; Vajdi, Amir; Tani, Tetsuo; et al (January 2023, Communications Biology)

   Abstract Human cancers often re-express germline factors, yet their mechanistic role in oncogenesis and cancer progression remains unknown. Here we demonstrate that DEAD-box helicase 4 (DDX4), a germline factor and RNA helicase conserved in all multicellular organisms, contributes to increased cell motility and cisplatin-mediated drug resistance in small cell lung cancer (SCLC) cells. Proteomic analysis suggests that DDX4 expression upregulates proteins related to DNA repair and immune/inflammatory response. Consistent with these trends in cell lines, DDX4 depletion compromised in vivo tumor development while its overexpression enhanced tumor growth even after cisplatin treatment in nude mice. Further, the relatively higher DDX4 expression in SCLC patients correlates with decreased survival and shows increased expression of immune/inflammatory response markers. Taken together, we propose that DDX4 increases SCLC cell survival, by increasing the DNA damage and immune response pathways, especially under challenging conditions such as cisplatin treatment. 

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5. Glial granules contain germline proteins in the Drosophila brain, which regulate brain transcriptome

   https://doi.org/10.1038/s42003-020-01432-z  

   Tindell, Samuel J.; Rouchka, Eric C.; Arkov, Alexey L. (December 2020, Communications Biology)

   null (Ed.)

   Abstract Membraneless RNA-protein granules play important roles in many different cell types and organisms. In particular, granules found in germ cells have been used as a paradigm to study large and dynamic granules. These germ granules contain RNA and proteins required for germline development. Here, we unexpectedly identify large granules in specific subtypes of glial cells (“glial granules”) of the adult Drosophila brain which contain polypeptides with previously characterized roles in germ cells including scaffold Tudor, Vasa, Polar granule component and Piwi family proteins. Interestingly, our super-resolution microscopy analysis shows that in the glial granules, these proteins form distinct partially overlapping clusters. Furthermore, we show that glial granule scaffold protein Tudor functions in silencing of transposable elements and in small regulatory piRNA biogenesis. Remarkably, our data indicate that the adult brain contains a small population of cells, which express both neuroblast and germ cell proteins. These distinct cells are evolutionarily conserved and expand during aging suggesting the existence of age-dependent signaling. Our work uncovers previously unknown glial granules and indicates the involvement of their components in the regulation of brain transcriptome. 

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