Your search keyword '"Kalluchi, Achyuth"' showing total 30 results

1. Understanding the function of Pax5 in development of docetaxel-resistant neuroendocrine-like prostate cancers.

Author

Bhattacharya, Sreyashi, Harris, Hannah, Islam, Ridwan, Bodas, Sanika, Polavaram, Navatha, Mishra, Juhi, Das, Dipanwita, Seshacharyulu, Parthasarathy, Kalluchi, Achyuth, Pal, Anirban, Kohli, Manish, Lele, Subodh, Muders, Michael, Batra, Surinder, Ghosh, Paramita, Datta, Kaustubh, Rowley, M, and Dutta, Samikshan

Subjects

Humans, Male, Docetaxel, Prostatic Neoplasms, Drug Resistance, Neoplasm, Cell Line, Tumor, PAX5 Transcription Factor, Gene Expression Regulation, Neoplastic, Antineoplastic Agents, Carcinoma, Neuroendocrine, Promoter Regions, Genetic, Receptors, Androgen

Abstract

Resistance to the current Androgen Receptor Signaling Inhibitor (ARSI) therapies has led to higher incidences of therapy-induced neuroendocrine-like prostate cancer (t-NEPC). This highly aggressive subtype with predominant small-cell-like characteristics is resistant to taxane chemotherapies and has a dismal overall survival. t-NEPCs are mostly treated with platinum-based drugs with a combination of etoposide or taxane and have less selectivity and high systemic toxicity, which often limit their clinical potential. During t-NEPC transformation, adenocarcinomas lose their luminal features and adopt neuro-basal characteristics. Whether the adaptive neuronal characteristics of t-NEPC are responsible for such taxane resistance remains unknown. Pathway analysis from patient gene-expression databases indicates that t-NEPC upregulates various neuronal pathways associated with enhanced cellular networks. To identify transcription factor(s) (TF) that could be important for promoting the gene expression for neuronal characters in t-NEPC, we performed ATAC-Seq, acetylated-histone ChIP-seq, and RNA-seq in our NE-like cell line models and analyzed the promoters of transcriptionally active and significantly enriched neuroendocrine-like (NE-like) cancer-specific genes. Our results indicate that Pax5 could be an important transcription factor for neuronal gene expression and specific to t-NEPC. Pathway analysis revealed that Pax5 expression is involved in axonal guidance, neurotransmitter regulation, and neuronal adhesion, which are critical for strong cellular communications. Further results suggest that depletion of Pax5 disrupts neurite-mediated cellular communication in NE-like cells and reduces surface growth factor receptor activation, thereby, sensitizing them to docetaxel therapies. Moreover, t-NEPC-specific hydroxymethylation of Pax5 promoter CpG islands favors Pbx1 binding to induce Pax5 expression. Based on our study, we concluded that continuous exposure to ARSI therapies leads to epigenetic modifications and Pax5 activation in t-NEPC, which promotes the expression of genes necessary to adopt taxane-resistant NE-like cancer. Thus, targeting the Pax5 axis can be beneficial for reverting their taxane sensitivity.

Published

2024

2. EHD1-dependent traffic of IGF-1 receptor to the cell surface is essential for Ewing sarcoma tumorigenesis and metastasis

Author

Chakraborty, Sukanya, Bhat, Aaqib M., Mushtaq, Insha, Luan, Haitao, Kalluchi, Achyuth, Mirza, Sameer, Storck, Matthew D., Chaturvedi, Nagendra, Lopez-Guerrero, Jose Antonio, Llombart-Bosch, Antonio, Machado, Isidro, Scotlandi, Katia, Meza, Jane L., Ghosal, Gargi, Coulter, Donald W., Jordan Rowley, M., Band, Vimla, Mohapatra, Bhopal C., and Band, Hamid

Published

2023

3. HiCrayon reveals distinct layers of multi-state 3D chromatin organization.

Author

Nolan, Ben, Harris, Hannah L, Kalluchi, Achyuth, Reznicek, Timothy E, Cummings, Christopher T, and Rowley, M Jordan

Published

2024

4. Sex-specific multi-level 3D genome dynamics in the mouse brain

Author

Rocks, Devin, Shukla, Mamta, Ouldibbat, Laila, Finnemann, Silvia C., Kalluchi, Achyuth, Rowley, M. Jordan, and Kundakovic, Marija

Published

2022

5. Data from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

6. Table S2 from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

7. Supplementary Methods from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

8. Figure S4 from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

9. FIGURE 3 from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

10. FIGURE 4 from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

11. FIGURE 5 from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

12. FIGURE 1 from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

13. FIGURE 6 from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

14. FIGURE 2 from Novel Spirocyclic Dimer, SpiD3, Targets Chronic Lymphocytic Leukemia Survival Pathways with Potent Preclinical Effects

Author

Eiken, Alexandria P., primary, Smith, Audrey L., primary, Skupa, Sydney A., primary, Schmitz, Elizabeth, primary, Rana, Sandeep, primary, Singh, Sarbjit, primary, Kumar, Siddhartha, primary, Mallareddy, Jayapal Reddy, primary, de Cubas, Aguirre A, primary, Krishna, Akshay, primary, Kalluchi, Achyuth, primary, Rowley, M. Jordan, primary, D'Angelo, Christopher R., primary, Lunning, Matthew A., primary, Bociek, R. Gregory, primary, Vose, Julie M., primary, Natarajan, Amarnath, primary, and El-Gamal, Dalia, primary

Published

2024

15. Novel spirocyclic dimer, SpiD3, targets chronic lymphocytic leukemia survival pathways with potent preclinical effects

Author

Eiken, Alexandria P, primary, Smith, Audrey L, additional, Skupa, Sydney A, additional, Schmitz, Elizabeth, additional, Rana, Sandeep, additional, Singh, Sarbjit, additional, Kumar, Siddhartha, additional, Mallareddy, Jayapal Reddy, additional, de Cubas, Aguirre A, additional, Krishna, Akshay, additional, Kalluchi, Achyuth, additional, Rowley, M. Jordan, additional, D'Angelo, Christopher R, additional, Lunning, Matthew A., additional, Bociek, R Gregory, additional, Vose, Julie M., additional, Natarajan, Amarnath, additional, and El-Gamal, Dalia, additional

Published

2024

16. Three-dimensional genome architecture persists in a 52,000-year-old woolly mammoth skin sample

Author

Sandoval-Velasco, Marcela, Dudchenko, Olga, Rodríguez, Juan Antonio, Estrada, Cynthia Pérez, Dehasque, Marianne, Fontsere, Claudia, Mak, Sarah S. T., Khan, Ruqayya, Contessoto, Vinícius G., Oliveira Junior, Antonio B., Kalluchi, Achyuth, Herrera, Bernardo J. Zubillaga, Jeong, Jiyun, Roy, Renata P., Christopher, Ishawnia, Weisz, David, Omer, Arina D., Batra, Sanjit S., Shamim, Muhammad S., Durand, Neva C., O'Connell, Brendan, Roca, Alfred L., Plikus, Maksim V., Kusliy, Mariya A., Romanenko, Svetlana A., Lemskaya, Natalya A., Serdyukova, Natalya A., Modina, Svetlana A., Perelman, Polina L., Kizilova, Elena A., Baiborodin, Sergei I., Rubtsov, Nikolai B., Machol, Gur, Rath, Krisha, Mahajan, Ragini, Kaur, Parwinder, Gnirke, Andreas, Garcia-Treviño, Isabel, Coke, Rob, Flanagan, Joseph P., Pletch, Kelcie, Ruiz-Herrera, Aurora, Plotnikov, Valerii, Pavlov, Innokentiy S., Pavlova, Naryya I., Protopopov, Albert V., Di Pierro, Michele, Graphodatsky, Alexander S., Lander, Eric S., Rowley, M. Jordan, Wolynes, Peter G., Onuchic, José N., Dalén, Love, Marti-Renom, Marc A., Gilbert, M. Thomas P., Aiden, Erez Lieberman, Sandoval-Velasco, Marcela, Dudchenko, Olga, Rodríguez, Juan Antonio, Estrada, Cynthia Pérez, Dehasque, Marianne, Fontsere, Claudia, Mak, Sarah S. T., Khan, Ruqayya, Contessoto, Vinícius G., Oliveira Junior, Antonio B., Kalluchi, Achyuth, Herrera, Bernardo J. Zubillaga, Jeong, Jiyun, Roy, Renata P., Christopher, Ishawnia, Weisz, David, Omer, Arina D., Batra, Sanjit S., Shamim, Muhammad S., Durand, Neva C., O'Connell, Brendan, Roca, Alfred L., Plikus, Maksim V., Kusliy, Mariya A., Romanenko, Svetlana A., Lemskaya, Natalya A., Serdyukova, Natalya A., Modina, Svetlana A., Perelman, Polina L., Kizilova, Elena A., Baiborodin, Sergei I., Rubtsov, Nikolai B., Machol, Gur, Rath, Krisha, Mahajan, Ragini, Kaur, Parwinder, Gnirke, Andreas, Garcia-Treviño, Isabel, Coke, Rob, Flanagan, Joseph P., Pletch, Kelcie, Ruiz-Herrera, Aurora, Plotnikov, Valerii, Pavlov, Innokentiy S., Pavlova, Naryya I., Protopopov, Albert V., Di Pierro, Michele, Graphodatsky, Alexander S., Lander, Eric S., Rowley, M. Jordan, Wolynes, Peter G., Onuchic, José N., Dalén, Love, Marti-Renom, Marc A., Gilbert, M. Thomas P., and Aiden, Erez Lieberman

Abstract

Analyses of ancient DNA typically involve sequencing the surviving short oligonucleotides and aligning to genome assemblies from related, modern species. Here, we report that skin from a female woolly mammoth (†Mammuthus primigenius) that died 52,000 years ago retained its ancient genome architecture. We use PaleoHi-C to map chromatin contacts and assemble its genome, yielding 28 chromosome-length scaffolds. Chromosome territories, compartments, loops, Barr bodies, and inactive X chromosome (Xi) superdomains persist. The active and inactive genome compartments in mammoth skin more closely resemble Asian elephant skin than other elephant tissues. Our analyses uncover new biology. Differences in compartmentalization reveal genes whose transcription was potentially altered in mammoths vs. elephants. Mammoth Xi has a tetradic architecture, not bipartite like human and mouse. We hypothesize that, shortly after this mammoth’s death, the sample spontaneously freeze-dried in the Siberian cold, leading to a glass transition that preserved subfossils of ancient chromosomes at nanometer scale., Analyses of ancient DNA typically involve sequencing the surviving short oligonucleotides and aligning to genome assemblies from related, modern species. Here, we report that skin from a female woolly mammoth (†Mammuthus primigenius) that died 52,000 years ago retained its ancient genome architecture. We use PaleoHi-C to map chromatin contacts and assemble its genome, yielding 28 chromosome-length scaffolds. Chromosome territories, compartments, loops, Barr bodies, and inactive X chromosome (Xi) superdomains persist. The active and inactive genome compartments in mammoth skin more closely resemble Asian elephant skin than other elephant tissues. Our analyses uncover new biology. Differences in compartmentalization reveal genes whose transcription was potentially altered in mammoths vs. elephants. Mammoth Xi has a tetradic architecture, not bipartite like human and mouse. We hypothesize that, shortly after this mammoth's death, the sample spontaneously freeze-dried in the Siberian cold, leading to a glass transition that preserved subfossils of ancient chromosomes at nanometer scale.

Published

2024

17. Understanding the role of Pax5 in development of taxane-resistant neuroendocrine like prostate cancers

Author

Dutta, Samikshan, primary, Bhattacharya, Sreyashi, additional, Harris, Hanna, additional, Islam, Ridwan, additional, Bodas, Sanika, additional, Polavaram, Navatha, additional, Mishra, Juhi, additional, Das, Dipanwita, additional, Seshacharyulu, Parthasarathy, additional, Kalluchi, Achyuth, additional, Pal, Anirban, additional, Kohli, Manish, additional, Lele, Subodh, additional, Muders, Michael, additional, Batra, Surinder, additional, Ghosh, Paramita, additional, Datta, Kaustubh, additional, and Rowley, Michael, additional

Published

2023

18. Chromatin alternates between A and B compartments at kilobase scale for subgenic organization

Author

Harris, Hannah L., primary, Gu, Huiya, additional, Olshansky, Moshe, additional, Wang, Ailun, additional, Farabella, Irene, additional, Eliaz, Yossi, additional, Kalluchi, Achyuth, additional, Krishna, Akshay, additional, Jacobs, Mozes, additional, Cauer, Gesine, additional, Pham, Melanie, additional, Rao, Suhas S. P., additional, Dudchenko, Olga, additional, Omer, Arina, additional, Mohajeri, Kiana, additional, Kim, Sungjae, additional, Nichols, Michael H., additional, Davis, Eric S., additional, Gkountaroulis, Dimos, additional, Udupa, Devika, additional, Aiden, Aviva Presser, additional, Corces, Victor G., additional, Phanstiel, Douglas H., additional, Noble, William Stafford, additional, Nir, Guy, additional, Di Pierro, Michele, additional, Seo, Jeong-Sun, additional, Talkowski, Michael E., additional, Aiden, Erez Lieberman, additional, and Rowley, M. Jordan, additional

Published

2023

19. Considerations and caveats for analyzing chromatin compartments

Author

Kalluchi, Achyuth, primary, Harris, Hannah L., additional, Reznicek, Timothy E., additional, and Rowley, M. Jordan, additional

Published

2023

20. Abstract 2478: The interplay between Apurinic/apyrimidinic Endonuclease 1 (APE1) and DNA G-quadruplex (G4) in regulating triple-negative breast cancer (TNBC) metastasis

Author

Chen, Yingling, primary, Pramanik, Suravi, additional, Tarpley, Mason, additional, Kalluchi, Achyuth, additional, Mohapatra, Bhopal, additional, Hewitt, Kyle, additional, Rowley, Michael J., additional, Band, Vimla, additional, and Bhakat, Kishor, additional

Published

2023

21. EHD1-dependent traffic of IGF-1 receptor to the cell surface is essential for Ewing sarcoma tumorigenesis and metastasis

Author

Chakraborty, Sukanya, primary, Bhat, Aaqib M., additional, Mushtaq, Insha, additional, Luan, Haitao, additional, Kalluchi, Achyuth, additional, Mirza, Sameer, additional, Storck, Matthew D., additional, Chaturvedi, Nagendra, additional, Lopez-Guerreo, Jose Antonio, additional, Llombart-Bosch, Antonio, additional, Machado, Isidro, additional, Scotlandi, Katia, additional, Meza, Jane L., additional, Ghosal, Gargi, additional, Coulter, Donald W., additional, Rowley, Jordan M., additional, Band, Vimla, additional, Mohapatra, Bhopal C., additional, and Band, Hamid, additional

Published

2023

22. Elevating SOX2 Downregulates MYC through a SOX2:MYC Signaling Axis and Induces a Slowly Cycling Proliferative State in Human Tumor Cells

Author

Metz, Ethan P., primary, Wilder, Phillip J., additional, Popay, Tessa M., additional, Wang, Jing, additional, Liu, Qi, additional, Kalluchi, Achyuth, additional, Rowley, M. Jordan, additional, Tansey, William P., additional, and Rizzino, Angie, additional

Published

2022

23. Kilobase-Level Nuclear Compartments Separate Active Regulatory Elements From Adjacent Regions

Author

Gu, Huiya, primary, Harris, Hannah L., additional, Olshansky, Moshe, additional, Wang, Ailun, additional, Farabella, Irene, additional, Eliaz, Yossi, additional, Krishna, Akshay, additional, Kalluchi, Achyuth, additional, Jacobs, Mozes, additional, Cauer, Gesine, additional, Pham, Melanie, additional, Rao, Suhas S.P., additional, Dudchenko, Olga, additional, Omer, Arina, additional, Mohajeri, Kiana, additional, Kim, Sungjae, additional, Nichols, Michael H., additional, Davis, Eric S., additional, Gkountaroulis, Dimos, additional, Udupa, Devika, additional, Aiden, Aviva Presser, additional, Corces, Victor, additional, Phanstiel, Douglas H., additional, Noble, William Stafford, additional, Nir, Guy, additional, Di Pierro, Michele, additional, Seo, Jeong-Sun, additional, Talkowski, Michael E., additional, Lieberman Aiden, Erez, additional, and Rowley, M. Jordan, additional

Published

2022

24. Ecdysoneless Protein Regulates Viral and Cellular mRNA Splicing to Promote Cervical Oncogenesis

Author

Mirza, Sameer, primary, Kalluchi, Achyuth, additional, Raza, Mohsin, additional, Saleem, Irfana, additional, Mohapatra, Bhopal, additional, Pal, Dhananjaya, additional, Ouellette, Michel M., additional, Qiu, Fang, additional, Yu, Lulu, additional, Lobanov, Alexei, additional, Zheng, Zhi-Ming, additional, Zhang, Ying, additional, Alsaleem, Mansour A., additional, Rakha, Emad A., additional, Band, Hamid, additional, Rowley, M. Jordan, additional, and Band, Vimla, additional

Published

2021

25. Fine-mapping of nuclear compartments using ultra-deep Hi-C shows that active promoter and enhancer elements localize in the active A compartment even when adjacent sequences do not

Author

Gu, Huiya, primary, Harris, Hannah, additional, Olshansky, Moshe, additional, Eliaz, Yossi, additional, Krishna, Akshay, additional, Kalluchi, Achyuth, additional, Jacobs, Mozes, additional, Cauer, Gesine, additional, Pham, Melanie, additional, Rao, Suhas S.P., additional, Dudchenko, Olga, additional, Omer, Arina, additional, Mohajeri, Kiana, additional, Kim, Sungjae, additional, Nichols, Michael H, additional, Davis, Eric S., additional, Udupa, Devika, additional, Aiden, Aviva Presser, additional, Corces, Victor G., additional, Phanstiel, Douglas H., additional, Noble, William Stafford, additional, Seo, Jeong-Sun, additional, Talkowski, Michael E., additional, Aiden, Erez Lieberman, additional, and Rowley, M. Jordan, additional

Published

2021

26. Sex-specific multi-level 3D genome dynamics in the mouse brain

Author

Rocks, Devin, primary, Shukla, Mamta, additional, Finnemann, Silvia C., additional, Kalluchi, Achyuth, additional, Rowley, M. Jordan, additional, and Kundakovic, Marija, additional

Published

2021

27. HiCrayon reveals distinct layers of multi-state 3D chromatin organization.

Author

Nolan B, Harris HL, Kalluchi A, Reznicek TE, Cummings CT, and Rowley MJ

Abstract

The co-visualization of chromatin conformation with 1D 'omics data is key to the multi-omics driven data analysis of 3D genome organization. Chromatin contact maps are often shown as 2D heatmaps and visually compared to 1D genomic data by simple juxtaposition. While common, this strategy is imprecise, placing the onus on the reader to align features with each other. To remedy this, we developed HiCrayon, an interactive tool that facilitates the integration of 3D chromatin organization maps and 1D datasets. This visualization method integrates data from genomic assays directly into the chromatin contact map by coloring interactions according to 1D signal. HiCrayon is implemented using R shiny and python to create a graphical user interface (GUI) application, available in both web or containerized format to promote accessibility. HiCrayon is implemented in R, and includes a graphical user interface (GUI), as well as a slimmed-down web-based version that lets users quickly produce publication-ready images. We demonstrate the utility of HiCrayon in visualizing the effectiveness of compartment calling and the relationship between ChIP-seq and various features of chromatin organization. We also demonstrate the improved visualization of other 3D genomic phenomena, such as differences between loops associated with CTCF/cohesin vs. those associated with H3K27ac. We then demonstrate HiCrayon's visualization of organizational changes that occur during differentiation and use HiCrayon to detect compartment patterns that cannot be assigned to either A or B compartments, revealing a distinct 3rd chromatin compartment. Overall, we demonstrate the utility of co-visualizing 2D chromatin conformation with 1D genomic signals within the same matrix to reveal fundamental aspects of genome organization. Local version: https://github.com/JRowleyLab/HiCrayon Web version: https://jrowleylab.com/HiCrayon., Competing Interests: Competing Interests The authors declare that they have no competing interests.

Published

2024

28. Understanding the role of Pax5 in development of taxane-resistant neuroendocrine like prostate cancers.

Author

Dutta S, Bhattacharya S, Harris H, Islam R, Bodas S, Polavaram N, Mishra J, Das D, Seshacharyulu P, Kalluchi A, Pal A, Kohli M, Lele S, Muders M, Batra S, Ghosh P, Datta K, and Rowley M

Abstract

Resistance to the current Androgen Receptor Signaling Inhibitor (ARSI) therapies has led to higher incidences of therapy-induced neuroendocrine-like prostate cancer (t-NEPC). This highly aggressive subtype with predominant small cell-like characteristics is resistant to taxane chemotherapies and has a dismal overall survival. t-NEPCs are mostly treated with platinum-based drugs with a combination of etoposide or taxane and have less selectivity and high systemic toxicity, which often limit their clinical potential. During t-NEPC transformation, adenocarcinomas lose their luminal features and adopt neuro-basal characteristics. Whether the adaptive neuronal characteristics of t-NEPC are responsible for such taxane resistance remains unknown. Pathway analysis from patient gene-expression databases indicates that t-NEPC upregulates various neuronal pathways associated with enhanced cellular networks. To identify transcription factor(s) (TF) that could be important for promoting the gene expression for neuronal characters in t-NEPC, we performed ATAC-Seq, acetylated-histone ChIP-seq, and RNA-seq in our NE-like cell line models and analyzed the promoters of transcriptionally active and significantly enriched neuroendocrine-like (NE-like) cancer-specific genes. Our results indicate that Pax5 could be an important transcription factor for neuronal gene expression and specific to t-NEPC. Pathway analysis revealed that Pax5 expression is involved in axonal guidance, neurotransmitter regulation, and neuronal adhesion, which are critical for strong cellular communications. Further results suggest that depletion of Pax5 disrupts cellular interaction in NE-like cells and reduces surface growth factor receptor activation, thereby, sensitizing them to taxane therapies. Moreover, t-NEPC specific hydroxymethylation of Pax5 promoter CpG islands favors Pbx1 binding to induce Pax5 expression. Based on our study, we concluded that continuous exposure to ARSI therapies leads to epigenetic modifications and Pax5 activation in t-NEPC, which promotes the expression of genes necessary to adopt taxane-resistant NE-like cancer. Thus, targeting the Pax5 axis can be beneficial for reverting their taxane sensitivity., Competing Interests: Conflicts of Interest: The authors are declaring no conflict of interest.

Published

2023

29. EHD1-dependent traffic of IGF-1 receptor to the cell surface is essential for Ewing sarcoma tumorigenesis and metastasis.

Author

Chakraborty S, Bhat AM, Mushtaq I, Luan H, Kalluchi A, Mirza S, Storck MD, Chaturvedi N, Lopez-Guerrero JA, Llombart-Bosch A, Machado I, Scotlandi K, Meza JL, Ghosal G, Coulter DW, Rowley JM, Band V, Mohapatra BC, and Band H

Abstract

Overexpression of EPS15 Homology Domain containing 1 (EHD1) has been linked to tumorigenesis but whether its core function as a regulator of intracellular traffic of cell surface receptors plays a role in oncogenesis remains unknown. We establish that EHD1 is overexpressed in Ewing sarcoma (EWS), with high EHD mRNA expression specifying shorter patient survival. ShRNA and CRISPR-knockout with mouse Ehd1 rescue established a requirement of EHD1 for tumorigenesis and metastasis. RTK antibody arrays identified the IGF-1R as a target of EHD1 regulation in EWS. Mechanistically, we demonstrate a requirement of EHD1 for endocytic recycling and Golgi to plasma membrane traffic of IGF-1R to maintain its surface expression and downstream signaling. Conversely, EHD1 overexpression-dependent exaggerated oncogenic traits require IGF-1R expression and kinase activity. Our findings define the RTK traffic regulation as a proximal mechanism of EHD1 overexpression-dependent oncogenesis that impinges on IGF-1R in EWS, supporting the potential of IGF-1R and EHD1 co-targeting.

Published

2023

30. Ecdysoneless Protein Regulates Viral and Cellular mRNA Splicing to Promote Cervical Oncogenesis.

Author

Mirza S, Kalluchi A, Raza M, Saleem I, Mohapatra B, Pal D, Ouellette MM, Qiu F, Yu L, Lobanov A, Zheng ZM, Zhang Y, Alsaleem MA, Rakha EA, Band H, Rowley MJ, and Band V

Subjects

Female, Humans, Transfection, Carrier Proteins metabolism, Oncogenes genetics, RNA Splicing genetics, RNA, Messenger metabolism, Uterine Cervical Neoplasms genetics

Abstract

High-risk human papillomaviruses (HPV), exemplified by HPV16/18, are causally linked to human cancers of the anogenital tract, skin, and upper aerodigestive tract. Previously, we identified Ecdysoneless (ECD) protein, the human homolog of the Drosophila ecdysoneless gene, as a novel HPV16 E6-interacting protein. Here, we show that ECD, through its C-terminal region, selectively binds to high-risk but not to low-risk HPV E6 proteins. We demonstrate that ECD is overexpressed in cervical and head and neck squamous cell carcinoma (HNSCC) cell lines as well as in tumor tissues. Using The Cancer Genome Atlas dataset, we show that ECD mRNA overexpression predicts shorter survival in patients with cervical and HNSCC. We demonstrate that ECD knockdown in cervical cancer cell lines led to impaired oncogenic behavior, and ECD co-overexpression with E7 immortalized primary human keratinocytes. RNA-sequencing analyses of SiHa cells upon ECD knockdown showed to aberrations in E6/E7 RNA splicing, as well as RNA splicing of several HPV oncogenesis-linked cellular genes, including splicing of components of mRNA splicing machinery itself. Taken together, our results support a novel role of ECD in viral and cellular mRNA splicing to support HPV-driven oncogenesis. IMPLICATIONS: This study links ECD overexpression to poor prognosis and shorter survival in HNSCC and cervical cancers and identifies a critical role of ECD in cervical oncogenesis through regulation of viral and cellular mRNA splicing., (©2021 The Authors; Published by the American Association for Cancer Research.)

Published

2022