Lakshmi Reddy Bollu

Gain of Glucose-Independent Growth upon Metastasis of Breast Cancer Cells to the Brain

Breast cancer brain metastasis is resistant to therapy and a particularly poor prognostic feature in patient survival. Altered metabolism is a common feature of cancer cells, but little is known as to what metabolic changes benefit breast cancer brain metastases. We found that brain metastatic breast cancer cells evolved the ability to survive and proliferate independent of glucose due to enhanced gluconeogenesis and oxidations of glutamine and branched chain amino acids, which together sustain the nonoxidative pentose pathway for purine synthesis. Silencing expression of fructose-1,6-bisphosphatases (FBP) in brain metastatic cells reduced their viability and improved the survival of metastasis-bearing immunocompetent hosts. Clinically, we showed that brain metastases from human breast cancer patients expressed higher levels of FBP and glycogen than the corresponding primary tumors. Together, our findings identify a critical metabolic condition required to sustain brain metastasis and suggest that targeting gluconeogenesis may help eradicate this deadly feature in advanced breast cancer patients.

ATP Citrate Lyase Mediates Resistance of Colorectal Cancer Cells to SN38

Combination chemotherapy is standard for metastatic colorectal cancer; however, nearly all patients develop drug resistance. Understanding the mechanisms that lead to resistance to individual chemotherapeutic agents may enable identification of novel targets and more effective therapy. Irinotecan is commonly used in first- and second-line therapy for patients with metastatic colorectal cancer, with the active metabolite being SN38. Emerging evidence suggests that altered metabolism in cancer cells is fundamentally involved in the development of drug resistance. Using Oncomine and unbiased proteomic profiling, we found that ATP citrate lyase (ACLy), the first-step rate-limiting enzyme for de novo lipogenesis, was upregulated in colorectal cancer compared with its levels in normal mucosa and in chemoresistant colorectal cancer cells compared with isogenic chemo-naïve colorectal cancer cells. Overexpression of exogenous ACLy by lentivirus transduction in chemo-naïve colorectal cancer cells led to significant chemoresistance to SN38 but not to 5-fluorouracil or oxaliplatin. Knockdown of ACLy by siRNA or inhibition of its activity by a small-molecule inhibitor sensitized chemo-naïve colorectal cancer cells to SN38. Furthermore, ACLy was significantly increased in cancer cells that had acquired resistance to SN38. In contrast to chemo-naïve cells, targeting ACLy alone was not effective in resensitizing resistant cells to SN38, due to a compensatory activation of the AKT pathway triggered by ACLy suppression. Combined inhibition of AKT signaling and ACLy successfully resensitized SN38-resistant cells to SN38. We conclude that targeting ACLy may improve the therapeutic effects of irinotecan and that simultaneous targeting of ACLy and AKT may be warranted to overcome SN38 resistance. Mol Cancer Ther; 12(12); 2782–91. ©2013 AACR.

Intracellular activation of EGFR by fatty acid synthase dependent palmitoylation

Epidermal growth factor receptor (EGFR) is an oncogenic receptor tyrosine kinase. Canonically, the tyrosine kinase activity of EGFR is regulated by its extracellular ligands. However, ligand-independent activation of EGFR exists in certain cancer cells, and the underlying mechanism remains to be defined. In this study, using PC3 and A549 cells as a model, we have found that, in the absence of extracellular ligands, a subpopulation of EGFR is constitutively active, which is needed for maintaining cell proliferation. Furthermore, we have found that fatty acid synthase (FASN)-dependent palmitoylation of EGFR is required for EGFR dimerization and kinase activation. Inhibition of FASN or palmitoyl acyltransferases reduced the activity and down-regulated the levels of EGFR, and sensitized cancer cells to EGFR tyrosine kinase inhibitors. It is concluded that EGFR can be activated intracellularly by FASN-dependent palmitoylation. This mechanism may serve as a new target for improving EGFR-based cancer therapy.

Involvement of de novo synthesized palmitate and mitochondrial EGFR in EGF induced mitochondrial fusion of cancer cells

Increased expressions of fatty acid synthase (FASN) and epidermal growth factor receptor (EGFR) are common in cancer cells. De novo synthesis of palmitate by FASN is critical for the survival of cancer cells via mechanisms independent of its role as an energy substrate. Besides the plasma membrane and the nucleus, EGFR can also localize at the mitochondria; however, signals that can activate mitochondrial EGFR (mtEGFR) and the functions of mtEGFR of cancer cells remain unknown. The present study characterizes mtEGFR in the mitochondria of cancer cells (prostate and breast) and reveals that mtEGFR can promote mitochondrial fusion through increasing the protein levels of fusion proteins PHB2 and OPA1. Activation of plasma membranous EGFR (pmEGFR) stimulates the de novo synthesis of palmitate through activation of FASN and ATP-citrate lyase (ACLy). In vitro kinase assay with isolated mitochondria shows that palmitate can activate mtEGFR. Inhibition of FASN blocks the mtEGFR phosphorylation and palmitoylation induced by EGF. Mutational studies show that the cysteine 797 is important for mtEGFR activation and palmitoylation. Inhibition of FASN can block EGF induced mitochondrial fusion and increased the sensitivity of prostate cancer cells to EGFR tyrosine kinase inhibitor. In conclusion, these results suggest that mtEGFR can be activated by pmEGFR through de novo synthesized palmitate to promote mitochondrial fusion and survival of cancer cells. This mechanism may serve as a novel target to improve EGFR-based cancer therapy.

EGFR–SGLT1 interaction does not respond to EGFR modulators, but inhibition of SGLT1 sensitizes prostate cancer cells to EGFR tyrosine kinase inhibitors

Overexpression of epidermal growth factor receptor (EGFR) is associated with poor prognosis in malignant tumors. Sodium/glucose co‐transporter 1 (SGLT1) is an active glucose transporter that is overexpressed in many cancers including prostate cancer. Previously, we found that EGFR interacts with and stabilizes SGLT1 in cancer cells.

Sodium/Glucose Co-transporter 1 Expression Increases in Human Diseased Prostate

Sodium/glucose co-transporter 1 (SGLT1) is an active glucose transporter that takes up glucose into cells independent of the extracellular concentration of glucose. This transporter plays a critical role in maintaining glucose homeostasis at both physiological and pathological levels. The expression level of SGLT1 in normal and diseased human prostatic tissue has not been determined. We produced two rabbit polyclonal antibodies against human SGLT1, one each for immunohistochemical and Western blot analyses, and characterized the expression of SGLT1 in human prostate tissues: normal prostate (n=3), benign prostatic hyperplasia (BPH) (n=53), prostatic intraepithelial neoplasia (PIN) (n=9), and prostate cancer (PCa) (n=44). In normal prostate tissue, SGLT1 was weakly expressed exclusively in the epithelium. The transporter was significantly increased in the basal cells and stromal cells of BPH, increased in the epithelial cells of PIN, and frequently overexpressed in stromal cells and universally overexpressed in the tumor cells of PCa. The pattern of expression was shown as membranous/ cytoplasmic staining in low-grade cancer cells and nuclear envelope staining in high-grade cancer cells. The SGLT1-positive stromal cells of BPH and PCa tissues were negative for tenascin, a marker of reactive stromal cells. We concluded that SGLT1 is up-regulated in BPH and PCa, and SGLT1 may serve as a potential therapeutic target for treating these prostate disorders.

Transcriptional Regulation of Core Autophagy and Lysosomal Genes by the Androgen Receptor Promotes Prostate Cancer Progression.

ABSTRACT AR (androgen receptor) signaling is crucial for the development and maintenance of the prostate as well as the initiation and progression of prostate cancer. Despite the ARs central role in prostate cancer progression, it is still unclear which AR-mediated processes drive the disease. Here, we identified 4 core autophagy genes: ATG4B, ATG4D, ULK1, and ULK2, in addition to the transcription factor TFEB, a master regulator of lysosomal biogenesis and function, as transcriptional targets of AR in prostate cancer. These findings were significant in light of our recent observation that androgens promoted prostate cancer cell growth in part through the induction of autophagy. Expression of these 5 genes was essential for maximal androgen-mediated autophagy and cell proliferation. In addition, expression of each of these 5 genes alone or in combination was sufficient to increase prostate cancer cell growth independent of AR activity. Further, bioinformatic analysis demonstrated that the expression of these genes correlated with disease progression in 3 separate clinical cohorts. Collectively, these findings demonstrate a functional role for increased autophagy in prostate cancer progression, provide a mechanism for how autophagy is augmented, and highlight the potential of targeting this process for the treatment of advanced prostate cancer.

Alcohol Regulates Genes that Are Associated with Response to Endocrine Therapy and Attenuates the Actions of Tamoxifen in Breast Cancer Cells

Hereditary, hormonal, and behavioral factors contribute to the development of breast cancer. Alcohol consumption is a modifiable behavior that is linked to increased breast cancer risks and is associated with the development of hormone-dependent breast cancers as well as disease progression and recurrence following endocrine treatment. In this study we examined the molecular mechanisms of action of alcohol by applying molecular, genetic, and genomic approaches in characterizing its effects on estrogen receptor (ER)-positive breast cancer cells. Treatments with alcohol promoted cell proliferation, increased growth factor signaling, and up-regulated the transcription of the ER target gene GREB1 but not the canonical target TFF1/pS2. Microarray analysis following alcohol treatment identified a large number of alcohol-responsive genes, including those which function in apoptotic and cell proliferation pathways. Furthermore, expression profiles of the responsive gene sets in tumors were strongly associated with clinical outcomes in patients who received endocrine therapy. Correspondingly, alcohol treatment attenuated the anti-proliferative effects of the endocrine therapeutic drug tamoxifen in ER-positive breast cancer cells. To determine the contribution and functions of responsive genes, their differential expression in tumors were assessed between outcome groups. The proto-oncogene BRAF was identified as a novel alcohol- and estrogen-induced gene that showed higher expression in patients with poor outcomes. Knock-down of BRAF, moreover, prevented the proliferation of breast cancer cells. These findings not only highlight the mechanistic basis of the effects of alcohol on breast cancer cells and increased risks for disease incidents and recurrence, but may facilitate the discovery and characterization of novel oncogenic pathways and markers in breast cancer research and therapeutics.

Identification of a Novel Coregulator, SH3YL1, That Interacts With the Androgen Receptor N-Terminus

Nuclear receptor (NR)-mediated transcriptional activity is a dynamic process that is regulated by the binding of ligands that induce distinct conformational changes in the NR. These structural alterations lead to the differential recruitment of coregulators (coactivators or corepressors) that control the expression of NR-regulated genes. Here, we show that a stretch of proline residues located within the N-terminus of androgen receptor (AR) is a bona fide coregulator binding surface, the disruption of which reduces the androgen-dependent proliferation and migration of prostate cancer (PCa) cells. Using T7 phage display, we identified a novel AR-interacting protein, Src homology 3 (SH3)-domain containing, Ysc84-like 1 (SH3YL1), whose interaction with the receptor is dependent upon this polyproline domain. As with mutations within the AR polyproline domain, knockdown of SH3YL1 attenuated androgen-mediated cell growth and migration. RNA expression analysis revealed that SH3YL1 was required for the induction of a subset of AR-modulated genes. Notable was the observation that ubinuclein 1 (UBN1), a key member of a histone H3.3 chaperone complex, was a transcriptional target of the AR/SH3YL1 complex, correlated with aggressive PCa in patients, and was necessary for the maximal androgen-mediated proliferation and migration of PCa cells. Collectively, these data highlight the importance of an amino-terminal activation domain, its associated coregulator, and downstream transcriptional targets in regulating cellular processes of pathological importance in PCa.

Abstract P1-08-04: SOX9 is a critical regulator of triple-negative breast cancer cell growth and invasion

Background: SRY (Sex Determining Region Y)-related HMG-box (SOX) genes belong to a super-family of genes, which is characterized by a homologous sequence called the HMG-box residing on the Y-chromosome. There are 20 SOX genes present in humans and mice. We performed a siRNA screen of SOX transcription factors, and found that SOX9 was essential for breast cancer cell growth. The SOX9 protein recognizes the sequence CCTTGAG along with other members of the HMG-box class DNA-binding proteins and has been shown to be required for development, differentiation and lineage commitment. Moreover, SOX9 is expressed in adenocarcinomas, and is highly expressed in the most aggressive cancers. Our previous data shows SOX9 is highly expressed in “triple negative breast cancer” (TNBC) than in non-TNBC. Thus, we hypothesized that the SOX9 transcription factor acts as an essential molecule regulating TNBC growth and invasion. To test the hypothesis, we used SOX9-overexpressed, or SOX9-knockdown/knockout breast cancer cell models to determine whether SOX9 is necessary and/or sufficient to regulate TNBC cell proliferation, migration and invasion. Methods: We measured the cell growth using an automated cell counting assay. Cell migration and invasion were detected by transwell migration & invasion assays in ER-positive (MCF7 and ZR75-1) and ER-negative (MDA231 and MDA468) breast cancer cells. DOX-inducible SOX9-knockout cell lines were established in MDA231, MDA468, and LM2 cell lines using an inducible Cas9-CRISPR system. A SOX9 expressing lentivirus was used to overexpress SOX9, and siRNAs was used to knockdown SOXs in the different breast cancer cells. Protein and mRNA levels of SOX9 in TNBC, non-TNBC, immortalized human breast epithelial cell lines were examined by western blotting and qRT-PCR assay. Results: Knockdown of SOXs by siRNA caused decreased cell proliferation of MDA231 by ≥50% and of MDA468 by 30%-50% in siSOX4, siSOX6, siSOX9, siSOX10 and siSOX11 treatment groups (but not in siSOX8 and siSOX17 treatment groups). However, in MCF7 and T47D cell lines, treatment with siRNA to these SOX factors did not cause significant cell growth reduction. We demonstrated that SOX9 is more highly expressed in TNBC cells at both the mRNA and protein levels. Knockdown of SOX9 decreased cell migration and invasion of MDA231 to 25% and 50% respectively. The same effect also was observed in MDA468 cells, with approximately a 50% decline in migration and invasion. In SOX9-knockout MDA231, MDA468, and LM2 cells, cell proliferation, migration, and invasion were significantly reduced. In contrast, overexpression of SOX9 in MCF7 and ZR75-1 cells increased cell migration and invasion. We are now conducting in vivo studies to determine the effect of SOX9 on breast cancer cell metastasis. Conclusion: SOX9 is a critical regulator of TNBC cell proliferation, migration and invasion. These studies suggest that regulating SOX9 transcription factor and its signaling pathway will be a promising therapeutic strategy to treat TNBC and prevent metastasis. This work was supported by a Susan G. Komen Scientific Advisory Board Grant, SAB1600006 (PB), and a grant from the Breast Cancer Research Foundation 2015-2016 BCRF grant(PB), and by the Charles Cain Endowment (PB). Citation Format: Ma Y, Shepherd J, Mazumdar A, Zhao D, Bollu L, Hill J, Zhang Y, Brown P. SOX9 is a critical regulator of triple-negative breast cancer cell growth and invasion [abstract]. In: Proceedings of the 2016 San Antonio Breast Cancer Symposium; 2016 Dec 6-10; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2017;77(4 Suppl):Abstract nr P1-08-04.