In breast cancer (BC) the employment of sequencing technologies for metagenomic analyses has allowed not only the description of the overall metagenomic landscape but also the specific microbial changes and their functional implications. Most of the available data suggest that BC is related to bacterial dysbiosis in both the gut microenvironment and breast tissue. It is hypothesized that changes in the composition and functions of several breast and gut bacterial taxa may contribute to BC development and progression through several pathways. One of the most prominent roles of gut microbiota is the regulation of steroid-hormone metabolism, such as estrogens, a component playing an important role as risk factor in BC development, especially in postmenopausal women. On the other hand, breast and gut resident microbiota are the link in the reciprocal interactions between cancer cells and their local environment, since microbiota are capable of modulating mucosal and systemic immune responses. Several in vivo and in vitro studies show remarkable evidence that diet, probiotics and prebiotics could exert important anticarcinogenic effects in BC. Moreover, gut microbiota have an important role in the metabolism of chemotherapeutic drugs and in the activity of immunogenic chemotherapies since they are a potential dominant mediator in the response to cancer therapy. Then, the microbiome impact in BC is multi-factorial, and the gut and breast tissue bacteria population could be important in regulating the local immune system, in tumor formation and progression and in therapy response and/or resistance.
Endometrial cancer is one of the most common gynaecological malignancies worldwide. Histologically, two types of endometrial cancer with morphological and molecular differences and also therapeutic implications have been identified. Type I endometrial cancer has an endometrioid morphology and is estrogen-dependent, while Type II appears with non-endometrioid differentiation and follows an estrogen-unrelated pathway. Understanding the molecular biology and genetics of endometrial cancer is crucial for its prognosis and the development of novel therapies for its treatment. However, until now, scant attention has been paid to environmental components like the microbiome. Recently, due to emerging evidence that the uterus is not a sterile cavity, some studies have begun to investigate the composition of the endometrial microbiome and its role in endometrial cancer. In this review, we summarize the current state of this line of investigation, focusing on the relationship between gut and endometrial microbiome and inflammation, estrogen metabolism, and different endometrial cancer therapies.
Breast cancer (BC) is the most frequent neoplasia affecting women worldwide normally detected at early stages. In this regard, early diagnosis drastically decreases mortality, however, around 20% of these patients will later relapse. This is mainly caused by undetectable molecular residual disease (MRD) not eliminated by standard primary treatments. Therefore, it is crucial to detect the after-treatment MRD to stratify the patients by their risk of relapse. Liquid biopsies have emerged as non-invasive method to obtain information about tumors and improve clinical cancer management. Regarding this, much has been hypothesized about utilizing high blood volumes to overcome the necessity of complex and resource-intensive next generation sequencing (NGS) methodologies to detect highly diluted blood tumor components in localized cancers. Herein, we employed a combined analysis of circulating tumor DNA (ctDNA) and circulating tumor cells (CTCs) together with high blood volumes and single-assay droplet digital PCR (ddPCR) to detect MRD with ultra-high sensitivity. We prospectively assayed 124 samples extracted at baseline, post-neoadjuvant therapy (NAT), post-surgery and a follow-up on a six-monthly basis. A median of 76.40 mL of blood to detect CTCs and 40 mL of plasma to detect ctDNA per patient from 19 BC women were used in this study. ddPCR assays were performed with a median of 14 partitions per determination to detect ctDNA and 12 partitions for CTCs. Overall, ctDNA, CTCs and ctDNA and/or CTCs were detected in 84.21%, 66.66% and 89.47% respectively in the pre-treatment blood samples. MRD (ctDNA and/or CTCs) was detected in 73.68% of the after NAT blood samples. On the other hand, it was detected in 46.66% and 70.00% of the post-surgery and follow-up samples respectively. Post-NAT MRD was detected in 57.14% (4/7) and 83.33% (10/12) of patients with and without pathological complete response pCR respectively. To note, the discordant patients achieving pCR in tissue with detectable MRD in blood were high-risk BC. Importantly, in one of the two patients without pCR and no MRD detected, not enough sample were available to complete the analysis. The other discordant patient presented a localized disease with residual cancer burden value of 1 and no lymph nodes affected. In 1 out of 19 (5.26%) patient clinically relapsed with a positive MRD detection 6 months earlier. Applying this methodology, we observed a sensitivity of 0.004% in ctDNA detection and 0.224 CTCs per mL of blood. Overall, this novel methodology greatly improves sensitivity for ctDNA and CTCs detection in treatment-naïve early BC. In addition, MRD was successfully detected in post-treatment samples antedating clinical relapse by 6 months in one patient. This prospective study is potentially demonstrating that using high blood volumes and a single-assay ddPCR is a cost-effective strategy to monitor localized BC and predict relapses. Citation Format: Alfonso Alba-Bernal, Ana Godoy-Ortiz, María Emilia Domínguez-Recio, Begoña Jimenez-Rodriguez, María Elena Quirós-Ortega, Esperanza López-López, Guillermo Carbajosa-Antona, Jesús Peralta-Linero, Luis Vicioso, Estefanía Bellagarza-García, Guadalupe Dolores Garrido-Ruiz, Cynthia Robles-Podadera, Alicia Garrido-Aranda, María Dunia Roldán-Díaz, Jesús Velasco-Suelto, Rocío Lavado-Valenzuela, Martina Álvarez, Nuria Ribelles, Javier Pascual, Emilio Alba, Iñaki Comino-Méndez. Increasing blood volumes to detect minimal residual disease in neoadjuvant-treated early breast cancer patients. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 6610.
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