# MicroRNA Profiling as a Predictive Indicator for Time to First Treatment in Chronic Lymphocytic Leukemia: Insights from the O-CLL1 Prospective Study

**Authors:** Ennio Nano, Francesco Reggiani, Adriana Agnese Amaro, Paola Monti, Monica Colombo, Nadia Bertola, Fabiana Ferrero, Franco Fais, Antonella Bruzzese, Enrica Antonia Martino, Ernesto Vigna, Noemi Puccio, Mariaelena Pistoni, Federica Torricelli, Graziella D’Arrigo, Gianluigi Greco, Giovanni Tripepi, Carlo Adornetto, Massimo Gentile, Manlio Ferrarini, Massimo Negrini, Fortunato Morabito, Antonino Neri, Giovanna Cutrona

PMC · DOI: 10.3390/ncrna10050046 · 2024-08-23

## TL;DR

This study shows that specific microRNAs can improve predictions of when chronic lymphocytic leukemia patients will need treatment.

## Contribution

The study identifies 16 miRNAs that independently predict time to first treatment in CLL, improving prognostic models.

## Key findings

- Six established variables predicted TTFT with a Harrell’s C-index of 75% and 45.4% variance explained.
- Adding 16 miRNAs increased the C-index to 81.1% and explained 63.3% of TTFT variance.
- miRNA–mRNA correlations suggest biological pathways relevant to treatment response and disease progression.

## Abstract

A “watch and wait” strategy, delaying treatment until active disease manifests, is adopted for most CLL cases; however, prognostic models incorporating biomarkers have shown to be useful to predict treatment requirement. In our prospective O-CLL1 study including 224 patients, we investigated the predictive role of 513 microRNAs (miRNAs) on time to first treatment (TTFT). In the context of this study, six well-established variables (i.e., Rai stage, beta-2-microglobulin levels, IGVH mutational status, del11q, del17p, and NOTCH1 mutations) maintained significant associations with TTFT in a basic multivariable model, collectively yielding a Harrell’s C-index of 75% and explaining 45.4% of the variance in the prediction of TTFT. Concerning miRNAs, 73 out of 513 were significantly associated with TTFT in a univariable model; of these, 16 retained an independent relationship with the outcome in a multivariable analysis. For 8 of these (i.e., miR-582-3p, miR-33a-3p, miR-516a-5p, miR-99a-5p, and miR-296-3p, miR-502-5p, miR-625-5p, and miR-29c-3p), a lower expression correlated with a shorter TTFT, whereas in the remaining eight (i.e., miR-150-5p, miR-148a-3p, miR-28-5p, miR-144-5p, miR-671-5p, miR-1-3p, miR-193a-3p, and miR-124-3p), the higher expression was associated with shorter TTFT. Integrating these miRNAs into the basic model significantly enhanced predictive accuracy, raising the Harrell’s C-index to 81.1% and the explained variation in TTFT to 63.3%. Moreover, the inclusion of the miRNA scores enhanced the integrated discrimination improvement (IDI) and the net reclassification index (NRI), underscoring the potential of miRNAs to refine CLL prognostic models and providing insights for clinical decision-making. In silico analyses on the differently expressed miRNAs revealed their potential regulatory functions of several pathways, including those involved in the therapeutic responses. To add a biological context to the clinical evidence, an miRNA–mRNA correlation analysis revealed at least one significant negative correlation between 15 of the identified miRNAs and a set of 50 artificial intelligence (AI)-selected genes, previously identified by us as relevant for TTFT prediction in the same cohort of CLL patients. In conclusion, the identification of specific miRNAs as predictors of TTFT holds promise for enhancing risk stratification in CLL to predict therapeutic needs. However, further validation studies and in-depth functional analyses are required to confirm the robustness of these observations and to facilitate their translation into meaningful clinical utility.

## Linked entities

- **Genes:** NOTCH1 (notch receptor 1) [NCBI Gene 4851]
- **Diseases:** chronic lymphocytic leukemia (MONDO:0004948), CLL (MONDO:0004948)

## Full-text entities

- **Genes:** IGHV3-69-1 (immunoglobulin heavy variable 3-69-1 (pseudogene)) [NCBI Gene 28402] {aka IGHV3-H, IGHV3H}, MIR296 (microRNA 296) [NCBI Gene 407022] {aka MIRN296, miRNA296, mir-296}, NOTCH1 (notch receptor 1) [NCBI Gene 4851] {aka AOS5, AOVD1, TAN1, hN1}, MIR502 (microRNA 502) [NCBI Gene 574504] {aka MIRN502, hsa-mir-502, mir-502}, FSD1 (fibronectin type III and SPRY domain containing 1) [NCBI Gene 79187] {aka GLFND, MIR1}, MIR28 (microRNA 28) [NCBI Gene 407020] {aka MIRN28, hsa-mir-28, miR-28}, MIR671 (microRNA 671) [NCBI Gene 768213] {aka MIRN671, hsa-mir-671, mir-671}, MIR150 (microRNA 150) [NCBI Gene 406942] {aka MIRN150, miRNA150, mir-150}, MIR148A (microRNA 148a) [NCBI Gene 406940] {aka MIRN148, MIRN148A, hsa-mir-148, mir-148a}, MIR625 (microRNA 625) [NCBI Gene 693210] {aka MIRN625, hsa-mir-625}, MIR33A (microRNA 33a) [NCBI Gene 407039] {aka MIR33, MIRN33, MIRN33A, hsa-mir-33, hsa-mir-33a, miR-33}, MIR144 (microRNA 144) [NCBI Gene 406936] {aka MIRN144, mir-144}, MIR124-3 (microRNA 124-3) [NCBI Gene 406909] {aka MIRN124-3, MIRN124A3, mir-124-3}, MIR193A (microRNA 193a) [NCBI Gene 406968] {aka MIRN193, MIRN193A, mir-193a}, HLA-G (major histocompatibility complex, class I, G) [NCBI Gene 3135] {aka MHC-G}, MIR99A (microRNA 99a) [NCBI Gene 407055] {aka MIRN99A, mir-99a}
- **Diseases:** CLL (MESH:D015451)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11417859/full.md

---
Source: https://tomesphere.com/paper/PMC11417859