Chimeric antigen receptor T (CAR-T) cell therapy has revolutionized the treatment of B-cell malignancies, achieving deep and durable remissions in patients with B-cell acute lymphoblastic leukemia (B-ALL).¹ Despite remarkable therapeutic successes, rare but clinically significant secondary hematologic malignancies have been reported during CAR-T cell therapy, often driven by lineage switching or clonal selection.² Moreover, CAR-T cell therapy drives profound remodeling of the immune microenvironment, and the sustained inflammatory signaling may promote clonal evolution and influence disease progression.³ High-resolution approaches, such as single-cell RNA sequencing (scRNA-seq) and single-cell B-cell receptor sequencing (scBCR-seq), enable characterization of transcriptional programs, clonal identity, and temporal dynamics to dissect CAR-T cell therapy-induced clonal evolution and immune remodeling.⁴

Here, we report a case of B-ALL with B-cell receptor (BCR) heterogeneity at diagnosis that evolved into smoldering multiple myeloma (SMM) following CD19-targeted CAR-T therapy. The co-occurrence of B-ALL and SMM is exceptionally rare, as it requires malignant clones at distinct stages of B-cell development. This case provides a unique opportunity to dissect how CAR-T cell therapy drives B-lineage clonal evolution and reshapes the immune microenvironment. To this end, bone marrow mononuclear cells (BMMNC) were collected at multiple time points and subjected to longitudinal scRNA-seq and scBCR-seq to track dynamic changes in malignant and immune cell populations, thereby elucidating the mechanisms of clonal evolution and immune remodeling following CAR-T cell therapy. The patient gave informed consent and was enrolled in a clinical trial registered at clinicaltrials.gov (Identifier: NCT00123456).

In a study published in Nature today¹, researchers report a ‘megacluster’ of genes in Streptomyces bacteria that target a key metabolic process in bacteria. Streptomyces is one of the most studied bacterial genera and produces many antibiotic compounds, including those used to produce streptomycin, the first effective antibiotic against tuberculosis.

“They’ve discovered something new in a system so extensively studied — hidden in plain sight,” says Mark Blaskovich, who works on antibiotic development at the University of Queensland in Brisbane, Australia. The gene cluster produces five compounds — four antibiotics and a protein — that target different stages of the production of biotin, or vitamin B7, which is essential for bacterial cell growth. “Since evolution has already optimized this combination, we may be able to leverage it to develop novel antibiotic combinations,” Blaskovich says.

It is much more difficult for bacteria to develop resistance to antibiotics that attack multiple parts of an essential metabolic pathway, explains Brendan Wren, a microbiologist at the London School of Hygiene & Tropical Medicine. The latest work could also lead to the discovery of gene clusters that produce antibiotic compounds involved in other metabolic processes.