Abstract
Tuberculosis (TB), primarily caused by Mycobacterium tuberculosis (Mtb), remains a leading cause of infectious disease mortality worldwide. Global TB control efforts face several hurdles, including the lack of a broadly effective vaccine, limited sensitivity of current diagnostics, particularly for paucibacillary and extrapulmonary TB, and significant adverse effects associated with prolonged small-molecule drug regimens. The growing prevalence of multidrug-resistant (MDR) and extensively drug-resistant (XDR) strains further underscores the urgent need for innovative therapeutic strategies. We outline characteristics of next-generation TB therapeutics. We show that antibody (Ab)-drug conjugates (ADCs) satisfy many of those desirable characteristics. Since a major hurdle to this approach lies in Mtb-specific Abs, we highlight an open-access resource comprising a broad panel of Mtb-specific mouse monoclonal antibodies targeting key factors involved in Mtb survival, immune evasion, and pathogenesis. These critical Mtb virulence factors include heat shock proteins (GroES, DnaK, and HspX), surface-associated or secreted proteins (LAM, Ag85, HBHA, Mpt64/CFP-21, and PhoS1/PstS1), cell wall/envelope-associated proteins (LprG/p27), and detoxifying enzymes (KatG and SodA). The resource provides full-length sequences of the immunoglobulin variable regions, enabling antibody engineering and facilitating translational TB research across vaccine design, diagnostic development, and immunotherapeutic applications, in addition to ADCs. This ADC targeted delivery strategy holds promise for overcoming TB heterogeneity and eliminating both active and dormant Mtb populations within a single therapeutic formulation and offers a novel avenue for precision TB treatment.