ABSTRACT: Type I-B CRISPR-Cas systems represent the most abundant CRISPR subtype in nature and have emerged as powerful tools for endogenous genome editing in diverse prokaryotes. Here we reconstitute and characterize the type I-B1 system from the thermophile Thermotoga maritima (Tma) using purified components. We demonstrate that Tma Cascade requires standalone Cas11 expression, as the cryptic internal translation start site within cas8b1 is non-functional in E. coli. The reconstituted system exhibits canonical type I function including RNA-guided DNA binding, PAM-dependent target discrimination, Cas3-mediated degradation, and seed region interrogation spanning seven PAM-proximal nucleotides. Using next-generation sequencing-based PAM library screens, we define a YYD consensus PAM (Y = C/T; D = G/A/T) with strong discrimination against the array repeat-adjacent sequence (AAC). Comprehensive PAM profiling reveals context-dependent tolerance for non-consensus sequences and identifies numerous intermediate-activity PAMs that may function in priming. Comparison with other characterized type I-B systems reveals correlation between Cas8b variant and position -3 specificity, conserved pyrimidine preference at position -2, and variability at position -1. This work establishes a thermostable type I-B platform for biotechnological applications and provides insights into evolutionary mechanisms balancing PAM promiscuity with self-discrimination in the most abundant CRISPR-Cas subtype.