2=-Chloropentostatin (2=-Cl PTN, 2=-chloro-2=-deoxycoformycin) and 2=-amino-2=-deoxyadenosine (2=-amino dA) are two adenosine-derived nucleoside antibiotics coproduced by Actinomadura sp. strain ATCC 39365. 2=-Cl PTN is a potent adenosine deaminase (ADA) inhibitor featuring an intriguing 1,3-diazepine ring, as well as a chlorination at C-2= of ribose, and 2=-amino dA is an adenosine analog showing bioactivity against RNA-type virus infection. However, the biosynthetic logic of them has remained poorly understood. Here, we report the identification of a single gene cluster (ada) essential for the biosynthesis of 2=-Cl PTN and 2=-amino dA. Further systematic genetic investigations suggest that 2=-Cl PTN and 2=-amino dA are biosynthesized by independent pathways. Moreover, we provide evidence that a predicted cation/H ϩ antiporter, AdaE, is involved in the chlorination step during 2=-Cl PTN biosynthesis. Notably, we demonstrate that 2=-amino dA biosynthesis is initiated by a Nudix hydrolase, AdaJ, catalyzing the hydrolysis of ATP. Finally, we reveal that the host ADA (designated ADA1), capable of converting adenosine/2=-amino dA to inosine/2=-amino dI, is not very sensitive to the powerful ADA inhibitor pentostatin. These findings provide a basis for the further rational pathway engineering of 2=-Cl PTN and 2=-amino dA production.IMPORTANCE 2=-Cl PTN/PTN and 2=-amino dA have captivated the great interests of scientists, owing to their unusual chemical structures and remarkable bioactivities. However, the precise logic for their biosynthesis has been elusive for decades. Actually, the identification and elucidation of their biosynthetic pathways not only enrich the biochemical repertoire of novel enzymatic reactions but may also lay solid foundations for the pathway engineering and combinatorial biosynthesis of this family of purine nucleoside antibiotics to generate novel hybrid analogs with improved features.KEYWORDS 2=-chloropentostatin, 2=-amino-2=-deoxyadenosine, nucleoside antibiotics, biosynthesis, Nudix hydrolase, adenosine deaminase N ucleoside antibiotics are a large family of important microbial natural products harboring wide-range biological properties and distinctive structural features (1-3). Their biosynthesis generally follows a succinct logic by sequential enzymatic modification of nucleosides or nucleotides originating from primary metabolisms (1). Usually, nucleosides and nucleotides play pleiotropic roles in most fundamental cellular metabolisms; therefore, nucleoside antibiotics are able to target the biosynthesis of diverse biomacromolecules, including nucleic acids, proteins, and glycans (1).