Functional analysis of the Escherichia coli molybdopterin cofactor biosynthesis protein MoeA by site-directed mutagenesis

The emergence of catalytic and structural diversity within the beta-clip fold

The beta-clip fold includes a diverse group of protein domains that are unified by the presence of two characteristic waist-like constrictions, which bound a central extended region. Members of this fold include enzymes like deoxyuridine triphosphatase and the SET methylase, carbohydrate-binding domains like the fish antifreeze proteins/Sialate synthase C-terminal domains, and functionally enigmatic accessory subunits of urease and molybdopterin biosynthesis protein MoeA. In this study, we reconstruct the evolutionary history of this fold using sensitive sequence and structure comparisons methods. Using sequence profile searches, we identified novel versions of the beta-clip fold in the bacterial flagellar chaperone FlgA and the related pilus protein CpaB, the StrU-like dehydrogenases, and the UxaA/GarD-like hexuronate dehydratases (SAF superfamily). We present evidence that these versions of the beta-clip domain, like the related type III anti-freeze proteins and C-terminal domains of sialic acid synthases, are involved in interactions with carbohydrates. We propose that the FlgA and CpaB-like proteins mediate the assembly of bacterial flagella and Flp pili by means of their interactions with the carbohydrate moieties of peptidoglycan. The N-terminal beta-clip domain of the hexuronate dehydratases appears to have evolved a novel metal-binding site, while their C-terminal domain is likely to adopt a metal-binding TIM barrel-like fold. Using structural comparisons, we show that the beta-clip fold can be further classified into two major groups, one that includes the SAF, SET, dUTPase superfamilies, and the other that includes the phage lambda head decoration protein, the beta subunit of urease and the C-terminal domain of the molybdenum cofactor biosynthesis protein MoeA. Structural comparisons also suggest the beta-clip fold was assembled through the duplication of a three-stranded unit. Though the three-stranded units are likely to have had a common origin, we present evidence that complete beta-clip domains were assembled through such duplications, independently on multiple occasions. There is also evidence for circular permutation of the basic three-stranded unit on different occasions in the evolution of the beta-clip unit. We also describe how assembly of this fold from a basic three-stranded unit has been utilized to accommodate a variety of activities in its different versions.

Sequence and transcriptional analysis of a gene cluster of Pseudomonas putida 86 involved in quinoline degradation

Although quinoline 2-oxidoreductase (Qor) and 1H-2-oxoquinoline 8-monooxygenase (OxoOR), which catalyse the first two steps of quinoline degradation by Pseudomonas putida 86, and their genes have been investigated in some detail, the genetic organization and regulation of the catabolic pathway are not known yet. A gene cluster involved in quinoline degradation was characterized. Upstream of oxoO encoding the oxygenase component of OxoOR, the gene oxoS coding for a XylS-type protein is located. The DNA region downstream of oxoO comprises potential open reading frames (ORFs) that may code for further catabolic enzymes (an alpha/beta-hydrolase fold protein, and an amidase), and for accessory proteins presumably required for the assembly of metal cofactor containing holoenzymes (XdhC-like protein, MoeC- and MobA-like protein(s), IscS and IscU). The potential iscU gene is followed by the genes qorMSL that encode the structural subunits of Qor. Three potential ORFs (ORFs7-9) are located between qorMSL and oxoR, which codes for the reductase component of OxoOR. ORFs7-9 have counterparts in the cox (CO oxidizing system) and nic (nicotine degradation) gene clusters. Transcription of all these genes and ORFs located downstream of oxoS is induced by quinoline or 1H-2-oxoquinoline. Insertional inactivation of oxoS abolished quinoline-induced transcription. However, weak transcription of ORFs7-9 also occurred independent of quinoline and OxoS. The typical tandem recognition site for a XylS-type transcriptional activator was identified in the putative promoter region of qorM, and archetypal XylS indeed was found to activate synthesis of Qor. Motifs corresponding to single half-sites of a XylS-type binding site are located upstream of oxoO, the xdhC-like gene, and oxoR. Putative quinoline-specific transcriptional start sites were identified for these genes, and for qorM. The gene cluster probably is transcribed from several promoters, resulting in multiple overlapping polycistronic mRNAs.

The active site of the molybdenum cofactor biosynthetic protein domain Cnx1G

The final step of molybdenum cofactor biosynthesis in plants is catalyzed by the two-domain protein Cnx1. The G domain of Cnx1 (Cnx1G) binds molybdopterin with high affinity and transfers molybdenum to molybdopterin. Here, we describe the functional and structural characterization of structure-based Cnx1G mutants. For molybdopterin binding residues Thr542 and Ser573 were found to be important because different mutations of those residues resulted in 7- to 26-fold higher k(D) values for molybdopterin binding. Furthermore, we showed that the terminal phosphate of molybdopterin is directly involved in protein-pterin interactions as dephosphorylated molybdopterin binds with one magnitude of order lower affinity to the wild-type protein. Molybdopterin binding was not affected in mutants defective in Ser476, Asp486, or Asp515. However, molybdenum insertion was completely abolished, indicating their important role for catalysis. Based on these results we propose the binding of molybdopterin to a large depression in the structure of Cnx1G formed by beta5, alpha5, beta6, and alpha6, whereas the negatively charged depression formed by the loop between beta3 and alpha4, the N-terminal end of alpha2, the 3(10) helix, and the region between beta6 and alpha6 is involved in catalysis.