Direct and indirect roles of His‐418 in metal binding and in the activity of β‐galactosidase (E. coli)

The active site of ß‐galactosidase (E. coli) contains a Mg²⁺ ion ligated by Glu‐416, His‐418 and Glu‐461 plus three water molecules. A Na⁺ ion binds nearby. To better understand the role of the active site Mg²⁺ and its ligands, His‐418 was substituted with Asn, Glu and Phe. The Asn‐418 and Glu‐418 variants could be crystallized and the structures were shown to be very similar to native enzyme. The Glu‐418 variant showed increased mobility of some residues in the active site, which explains why the substitutions at the Mg²⁺ site also reduce Na⁺ binding affinity. The Phe variant had reduced stability, bound Mg²⁺ weakly and could not be crystallized. All three variants have low catalytic activity due to large decreases in the degalactosylation rate. Large decreases in substrate binding affinity were also observed but transition state analogs bound as well or better than to native. The results indicate that His‐418, together with the Mg²⁺, modulate the central role of Glu‐461 in binding and as a general acid/base catalyst in the overall catalytic mechanism. Glucose binding as an acceptor was also dramatically decreased, indicating that His‐418 is very important for the formation of allolactose (the natural inducer of the lac operon).     

Hydrolysis of peptidoglycan is modulated by amidation of meso‐diaminopimelic acid and Mg2+ in Bacillus subtilis

The ability of excess Mg²⁺ to compensate the absence of cell wall related genes in Bacillus subtilis has been known for a long time, but the mechanism has remained obscure. Here, we show that the rigidity of wild‐type cells remains unaffected with excess Mg²⁺, but the proportion of amidated meso‐diaminopimelic (mDAP) acid in their peptidoglycan (PG) is significantly reduced. We identify the amidotransferase AsnB as responsible for mDAP amidation and show that the gene encoding it is essential without added Mg²⁺. Growth without excess Mg²⁺ causes ΔasnB mutant cells to deform and ultimately lyse. In cell regions with deformations, PG insertion is orderly and indistinguishable from the wild‐type. However, PG degradation is unevenly distributed along the sidewalls. Furthermore, ΔasnB mutant cells exhibit increased sensitivity to antibiotics targeting the cell wall. These results suggest that absence of amidated mDAP causes a lethal deregulation of PG hydrolysis that can be inhibited by increased levels of Mg²⁺. Consistently, we find that Mg²⁺ inhibits autolysis of wild‐type cells. We suggest that Mg²⁺ helps to maintain the balance between PG synthesis and hydrolysis in cell wall mutants where this balance is perturbed in favor of increased degradation.     

Genetic analysis of the histidine operon control region of Salmonella typhimurium

Mutants of the histidine operon control region (hisO) include two classes: (1) those completely unable to express the operon (His auxotrophs), and (2) prototrophs that are unable to achieve fully induced levels of operon expression (still His⁺ but sensitive to the drug amino-triazole). Using new, as well as previously existing hisO mutants, we constructed a fine-structure deletion map of hisO. Mutations that presumably alter the his promoter map at one end of hisO; mutations that alter the his attenuator map at the other end of hisO. Between the promoter and the attenuator lie a number of mutations that affect either the translation of the his leader peptide gene, or the formation and stability of his leader messenger RNA structures. All of the point mutations mapping in this central region revert to His⁺ at a very high frequency (10^?5 to 10^?6); this frequency is increased by both base substitution and frameshift-inducing mutagens. Many of the His^? mutants are suppressed by informational suppressors; all three types of nonsense mutations have been identified, demonstrating that translation of a region of hisO between the promoter and attenuator is essential for his operon expression. All of the hisO mutations tested are cis-dominant.     

PufQ regulates porphyrin flux at the haem/bacteriochlorophyll branchpoint of tetrapyrrole biosynthesis via interactions with ferrochelatase

Facultative phototrophs such as Rhodobacter sphaeroides can switch between heterotrophic and photosynthetic growth. This transition is governed by oxygen tension and involves the large‐scale production of bacteriochlorophyll, which shares a biosynthetic pathway with haem up to protoporphyrin IX. Here, the pathways diverge with the insertion of Fe²⁺ or Mg²⁺ into protoporphyrin by ferrochelatase or magnesium chelatase, respectively. Tight regulation of this branchpoint is essential, but the mechanisms for switching between respiratory and photosynthetic growth are poorly understood. We show that PufQ governs the haem/bacteriochlorophyll switch; pufQ is found within the oxygen‐regulated pufQBALMX operon encoding the reaction centre–light‐harvesting photosystem complex. A pufQ deletion strain synthesises low levels of bacteriochlorophyll and accumulates the biosynthetic precursor coproporphyrinogen III; a suppressor mutant of this strain harbours a mutation in the hemH gene encoding ferrochelatase, substantially reducing ferrochelatase activity and increasing cellular bacteriochlorophyll levels. FLAG‐immunoprecipitation experiments retrieve a ferrochelatase‐PufQ‐carotenoid complex, proposed to regulate the haem/bacteriochlorophyll branchpoint by directing porphyrin flux toward bacteriochlorophyll production under oxygen‐limiting conditions. The co‐location of pufQ and the photosystem genes in the same operon ensures that switching of tetrapyrrole metabolism toward bacteriochlorophyll is coordinated with the production of reaction centre and light‐harvesting polypeptides.