Six-month results following treatment of aggressive periodontitis with antimicrobial photodynamic therapy or amoxicillin and metronidazole

Objective

The use of antibacterial photodynamic therapy (aPDT) additionally to scaling and root planing (SRP) has been shown to positively influence the clinical outcomes. However, at present, it is unknown to what extent aPDT may represent a potential alternative to the use of systemic antibiotics in nonsurgical periodontal therapy in patients with aggressive periodontitis (AP). The aim of this study was to evaluate the outcomes following nonsurgical periodontal therapy and additional use of either aPDT or amoxicillin and metronidazole (AB) in patients with AP.

Material and methods

Thirty-six patients with AP displaying at least three sites with pocket depth (PD) ≥6 mm were treated with SRP and either systemic administration of AB for 7 days or with two episodes of aPDT. The following clinical parameters were evaluated at baseline and at 6 months: plaque index (PI), bleeding on probing (BOP), PD, gingival recession (GR) and clinical attachment level (CAL).

Results

Thirty-five patients have completed the 6-month evaluation. At 6 months, mean PD was statistically significantly reduced in both groups (from 5.0?±?0.8 to 3.0?±?0.6 mm with AB and from 5.1?±?0.5 to 3.9?±?0.8 mm with aPDT (p?p?p?p?=?0.03). Both therapies resulted in statistically significant reductions in all parameters compared to baseline.

Conclusion

While both treatments resulted in statistically significant clinical improvements, AB showed statistically significantly higher PD reduction and lower number of pockets ≥7 mm compared to aPDT.

Clinical relevance

In patients with AP, the two times application of aPDT in conjunction with nonsurgical periodontal therapy cannot be considered an alternative to the systemic use of amoxicillin and metronidazole.     

Osteonecrosis of the maxilla related to long-standing methamphetamine abuse: a possible new aspect in the etiology of osteonecrosis of the jaw

Background

Osteonecrosis of the jaw (ONJ) related to toxic effects of illicit drugs such as cocaine is not very common and might be overshadowed today by the incidence of bisphosphonate-related osteonecrosis of the jaw. However, we present a case which suggests a close relationship between abuse of the illicit drug methamphetamine (MA) and ONJ.

Case report

A 44-year-old male with extended osteonecrosis of the maxilla admitted chronic abuse and synthesis of MA for at least the previous two decades. Furthermore, he confessed self-extracting teeth since he became addicted to MA. However at presentation, he had been successfully cured of his addiction to MA. A step-by-step surgical treatment was planned using computer-aided design/computer-aided manufacturing techniques. After resection of necrotic bone, a vascularized osteomyocutaneous fibular flap was applied secondarily.

Discussion

Two possible mechanisms, alone or in combination, could possibly lead to MA-related ONJ. Self-extraction of teeth as a psychopathologic behavior of self-destruction among MA abusers results in wounds that allow unhindered invasion of microorganisms causing osteomyelitis and ONJ, while on the other hand, the heating of white phosphor releases toxic phosphorous vapor, which could be inhaled and consequently cause ONJ of the maxilla. However, since the worldwide prevalence of MA abuse is remarkably high, a relationship between MA abuse and ONJ will offer a new aspect in the etiology of ONJ and might present a further therapeutic challenge.     

Structural insight into the molecular mechanism of allosteric activation of human cystathionine β-synthase by S-adenosylmethionine

Cystathionine β-synthase (CBS) is a heme-dependent and pyridoxal-5′-phosphate–dependent protein that controls the flux of sulfur from methionine to cysteine, a precursor of glutathione, taurine, and H₂S. Deficiency of CBS activity causes homocystinuria, the most frequent disorder of sulfur amino acid metabolism. In contrast to CBSs from lower organisms, human CBS (hCBS) is allosterically activated by S-adenosylmethionine (AdoMet), which binds to the regulatory domain and triggers a conformational change that allows the protein to progress from the basal toward the activated state. The structural basis of the underlying molecular mechanism has remained elusive so far. Here, we present the structure of hCBS with bound AdoMet, revealing the activated conformation of the human enzyme. Binding of AdoMet triggers a conformational change in the Bateman module of the regulatory domain that favors its association with a Bateman module of the complementary subunit to form an antiparallel CBS module. Such an arrangement is very similar to that found in the constitutively activated insect CBS. In the presence of AdoMet, the autoinhibition exerted by the regulatory region is eliminated, allowing for improved access of substrates to the catalytic pocket. Based on the availability of both the basal and the activated structures, we discuss the mechanism of hCBS activation by AdoMet and the properties of the AdoMet binding site, as well as the responsiveness of the enzyme to its allosteric regulator. The structure described herein paves the way for the rational design of compounds modulating hCBS activity and thus transsulfuration, redox status, and H₂S biogenesis.Cystathionine β-synthase (CBS; EC 4.2.1.22) is a pyridoxal-5′-phosphate (PLP)-dependent enzyme that catalyzes the β-replacement of the hydroxyl group of l-serine (Ser) by l-homocysteine (Hcy), yielding cystathionine (Cth) (1). A deficient activity of human CBS (hCBS) is the cause of classical homocystinuria [CBS-deficient homocystinuria (CBSDH); Online Mendelian Inheritance in Man (OMIM) no. 236200], an autosomal, recessive inborn error of sulfur amino acid metabolism, characterized by increased levels of Hcy in plasma and urine. CBSDH manifests as a combination of connective tissue defects, skeletal deformities, vascular thrombosis, and mental retardation (2).The hCBS is a homotetrameric enzyme whose subunits are organized into three structural domains. The N-terminal region binds heme and is thought to function in redox sensing and/or enzyme folding (3, 4). The central catalytic core shows the fold of the type II family PLP-dependent enzymes (5, 6). Finally, the C-terminal region consists of a tandem pair of CBS motifs (7–9) that bind S-adenosylmethionine (AdoMet) and lead to an increase in catalytic activity by up to fivefold (10, 11). The CBS motif pair, commonly known as a “Bateman module” (12, 13), is responsible for CBS subunit tetramerization (14, 15). The presence of pathogenic missense mutations in this region often does not impair enzyme activity but typically interferes with binding of AdoMet and/or the enzyme’s activation by AdoMet (15–17). Removal of the regulatory region leads to a dimer with much increased activity (14, 15). Recently, we showed that removal of residues 516–525, forming a flexible loop of the CBS2 motif of hCBS, yields dimeric species (hCBSΔ516–525) with intact AdoMet binding capacity and activity responsiveness to AdoMet similar to a native hCBS WT (18).hCBS is regulated by a complex molecular mechanism that remains poorly understood. More than a decade ago, we and others hypothesized that hCBS might exist in two different conformations: a “basal” state with low activity, where the C-terminal regulatory domain would restrict the access of substrates into the catalytic site, and an AdoMet-bound “activated” state, where the AdoMet-induced conformational change would allow for enzyme activation (16, 19). Recently, we have unveiled the relative orientations of the regulatory and catalytic domains in hCBS (18), which were in a striking contrast to those of both the previous in silico models (20, 21) and the Drosophila melanogaster (dCBS) structure (22). Our data showed that, although the pairing mode and the orientation of catalytic cores are similar in both insect dCBS and hCBS, the position of their regulatory domains is markedly different (18). In the basal state, the Bateman modules from each hCBS unit are far apart and do not interact with each other, being placed just above the entrance of the catalytic site of the complementary subunit, thus hampering the access of substrates into this cavity. Our hCBSΔ516–525 structure additionally revealed the presence of two major cavities in the Bateman module, S1 and S2, one of which (S2) is solvent-exposed and probably represents the primary binding site for AdoMet (18). These findings are in agreement with the much higher basal activity of dCBS and its inability to bind or to be regulated by AdoMet (23, 24) and suggest that the structural basis underlying the regulation of the human enzyme markedly differs from CBS regulation in insects or yeast (24). Taken together, the available data indicate that binding of AdoMet to the Bateman module weakens the interaction between the regulatory domain and the catalytic core although the mechanism and the magnitude of the underlying structural effect are still under debate (16, 19, 25–27).To solve the molecular mechanism of hCBS regulation by AdoMet, we have analyzed the crystals of an engineered hCBSΔ516–525 protein that bears the mutation E201S, which potentially weakens and/or disrupts the interaction between the Bateman module and the catalytic core (Fig. 1A), thus favoring the activation of the enzyme. The data presented here fill a long-sought structural gap by unraveling the crystal structure of AdoMet-bound hCBS, thus providing the overall fold of the enzyme in its activated conformation and the identity of the AdoMet binding sites. Comparison with the structures of hCBS in basal conformation and constitutively activated dCBS was instrumental in the understanding of the regulatory role played by the C-terminal domain as well as the effect of some of the pathogenic mutations in the activation and/or inhibition of this key molecule of transsulfuration.Open in a separate windowFig. 1.Interactions between protein domains in basal hCBS. (A) In hCBSΔ516–525, residues Y484, N463, and S466 anchor the Bateman module (blue) to the protein core (gray) through H-bonds with the residues E201 and D198 from the loop L191–202, thus occluding the entrance to the catalytic pocket. (B) The CBS-specific activity of selected hCBS variants in the absence (blue bars) and the presence (red bars) of 300 µM AdoMet. hCBS enzyme species marked with “Δ” lack residues 516–525 and form dimers.