ABSTRACT
Esophageal melanocytosis is a rare entity defined by the proliferation of a melanocytic basal layer of the esophageal squamous lining and deposition of melanin in the esophageal mucosa. Esophageal melanocytosis is considered a benign entity of unknown etiology; however, it has been reported as a melanoma precursor. We report a case of esophageal melanocytosis in a diabetic and hypertensive 67-year-old male with recurrent dizziness and syncope for the past 6 months. Given his complaint of dyspepsia, he underwent an upper gastrointestinal endoscopy, in which an esophageal biopsy revealed the diagnosis of esophageal melanocytosis. The definitive diagnosis of esophageal melanocytosis can only be made by histological analysis. The histologic differential diagnoses include melanocytic nevi and malignant melanoma. Therefore, they need to be ruled out.
ABSTRACT
We present here the draft genome sequences of four marine bacterial strains which can use ulvan as their sole carbon source. We used ulvan extracted from the green alga Ulva ohnoi Each bacterium contains a polysaccharide-utilizing locus, which is necessary for the complete degradation of ulvan.
ABSTRACT
Ulvan is a complex water-soluble sulfated polysaccharide in the cell wall of green algae belonging to genus Ulva. It is composed of l-rhamnose-3-sulfate (Rha3S), glucuronic acid (GluA), iduronic acid (IduA), and d-xylose (Xyl) distributed in three repetition moieties. The first step of a bacterial ulvan degradation is the cleavage of the ß-glycosidic bond between Rha3S and GluA/IduA through a ß-elimination mechanism by a ulvan lyase to produce oligo-ulvans with unsaturated 4-deoxy-L-threo-hex-4-enopyranosiduronate (Δ) at the non-reducing end. We have identified an ulvan associated polysaccharide utilization locus (PUL) residing between two ulvan lyase genes belonging to families of polysaccharide lyase 24 (PL24) and PL25 in the genome of a ulvan-utilizing bacterium Glaciecola KUL10 strain. The PUL contains many genes responsible for oligo-ulvan degradation. Among them, we demonstrated that both KUL10_26540 and KUL10_26770 had an unsaturated ß-glucuronyl hydrolase activity to produce Rha3S and oligosaccharides, such as Rha3S-GluA-Rha3S, Rha3S-IduA-Rha3S and, Rha3S-Xyl-Rha3S, by releasing 5-dehydro-4-deoxy-d-glucuronate. KUL10_26540 showed much higher activity than KUL10_26770 and was more active on disaccharide than tetrasaccharide. We also found a rhamnosidase activity on four KUL10 gene products, although they could not react on the sulfated rhamnose.
