Deficiency of ß-xylosidase activity in Aspergillus luchuensis mut. kawachii IFO 4308.

In this study, we investigated a deleterious mutation in the ß-xylosidase gene, xylA (AkxylA), in Aspergillus luchuensis mut. kawachii IFO 4308 by constructing an AkxylA disruptant and complementation strains of AkxylA and xylA derived from A. luchuensis RIB2604 (AlxylA), which does not harbor the mutation in xylA. Only the AlxylA complementation strain exhibited significantly higher growth and substantial ß-xylosidase activity in medium containing xylan, accompanied by an increase in XylA expression. This resulted in lower xylobiose and higher xylose concentrations in the mash of barley shochu. These findings suggest that the mutation in xylA affects xylose levels during the fermentation process. Because the mutation in xylA was identified not only in the genome of strain IFO 4308 but also the genomes of other industrial strains of A. luchuensis and A. luchuensis mut. kawachii, these findings enhance our understanding of the genetic factors that affect the fermentation characteristics.

Bifidobacterial GH146 ß-L-arabinofuranosidase for the removal of ß1,3-L-arabinofuranosides on plant glycans.

L-Arabinofuranosides with ß-linkages are present in several plant molecules, such as arabinogalactan proteins (AGPs), extensin, arabinan, and rhamnogalacturonan-II. We previously characterized a ß-L-arabinofuranosidase from Bifidobacterium longum subsp. longum JCM 1217, Bll1HypBA1, which was found to belong to the glycoside hydrolase (GH) family 127. This strain encodes two GH127 genes and two GH146 genes. In the present study, we characterized a GH146 ß-L-arabinofuranosidase, Bll3HypBA1 (BLLJ_1848), which was found to constitute a gene cluster with AGP-degrading enzymes. This recombinant enzyme degraded AGPs and arabinan, which contain Araf-ß1,3-Araf structures. In addition, the recombinant enzyme hydrolyzed oligosaccharides containing Araf-ß1,3-Araf structures but not those containing Araf-ß1,2-Araf and Araf-ß1,5-Araf structures. The crystal structures of Bll3HypBA1 were determined at resolutions up to 1.7 Å. The monomeric structure of Bll3HypBA1 comprised a catalytic (α/α)6 barrel and two ß-sandwich domains. A hairpin structure with two ß-strands was observed in Bll3HypBA1, to extend from a ß-sandwich domain and partially cover the active site. The active site contains a Zn2+ ion coordinated by Cys3-Glu and exhibits structural conservation of the GH127 cysteine glycosidase Bll1HypBA1. This is the first study to report on a ß1,3-specific ß-L-arabinofuranosidase. KEY POINTS: • ß1,3-l-Arabinofuranose residues are present in arabinogalactan proteins and arabinans as a terminal sugar. • ß-l-Arabinofuranosidases are widely present in intestinal bacteria. • Bll3HypBA1 is the first enzyme characterized as a ß1,3-linkage-specific ß-l-arabinofuranosidase.

Assimilation of arabinogalactan side chains with novel 3-O-ß-L-arabinopyranosyl-α-L-arabinofuranosidase in Bifidobacterium pseudocatenulatum.

Aim: Dietary plant fibers affect gut microbiota composition; however, the underlying microbial degradation pathways are not fully understood. We previously discovered 3-O-α-D-galactosyl-α-L-arabinofuranosidase (GAfase), a glycoside hydrolase family 39 enzyme involved in the assimilation of side chains of arabinogalactan protein (AGP), from Bifidobacterium longum subsp. longum (B. longum) JCM7052. Although GAfase homologs are not highly prevalent in the Bifidobacterium genus, several Bifidobacterium strains possess the homologs. To explore the differences in substrate specificity among the homologs, a homolog of B. longum GAfase in Bifidobacterium pseudocatenulatum MCC10289 (MCC10289_0425) was characterized. Methods: Gum arabic, larch, wheat AGP, and sugar beet arabinan were used to determine the substrate specificity of the MCC10289_0425 protein. An amino acid replacement was introduced into GAfase to identify a critical residue that governs the differentiation of substrate specificity. The growth of several Bifidobacterium strains on ß-L-arabinopyranosyl disaccharide and larch AGP was examined. Results: MCC10289_0425 was identified to be an unprecedented 3-O-ß-L-arabinopyranosyl-α-L-arabinofuranosidase (AAfase) with low GAfase activity. A single amino acid replacement (Asn119 to Tyr) at the catalytic site converted GAfase into AAfase. AAfase releases sugar source from AGP, thereby allowing B. pseudocatenulatum growth. Conclusion: Bifidobacteria have evolved several homologous enzymes with overlapping but distinct substrate specificities depending on the species. They have acquired different fitness abilities to respond to diverse plant polysaccharide structures.

Identification and characterization of endo-α-, exo-α-, and exo-ß-D-arabinofuranosidases degrading lipoarabinomannan and arabinogalactan of mycobacteria.

The cell walls of pathogenic and acidophilic bacteria, such as Mycobacterium tuberculosis and Mycobacterium leprae, contain lipoarabinomannan and arabinogalactan. These components are composed of D-arabinose, the enantiomer of the typical L-arabinose found in plants. The unique glycan structures of mycobacteria contribute to their ability to evade mammalian immune responses. In this study, we identified four enzymes (two GH183 endo-D-arabinanases, GH172 exo-α-D-arabinofuranosidase, and GH116 exo-ß-D-arabinofuranosidase) from Microbacterium arabinogalactanolyticum. These enzymes completely degraded the complex D-arabinan core structure of lipoarabinomannan and arabinogalactan in a concerted manner. Furthermore, through biochemical characterization using synthetic substrates and X-ray crystallography, we elucidated the mechanisms of substrate recognition and anomer-retaining hydrolysis for the α- and ß-D-arabinofuranosidic bonds in both endo- and exo-mode reactions. The discovery of these D-arabinan-degrading enzymes, along with the understanding of their structural basis for substrate specificity, provides valuable resources for investigating the intricate glycan architecture of mycobacterial cell wall polysaccharides and their contribution to pathogenicity.

Pathogen Profiles in Outpatients with Non-COVID-19 during the 7th Prevalent Period of COVID-19 in Gunma, Japan.

The identification of pathogens associated with respiratory symptoms other than the novel coronavirus disease 2019 (COVID-19) can be challenging. However, the diagnosis of pathogens is crucial for assessing the clinical outcome of patients. We comprehensively profiled pathogens causing non-COVID-19 respiratory symptoms during the 7th prevalent period in Gunma, Japan, using deep sequencing combined with a next-generation sequencer (NGS) and advanced bioinformatics technologies. The study included nasopharyngeal swabs from 40 patients who tested negative for severe acute respiratory syndrome coronavirus type 2 (SARS-CoV-2) using immuno-chromatography and/or quantitative reverse transcription polymerase chain reaction (qRT-PCR) methods. Comprehensive pathogen sequencing was conducted through deep sequencing using NGS. Additionally, short reads obtained from NGS were analyzed for comprehensive pathogen estimation using MePIC (Metagenomic Pathogen Identification Pipeline for Clinical Specimens) and/or VirusTap. The results revealed the presence of various pathogens, including respiratory viruses and bacteria, in the present subjects. Notably, human adenovirus (HAdV) was the most frequently detected virus in 16 of the 40 cases (40.0%), followed by coryneforms, which were the most frequently detected bacteria in 21 of the 40 cases (52.5%). Seasonal human coronaviruses (NL63 type, 229E type, HKU1 type, and OC43 type), human bocaviruses, and human herpesviruses (human herpesvirus types 1-7) were not detected. Moreover, multiple pathogens were detected in 50% of the subjects. These results suggest that various respiratory pathogens may be associated with non-COVID-19 patients during the 7th prevalent period in Gunma Prefecture, Japan. Consequently, for an accurate diagnosis of pathogens causing respiratory infections, detailed pathogen analyses may be necessary. Furthermore, it is possible that various pathogens, excluding SARS-CoV-2, may be linked to fever and/or respiratory infections even during the COVID-19 pandemic.

Molecular Evolutionary Analyses of the RNA-Dependent RNA Polymerase (RdRp) Region and VP1 Gene in Human Norovirus Genotypes GII.P6-GII.6 and GII.P7-GII.6.

To understand the evolution of GII.P6-GII.6 and GII.P7-GII.6 strains, the prevalent human norovirus genotypes, we analysed both the RdRp region and VP1 gene in globally collected strains using authentic bioinformatics technologies. A common ancestor of the P6- and P7-type RdRp region emerged approximately 50 years ago and a common ancestor of the P6- and P7-type VP1 gene emerged approximately 110 years ago. Subsequently, the RdRp region and VP1 gene evolved. Moreover, the evolutionary rates were significantly faster for the P6-type RdRp region and VP1 gene than for the P7-type RdRp region and VP1 genes. Large genetic divergence was observed in the P7-type RdRp region and VP1 gene compared with the P6-type RdRp region and VP1 gene. The phylodynamics of the RdRp region and VP1 gene fluctuated after the year 2000. Positive selection sites in VP1 proteins were located in the antigenicity-related protruding 2 domain, and these sites overlapped with conformational epitopes. These results suggest that the GII.6 VP1 gene and VP1 proteins evolved uniquely due to recombination between the P6- and P7-type RdRp regions in the HuNoV GII.P6-GII.6 and GII.P7-GII.6 virus strains.

Bifidobacterial GH146 ß-l-Arabinofuranosidase (Bll4HypBA1) as the Last Enzyme for the Complete Removal of Oligoarabinofuranosides from Hydroxyproline-Rich Glycoproteins.

In plant cell walls, the hydroxyproline-rich glycoproteins (HRGPs) such as extensin contain oligoarabinofuranoside linked to a hydroxyproline (Hyp) residue. The mature arabinooligosaccharide was revealed to be a tetrasaccharide (α-l-Araf-(1→3)-ß-l-Araf-(1→2)-ß-l-Araf-(1→2)-ß-l-Araf, l-Araf4 ), whose linkages are targets of the bifidobacterial and Xanthomonas arabinooligosaccharide-degrading enzymes. The l-Araf4 motif was cleaved by GH43 α-l-arabinofuranosidase (Arafase) and converted to an l-Araf3 -linked structure. The latter is then cleaved by GH121 ß-l-arabinobiosidase (HypBA2), producing ß-l-Araf-(1→2)-l-Ara (ß-l-arabinobiose) and mono-ß-l-Araf linked to the HRGP backbone. In bifidobacteria, the ß-l-arabinobiose is then hydrolyzed by GH127 ß-l-Arafase (Bll1HypBA1), a mechanistically unique cysteine glycosidase. We recently identified the distantly related homologue from Xanthomonas euvesicatoria as GH146 ß-l-Arafase along with paralogues from Bifidobacterium longum, one of which, Bll4HypBA1 (BLLJ_0089), can degrade l-Araf1 -Hyp in a similar way to that of GH146. As the chemical synthesis of the extensin hydrophilic motif 1 a, which possesses three distinct linkages that connect four oligoAraf residues [Hyp(l-Arafn ) (n=4, 3, 1)], was achieved previously, we precisely monitored the step-wise enzymatic cleavage of 1 a in addition to that of potato lectin. The results unequivocally revealed that this enzyme specifically degrades the Hyp(l-Araf1 ) motif.

Identification and structural basis of an enzyme that degrades oligosaccharides in caramel.

Cooking with fire produces foods containing carbohydrates that are not naturally occurring, such as α-d-fructofuranoside found in caramel. Each of the hundreds of compounds produced by caramelization reactions is considered to possess its own characteristics. Various studies from the viewpoints of biology and biochemistry have been conducted to elucidate some of the scientific characteristics. Here, we review the composition of caramelized sugars and then describe the enzymatic studies that have been conducted and the physiological functions of the caramelized sugar components that have been elucidated. In particular, we recently identified a glycoside hydrolase (GH), GH172 difructose dianhydride I synthase/hydrolase (αFFase1), from oral and intestinal bacteria, which is implicated in the degradation of oligosaccharides in caramel. The structural basis of αFFase1 and its ligands provided many insights. This discovery opened the door to several research fields, including the structural and phylogenetic relationship between the GH172 family enzymes and viral capsid proteins and the degradation of cell membrane glycans of acid-fast bacteria by some αFFase1 homologs. This review article is an extended version of the Japanese article, Identification and Structural Basis of an Enzyme Degrading Oligosaccharides in Caramel, published in SEIBUTSU BUTSURI Vol. 62, p. 184-186 (2022).

Mechanism-based inhibition of GH127/146 cysteine glycosidases by stereospecifically functionalized l-arabinofuranosides.

To understand the precise mechanism of the glycoside hydrolase (GH) family 127, a cysteine ß-l-arabinofuranosidase (Arafase) - HypBA1 - has been isolated from Bifidobacterium longum in the human Gut microbiota, and the design and synthesis of the mechanism-based inhibitors such as l-Araf-haloacetamides have been carried out. The α-l-Araf-azide derivative was used as the monoglycosylamine equivalent to afford the l-Araf-chloroacetamides (α/ß-1-Cl) as well as bromoacetamides (α/ß-1-Br) in highly stereoselective manner through Staudinger reaction followed by amide formation with/without anomerization. Against HypBA1, the probes 1, especially in the case of α/ß-1-Br inhibited the hydrolysis. Conformational implications of these observations are discussed in this manuscript. Additional examinations using l-Araf-azides (α/ß-5) resulted in further mechanistic observations of the GH127/146 cysteine glycosidases, including the hydrolysis of ß-5 as the substrate and oxidative inhibition by α-5 using the GH127 homologue.

Synthesis of naturally occurring ß-l-arabinofuranosyl-l-arabinofuranoside structures towards the substrate specificity evaluation of ß-l-arabinofuranosidase.

Methyl ß-l-arabinofuranosyl-(1 â†’ 2)-, -(1 â†’ 3)-, and -(1 â†’ 5)-α-l-arabinofuranosides have been stereoselectively synthesized through 2-naphthylmethyl ether-mediated intramolecular aglycon delivery (NAP-IAD), whose ß-linkages were confirmed by NMR analysis on the 3JH1-H2 coupling constant and 13C chemical shift of C1. The NAP-IAD approach was simply extended for the synthesis of trisaccharide motifs possessing ß-l-arabinofuranosyl-(1 â†’ 5)-l-arabinofuranosyl non-reducing terminal structure with the branched ß-l-arabinofuranosyl-(1 â†’ 5)-[α-l-arabinofuranosyl-(1 â†’ 3)]-α-l-arabinofuranosyl and the liner ß-l-arabinofuranosyl-(1 â†’ 5)-ß-l-arabinofuranosyl-(1 â†’ 5)-ß-l-arabinofuranosyl structures in olive arabinan and dinoflagellate polyethers, respectively. The results on the substrate specificity of a bifidobacterial ß-l-arabinofuranosidase HypBA1 using the regioisomers indicated that HypBA1 could hydrolyze all three linkages however behaved clearly less active to ß-(1 â†’ 5)-linked disaccharide than other two regioisomers including the proposed natural degradation product, ß-(1 â†’ 2)-linked one from plant extracellular matrix such as extensin. On the other hand, Xanthomonas XeHypBA1 was found to hydrolyze all three disaccharides as the substrate with higher specificity to ß-(1 â†’ 2)-linkage than bifidobacterial HypBA1.

Two α-L-arabinofuranosidases from Bifidobacterium longum subsp. longum are involved in arabinoxylan utilization.

Arabinoxylan (AX) and arabinoxylooligosaccharides (AXOs) are carbohydrate sources utilized by Bifidobacterium longum subsp. longum. However, their degradation pathways are poorly understood. In this study, we characterized two genes, BLLJ_1850 and BLLJ_1851, in the hemicellulose-degrading gene cluster (BLLJ_1836-BLLJ_1859) of B. longum subsp. longum JCM 1217. Both recombinant enzymes expressed in Escherichia coli exhibited exo-α-L-arabinofuranosidase activity toward p-nitrophenyl-α-L-arabinofuranoside. BlArafE (encoded by BLLJ_1850) contains the glycoside hydrolase family 43 (GH43), subfamily 22 (GH43_22), and GH43_34 domains. The BlArafE GH43_22 domain was demonstrated to release α1,3-linked Araf from AX, but the function of BlArafE GH43_34 could not be clearly identified in this study. BlArafD (encoded by BLLJ_1851) contains GH43 unclassified subfamily (GH43_UC) and GH43_26 domains. The BlArafD GH43_UC domain showed specificity for α1,2-linked Araf in α1,2- and α1,3-Araf double-substituted structures in AXOs, while BlArafD GH43_26 was shown to hydrolyze α1,5-linked Araf in the arabinan backbone. Co-incubation of BlArafD and BlArafE revealed that these two enzymes sequentially removed α1,2-Araf and α1,3-Araf from double-substituted AXOs in this order. B. longum strain lacking BLLJ_1850-BLLJ_1853 did not grow in the medium containing α1,2/3-Araf double-substituted AXOs, suggesting that BlArafE and BlArafD are important for the assimilation of AX. KEY POINTS: • BlArafD GH43 unclassified subfamily domain is a novel α1,2-L-arabinofuranosidase. • BlArafE GH43 subfamily 22 domain is an α1,3-L-arabinofuranosidase. • BlArafD and BlArafE cooperatively degrade α1,2/3-Araf double-substituted arabinoxylan.

Mechanism of Cooperative Degradation of Gum Arabic Arabinogalactan Protein by Bifidobacterium longum Surface Enzymes.

Gum arabic is an arabinogalactan protein (AGP) that is effective as a prebiotic for the growth of bifidobacteria in the human intestine. We recently identified a key enzyme in the glycoside hydrolase (GH) family 39, 3-O-α-d-galactosyl-α-l-arabinofuranosidase (GAfase), for the assimilation of gum arabic AGP in Bifidobacterium longum subsp. longum. The enzyme released α-d-Galp-(1→3)-l-Ara and ß-l-Arap-(1→3)-l-Ara from gum arabic AGP and facilitated the action of other enzymes for degrading the AGP backbone and modified sugar. In this study, we identified an α-l-arabinofuranosidase (BlArafE; encoded by BLLJ_1850), a multidomain enzyme with both GH43_22 and GH43_34 catalytic domains, as a critical enzyme for the degradation of modified α-l-arabinofuranosides in gum arabic AGP. Site-directed mutagenesis approaches revealed that the α1,3/α1,4-Araf double-substituted gum arabic AGP side chain was initially degraded by the GH43_22 domain and subsequently cleaved by the GH43_34 domain to release α1,3-Araf and α1,4-Araf residues, respectively. Furthermore, we revealed that a tetrasaccharide, α-l-Rhap-(1→4)-ß-d-GlcpA-(1→6)-ß-d-Galp-(1→6)-d-Gal, was a limited degradative oligosaccharide in the gum arabic AGP fermentation of B. longum subsp. longum JCM7052. The oligosaccharide was produced from gum arabic AGP by the cooperative action of the three cell surface-anchoring enzymes, GAfase, exo-ß1,3-galactanase (Bl1,3Gal), and BlArafE, on B. longum subsp. longum JCM7052. Furthermore, the tetrasaccharide was utilized by the commensal bacteria. IMPORTANCE Terminal galactose residues of the side chain of gum arabic arabinogalactan protein (AGP) are mainly substituted by α1,3/α1,4-linked Araf and ß1,6-linked α-l-Rhap-(1→4)-ß-d-GlcpA residues. This study found a multidomain BlArafE with GH43_22 and GH43_34 catalytic domains showing cooperative action for degrading α1,3/α1,4-linked Araf of the side chain of gum arabic AGP. In particular, the GH43_34 domain of BlArafE was a novel α-l-arabinofuranosidase for cleaving the α1,4-Araf linkage of terminal galactose. α-l-Rhap-(1→4)-ß-d-GlcpA-(1→6)-ß-d-Galp-(1→6)-d-Gal tetrasaccharide was released from gum arabic AGP by the cooperative action of GAfase, GH43_24 exo-ß-1,3-galactanase (Bl1,3Gal), and BlArafE and remained after B. longum subsp. longum JCM7052 culture. Furthermore, in vitro assimilation test of the remaining oligosaccharide using Bacteroides species revealed that cross-feeding may occur from bifidobacteria to other taxonomic groups in the gut.

Substrate complex structure, active site labeling and catalytic role of the zinc ion in cysteine glycosidase.

ß-l-Arabinofuranosidase HypBA1 from Bifidobacterium longum belongs to the glycoside hydrolase family 127. At the active site of HypBA1, a cysteine residue (Cys417) coordinates with a Zn2+ atom and functions as the catalytic nucleophile for the anomer-retaining hydrolytic reaction. In this study, the role of Zn2+ ion and cysteine in catalysis as well as the substrate-bound structure were studied based on biochemical and crystallographic approaches. The enzymatic activity of HypBA1 decreased after dialysis in the presence of EDTA and guanidine hydrochloride and was then recovered by the addition of Zn2+. The Michaelis complex structure was determined using a crystal of a mutant at the acid/base catalyst residue (E322Q) soaked in a solution containing the substrate p-nitrophenyl-ß-l-arabinofuranoside. To investigate the covalent thioglycosyl enzyme intermediate structure, synthetic inhibitors of l-arabinofuranosyl haloacetamide derivatives with different anomer configurations were used to target the nucleophilic cysteine. In the crystal structure of HypBA1, ß-configured l-arabinofuranosylamide formed a covalent link with Cys417, whereas α-configured l-arabinofuranosylamide was linked to a noncatalytic residue Cys415. Mass spectrometric analysis indicated that Cys415 was also reactive with the probe molecule. With the ß-configured inhibitor, the arabinofuranoside moiety was correctly positioned at the subsite and the active site integrity was retained to successfully mimic the covalent intermediate state.

Identification of difructose dianhydride I synthase/hydrolase from an oral bacterium establishes a novel glycoside hydrolase family.

Fructooligosaccharides and their anhydrides are widely used as health-promoting foods and prebiotics. Various enzymes acting on ß-D-fructofuranosyl linkages of natural fructan polymers have been used to produce functional compounds. However, enzymes that hydrolyze and form α-D-fructofuranosyl linkages have been less studied. Here, we identified the BBDE_2040 gene product from Bifidobacterium dentium (α-D-fructofuranosidase and difructose dianhydride I synthase/hydrolase from Bifidobacterium dentium [αFFase1]) as an enzyme with α-D-fructofuranosidase and α-D-arabinofuranosidase activities and an anomer-retaining manner. αFFase1 is not homologous with any known enzymes, suggesting that it is a member of a novel glycoside hydrolase family. When caramelized fructose sugar was incubated with αFFase1, conversions of ß-D-Frup-(2→1)-α-D-Fruf to α-D-Fruf-1,2':2,1'-ß-D-Frup (diheterolevulosan II) and ß-D-Fruf-(2→1)-α-D-Fruf (inulobiose) to α-D-Fruf-1,2':2,1'-ß-D-Fruf (difructose dianhydride I [DFA I]) were observed. The reaction equilibrium between inulobiose and DFA I was biased toward the latter (1:9) to promote the intramolecular dehydrating condensation reaction. Thus, we named this enzyme DFA I synthase/hydrolase. The crystal structures of αFFase1 in complex with ß-D-Fruf and ß-D-Araf were determined at the resolutions of up to 1.76 Å. Modeling of a DFA I molecule in the active site and mutational analysis also identified critical residues for catalysis and substrate binding. The hexameric structure of αFFase1 revealed the connection of the catalytic pocket to a large internal cavity via a channel. Molecular dynamics analysis implied stable binding of DFA I and inulobiose to the active site with surrounding water molecules. Taken together, these results establish DFA I synthase/hydrolase as a member of a new glycoside hydrolase family (GH172).

Characterization of a GH36 α-D-Galactosidase Associated with Assimilation of Gum Arabic in Bifidobacterium longum subsp. longum JCM7052.

We recently characterized a 3-O-α-D-galactosyl-α-L-arabinofuranosidase (GAfase) for the release of α-D-Gal-(1→3)-L-Ara from gum arabic arabinogalactan protein (AGP) in Bifidobacterium longum subsp. longum JCM7052. In the present study, we cloned and characterized a neighboring α-galactosidase gene (BLGA_00330; blAga3). It contained an Open Reading Frame of 2151-bp nucleotides encoding 716 amino acids with an estimated molecular mass of 79,587 Da. Recombinant BlAga3 released galactose from α-D-Gal-(1→3)-L-Ara, but not from intact gum arabic AGP, and a little from the related oligosaccharides. The enzyme also showed the activity toward blood group B liner trisaccharide. The specific activity for α-D-Gal-(1→3)-L-Ara was 4.27- and 2.10-fold higher than those for melibiose and raffinose, respectively. The optimal pH and temperature were 6.0 and 50 °C, respectively. BlAga3 is an intracellular α-galactosidase that cleaves α-D-Gal-(1→3)-L-Ara produced by GAfase; it is also responsible for a series of gum arabic AGP degradation in B. longum JCM7052.

Complete Genome Sequence of Bifidobacterium longum subsp. longum JCM7052.

We report the complete genome sequence of Bifidobacterium longum subsp. longum JCM7052, isolated from human feces in Japan. This strain has the capability of growing on and utilizing gum arabic as an energy source. The complete genome is 2,273,627 bp long, with 1,929 protein-coding genes and 59.9 mol% G+C content.

Novel 3-O-α-d-Galactosyl-α-l-Arabinofuranosidase for the Assimilation of Gum Arabic Arabinogalactan Protein in Bifidobacterium longum subsp. longum.

Gum arabic arabinogalactan (AG) protein (AGP) is a unique dietary fiber that is degraded and assimilated by only specific strains of Bifidobacterium longum subsp. longum Here, we identified a novel 3-O-α-d-galactosyl-α-l-arabinofuranosidase (GAfase) from B. longum JCM7052 and classified it into glycoside hydrolase family 39 (GH39). GAfase released α-d-Galp-(1→3)-l-Ara and ß-l-Arap-(1→3)-l-Ara from gum arabic AGP and ß-l-Arap-(1→3)-l-Ara from larch AGP, and the α-d-Galp-(1→3)-l-Ara release activity was found to be 594-fold higher than that of ß-l-Arap-(1→3)-l-Ara. The GAfase gene was part of a gene cluster that included genes encoding a GH36 α-galactosidase candidate and ABC transporters for the assimilation of the released α-d-Galp-(1→3)-l-Ara in B. longum Notably, when α-d-Galp-(1→3)-l-Ara was removed from gum arabic AGP, it was assimilated by both B. longum JCM7052 and the nonassimilative B. longum JCM1217, suggesting that the removal of α-d-Galp-(1→3)-l-Ara from gum arabic AGP by GAfase permitted the cooperative action with type II AG degradative enzymes in B. longum The present study provides new insight into the mechanism of gum arabic AGP degradation in B. longumIMPORTANCE Bifidobacteria harbor numerous carbohydrate-active enzymes that degrade several dietary fibers in the gastrointestinal tract. B. longum JCM7052 is known to exhibit the ability to assimilate gum arabic AGP, but the key enzyme involved in the degradation of gum arabic AGP remains unidentified. Here, we cloned and characterized a GH39 3-O-α-d-galactosyl-α-l-arabinofuranosidase (GAfase) from B. longum JCM7052. The enzyme was responsible for the release of α-d-Galp-(1→3)-l-Ara and ß-l-Arap-(1→3)-l-Ara from gum arabic AGP. The presence of a gene cluster including the GAfase gene is specifically observed in gum arabic AGP assimilative strains. However, GAfase carrier strains may affect GAfase noncarrier strains that express other type II AG degradative enzymes. These findings provide insights into the bifidogenic effect of gum arabic AGP.

Detailed Structure and Pathophysiological Roles of the IgA-Albumin Complex in Multiple Myeloma.

Immunoglobulin A (IgA)-albumin complexes may be associated with pathophysiology of multiple myeloma, although the etiology is not clear. Detailed structural analyses of these protein-protein complexes may contribute to our understanding of the pathophysiology of this disease. We analyzed the structure of the IgA-albumin complex using various electrophoresis, mass spectrometry, and in silico techniques. The data based on the electrophoresis and mass spectrometry showed that IgA in the sera of patients was dimeric, linked via the J chain. Only dimeric IgA can bind to albumin molecules leading to IgA-albumin complexes, although both monomeric and dimeric forms of IgA were present in the sera. Molecular interaction analyses in silico implied that dimeric IgA and albumin interacted not only via disulfide bond formation, but also via noncovalent bonds. Disulfide bonds were predicted between Cys34 of albumin and Cys311 of IgA, resulting in an oxidized form of albumin. Furthermore, complex formation prolongs the half-life of IgA molecules in the IgA-albumin complex, leading to excessive glycation of IgA molecules and affects the accumulation of IgA in serum. These findings may demonstrate why complications such as hyperviscosity syndrome occur more often in patients with IgA dimer producing multiple myeloma.

Phos-tag diagonal electrophoresis precisely detects the mobility change of phosphoproteins in Phos-tag SDS-PAGE.

Phos-tag diagonal electrophoresis was developed to identify precisely a change in electrophoretic mobility of phosphoproteins in Phos-tag SDS-PAGE. Previously, if a single protein band was detected, it was impossible to determine whether mobility of the protein altered by Mn2+ Phos-tag in Phos-tag SDS-PAGE gels because SDS-PAGE and Phos-tag SDS-PAGE were performed on different gels. Moreover, when multiple protein bands were detected, it was difficult to determine whether the band with the highest mobility was altered mobility by Mn2+ Phos-tag. However, these problems were resolved by Phos-tag diagonal electrophoresis in which SDS-PAGE and Phos-tag SDS-PAGE patterns were provided on a single gel. Using this technique we identified phosphorylation states of various proteins such as α-lactalbumin, α- and ß-casein, ovalbumin, basic 7S globulin, and 26S proteasome subunits. In the analyses of 26S proteasome subunits from humans and yeast, we could confirm that all subunits are phosphorylated, and find that the number of major proteins with different phosphorylation states is a few in each of the subunits despite having many phosphorylation sites. SIGNIFICANCE: Previously, Phos-tag SDS-PAGE has been developed to identify a change in electrophoretic mobility of phosphoproteins. However, we had a problem in this technique; it was often difficult to recognize the mobility shift by Mn2+ Phos-tag when we used separately SDS-PAGE and Phos-tag SDS-PAGE. Such a problem was resolved by Phos-tag diagonal electrophoresis in which SDS-PAGE and Phos-tag SDS-PAGE patterns are provided on a single gel. This technique was useful to identify phosphorylation states of various proteins. : Phos-tag diagonal electrophoresis, mass spectrometry, phosphoproteins, basic 7S globulin, proteasome.