Enhancement of protein secretion by TatAC overexpression in Streptomyces griseus

Molecular and Biochemical Characterization of Xylanase Produced by Streptomyces viridodiastaticus MS9, a Newly Isolated Soil Bacterium

A xylan-degrading bacterial strain, MS9, was recently isolated from soil samples collected in Namhae, Gyeongsangnam-do, Republic of Korea. This strain was identified as a variant of Streptomyces viridodiastaticus NBRC13106T based on 16S rRNA gene sequencing, DNA-DNA hybridization analysis, and other chemotaxonomic characteristics, and was named S. viridodiastaticus MS9 (=KCTC29014= DSM42055). In this study, we aimed to investigate the molecular and biochemical characteristics of a xylanase (XynCvir) identified from S. viridodiastaticus MS9. XynCvir (molecular weight ≍ 21 kDa) was purified from a modified Luria-Bertani medium, in which cell growth and xylanase production considerably increased after addition of xylan. Thin layer chromatography of xylan-hydrolysate showed that XynCvir is an endo-(1,4)-β-xylanase that degrades xylan into a series of xylooligosaccharides, ultimately converting it to xylobiose. The Km and Vmax values of XynCvir for beechwood xylan were 1.13 mg/ml and 270.3 U/mg, respectively. Only one protein (GHF93985.1, 242 amino acids) containing an amino acid sequence identical to the amino-terminal sequence of XynCvir was identified in the genome of S. viridodiastaticus. GHF93985.1 with the twin-arginine translocation signal peptide is cleaved between Ala-50 and Ala-51 to form the mature protein (21.1 kDa; 192 amino acids), which has the same amino-terminal sequence (ATTITTNQT) and molecular weight as XynCvir, indicating GHF93985.1 corresponds to XynCvir. Since none of the 100 open reading frames most homologous to GHF93985.1 listed in GenBank have been identified for their biochemical functions, our findings greatly contribute to the understanding of their biochemical characteristics.

Enhanced production of neoagarobiose from agar with Corynebacterium glutamicum producing exo-type and endo-type β-agarases

Neoagarobiose (NA2) derived from agar marine biomass is a rare reagent that acts as an anti-melanogenesis reagent and moisturizer. Here, for the economical manufacturing of NA2, we developed the co-secretory production system of endo-type β-agarases (DagA) and exo-type β-agarases (EXB3) in Corynebacterium glutamicum. For this purpose, we first developed a secretory system of DagA via Tat pathway. To improve the secretion efficiency, we coexpressed two Tat pathway components (TatA and TatC), and to improve the purity of secreted DagA in the culture supernatant, two endogenous protein genes (Cg2052 and Cg1514) were removed. Using the engineered strain (C. glutamicum SP002), we confirmed that DagA as high as 1.53 g l^-1 was successfully produced in the culture media with high purity (72.7% in the supernatant protein fraction). Next, we constructed the expression system (pHCP-CgR-DagA-EXB3) for the simultaneous secretion of EXB3 via Sec-pathway together with DagA, and it was clearly confirmed that DagA and EXB3 were successfully secreted as high as 54% and 24.5%, respectively. Finally, using culture medium containing DagA and EXB3, we successfully demonstrated the conversion of high-concentration agar (40 g l^-1 ) into NA2 via a two-stage hydrolysis process.

An auto-inducible expression and high cell density fermentation of Beefy Meaty Peptide with Bacillus subtilis

Currently, some cases about the expression of flavor peptides with microorganisms were reported owing to the obvious advantages of biological expression over traditional methods. However, beefy meaty peptide (BMP), the focus of umami peptides, has neither been concerned in its safe expression nor its overproduction in fermenter. In this study, multi-copy BMP (8BMP) was successfully auto-inducibly expressed and efficiently produced in Bacillus subtilis 168. First, 8BMP was successfully auto-inducibly expressed with srfA promoter in B. subtilis 168. Further, the efficient production of 8BMP was researched in a 5-L fermenter: the fermentation optimized by Pontryagin's maximum principle obtained the highest 8BMP yield (3.16 g/L), which was 1.2 times and 1.8 times than that of two-stage feeding cultivation (2.67 g/L) and constant-rate feeding cultivation (1.75 g/L), respectively. Overall, the auto-inducible expression of 8BMP in B. subtilis and fermentation with Pontryagin's maximum principle are conductive for overproduction of BMP and other peptides.

Expression of alcohol oxidase gene from Ochrobactrum sp. AIU 033 in recombinant Escherichia coli through the twin-arginine translocation pathway

We cloned a set of genes encoding alcohol oxidase from Ochrobactrum sp. AIU 033 (OcAOD), which exhibits the appropriate substrate specificity for glyoxylic acid production from glycolic acid. The set of genes for OcAOD contained two open reading frames consisting of 555-bp (aodB) and 1572-bp (aodA) nucleotides, which encode the precursor for the β-subunit and α-subunit of OcAOD, respectively. We expressed the cloned genes as an active product in Escherichia coli BL21(DE3). The recombinant OcAOD oxidized glycolic acid and primary alcohols with C2-C8 but not glyoxylic acid (as is the case for native OcAOD), whereas the K_m and V_max values for glycolic acid and the pH stability were higher than those of native OcAOD. A consensus sequence for the twin-arginine translocation (Tat) pathway was identified in the N-terminal region of the precursor for the β-subunit, and the active form of OcAOD was localized in the periplasm of recombinant E. coli, which indicated that OcAOD would be transported from the cytoplasm to the periplasm by the hitchhiker mechanism through the Tat pathway. The OcAOD productivity of the recombinant E. coli was 24-fold higher than that of Ochrobactrum sp. AIU 033, and it was further enhanced by 1.2 times by the co-expression of additional tatABC from E. coli BL21(DE3). Our findings thus suggest a function of the β-subunit of OcAOD in membrane translocation, and that the recombinant OcAOD has characteristics that are suitable for the enzymatic synthesis of glyoxylic acid as well as native OcAOD.

The Tat pathway is prevalent in Listeria monocytogenes lineage II and is not required for infection and spread in host cells

Listeria monocytogenes, a foodborne pathogenic bacterium, remains a serious public health concern due to its frequent occurrence in food products coupled with a high mortality rate. Bacterial pathogenicity depends greatly on the ability to secrete virulence factors to or beyond the bacterial cell surface. The Tat pathway, one of the secretion systems present in L. monocytogenes, was until now only investigated in silico. In L. monocytogenes strain EGDe two genes constitute this pathway, tatC(lmo0361) and tatA(lmo0362). Here we show that tatC and tatA are cotranscribed in a bicistronic- and growth-phase-dependent manner, being downregulated in the stationary phase. An EGDe tatAC mutant strain (EGDe ΔtatAC) was constructed, confirming that the Tat pathway is not essential for L.monocytogenes survival or biofilm-forming ability. When compared to the wild-type EGDe, deletion of tatAC did not decrease the virulence potential of EGDe ΔtatAC in HT-29 human epithelial cell line and even increased (p < 0.05) the virulence potential for mice. Moreover, we show that tat genes are prevalent in L. monocytogenes strains belonging to genetic lineage II and are generally absent from lineage I, which is more associated with human cases, thus excluding the possibility of using the Tat system as a target for novel antimicrobial compounds targeting L.monocytogenes.

Biotechnological applications of bacterial protein secretion: from therapeutics to biofuel production

Recent years have witnessed significant progresses in engineering of recombinant protein secretion. The relatively simple secretion mechanisms, Type I and Type V (autotransporters), are increasingly used for secretion of recombinant proteins. The secretion level of target proteins varied from milligrams to grams per liter. The range of proteins was significantly expanded beyond medical application. Notable additions include biofuel productions from renewable feedstock. Despite the progress, almost all successes in the engineering efforts come with significant trials and errors, highlighting the need for a better understanding of secretion systems and rational based methods.