This study was aimed to isolate bacterial inoculants producing chitinase and evaluate their application effects on corn silage. Four corn silages were collected from four beef cattle farms to serve as the sources of bacterial inoculants. All isolates were tested against Fusarium graminearum head blight fungus MHGNU F132 to confirm their antifungal effects. The enzyme activities (carboxylesterase and chitinase) were also measured to isolate the bacterial inoculant. Based on the activities of anti-head blight fungus, carboxylesterase, and chitinase, L. buchneri L11-1 and L. paracasei L9-3 were subjected to silage production. Corn forage (cv. Gwangpyeongok) was ensiled into a 10 L mini silo (5 kg) in quadruplication for 90 days. A 2 × 2 factorial design consists of F. graminearum contamination at 1.0104 cfu/g (UCT (no contamination) vs. CT (contamination)) and inoculant application at 2.1 × 105 cfu/g (CON (no inoculant) vs. INO (inoculant)) used in this study. After 90 days of ensiling, the contents of CP, NDF, and ADF increased (p<0.05) by F. graminearum contamination, while IVDMD, acetate, and aerobic stability decreased (p<0.05). Meanwhile, aerobic stability decreased (p<0.05) by inoculant application. There were interaction effects (p<0.05) on IVNDFD, NH3-N, LAB, and yeast, which were highest in UCT-INO, UCT-CON, CT-INO, and CT-CON & INO, respectively. In conclusion, this study found that mold contamination could negatively impact silage quality, but isolated inoculants had limited effects on IVNDFD and yeast.

Insect cuticle or exoskeleton is an extracellular matrix consisting of three major morphologically distinct layers, the water-proofing envelope, the protein-rich epicuticle and the chitin/protein-rich procuticle. To accommodate growth, insects must periodically replace their cuticles in a process called “molting or ecdysis”. During each molt cycle a new cuticle is deposited simultaneously with degradation of the inner part of the chitinous procuticle of the old one by molting fluid enzymes including epidermal chitinases. In this study, we show a novel role for an epidermal endochitinase containing two catalytic domains, TcCHT7, from the red flour beetle, Tribolium castaneum, belonging to a subfamily (group III) of insect chitinases in organizing chitin in the newly forming cuticle rather than in degrading chitin present in the prior one. RNAi of TcCHT7 reveals that this enzyme is nonessential for any type of molt or degradation of the chitinous matrix in the old cuticle. In contrast, TcCHT7 is required for formation of properly oriented long chitin fibers inside pore canals that are vertically oriented columnar structures, which contribute to maintain the integrity and the mechanical strength of a light-weight, yet rigid, adult cuticle. Because group III chitinases are highly conserved among insect and other arthropod species, these enzymes have a critical role in the higher ordered organization of chitin fibers for development of the structural integrity of many invertebrate cuticular extracellular matrices. This work was supported by NRFs (NRF-2015R1A2A2A01006614 and NRF-2018R1A2B6005106)

To accommodate growth, insects must periodically replace their chitin/protein-rich cuticles in a process called “molting or ecdysis”. During each molt cycle, a new cuticle is deposited simultaneously with degradation of the chitinous procuticle of the old one by molting fluid enzymes including epidermal chitinases. Here, we demonstrated a novel role for an endochitinase, TcCHT7, from the red flour beetle, Tribolium castaneum, belonging to a subfamily (Group III) that contain two catalytic domains, in organizing chitin in the newly forming cuticle rather than in degrading chitin present in the prior one. The conservation of CHT7-like proteins among many insect and other arthropod species indicates a critical role for the Group III class of chitinases in the higher ordered organization of chitin fibers for development of the structural integrity of many invertebrate exoskeletons.

Insect chitinases (CHTs), an extracellular enzyme, belong to family 18 glycosyl hydrolases that hydrolyze chitin by an endo-type manner. In insect genomes, there are a large number of genes encoding CHT-like proteins, and they have been classified into eleven groups based on phylogenetic analysis. In this study, we have investigated functions of a group III chitinase (TcCHT7) in Tribolium castaneum. Although, unlike most insect CHTs, TcCHT7 contains a predicted transmembrane segment in N-terminal, immunohistochemical analysis reveals that it is localized in the newly forming procuticle, suggesting that TcCHT7 is released from the plasma membrane of underlying epidermal cells. RNAi for TcCHT7 does not affect on any types of molting. However the resulting pupae and adults fail to undergo wing-expansion and abdominal contraction. In addition, TcCHT7-deficient insects exhibit ultrastructural defects in both rigid (e.g. elytron) and soft (e.g. hindwing) cuticles. These results demonstrate that functional importance of TcCHT7 in the formation of the rigid and soft cuticles of the beetle.

Insect chitinases (CHTs) belong to family 18 glycosylhydrolases and hydrolyze chitin by an endo-type manner. One of the functions of CHTs is in the turnover of chitin-containing extracellular matrices such as the cuticle and peritrophic matrix of the midgut. There are a large number of genes encoding CHT-like proteins in insects, and they have been classified into eleven groups based on phylogenetic analysis. We have investigated functions of a group III chitinase in Tribolium castaneum (TcCHT7) containing a predicted transmembrane segment in N-terminal region. Recombinant TcCHT7 exhibits chitinolytic activity against CM-Chitin-RBV. Immunohistochemical analysis shows that TcCHT7 is localized in newly formed procuticle in elytral cuticles, suggesting that TcCHT7 is released from the plasma membrane of underlying epidermal cells. TcCHT7-deficient pupae and adults fail to undergo wing-expansion and abdominal contraction. In addition, cuticular chitin accumulates in the inner region of the procuticle where disorganized horizontal laminae and pore canals are evident. These results demonstrate that TcCHT7 plays a critical role in the formation of the rigid and soft cuticles of the beetle. This work was supported by NRFs (NRF-2015 R1A2A2A01006614).

RNA interference(RNAi) is the method which controls phenotypes of gene in live cells. Chitinase is the enzyme helping digestion and absorption of old cuticles during the ecdysis of insects. In order to investigate molting-inhibition effect with the chitinase related gene in Spodoptera litura, RNA was extracted from the 5th instars. cDNA was synthesized and then we obtained about 645bp size chitinase. After PCR products were cloned into a pGEM T-easy vector, colonies were picked. DNA was extracted from the colony cultures. EcoR I enzyme was used to check whether PCR products were inserted or not. To synthesize the dsRNA, each DNA was cut with Spe I and Nco I enzymes. After synthesis, of dsRNA, approximately 5ul dsRNA was injected into the 3rd abdominal segment of S. litura 4th larvae. We confirmed insects that were phenotypically abnormal - for instance molting inhibition, change of integument color, malformation.

Insect chitinases (CHTs), which belong to family 18 glycosylhydrolases (GH-18), have been detected in molting fluid and gut tissues and are predicted to mediate the digestion of chitin present in the exoskeleton and peritrophic matrix (PM) in the gut. Based on amino acid sequence similarity and phylogenetic analysis, insect CHT family proteins have been classified into eight groups (group I to VIII). The CHTs belonging to different groups have distinctly different developmental patterns of expression and tissue specificity, suggestive of distinct biological functions. CHT7s belong to Group III chitinase contain two catalytic domains and one chitin binding domain (CBD). The catalytic domain 1 of this group of chitinases exhibits greater sequence similarity to one another than to the catalytic domain 2 in the same protein(s), suggesting distinct functions and/or evolutionary origins for each of these two catalytic domains. This group of chitinases, unlike most insect CHTs, possesses a predicted transmembrane segment at the N-terminal region. The recombinant T. castaneum CHT7 that was expressed in Hi-5 insect cells was bound to the cell membrane. Apparently, the catalytic domains of this CHT face the extracellular space as revealed by its ability to hydrolyze an artificial chitin substrate added to the medium. DsRNA-based functional studies (RNAi) for several CHT genes in Tribolium castaneum indicated that CHTs belong to groups I (TcCHT5) and II (TcCHT10) are critical for molting and turnover of chitin in the old cuticle. In other hand, RNAi for TcCHT7 did not affect any types of molting such as larval-larval, larval-pupal and pupal-adult. The resulting pupae or adults, however, failed to wing-expansion and abdominal contraction. Immunohistochemical analysis revealed that TcCHT7 protein is localized in newly synthesized procuticle, suggesting that TcCHT7 could be released form the plasma membrane of epidermal cells by proteolysis. Chitin seems to accumulate within the assembly zone of the elytral and body wall cuticle in dsTcCHT7-treated animals. Transmission electron microscopy revealed that down-regulation of TcCHT7 transcripts resulted in disorganization of chitin laminar and vertical canals in the procuticle. These results suggest that TcCHT7 may have critical roles in the laminar assembly and synthesis and/or deposition of cuticular chitin. This work was supported by NRF (NRF-2012R1A2A1A01006467).

RNA interference(RNAi)는 살아있는 세포에서 유전자의 표현력을 제어하는 방 법이다. 키틴을 분해하는 Chitinase는 곤충의 탈피에 관여하여 오래된 큐티클의 소 화 재흡수에 도움을 주는 효소이다. Chitinase를 이용하여 RNA interference 효과 를 보기 위해 담배거세미나방으로부터 RNA를 추출하였다. RNA 추출은 담배거 세미나방의 번데기, 번데기 직전의 유충, 5령 유충, 5령 유충의 외피로부터 각각 실 시하였다. RNA 추출물을 주형으로 cDNA를 합성하였고, 시퀀스 분석 결과 담배 거세미나방의 Chitinase의 크기는 약 610bp였다. 추후 담배거세미나방 Chitinase 의 dsRNA 합성과 생물검정을 통해 RNAi 효과를 확인하고자 한다.

An entomopathogenic filamentous fungus, Paecilomyces lilacinus strain HY-4, has a great potential as a promising bio-pesticide due to its superior pathogenicity against Adoretus tenuimaculatus and Tetranychus urticae. When the fungal strain infects host cuticle, it secrets a combination of hydrolytic enzymes including chitinase to solubilize the cuticle. Thus, we investigated effects of different carbon and nitrogen sources on the production of a chitinase from P. lilacinus strain HY-4. The organism produced an extracellular chitinase at a relatively high level (45.4 mU/ml) when cultivated for 5 days on a medium supplemented with insect pupa (0.5%) and colloidal chitin (1%), which was prepared by treating chitin from crab shells (Sigma-Aldrich Co. Ltd.) with 12 N HCl solution. However, extracellular secretion of chitinase by strain HY-4 was found to be significantly repressed in the presence of glucose (1%).

Baculovirus chitinase gene (ChiA) is a late gene and is essential for liquefying host insect at the late stage of infection for its hydrolyzing chitin function. In previous report, baculovirus ChiA can offer many interseting new opportunities for pest control. Recently, a putative chitinase gene (ChiA) was identified in the Spodopter litura nucleopolyhedorvirus (SlMNPV-K1) genome. The open reading frame (ORF) contains 1,692 nucelotides (nt) and encodes a protein of 563 amino acids (aa) with a predicted molecular weight of 62.62 kDa. To conform the insecticidal activity of ChiA from SlMNPV-K1, we constructed a baculovirus transfer vector, pBac-SlChiA, and this transfer vector was co-transfected with the bApGOZA DNA into sf9 cell to generate corresponding recombinant viru which designed Ap-SlChiA. Western blot analysis indicate that SlMNPV-K1 ChiA was successfully expressed. We found the chitinase activity of recombinant virus was enhanced 53% than wide type AcMNPV by chitinase assay, and the recombinant virus showed higher evidently insecticidal activity against 3rd instar larvae of Spodotera exigua than wide type AcMNPV (4.5 time). These results suggested that the chitinase gene from SlMNPV-K1 could be successfully applied to improve pathogenicity of bauclovirus

Phytopathogenic fungi들에 대해 매우 공격적인 Trichoderma hurzianum은 다른 곰팡이들의 세포벽 주성분인 chitin을 분해하는 extracellualr chitinase를 분비하기 때문에 매우 효율적인 biocontrol agent로 사용할 수 있다. Trichoderma harzianum의 생물학적 제어 기능을 이용하기 위하여 extracellualr chitinase의 생산성을 높일 수 있는 batch모드에서의 적정

Zoysiagrass are damaged by fungi diseases such as large patch, dollar spot, pythium blight and brown patch. Large patch is one of the major diseases caused by Rhizoctonia solani AG2-2 on zoysiagrass fields e.g. golf courses. Plant chitinases have been known PR (Pathogen related)-protein. In this study, we isolated two chitinase genes (Zjchi1 and Zjchi2) from zoysiagrass. Antifungal activity analysis revealed that Zjchi2 protein inhibited mycelium extension of fungi. A further study, we cloned 5` upstream region from two chitinase genes for investigating transcription regulatory mechanism that inducing of two chitinase genes dependent R. solani. -818 bp and -799 of upstream region from Zjchi1 and Zjchi2 successfully isolated using in vitro LA (Long and Accurate) PCR system. And then, we generated promoter-GUS reporter constructs with deletion construct based on W-boxes. Constructs were introduced into Arabidopsis thaliana by Agrobacterium-mediated transformation for stable expression of GUS reporter gene.