Role of cell-substrate association during plant biomass solubilization by the extreme thermophile Caldicellulosiruptor bescii.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-02-21 DOI:10.1007/s00792-023-01290-7
Tunyaboon Laemthong, Ryan G Bing, James R Crosby, Mohamad J H Manesh, Michael W W Adams, Robert M Kelly
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Abstract

Caldicellulosiruptor species are proficient at solubilizing carbohydrates in lignocellulosic biomass through surface (S)-layer bound and secretomic glycoside hydrolases. Tāpirins, surface-associated, non-catalytic binding proteins in Caldicellulosiruptor species, bind tightly to microcrystalline cellulose, and likely play a key role in natural environments for scavenging scarce carbohydrates in hot springs. However, the question arises: If tāpirin concentration on Caldicellulosiruptor cell walls increased above native levels, would this offer any benefit to lignocellulose carbohydrate hydrolysis and, hence, biomass solubilization? This question was addressed by engineering the genes for tight-binding, non-native tāpirins into C. bescii. The engineered C. bescii strains bound more tightly to microcrystalline cellulose (Avicel) and biomass compared to the parent. However, tāpirin overexpression did not significantly improve solubilization or conversion for wheat straw or sugarcane bagasse. When incubated with poplar, the tāpirin-engineered strains increased solubilization by 10% compared to the parent, and corresponding acetate production, a measure of carbohydrate fermentation intensity, was 28% higher for the Calkr_0826 expression strain and 18.5% higher for the Calhy_0908 expression strain. These results show that enhanced binding to the substrate, beyond the native capability, did not improve C. bescii solubilization of plant biomass, but in some cases may improve conversion of released lignocellulose carbohydrates to fermentation products.

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细胞-底物结合在极端嗜热Caldicelllosiruptor bescii溶解植物生物质过程中的作用。
Caldicellosiruptor物种擅长通过表面(S)层结合和分泌组糖苷水解酶溶解木质纤维素生物质中的碳水化合物。Tāpirins是Caldicelllosiruptor物种中的表面相关非催化结合蛋白,与微晶纤维素紧密结合,可能在自然环境中清除温泉中稀缺的碳水化合物方面发挥关键作用。然而,问题来了:如果Caldicelllosiruptor细胞壁上的tāpirin浓度增加到高于天然水平,这会对木质纤维素碳水化合物水解,从而对生物质溶解有任何好处吗?这个问题是通过将紧密结合的非本土tāpirins基因工程转化为C.bescii来解决的。与亲本相比,工程化的贝氏C.bescii菌株与微晶纤维素(Avicel)和生物质的结合更紧密。然而,tāpirin过表达并没有显著改善小麦秸秆或甘蔗渣的溶解或转化。当与杨树孵育时,与亲本相比,tāpirin工程菌株的增溶作用增加了10%,相应的醋酸盐产量(衡量碳水化合物发酵强度的指标)对Calkr_0826表达菌株高28%,对Calhy_0908表达菌株则高18.5%。这些结果表明,与底物的结合增强,超出了天然能力,并没有改善C.bescii对植物生物质的增溶作用,但在某些情况下,可能会改善释放的木质纤维素碳水化合物向发酵产物的转化。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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