Ignacio G. Barroso, Carolina K. Canettieri, Clelia Ferreira, Walter R. Terra
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Gene expression and peptidase activities were usually consistent for putative intracellular and membrane-bound enzymes. However, secreted peptidase gene expression and activities have divergent values, especially in the PM, which may be due to the countercurrent water flux causing enzyme recycling, thus decreasing their excretion. Data suggest that Trys and APs act in the AM. In the acidic MM, lysozymes kill microorganisms found in the diet, releasing proteins digested by cathepsins D, which may also digest Trys coming from the AM. Finally, highly active serine endopeptidases, CPs, dipeptidases, and APs complete protein digestion in PM. Absorption of peptides and amino acids coupled to protons may occur along the midgut, especially in PM, as occurs for facilitated amino acid transport. Absorption with sodium ions is probably restricted to AM and PM. 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引用次数: 0
摘要
通过RNA-Seq分析、蛋白质生物信息学、微绒毛膜富集的中肠蛋白质组学和酶活性,提出了姬鹟幼虫沿中肠消化蛋白质以及吸收肽和氨基酸的模型。肽酶基因在后中肠(PM)中高表达,而酪蛋白酶基因的表达仅限于中肠(MM)。几乎所有肽酶基因在中中肠(MM)的表达量都最低,但膜结合丝氨酸内肽酶基因的表达量却很高。前中肠(AM)的丝氨酸内肽酶和氨基肽酶(AP)基因表达量居中,而羧肽酶(CPs)的表达量较低。假定的细胞内酶和膜结合酶的基因表达和肽酶活性通常是一致的。然而,分泌型肽酶基因表达量和活性值存在差异,尤其是在 PM 中,这可能是由于逆流水流导致酶的循环,从而减少了它们的排泄。数据表明,Trys 和 APs 在 AM 中起作用。在酸性的 MM 中,溶菌酶会杀死食物中的微生物,释放出由促蛋白酶 D 消化的蛋白质,促蛋白酶 D 也可能消化来自 AM 的 Trys。最后,高活性丝氨酸内肽酶、CPs、二肽酶和 APs 在 PM 中完成蛋白质消化。与质子偶联的肽和氨基酸的吸收可能会沿着中肠进行,尤其是在原生动物体内,就像氨基酸的运输一样。钠离子的吸收可能仅限于 AM 和 PM。我们的研究结果为了解驯鹿幼虫的蛋白质消化和氨基酸吸收机制提供了宝贵的信息。
Protein digestion and amino acid absorption mechanisms along the midgut of Musca domestica larvae
A model of protein digestion and peptide and amino acid absorption along the midgut of Musca domestica larvae was proposed and supported by RNA-Seq analyses, protein bioinformatics, microvillar-membrane-enriched midgut proteomics, and enzymatic activities. Peptidase genes are highly expressed in the posterior midgut (PM), whereas those for cathepsins have expression limited to the middle midgut (MM). MM has the lowest levels of gene expression of almost all peptidases but has high expression of genes for membrane-bound serine endopeptidases. The anterior midgut (AM) has intermediate expression values of serine endopeptidase and aminopeptidase (AP) genes and low expression of carboxypeptidases (CPs). Gene expression and peptidase activities were usually consistent for putative intracellular and membrane-bound enzymes. However, secreted peptidase gene expression and activities have divergent values, especially in the PM, which may be due to the countercurrent water flux causing enzyme recycling, thus decreasing their excretion. Data suggest that Trys and APs act in the AM. In the acidic MM, lysozymes kill microorganisms found in the diet, releasing proteins digested by cathepsins D, which may also digest Trys coming from the AM. Finally, highly active serine endopeptidases, CPs, dipeptidases, and APs complete protein digestion in PM. Absorption of peptides and amino acids coupled to protons may occur along the midgut, especially in PM, as occurs for facilitated amino acid transport. Absorption with sodium ions is probably restricted to AM and PM. Our findings provide valuable insights into the protein digestion and amino acid absorption mechanism in M. domestica larvae.
期刊介绍:
Comparative Biochemistry & Physiology (CBP) publishes papers in comparative, environmental and evolutionary physiology.
Part B: Biochemical and Molecular Biology (CBPB), focuses on biochemical physiology, primarily bioenergetics/energy metabolism, cell biology, cellular stress responses, enzymology, intermediary metabolism, macromolecular structure and function, gene regulation, evolutionary genetics. Most studies focus on biochemical or molecular analyses that have clear ramifications for physiological processes.