Microbial
production of α-farnesene from renewable raw materials
is a feasible alternative to traditional petroleum craft. Recently,
the research on improving α-farnesene production in Pichia pastoris mainly focused on cytoplasmic engineering,
while comprehensive engineering of multiple subcellular compartments
is rarely reported. Here, we first sought to confirm that the isopentenol
utilization pathway (IUP) could act as a two-step shortcut for IPP
synthesis in P. pastoris peroxisomes. In addition,
we proposed dual regulation of cytoplasm and peroxisomes to boost
α-farnesene synthesis in P. pastoris X33, thus
the resultant strain produced 2.18 ± 0.04 g/L, which was 1.3
times and 2.1 times than that of the strain only with peroxisomal
or cytoplasmic engineering, respectively. The α-farnesene production
achieved 2.56 ± 0.04 g/L in shake flasks after carbon source
cofeeding, which was the highest reported production in worldwide
literatures to the best of my knowledge. Therefore, we propose these
strategies as efficient approaches to enhancing α-farnesene
production in P. pastoris, which might bring new
ideas for the biosynthesis of high-value compounds.
Antisense RNA molecule represents a unique type of DNA transcript that comprises 19-23 nucleotides and is complementary to mRNA. Antisense RNAs play the crucial role in regulating gene expression at multiple levels, such as at replication, transcription, and translation. In addition, artificial antisense RNAs can effectively regulate the expression of related genes in host cells. With the development of antisense RNA, investigating the functions of antisense RNAs has emerged as a hot research field. This review summarizes our current understanding of antisense RNAs, particularly of the formation of antisense RNAs and their mechanism of regulating the expression of their target genes. In addition, we detail the effects and applications of antisense RNAs in antivirus and anticancer treatments and in regulating the expression of related genes in plants and microorganisms. This review is intended to highlight the key role of antisense RNA in genetic research and guide new investigators to the study of antisense RNAs.
Fructose-1,6-bisphosphatase (FBPase) and fructokinase (ScrK) have important roles in regenerating glucose-6-phosphate in the pentose phosphate pathway (PPP), and thus increasing L-lysine production. This article focuses on the development of L-lysine high-producing strains by heterologous expression of FBPase gene fbp and ScrK gene scrK in C. glutamicum lysC (fbr) with molasses as the sole carbon source. Heterologous expression of fbp and scrK lead to a decrease of residual sugar in fermentation broth, and heterologous expression of scrK prevents the fructose efflux. Heterologous expression of fbp and scrK not only increases significantly the activity of corresponding enzymes but also improves cell growth during growth on molasses. FBPase activities are increased tenfold by heterologous expression of fbp, whereas the FBPase activity is only increase fourfold during co-expression of scrK and fbp. Compared with glucose, the DCW of heterologous expression strains are higher on molasses except co-expression of fbp and scrK strain. In addition, heterologous expression of fbp and scrK can strongly increase the L-lysine production with molasses as the sole carbon source. The highest increase (88.4 %) was observed for C. glutamicum lysC (fbr) pDXW-8-fbp-scrK, but the increase was also significant for C. glutamicum lysC (fbr) pDXW-8-fbp (47.2 %) and C. glutamicum lysC (fbr) pDXW-8-scrK (36.8 %). By-products, such as glycerol and dihydroxyacetone, are decreased by heterologous expression of fbp and scrK, whereas trehalose is only slightly increased. The strategy for enhancing L-lysine production by regeneration of glucose-6-phosphate in PPP may provide a reference to enhance the production of other amino acids during growth on molasses or starch.
Six key enzymes are vital for MK-7 production, but the same enzyme has different effect on MK-7 production in different cultivating methods. Thus, the high enzyme activity and high-traffic biosynthetic pathway are beneficial to synthesize MK-7.
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