Lignocellulosic
biomass is the most abundant organic carbon source
and has received a great deal of interest as renewable and sustainable
feedstock for the production of potential biofuels and value-added
chemicals with a wide range of designed catalytic systems. However,
those natural polymeric materials are composed of short-chain monomers
(typically C6 and C5 sugars) and complex lignin
molecules containing plenty of oxygen, resulting in products during
the downstream processing having low-grade fuel properties or limited
applications in organic syntheses. Accordingly, approaches to increase
the carbon-chain length or carbon atom number have been developed
as crucial catalytic routes for upgrading biomass into energy-intensive
fuels and chemicals. The primary focus of this review is to systematically
describe the recent examples on the selective synthesis of long-chain
oxygenates via different C–C coupling catalytic processes,
such as Aldol condensation, hydroalkylation/alkylation, oligomerization,
ketonization, Diels–Alder, Guerbet, and acylation reactions.
Other integrated reaction steps including, for example, hydrolysis,
dehydration, oxidation, partial hydrogenation, and hydrodeoxygenation
(HDO) to derive corresponding key intermediates or final products
are also reviewed. The effects of catalyst structure/type and reaction
parameters on the catalytic performance along with relevant reaction
mechanisms are in detail discussed. Apart from this, the formation
of other useful compounds containing C–X bonds (X = O, N, and
S) derived from biomass-based substrates for producing fuel additives
and valuable chemicals is also briefly reviewed.
Withaferin A (WA) is present abundantly in Withania somnifera, a well-known Indian medicinal plant. Here we demonstrate how WA exhibits a strong growth-inhibitory effect on several human leukemic cell lines and on primary cells from patients with lymphoblastic and myeloid leukemia in a dose-dependent manner, showing no toxicity on normal human lymphocytes and primitive hematopoietic progenitor cells. WA-mediated decrease in cell viability was observed through apoptosis as demonstrated by externalization of phosphatidylserine, a time-dependent increase in Bax/Bcl-2 ratio; loss of mitochondrial transmembrane potential, cytochrome c release, caspases 9 and 3 activation; and accumulation of cells in sub-G0 region based on DNA fragmentation. A search for the downstream pathway further reveals that WA-induced apoptosis was mediated by an increase in phosphorylated p38MAPK expression, which further activated downstream signaling by phosphorylating ATF-2 and HSP27 in leukemic cells. The RNA interference of p38MAPK protected these cells from WA-induced apoptosis. The RNAi knockdown of p38MAPK inhibited active phosphorylation of p38MAPK, Bax expression, activation of caspase 3 and increase in Annexin V positivity. Altogether, these findings suggest that p38MAPK in leukemic cells promotes WA-induced apoptosis. WA caused increased levels of Bax in response to MAPK signaling, which resulted in the initiation of mitochondrial death cascade, and therefore it holds promise as a new, alternative, inexpensive chemotherapeutic agent for the treatment of patients with leukemia of both lymphoid and myeloid origin.
Withania somnifera is one of the most valuable medicinal plants used in Ayurvedic and other indigenous medicine systems due to bioactive molecules known as withanolides. As genomic information regarding this plant is very limited, little information is available about biosynthesis of withanolides. To facilitate the basic understanding about the withanolide biosynthesis pathways, we performed transcriptome sequencing for Withania leaf (101L) and root (101R) which specifically synthesize withaferin A and withanolide A, respectively. Pyrosequencing yielded 8,34,068 and 7,21,755 reads which got assembled into 89,548 and 1,14,814 unique sequences from 101L and 101R, respectively. A total of 47,885 (101L) and 54,123 (101R) could be annotated using TAIR10, NR, tomato and potato databases. Gene Ontology and KEGG analyses provided a detailed view of all the enzymes involved in withanolide backbone synthesis. Our analysis identified members of cytochrome P450, glycosyltransferase and methyltransferase gene families with unique presence or differential expression in leaf and root and might be involved in synthesis of tissue-specific withanolides. We also detected simple sequence repeats (SSRs) in transcriptome data for use in future genetic studies. Comprehensive sequence resource developed for Withania, in this study, will help to elucidate biosynthetic pathway for tissue-specific synthesis of secondary plant products in non-model plant organisms as well as will be helpful in developing strategies for enhanced biosynthesis of withanolides through biotechnological approaches.
Lignocellulosic biomass is an important renewable resource that could substitute fossil feedstocks as a raw material for high value chemicals production.
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