Molecular and functional analysis of three fatty acyl-CoA reductases with distinct substrate specificities in copepod Calanus finmarchicus.

The marine copepod Calanus finmarchicus constitutes the substantial amount of biomass in the Arctic and Northern seas. It is unique in that this small crustacean accumulates a high level of wax esters as carbon storage which is mainly comprised of 20:1n-9 and 22:1n-11 alcohols (Alc) linked with various kinds of fatty acids, including n-3 polyunsaturated fatty acids. The absence of 20:1n-9 Alc and 22:1n-11 Alc in diatoms and dinoflagellates, the primary food sources of copepods, suggests the existence of de novo biosynthesis of fatty alcohols in C. finmarchinus. Here, we report identification of three genes, CfFAR1, CfFAR2, and CfFAR3, coding for fatty acyl-CoA reductases involved in the conversion of various fatty acyl-CoAs to their corresponding alcohols. Functional characterization of these genes in yeast indicated that CfFAR1 could use a wide range of saturated fatty acids from C18 to C26 as substrates, CfFAR2 had a narrow range of substrates with only very-long-chain saturated fatty acid 24:0 and 26:0, while CfFAR3 was active towards both saturated (16:0 and 18:0) and unsaturated (18:1 and 20:1) fatty acids producing corresponding alcohols. This finding suggested that these three fatty acyl-CoA reductases are likely responsible for de novo synthesis of a series of fatty alcohol moieties of wax esters in C. finmarchicus.

A fatty acyl-CoA reductase highly expressed in the head of honey bee (Apis mellifera) involves biosynthesis of a wide range of aliphatic fatty alcohols.

Honey bees (Apis mellifera) are social insects which have remarkable complexity in communication pheromones. These chemical signals comprise a mixture of hydrocarbons, wax esters, fatty acids, aldehydes and alcohols. In this study, we detected several long chain aliphatic alcohols ranging from C18-C32 in honey bees and the level of these alcohols varied in each body segment. C18:0Alc and C20:0Alc are more pronounced in the head, whereas C22:0Alc to C32Alc are abundant in the abdomen. One of the cDNAs coding for a fatty acyl-CoA reductase (AmFAR1) involved in the synthesis of fatty alcohols was isolated and characterized. AmFAR1 was ubiquitously expressed in all body segments with the predominance in the head of honey bees. Heterologous expression of AmFAR1 in yeast revealed that AmFAR1 could convert a wide range of fatty acids (14:0-22:0) to their corresponding alcohols, with stearic acid 18:0 as the most preferred substrate. The substrate preference and the expression pattern of AmFAR1 were correlated with the level of total fatty alcohols in bees. Reconstitution of the wax biosynthetic pathway by heterologous expression of AmFAR1, together with Euglena wax synthase led to the high level production of medium to long chain wax monoesters in yeast.

Fatty acyl-CoA reductase and wax synthase from Euglena gracilis in the biosynthesis of medium-chain wax esters.

Euglena gracilis, a unicellular phytoflagellate, can accumulate a large amount of medium-chain wax esters under anaerobic growth conditions. Here we report the identification and characterization of two genes involved in the biosynthesis of wax esters in E. gracilis. The first gene encodes a fatty acyl-CoA reductase (EgFAR) involved in the conversion of fatty acyl-CoAs to fatty alcohols and the second gene codes for a wax synthase (EgWS) catalyzing esterification of fatty acyl-CoAs and fatty alcohols, yielding wax esters. When expressed in yeast (Saccharomyces cerevisiae), EgFAR converted myristic acid (14:0) and palmitic acid (16:0) to their corresponding alcohols (14:0Alc and 16:0Alc) with myristic acid as the preferred substrate. EgWS utilized a broad range of fatty acyl-CoAs and fatty alcohols as substrates with the preference towards myristic acid and palmitoleyl alcohol. The wax biosynthetic pathway was reconstituted by co-expressing EgFAR and EgWS in yeast. When myristic acid was fed to the yeast, myristyl myristate (14:0-14:0), myristyl palmitoleate (14:0-16:1), myristyl palmitate (14:0-16:0) and palmityl myristate (16:0-14:0) were produced. These results indicate EgFAR and EgWS are likely the two enzymes involved in the biosynthesis of medium-chain wax esters in E. gracilis.

Protein storage vacuoles of Brassica napus zygotic embryos accumulate a BURP domain protein and perturbation of its production distorts the PSV.

BNM2is a prototypical member of the enigmatic BURP domain protein family whose members contain the signature FX6-7GX10-28PX25-31CX11-12X2SX45-56CHX10 CHX25-29CHX2TX15-16PX5CH in the C-terminus. This protein family occurs only in plants, and the cognate genes vary very widely in their expression contexts in vegetative and reproductive tissues. None of theBURP family members has been assigned any biochemical function. BNM2 was originally discovered as a gene expressed in microspore derived embryos (MDE) of Brassica napus but we found that MDE do not contain the corresponding protein. We show that BNM2 protein production is confined to the seeds and localized to the protein storage vacuoles (PSV) even though the transcript is found in vegetative parts and floral buds as well. In developing seeds, transcript accumulation precedes protein appearance by more than 18 days. RNA accumulation peaks at approximately 20 days post anthesis (DPA) whereas protein accumulation reaches its maximum at approximately 40 DPA. Transgenic expression of BNM2 does not abrogate this regulation to yield ectopic protein production or to alter the temporal aspect ofBNM2 accumulation. Overexpression ofBNM2 led to spatial distortion of storage protein accumulation within PSV and to some morphological alterations of PSVs. However, the overall storage protein content was not altered.

Purification and characterization of rice DNA methyltransferase.

Epigenetic modification is essential for normal development and plays important roles in gene regulation in higher plants. Multiple factors interact to regulate the establishment and maintenance of DNA methylation in plant genome. We had previously cloned and characterized DNA methyltransferase (DNA MTase) gene homologues (OsMET1) from rice. In this present study, determination of DNA MTase activity in different cellular compartments showed that DNA MTase was enriched in nuclei and the activity was remarkably increased during imbibing dry seeds. We had optimized the purification technique for DNA MTase enzyme from shoots of 10-day-old rice seedlings using the three successive chromatographic columns. The Econo-Pac Q, the Hitrap-Heparin and the Superdex-200 columns yielded a protein fraction of a specific activity of 29, 298 and 800 purification folds, compared to the original nuclear extract, respectively. The purified protein preferred hemi-methylated DNA substrate, suggesting the maintenance activity of methylation. The native rice DNA MTase was approximately 160-170 kDa and exhibited a broad pH optimum in the range of 7.6 and 8.0. The enzyme kinetics and inhibitory effects by methyl donor analogs, base analogs, cations, and cationic amines on rice DNA MTase were examined. Global cytosine methylation status of rice genome during development and in various tissue culture systems were monitored and the results suggested that the cytosine methylation level is not directly correlated with the DNA MTase activity. The purification and characterization of rice DNA MTase enzyme are expected to enhance our understanding of this enzyme function and their possible contributions in Gramineae plant development.

Investigations of combinations of mutations in the jellyfish green fluorescent protein (GFP) that afford brighter fluorescence, and use of a version (VisGreen) in plant, bacterial, and animal cells.

Among the GFPs used for imaging green fluorescence, the Emerald version has been considered the best GFP to use but there is no formal report on its construction or the relevance of the amino acid (aa) substitutions in it relative to the commonly used GFPs. Here, we have shown that a version of Emerald makes Escherichia coli host cells visibly green even under dim room light conditions. Exploiting this feature, we have determined for the first time whether the changes in the structure of Emerald protein brought about by the aa substitutions are all indeed essential for brightness. F64L and S72A accompanying the classical S65T substitution on the chromophore-bearing helix are essential. Two amino acid changes, one on the surface (N149K) of the beta barrel that encases the helix and the other (I167T) near the chromophore enhance the visible green colour individually and additively when present together. The other two substitutions, M153T (on the surface) and H231L (on the surface), do not contribute to the visible green phenotype, even though in earlier studies M153T has been reported to enhance GFP fluorescence. The GFP version with F64L-S65T-S72A-N149K-I167T is referred to as VisGreen. We found VisGreen and Emerald to be indistinguishable in their quantum yield, molar extinction coefficient, folding efficiency, or photosensitivity. VisGreen rendered bacterial, plant, and animal cells highly fluorescent. Interestingly, N149K in the above combination was not essential to render bacterial cells highly fluorescent.

Characterization of two rice DNA methyltransferase genes and RNAi-mediated reactivation of a silenced transgene in rice callus.

Two genomic clones ( OsMET1-1, AF 462029 and OsMET1-2, TPA BK001405), each encoding a cytosine-5 DNA methyltransferase (MTase), were isolated from rice ( Oryza sativa L.) BAC libraries. OsMET1-1 has an open reading frame of 4,566 nucleotides with 12 exons and 11 introns while OsMET1-2 has an open reading frame of 4,491 nucleotides with 11 exons and 10 introns. Although OsMET1-1 and OsMET1-2 have high sequence similarity overall, they share only 24% identity in exon 1, and intron 3 of OsMET1-1 is absent from OsMET1-2. As for other eukaryotic DNA MTases of the Dnmt1/MET l class, the derived amino acid sequences of OsMET1-1 and OsMET1-2 suggest that they are comprised of two-thirds regulatory domain and one-third catalytic domain. Most functional domains identified for other MTases were present in the rice MET1 sequences. Amino acid sequence comparison indicated high similarity (56-75% identity) of rice MET1 proteins to other plant MET1 sequences but limited similarity (approx. 24% identity) to animal Dnmt1 proteins. Genomic blot and database analysis indicated the presence of a single copy of OsMET1-1 (on chromosome 3) and single copy of OsMET1-2 (on chromosome 7). Ribonuclease protection assays revealed expression of both OsMET1-1 and OsMET1-2 in highly dividing cells, but the steady-state level of OsMET1-2 was 7- to 12-fold higher than that for OsMET1-1 in callus, root and inflorescence. The functional involvement of the rice DNA MTases in gene silencing was investigated using an RNAi strategy. Inverted repeat constructs of either the N- or C-terminal regions of OsMET1-1 were supertransformed into calli derived from a rice line bearing a silenced 35S-uidA-nos transgene. Restoration of uidA expression in the bombarded calli was consistent with the inactivation of maintenance methylation and with previous evidence for the involvement of methylation in silencing of this line.