The high percentage of alpha-linole

The high percentage of alpha-linolenic acid causes the oxidative
instability of linseed oil, and therefore it is mainly used in the
chemical industry as a component of paints, inks and varnishes.
Improved oxidative stability has been obtained by altering the fatty
acid profile, for example by lowering alpha-linolenic and increasing
linoleic acid content. Ethyl methane sulfonate (EMS)-mediated
mutagenesis caused a point mutation in fatty acid desaturase 3
(FAD3), resulting in non-functional enzymatic activity and thus
reducing the level of alpha-linolenic acid and accumulation of
linoleic acid (Vrinten et al., 2005).
Genetic engineering has also been used for altering the fatty
acid profile in the linseed plant. Examples are expression of an
exogenous gene from potato (Solanum sogarandinum L.) of glucosyl
transferase modifying flavonoid compounds (GT plant type)
or simultaneous expression of three key genes of the flavonoid
pathway coding chalcone synthase, chalcone isomerase and dihydroflavonol
reductase, all derived from petunia (Petunia hybrida L.)
(W92 plant type) and silencing of the endogenous chalcone synthase
gene (W86 plant type), resulting in variations of fatty acid
profiles. W86 oil showed a 10-fold increase in the omega-3 fatty
acid level. In contrast, a 10% increase in the level of omega-6 was
detected in W92 type (Table 1).
Besides favorable changes in fatty acids profile, these results
showed for the first time the regulatory connection between separate
metabolic pathways (i.e. phenylpropanoid and fatty acid). The
variations in polyunsaturated fatty acid (PUFA) content affect oil
stability. The thiobarbituric acid reactive substances (TBARS) measurements
show a decrease in the level of oxidation products by
10.21, 50.93 and 86.53% for W86, GT and W92 oil, respectively, in
comparison to control plants (data not published yet). Since the
levels of omega-3 fatty acid in GT and W92 types were almost the
same, while oxidative status substantially changed, the intriguing
question arises: what are the other compounds involved in fatty
acid protection against oxidation?
To identify the compounds that might participate in oil stability,
content of water- and lipid-soluble antioxidants in the oil
was recently determined (Table 2). Of water-soluble components
(0.05 g/g FW) vanillin was identified as the most abundant (45%)
phenolic compound in linseed oil. The other identified components
are non-hydrolysable (proanthocyanidins) and hydrolysable
tannins (5.4 and 3.0%, respectively), p-coumaric acid, ferulic acid,
caffeic acid, coniferyl and syringic aldehyde (10, 16, 3, 9 and 7%,
respectively) and small amounts of flavonoids, probably luteolin
and kaempferol derivatives. Lipid-soluble secondary metabolites
are highly (0.9 mg/g FW) represented in oil. Among these components,
-tocopherol (50%), plastochromanol-8 (44.5%), lutein (3%)
and -carotene (1.5%) have been found in linseed oil. The highest
positive correlation coefficient was obtained for total phenolic
content and oil stability. Thus,it suggests that accumulationof compounds
from the phenylpropanoid pathway is required for linseed
oil stability improvement. High oxidative stability of linseed oil
enhances its application not only in the chemical industry but also
for biomedical application.
Several clinical research studies in humans have aimed at
assessing the efficacy of linseed bioactivity in health and disease.
For example, many research reports suggest the beneficial impact
of a diet high in alpha-linolenic acid from linseed oil on reducing
markers of oxidative stress and inflammation associated with
risk of many common chronic diseases (e.g. atherosclerosis) (Goyal
et al., 2014).
From a biochemical point of view, polyunsaturated fatty acids
intake modulates membrane lipid composition. Consumption of
linseed oil protects against the negative consequences of unbalanced
human diet, and prevents or delays the onset of chronic
diseases (for example atherosclerosis) through reducing the burden
of oxidative stress and generation of anti-inflammatory
mediators.
In the light of recent experiments, it is evident that a wellbalanced
diet might contribute to cardiovascular disease and breast
cancer treatment in a positive manner. In a very recent study, the
effect of flax seed daily ingestion on blood pressure of peripheral
artery disease patients was examined (Rodriguez-Leyva et al.,
2013). Those patients that entered the trial with blood pressure
(BP) ≥ 140 mm Hg and ingested daily 30 g of milled flaxseed
with the food for 6 months showed a significant reduction (ca.
15 mm Hg) in BP. The reduction in BP correlated with circulating
alpha-linolenic acid and lignan levels. Thus, it was concluded that
linseed included in the daily diet induced an anti-hypersensitive
effect.
Linseed intake might be associated with decreased risk of breast
cancer. Its daily ingestion of 25 g increased the tumor apoptotic
index and reduced cell proliferation among breast cancer patients
(Flower et al., 2013).