Species in the genera Pediococcus a

Species in the genera Pediococcus and Pseudomonas were also
frequently isolated in previous studies but were not detected in this
study. Pediococcus halophilus, which was isolated in previous
studies (Kim et al., 1999a; Lee, 1969; Sands and Crisan, 1974), was
reclassified as T. halophilus (Collins et al., 1990), and Aerococcus
urinaeequi, isolated from Saeu-jeot, was formerly named as Pediococcus
urinaeequi (Felis et al., 2005). Although clues for the
involvement of Pediococcus spp. in jeotgal ripening have been
suggested, only five strains in the genera Tetragenococcus and Aerococcus
were isolated from both jeotgal samples. Meanwhile, the
names of Pseudomonas spp. found in previous jeotgal studies have
not been changed at the genus level, and species in that genus were
not isolated in our study. Therefore, species in the genera Pediococcus
and Pseudomonas may not be the dominant populations
involved in jeotgal fermentation. The differences between the
aforementioned previous studies and the present study are mainly
attributable to the introduction of phylogenetic identification and
the ambiguity of conventional identification methods that rely on
physiological and phenotypic characteristics.
Isolation of LAB from jeotgal suggests the existence of LAB in the
marine environment. Considering the population difference of LAB
in the bacterial communities of Myeolchi-jeot and Saeu-jeot, their
survival may be reduced dramatically depending upon the prevailing
salt concentration. Weissella hellenica, Lactobacillus sakei
subsp. sakei, and Lactobacillus graminis were commonly isolated
from both jeotgal samples and thus may have a strong salt tolerance
among the isolated LAB. They are frequently found in kimchi,
a popular Korean fermented vegetable (Kim et al., 2008; Shim and
Lee, 2008). Jeotgal is added as a condiment to improve the flavor of
kimchi and thus may be a source of LAB. Although the existence of
LAB in jeotgal has been confirmed herein, their roles in jeotgal
fermentation have not been elucidated. The salt concentration in
jeotgal is too high to support the growth of LAB.
Species in the genus Sporosarcina were isolated in the highest
numbers from Myeolchi-jeot, but they were not isolated from Saeujeot.
They were intolerant to saltlevels greater than 10% NaCl (Table 3),
and no proteinase-producing strain was isolated in this research. The
isolation of a high number of Sporosarcina spp. could be restricted to
a selected sample. Um and Lee (1996) measured the numbers of
Staphylococcus spp. in 40 kinds of jeotgal by counting the numbers of
colonies that appeared on mannitol salt agar. Staphylococcus spp. at
over 100 CFU/ml were detected from most of the jeotgal samples, but
they were not detected at all in other samples. The detection of
Staphylococcus spp. depended on the selected specimens rather than
on the actual kind of jeotgal. This suggests that both the matrix
composition and also the fermentation parameters play a defining
role in the community of microorganisms.
The fermentation period of jeotgal depends on the salt concentration
and fermentation temperature: two months for jeotgal
with low-salt levels (6e18%), and a few years for jeotgal with
a high-salt content (over 20%). The favorable taste and flavor may
be developed gradually during fermentation by several enzymatic
reactions and the process of microbial degradation. As the result,
the fermented seafood contains relatively high amounts of amino
acids and the degradation products of seafood protein (Lee, 1989).
From studies on fish sauce, which is manufactured similarly to
jeotgal, protein hydrolysis is known to be induced by endogenous
protease in raw materials as well as protease produced by halophilic
bacteria (Gildberg and Thongthai, 2001). According to
research on the autolytic activity of endogenous proteinases in
Indian anchovy, proteolytic activity decreased with increasing NaCl
concentration, and the residual autolytic activity at 25% NaCl was
52% of control values (no NaCl) (Siringan et al., 2006). This report
strongly supports the idea that endogenous proteinases could
hydrolyze muscle proteins, even at high-salt concentration.
However, a few halophilic bacteria that can conduct proteolysis in
high-salt conditions were isolated from fish sauce. Filobacillus sp.
RF2-5, isolated from fish sauce in Thailand, produced a serine
proteinase that was highly stable at 25% NaCl (Hiraga et al., 2005),
110 L. Guan et al. / Food Microbiology 28 (2011) 101e113
and Virgibacillus sp. SK37, with caseinolytic activity at 25% NaCl,
was also isolated in fish sauce (Sinsuwan et al., 2007). In research
on the acceleration of fish sauce fermentation using proteinases
and bacterial starter cultures, starter cultures prepared from two
strains of Virgibacillus and a Staphylococcus strain were added
separately to anchovies that were hydrolyzed by proteases
(Yongsawatdigul et al., 2007). The inoculated cultures in fish sauce
did not proliferate but maintained their population in the 25% NaCl
condition; an increase in the a-amino content in the fish sauces was
detected by starter inoculations. The sample inoculated with
a Staphylococcus strain produced higher levels of volatile fatty acids
and showed similar sensory characteristics to the long-term fermented
commercial fish sauce. The occurrence of proteolysis by
halophilic bacteria and flavor formation by a Staphylococcus strain
were demonstrated by this research.
In our research, halophilic bacterial counts on nutrient agar
containing 15% NaCl were not high enough to consider them as the
main source of protease, and a protease producer exhibiting
proteolytic activity in media containing over 15% NaCl content was
not isolated. Therefore, protein hydrolysis of jeotgal may rely
mainly on the action of endogenous proteinases associated with
marine animals and only partially on those of halophilic bacteria. In
this research, the genus Bacillus and its relatives were detected as
the major genera of Myeolchi-jeot, and the genus Staphylococcus
was the major constituent of Saeu-jeot. These organisms were
isolated from both jeotgal samples, but their proportions in the
bacterial community may have been influenced by matrix
composition and fermentation parameters. The genus Virgibacillus
shared the second largest portion in the cultivable bacterial
community of Myeolchi-jeot, and the existence of Virgibacillus
strains having protease activity under high-salt conditions was
shown in previous studies (Sinsuwan et al., 2007; Yongsawatdigul
et al., 2007). Although species in the genus Virgibacillus were not
isolated from Saeu-jeot, they are able to grow in high-salt-containing
jeotgal and to exhibit protease activity. The number of
species in the genus Staphylococcus isolated from Saeu-jeot was too
large to ignore their possible role in jeotgal fermentation. They were
also isolated from Myeolchi-jeot as dominant bacteria and exhibited
growth on media containing 20% NaCl. High-salt conditions
inhibited the protease activities of Staphylococcus strains, and
isolation of a high-protease-producing strain has not been reported.
However, in the study of Yongsawatdigul et al. (2007), the
a-amino content of fish sauce inoculated with Staphylococcus sp.
was higher than that inoculated with two Virgibacillus strains. An
increase in a-amino content may not represent direct proof of
protease production, but it suggests that its protease works under
high-salt conditions. The Staphylococcus spp. predominating in
jeotgal may not be hugely involved in proteolysis but may play
significant roles in jeotgal fermentation (for example, as producers
of desirable flavor). Bacteria in the genus Bacillus and its relatives
and the genus Staphylococcus may be the major organisms involved
in jeotgal fermentation