Rapp. Comm. int. Mer Médit., 36,2001
211
Introduction
Microorganisms, especially bacteria, play an important role in the
marine ecosystem, and number of heterotrophic bacteria serve as trophic
level indicators. The coastal zone is an area where river and discharge
receive great amounts of dissolved organic matter. Bacterioplankton can
transform part of these substances to biomass supplying the grazing food
chain in the ecosystem. In coastal areas distribution of bacterial numbers
and activity is affected by ?uctuations of some biotic and abiotic factors
(1). The Black Sea is a semi-enclosed sea, constituting a “unicum hydro-
biologicum”by virtue of its physical, chemical and biological conditions.
During recent decades, the Black Sea has become seriously perturbed by
anthropogenic forces, a large quantity of inorganic and organic compounds
is introduced every year by rivers and by industrial and domestic dis-
charges. The increasing nutrient inputs was re?ected in changes in many
abiotic and biotic factors with severe impacts on the entire marine ecosys-
tem structure of the Black Sea (3). Therefore, it is necessary to understand
function and structure of the ecosystem from eutrophied and polluted
areas, in order to improve this ecosystem.
This paper reports the distribution and characteristics of heterotrophic
marine bacteria in the coastal waters from the Mamaia Bay, Romania as
affected by ?uctuations of physico-chemical and biological factors during
the 2000 year.
Material and Methods
Mamaia Bay (Fig.1) is an area from the Southern part of Romanian
Black Sea coast in which there are many social and economic activities,
especially touristic activities.
The water quality from this site is under the in?uence either directly or
indirectly of sewage discharges into the sea at various points along the
coast, which increase during summer owing to the increase of the popula-
tion. Therefore, seawater in this area may become gradually contaminated
with pathogens, organic and inorganic compounds
Seawater samples were collected from Mamaia Bay at bimonthly inter-
vals between January to December 2000. Samples were taken aseptically
from 0.3 - 0.5 m below the surface and processed within a few hours after
collection.Water temperature and salinity were assessed during the study.
Spreading technique on solid ZoBell’s medium was used for determina-
tion of heterotrophic bacteria measured duplicate (2). The number of het-
erotrophic bacteria was expressed as CFU ml
-
1
(
c
o
l
o
ny forming units) after
7 days of incubation of 21° C. For the determination of phy
s
i
o
l
o
g
i
c
a
l
groups of bacteria, gelatin (0.4%) for proteolytic bacteria, Tween 80 (0.1%)
for lipolytic bacteria, and soluble starch (0.2%) for amylolytic bacteria were
added, respectively as the sole carbon source to the basal mediu (2) .
Results and discussion
Water temperature (Table 1) and salinity ?uctuated between 3.2 – 23.8°
C and 13.69 – 17.99% respectively.Total saprophytic bacteria numbers
(Fig. 2) ranged within 5.4x 10
2
- 2.8x 10
5
CFU / ml showed distinct sea-
sonal ?uctuations, with maxima in summer ( June) and minima in winter
(January).
The distribution of saprophyte numbers was strongly correlated with the
water temperature and phytoplankton development (Fig. 2).
The specialized bacteria also showed a similar tendency.This may be
related to a greater availability of easily degradable organic compounds
and to higher temperatures. In fact, during the summer the alochtonous
inputs of organic substrates must have increased owing to the phytoplank-
ton blooms, and the substrates released by the macrophytes which are usu-
ally more readily available during this period. In addition, the sewage
out?ow increases during summer due to large number of tourists in the
Mamaia Bay.
References
1 - Azam F., Fenchel J.G., Grey J.S., Meyer-Reil L-A.,Thingstad F., 1983. The
ecological role of watercolumn microbes in the sea. Ecol. Progr. Ser., 10 :
257-263.
2 -Polczar M.J., 1957. Manual of microbiological methods. Mc Graw-Hill Co.
NewYork.
3 - Bodeanu N., 1993. Microbial blooms in the Romanian area of the Black
Sea and contemporany eutrophication conditions. In:SmaydaT.J. and Shmizu
Y. (eds.), Toxic phytoplankton blooms in the sea. Elsevier,Amsterdam, pp.
203-209.
D
I
S
T
R
I
BUTION OF HETEROT
ROPHIC MARINE BACTERIA IN THE ROMANIAN AREA OF THE BLACK SEA
Elena Stoica
National Institute for Marine Research and Development «Grigore Antipa», Constanta, Romania - estoica@alpha.rmri.ro
Abstract
During 2000 annual distribution of heterotrophic marine bacteria and seasonal characteristics were inve
s
t
i
gated in the water of the Romanian
Black Sea coast. The heterotrophic marine bacteria density (CFU on agar plates) ranged from 5.4 x 10
2
to 2.8 x 10
5
CFU ml
-
1
with a
maximum value in summer. As for the distribution of the physiological groups of bacteria (proteolytic, lipolytic, amylolytic), amylolytic
bacteria were 80% of total heterotrophic marine bacteria during the inve
s
t
i
gation period.
Keywords : bacteria, coastal waters, Black Sea
Fig.1. Location of the Mamaia Bay area
Table 1. Seasonal ?uctuation of heterotrophic bacteria (CFU / ml ,
1
*
=
Totalsaprophytes,2*=proteolyticbacteria,3*=lipolyticbacteria,
4*=amylolytic bacteria), temperature and salinity in seawater from
Month° C%01
2*
3*
4*
Jan.3.215.65.42x10
2
3.48x10
2
1.2x1020.4x10
2
Feb.4.816.848.76x10
2
5.66x10
2
2.8x1020.6x10
2
Mar.6.116.751.94x10
3
8.9x10
2
8.6x1020.9x10
2
Apr.10.414.674x10
3
1.5x10
3
2x1031.6x10
2
May1513.694.8x10
4
2.8x10
4
1.8x1048.1x10
2
Jun.20152.88x10
5
6.8x10
4
2.4x1051.8x10
5
Jul.18.517.997.8x10
4
3.8x10
4
5.6x1043.5x10
3
Aug.23.815.252.1x10
4
1.2x10
4
1.8x1042.1x10
3
Sep.19.415.833x10
4
2.4x10
4
9.8x1041.6x10
3
Oct.14.714.176.7x10
4
2.6x10
4
3.8x1041.6x10
4
Nov.12.916.418.4x10
4
6x10
4
3.4x1041.5x10
4
Fig. 2. Evolution of investigated bacteria and physico-chemical parame-
ters according to seasons (TH= total heterotrophyc bacteria, PB= prote-
olytic bacteria, AB= amylolytic bacteria, LB= lipolityc bacteria, T= tem-
