Hence, there has been a significant focus in recent years on developing methods for the in vitro culture of those species hitherto refractory to cultivation. The finding that certain bacterial species have never been identified by culture may be a simple matter of coincidence: an organism that has a low prevalence or is particularly slow-growing may have been overlooked in cultural analyses. Additionally,
many genetically distinct phylotypes are phenotypically indistinguishable and are lumped together if conventional biochemical methods for identification are used. Conversely, some bacteria are genuinely resistant to culture in isolation on conventional media. Certain bacteria have fastidious growth requirements www.selleckchem.com/products/Adriamycin.html including the need for specific nutrients, pH conditions, incubation temperatures or levels of oxygen in the atmosphere. Kopke et al. (2005) investigated the effect of different substrates and culture conditions on the growth of bacteria from comparable samples of coastal sediments, and found that the various cultivation approaches resulted in the isolation of different groups of bacteria specific to each method, confirming the impact of cultivation conditions on the yield of culture. Thus, if the specific requirements for the growth of a bacterium are not met by the artificial medium and incubation conditions, or if there is
competition for nutrients among mixtures of organisms cultured together, some STI571 supplier bacteria may not grow. Growth may also
be inhibited by bacteriocins released from other bacteria in a mixed culture or by antibacterial substances present within the medium (Tamaki et al., 2005). In order to make the best estimate of the true diversity of the community present, multiple methods of cultivation should be used. The formation of biofilms appears to be Celecoxib an inevitable result of bacterial colonization of surfaces and has been identified in the earliest fossil records (Hall-Stoodley et al., 2004). Bacterial biofilms have many of the features of multicellular organisms and individual species within biofilms cooperate to resist external stresses (Stoodley et al., 2002). Such interactions enable the biofilm to function as a complex unit (Stoodley et al., 2002; Marsh, 2005; ten Cate, 2006). There may be cross-feeding or metabolic cooperation between species for the provision of nutrients (Belenguer et al., 2006), such as the production of lactic acid (through fermentation of carbohydrates) by Streptococcus mutans, which is utilized as a source of carbon by Veillonella spp. (Mikx & Van der Hoeven, 1975). Another key feature of biofilm communities is bacterial communication through networks of signals (Davey, 2008). These include quorum-sensing mechanisms that are involved in the regulation of the bacterial community structure, properties and survival (De Kievit et al., 2001; Konaklieva & Plotkin, 2006; ten Cate, 2006).