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The Chemistry and Fertility of Soils under Tropical Weeds   83



                           2011)  bacteria  may  live  better  in  neutral  and  alkaline  soils,  while  fungi  may  live
                           better in acidic soils.  Therefore, the decrease in soil pH may lower the populations
                           and activities of bacteria and increase those of fungi.  It has been reported recently
                           that liming at 0-5 cm top-layer of Typic Hapludox in Brazil increased not only the
                           soil pH but also the population, activity, and bacteria/fungi ratio (Garbuio et al.,
                           2011).
                              As discussed previously, soil researchers also suggest that soil pH may greatly
                           affect the soil enzymatic activities, particularly more important for phosphatases.
                           Soil pH determines the magnitude of their activities and types in soils (Malcolm,
                           1983; Nakas et al., 1987; Rojo et al., 1990; Reddy et al., 1991; Trasar-Cepeda et al.,
                           1991; Salam et al., 1998b; 1998e; Sarapatka et al., 2004).  Sarapatka et al. (2004)
                           document that acid phosphatase activity in the root zones of various species and
                           cereal  cultivars  was  negatively  correlated  with  increasing  pH  and  available
                           phosphorus level in the nutrient medium.  Frankenberger and Johanson (1982) also
                           show  the  dependence  of  other  enzymes  i.e.  urease  and  phosphodiesterase
                           activities on soil pH.   The activities of soil enzymes may change accordingly  as a
                           result of ionization and deionization of the functional sites of the enzyme proteins
                           with the increase in soil pH.
                              This  behavior  was  clearly  demonstrated  by  phosphatases  in  tropical  soils.
                           Salam et al. (1998b) treated tropical soil samples of some deforested locations in
                           West Lampung, Indonesia, at a series of buffered pH of 3 to 12.  The results are
                           shown  previously  in Fig. 4.3.  Similar patterns  were also  documented by  Trasar-
                           Cepeda et al. (1991) and Nakas et al. (1987).  Ekenler and Tabatabai (2003) suggest
                           that acid phosphatase was the most sensitive and arylsulfatase the least sensitive
                           to changes in soil pH.
                              Salam  (2014)  argues  that  the  lower  activity  of  phosphatase  at  low  pH  is
                                                          +
                           probably  due  to  the  ionization  of  H   ion  on  the  functional  groups  of  enzyme
                           proteins.    As  the  soil  pH  rises,  the  ionization  of  enzyme  functional  groups
                           progresses and so does the activity of phosphatase.  At this range of soil pH, the
                           activity  of  phosphatase  increases  with  the  increase  in  soil  pH  until  the  related
                           optimum  pH,  in  which  the  activity  of  phosphatase  is  the  highest,  the  activity
                           declines to an asymptotic value at higher pH.  The cause of this phenomenon is
                           unclear.    The  negative  effect  of  high  pH  on  the  populations  and  activities  of
                           particular enzyme producers is probable.
                              The  increasing  pattern  of  phosphatase  activities  at  low  pH  and  decreasing
                           pattern  at  higher  pH  above  the  optimum  pH  were  also  previously  reported  by
                           several  workers  (Frankenberger  and  Johanson,  1982;  Malcolm,  1983;  Trasar-

                                                          Abdul Kadir Salam and Nanik Sriyani  – 2019
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