4, and the environment changed [28], [31], [32] and [33]. It is parallel changes such as these that have led
to a reconsideration of how evolution developed particularly before 0.50 Ga. Since that time the environment appears to have altered little with the exception of major physical or chemical interruptions for short periods and with very little influence on the long-term evolution of organisms. The apparent contradiction in that it appears that the major changes in variety of organisms occurred after 0.54 Ga, is resolved by the fact that the final development of chemistry of the environment and organisms by this time has permitted a huge variety of shape and sizes of organisms. There is however no change in NVP-BKM120 order the basic chemistry [34]. To explain the earlier changing nature of evolution, whilst including a sequence of small changes by mutation, to more rapid changes geneticists have drawn attention to the duplication of genes [35]. In my opinion the best chance of inspecting the early evolution invoking the duplication of proteins is to selleck chemical study the metalloproteins in different organisms. The metalloproteins are of special value in that their differences in organisms of different dates
of origin and their duplication can be related directly to dates of changes in the environment [36]. Zinc is an example of the changes. The duplication of some zinc proteins in different organisms is shown in Table 1, the greatest differences between the organisms is shown in the number of zinc finger proteins and in zinc metallo-proteases, E.C.3.4. PIK3C2G In particular animals have very many duplicates compared with plants and lower organisms. Animals also have much greater numbers of calcium signalling EF-hand proteins, Table 2. Other zinc proteins such as carbonic anhydrase have many fewer duplicates. Note that duplicates give
rise to divergent but not to convergent series. The need for many multiples of particular proteins for signalling arises from the variety of organs in organisms. For example different finger proteins are required in the expression of proteins for the different rate of construction (growth) of muscles and nerves including the brain of animals via hormones. Calcium proteins are required in signalling to cells in all these different organs in animals more than in plants or lower organisms. Zinc metalloproteases, E.C.3.4, are required in growth and maintenance of animal structures since during growth the connective tissue must be repeatedly broken and repaired. Finally we note that duplication of zinc proteins are in a different pattern of organisms from copper and iron proteins which are commonly oxidases, not hydrolases, and are notably more common in plants than animals, Table 2. The oxidases are closely linked to protection which is very different in these two classes of organisms, oxidation in plants and immune reactions in animals.