On the evolution of protamines in bony Fish: Alternatives to the “Retroviral horizontal transmission” hypothesis

Fish protamines are highly specialized molecules which are responsible for chromatin condensation during the last stages of spermatogenesis (spermiogenesis). However, not all fish contain protamines in their sperm nuclei; rather, there seems to be a random distribution of protamines within this group. The origin of this sporadic presence of protamines in the sperm and its significance have not yet been precisely determined. In this paper we have conducted an exhaustive survey of the literature available on the different types of nuclear protein composition of the sperm of teleost fish in order to try to correlate these data with what is presently known about the taxonomy of this group. The results of this analysis have allowed us to make the following observations. The divergence between protamines and histones has occurred several times during the evolution of the bony fish. However, the relative frequency of this divergence is almost negligible during the differentiation of genera and species (intrafamily variation) and is very small during the differentiation of families (interfamily variation). Nevertheless, the divergence is very noticeable among the different orders. It is therefore possible to conclude from all this that the sporadic distribution of protamines in bony fish is not a random event as initially believed. Furthermore, such a heterogeneous distribution of protamines cannot be easily accounted for by a mechanism of horizontal retroviral transmission through repeated and independent acquisition of a prot amine gene as has been recently proposed (Jankowski, Stater, Dixon (1986) J Mol Evol 23:1–10). Rather, it could possibly be explained by a repeated and independent loss of the expression of the protamine gene (or loss of the gene itself) which mainly occurred during the diversification of the orders of this group.Correspondence to: J. Ausio     

Immunogold localization of prolamines in developingHaynaldia villosa endosperm

Summary Haynaldia villosa is a wild grass belonging to the tribe Triticeae, which includes important crops such as wheat, barley, and rye. The alcohol-soluble proteins ofH. villosa have extensive immunological relatedness with wheat prolamines as visualized by Western blot analysis. Amorphous protein inclusions surrounded by a limiting membrane are commonly found in the vacuoles of endosperm and subaleurone layers ofH. villosa seeds. A layer of cells just beneath the aleurone layer is rich in ER. Unlike that in other cell types, the ER in these cells is highly dilated and contains materials at its swollen distal ends. These materials are structurally similar to substances found in the protein bodies. Protein A-gold immunocytochemical localization studies employing antibodies against wheat prolamine confirmed that the inclusions found in the lumen of the ER do not contain prolamines. This observation indicates that the ER does not act as the site of prolamine accumulation inH. villosa. Protein bodies found in the vacuoles and the vesicles associated with the Golgi complexes were specifically labeled. This suggests that Golgi complexes mediate the transport of prolamines into vacuoles ofH. villosa endosperm cells, in a fashion analogous to that of other vacuolar proteins of dicotyledonous plants.     

The α-gliadin gene family. I. Characterization of ten new wheat α-gliadin genomic clones, evidence for limited sequence conservation of flanking DNA, and Southern analysis of the gene family

 A detailed study of the organization of the wheat α-gliadin gene family is described. In the first stage of this study recombinant libraries of sufficient size and quality were constructed to allow examination of large, closely-related, gene families. A large number of α-gliadin clones were then isolated in a partial screen of these libraries. A set of these clones were sequenced and ten new gene sequences are now reported. Including these new sequences, 20 of the 27 known α-gliadin genomic and cDNA sequences are from cv Cheyenne, making this cultivar the best studied for gliadin family organization. An analysis of the DNA flanking the coding regions shows divergences which may indicate the functional ends of the α-gliadin genes. High-resolution Southern analyses on DNA from aneuploid and chromosome-substitution lines allow most of the 20 distinct α-gliadin HindIII restriction fragments in cvs Cheyenne and Chinese Spring to be assigned to specific genomes. It is estimated that as many as 150 α-gliadin genes occur in the cultivar Cheyenne, and the limitations of such estimates are discussed. Received: 1 October 1996 / Accepted: 20 December 1996