Patterns of sperm-specific histone variation in sea stars and sea urchins: primary structural homologies in the N-terminal region of spermatogenic H1.

An electrophoretic characterization of histones from pyloric caeca, testes, and sperm of Asterias vulgaris revealed a sperm/testes-specific variant of histone H1 significantly larger than its somatic counterpart from pyloric caeca. Additional proteins were observed in H1 regions of acetic acid-urea polyacrylamide gels in testicular extracts. Sperm or testis-specific variants of H2B observed in sea urchins were not found in the sea star. Evidence presented suggests that sperm- or testes-specific H1 species of intermediate mobility may arise from a single, slow-migrating H1 species (SpH1). Although an increase in nonspecific DNA binding by nuclear proteins must occur during the process of spermatogenesis, different organisms exhibit various patterns of sperm-specific protein mediating differential binding during the process. Sperm-specific variants of both H1 and H2B histones are observed in sea urchins, while the only variant observed in sea stars during spermatogenesis is SpH1. Sequencing of the N-terminus of SpH1 from A. vulgaris revealed a repeating tetrapeptide in residues 3-6 and 8-11 (Ser-Pro-Arg-Lys and Ser-Pro-Lys-Lys, respectively), homologous to repeats in the N-termini of sperm-specific H1s from sea urchins. Primary structure within critical, variable regions of molecules responsible for nonspecific DNA binding appear conserved in many organisms. The occurrence of repeating tetrapeptides in SpH1 and other DNA binding proteins suggests that such domains may function similarly in various chromatins undergoing regulated or reversible condensation.